WO2022214710A2

WO2022214710A2 - System and method for risk-free processing of data containing malware

Info

Publication number: WO2022214710A2
Application number: PCT/EP2022/059665
Authority: WO
Inventors: Benjamin Ohmer
Original assignee: Valutis Technologies GmbH
Priority date: 2021-04-09
Filing date: 2022-04-11
Publication date: 2022-10-13
Also published as: WO2022214710A3; DE102022203638A1

Abstract

The present invention relates to an email processing method. The method for email processing comprises at least the following steps: receiving email data (509), in particular via an email data interface (501); generating a plurality of different analogue signals (4) of a content part representation type, wherein the plurality of different analogue signals (4) of the content part representation type represent content part representation data (521), wherein the content part representation data (521) represent at least one optically reproducible part (511) of content of digital source data (510), and wherein the digital source data (510) represent the email data (509), in particular email text data and/or email image data and/or email attachment data, or are formed by the email data (509); converting the analogue signals (4) of the content part representation type into digital email result data (506), wherein the digital email result data (506) have an email result data set (532) as content, wherein the email result data set (532) is a digital representation (534) of the analogue signals (4) of the content part representation type, and wherein the email result data set (532) represents at least one optically imageable part (511) of the content of the digital source data (510); and preferably includes storing the email result data (506).

Description

System and method for risk-free treatment of malware

Data

The spread and use of the Internet means that a great deal of criminal energy is used to illegally steal money. An example of this is e.g. encryption Trojans. Such encryption trojans or encryption software have the effect that significant amounts of data are encrypted by companies and private individuals and the decryption key may only be released in exchange for the payment of a ransom.

Solutions for safety-critical issues use so-called "air gap" systems. The functionality of such systems is described, for example, in https://de.wikipedia.org/wiki/Air_Gap. However, such systems have significant hurdles, particularly with regard to the ease of use, which means that such systems are not accessible to a mass market.

It is the object of the present invention to create a possibility that makes it possible to prevent damage caused by malware, in particular to manage or prepare or store data or information in such a way that they are protected against malicious encryption. Furthermore, the solution should also be easy to implement. The solution should preferably be able to be used in various technical areas.

A solution to the aforementioned problem is provided by an email transmission system according to claim 1. The e-mail transmission system according to the invention has at least one e-mail data interface, the e-mail data interface being designed at least for receiving e-mail data, and a system for converting digital e-mail output data into analog signals and for converting the analog signals into digital e-mail result data, in particular a digital result file or digital Results database entries, the digital email output data representing at least one optically mappable part of a content of digital source data, the digital source data representing or forming the email data, in particular email text data and/or email image data and/or email attachment data. The system for converting the digital email output data into the analog signals and for converting the analog signals into the digital email result data preferably has at least one email output data processing processor for generating a large number of different analog signals of the content part representation type, with one of the large number of different analog Signals of the content part representation type content part representation data are represented, the content part representation data representing at least an optically reproducible part of the content of the digital source data, the email output data processing processor having at least one signal output for outputting the analog signals of the content representation type. Furthermore, the system preferably has at least one email input signal processing processor for converting the analog signals of the content part representation type into the digital email result data, the email input signal processing processor having at least one signal input for receiving the signals of the content part representation type output via the at least one signal output of the email output data processing processor , wherein the digital e-mail result data has an e-mail result data record as its content, the e-mail result data record being a digital representation of the analog signals of the content partial representation type, the e-mail Result data set represents at least an optically mappable part of the content of the digital source data and preferably has an email output data generation processor, with the email

Output data generation processor, the email data received via the email data interface can be converted into the digital email output data.

This solution is advantageous because digital data can be converted into non-executable data through the digital-analog-digital interface, since these are only available as "content" and therefore not in an executable form.

The e-mail transmission system preferably has an OCR unit (“optical character recognition unit”) for handling the characters contained in the digital result data. Basic functions of the OCR technology are known, for example, from https://de.wikipedia.org/wiki/TextTEC.

The bit sequences of the digital email result data and the digital source data being different are preferred.

The content part representation data preferably each represent a one-dimensional or two-dimensional pixel arrangement of at least part of the content of the source data, in particular one or more pages (e.g. A4 page/s). The digital e-mail output data is preferably represented by a plurality of content part representation data, the plurality of content part representation data being represented by the plurality of different analog signals of the content part representation type.

The e-mail output data processing processor and the e-mail output data generation processor can be one processor or the functions of the e-mail output data processing processor and the e-mail

Output data generation processors can be executed by a processor.

The email output data generation processor can be configured to operate or execute a sandbox, in particular a virtual machine, or a large number of sandboxes, in particular a large number of virtual machines. The general functionality of a sandbox is described here, for example: https://de.wikipedia.org/wiki/Sandbox.

The sandbox is preferably configured to open and/or execute the email data, in particular to open and/or execute the email attachment data.

According to a preferred embodiment of the present invention, the e-mail output data generation processor is preferably configured to generate the partial content representation data, in particular to generate at least one optical partial image of the opened and/or executed e-mail data.

According to a preferred embodiment of the present invention, multiple content representation data parts can be generated if multiple content representation data parts are required for the complete representation of the optically mappable part of the content of the digital source data.

According to a preferred embodiment of the present invention, the e-mail output data processing processor has at least one data interface for receiving the digital e-mail output data.

According to a preferred embodiment of the present invention, the email output data generation processor is configured to analyze the digital email output data with regard to one or more defined properties, in particular, formatting and/or field links and/or table functions and/or image configurations and/or control functions and/or authorizations and/or links are preferred, with the email

output data processing processor is configured to provide an optical property representation, in particular formatting information and/or field linkage information and/or table function information and/or image configuration information and/or control function information and/or authorization information and/or links, in particular a code or to generate several codes, in particular one QR code or several QR codes, in particular in a form that can be output optically, in particular to generate one code or several codes, in particular one QR code or several QR codes.

The email raw data generation processor is configured to launch and/or use and/or run multiple sandboxes in accordance with a preferred embodiment of the present invention.

According to a preferred embodiment of the present invention, the email output data generation processor can start and/or use and/or execute a respective sandbox for different email data, in particular different emails and/or different email data attachments.

According to a preferred embodiment of the present invention, the sandbox can be terminated or deleted or closed or shut down after the email data has been displayed and/or executed and/or simulated and/or prepared by the email output data generation processor.

According to a preferred embodiment of the present invention, the email output data generation processor is configured such that it starts and/or uses and/or executes at least one sandbox for a number of email mailboxes, with the sandboxes preferably being kept in a “standby” mode, particularly after they have been started will be received by email data in the mailbox running in the respective sandbox.

According to a preferred embodiment of the present invention, the email output data generation processor is configured so that one or one or more or the majority of the sandboxes leave the "standby" mode at defined intervals and the respective mailbox starts an email retrieval via the email data interface from an email server.

According to a preferred embodiment of the present invention, the email output data generation processor is configured such that each sandbox can be assigned a uniquely identified physical memory, in particular one or more portions of a specific physical memory, in particular an HDD or SDD hard disk.

According to a preferred embodiment of the present invention, the email output data generation processor is configured to assign the physical memory to the sandboxes in such a way that the physical memory parts assigned to the respective sandboxes are separated from one another by at least one physical memory unit and preferably by a plurality of physical memory units.

The email raw data generation processor is configured in accordance with a preferred embodiment of the present invention so that the unique Identified physical memory, in particular one or more parts of a specific physical memory, in particular an HDD or SDD hard drive, to which a terminated or closed or destroyed sandbox was assigned can be partially, in particular not completely, assigned to at least one new sandbox and preferably to several new sandboxes .

According to a preferred embodiment of the present invention, at least part of the e-mail result data set can be made available by the e-mail input signal processing processor or by a function processor device for optical output to a terminal device.

According to a preferred embodiment of the present invention, the terminal is configured to provide the email data, in particular to transmit the email data to the terminal, based on the part of the email results data set provided.

According to a preferred embodiment of the present invention, the e-mail transmission system has a system for converting digital output data into analog signals and for converting the analog signals into digital result data, in particular a digital result file or digital result database entries, the digital output data representing a bit combination of digital e-mail attachment data, converting the analog signals into digital result data is preferably to be understood as generating digital result data, the digital result data containing a result data record. The result data set is preferably a digital representation of the analog signals of the bit part combination representation type. According to a preferred embodiment of the present invention, the system for converting digital output data into analog signals and for converting the analog signals into digital result data has an output data processing processor for generating a large number of different analog signals of a bit part combination representation type, the bit combination being represented by a plurality of bit part combinations, wherein the multiple bit-part combinations are represented by the multiplicity of different analog signals of the bit-part combination representative type, each analog signal of the bit-part combination representative type of the multiplicity of different analog signals of the bit-part combination representative type representing a defined bit-part combination of the multiple bit-part combinations, in particular directly or indirectly, with the output data processing processor at least one data interface for receiving of the digital output data t, wherein the output data processing processor has at least one signal output for outputting the analog signals of the bit part combination representation type. Furthermore, according to a preferred embodiment of the present invention, the system has an input signal processing processor for converting the analog signals of the bit part combination representation type into the digital result data, the input signal processing processor having at least one signal input for receiving the signals output via the at least one signal output of the output data processing processor, the digital result data have a result data set as its content, the result data set being a digital representation of the analog signals of the bit part combination representation type, the result data set representing at least the bit combination of the digital email attachment data completely and preferably having it, the bit sequences of the digital result data and the digital email attachment data being different. The output data processing processor and the email

According to a preferred embodiment of the present invention, the output data processing processor can be a processor, in particular the same processor.

