DE202023100401U1 - Deployable quantum computer with means to enable deployment - Google Patents

Abstract

Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or portable quantum computing system (QUSYS) or in a vehicle or in a deployable weapon system,
- wherein the quantum computer (QC) comprises quantum bits and
- wherein the quantum computer (QC) comprises first means for manipulating the quantum states of quantum bits of the quantum bits and
- wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits comprise paramagnetic centers and wherein the quantum computer (QC) comprises a control device ( µC)
- to control the first funds and
- to control the second funds and
- includes for recording measurement results of the second resources and characterized in that,
- that the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) designed to
- predict changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or
- to detect changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or
- to compensate for changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or
- to reduce the effect of such changes in acceleration, in particular during a relocation of the deployable quantum computer (QC),
- where the third means in particular
• one or more acceleration sensor systems and/or acceleration sensors and/or
• one or more position displacement sensors and/or
• one or more attitude control system and/or
• one or more positioning tables and/or positioning devices and/or
• one or more image capture devices and/or image processing devices and/or
• other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits.

Description

This application claims the priority of German patent application DE 10 2022 105 465.9 of March 8, 2022.

field of invention

The invention is directed to a vehicle with a deployable quantum computer, the corresponding quantum computer and the associated deployable quantum computer system.

General introduction

Various NP-complete optimization problems arise in vehicles, and in particular military vehicles. Access to quantum computers with superconducting quantum bits via data links may be disrupted or disrupted. Then it would no longer be possible to process the corresponding civil and/or military optimization problems.

State of the art

For example, the writing presented here refers to the writings DE 10 2020 007 977 B4 , DE 10 2020 125 189 A1 , DE 10 2020 101 784 B3 , DE 10 2020 007 977 B4 and to the book Steven Prawer (Editor), Igor Aharonovich (Editor), "Quantum Information Processing with Diamond: Principles and Applications", Woodhead Publishing Series in Electronic and Optical Materials, Volume 63, Woodhead Publishing, May 8, 2014, ISBN- 10: 0857096567, ISBN-13: 978-0857096562, the contents of which, to the extent permitted by the legal system of a state in which a later internationalization of this application takes place, are part of the disclosure of the document presented here.

From a presentation by Quantum Brillance as part of the Quantum Business Network: QBN Webinar: Diamond-based Quantum Technologies for Mobile Applications. Published on 01/26/2021. URL: https://www.youtube.com/watch?v=j0SZirc7TO8 the need for mobile quantum computers and their usability for some applications is known. The Quantum Brillance presentation reproduced in the video states that NV centers would be particularly suitable. At 1:18:16, for example, the lecture refers to a technical teaching on the implementation of the mobile quantum computer similar to that in property law DE 10 2020 008 157 B3 Claim 1 described.

From a presentation by the Fraunhofer Institute IAF as part of the Quantum Business Network: QBN Webinar: Diamond-based Quantum Technologies for Mobile Applications. Published on 01/26/2021. URL: https://www.youtube.com/watch?v=jOSZirc7T08 other possible basic constructions of a quantum computer are known. The Fraunhofer Institute lecture reproduced in the video shows an example of a quantum register with crossbar structure at time 56:07. The lecture also refers to the technical teaching for the realization of the mobile quantum computer similar to that in property law DE 10 2020 008 157 B3 8th , 19 , 20 described.

The following two writings referred to this webinar:

• https://quantumbusinessnetwork.de/qbn-webinar-diamond-based-quantum-technologies-formobile-applications/ -Firmenschrift und

Quantum Business Network UG (limited liability): QBN webinar: Diamond-based Quantum Technologies for mobile applications. Munich, DE 2021. S1-3. URL:

• https://quantumbusinessnetwork.de/qbn-webinar-diamond-based-quantum-technologies-formobile-applications/ -company font and

Quantum Business Network UG (limited liability): QBN webinar: Diamond-based Quantum Technologies for mobile applications. In Zoom Webinar & YouTube livestream - 01/26/2021, p. 1-2. URL: https://quantumbusinessnetwork.de/events/qbn-webinar-diamond-based-quantumtechnologies-for-mobile-applications/.

Also from Krelina, Michal. "Quantum technology for military applications. EJP Quantum Technology, 2021, vol. 8, no. 1, p. 24 . DOI: https://doi.org/10.1140/epjqt/s40507-021-00113-y (Open Access) potential uses of a mobile quantum computer are known. The realization of such is seen as still a long way off.

An article on laptops is known from Wikipedia for the mobile energy supply of conventional computers: “Laptop” in Wikipedia, the free encyclopedia. Editing status: March 7, 2022, 20:44 UTC URL: https://en.wikipedia.org/w/index.php?title=Laptop&oldid=1075413853.

• https://en.wikipedia.org/w/index.php?title=Lithium-ion_battery&oldid=1075814088.

An article on lithium-ion batteries is known from Wikipedia for the mobile energy supply of conventional computers: "Lithium-ion battery". In: Wikipedia, the free encyclopedia. Edit status: March 7, 2022, 20:44 UTC. URL:

• https://en.wikipedia.org/w/index.php?title=Lithium-ion_battery&oldid=1075814088.

However, when testing the mobile quantum computer presented here, it became apparent that the technical teaching of the DE 10 2020 008 157 B3 alone is not sufficient, as special conditions prevail in mobile use.

All of these writings do not clarify the special conditions of mobile use.

Task

The proposal is therefore based on the task of specifying a solution for the provision of mobile quantum computers.

This object is solved by an independent claim. Further refinements are the subject of dependent claims.

solution of the task

quantum computer

This writing describes on the basis of in the DE 10 2020 101 784 B3 described technical teaching a quantum computer. The document presented here describes a quantum computer with optical readout. As an alternative or in addition to this, the document presented here describes a quantum computer with electrical readout. The quantum computer presented here is based on quantum dots. Preferably, the quantum dots include paramagnetic centers in a substrate. Preferably the substrate comprises diamond. The paramagnetic centers preferably comprise NV centers and/or SiV centers and/or TR1 centers. The quantum computer presented here preferably has an optical device. According to the technical teaching of the document presented here, the optical device is firstly used preferably for irradiating quantum dots and thus the paramagnetic centers with pump radiation. Secondly, the optical device preferably serves to extract fluorescence radiation from the quantum dots. The optical device is thus preferably used for the extraction of fluorescence radiation from paramagnetic centers. The optical device is thus preferably used for the extraction of fluorescence radiation from NV centers. An optical functional element of the device is therefore preferably a paramagnetic center in a crystal, in particular an NV center in a diamond crystal and/or a SiV center in a diamond crystal and/or a G center in a silicon crystal or a paramagnetic center in a mixed crystal from elements of the fourth main group of the periodic table. In this context, the document presented here refers to the German patent DE 10 2020 101 784 B3 , the technical teaching of which is a full part of this disclosure, insofar as this is permitted by the law of the state in which an international application for the content of the document presented here is nationalized.

Such a quantum computer preferably comprises one or more micro-integrated circuits for generating the radio frequency signals, the microwave signals, the DC voltages and control currents and for controlling the light source (LED), which serves as a pump radiation source for resetting the quantum dots of the quantum bits of the relocatable quantum computer.

All of these components of the relocatable quantum computer, including the said microintegrated circuits, are preferably accommodated on the circuit carrier, which can be designed to be particularly compact as a result.

The paper presented here discloses a deployable quantum computer. A smartphone, or a wearable quantum computing system, or a vehicle, or an autonomous vehicle, or a robot, or an airplane, or a missile, or a rocket, or a satellite, or a spacecraft, or a For example, a space station, or a buoy, or a ship, or an underwater vehicle, or an underwater buoy, or a deployable weapon system, or another mobile device may include such a deployable quantum computer. All of these devices are hereinafter referred to as vehicles for convenience. A drive unit for such systems can also include such a deployable quantum computer. Such a propulsion unit can be an electrostatic or electromagnetic motor, or an internal combustion engine, or a heat engine, or a turbine, or a jet engine, or a hypersonic engine, or a rocket engine, or a plasma engine, or an engine with a magnetic field for confining a plasma, such as from the Vasimir Project known to be. (See e.g.: Franklin R. Chang Diaz, F. Wall y Baitty, Jared P. Squire, Richard H. Goulding, Edgar A. Bering, Roger D. Bengtson, "The Vasimr Engine: Project Status and Recent Accomplishments", downloadable on 09.01.2022 from https://ntrs.nasa.gov/api/citations/20110011201/downloads/20110011201.pdf.) Deployability in the sense of the document presented here means that the claimed device is suitable and designed for this, in a short time to be moved from a first location to a second location and to be operated at both the first location and the second location and/or during the movement from the first location to the second location. Here, short time is typically a time shorter than a day, preferably shorter than 12 hours, preferably shorter than 6 hours, preferably shorter than 2 hours, better than 1 hour, preferably shorter than 30 minutes, preferably shorter than 15 minutes, preferably shorter than 5 minutes Understandable in less than 2 minutes, better understood in less than 1 minute. The time for moving the device from a first location to a second location can also be 0s if the device is ready for use almost immediately from the user's point of view and/or is permanently ready for use and simply moves, for example, i.e. remains operational during the movement. In the context of the document presented here, readiness for action means being ready for the intended use.

The paper presented here proposes a deployable quantum computer QC in a mobile device. How the document presented here understands the term mobile device is described above. A substrate D forms the core of the quantum computer QC. The substrate D preferably has one or more quantum dots NV1, NV2, NV3. The quantum bits of the quantum computer QC preferably include one or more of these quantum dots NV1, NV2, NV3. Their nature is explained in more detail below. In this context, however, the writing presented here expressly also refers to the writing DE 10 2020 007 977 B4 , the content of which is an extensive part of the disclosure content of the document submitted here, insofar as the legal system of the state in which the nationalization takes place permits this in the event of a later nationalization of a later international application.

Furthermore, the relocatable quantum computer QC presented here preferably includes a light source LD and an associated light source driver LDRV. In order to be able to influence the quantum state of the quantum dots NV1, NV2, NV3 and thus the quantum state of the quantum bits of the quantum computer QC, the proposed relocatable quantum computer QC preferably has one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the Quantum dots NV1, NV2, NV3 within the quantum bits of the quantum computer QC. The relocatable quantum computer QC preferably includes a control device μC. The control device μC preferably controls the light source driver LDRV and thus the emission of pump radiation LB with the pump radiation wavelength λ _pmp . The control device μC preferably also controls the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The control device μC preferably has a memory, one or more memories RAM, NVM. the control device μC for program commands and data. The proposed quantum computer QC preferably includes a waveform generator WFG for controlling the light source driver LDRV by means of a transmission signal S5. The control device μC preferably also controls the waveform generator WFG. The proposed quantum computer QC preferably also includes an optical system OS for irradiating the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in the substrate D with the pump radiation LB from the light source LD. Furthermore, the proposed relocatable quantum computer QC preferably comprises an optical and/or electronic quantum state readout device for reading out the current quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. In the case of an optical quantum state readout device, the quantum state readout device preferably comprises a photodetector PD and an amplifier V. In the case of an electrical quantum state readout device, the quantum state readout device preferably comprises contacts for contacting the substrate D and a voltage source for generating an extraction voltage between such contacts of the substrate D and an amplifier V to Amplification of the thus extracted photocurrent of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The amplifier V can include a transimpedance amplifier as an internal amplifier IVV. In the case includes quantum state readout device a device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferably located in the substrate D. The substrate D is preferably doped in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. This doping preferably shifts the Fermi level in the area of the quantum dots NV1, NV2, NV3 in such a way that the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are electrically charged. The substrate D is preferably n-doped in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. This n-doping preferably shifts the Fermi level in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in such a way that the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are negatively electrically charged. Typically, the waveform generator WFG generates a light source control signal S5, typically depending on the settings of the control device μC. The light source driver LDRV preferably supplies the light source LD with electrical energy as a function of the light source control signal S5 and, if appropriate, typically as a function of settings in the control device μC. The control device μC typically controls the waveform generator WFG. The light source LD at least temporarily irradiates the quantum dot or the multiple quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with pump radiation LB of the pump radiation wavelength λ _pmp by means of the optical system OS. The one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC emit fluorescence radiation FL having a fluorescence radiation wavelength λ _fl as a result of being irradiated with electromagnetic radiation having the pump radiation wavelength λ _pmp . In the case of the optical readout of the quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the photodetector PD detects at least part of the fluorescence radiation FL using the optical system OS. In this case, the photodetector PD converts at least part of the fluorescence radiation FL into a receiver output signal S0. A downstream amplifier V amplifies and, if necessary, filters the receiver output signal S0 to form a received signal S1. In the case of electronic readout of the quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC generates the received signal S1. The control device μC controls the one or more devices mWA, MW/RF-AWFG to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3. The control device µC can be used by controlling one or more devices mWA, MW/RF-AWFG to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or by controlling the emission of the light source LD Change states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The control device µC can be used by controlling one or more devices mWA, MW/RF-AWFG to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or by controlling the emission of the light source LD couple states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. For this purpose, the control device μC typically has means for generating a measured value signal S4 with one or more measured values from one or more received signals S1. In this case, the measured value signal S4 depends on quantum states of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. What is special about the quantum computer QC is that, in contrast to the prior art, the relocatable quantum computer QC and/or the mobile device has a relocatable energy supply (LDV, TS, BENG, SRG) for supplying at least some of the sub-devices of the quantum computer QC with energy. The deployable energy supply (LDV, TS, BENG, SRG) preferably has a mobile energy supply (LDV, TS, BENG) and an energy processing device SRG, in particular a voltage converter or a voltage regulator or a current regulator.

Another embodiment of the relocatable quantum computer QC preferably has not only quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, but also one or more nuclear quantum dots CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ on. In this case, the proposed deployable quantum computer QC preferably also has one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the nuclear quantum points CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ on. Typically, the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the nuclear quantum dots CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ are wholly or at least partially identical to the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3, which are then simultaneously one or more devices for generating an electromagnetic wave field am respective location of the nuclear quantum dots CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of Quantum computer QC are. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear nuclear quantum dots CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are preferably located in the common substrate D. control device μC controls the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field. The control device μC can then control the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field and/or by controlling the emission of the light source LD. or change quantum states of the nuclear quantum _dots CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. The control device µC can then, by controlling the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field and/or by controlling the emission of the light source LD, can combine quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with other quantum dots NV1 , NV2, NV3 of the quantum bits of the quantum computer QC. The control device μC can then, by driving the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field and/or by controlling the emission of the light source LD, quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC couple. The control device μC can then control the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field and/or by controlling the emission of the light source LD nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the quantum computer QC nuclear quantum bits with other nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the quantum computer nuclear bits Quantum Computer QC. The measured value signal S4 depends on quantum states of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or on states of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC.

In a further detail of the deployable quantum computer QC, the mobile energy supply (LDV, TS, BENG) supplies the energy processing device SRG with energy, with the energy processing device SRG in turn supplying other device parts of the deployable quantum computer QC with electrical energy.

In a more specific variant, the mobile energy supply (LDV, TS, BENG) includes a charging device LDV and a disconnecting device TS and an energy reserve BENG. This enables an improvement in the EMI sensitivity of the deployable quantum computer QC. (EMC = electromagnetic compatibility). For this purpose, the proposed relocatable quantum computer QC preferably has a first operating mode and a second operating mode. In the first operating mode of the deployable quantum computer QC, the separating device TS connects the charging device LDV to the energy reserve BENG, so that the charging device LDV charges the energy reserve BENG with electrical energy from an external power supply PWR in this first operating mode. In the first operating mode, the separating device TS firstly connects the charging device LDV to the energy conditioning device SRG and secondly the charging device LDV supplies the energy conditioning device SRG with electrical energy from the external energy supply PWR. In the second operating mode, firstly the disconnecting device TS preferably separates the charging device LDV from the energy reserve BENG and secondly the disconnecting device TS disconnects the charging device LDV from the energy conditioning device SRG. Thirdly, in the second operating mode, the energy reserve BENG preferably supplies the energy conditioning device SRG with electrical energy.

In a further embodiment, the deployable quantum computer QC includes a housing GH and a shield AS. The light source LD and the light source driver LDRV and the substrate D and the devices mWA, MW/RF-AWFG for generating the electromagnetic wave field and the control device µC and the memory RAM, NVM of the control device µC and the optical system OS and possibly the amplifier V and the shield AS are inside the housing GH. This protects these device parts and possibly the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the substrate D from disruptive EMC influences. Typically, the shield AS may be part of the housing GH or the housing GH itself. Preferably there are at least parts of the device parts of the energy supply (LDV, TS, BENG, SRG) of the deployable quantum computer QC or such parts of the energy supply (LDV, TS, BENG, SRG) of the deployable quantum computer QC that for a certain time an autonomous energy supply for an autonomous operation allow the relocatable quantum computer QC to be located within the common housing GH. The parts preferably have their own shielding AS.

An energy conditioning device SRG and an energy reserve BENG of the energy supply (LDV, TS, BENG, SRG) of the quantum computer QC are preferably located within the shielding AS.

So that the relocatable quantum computer QC can also be operated as a mobile quantum computer QC during the relocation, the relocatable quantum computer QC includes means for its operation, with the relocatable quantum computer QC and all the necessary means for operating this relocatable quantum computer QC being part of a mobile device. In order for this to be possible, these means for operating the relocatable quantum computer QC are typically also relocatable. For the same reason, these means for operating the relocatable quantum computer QC are preferably part of the relocatable quantum computer QC. Both the relocatable quantum computer QC and these means for operating the relocatable quantum computer QC are preferably part of the mobile device. It is typically irrelevant whether the operation of the relocatable quantum computer QC is linked to means and/or commands from outside the relocatable quantum computer QC despite the presence of all means for operating the relocatable quantum computer QC as part of the relocatable quantum computer QC.

As mentioned above, the deployable quantum computer QC is often part of a mobile device, the mobile device being in particular a smartphone or a portable quantum computer system or a vehicle or a robot or an airplane or a missile or a satellite or a spacecraft or a space station or a Floating body or a ship or an underwater vehicle or an underwater floating body or a deployable weapon system or another mobile device.

In a further embodiment, the relocatable quantum computer QC preferably includes a positioning device XT, YT. The positioning device XT, YT can preferably position the substrate D in relation to the optical system OS in such a way that the optical system OS interacts with the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field in a first position a first set of quantum dots of the quantum bits of the quantum computer QC with a first number of quantum dots of the quantum bits of the quantum computer QC and possibly a second number of nuclear quantum dots of the nuclear quantum bits of the quantum computer QC and secondly, in a second positioning, a second set of quantum dots of Can drive quantum bits of the quantum computer QC with a third number of quantum dots of the quantum bits of the quantum computer QC and possibly a fourth number of nuclear quantum dots of the nuclear quantum bits of the quantum computer QC. The control device μC preferably controls the positioning device XT, YT for the substrate D in such a way that it assumes the first positioning or the second positioning or further positioning. In this way, the relocatable quantum computer QC can always be reconfigured depending on its operating temperature during operation and/or during breaks in operation, so that it can always use a maximum of quantum dots of the quantum bits of the quantum computer QC and core quantum dots of the nuclear quantum bits of the quantum computer QC.

In a further refinement, the deployable quantum computer QC therefore has a temperature sensor ST, which determines a measured temperature value for the temperature of the substrate D or for the temperature of a partial device of the deployable quantum computer QC that is thermally connected thereto.

This results in a version of the relocatable quantum computer QC, wherein the relocatable quantum computer QC is set up and provided for this purpose, with a reduced first number of quantum dots of the quantum bits of the quantum computer QC, even at room temperature of the substrate D or a measured temperature value that has a value greater than 0° C corresponds to being able to work. At the same time, however, the relocatable quantum computer QC is also set up and intended to be able to work with an increased, third number of quantum dots of the quantum bits of the quantum computer QC at a measured temperature value that corresponds to a value less than 0°C. In this way, the relocatable quantum computer QC can always be reconfigured depending on its operating temperature during operation and/or during breaks in operation, so that it can always use a maximum of quantum dots of the quantum bits of the quantum computer QC and core quantum dots of the nuclear quantum bits of the quantum computer QC.

The document presented here therefore discloses in one form a relocatable quantum computer QC, which is set up and provided for this purpose, with a reduced second number of nuclear quantum dots of the nuclear quantum bits of the quantum computer QC to be able to work even at room temperature of the substrate D or a temperature measurement value which corresponds to a value greater than 0°C. The relocatable quantum computer QC is preferably simultaneously set up and intended to be able to work with an increased fourth number of nuclear quantum dots of the nuclear quantum bits of the quantum computer QC at a temperature measurement value that corresponds to a value less than 0°C. In this way, the relocatable quantum computer QC can always be reconfigured depending on its operating temperature during operation and/or during breaks in operation, so that it can always use a maximum of quantum dots of the quantum bits of the quantum computer QC and core quantum dots of the nuclear quantum bits of the quantum computer QC.

In a further embodiment, the deployable quantum computer QC has one or more deployable cooling devices KV, which can be deployed together with the deployable quantum computer (QC). One or more of the deployable cooling devices KV are preferably suitable and/or provided for the spin temperature of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and/or the temperature of the substrate D.

In a further embodiment, one or more such cooling devices KV reduce the temperature of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or the temperature of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and/or the temperature of the substrate D to such an extent that the relocatable quantum computer QC has an increased third compared to the reduced first number of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC Number of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC can work. One or more such cooling devices KV preferably lower the temperature of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or the temperature of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and/or the temperature of the substrate D to the extent that the quantum computer QC with a reduced second number of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC with an increased fourth number of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ the nuclear quantum bits of the quantum computer QC can work.

In a further embodiment, one or more of the deployable cooling devices KV of the quantum computer QC include one or more closed loop helium gas cooling systems HeCLCS or one or more deployable closed loop helium gas cooling systems HeCLCS include one or more deployable cooling devices KV.

In a further embodiment, the deployable quantum computer QC includes a deployable second deployable energy supply BENG2, which differs from the first deployable energy supply BENG. The second deployable energy supply BENG2 preferably supplies one or more of the deployable cooling devices KV and/or one or more of the closed-loop helium gas cooling systems HeCLCS with energy.

In another embodiment, the relocatable quantum computer QC and/or the mobile device have a mobile data interface DBIF, in particular a mobile radio data interface and/or a wired data interface.

In a further embodiment, a higher-level computer system, for example a central control device ZSE, can preferably use this data interface DBIF to control the control device µC in such a way that the control device µC of the relocatable quantum computer QC uses the relocatable quantum computer QC to carry out at least one manipulation of a state of at least one quantum bit of the quantum bits NV1, NV2, NV3 and/or to carry out at least one manipulation of a state of at least one nuclear quantum bit of the nuclear nuclear quantum bits CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ caused. In this case, the higher-level central control unit ZSE preferably controls the control device μC via the mobile data interface DBIF.

The first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 preferably include one or more batteries and/or one or more accumulators or one or more capacitors and/or one or more interconnections of several of these energy stores. The relocatable quantum computer QC and/or the mobile device preferably have a or several loading devices LDV on. Typically, one or more charging devices LDV are intended and/or provided to store energy at least temporarily in at least some or all of the rechargeable energy stores BENG, BENG2.

In one variant, the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 in the deployable quantum computer QC can comprise one or more energy storage devices that generate energy from at least one or more fluids by means of chemical and/or electrochemical processes. In this case, the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 and/or the quantum computer QC preferably have one or more storage tanks for these fluids. One or more of these storage tanks supply one or more energy stores of the quantum computer QC with one or more of these fluids, which are typically used to generate energy. One or more of the energy stores preferably include one or more galvanic cells and/or one or more fuel cells and/or one or more internal combustion engines and/or turbines and the like, each of which is coupled to one or more electrical generators and/or one or multiple thermal energy conversion machines each coupled to one or more electrical generators. One or more of the mobile energy supplies of the quantum computer QC preferably have one or more energy conditioning devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators. One or more of the energy stores preferably supply the energy processing devices SRG with energy. One or more of the energy conditioning devices SRG preferably in turn supply one or more device parts of the quantum computer QC with electrical energy that has been suitably conditioned and stabilized for the relevant device part.

In a further variant of the deployable quantum computer QC, the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores that generate energy using mechanical processes. Preferably, one or more of these energy stores then comprise one or more generators and/or one or more alternators and/or one or more electric motors that can be operated as a generator. Typically, one or more mobile energy supplies of the quantum computer QC have one or more energy conditioning devices SRG, in particular one or more voltage converters or one or more voltage regulators or one or more current regulators. One or more of the energy stores supply one or more of the energy processing devices SRG with energy. One or more of the energy processing devices SRG then preferably supply electrical energy to one or more other device parts of the deployable quantum computer QC.

In a further variant of the deployable quantum computer QC, the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 preferably comprise one or more energy stores that generate energy by converting electromagnetic radiation, in particular light, into electrical energy. For this purpose, one or more of the energy stores preferably include one or more solar cells and/or one or more functionally equivalent devices, such as PN junctions. In this case, one or more of the mobile energy supplies of the quantum computer QC preferably have one or more energy conditioning devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators. One or more of the energy stores of the energy reserve BENG, BENG2 of the quantum computer QC then typically supply one or more of the energy processing devices SRG with energy at least temporarily. One or more energy processing devices SRG then supply electrical energy to one or more other device parts of the quantum computer QC.

In a further variant of the deployable quantum computer QC, the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores that generate energy using nuclear processes. One or more of the mobile energy supplies of the quantum computer QC include one or more energy conditioning devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators. One or more of the energy stores of the energy reserve BENG, BENG2 of the quantum computer QC preferably at least temporarily supply one or more of the energy processing devices SRG with energy. One or more of these energy processing devices SRG then in turn supply one or more device parts of the deployable quantum computer QC with electrical energy.

In a further embodiment, one or more of the energy stores comprise one or more thermonuclear batteries or radionuclide batteries or one or more devices that are functionally equivalent to such a thermonuclear battery.

In a further variant, the substrate D comprises diamond. In that case, one or more of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in the substrate D are preferably defect centers and/or paramagnetic centers in diamond. One or more of the defect centers in diamond NV centers or ST1 centers or SiV centers or TR12 centers are then very particularly preferred.

Preferably, the relocatable quantum computer QC comprises one or more nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC based on isotopes with a magnetic moment µ. The nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are preferably coupled with quantum points NV1, NV2, NV3 of the quantum bits of the quantum computer QC .

The substrate D is preferably at least partially in the area of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and the quantum dots NV1 , NV2, NV3 of the quantum bits of the quantum computer QC isotopically pure. This has the advantage that the magnetic moments of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC do not couple with such parasitic magnetic moments of impurities of the substrate D. For this purpose, the isotopes of the substrate D apart from atoms that have the nuclear quantum dots CI1 ₁ , CI12, CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC form, preferably essentially no nuclear magnetic moment.

In a further embodiment, the relocatable quantum computer QC has one or more fans and/or one or more heat exchangers for exchanging heat with the environment and/or one or more heat exchangers for exchanging heat with the ambient air and/or one or more radiant coolers for exchanging heat with the ambient air or the environment by means of electromagnetic heat radiation.

In a further variant of the deployable quantum computer QC, one or more of the fans and/or one or more of the heat exchangers exchange energy in the form of heat with one or more of the deployable cooling devices KV.

In a further modification, the deployable quantum computer QC has internal shielding AS. The internal shielding AS preferably shields the substrate D with the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and possibly the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC against electromagnetic fields of the control device μC and/or the memory RAM, NVM and/or the energy supply SRG, TS, LDV, BENG, BENG2 and/or the light source driver LDRV and/or the light source LD . In a further modification, the deployable quantum computer QC has internal shielding AS. The internal shielding AS preferably shields the substrate D with the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and possibly the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC against magnetic fields of the control device μC and/or the memory RAM, NVM and/or the energy supply SRG, TS, LDV, BENG, BENG2 and/or the light source driver LDRV and/or the light source LD.

In order to be able to move the relocatable quantum computer QC, the relocatable quantum computer QC is in this case preferably equipped at least temporarily with one or more wheels or a chassis or device parts that are functionally equivalent to these and that can also be driven and/or braked.

In another embodiment, the relocatable quantum computer QC has at least temporarily one or more drive devices. According to the proposal, one or more of the drive devices is a wheel or a ship's propeller or a propeller or a turbine or a rocket engine or a drive wheel or an MHD engine. MHD stands for magnetohydrodynamic.

In configurations of the deployable quantum computer QC that are to be operated in a fluid and moved for deployments, it is expedient if, in certain applications, such a deployable quantum computer QC has aerodynamically and/or hydrodynamically shaped functional elements to reduce and/or control aerodynamic effects and/or hydrodynamic Effects and / or for generating a dynamic lift, in particular wings and / or flaps.

• - die Steuervorrichtung µC und/oder
• - der Speicher RAM, NVM der Steuervorrichtung µC und/oder
• - der Rechnerkern CPU und/oder
• - die Datenschnittstelle DBIF und/oder
• - die interne Datenschnittstelle MDBIF und/oder
• - der Lichtquellentreiber LDRV und/oder
• - der Wellenformgenerator WFG und/oder
• - der Verstärker V und/oder
• - der Fotodetektor PD und/oder
• - die erste Kameraschnittstelle CIF und/oder
• - die zweite Kameraschnittstelle CIF2 und/oder
• - die erste Kamera CM1 und/oder
• - die zweite Kamera CM2 und/oder
• - der Temperatursensor ST und/oder
• - der Mikrowellen- und/oder Radiowellenfrequenzgenerator MW/RF-AWFG zur Erzeugung weitestgehend frei vorgebbarer Wellenformen und/oder
• - die Magnetfeldsensoren MSx, MSy, MSz und /oder
• - die Magnetfeldsteuerungen MFSx, MFSy, MFSz und/oder
• - die erste Energieaufbereitungsvorrichtung SRG und/oder
• - die zweite Energieaufbereitungsvorrichtung SRG2 und/oder
• - die Energiereserve BENG und/oder
• - die zweite Energiereserve BENG2 und/oder
• - die Trennvorrichtung TS und/oder
• - die Ladevorrichtung LDV.

In some special versions of the relocatable quantum computer QC, it makes sense for electronic device parts of the quantum computer QC to be designed, at least in part, in hard-radiation electronics. Such preferably radiation-hard device parts of the quantum computer QC are, for example:

• - The control device μC and/or
• - The memory RAM, NVM of the control device μC and/or
• - the computer core CPU and/or
• - the data interface DBIF and/or
• - the internal data interface MDBIF and/or
• - the light source driver LDRV and/or
• - the waveform generator WFG and/or
• - the amplifier V and/or
• - the photodetector PD and/or
• - the first camera interface CIF and/or
• - the second camera interface CIF2 and/or
• - the first camera CM1 and/or
• - the second camera CM2 and/or
• - the temperature sensor ST and/or
• - The microwave and/or radio wave frequency generator MW/RF-AWFG for generating largely freely definable waveforms and/or
• - the magnetic field sensors MSx, MSy, MSz and/or
• - the magnetic field controls MFSx, MFSy, MFSz and/or
• - the first energy conditioning device SRG and/or
• - the second energy conditioning device SRG2 and/or
• - the energy reserve BENG and/or
• - the second energy reserve BENG2 and/or
• - the separator TS and/or
• - the loader LDV.

Radiation-hard in the sense of the document presented here means that these functional elements of the quantum computer QC are intended and/or suitable for use in space and/or in areas of increased ionizing radiation, such as nuclear reactors or the environment of thermonuclear batteries.

In many applications, it is advantageous if the relocatable quantum computer QC has a control device μC that executes a neural network model at least temporarily. The neural network model, which the control device μC typically executes, processes input values and/or the values of input signals. The neural network model, which the control device μC typically executes, outputs output signals and/or output values of output signals. The control device μC then influences states of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or preferably depending on output signals and/or output values of the neural network model that the control device μC typically executes States of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , _{CI3 2} , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. Conversely, the control device μC preferably influences the states of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or states of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC input signals and/or input values of the neural network model that the control device μC typically executes.

Thus, the document presented here discloses, inter alia, a smartphone and/or a wearable quantum computer system and/or a mobile quantum computer system and/or vehicle and/or robot and/or airplane and/or missile and/or satellite and/or a spacecraft and/or space station and/or float and/or ship and/or underwater vehicle and/or surface float and/or underwater float and/or deployable weapon system and/or warhead and/or surface or underwater vehicle and/or projectile and/or other mobile device and/or moveable Contraption. The document presented here refers to all of these below as “vehicle” for the sake of simplicity. The document presented here thus proposes a vehicle in this very broad sense, comprising a deployable quantum computer QC as previously described. Conversely, the paper presented here proposes a deployable quantum computer as previously described, which is a vehicle in the broad sense previously described.

In a further preferred variant, the quantum computer QC is intended to decrypt and/or encrypt the data communication, in particular of the control device μC, via a data interface DBIF. It is preferably the data interface DBIF of the control device μC.

Such a vehicle preferably comprises sensors and/or measuring devices in the broadest sense, the measured values about the surroundings of the vehicle and/or states of the vehicle and/or states of the vehicle occupants or users of the vehicle and/or states of the vehicle's payload to the Supply control device µC. Under certain circumstances, the control device μC also receives measured values about the surroundings of the vehicle via the data interface DBIF. The quantum computer QC and, if applicable, the control device μC can preferably determine a situation assessment for the overall condition of the vehicle and/or the environment of the vehicle as a function of such measured values. The overall condition of the vehicle within the meaning of the document presented here can include the condition of the surroundings of the vehicle and/or the condition of the vehicle occupants and/or the condition of a payload of the vehicle.

• - ein Radar-Sensor und/oder
• - ein Mikrofon und/oder
• - ein Ultraschalmikrofon und/oder
• - ein Infraschallmikrofon und/oder
• - einen Ultraschalltransducer und/oder
• - einen Infrarotsensor und/oder
• - einen Gassensor und/oder
• - einen Beschleunigungssensor und/oder
• - ein Geschwindigkeitssensor und/oder
• - einen Strahlungsdetektor und/oder
• - ein bildgebendes System und/oder
• - eine Kamera und/oder
• - eine Infrarotkamera und/oder
• - eine Multispektralkamera und/oder
• - ein LIDAR-System und/oder
• - ein Ultraschallmesssystem und/oder
• - ein Dopplerradarsystem und/oder
• - ein Quantenradarsystem und/oder
• - ein Quantensensor und/oder
• - ein Positionssensor und/oder
• - ein Navigationssystem und/oder
• - ein GPS-Sensor (oder eine funktionsäquivalente Vorrichtung) und/oder
• - ein Lagesensor und/oder
• - ein Partikelzähler und/oder
• - ein Detektionssystem für biologische Stoffe, insbesondere für biologische Kampstoffe, und/oder
• - ein Gravimeter und/oder
• - ein Kompass und/oder
• - ein Gyroskop und/oder
• - ein MEMS-Sensor und/oder
• - ein Drucksensor und/oder
• - ein Neigungswinkelsensor und/oder
• - ein Temperatursensor und/oder
• - ein Feuchtesensor und/oder
• - ein Windgeschwindigkeitssensor und/oder
• - ein Wellenfrontsensor und/oder
• - ein mikrofluidisches Messsystem und/oder
• - ein Abstandsmesssystem und/oder
• - ein Längenmesssystem und/oder
• - ein biologischer Sensor zur Detektion biologischer Marker und/oder Viren und/oder Mikroben oder dergleichen und/oder
• - ein Sensorsystem zur Erfassung biologischer Messwerte von Fahrzeuginsassen und/oder zur Erfassung biologischer Messwerte lebender Ladung, insbesondere von Tieren und/oder biologischen Materialien,
• - ein Seat-Occupation-Messystem und/oder
• - ein Spannungssensor und/oder ein Stromsensor und/oder ein Leistungssensor.

In a further form, the document presented here proposes that at least one or more sensors SENS of the vehicle is one of the following sensors SENS supplying measured values or comprises at least one of the following sensors SENS supplying measured values as a subsystem:

• - a radar sensor and/or
• - a microphone and/or
• - an ultrasonic microphone and/or
• - an infrasonic microphone and/or
• - an ultrasound transducer and/or
• - an infrared sensor and/or
• - a gas sensor and/or
• - an acceleration sensor and/or
• - a speed sensor and/or
• - a radiation detector and/or
• - an imaging system and/or
• - a camera and/or
• - an infrared camera and/or
• - a multispectral camera and/or
• - a LIDAR system and/or
• - an ultrasonic measuring system and/or
• - a Doppler radar system and/or
• - a quantum radar system and/or
• - a quantum sensor and/or
• - a position sensor and/or
• - a navigation system and/or
• - a GPS sensor (or a functionally equivalent device) and/or
• - a position sensor and/or
• - a particle counter and/or
• - a detection system for biological substances, in particular for biological warfare agents, and/or
• - a gravimeter and/or
• - a compass and/or
• - a gyroscope and/or
• - a MEMS sensor and/or
• - a pressure sensor and/or
• - an inclination angle sensor and/or
• - a temperature sensor and/or
• - a humidity sensor and/or
• - a wind speed sensor and/or
• - a wavefront sensor and/or
• - a microfluidic measuring system and/or
• - a distance measuring system and/or
• - a length measuring system and/or
• - a biological sensor for detecting biological markers and/or viruses and/or microbes or the like and/or
• - a sensor system for acquiring biological measurements of vehicle occupants and/or for acquiring biological measurements of living cargo, in particular of animals and/or biological materials,
• - a seat occupation measurement system and/or
• - a voltage sensor and/or a current sensor and/or a power sensor.

As a logical further development, the document presented here proposes a vehicle in the broad sense described above, in which the quantum computer QC controls the vehicle and/or device parts of the vehicle and/or influences a control of the vehicle or a device part of the vehicle depending on these measured values .

The document presented here also proposes a variant in which the vehicle has an interior and in which the quantum computer QC influences parameters of the interior of the vehicle and/or a device part in the interior of the vehicle depending on the measured values.

The technical teaching presented here discloses in particular that the vehicle can be a weapon system and/or that the vehicle can include a weapon system that is coupled to the quantum computer QC.

For military applications, the vehicle may include a fire control system. The fire control system can in turn include one or more quantum computers QC and/or be coupled to one or more quantum computers QC. The control of the weapon system is preferably dependent on the Fire control system at least temporarily from the quantum computer QC and its signaling. The weapon system is preferably controlled by the fire control system when the fire control system interacts with the quantum computer QC.

The vehicle preferably includes an evaluation device that classifies the intended control of the weapon system with regard to the effects to be expected before the control is carried out and determines a control command class. The evaluation device preferably prevents execution of the control or postpones this execution until it is released by a human user if the control command determined in cooperation with the quantum computer QC falls into a predefined control class.

The vehicle can, for example, identify one or more targets with the help of the deployable quantum computer QC.

The vehicle can then use the deployable quantum computer QC, for example, to classify one or more targets, in particular with the aid of a neural network program, which a control computer μC of the deployable quantum computer QC can execute, for example.

In the case of a vehicle for military purposes or a weapon system, the vehicle or the weapon system can use the quantum computer QC to determine a chronological order or prioritization of combating multiple targets.

In the case of a vehicle for military purposes or a weapon system, the vehicle or the weapon system can use the quantum computer QC to determine a point in time for attacking a target.

In the case of a vehicle for military purposes or a weapon system, the vehicle or the weapon system can use the quantum computer QC to determine a weapon type and/or ammunition for combating a target.

The document presented here proposes, among other things, a vehicle that uses the quantum computer QC to determine a route for the vehicle.

In the case of a military vehicle or weapon system, the vehicle or weapon system can use the quantum computer QC to determine a route for a weapon or warhead or missile or ammunition or other vehicle.

The document presented here also proposes, among other things, a vehicle in which the control device μC at least temporarily executes a neural network model and in which the neural network model processes input values and/or input signals and outputs output signals and/or output values. As already described above, the control device μC typically influences states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , typically as a function of output signals and/or output values of the neural network model. CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the quantum computer QC nuclear quantum bits. Typically, in this form, the control device µC influences the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC input signals and/or input values of the neural network model.

substrate

As described above, the relocatable quantum computer QC is proposed to comprise a substrate D with one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The substrate D preferably comprises diamond as the substrate material. The diamond is preferably isotopically pure or has at least one isotopically pure partial area, which preferably has the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferably paramagnetic centers. In the case when the substrate material of the material of the substrate D comprises diamond, the paramagnetic centers are preferably ST1 centers and/or preferably TR1 centers and/or very particularly preferably NV centers. This means that interference emanating from such isotopic impurities, the Funk functionality of the quantum bits or at most only slightly disturbed. In relation to diamond, this means that the diamond preferably essentially consists of ¹² C isotopes as basic isotopes. Such ¹² C isotopes have no magnetic moment that can interact with the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 1 , _{CI3 2 ,} CI3 ₃ of the nuclear quantum bits of the quantum computer QC are preferably also located in the isotopically pure region of the substrate D. When talking about isotopic purity here, the isotopes that serve as the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are at not taken into account when assessing isotopic purity. At this point, this writing expressly refers to the writing DE 10 2020 125 189 A1 , whose technical teaching for the following international procedures is part of the disclosure of this document by referencing, insofar as this is legally permissible in the relevant application countries. Isotopically pure as used in this disclosure and the DE 10 2020 125 189 A1 A material is when the concentration of isotopes other than the basic isotopes that dominate the material is so low that the technical purpose is achieved to an extent sufficient for the production and sale of products with an economically sufficient production yield. The DE 10 2020 125 189 A1 lists the relevant isotopic ratios of the relevant elements on which the technical teaching disclosed here is based. Since isotopically pure diamonds are extremely expensive, it makes sense if the substrate D comprises a diamond material and, for example, the diamond material comprises an epitaxially at least locally grown isotopically pure layer essentially made of ¹² C isotopes. This can be deposited on the original surface of a silicon wafer used as substrate D or on a diamond surface, for example by means of CVD and other deposition methods. From now on, the term substrate D includes the part of the combination of substrate D and epitaxially grown layer DEPI in which the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are manufactured. Typically this is the epitaxial layer DEPI. Essentially means that the total proportion K _1G 'of the C isotopes with a magnetic moment that are part of the substrate D, based on 100% of the C atoms that are part of the substrate D, compared to the tables in DE 10 2020 125 189 A1 specified natural total fraction K _1G to a fraction K _1G 'of the C isotopes with magnetic moment, which are part of the substrate D, based on 100% of the C isotopes, which are part of the substrate D, is reduced. This proportion K _1G 'is preferably less than 50%, better less than 20%, better less than 10%, better less than 5%, better less than 2%, better less than 1%, better less than 0.5% , better less than 0.2%, better less than 0.1% of the natural total fraction K _1G for C isotopes with magnetic moment on the C isotopes of the substrate D in the area of influence of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 _{1 , CI2 2 ,} CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. When determining the proportion K _1G ', those C atoms of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are not taken into account, since their magnetic moments are intentional and therefore not parasitic.

The use of NV centers and/or ST1 centers and/or TR12 centers or L1 centers as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC enables the operation of the quantum computer QC at room temperature and thus the ability to relocate the Quantum Computer's QC. The electron spin configuration of such a paramagnetic center serves as a quantum dot of the quantum dots NV1, NV2, NV3. of the quantum bits of the quantum computer QC. The relocatable quantum computer _QC preferably includes nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ in addition to such quantum dots NV1, NV2, NV3 as quantum bits as nuclear nuclear quantum bits. Typically, the magnetic moments of isotopes that have non-zero magnetic moments due to a nuclear spin serve as nuclear nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. Such nuclear magnetic moments of the relevant isotopes of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC preferably couple with the electron configuration of the paramagnetic centers of the Quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. In this way, a control device μC of the quantum computer QC can control the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC by manipulating the states of the quantum dots Manipulating NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The control device μC can also read the nuclear quantum states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC by means of an electrical or optical readout of the Capture quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The control device μC can also use nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , _{CI3 3} of the nuclear quantum bits of the quantum computer that are distant from one another Coupling QC with each other by means of chains of coupled quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , _{CI3 1 ,} CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC thus form nuclear nuclear quantum bits. These nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are preferably the nuclear spins of isotopes with a magnetic nuclear core moment. At this point, the writing presented here expressly refers to the writing again DE 10 2020 125 189 A1 , whose technical teaching for the following international procedures is part of the disclosure of this document by referencing, insofar as this is legally permissible in the relevant application countries. The nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , _{CI3 1 ,} CI3 ₂ , CI3 ₃ of the nuclear quantum bits are characterized by very long T2 times. Preferably, the proposed deployable quantum computer QC uses its quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to control and entangle the states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and to read out the nuclear quantum states of the nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC . The quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC can be read out optically and/or electrically. With regard to the electrical readout, this document expressly refers to the document DE 10 2020 125 189 A1 , whose technical teaching for the following international procedures is part of the disclosure of the document presented here by referencing, insofar as this is legally permissible in the relevant application countries. Another advantage of the relocatable quantum computer QC proposed here is the relatively simple usability and the better selectivity of the control of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the good scalability compared to other quantum computers.

As described above, a proposed quantum computer QC typically comprises a substrate D with one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. In addition, the substrate D preferably has one or more nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferably one or more paramagnetic centers that form one or more quantum bits. The nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are preferably one or more isotopes with a magnetic moment which form one or more nuclear quantum bits. The document presented here expressly refers to the DE 10 2020 125 189 A1 . The nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are therefore preferably the magnetic moments of isolated isotopes in the vicinity the quantum dots NV1, NV2, NV3 the quantum bits of the quantum computer QC. Proximity here means that a coupling of the magnetic moments of the isotopes concerned, which form the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC form, with the nearby quantum dot of the nearby quantum bit is possible with the device presented here.

The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC preferably have a magnetic moment of an electron configuration of the respective quantum dot. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC couple to one another preferably by means of this magnetic moment in the sense of the technical teaching of the document presented here. One or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferably paramagnetic centers in the substrate D. The Fermi level of the substrate D is preferably set in the region of a paramagnetic center used as a quantum dot in such a way that the paramagnetic center is electrically charged. The electrical charge is preferably negative. In the case of an NV center as the paramagnetic center, the NV center is preferably negatively charged. In the case of an NV center as the paramagnetic center, the NV center is thus preferably an NV ^- center. Preferably, therefore, the NV centers in the substrate D comprise NV ^- centers. A doping of the substrate D in the area of the paramagnetic center preferably ensures that the paramagnetic center is electrically charged in the intended manner. Isotopes without a magnetic moment as doping atoms preferably dope the material of the substrate D in the region of the relevant quantum dot of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. These doping atoms preferably shift the Fermi level in the region of this quantum dot without a magnetic moment. These doping atoms thus preferably shift the Fermi level in the region of the relevant paramagnetic center without a magnetic moment. The substrate D preferably comprises essentially apart from the isotopes serving as nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC, isotopes with no nuclear magnetic moment. Since the atoms of the III. Main group of the periodic table and the V. Main group of the periodic table usually have no stable isotopes without a magnetic moment, therefore the material of the substrate (D) is preferably mixtures and/or compounds of isotopes without a magnetic moment, for example isotopes of VI. Main group - eg ¹² C, ¹⁴ C, ²⁸ Si, ³⁰ Si, ⁷⁰ Ge, ⁷² Ge, ⁷⁴ Ge, ⁷⁶ Ge, ¹¹² Zn, ¹¹⁴ Zn, ¹¹⁶ Zn, ¹¹⁸ Zn, ¹²⁰ Zn, ¹²² Zn, ¹²⁴ Zn and/or the sixth Main Group ¹⁶ O, ¹⁸ O, ³² S, ³⁴ S, ³⁶ S, ⁷⁴ Se, 76 Se, ⁷⁸ Se, ⁸⁰ Se, ⁸² Se, ¹²⁰ Te, ¹²² Te, ¹²⁴ Te, ¹²⁶ Te, ^{128 Te} , ¹³⁰ Te, and /or of main group II ²⁴ Mg ^{, 26} Mg, ⁴⁰ Ca, ⁴² Ca, 44 Ca, 46 Ca, ⁴⁸ Ca, ⁸⁴ Sr, ⁸⁶ Sr, ⁸⁸ Sr ^{, 130} Ba, ¹³² Ba, ¹³⁴ Ba, ¹³⁶ Ba, ¹³⁸ Ba , and/or the II. subgroup ⁴⁶ Ti, ⁴⁸ Ti, ⁵⁰ Ti, ⁹⁰ Zr, ⁹⁰ Zr, ⁹² Zr, ⁹⁴ Zr, ⁹⁶ Zr, ¹⁷⁴ Hf, ¹⁷⁶ Hf, ¹⁷⁸ Hf, and/or the IV. subgroup ⁵⁰ Cr , ⁵² Cr, ⁵³ Cr, ⁹² Mo, ⁹⁴ Mo, ⁹⁶ Mo, ⁹⁸ Mo, ¹⁰⁰ Mo, ¹⁸⁰ W, ¹⁸² W, ¹⁸⁴ W, ¹⁸⁶ W, and/or the VI. Subgroup ⁵⁴ Fe, ⁵⁶ Fe, ⁵⁸ Fe, ⁹⁶ Ru, ⁹⁸ Ru, ¹⁰⁰ Ru, ¹⁰² Ru, ¹⁰⁴ Ru, ¹⁸⁴ Os, ¹⁸⁶ Os, ¹⁸⁸ Os, ¹⁹⁰ Os, ¹⁹² Os and/or VIII. Subgroup ⁵⁸ Ni, ⁶⁰ Ni, ⁶² Ni, ⁶⁴ Ni, ¹⁰² Pd, ¹⁰² Pd, 104 Pd ^{, 106} Pd, ¹⁰⁸ Pd, ¹¹⁰ Pd, ¹⁹⁰ Pt, ¹⁹² Pt, ¹⁹⁴ Pt, ¹⁹⁶ Pt, ¹⁹⁸ Pt and/or the X. subgroup ⁶⁴ Zn, ⁶⁶ Zn, ⁶⁸ Zn, ⁷⁰ Zn, ¹⁰⁶ Cd, 108 Cd, ¹¹⁰ Cd, ¹¹² Cd, ^{114 Cd} , ¹¹⁶ Cd, ¹⁹⁶ Hg, ¹⁹⁸ Hg, ²⁰⁰ Hg, ²⁰² Hg, ²⁰⁴ Hg and/or the lanthanides: ¹³⁶ Ce, ¹³⁸ Ce, ¹⁴⁰ Ce, ¹⁴² Ce ^, 142 Nd, ¹⁴⁴ Nd, ¹⁴⁶ Nd, ¹⁴⁸ Nd, ¹⁵⁰ Nd, 144 Sm, ¹⁴⁶ Sm, ¹⁴⁸ Sm, ¹⁵⁰ Sm, ¹⁵² Sm, ¹⁵⁴ Sm, ¹⁵² Gd, ¹⁵⁴ Gd, ^{156 Gd} , ¹⁵⁸ Gd ^{, 160} Gd, ¹⁵⁶ Dy, ¹⁵⁸ Dy, 160 Dy, ¹⁶² Dy, ¹⁶⁴ Dy, ¹⁶² He, ¹⁶⁴ He, ¹⁶⁶ He, ¹⁶⁸ He, ¹⁷⁰ He, ¹⁶⁸ Yb, ¹⁷⁰ Yb, ¹⁷² Yb, ¹⁷⁴ Yb, ¹⁷⁶ Yb, and/or the actinides ²³² Th, ²³⁴ Pa, ²³⁴ U, ²³⁸ U, ²⁴⁴ Pu. These isotopes can also be used as doping atoms for doping the substrate (D). If the substrate D comprises diamond and if the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC comprise paramagnetic centers, ³² S, ³⁴ S, ³⁶ S, ¹⁶ O and ¹⁸ O are preferred as doping isotopes for shifting the Fermi level . For the formation of NV centers in diamond as substrate D, an advantageous effect can also be observed for doping with phosphorus, but this is less optimal. The phosphorus isotopes typically exhibit a magnetic moment that interacts with the electron configuration of the paramagnetic centers. However, this interaction is typically undesirable.

Light source LD

According to the proposal, the proposed relocatable quantum computer QC preferably comprises a light source LD. The light source LD is preferably a laser that can irradiate the quantum dots NV1, NV2, NV3 of the quantum bits of the deployable quantum computer QC with pump radiation LB of a pump radiation wavelength λ _pmp . The light jellyfish LD preferably irradiates the relevant quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with pump radiation LB, which is pulse-modulated in its intensity profile over time, ie is preferably pulsed.