The input signal processing processor and the email

According to a preferred embodiment of the present invention, input signal processing processors can be a processor, in particular the same processor.

The above-mentioned object is achieved according to the invention by an enamel processing method according to claim 23. The email processing method has at least the following steps:

Receiving email data, in particular via an email data interface, generating a multiplicity of different analog signals of a content part representation type, with content part representation data being represented from the multiplicity of different analog signals of the content part representation type, with the content part representation data representing at least one optically reproducible part of a content of digital source data, with the digital Source data representing the e-mail data, in particular e-mail text data and/or e-mail image data and/or e-mail attachment data, or are formed by the e-mail data, and converting the analog signals of the content part representation type into digital e-mail result data, the digital e-mail result data containing an e-mail result data record, wherein the e-mail result data set is a digital representation of the analog signals of the content part representation type, wherein the e-mail result data set contains at least one optically a imageable part of the content of the digital source data represents and preferably has and storing the email result data.

The aforementioned object is also achieved according to the invention by a device or system for converting digital output data into analog signals and for converting the analog signals into digital result data, in particular a digital result file or digital result database entries, according to claim 24, the digital output data being a bit combination of digital represent source data, in particular a digital file or a digital data stream, with the conversion of the analog signals into digital result data preferably being understood as generating digital result data, with the digital result data containing a result data record, with the result data record being a digital representation of the analog signals of the Please part combination representation type is. The device or system preferably has: An output data processing processor for generating a plurality of different analog signals of a bit-part combination representation type, the bit combination being represented by a plurality of bit-part combinations, the plurality of bit-part combinations being represented by the plurality of different analog signals of the bit-part combination representation type, each analog signal of the bit-part combination representation type of the multiplicity of different analog signals of the bit-part combination representation type represents a defined bit-part combination of the plurality of bit-part combinations, in particular directly or indirectly, with the output data processing processor having at least one data interface for receiving the digital output data, with the output data processing processor having at least one signal output for outputting the analog signals of the bit-part combination representation type , and an input signal processing processor for converting the analog signals of the bit part combination representation type into the digital result data, the input signal processing processor having at least one signal input for receiving the signals output via the at least one signal output of the output data processing processor, the digital result data containing a result data set, the result data set is a digital representation of the analog signals of the bit part combination representation type, the result data set representing at least the bit combination of the digital source data completely and preferably having it, bit sequences of the digital result data and the digital source data being different.

Storage media of any type store the data stored on them in an arrangement of mostly binary character strings or states. With HDDs, for example, different states are usually generated and stored by differently polarized magnetic memory components. Electronic read only memories achieve storage through arrays of differently switched switches or differently charged transistors or other components. Optical storage media such as CDs use processes such as lasers to generate optically detectable changes in/on the storage medium, which in turn can then be read out with optical detection.

What all storage types have in common is that the content to be stored is entered directly into a combination of binary character strings that corresponds to them, e.g. bits. A dedicated bit sequence corresponds exactly to the content to be stored. Malware hidden within a file can be executed at any time with this type of storage and cause damage. Common protective measures try to ensure the security of the data structure by searching for known malicious code or by AI-supported prediction of potentially harmful code and its removal. The fact that this approach only protects against some of the threats that actually occur is confirmed by the numerous reports of cyber attacks, data leaks or ransomware blackmail.

As long as the algorithms for detecting malicious software are looking for the actual malicious code in a correspondingly higher programming language or, at best, in its bit equivalent, the malicious software remains active and therefore potentially dangerous until it is detected and combated.

The present invention already passivates the malware at the moment of storage. For this purpose, an interface is created that only makes the actual data storage unidirectionally accessible. In addition, the contents to be stored or their bit equivalents are translated into analog signals and transmitted to the memory side via appropriate signal lines. An image of the analog signals or their sequence or arrangement is then stored there as a memory equivalent. For example, a result file is created that contains the history of several incoming analog signals. This content represents the bit equivalent of the original file or content to be saved. The generated result file could, for example, also be a text file with a sequence of ones and zeros corresponding to the bit correspondence of the original file. The bit equivalent of the result file on the storage medium then no longer contains any bit sequences that belong to the malware that may be hidden in the original file, since these only exist as a sequence of ones and zeros and thus as regular text and no longer as an executable bit sequence.

According to a particularly preferred embodiment of the present invention, malware can be searched for and removed in the bit combinations contained in the result data record of the digital result data. This is advantageous since the malicious software cannot be executed or executed in this form, which means that the bit combination/s can be reliably analyzed. According to a preferred embodiment, the bit combination contained in the result data set can be analyzed to detect software components. An analysis processor is preferably provided for carrying out the analysis and is part of the device or the system for converting digital output data into analog signals and for converting the analog signals into digital result data. The software components are preferably malware or malware components.

According to a further preferred embodiment of the present invention, the result data set has metadata and/or optical representation data on the content of the data in addition to the bit combination of the digital source data.

According to a further preferred embodiment of the present invention, the multiplicity of different analog signals of the bit-part combination representation type comprises at least four different analog signals of the bit-part combination representation type and preferably thirty-two different analog signals of the bit-part combination representation type and particularly preferably at least one hundred and twenty-eight different analog signals of the bit-part combination representation type and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty four different bit part combination representation type analog signals.

According to a further preferred embodiment of the present invention, the output data processing processor for generating the multiplicity of different analog signals of the bit part combination representation type has at least one signal output, wherein the signal output can be subjected to a multiplicity of different combinations of at least voltage and current intensity.

According to a further preferred embodiment of the present invention, the different combinations of at least voltage and current intensity are analog individual signals or modulated analog multiple signals.

The output data processing processor for generating the multiplicity of different analog signals of the bit part combination representation type according to a further preferred embodiment of the present invention has a multiplicity of independently controllable signal outputs, with at least several signal outputs from the output data processing processor each having a multiplicity of different combinations of voltage and current strength being acted upon.

According to a further preferred embodiment of the present invention, a large number of different combinations of voltage and current intensity per signal output comprises at least four combinations and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty-eight different combinations and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different combinations.

According to a further preferred embodiment of the present invention, at least several of the independently controllable signal outputs can be controlled simultaneously to generate one signal each, or at least several of the independently controllable signal outputs can be controlled simultaneously to generate a modulated analog signal.

According to a further preferred embodiment of the present invention, the result data, in particular the result file, have a result data format and the digital source data have a source data format, the source data format and the result data format being different.

According to a further preferred embodiment of the present invention, the input signal processing processor has at least one

Input signal processing processor output for outputting the digital representation of the analog signals.

According to a further preferred embodiment of the present invention, the input signal processing processor output is coupled to a storage medium for digitally storing data, there preferably being no digital data connection between the storage medium and the output data processing processor for the transmission of digital output data.

According to a further preferred embodiment of the present invention, the input signal processing processor and the output data processing processor are arranged on one circuit board.

According to a further preferred embodiment of the present invention, the path of the analog signals of the bit part combination representation type from the output data processing processor to the input signal processing processor is shorter than 100 cm, in particular shorter than 20 cm or preferably shorter than 50 mm or particularly preferably shorter than 10 mm and most preferably shorter than 5 mm.

According to a further preferred embodiment of the present invention, a function output signal processing processor is provided for generating a large number of different analog signals for mapping the control of the function processor device, the large number of different analog signals being able to be generated in at least four mutually different states.

According to a further preferred embodiment of the present invention, a function data processing processor is provided for generating visualization data for visualizing a function processor control mask.

A drive data processing processor for generating a plurality of different drive representation type analog signals in response to digital drive data is provided according to a further preferred embodiment of the present invention, wherein the digital drive data represents a plurality of different input commands from at least one input device.

According to a further preferred embodiment of the present invention, the large number of different input commands for the digital control data are represented by a number of different analog signals of the control representation type, the large number of different analog signals preferably being able to be generated in at least four different states. According to a further preferred embodiment of the present invention, several or each analog signal of the control representative type of the multiplicity of different analog signals of the control representative type represents a defined input command, in particular directly or indirectly, wherein the control data processing processor has at least one data interface for receiving the digital control data and wherein the

Control data processing processor has at least one signal output for outputting the analog signals of the control representative type. According to a further preferred embodiment of the present invention is a

Drive input signal processing processor for converting the drive representation type analog signals into the digital result drive data for manipulating the Result data provided, wherein the control input signal processing processor has at least one signal input for receiving the signals output via the at least one signal output of the control data processing processor. According to a further preferred embodiment of the present invention, the digital result drive data represent or form a digital representation of the analog signals of the drive representation type.

According to a further preferred embodiment of the present invention, the control input signal processing processor and the input signal processing processor can be embodied as one or the same processor. The drive data processing processor and the

Output data processing processor can be designed as one or the same processor.

The control input signal processing processor is coupled at least indirectly to at least one function processor device, wherein the function processor device can be controlled to execute at least one defined function and preferably a large number of different functions depending on the digital result control data.

According to a further preferred embodiment of the present invention, the digital result control data can be generated for defined analog signals of the control representation type.

According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type of the defined function or the defined functions are assigned to the function processor device or represent them.

According to a further preferred embodiment of the present invention, a function output signal processing processor is provided for generating a multiplicity of different analog signals of the function processing type for mapping the activation of the function processor device, the multiplicity of different analog signals being able to be generated in preferably at least four different states.

A function data processing processor for generating visualization data for visualizing a function processor control visualization, in particular a function processor control mask, is provided according to a further preferred embodiment of the present invention.

According to a further preferred embodiment of the present invention, the function processor control visualization can be generated at least partially as a function of the analog signals of the function processing type generated by the function output signal processing processor, wherein the function processor control visualization can be manipulated by the at least one input device, the digital control data being able to be generated as a function of the manipulation of the function processor control visualization are, the function processor control visualization and the control data processing processor being connected to one another at least indirectly via the data interface.

Alternatively, digital result control data can be generated for all analog signals of the control representation type. In addition, function control data for controlling the defined function or for controlling the defined functions can be provided. Furthermore, a comparison of the digital result control data and the provided function control data can be brought about, with the function processor device being controlled to execute at least the defined function and preferably the multiplicity of different functions if the digital result control data can be assigned to the provided function control data, in particular if the digital result control data and the provided function control data match.

Furthermore, the above-mentioned object is achieved by a method for converting digital output data into analog signals and for converting the analog signals into digital result data, in particular a digital result file or digital result database entries, according to Claim 56, the digital output data being a bit combination of digital source data, in particular a digital file or a digital data stream, with the conversion of the analog signals into digital result data preferably being understood as generating digital result data, with the result data set being a digital representation of the analog signals of the bit part combination representation type, with the result data set containing at least the bit combination of the digital source data completely represented and preferably has. The method according to the invention preferably has the steps: generating a large number of different analog signals of the bit part combination representation type, in particular with an output data processing processor, the bit combination being represented by a plurality of bit part combinations, the plurality of bit part combinations being represented by the large number of different analog signals of the bit part combination representation type, each analog signal of the bit-part combination representation type of the multiplicity of different analog signals of the bit-part combination representation type represents a defined bit-part combination of the plurality of bit-part combinations, in particular directly or indirectly, and converting the analog signals of the bit-part combination representation type into the digital result data, in particular with an input signal processing processor, the digital result data containing a result data record have, where the resultd data set is a digital representation of the analog signals of the bit part combination representation type, the result data set representing at least the bit combination of the digital source data completely and preferably having it, bit sequences of the digital result data and the digital source data being different.

According to a further preferred embodiment of the present invention, the bit combination contained in the result data record is analyzed with regard to software components, the software components preferably being malware or being components of malware.

Furthermore, the above object is achieved by an apparatus or system for converting digital drive data into analog signals of a drive representative type and for converting the analog signals of the drive representative type into digital result drive data, according to claim 57, wherein the digital drive data includes a plurality of different input commands from at least one represent input device. The device or the system preferably has: A control data processing processor for generating a large number of different analog signals of the control representation type, the large number of different input commands of the digital control data being represented by a number of different analog signals of the control representation type, the large number of different analog signals of the control representation type in at least four different states can be generated, with several or each analog signal of the control representation type of the plurality of different analog signals of the control representation type a defined input command, in particular immediately or io indirectly, wherein the control data processing processor has at least one data interface for receiving the digital control data, wherein the control data processing processor has at least one signal output for outputting the analog signals of the control representation type, and a

Control input signal processing processor for converting the analog signals of the control representation type into the digital result control data, the control input signal processing processor having at least one signal input for receiving the signals output via the at least one signal output of the control data processing processor

Has driving representative type. The resultant digital drive data is, according to a preferred embodiment of the present invention, a digital representation of the drive representation type analog signals.

According to a preferred embodiment of the present invention, the control input signal processing processor is at least indirectly coupled to at least one function processor device, wherein the control of the function processor device can be effected to execute at least one defined function and preferably a large number of different functions depending on the digital result control data.

According to a preferred embodiment of the present invention, the digital result drive data can be generated for defined analog signals of the drive representation type.

According to a preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to or represent the defined function or functions of the function processor device.

Alternatively, digital result control data can be generated for all analog signals of the control representation type. In addition, function control data for controlling the defined function or for controlling the defined functions can be provided. Furthermore, a comparison of the digital result control data and the provided function control data can be effected, with the function processor device being controlled to execute at least the defined function and preferably the multiplicity of different functions if the digital result control data can be assigned to the provided function control data, in particular if the digital result control data and the intended function control data.

A function output signal processing processor for generating a multiplicity of different analog signals of the function processing type for mapping the activation of the function processor device is provided according to a preferred embodiment of the present invention, wherein the multiplicity of different analog signals can be generated in preferably at least four different states and wherein a function data processing processor for generating Visualization data for the visualization of a function processor control visualization, in particular a function processor control mask, is provided.

According to a preferred embodiment of the present invention, the function processor control visualization can be generated at least partially as a function of the analog signals of the function processing type generated by the function output signal processing processor. A manipulation of According to a preferred embodiment of the present invention, the function processor control visualization can be brought about by the at least one input device, the digital control data being able to be generated as a function of the manipulation of the function processor control visualization, the function processor control visualization and the control data processing processor being connected to one another at least indirectly via the data interface.

According to a preferred embodiment of the present invention, the function processor device is for controlling one or more actuators, in particular motor(s), and/or for controlling one or more water supply device(s) and/or a factory, in particular for the production of chemical base materials, a refinery or waste incineration or Food production or drug/vaccine production, or multiple factories and/or one medical device or multiple medical devices and/or one communication device or multiple communication devices and/or one energy supply device, in particular solar power plant, coal-fired power plant, wind power plant, gas power plant, nuclear power plant, hydroelectric power plant or tidal power plant, or several energy supply devices and/or a production device, in particular an industrial robot, or several production devices and/or a vehicle, in particular a train, ship, car, truck, Airplane, gondola, bus or construction machine or several vehicles trained or set up.

Additionally or alternatively, the function processor device can be used to control one or more actuators, in particular motors, and/or to control one or more switches, in particular electrical switches, and/or to control one or more communication devices, in particular antennas, routers, Satellite and/or be designed to control one or more processor(s) and/or machine(s) and/or to control a computer and/or a server or be part of one or more actuators, in particular motor(s) and/or a or more switches, in particular electrical switches, and/or one or more communication devices, in particular antenna, router, satellite and/or one or more processor(s) and/or machine(s) and/or one or more computer(s), in particular mobile phone, Tablet PC, TV, Smartwatch, laptop, desktop computer and/or a server or a server network.

Furthermore, the above-mentioned object is achieved according to the invention by a method for converting digital control data into analog signals of a control representative type and for converting the analog signals of the control representative type into digital result control data, according to claim 87, the digital control data having a large number of different input commands from at least one input device represent. The method preferably has at least the steps: generating a large number of different analog signals of the control representative type, in particular with a control data processing processor, the large number of different input commands of the digital control data being represented by a number of different analog signals of the control representative type, the large number of different analog signals of the control representative type being represented are generated in at least four mutually different states, with several or each analog signal of the control representation type of the multiplicity of different analog signals of the control representation type representing a defined input command, in particular directly or indirectly, and converting the analog signals of the control representation type into the digital result control data, in particular with a Driving input signal processing processor, wherein the digital result driving data a dig ital representation of the analog signals of the driving representation type. According to a preferred embodiment of the present invention, the method is characterized by the step of activating at least one defined function and preferably a large number of different functions as a function of the digital result activation data.

The digital result drive data is generated according to a preferred embodiment of the present invention for defined analog signals of the drive representation type.

According to a preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the defined function or the defined functions of the function processor device or represent them.

The above object is further achieved by a passivation device or a passivation system for converting digital output data into digital result data according to claim 91, wherein the digital result data represents the digital output data in a non-executable state, and for manipulating the digital result data in the non-executable state, wherein the digital output data represents a bit combination of digital source data, in particular a digital file or a digital data stream. The passivation device or the passivation system preferably has an output data processing processor for generating a plurality of different analog signals of a bit-part combination representation type, the bit combination being represented by a plurality of bit-part combinations, the plurality of bit-part combinations being represented by the plurality of different analog signals of the bit-part combination representation type, each analog signal of the Bit-part combination representation type of the large number of different analog signals of the bit-part combination representation type represents a defined bit-part combination of the several bit-part combinations, in particular directly or indirectly, with the output data processing processor having at least one data interface for receiving the digital output data, with the output data processing processor having at least one signal output for outputting the analog signals of the bit-part combination ion representative type, and one

Input signal processing processor for converting the analog signals of the bit-part combination representation type into the digital result data, the input signal processing processor having at least one signal input for receiving the analog signals of the bit-part combination representation type output via the at least one signal output of the output data processing processor, the digital result data containing a result data record, the result data record having a digital representation of the analog signals of the bit part combination representation type, the result data set representing at least the bit combination of the digital source data in full and preferably having it, bit sequences of the digital result data and the digital source data being different, and a control data processing processor for generating a large number of different analog signals of a control representation type in Dependence on digital controls rdaten, wherein the digital control data represent a large number of different input commands from at least one input device, the large number of different input commands of the digital control data being represented by a number of different analog signals of the type of control representation, the large number of different analog signals of the type of control representation being able to be generated in at least four different states wherein a plurality of or each analog drive representation type signal of the plurality of different analog drive representation type signals defines one Input command, in particular directly or indirectly, represented, wherein the control data processing processor has at least one data interface for receiving the digital control data, wherein the control data processing processor has at least one signal output for outputting the analog signals of the control representation type, and one

Control input signal processing processor for converting the analog signals of the control representation type into the digital result control data for manipulating the result data, the control input signal processing processor having at least one signal input for receiving the analog signals of the control representation type output via the at least one signal output of the control data processing processor, the digital result control data having a digital representation of at least one are part of the analog signals of the control representation type, the control input signal processing processor being coupled at least indirectly to a function processor device for executing or effecting at least one function and preferably a plurality of functions.