The light source LD can preferably emit light pulses of the pump radiation LB at light pulse start times _tsp that can be predetermined by the control device μC in relation to a reference time t _0p with a light pulse duration t _dp . A control device μC of the relocatable quantum computer preferably controls the light source LD with the aid of a light source driver LDRV via a control data bus SDB. The light source driver LDRV supplies the light source LD with energy. This energy supply to the light source LED typically depends on control commands which the light source driver LDRV receives from the control device μC via the control data bus SDB. The radiant power of the pump radiation LB emitted by the light source LD typically depends on control commands which the light source driver LDRV receives from the control device μC via the control data bus SDB, and on one or more transmission signals S5. The light source LD is preferably a semiconductor laser. The light source LED is very particularly preferably a laser diode. However, the use of an LED (light-emitting diode) as the light source LD is also conceivable. In the exemplary use of NV centers as paramagnetic centers NV1, NV2, NV3 in diamond as quantum dots of the quantum bits of the quantum computer QC, the light from the light source LD used as pump radiation LB preferably has a wavelength in a wavelength range from 400 nm to 700 nm wavelength and/or or better 450 nm to 650 nm and/or better 500 nm to 550 nm and/or better 515 nm to 540 nm. In the course of developing the technical content of this document, a wavelength of 532 nm resulted in the electromagnetic radiation of the light source used as pump radiation LB LD good results. The light source LD preferably includes a laser, which is preferably a semiconductor laser. In the case of NV centers as paramagnetic centers in diamond as the substrate D, a laser diode from Osram of the type PLT5 520B with a wavelength of 520 nm has proven itself as an exemplary light source LD for irradiating the NV centers in diamond with pump radiation LB. The proposed relocatable quantum computer QC preferably includes the said light source driver LDRV, which controls the emission of the pump radiation LB by the light source LD.

A waveform generator WFG preferably controls the light source driver LDRV and thus the light source LD by means of a transmission signal S5. The waveform generator WFG generates the transmission signal S5, preferably synchronized in time with the radio frequency and microwave signals that the microwave and/or radio wave frequency generator MW/RF-AWFG generates to generate largely freely definable waveforms (Arbitrary Wave Form Generator) and by means of a Microwave and / or radio wave antenna mWA radiates into the substrate D. The microwave and/or radio wave antenna mWA thus irradiates the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in a fixed temporal phase relationship to the light pulses of the irradiation of the irradiation of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC with pump radiation LB through the light source LD. Typically, the microwave and/or radio wave frequency generator MW/RF-AWFG synchronizes the waveform generator WFG to the transmission signal S5, preferably to the transmission signal S5. This ensures that the phase relation between the radio and microwave signals of the microwave and/or radio wave frequency generator MW/RF-AWFG on the one hand and the light pulses of the light source LD on the other hand is in a predeterminable phase relationship to one another. The computer core CPU of the control device µC of the deployable quantum computer QC preferably adjusts the operating parameters of the waveform generator WFG and the microwave and/or radio wave frequency generator MW/RF-AWFG according to the desired quantum operation in such a way that these the quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC as intended.

The light source LD preferably comprises a photodetector. The system preferably comprises light source LD and light source driver LDRV and a regulator. The photodetector PD of the light source LD can be a photodiode, for example, which typically monitors the intensity of the pump radiation LB emitted by the light source LD. The controller is preferably part of the light source driver LDRV. The light source driver LDRV preferably drives the light source LD as a function of the transmission signal S5. The controller is preferably a P controller or better an I controller or better a PI controller or better a PID controller or a controller with a frequency-optimized frequency response of the gain of the open control loop or the loop gain. The controller preferably compares the value of the measurement signal of the photodetector of the light source LD with the transmission signal S5 of the waveform generator WFG. Depending on the result of the comparison of the value of the transmission signal S5 with the value of the measurement signal of the photodetector of the light source LD, the controller of the light source LD then readjusts the intensity of the pump radiation LB. The controller of the light source LD readjusts the intensity of the pump radiation LB, preferably by changing the driver power of the light source driver LDRV. As a result, in the ideal case in the steady state, the intensity of the pump radiation LB essentially corresponds to the value of the transmission signal S5, apart from control deviations. In the ideal case, the regulator of the light source driver LDRV has an analog-to-digital converter and a data interface to the internal control data bus SDB of the relocatable quantum computer QC. In this case, the controller and/or a control computer of the light source driver LDRV and/or a control computer of the light source LD can, for example via the control data bus SDB of the relocatable quantum computer QC, transmit the data transmitted by the controller of the light source driver LDRV of the light source LD and/or the control computer of the light source LD and /or provide the controller of the light source driver LDRV with detected intensity values of the pump radiation LB of the control device μC of the deployable quantum computer QC. In this case, the regulator and/or said control computer of the light source LD and/or the control computer of the light source LD can, for example via the control data bus SDB of the deployable quantum computer QC, read the other operating parameters of the light source LD, for example by an analog-to-digital converter and /or also provide sensors within the light source LD and/or the light source driver LDRV, such as respective operating voltages, respective temperatures or the like, to the control device μC of the relocatable quantum computer QC. An amplifier of the light source LD and/or an amplifier of the light source driver LDRV preferably amplify the signal of the photodetector of the light source LD before, for example, the analog-to-digital converter of the controller of the light source driver LDRV converts this into a digital measurement signal for the controller of the light source driver LDRV Light source LD converts. The control device μC can configure, for example, the light source LD and/or the light source driver LDRV and their components via the control data bus SDB. Such configuration goals can be, for example but not limited to, the controller of the light source driver LDRV of the light source LD and its control parameters and/or the gain and/or the frequency response of the amplifier of the light source LD and/or the gain and/or the frequency response of the amplifier of the light source driver LDRV and be their parameters. The light source driver LDRV and the light source LD can form a unit. The light source driver LDRV and the light source LD can have one or more have a common control computer and/or one or more common analog-to-digital converters. For setting analog control parameters, the light source LD and/or the light source driver LD can have one or more digital-to-analog converters that provide analog control levels within the light source LD and/or the light source driver LD. The control device μC of the quantum computer QC preferably controls this digital-to-analog converter via the control data bus SDB. The possibly existing control computer of the light source LD and/or the possibly existing control computer of the LED driver LDRV can possibly also control the digital-to-analog converter.

optical system

The optical system OS preferably includes a confocal microscope. The light source LD emits the pump radiation LB. In the example of 1 the pump radiation LB passes through the dichroic mirror DBS. The optical system OS focuses the pump radiation LB on quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the focal point of the optical system OS. In this case, the optical system OS preferably uses its confocal microscope. The irradiation of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC typically causes the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to emit fluorescence radiation FL. The optical system OS typically captures at least part of the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The optical system OS feeds this detected fluorescence radiation FL to the photodetector PD via the dichroic mirror DBS. The dichroic mirror DBS or another device preferably separates the pump radiation LB and the fluorescence radiation FL from one another in such a way that essentially only fluorescence radiation FL preferably reaches the photodetector PD. Instead of a dichroic mirror DBS, the quantum computer QC proposed here can therefore also comprise a combination of a semitransparent mirror and an optical filter. In this case, the optical filter is then preferably arranged on the side of the photodetector PD relative to the semitransparent mirror. The optical filter then preferably allows radiation with the fluorescence wavelength λ _fl of the fluorescence radiation FL to pass through essentially unattenuated. In this case, the optical filter preferably essentially does not allow radiation with the pump radiation wavelength λ _pmp of the pump radiation LB to pass through. In the example of 1 the proposed quantum computer QC has a further semi-transparent or partially reflecting mirror STM. In the example of 1 the further semi-transparent or partially reflecting mirror STM divides part of the fluorescence radiation FL. The further semi-transparent or partially reflecting mirror STM feeds this divided fluorescence radiation FL to an exemplary first camera CM1. The first camera CM1 captures an image of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC emitting fluorescence radiation FL. About an exemplary first camera interface CIF and the control data bus SDB can in the example 1 the control device μC access the first camera CM1 and the captured image of the first camera CM1. For example, a user can access the image of the first camera CM1 via the external data bus EXTDB or another interface of the control device μC via the control computer μC and control parts of the quantum computer QC depending on the captured image of the first camera CM1. The computer core CPU of the control device μC can, for example, query the captured image of the first camera CM1 via the control data bus SDB and then evaluate it or store it in a memory RAM, NVM or process it in some other way. For example, the computer core CPU of the control device μC can run an image processing program. For example, the computer core CPU of the control device µC or another suitable sub-device of the quantum computer QC can, for example by evaluating the image captured by the first camera CM1, determine a mechanical offset of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in relation to the optical system OS and determine a Determine offset vector. The computer core CPU of the control device μC or the other suitable sub-device of the quantum computer QC preferably corrects this offset of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC compared to the optical system OS. For example, the computer core CPU of the control device μC or the other suitable sub-device of the quantum computer QC can eliminate the detected offset vector by means of a translational positioning device in the X direction XT and/or a translational positioning device in the Y direction YT. For this purpose, the translatory positioning device preferably moves the substrate D with the quantum ALU made of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 in the X direction XT ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the x-direction in such a way that the X-component of the detected displacement vector preferably becomes substantially 0. For example, the control device μC can preferably control the translational positioning device XT in the X direction via the control data bus SDB by means of an X control device GDX and operating parameters of the Query positioning device XT in the X direction. For this purpose, the X control device GDX for the translatory positioning device XT in the X direction is preferably connected to the control data bus SDB. In this case, the computer core CPU of the control device μC or the other suitable partial device of the quantum computer QC preferably carries out a control algorithm which corresponds to a PI or PI controller or another suitable controller. Furthermore, the translatory positioning device preferably moves the substrate D with the quantum ALU made of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the Y-direction in such a way that the Y-component of the detected displacement vector preferably becomes substantially 0. For example, the control device μC can preferably control the translational positioning device YT in the Y direction via the control data bus SDB using a Y control device GDY for the translational positioning device YT in the Y direction and query operating parameters of the positioning device YT in the Y direction. For this purpose, the Y control device GDY for the translational positioning device YT in the Y direction is preferably connected to the control data bus SDB. In this case, the computer core CPU of the control device μC or the other suitable partial device of the quantum computer QC preferably carries out a control algorithm which corresponds to a PI or PI controller or another suitable controller. The quantum computer QC preferably also has a device for refocusing. For example, the optical system OS can include a sub-device that allows the optical system OS to be displaced in the Z direction relative to the substrate D. The computer core CPU of the control device μC can preferably control this sub-device for shifting the optical system OS in the Z-direction via the control data bus STB. The computer core CPU of the control device μC can preferably access operating parameters of this sub-device for shifting the optical system OS in the Z direction via the control data bus STB and preferably automatically focus the confocal microscope of the optical system OS. The computer core CPU of the control device μC preferably readjusts the distance between the optical system OS and the substrate D via the control data bus STB in a manner dependent on the image captured by the first camera CM1, using this sub-device to shift the optical system OS in the Z-direction that the focus of the recorded images of the first camera is on the fluorescent quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and also remains in the event of mechanical disturbances. If the control device µC reduces or suppresses the fluorescence radiation FL of such quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC too far by manipulating the quantum state of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the control device µC takes into account the fluorescence radiation FL of this Quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are no longer preferred for the duration of this state of these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC when controlling the position of the substrate D in relation to the optical system OS or when controlling the focus of the optical system OS. If the control device μC enables or increases the fluorescence radiation FL of such quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to a sufficient extent by manipulating the quantum state of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the control device μC takes into account the fluorescence radiation FL these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferred again for the duration of this state of these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC when controlling the position of the substrate D in relation to the optical system OS or when controlling the focus of the optical system OS. The proposed quantum computer QC thus preferably includes one or more control loops for stabilizing the spatial position of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC relative to the focal point of the optical system OS and possibly preferably one or more control loops to stabilize the focus of the optical system OS on the quantum dots NV1, NV2, NV3 of the quantum bits of the Quantum computer QC and/or the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC of the substrate D.

If necessary, the control device μC readjusts the light source LD and/or the light source driver LDRV depending on the captured image of the first camera CM1. For this purpose, the light source driver LDRV is preferably connected to the control data bus SDB. The computer core CPU can then control the light source driver LDRV via this control data bus STB and preferably query its operating parameters. It is conceivable that the proposed quantum computer QC comprises an optical monitoring device within the light source LD and/or within the light source driver LDRV, for example a monitor photodiode with a monitor diode evaluation device associated with this monitor photodiode, which monitors the intensity of the emission of the pump radiation LB of the light source LD and its parameters recorded. The computer core CPU of the control device μC can then preferably use this via the control data bus SDB read out the recorded parameters. The control device µC and/or said optical monitoring device of the light source LD and/or the light source driver LDRV and/or another partial device of the deployable quantum computer QC can then measure the intensity of the emission of the pump radiation LB of the light source LD, for example as a function of the value of the transmission signal S5 or adjust another parameter specified by you.

The photodetector PD detects the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The photodetector PD converts the detected fluorescence radiation FL into a receiver output signal S0. An amplifier V preferably amplifies and/or filters the receiver output signal S0. The amplifier V preferably amplifies and/or filters the receiver output signal S0 as a function of the transmission signal S5. The amplifier V preferably comprises one or more analog-to-digital converters. The computer core CPU of the control device can preferably request values from these analog-to-digital converters via the control data bus SDB. An analog-to-digital converter ADCV of the amplifier, in cooperation with an internal amplifier IVV of the amplifier V, preferably converts the receiver output signal S0 into measured values of samples of the receiver output signal S0. The amplifier V is preferably connected to the control data bus SDB for this purpose. The computer core CPU of the control device STV can preferably set and/or query operating parameters of the amplifier V via the control data bus SDB. These operating parameters can be, for example, the amplification and/or filter parameters of a filter that the amplifier V carries out.

Microwave control MW/RF-AWFG, mWA

The proposed relocatable quantum computer QC preferably comprises one or more devices MW/RF-AWFG, mWA for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the quantum computer QC nuclear quantum bits. For example, such a device MW / RF-AWFG, mWA for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and / or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC one or more microwave/radio frequency generators with preferably freely selectable waveform MW/RF-AWFG and one or more via one or more waveguides antennas connected to these include mWA. These antennas mWA then generate said electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. A simple wire can already serve as an antenna mWA if the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are arranged at a sufficiently small distance from the wire. Said electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC depends on the output signals of the one or more microwave/radio frequency generators, each with a preferably freely selectable waveform MW/RF-AWFG. The control device µC preferably controls the one or more devices MW/RF-AWFG, mWA via the control data bus SDB to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , _{CI3 2 ,} CI3 ₃ of the quantum computer QC nuclear quantum bits. The transmission signal S5 preferably synchronizes the generation of the electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC by the one or more devices MW/RF-AWFG, mWA for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and /or at the respective location of the nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. For example, the transmission signal S5 can generate the electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC by the one or more devices MW/RF-AWFG, mWA for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and /or at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , _{CI3 1 ,} CI3 ₂ , Synchronize CI3 ₃ of the nuclear quantum bits of the quantum computer QC with the light source driver LDRV and thus with the emission of the pump radiation LB of the light source LD.

Control device µC

The relocatable quantum computer QC preferably includes the already mentioned control device μC with the computer core CPU. The control device μC is preferably a conventional digital computer in Von Neumann or Harvard architecture. The control device μC preferably includes a computer core CPU and preferably one or more data and program memories RAM NVM. For example, it can be an ARM controller. For example, the computer core CPU can be an ARM Cortex-A78AE for safety-critical applications. The ARM-Cortex-A78AE is characterized by including supporting device parts and functions to meet the ISO 26262 ASIL Band ASIL D safety requirements. The document presented here therefore proposes providing a computer core CPU in certain cases, which supports device parts and functions to meet the ISO 26262 ASIL volume ASIL D safety requirements or functionally equivalent standards such as IEC 61508 and/or IEC 62061:2021, EN 61511, EN 50129, EN 62304, US RTCA DO-178B, US RTCA DO-254, EUROCAE ED-12B. The data and program memory RAM NVM or the plurality of data and program memories RAM NVM can be designed entirely or partially as a non-volatile memory NVM and/or entirely or partially as a volatile memory RAM. The data and program memory of the control device μC can be read-only in whole or in part and write/readable in whole or in part. The data and program memory RAM NVM can include, for example, a RAM, an SRAM, a DRAM, a ROM, an EEPROM, a PROM, a flash memory and/or memories functionally equivalent thereto. The control device μC can include a bootstrap device for loading the start program into the data and program memory. The data and program memory RAM NVM of the control device μC can include a BIOS. The data and program memory RAM NVM of the control device μC can include a data memory and/or a program memory. The computer core CPU of the control device μC can include a data interface DBIF for communication with other computer systems, in particular with a higher-level central control unit ZSE and with user interfaces. This data interface DBIF can be wired and/or wireless. The document presented here refers to the relevant literature on data networks.

Control tasks of the control device µC

The control device μC of the proposed deployable quantum computer QC preferably also controls the intensity and modulation of the pump radiation LB and intensity modulation of the light source LD by means of its computer core μC. For this purpose, for example, the computer core CPU of the control device μC can control the time course of the intensity of the pump radiation LB emitted by the light source LD. The intensity profile over time of the pump radiation LB of the light source LD is preferably pulse-modulated. The computer core CPU of the control device μC controls the light source LED by means of the waveform generator WFG via the light source driver LDRV. The computer core CPU of the control device μC preferably controls the intensity I _P and/or the time position t _sp of the pulses and/or the time duration t _dp of the pulses of the pulsed pump radiation LB of the light source LD. The computer core CPU of the control device µC of the deployable quantum computer QC can thus determine the states of the quantum dots via this intensity I _p of the pulses of the pump radiation LB and via the time position t _sp of the pulses of the pump radiation LB and via the time duration t _dp of the pulses of the pump radiation LB Affect NV1, NV2, NV3 of the quantum bits of the proposed relocatable quantum computer QC. Therefore, via this intensity I _p of the pulses of the pump radiation LB and via the temporal position t _sp of the pulses of the pump radiation LB and via the temporal duration t _dp of the pulses of the pump radiation LB, the computer core CPU of the control device µC of the deployable quantum computer QC can determine the states of Couple quantum dots NV1, NV2, NV3 of the quantum dots of the quantum bits of the quantum computer QC. The device synchronizes these pulses of the pump radiation LB, for example by means of the computer core CPU of the control device μC and/or by means of suitable synchronizations and/or by means of synchronization signals with microwave and/or Radio signals for controlling the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the Quantum Computer's QC. Such a synchronization signal can be the transmission signal S5. These microwave and/or radio signals generated by the microwave and/or radio wave frequency generator MW/RF-AWFG also affect the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, depending on the state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC . About such influences on the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the proposed NEN relocatable quantum computer QC, the computer core CPU of the control device µC can typically also read the states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC influence and possibly the states of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC with states of quantum dots NV1, NV2, NV3 of Coupling quantum bits of the quantum computer QC. By influencing the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC of the proposed relocatable quantum computer QC, the computer core CPU of the control device µC can typically also influence the states of the nuclear quantum dots CI1, CI2, CI3 of the nuclear quantum bits of the quantum computer QC and, if necessary, coupling the states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC with one another.

Said computer core CPU of the control device µC preferably controls the one or more devices MW/RF-AWFG, mWA to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. These one or more devices MW/RF-AWFG, mWA for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC preferably generate one or more possibly overlapping electromagnetic fields at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , _{CI1 3} , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. These electromagnetic fields are preferably designed in such a way that they have a suitable frequency, in particular a microwave and/or radio wave frequency, f _HF , which is typically modulated with a time envelope curve in pulse form. The generation of the pulses of these pulsed electromagnetic fields with microwave and/or radio wave frequency f _HF is preferably synchronized in time with the generation of the pulses of the pump radiation LB of the light source LED, for example via the transmission signal S5. Such a pulse of these pulsed electromagnetic fields with microwave and/or radio wave frequency f _HF preferably begins at a pulse start time t _spHF relative to the reference time t _0HF and preferably has a pulse duration t _dHF . Said computer core CPU of the control device µC preferably controls both the one or more devices MW/RF-AWFG for generating the said electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , _{CI3 2 ,} CI3 ₃ of the quantum computer QC nuclear quantum bits. Said computer core CPU of the control device µC preferably sets the frequency of the electromagnetic field f _HF , which the one or more devices MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and generate the nuclear quantum bits of the quantum computer QC at the respective location of the nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ . Said computer core CPU preferably also provides the control device μC with a pulse start time t _spHF relative to the reference time t _0HF and, if necessary, a pulse duration t _dHF of a temporal envelope curve of the emission of an electromagnetic field by the one or more devices MW/RF-AWFG for generation an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , C13 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in pulse form. In addition, said computer core CPU of the control device μC preferably also sets the amplitude I _pHF of this pulse, which these devices MW/RF-AWFG, mWA generate.

In addition, the computer core CPU of the control device μC optionally controls other functions of the relocatable quantum computer QC and its sub-devices and methods. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the pairs of two quantum dots of two quantum bits of the quantum computer QC and the pairs of one quantum dot of one quantum bit of the quantum computer QC and one nuclear quantum dot of a nuclear quantum bit of the quantum computer QC typically have different resonance frequencies f _HF up. The reasons for this are, firstly, the different spatial distances between the quantum dots within the various pairs of two quantum dots and, secondly, the different spatial distances within the various pairs of a quantum dot and a nuclear quantum dot assigned to this quantum dot. The computer core CPU of the control device μC preferably measures this at the start of operation and/or while it is still in the factory in a test run or trial operation Resonance frequencies f _HF off. To do this, use the means described above. At this point, the writing presented here expressly refers to the writing again DE 10 2020 125 189 A1 . The computer core CPU of the control device μC stores the resonant frequency values determined in this way, preferably in a memory NVM of the control device μC, as stored resonant frequencies. This memory is preferably a non-volatile memory NVM. This has the advantage that this determination of the resonant frequencies by a scanning process with a typically step-by-step tuning of the frequency f _HF is then necessary less frequently and is not necessary every time the quantum computer QC is restarted. During operation, the computer core CPU of the control device µC uses these resonant frequencies stored in the memory NVM of the control device µC in order to set the frequency f _HF of the electromagnetic field to be generated in such a way that one or more devices MW/RF-AWFG, mWA are targeted for generating an electromagnetic field the state of a very specific quantum dot of a very specific quantum bit of the quantum computer QC and/or specifically the state of a very specific pair of quantum dots and/or a very specific pair of a quantum dot and a nuclear quantum dot can specifically affect the states of a very specific group of quantum dots. At this point, the writing presented here expressly refers to the writing again DE 10 2020 125 189 A1 .

The computer core CPU of the control device μC can preferably control the light source driver LDRV via the internal data interface MDBIF and the control data bus SDB and read out operating parameters of the light source driver LDRV such as internal temperatures, internal supply voltages etc.

The computer core CPU of the control device μC can preferably control the light source LD and read operating parameters of the light source LD, such as temperature, light emission intensity, etc., via the internal data interface MDBIF and the control data bus SDB.

The computer core CPU of the control device μC can preferably control the waveform generator WFG and read operating parameters of the waveform generator WFG via the internal data interface MDBIF and the control data bus SDB.

The computer core CPU of the control device μC can preferably control the amplifier V via the internal data interface MDBIF and the control data bus SDB and read out operating parameters of the amplifier V, such as gains and/or filter parameters.

The computer core CPU of the control device μC can preferably use the internal data interface MDBIF and the control data bus SDB to record and read out the measured values of the receiver output signal S0 of the photodetector PD, which have been amplified and filtered by the analog-to-digital converter ADCV of the amplifier V and by the amplifier V. If possible, the computer core CPU of the control device μC can preferably configure the photodetector PD via the internal data interface MDBIF and, if necessary, read out further operating parameters, such as a bias voltage or a temperature, or set the bias voltage.

The computer core CPU of the control device μC can preferably configure and read out the first camera CM1 via the internal data interface MDBIF and the control data bus SDB and a first camera interface CIF. The first camera CM1 preferably captures an image of the substrate D. The first camera CM1 preferably captures an image of the distribution of the fluorescence radiation FL of the substrate D and preferably transmits this image to the computer core CPU of the control device μC. The first camera CM1 thus preferably captures an image of the distribution of the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC of the substrate D and preferably transmits this image to the computer core CPU of the control device μC. The computer core CPU of the control device μC can thus control the first camera CM1 and read out operating parameters and data from the camera CM1.

The computer core CPU of the control device μC can control the X control device GDX for the translatory positioning device XT in the X direction, preferably via the internal data interface MDBIF and the control data bus SDB, and can read out operating parameters of the X control device GDX and adjust them if necessary.

The computer core CPU of the control device μC can preferably control the Y control device GDY for the translatory positioning device YT in the Y direction via the internal data interface MDBIF and the control data bus SDB and read out operating parameters of the Y control device GDY and adjust them if necessary.

The computer core CPU of the control device μC can preferably control the translational positioning device XT in the X direction via the internal data interface MDBIF and the control data bus SDB and via the X control device GDX and read out operating parameters of the translational positioning device XT in the X direction and adjust them if necessary.

The computer core CPU of the control device μC can preferably control the translational positioning device YT in the Y direction via the internal data interface MDBIF and the control data bus SDB and via the Y control device GDY and read out operating parameters of the translational positioning device YT in the Y direction and adjust them if necessary.

The computer core CPU of the control device μC preferably detects the position of the substrate D relative to the optical system OS. The computer core CPU of the control device µC can, for example and preferably via the internal data interface MDBIF and the control data bus SDB and via the first camera interface CIF and the first camera CIM1, preferably detect this position of the substrate D relative to the optical system OS and changes in this position of the substrate D relative to the optical system OS by means of the Y control device GDY and the translational positioning device YT in the Y direction and by means of the X control device GDX and the translational positioning device XT in the X direction in such a way that these corrections correct these changes in this position of the substrate D relative to the optical system OS undo.

The computer core CPU of the control device μC can preferably read out and optionally configure a temperature sensor ST via the internal data interface MDBIF and the control data bus SDB.

The computer core CPU of the control device μC can preferably reconfigure or operate one or more device parts of the deployable quantum computer QC via the internal data interface MDBIF and the control data bus SDB depending on the temperature detected by the temperature sensor ST. In particular, the computer core CPU of the control device µC can operate one or more fans of the quantum computer QC or functionally equivalent cooling devices such as water or oil coolers with corresponding coolant circuits or change their operating parameters in such a way that the temperature recorded by the temperature sensor TS remains within a specified temperature range. The proposed quantum computer QC can have one or more temperature sensors TS and one or more coolant circuits and/or one or more fans. All suitable fluids can be used as coolants. Air, water and oil are particularly preferred. The cooling typically serves to dissipate the waste heat from device parts of the quantum computer QC. Typically, a target temperature in the range of 0°C to 50°C is preferred. A military temperature range of -40°C to 125°C seems reasonable for military applications. Instead of a cooling device, the quantum computer QC can also have a heater for air conditioning purposes, in which case the computer core CPU of the control device µC can then control this heater, preferably via the internal data interface MDBIF and the control data bus SDB, depending on the temperature recorded by the temperature sensor ST, such that inside the quantum computer QC exceeds a minimum temperature. For example, the heating may be electrical, chemical, or thermonuclear.

The computer core CPU of the control device µC preferably detects the position of the substrate D relative to the optical system OS and the position of a permanent magnet PM relative to the substrate D. The computer core CPU of the control device µC can, for example and preferably, via the internal data interface MDBIF and the control data bus SDB and via the second camera interface CIF2 and the second camera CIM2 preferably capture this position of the substrate D relative to the optical system OS and the position of a permanent magnet PM relative to the substrate D, for example in the side view.

The computer core CPU of the control device μC can preferably configure and read out the second camera CM2 via the internal data interface MDBIF and the control data bus SDB and the second camera interface CIF2. The second camera CM2 preferably captures an image of the substrate D relative to the optical system OS and the position of a permanent magnet PM relative to the substrate D, for example in the side view. For this purpose, a light LM with a light source preferably illuminates the area that the second camera CM2 is intended to capture. The second camera CM2 preferably captures this image and preferably transmits this image to the computer core CPU of the control device μC. The computer core CPU of the control device μC can thus control the second camera CM2 and read out operating parameters and data from the second camera CM2. This second camera CM2 enables the positioning process and the positioning of the substrate D with respect to the optical system OS by means of the translational positioning device XT in the X direction and the translational positioning device YT in the Y direction in remote maintenance. To observe and check direction and, if necessary, to observe and check the positioning process and the positioning of the substrate D relative to a permanent magnet PM by means of the positioning device PV of this permanent magnet PM, without having to check the housing of the quantum computer QC. The second camera CM2 preferably transmits the image of the observed image area via the second camera interface CIF2, the control data bus SDB, the internal data interface MDBIF, the internal data bus INTDB of the control device µC, the computer core CPU of the control device µC, the external data interface DBIF of the control device µC and the external data bus EXTDB to a higher-level control unit ZSE or another computer that has a suitable man-machine interface. This man-machine interface can have a screen and a keyboard or the like, so that an operator of the quantum computer QC can make inputs here for the control of device parts of the quantum computer QC or the quantum computer QC as a whole. This or another human-machine interface can be used to display calculation results from the quantum computer QC and/or status reports from the quantum computer QC, in particular from the computer core CPU of the control device µC and/or operating parameters and/or status reports from device parts of the quantum computer QC. In particular, the man-machine interface can display images and/or video sequences from the first camera CM1 and/or the second camera CM2. These images and/or video sequences can be processed beforehand for display by the computer core CPU of the control device μC of the quantum computer QC or a computer that is connected to the deployable quantum computer QC via the external data bus EXTDB. The computer can be a central control unit ZSE. For example, they can be false-color images, image sections and distorted images and videos or the like.

The first camera CM1 and/or the second camera CM2 need not necessarily be RGB cameras. Rather, they can also be sensitive to radiation that is not visible to humans. The first camera CM1 and/or the second camera CM2 can also be multispectral cameras in order, for example, to be able to optimally observe the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The first camera CM1 preferably comprises imaging optics and an imaging photodetector circuit, for example a CCD sensor IC, and camera evaluation electronics which are coupled to the first camera interface CIF. The second camera CM2 preferably includes second imaging optics and a second imaging photodetector circuit, for example a second CCD sensor IC, and second camera evaluation electronics which are coupled to the second camera interface CIF2.

The computer core CPU of the control device μC can preferably control a control device PVC for a positioning device PV of the permanent magnet PM via the internal data interface MDBIF and the control data bus SDB and read out and, if necessary, modify operating parameters of the control device PVC for a positioning device PV of the permanent magnet PM.

For example, the computer core CPU of the control device µC can detect changes in the position of the substrate D relative to the optical system OS and the position of a permanent magnet PM relative to the substrate D, for example in the side view, preferably via the internal data interface MDBIF and the control data bus SDB, and detect such changes in the position of the Permanent magnets PM compensate again relative to the substrate D by means of a positioning device PV of the permanent magnet PV. For this purpose, the computer core CPU of the control device μC preferably uses the control device PVC for a positioning device PV of the permanent magnet PM. The computer core CPU of the control device μC can thereby preferably control the positioning device PV of the permanent magnet PM via the internal data interface MDBIF and the control data bus SDB by means of the control device PVC and read out operating parameters of the positioning device PV and modify them if necessary. In particular, the computer core CPU of the control device μC can, for example, preferably control and change the position of the permanent magnet PM via the internal data interface MDBIF and the control data bus SDB using the positioning device PV. The computer core CPU of the control device μC can preferably detect changes in the position of the permanent magnet PM relative to the substrate D using the second camera CM2 and compensate again using the positioning device PV.

The proposed quantum computer QC thus comprises first means (CM1, CM2) to detect changes in the arrangement of device parts (OS, D, PM) relative to one another, and second means (XT, YT, PV) to undo the detected changes. The first means can also include functionally equivalent sensors, in particular position sensors. The second means can also include other functionally equivalent actuators.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB, control and control a microwave and/or radio wave frequency generator MW/RF-AWFG to generate largely freely definable waveforms (Arbitrary Wave Form Generator). Read out operating parameters and adjust if necessary. In particular, the computer core CPU of the control device μC can, for example, preferably program or set the waveforms generated by the microwave and/or radio wave frequency generator MW/RF-AWFG via the internal data interface MDBIF and the control data bus SDB, or read out the set waveform.

The computer core CPU of the control device μC can, for example, preferably set and configure the microwave and/or radio wave antenna mWA via the internal data interface MDBIF and the control data bus SDB and/or read out such a configuration of the microwave and/or radio wave antenna mWA. The microwave and/or radio wave frequency generator MW/RF-AWFG typically controls the microwave and/or radio wave frequency generator MW/RF-AWFG with the microwave and/or radio wave frequency generator MW/RF-AWFG waveforms generated by the microwave and/or radio wave frequency generator MW/RF-AWFG at. The microwave and/or radio wave antenna mWA irradiates the substrate D with the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with the electromagnetic radiation corresponding to the microwave and/or radio wave frequency generator MW/RF-AWFG waveforms of the microwave and/or or radio wave frequency generator MW/RF-AWFG.

As a result, the electromagnetic radiation manipulates the quantum state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the core quantum dots according to the waveforms of the microwave and/or radio wave frequency generator MW/RF-AWFG generated by the microwave and/or radio wave frequency generator MW/RF-AWFG CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the substrate D. This allows the computer core CPU of the control device μC, for example via the internal data interface MDBIF and the control data bus SDB the quantum state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the substrate D. The computer core CPU of the control device µC can typically use the internal data interface MDBIF and the control data bus SDB by means of the waveform generator WFG and the light source driver LDRV and the light source LD, but also in a different way the quantum state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the Manipulate nuclear quantum dots CI1 ₁ , CI1 ₂ , _{CI1 3} , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in the substrate D.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB, have a cooling device KV of the substrate D and possibly in the 1 control non-illustrated auxiliary devices of the cooling device KV of the substrate D and record and read their status information. The auxiliary device for the cooling device KV of the substrate D can, for example, be what is known as a closed-loop helium gas cooling system HeCLCS, which uses helium as a coolant. The computer core CPU of the control device μC can control the closed loop helium gas cooling system HeCLCS, for example, preferably via the internal data interface MDBIF and the control data bus SDB. For example, this coolant can flow through a cooling surface as a cooling device KV, with the substrate D being fastened in a thermally conductive manner on the surface of the cooling surface serving as the cooling device KV, and with the substrate thereby being cooled by the closed-loop helium gas cooling system HeCLCS. Preferably, the translational positioning device XT in the X direction and the translational positioning device YT in the Y direction position the combination of the cooling device KV and substrate D.

The computer core CPU of the control device μC can, for example, preferably control a charging device LDV via the internal data interface MDBIF and the control data bus SDB and read out operating parameters and data from the charging device LDV. Such an operating parameter can be, for example, the voltage value of the mains voltage of the electrical supply network that supplies the charging device LDV with electrical energy.

The computer core CPU of the control device μC can, for example, preferably control a separating device TS via the internal data interface MDBIF and the control data bus SDB and read out operating parameters and data from the separating device TS. For example, the computer core CPU of the control device .mu.C, the outputs of the charging device LDV from the first energy reserve BENG and / or separate the second energy reserve BENG2 so that, firstly, it no longer charges the first energy reserve BENG and/or the second energy reserve BENG2 with electrical energy and, secondly, the other parts of the device of the quantum computer do not or only significantly less interfere. For example, the computer core CPU of the control device μC can connect the outputs of the charging device LDV to the first energy reserve BENG and/or to the second energy reserve BENG2, so that it charges the first energy reserve BENG and/or the second energy reserve BENG2 with electrical energy.

The computer core CPU of the control device μC can, for example, preferably control the first energy reserve BENG and/or read operating parameters and data from the first energy reserve BENG via the internal data interface MDBIF and the control data bus SDB. For example, the first energy reserve BENG can include a number of sub-modules which the computer core CPU of the control device μC monitors. For example, the computer core CPU of the control device μC can record the temperature of these sub-modules and/or the pressure in these sub-modules and/or the state of charge of these sub-modules. For this purpose, the first energy reserve BENG preferably includes suitable sensors, the values of which can be recorded by the computer core CPU of the control device μC. In the event of an error, the computer core CPU of the control device μC can thereby detect this error in the recorded parameters of these submodules and switch out faulty submodules from the group and bridge the resulting gap. The document presented here understands defective sub-modules and/or sub-modules with malfunctions and/or sub-modules that are presumably defective and/or presumably have malfunctions to be defective. For this purpose, the first energy reserve BENG preferably includes suitable switches and/or changeover switches, the switching state of which can be influenced by the computer core CPU of the control device μC.

In this way, the computer core CPU of the control device μC can preferably influence the energy supply of a first energy conditioning device SRG.

The computer core CPU of the control device μC can, for example, preferably control the first energy processing device SRG via the internal data interface MDBIF and the control data bus SDB and/or record and read operating parameters and data of the first energy processing device SRG. In this way, the computer core CPU of the control device μC can typically monitor and control the energy supply of the remaining device parts of the quantum computer QC.

If DMA accesses from the other device parts of the quantum computer QC are permitted, they can, for example, preferably via the internal data interface MDBIF and the control data bus SDB by means of a DMA access to the control device µC and/or the memory RAM, NVM of the control device µC and/or the the computer core CPU and/or the control device μC and the data interface DBIF and the external data bus EXTDB access devices outside of the quantum computer QC.

The possibly existing internal control computers of device parts of the quantum computer QC can, for example, preferably communicate via the control device μC and the data interface DBIF and the external data bus EXTDB with devices outside of the quantum computer QC and exchange data with these external devices. Such external devices can be, for example, control units of a motor vehicle or the like. In particular, data exchange with the Internet or a comparable data network with a large number of computer systems is conceivable. These computer systems can include, for example, a relocatable central control unit ZSE of a relocatable quantum computer system QUSYS, part of which can be the relocatable quantum computer QC.

The computer core CPU of the control device μC can read and write data to the volatile memory RAM of the control device μC. Typically, the data content of the volatile memory RAM includes program data and/or operating data and/or program instructions.

The computer core CPU of the control device μC can read the data of the non-volatile memory NVM of the control device μC. The non-volatile memory NVM of the control device μC preferably includes a writable non-volatile memory such as a flash memory. Typically, the data content of the non-volatile memory NVM includes program data and/or operational data and/or program instructions. The data content of a non-volatile and writable memory NVM preferably includes the parameters of the resonant frequencies for driving the nuclear quantum bits CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ .

The computer core CPU of the control device μC can, for example, read and/or write data to the memory RAM, NVM of the control device μC.

The computer core CPU of the control device μC can preferably access a higher-level computer system, for example a central control unit ZSE and/or the control devices of other quantum computers QC1 to QC16, via the data interface DBIF and the external data bus EXTDB.

The computer core CPU of the control device μC can access the control data bus SDB via the internal data interface MDBIF and other device parts of the relocatable quantum computer QC via this control data bus SDB.

The computer core CPU of the control device μC can, for example, preferably control the light source driver LDRV and/or read out operating parameters and data of the light source driver LDRV via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, the light intensity and other adjustable operating parameters. The data that the computer core CPU of the control device μC can read from the light source driver LDRV via the internal data interface MDBIF and the control data bus SDB can include, for example, current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values derived from them. In this way, the computer core CPU of the control device μC can typically monitor and control the light source driver LDRV of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the waveform generator WFG via the internal data interface MDBIF and the control data bus SDB and/or read operating parameters and data from the waveform generator WFG. The control data can include, for example, the data of the waveform to be generated of the transmission signal S5 of the waveform generator WFG and/or the speed/frequency of the generation of the predetermined waveform of the generated transmission signal S5 of the waveform generator WFG and other adjustable operating parameters of the waveform generator WFG. The data that the computer core CPU of the control device μC can read from the waveform generator WFG via the internal data interface MDBIF and the control data bus SDB can include, for example, current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values derived from them. Typically, this allows the computer core CPU of the control device μC to monitor and control the waveform generator WFG of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the amplifier V and/or read operating parameters and data from the amplifier V via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, the gain and/or filter parameters of the amplifier V and other adjustable operating parameters of the amplifier V. The data that the computer core CPU of the control device μC can read out of the amplifier V via the internal data interface MDBIF and the control data bus SDB can include, for example, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values derived therefrom. Typically, this allows the computer core CPU of the control device μC to monitor and control the amplifier V of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the photodetector PD via the internal data interface MDBIF and the control data bus SDB and/or read operating parameters and data from the photodetector PD. The control data can be, for example, the gain and/or filter parameters of a control circuit that may be present and integrated in the photodetector PD, which controls the actual photon-sensitive element of the photodetector PD and captures the values relevant for the detection of photons and converts them into a readable signal. The data that the computer core CPU of the control device μC can read out from the photodetector PD via the internal data interface MDBIF and the control data bus SDB can include, for example, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values derived from them. Typically, this allows the computer core CPU of the control device μC to monitor and control the photodetector PD of the quantum computer QC. In the simplest case, however, it can also be a completely passive photodetector PD without any intelligence, which only transfers an analog output signal to the amplifier V.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB and a first camera interface CIF, the first Control camera CM1 and/or read operating parameters and data from the first camera CM1. The control data can include, for example, operating parameters of the first camera CM1 such as brightness, contrast, color settings, apertures, focus, etc. of the first camera CM1 and other adjustable operating parameters of the first camera CM1. The data that the computer core CPU of the control device μC can read out from the first camera CM1 via the internal data interface MDBIF and the control data bus SDB can, for example, be the image data, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and from it include derived values. In this way, the computer core CPU of the control device μC can typically monitor and control the first camera CM1 of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the first camera interface CIF and/or read operating parameters and data from the first camera interface CIF via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the first camera interface CIF such as memory depth, DMA access parameters and other adjustable operating parameters of the first camera interface CIF. The data that the computer core CPU of the control device μC can read out from the first camera interface CIF via the internal data interface MDBIF and the control data bus SDB can, for example, be the image data of the first camera CM1, internal current levels, internal values of electrical voltages, operating temperatures, identification data such as the serial number etc. and values derived therefrom. In this way, the computer core CPU of the control device μC can typically monitor and control the first camera interface CIF of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the second camera CM2 and/or read operating parameters and data of the second camera CM2 via the internal data interface MDBIF and the control data bus SDB and a second camera interface CIF2. The control data can include, for example, operating parameters of the second camera CM2 such as brightness, contrast, color settings, apertures, focus, etc. of the second camera CM2 and other adjustable operating parameters of the second camera CM2. The data that the computer core CPU of the control device μC can read out from the second camera CM2 via the internal data interface MDBIF and the control data bus SDB can, for example, be the image data, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and from it include derived values. In this way, the computer core CPU of the control device μC can typically monitor and control the second camera CM2 of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the second camera interface CIF2 and/or read operating parameters and data from the second first camera interface CIF2 via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the second camera interface CIF2 such as memory depth, DMA access parameters and other adjustable operating parameters of the second first camera interface CIF2. The data that the computer core CPU of the control device μC can read out from the second camera interface CIF2 via the internal data interface MDBIF and the control data bus SDB can, for example, be the image data of the second camera CM2, internal current levels, internal values of electrical voltages, operating temperatures, identification data such as the serial number etc. and values derived therefrom. In this way, the computer core CPU of the control device μC can typically monitor and control the second camera interface CIF2 of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB, control a lamp with a lamp LM for illuminating the field of view of the second camera CM2 and/or read out operating parameters and data of the lamp with the lamp LM. The control data can include, for example, operating parameters of the lamp with the light source LM such as brightness, alignment and other adjustable operating parameters of the lamp with the light source LM. The data that the computer core CPU of the control device µC can read out from the lamp with the lamp LM via the internal data interface MDBIF and the control data bus SDB can include internal currents, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values derived from them include. Typically, this allows the computer core CPU of the control device μC to monitor and control the lamp with the light source LM of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control one or more temperature sensors ST via the internal data interface MDBIF and the control data bus SDB and/or read out operating parameters and data of the one or more temperature sensors ST. The control data can include, for example, operating parameters of the one or more temperature sensors ST and other adjustable operating parameters of the one or more temperature sensors ST. The data that the computer core CPU of the control device μC can read out from the one or more temperature sensors ST via the internal data interface MDBIF and the control data bus SDB can include temperature data, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc values derived therefrom. Typically, this allows the computer core CPU of the control device μC to monitor and control the one or more temperature sensors ST of the quantum computer QC and of the quantum computer QC itself.

The one temperature sensor ST or the multiple temperature sensors ST can include, for example, NTC resistors, PTC resistors, PN junctions, thermocouples (e.g. platinum/rhodium thermocouples) or the like and/or evaluation electronics as temperature-sensitive sensor elements.

If the quantum computer QC is to be used in hot or very cold environments, the quantum computer QC can have one or more heating devices and/or cooling devices for the quantum computer QC as a whole. If the quantum computer QC is to be used in hot or very cold environments, the computer core CPU of the control device µC can then, for example, preferably via the internal data interface MDBIF and the control data bus SDB, these one or more heating devices for the quantum computer QC and/or these one or more cooling devices for the quantum computer QC as a whole and/or read out operating parameters and data of these one or more heating devices and/or cooling devices for the quantum computer QC. The control data may include, for example, operating parameters of the one or more heaters and/or one or more coolers for the quantum computer QC and other adjustable operating parameters of the one or more heaters and/or coolers for the quantum computer QC. The data that the computer core CPU of the control device μC can read out from the one or more heating devices and/or cooling devices for the quantum computer QC via the internal data interface MDBIF and the control data bus SDB can include temperature data, internal current levels, internal values, electrical voltages, operating temperatures, Identification data such as the serial number etc. and values derived therefrom include. Typically, this allows the computer core CPU of the control device μC to monitor and control the one or more heating devices and/or cooling devices for the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB, control the microwave and/or radio wave frequency generator MW/RF-AWFG to generate largely freely definable waveforms and/or operating parameters and data of the microwave and/or radio wave frequency generator Read MW/RF-AWFG. The control data can be, for example, operating parameters of the microwave and/or radio wave frequency generator MW/RF-AWFG such as waveform, wave frequency, amplitude and time delay compared to a synchronization signal, such as the transmission signal S5, and other adjustable operating parameters of the microwave and/or radio wave frequency generator MW/RF -AWFG include. The data that the computer core CPU of the control device μC can read out from the microwave and/or radio wave frequency generator MW/RF-AWFG via the internal data interface MDBIF and the control data bus SDB can include internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number etc. and values etc. derived therefrom. In this way, the computer core CPU of the control device μC can typically monitor and control the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably via the internal data interface MDBIF and the control data bus SDB and via the magnetic field controllers MFSx, MFSy, MFSz control the magnetic field sensors MSx, MSy, MSz and/or read out operating parameters and data from the magnetic field sensors MSx, MSy, MSz. The control data can include, for example, operating parameters of the magnetic field sensors MSx, MSy, MSz such as sensitivity, current flow and other adjustable operating parameters of the microwave and/or radio wave frequency generator MW/RF-AWFG. The data that the processor core CPU of the control device µC can read out from the magnetic field sensors MSx, MSy, MSz via the internal data interface MDBIF and the control data bus SDB can include the measured magnetic field values, internal current strengths, internal values of electrical voltages, operating temperatures, identification data such as the serial number, etc. and values etc. derived therefrom. Typically, this can the computer core CPU of the control device μC monitors and controls the magnetic field sensors MSx, MSy, MSz of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the first magnetic field controller MFSx and/or read operating parameters and data of the first magnetic field controller MFSx via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the first magnetic field controller MFSx such as the strength of the magnetic flux density B _x to be set in the direction of the first direction, the energizing of the first magnetic field generator MGx to be set and other adjustable operating parameters of the first magnetic field controller MFSx. The data that the computer core CPU of the control device μC can read out from the first magnetic field controller MFSx via the internal data interface MDBIF and the control data bus SDB can include the measured magnetic field values, internal current strengths, internal values of electrical voltages, operating temperatures, identification data such as the serial number, etc. and derived data Values etc. include. In this way, the computer core CPU of the control device μC can typically monitor and control the first magnetic field control MFSx of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the second magnetic field controller MFSy and/or read operating parameters and data of the second magnetic field controller MFSy via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the second magnetic field control MFSy such as the strength of the magnetic flux density B _y to be set in the direction of the second direction, the current to be set for the second magnetic field generating means MGy and other adjustable operating parameters of the second magnetic field control MFSy. The data that the computer core CPU of the control device μC can read out from the second magnetic field controller MFSy via the internal data interface MDBIF and the control data bus SDB can include the measured magnetic field values, internal current strengths, internal values of electrical voltages, operating temperatures, identification data such as the serial number, etc. and derived data Values etc. include. In this way, the computer core CPU of the control device μC can typically monitor and control the second magnetic field control MFSy of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the third magnetic field controller MFSz and/or read out operating parameters and data of the third magnetic field controller MFSz via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the third magnetic field control MFSz such as the strength of the magnetic flux density B _z to be set in the direction of the third direction, the energization to be set of the third magnetic field generating means MGy and other adjustable operating parameters of the third magnetic field control MFSz. The data that the computer core CPU of the control device μC can read out from the third magnetic field controller MFSz via the internal data interface MDBIF and the control data bus SDB can include the measured magnetic field values, internal current strengths, internal values of electrical voltages, operating temperatures, identification data such as the serial number, etc. and derived data Values etc. include. In this way, the computer core CPU of the control device μC can typically monitor and control the third magnetic field control MFSz of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the first energy processing device SRG and/or read operating parameters and data of the first energy processing device SRG via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the first energy processing device SRG such as the voltage values to be supplied to other device parts and maximum current intensities and other adjustable operating parameters of the first energy processing device SRG. The data that the computer core CPU of the control device μC can read out from the first energy processing device SRG via the internal data interface MDBIF and the control data bus SDB can include internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values, etc. include. In this way, the computer core CPU of the control device μC can typically monitor and control the first energy processing device SRG of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the second energy processing device SRG2 and/or read operating parameters and data of the second energy processing device SRG2 via the internal data interface MDBIF and the control data bus SDB. The control data can, for example, be operating parameters of the second energy conditioning device SRG2, such as the voltage values and maximum currents to be supplied to other parts of the device and other adjustable operating parameters of the second energy conditioning device SRG2. The data that the computer core CPU of the control device μC can read out from the second energy processing device SRG2 via the internal data interface MDBIF and the control data bus SDB can include internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values, etc. include. In this way, the computer core CPU of the control device μC can typically monitor and control the second energy processing device SRG2 of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the energy reserve BENG and/or read out operating parameters and data from the energy reserve BENG via the internal data interface MDBIF and the control data bus SDB. If the energy reserve BENG has its own control and monitoring device, the computer core CPU of the control device μC can, for example, preferably send control data to this control and monitoring device of the energy reserve BENG via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the energy reserve BENG such as maximum temperatures, etc. The control and monitoring device for the energy reserve BENG preferably has means for monitoring important, particularly safety-related operating parameters of the energy reserve BENG. These means can include temperature sensors, voltage and current sensors or pressure sensors for measuring the internal pressure of battery cells. The data that the computer core CPU of the control device µC can read out from the energy reserve BENG via the internal data interface MDBIF and the control data bus SDB can include, for example, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values, etc., derived from this. include. In this way, the computer core CPU of the control device μC can typically monitor and control the energy reserve BENG of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the energy reserve BENG and/or read operating parameters and data from the second energy reserve BENG2 via the internal data interface MDBIF and the control data bus SDB. If the second energy reserve BENG2 has its own control and monitoring device, the computer core CPU of the control device μC can, for example, preferably send control data to this control and monitoring device of the second energy reserve BENG2 via the internal data interface MDBIF and the control data bus SDB. The control data can include operating parameters of the second energy reserve BENG2 such as maximum temperatures etc., for example. The control and monitoring device for the second energy reserve BENG2 preferably has means for monitoring important, particularly safety-related operating parameters of the second energy reserve BENG2. These means can include temperature sensors, voltage and current sensors or pressure sensors for measuring the internal pressure of battery cells. The data that the computer core CPU of the control device μC can read out from the second energy reserve BENG2 via the internal data interface MDBIF and the control data bus SDB can include, for example, internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values, etc., derived from this . In this way, the computer core CPU of the control device μC can typically monitor and control the second energy reserve BENG2 of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the separating device TS via the internal data interface MDBIF and the control data bus SDB and/or read operating parameters and data from the separating device TS. If the separating device TS has its own control and monitoring device, the computer core CPU of the control device μC can, for example, preferably send control data to this control and monitoring device of the separating device TS via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the disconnecting device TS such as the closed state (connected/disconnected), maximum temperatures, etc. The control and monitoring device of the separating device TS preferably has means for monitoring important, in particular safety-relevant, operating parameters of the separating device TS. These means can include temperature sensors, voltage and current sensors. The data that the computer core CPU of the control device μC can read out from the disconnecting device TS via the internal data interface MDBIF and the control data bus SDB can, for example, include internal current levels, internal values, electrical voltages, operating temperatures, identification data such as the serial number, etc. and values, etc., derived from this. include. Typically, this allows the computer core CPU of the control device μC to monitor and control the separating device TS of the quantum computer QC.

The computer core CPU of the control device μC can, for example, preferably control the charging device LDV and/or read operating parameters and data from the charging device LDV via the internal data interface MDBIF and the control data bus SDB. If the loading device LDV has its own control and monitoring device, the computer core CPU of the control device μC can, for example, preferably send control data to this control and monitoring device of the loading device LDV via the internal data interface MDBIF and the control data bus SDB. The control data can include, for example, operating parameters of the charging device LDV, such as the mains voltage of the power supply PWR of the charging device LDV, output voltages to be set for the charging device LDV, maximum temperatures, etc. The control and monitoring device of the separating device TS preferably has means to monitor important, in particular safety-relevant operating parameters of the charging device LDV. These means can include temperature sensors, voltage and current sensors. The data that the computer core CPU of the control device μC can read out from the charging device LDV via the internal data interface MDBIF and the control data bus SDB can, for example, be the actual mains voltage of the power supply PWR of the charging device LDV, actually set output voltages of the charging device LDV, internal currents, internal Values include electrical voltages, operating temperatures, identification data such as the serial number etc. and values etc. derived therefrom. Typically, this allows the computer core CPU of the control device μC to monitor and control the charging device LDV of the quantum computer QC.

The proposed relocatable quantum computer QC preferably has a quantum computer monitoring device QUV, which monitors the quantum computer QC while the quantum computer QC executes a quantum computer program with a quantum computer program flow, which is preferably stored in its memory RAM, NVM. In the sense of the document presented here, “monitor” is to be understood in such a way that the quantum computer monitoring device QUV is an additional device to the device parts of the quantum computer QC. The quantum computer monitoring device QUV has the function of a watchdog in relation to the control device μC. In relation to the quantum components of the quantum computer QC, however, the quantum computer monitoring device QUV has additional functions. Since the operation of the quantum components of the quantum computer QC only follows statistical laws and otherwise has non-deterministic components, the use of a conventional watchdog only makes sense for the control device µC and for the application to the quantum components of the quantum computer QC and their interaction with each other and with the control device µC and the other parts of the device of the quantum computer QC does not make sense. With the quantum computer monitoring device QUV, the document presented here presents a new additional device part that also monitors these non-deterministic parts of the quantum computer QC for defects. Under-monitoring here means the observation of the processes in the quantum computer QC and the evaluation of these observations in normal operation. The document presented here also proposes that the quantum computer monitoring device QUV can set the quantum computer QC predefined tasks between two quantum computer program calculations and can statistically evaluate the response of the quantum computer QC according to timing and content. Such a quantum computer monitoring device QUV is thus the quantum computer equivalent for a quantum computer QC to a question-and-answer watchdog for a normal processor. Thus, without the quantum computer monitoring device QUV, the quantum computer QC is still a functional quantum computer QC. In particular, the quantum computer monitoring device QUV is not a control device μC that initiates program branches and/or jumps in the quantum computer program flow as a function of detected quantum states of the quantum bits of the quantum computer. The document presented here refers to the still unpublished German patent application DE 10 2021 110 964.7 and its subsequent applications, which may have arisen as a result of priority claims. This quantum computer monitoring device QUV monitors the correct quantum computer program flow of the quantum computer program of the quantum computer QC monitors. Preferably monitors the

• - einen oder mehrere Werte von Betriebsspannungen von Vorrichtungsteilen des Quantencomputers QC,
• - einen oder mehrere Werte von Stromaufnahmen von Vorrichtungsteilen des Quantencomputers QC,
• - den Prozessortakt des Rechnerkerns CPU der Steuervorrichtung µC des Quantencomputers QC und/oder dessen Frequenz,
• - die Prozessortakte anderer Vorrichtungsteile des Quantencomputers QC und/oder deren Frequenz,
• - die Lichtabgabe der Lichtquelle LD des Quantencomputers QC, insbesondere die Intensität der Pumpstrahlung LB der Lichtquelle LD,
• - die Signalerzeugung des der Wellenformgenerators WFG des Quantencomputers QC,
• - die Funktionstüchtigkeit der Datenschnittstelle DBIF,
• - die Funktionstüchtigkeit der die internen Datenschnittstelle MDBIF,
• - die Funktionstüchtigkeit des Lichtquellentreibers LDRV,
• - die Funktionstüchtigkeit des Verstärkers V,
• - die Funktionstüchtigkeit der Fotodetektor PD,
• - die Temperatur mittels eines Temperatursensors ST,
• - die Funktionstüchtigkeit des Mikrowellen- und/oder Radiowellenfrequenzgenerators MW/RF-AWFG zur Erzeugung weitestgehend frei vorgebbarer Wellenformen,
• - die Funktionstüchtigkeit der Magnetfeldsensoren MSx, MSy, MSz,
• - die Funktionstüchtigkeit der Magnetfeldsteuerungen MFSx, MFSy, MFSz,
• - die Funktionstüchtigkeit der ersten Energieaufbereitungsvorrichtung SRG,
• - die Funktionstüchtigkeit der zweiten Energieaufbereitungsvorrichtung SRG2,
• - die Funktionstüchtigkeit der Energiereserve BENG,
• - die Funktionstüchtigkeit der zweiten Energiereserve BENG2,
• - die Funktionstüchtigkeit der Trennvorrichtung TS,
• - die Funktionstüchtigkeit der Ladevorrichtung LDV.
• - -die Detektionsfähigkeit von elektromagnetischer Strahlung eines Fotodetektors
• - -die bestimmungsgemäß korrekte Erzeugung elektromagnetischer Felder, insbesondere von Mikrowellenfeldern und/oder Radiowellenfeldern eine Vorrichtung des Quantencomputers QC zur Manipulation eines oder mehrerer Quantenbits QUB,
• - -den komplexen und/oder realen und/oder imaginären Leitwert einer Leitung und der Mikrowellen- und/oder Radiowellenantenne MWA, die Teil der Vorrichtung des Quantencomputers QC zur Manipulation eines oder mehrerer Quantenpunkte NV1, NV2, NV3 der Quantenbits des Quantencomputers QC ist.

Quantum computer monitoring device QUV monitors at least the value and/or value curve of at least one, better several and optimally all of the following operating parameters:

• - one or more values of operating voltages of device parts of the quantum computer QC,
• - one or more values of current consumptions of device parts of the quantum computer QC,
• - the processor clock of the computer core CPU of the control device µC of the quantum computer QC and/or its frequency,
• - the processor clocks of other device parts of the quantum computer QC and/or their frequency,
• - the light output of the light source LD of the quantum computer QC, in particular the intensity of the pump radiation LB of the light source LD,
• - the signal generation of the waveform generator WFG of the quantum computer QC,
• - the functionality of the data interface DBIF,
• - the functionality of the internal data interface MDBIF,
• - the functionality of the light source driver LDRV,
• - the functionality of the amplifier V,
• - the functionality of the photodetector PD,
• - the temperature by means of a temperature sensor ST,
• - the functionality of the microwave and/or radio wave frequency generator MW/RF-AWFG for generating largely freely definable waveforms,
• - the functionality of the magnetic field sensors MSx, MSy, MSz,
• - the functionality of the magnetic field controls MFSx, MFSy, MFSz,
• - the functionality of the first energy processing device SRG,
• - the functionality of the second energy processing device SRG2,
• - the functionality of the energy reserve BENG,
• - the functionality of the second energy reserve BENG2,
• - the functionality of the disconnecting device TS,
• - the functionality of the LDV charging device.
• - -the detection capability of electromagnetic radiation of a photodetector
• - -the intended correct generation of electromagnetic fields, in particular microwave fields and/or radio wave fields, a device of the quantum computer QC for manipulating one or more quantum bits QUB,
• - -the complex and/or real and/or imaginary conductance of a line and the microwave and/or radio wave antenna MWA, which is part of the device of the quantum computer QC for manipulating one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC.

If there are disturbances at these points, firstly it is no longer certain whether the quantum computer QC has determined the results of quantum computer calculations correctly, and/or secondly whether all parts of the device of the quantum computer QC are working correctly and/or thirdly whether the Quantum computer program flow of the quantum computer QC is correct, since, for example, branches and/or data and/or quantum states can be incorrect. Uncertain decisions may therefore be made.

Quantum computer overhaul device QUV

Typically, the T2 times of the quantum dots NV1, NV2, NV3 of the quantum computer QC quantum bits and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. Therefore, there are time gaps between two quantum computer calculations, during which a quantum computer monitoring device QUV of the quantum computer QC can check the functionality of the remaining quantum computer QC.

Typically, the quantum computer QC performs its quantum computer calculations within first periods of time, which are typically shorter than the T2 times of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are, by. The quantum computer monitoring device QUV preferably carries out tests of the remaining device parts of the quantum computer QC within second time periods. The first periods are preferred over the second periods different. A quantum computer calculation in the sense of this document comprises at least one quantum operation, such as an initialization of one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and/or for example the execution of a quantum gate such as a CNOT operation or a CCNOT operation or a Hadamard gate or a π pulse or an X gate Etc.

The paper presented here refers in this connection to the book by Steven Prawer (editor), Igor Aharonovich (editor), "Quantum Information Processing with Diamond: Principles and Applications", Woodhead Publishing Series in Electronic and Optical Materials, Volume 63, Woodhead Publishing , 8 May 2014, ISBN-10: 0857096567, ISBN-13: 978-0857096562.

Since the result of a quantum calculation of the quantum computer QC only delivers correct results with certain statistics, the quantum computer monitoring device QUV collects several of the results of several similar requests from the quantum computer monitoring device QUV for carrying out quantum calculations to the computer core CPU sent as a response from the rest of the quantum computer QC Quantum computer QC and evaluates them preferably statistically. If the statistics determined for the results of several similar queries from the quantum computer monitoring device QUV transmitted by the computer core CPU for carrying out quantum calculations to the computer core CPU of the quantum computer QC deviate from an expected statistic by more than x*σ, the quantum computer monitoring device QUV typically concludes that the statistic is non-statistical Quantum computer QC bug.

A non-statistical error of the quantum computer QC in the sense of the document presented here is a defect or a malfunction of a device part of the quantum computer QC and/or a loss of data and/or a data corruption and/or an unauthorized change of a quantum state of a quantum bit of the quantum computer QC, which cannot be explained by the natural statistical errors when reading out quantum states. A non-statistical error of the quantum computer QC within the meaning of the document presented here is typically also a sufficiently probable suspicion of a defect or malfunction of a device part of the quantum computer QC and/or a sufficiently probable suspicion of a loss of data and/or a sufficiently probable suspicion of data corruption and/or a sufficiently probable suspicion of an unauthorized change in a quantum state of a quantum bit of the quantum computer QC, whereby these presumed non-statistical errors cannot be explained by the natural statistical errors when reading out quantum states.

A non-statistical quantum error is a non-statistical error which, for physical reasons, cannot be reliably detected by a conventional watchdog and/or Q&A watchdog, in particular due to the quantum nature of a device part or method step involved in the non-statistical quantum error.

where σ is the standard deviation of the statistical distribution of the expected response value. x is preferably between 1 and 4. Depending on the type of non-statistical error in the execution of a quantum computer program, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds a permissible value, the quantum computer monitoring device QUV of the quantum computer QC initiates countermeasures, since the quantum monitoring device QUV then concludes that the quantum computer QC has a non-statistical error.

In the simplest case, exemplary countermeasures can include, for example, resetting and reinitializing the quantum computer QC and/or device parts of the quantum computer QC and/or starting a more extensive self-test program.

A special countermeasure can, for example, also be a translational displacement of the substrate D in relation to the optical system OS, so that other quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC communicate with other nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC the previously used quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC replaced. In which case is a reinitialization of the quantum computer QC is unavoidable. In particular, the computer core determines the CPU using the methods of DE 10 2020 007 977 B4 the resonance frequencies for driving and manipulating and entanglement of the other quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with other nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and preferably stores them in its non-volatile memory NVM and less preferably in its volatile memory RAM. For the translational displacement of the substrate D relative to the optical system OS, the computer core CPU preferably uses the translational positioning device XT of the substrate D in the X direction and the translational positioning device of the substrate D in the Y direction.

For example, the quantum computer monitoring device QUV of the quantum computer QC can also prompt the computer core CPU by means of a request message via the internal data bus INTDB to carry out a specified quantum computer calculation after a quantum computer calculation has been carried out in the first period of time and to transmit the result of the quantum computer calculation back to the quantum computer monitoring device QUV. If the relocatable quantum computer QC does not respond to the quantum computer monitoring device QUV of the relocatable quantum computer QC within a predetermined time window, then an error may be present. If the computer core CPU does not respond within a predetermined time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the relocatable quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the execution as faulty. For this purpose, the quantum computer monitoring device QUV of the relocatable quantum computer QC preferably keeps statistical records. If the statistical distribution of the contents of the responses of the computer core CPU of the control device μC of the relocatable quantum computer QC does not correspond to an expected statistical distribution, the quantum computer monitoring device QUV of the relocatable quantum computer QC preferably also concludes that there is a non-statistical error. Depending on the type of non-statistical error, the quantum computer monitoring device QUV of the relocatable quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds a permissible value, the quantum monitoring device QUV concludes that there is a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the relocatable quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

Such a test typically also checks the correct generation of electromagnetic fields, in particular microwave fields and/or radio wave fields, by a device of the deployable quantum computer QC for manipulating one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in the sense of the document presented here for example the waveform generator, the light source driver LDRV, the light source LD, the microwave and/or radio wave frequency generator MW/RF-AWFG for generating largely freely definable waveforms (Arbitrary Wave Form Generator) and the microwave and/or radio wave antenna mWA and in the broadest sense the magnetic field generating means MGx, MGy, MGz and the associated magnetic field controllers MFSx, MFSy, MFSz and the magnetic field sensors MSx, MSy, MSz. Such a test also partly tests -the complex and/or real and/or imaginary conductance of a line and the microwave and/or radio wave antenna MWA, which is part of the device of the quantum computer QC for manipulating one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU by means of a request message via the internal data bus INTDB to query one or more values of operating voltages of device parts of the quantum computer QC in the second time periods after performing a quantum computer calculation and forward to the quantum computer monitor QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. If, for example, the frequency of a certain error exceeds a permissible value, the quantum computer monitor preferably concludes a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after carrying out a quantum computer calculation in the first time periods, one or more values of power consumption of device parts of the quantum computer QC, of other device parts of the quantum computer QC in the query second time periods and pass it on to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

The clock generator OSZ of the computer core CPU of the control device μC of the quantum computer QC typically supplies the computer core CPU of the control device μC of the quantum computer QC with a clock for operating the computer core CPU of the control device μC of the quantum computer QC. The clock generator OSZ of the computer core CPU of the control device μC of the quantum computer QC can also preferably supply further digital circuits and device parts of the quantum computer QC with a clock for operating these digital circuits and device parts of the quantum computer QC.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the processor clock of the computer core CPU of the control device µC of the quantum computer QC and/or its frequency, in particular during or after the execution of a quantum computer calculation in the first time periods and/or the second time period . If an error occurs, such as an incorrect processor clock frequency or processor clock jitter, the quantum computer monitoring device QUV of the quantum computer QC assesses the processor clock as faulty. For the purpose of the document presented here, the quantum computer monitoring device QUV preferably evaluates such an error as a non-statistical error. The quantum computer monitoring device QUV of the quantum computer QC thus preferably monitors the clock generator OSZ of the computer core CPU of the control device μC of the quantum computer QC.

Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds a permissible maximum frequency value, then the quantum computer monitoring device QUV evaluates this error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitoring device QUV of the quantum computer QC preferably initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

The quantum computer monitoring device QUV of the quantum computer QC may have its own monitoring clock generator ÜOSZ. The monitoring clock generator ÜOSZ of the quantum computer monitoring device QUV of the quantum computer QC typically supplies the quantum computer monitoring device QUV of the quantum computer QC with a clock for operating the quantum computer monitoring device QUV of the quantum computer QC.

For example, the processor core CPU of the quantum computer QC can check the processor clock of the quantum computer monitoring device QUV of the quantum computer QC and/or its frequency and/or the monitoring clock generation ÜOSZ after a quantum computer calculation has been carried out in the second time periods. If an error occurs, such as an incorrect processor frequency frequency or a processor clock jitter, the processor core CPU of the quantum computer QC evaluates the processor clock of the quantum computer monitoring device QUV of the quantum computer QC as faulty. The computer core CPU of the quantum computer QC thus preferably monitors the monitoring clock generation ÜOSZ of the quantum computer monitoring device QUV of the quantum computer QC.

Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds a permissible value, the quantum computer monitoring device QUV evaluates this error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

The quantum computer monitoring device QUV preferably has a separate energy supply with preferably an additional energy reserve and its own energy conditioning device. The charging device LDV or another additional charging device preferably feeds this additional own energy processing device and/or the charging of this additional energy reserve. These optional device parts, the additional energy reserve, the additional energy conditioning device and the additional charging device and possibly an additional separating device of the quantum computer monitoring device QUV of the quantum computer QC and their connecting lines are in the 1 not shown for a better overview.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check processor takes of other device parts of the quantum computer QC and/or their frequency, in particular during or after the execution of a quantum computer calculation in the first time periods and/or the second time period. If an error occurs, such as an incorrect processor clock frequency or a processor clock jitter, the quantum computer monitoring device QUV of the quantum computer QC assesses the relevant processor clock as faulty. Thus, the quantum computer monitoring device QUV of the quantum computer QC preferably also monitors the clock generators of other device parts of the quantum computer QC. These clocks of other device parts of the quantum computer QC are in the 1 also not shown for a better overview. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error in the other processor clocks of other device parts of the quantum computer QC exceeds a permissible value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the light output of the light source LD of the quantum computer QC, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU by means of a request message via the internal data bus INTDB to query one or more values of monitor diodes of the light source LD of the quantum computer QC in the second time periods and within one after performing a quantum computer calculation in the first time periods predetermined time window to pass on to the quantum computer monitoring device QUV of the quantum computer QC. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the activation of the light source LD of the quantum computer QC by the light source driver LDRV and the functionality of the light source driver LDRV, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after carrying out a quantum computer calculation in the first time periods by means of an analog-to-digital converter or the like, one or more values of the operating parameters of the light source driver LDRV and/or or to capture one or more values of the control signals of the light source driver LDRV for the light source LD of the quantum computer QC in the second time periods and pass them on to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the generation of the transmission signal S5 by the waveform generator WFG of the quantum computer QC, in particular after a quantum computer calculation has been carried out in the second time periods. For this purpose, the quantum computer QC and/or the waveform generator WFG can include a measuring device, for example a digital storage oscilloscope or a similar signal detection device that detects the time profile of the transmission signal S5. For example, it can be an analog-to-digital converter that captures this signal profile of the transmission signal S5. For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU by means of a request message via the internal data bus INTDB to cause the waveform generator WFG of the quantum computer QC to generate a transmission signal S5 in the second time periods after a quantum computer calculation has been carried out and by means of the said signal detection device to detect the time profile of the transmission signal S5. The computer core CPU preferably evaluates the time profile of the transmission signal S5 recorded in this way and transmits the result of this evaluation to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV. It is also conceivable that the computer core CPU of the quantum computer QC transmits the detected signal profile of the transmission signal S5 to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV and then the quantum computer monitoring device QUV evaluates the recorded signal profile of the transmission signal S5. The response of the computer core CPU should be made within a predetermined time window to the quantum computer monitoring device QUV of the quantum computer QC. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the generation of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC, in particular after a quantum computer calculation has been carried out in the second time periods. For this he can Quantum computer QC and/or the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC via a measuring device, for example a digital storage oscilloscope or a similar signal acquisition device that measures the time profile of the output signal of the microwave and/or radio wave frequency generator MW/RF -AWFG captured by Quantum Computer QC. For example, it can be an analog-to-digital converter that captures this waveform of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC. For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after performing a quantum computer calculation in the first time periods, the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC in the second time periods generation of an output signal with a specific waveform for test purposes and to use said signal acquisition device to acquire the time profile of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC. The quantum computer monitoring device QUV of the quantum computer QC can also prompt the computer core CPU by means of the request message via the internal data bus INTDB to use the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC in the second time periods after a quantum computer calculation has been carried out in the first time periods generate an output signal with a specific waveform for test purposes and to use the said signal detection device to detect the amount and/or phase of the power reflected by the microwave and/or radio wave antenna MWA and thus to the impedance of the microwave and/or radio wave antenna MWA and to close its supply line and to record it. The computer core CPU preferably evaluates the recorded time profile of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC and/or the measured values recorded and transmits the result of this evaluation to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV. It is also conceivable that the computer core CPU of the quantum computer QC transmits the detected signal profile of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV and then to the quantum computer monitoring device QUV evaluates the detected signal curve of the output signal of the microwave and/or radio wave frequency generator MW/RF-AWFG of the quantum computer QC. The response of the computer core CPU should be made within a predetermined time window to the quantum computer monitoring device QUV of the quantum computer QC. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU to check the functionality of the data interface DBIF in the second time periods, in particular after a quantum computer calculation has been carried out. For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after performing a quantum computer calculation in the first time periods, to communicate via the data interface DBIF and the external data bus EXTDB with a higher-level computer system for test purposes in the second to cause periods. The higher-level computer system can be a central control unit ZSE, for example. The higher-level computer system preferably responds within a predetermined period of time with an answer that can be evaluated. The computer core CPU preferably evaluates the message received from the external computer system via the data interface DBIF and the external data bus EXTDB and transmits the result of this evaluation to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV. It is also conceivable that the computer core CPU of the quantum computer QC receives the data from the external computer system via the data interface DBIF and the external data bus EXTDB received message to the quantum computer monitoring device QUV in response to the query of the quantum computer monitoring device QUV and then the quantum computer monitoring device QUV evaluates the message received from the external computer system via the data interface DBIF and the external data bus EXTDB. The response from the computer core CPU and the higher-level computer system, for example the central control device ZSE, should preferably be sent to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the internal data interface MDBIF, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after performing a quantum computer calculation in the first time periods, to communicate via the internal data interface MDBIF and the control data bus SDB with an internal computer core of another device part of the quantum computer to prompt QC in the second periods. The internal computer core of the other device part of the quantum computer QC preferably responds within a predetermined period of time with an answer that can be evaluated. The computer core CPU preferably evaluates the message received via the internal data interface MDBIF and the internal data bus INTDB and the control data bus SDB from the internal computer core of the other device part of the quantum computer QC and transmits the result of this evaluation to the quantum computer monitoring device QUV in response to the query from the quantum computer monitoring device QUV. It is also conceivable that the computer core CPU of the quantum computer QC sends the message received via the internal data interface MDBIF and the internal data bus INTDB and the control data bus SDB from the internal computer core of the other device part of the quantum computer QC to the quantum computer monitoring device QUV in response to the request Quantum computer monitoring device QUV transmitted and then the quantum computer monitoring device QUV evaluates the message received via the internal data interface MDBIF and the internal data bus INTDB and the control data bus SDB from the internal computer core of the other device part of the quantum computer QC. The response from the computer core CPU and the internal computer core of the other device part of the quantum computer QC should preferably be made within a predetermined time window to the quantum computer monitoring device QUV of the quantum computer QC. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the amplifier V and the functionality of the photodetector PD, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC, the computer core CPU by means of a request message via the internal Cause data bus INTDB, after performing a quantum computer calculation in the first time periods, cause the light source LD of the quantum computer QC to emit a defined light or cause a test radiation source of the quantum computer QC to emit a test light emission in the second time periods, which irradiates the photodetector PD and/or the photodetector Cause PD to generate a test signal for the amplifier V in the second time periods and query the recorded values in the amplifier V and/or to record operating parameters of the amplifier V and the photodetector PD and pass them on to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

The computer core CPU of the control device μC of the quantum computer QC can typically control the preferably provided test radiation source of the quantum computer QC via the internal data bus interface MDBIF and the internal data bus INTDB and the control data bus SDB. Typically, the control device μC of the quantum computer QC can irradiate the photodetector PD of the quantum computer QC with an optical test signal, for example by means of an optical test radiation source, in order to ensure the functionality of the quantum computer QC. For a better overview, this test radiation source of the deployable quantum computer QC for irradiating the photodetector PD with test radiation is in the 1 not marked.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check temperatures within the quantum computer QC using one or more temperature sensors ST in the second time periods, in particular after a quantum computer calculation has been carried out. For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU by means of a request message via the internal data bus INTDB to record one or more temperatures within the quantum computer QC by means of one or more temperature sensors ST of the quantum computer QC after a quantum computer calculation has been carried out in the first time periods and pass on the recorded temperature readings to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the magnetic field sensors MSx, MSy, MSz and/or the functionality of the magnetic field controls MFSx, MFSy, MFSz and/or the functionality of the Check magnetic field generating means MGx, MGy, MGz. For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU by means of a request message via the internal data bus INTDB to carry out a quantum computer calculation in the first time periods by means of the magnetic field controls MFSx, MFSy, MFSz and the magnetic field generating means MGx, MGy, MGz of the quantum computer QC magnet to set ic flux densities and to record them by means of the magnetic field sensors MSx, MSy, MSz and to pass on the measured values recorded to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the first energy conditioning device SRG and/or the functionality of the second energy conditioning device SRG2 and/or the functionality of the other energy conditioning devices, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC can use a request message via the internal data bus INTDB to cause the computer core CPU to supply certain supply voltages after a quantum computer calculation has been carried out in the first time periods using the first energy conditioning device SRG and/or the second energy conditioning device SRG2 and/or the other energy conditioning devices to adjust and/or modify device parts of the quantum computer QC and to forward their voltage values and/or current values by means of measuring devices, for example, and to forward the measured values recorded to the quantum computer monitoring device QUV of the quantum computer QC within a predetermined time window. If the computer core CPU does not respond within a specified time window after the query by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring device QUV of the quantum computer QC evaluates the Execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the energy reserve BENG and/or the functionality of the second energy reserve BENG2 and/or the functionality of any other energy reserves or other parts of the device, in particular after a quantum computer calculation has been carried out in the second time periods or to check already named device parts of the quantum computer QC. For example, the quantum computer monitoring device QUV of the quantum computer QC can prompt the computer core CPU by means of a request message via the internal data bus INTDB, after carrying out a quantum computer calculation in the first time periods by means of charging devices, such as the charging device LDV already mentioned, the state of charge of the energy reserve BENG and/or the To change the functionality of the second energy reserve BENG2 and/or the functionality of any other energy reserves or other parts of the device and to record the values of the respective current consumption and the voltage curve using suitable measuring equipment of the quantum computer QC and thus, for example, to conclude the impedance of these energy reserves. In this case, the quantum computer monitoring device QUV of the quantum computer QC causes the computer core CPU to pass on the measured values within a specified time window to the quantum computer monitoring device QUV of the quantum computer QC via the internal data bus INTDB using the said request message. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with values that are within expected value ranges, the quantum computer monitoring calculation device QUV of the quantum computer QC the execution as faulty. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

For example, the quantum computer monitoring device QUV of the quantum computer QC can cause the computer core CPU to check the functionality of the separating device TS of the quantum computer QC and the functionality of the charging device LDV of the quantum computer QC, in particular after a quantum computer calculation has been carried out in the second time periods. For example, the quantum computer monitoring device QUV of the quantum computer QC can use a request message via the internal data bus INTDB to cause the computer core CPU to open the separating device TS after a quantum computer calculation has been carried out in the first time periods and, using the charging devices, such as the charging device LDV already mentioned, to check the state of charge of the of the energy reserve BENG and/or the functional capability of the second energy reserve BENG2 and/or the functional capability of any other energy reserves or any other device parts and in doing so to record the values of the respective current consumption and the voltage curve using suitable measuring equipment of the quantum computer QC and the disconnecting device TS close and by means of the charging devices, such as the already named charging device LDV, the state of charge of the energy reserve BENG and / or the functionality of the second energy reserve BENG2 and / or the functional to change the ability of any other energy reserves or any other parts of the device again and to record second values of the respective current consumption and the voltage curve using suitable measuring equipment of the quantum computer QC. In this case, the quantum computer monitoring device QUV of the quantum computer QC causes the computer core CPU to forward the recorded measured values and the second measured value to the quantum computer monitoring device QUV of the quantum computer QC via the internal data bus INTDB within a specified time window by means of the said request message. If the computer core CPU does not respond within a specified time window after the request was made by the quantum computer monitoring device QUV of the quantum computer QC to the computer core CPU of the control device µC of the quantum computer QC with first and second values that are within expected value ranges, the quantum computer monitoring device QUV des Quantum Computer's QC the execution as buggy. Depending on the type of error, the quantum computer monitoring device QUV of the quantum computer QC initiates a countermeasure or changes the database of a statistical evaluation. For example, if the frequency of a specific error exceeds an allowable value, the quantum computer monitoring device QUV evaluates the error as a non-statistical error. In the event of a non-statistical error, the quantum computer monitor QUV of the quantum computer QC typically initiates countermeasures. These can be the countermeasures already described in the document presented here or other countermeasures.

Quantum computer system QSYS

If the proposed relocatable quantum computer QC is integrated into a quantum computer system QUSYS with a second, preferably mobile quantum computer QC2, it is advantageous if signaling, in particular of a quantum computer calculation result, is sent from the quantum computer QC via at least one signal connection, for example an external data bus EXTDB, to the second Quantum computer QC2 and / or vice versa.

The relocatable quantum computer system QUSYS preferably comprises at least two quantum computers, a first relocatable quantum computer QC1 and a second relocatable quantum computer QC2, with a plurality of measuring devices for detecting operating variables of the quantum computer system QUSYS or a device or a system. The states of the device or the system may typically depend on the quantum computer system QUSYS, with the first relocatable quantum computer QC1 preferably performing at least two times the same quantum computer calculation that the second relocatable quantum computer QC2 performs. In this case, the quantum computer calculation preferably includes a monitoring measure for checking the functionality of the respective relocatable quantum computer QC1, QC2. In this case, the first relocatable quantum computer QC1 preferably carries out the quantum computer calculation of the first relocatable quantum computer QC1 independently of performing the quantum computer calculation of the second deployable quantum computer QC2. This enables the comparison of the results of the quantum computer calculations by the computer cores CPU of the control devices μC of the relocatable quantum computers QC1, QC2 and/or the quantum computer monitoring devices QUV of the relocatable quantum computers QC1, QC1.

Procedures for monitoring

The document presented here also proposes a method for monitoring the execution of a quantum computer program that can be run on at least one control device μC of a relocatable quantum computer QC by means of a quantum computer monitoring device QUV of the quantum computer QC. The relocatable quantum computer QC comprises quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and preferably nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the Quantum computer QC and the control device μC with the computer core CPU and first means for manipulating quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and, if necessary, for manipulating nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and second means for reading out the state of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and possibly nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. The computer core CPU of the control device μC preferably controls the first means for manipulating quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and, if applicable, core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC and the second means for reading out the state of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and possibly nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. The quantum computer monitoring device QUV preferably triggers the quantum bits of the quantum computer QC and possibly core quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ if a subset of the quantum dots and/or possibly the core quantum points of the quantum dots NV1, _NV2 , NV3 are manipulated , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC during the quantum computer program runtime an exception condition (exception), in particular an interruption (interrupt) of the quantum computer program flow, if this manipulation was not intended. This can happen during a program jump due to disturbances such as cosmic radiation, which is intercepted by this.

The document presented here proposes a non-volatile memory NVM for the relocatable quantum computer QC, in particular a read-only memory or a flash memory or a non-volatile memory, for a relocatable quantum computer QC in particular as part of a control unit of a vehicle. A quantum computer program is preferably stored in the non-volatile memory NVM, which is executable on at least one computer core μC of the quantum computer QC and is suitable for executing the method described above.

• Auf dem mindestens einen Rechnerkern CPU der Steuervorrichtung µC soll ein Quantencomputerprogramm ablauffähig sein. Die Quantencomputerüberwachungsvorrichtung QUV überwacht während der Quantencomputerprogrammlaufzeit den Ablauf des Quantencomputerprogramms während der Ausführung durch die anderen Vorrichtungsteile des Quantencomputers QC. Beim einem Zugriff des Rechnerkerns CPU auf einen bestimmten Adressbereich innerhalb eines Speichers RAM, NVM der Steuervorrichtung µC des Quantencomputers QC oder auf andere vorbestimmte Vorrichtungsteile des Quantencomputers QC erzeugt die Quantencomputerüberwachungsvorrichtung QUV eine Ausnahmebedingung (Exception), insbesondere eine Unterbrechung (Interrupt) des Quantencomputerprogrammablaufs. Woraufhin der Rechnerkern CPU der Steuervorrichtung µC des Quantencomputers QC die Ausführung des Quantencomputerprogramms typischerweise in vorzugsweise vorbestimmter Weise unterbricht.

The document presented here proposes the following to further ensure the functionality of the relocatable quantum computer QC with at least one computer core CPU, a control device µC and with a quantum computer monitoring device QUV:

• A quantum computer program should be able to run on the at least one computer core CPU of the control device μC. During the quantum computer program runtime, the quantum computer monitoring device QUV monitors the execution of the quantum computer program during execution by the other device parts of the quantum computer QC. When the computer core CPU accesses a specific address range within a memory RAM, NVM of the control device µC of the quantum computer QC or other predetermined device parts of the quantum computer QC, the quantum computer monitoring device QUV generates an exception condition (Exception), in particular an interruption (interrupt) of the quantum computer program flow. Whereupon the computer core CPU of the control device μC of the quantum computer QC typically interrupts the execution of the quantum computer program in a preferably predetermined manner.

The computer core CPU of the control device μC or a central control unit ZSE or another computer system, which can be connected, for example, to the computer core CPU of the control device μC of the quantum computer QC via the external data bus EXTDB, can configure the quantum computer monitoring device QUV, for example. The quantum computer QC and/or the computer core μC preferably has means for running through an exception routine (Exception-Rou tine) after throwing an exception during quantum computer program runtime. The exception handling routine can itself be a quantum computer program.

Further transfer procedure

• - Überwachen des korrekten Quantencomputerprogrammablaufs des Quantencomputerprogramms des verlegbaren Quantencomputers QC, insbesondere durch die Quantencomputerüberwachungsvorrichtung QUV oder ein andere Rechnersystem;
• - Durchführen vorbestimmter Quantencomputerberechnungen mit mindestens einer Quantenoperation zur Berechnung vorbestimmter Quantencomputerberechnungsergebnisse in vorbestimmten Zeiträumen vor vorbestimmten Zeitpunkten, insbesondere durch den Quantencomputer QC, und
• - Ansteuern einer Quantencomputerüberwachungsvorrichtung QUV nach diesen vorbestimmten Zeitpunkten und Durchführung eines Rücksetzens (Reset-Funktion) oder Reinitialisierens des Quantencomputers QC auf einen vordefinierten Quantencomputerprogrammrestartzustand oder dergleichen, wenn diese Ansteuerung nicht in vorbestimmter Weise erfolgt durchführt.

The document presented here proposes a method for operating a relocatable quantum computer system QUSYS with a relocatable quantum computer QC and with a quantum computer monitoring device QUV with the following exemplary steps:

• - Monitoring the correct quantum computer program flow of the quantum computer program of the relocatable quantum computer QC, in particular by the quantum computer monitoring device QUV or another computer system;
• - performing predetermined quantum computer calculations with at least one quantum operation for calculating predetermined quantum computer calculation results in predetermined time periods before predetermined times, in particular by the quantum computer QC, and
• - Activating a quantum computer monitoring device QUV after these predetermined points in time and performing a reset (reset function) or reinitializing the quantum computer QC to a predefined quantum computer program restart state or the like if this activation does not take place in a predetermined manner.

data buses

The proposed quantum computer QC preferably includes a data interface DBIF with which the proposed quantum computer QC can communicate and exchange data with higher-level computer systems and/or other quantum computers QC2. In particular, the proposed quantum computer QC can communicate and exchange data with a central control unit ZSE via the data interface DBIF. The data interface can be wired and/or wireless.

The computer core CPU of the control device μC and/or the quantum computer monitoring device QUV with the relocatable quantum computer QC can communicate with the device parts of the quantum computer QC and exchange data and signals via the internal data interface MDBIF and the control data bus SDB

magnetic system

The deployable quantum computer QC preferably comprises a system for compensating for external magnetic fields and the earth's magnetic field. For this purpose, the proposed mobile deployable quantum computer QC preferably has a sensor system for three-dimensional detection of the three-dimensional vector of the magnetic flux density B. Preferably, the sensor system for three-dimensional detection of the three-dimensional vector of the magnetic flux density B detects this three-dimensional vector of the magnetic flux density B in the vicinity of the substrate D. For example, the sensor system for three-dimensional detection of the three-dimensional vector of the magnetic flux density B can include three magnetic field sensors MSx, MSy, MSz for the three spatial directions X, Y, and Z. It is conceivable to use a single sensor system if the orientation of the magnetic field allows it. For example, the quantum computer QC can include a magnetic field sensor MSx for the magnetic flux density B _x in the direction of the X axis. For example, the quantum computer QC can include a magnetic field sensor MSy for the magnetic flux density B _y in the direction of the Y axis. For example, the quantum computer QC can include a magnetic field sensor MSz for the magnetic flux density B _z in the direction of the Z axis.

Typically, the proposed mobile quantum computer QC includes magnetic field generating devices PM, MGx, MGy, MGz. The magnetic field generating devices can include permanent magnets PM and/or coils MGx, MGy, MGz, in particular Helmholtz coils and Helmholtz coil pairs, as magnetic field generating means. The permanent magnets PM permanently generate a magnetic flux density. The coils MGx, MGy, MGz generate a magnetic flux density corresponding to their electrical current flow. The permanent magnets PM and the magnetic field generating means MGx, MGy, MGz are preferably part of a magnetic circuit. Preferably, but not necessarily, the magnetic circuit includes a yoke. The permanent magnet PM is preferably located in an air gap. A positioning device PV can preferably reposition the permanent magnet PM relative to the substrate D and/or in the air gap and thus change the magnetic flux density B acting on the substrate D with the quantum dots of the quantum bits of the quantum computer QC.

The control device μC of the quantum computer QC preferably includes a navigation device GPS, which communicates the current position to the computer core CPU of the control device μC. The control device μC can preferably determine the resulting strength of the earth's magnetic field and its magnetic flux density component with the aid of geomagnetic maps of the earth's magnetic field. If the quantum computer QC is moved or rotated in a translatory manner, the computer core CPU of the quantum computer QC can, for example, receive predicted values for future translatory coordinates and/or future rotations via the external data bus EXTDB or predict them from received or determined speed values and rotational speed values. Therefore, the computer core CPU of the quantum computer QC can then make changes to the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ predict the future magnetic field acting on the nuclear quantum bits of the quantum computer QC and compensate by changing the magnetic field generated in the quantum computer QC by means of the magnetic field generating devices PM, MGx, MGy, MGz.

• In einem ersten Schritt a) stellt die Steuervorrichtung µC bevorzugt beispielsweise mittels Magnetfeldsensoren MSx, MSy, MSz das derzeit wirkende externe Magnetfeld fest. In einem zweiten Schritt erfasst die Steuervorrichtung µC beispielsweise mittels eines Navigationssystems NAV und/oder einer Positionsermittlungsvorrichtung GPS die aktuellen Koordinaten und/oder die aktuelle Geschwindigkeit und/oder Beschleunigung. Auf Basis dieser Daten und ggf. zusätzlicher Daten, wie zum Beispiel einer elektronischen Karte des Erdmagnetfeldes berechnet beispielsweise die Steuervorrichtung µC des verlegbaren Quantencomputers QC das zu erwartende neue externe Magnetfeld und passt bevorzugt die Bestromung der Magnetfelderzeugungsmittel MGx, MGy, MGz so an, dass diese Änderung des externen Magnetfelds durch die Bewegung des Verlegbaren Quantencomputers QC im Wesentlichen nicht wirksam wird und die Berechnungsergebnisse von Quantencomputerprogrammen des verlegbaren Quantencomputers QC im Wesentlichen nicht beeinflussen.

The method for preventing the operation of the deployable quantum computer QC from being disrupted by changes in external magnetic fields as a result of a movement of the deployable quantum computer QC preferably takes place as follows:

• In a first step a), the control device μC preferably uses magnetic field sensors MSx, MSy, MSz to determine the currently active external magnetic field. In a second step, the control device μC records the current coordinates and/or the current speed and/or acceleration, for example using a navigation system NAV and/or a position determination device GPS. On the basis of this data and any additional data, such as an electronic map of the earth's magnetic field, for example, the control device µC of the deployable quantum computer QC calculates the new external magnetic field to be expected and preferably adjusts the energization of the magnetic field generating means MGx, MGy, MGz so that they Change in the external magnetic field by the movement of the deployable quantum computer QC essentially does not take effect and does not affect the calculation results of quantum computer programs of the deployable quantum computer QC essentially.

To simplify the presentation, we assume here that the navigation device GPS not only determines the translational coordinates, e.g. the position on the earth's surface, but also the angular orientation of the deployable quantum computer QC and the angular velocity of the change in these angles. The computer system CPU of the deployable quantum computer QC can only suitably precalculate the necessary adjustment of the magnetic field generation and control the magnetic field-generating devices PM, MGx, MGy, MGz suitably by taking into account the translational changes and the rotational changes in the position and orientation of the deployable quantum computer QC.

For this purpose, the computer core CPU of the control device μC can, for example, cause the first magnetic field controller MFSx to adapt the energization of the first magnetic field generating means MGx, which preferably generates a magnetic flux density B _x , with electric current.

For this purpose, the computer core CPU of the control device μC can, for example, also cause the second magnetic field controller MFSy to adapt the energization of the second magnetic field generating means MGy, which preferably generates a magnetic flux density B _y , with electric current. For this purpose, the computer core CPU of the control device μC can, for example, also cause the third magnetic field controller MFSz to adapt the energization of the third magnetic field generating means MGz, which preferably generates a magnetic flux density _Bz , with electric current.

For this purpose, the computer core CPU of the control device μC can, for example, also cause the positioning device PV of the permanent magnet PM to spatially adjust the positioning of the permanent magnet PM, which preferably generates a permanent, spatially inhomogeneous magnetic flux density B, and thus the magnetic flux density at the location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC.

The computer core CPU of the control device μC preferably detects the actual magnetic field using the said magnetic field sensors MSx, MSy, MSz and regulates the magnetic flux density using the actuators described immediately above in the form of the magnetic field-generating devices PM, MGx, MGy, MGz to compensate for deviations between the detected magnetic flux density vector and the desired magnetic flux density vector.

The quantum computer QC preferably includes an acceleration sensor system that can detect translational and/or rotational accelerations and delivers the corresponding values to the computer core CPU of the control device µC of the quantum computer QC, so that countermeasures can be taken in the form of counter-accelerations of a position control system not shown in the figures can. If necessary, the computer core CPU of the control device μC of the quantum computer QC can use the positioning device PV of the permanent magnet PM and/or the translational positioning device XT in the X direction and/or the translational positioning device YT in the Y direction for some such countermeasures. The computer core CPU of the control device μC of the deployable quantum computer QC can also modify the focus of the optical system OS depending on such coordinate forecasts and/or speed forecasts and/or acceleration forecasts for translatory movements and rotary movements in order to maintain the focus. For example, the computer core CPU of the control device µC of the deployable quantum computer QC can predict deformations and mechanical vibrations within the deployable quantum computer QC on the basis of such coordinate forecasts and/or speed forecasts and/or acceleration forecasts for translational movements and rotary movements and, if necessary, detect such using suitable sensors such as cameras and Detect and compensate position and distance sensors within the quantum computer QC.

power supply

The relocatable quantum computer QC preferably receives its energy via an energy supply EV. A charging device LDV of the power supply EV receives the power externally from a power source PWR.

A good overview of possible sources of electrical energy is given in the book: Vasily Y. Ushakov (author), "Electrical Power Engineering: Current State, Problems and Perspectives (Green Energy and Technology)", Paperback - August 18, 2018, Springer; 1st ed. 2018 edition (18 August 2018), ISBN-10: 3319872850, ISBN-13: 978-3319872858.

This energy source can be one of the following energy sources, for example:

electric generator

The energy source can be an electrical generator that converts mechanical energy into electrical energy. The mechanical energy can be, for example, energy transmitted via a shaft or the energy of a moving fluid. For example, it can be an electrical machine, such as a synchronous or asynchronous or direct current motor, a linear motor, a reluctance motor or a BLDC motor or the like, which converts the mechanical energy of a linear and/or rotary movement by means of induction into lines of a stator and/or or rotor into electrical energy. It can also be a magnetohydrodynamic generator, referred to as an MHD generator for short, which converts the movement of an electrically conductive fluid into electrical energy. The fluid can be a plasma or an electrically conductive liquid such as a saline solution or a molten metal. The actual energy source can be, for example, a nuclear reactor, an internal combustion engine, a heating device, a jet engine, a rocket engine, a ship propulsion system, a Stirling engine, a turbine, a water turbine, a gas turbine, a wind turbine, a tidal power plant, a wave power plant and the like . Magnetohydrodynamic generators are, for example, from the writings DE 20 2021 101 169 U1 , WO 2021 159 117 A1 , EP 3 863 165 A1 , U.S. 2021 147 061 A1 , CN 108 831 576 B , U.S. 2019 368 464 A1 , WO 2019 143 396 A2 , EP 3 646 452 B1 , CN 20 634 1126 U , EP 3 279 603 B1 , EP 3 400 642 B1 , EP 3 345 290 B1 , EP 3 093 966 B1 , WO 2016 100 008 A2 , DE 10 2014 225 346 A1 , RU 2014 143 858 A , EP 3 007 350 B1 , U.S. 2016 377 029 A1 , RU 2 566 620 C2 , EP 3 075 064 A1 , EP 2 874 292 B1 , EP 2 986 852 B1 , CN 10 385 5907 B , RU 126 229 U1 , WO 2014 031 037 A2 known. Due to the large number of fonts, the font presented here does not include a complete list. The paper presented here refers to the book Hugo K. Messerle (author), "Magnetohydrodynamic Electrical Power Generation (UNESCO Energy Engineering Series)", John Wiley & Sons Ltd (1 August 1995), ISBN-10: 0471942529, ISBN-13 : 978-0471942528.

electrochemical cell

The energy source can be an electrochemical cell. This can be, for example, an electrochemical cell in the broadest sense, which provides electrical energy by means of chemical reactions. The document presented includes accumulators, batteries and fuel cells among these electrochemical cells.

Nuclear Energy Sources

In the case of nuclear energy sources, the document presented here distinguishes between those which, on the one hand, first convert the nuclear energy into mechanical energy, for example by means of steam circuits and turbines, and then, using the above-mentioned generators, convert it into electrical energy and, on the other hand, convert it into nuclear energy convert directly into electrical energy. The document presented here names examples of betavoltaic cells and thermonuclear generators. These have the advantage that they can be carried out on the go. They therefore fit particularly well with the technical teaching presented here. The radionuclide batteries considered here preferentially use the isotopes ⁶⁰ Co, ⁹⁰ Sr, ¹⁰⁶ Ru, ¹⁴⁴ Cs, ¹⁴⁷ Pm, ²¹⁰ Pm, ²¹⁰ Po, ²³⁸ Pu, ²⁴² Cm, ²⁴¹ Am, ²⁴³ Am. The deployable quantum computer QC is preferably protected from the radiation of such a nuclear energy source by a radiation shield, for example made of lead. The radionuclide batteries also include betavoltaic cells, which, for example, convert beta radiation from beta emitters directly into electrical energy.

Such radionuclide batteries are, for example, from the writings DE 1 240 967 B , DE 1 564 070 B1 , DE 2 124 465 B2 , DE 7 219 216 U , DE 19 782 844 538 B1 , DE 69 411 078 T2 , U.S. 5,443,657 A , U.S. 5,859,484 A , DE 19 602 875 A1 , DE 19 738 066 A1 , DE 19 957 669 A1 , DE 19 957 669 A1 , U.S. 8,552,616 B2 , WO 2009 103 974 A1 and U.S. 2018 226 165 A1 known.

The energy source can also be a renewable energy source such as a solar cell or a hydroelectric power plant with a water turbine and a generator or a wind power plant with a wind turbine and a generator.

The energy source can also be conventional coal, lignite, oil and gas power plants that combust carbonaceous and/or hydrocarbonaceous fuels to generate thermal energy and then convert the thermal energy to mechanical energy and then convert the mechanical energy to electrical energy.

The energy source can be so-called energy harvesting devices. These are devices that use energy differences that are present in the environment or otherwise, e.g. to gain energy from the kinetic energy of a person or another moving object or from thermal differences, for example in heating systems or the same energy.

Finally, the energy source can simply be the power grid, in which case the primary energy source can remain undetermined.

The charging device LDV preferably prepares the energy from the energy supply PWR of the charging device LDV to such an extent that the charging device LDV can charge an energy reserve BENG, BENG2 with the energy from the energy supply PWR. For example, it can be a voltage converter and/or a buck converter or a boost converter or a buck-boost converter depending on the type of power supply PWR. The charging device LDV preferably monitors the charging process of the respective energy reserve BENG, BENG2 when it charges it.

If the quantum computer QC does not run a quantum computer program and/or does not perform any quantum operations, the charging device LDV can also supply device parts of the relocatable quantum computer QC via respective energy processing devices SRG, SRG2. The charging device LDV then preferably also charges one or more of the energy reserves BENG, BENG2 of the deployable quantum computer QC. In the example of 1 For example, the proposed relocatable quantum computer QC has two energy reserves BENG, BENG2 and two energy conditioning devices SRG, SRG2. The document presented here indicates that the number of energy reserves, energy conditioning devices and charging devices and disconnecting devices is greater than in the example of FIG 2 can be.

Although the charging device LDV represents a barrier to transients in the power supply PWR, the charging device LDV generally cannot completely suppress these transient disturbances in the power supply PWR. The charging device LDV also produces transient interference itself, for example if the charging device LDV is a switched-mode power supply. It has therefore proven useful to use one or more low-noise energy reserves BENG, BENG2 for supplying device parts that are particularly susceptible to interference, such as the photodetector PD, the amplifier V, the light source driver LDRV, the light source LD and, if applicable, for device parts MFSx, MFSy, MFSz, MGx that generate magnetic fields. MGy, MGz and device parts with a signal scheme that is particularly sensitive in terms of time, such as the waveform generator WFG and the microwave and/or radio wave frequency generator MW/RF-AWFG for generating largely freely definable waveforms (Arbitrary Wave Form Generator). These device parts particularly preferably stabilize their internal supply voltages again within these device parts in order to suppress the noise and the disturbances of the energy supply to the maximum. The quantum computer QC preferably comprises one or more energy conditioning devices SRG, SRG2 for supplying the device parts from the one energy reserve or the plurality of energy reserves BENG, BENG2. The energy processing devices preferably adapt the voltage level supplied by the charging device LDV or the energy reserves BENG, BENG2 to the required voltage level of the respectively supplied device part of the quantum computer QC, preferably with a voltage reserve. In a second control stage, which is preferably a linear controller, these linear controllers can then, for example, use the voltage reserve in order to set the actual supply voltage of the relevant device parts of the quantum computer QC with low noise and precisely.

One or more separating devices TS preferably separate the one charging device or the multiple charging devices LDV from the one energy conditioning device or the multiple energy conditioning devices SRG, SRG2 and/or the one low-noise energy reserve or from the multiple low-noise energy reserves BENG, BENG2 when the quantum computer is on executes a quantum computer program and/or performs a quantum operation. A quantum operation within the meaning of the document presented here is a manipulation of a quantum dot NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or a nuclear quantum dot Cl1 ₁ , CI1 ₂ ,CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. A quantum computer program in the sense of the document presented here is a program that includes at least one quantum operation. One or more binary data in the memory NVN, RAM of the control device μC of the relocatable quantum computer QC preferably encode such a quantum operation. For example, it can be a predetermined data word. A quantum operation within the meaning of the document presented here manipulates at least the quantum state of at least one quantum dot of the quantum dots NV1, NV2, NV3 of the quantum bits of the relocatable quantum computer QC and/or manipulates at least the quantum state of at least one nuclear quantum dot of the nuclear quantum dots CI1 ₁ , CI1 ₂ ,CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the deployable quantum computer QC. The technical teaching of the document presented here also designates the data word that symbolizes such a quantum operation as a quantum op code. A quantum computer program includes at least one quantum op-code. In the above case, when the relocatable quantum computer QC executes a quantum computer program and/or executes a quantum operation, the one energy reserve or the several energy reserves BENG, BENG2 preferably supply the one energy conditioning device or the several energy conditioning devices SRG, SRG2 with electrical energy that is particularly is low noise.