According to a further preferred embodiment of the present invention, the function processor device can be activated to execute at least the defined function and preferably the large number of different functions as a function of the digital result activation data, the defined function at least or precisely comprising the manipulation of the result data.

According to a further preferred embodiment of the present invention, the digital result control data can be generated for defined analog signals of the control representation type. The defined analog signals of the drive representation type of the defined function or functions are associated with or represent the function processor means.

Furthermore, according to a further preferred embodiment of the present invention, a function output signal processing processor can be provided for generating a multiplicity of different analog signals of a function processing type for mapping the control of the function processor device, wherein the multiplicity of different analog signals of the function processing type can be generated in at least four different states, with a Function data processing processor for generating visualization data for visualizing a function processor control visualization, in particular function processor control mask, is provided, the

Function processor control visualization can be generated at least partially as a function of the analog signals of the function processing type generated by the function output signal processing processor, wherein the function processor control visualization can be manipulated by the at least one input device, the digital control data depending on the manipulation of the Function processor control visualization can be generated, the function processor control visualization and the control data processing processor being connected to one another at least indirectly via the data interface.

Furthermore, the above-mentioned object is achieved by a method for converting digital output data into digital result data according to Claim 121, the digital result data representing the digital output data in a non-executable state, and for manipulating the digital result data in the non-executable state, the digital Output data represent a bit combination of digital source data, in particular a digital file or a digital data stream. The method preferably has at least the following steps: generating a multiplicity of different analog signals of a bit-part combination representation type, in particular with an output data processing processor, the bit combination being represented by a plurality of bit-part combinations, the multiplicity of bit-part combinations being represented by the multiplicity of different analog signals of the bit-part combination representation type, each analog Signal of the bit part combination representation type of the multiplicity of different analog signals of the bit part combination representation type represents a defined bit part combination of the several bit part combinations, in particular directly or indirectly, and converting the analog signals of the bit part combination representation type into the digital result data, in particular with an input signal processing processor, the digital result data having a result data record as content , where the result record is a digital representation of the analog signals of the bit part combination representation type, the result data set representing at least the bit combination of the digital source data completely and preferably having it, bit sequences of the digital result data and the digital source data being different, and generating a large number of different analog signals of a control representation type depending on digital control data, in particular with a control data processing processor, the digital control data representing a large number of different input commands from at least one input device, the large number of different input commands of the digital control data being represented by a number of different analog signals of the control representation type, the large number of different analog signals of the control representation type being in at least four different states are generated, with several e or each analog signal of the control representation type of the multiplicity of different analog signals of the control representation type represents a defined input command, in particular directly or indirectly, and converting the analog signals of the control representation type into the digital result control data for manipulating the result data, in particular with a control input signal processing processor, the digital result control data are a digital representation of at least part of the analogue signals of the driving representation type, and driving at least the defined function and preferably the plurality of different functions depending on the digital result driving data, wherein the defined function comprises at least or precisely manipulating the result data. According to a further preferred embodiment of the present invention, the digital result control data can be generated for defined analog signals of the control representation type. According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the defined function or the defined functions or represent them.

Furthermore, according to a further preferred embodiment of the present invention, the method can include the step of generating a large number of different analog signals of a function processing type for mapping the activation of the defined function, wherein the multiplicity of different analog signals of the function processing type are generated in at least four mutually different states, and also the step of generating visualization data for visualizing a function processor activation visualization, in particular

Function processor control mask, the function processor control visualization being generated at least partially as a function of the generated analog signals of the function processing type, the function processor control visualization being manipulated by the at least one input device, the digital control data being generated as a function of the manipulation of the function processor control visualization.

Furthermore, the above-mentioned object is achieved according to the invention by a system according to claim 125. The system preferably has at least one access system connected to a network, in particular the Internet, in particular an access server, and at least one data and/or programming system, in particular a data and/or program server, with the data and/or or program system preferably has no data connection for exchanging digital signals with the access system.

Furthermore, the system has a system for converting digital control data into analog signals of a control representative type and for converting the analog signals of the control representative type into digital result control data, the digital control data having a large number of different input commands from at least one input device, in particular an input device, a terminal device, the system for converting digital drive data into analog signals of a drive representation type and for converting the analog signals of the drive representation type into digital result drive data

Control data processing processor for generating a large number of different analog signals of the control representation type, the large number of different input commands of the digital control data being represented by a number of different analog signals of the control representation type, the large number of different analog signals of the control representation type being able to be generated in at least four different states, a plurality of or each analog signal of the control representation type of the multiplicity of different analog signals of the control representation type represents a defined input command, in particular directly or indirectly, the control data processing processor having at least one data interface for receiving the digital control data, the control data processing processor having at least one signal output for outputting the analog signals of the control representation type has, and an Anst your input signal processing processor for converting the analog signals of the control representation type into the digital result control data, wherein the control input signal processing processor has at least one signal input for receiving the signals output via the at least one signal output of the control data processing processor

control representation type, wherein the digital result control data is a digital representation of the analog signals of the control representation type, wherein the data and/or programming system and the access system have the system for converting digital control data into analog signals of a control representation type and for converting the analog signals of the Control representative type are linked to one another in digital result control data, with the access system via the network, in particular the Internet, with the end device, in particular cell phones, laptops, desktop computers, tablet PCs and/or IoT devices, such as refrigerators, barriers, household appliances, motor vehicles, or infrastructure facilities, like traffic lights, locks, Interlockings or lighting, in particular street lighting, a data exchange can be effected, the digital control data being able to be transmitted from the access system to the control data processing processor as a function of the data exchange with the terminal device, the digital result control data being receivable from the data and/or programming system, At least one defined function and preferably a large number of different functions can be effected or executed by a function processor device of the data and/or programming system as a function of the digital result control data.

According to a further preferred embodiment of the present invention, the digital result control data for can be generated as defined analog signals of the control representation type.

According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the defined function or the defined functions of the function processor device or represent them. According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the digital result control data via an assignment unit, in particular an assignment list or assignment table. According to a further preferred embodiment of the present invention, no result control data can be generated for analog signals of the control representation type, to which no digital result control data are assigned, or exclusion result data can preferably be generated, the exclusion result data representing a documentation of the signal transmission event, in particular with information on the analog signals of the control representation type .

Furthermore, according to a further preferred embodiment of the present invention, a function output signal processing processor can be provided for generating a multiplicity of different analog signals of the function processing type for mapping the activation of the function processor device, the multiplicity of different analog signals being able to be generated in at least four different states, the function output signal processing processor being a is part of the system for converting digital drive data into analogue signals of a drive representation type and for converting the analogue signals of the drive representation type into digital result drive data or is part of the data and/or programming system.

A function data processing processor for generating visualization data for visualizing a function processor control visualization, in particular a function processor control mask, is provided according to a further preferred embodiment of the present invention, the function data processing processor preferably being part of the system for converting digital control data into analog signals of a control representation type and for converting the analog signals of the control representation type into digital result control data or part of the access system.

According to a further preferred embodiment of the present invention, the function processor control visualization can be generated at least partially as a function of the analog signals of the function processing type generated by the function output signal processing processor, wherein the function processor control visualization can be manipulated by the at least one input device, the digital control data being able to be generated as a function of the manipulation of the function processor control visualization are, where the Function processor control visualization and control data processing processor are at least indirectly connected to each other via the data interface.

Furthermore, according to a further preferred embodiment of the present invention, an update or reconfiguration unit for converting digital configuration output data into update or reconfiguration data can be provided, the digital configuration output data representing a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream , wherein the update or reconfiguration unit has at least: A configuration output data processing processor for generating a large number of different analog signals of a configuration bit part combination representation type, the configuration bit combination of the digital configuration data being represented by a plurality of configuration bit part combinations, the configuration bit combination having preferred content of the digital configuration output data, the multiple configuration bit parts ko Combinations of the multiplicity of different analog signals of the configuration bit part combination representation type is represented, the multiplicity of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the multiplicity of different analog signals of the configuration bit part combination representation type having a defined configuration Bit part combination of the several configuration bit part combinations, in particular directly or indirectly, represented, the configuration

Output data processing processor has at least one data interface for receiving the digital configuration output data, the configuration output data processing processor having at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration input signal processing processor for converting the analog signals of the configuration bit part combination representation type into digital configuration result data , wherein the configuration input signal processing processor has at least one signal input for receiving the analog signals of the configuration bit part combination representation type output via the at least one signal output of the configuration output data processing processor, wherein update or reconfiguration data for updating or reconfiguring the function processor device can be generated from the digital configuration result data.

An update or reconfiguration data generation processor is provided according to a further preferred embodiment of the present invention, wherein the update or reconfiguration data generation processor can transfer configuration bit part combinations of the digital result data to generate the update or reconfiguration data in a predetermined order using assignment data.

According to a further preferred embodiment of the present invention, the assignment data are provided in a data memory which can be accessed by the update or reconfiguration data generation processor.

According to a further preferred embodiment of the present invention, a multitude of assignment data is provided, with a mechanism for selecting the assignment data being stored. According to a further preferred embodiment of the present invention, the mechanism is designed to effect the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

The above-mentioned object is achieved according to the invention by a method for controlling a data and/or program system according to claim 145, the data and/or program system not being connected to an access system via a data connection for exchanging digital signals. The method preferably has at least the following steps: generating a large number of different analog signals of a control representation type, in particular with a

Drive data processing processor, wherein the plurality of different input commands of the digital drive data are represented by a plurality of different drive representation type analog signals, wherein the plurality of different drive representation type analog signals are generated in at least four states different from each other, wherein a plurality or each of the drive representation type analog signals of the plurality of different analog signals of the control representation type represents a defined input command, in particular directly or indirectly, and converting the analog signals of the control representation type into the digital result control data, in particular with a control input signal processing processor, the digital result control data being a digital representation of the analog signals of the control representation type, with the access system via the Network, in particular the Internet, with the end device, in particular re mobile phones, laptops, desktop computers, tablet PCs and/or IoT devices, such as refrigerators, barriers, household appliances, motor vehicles, or infrastructure facilities such as traffic lights, locks, signal boxes or lighting, in particular street lighting, a data exchange is effected, depending on the access system the data exchange with the terminal transmits the digital control data for generating the large number of different analog signals of the control representative type, the digital result control data being received from the data and/or program system, with at least one defined function processor device of the data and/or program system Function and preferably a variety of different functions depending on the digital result control data is effected or executed.

The above-mentioned object is achieved according to the invention by a machine system according to claim 46. The machine system preferably has: at least one machine device controlled by a function processor device and a system for converting digital control data into analog signals of a control representative type and for converting the analog signals of the control representative type into digital result control data, the digital control data containing a large number of different input commands of at least represent an input device, in particular an input device of a terminal device. The system for converting digital drive data into analog signals of a drive representation type and for converting the analog signals of the drive representation type into digital result drive data preferably comprises: a drive data processing processor for generating a plurality of different analog signals of the

Driving representation type, wherein the plurality of different input commands of the digital driving data are represented by a plurality of different analog signals of the driving representation type, wherein the plurality of different analog signals of the driving representation type in at least four of each other different states can be generated, with several or each analog signal of the control representative type of the multiplicity of different analog signals of the control representative type representing a defined input command, in particular directly or indirectly, with the control data processing processor having at least one data interface for receiving the digital control data, with the control data processing processor having at least one signal output for outputting the drive representative type analog signals

control representation type, the digital result control data being a digital representation of the analog signals of the control representation type, the digital control data being sent to the control data processing processor via an input data interface of the system for converting digital control data into analog signals of a control representation type and for converting the analog signals of the control representation type into digital result control data can be transmitted or supplied, with the machine device being able to receive the digital control result data, with at least one defined function and preferably a large number of different functions being able to be effected or executed or controlled or triggered or deactivated or activated by the function processor device of the machine device as a function of the digital result control data.

Machines and industrial plants are generally controlled by appropriate control commands. These control commands are usually written in simple languages suitable for the application or in a form that the machine or system can understand. Motorized machines such as CNC systems or 3D printers often receive their instructions as G-code. Defined variables are assigned concrete values that cause a fixed movement (usually rotation) of the motors installed in the machine.

These machine instructions can be generated both externally and, increasingly, within the machine. In the case of the latter, the actual instruction is generated from a program using a language that is easier for the user to understand. A potential security risk arises here, since this user language and the interface usually required for transmitting the language could also be used by unauthorized third parties. In addition to the obvious danger that an externally controlled machine poses to the immediate environment, at least errors in the products dependent on the machine processes, such as products, must be expected. The destruction of the machine itself is of course possible and cannot be ruled out - whether through destructive will of the polluter or through accidental incorrect operation due to ignorance of the correct operation of the machine.

All of this can also be done independently of direct access to the machine by an attacker. Possible threats here are also autonomous programs, malware, AI attackers and other malicious software.

The present invention includes an interface and associated methods that eliminate the aforementioned multi-step process threats. In order to prevent direct access for an attacker, control commands are introduced via the exclusively unidirectional interface. There is no data exchange via the interface. Instead, the desired commands become a sequence or unilaterally Composition of purely analog signals generated. These are transmitted to the receiver via a signal line that works exclusively from the transmitter to the receiver and compared there with an allocation table. The signals that can be assigned to a specific control command are executed, while all others are discarded.

Since the unassigned signals are not stored in digital form, even if malware is successfully transmitted, it cannot be executed.

Even if (intermediate) storage is desired or necessary, instead of the actual content of the transmission, only an image of the transmitted analog signal values and waveforms is stored. Malicious code stored in this way cannot be executed on the target system and is therefore passivated and cannot cause any damage.

Any required feedback from the machine, for example in the form of sensor data etc., is also transmitted via a unidirectional interface as analog signals representing these states. Thus, the control of the machine, including the feedback on the effects of the control commands, takes place only indirectly through appropriate translations on both sides and the use of analogue signals that are only sent unidirectionally.

According to a further preferred embodiment of the present invention, the input data interface can be an input device, a computer or an access system, in particular an access server.

According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the defined function or the defined functions of the function processor device or represent them.

According to a further preferred embodiment of the present invention, the defined analog signals of the control representation type are assigned to the digital result control data via an assignment unit, in particular an assignment list or assignment table.

According to a further preferred embodiment of the present invention, no result control data can be generated or exclusion result data can be generated for analog signals of the control representation type, to which no digital result control data are assigned, the exclusion result data representing a documentation of the signal transmission event, in particular with information on the analog signals of the control representation type.

According to a further preferred embodiment of the present invention, a function output signal processing processor for generating a multiplicity of different analog signals of the function processing type is provided for mapping the activation of the function processor device, with the multiplicity of different analog signals being able to be generated in preferably at least four different states.

According to a further preferred embodiment of the present invention, the function output signal processing processor is a part of the system for converting digital drive data into analog signals of a drive representation type and for Converting the drive representation type analog signals into digital result drive data or a part of the machine equipment.

According to a further preferred embodiment of the present invention, the function data processing processor is part of the system for converting digital drive data into analog signals of a drive representation type and for converting the analog signals of drive representation type into digital result drive data or a part of the machine equipment.

An update or reconfiguration unit for converting digital configuration output data into update or reconfiguration data is provided according to a further preferred embodiment of the present invention, the digital configuration output data representing a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream, wherein the Update or reconfiguration unit at least has: A configuration output data processing processor for generating a large number of different analog signals of a configuration bit part combination representation type, the configuration bit combination of the digital configuration data being represented by a plurality of configuration bit part combinations, the configuration bit combination preferably being the content of the digital configuration - Output data is where the multiple configuration bit part combinations of the multiplicity of different analog signals of the configuration bit part combination representation type is represented, the multiplicity of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the multiplicity of different analog signals of the configuration bit part combination representation type representing a defined configuration bit part combination of multiple configuration bit part combinations, in particular directly or indirectly, wherein the configuration output data processing processor has at least one data interface for receiving the digital configuration output data, wherein the configuration output data processing processor has at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration -Input signal processing processor for converting the analog signals of the configuration bit part combination representation type into digital configuration result data, wherein the configuration input signal processing processor has at least one signal input for receiving the analog signals of the configuration bit part combination representation type output via the at least one signal output of the configuration output data processing processor, wherein the digital Configuration result data update or reconfiguration data for updating or reconfiguring the function processor device can be generated.

An update or reconfiguration data generation processor is provided according to a further preferred embodiment of the present invention, wherein the update or reconfiguration data generation processor can transfer configuration bit part combinations of the digital result data to generate the update or reconfiguration data in a predetermined order using allocation data.

According to a further preferred embodiment of the present invention, a multitude of assignment data is provided, with a mechanism for selecting the assignment data being stored.

According to a further preferred embodiment of the present invention, the mechanism is designed to effect the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

According to a further preferred embodiment of the present invention, the machine device is a motor vehicle, in particular in a car, truck, airplane or boat, a multi-axis robot, a production plant or a printing shop.

The above-mentioned object is achieved according to the invention by a method for controlling a machine system according to claim 168. The method according to the invention for controlling a machine system preferably has at least the following steps: generating a large number of different analog signals of a control representation type, with a large number of different input commands of digital control data being represented by a number of different analog signals of the control representation type, with the large number of different analog signals of the control representation type being at least four different states are generated, with several or each analog signal of the control representation type of the plurality of different analog signals of the control representation type representing a defined input command, in particular directly or indirectly, and converting the analog signals of the control representation type into the digital result control data, the digital result control data are a digital representation of the analog signals of the driving representation type, wob ei the digital control data for generating the large number of different analog signals of the control representative type are transmitted or supplied via an input data interface, with the digital result control data being received by the machine device, with at least one defined function and preferably a large number of different functions depending on the digital result control data is effected or executed or controlled or triggered or deactivated or activated.

Furthermore, the present invention can relate to a malware deactivation method, which preferably has at least the steps: generating a plurality on different analog signals of the bit-part combination representation type, in particular by an output data processing processor, with the plurality of different analog signals of the bit-part combination representation type representing a plurality of bit-part combinations, with the plurality of bit-part combinations representing a bit combination of digital source data, with the individual bit-part combinations each having the same length, with the bit-part combinations at least has a length of two bits and preferably at least or exactly 16 bits or particularly preferably at least or exactly 64 bits or very particularly preferably at least or exactly 256 bits or most preferably at least or exactly or up to 1024 bits, each combination of bits having a defined analog signal of the bit part combination representation type is assigned, receiving the analog signals of the bit part combination representation type, in particular by a

Input signal processing processor, generation of digital result data, in particular by the input signal processing processor, a result data set being generated from the analog signals, the result data set representing at least the bit combination of the digital source data in full and preferably having it, the digital result data containing the result data set, bit sequences of the digital Result data and the digital source data are different, storing the digital result data.