One or more separating devices TS preferably connect the one charging device or the multiple charging devices LDV to the one energy conditioning device or the multiple energy conditioning devices SRG, SRG2 and/or the one low-noise energy reserve or from the multiple low-noise energy reserves BENG, BENG2 if the deployable quantum computer QC does not run a quantum computer program and/or does not perform a quantum operation. In this case, the charging device LDV preferably charges the one energy reserve or the multiple energy reserves BENG, BENG2 and, if necessary, supplies the one energy conditioning device or the multiple energy conditioning devices SRG, SRG2 with electrical energy, which is now typically less noisy.

magnetic field shielding

In order to reduce the influence of external magnetic fields, it makes sense if the proposed quantum computer QC is provided with a shielding AS for these external magnetic fields. This shielding can, for example, be a passive shielding AS in the form of μ-metal mats and/or an active shielding AS in the form of a magnetic field-generating system that generates an opposing magnetic field to an external magnetic interference field and thereby interferes with its effect reduced and/or even compensated. The proposed quantum computer therefore preferably includes one or more sensors MSx, MSy, MSz for detecting the strength of the magnetic flux density B and/or the magnetic field strength H. The control device μC preferably uses the sensors detected by the one or more sensors MSx, MSy, MSz Values of the magnetic flux density B and/or the magnetic field strength H for controlling magnetic field generating means MGx, MGy, MGz. The magnetic field generating means MGx, MGy, MGz preferably generate a compensating magnetic flux density B of an opposing magnetic field that compensates for the magnetic flux density B of the magnetic interference field.

A first sensor MSx preferably detects the strength of the magnetic flux density B and/or the magnetic field strength H in a first direction, for example an X-axis. A first magnetic field controller MFSx preferably supplies a first magnetic field generating means MGx with electrical energy. The first magnetic field generating means MGx preferably generates a magnetic flux density B _x , which preferably essentially has a direction that preferably corresponds to the first direction, ie for example the direction of the X axis. The first magnetic field controller MFSx preferably energizes the first magnetic field generating means MGx with a first electric current Ix. The control device μC preferably controls the first magnetic field generating means MGx via the first magnetic field controller MFSx. The first magnetic field controller MFSx preferably regulates the generation of the magnetic flux density B _x by the first magnetic field generating means MGx in such a way that the magnetic flux density B detected by the first sensor MSx or the magnetic field strength H detected by the first sensor MSx corresponds to a first value. This first value is preferably zero. For this purpose, the first magnetic field controller MFSx evaluates the value of the magnetic flux density B detected by the first sensor MSx or the value of the magnetic field strength H detected by the first sensor MSx.

A second sensor MSy preferably detects the strength of the magnetic flux density B and/or the magnetic field strength H in a second direction, for example a Y-axis. The direction of the Y-axis is preferably chosen perpendicular to the direction of the X-axis. A second magnetic field controller MFSy preferably supplies a second magnetic field generating means MGy with electrical energy. The second magnetic field generating means MGy preferably generates a magnetic flux density B _y , which preferably essentially has a direction that preferably corresponds to the second direction, ie for example the direction of the Y axis. The second magnetic field controller MFSy preferably energizes the second magnetic field generating means MGy with a second electric current Iy. The control device μC preferably controls the second magnetic field generating means MGy via the second magnetic field controller MFSy. The second magnetic field controller MFSy preferably regulates the generation of the magnetic flux density B _y by the second magnetic field generating means MGy in such a way that the magnetic flux density B detected by the second sensor MSy or the magnetic field strength H detected by the second sensor MSy corresponds to a second value. This second value is preferably zero. For this purpose, the second magnetic field controller MFSy evaluates the value of the magnetic flux density B detected by the second sensor MSy or the value of the magnetic field strength H detected by the second sensor MSy.

A third sensor MSz preferably detects the strength of the magnetic flux density B and/or the magnetic field strength H in a third direction, for example a Z-axis. The direction of the Z-axis is preferably chosen perpendicular to the direction of the X-axis and perpendicular to the direction of the Y-axis. A third magnetic field controller MFSz preferably supplies a third magnetic field generating means MGz with electrical energy. The third magnetic field generating means MGz preferably generates a magnetic flux density B _z which preferably essentially has a direction which preferably corresponds to the third direction, ie for example the direction of the Z axis. The third magnetic field controller MFSz preferably energizes the third magnetic field generating means MGz with a third electric current Iz. The control device μC preferably controls the third magnetic field generating means MGz via the third magnetic field controller MFSz. The third magnetic field controller MFSz preferably regulates the generation of the magnetic flux density B _z by the third magnetic field generating means MGz in such a way that the magnetic flux density B detected by the third sensor MSz or the magnetic field strength H detected by the third sensor MSz corresponds to a third value. This third value is preferably zero. For this purpose, the third magnetic field controller MFSz evaluates the value of the magnetic flux density B detected by the third sensor MSz or the value of the magnetic field strength H detected by the third sensor MSz.

The proposed relocatable quantum computer QC typically has an optical system OS that allows the light source LED to irradiate the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with pump radiation LB. The optical system OS is preferably a confocal microscope. However, the optical system OS preferably also enables the optical off reading the state of quantum dots NV1, NV2, NV3 of the quantum bits of the relocatable quantum computer QC. For this purpose, the relocatable quantum computer QC of the relocatable quantum computer system QUSYS preferably has a dichroic mirror DBS, which allows the fluorescence radiation FL emitted by the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to pass through and the pump radiation LB of the light source LD onto the quantum dots NV1, NV2, NV3 directs the quantum bits of the quantum computer QC and keeps the pump radiation LB away from the photodetector PD for detecting the fluorescence radiation FL. Instead of a dichroic mirror DBS, the relocatable quantum computer QC of the quantum computer system QUSYS can also have a dichroic mirror DBS, which reflects away the fluorescence radiation FL emitted by the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and reflects the pump radiation LB of the light source LD via the optical System OS on the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC can happen, so that the pump radiation LB of the light source LD irradiates these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with pump radiation LB of the pump radiation wavelength λ _pmp . In this case, the optical system OS preferably captures the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the dichroic mirror DBS reflects this fluorescence radiation FL onto the photodetector PD for detecting the fluorescence radiation FL. The proposed relocatable quantum computer QC thus includes, if it uses an optical readout of the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, a photodetector PD for detecting the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The photodetector PD typically generates a received signal S0 as a function of the fluorescence radiation FL. An amplifier V following in the signal path typically amplifies and filters the received signal S0 to form an amplified received signal S1. The amplifier V is thus typically used to amplify and/or filter the output signal of the photodetector PD, which is typically the received signal S0. The amplified received signal S1 is preferably a digitized signal consisting of one or more samples. The control device μC preferably detects the value of the amplified received signal S1 by means of an analog-to-digital converter ADCV, for example. The proposed relocatable quantum computer QC includes, if it uses an electronic readout of the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, a corresponding device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. At this point, the writing presented here expressly refers to the writing again DE 10 2020 125 189 A1 . These device parts are preferably accommodated in a preferably common housing GH, which is preferably part of the relocatable quantum computer QC in the sense of the document presented here. As already described above, the quantum dots NV1, NV2, NV3 are the quantum bits of the quantum computer QC, and the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ the nuclear ones Quantum bits of the quantum computer QC preferably within said substrate D. The substrate D is preferably doped with dopants. The substrate D preferably essentially comprises atoms without a magnetic moment, preferably at least in the effective range of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. In the case of diamond as the material of the substrate D, the diamond preferably essentially comprises ¹² C isotopes. In the case of the use of NV centers in diamond, particularly preferably form as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC oxygen atoms ¹⁶ O, ¹⁸ O and/or phosphorus and/or sulfur atoms ³² S, ³⁴ S, ³⁶ S without magnetic Moment in the substrate D in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC from the doping. This doping in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC has two tasks. First, these doping atoms change the Fermi level E _F in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. If NV centers are used as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, this doping with said doping atoms shifts the Fermi level E _F in the region of these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. In the case of n-doping, this n-doping shifts the Fermi level E _F in the area of these quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in such a way that the Fermi level is raised and that the energetically lower-lying NV centers are preferably negatively charged. The NV centers then represent NV centers. Since NV centers have a magnetic moment of this electron configuration due to the negative charge electron, ^NV centers are therefore particularly suitable for use as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC . Secondly, this doping, which is preferably n-doping, means that the defects (English vacancies) in the diamond are electrically charged during implantation to form the NV centers and therefore do not cluster together due to the electrical repulsion of the negatively charged individual defects . This keeps the concentration of single defects high, increasing the likelihood of NV center formation during nitrogen implantation in diamond. In this case, with a doping of a diamond substrate D with sulfur in time before Nitrogen implantation gives the best results. Doping with a sulfur isotope without a nuclear magnetic moment is preferred. Such isotopes are the isotopes ³² S, ³⁴ S, ³⁶ S. An alternative is doping with the oxygen isotopes ¹⁶ O, ¹⁸ O, but this is less suitable. It is known that n-doping with phosphorus should also be successful. However, phosphorus has a nuclear magnetic moment. In principle, therefore, an N-doping with atoms that do not have a magnetic nuclear moment makes sense. Shifting the Fermi level E _F by other means, for example by means of preferably very thin electrodes precharged to a suitable potential relative to the substrate D, also led to such effects prior to the elaboration of this document. The substrate D of the relocatable quantum computer thus preferably has, at least temporarily, a local shift in the Fermi level E _F , so that this is then energetically shifted in such a way that the yield of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in the form of NV centers is increased during the implantation of the nitrogen atoms. In an analogous manner, the Fermi level E _F of other substrate materials and/or in relation to other paramagnetic centers (eg the ST1 center) can be influenced during the formation of these paramagnetic centers. The light source LD and the light source driver LDRV and the substrate D and the devices for generating the electromagnetic wave field MW/RF-AWFG, mWA, MGx, MGy, MGz and the control device µC and the memory RAM, NVM of the control device µC and the The optical system OS and possibly the amplifier V and the shielding AS are located within the housing GH, which means that they are preferably shielded from electromagnetic interference radiation penetrating from the outside. For this purpose, the material of the housing GH preferably comprises an electrically conductive material. The housing GH preferably forms a Faraday cage. The material of the housing GH preferably also includes a material for shielding magnetostatic and/or quasi-static magnetic fields. For this purpose, the material of the housing GH preferably includes so-called μ-metal, which is a particularly soft magnetic material.

The preferred μ-metal (Mu-metal, English Mu-metal or English permalloy) proposed here for use in quantum computers QC and quantum technological devices typically belongs to a group of soft magnetic nickel-iron alloys with 72 to 80% nickel and proportions of Copper, molybdenum, cobalt or chromium with high magnetic permeability, which is used in the proposed deployable quantum computer QC or the proposed quantum technological device AS for shielding low-frequency external magnetic fields.

According to the proposal, such µ-metal has a high permeability (µ _r =50,000 to 140,000 or more), which causes the magnetic flux of the external low-frequency magnetic fields to concentrate in the material of the housing GH of the deployable quantum computer QC. When shielding AS from low-frequency or static magnetic interference fields, this effect leads to considerable shielding attenuation. Thus, the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are also then shielded against such external magnetic fields if the relocatable quantum computer QC changes its spatial orientation and/or location in the course of a relocation, with such a change in the orientation of the relocatable quantum computer QC and/or the change in location of such a relocatable quantum computer QC typically being associated with a change the orientation and/or the strength of the magnetic fields acting on the deployable quantum computer QC relative to the deployable quantum computer QC. This is particularly advantageous if the relocatable quantum computer QC does not have active shielding against external magnetic fields, e.g. MGX, MGy, MGz would generate an opposing magnetic field for compensation.

The document presented here also proposes, inter alia, that the shielding AS of the quantum computer QC can be part of the housing GH of the deployable quantum computer QC or the housing GH of the deployable quantum computer QC itself. As already described, the control device μC controls the light source LD with the aid of said light source driver LDRV. In this case, the control device μC preferably generates a light source control signal, which can be the transmission signal S5, for example, by means of suitable means. The light source driver LDRV then typically supplies the light source LD with electrical energy as a function of the light source control signal from the control device μC. The light source LD thus preferably generates the pump radiation LB as a function of the light source control signal from the control device μC. The light source LD thus preferably generates the pump radiation LB as a function of the transmission signal S5. In the case of 1 the control device μC transmits the light source control signal preferably via the control data bus SDB and the waveform generator WFG as a transmission signal S5. In the following, the reader can therefore assume, for the sake of simplification and better understanding, that in the 1 the light source control signal is equal to the transmission signal S5. The light source LD then uses the optical system OS to irradiate the quantum dot or the multiple quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with pump radiation LB of a pump radiation wavelength λ _pmp . The pump radiation wavelength λ _pmp is preferably between 400 nm and 700 nm wavelength and/or better between 450 nm and 650 nm and/or better between 500 nm and 550 nm and/or better between 515 nm and 540 nm and/or optimally at one wavelength of 532 nm. In the case of NV centers in diamond, a laser diode from Osram of the type PLT5 520B with a wavelength of 520 nm has proven itself as an exemplary source of the pump radiation LB for the irradiation of NV centers in diamond as the material of the substrate D . The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC then emit fluorescence radiation FL with a fluorescence wavelength λ _fl depending on their state and on the pump radiation LB. In the case of NV centers as paramagnetic centers of quantum dots of the quantum bits of the quantum computer QC, the <fluorescence wavelength is typically in the range of 638 nm. The intensity I _fl of the fluorescence radiation FL typically depends on the intensity I _pmp of the pump radiation LB and thus also on the light source control signal. The one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC thus emit fluorescence radiation FL with a fluorescence radiation wavelength λ _fl when irradiated with electromagnetic radiation of the pump radiation wavelength λ _pmp . In the case of an optical readout of the state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC or of the quantum dot of the quantum bit of the quantum computer QC, the photodetector PD uses the optical system OS to detect the fluorescence radiation FL and converts the fluorescence radiation FL into a receiver output signal S0 . The receiver output signal S0 typically depends on the fluorescence radiation FL hitting the photodetector PD. The receiver output signal S0 preferably depends on the intensity I _fl of the fluorescence radiation FL that hits the photodetector PD. In the case of the optical readout of the state of the quantum dot(s) NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the amplifier V amplifies and/or filters the receiver output signal S0 and preferably makes the signal available to the computer core CPU of the control device µC as an amplified received signal S1 . The amplifier V preferably stores the values of the sampled values of the amplified received signal S1 in a memory of the amplifier V and digitized by means of an analog-to-digital converter of the amplifier V. The computer core CPU of the control device μC of the deployable quantum computer QC can then, for example via the control data bus SDB, query these sampled values of the amplified received signal S1 from the memory of the amplifier V and process them further. In the case of the electronic readout of the quantum dots NV1, V2, NV3 of the quantum bits of the quantum computer QC generate in 1 For a better overview, devices HS1 to HS3 and VS1, not shown, for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with a control unit B CBB a second received signal. As already described, the control device μC of the relocatable quantum computer QC controls the one or more devices for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the quantum computer QC nuclear quantum bits. By controlling the one or more devices (LH1, LH2, LH3, LV1) to generate an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the quantum bits of the quantum computer QC and/or by controlling the emission of the light source LD, the control device μC of the relocatable quantum computer QC can thus determine the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC change and/or couple to one another. The control device μC of the relocatable quantum computer QC preferably has means for generating a measured value signal with one or more measured values from one or more received signals, in particular from the first received signal and/or the second received signal. Since these received signals depend on the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ the measured value signal typically also depends on the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC.

In order to achieve deployability, the use of a deployable quantum computer QC capable of being deployed at room temperature has so far been used on the basis of paramagnetic centers as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC using nuclear magnetic moments as nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC with optical pump radiation LB and optical state readout or electron ic state readout of the quantum dot states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and a suitable deployable, passive shielding AS as possible proposed.

The proposal presented here now proposes that the relocatable quantum computer QC and/or the mobile device have a relocatable energy supply EV for supplying the relocatable quantum computer QC with energy. This is the only way to complete the installability. The power supply EV is preferably located within the housing GH. In this case, the housing GH can comprise a sub-housing with a magnetically shielded area in which the sub-devices of the deployable quantum computer QC that are sensitive to magnetic fields are located.

Outside of this sub-housing, but still inside the housing GH, are preferably the parts of the deployable quantum computer QC which are not or less sensitive to external magnetic and electromagnetic interference fields and/or themselves generate electromagnetic and/or magnetic interference fields. The energy supply EV is therefore preferably placed outside the sub-housing within the housing GH of the deployable quantum computer QC. The quantum computers QC1 to QC16 of a quantum computer system QUSYS can also have a common housing GH.

Typically, the proposed deployable quantum computer QC is part of the deployable quantum computer system QUSYS, e.g. the smartphone or the portable quantum computer system QUSYS or the vehicle or the deployable weapon system, together with all the necessary means for its operation.

These means of operating the relocatable quantum computer QC must therefore also be relocatable. The proposed deployable quantum computer system QUSYS comprises as deployable means for its operation and in particular one or more deployable energy supplies EV and/or one or more deployable quantum computers QC. For the purposes of this document, these means for operating the deployable quantum computer QC are also part of the smartphone or the piece of clothing or the wearable quantum computer system QUSYS or the vehicle or the deployable weapon system. It is irrelevant for the interpretation of the claims whether the operation of the relocatable quantum computer QC is linked to means and/or commands outside of the quantum computer QC despite the presence of all means for operating the relocatable quantum computer QC as part of the relocatable quantum computer QC. It is important that the relocatable quantum computer QC is potentially functional without these means and/or commands outside of the quantum computer QC. For example, a relocatable quantum computer system QUSYS that is waiting for an external start command due to the programming of the central control device ZSE and/or the programming of a control device µC of a quantum computer QC of the quantum computer system QUSYS is still covered by the claims.

The mobile deployable energy supply EV preferably comprises one or more deployable charging devices LDV with one or more power supplies PWR of the charging device en LDV, one or more deployable disconnecting devices TS, one or more deployable energy reserves BENG and one or more deployable energy conditioning devices SRG.

The mobile energy supply EV preferably includes an energy processing device SRG, in particular a voltage converter or a voltage regulator or a current regulator, which prevents changes in the energy content of the energy reserve BENG of the energy supply EV, for example the state of charge of an accumulator as an energy reserve BENG of the energy supply EV, from affecting the relocatable quantum computer QC and/or the quantum computer system QUSYS. The mobile energy supply EV supplies the energy processing device SRG with energy and the energy processing device SRG supplies electrical energy, for example to the relocatable quantum computer QC and possibly other parts of the quantum computer system QUSYS. In this case, the energy supply EV supplies the quantum computer QC, for example, with electrical energy only indirectly via the energy processing device SRG.

Typically, the relocatable quantum computer QC is set up and provided according to the proposal to be able to work with a reduced first number of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC even at room temperature. Room temperature as the operating temperature of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC leads to a broadening of the resonances in the resonance spectrum, so that they overlap. The proposed relocatable quantum computer QC therefore preferably has a relocatable cooling device KV, which together is relocatable with the relocatable quantum computer QC. The relocatable cooling device KV in question is preferably suitable and/or provided for reducing the temperature of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC. The lowering of the operating temperature of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC leads to a narrowing of the resonances in the resonance spectrum, so that they overlap to a lesser extent or not at all. Such cooling by means of a cooling device KV preferably lowers the temperature of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC to the extent that the quantum computer QC works with a second number of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC that is increased compared to the first number of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC can.

The deployable quantum computer QC preferably comprises a closed loop helium gas cooling system HeCLCS as the deployable cooling device KV, which is also referred to as a closed cycle cryocooler. For example, we refer to https://en.wikipedia.org/wiki/Cryocooler.

A further form of the proposal relates to a deployable quantum computer which has a deployable second deployable energy supply. The deployable second energy supply can be completely or partially identical to the first deployable energy supply (Bat). This second relocatable energy supply BENG preferably supplies the relocatable cooling device KV with energy. This has the advantage that the first energy supply is not disturbed by transient disturbances in the electric motors of the deployable cooling device KV.

Another aspect of the proposal concerns a deployable quantum computer QC for use in a mobile device. Use in a smartphone or a portable quantum computer system QUSYS or in a motor vehicle or in a weapon system is very particularly preferred. This means that the paper presented here proposes a deployable weapon system with a deployable quantum computer QC being part of the deployable weapon system. The use of the deployable quantum computer QC as part of the fire control system of the weapon system or the navigation system GPS, NAV of the weapon system is particularly preferred. The weapon system particularly preferably uses the deployable quantum computer QC to solve NP-complete problems, such as, for example, but not only the identification of targets, the classification of targets, the assignment of targets to known enemy objects such as aircraft and/or rocket types, vehicle types, ship types, Missile types, floating body types, types of underwater vehicles, types of underwater objects, types of spacecraft, types of satellites, etc. Furthermore, the selection of the order of target engagement and/or the selection of weapons and/or the selection of ammunition for combating the targets can Problems that the weapon system solves with the help of the deployable quantum computer QC. In addition, the deployable weapon system can use the deployable quantum computer QC to determine and/or modify and/or monitor the route of the respective projectile or warhead or weapon carrier to the target with the help of the deployable quantum computer QC.

Such a method begins with the acquisition of environmental data by the quantum computer system QUSYS in step A). The environmental data is typically recorded by means of suitable sensors, which can be part of the quantum computer system QUSYS or which are connected to this quantum computer system QUSYS via data connections and transmit environmental data to the quantum computer system QUSYS. In a step B), the quantum computer system QUSYS identifies objects in the environment of the quantum computer system QUSYS, where this environment can also be remote from the quantum computer system QUSYS. In a step C), the quantum computer system QUSYS classifies the identified objects in the environment of the quantum computer system QUSYS. In step C), the quantum computer system QUSYS typically classifies the objects according to their level of danger and/or vulnerability and/or strategic effect in order to maximize the effectiveness of a weapon. This classification in step C) is preferably carried out using a neural network model, which the quantum computer system QUSYS preferably executes. The quantum computer system QUSYS preferably uses one or more quantum operations for manipulating the quantum state of one or more quantum dots NV1, NV2, NV3 of the quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS for this step C) in order to classify the objects. In a step D, the quantum computer system QUSYS specifies the weapons and/or the ammunition and/or the configuration and/or the order of the objects attacked and/or the objects attacked and/or the objects not attacked. This determination is preferably made in step D) using a neural network model that Quantum computer system QUSYS preferably executes. In step D), the quantum computer system QUSYS preferably uses one or more quantum operations to manipulate the quantum state of one or more quantum dots NV1, NV2, NV3 of the quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS to make these determinations. In a step E), the quantum computer system QUSYS preferably proposes one or more of these defined attack scenarios to an operator, for example one or more pilots and/or one or more fire control officers or the like. If they give the fire order, the quantum computer system QUSYS can, for example, implement the released attack scenario in a step F). this is in 12 shown.

The deployable quantum computer QC preferably has a shielding AS. The shielding AS preferably shields the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, ie for example the NV centers, from electromagnetic fields and/or electromagnetic waves.

The deployable quantum computer QC preferably includes an optical system OS that directs the electromagnetic radiation from the light source LD onto the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, ie for example the paramagnetic centers or the NV centers. The optical system OS preferably includes a confocal microscope.

The optical system OS preferably comprises a first camera CM1, which captures the fluorescence radiation FL from the paramagnetic centers NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or from clusters of such paramagnetic centers, for example from NV centers and/or clusters of NV centers. Other fluorescent defect centers with other fluorescence wavelengths are conceivable. Such other fluorescent defect centers with other fluorescence wavelengths can thus have a fluorescence radiation with a fluorescence wavelength that is different from the fluorescence wavelength λ _fl of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and therefore, for example, by means of a dichroic mirror instead of the semi-transparent mirror STM or can be optically separated from the pump radiation LB and the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC by means of an optical filter. The substrate D is preferably mounted on a positioning table. The positioning table preferably includes a translational positioning device XT in the X direction and a translational positioning device YT in the Y direction, which the control device μC of the quantum computer QC preferably controls via the control data bus SDB. The first camera CM1 preferably captures the position of the substrate D relative to the optical system OS and thus the position of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC in the substrate D. The first camera CM1 thus captures the position of the paramagnetic centers, for example of the NV centers relative to the optical system OS. If the substrate D shifts relative to the optical system OS, for example due to mechanical vibrations or other disturbances, an image processing system of the deployable quantum computer QC detects this mechanical shift, for example by evaluating the position of fluorescent paramagnetic defect centers. The image processing system preferably uses the first camera CM1 to capture the fluorescence pattern of the defect centers and compares their position on the image with target positions. The image processing system preferably determines a displacement vector and repositions the substrate D using the positioning table XT, YT relative to the optical system OS as a function of the determined displacement vector. The image processing device preferably carries out this repositioning in such a way that the position of the quantum dot of the quantum bit of the quantum computer QC, for example the paramagnetic center or a cluster of paramagnetic centers, relative to the optical system OS is preferably essentially unchanged after the repositioning has been completed. The image processing system is preferably part of the deployable quantum computer QC. Typically, the controller µC of the quantum computer works as the image processing system. However, the image processing system can also be a separate sub-device of the relocatable quantum computer QC. In that case, the control device μC preferably controls the separate image processing system via the control data bus SDB. The image processing system can then be part of the first camera interface CIF, for example. Instead of an image processing system, other positional displacement sensors can also detect the displacements of the substrate D relative to the optical system. The proposed quantum computer QC then readjusts the position of the substrate D relative to the optical system OS on the basis of the position displacement data of such position displacement sensors. For example, such position displacement sensors can transmit the detected position displacement data to the control device µC of the quantum computer QC via the control data bus SDB, so that the control device µC of the quantum computer QC, for example depending on this recorded position displacement data via the control data bus SDB, moves the positioning table by means of the translatory positioning device XT in the X direction and by means of of the translational positioning device YT in the Y-direction, the control device μC repositions the substrate D relative to the optical system OS as a function of this determined position shift data as if essentially no shift had taken place. This ensures that the relocatable quantum computer QC works even with vibrations, accelerations and the like.

The relocatable quantum computer QC preferably comprises a photodetector PD and an amplifier V. The photodetector PD detects the fluorescence radiation FL of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC when the light source LD detects it with its electromagnetic radiation, which serves as pump radiation LB. irradiated. The relocatable quantum computer QC preferably uses this to read out the quantum state of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC are preferably paramagnetic centers as quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. The paramagnetic centers are preferably NV centers in diamond. The amplifier V amplifies and/or filters the receiver output signal S0 from the photodetector PD to form an amplified receiver output signal S1. The amplified receiver output signal can, for example, also be an ordered set of data in a memory of the amplifier V, with the computer core CPU of the control device μC preferably being able to read this memory of the amplifier V at least partially via the control data bus SDB.

Furthermore, in parallel or as an alternative to this optical readout of the state of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC, the relocatable quantum computer QC can also carry out an electronic readout of quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. For this purpose, the relocatable quantum computer QC can have a device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC as an alternative or in parallel to the photodetector PD and the amplifier V. The device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC preferably comprises electrically conductive lines for applying electric fields in the effective area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and contacts for sucking off charge carriers in the area the quantum dots NV1, NV2, NV3 the quantum bits of the quantum computer QC. Furthermore, the device for electronically reading out the states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC preferably includes devices for providing the control signals for controlling the said electrically conductive lines for applying electric fields in the effective range of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC. Furthermore, the device for electronically reading out the states of the quantum dots NV1, NV2 of the quantum bits of the quantum computer QC, NV3 preferably includes devices amplifiers for amplifying the sucked off via the contacts for the suction of charge carriers in the area of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC electric currents of charge carriers. The proposed quantum computer QC preferably has one or more digital-to-analog converters that are involved in generating the control signals for controlling the said electrically conductive lines LH1, LH2, LH3, LV1 for applying electric fields in the effective range of the quantum dots NV1, NV2 , NV3 of the quantum bits of the quantum computer QC. The first horizontal driver stage HD1 preferably has an analog-to-digital converter for driving the first quantum dot NV1 to be driven of the first quantum bit of the quantum computer QC, which the computer core CPU of the control device μC can preferably control via the control data bus STB. The second horizontal driver stage HD2 preferably has an analog-to-digital converter for driving the second quantum dot NV2 to be driven of the second quantum bit of the quantum computer QC, which the computer core CPU of the control device μC can preferably control via the control data bus STB. The third horizontal driver stage HD3 preferably has an analog-to-digital converter for driving the third quantum dot NV3 to be driven of the third quantum bit of the quantum computer QC, which the computer core CPU of the control device μC can preferably control via the control data bus STB. The control device μC preferably controls one or more of these digital-to-analog converters via an internal control data bus SDB of the deployable quantum computer QC.

Summary

The document presented here describes a deployable quantum computer QC in a mobile device. The mobile device can in particular be a smartphone and/or a portable quantum computer system QUSYS and/or a mobile quantum computer system QUSYS and/or a vehicle and/or a robot and/or an airplane and/or a missile and/or around a satellite and/or around a space missile and/or around a space station and/or around a buoy and/or around a ship and/or around an underwater vehicle and/or around a surface water buoy and/or around an underwater buoy and/or around a deployable weapon system and/or around a warhead and/or around a surface or underwater vehicle and/or a missile and/or another mobile device and/or a moving device. The relocatable quantum computer QC presented here typically comprises quantum bits, which typically comprise quantum dots. The quantum dots preferably comprise paramagnetic centers in a substrate D. The paramagnetic centers are preferably NV centers in diamond. Preferably, the substrate (D) comprises diamond. The relocatable quantum computer QC presented here typically includes nuclear quantum bits—also referred to here as nuclear quantum bits—which typically include nuclear quantum dots—also referred to here as nuclear quantum dots. The nuclear quantum dots preferably comprise nuclear magnetic moment/spin isotopes in the substrate D that can couple to the quantum dots. These isotopes are preferably nitrogen isotopes of the nitrogen atoms of the NV centers and/or ¹³ C isotopes of carbon in diamond. The relocatable quantum computer QC preferably comprises first means (e.g. LD, OS, MWA, MGx, MGy, MGz, LDRV, WFG, MW/RF-AWFG, PV, PM etc.) for manipulating one or more of the quantum states of one or more quantum bits of the quantum bits of the quantum computer QC. Typically, the relocatable quantum computer QC comprises second means (e.g. OS, CM1, CIF, PD, V, DBS, STM, XT, YT, KV etc.) for reading out one or more of the quantum states of one or more of the quantum bits of the quantum computer QC. Preferably, one or more quantum bits of the one or more quantum bits comprise paramagnetic centers as quantum dots. Preferably, these paramagnetic centers include NV centers and/or SiV centers and/or TR1 centers and/or L1 centers and/or TiV centers and/or GeV centers and/or SnV centers and/or NiN ₄ - centers and/or PbV centers and/or ST1 centers etc. in diamond as the substrate material. In this context, the document presented here refers to the ZPL table chapter of the glossary with regard to the possible pump radiation wavelengths λ _pmp and the associated paramagnetic centers. NV centers in diamond are particularly suitable as paramagnetic centers of the quantum dots of the quantum bits of the quantum computer QC.

The quantum computer QC preferably includes the control device μC for controlling the first means and the second means and for acquiring measurement results from the second means.

The relocatable quantum computer (QC) also preferably includes third means (PV, XT, YT, CM1, OS, STM, CIF, μC) that are set up to detect changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), to predict. This enables countermeasures to be initiated before they become necessary. This is particularly advantageous when coils have to be energized as part of such countermeasures and/or capacitors or parasitic capacitances have to be recharged as part of such countermeasures.

The relocatable quantum computer (QC) also preferably includes third means (PV, XT, YT, CM1, OS, STM, CIF, μC) that are set up to detect changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), capture. This enables the regulation of countermeasures.

The relocatable quantum computer (QC) also preferably includes third means (PV, XT, YT, CM1, OS, STM, CIF, μC) that are set up to detect changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), to compensate. This is a possible countermeasure.

The deployable quantum computer (QC) also preferably comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) that are set up to measure the effect of such changes in acceleration, in particular during a deployment of the deployable quantum computer ( QC), to decrease. If no compensation is completely possible for whatever reason, the quantum computer QC can try to maintain the ability to work in this way.

The third resources (PV, XT, YT, CM1, OS, STM, CIF, µC) can in particular be one or more acceleration sensor systems and/or acceleration sensors and/or one or more position displacement sensors and/or one or more attitude control systems and/or one or several positioning tables and/or positioning devices and/or one or more image capturing devices and/or image processing devices. The third means (PV, XT, YT, CM1, OS, STM, CIF, μC) can in particular other fluorescent defect centers in the substrate D with other fluorescences z wavelengths which, when irradiated with pump radiation that matches these other defect centers, emit fluorescence radiation with a fluorescence wavelength that differs from the fluorescence wavelength λ _fl of the quantum dots (NV1, NV2, NV3) of the quantum bits.

For example, the light source LD can comprise a first pump radiation source for electromagnetic radiation with the first pump radiation wavelength λ _pmp for exciting the fluorescence radiation λ _fl of a first type of paramagnetic centers of the quantum dots of the quantum bits of the quantum computer QC, for example NV centers.

For example, the light source LD can include a second pump radiation source for electromagnetic radiation with a second pump radiation wavelength λ _pmp for exciting the fluorescence radiation λ _fl of a second type of paramagnetic centers of the quantum dots of the quantum bits of the quantum computer QC, for example SiV centers.

This can continue like this.

For example, the light source LD can comprise an nth pump radiation source for electromagnetic radiation with an nth pump radiation wavelength λ _pmp for exciting the fluorescence radiation λ _fl of an nth type of paramagnetic centers of the quantum dots of the quantum bits of the quantum computer QC.

Preferably, the first type of paramagnetic centers differs from all other n-1 types of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.

Preferably, the second type of paramagnetic centers differs from all other n-1 types of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.
etc.

Preferably, the nth kind of paramagnetic centers differs from all other n-1 kinds of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.

Typically, the first pump radiation wavelength of the first kind of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC differs from the n-1 other pump radiation wavelengths of the other n-1 kinds of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the used quantum computer QC.

Typically, the second pump radiation wavelength of the second type of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC differs from the n-1 other pump radiation wavelengths of the other n-1 types of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the used quantum computer QC.
etc.

Typically, the nth pump radiation wavelength of the nth kind of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC differs from the n-1 other pump radiation wavelengths of the other n-1 kinds of paramagnetic centers that the quantum computer QC uses as Quantum dots used by quantum bits of the quantum computer QC.

Typically, the first fluorescence radiation wavelength of the first kind of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC differs from the n-1 other fluorescence radiation wavelengths of the other n-1 kinds of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the used quantum computer QC.

Typically, the second fluorescence radiation wavelength of the second type of paramagnetic centers, which the quantum computer QC as quantum dots differs from quantum bits of the quantum computers QC uses, from the n-1 other fluorescence radiation wavelength of the other n-1 kinds of paramagnetic centers which the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.
etc.

Typically, the n-th fluorescence wavelength of the n-th kind of paramagnetic centers that the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC differs from the n-1 other fluorescence wavelengths of the other n-1 kinds of paramagnetic centers that the quantum computer QC uses as Quantum dots used by quantum bits of the quantum computer QC.

The quantum computer QC can now use the other defect centers mentioned in a crystal of the substrate D to readjust the positioning. When irradiated with a further pump radiation with a further pump radiation wavelength, these other defect centers emit a further fluorescence radiation with a further fluorescence radiation wavelength.

The further type of said other defect centers preferably differs from all other n-1 types of paramagnetic centers which the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.

Typically, the further pump radiation wavelength of said other defect centers differs from the n other pump radiation wavelengths of the other n kinds of paramagnetic centers which the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.

Typically, the other fluorescence radiation wavelength of said other defect centers differs from the n other fluorescence radiation wavelengths of other n kinds of paramagnetic centers which the quantum computer QC uses as quantum dots of quantum bits of the quantum computer QC.

For example, the light source LD can comprise a further pump radiation source for electromagnetic radiation with the further pump radiation wavelength λ _pmp for exciting the further fluorescence radiation λ _f1 of the said other defect centers.

The light source LD preferably has a system of mirrors and/or prisms and/or beam splitters and/or semi-transparent mirrors in order to combine the different light beams of the different pump radiations into a single light beam, with which the optical system OS then uses the substrate D with the paramagnetic Centers of the quantum dots and the other defect centers are irradiated. A frequency-selective prism and/or mirror system or the like then separates the different fluorescence radiations again by evaluating the radiation wavelengths. In the example of 1 For example, the first camera CM1 can determine the position of the other defect centers and use image processing software to determine the defocusing and the x and y offset of the substrate D relative to the optical system OS. This enables position correction by the translational positioning device in the X direction XT and the translational positioning device in the Y direction YT, and refocusing by the optical system OS. Preferably, the quantum computer QC for applying this method comprises paramagnetic centers preferably used for each type and for the other defect centers via a semitransparent mirror STM and a camera CM1 and a camera interface CIF. A wavelength-sensitive optical functional element is preferably located in the beam path in front of the respective camera, which ensures that only the fluorescence radiation of the relevant paramagnetic center or of the other defect center reaches the assigned camera CM1. The control device μC preferably controls all components of the light source LD. The control device μC preferably controls the position correction by the translational positioning device in the X-direction XT and the translational positioning device in the Y-direction YT, as well as the refocusing by the optical system OS. The control device μC preferably captures the images captured by the first cameras CM1. The control device μC preferably evaluates the image of the further fluorescence radiation of the other defect centers captured by the first camera for the other defect centers and uses image processing software to determine a measured value for the defocusing of the optical system OS in relation to the substrate D and a measured value for the x -Offset of the substrate D with respect to the optical system OS and a measured value for the y-offset of the substrate D with respect to the optical system OS. The control device μC preferably controls the posi with the aid of these measured values tion correction by the translational positioning device in the X direction XT and the translational positioning device in the Y direction YT, and the refocusing by the optical system OS.

The relocatable quantum computer QC preferably comprises third means (PV, XT, YT, CM1, OS, STM, CIF, μC) which are set up to predict an acceleration, in particular during a relocation of the relocatable quantum computer QC, and/or an acceleration, in particular during a relocation of the relocatable quantum computer QC, and/or to compensate for an acceleration, in particular during a relocation of the relocatable quantum computer QC, and/or to reduce the effect of an acceleration, in particular during a relocation of the relocatable quantum computer QC. Such third means can be, for example, one or more acceleration sensor systems for the substrate D and/or for device parts of the quantum computer QC and/or for the quantum computer QC and/or acceleration sensors for the substrate D and/or for device parts of the quantum computer QC and/or for the quantum computer QC and/or one or more position displacement sensors for the substrate D relative to device parts of the quantum computer QC and/or for device parts of the quantum computer QC to each other and/or for the quantum computer QC relative to an external reference point etc. Such third means can include, for example, one or more attitude control systems, which can be part of the quantum computer QC and/or the control device μC, for example. Such third means can, for example, comprise one or more positioning tables which hold one or more components of the optical functional elements of the quantum computer QC essentially in position in relation to one another. The positioning tables can adjust, for example, 1 to 6 translational and rotational degrees of freedom. The control device μC preferably controls these positioning tables via the control data bus SDB. The X-direction positioning device XT and the translational Y-direction positioning device YT are examples of such positioning tables.

The relocatable quantum computer QC preferably comprises one or more image acquisition devices and/or image processing devices as third means (PV, XT, YT, CM1, OS, STM, CIF, µC) in order to be able to detect rotations and/or misalignments of functional elements of the quantum computer QC .

In this context, the document presented here has already suggested that the substrate D of the relocatable quantum computer QC prefers other fluorescent defect centers with other fluorescence wavelengths that have a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength λ _fl of the quantum dots (NV1, NV2, NV3) of the quantum bits , includes to allow the repositioning of the substrate D with respect to the optical system OS.

The quantum computer QC preferably comprises fourth means QUV, which are set up to transmit mechanical shocks and/or vibrations among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT , YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer QC to prevent and/or attenuate each other. In addition to the positioning devices already mentioned, which can serve this purpose as active functional elements and which the document presented here has already named, passive functional elements such as springs and/or shock absorbers and/or elastic mounts with a loss component can also be considered. A vibration damper is a system for damping mechanical vibrations (vibrations, shocks, impacts). The aim is to convert kinetic energy into thermal energy. For example, the fourth means can include friction brakes, which typically work independently of frequency and are supported on a counterpart which is either stationary or has a different resonant frequency. The counterpart is preferably located outside of the quantum computer QC or at least mechanically separate from the optical functional elements (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2) of the quantum computer QC. Preferably connects the in 17 Schematically drawn mechanical basic construction MGK the optical functional elements (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2 ) of the quantum computer QC with each other. Fourth means preferably protect this mechanical basic construction and the optical functional elements connected to it (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM , PD, CM1, CM2) of the quantum computer QC against vibrations, structure-borne noise and small accelerations. The vibration dampers, loosely referred to as "shock absorbers", which are part of the wheel suspension of most vehicles with suspension, reduce linear vibrations. Torsional vibration dampers such as flat surface dampers reduce torsional vibrations.

Vibration dampers that are tuned to specific frequency ranges, move freely with the vibrating object, and do not require external anchoring can limit linear vibrations Zen. One method of influencing the resonant frequency is to change the mass or stiffness of the structure to avoid oscillation caused by external stimuli.

These fourth means are preferred firstly between the mechanical basic construction MGK with the optical functional elements connected to it (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2) on the one hand and the housing GH of the quantum computer QC inserted. In this case, they dampen the transmission of structure-borne noise etc. from the housing GH of the quantum computer QC and from the other parts of the device of the quantum computer QC to the mechanical basic construction MGK with the optical functional elements connected to it (LD, DBS, OS, D, KV, XT , YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2). Secondly, these fourth means are preferably inserted between the housing GH of the quantum computer QC and the supports of the quantum computer QC, on which it is mechanically mounted. In this case, they dampen the transmission of structure-borne noise etc. from the mobile device, i.e. the vehicle (in the sense of the document presented here) to the housing GH of the quantum computer QC and its device parts.

Thus, the quantum computer QC preferably has fifth means that are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer QC and/or to to prevent and/or dampen the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer QC, in particular via structure-borne noise.

These fifth resources can be found, for example, in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer QC and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx , MSy, MSz, MWA, CM2, LM, HECLCS) must be inserted. For example, wires and/or lines in the form of mechanical springs can be helical in order to prevent the transmission of forces.

Such fifth resources can also be used, for example, in data lines SDA to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer QC and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) must be inserted.

Such fifth means can be special mechanical forms, at least in sections (e.g. said springs), of supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer QC and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS).

Such fifth means can be special mechanical shapes, at least in sections (e.g. said springs), from data lines SDA to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer QC and/or to the other auxiliary device parts (KV, XT , YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS).

The quantum computer QC preferably comprises sixth means, in particular a quantum computer monitoring device QUV, which are set up to detect a non-statistical error in the quantum computer QC and/or to carry out or initiate countermeasures when a non-statistical error occurs in the quantum computer QC.

The quantum computer QC preferably comprises seventh means, in particular a quantum computer monitoring device QUV, which are set up to detect a non-statistical error in the quantum computer QC and/or, if a non-statistical error occurs in the quantum computer QC, to report such a non-statistical error to a higher-level system, e.g. a central control unit ZSE.

The quantum computer QC preferably comprises eighth means, in particular a quantum computer monitoring device QUV, which are set up to detect a non-statistical quantum error in the quantum computer QC and/or to implement or initiate countermeasures when a non-statistical error occurs in the quantum computer QC.

The quantum computer QC preferably comprises ninth means, in particular a quantum computer monitoring device QUV, which are set up to detect a non-statistical quantum error of the quan tencomputers QC and/or to signal such a non-statistical quantum error to a higher-level system, for example a central control unit ZSE, when a non-statistical error occurs in the quantum computer QC.

The quantum computer QC preferably comprises tenth means (MSx, MSy, MSz, MFSx, MFSy, MFSz, PM, MGx, MGy, MGz, PV), which are set up to detect changes in the magnetic field at the location of the quantum bits during and/or after a transfer of the quantum computer QC and to compensate.

The quantum computer QC preferably includes eleventh means AS for shielding external magnetic field changes.

Typically, only the interaction of the third to eleventh means achieves the effect of trouble-free operation after the quantum computer QC has been relocated and/or during the relocation of the quantum computer QC.

Advantage

Such a relocatable quantum computer QC or such a relocatable quantum computer system QUSYS allows, at least in some implementations, to solve NP complete problems in mobile devices. However, the advantages are not limited to this.

Features of the proposal

The following list of characteristics reflects the characteristics of the proposal. The features and their sub-features can be combined with each other and with other features and sub-features of this proposal and with features of the description as far as the result of this combination makes sense. In the case of a combination, it is not necessary to include all sub-characteristics of a characteristic in one characteristic.

The features are therefore only preferred combinations of characteristics of different examples. The feature references can therefore be expressly changed if they make sense. They simplify the post-processing of the proposal. The claim results from the applicable claims.

• - mit einem Substrat D und
• - mit einem oder mehreren Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und
• - mit einer Lichtquelle LD und
• - mit einem Lichtquellentreiber LDRV und
• - mit einer oder mehreren Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes am jeweiligen Ort der Quantenpunkte NV1, NV2, NV, insbesondere der Quantenbits des Quantencomputers QC, und
• - mit einer Steuervorrichtung µC und
• - mit einem oder mehreren Speicher RAM, NVM der Steuervorrichtung µC und
• - mit einem Wellenformgenerator WFG und
• - mit einem optischen System OS und
• - mit einer Quantenzustandsauslesevorrichtung,
• - wobei die Quantenzustandsauslesevorrichtung
  • - einen Fotodetektor PD und einem Verstärker V umfassen kann und/oder
  • - eine Vorrichtung zum elektronischen Auslesen der Zustände der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, umfassen kann, und
• - wobei die Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, sich in dem Substrat D befinden und
• - wobei das Substrat D dotiert ist, sodass das Fermi-Niveau im Bereich der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, so zu verschoben ist, dass die Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, elektrisch geladen sind, und
• - wobei insbesondere das Substrat D n-dotiert ist, sodass das Fermi-Niveau im Bereich der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, so angehoben ist, dass die Quantenpunkte NV1, NV2, insbesondere der Quantenbits des Quantencomputers QC, negativ elektrisch geladen sind, und
• -- wobei der Wellenformgenerator WFG das Lichtquellensteuersignal S5 erzeugt und
• - wobei der Lichtquellentreiber LDRV die Lichtquelle LD in Abhängigkeit von einem Lichtquellensteuersignal S5 mit elektrischer Energie versorgt und
• - wobei die Steuervorrichtung µC den Wellenformgenerator WFG steuert und
• - wobei die Lichtquelle LD mittels des optischen Systems OS den Quantenpunkt oder die mehreren Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, mit Pumpstrahlung LB einer Pumpstrahlungswellenlänge λ_pmp bestrahlt und
• - wobei der eine Quantenpunkt oder die mehreren Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, Fluoreszenzstrahlung FL mit einer Fluoreszenzstrahlungswellenlänge λ_fl bei Bestrahlung mit elektromagnetischer Strahlung der Pumpstrahlungswellenlänge λ_pmp emittiert und
• - wobei der Fotodetektor PD mittels des optischen Systems OS zumindest einen Teil der Fluoreszenzstrahlung FL erfasst und ein Empfängerausgangssignal S0 wandelt und wobei der Verstärker V das Empfängerausgangssignal zu einem Empfangssignal S1 verstärkt und filtert und/oder wobei die Vorrichtung zum elektronischen Auslesen der Zustände der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, ein Empfangssignal S1 erzeugt und
• - wobei die Steuereinrichtung µC die einer oder mehreren Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes am jeweiligen Ort der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC,s teuert und
• - wobei die Steuereinrichtung µC durch Ansteuerung der einer oder mehreren Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes am jeweiligen Ort der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder durch Steuerung der Emission der Lichtquelle LD Zustände der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, ändern und/oder miteinander verkoppeln kann und
• - wobei die Steuereinrichtung µC über Mittel verfügt, um aus einem oder mehreren Empfangssignalen S1 ein Messwertsignal S4 mit einem oder mehreren Messwerten zu erzeugen und
• - wobei das Messwertsignal S4 von Zuständen von Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, abhängt,

gekennzeichnet dadurch

• - dass der verlegbare Quantencomputer und/oder die mobile Vorrichtung eine verlegbare Energieversorgung LDV, TS, BENG, SRG zur Versorgung zumindest eines Teils der Teilvorrichtungen des Quantencomputers mit Energie aufweist und
• - wobei die verlegbare Energieversorgung LDV, TS, BENG, SRG eine mobile Energieversorgung LDV, TS, BENG und eine Energieaufbereitungsvorrichtung SRG, insbesondere einen Spannungswandler oder einen Spannungsregler oder einen Stromregler, aufweist.

Feature 1: Deployable quantum computer in a mobile device, in particular for use in a smartphone or a portable quantum computer system or in a vehicle or in a deployable weapon system,

• - with a substrate D and
• - with one or more quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and
• - with a light source LD and
• - with a light source driver LDRV and
• - With one or more devices mWA, MW / RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV, in particular the quantum bits of the quantum computer QC, and
• - With a control device µC and
• - With one or more memory RAM, NVM and the control device μC
• - with a waveform generator WFG and
• - with an optical system OS and
• - with a quantum state readout device,
• - wherein the quantum state readout device
  • - can comprise a photodetector PD and an amplifier V and/or
  • - a device for electronically reading out the states of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and
• - wherein the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, are in the substrate D and
• - wherein the substrate D is doped so that the Fermi level in the area of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, is shifted so that the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC , are electrically charged, and
• - In particular, the substrate D is n-doped so that the Fermi level in the area of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, is raised so that the quantum dots NV1, NV2, in particular the quantum bits of the quantum computer QC , are negatively charged, and
• -- wherein the waveform generator WFG generates the light source control signal S5 and
• - wherein the light source driver LDRV supplies the light source LD with electrical energy as a function of a light source control signal S5 and
• - Wherein the control device μC controls the waveform generator WFG and
• - wherein the light source LD irradiates the quantum dot or the plurality of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, with pump radiation LB of a pump radiation wavelength λ _pmp by means of the optical system OS and
• - wherein the one or more quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, emits fluorescence radiation FL with a fluorescence radiation wavelength λ _fl when irradiated with electromagnetic radiation of the pump radiation wavelength λ _pmp and
• - wherein the photodetector PD detects at least part of the fluorescence radiation FL by means of the optical system OS and converts a receiver output signal S0 and wherein the amplifier V amplifies and filters the receiver output signal to form a received signal S1 and/or wherein the device for electronically reading out the states of the quantum dots NV1 , NV2, NV3, in particular the quantum bits of the quantum computer QC, generates a received signal S1 and
• - Wherein the control device μC controls the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC,s and
• - wherein the control device µC by controlling the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or by controlling the emission of the Light source LD can change states of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or couple them to one another and
• - Wherein the control device μC has means for generating a measured value signal S4 with one or more measured values from one or more received signals S1 and
• - where the measured value signal S4 depends on states of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC,

characterized by

• - that the relocatable quantum computer and/or the mobile device has a relocatable energy supply LDV, TS, BENG, SRG for supplying at least some of the sub-devices of the quantum computer with energy and
• - wherein the deployable energy supply LDV, TS, BENG, SRG has a mobile energy supply LDV, TS, BENG and an energy processing device SRG, in particular a voltage converter or a voltage regulator or a current regulator.