According to a preferred embodiment of the present invention, the analog signals are converted into the result data set representing the respective analog signal by comparison with a signal value assignment list or signal value assignment table, or the result data set represents a large number of physical property data, the physical property data being one or more physical Represent property/s of the individual analog signals, in particular the voltage value and/or the frequency and/or the amplitude.

According to a preferred embodiment of the present invention, each analog signal can be assigned to exactly one bit part combination by means of the identifying result data and a value-bit part assignment list or value-bit part assignment table.

According to a preferred embodiment of the present invention, the different physical property data can be assigned to exactly one bit part combination by means of the identifying result data and a property-bit part assignment list or property-bit part assignment table.

The function processor device is preferably provided for manipulating the digital result data. Manipulation of the digital result data is preferably to be understood as meaning at least one or more or all of the following functions: copy, move, rename, delete, open, edit, increase, start, trigger, end, accelerate, decrease, increase and/or save , Etc.

Furthermore, the above-mentioned object can also be achieved by an update or reconfiguration unit for converting digital configuration output data into update or reconfiguration data, the digital configuration output data representing a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream. The update or reconfiguration unit has at least: A configuration output data processing processor for generating a large number of different analog signals of a configuration bit part combination representation type, the configuration bit combination of the digital configuration data being represented by a plurality of configuration bit part combinations, the configuration bit combination having preferred content of the digital configuration output data, where the multiple configuration bit part combinations is represented by the plurality of different analog signals of the configuration bit part combination representation type, the plurality of analog signals representing multiple configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the plurality of different analog signals of the configuration bit part combination representation type one defined configuration bit part combination of the multiple configuration bit part combinations, in particular directly or indirectly, where the configuration

According to a preferred embodiment of the present invention, an update or reconfiguration data generation processor is provided, wherein the update or reconfiguration data generation processor can convert configuration-bit part combinations of the digital result data into a predetermined order by means of assignment data for generating the update or reconfiguration data.

According to a preferred embodiment of the present invention, the assignment data are provided in a data memory which can be accessed by the update or reconfiguration data generation processor.

According to a preferred embodiment of the present invention, a large number of allocation data is provided, with a mechanism for selecting the allocation data being stored. According to a preferred embodiment of the present invention, the mechanism is designed to effect the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

The processor, in particular the function processor device and/or the control input signal processing processor and/or the input signal processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device, can be provided as a dedicated processing element, e.g. B. a processing unit, a microcontroller, an FPGA, a CPLD or similar. The processor, in particular the function processor device and/or the control input signal processing processor and/or the input signal processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device, can also be provided, at least in part, as a computer program product that contains computer-readable instructions that are processed by a processing element can be executed. In a further embodiment, the processor, in particular the function processor device, and/or the control input signal processing processor and/or the input signal processing processor and/or the update or reconfiguration data generation processor and/or the activation processor of the function processor device, are provided as an addition or additional function or method to the firmware or operating system of a processing element that already exists in the respective application as corresponding computer-readable instructions. Such computer-readable instructions may be stored in memory associated with or integrated with the processing element. The processing element can load the computer-readable instructions from memory and execute them.

For example, the function processor device and/or the control input signal processing processor and/or the input signal processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device can be designed as a physical processor.

Additionally or alternatively, the processor, in particular the

Output data processing processor and/or the control data processing processor and/or the function data processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device, are provided as a dedicated processing element, e.g. B. a processing unit, a microcontroller, an FPGA, a CPLD or similar. The processor, in particular the output data processing processor and/or the control data processing processor and/or the function data processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device, can also be provided, at least in part, as a computer program product that contains computer-readable instructions that are processed by a processing element can be executed. In a further embodiment, the processor, in particular the

Output data processing processor and/or the control data processing processor and/or the function data processing processor and/or the update or reconfiguration data generation processor and/or the control processor of the function processor device, are provided as an addition or additional function or method to the firmware or the operating system of a processing element that is already in the respective application is available as appropriate computer-readable instructions. Such computer-readable instructions may be stored in memory associated with or integrated with the processing element. The processing element can load the computer-readable instructions from memory and execute them.

In addition, any required supporting or additional hardware can be provided, such as: B. a power supply circuit and a clock generation circuit.

In the context of the present invention, the term access server preferably refers to a server which can be controlled via a network, in particular the Internet or an intranet, by means of digital signals or by means of which data exchange can be effected via the network, the data exchange being based on the exchange of digital signals based.

The analog signals of the content part representation type preferably represent content of the source data and are particularly preferably generated by the output data generation processor. The multiplicity of different analog signals of the content part representation type preferably has at least four different analog signals of the content part representation type and preferably thirty-two different analog signals of the content part representation type and particularly preferably at least one hundred and twenty-eight different analog signals of the content part representation type and most preferably at least or up to two hundred fifty-six or five hundred twelve or one thousand twenty-four different analog signals of the content part representation type. The output data generation processor preferably has at least one signal output for generating the multiplicity of different analog signals of the content part representation type, wherein the signal output can preferably be subjected to a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current are preferably individual analog signals or modulated multiple signals. The output data generation processor preferably has a large number of independently controllable signal outputs for generating the large number of different analog signals of the content part representation type, wherein at least several signal outputs can each be supplied with a large number of different combinations of voltage and current intensity by the output data generation processor. A large number of different combinations of voltage and current preferably has at least four combinations per signal output and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty-eight different combinations and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different combinations. Preferably, at least several of the signal outputs that can be controlled independently of one another can be controlled simultaneously to generate one signal each, or at least several of the signal outputs that can be controlled independently of one another can preferably be controlled simultaneously to generate a modulated signal.

The analog signals of the configuration bit part combination representation type preferably represent configuration bit part combinations and are particularly preferably generated by the configuration output data processing processor.

The plurality of different analog signals of the configuration bit part combination representation type preferably has at least four different analog signals of the configuration bit part combination representation type and preferably thirty-two different analog signals of the configuration bit part combination representation type and particularly preferably at least one hundred and twenty eight different analog signals of the configuration bit part combination representation type and most preferably at least or up to two hundred fifty-six or five hundred twelve or one thousand twenty four different analog signals of the configuration bit part combination representation type. The configuration output data processing processor preferably has at least one signal output for generating the multiplicity of different analog signals of the configuration bit part combination representation type, wherein the signal output can preferably be supplied with a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current are preferably individual analog signals or modulated multiple signals. The configuration output data processing processor preferably has a multiplicity of independently controllable signal outputs for generating the multiplicity of different analog signals of the configuration bit part combination representation type, with at least several signal outputs from the configuration output data processing processor each having a multiplicity different combinations of voltage and current can be applied. A large number of different combinations of voltage and current preferably has at least four combinations per signal output and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty-eight different combinations and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different combinations. Preferably, at least several of the signal outputs that can be controlled independently of one another can be controlled simultaneously to generate one signal each, or at least several of the signal outputs that can be controlled independently of one another can preferably be controlled simultaneously to generate a modulated signal.

The analog signals of the bit-part combination representation type preferably represent bit-part combinations and are particularly preferably generated by the output data processing processor.

The multiplicity of different analog signals of the bit-part combination representation type preferably has at least four different analog signals of the bit-part combination representation type and preferably thirty-two different analog signals of the bit-part combination representation type and particularly preferably at least one hundred and twenty-eight different analog signals of the bit-part combination representation type and most preferably at least or up to two hundred fifty-six or five hundred twelve or one thousand twenty-four different analog signals of the Request part combination representation type. The output data processing processor preferably has at least one signal output for generating the multiplicity of different analog signals of the bit part combination representation type, wherein the signal output can preferably be supplied with a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current are preferably individual analog signals or modulated multiple signals. The output data processing processor preferably has a large number of independently controllable signal outputs for generating the large number of different analog signals of the bit part combination representation type, wherein at least several signal outputs can each be supplied with a large number of different combinations of voltage and current intensity by the output data processing processor. A large number of different combinations of voltage and current preferably has at least four combinations per signal output and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty-eight different combinations and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different combinations. Preferably, at least several of the signal outputs that can be controlled independently of one another can be controlled simultaneously to generate one signal each, or at least several of the signal outputs that can be controlled independently of one another can preferably be controlled simultaneously to generate a modulated signal.

The drive representation type analog signals preferably represent digital drive data and are preferably generated by the drive data processing processor.

Preferably, the plurality of different drive representation type analog signals comprises at least four different drive representation type analog signals, and more preferably thirty-two different analog signals of the drive representation type and more preferably at least one hundred and twenty eight different analog signals of the drive representation type and most preferably at least or up to two hundred fifty six or five hundred twelve or one thousand twenty four different analog signals of the drive representation type. The control data processing processor has at least one signal output for generating the multiplicity of different analog signals of the control representative type, wherein the signal output can preferably be supplied with a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current are preferably individual analog signals or modulated multiple signals. Of the

To generate the large number of different analog signals of the control representative type, the control data processing processor preferably has a large number of signal outputs that can be controlled independently of one another, with at least several signal outputs being able to be acted upon by the control data processing processor with a large number of different combinations of voltage and current intensity. A large number of different combinations of voltage and current per signal output preferably comprises at least four combinations and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty-eight different combinations and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different combinations. Preferably, at least several of the signal outputs that can be controlled independently of one another can be controlled simultaneously to generate one signal each, or at least several of the signal outputs that can be controlled independently of one another can be controlled simultaneously to generate a modulated signal.

The analog signals of the function processing type preferably represent the control or control data for controlling the function processor device, with the analog signals of the function processing type preferably being generated by the function output signal processing processor.

The multiplicity of different analog signals of the function processing type preferably has at least four different analog signals of the function processing type and preferably thirty-two different analog signals of the function processing type and particularly preferably at least one hundred and twenty-eight different analog signals of the function processing type and most preferably at least or up to two hundred and fifty-six or five hundred twelve or one thousand twenty-four different analog signals of the function processing type. The function output signal processing processor preferably has at least one signal output for generating the multiplicity of different analog signals of the function processing type, wherein the signal output can preferably be subjected to a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current are preferably individual analog signals or modulated multiple signals. The function output signal processing processor preferably has a large number of independently controllable signal outputs for generating the large number of different analog signals of the function processing type, with at least several signal outputs from the function output signal processing processor each having a large number of different combinations of voltage and current intensity. A large number of different combinations of voltage and current strength preferably has at least four combinations per signal output and preferably thirty-two different combinations and particularly preferably at least one hundred and twenty eight different combinations and most preferably at least or up to two hundred fifty six or five hundred twelve or one thousand twenty four different combinations.

The analog signals of a bit part combination representation type and/or the analog signals of a function processing type and/or the analog signals of a control representation type preferably differ in the complexity of the respective signal and/or in the form of the respective analog signal, in particular the voltage and/or the amplitude and /or the frequency and/or length and/or power, and/or the channel or combination of channels used.

Additionally or alternatively, combinations or sequences of analog signals of the bit-part combination-representation type or a modulated analog signal of the bit-part combination-representation type are different from combinations or sequences of analog signals of the drive-representation type or of a modulated analog signal of the drive-representation type and/or of combinations or series of analog signals of the function-processing type or different from a modulated analog signal of functional processing type.

Further variants or alternatives or additions can be found in the following part of the description, which means that the present invention can also relate, for example, to a system and/or method for archiving and/or backing up data, in particular files.

The present invention can thus relate to a system and/or method for archiving and/or backing up information, in particular data, in particular a file. The method can have one or more or all of the following steps:

Providing or generating digital output data, in particular one or at least one or precisely digital file and preferably several digital files

Generating analog signals, wherein the analog signals represent the content of the digital file and/or wherein the analog signals represent a visual representation of at least part of the information represented by the digital file. The analog signals can, for example, represent control signals for controlling a display. Additionally or alternatively, the analog signals can represent one or more, in particular a multiplicity of consecutive, in particular directly consecutive, pixel arrangements.

Furthermore, the method can have the step of converting the analog signals into digital result data.

Alternatively, the system can have the steps of generating digital signals, in particular digital video data and/or digital image data, the digital video and/or image data representing the content of the digital file and/or the digital video and/or image data representing an optical reproduction represent at least part of the information represented by the digital file. The digital video and/or image data can represent control signals for driving a display, for example. Additionally or alternatively, the digital video and/or image data can represent one or more, in particular a multiplicity of consecutive, in particular directly consecutive, pixel arrangement(s). Furthermore, the method can have the step of converting the digital video and/or image data into digital result data.

The digital output data preferably represent a pixel arrangement, with the pixel arrangement preferably representing at least text and/or image and/or code information. Alternatively, the digital output data preferably represent at least text and/or image and/or code data, with the text and/or image and/or code data being able to be optically output as one or more defined pixel arrangements. For example, a pixel arrangement or several pixel arrangements are specified by text data, which are formed by zeros and ones, which e.g. represents the information content "Berlin is a city". The pixel arrangement may vary from output medium to output medium, so the text data preferably represents multiple pixel arrangements. Particularly preferably, the respective resolution is not important for the pixel arrangement. Particularly preferably, it is only important that the pixel arrangement is reproduced in such a way that the information content is retained.

A defined pixel arrangement can particularly preferably also be used as a control input for controlling the optical output device, in particular the display.

The digital output data preferably represent an e-mail file. Additionally or alternatively, the digital output data represents an image and/or text file and/or a spreadsheet file and/or an attachment file, in particular a file that is sent by email. The attachment file can be an image and/or text file and/or a spreadsheet file, for example.

The image and/or text file and/or a spreadsheet file preferably represents at least text and/or image and/or code data, the text and/or image and/or code data preferably having one or more pixel arrangements for the optical reproduction of the the information represented by the text and/or image and/or code data.

An optical output device preferably has a large number of pixels. A first part of the pixels of the output device, in particular of a display, can preferably be controlled in a first configuration depending on the pixel arrangement, and a second part of the pixels of the output device can preferably be controlled in a second configuration. It is also possible that, instead of two configurations, three or more than three configurations, in particular five or more than five configurations or ten or more than ten configurations, can be provided or set.

For example, the image and/or text file and/or a spreadsheet file has content data that can be output optically, in particular text and/or image data and/or spreadsheet data, on the one hand, and function data that can be output visually on the other. The content data preferably represent one or more pixel arrangements for optical reproduction of the information represented by the text and/or image and/or spreadsheet data. The functional data preferably represent one or more pixel arrangements for the optical reproduction of formatting properties represented by text and/or image and/or code data, in particular font size, font color, typeface, page margins, line spacing, paragraphs and/or page breaks, and/or functional context properties, in particular field relationships and/or comments and/or change properties. The content data are preferably formatted according to the function data or the properties represented by the function data have some, most or all of them. An image and/or text file and/or a spreadsheet file can preferably be output as one or at least one or exactly one defined pixel arrangement. At least part of the pixel arrangement preferably represents the content data. The at least one part and/or at least one further part of the pixel arrangement particularly preferably represents the functional data.

If the image and/or text file and/or a spreadsheet file represents X pages of content data, for example, a pixel arrangement representing the function data can be provided on another page or on one of these X pages or on some of these X pages or on each of the X pages.

For example, the pixel arrangement that represents the function data can only represent function data for a defined portion of the entire pixel arrangement, in particular a line or a paragraph or a page or a defined number of lines or a defined number of paragraphs or a defined number of pages.

Alternatively, the pixel array that represents the feature data may represent feature data for the entire pixel array.

The pixel arrangement that represents the functional data can, for example, represent a text and/or an image and/or a code, in particular a QR code or EAN code.

The system and/or method can thus comprise the generation of digital output data, the digital output data being an image and/or text file and/or a spreadsheet file and representing functional data in a form which can be displayed visually. The functional data are preferably continuously generated and/or adapted as a function of the formatting that has been carried out. Alternatively, the function data can be generated and/or adjusted when saving the image and/or text file and/or a spreadsheet file. The function data is preferably generated when it is saved for the first time and then adapted for each subsequent save (if changes have been made). Alternatively, the function data can be generated anew each time it is saved.

The present invention can thus additionally or alternatively relate to a method and/or system for generating digital output data, the digital output data being an image and/or text file and/or a spreadsheet file and representing functional data in an optically displayable form. The functional data are preferably continuously generated and/or adapted as a function of the formatting that has been carried out. Alternatively, the function data can be generated and/or adjusted when saving the image and/or text file and/or a spreadsheet file. The function data is preferably generated when it is saved for the first time and then adapted for each subsequent save (if changes have been made). Alternatively, the function data can be generated anew each time it is saved.

The system and/or the method preferably has the step of storing the digital result data.

The result data are preferably different from the initial data.

The digital output data represent at least partially and preferably mostly (quantitatively) text information and/or image information and/or code, in particular QR code or bar code. The text information and/or image information and/or code information is preferably provided or generated as digital data, in particular text data and/or image data and/or code data. It is possible that the initial data initially contain text information, in particular in the form of text data, it being possible for this text information to be converted into code, in particular QR code or bar code. In addition or as an alternative, it is possible for the output data to initially contain image information, in particular in the form of image data, with this image information being able to be converted into code, in particular QR code or barcode.

The result data are preferably prepared by means of an OCR (optical character recognition) acquisition.

The digital output data are preferably converted into a transfer format. The transfer format preferably has a plurality of pages or sections that can be displayed in succession, which define pages or sections that can be displayed in succession. The individual pages or sections can correspond to e.g. screenshots. The individual pages or sections preferably have no components or components that overlap in a defined manner. Furthermore, the individual pages or sections can contain image information which specifies arrangement commands and/or formatting commands for the text information contained in the respective section or pages. The image information, which contains the arrangement commands and/or formatting commands, can be provided, for example, as a code, in particular as a QR code or bar code. This embodiment is advantageous because long texts or e-mails that cannot be reproduced on one page can be converted in a number of steps or in a number of signal sequences, each of which represents different images. Digital image files which represent the multiple pages can then be generated from the signal sequences. For example, using OCR, the content of the text or email can then be recorded and the respective arrangement commands and/or formatting commands can be read out. A text is then preferably generated using the arrangement commands and/or formatting commands, which text corresponds to the original email or the original text.

Furthermore, the arrangement commands can also represent and/or identify fields such as recipient or sender or subject and assign them to the respective text content.

Analog signals can thus preferably be generated based on digital output data. The digital output data preferably represent text data and/or image data and/or code data, in particular a QR code or bar code.

The analog signals are represented, for example, by one or exactly one analog signal. The one or precisely one analog signal preferably represents a defined or predetermined pixel arrangement, in particular the number of pixels and the orientation of the pixels (XxY). One or exactly one analog signal is preferably configured in such a way that it contains image information with at least or exactly 19200 pixels, in particular 160 x 120 pixels, or with at least or exactly or up to 307200 pixels, in particular 640 x 480 pixels, or with at least or exactly or up to 480000 pixels, in particular 800x600 pixels, or with at least or exactly or up to 3686400 pixels, in particular 2560x1440 pixels. Such analog signals may be referred to as video graphics array signals, for example.