• - mit einem oder mehreren nuklearen Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, insbesondere der nuklearen Quantenbits des Quantencomputers QC, und
• - wobei die eine oder die mehreren Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes am jeweiligen Ort der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, gleichzeitig auch eine oder die mehrere Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes am jeweiligen Ort der Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, sind und
• - wobei die Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und die nuklearen Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, sich in dem gemeinsamen Substrat D befinden und
• - wobei die Steuereinrichtung µC die eine oder die mehreren Vorrichtungen zur Erzeugung eines elektromagnetischen Wellenfeldes steuert und
• - wobei die Steuereinrichtung µC durch Ansteuerung der einer oder mehreren Vorrichtungen zur Erzeugung eines elektromagnetischen Wellenfeldes und/oder durch Steuerung der Emission der Lichtquelle LD
  • - Zustände der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, ändern kann und/oder
  • - Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, mit anderen Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, verkoppeln kann und/oder
  • - Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, mit Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, verkoppeln kann und/oder
  • - Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, mit anderen Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, verkoppeln kann,
• - dass das Messwertsignal S4 von Zuständen von Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder von Zuständen von Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, abhängt.

Feature 2: Relocatable quantum computer according to feature 1,

• - with one or more nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , in particular the nuclear quantum bits of the quantum computer QC, and
• - Wherein the one or more devices mWA, MW / RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3, in particular the Quantum bits of the quantum computer QC, at the same time also one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the nuclear quantum _points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, are and
• - where the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and the nuclear nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, located in the common substrate D and
• - Wherein the control device μC controls the one or more devices for generating an electromagnetic wave field and
• - Wherein the control device μC by controlling the one or more devices for generating an electromagnetic wave field and/or by controlling the emission of the light source LD
  • - States of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, can change and/or
  • - Quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, can couple with other quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or
  • - Quantum dots NV1, NV2, NV3, especially the quantum bits of the quantum computer QC, with nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , especially the nuclear quantum bits of the quantum computer QC, can couple and/or
  • - Nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , especially the nuclear quantum bits of the quantum computer QC, with other nuclear quantum points CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, can couple,
• - that the measured value signal S4 of states of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or of states of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC.

• - wobei die mobile Energieversorgung LDV, TS, BENG die Energieaufbereitungsvorrichtung SRG, mit Energie versorgt und
• - wobei die Energieaufbereitungsvorrichtung SRG andere Vorrichtungsteile des den Quantencomputers mit elektrischer Energie versorgt.

Feature 3: Relocatable quantum computer according to feature 1 or 2,

• - wherein the mobile energy supply LDV, TS, BENG supplies the energy processing device SRG with energy and
• - wherein the energy conditioning device SRG supplies other device parts of the quantum computer with electrical energy.

• wobei die mobile Energieversorgung LDV, TS, BENG eine Ladevorrichtung LDV und eine Trennvorrichtung TS und eine Energiereserve BENG aufweist und
• wobei der Quantencomputer einen ersten Betriebsmodus und einen zweiten Betriebsmodus aufweist und
• wobei in dem ersten Betriebsmodus
  • - zum Ersten die Trennvorrichtung TS die Ladevorrichtung LDV mit der Energiereserve BENG verbindet und
  • - zum Zweiten die Ladevorrichtung LDV die Energiereserve BENG mit elektrischer Energie einer externen Energieversorgung PWR lädt und/oder
• wobei in dem ersten Betriebsmodus
  • - zum Ersten die Trennvorrichtung TS die Ladevorrichtung LDV mit der Energieaufbereitungsvorrichtung SRG verbindet und
  • - zum Zweiten die Ladevorrichtung LDV die Energieaufbereitungsvorrichtung SRG mit elektrischer Energie einer externen Energieversorgung PWR versorgt und/oder
• wobei in dem zweiten Betriebsmodus
  • - zum Ersten die Trennvorrichtung TS die Ladevorrichtung LDV von der der Energiereserve BENG trennt und
  • - zum Zweiten die Trennvorrichtung TS die Ladevorrichtung LDV von der Energieaufbereitungsvorrichtung SRG trennt und
  • - zum Dritten die Energiereserve BENG die Energieaufbereitungsvorrichtung SRG mit elektrischer Energie versorgt.

Feature 4: deployable quantum computer according to one of features 1 to 3,

• wherein the mobile energy supply LDV, TS, BENG has a charging device LDV and a disconnecting device TS and an energy reserve BENG and
• wherein the quantum computer has a first operating mode and a second operating mode and
• wherein in the first mode of operation
  • - First, the disconnecting device TS connects the charging device LDV to the energy reserve BENG and
  • - Secondly, the charging device LDV charges the energy reserve BENG with electrical energy from an external energy supply PWR and/or
• wherein in the first mode of operation
  • - Firstly, the separating device TS connects the charging device LDV to the energy conditioning device SRG and
  • - Secondly, the charging device LDV supplies the energy conditioning device SRG with electrical energy from an external energy supply PWR and/or
• wherein in the second mode of operation
  • - Firstly, the disconnecting device TS separates the charging device LDV from that of the energy reserve BENG and
  • - Secondly, the separating device TS separates the charging device LDV from the energy conditioning device SRG and
  • - Thirdly, the energy reserve BENG supplies the energy processing device SRG with electrical energy.

• - mit einem Gehäuse GH und
• - mit einer Abschirmung AS,
• - wobei die Lichtquelle LD und der Lichtquellentreiber LDRV und das Substrat D und die Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung des elektromagnetischen Wellenfeldes und die Steuervorrichtung µC und der Speicher RAM, NVM der Steuervorrichtung µC und das optische System OS und ggf. der Verstärker V und die Abschirmung AS sich innerhalb des Gehäuses GH befinden und
• - wobei die Abschirmung AS Teil des Gehäuses GH oder das Gehäuse GH sein kann und
• - wobei sich zumindest ein Teil der Energieversorgung LDV, TS, BENG, SRG des verlegbaren Quantencomputers QC oder solche Teile der Energieversorgung LDV, TS, BENG, SRG des verlegbaren Quantencomputers QC, die für eine gewisse Zeit eine autonome Energieversorgung für einen autonomen Betrieb des verlegbaren Quantencomputers QC sich innerhalb des gemeinsamen Gehäuses GH befinden.

Feature 5: Relocatable quantum computer according to one of features 1 to 4,

• - with a housing GH and
• - with a shield AS,
• - Wherein the light source LD and the light source driver LDRV and the substrate D and the devices mWA, MW/RF-AWFG for generating the electromagnetic wave field and the control device µC and the memory RAM, NVM of the control device µC and the optical system OS and possibly the Amplifier V and the shield AS are located within the housing GH and
• - wherein the shielding AS can be part of the housing GH or the housing GH and
• - where at least a part of the energy supply LDV, TS, BENG, SRG of the deployable quantum computer QC or such parts of the energy supply LDV, TS, BENG, SRG of the deployable quantum computer QC, which for a certain time an autonomous energy supply for an autonomous operation of the deployable Quantum computer QC are located within the common housing GH.

• - wobei eine Energieaufbereitungsvorrichtung SRG und eine Energiereserve BENG der Energieversorgung LDV, TS, BENG, SRG des verlegbaren Quantencomputers QC sich innerhalb der Abschirmung AS befinden.

Feature 6: deployable quantum computer QC according to feature 5,

• - An energy conditioning device SRG and an energy reserve BENG of the energy supply LDV, TS, BENG, SRG of the deployable quantum computer QC are located within the shielding AS.

• - wobei der verlegbare Quantencomputer QC und alle notwendigen Mitteln zum Betrieb dieses verlegbaren Quantencomputers QC Teil einer mobilen Vorrichtung sind und
• - wobei diese Mittel zum Betrieb des verlegbaren Quantencomputers QC ebenfalls verlegbar sind und wobei diese Mittel zum Betrieb des verlegbaren Quantencomputers QC Teil des Quantencomputers QC sind und
• - wobei diese Mittel zum Betrieb des verlegbaren Quantencomputers QC ebenfalls Teil der mobilen Vorrichtung sind und
• - wobei dabei unerheblich ist, ob der Betrieb des verlegbaren Quantencomputers QC trotz des Vorhandenseins aller Mittel zum Betrieb des verlegbaren Quantencomputers QC als Teil des verlegbaren Quantencomputers QC an Mittel und/oder Kommandos von außerhalb des verlegbaren Quantencomputers QC gekoppelt ist.

Feature 7: Deployable quantum computer QC according to one of features 1 to 6,

• - wherein the deployable quantum computer QC and all means necessary to operate this deployable quantum computer QC are part of a mobile device and
• - these means for operating the relocatable quantum computer QC also being relocatable and these means for operating the relocatable quantum computer QC being part of the quantum computer QC and
• - these means for operating the deployable quantum computer QC also being part of the mobile device and
• - It is irrelevant whether the operation of the relocatable quantum computer QC is linked to means and/or commands from outside the relocatable quantum computer QC despite the presence of all means for operating the relocatable quantum computer QC as part of the relocatable quantum computer QC.

• - wobei die mobile Vorrichtung insbesondere ein Smartphone oder ein Kleidungsstück oder ein Schmuckstück oder ein tragbares Quantencomputersystem oder ein Fahrzeug oder ein Roboter oder ein Flugzeug oder ein Flugkörper oder ein Satellit oder ein Rumflugkörper oder eine Raumstation oder ein Schwimmkörper oder ein Schiff oder ein Unterwasserfahrzeug oder ein Unterwasserschwimmkörper oder ein verlegbares Waffensystem oder eine andere mobile Vorrichtung ist.

Feature 8: deployable quantum computer QC according to feature 7,

• - wherein the mobile device is in particular a smartphone, or a piece of clothing, or a piece of jewelry, or a wearable quantum computer system, or a vehicle, or a robot, or an airplane, or a missile, or a satellite, or a spacecraft, or a space station, or a floating body, or a ship, or an underwater vehicle, or a underwater float or a deployable weapon system or other mobile device.

• - wobei der verlegbare Quantencomputer QC eine Positioniervorrichtung XT, YT umfasst und
• - wobei die Positioniervorrichtung XT, YT das Substrat D so gegenüber dem optischen System OS positionieren kann, dass das optische System OS im Zusammenwirken mit der einen oder den mehreren Vorrichtungen mWA, MW/RF-AWFG zur Erzeugung eines elektromagnetischen Wellenfeldes
  • - zum Ersten in einer ersten Positionierung eine erste Menge von Quantenpunkten, insbesondere der Quantenbits des Quantencomputers QC, mit einer ersten Anzahl von Quantenpunkten, insbesondere der Quantenbits des Quantencomputers QC, und ggf. einer zweiten Anzahl von Kernquantenpunkten, insbesondere der nuklearen Quantenbits des Quantencomputers QC, ansteuern kann und
  • - zum Zweiten in einer zweiten Positionierung eine zweite Menge von Quantenpunkten der Quantenbits des Quantencomputers QC mit einer dritten Anzahl von Quantenpunkten, insbesondere der Quantenbits des Quantencomputers QC, und ggf. einer vierten Anzahl von Kernquantenpunkten, insbesondere der nuklearen Quantenbits des Quantencomputers QC, ansteuern kann und
• - wobei die Steuervorrichtung µC die Positioniervorrichtung XT, YT für das Substrat D so steuern kann, dass sie eine erste Positionierung und/oder die zweite Positionierung oder weitere Positionierungen einnehmen kann.

Feature 9: Deployable quantum computer QC according to one of features 1 to 8

• - wherein the deployable quantum computer QC comprises a positioning device XT, YT and
• - wherein the positioning device XT, YT can position the substrate D in relation to the optical system OS such that the optical system OS cooperates with the one or more devices mWA, MW/RF-AWFG for generating an electromagnetic wave field
  • - Firstly, in a first positioning, a first set of quantum dots, in particular the quantum bits of the quantum computer QC, with a first number of quantum dots, in particular the quantum bits of the quantum computer QC, and possibly a second number of nuclear quantum dots, in particular the nuclear quantum bits of the quantum computer QC , can control and
  • - Secondly, in a second positioning, a second set of quantum dots of the quantum bits of the quantum computer QC can be controlled with a third number of quantum dots, in particular the quantum bits of the quantum computer QC, and possibly a fourth number of nuclear quantum dots, in particular the nuclear quantum bits of the quantum computer QC and
• - Wherein the control device μC can control the positioning device XT, YT for the substrate D in such a way that it can assume a first positioning and/or the second positioning or further positioning.

• - wobei der verlegbare Quantencomputer QC einen Temperatursensor ST aufweist, der einen Temperaturmesswert für die Temperatur des Substrats D oder für die Temperatur einer damit thermisch verbundenen Teilvorrichtung des verlegbaren Quantencomputers ermittelt.

Feature 10: Relocatable quantum computer QC according to one of features 1 to 9

• - Wherein the deployable quantum computer QC has a temperature sensor ST, which determines a measured temperature value for the temperature of the substrate D or for the temperature of a sub-device of the deployable quantum computer that is thermally connected thereto.

• - wobei der verlegbare Quantencomputer QC dazu eingerichtet und vorgesehen ist, mit einer verringerten ersten Anzahl an Quantenpunkten, insbesondere der Quantenbits des Quantencomputers QC, auch bei Raumtemperatur des Substrats D oder einem Temperaturmesswert, der einem Wert größer als 0°C entspricht, arbeiten zu können, und
• - wobei der verlegbare Quantencomputer QC dazu eingerichtet und vorgesehen ist, mit einer erhöhten dritten Anzahl an Quantenpunkten, insbesondere der Quantenbits des Quantencomputers QC. bei einem Temperaturmesswert, der einem Wert kleiner als 0°C entspricht, arbeiten zu können.

Feature 11: Relocatable quantum computer QC according to feature 10,

• - wherein the relocatable quantum computer QC is set up and provided to be able to work with a reduced first number of quantum dots, in particular the quantum bits of the quantum computer QC, even at room temperature of the substrate D or a measured temperature value that corresponds to a value greater than 0°C , and
• - wherein the relocatable quantum computer QC is set up and provided with an increased third number of quantum dots, in particular the quantum bits of the quantum computer QC. to be able to work with a measured temperature value that corresponds to a value less than 0°C.

• - wobei der verlegbare Quantencomputer QC dazu eingerichtet und vorgesehen ist, mit einer verringerten zweiten Anzahl an Kernquantenpunkten, insbesondere der nuklearen Quantenbits des Quantencomputers Q,C auch bei Raumtemperatur des Substrats D oder einem Temperaturmesswert, der einem Wert größer als 0°C entspricht, arbeiten zu können, und
• - wobei der verlegbare Quantencomputer QC dazu eingerichtet und vorgesehen ist, mit einer erhöhten vierten Anzahl an Kernquantenpunkten, insbesondere der nuklearen Quantenbits des Quantencomputers QC, bei einem Temperaturmesswert, der einem Wert kleiner als 0°C entspricht, arbeiten zu können.

Feature 12: Relocatable quantum computer QC according to feature 11,

• - wherein the relocatable quantum computer QC is set up and provided to work with a reduced second number of nuclear quantum dots, in particular the nuclear quantum bits of the quantum computer Q,C, even at room temperature of the substrate D or a temperature measurement value that corresponds to a value greater than 0°C to be able to, and
• - wherein the relocatable quantum computer QC is set up and intended to be able to work with an increased fourth number of nuclear quantum dots, in particular the nuclear quantum bits of the quantum computer QC, at a measured temperature value which corresponds to a value less than 0°C.

• - wobei der verlegbare Quantencomputer QC eine oder mehrere verlegbare Kühlvorrichtungen KV aufweist, die zusammen mit dem verlegbaren Quantencomputer QC verlegbar sind, und
• - wobei eine oder mehrere der verlegbaren Kühlvorrichtungen KV dazu geeignet und/oder vorgesehen sind, die Spin-Temperatur von Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder von Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, und/oder die Temperatur des Substrats D zu senken.

Feature 13: Deployable quantum computer QC according to one of features 1 to 12,

• - wherein the relocatable quantum computer QC has one or more relocatable cooling devices KV, which can be relocated together with the relocatable quantum computer QC, and
• - Wherein one or more of the deployable cooling devices KV are suitable and/or provided for the spin temperature of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, and/or the temperature of the substrate D to be lowered.

• - wobei eine oder mehrere solcher Kühlvorrichtungen KV die Temperatur von Quantenpunkten NV1, NV2, NV3 , insbesondere der Quantenbits des Quantencomputers QC, und/oder die Temperatur von Kernquantenpunkten CI1, CI2, CI3, insbesondere der nuklearen Quantenbits des Quantencomputers QC, und/oder die Temperatur des Substrats D soweit senken, dass der verlegbare Quantencomputer QC mit einer gegenüber der verringerten ersten Anzahl an Quantenpunkten NV1, NV2, NV3 , insbesondere der Quantenbits des Quantencomputers QC, erhöhten dritten Anzahl an Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, arbeiten kann und/oder
• - wobei eine oder mehrere solcher Kühlvorrichtungen KV die Temperatur von Quantenpunkten NV1, NV2, NV3 , insbesondere der Quantenbits des Quantencomputers QC, und/oder die Temperatur von Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, und/oder die Temperatur des Substrats D soweit senken, dass der Quantencomputer QC mit einer gegenüber der verringerten zweiten Anzahl an Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, mit einer erhöhten vierten Anzahl an Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, arbeiten kann.

Feature 14: Relocatable quantum computer QC according to feature 13,

• - wherein one or more such cooling devices KV the temperature of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and / or the temperature of nuclear quantum dots CI1, CI2, CI3, in particular the nuclear quantum bits of the quantum computer QC, and / or the Lower the temperature of the substrate D to the extent that the deployable quantum computer QC has a reduced first number of quantum dots NV1, NV2, NV3, in particular which of the quantum bits of the quantum computer QC, increased third number of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, can work and/or
• - wherein one or more such cooling devices KV the temperature of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and / or the temperature of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, and/or the temperature of the substrate D to the extent that the quantum computer QC with a reduced second number of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, with an increased fourth number of nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, can work.

• - wobei ein oder mehrere verlegbare Kühlvorrichtungen KV des Quantencomputers QC ein oder mehrere Closed Loop Helium Gas Cooling-Systeme HeCLCS umfassen oder wobei ein oder mehrere verlegbare Closed Loop Helium Gas Cooling Systeme HeCLCS ein oder mehrere verlegbare Kühlvorrichtungen KV umfassen.

Feature 15: Deployable quantum computer QC according to one of features 13 to 14,

• - wherein one or more deployable cooling devices KV of the quantum computer QC comprise one or more closed loop helium gas cooling systems HeCLCS or wherein one or more deployable closed loop helium gas cooling systems HeCLCS comprise one or more deployable cooling devices KV.

• - wobei der verlegbare Quantencomputer QC eine verlegbare zweite verlegbare Energieversorgung BENG2 aufweist, die von der ersten verlegbaren Energieversorgung BENG verschieden ist, und
• - wobei eine zweite verlegbare Energieversorgung BENG2 ein oder mehrere der verlegbaren Kühlvorrichtungen KV und/oder ein oder mehrere der Closed Loop Helium Gas Cooling-Systeme HeCLCS mit Energie versorgt.

Feature 16: Deployable quantum computer QC according to one or more of the preceding features 13 to 15

• - wherein the deployable quantum computer QC comprises a deployable second deployable power supply BENG2 different from the first deployable power supply BENG, and
• - wherein a second deployable energy supply BENG2 supplies one or more of the deployable cooling devices KV and/or one or more of the closed loop helium gas cooling systems HeCLCS with energy.

• - wobei der verlegbare Quantencomputer QC und/oder die mobile Vorrichtung eine mobilen Datenschnittstelle DBIF, insbesondere eine mobilen Funkdatenschnittstelle und/oder eine drahtgebundene Schnittstelle, aufweist.

Feature 17: Deployable quantum computer QC according to one or more of the preceding features 1 to 16,

• - wherein the relocatable quantum computer QC and/or the mobile device has a mobile data interface DBIF, in particular a mobile radio data interface and/or a wired interface.

• - wobei ein übergeordnetes System die Steuervorrichtung µC so steuern kann, dass die Steuervorrichtung µC des verlegbaren Quantencomputers QC den verlegbaren Quantencomputer QC zur Durchführung zumindest einer Manipulation eines Quantenzustands zumindest eines Quantenbits der Quantenbits NV1, NV2, NV3 und/oder zur Durchführung zumindest einer Manipulation eines Quantenzustands zumindest eines nuklearen Kernquantenbits der nuklearen Kernquantenbits CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃ veranlasst und
• - wobei das übergeordnete System dabei die Steuervorrichtung µC über die mobile Datenschnittstelle DBIF steuert.

Feature 18: Relocatable quantum computer QC according to feature 17,

• - wherein a higher-level system can control the control device µC in such a way that the control device µC of the relocatable quantum computer QC the relocatable quantum computer QC to carry out at least one manipulation of a quantum state of at least one quantum bit of the quantum bits NV1, NV2, NV3 and/or to carry out at least one manipulation of a Quantum state of at least one nuclear quantum bit of the nuclear quantum bits CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ and
• - The higher-level system controls the control device μC via the mobile data interface DBIF.

• - wobei die erste verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 eine Batterie oder ein Akkumulator oder ein Kondensator oder eine Zusammenschaltung mehrerer dieser Energiespeicher umfassen.

Feature 19: Relocatable quantum computer QC according to one or more of the preceding features 1 to 18,

• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise a battery or an accumulator or a capacitor or an interconnection of several of these energy stores.

• - wobei die erste verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 wiederaufladbare Energiespeicher, insbesondere Akkumulatoren und/oder Kondensatoren und/oder dergleichen, umfassen und
• - wobei der verlegbare Quantencomputer QC und/oder die mobile Vorrichtung eine oder mehrere Ladevorrichtungen LDV aufweist und
• - wobei eine oder mehrere Ladevorrichtungen LDV dazu bestimmt sind und/oder vorgesehen sind zumindest zeitweise in zumindest einigen oder allen der wiederaufladbaren Energiespeicher BENG, BENG2 Energie zu speichern.

Feature 20: deployable quantum computer QC according to feature 19,

• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise rechargeable energy stores, in particular accumulators and/or capacitors and/or the like, and
• - wherein the deployable quantum computer QC and/or the mobile device has one or more charging devices LDV and
• - Wherein one or more charging devices LDV are intended and/or are provided to store energy at least temporarily in at least some or all of the rechargeable energy stores BENG, BENG2.

• - wobei die ersten verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 einen oder mehrere Energiespeicher umfassen, die jeweils Energie mittels chemischer und/oder elektrochemischer Vorgänge aus zumindest einem oder mehreren Fluiden erzeugen, und
• - wobei die ersten verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 und/oder der verlegbare Quantencomputer QC einen oder mehrere Vorratstanks für diese Fluide umfassen und
• - wobei einer oder mehrere der Vorratstanks die einen oder mehrere der Energiespeicher mit einem oder mehreren dieser Fluide versorgen und
• - wobei einer oder mehrere der Energiespeicher eine oder mehrere galvanische Zellen und/oder eine oder mehrere Brennstoffzellen und/oder eine oder mehrere Verbrennungsmaschinen, die jeweils mit einem oder mehreren elektrischen Generatoren gekoppelt sind, und/oder eine oder mehrere thermische Energieumwandlungsmaschinen, die jeweils mit einem oder mehreren elektrischen Generatoren gekoppelt sind, umfassen und
• - wobei eine oder mehrere der mobilen Energieversorgungen eine oder mehrere Energieaufbereitungsvorrichtungen SRG, insbesondere einen oder mehrere Spannungswandler und/oder einen oder mehrere Spannungsregler und/oder einen oder mehrere Stromregler, aufweisen und
• - wobei einer oder mehrere der Energiespeicher des Quantencomputers QC zumindest zeitweise eine oder mehrere der Energieaufbereitungsvorrichtungen SRG mit Energie versorgen und
• - wobei eine oder mehrere der Energieaufbereitungsvorrichtungen SRG einen oder mehrere Vorrichtungsteile des verlegbaren Quantencomputers QC mit elektrischer Energie versorgen.

Feature 21: Relocatable quantum computer QC according to one or more of the preceding features 1 to 20,

• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores, each of which generates energy from at least one or more fluids by means of chemical and/or electrochemical processes, and
• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 and/or the deployable quantum computer QC comprise one or more storage tanks for these fluids and
• - Wherein one or more of the storage tanks supply the one or more of the energy stores with one or more of these fluids and
• - wherein one or more of the energy storage one or more galvanic cells and / or one or more fuel cells and / or one or more combustion engines, each coupled to one or more electrical generators, and / or one or more thermal energy conversion machines, each with one or more electrical generators are coupled, comprise and
• - wherein one or more of the mobile energy supplies have one or more energy processing devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators, and
• - wherein one or more of the energy stores of the quantum computer QC at least temporarily supply one or more of the energy processing devices SRG with energy and
• - wherein one or more of the energy processing devices SRG supply one or more device parts of the deployable quantum computer QC with electrical energy.

• - wobei die ersten verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 einen oder mehrere Energiespeicher umfassen, die Energie mittels mechanischer Vorgänge erzeugen, und
• - wobei einer oder mehrere dieser Energiespeicher einen oder mehrere Generatoren und/oder eine oder mehrere Lichtmaschinen und/oder einen oder mehrere als Generator betreibbare Elektromotoren umfassen und
• - wobei eine oder mehrere mobile Energieversorgungen des Quantencomputers QC eine oder mehrere Energieaufbereitungsvorrichtungen SRG, insbesondere einen oder mehrere Spannungswandler und/oder einen oder mehrere Spannungsregler und/oder einen oder mehrere Stromregler, aufweisen und
• - wobei einer oder mehrere der Energiespeicher des Quantencomputers QC zumindest zeitweise eine oder mehrere der Energieaufbereitungsvorrichtungen SRG mit Energie versorgen und
• - wobei eine oder mehrere der Energieaufbereitungsvorrichtungen SRG einen oder mehrere Vorrichtungsteile des verlegbaren Quantencomputers QC mit elektrischer Energie versorgen.

Feature 22: Relocatable quantum computer QC according to one or more of the preceding features 1 to 21,

• - Wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores which generate energy by means of mechanical processes, and
• - wherein one or more of these energy stores comprise one or more generators and/or one or more alternators and/or one or more electric motors that can be operated as a generator and
• - wherein one or more mobile energy supplies of the quantum computer QC have one or more energy processing devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators, and
• - wherein one or more of the energy stores of the quantum computer QC at least temporarily supply one or more of the energy processing devices SRG with energy and
• - wherein one or more of the energy processing devices SRG supply one or more device parts of the deployable quantum computer QC with electrical energy.

• - wobei die erste verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 einen oder mehrere Energiespeicher umfassen, die Energie mittels der Umwandlung elektromagnetischer Strahlung, insbesondere von Licht, in elektrische Energie erzeugen, und
• - wobei einer oder mehrere der Energiespeicher eine oder mehrere Solarzellen oder eine oder mehrere funktionsäquivalente Vorrichtungen, wie beispielsweise PN-Übergänge, umfassen und
• - wobei eine oder mehrere mobile Energieversorgungen des Quantencomputers QC eine oder mehrere Energieaufbereitungsvorrichtungen SRG, insbesondere einen oder mehrere Spannungswandler und/oder einen oder mehrere Spannungsregler und/oder einen oder mehrere Stromregler, aufweisen und
• - wobei einer oder mehrere der Energiespeicher des Quantencomputers QC zumindest zeitweise eine oder mehrere der Energieaufbereitungsvorrichtungen SRG mit Energie versorgen und
• - wobei eine oder mehrere der Energieaufbereitungsvorrichtungen SRG einen oder mehrere Vorrichtungsteile des verlegbaren Quantencomputers QC mit elektrischer Energie versorgen.

Feature 23: Relocatable quantum computer QC according to one or more of the preceding features 1 to 22,

• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores which generate energy by converting electromagnetic radiation, in particular light, into electrical energy, and
• - wherein one or more of the energy stores include one or more solar cells or one or more functionally equivalent devices, such as PN junctions, and
• - wherein one or more mobile energy supplies of the quantum computer QC have one or more energy processing devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators, and
• - wherein one or more of the energy stores of the quantum computer QC at least temporarily supply one or more of the energy processing devices SRG with energy and
• - wherein one or more of the energy processing devices SRG supply one or more device parts of the deployable quantum computer QC with electrical energy.

• - wobei die ersten verlegbare Energiereserve BENG und/oder die zweite verlegbare Energiereserve BENG2 einen oder mehrere Energiespeicher umfassen, die Energie mittels nuklearer Vorgänge erzeugen, und
• - wobei eine oder mehrere der mobilen Energieversorgungen des Quantencomputers QC eine oder mehrere Energieaufbereitungsvorrichtungen SRG, insbesondere einen oder mehrere Spannungswandler und/oder einen oder mehrere Spannungsregler und/oder einen oder mehrere Stromregler, aufweist und
• - wobei einer oder mehrere der Energiespeicher des Quantencomputers QC zumindest zeitweise eine oder mehrere der Energieaufbereitungsvorrichtungen SRG mit Energie versorgen und
• - wobei eine oder mehrere der Energieaufbereitungsvorrichtungen SRG einen oder mehrere Vorrichtungsteile des verlegbaren Quantencomputers QC mit elektrischer Energie versorgen.

Feature 24: Deployable quantum computer QC according to one or more of the preceding features 1 to 23,

• - wherein the first deployable energy reserve BENG and/or the second deployable energy reserve BENG2 comprise one or more energy stores that generate energy by means of nuclear processes, and
• - wherein one or more of the mobile energy supplies of the quantum computer QC has one or more energy conditioning devices SRG, in particular one or more voltage converters and/or one or more voltage regulators and/or one or more current regulators, and
• - wherein one or more of the energy stores of the quantum computer QC at least temporarily supply one or more of the energy processing devices SRG with energy and
• - wherein one or more of the energy processing devices SRG supply one or more device parts of the deployable quantum computer QC with electrical energy.

• - wobei der Energiespeicher eine thermonukleare Batterie oder eine funktionsäquivalente Vorrichtung umfasst und

Feature 25: Relocatable quantum computer QC according to feature 24,

• - wherein the energy store comprises a thermonuclear battery or a functionally equivalent device and

• - wobei das Substrat D Diamant umfasst und
• - wobei Quantenpunkte, insbesondere der Quantenbits des Quantencomputers QC, in dem Substrat D Defektzentren und/oder paramagnetische Zentren in Diamant sind.

Feature 26: Relocatable quantum computer QC according to one or more of the preceding features 1 to 25,

• - wherein the substrate D comprises diamond and
• - wherein quantum dots, in particular the quantum bits of the quantum computer QC, in the substrate D are defect centers and/or paramagnetic centers in diamond.

• - wobei Defektzentren in Diamant NV-Zentren oder ST1-Zentren oder SiV-Zentren oder TR12-Zentren sind.

Feature 27: deployable quantum computer QC according to feature 26,

• - where defect centers in diamond are NV centers or ST1 centers or SiV centers or TR12 centers.

• - mit einem oder mehreren Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃ insbesondere der nuklearen Quantenbits des Quantencomputers QC.

Feature 28: Deployable quantum computer QC according to one or more of the preceding features 1 to 27,

• - With one or more nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , _{CI3 2 ,} CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC.

• - wobei die Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃ der nuklearen Quantenbits des Quantencomputers QC mit Quantenpunkten NV1, NV2, NV3 insbesondere der Quantenbits des Quantencomputers QC gekoppelt sind.

Feature 29: deployable quantum computer QC according to feature 28,

• - Wherein the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC are coupled with quantum dots NV1, NV2, NV3 in particular of the quantum bits of the quantum computer QC are.

• - wobei das Substrat D im Wesentlichen zumindest bereichsweise isotopenrein ist und
• - wobei die Isotope des Substrats D abgesehen von Atomen, die die Kernquantenpunkte CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, bilden, im Wesentlichen kein magnetisches Kernmoment aufweisen.

Feature 30: Deployable quantum computer QC according to one or more of the two preceding features 28 or 29,

• - Wherein the substrate D is essentially isotopically pure, at least in regions, and
• - where the isotopes of the substrate D apart from atoms forming the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC , essentially have no nuclear magnetic moment.

• - wobei der verlegbare Quantencomputer QC einen oder mehrere Lüfter und/oder einen oder mehrere Wärmetauscher zum Wärmeaustausch mit der Umgebung und/oder einen oder mehrere Wärmetauscher zum Wärmeaustausch mit der Umgebungsluft und/oder einen oder mehrere Strahlungskühler zum Wärmeaustausch mit der Umgebungsluft oder der Umgebung mittels elektromagnetischer Wärmestrahlung aufweist.

Feature 31: Deployable quantum computer QC according to any one of features 1 to 30

• - wherein the relocatable quantum computer QC has one or more fans and/or one or more heat exchangers for exchanging heat with the environment and/or one or more heat exchangers for exchanging heat with the ambient air and/or one or more radiant coolers for exchanging heat with the ambient air or the environment has electromagnetic thermal radiation.

• - wobei einer oder mehrere der Lüfter und/oder einer oder mehrere der Wärmetauscher mit einer oder mehrerer der verlegbaren Kühlvorrichtungen KV Energie in Form von Wärme austauschen.

Feature 32: Relocatable quantum computer QC according to feature 31 and feature 13

• - wherein one or more of the fans and/or one or more of the heat exchangers exchange energy in the form of heat with one or more of the deployable cooling devices KV.

• - mit einer internen Schirmung AS,
• - wobei die interne Schirmung AS das Substrat D mit den Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und ggf. den Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, gegen elektromagnetische Felder der Steuervorrichtung µC und/oder des Speichers RAM, NVM und/oder der Energieversorgung SRG, TS, LDV, BENG, BENG2 und/oder des Lichtquellentreibers LDRV und/oder der Lichtquelle LD abschirmt und/oder
• - wobei die interne Schirmung AS das Substrat D mit den Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und ggf. den Kernquantenpunkten CI1₁, CI1₂, CI1₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, anderer Vorrichtungsteile des Quantencomputers QC und/oder gegen Magnetfelder der Steuervorrichtung µC und/oder des Speichers RAM, NVM und/oder der Energieversorgung SRG, TS, LDV, BENG, BENG2 und/oder des Lichtquellentreibers LDRV und/oder der Lichtquelle LD und/oder anderer Vorrichtungsteile des Quantencomputers QC abschirmt

Feature 33: Deployable quantum computer QC according to one or more of the preceding features 1 to 32,

• - with an internal shielding AS,
• - Wherein the internal shielding AS is the substrate D with the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and possibly the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, against electromagnetic fields of the control device µC and/or the memory RAM, NVM and/or the energy supply SRG, TS, LDV, BENG, BENG2 and/or the light source driver LDRV and / or the light source LD shields and / or
• - Wherein the internal shielding AS is the substrate D with the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and possibly the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, other parts of the device of the quantum computer QC and/or against magnetic fields of the control device µC and/or the memory RAM, NVM and/or the power supply SRG, TS, LDV, BENG, BENG2 and/or the light source driver LDRV and/or the light source LD and/or other device parts of the quantum computer QC

• - wobei der verlegbare Quantencomputer QC mit einem oder mehreren Rädern oder einem Fahrgestell oder funktionsäquivalenten Vorrichtungsteilen, die auch angetrieben und/oder gebremst sein können, zumindest zeitweise ausgestattet ist.

Feature 34: Deployable quantum computer QC according to one or more of the preceding features 1 to 33

• - wherein the relocatable quantum computer QC is at least temporarily equipped with one or more wheels or a chassis or functionally equivalent device parts, which can also be driven and/or braked.

• - wobei der verlegbare Quantencomputer QC mit einer oder mehreren Antriebsvorrichtungen zumindest zeitweise ausgestattet ist.
• - wobei es sich bei einem oder mehreren der Antriebsvorrichtungen um ein Rad oder eine Schiffsschraube oder einen Propeller oder eine Turbine oder ein Raketentriebwerk oder ein Antriebsrad oder ein MHD-triebwerk handelt.

Feature 35: Deployable quantum computer QC according to one or more of the preceding features 1 to 34,

• - wherein the relocatable quantum computer QC is at least temporarily equipped with one or more drive devices.
• - wherein one or more of the propulsion devices is a wheel, or a propeller, or a propeller, or a turbine, or a rocket engine, or a driving wheel, or an MHD engine.

• - wobei der verlegbare Quantencomputer QC aerodynamisch geformte Funktionselemente zur Reduzierung und/oder Kontrolle aerodynamischer Effekte und/oder hydrodynamisch geformte Funktionselemente zur Reduzierung und/oder Kontrolle hydrodynamischer Effekte zur Erzeugung eines dynamischen Auftriebs, insbesondere Flügel und /oder Flaps, aufweist.

Feature 36: deployable quantum computer QC according to one or more of the preceding features 1 to 35,

• - wherein the deployable quantum computer QC has aerodynamically shaped functional elements for reducing and/or controlling aerodynamic effects and/or hydrodynamically shaped functional elements for reducing and/or controlling hydrodynamic effects for generating dynamic lift, in particular wings and/or flaps.

• - elektronische Vorrichtungsteile des Quantencomputers QC als Funktionselemente des Quantencomputers QC, zumindest teilweise in strahlenharter Elektronik ausgeführt sind und
• - wobei die Steuervorrichtung µC und/oder der Speicher RAM, NVM der Steuervorrichtung µC und/oder der Rechnerkern CPU und/oder die Datenschnittstelle DBIF und/oder die interne Datenschnittstelle MDBIF und/oder der Lichtquellentreiber LDRV und/oder der Wellenformgenerator WFG und/oder der Verstärker V und/oder der Fotodetektor PD und/oder die erste Kameraschnittstelle CIF und/oder die zweite Kameraschnittstelle CIF2 und/oder die erste Kamera CM1 und/oder die zweite Kamera CM2 und/oder der Temperatursensor ST und/oder der Mikrowellen- und/oder Radiowellenfrequenzgenerator MW/RF-AWFG zur Erzeugung weitestgehend frei vorgebbarer Wellenformen und/oder die Magnetfeldsensoren MSx, MSy, MSz und /oder die Magnetfeldsteuerungen MFSx, MFSy, MFSz und/oder die erste Energieaufbereitungsvorrichtung SRG und/oder die zweite Energieaufbereitungsvorrichtung SRG2 und/oder die Energiereserve BENG und/oder die zweite Energiereserve BENG2 und/oder die Trennvorrichtung TS und/oder die Ladevorrichtung LDV des verlegbaren Quantencomputers solche zumindest teilweise in strahlenharter Elektronik ausgeführten Funktionselemente des Quantencomputers QC sein können und
• - wobei strahlenhart bedeutet, dass diese Funktionselemente des Quantencomputers QC für den Einsatz im Weltraum und/oder in Bereichen erhöhter ionisierender Strahlung, wie beispielsweise Kernreaktoren oder das Umfeld thermonuklearer Batterien vorgesehen und/oder geeignet sind.

Feature 37: Deployable quantum computer QC according to one or more of the preceding features 1 to 36

• - Electronic device parts of the quantum computer QC are designed as functional elements of the quantum computer QC, at least partially in radiation-hard electronics and
• - wherein the control device µC and/or the memory RAM, NVM of the control device µC and/or the computer core CPU and/or the data interface DBIF and/or the internal data interface MDBIF and/or the light source driver LDRV and/or the waveform generator WFG and/or the amplifier V and/or the photodetector PD and/or the first camera interface CIF and/or the second camera interface CIF2 and/or the first camera CM1 and/or the second camera CM2 and/or the temperature sensor ST and/or the microwave and /or radio wave frequency generator MW/RF-AWFG for generating largely freely definable waveforms and/or the magnetic field sensors MSx, MSy, MSz and/or the magnetic field controllers MFSx, MFSy, MFSz and/or the first energy processing device SRG and/or the second energy processing device SRG2 and/or or the energy reserve BENG and/or the second energy reserve BENG2 and/or the separating device TS and/or the charging device LDV des relocatable quantum computer can be such functional elements of the quantum computer QC that are at least partially executed in radiation-hard electronics and
• - where radiation-hard means that these functional elements of the quantum computer QC are intended and/or suitable for use in space and/or in areas of increased ionizing radiation, such as nuclear reactors or the environment of thermonuclear batteries.

• - wobei die Steuervorrichtung µC zumindest zeitweise ein neuronales Netzwerkmodell ausführt und
• - wobei das neuronale Netzwerkmodell Eingangswerte und/oder Eingangssignale verarbeitet und
• - wobei das neuronale Netzwerkmodell Ausgangssignale und/oder Ausgangswerte ausgibt und
• - wobei die Steuervorrichtung µC in Abhängigkeit von Ausgangssignalen und/oder Ausgangswerten des neuronalen Netzwerkmodells Zustände von Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder Zustände von Kernquantenpunkten CI1₁, CI1₂, C11₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, beeinflusst und/oder
• - wobei die Steuervorrichtung µC in Abhängigkeit von Zuständen von Quantenpunkten NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder Zuständen von Kernquantenpunkten CI1₁, CI1₂, C11₃, CI2₁, CI2₂, C12₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, Eingangssignale und/oder Eingangswerte des neuronalen Netzwerkmodells beeinflusst.

Feature 38: Deployable quantum computer QC according to one or more of the preceding features 1 to 37,

• - wherein the control device μC at least temporarily executes a neural network model and
• - wherein the neural network model processes input values and/or input signals and
• - wherein the neural network model emits output signals and/or output values and
• - wherein the control device μC, depending on output signals and/or output values of the neural network model, states of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or states of nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, influenced and/or
• - wherein the control device µC depending on states of quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or states of nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , C12 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, influence input signals and/or input values of the neural network model.

• - wobei der hier vorgelegte Merkmal und die von ihm abhängigen Merkmale alle diese im Folgenden als Fahrzeug bezeichnen und
• - wobei das Fahrzeug einen verlegbaren Quantencomputer QC nach einem oder mehreren der vorhergehenden Merkmale 0 bis 0 umfasst oder
• - wobei der verlegbaren Quantencomputer QC nach einem oder mehreren der vorhergehenden Merkmale 0 bis 0 das Fahrzeug umfasst.

Feature 39: Smartphone and/or a portable quantum computer system and/or a mobile quantum computer system and/or vehicle and/or robot and/or airplane and/or missile and/or satellite and/or a rum missile and/or space station and/or floating body and /or ship and/or underwater vehicle and/or surface float and/or underwater float and/or deployable weapon system and/or warhead and/or surface or underwater vehicle and/or projectile and/or other mobile device and/or movable device,

• - the feature presented here and the features dependent on it all hereinafter refer to as a vehicle and
• - wherein the vehicle comprises a deployable quantum computer QC according to one or more of the preceding features 0 to 0, or
• - wherein the deployable quantum computer QC according to one or more of the preceding features 0 to 0 comprises the vehicle.

• - wobei der Quantencomputer QC dazu vorgesehen ist, Datenkommunikation über die Datenschnittstelle DBIF zu entschlüsseln und/oder zu verschlüsseln.

Feature 40: Vehicle according to the preceding feature 39

• - Wherein the quantum computer QC is intended to decrypt and/or encrypt data communication via the data interface DBIF.

• - wobei das Fahrzeug Sensoren und/oder Messmittel, die Messwerte über die Umgebung des Fahrzeugs und/oder Zustände des Fahrzeugs und/oder Zustände der Fahrzeuginsassen bzw. Nutzer/Nutzerinnen des Fahrzeugs und/oder Zustände der Zuladung des Fahrzeugs an die Steuervorrichtung µC liefern, umfasst und/oder
• - wobei die Steuervorrichtung µC Messwerte über die Umgebung des Fahrzeugs über die Datenschnittstelle DBIF erhält und/oder
• - wobei der Quantencomputer QC in Abhängigkeit von diesen Messwerten eine Lagebeurteilung für den Gesamtzustand des Fahrzeugs und/oder der Umgebung des Fahrzeugs ermittelt und
• - wobei der Gesamtzustand des Fahrzeugs den Zustand des Umfelds des Fahrzeugs und/oder den Zustand der Fahrzeuginsassen und/oder den Zustand einer Zuladung des Fahrzeugs umfassen kann.

Feature 41: Vehicle according to one or more of the preceding features 39 to 40

• - Wherein the vehicle has sensors and/or measuring means, the measured values about the surroundings of the vehicle and/or states of the vehicle and/or states of the vehicle occupants or users/benefits Channels of the vehicle and / or conditions of the payload of the vehicle to the control device μC deliver includes and / or
• - wherein the control device μC receives measured values about the surroundings of the vehicle via the data interface DBIF and/or
• - wherein the quantum computer QC determines a situation assessment for the overall condition of the vehicle and / or the environment of the vehicle as a function of these measured values and
• - Wherein the overall condition of the vehicle can include the condition of the surroundings of the vehicle and/or the condition of the vehicle occupants and/or the condition of a payload of the vehicle.

• - wobei zumindest ein Sensor des Fahrzeugs einer der folgenden Messwerte liefernden Sensoren ist oder zumindest einen der folgenden Messwert liefernden Sensoren als Untersystem umfasst:
  • - ein Radar-Sensor und/oder
  • - ein Mikrofon und/oder
  • - ein Ultraschalmikrofon und/oder
  • - einen Ultraschalltransducer und/oder
  • - einen Infrarotsensor und/oder
  • - einen Gassensor und/oder
  • - einen Beschleunigungssensor und/oder
  • - einen Strahlungsdetektor und/oder
  • - ein bildgebendes System und/oder
  • - eine Kamera und/oder
  • - eine Infrarotkamera und/oder
  • - eine Multispektralkamera und/oder
  • - ein LIDAR-System und/oder
  • - ein Ultraschallmesssystem und/oder
  • - ein Dopplerradarsystem und/oder
  • - ein Quantenradarsystem und/oder
  • - ein Quantensensor und/oder
  • - ein Positionssensor und/oder
  • - ein Navigationssystem und/oder
  • - ein Lagesensor und/oder
  • - ein Partikelzähler und/oder
  • - ein Detektionssystem für biologische Stoffe, insbesondere für biologische Kampstoffe, und/oder
  • - ein Gravimeter und/oder
  • - ein Kompass und/oder
  • - ein Gyroskop und/oder
  • - ein MEMS-Sensor und/oder
  • - ein Drucksensor und/oder
  • - ein Neigungswinkelsensor und/oder
  • - ein Temperatursensor und/oder
  • - ein Feuchtesensor und/oder
  • - ein Windgeschwindigkeitssensor und/oder
  • - ein Wellenfrontsensor und/oder
  • - ein mikrofluidisches Messsystem und/oder
  • - ein Abstandsmesssystem und/oder
  • - ein Längenmesssystem und/oder
  • - ein biologischer Sensor zur Detektion biologischer Marker und/oder Viren und/oder Mikroben oder dergleichen und/oder
  • - ein Sensorsystem zur Erfassung biologischer Messwerte von Fahrzeuginsassen und/oder zur Erfassung biologischer Messwerte lebender Ladung, insbesondere von Tieren und/oder biologischen Materialien,
  • - ein Seat-Occupation-Messystem und/oder
  • - ein Spannungssensor und/oder ein Stromsensor und/oder ein Leistungssensor.

Feature 42: Vehicle according to feature 41

• - wherein at least one sensor of the vehicle is one of the following sensors supplying measured values or comprises at least one of the following sensors supplying measured values as a subsystem:
  • - a radar sensor and/or
  • - a microphone and/or
  • - an ultrasonic microphone and/or
  • - an ultrasound transducer and/or
  • - an infrared sensor and/or
  • - a gas sensor and/or
  • - an acceleration sensor and/or
  • - a radiation detector and/or
  • - an imaging system and/or
  • - a camera and/or
  • - an infrared camera and/or
  • - a multispectral camera and/or
  • - a LIDAR system and/or
  • - an ultrasonic measuring system and/or
  • - a Doppler radar system and/or
  • - a quantum radar system and/or
  • - a quantum sensor and/or
  • - a position sensor and/or
  • - a navigation system and/or
  • - a position sensor and/or
  • - a particle counter and/or
  • - a detection system for biological substances, in particular for biological warfare agents, and/or
  • - a gravimeter and/or
  • - a compass and/or
  • - a gyroscope and/or
  • - a MEMS sensor and/or
  • - a pressure sensor and/or
  • - an inclination angle sensor and/or
  • - a temperature sensor and/or
  • - a humidity sensor and/or
  • - a wind speed sensor and/or
  • - a wavefront sensor and/or
  • - a microfluidic measuring system and/or
  • - a distance measuring system and/or
  • - a length measuring system and/or
  • - a biological sensor for detecting biological markers and/or viruses and/or microbes or the like and/or
  • - a sensor system for acquiring biological measurements of vehicle occupants and/or for acquiring biological measurements of living cargo, in particular of animals and/or biological materials,
  • - a seat occupation measurement system and/or
  • - a voltage sensor and/or a current sensor and/or a power sensor.

• - wobei der Quantencomputer QC in Abhängigkeit von diesen Messwerten das Fahrzeug und/oder Vorrichtungsteile des Fahrzeugs steuert und/oder eine Steuerung des Fahrzeugs oder eines Vorrichtungsteils des Fahrzeugs beeinflusst.

Feature 43: Vehicle according to feature 41 and/or 42

• - The quantum computer QC depending on these measured values controlling the vehicle and/or parts of the vehicle and/or influencing a control of the vehicle or a part of the vehicle.

• - wobei das Fahrzeug einen Innenraum aufweist und
• - wobei der Quantencomputer QC in Abhängigkeit von den Messwerten Parameter des Innenraums des Fahrzeugs und/oder ein Vorrichtungsteil im Innenraum des Fahrzeugs beeinflusst.

Feature 44: Vehicle according to feature 43

• - wherein the vehicle has an interior and
• - wherein the quantum computer QC influences parameters of the interior of the vehicle and/or a device part in the interior of the vehicle as a function of the measured values.

• - wobei es sich bei dem Fahrzeug um ein Waffensystem handelt und/oder
• - wobei das Fahrzeug ein Waffensystem umfasst, das mit dem Quantencomputer QC gekoppelt ist.

Feature 45: Vehicle according to one or more of the preceding features 39 to 44

• - wherein the vehicle is a weapon system and/or
• - wherein the vehicle comprises a weapon system coupled to the quantum computer QC.

• - wobei das Fahrzeug ein Feuerleitsystem umfasst und
• - wobei das Feuerleitsystem den Quantencomputer QC umfasst oder mit dem Quantencomputer gekoppelt ist und
• - wobei die Steuerung des Waffensystems durch das Feuerleitsystem zumindest zeitweise von dem Quantencomputer QC abhängt oder im Zusammenwirken mit dem Quantencomputer QC geschieht.

Feature 46: Vehicle according to feature 45

• - wherein the vehicle comprises a fire control system and
• - wherein the fire control system comprises the quantum computer QC or is coupled to the quantum computer and
• - Wherein the control of the weapon system by the fire control system depends at least temporarily on the quantum computer QC or takes place in cooperation with the quantum computer QC.

• - wobei das Fahrzeug eine Bewertungsvorrichtung umfasst, die die beabsichtigte Steuerung des Waffensystems hinsichtlich der zu erwartenden Wirkungen vor der Ausführung der Steuerung klassifiziert und eine Steuerungsbefehlsklasse ermittelt und
• - wobei die Bewertungsvorrichtung eine Ausführung der Steuerung verhindert oder bis zu einer Freigabe durch einen menschlichen Benutzer aufschiebt, wenn der im Zusammenwirken mit dem Quantencomputer QC ermittelte Steuerungsbefehl in eine vorgegebene Steuerungsklasse fällt.

Feature 47: Vehicle according to features 45 to 46

• - Wherein the vehicle comprises an evaluation device which classifies the intended control of the weapon system with regard to the effects to be expected before the control is carried out and determines a control command class and
• - wherein the evaluation device prevents execution of the control or postpones it until it is released by a human user if the control command determined in cooperation with the quantum computer QC falls into a predetermined control class.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC eine ein oder mehrere Ziele identifiziert.

Feature 48: Vehicle according to features 45 to 48

• - wherein the vehicle identifies one or more targets with the help of the quantum computer QC.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC das eine Ziel oder mehrere Ziele klassifiziert.

Feature 49: Vehicle according to feature 48

• - wherein the vehicle uses the quantum computer QC to classify the one or more targets.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC eine zeitliche Reihenfolge oder Priorisierung der Bekämpfung mehrerer Ziele ermittelt.

Feature 50: Vehicle according to any one of features 45 to 49

• - The vehicle using the quantum computer QC determines a chronological order or prioritization of combating multiple targets.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC einen Zeitpunkt zur Bekämpfung eines Ziels ermittelt.

Feature 51: Vehicle according to any of features 45 to 50

• - The vehicle using the quantum computer QC determines a point in time to attack a target.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC einen Waffentyp und/oder eine Munition zur Bekämpfung eines Ziels ermittelt.

Feature 52: Vehicle according to any one of features 45 to 51

• - Wherein the vehicle uses the quantum computer QC to determine a weapon type and/or ammunition for combating a target.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC eine Route für das Fahrzeug ermittelt.

Feature 53: Vehicle according to any of features 39 to 52

• - wherein the vehicle uses the quantum computer QC to determine a route for the vehicle.

• - wobei das Fahrzeug mit Hilfe des Quantencomputers QC eine Route für das eine Waffe oder einen Gefechtskopf oder ein Geschoss oder eine Munition oder ein anderes Fahrzeug ermittelt.

Feature 54: Vehicle according to any of features 45 to 52

• - wherein the vehicle uses the quantum computer QC to determine a route for the one weapon or warhead or missile or ammunition or other vehicle.

• - wobei die Steuervorrichtung µC zumindest zeitweise ein neuronales Netzwerkmodell ausführt und
• - wobei das neuronale Netzwerkmodell Eingangswerte und/oder Eingangssignale verarbeitet und
• - wobei das neuronale Netzwerkmodell Ausgangssignale und/oder Ausgangswerte ausgibt und
• - wobei die Steuervorrichtung µC in Abhängigkeit von Ausgangssignalen und/oder Ausgangswerten des neuronalen Netzwerkmodells Zustände der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder Zustände der Kernquantenpunkte CI1₁, CI1₂, C11₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, beeinflusst und/oder
• - wobei die Steuervorrichtung µC in Abhängigkeit von Zuständen der Quantenpunkte NV1, NV2, NV3, insbesondere der Quantenbits des Quantencomputers QC, und/oder Zuständen der Kernquantenpunkte CI1₁, CI1₂, C11₃, CI2₁, CI2₂, CI2₃, CI3₁, CI3₂, CI3₃, insbesondere der nuklearen Quantenbits des Quantencomputers QC, Eingangssignale und/oder Eingangswerte des neuronalen Netzwerkmodells beeinflusst.

Feature 55: Vehicle according to one or more of features 39 to 54

• - wherein the control device μC at least temporarily executes a neural network model and
• - wherein the neural network model processes input values and/or input signals and
• - wherein the neural network model emits output signals and/or output values and
• - wherein the control device μC, depending on output signals and/or output values of the neural network model, states of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, influenced and/or
• - wherein the control device µC depending on states of the quantum dots NV1, NV2, NV3, in particular the quantum bits of the quantum computer QC, and/or states of the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ , in particular the nuclear quantum bits of the quantum computer QC, influence input signals and/or input values of the neural network model.

character list

• 1 shows the quantum computer QC described above in a schematically simplified manner.
• 2 shows two exemplary quantum bits QUB1, QUB2.
• 3 Figure 12 shows the block diagram of an exemplary quantum computer QC with an exemplary three-bit quantum register indicated schematically.
• 4 shows an exemplary quantum computer system QUSYS with an exemplary central control unit ZSE.
• 5 shows an exemplary aircraft FZ as an exemplary vehicle with multiple deployable quantum computers QC1, QC2.
• 6a shows another example of use of the proposed deployable quantum computer QC in an aircraft FZ.
• 6b shows a deployable quantum computer QC in a sea container SC on a low-loader TL with a tractor ZM.
• 6c shows an exemplary aircraft carrier FZT as an exemplary floating body.
• 6d shows a factory building FHB as an example of a stationary device in which several relocatable quantum computers QC have been introduced here by way of example.
• 7 shows another example of a vehicle with a proposed quantum computer system QUSYS with two quantum computers QC here by way of example, which is an example of a submarine SUB.
• 8th shows a vehicle with a first quantum computer QC1, a second quantum computer QC2, a central control unit ZSE and an external data bus EXTDB, which connects them to a quantum computer system QUSYS, the vehicle in the example being the 8th an exemplary motor vehicle is KFZ.
• 9 shows a check whether the solution of an NP-complete problem is in fact a solution.
• 10 shows a quantum computer system QUSYS with a daisy-chain arrangement of the quantum computers QC1 to QC16.
• 11 shows a quantum computer system QUSYS with several sub-quantum computer systems.
• 12 shows the solution of an NP-complete problem using a mobile relocatable quantum computer QC.
• 13 shows an exemplary structure of an amplifier V, as shown in FIG 1 is drawn.
• 14 shows an example of a garment with a deployable quantum computer system QUSYS.
• 15 FIG. 12 shows an example of a satellite or spacecraft as an example of a vehicle with a deployable quantum computing system QUSYS.
• 16 shows an example of a smartphone with a deployable quantum computer system QUSYS.
• 17 largely corresponds to the 1 , whereby the mechanical basic construction MGK is also shown.

Description of the figures

The figures explain the proposal in a schematic and simplified manner. The disclosure of the document presented here is not limited to the figures and also includes other combinations.

figure 1

1 shows the exemplary relocatable quantum computer QC described above in a schematically simplified manner. The document presented here does not repeat the description at this point.

figure 2

The 2 shows two exemplary quantum bits QUB1, QUB2. In the following, the document presented here initially describes the first quantum bit QUB1. The second quantum bit QUB2 results analogously. The substrate D has an underside US on which a backside contact BSC is attached. The substrate D is particularly preferably made of diamond. The quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer are preferably irradiated QC with pump radiation LB from the underside US of the substrate D. The isotopes of the substrate D preferably have essentially no nuclear magnetic moment μ. An epitaxial layer DEPI is applied to the substrate D to improve the electronic properties. The substrate D and/or the epitaxial layer DEPI preferably comprise essentially only isotopes without a nuclear magnetic moment μ. The substrate D and/or the epitaxial layer DEPI preferably comprises essentially only one isotope type of an isotope without a nuclear magnetic moment μ. The package made up of substrate D and epitaxial layer DEPI has a surface OF. A vertical line LV1 is applied to the surface OF as part of an exemplary crossbar structure, through which a vertical electric current IV1 modulated with a vertical modulation flows. The surface OF and the vertical line LV1 are covered by an insulation IS. There may be additional insulation between the vertical line LV1 and the surface OF in order to electrically insulate the vertical line LV1. A first horizontal line LH1, through which a first horizontal electrical current IH1 modulated with a first horizontal modulation flows, is applied to the insulation IS. The first vertical line LV1 and the first horizontal line LH1 are preferably electrically isolated from one another. Preferably, the angle α ₁₁ between the first hori zontal line LH1 and the first vertical line LV1 a right angle of 90°. The first horizontal line LH1 and the first vertical line LV1 preferably cross above the paramagnetic center of the first quantum dot NV1 of the first quantum bit of the quantum computer QC. The first quantum dot NV1 of the first quantum bit of the quantum computer QC is preferably an NV center in diamond. The first quantum dot NV1 of the first quantum bit of the quantum computer QC is preferably located directly below the crossing point of the first horizontal line LH1 and the first vertical line LV1 at a first distance d1 below the surface OF in the epitaxial layer DEPI. The first distance d1 is preferably between 10 μm and 20 μm, worse between 5 μm and 40 μm, worse between 2.5 μm and 80 μm. In the case of diamond as the material of the epitaxial layer DEPI, the first quantum dot NV1 of the first quantum bit of the quantum computer QC can be an NV center, for example. The use of SiV and/or TR12 centers and other paramagnetic centers in diamond is also conceivable. If the horizontal modulation of the first horizontal current IH1 is shifted by +/-ττ/2 compared to the vertical modulation of the first vertical current IV1, then a rotating magnetic field B _NV , for example, results at the location of the first quantum dot NV1 of the first quantum bit of the quantum computer QC, affecting the first quantum dot NV1 of the first quantum bit of the quantum computer QC. The control device μC of the quantum computer QC can use this to manipulate the first quantum dot NV1 of the first quantum bit of the quantum computer QC. In this case, the control device μC selects the frequency in such a way that the first quantum dot NV1 of the first quantum bit of the quantum computer QC resonates with the rotating magnetic field B _NV . The duration of the pulse then determines the angle of rotation of the quantum information of the first quantum dot NV1 of the first quantum bit of the quantum computer QC. The direction of polarization determines the direction.

The 2 includes, for example, six nuclear quantum dots of the nuclear quantum bits of the quantum computer QC viz
firstly, a first nuclear quantum point CI1 ₁ of the first nuclear quantum bit of the quantum computer QC, which is associated with the first quantum point NV1 of the first quantum bit of the quantum computer QC, and
second, a second nuclear quantum point CI1 ₂ of the second nuclear quantum bit of the quantum computer QC, which is associated with the first quantum point NV1 of the first quantum bit of the quantum computer QC, and
third, a third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the quantum computer QC, which is associated with the first quantum point NV1 of the first quantum bit of the quantum computer QC, and
Fourth, a first nuclear quantum dot CI2 ₁ of the first nuclear quantum bit of the quantum computer QC, which is associated with the second quantum dot NV2 of the second quantum bit of the quantum computer QC, and
fifth, a second nuclear quantum dot CI2 ₂ of the second nuclear quantum bit of the quantum computer QC, which is associated with the second quantum dot NV2 of the second quantum bit of the quantum computer QC, and
Sixth, a third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the quantum computer QC, which is associated with the second quantum point NV2 of the second quantum bit of the quantum computer QC.

Each of the nuclear quantum dots of the nuclear quantum bits of the quantum computer QC forms a respective nuclear quantum bit (nuclear quantum bit) with the lines LV1, LH1, LH2. In the respective nuclear quantum bit, the quantum dot NV1, NV2 is replaced by the nuclear quantum dot CI1 ₁ , CI1 ₂ , CI1 ₃ in QUB1 and CI2 ₁ , CI2 ₂ , CI2 ₃ in QUB2.

Isotopes with a magnetic nuclear spin preferably form the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the quantum computer QC in the substrate D. In the case of diamond as the material of the epitaxial layer DEPI or des Substrate D can be a nuclear quantum dot of a nuclear quantum bit of the quantum computer QC, for example a ¹³ C isotope or an atomic nucleus of a nitrogen atom of an NV center.

2 12 shows an exemplary quantum register with a first quantum bit QUB1 and a second quantum bit QUB2. The quantum bits QUB1, QUB2 of the quantum register have a common substrate D and a common epitaxial layer DEPI. The first vertical line of the first quantum bit QUB1 is the first vertical line LV1 of the second quantum bit QUB2. The first vertical line LV1 and the first horizontal line LH1 preferably cross above the first quantum dot NV1 of the first quantum bit of the quantum computer QC, which is preferably a first distance d1 below the surface OF lies at a preferably right angle α ₁₁ of 90°. The first vertical horizontal line LV1 and the second horizontal line LH2 preferably cross above the second quantum dot NV2 of the second quantum bit of the quantum computer QC, which is preferably a second distance d2 below the surface, preferably at a right angle α ₁₂ . Preferably, the first distance d1 and the second distance d2 are similar to each other. With NV centers in diamond as quantum dots NV1, NV2 of the quantum bits of the quantum computer QC, these distances d1, d2 are preferably 10 nm to 20 nm. A first vertical current IV1 modulated with a horizontal modulation flows through the first vertical line LV1. A first horizontal current IH1 modulated with a first horizontal modulation flows through the first horizontal line LH1. A second horizontal current IH2 modulated with a second horizontal modulation flows through the second horizontal line LH2. The first quantum dot NV1 of the first quantum bit of the quantum computer QC is spaced from the second quantum dot NV2 of the second quantum bit of the quantum computer QC by a distance sp12.

The 2 shows an exemplary core-electron-core-electron quantum register CECEQUREG.

The core-electron-core-electron quantum register comprises an electron-electron quantum register in which the first quantum dot NV1 of the first quantum bit QUB1 of the quantum computer QC can couple with the second quantum dot NV2 of the second quantum bit QUB2 of the quantum computer QC.

The core-electron core-electron quantum register comprises a first core-electron quantum register in which the first quantum dot NV1 of the first quantum bit QUB1 of the quantum computer QC can couple with the first core quantum dot CI1 ₁ of the first core quantum bit of the nuclear quantum bits of the quantum computer QC.

The core-electron core-electron quantum register comprises a second core-electron quantum register in which the first quantum dot NV1 of the first quantum bit QUB1 of the quantum computer QC can couple with the second core quantum dot CI1 ₂ of the second core quantum bit of the nuclear quantum bits of the quantum computer QC.

The core-electron core-electron quantum register includes a third core-electron quantum register in which the first quantum dot NV1 of the first quantum bit QUB1 of the quantum computer QC can couple with the third core quantum dot CI1 ₃ of the second core quantum bit of the nuclear quantum bits of the quantum computer QC.

The core-electron core-electron quantum register includes a fourth core-electron quantum register in which the second quantum dot NV2 of the second quantum bit QUB2 of the quantum computer QC can couple with the first core quantum dot CI2 ₁ of the fourth core quantum bit of the nuclear quantum bits of the quantum computer QC.

The core-electron core-electron quantum register includes a fifth core-electron quantum register in which the second quantum dot NV2 of the second quantum bit QUB2 of the quantum computer QC couple with the second nuclear quantum dot 1,CI2 ₂ of the fifth core quantum bit of the nuclear quantum bits of the quantum computer QC can.

The core-electron core-electron quantum register includes a sixth core-electron quantum register in which the second quantum dot NV2 of the second quantum bit QUB2 of the quantum computer QC can couple with the third core quantum dot CI2 ₃ of the sixth core quantum bit of the nuclear quantum bits of the quantum computer QC.

This is the simplest form of a quantum bus with a first quantum ALU QUALU1 (NV1, CI1 ₁ , CI1 ₂ , Cl1 ₃ ) and a second quantum ALU QUALU2 (NV2, CI2 ₁ , CI2 ₂ , CI2 ₃ ). The control device μC can use _the first quantum point NV1 of the first quantum bit of the _quantum computer _{QC and the second} Quantum dot NV2 of the second quantum bit of the quantum computer QC entangle with each other. The first quantum dot NV1 of the first quantum bit of the quantum computer QC and the second quantum dot NV2 of the second quantum bit of the quantum computer QC preferably serve to transport the dependency and the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ the nuclear Quantum computer QC quantum bits for calculations and storage. Here, use is made of the fact that the range of the coupling of the quantum dots NV1, NV2 of the quantum bits of the quantum computer QC with one another is greater than the range of the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the quantum computer QC among themselves and that the T2 time of the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , C12 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the quantum computer QC is longer than that of the quantum dots NV1, NV2 of the quantum bits of the quantum computer QC.

Typically, the distance between the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ of the first quantum ALU QUALU1 of the quantum computer QC and the second quantum dot NV2 of the second quantum bit of the quantum computer QC is greater than the electron-nucleus coupling range, so the state of the core quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ of the nuclear quantum bits of the first quantum ALU QUALU1 of the quantum computer QC can not affect the state of the second quantum dot NV2 of the second quantum bit of the quantum computer QC and the state of the second quantum dot NV2 of the second quantum bit of the quantum computer QC the state of the nuclear quantum dots CI1 ₁ , CI1 ₂ , CI1 ₃ of the nuclear quantum bits of the first quantum ALU QUALU1 of the quantum computer QC can not affect.

Typically, the distance between the nuclear quantum dots CI2 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the second quantum ALU QUALU2 of the quantum computer QC and the first quantum dot NV1 of the first quantum bit of the quantum computer QC is greater than the electron-nucleus coupling range, so the state of the nuclear quantum dots CI2 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the second quantum ALU QUALU2 of the quantum computer QC cannot affect the state of the first quantum dot NV1 of the first quantum bit of the quantum computer QC and the state of the first quantum dot NV1 of the first quantum bit of the quantum computer QC the state of the nuclear quantum dots CI2 ₁ , CI2 ₂ , CI2 ₃ of the nuclear quantum bits of the second quantum ALU QUALU2 of the quantum computer QC cannot directly affect.

2 FIG. 1 shows an exemplary quantum register with a second horizontal shielding line SH2 and with a first horizontal shielding line SH1 and with a third horizontal shielding line SH3. The additional shield lines allow the injection of further currents to improve the selection of the quantum dots of the quantum bits of the quantum computer QC during the execution of the operations by energizing the vertical and horizontal lines. The two additional lines allow an even better adjustment.

2 shows an exemplary two-bit electron-electron quantum register with a common first vertical line LV1, several shielding lines and two quantum dots NV1, NV2 of the quantum bits of the quantum computer QC. In the 2 In order to explain the readout process, a first vertical shielding line SV1 is drawn in parallel to the first vertical line LV1. Since this is a cross-sectional image, the corresponding second vertical shielding line SV2, which also runs parallel to the first vertical line LV1 on the other side thereof, is not shown. In this example, the shielding lines are connected to the substrate D by contacts. If an extraction field is now created between two shielding lines running in parallel by applying an extraction voltage between these shielding lines SV1, SV2, a measurable current flow occurs when the light source LD irradiates the quantum dots NV1, NV2 of the quantum bits of the quantum computer QC with pump radiation LB and this is in the are in the right quantum state. More can be found, for example, in Petr Siyushev, Milos Nesladek, Emilie Bourgeois, Michal Gulka, Jaroslav Hruby, Takashi Yamamoto, Michael Trupke, Tokuyuki Teraji, Junichi Isoya, Fedor Jelezko, "Photoelectrical imaging and coherent spin-state readout of single nitrogenvacancy centers in diamond" , Science 363, 728-731 (2019) 15 February 2019.

The two quantum dots NV1, NV2 of the quantum bits of the quantum computer QC of 2 are each part of several core-electron quantum registers. Each quantum dot NV1, NV2 of the quantum bits of the quantum computer QC is the in the example 2 Part of a respective QuantenALU QUALU1, QUALU2.

The first quantum dot NV1 first quantum bits of the first quantum ALU QUALU1 of the quantum computer QC can in the example 2 interact with a first nuclear quantum point CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the first horizontal line LH1 and the first vertical line LV1 with a first horizontal current IH1 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with a first electron-nuclear radio wave resonance frequency f _{RWEC1_1} for the first quanta ALU QUALU1 or a first nuclear-electron microwave resonance frequency f _{MWCE1_1} for the first quanta ALU QUALU1 modulated. The quantum computer QC measures this first electron-nuclear radio wave resonance frequency f _{RWEC1_1} for the first quantum ALU QUALU1 and this first nuclear-electron microwave resonance frequency (f _{MWCE1_1} ) for the first quantum ALU QUALU1 preferably once in an initialization step through an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

In the example, the first quantum dot NV1 of the quantum bits of the first quantum ALU QUALU1 of the quantum computer QC can be the 2 interact with a second nuclear quantum point CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the first horizontal line LH1 and the first vertical line LV1 with a first horizontal current IH1 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with a second electron-nuclear radio-wave resonance frequency f _{RWEC2_1} for the first quanta ALU QUALU1 or a second nuclear-electron microwave resonance frequency f _{MWCE2_1} for the first quanta ALU QUALU1 modulated. The quantum computer QC measures this second electron-nuclear radio wave resonance frequency f _{RWEC2_1} for the first quanta ALU QUALU1 and this second nuclear-electron microwave resonance frequency (f _{MWCE2_1} ) for the first quanta ALU QUALU1 preferably in an initialization step once by an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

The first quantum dot NV1 of the first quantum bit of the first quantum ALU QUALU1 of the quantum computer QC can in the example of 2 interact with a third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the first horizontal line LH1 and the first vertical line LV1 with a first horizontal current IH1 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with a third electron-nuclear radio wave resonance frequency f _{RWEC3_1} for the first QuantenALU QUALU1 or a third nuclear-electron microwave resonance frequency f _{MWCE3_1} for the first QuantenALU QUALU1 modulated. The quantum computer QC measures this third electron-nuclear radio wave resonance frequency f _{RWEC3_1} for the first quanta ALU QUALU1 and this third nuclear-electron microwave resonance frequency (f _{MWCE3_1} ) for the first quanta ALU QUALU1 preferably in an initialization step once by an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

The second quantum dot NV2 of the quantum bit of the second quantum ALU QUALU2 can in the example 2 interact with a first nuclear quantum point CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the second horizontal line LH2 and the first vertical line LV1 with a second horizontal current IH2 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with a fourth electron-nuclear radio wave resonance frequency f _{RWEC1_2} for the second QuantenALU QUALU2 or a fourth nuclear-electron microwave resonance frequency f _{MWCE1_2} for the second QuantenALU QUALU2 modulated. The quantum computer QC measures this fourth electron-nuclear radio wave resonance frequency f _{RWEC1_2} for the second QuantenALU QUALU2 and this fourth nuclear-electron microwave resonance frequency (f _{MWCE1_2} ) for the second QuantenALU QUALU2 preferably in an initialization step once by an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

In the example, the second quantum dot NV2 of the quantum bit of the second quantum ALU QUALU2 of the quantum computer QC 2 interact with a second nuclear quantum point CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the second horizontal line LH2 and the first vertical line LV1 with a second horizontal current IH2 and a first vertical Current IV1 energized, which the microwave and / or radio wave frequency generator MW / RF-AWFG with a fifth electron-nuclear radio wave re modulated resonance frequency f _{RWEC2_2} for the second QuantenALU QUALU2 or a fifth nuclear-electron microwave resonance frequency f _{MWCE2_2} for the second QuantenALU QUALU2. The quantum computer QC measures this fifth electron-nuclear radio wave resonance frequency f _{RWEC2_2} for the second QuantenALU QUALU2 and this fifth nuclear-electron microwave resonance frequency (f _{MWCE2_2} ) for the second QuantenALU QUALU2 preferably in an initialization step once by an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

The second quantum dot NV2 of the quantum bit of the second quantum ALU QUALU2 can in the example 2 interact with a third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG supplies the second horizontal line LH2 and the first vertical line LV1 with a second horizontal current IH2 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with a sixth electron-nuclear radio wave resonance frequency f _{RWEC2_2} for the second QuantenALU QUALU2 or a sixth nuclear-electron microwave resonance frequency f _{MWCE3_2} for the second QuantenALU QUALU2 modulated. The quantum computer QC measures this sixth electron-nuclear radio wave resonance frequency f _{RWEC3_2} for the second QuantenALU QUALU2 and this sixth nuclear-electron microwave resonance frequency (f _{MWCE3_2} ) for the second QuantenALU QUALU2 preferably in an initialization step once by an OMDR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory NVM, RAM of the processor core CPU of the control device μC, which it calls up when the processor core CPU is to control the corresponding first core-electron quantum register CEQUREG1. The computer core CPU of the control device μC then sets the frequencies accordingly.

Since the coupling range of the quantum dots NV1, NV2 of the quantum bits of the quantum computer QC is greater, they can be coupled with one another. The second quantum dot NV2 second quantum bits of the second quantum ALU QUALU2 of the quantum computer QC can in the example of 2 interact with the first quantum dot NV1 of the first quantum bit of the first quantum ALU QUALU1 of the quantum computer QC when the microwave and/or radio wave frequency generator MW/RF-AWFG connects the first horizontal line LH1 and the second horizontal line LH2 and the first vertical line LV1 with a first horizontal current IH1 and a second horizontal current IH2 and a first vertical current IV1 energized by the microwave and/or radio wave frequency generator MW/RF-AWFG with an electron1-electron2 microwave resonance frequency f _MWEE12 for the coupling of the first quantum dot NV1 of the first Quantum bits of the first quantum ALU QUALU1 of the quantum computer QC are modulated with the second quantum dot NV2 of the second quantum bit of the second quantum ALU QUALU2 of the quantum computer QC. The computer core CPU of the quantum computer QC measures this electron1-electron2 microwave resonance frequency f _MWEE12 for the coupling of the first quantum dot NV1 of the first quantum bit of the first quantum ALU QUALU1 of the quantum computer QC preferably once in said initialization step by a further ODMR measurement. The processor core CPU of the quantum computer QC stores the measured values in a memory RAM, NVM of the processor core CPU of the control device µC, which this processor core CPU calls up when the corresponding electron-electron quantum register comprising the first quantum dot NV1 of the first quantum bit of the quantum computer QC and the second quantum dot NV2 of the second quantum bit of the quantum computer QC is to be controlled. The computer core CPU of the control device μC then sets the frequencies accordingly.

figure 3

3 shows the block diagram of an exemplary quantum computer QC with an exemplary schematically indicated three-bit quantum register, which could possibly also be replaced by a three-bit core-electron-core-electron quantum register (CECEQUREG) with three quantum ALUs. An extension to an n-bit quantum register is easily possible for a person skilled in the art.

The core of the exemplary control device 3 is a control device μC, which preferably includes a computer core CPU. The overall device preferably has a magnetic field control, preferably in the form of a first magnetic field control MFSx and a second magnetic field control MFSy and a third magnetic field control MFSz, which preferably receives its operating parameters from said control device μC and preferably returns operating status data to this control device μC. The magnetic field control MFSx, MFSy, MFSz is preferably a multidimensional controller whose task it is to compensate an external magnetic field by active counter-regulation. The magnetic field control MFSx, MFSy, MFSz preferably uses one or more magnetic field sensors MSx, MSy, MSZ for this purpose, which preferably detects the magnetic flux in the quantum computer QC preferably in the vicinity of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and not in the Figure for a better overview drawn nuclear quantum points CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC recorded. The magnetic field sensors MSx, MSy, MSZ are preferably quantum sensors. Examples are the applications DE 10 2018 127 394.0, DE 10 2019 130 114.9, DE 10 2019 120 076.8 and DE 10 2019 121 137 .9 referenced. With the help of the magnetic field control device, for example in the form of the first magnetic field generating means MGx and the second magnetic field generating means MGy and the third magnetic field generating means MGz and, the magnetic field control MFSx, MFSy, MFSz regulates the magnetic flux density B in the vicinity of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and the nuclear quantum points CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 1 , _{CI3 2 ,} CI3 ₃ of the nuclear quantum bits of the quantum computer QC, which are not drawn in the figure for a better overview. The document presented here proposes using preferably quantum sensors as magnetic field sensors MSx, MSy, MSZ, since these have higher accuracy in order to sufficiently stabilize the magnetic field.

The control device μC preferably controls the horizontal and vertical driver stages HD1, HD2, HD3 via a control unit ACBA, which preferably energize the horizontal lines LH1, LH2, LH3 and vertical lines LV1 with the respective horizontal and vertical currents and the correct frequencies and times Generate burst durations and burst positions relative to a time starting point t ₀ .

The control unit A CBA sets the frequency and the pulse duration of the first horizontal shielding current ISH1 for the first horizontal shielding line SH1 in the first horizontal driver stage HD1 in accordance with the specifications of the control device μC.

The control unit A CBA adjusts the frequency and the pulse duration of the second horizontal shielding current ISH2 for the second horizontal shielding line SH2 in the first horizontal driver stage HD1 and in the second horizontal driver stage HD2 according to the specifications of the control device μC.

The control unit A CBA adjusts the frequency and the pulse duration of the third horizontal shielding current ISH3 for the third horizontal shielding line SH3 in the second horizontal driver stage HD2 and in the third horizontal driver stage HD3 according to the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the fourth horizontal shielding current ISH4 for the fourth horizontal shielding line SH4 in the third horizontal driver stage HD3 and in the fourth horizontal driver stage HD4, which is only indicated due to lack of space, according to the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the first horizontal current IH1 for the first horizontal line LH1 in the first horizontal driver stage HD1 in accordance with the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the second horizontal current IH2 for the second horizontal line LH2 in the second horizontal driver stage HD2 in accordance with the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the third horizontal current IH3 for the third horizontal line LH3 in the third horizontal driver stage HD3 in accordance with the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the first vertical shielding current ISV1 for the first vertical shielding line SV1 in the first vertical driver stage HV1 in accordance with the specifications of the control device μC.

The control unit A CBA sets the frequency and the pulse duration of the first vertical current IV1 for the first vertical line LV1 in the first vertical driver stage VD1 in accordance with the specifications of the control device μC.

Synchronized by the control unit A CBA, these driver stages VD1, HD1, HD2, HD3, HD4 feed their current into the lines SV1, LV1, SV2, SH1, LH1, SH2, LH2, SH3, LH3, SH4 a.

When the quantum states of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC or the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC necessary.

A control unit B CBB is connected to the control device μC via the control data bus SDB. The control device configures the A control unit B CBB via the control data bus SDB and sets operating parameters and reads out data and operating states via the control data bus SDB. The control unit B CBB preferably records the respective photocurrent that the receiver stages HS1, HS2, HS3, VS1 record and makes the measurement data available to the control device μC via the control data bus SDB.

Beforehand, the control device μC configures a first horizontal receiver stage HS1 via the control data bus SDB and typically via the control unit B CBB in such a way that it removes the currents fed in from the first horizontal driver stage HD1 on the other side of the lines.

Beforehand, the control device μC configures a second horizontal receiver stage HS2 via the control data bus SDB and typically via the control unit B CBB in such a way that it draws the currents fed in from the second horizontal driver stage HD2 on the other side of the lines.

Beforehand, the control device μC configures a third horizontal receiver stage HS3 via the control data bus SDB and typically via the control unit B CBB in such a way that it draws the currents fed in from the third horizontal driver stage HD3 on the other side of the lines.

Beforehand, the control device μC configures a first vertical receiver stage VS1 via the control data bus SDB and typically via the control unit B CBB in such a way that it removes the currents fed in from the first vertical driver stage VD1 on the other side of the lines.

Furthermore, the exemplary system of 3 a light source LD for pump radiation LB within the meaning of this document. The control device μC can use a light source driver LDRV to irradiate the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC with the pump radiation LB via the optical system OS. When irradiated with this pump radiation LB, the paramagnetic centers of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC produce photoelectrons, which are detected by the first horizontal receiver stage HS1 and/or the second horizontal receiver stage HS2 and/or the third horizontal receiver stage HS3 and/or the first vertical receiver stage VS1 can be extracted by applying an extraction field, for example to the connected shielding lines SH1, SH2, SH3, SH4, SV1, SV2.

The microwave and / or radio wave frequency generator MW / RF-AWFG for generating largely freely definable waveforms (English: Arbitrary Wave Form Generator) includes in the example of 3 the control unit A CBA, the first horizontal driver stage HD1, the second horizontal driver stage HD2, the third horizontal driver stage HD2 and the first vertical driver stage VD1.

In addition, the microwave and / or radio wave frequency generator MW / RF-AWFG for generating largely freely definable waveforms (English: Arbitrary Wave Form Generator) can also be interpreted in such a way that in the example of 3 the control unit B CBB, the first horizontal receiver stage HS1, the second horizontal receiver stage HS2, the third horizontal receiver stage HS2 and the first vertical receiver stage VS1.

The lines SV1, LV1, SV2, SH1, LH1, SH2, LH2, SH3, LH3, SH4 form in the example of 3 the exemplary microwave and/or radio wave antenna mWA.

figure 4

4 shows an exemplary quantum computer system QUSYS with an exemplary central control unit ZSE. In this example, the exemplary central control unit ZSE is connected to a multiplicity of quantum computers QC1 to QC16 via a preferably bidirectional data bus, the external data bus EXTDB. Such a quantum computer system QUSYS preferably comprises more than one quantum computer QC1 to QC16. In the example of 4 each of the quantum computers QC1 to QC16 includes a respective control device μC1 to μC16. The quantum computer system QUSYS preferably includes a charging device LDV, which charges an energy reserve BENG with the energy from a power supply PWR of the charging device LDV and/or supplies an energy conditioning device SRG with electrical energy. The energy processing device SRG supplies one or more device parts of the quantum computer system QUSYS with electrical energy from the energy reserve BENG and/or with electrical energy from the charging device LDV. The energy processing device SRG preferably supplies one or more device parts of the quantum computer system QUSYS with electrical energy from the energy reserve BENG if a device part of the quantum computer system QUSYS performs a quantum operation to manipulate a quantum dot NV1, NV2, NV3 of the quantum bits of the quantum computer QC and/or to manipulate a core quantum dot CI1 ₁ , CI1 ₂ , C11 ₃ , C12 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC executes. In the example of 4 For example, 16 quantum computers QC1 to QC16 are connected to the central control device ZSE via the external data bus EXTDB. The external data bus EXTDB can be any suitable data transmission system. For example, it can be wired, wireless, fiber optic, optical, acoustic, or radio-based. In the case of a wired system, the external data bus EXTDB can be a single-wire data bus, such as a LIN bus, or a two-wire data bus, such as a CAN data bus, in whole or in part. The external data bus EXTDB can be, for example, a more complex data bus with multiple conductors and/or multiple logic levels, etc., in whole or in part. The external data bus EXTDB can be, for example, an Ethernet data bus in whole or in part. The external data bus EXTDB can consist entirely of one type of data bus or be composed of different data transmission paths of different types. The external data bus EXTDB can be star-shaped as in the example 4 be arranged. The external data bus EXTDB can also be implemented in whole or in part, for example as in a daisy chain (https://de.wikipedia.org/wiki/Daisy_Chain) as a concatenation of the bus nodes in the form of the quantum computers QC1 to QC16, in which case each the control devices of the relevant quantum computer of this part of the quantum computer system QUSYS preferably have more than one data interface in order to be able to connect more than one external data bus EXTDB to the relevant quantum computer, for example for such a chain. It is conceivable that one or more quantum computers of the quantum computers QC1 to QC16 then act as bus masters and thus as central control devices ZSE for subordinate sub-networks of the quantum computer system QUSYS.

It is therefore also conceivable that the central control device ZSE of the quantum computer system QUSYS is the control device µC of a quantum computer QC or that the central control device ZSE of the quantum computer system QUSYS is a quantum computer QC with is a control device μC, in which case the 4 on the "normal" computer properties of the control device µC, which control the quantum computer system QUSYS as the central control device ZSE. From the perspective of the quantum computers QC1 to QC16, the central control device ZSE corresponds to an external monitoring computer of the quantum computer system QUSYS.

The data transmission network of the quantum computer system QSYS can correspond in whole or in part to a linear chain of bus nodes in the form of the quantum computers QC1 to QC16 along part of the external data bus EXTDB or along the external data bus EXTDB, which are also closed to form a ring (keyword: token ring). .

The data transmission network of the quantum computer system QSYS can be wholly or partially a star structure of bus nodes in the form of the quantum computers QC1 to QC16, which are connected to one or more data lines and/or data transmission media. A star structure is present, for example, in radio transmission of data. One, several or all of the quantum computers QC1 to QC16 can also be connected to the central control device ZSE via a point-to-point connection. In that case, the central control device ZSE must have a separate data interface for each point-to-point connection.

The data transmission network of the quantum computer system QSYS can be set up as a tree structure, with individual quantum computers having more than one data bus interface, for example, and being able to serve as a bus master, i.e. central control device ZSE for the sub-network of the data transmission network made up of data buses and quantum computers.

The quantum computer system QUSYS can thus be structured hierarchically, with the control devices μC of individual quantum computers being the central control device ZSE of sub-quantum computer systems. The sub-quantum computer systems are themselves quantum computer systems QUSYS. The central control device ZSE of the sub-quantum computer system is preferably itself a quantum computer, which is preferably itself part of a higher-level quantum computer system QUSYS.

This hierarchy allows different calculations to be processed in parallel in different sub-quantum computer systems, with the number of quantum computers used being chosen differently depending on the task.

The quantum computer system QUSYS thus preferably comprises a plurality of computer units coupled to one another. The computer units are typically computer cores CPU of the control devices μC of the quantum computers QC1 to QC16. Such a computing unit can use an artificial intelligence program that can be coupled to the quantum computers and/or the quantum registers and/or the quantum bits. Both the input into the artificial intelligence program can depend on the state of the quantum dots of the quantum bits of these components of the quantum computer system, and the activation of the quantum bits and quantum dots of these components of the quantum computer system can depend on the results of the artificial intelligence program. The artificial intelligence program can be executed both in the central control device ZSE and in the control devices μC1 to μC16 of the quantum computers QC1 to QC16. In this case, only parts of the artificial intelligence program can be executed in the central control device ZSE, while other parts of the artificial intelligence program are executed in the control devices μC of quantum computers within the quantum computer system. Also, only parts of the artificial intelligence program can be executed in one of the control devices µC1 to µC16 of the quantum computers QC1 to QC16, while other parts of the artificial intelligence program are executed in other control devices µC1 to µC16 of other quantum computers QC1 to QC16 within the quantum computer system QUSYS become. This processing of a program of the artificial intelligence can thus be distributed over the quantum computer system QUSYS or be concentrated in a control device of the control devices μC1 to μC16 of the quantum computers QC1 to QC16. The artificial intelligence program interacts with quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computers QC1 to QC16. In reality, the control device can also be a system of control devices μC1 to μC16. A control device can, for example, be the central control device ZSE of a quantum computer system QSYS with one or more quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computers QC1 to QC16 and/or one or more control devices µC of one or more quantum computers QC1 to QC16, each with one or more Quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computers QC1 to QC16 include. More complex topologies with further interconnected computer nodes and data bus branches are conceivable. The control device, which as described can also be a combination of control devices, executes an artificial intelligence program. Such an artificial intelligence program can be, for example, a neural network model with neural network nodes.

For example, one or more of the control devices of the control devices μC1 to μC16 of the quantum computers QC1 to QC16 and/or the central control unit ZSE can execute a machine learning method. The paper presented here refers, for example, to Akinori Tanaka, Akio Tomiya, Koji Hashimoto, "Deep Learning and Physics (Mathematical Physics Studies)" February 21, 2021, Publisher: Springer; 1st ed. 2021 Edition, ISBN-10: 9813361077, ISBN-13: 978-9813361072 and Ovidiu Calin, "Deep Learning Architectures: A Mathematical Approach (Springer Series in the Data Sciences)", Springer; 1st ed. 2020 edition (February 14, 2021), ISBN-10: 3030367231, ISBN-13: 978-3030367237. The methods explained in these documents are part of the disclosure of the document presented here, insofar as a quantum computer QC, as presented in the document presented here, executes. One of the most common artificial intelligence techniques that a proposed quantum computer QC and/or a proposed quantum computer system QUSYS can execute is machine learning. Machine learning is a self-adaptive algorithm that a proposed quantum computer QC and/or a proposed quantum computer system QUSYS can execute. The so-called Deep learning that a proposed quantum computer QC and/or a proposed quantum computer system QUSYS can perform is typically a subset of machine learning. In machine learning, a proposed quantum computer QC and/or a proposed quantum computer system QUSYS uses a series of hierarchical layers or a hierarchy of concepts in order to carry out the machine learning process. The proposed quantum computer QC or the proposed quantum computer system QUSYS preferably uses a model of artificial neural networks that are organized and constructed virtually like the human brain. The virtual neurons of the neural network model, which the proposed quantum computer QC or the proposed quantum computer system QUSYS executes, are preferably connected to one another virtually like a network. The first virtual layer of the neural network, the visible input layer, processes a raw data input, such as the individual pixels of an image. Data input contains variables accessible to observation, hence “visible layer”. This first virtual layer of the neural network model forwards its outputs to the next virtual layer of the network model when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS. This second virtual layer processes the information from the previous virtual layer and also forwards the result when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS. The next third virtual layer of the neural network model receives the information from the second virtual layer when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS. The third virtual layer of the neural network model processes this information further when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS. These layers are called hidden layers. The features they contain are becoming increasingly abstract. Their values are not given in the original data. Instead, when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS, the neural network model should preferably determine which concepts are useful for explaining the relationships in the observed data. This now continues across all virtual layers of the artificial neural network model. The result is output in the visible last virtual layer when the neural network model is executed by the proposed quantum computer QC or by the proposed quantum computer system QUSYS. This breaks down the desired complex data processing into a series of nested simple mappings, each describing a different layer of the neural network model.

The neural network model typically uses one or more input values and/or one or more input signals. The neural network model typically provides one or more output values and/or one or more output signals. It is now proposed here to supplement the artificial intelligence program with a program that executes one or more of the above-mentioned quantum operations on one or more of the quantum computers QC1 to QC16. This coupling CAN, FOR EXAMPLE, IN ONE direction take place by controlling one or more quantum dots NV1 to NV3. in particular by means of horizontal lines LH1, LH2, LH3 and/or vertical lines LV1, from one or more output values and/or one or more output signals of the neural network model. In the other direction, states of one or more quantum dots are read out at a time and used as input in the artificial intelligence program, in this example the neural network model. The value of one or more input values and/or one or more input signals of the artificial intelligence program, here the neural network model, then depends on the state of one or more of the quantum dots NV1, NV2, NV3 of the quantum bits of the respective quantum computer QC and/or one or several nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , C12 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI33 of the nuclear quantum bits of the respective quantum computer QC.

figure 5

5 shows an aircraft FZ with several deployable quantum computers QC1, QC2. In the example of 5 the exemplary aircraft FZ has a first quantum computer QC1 and a second quantum computer QC2 and a central control unit ZSE, which is connected to the exemplary two quantum computers QC1, QC2 via an external data bus EXTDB. The external data bus EXTDB is the preferred part of the proposed aircraft FZ. The deployable quantum computers QC1, QC2 preferably solve NP-hard problems in the proposed aircraft FZ.

• • https://de.wikipedia.org/wiki/NP_(Komplexit%C3%A4tsklasse) und
• • https://en.wikipedia.org/wiki/NP-hardness

For example, see for more information on NP-hard problems

• • https://de.wikipedia.org/wiki/NP_(complexity%C3%A4tsclass) and
• • https://en.wikipedia.org/wiki/NP-hardness

Such problems can, for example, concern the arrangement of certain loads in the cargo hold or optimization problems such as the optimal travel route. It is also conceivable that the deployable quantum computers QC1, QC2 in the aircraft FZ carry out or support artificial intelligence tasks. The relocatable quantum computers QC1, QC2 are preferably connected via the external data bus EXTDB to the central control device ZSE, which is typically another control device of the aircraft FZ. For example, the central control device ZSE can be a computer system in the cockpit of the aircraft FZ or in a server room of the aircraft FZ. The proposed aircraft FZ thus preferably includes a quantum computer system QUSYS with at least one quantum computer QC1, QC2.

The quantum computers QC1, QC2 can also support the pilots and the other computer systems of the aircraft FZ. For example, the quantum computers QC1, QC2 of the aircraft FZ can support the flight attitude control system FLR and/or the navigation system and the autopilot NAV or take over their function in whole or in part. Of course, the functions of a quantum computer QC are not limited to these functions of an aircraft FZ.

For example, in question:

Airborne Weather Radar

Evaluation of the Airborne Weather Radar: The weather radar is usually installed in the front behind a radome, a closed protective cover (radar nose), of the FZ aircraft. It determines the weather in the area. The weather radar can transmit data to one or more quantum computers QC1, QC2 via the external data bus EXTDB. The quantum computers QC1, QC2 can then evaluate the weather radar data. The quantum computers QC1, QC2 preferably receive further data, for example via radio interfaces of the aircraft FZ from other places, such as weather services, headquarters of the airlines, aircraft manufacturers, etc. Typical NP complete problems that can be solved particularly well with quantum computers QC in this context are the evaluation of the Weather data and the optimization of the flight route with regard to danger, flight time, costs, etc. The quantum computers QC1, QC2 can carry out these calculations of NP-complete problems and warn the pilots of dangerous weather phenomena at an early stage and submit optimization proposals. If necessary, conventional computer systems of the aircraft can verify the results of the quantum computer programs that were executed on the quantum computers QC1, QC2 again in a conventional manner, since then no optimization search is necessary, and confirm the correctness of the quantum computer calculation to the pilot. The writing presented here refers to this as an example 9 .

ECAM (Electronic Centralized Aircraft Monitoring) or EICAS (Engine Indication and Crew Alerting System)

A further possible application is, for example, support for the ECAM (Electronic Centralized Aircraft Monitoring) by the quantum computers QC1, QC2 of the quantum computer system QUSYS of the aircraft. This electronic system preferably displays the most important engine parameters in the aircraft and checks all aircraft systems, such as fuel and hydraulics. It reports errors, especially non-statistical errors - in particular defects and malfunctions, and gives tips on how to fix the problem. This electronic system typically displays the most important engine parameters in the aircraft FZ and checks all aircraft systems, such as for fuel and hydraulics. It reports suspected or detected errors, especially non-statistical errors - in particular defects and malfunctions, and gives tips on how to fix the problem. For this purpose, the quantum computers QC1, QC2 can carry out quantum computer calculations in order to be able to recognize the probabilities of critical combinations of aircraft and environmental parameters and to determine measures, sequences of measures and flight routes, etc. in such a way that the probability of critical situations is minimized with maximum effectiveness.

TCAS (Traffic Alert and Collision Avoidance System)

The TCAS is an on-board early warning system of the proposed aircraft FZ to avoid aircraft collisions in the air. If two planes are on a collision course, it recommends a suitable evasive maneuver to the two pilots to avert an imminent collision. The quantum computers QC1, QC2 can, for example, taking into account the weather conditions etc., suggest alternative courses which firstly have a minimal collision probability and secondly are also optimal with regard to the weather conditions.

figure 6

Figure 6a

6a shows another example of use of the proposed deployable quantum computer QC in an aircraft FZ. In the example of 6a it is a military aircraft FZ. A military aircraft may be, for example, an interceptor, a long-range bomber, or a general fighter, or a helicopter, or the like.

It can also be a drone or the like.

In the example of 6a the fighter plane includes a quantum computer QC. For example, the quantum computer QC, in cooperation with a central control unit ZSE of the aircraft FZ, can solve the NP-complete problem of risk assessment of objects in the vicinity of the aircraft and along the route to the target, target selection and target determination and the sequence of target engagement, ammunition and weapon selection and process the fastest and at the same time the least risky route to the destination. In the example, the quantum computer QC is the 6 connected via an external data bus EXTDB within the aircraft FZ to the central control unit ZSE. The quantum computer QC preferably corresponds to a quantum computer QC 1 or the previous description.

In the example of 6a the exemplary combat aircraft FZ is armed with a first rocket RKT and a second rocket RKT. Arming with other weapons such as automatic cannons, jamming transmitters, reconnaissance devices etc. is also conceivable instead of arming with RKT rockets and/or in addition to arming with rockets. In this respect, the rockets are only examples of additional equipment that can be transported as payload by the FZ combat aircraft. In this respect, the aircraft FZ is only an example of a vehicle in the broadest sense.

In the example of 6a the vehicle in the form of the FZ aircraft has a quantum computer system QUSYS similar to the 4 with one or more central control devices ZSE, which are connected to one or more quantum computers QC via one or more external data buses EXTDB.

In the example of 6a the payload in the exemplary form of two RKT rockets each has its own quantum computer systems QUSYS similar to the 4 with one or more central control devices ZSE of the respective payload, which are connected via one or more external data buses EXTDB of the respective payload to one or more quantum computers QC of the respective payload. In the example of 6a each of the two exemplary rockets RKT has its own quantum computer system QUSYS of the respective rocket RKT similar to the 4 with one or more respective central control devices ZSE of the respective rocket RKT, which are connected to one or more quantum computers QC of the respective rocket RKT via one or more external data buses EXTDB of the respective rocket RKT.

In the state shown, the combat aircraft FZ therefore has several quantum computer systems QUSYS. A first quantum computer system QUSYS comprises at least one central control unit ZSE of the combat aircraft FZ and at least one external data bus EXTDB of the combat aircraft FZ and at least one quantum computer QC of the combat aircraft FZ. An exemplary second quantum computer system QUSYS comprises at least one central control unit ZSE of the first exemplary rocket RKT and at least one external data bus EXTDB of the first exemplary rocket RKT and at least one quantum computer QC of the first exemplary rocket RKT. An exemplary third quantum computer system QUSYS includes at least one central control unit ZSE of the two th exemplary rocket RKT and at least one external data bus EXTDB of the second exemplary rocket RKT and at least one quantum computer QC of the second exemplary rocket RKT.

The document presented here proposes that an external data bus EXTDB connects the first quantum computer system to the second and third quantum computer systems as long as the payloads are connected to the aircraft FZ.

After the RKT rockets have been fired, i.e. when the aircraft FZ separates from its payload in the form of the RKT rockets, a quantum computer system separation device QCTV separates the QUSYS quantum computer system of the separated payload, here the RKT rocket fired, from the QUSYS quantum computer system of the aircraft FZ. The vehicle here is an aircraft FZ, for example. However, a vehicle within the meaning of the document presented here can also be a motor vehicle, a two-wheeler, a tricycle or a truck, a commercial vehicle, a robot, a transport vehicle, a drone, a robotic drone, a missile, a floating body, a submersible body , a ship, a submarine, a sea mine, a land mine, a rocket, a projectile, a satellite, a space station, a trailer, a barge, a container, in particular a sea container or the like. The quantum computer system separation device QCTV preferably separates an external data bus EXTDB, which, for example, connects a first quantum computer system QUSYS to a second quantum computer system QUSYS, if necessary, so that the quantum computer system QUSYS, which previously included the first and the second quantum computer system QUSYS, is separated by the quantum computer system separation device QCTV in two separate quantum computer systems QUSYS disintegrates. Conversely, the quantum computer system separator QCTV can also connect a previously separate first quantum computer system QUSYS to a previously separate second quantum computer system QUSYS, for example via one or more external data buses EXTDB and couple them if necessary, so that a new, enlarged quantum computer system QUSYS is created, which then connects the first and second Quantum computer system QUSYS comprises by connecting these two quantum computer systems via quantum computer system separation device merged into one quantum computer system QUSYS. In such a new quantum computer system QUSYS from at least two previously separate quantum computer systems QUSYS, the central control unit ZSE of the quantum computer system QUSYS of the vehicle, here the combat aircraft FZ, preferably has a higher priority than the central control unit ZSE of the quantum computer system QUSYS of the payload, here the rocket RKT. This merging is particularly advantageous during the charging process, in which the payload is connected to the vehicle.

After the payload has been separated from the vehicle, the QUSYS quantum computer system can preferably act autonomously for the payload. In the example of 6a This means that after the separation of the rocket RKT as an exemplary payload from the combat aircraft FZ as an exemplary vehicle, the quantum computer system QUSYS of the rocket RKT can preferably act autonomously. However, it is conceivable that the quantum computer system QUSYS of the payload, here in the form of an RKT rocket, after separation from the vehicle, here in the form of the FZ combat aircraft, via a wireless or wired or via an optical fiber or a functionally equivalent data transmission link with the quantum computer system QUSYS of the vehicle, here the combat aircraft FZ, remains connected. In the extreme case, it is conceivable that, for example, each of the quantum computers QC1 to QC16 of the 4 the quantum computer QC of an individual vehicle, which are connected to a central control unit ZSE in a lead vehicle and/or to one another via a radio link as an external data bus EXTDB. For example, an exemplary quantum computer system QUSYS can be a drone swarm, in which each of the drones includes one or more quantum computers QC that communicate with one another wirelessly, for example via radio links or laser beam connections as an external data bus EXTDB. In the exemplary case of a swarm of drones, the quantum computer system QUSYS of the quantum computers QC1 to QC16 of the exemplary drones can therefore also not include a central control device ZSE. All drones are preferably designed roughly the same and then organize themselves preferably using swarm technologies.

In the example of 6a each rocket RKT includes a quantum computer QC. The quantum computer QC can, for example, in cooperation with a central control unit ZSE of the rocket RKT in question, the NP-complex problem of risk assessment of objects in the vicinity of the rocket RKT in question and along the route of the rocket RKT in question to the target, the target selection and target determination and the order of the Target engagement ammo and weapon selection and edit the quickest yet least risky route to the target. The RKT missile can also be a drone or a cruise missile that can engage multiple targets if necessary. The quantum computer QC of the rocket RKT in question is the in the example 6a via an external data bus EXTDB connected within the RKT rocket in question to the central control unit ZSE of the RKT rocket in question. The quantum computer QC of the rocket RKT in question preferably corresponds to a quantum computer QC 1 or the previous description.

Figure 6b

The 6b shows an exemplary deployable quantum computer QC in a sea container SC on a low loader TL with a tractor ZM. Both the sea container SC and the low-loader TL as well as the towing vehicle ZM can include one or more quantum computers QC and/or one or more quantum computer systems QUSYS. One or more quantum computers QC and/or one or more quantum computer systems QUSYS can be placed inside the sea container SC. All of these quantum computers QC and / or quantum computer systems QUSYS can during transport and / or before and / or after one or more quantum computer system QUSYS, as in the example of 6a explained in particular be interconnected at times. In the example of 6c an additional energy reserve BENG supplies the quantum computer system QUSYS with the quantum computer QC within the exemplary sea container SC with electrical energy.

Figure 6c

The 6c shows an exemplary aircraft carrier FZT. The exemplary aircraft carrier FZT comprises one or more quantum computers QC and/or one or more quantum computer systems QUSYS. The example aircraft carrier FZT is an example of a warship that includes one or more quantum computers QC and/or one or more quantum computer systems QUSYS. The example aircraft carrier FZT is an example of a ship that includes one or more quantum computers QC and/or one or more quantum computer systems QUSYS. The exemplary aircraft carrier FZT is an example of a floating body that includes one or more quantum computers QC and/or one or more quantum computer systems QUSYS. The example aircraft carrier FZT is an example of a vehicle that includes one or more quantum computers QC and/or one or more quantum computer systems QUSYS. The quantum computers QC and/or quantum computer systems QUSYS are preferably relocatable quantum computers QC within the meaning of the document presented here. For example, quantum computer systems QUSYS and/or quantum computer QC of aircraft FZ on the aircraft carrier FZT can be connected during transport by the aircraft carrier FZT and/or in the aircraft carrier FZT with one or more quantum computers QC and/or quantum computer systems QUSYS on the aircraft carrier FZT, for example via one or more quantum computer system separators QCTV and one or more external data buses EXTDB connected to larger quantum computer systems QUSYS.

In the example of 6c the aircraft carrier FZT includes, for example, one or more quantum computers QC and/or one or more quantum computer systems QUSYS. One or more of these quantum computers QC and/or one or more quantum computer systems QUSYS can, for example, in cooperation with a central control unit ZSE of the aircraft carrier FZT, solve the NP-complete problem of risk assessment of objects in the vicinity of the aircraft carrier FZT and along the route to a target, the target selection and target definition and the sequence of target engagements of aircraft, ammunition and weapon selection and edit the fastest and at the same time the least risky route to the target. The quantum computer(s) QC and/or the quantum computer system or quantum computer systems QUSYS on the aircraft carrier FZT are preferably connected to one another and to those of other devices on the aircraft carrier FZT via an external data bus EXTDB and, if appropriate, suitable quantum computer system separator devices QCTV within the aircraft carrier FZT. A quantum computer QC of the aircraft carrier FZT preferably corresponds to a quantum computer QC of 1 or the previous description.

Figure 6d

The 6d shows a factory building FHB as an example of a stationary device in which several quantum computers QC have been introduced here by way of example. In the example of 6d the normal power grid PWR supplies the deployable quantum computer systems QUSYS with their quantum computers QC within the exemplary stationary devices FBH with electrical energy. The stationary device FHB can, for example, comprise one or more quantum computer systems QUSYS with one or more quantum computers QC. The or the quantum computer QC and/or the quantum computer system or the quantum computer systems QUSYS of the stationary device FHB are preferably via a external data bus EXTDB and possibly suitable quantum computer system separation devices QCTV within the stationary device FHB with each other and with those of other devices of the stationary device FHB. A quantum computer QC of the stationary device FHB preferably corresponds to a quantum computer QC of 1 or the previous description.

figure 7

7 shows another example of a vehicle with a proposed quantum computer system QUSYS with two quantum computers QC here as an example. It is an exemplary submarine SUB. The exemplary submarine SUB has an energy system ERS as the energy source of the submarine SUB. The energy system ERS also represents the energy supply PWR of the charging device LDV of the quantum computer system QUSYS of the submarine SUB. The submarine SUB typically has a very large energy reserve BTR. A drive ENG drives in the example 7 the submarine SUB via one or more exemplary ship screws SCHR.

In the example of 7 the submarine SUB has a plurality of RKT missiles as armament. It can also be cruise missiles or other devices that are located on the submarine SUB as devices that can be separated from the submarine SUB. In this respect, the RKT rockets are only examples of devices that can be separated from a vehicle and, for example, as here, are on or in the vehicle, here a submarine SUB, as payload. For example, one or more of the missiles RKT of the submarine SUB may comprise one or more quantum computer systems QUSYS and/or one or more quantum computers QC. The one or more quantum computer systems QUSYS and/or one or more quantum computers QC are preferred by means of a quantum computer system separator QCTV and an external data bus EXTDB with the one and/or more quantum computer systems QUSYS and/or the one or more quantum computers QC1, QC2 of the submarine SUB tied together. The document presented here already describes the separation and connection of quantum computer systems QUSYS in the description of the 6a . Here the submarine SUB takes the role of the aircraft FZ 6a a. The relationships disclosed there also apply here to the extent applicable and are claimed to the extent applicable and reasonable. A missile launch control RKTC is an example of a fire control system of a vehicle. Here the vehicle is the submarine SUB. In the example of 7 the missile launch control RKTC and the submarine SUB can each have one or more quantum computer systems QUSYS and/or one or more quantum computers QC. Since the missile launch control RKTC is part of the submarine, the one or more quantum computer systems QUSYS and/or the one or more quantum computers QC of the missile launch control RKTC are also part of the submarine SUB. An external data bus EXTDB preferably connects the one or more quantum computer systems QUSYS and/or the one or more quantum computers QC of the missile launch control RKTC to the one or more quantum computer systems QUSYS and/or the one or more quantum computers QC of the submarine SUB.

In the example of 7 the submarine SUB has a plurality of torpedoes TRP as armament. They may be cruise missiles or other devices that are located on the submarine SUB as devices that can be separated from the submarine SUB and are separated, for example, via the torpedo tubes as an example of a mechanical separation device, for example by firing. In this respect, the torpedoes TRP are only examples of devices that can be separated from a vehicle and, for example, as here, are on or in the vehicle, here a submarine SUB, as payload. For example, one or more of the torpedoes TRP of the submarine SUB may comprise one or more quantum computer systems QUSYS and/or one or more quantum computers QC. The one or more quantum computer systems QUSYS and/or one or more quantum computers QC are preferred by means of a quantum computer system separator QCTV and an external data bus EXTDB with the one and/or more quantum computer systems QUSYS and/or the one or more quantum computers QC1, QC2 of the submarine SUB tied together. The document presented here already describes the separation and connection of quantum computer systems QUSYS in the description of the 6a . Here the submarine SUB takes the role of the aircraft FZ 6a a. The relationships disclosed there also apply here to the extent applicable and are claimed to the extent applicable and reasonable. A torpedo launch control TRPC is an example of a fire control system of a vehicle. Here the vehicle is the submarine SUB. In the example of 7 the torpedo launch control TRPC and the submarine SUB can each have one or more quantum computer systems QUSYS and/or one or more quantum computers QC. Since the torpedo launch control TRPC is part of the submarine SUB, the one or more quantum computer systems are also QUSYS and/or the one or more quantum computers QC of the torpedo launch control RKTC part of the submarine SUB. An external data bus EXTDB preferably connects the one or more quantum computer systems QUSYS and/or the one or more quantum computers QC of the torpedo launch control TRPC with the one or more quantum computer systems QUSYS and/or the one or more quantum computers QC of the submarine SUB.

In addition, the submarine SUB in the example of the 7 preferably via a large number of sensors SENS which, for example, are connected by an external data bus EXTDB to one or more quantum computer systems QUSYS and/or quantum computers QC on board the submarine SUB. These can be, for example, sound sensors and/or ultrasonic sensors, conductivity sensors, antennas, sensors for electromagnetic and/or ionizing radiation, particle detectors, pressure sensors, speed sensors, position sensors, attitude sensors, acceleration sensors, magnetometers, LIDAR sensors, RADAR sensors, quantum sensors and the act same. The SENS sensors can also be sensor systems, sensor arrays and other measuring systems. The SENS sensors can record measured values inside and outside the vehicle, here a submarine SUB.

In the example of 7 For example, one or more quantum computers QC and/or one or more quantum computer systems QUSYS on board the vehicle, here a submarine SUB, for example in cooperation with a central control unit ZSE of the vehicle, the NP-complete problem of the risk assessment of objects in the vicinity of the vehicle, here example of the submarine SUB, and/or along the course to the vehicle's target, the target selection and target determination and the order of target engagement, the ammunition and weapon selection and the fastest and at the same time the least risky route of the vehicle to the target. The quantum computers QC1, QC2 of the submarine SUB and the other device parts are shown in the example of FIG 7 connected via an external data bus EXTDB within the submarine SUB to the central control unit ZSE of the submarine SUB. The quantum computers QC1, QC2 and the other parts of the device preferably correspond to a quantum computer QC 1 or the previous description.

figure 8

8th shows an exemplary vehicle with a first quantum computer QC1, a second quantum computer QC2, a central control unit ZSE and an external data bus EXTDB, which connects them to a quantum computer system QUSYS. The vehicle is in the example 8th an exemplary motor vehicle KFZ. The vehicle includes a GPS receiver for determining the current position on the earth's surface and a navigation system NAV as exemplary sensors SENS. The vehicle may include one or more quantum computers QC and/or one or more quantum computer systems QUSYS, which may be interconnected via one or more external data buses EXTDB. The one or more external data buses can connect the one or more quantum computers QC and/or one or more quantum computer systems QUSYS to one or more actuators and/or one or more sensors. The sensors can also be sensor systems. For example, it can be acceleration and position sensors, impact sensors, ultrasonic measurement systems, radar systems, LIDAR systems, sensor systems of the drive and the energy store, etc. The actuators can be transmitters, lasers, motors, etc.

In the example of 8th For example, one or more quantum computers QC and/or one or more quantum computer systems QUSYS on board the vehicle, here a car KFZ, for example in interaction with a central control unit ZSE of the vehicle, the NP-complete problem of risk assessment of objects in the vicinity of the vehicle, here example of the car KFZ, and / or edit along the route to the destination of the vehicle, the destination selection and destination and the order of arrival and the fastest and at the same time the least risky route of the vehicle to the destination. The quantum computer QC1, QC2 of the vehicle, here an example of the car KFZ, and the other device parts of the vehicle, here an example of the car KFZ, are in the example 8th via an external data bus EXTDB within the vehicle, here for example the car KFZ, preferably with the central control unit ZSE of the vehicle, here for example the car KFZ. The quantum computers QC1, QC2 and the other parts of the device preferably correspond to a quantum computer QC 1 or the previous description.

figure 9

9 shows a typical solution of an NP-complete problem. The elaboration of the proposal presented here showed that solving a problem with a quantum computer takes place in four instead of three steps.

Computer programs that run on conventional computers with Harvard or non-Neumann architecture prefer to solve problems using the steps of analysis, elaboration and synthesis.

In the analysis step (step A)), the computer adapts the problem to the way the computer works. For example, a reading routine translates a text file containing readable numbers into binary data that is stored in the computer's memory.

In a second step, the elaboration (step B), the computer then carries out a calculation, for example, in which these binary data serve as input data, for example, and determines binary result data.

In a third step, the synthesis step (step D), the computer adapts this result to the intended use. For example, in the example described here, the computer could convert the binary result data into readable digits of the corresponding numbers in an output text file.

The elaboration has now shown that, especially in safety-relevant applications, after solving an NP-complete problem in elaboration step B) using a quantum computer QC, the quantum computer system QUSYS must carry out a check in step C). In this test step, the quantum computer system QUSYS or the quantum computer QC preferably uses a conventional computer core CPU or a central control unit ZSE to check whether the solution determined in the elaboration is actually a solution. Quantum operations are always statistical operations that can also deliver incorrect results. If necessary, the quantum computer system QUSYS repeats the calculation.

figure 10

10 equals to 4 , the 16 quantum computers QC1 to QC16 of the quantum computer system QUSYS now being inserted into the external data bus EXTDB by way of example. The control device μC, for example, each of the quantum computers QC1 to QC16 has, for example, two external data interfaces DBIFa and DBIFb instead of a data bus interface DBIF, as in 1 shown. In this way, for example, the central control unit ZSE can allocate a unique bus node address to each of the quantum computers QC. Typically, the control devices µC of the quantum computers QC1 to QC16 only pass on data that they from the data bus side with the central control device ZSE to the quantum computer and bus node of the other half of the data bus if they themselves have already received a valid bus node address from the central control device ZSE. In this way, the central control device ZSE can gradually assign a quantum computer address as bus node address of the external data bus EXTDB to all quantum computers of the quantum computers QC1 to QC16, starting with the first quantum computer QC1. After switching on or after a system reset, all quantum computers QC1 to QC16 preferably have an invalid default quantum computer address, which is typically the same for all, as the initial bus node address. As a result, the central control device can provide the quantum computer of the quantum computers QC1 to QC16 which has not yet been provided with a valid bus node address and is closest to it with a valid bus node address. As a result, in the next step, the central control device ZSE can reach and initialize the underlying quantum computer of the quantum computers QC1 to QC16 and so on until all quantum computers of the quantum computers QC1 to QC16 have received a valid quantum computer address as the bus node address. The quantum computer system QSYS preferably carries out an initialization of the quantum computers QC1 to QC16 of the quantum computer system QUSYS after switching on. The initialization of the quantum computer system QUSYS preferably also includes carrying out an auto-addressing method for assigning bus node addresses to the bus nodes of the external data bus EXTDB. In the example of 10 the bus nodes are the quantum computers QC1 to QC16. In the example of 10 the central control device ZSE preferably assumes the role of a bus master, which generates and assigns the bus node addresses and controls the quantum computers QC1 to QC16.

figure 11

11 shows an exemplary quantum computer system QUSYS with four sub-quantum computer systems.

The first quantum computer QC1 forms a first sub-quantum computer system with the second quantum computer QC2 and the third quantum computer QC3 and the fourth quantum computer QC4. A first sub-data bus UDB1 connects the quantum computers QC1, QC2, QC3, QC4 of the first sub-quantum computer system. The first quantum computer QC1 can serve as a bus master for the other quantum computers QC2, QC3, QC4 of the first sub-quantum computer system.

The fifth quantum computer QC5 forms a second sub-quantum computer system with the sixth quantum computer QC6 and the seventh quantum computer QC7 and the eighth quantum computer QC8. A second sub-data bus UDB2 connects the quantum computers QC5, QC6, QC7, QC8 of the second sub-quantum computer system. The fifth quantum computer QC5 can serve as a bus master for the other quantum computers QC6, QC7, QC8 of the second sub-quantum computer system.

The ninth quantum computer QC9 forms a third sub-quantum computer system with the tenth quantum computer QC10 and the eleventh quantum computer QC11 and the twelfth quantum computer QC12. A third sub-data bus UDB3 connects the quantum computers QC9, QC10, QC11, QC12 of the third sub-quantum computer system. The ninth quantum computer QC9 can serve as a bus master for the other quantum computers QC10, QC11, QC12 of the third sub-quantum computer system.

The thirteenth quantum computer QC13 forms a fourth sub-quantum computer system with the fourteenth quantum computer QC14 and the fifteenth quantum computer QC15 and the sixteenth quantum computer QC16. A fourth sub-data bus UDB4 connects the quantum computers QC13, QC14, QC15, QC16 of the fourth sub-quantum computer system. The thirteenth quantum computer QC13 can serve as a bus master for the other quantum computers QC14, QC15, QC16 of the fourth sub-quantum computer system.

In the example of 11 the external data bus EXTDB connects the first quantum computer QC1 and the fifth quantum computer QC5 and the ninth quantum computer QC9 and the thirteenth quantum computer QC13 and the central control unit ZSE.

figure 12

12 shows the solution of an NP-complete problem using a mobile relocatable quantum computer QC. Such a method begins with the acquisition of environmental data by the quantum computer system QUSYS in step A). The environmental data is typically recorded by means of suitable sensors, which can be part of the quantum computer system QUSYS or which are connected to this quantum computer system QUSYS via data connections and transmit environmental data to the quantum computer system QUSYS. In a step B), the quantum computer system QUSYS identifies objects in the environment of the quantum computer system QUSYS, where this environment can also be remote from the quantum computer system QUSYS. In a step C), the quantum computer system QUSYS classifies the identified objects in the environment of the quantum computer system QUSYS. In step C), the quantum computer system QUSYS typically classifies the objects according to their level of danger and/or vulnerability and/or strategic effect in order to maximize the effectiveness of a weapon. This classification in step C) is preferably carried out using a neural network model, which the quantum computer system QUSYS preferably executes. For this step C), the quantum computer system QUSYS preferably uses one or more quantum operations to manipulate the quantum state of one or more quantum dots NV1, NV2, NV3 of one or more quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS to classify the objects. In a step D, the quantum computer system QUSYS specifies the weapons and/or the ammunition and/or the configuration and/or the order of the objects attacked and/or the objects attacked and/or the objects not attacked. This specification is preferably made in step D) using a neural network model, which the quantum computer system QUSYS preferably executes. In step D), the quantum computer system QUSYS preferably uses one or more quantum operations to manipulate the quantum state of one or more quantum dots NV1, NV2, NV3 of one or more quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS to make these determinations. In a step E) proposes the quantum computer system QUSYS prefers one or more of these specified attack scenarios to an operator, for example one or more pilots and/or one or more fire control officers or the like. If they give the fire order, the quantum computer system QUSYS can, for example, implement the released attack scenario in a step F).

This exemplary application can be generalized to solve NP-complete problems. Such a generalized method begins with the acquisition of data by the quantum computer system QUSYS in step A). The data is typically recorded using suitable sensors and/or databases or other data sources, which can be part of the quantum computer system QUSYS or which are connected to this quantum computer system QUSYS via data connections and transmit the data to the quantum computer system QUSYS. In a step B), the quantum computer system QUSYS identifies suitable data objects. In a step C), the quantum computer system QUSYS classifies the identified data objects. Typically, in step C), the quantum computer system QUSYS classifies the objects according to categories that are relevant for solving the respective problem in order to maximize the effect. This classification in step C) is preferably carried out using a neural network model, which the quantum computer system QUSYS preferably executes. For this step C), the quantum computer system QUSYS preferably uses one or more quantum operations to manipulate the quantum state of one or more quantum dots NV1, NV2, NV3 of one or more quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS to carry out the classification of the data objects. In a step D), the quantum computer system QUSYS specifies the means for achieving the purpose and the parameters and means configurations when using these means and/or the order of the processed or unprocessed data objects and/or the order of the means used. This specification is preferably made in step D) using a neural network model, which the quantum computer system QUSYS preferably executes. In step D), the quantum computer system QUSYS preferably uses one or more quantum operations to manipulate the quantum state of one or more quantum dots NV1, NV2, NV3 of one or more quantum bits of one or more quantum computers QC1 to QC16 of the quantum computer system QUSYS to make these determinations. In a step E), the quantum computer system QUSYS preferably proposes one or more of these specified scenarios to an operator or the like. If they give a start signal, the quantum computer system QUSYS can, for example, implement the released scenario in a step F).

figure 13

The 13 shows an exemplary structure of an amplifier V, as shown in FIG 1 is drawn. An internal amplifier IVV of the amplifier V amplifies and filters the receiver output signal S0 to an output signal V1 of the internal amplifier IVV of the amplifier V. An analog-to-digital converter ADCV of the amplifier V converts the output signal V1 of the internal amplifier IVV of the amplifier V to digitized sampled values on a data line V2 between the control device μCV of the amplifier V and the analog-to-digital converter ADCV of the amplifier V. The control device μCV of the amplifier V and places these sampled values preferably in a memory MEMV of the amplifier V; via a memory data bus MEMDBV between control device μCV of amplifier V and memory MEMV of amplifier V. The control device µC of the relocatable quantum computer QC can then access the data in the memory MEMV of the amplifier V via the control data bus SDB, the data interface VIF of the amplifier V, the internal control data bus SDBV of the amplifier V and the control device µCV of the amplifier V and process them further.

figure 14

14 shows an example of a garment with a deployable quantum computer system QUSYS. For the follow-up work, the writing presented here refers to the writing as an example WO 2020 239 172 A1 , which discloses a method for CMOS integration.

The document presented here proposes incorporating one or more quantum computers QC1, QC2 and a central control unit ZSE into the material of a garment KLST. The quantum computer system QUSYS preferably corresponds to the quantum computer system QUSYS 4 , 10 or 11 or similar. The item of clothing can also be a watch or the like.

figure 15

15 FIG. 12 shows an example of a satellite or spacecraft as an example of a vehicle with a deployable quantum computing system QUSYS. The document presented here proposes integrating one or more quantum computers QC1, QC2 and a central control unit ZSE in the satellite or the spacecraft. The quantum computer system QUSYS preferably corresponds to the quantum computer system QUSYS 4 , 10 or 11 or similar.

figure 16

16 shows an example of a smartphone with a deployable quantum computer system QUSYS. The document presented here proposes integrating one or more quantum computers QC1, QC2 and a central control unit ZSE into the smartphone. For the follow-up work, the writing presented here refers to the writing as an example WO 2020 239 172 A1 , which discloses a method for CMOS integration. The quantum computer system QUSYS preferably corresponds to the quantum computer system QUSYS 4 , 10 or 11 or similar.

figure 17

17 largely corresponds to the 1 . In addition, the mechanical basic construction MGK is drawn. Preferably connects the in 17 Schematically drawn mechanical basic construction MGK the optical functional elements (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2 ) of the quantum computer QC with each other. The basic mechanical construction MGK is preferably mechanically connected to the housing GH of the quantum computer QC via fourth means, for example vibration dampers. The fourth means prevent or dampen the transmission of structure-borne noise etc. from the housing GH of the quantum computer QC or other parts of the device of the quantum computer QC to the mechanical basic construction MGK with the optical functional elements (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1, CM2) of the quantum computer QC. Preferably, the quantum computer QC itself is mechanically damped by appropriate fourth means attached to or in the mobile device, for example a vehicle. The document presented here refers to the varied definition of the term vehicle in this context in this document.

The leads from device parts of the quantum computer QC that are not directly mechanically connected to the mechanical basic construction MGK to device parts (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy , MSx, MSz, STM, PD, CM1, CM2), which are directly connected to the mechanical basic construction MGK, preferably have fifth means that are set up to transmit structure-borne noise and forces from the device parts of the quantum computer QC that are not directly are mechanically connected to the mechanical basic construction MGK to device parts (LD, DBS, OS, D, KV, XT, YT, MWA, MGX, MGy, MGz, MGz, PM, PV, MSy, MSx, MSz, STM, PD, CM1 , CM2).

glossary

vehicle

However, a vehicle within the meaning of the document presented here can also be a motor vehicle, a two-wheeler, a tricycle or a truck, a commercial vehicle, a robot, a transport vehicle, a drone, a robotic drone, a missile, a floating body, a submersible body , a ship, a submarine, a sea mine, a land mine, a rocket, a projectile, a satellite, a space station, a trailer, a barge, a container, in particular a sea container and/or smartphone and/or an article of clothing and/or a piece of jewelry and/or a wearable quantum computer system and/or a mobile quantum computer system and/or vehicle and/or robot and/or airplane and/or rumbling vehicle and/or underwater vehicle and/or surface water craft and/or underwater water craft and/or or a mobile medical device and/or a deployable weapon system and/or warhead and/or surface or underwater vehicle and/or sc hoss and/or other mobile device and/or movable device and/or the like. If the document presented here describes a specific vehicle, the description also includes and claims all other vehicles described above, insofar as this makes sense in the relevant context. In particular, all applications to weapons and weapon systems and movable medical devices, which are typically at least temporarily deployable. In the sense of the document presented here, this document interprets the term vehicle very broadly as a "transportable device" which may, in particular, temporarily have its own drive and/or auxiliary means for transport on water and/or on land and/or in in the air and/or in space.

horizontal

The adjective "horizontal" is used in this disclosure as part of the name of the device parts and associated sizes unless expressly stated otherwise. This happens because the quantum bits are numbered consecutively. This allows the columns (vertical) and rows (horizontal) to be better distinguished within two-dimensional quantum bit arrays. A “horizontal line” is therefore a line within such a two- or one-dimensional arrangement that runs along a line. The associated current is then referred to as “horizontal line current” in an analogous manner, for example, to give an example for naming a variable.

isotopically pure

A material is isotopically pure within the meaning of this disclosure if the concentration of isotopes other than the basic isotopes that dominate the material is so low that the technical purpose is sufficiently low for the production and sale of products with an economically sufficient production yield is achieved. This means that disturbances emanating from such isotope impurities do not disturb the functionality of the quantum bits, or at most only slightly disturb them. In relation to diamond, this means that diamond preferably consists essentially of ¹² C isotopes as basic isotopes, which have no magnetic moment.

Vicinity

For example, when this disclosure refers to a “device that is near the normal point (LOTP) or at the normal point (LOTP) for generating a circularly polarized microwave field”, the term proximity is to be understood as such that this device exerts or can exert an intended effect with its polarized microwave field or otherwise on the quantum dot (NV), which is located on the plumb line (LOT), which in turn intends to do so in connection with the disclosure presented here it is to be understood that the intended effect allows a method step to be carried out in the functional steps for the intended use of a device proposed here.

NP completeness

In computer science, a problem is called NP-complete (complete for the class of problems that can be solved non-deterministically in polynomial time) if it is one of the most difficult problems in the class NP, i.e. it is both in NP and NP-hard is. Colloquially, this means that it probably cannot be solved efficiently.

Formally, NP-completeness is only defined for decision problems (possible solutions only "yes" or "no"), while one speaks of NP-equivalence for other problem types (e.g. search problems or optimization problems). Colloquially, however, this distinction is often not made, so that one generally speaks of "NP-complete problems", regardless of whether a decision problem is present or not. This is possible because different problem types can be transferred into one another (reduced to one another).

• • in der Komplexitätsklasse NP liegt: Ein deterministisch arbeitender Rechner benötigt nur polynomiell viel Zeit, um zu entscheiden, ob eine vorgeschlagene Lösung eines zugehörigen Suchproblems tatsächlich eine Lösung ist, und
• • zu den NP-schweren Problemen gehört: Alle anderen Probleme, deren Lösungen deterministisch in polynomieller Zeit überprüft werden können, können auf das Problem derart zurückgeführt werden, dass diese Rückführung auf einem deterministischen Rechner höchstens polynomielle Zeit in Anspruch nimmt. Man spricht von einer Polynomialzeitreduktion.

A decision problem is NP-complete if it

• • is in the complexity class NP: A deterministically working computer only needs a polynomial amount of time to decide whether a proposed solution of an associated search problem is actually a solution, and
• • Belongs to the NP-hard problems: All other problems whose solutions can be verified deterministically in polynomial time can be reduced to the problem in such a way that this reduction takes at most polynomial time on a deterministic computer. One speaks of a polynomial time reduction.

NP-complete problems can probably not be solved efficiently, since their solution takes a long time on real computers. In practice, this does not always have a negative effect, which means that there are solution methods for many NP-complete problems that can be used to solve them in an acceptable time for orders of magnitude that occur in practice.

• • Für kein NP-vollständiges Problem konnte bisher nachgewiesen werden, dass es in polynomieller Zeit lösbar wäre.
• • Falls nur ein einziges dieser Probleme in polynomieller Zeit lösbar wäre, dann wäre jedes Problem in NP in polynomieller Zeit lösbar, was große Bedeutung für die Praxis haben könnte (jedoch nicht notwendigerweise haben muss).

Many problems that arise in practice and are important are NP-complete, which makes NP-completeness a central concept in computer science. This importance is further reinforced by the so-called P-NP problem:

• • So far, no NP-complete problem has been shown to be solvable in polynomial time.
• • If just one of these problems were solvable in polynomial time, then every problem in NP would be solvable in polynomial time, which could (but need not) have great practical implications.

Since Cook's introduction of NP-completeness, completeness has been expanded into a general concept for arbitrary complexity classes.

Quantum computer program and quantum operation and quantum 0p code

In the sense of the document presented here, a quantum computer program is a program that includes at least one quantum operation and is executed by a control device μC of a relocatable quantum computer QC. One or more binary data in the memory NVN, RAM of the control device μC of the relocatable quantum computer QC preferably encode such a quantum operation. For example, it can be a predetermined data word. A quantum operation within the meaning of the document presented here manipulates at least the quantum state of at least one quantum dot of the quantum dots NV1, NV2, NV3 of the quantum bits of the relocatable quantum computer QC and/or manipulates at least the quantum state of at least one nuclear quantum dot of the nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits (nuclear quantum bits) of the deployable quantum computer QC. The technical teaching of the document presented here also designates the data word that symbolizes such a quantum operation as a quantum op code. A quantum computer program thus comprises at least one quantum op-code. The quantum op-code can also include multiple data words.

Pure substrate

A pure substrate within the meaning of this disclosure is present when the concentration of atoms other than the basic atoms that dominate the material of the substrate is so low that the technical purpose is sufficiently important for the production and sale of products an economically sufficient production yield is achieved. This means that disturbances originating from such atomic impurities do not disturb the functionality of the quantum bits, or at most only slightly disturb them. In relation to diamond, this means that the diamond preferably essentially consists of carbon atoms and contains no or only an insignificant number of foreign atoms. The substrate preferably contains no ferromagnetic impurities such as Fe and/or Ni, since their magnetic fields can interact with the spin of the quantum dot (NV) of the respective quantum bit of the quantum computer QC.

insignificant phase shift

For purposes of this disclosure, an insignificant phase rotation of the state vector of a quantum dot of a quantum bit of the quantum computer QC is a phase rotation that can be considered insignificant or correctable for operation and functionality. It can therefore be assumed to be equal to zero in a first approximation.

vertical

The adjective "vertical" is used in this disclosure, unless expressly stated otherwise, as part of the name of the device parts and the associated sizes. This is because the quantum bits are numbered consecutively. This allows the columns (vertical) and rows (horizontal) within two-dimensional Quantum bit arrangements are better distinguished. A "vertical line" is therefore a line within such a two- or one-dimensional arrangement that runs along a Column is guided along. The associated current is then referred to, for example, in an analogous manner as "vertical line current" to give an example of naming a variable.

ZPL table

The table is only an exemplary compilation of some possible paramagnetic centers. These can be used as quantum bits. The document presented here strongly recommends the use of NV centers as paramagnetic centers of quantum dots of quantum bits of the quantum computer QC. The functionally equivalent use of other paramagnetic centers in other materials of the crystal of the substrate D is expressly possible. The pump radiation wavelengths λ _pmp of the pump radiation LB are also exemplary. Other pump radiation wavelengths λ _pmp are generally possible if they are shorter than the wavelength of the ZPL to be excited. Material of the crystal of the substrate D impurity center ZPL exemplary pump radiation wavelength (λ _pmp ) reference diamond NV Center 520nm, 532nm diamond SiV center 738nm 685 nm /2/, /3/, /4/ diamond GeV center 602 nm 532nm /4/, /5/ diamond SnV center 620nm 532nm /4/, /6/ diamond PbV center 520nm, 450nm /4/, /7/ 552 nm /4/, /7/ 715 nm 532nm /7/ diamond ST1 center 555 nm 532nm /15/ diamond TR12 center 471 nm 410nm /16/ silicon G center 1278.38nm 637 nm /8th/ silicon carbide V _SI center 862nm(V1) 4H, 730nm /1/, /9/, /10/ 858.2nm(V1') 4H 730nm /1/, /9/, /10/ 917nm(V2) 4H, 730nm /1/, /9/, /10/ 865nm(V1) 6H, 730nm /1/, /9/, /10/ 887nm(V2) 6H, 730nm /1/, /9/, /10/ 907nm(V3) 6H 730nm /1/, /9/, /10/ silicon carbide DV center 1078-1132nm 6H 730nm /9/ silicon carbide V _C V _SI center 1093-1140nm 6H 730nm /9/ silicon carbide CAV center 648.7nm 4H, 6H, 3C 730nm /9/ 651.8nm 4H, 6H, 3C 730nm /9/ 665.1nm 4H, 6H, 3C 730nm /9/ 668.5nm 4H, 6H, 3C 730nm /9/ 671.7nm 4H, 6H, 3C 730nm /9/ 673nm 4H, 6H, 3C 730nm /9/ 675.2nm 4H, 6H, 3C 730nm /9/ 676.5nm 4H, 6H, 3C 730nm /9/ silicon carbide N _C V _SI center 1180nm-1242nm 6H 730nm /9/, /13/, /14/

List of reference literature for the above table

• /1/ Marina Radulaski, Matthias Widmann, Matthias Niethammer, Jingyuan Linda Zhang, Sang-Yun Lee, Torsten Rendler, Konstantinos G. Lagoudakis, Nguyen Tien Son, Erik Janzen, Takeshi Ohshima, Jörg Wrachtrup, Jelena Vučković, "Scalable Quantum Photonics with Single Color Centers in Silicon Carbide”, Nano Letters 17 (3), 1782-1786 (2017), DOI: 10.1021/acs.nanolett.6b05102, arXiv:1612.02874
• /2/ C Wang, C Kurtsiefer, H Weinfurter, and B Burchard "Single photon emission from SiV centers in diamond produced by ion implantation" J. Phys. B: At. Mol.Opt. Phys., 39(37), 2006
• /3/ Björn Tegetmeyer, "Luminescence properties of SiV-centers in diamond diodes" doctoral thesis, University of Freiburg, January 30, 2018
• /4/ Carlo Bradac, Weibo Gao, Jacopo Forneris, Matt Trusheim, Igor Aharonovich, "Quantum Nanophotonics with Group IV defects in Diamond", DOI:10.1038/s41467-020-14316-x, arXiv:1906.10992
• /5/ Rasmus Høy Jensen, Erika Janitz, Yannik Fontana, Yi He, Olivier Gobron, Ilya P. Radko, Mihir Bhaskar, Ruffin Evans, Cesar Daniel Rodriguez Rosenblueth, Lilian Childress, Alexander Huck, Ulrik Lund Andersen Cavity-Enhanced Photon Emission from a Single Germanium Vacancy Center in a Diamond Membrane”, arXiv:1912.05247v3 [quant-ph] 25 May 2020
• /6/ Takayuki Iwasaki, Yoshiyuki Miyamoto, Takashi Taniguchi, Petr Siyushev, Mathias H. Metsch, Fedor Jelezko, Mutsuko Hatano, "Tin-Vacancy Quantum Emitters in Diamond", Phys. Rev. Lett. 119, 253601 (2017), DOI: 10.1103/PhysRevLett.119.253601, arXiv:1708.03576 [quant-ph]
• /7/ Matthew E Trusheim, Noel H Wan, Kevin C Chen, Christopher J Ciccarino, Ravishankar Sundararaman, Girish Malladi, Eric Bersin, Michael Walsh, Benjamin Lienhard, Hassaram Bakhru, Prineha Narang, Dirk Englund, Lead-Related Quantum Emitters in Diamond” Phys. Rev. B 99, 075430 (2019), DOI: 10.1103/PhysRevB.99.075430, arXiv:1805.12202 [quant-ph]
• /8th/ M. Hollenbach, Y. Berencen, U. Kentsch, M. Helm, GV Astakhov "Engineering telecom single-photon emitters in silicon for scalable quantum photonics" Opt. Express 28, 26111 (2020), DOI: 10.1364/OE.397377, arXiv:2008.09425 [physics.app-ph]
• /9/ Castelletto and Alberto Boretti, "Silicon carbide color centers for quantum applications" 2020 J. Phys. Photonics2 022001
• /10/ V Ivády, J Davidsson, NT Son, T Ohshima, IA Abrikosov, A Gali, "Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide", Phys. Rev.B, 2017, 96,161114
• /11/ J Davidsson, V Ivády, R Armiento, NT Son, A Gali, IA Abrikosov, "First principles predictions of magneto-optical data for semiconductor point defect identification: the case of divacancy defects in 4H-SiC", New J Phys., 2018, 20, 023035
• /12/ J Davidsson, V Ivády, R Armiento, T Ohshima, NT Son, A Gali, IA Abrikosov "Identification of divacancy and silicon vacancy qubits in 6H-SiC", Appl. physics Latvia 2019, 114, 112107
• /13/ SA Zargaleh, S. Hameau, B. Eble, F. Margaillan, HJ von Bardeleben, JL Cantin, W. Gao , "Nitrogen vacancy center in cubic silicon carbide: a promising qubit in the 1.5µm spectral range for photonic quantum networks" Phys . Rev.B, 2018, 98, 165203
• /14/ SA Zargaleh et al "Evidence for near-infrared photoluminescence of nitrogen vacancy centers in 4H-SiC" Phys. Rev.B, 2016, 94, 060102
• /15/ Balasubramanian P, Metsch MH, Reddy, Prithvi R, Lachlan J, Manson NB, Doherty MW, Jelezko F, "Discovery of ST1 centers in natural diamond" Nanophotonics, Vol 8, No 11, 2019, pp 1993 -2002. https://doi.org/10.1515/nanoph-2019-0148
• /16/ Foglszinger J, Denisenko A, Kornher T, Schreck M, Knolle W, Yavkin B, Kolesov R, Wrachtrup J. "ODMR on Single TR12 Centers in Diamond" arXiv:2104.04746v1 [physics.optics]

Non-statistical error of the quantum computer QC

A non-statistical error of the quantum computer QC in the sense of the document presented here is a defect or a malfunction of a device part of the quantum computer QC and/or a loss of data and/or a data corruption and/or an unauthorized change of a quantum state of a quantum bit of the quantum computer QC, which cannot be explained by the natural statistical errors when reading out quantum states. A non-statistical error of the quantum computer QC within the meaning of the document presented here is typically also a sufficiently probable suspicion of a defect or malfunction of a device part of the quantum computer QC and/or a sufficiently probable suspicion of a loss of data and/or a sufficiently probable suspicion of data corruption and/or a sufficiently probable suspicion of an unauthorized change in a quantum state of a quantum bit of the Quantum computer QC, whereby these presumed non-statistical errors cannot be explained by the natural statistical errors when reading out quantum states.

A non-statistical quantum error is a non-statistical error which, for physical reasons, cannot be reliably detected by a conventional watchdog and/or Q&A watchdog, in particular due to the quantum nature of a device part or method step involved in the non-statistical quantum error.

Miscellaneous

The above description is not exhaustive and does not limit this disclosure to the examples shown and/or described. Other variations to the disclosed examples may be understood and practiced by those of ordinary skill in the art given the drawings, disclosure, and claims. The indefinite article "a" or "an" and its inflections do not exclude a plurality, while the mention of a definite number of elements does not exclude the possibility of there being more or fewer elements. A single entity may perform the functions of multiple elements recited in the disclosure, and conversely, multiple elements may perform the function of one entity. Numerous alternatives, equivalents, variations, and combinations are possible without departing from the scope of the present disclosure. Unless otherwise stated, all features of the present invention can be freely combined with one another. This applies to the entire document presented here, in particular every statement and every combination of noun and adjective in the document presented here. Unless otherwise stated, the features described in the description of the figures can also be freely combined with the other features as features of the invention. A limitation of individual features of the exemplary embodiments to the combination with other features of the exemplary embodiments is expressly not intended. In addition, physical features of the device can also be reworded as method features and method features can be reworded as physical features of the device. Such a reformulation is thus automatically disclosed. The applicable claim results from the applicable claims.

In the foregoing detailed description, reference is made to the accompanying drawings. The examples in the specification and drawings should be considered as illustrative and not limiting on the specific example or element described. Several examples can be derived from the foregoing description and/or the drawings and/or the claims by modifying, combining or varying certain elements. Furthermore, examples or elements that are not literally described can be derived from the description and/or the drawings by a person skilled in the art.

reference list

ADCV

amplifier V analog-to-digital converter;

AS

Shielding;

BENG

first energy reserve;

BENG2

second energy reserve;

BNV

rotating magnetic field;

BSC

rear contact;

BTR

Energy reserve of the vehicle (submarine, car, etc.);

CBA

control unit A;

CBB

control unit B;

CECEQUREG

core-electron-core-electron quantum register;

CEQUREG1

first core-electron quantum register;

CEQUREG2

second core-electron quantum register;

CI1

first nuclear quantum dot of the first nuclear quantum bit of the quantum computer QC. The exemplary first nuclear quantum point CI1 of a nuclear quantum bit of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the nuclear quantum point CI1 of the nuclear quantum bit of the quantum computer QC preferably being essentially or even more preferred includes absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 .;

CI11

first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC. The exemplary first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is preferably an isotope with a nuclear magnetic moment in the substrate D, with the substrate D in the region of the nuclear quantum dot CI1 ₁ preferably being essentially or even more so preferably includes absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC as shown in FIG 2 the first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC;

CI12

second nuclear quantum point CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC. The exemplary second nuclear quantum point CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the nuclear quantum point CI1 ₂ of the nuclear quantum bit of the quantum computer QC preferably essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The second nuclear quantum point CI1 ₂ of the second quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the second nuclear quantum dot CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC as shown in FIG 2 the second nuclear quantum dot CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC;

CI13

third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC. The exemplary third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes having a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the third nuclear quantum dot CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC as shown in FIG 2 the third nuclear quantum point CI1 ₃ of the third nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum point NV1 of the first quantum bit of the quantum computer QC;

CI2

second nuclear quantum dot of the second nuclear quantum bit of the quantum computer QC. The exemplary second nuclear quantum point CI2 of the second nuclear quantum bit of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the nuclear quantum point CI2 of the second nuclear quantum bit of the quantum computer QC preferably being essentially or still more preferably absolutely no isotopes having a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 .;

CI21

first nuclear quantum dot CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC. The exemplary first nuclear quantum point CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the first nuclear quantum point CI2 ₁ of the first nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The first nuclear quantum dot CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the first nuclear quantum dot CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum dot NV2 of the second quantum bit of the quantum computer QC as shown in FIG 2 the first nuclear quantum dot CI2 ₁ of the first nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum dot NV2 of the second quantum bit of the quantum computer QC;

CI22

second nuclear quantum dot CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC. The exemplary second nuclear quantum point CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the second nuclear quantum point CI2 ₂ of the second nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The second nuclear quantum dot CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the second nuclear quantum dot CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum dot NV2 of the second quantum bit of the quantum computer QC as shown in FIG 2 the second nuclear quantum dot CI2 ₂ of the second nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum dot NV2 of the second quantum bit of the quantum computer QC;

CI23

third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC. The exemplary third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The third nuclear quantum dot CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is in the 3 not shown for a better overview. The reader should assume that in the 3 the third nuclear quantum dot CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum dot NV2 of the second quantum bit of the quantum computer QC as shown in FIG 2 the third nuclear quantum point CI2 ₃ of the third nuclear quantum bit of the second quantum ALU QUALU2 of the quantum computer QC is coupled to the second quantum point NV2 of the second quantum bit of the quantum computer QC;

CI3

third nuclear quantum dot of the third nuclear quantum bit of the quantum computer QC. The exemplary third nuclear quantum point CI3 of the third nuclear quantum bit of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the nuclear quantum point CI3 of the third nuclear quantum bit of the quantum computer QC preferably being essentially or still more preferably absolutely no isotopes having a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 ;

CI31

first nuclear quantum dot CI3 ₁ of the first nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC. The exemplary first nuclear quantum point CI3 ₁ of the first nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the first nuclear quantum point CI3 ₁ of the first nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The first nuclear quantum dot CI3 ₁ of the first nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is in the 3 and in the 2 not shown for a better overview. The reader should assume that in the 3 the first nuclear quantum dot CI3 ₁ of the first nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is coupled to the third quantum dot NV3 of the third quantum bit of the quantum computer QC as shown in FIG 2 the first nuclear quantum dot CI1 ₁ of the first nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC;

CI32

second nuclear quantum dot CI3 ₂ of the second nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC. The exemplary second nuclear quantum point CI3 ₂ of the second nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the second nuclear quantum point CI3 ₂ of the second nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The second nuclear quantum dot CI3 ₂ of the second nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is in the 3 and in the 2 not shown for a better overview. The reader should assume that in the 3 the second core quantum dot CI3 ₂ of the second quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is coupled to the third quantum dot NV3 of the third quantum bit of the quantum computer QC as shown in FIG 2 the second nuclear quantum dot CI1 ₂ of the second nuclear quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC;

CI33

third nuclear quantum point CI3 ₃ of the third nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC. The exemplary third nuclear quantum point CI3 ₃ of the third nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is preferably an isotope with a magnetic nuclear moment in the substrate D, with the substrate D in the region of the third nuclear quantum point CI3 ₃ of the third nuclear quantum bit of the Quantum computer QC preferably comprises essentially or even more preferably absolutely no isotopes with a nuclear magnetic moment. In this context, the document presented here refers to the technical teaching of those already cited DE 10 2020 007 977 B4 . The third nuclear quantum dot CI3 ₃ of the third nuclear quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is in the 3 and in the 2 not shown for a better overview. The reader should assume that in the 3 the third core quantum point CI3 ₃ of the third quantum bit of the third quantum ALU QUALU3 of the quantum computer QC is coupled to the third quantum point NV3 of the third quantum bit of the quantum computer QC as shown in FIG 2 the first core quantum dot CI1 ₁ of the first quantum bit of the first quantum ALU QUALU1 of the quantum computer QC is coupled to the first quantum dot NV1 of the first quantum bit of the quantum computer QC;

CIF

first camera interface;

CIF2

second camera interface;

CM1

first camera;

CM2

second camera;

CPU

computer core;

D

substrate;

d1

first distance at which the first quantum dot NV1 of the first quantum bit of the quantum computer QC is below the surface OF of the substrate D of the quantum computer QC;

d2

second distance in which the second quantum dot NV2 of the second quantum bit of the quantum computer QC is below the surface OF of the substrate D of the quantum computer QC;

DBIF

data interface;

DBIFa

data interface A;

DBIFb

data interface B;

DBS

dichroic mirror;

DEV

Power supply of other device parts of the quantum computer QC, this typically also relates to device parts with different reference numbers. For a better overview, the power supply lines of the other parts of the device of the quantum computer QC are shown in FIG 1 not drawn;

CLOSELY

propulsion of the vehicle;

ERS

energy system;

EXDB

external data bus;

EV

Power supply;

λfl

fluorescence radiation wavelength;

λpmp.

pump radiation wavelength;

FHB

factory floor or stationary device;

fHF

microwave and/or radio wave frequency;

FL

fluorescence radiation;

FLC

fire control station. The fire control center can be a central control unit ZSE.

FLR

attitude control system;

car

Airplane;

FZT

aircraft carrier;

GDX

X control device for the translational positioning device in the X direction XT;

GDY

Y control device for the translational positioning device in the Y direction YT;

GH

Housing;

GPS

Navigation system or device for determining the position and/or orientation of the quantum computer QC. If necessary, the navigation system can also determine translational speeds and/or rotational speeds of the quantum computer QC and report this to the computer core CPU of the control device μC of the quantum computer QC via the internal data bus INTDB. If necessary, the navigation system can also determine translational accelerations and/or rotational accelerations of the quantum computer QC and report this to the computer core CPU of the control device μC of the quantum computer QC via the internal data bus INTDB;

HD1

first horizontal driver stage for driving the first quantum dot NV1 to be driven of the first quantum bit of the quantum computer QC;

HD2

second horizontal driver stage for driving the second quantum dot NV2 to be driven of the second quantum bit of the quantum computer QC;

HD3

third horizontal driver stage for driving the third quantum dot NV3 to be driven of the third quantum bit of the quantum computer QC;

HeCLCS

closed loop helium gas cooling system;

HS1

first horizontal receiver stage HS1, which can form a unit with the first horizontal driver stage HD1, for driving the first quantum dot NV1 to be driven of the first quantum bit of the quantum computer QC;

HS2

second horizontal receiver stage HS2, which can form a unit with the second horizontal driver stage HD2, for driving the second quantum dot NV2 to be driven of the second quantum bit of the quantum computer QC;

HS3

third horizontal receiver stage HS3, which can form a unit with the third horizontal driver stage HD3, for driving the third quantum dot NV3 to be driven of the third quantum bit of the quantum computer QC;

IH1

first horizontal stream. The first horizontal current is the electric current flowing through the first horizontal line LH1.

IH2

second horizontal stream. The second horizontal current is the electric current flowing through the second horizontal line LH2.

IH3

third horizontal stream. The third horizontal current is the electric current flowing through the third horizontal line LH3.

ip

Intensity of the pulses of the pulsed pump radiation LB of the light source LD;

IPHF

Amplitude I _pHF of a pulse of the temporal envelope curve of the emission of an electromagnetic field by the one or more devices MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the Nuclear quantum dots CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , _{CI3 2 ,} CI3 ₃ of the nuclear quantum bits of the quantum computer QC;

IS

Isolation;

ISH1

first horizontal shield current flowing through the first horizontal shield line SH1;

ISH2

second horizontal shield current current flowing through the second horizontal shield line SH2;

ISH3

third horizontal shield current current flowing through the third horizontal shield line SH3;

ISH4

fourth horizontal shield current Current flowing through the fourth horizontal shield line SH4;

ISV1

first vertical shield current flowing through the first vertical shield line SV1;

ISV2

second vertical shield current flowing through the second vertical shield line SV2;

IV1

first vertical stream. The first vertical current is the electric current flowing through the first vertical line LV1;

IVV

internal amplifier within the amplifier V;

car

car as an example of a vehicle;

KH1

first horizontal contact of the first quantum bit QUB1 with the first quantum dot NV1 of the first quantum bit of the quantum computer QC. The first horizontal contact of the first quantum bit QUB1 electrically connects, for example, the first horizontal shielding line SH1 in the first quantum bit QUB1 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KH2

second horizontal contact of the first quantum bit QUB1 with the first quantum dot NV1 of the quantum computer QC and first horizontal contact of the second quantum bit QUB2 with the second quantum dot NV2 of the quantum computer QC. The first quantum bit QUB1 and the second quantum bit QUB2 use in the example 3 this contact together. The contact electrically connects, for example, the second horizontal shielding line SH2 in the first quantum bit QUB1 and in the second quantum bit QUB2 to the substrate D and the epitaxial layer DEPI, respectively. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KH3

second horizontal contact of the second quantum bit QUB2 with the second quantum dot NV2 and first horizontal contact of the third quantum bit QUB3 with the third quantum dot NV3. The second quantum bit QUB2 and the third quantum bit QUB3 use in the example 3 this contact together. The contact electrically connects, for example, the third horizontal shielding line SH3 in the second quantum bit QUB2 and in the third quantum bit QUB3 to the substrate D and the epitaxial layer DEPI, respectively. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KH4

second horizontal contact of the third quantum bit QUB3 with the third quantum dot NV3. The contact electrically connects, for example, the fourth horizontal shielding line SH3 in the third quantum bit QUB3 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV11

first vertical contact of the first quantum bit QUB1 with the first quantum dot NV1. The first vertical contact of the first quantum bit QUB1 electrically connects the first vertical shielding line SV1 in the first quantum bit QUB1 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV12

second vertical contact of the first quantum bit QUB1 with the first quantum dot NV1. The second vertical contact of the first quantum bit QUB1 preferably electrically connects the second vertical shielding line SH2 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV21

first vertical contact of the second quantum bit QUB2 with the second quantum dot NV2. The first vertical contact of the second quantum bit QUB2 electrically connects the first vertical shielding line SV1 in the second quantum bit QUB2 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV22

second vertical contact of the second quantum bit QUB2 with the second quantum dot NV2. The second vertical contact of the second quantum bit QUB2 preferably electrically connects the second vertical shielding line SH2 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV31

first vertical contact of the third quantum bit QUB3 with the third quantum dot NV3. The first vertical contact of the third quantum bit QUB3 electrically connects the first vertical shielding line SV1 in the third quantum bit QUB3 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV32

second vertical contact of the third quantum bit QUB3 with the third quantum dot NV3. The second vertical contact of the third quantum bit QUB3 preferably electrically connects the second vertical shielding line SH2 to the substrate D or the epitaxial layer DEPI. In the case of diamond as the substrate material, it is preferably a contact that includes titanium or is made of titanium;

KV

mobile cooler;

LB

pump radiation;

LD

light source;

LDRV

light source driver;

LDV

loading device;

LH1

first horizontal line;

LH2

second horizontal line;

LH3

third horizontal line;

LM

Luminaire with a light source;

LV1

first vertical line;

µC

control device;

µC1

first quantum computer controller QC1;

µC1a

first controller A of the first quantum computer QC1;

µC1b

first controller B of the first quantum computer QC1;

pC2

second quantum computer controller QC2;

pC3

third controller of the third quantum computer QC3;

pC4

fourth quantum computer controller QC4;

pC5

fifth quantum computer controller QC5;

µC6

sixth controller of sixth quantum computer QC6;

µC7

seventh controller of the seventh quantum computer QC7;

µC8

eighth quantum computer controller QC8;

µC9

ninth controller of the ninth quantum computer QC9;

µC10

tenth controller of the tenth quantum computer QC10;

µC11

eleventh controller of eleventh quantum computer QC11;

µC12

twelfth quantum computer controller QC12;

µC13

thirteenth controller of the thirteenth quantum computer QC13;

µC14

fourteenth controller of the fourteenth quantum computer QC14;

µC15

fifteenth controller of the fifteenth quantum computer QC15;

µC16

sixteenth controller of the sixteenth quantum computer QC16;

µCV

amplifier V control device;

MDBIF

internal data interface MDBIF;

MEMDBV

Memory data bus between control device μCV of amplifier V and memory MEMV of amplifier V;

MEMV

Amplifier V memory;

MFSx

first magnetic field control;

MFSy

second magnetic field control;

MFSz

third magnetic field control;

MGK

mechanical basic construction.

MGx

first magnetic field generating means which preferably generates a magnetic flux density B _x which preferably essentially has a direction which preferably corresponds to the first direction, ie for example the direction of the X-axis;

MGy

second magnetic field generating means which preferably generates a magnetic flux density B _y which preferably essentially has a direction which preferably corresponds to the second direction, ie for example the direction of the Y-axis;

MGz

third magnetic field generating means which preferably generates a magnetic flux density B _z which preferably essentially has a direction which preferably corresponds to the third direction, ie for example the direction of the Y-axis;

MSx

Magnetic field sensor for the magnetic flux density B _x in the direction of the X axis;

MSy

Magnetic field sensor for the magnetic flux density B _y in the direction of the Y axis;

MSz

Magnetic field sensor for the magnetic flux density B _z in the direction of the Z axis;

mWA

microwave and/or radio wave antenna;

MW/RF-AWFG

Microwave and/or radio wave frequency generator for generating largely freely definable waveforms (Arbitrary Wave Form Generator);

NAV

navigation system and/or autopilot;

NV1

first quantum dot of the first quantum bit of the quantum computer QC. The exemplary first quantum dot NV1 is preferably a paramagnetic center in the substrate D. The exemplary first quantum dot NV1 is preferably an NV center or a SiV center or an ST1 center in the substrate D;

NV2

second quantum dot of the second quantum bit of the quantum computer QC. The exemplary second quantum dot NV2 is preferably a paramagnetic center in the substrate D. The exemplary second quantum dot NV2 is preferably an NV center or a SiV center or an ST1 center in the substrate D;

NV3

third quantum dot of the third quantum bit of the quantum computer QC. The exemplary third quantum dot NV3 is preferably a paramagnetic center in the substrate D. The exemplary third quantum dot NV3 is preferably an NV center or a SiV center or an ST1 center in the substrate D;

NVM

non-volatile memory;

OF

Surface;

OS

optical system;

OSZ

Clock generator of the computer core CPU of the control device μC of the quantum computer QC;

PD

photodetector;

p.m

permanent magnet;

PV

Positioning device for the permanent magnet PM;

PVC

Control device for the positioning device PV for the permanent magnet PM;

PWR

power supply of the charging device LDV;

QC

quantum computers;

QC1

first quantum computer;

QC2

second quantum computer;

QC3

third quantum computer;

QC4

fourth quantum computer;

QC5

fifth quantum computer;

QC6

sixth quantum computer;

QC7

seventh quantum computer;

QC8

eighth quantum computer;

QC9

ninth quantum computer;

QC10

tenth quantum computer;

QC11

eleventh quantum computer;

QC12

twelfth quantum computer;

QC13

thirteenth quantum computer;

QC14

fourteenth quantum computer;

QC15

fifteenth quantum computer;

QC16

sixteenth quantum computer;

QCTV

Quantum Computer System Separator. The quantum computer system separation device preferably separates an external data bus EXTDB, which, for example, connects a first quantum computer system QUSYS to a second quantum computer system QUSYS, if necessary, so that the quantum computer system QUSYS, which previously comprised the first and the second quantum computer system QUSYS, breaks down into two separate quantum computer systems QUSYS by the separation. However, the quantum computer system separation device can also connect a previously separate first quantum computer system QUSYS to a previously separate second quantum computer system QUSYS and, if necessary, couple them so that the quantum computer system QUSYS is created, which then includes the first and the second quantum computer system QUSYS by connecting these two quantum computer systems via quantum computer system separation device into one Quantum computer system QUSYS merges;

QUALU1

first quantum ALU. The exemplary first quantum ALU consists of a first quantum dot NV1 of the quantum bits of the quantum computer QC and a first core quantum dot CI1 ₁ of the nuclear quantum bits of the first quantum ALU of the quantum computer QC and a second core quantum dot CI1 ₂ of the nuclear quantum bits of the first quantum ALU of the quantum computer QC and a third core quantum dot CI1 _a of the nuclear quantum bits of the first quantum ALU of the quantum computer QC ( 2 );

QUALU2

second quantum ALU. The exemplary second quantum ALU consists of a second quantum dot NV2 of the quantum bits of the quantum computer QC and a first core quantum dot CI2 ₁ of the nuclear quantum bits of the second quantum ALU of the quantum computer QC and a second core quantum dot CI2 ₂ of the nuclear quantum bits of the second quantum ALU of the quantum computer QC and a third core quantum dot CI2 ₃ of the nuclear quantum bits of the second quantum ALU of the quantum computer QC ( 2 );

QUSYS

deployable quantum computer system;

R.A.M.

volatile memory;

RKT

Rocket. The rocket is just one example of a possible payload. The load can itself include one or more quantum computer systems QUSYS. The quantum computer system QUSYS of the payload is preferably connected to the quantum computer system QUSYS of the vehicle FZ or the object in which the payload is set up or stored during the time of the payload, for example via an external data bus EXTDB;

RKTC

missile launch control;

S0

receiver output signal;

S1

received signal;

S4

measured value signal;

S5

broadcast signal;

SC

sea container. The sea container is just one example of a transportable container in which one or more QUSYS quantum computer systems or one or more QC quantum computers can be operated;

SCHR

ship's propeller;

SDS

control data bus;

SDBV

internal control data bus within the amplifier V;

SENS

one or more sensors;

SH1

first horizontal shield line;

SH2

second horizontal shield line;

SH3

third horizontal shield line;

SH4

fourth horizontal shield line;

SRG

first energy processing device, in particular a voltage converter or a voltage regulator or a current regulator;

SRG2

second energy processing device, in particular a voltage converter or a voltage regulator or a current regulator;

ST

temperature sensor;

STM

semi-transparent mirror;

SUB

submarine;

SV1

first horizontal shield line;

SV2

second vertical shield line;

tsp

low loader. The low-loader is an example of a vehicle without its own propulsion.

TRP

torpedoes;

TRPC

torpedo launch control;

TS

separator;

t0HF

Reference instant of a pulse of the pulsed electromagnetic field with microwave and/or radio wave frequency f _HF . The reference point in time t _0HF is preferably equal to the reference point in time t _0p for a pulse sequence or at a fixed distance in time from the reference point in time for a pulse sequence t _0p ;

t0p

Reference time for a pulse sequence. The reference point in time t _0p for a pulse sequence is preferably equal to the reference point in time t _0HF or at a fixed distance in time from the reference point in time t _0HF ;

tdp

the duration t _dp of the pulses of the pulsed pump radiation LB of the light source LD;

tdHF

temporal pulse duration of the pulse of the pulsed electromagnetic field with microwave and/or radio wave frequency f _HF . It is the temporal pulse duration of the temporal envelope curve of the emission of an electromagnetic field by the one or more devices MW/RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective Location of the nuclear quantum dots CI1 ₁ , CI1 ₂ , _{C11 3} , CI2 1 , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC in pulse form;

etc

temporal position of the pulses of the pulsed pump radiation LB of the light source LD in relation to a reference time t _0. As a rule, the temporal position t _sp of a pulse designates the start time of the relevant pulse;

tspHF

Pulse start time t _spHF relative to the reference time t _0HF of a pulse of the temporal envelope curve of the emission of an electromagnetic field by the one or more devices MW / RF-AWFG for generating an electromagnetic wave field at the respective location of the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC and at the respective location of the nuclear quantum points CI1 ₁ , CI1 ₂ , C11 ₃ , CI2 ₁ , CI2 ₂ , CI2 ₃ , CI3 ₁ , CI3 ₂ , CI3 ₃ of the nuclear quantum bits of the quantum computer QC;

UDB1

first sub data bus;

UDB2

second sub data bus;

UDB3

third sub data bus;

UDB4

fourth sub data bus;

ÜOSZ

monitor clock generation of the quantum computer monitor device QUV of the quantum computer QC;

U.S

bottom of substrate D;

V

Amplifier;

V1

Output signal of internal amplifier IVV of amplifier V and input signal of analog-to-digital converter ADCV of amplifier V;

v2

Data line between the control device μCV of the amplifier V and the analog-to-digital converter ADCV of the amplifier V;

vbatext

electric power from an external power supply, such as an external power supply;

VD1

first vertical driver stage for driving the quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to be driven;

VIF

Data interface of the amplifier V to the control data bus SDB;

VS1

first vertical receiver stage, which can form a unit with the first vertical driver stage VD1, for driving the first quantum dots NV1, NV2, NV3 of the quantum bits of the quantum computer QC to be driven;

WFG

waveform generator;

XT

translational positioning device in the X direction;

YT

translational positioning device in the Y direction;

ZM

Tractor. The tractor is an example of a drive for a container with one or more quantum computers QC and/or one or more quantum computer systems QUSYS, which can be separated from the container or added to the container. In the example of 6b the container is an exemplary low-loader TL with a sea container SC;

ZSE

central control unit;

List of cited writings

• CN 103 855 907 B ,
• CN 108 831 576 B ,
• CN 20 634 1126 U ,
• DE 1 240 967 B ,
• DE 1 564 070 B1 ,
• DE 2 124 465 B2 ,
• DE 7 219 216 U ,
• DE 69 411 078 T2 ,
• DE 19 602 875 A1 ,
• DE 19 738 066 A1 ,
• DE 19 957 669 A1 ,
• DE 19 782 844 538 B1 ,
• DE 10 2014 225 346 A1 ,
• DE 10 2018 127 394.0 ,
• DE 10 2019 130 114.9 ,
• DE 10 2019 120 076.8 ,
• DE 10 2019 121 137 ,
• DE 10 2020 125 189 A1
• DE 10 2020 101 784 B3
• DE 10 2020 007 977 B4
• DE 10 2020 008 157 B3
• DE 10 2021 110 964.7
• DE 20 2021 101 169 U1
• EP 2 874 292 B1 ,
• EP 2 986 852 B1 ,
• EP 3 007 350 B1 ,
• EP 3 075 064 A1 ,
• EP 3 093 966 B1 ,
• EP 3 279 603 B1 ,
• EP 3 345 290 B1 ,
• EP 3 400 642 B1 ,
• EP 3 646 452 B1 ,
• EP 3 863 165 A1 ,
• RU 126 229 U1 ,
• RU 2 566 620 C2 ,
• RU 2014 143 858 A ,
• US 5 443 657 A ,
• US 5 859 484 A ,
• US 8 552 616 B2 ,
• US 2016 377 029 A1 ,
• US 2018 226 165 A1 ,
• US 2019 368 464 A1 ,
• US 2021 147 061 A1 ,
• WO 2009 103 974 A1 ,
• WO 2014 031 037 A2
• WO 2016 100 008 A2 ,
• WO 2019 143 396 A2 ,
• WO 2021 159 117 A1 ,
• https://de.wikipedia.org/wiki/Daisy_Chain
• https://en.wikipedia.org/wiki/Cryocooler
• https://www.youtube.com/watch?v=j0SZirc7TO8
• P. Balasubramanian, M. H. Metsch, Reddy, R. Prithvi, J. Lachlan, N. B. Manson, M. W. Doherty, F. Jelezko, „Discovery of ST1 centers in natural diamond“ Nanophotonics, Vol. 8, Nr. 11, 2019, Seiten 1993-2002. https://doi.org/10.1515/nanoph-2019-0148
• Castelletto and Alberto Boretti, „Silicon carbide color centers for quantum applications“ 2020 J. Phys. Photonics2 022001
• Carlo Bradac, Weibo Gao, Jacopo Forneris, Matt Trusheim, Igor Aharonovich, „Quantum Nanophotonics with Group IV defects in Diamond“, DOI: 10.1038/s41467-020-14316-x, arXiv:1906.10992
• Ovidiu Calin, „Deep Learning Architectures: A Mathematical Approach (Springer Series in the Data Sciences)“, Springer; 1st ed. 2020 Edition (14. Februar 2021), ISBN-10: 3030367231, ISBN-13: 978-3030367237
• Franklin R. Chang Diaz, F. Wall y Baitty, Jared P. Squire, Richard H. Goulding, Edgar A. Bering, Roger D. Bengtson, „The Vasimr Engine: Project Status and Recent Accomplishments", herunterladbar am 09.01.2022 von https://ntrs.nasa.gov/api/citations/20110011201/downloads/20110011201.pdf.
• J. Davidsson, V. Ivády, R. Armiento, N. T. Son, A. Gali, I. A. Abrikosov, „First principles predictions of magneto-optical data for semiconductor point defect identification: the case of divacancy defects in 4H-SiC“, New J. Phys., 2018, 20, 023035
• J. Davidsson, V. Ivády, R. Armiento, T. Ohshima, N. T. Son, A. Gali, I. A. Abrikosov „Identification of divacancy and silicon vacancy qubits in 6H-SiC“, Appl. Phys. Lett. 2019, 114, 112107
• J. Foglszinger, A. Denisenko, T. Kornher, M. Schreck, W. Knolle, B. Yavkin, R. Kolesov, J. Wrachtrup „ODMR on Single TR12 Centers in Diamond“ arXiv:2104.04746v1 [physics.optics]
• M. Hollenbach, Y. Berencen, U. Kentsch, M. Helm, G. V. Astakhov „Engineering telecom single-photon emitters in silicon for scalable quantum photonics“ Opt. Express 28, 26111 (2020), DOI: 10.1364/OE.397377, arXiv:2008.09425 [physics.app-ph]
• V. Ivády, J. Davidsson, N. T. Son, T. Ohshima, I. A. Abrikosov, A. Gali, „Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide“, Phys. Rev.B, 2017, 96,161114
• Takayuki Iwasaki, Yoshiyuki Miyamoto, Takashi Taniguchi, Petr Siyushev, Mathias H. Metsch, Fedor Jelezko, Mutsuko Hatano, „Tin-Vacancy Quantum Emitters in Diamond“, Phys. Rev. Lett. 119, 253601 (2017), DOI: 10.1103/PhysRevLett.119.253601, arXiv:1708.03576 [quant-ph]
• Rasmus Høy Jensen, Erika Janitz, Yannik Fontana, Yi He, Olivier Gobron, Ilya P. Radko, Mihir Bhaskar, Ruffin Evans, Cesar Daniel Rodriguez Rosenblueth, Lilian Childress, Alexander Huck, Ulrik Lund Andersen, „Cavity-Enhanced Photon Emission from a Single Germanium-Vacancy Center in a Diamond Membrane“, arXiv:1912.05247v3 [quant-ph] 25 May 2020
• Hugo K. Messerle (Autor), „Magnetohydrodynamic Electrical Power Generation (UNESCO Energy Engineering Series)“, John Wiley & Sons Ltd (1. August 1995), ISBN-10: 0471942529, ISBN-13: 978-0471942528.
• Steven Prawer (Herausgeber), Igor Aharonovich (Herausgeber), „Quantum Information Processing with Diamond: Principles and Applications“, Woodhead Publishing Series in Electronic and Optical Materials, Band 63, Woodhead Publishing, 8. Mai 2014, ISBN-10 : 0857096567, ISBN-13 : 978-0857096562
• Marina Radulaski, Matthias Widmann, Matthias Niethammer, Jingyuan Linda Zhang, Sang-Yun Lee, Torsten Rendler, Konstantinos G. Lagoudakis, Nguyen Tien Son, Erik Janzen, Takeshi Ohshima, Jörg Wrachtrup, Jelena Vučković, „Scalable Quantum Photonics with Single Color Centers in Silicon Carbide“, Nano Letters 17 (3), 1782-1786 (2017), DOI: 10.1021/acs.nanolett.6b05102, arXiv:1612.02874
• Petr Siyushev, Milos Nesladek, Emilie Bourgeois, Michal Gulka, Jaroslav Hruby, Takashi Yamamoto, Michael Trupke, Tokuyuki Teraji, Junichi Isoya, Fedor Jelezko, „Photoelectrical imaging and coherent spin-state readout of single nitrogen-vacancy centers in diamond“, Science 363, 728-731 (2019) 15 February 2019
• Akinori Tanaka, Akio Tomiya, Koji Hashimoto, „Deep Learning and Physics (Mathematical Physics Studies)“ 21. Februar 2021, Herausgeber: Springer; 1st ed. 2021 Edition, ISBN-10: 9813361077, ISBN-13: 978-9813361072
• Björn Tegetmeyer, „Luminescence properties of SiV-centers in diamond diodes“ Promotionsschrift, Universität Freiburg, 30.01.2018
• Matthew E. Trusheim, Noel H. Wan, Kevin C. Chen, Christopher J. Ciccarino, Ravishankar Sundararaman, Girish Malladi, Eric Bersin, Michael Walsh, Benjamin Lienhard, Hassaram Bakhru, Prineha Narang, Dirk Englund, „Lead-Related Quantum Emitters in Diamond“ Phys. Rev. B 99, 075430 (2019), DOI: 10.1103/PhysRevB.99.075430, arXiv:1805.12202 [quant-ph]
• Vasily Y. Ushakov (Autor), „Electrical Power Engineering: Current State, Problems and Perspectives (Green Energy and Technology)“, Taschenbuch - 18. August 2018, Springer; 1st ed. 2018 Edition (18. August 2018), ISBN-10: 3319872850, ISBN-13: 978-3319872858.
• C. Wang, C. Kurtsiefer, H. Weinfurter, and B. Burchard, „Single photon emission from SiV centres in diamond produced by ion implantation“ J. Phys. B: At. Mol.Opt. Phys., 39(37), 2006
• S. A. Zargaleh, S. Hameau, B. Eble, F. Margaillan, H. J. von Bardeleben, J. L. Cantin, W. Gao , „Nitrogen vacancy center in cubic silicon carbide: a promising qubit in the 1.5µm spectral range for photonic quantum networks“ Phys. Rev.B, 2018, 98, 165203
• S. A. Zargaleh et al „Evidence for near-infrared photoluminescence of nitrogen vacancy centers in 4H-SiC“ Phys. Rev.B, 2016, 94, 060102

Insofar as the law of the respective legal system of the state in which the international application of the document presented here is nationalized allows disclosure by reference in the context of the nationalization of an international subsequent application, the content of the following documents is an integral part of the disclosure presented here. ,

• CN 103 855 907 B ,
• CN 108 831 576 B ,
• CN 20 634 1126 U ,
• DE 1 240 967 B ,
• DE 1 564 070 B1 ,
• DE 2 124 465 B2 ,
• DE 7 219 216 U ,
• DE 69 411 078 T2 ,
• DE 19 602 875 A1 ,
• DE 19 738 066 A1 ,
• DE 19 957 669 A1 ,
• DE 19 782 844 538 B1 ,
• DE 10 2014 225 346 A1 ,
• DE 10 2018 127 394.0 ,
• DE 10 2019 130 114.9 ,
• DE 10 2019 120 076.8 ,
• DE 10 2019 121 137 ,
• DE 10 2020 125 189 A1
• DE 10 2020 101 784 B3
• DE 10 2020 007 977 B4
• DE 10 2020 008 157 B3
• DE 10 2021 110 964.7
• DE 20 2021 101 169 U1
• EP 2 874 292 B1 ,
• EP 2 986 852 B1 ,
• EP 3 007 350 B1 ,
• EP 3 075 064 A1 ,
• EP 3 093 966 B1 ,
• EP 3 279 603 B1 ,
• EP 3 345 290 B1 ,
• EP 3 400 642 B1 ,
• EP 3 646 452 B1 ,
• EP 3 863 165 A1 ,
• RU 126 229 U1 ,
• RU 2 566 620 C2 ,
• RU 2014 143 858 A ,
• U.S. 5,443,657 A ,
• U.S. 5,859,484 A ,
• U.S. 8,552,616 B2 ,
• U.S. 2016 377 029 A1 ,
• U.S. 2018 226 165 A1 ,
• U.S. 2019 368 464 A1 ,
• U.S. 2021 147 061 A1 ,
• WO 2009 103 974 A1 ,
• WO 2014 031 037 A2
• WO 2016 100 008 A2 ,
• WO 2019 143 396 A2 ,
• WO 2021 159 117 A1 ,
• https://de.wikipedia.org/wiki/Daisy_Chain
• https://en.wikipedia.org/wiki/Cryocooler
• https://www.youtube.com/watch?v=j0SZirc7TO8
• Balasubramanian P, Metsch MH, Reddy, Prithvi R, Lachlan J, Manson NB, Doherty MW, Jelezko F, "Discovery of ST1 centers in natural diamond" Nanophotonics, Vol 8, No 11, 2019, pp 1993 -2002. https://doi.org/10.1515/nanoph-2019-0148
• Castelletto and Alberto Boretti, "Silicon carbide color centers for quantum applications" 2020 J. Phys. Photonics2 022001
• Carlo Bradac, Weibo Gao, Jacopo Forneris, Matt Trusheim, Igor Aharonovich, "Quantum Nanophotonics with Group IV defects in Diamond", DOI:10.1038/s41467-020-14316-x, arXiv:1906.10992
• Ovidiu Calin, "Deep Learning Architectures: A Mathematical Approach (Springer Series in the Data Sciences)", Springer; 1st ed. 2020 edition (February 14, 2021), ISBN-10: 3030367231, ISBN-13: 978-3030367237
• Franklin R Chang Diaz, F Wall y Baitty, Jared P Squire, Richard H Goulding, Edgar A Bering, Roger D Bengtson, The Vasimr Engine: Project Status and Recent Accomplishments, downloadable 2022-01-09 from https://ntrs.nasa.gov/api/citations/20110011201/downloads/20110011201.pdf.
• J Davidsson, V Ivády, R Armiento, NT Son, A Gali, IA Abrikosov, "First principles predictions of magneto-optical data for semiconductor point defect identification: the case of divacancy defects in 4H-SiC", New J Phys., 2018, 20, 023035
• J Davidsson, V Ivády, R Armiento, T Ohshima, NT Son, A Gali, IA Abrikosov "Identification of divacancy and silicon vacancy qubits in 6H-SiC", Appl. physics Latvia 2019, 114, 112107
• Foglszinger J, Denisenko A, Kornher T, Schreck M, Knolle W, Yavkin B, Kolesov R, Wrachtrup J. "ODMR on Single TR12 Centers in Diamond" arXiv:2104.04746v1 [physics.optics]
• M. Hollenbach, Y. Berencen, U. Kentsch, M. Helm, GV Astakhov "Engineering telecom single-photon emitters in silicon for scalable quantum photonics" Opt. Express 28, 26111 (2020), DOI: 10.1364/OE.397377, arXiv:2008.09425 [physics.app-ph]
• V Ivády, J Davidsson, NT Son, T Ohshima, IA Abrikosov, A Gali, "Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide", Phys. Rev.B, 2017, 96,161114
• Takayuki Iwasaki, Yoshiyuki Miyamoto, Takashi Taniguchi, Petr Siyushev, Mathias H. Metsch, Fedor Jelezko, Mutsuko Hatano, "Tin-Vacancy Quantum Emitters in Diamond", Phys. Rev. Lett. 119, 253601 (2017), DOI: 10.1103/PhysRevLett.119.253601, arXiv:1708.03576 [quant-ph]
• Rasmus Høy Jensen, Erika Janitz, Yannik Fontana, Yi He, Olivier Gobron, Ilya P. Radko, Mihir Bhaskar, Ruffin Evans, Cesar Daniel Rodriguez Rosenblueth, Lilian Childress, Alexander Huck, Ulrik Lund Andersen Cavity-Enhanced Photon Emission from a Single Germanium Vacancy Center in a Diamond Membrane”, arXiv:1912.05247v3 [quant-ph] 25 May 2020
• Hugo K. Messerle (author), "Magnetohydrodynamic Electrical Power Generation (UNESCO Energy Engineering Series)", John Wiley & Sons Ltd (1 August 1995), ISBN-10: 0471942529, ISBN-13: 978-0471942528.
• Steven Prawer (editor), Igor Aharonovich (editor), "Quantum Information Processing with Diamond: Principles and Applications", Woodhead Publishing Series in Electronic and Optical Materials, Vol. 63, Woodhead Publishing, May 8, 2014, ISBN-10 : 0857096567, ISBN-13: 978-0857096562
• Marina Radulaski, Matthias Widmann, Matthias Niethammer, Jingyuan Linda Zhang, Sang-Yun Lee, Torsten Rendler, Konstantinos G. Lagoudakis, Nguyen Tien Son, Erik Janzen, Takeshi Ohshima, Jörg Wrachtrup, Jelena Vučković, "Scalable Quantum Photonics with Single Color Centers in Silicon Carbide”, Nano Letters 17 (3), 1782-1786 (2017), DOI: 10.1021/acs.nanolett.6b05102, arXiv:1612.02874
• Petr Siyushev, Milos Nesladek, Emilie Bourgeois, Michal Gulka, Jaroslav Hruby, Takashi Yamamoto, Michael Trupke, Tokuyuki Teraji, Junichi Isoya, Fedor Jelezko, "Photoelectrical imaging and coherent spin-state readout of single nitrogen-vacancy centers in diamond", Science 363, 728-731 (2019) 15 February 2019
• Akinori Tanaka, Akio Tomiya, Koji Hashimoto, “Deep Learning and Physics (Mathematical Physics Studies)” February 21, 2021, Editors: Springer; 1st ed. 2021 Edition, ISBN-10: 9813361077, ISBN-13: 978-9813361072
• Björn Tegetmeyer, "Luminescence properties of SiV-centers in diamond diodes" doctoral thesis, University of Freiburg, January 30, 2018
• Matthew E Trusheim, Noel H Wan, Kevin C Chen, Christopher J Ciccarino, Ravishankar Sundararaman, Girish Malladi, Eric Bersin, Michael Walsh, Benjamin Lienhard, Hassaram Bakhru, Prineha Narang, Dirk Englund, "Lead-Related Quantum Emitters in Diamond" Phys. Rev. B 99, 075430 (2019), DOI: 10.1103/PhysRevB.99.075430, arXiv:1805.12202 [quant-ph]
• Vasily Y. Ushakov (Author), "Electrical Power Engineering: Current State, Problems and Perspectives (Green Energy and Technology)", paperback - August 18, 2018, Springer; 1st ed. 2018 edition (18 August 2018), ISBN-10: 3319872850, ISBN-13: 978-3319872858.
• C Wang, C Kurtsiefer, H Weinfurter, and B Burchard "Single photon emission from SiV centers in diamond produced by ion implantation" J. Phys. B: At. Mol.Opt. Phys., 39(37), 2006
• SA Zargaleh, S. Hameau, B. Eble, F. Margaillan, HJ von Bardeleben, JL Cantin, W. Gao , "Nitrogen vacancy center in cubic silicon carbide: a promising qubit in the 1.5µm spectral range for photonic quantum networks" Phys . Rev.B, 2018, 98, 165203
• SA Zargaleh et al "Evidence for near-infrared photoluminescence of nitrogen vacancy centers in 4H-SiC" Phys. Rev.B, 2016, 94, 060102

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102020007977 B4 [0004, 0020, 0159, 0477, 0478]
• DE 102020125189 A1 [0004, 0074, 0075, 0076, 0089, 0224, 0478]
• DE 102020101784 B3 [0004, 0016, 0478]
• DE 102020008157 B3 [0005, 0006, 0012, 0478]
• DE 202021101169 U1 [0207, 0478]
• WO 2021159117 A1 [0207, 0478]
• EP 3863165 A1 [0207, 0478]
• US 2021147061 A1 [0207, 0478]
• CN 108831576B [0207, 0478]
• US 2019368464 A1 [0207, 0478]
• WO 2019143396 A2 [0207, 0478]
• EP 3646452 B1 [0207, 0478]
• CN 206341126 U [0207, 0478]
• EP 3279603 B1 [0207, 0478]
• EP 3400642 B1 [0207, 0478]
• EP 3345290 B1 [0207, 0478]
• EP 3093966 B1 [0207, 0478]
• WO 2016100008 A2 [0207, 0478]
• DE 102014225346 A1 [0207, 0478]
• RU 2014143858 A [0207, 0478]
• EP 3007350 B1 [0207, 0478]
• US2016377029 A1 [0207, 0478]
• RU 2566620 C2 [0207, 0478]
• EP 3075064 A1 [0207, 0478]
• EP 2874292 B1 [0207, 0478]
• EP 2986852 B1 [0207, 0478]
• CN 103855907B [0207, 0478]
• RU 126229 U1 [0207, 0478]
• WO 2014031037 A2 [0207, 0478]
• DE 1240967 B [0210, 0478]
• DE 1564070 B1 [0210, 0478]
• DE 2124465 B2 [0210, 0478]
• DE 7219216 U [0210, 0478]
• DE 19782844538 B1 [0210, 0478]
• DE 69411078 T2 [0210, 0478]
• US5443657A[0210,0478]
• US5859484A[0210,0478]
• DE 19602875 A1 [0210, 0478]
• DE 19738066 A1 [0210, 0478]
• DE 19957669 A1 [0210, 0478]
• US 8552616 B2 [0210, 0478]
• WO 2009103974 A1 [0210, 0478]
• US 2018226165 A1 [0210, 0478]
• DE 102019121137 [0376, 0478]
• WO 2020239172 A1 [0453, 0456]
• DE 102018127394 [0478]
• DE 102019130114 [0478]
• DE 102019120076 [0478]
• DE 102021110964 [0478]

Non-patent Literature Cited

• Krelina, Michal. "Quantum technology for military applications. EJP Quantum Technology, 2021, vol. 8, no. 1, p. 24 [0009]
• Marina Radulaski, Matthias Widmann, Matthias Niethammer, Jingyuan Linda Zhang, Sang-Yun Lee, Torsten Rendler, Konstantinos G. Lagoudakis, Nguyen Tien Son, Erik Janzen, Takeshi Ohshima, Jörg Wrachtrup, Jelena Vučković, "Scalable Quantum Photonics with Single Color Centers in Silicon Carbide”, Nano Letters 17 (3), 1782-1786 (2017), DOI: 10.1021/acs.nanolett.6b05102, arXiv:1612.02874 [0473, 0478]
• C Wang, C Kurtsiefer, H Weinfurter, and B Burchard "Single photon emission from SiV centers in diamond produced by ion implantation" J. Phys. B: At. Mol.Opt. Phys., 39(37), 2006 [0473, 0478]
• Björn Tegetmeyer, "Luminescence properties of SiV centers in diamond diodes" PhD thesis, University of Freiburg, January 30, 2018 [0473, 0478]
• Carlo Bradac, Weibo Gao, Jacopo Forneris, Matt Trusheim, Igor Aharonovich, "Quantum Nanophotonics with Group IV defects in Diamond", DOI:10.1038/s41467-020-14316-x, arXiv:1906.10992 [0473, 0478]
• Rasmus Høy Jensen, Erika Janitz, Yannik Fontana, Yi He, Olivier Gobron, Ilya P. Radko, Mihir Bhaskar, Ruffin Evans, Cesar Daniel Rodriguez Rosenblueth, Lilian Childress, Alexander Huck, Ulrik Lund Andersen Cavity-Enhanced Photon Emission from a Single Germanium Vacancy Center in a Diamond Membrane”, arXiv:1912.05247v3 [quant-ph] 25 May 2020 [0473, 0478]
• Takayuki Iwasaki, Yoshiyuki Miyamoto, Takashi Taniguchi, Petr Siyushev, Mathias H. Metsch, Fedor Jelezko, Mutsuko Hatano, "Tin-Vacancy Quantum Emitters in Diamond", Phys. Rev. Lett. 119, 253601 (2017), DOI: 10.1103/PhysRevLett.119.253601, arXiv:1708.03576 [quant-ph] [0473, 0478]
• Matthew E Trusheim, Noel H Wan, Kevin C Chen, Christopher J Ciccarino, Ravishankar Sundararaman, Girish Malladi, Eric Bersin, Michael Walsh, Benjamin Lienhard, Hassaram Bakhru, Prineha Narang, Dirk Englund, Lead-Related Quantum Emitters in Diamond” Phys. Rev. B 99, 075430 (2019), DOI: 10.1103/PhysRevB.99.075430, arXiv:1805.12202 [quant-ph] [0473, 0478]
• M. Hollenbach, Y. Berencen, U. Kentsch, M. Helm, G. V. Astakhov "Engineering telecom single-photon emitters in silicon for scalable quantum photonics" Opt. Express 28, 26111 (2020), DOI: 10.1364/OE.397377, arXiv:2008.09425 [physics.app-ph] [0473, 0478]
• Castelletto and Alberto Boretti, "Silicon carbide color centers for quantum applications" 2020 J. Phys. Photonics2 022001 [0473, 0478]
• V. Ivády, J. Davidsson, N. T. Son, T. Ohshima, I. A. Abrikosov, A. Gali, "Identification of Si-vacancy related room-temperature qubits in 4H silicon carbide", Phys. Rev.B, 2017, 96,161114 [0473, 0478]
• J Davidsson, V Ivády, R Armiento, NT Son, A Gali, I A Abrikosov, "First principles predictions of magneto-optical data for semiconductor point defect identification: the case of divacancy defects in 4H-SiC", New J Phys., 2018, 20, 023035 [0473, 0478]
• J Davidsson, V Ivády, R Armiento, T Ohshima, NT Son, A Gali, IA Abrikosov "Identification of divacancy and silicon vacancy qubits in 6H-SiC", Appl. Phys. Latvia 2019, 114, 112107 [0473, 0478]
• SA Zargaleh, S Hameau, B Eble, F Margaillan, H J von Bardeleben, J L Cantin, W Gao "Nitrogen vacancy center in cubic silicon carbide: a promising qubit in the 1.5 µm spectral range for photonic quantum networks" Phys . Rev.B, 2018, 98, 165203 [0473, 0478]
• SA Zargaleh et al "Evidence for near-infrared photoluminescence of nitrogen vacancy centers in 4H-SiC" Phys. Rev.B, 2016, 94, 060102 [0473, 0478]
• Balasubramanian P, Metsch MH, Reddy, Prithvi R, Lachlan J, Manson NB, Doherty MW, Jelezko F, "Discovery of ST1 centers in natural diamond" Nanophotonics, Vol 8, No 11, 2019, pages 1993 -2002. https://doi.org/10.1515/nanoph-2019-0148 [0473, 0478]
• Foglszinger J, Denisenko A, Kornher T, Schreck M, Knolle W, Yavkin B, Kolesov R, Wrachtrup J. "ODMR on Single TR12 Centers in Diamond" arXiv:2104.04746v1 [physics.optics] [ 0473, 0478]
• Ovidiu Calin, "Deep Learning Architectures: A Mathematical Approach (Springer Series in the Data Sciences)", Springer; 1st ed. 2020 Edition (February 14, 2021), ISBN-10: 3030367231, ISBN-13: 978-3030367237 [0478]
• Franklin R Chang Diaz, F Wall y Baitty, Jared P Squire, Richard H Goulding, Edgar A Bering, Roger D Bengtson, The Vasimr Engine: Project Status and Recent Accomplishments, downloadable 2022-01-09 from https://ntrs.nasa.gov/api/citations/20110011201/downloads/20110011201.pdf [0478]
• Hugo K. Messerle (author), "Magnetohydrodynamic Electrical Power Generation (UNESCO Energy Engineering Series)", John Wiley & Sons Ltd (1 August 1995), ISBN-10: 0471942529, ISBN-13: 978-0471942528. [0478]
• Steven Prawer (editor), Igor Aharonovich (editor), "Quantum Information Processing with Diamond: Principles and Applications", Woodhead Publishing Series in Electronic and Optical Materials, Vol. 63, Woodhead Publishing, May 8, 2014, ISBN-10 : 0857096567, ISBN-13 : 978-0857096562 [0478]
• Petr Siyushev, Milos Nesladek, Emilie Bourgeois, Michal Gulka, Jaroslav Hruby, Takashi Yamamoto, Michael Trupke, Tokuyuki Teraji, Junichi Isoya, Fedor Jelezko, "Photoelectrical imaging and coherent spin-state readout of single nitrogen-vacancy centers in diamond", Science 363, 728-731 (2019) 15 February 2019 [0478]
• Akinori Tanaka, Akio Tomiya, Koji Hashimoto, “Deep Learning and Physics (Mathematical Physics Studies)” February 21, 2021, Editors: Springer; 1st ed. 2021 Edition, ISBN-10: 9813361077, ISBN-13: 978-9813361072 [0478]
• Vasily Y. Ushakov (Author), "Electrical Power Engineering: Current State, Problems and Perspectives (Green Energy and Technology)", paperback - August 18, 2018, Springer; 1st ed. 2018 edition (18 August 2018), ISBN-10: 3319872850, ISBN-13: 978-3319872858. [0478]

Claims (15)

Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scenden defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and / or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can include fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - predict an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - an acceleration, in particular during a relocation of the deployable quantum compute rs (QC) and/or - to compensate for an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to reduce the effect of an acceleration, in particular during a relocation of the deployable quantum computer (QC), wherein the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more position control systems and/or • one or more positioning tables and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scuring defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) designed to - predict an acceleration, in particular during a relocation of the deployable quantum computer (QC), and /or - to detect an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a deployment of the deployable quantum computer (QC), and/or - the effect of an acceleration, in particular during relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or • one or more image capturing devices and/or image processing device and/or • other fl fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) comprises fourth means (QV), which are set up to reduce the transmission of mechanical shocks and/or vibrations, among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scuring defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - an acceleration, in particular during a relocation of the deployable quantum computer (QC), to predict and/or - to detect an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a deployment of the deployable quantum computer (QC), and/or - the effect of an acceleration, in particular during a relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or several positioning tables and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which emit fluorescence radiation with one of the fluorescence wavelengths (λ _fl ) of the quantum dots (NV1, NV2, NV3 ) of the quantum bits different having the fluorescence wavelength, and/or - that the quantum computer (QC) comprises fourth means (QV) which are set up to transmit mechanical shocks and/or vibrations among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent each other and /or to dampen and/or - that the quantum computer (QC) comprises fifth means (QV) which are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1 , LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) , In particular to prevent and / or dampen structure-borne noise, the fifth means ua - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy , MSz, MWA, CM2, LM, HECLCS) and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical, at least sectional formations of supply lines to optical device parts (D , OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can include and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the Quant encomputers (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS). Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, set up to - predict changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - changes in acceleration, in particular during a relocation of the deployable quantum computer computer (QC), and/or - to compensate for changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - the effect of such changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), - where the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more position control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which have a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits , incl s, and/or - that the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up for this purpose - an acceleration, in particular during a relocation of the relocatable quantum computer (QC), to predict and/or - to detect an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - the To reduce the effect of an acceleration, in particular during a relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or or • one or more positioning tables and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) comprises fourth means (QV) which are set up to transmit mechanical shocks and/or vibrations among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other and/or - that the quantum computer (QC) comprises fifth means (QV) which are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other H To prevent and/or dampen auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC), in particular via structure-borne noise, wherein the fifth means, among others - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can be inserted and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and /or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can be inserted and / or - special mechanical, at least in sections, forms of supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT , MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) comprises sixth means (QV) which are set up to detect a non-statistical error in the quantum computer (QC) and/or to implement or initiate countermeasures when a non-statistical error occurs in the quantum computer (QC). Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scuring defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - predict an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - the effect of an acceleration, in particular during a relocation of the relocatable quantum computer ( QC), to reduce, the third means in particular • one or more acceleration sensor systems and / or acceleration sensors and/or • one or more position displacement sensors and/or • one or more position control system and/or • one or more positioning table and/or • one or more image acquisition devices and/or image processing device and/or • other fluorescent defect centers in the substrate (D). other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) comprises fourth means (QUV), designed to prevent the transmission of mechanical shocks and/or vibrations between optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other and/or - that s the quantum computer (QC) comprises fifth means (QC) which are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum com computer (QC), in particular via structure-borne noise, to prevent and/or to dampen, the fifth means including - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/ or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS ) can be inserted and/or - special mechanical, at least in sections, formations of supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT , YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical, at least partially Ausfo Transmission of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx , MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) comprises sixth means (QV) set up to detect a non-statistical error of the quantum computer (QC) and/or or to carry out or initiate countermeasures when a non-statistical error occurs in the quantum computer (QC), and/or - that the quantum computer (QC) comprises seventh means (QV) which are set up to prevent a non-statistical error in the quantum computer (QC). and/or to signal such a non-statistical error to a higher-level system if a non-statistical error occurs in the quantum computer (QC). Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scuring defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - an acceleration, in particular during a relocation of the deployable quantum computer (QC), to predict and/or - to detect an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a deployment of the deployable quantum computer (QC), and/or - the effect of an acceleration, in particular during a relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or several positioning tables and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which emit fluorescence radiation with one of the fluorescence wavelengths (λ _fl ) of the quantum dots (NV1, NV2, NV3 ) of the quantum bits different having the fluorescence wavelength, and/or - that the quantum computer (QC) comprises fourth means (QV) which are set up to transmit mechanical shocks and/or vibrations among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent each other and /or to dampen and/or - that the quantum computer (QC) comprises fifth means (QV) which are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1 , LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) , In particular to prevent and / or dampen structure-borne noise, the fifth means ua - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy , MSz, MWA, CM2, LM, HECLCS) and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical, at least sectional formations of supply lines to optical device parts (D , OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can include and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the Quant encomputers (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) sixth means (QV) that are set up to detect a non-statistical error in the quantum computer (QC) and/or to implement or initiate countermeasures when a non-statistical error in the quantum computer (QC) occurs, and/or - that the quantum computer (QC) comprises seventh means (QV), which are set up to detect a non-statistical error in the quantum computer (QC) and/or to transmit such a non-statistical error to a higher-level system if a non-statistical error occurs in the quantum computer (QC). signal, and / or - that the quantum computer (QC) comprises eighth means (QV), which are set up to detect a non-statistical quantum error of the quantum computer (QC) and / or the occurrence of a non-sta tistic error of the quantum computer (QC) to carry out or initiate countermeasures. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic centers and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) has third means ( PV, XT, YT, CM1, OS, STM, CIF, µC) that are set up to - predict changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to compensate for changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), to reduce - the third means in particular • one or more acceleration sensor systems and / or Besch and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) has third means ( PV, XT, YT, CM1, OS, STM, CIF, µC) that are set up to - predict an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - an acceleration, in particular ere during a relocation of the relocatable quantum computer (QC), to compensate and / or - to reduce the effect of an acceleration, in particular during a relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and / or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control system and/or • one or more positioning table and/or • one or more image acquisition devices and/or image processing device and/or • other fluorescent defect centers in the substrate (D) with others Fluorescence wavelengths, which can comprise a fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC) comprises fourth means (QUV) which are set up to mechanical transmission ical shocks and/or vibrations, under optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA , CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other and/or - that the quantum computer (QC) comprises fifth means (QV) which are set up to reduce the transmission of mechanical shocks and /or vibrations, to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy , MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC), in particular via structure-borne noise, to prevent and/or to dampen, the fifth means including - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical , At least in sections formations of supply lines to optical Device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2 , LM, HECLCS) and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) comprises sixth means (QV) that are set up to detect a non-statistical error in the quantum computer (QC) and/or to implement or initiate countermeasures if a non-statistical error in the quantum computer (QC) occurs, and/or - that the quantum computer (QC) comprises seventh resources (QV). , which are set up to detect a non-statistical error of the quantum computer (QC) and/or if a non-statistical error of the quantum computer (QC) occurs, to signal such a non-statistical error to a higher-level system, and/or - that the quantum computer (QC) comprises eighth means (QV) which are set up to detect a non-statistical quantum error of the Quantum computer (QC) and/or to carry out or initiate countermeasures in the event of a non-statistical error in the quantum computer (QC), and/or - that the quantum computer (QC) comprises ninth means (QV) which are set up to to detect a statistical quantum error of the quantum computer (QC) and/or to signal such a non-statistical quantum error to a higher-level system if a non-statistical error of the quantum computer (QC) occurs. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - wherein the quantum computer (QC) comprises quantum bits and - wherein the quantum computer (QC) first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more quantum bits of the one or more quantum bits are paramagnetic Centers comprise and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) includes, which are set up to - predict changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - to detect changes in the acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - changes in the acceleration , in particular during a relocation of the relocatable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC), - the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or image processing devices and/or • other fluores scuring defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - predict an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/or - an acceleration, in particular during a relocation of the relocatable quantum computer (QC), to detect and/or - to compensate for an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to reduce the effect of an acceleration, in particular during a relocation of the deployable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and/or • one or more image acquisition devices and/or image processing devices and/or • others fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) fourth means (QV) compr t designed to prevent the transmission of mechanical shocks and/or vibrations among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other and/or - that the quantum computer (QC) comprises fifth means (QV) which are set up to prevent the transmission of mechanical shocks and/or vibrations to the optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC), in particular via structure-borne noise, to prevent and / or to dampen, the fifth means, inter alia - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/ or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS ) can be inserted and/or - special mechanical, at least in sections, formations of supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT , YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) comprises sixth means (QV) which are set up to detect a non-statistical error in the quantum computer (QC) and/or if a non-statistical error occurs in the quantum computer (QC ) to carry out or initiate countermeasures, and/or - that the quantum computer (QC) comprises seventh means (QV) which are set up to detect a non-statistical error of the quantum computer (QC) and/or if a non-statistical error of the quantum computer (QC) to signal such a non-statistical error to a higher-level system, and/or - that the quantum computer (QC) comprises eighth means (QV) which are set up to detect a non-statistical quantum error of the quantum computer (QC) and /or to carry out or initiate countermeasures in the event of a non-statistical error in the quantum computer (QC), and/or - that the Quantenco mputer (QC) includes ninth means (QV) that are set up to detect a non-statistical quantum error in the quantum computer (QC) and/or, if a non-statistical error in the quantum computer (QC) occurs, such a non-statistical quantum error to a higher-level system to signal and/or - that the quantum computer (QC) comprises tenth means (MSx, MSy, MSz, MFSx, MFSy, MFSz, PM, MGx, MGy, MGz, PV) which are set up to detect changes in the magnetic field at the location of the Detect and compensate for quantum bits during and/or after a quantum computer (QC) relocation. Deployable quantum computer (QC) in a mobile device, in particular for use in a smartphone or a portable quantum computer system (QUSYS) or in a vehicle or in a deployable weapon system, - the quantum computer (QC) comprising quantum bits and - wherein the quantum computer (QC) comprises first means for manipulating the quantum states of quantum bits of the quantum bits and - wherein the quantum computer (QC) comprises second means for reading out one or more quantum states (QC) of one or more quantum bits of the quantum bits and wherein one or more Quantum bits of the one or more quantum bits comprise paramagnetic centers and wherein the quantum computer (QC) comprises a control device (µC) - for controlling the first means and - for controlling the second means and - for acquiring measurement results of the second means and characterized in that - that the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) set up to - predict changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), and/ or - to detect changes in acceleration, in particular during a relocation of the relocatable quantum computer (QC). and/or - to compensate for changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to reduce the effect of such changes in acceleration, in particular during a relocation of the deployable quantum computer (QC), - wherein the third Means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more position control systems and/or • one or more positioning tables and/or positioning devices and/or • one or more image acquisition devices and/or Image processing devices and/or other fluorescent defect centers in the substrate (D) with other fluorescence wavelengths, which can include fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - there ss the quantum computer (QC) comprises third means (PV, XT, YT, CM1, OS, STM, CIF, µC) which are set up to - predict an acceleration, in particular during a relocation of the relocatable quantum computer (QC), and/ or - to detect an acceleration, in particular during a relocation of the deployable quantum computer (QC), and/or - to compensate for an acceleration, in particular during a deployment of the deployable quantum computer (QC), and/or - the effect of an acceleration, in particular during a Relocation of the relocatable quantum computer (QC), the third means in particular • one or more acceleration sensor systems and/or acceleration sensors and/or • one or more position displacement sensors and/or • one or more attitude control systems and/or • one or more positioning tables and /or • one or more image acquisition devices and/or image processing device and/or • other fluor Escing defect centers in the substrate (D) with other fluorescence wavelengths, which can comprise fluorescence radiation with a fluorescence wavelength different from the fluorescence wavelength (λ _fl ) of the quantum dots (NV1, NV2, NV3) of the quantum bits, and/or - that the quantum computer (QC ) comprises fourth means (QV), which are set up to reduce the transmission of mechanical shocks and/or vibrations, among optical device parts (D, OS, DBS, STM, PD, CM1, LD) and/or other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC) to prevent and/or attenuate each other and/or - that the quantum computer (QC) fifth means (QV) that are set up to transmit mechanical shocks and/or vibrations to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts ( KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) of the optical sub-devices of the quantum computer (QC), in particular through structure-borne noise, to prevent and / or to dampen, the fifth Means, among others - in supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the further auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can be inserted and/or - in data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) can be inserted and/or - special mechanical, at least sectional, formations of supply lines to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV, XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS ) can include and/or - special mechanical, at least sectional formations of data lines (SDA) to optical device parts (D, OS, DBS, STM, PD, CM1, LD) of the quantum computer (QC) and/or to the other auxiliary device parts (KV , XT, YT, MGx, MGy, MGz, MSx, MSy, MSz, MWA, CM2, LM, HECLCS) and/or - that the quantum computer (QC) sixth means (Q UV) that are set up to detect a non-statistical error of the quantum computer (QC) and/or to carry out or initiate countermeasures if a non-statistical error of the quantum computer (QC) occurs, and/or - that the quantum computer (QC) seventh means (QV) that are set up to detect a non-statistical error in the quantum computer (QC) and/or to signal such a non-statistical error to a higher-level system if a non-statistical error occurs in the quantum computer (QC), and /or - that the quantum computer (QC) comprises eighth means (QV) which are set up to detect a non-statistical quantum error in the quantum computer (QC) and/or to implement or take countermeasures when a non-statistical error in the quantum computer (QC) occurs initiate, and / or - that the quantum computer (QC) includes ninth means (QV), which are set up to a non st to detect atistic quantum errors of the quantum computer (QC) and/or, if a non-statistical error of the quantum computer (QC) occurs, to signal such a non-statistical quantum error to a higher-level system and/or - that the quantum computer (QC) uses tenth means (MSx, MSy , MSz, MFSx, MFSy, MFSz, PM, MGx, MGy, MGz, PV) configured to detect and compensate for changes in the magnetic field at the location of the quantum bits during and/or after a quantum computer (QC) relocation , and/or - that the quantum computer (QC) comprises eleventh means (AS) for shielding external magnetic field changes. Smartphone and/or a wearable quantum computing system (QUSYS) and/or a mobile quantum computing system (QUSYS) and/or vehicle and/or robot and/or airplane and/or missile and/or satellite and/or a spacecraft and/or space station and/or or float and/or ship and/or underwater vehicle and/or surface float and/or underwater float and/or deployable weapon system and/or warhead and/or surface or underwater vehicle and/or projectile and/or other mobile device and/or movable device, - wherein the claim presented here and the claims dependent thereon all refer to them hereinafter as a vehicle, and - wherein the vehicle comprises a deployable quantum computer (QC) according to one or more of the preceding Claims 1 until 10 comprises or - wherein the deployable quantum computer (QC) according to one or more of the preceding Claims 1 until 10 includes the vehicle. vehicle after claim 11 - Wherein the vehicle has sensors and/or measuring equipment, the measured values about the surroundings of the vehicle and/or states of the vehicle and/or states of the vehicle occupants or users of the vehicle and/or states of the vehicle's payload to the control device (μC) deliver, includes and/or - wherein the control device (μC) receives measured values about the environment of the vehicle via the data interface (DBIF) and/or - wherein the quantum computer (QC) makes an assessment of the overall condition of the vehicle and/or depending on these measured values or the environment of the vehicle is determined and - the overall condition of the vehicle can include the condition of the environment of the vehicle and/or the condition of the vehicle occupants and/or the condition of a payload of the vehicle. vehicle after claim 11 and/or 12 - the quantum computer (QC) depending on these measured values, the vehicle and/or Vor controls directional parts of the vehicle and/or influences a control of the vehicle or a device part of the vehicle. Vehicle according to one or more of the preceding Claims 11 until 13 - wherein the vehicle is a weapon system and/or - wherein the vehicle comprises a weapon system coupled to the quantum computer (QC). vehicle after Claim 14 - wherein the vehicle comprises a fire control system and - wherein the fire control system comprises the quantum computer (QC) or is coupled to the quantum computer (QC) and - wherein the control of the weapon system by the fire control system is at least temporarily dependent on the quantum computer (QC) or in cooperation with happening to the quantum computer (QC).

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