This embodiment is advantageous because the one or exactly one analog signal is particularly preferably configured in such a way that it contains image information with at least or up to or exactly 4147200 pixels, in particular 2880×1440 pixels, or with at least or exactly or up to 132710400 pixels, in particular 15360 x 8640 pixels.

This embodiment is advantageous for the case in which the text data and/or image data and/or code data can be represented by a pixel arrangement and the Pixel arrangement by which one or exactly one analog signal can be represented or is represented.

It is possible here for the same signals to be generated and compared with one another multiple times, in particular twice, three times or more than five times, with the signal being processed further if there is a match or a sufficient match. Preferably the same signals (or the signals relating to the same pixel arrangement) within a period of 5 minutes, preferably within a period of 60 seconds or within a period of 5 seconds or within a period of 1 second or within a period of 0.5 seconds generated.

It is possible here for the analog signals to be generated and compared with one another multiple times, in particular twice, three times or four times or more than five times, with the image information or output image information deviating at least in the case of two analog signals with regard to an image parameter. Image parameters can include, for example, brightness, contrast, sharpness, and image color. An additional or alternative image parameter can be image synchronization. Sub-result data is preferably generated for each analog signal. Particularly preferably, a plurality of sub-result data are processed or combined or connected to form image information or output image information to form result data for image information or output image information.

Sufficient agreement is preferably to be understood as a degree of agreement in which more than 60% of the signal components agree, in particular more than 70% or more or exactly 80% or more or exactly 90% or more or exactly 95% or more or exactly 99% or more or exactly 99.9% or more or exactly 99.999% of the signal components match.

Alternatively, it is also possible for result data to be generated based on the multiple generation of the same signal or the multiple generation of a signal for the same pixel arrangement, with the result data then preferably being compared with one another. The result data each represent a result data pixel arrangement. In the case of a match or a sufficient match, the result data are preferably further processed.

Sufficient agreement is preferably to be understood as a degree of agreement in which more than 60% of the result data pixel arrangement agrees, in particular more than 70% or more or exactly 80% or more or exactly 90% or more or exactly 95% or more or exactly 99% or more or exactly 99.9% or more or exactly 99.999% of the result data pixel arrangement matches.

The analog signals are represented, for example, by a number of different analog sub-signals. The partial signals are preferably generated one after the other, in particular in a defined sequence. Several partial signals are preferably generated per second, with particularly preferably exactly or more than 30 partial signals or exactly or more than 45 partial signals or exactly or more than 60 partial signals or exactly or more than 90 partial signals or exactly or more than 120 partial signals being generated per second.

The analog partial signals each preferably represent a defined or predetermined pixel arrangement, in particular the number of pixels and the orientation of the pixels (XxY). The analog partial signals are preferably configured in such a way that image information with at least or exactly 19200 pixels, in particular 160×120 pixels, or with at least or exactly or up to 307200 pixels, in particular 640×480 pixels, or with at least or exactly or up to 480000 pixels, in particular 800x600 pixels, or with at least or exactly or up to 3686400 pixels, in particular 2560x1440 pixels.

This embodiment is advantageous because the individual analog partial signals are particularly preferably configured in such a way that they contain image information with at least or up to or exactly 4147200 pixels, in particular 2880 x 1440 pixels, or with at least or exactly or up to 132710400 pixels, in particular 15360 x 8640 pixels, can represent.

The embodiment is also advantageous because pixel arrangements which have more than the number of pixels that can be represented by an analog partial signal can be converted into a transfer format or subdivided into a large number of sub-pixel arrangements, with the sub-pixel arrangements preferably being determined or specified in such a way that that preferably the entire sub-pixel arrangement can be represented by the analog partial signal.

It is possible here for the same partial signals to be generated multiple times, in particular twice, three times or more than five times, and compared with one another, with the partial signal being processed further if there is a match or a sufficient match. The same partial signals (or the partial signals relating to the same pixel arrangement, in particular the same subpixel arrangement) are preferred within a period of 5 minutes, preferably within a period of 60 seconds or within a period of 5 seconds or within a period of one second or within a period generated by 0.5 seconds.

Sufficient agreement is preferably understood to mean a degree of agreement in which more than 60% of the partial signal components agree, in particular more than 70% or more or exactly 80% or more or exactly 90% or more or exactly 95% or more or exactly 99% or more or exactly 99.9% or more or exactly 99.999% of the partial signal components match.

Alternatively, it is also possible for sub-result data to be generated based on multiple generation of the same partial signal or multiple generation of a partial signal for the same sub-pixel arrangement, with the sub-result data (regarding the same sub-pixel arrangement) then preferably being compared with one another will. The sub-result data each represent a sub-result data pixel arrangement. In the case of a match or a sufficient match, the sub-result data are preferably further processed.

It is possible here for the analog signals to be generated and compared with one another multiple times, in particular twice, three times or four times or more than five times, with the image information or output image information deviating at least in the case of two analog partial signals with regard to an image parameter. Image parameters can include, for example, brightness, contrast, sharpness, and image color. An additional or alternative image parameter can be image synchronization. Sub-result data is preferably generated for each analog signal. Particularly preferably, a plurality of sub-result data are processed or combined or connected to form image information or output image information to form result data for image information or output image information.

Sufficient agreement is preferably understood to mean a degree of agreement in which more than 60% of the sub-result data pixel arrangement agrees, in particular more than 70% or more or exactly 80% or more or exactly 90% or more or exactly 95% or more or exactly 99 % or more or exactly 99.9% or more or exactly 99.999% of the sub-result data pixel arrangement matches. The sub-result data are preferably combined to form result data. The sub-result data are preferably combined to form the result data according to predetermined criteria. The specified criteria are particularly preferably represented by one or more partial signals. In addition or as an alternative, the specified criteria are stored, in particular as a function of a category of the initial data. The specified criteria are preferably applied to the result data.

An analog interface is preferably provided, with the analog signals generated being transmitted via the analog interface before they are converted into the digital result data. There is therefore preferably a generating device for generating the analog signals and/or the analog partial signals. Furthermore, there is preferably a receiving device for receiving the analog signals and/or the analog partial signals. Particularly preferably, the generating device and the receiving device are preferably connected to one another directly, in particular directly.

Alternatively, the generating device and the receiving device can be connected to one another via a signal connection which is suitable for conducting an analog signal. Additionally or alternatively, a signal amplification device can be provided in the signal transport path between the generating device and the receiving device for amplifying the signals generated by the generating device.

For the purposes of the present invention, the analog interface can preferably be understood as the part between the generating device and the receiving device in which the generated analog signals are transmitted or routed or sent, preferably before processing, in particular conversion or processing or evaluation.

The output data is stored on a first digital storage medium and the result data is stored on a further digital storage medium, the first digital storage medium and the further digital storage medium being coupled to one another directly or indirectly exclusively via the analog interface.

A preparation and/or further processing processor unit is preferably provided on the part of the further digital storage medium, in particular an HDD or SSD or RAM. The preparation and/or further processing processor unit preferably prepares the result data, in particular as a function of the specified criteria. Additionally or alternatively, the preparation and/or further processing processor unit stores the result data in the further digital storage medium, in particular HDD or SSD, in particular in the form of one or more files. Furthermore, the processing and / or provides

Further processing processor unit the file or files with original data, in particular time, date, size, etc., and/or with content data, in particular description of the content, and/or subscriber data, in particular recipient data and/or sender data.

The present invention thus also relates, for example, to a system and/or method for digitally storing an analog copy or form of a file.

This solution is advantageous because the content of, for example, text documents or emails or image files is converted into an analog form, in particular an analog optical output format such as VGA, and this analog form is redigitized. Other non-optical information or components of the digital output file that are not output optically are therefore not re-digitized again. This means that executable malicious programs such as Eg Trojans not executable are redigitized but the optically output content of the respective file is.

For example, a message received as an email can thus be an output file within the meaning of the present invention. Due to its nature as a data unit, the email can also contain malware in addition to text data and/or image data and/or code data. According to the system and/or method according to the invention, analog signals are generated for the pixel arrangements that represent the optically outputtable text data and/or image data and/or code data, and based on these analog signals, a digital result file is generated again, which in turn is a digital representation of the represents pixel arrangement. Thus, only the text data and/or image data and/or code data represented by the pixel arrangement are transmitted, as a result of which malicious code is filtered out.

Furthermore, the present invention may relate to a system and/or method for providing a digital representation file. The representation file preferably contains a code, in particular binary code, from which a digital output file consists or which represents the digital file, in a processing format, in particular in text form or as a QR code, having at least the following steps:

Generating analog signals, the analog signals representing the binary code of the digital output file and/or representing an optical reproduction of the binary code, converting the analog signals into digital data, the digital data being stored in the form of the representation file, the digital data representing the binary code represent.

The method can preferably also have the step of processing, in particular preparing, the representation file to reconstruct the binary code or to reconstruct a form representing the binary code.

Before the step of generating the analog signals, the method can include the step of converting the code of the digital output file into an output form, in particular an output file or output stream. The output form is preferably a form suitable for optical output.

The digital data is preferably a text and/or image file or a video file or a text and/or image stream or a video stream. The content of the digital data is preferably a code that can be output optically, in particular a binary code or QR code.

Furthermore, the method can include the reconversion of the code that can be output, e.g. as a text and/or image file or a video file or a text and/or image stream or a video stream, into the form of a file.

The code can be present, for example, as a binary code or, for example, in the form of a code that differs from a binary code, in particular ASCII or QR or HEX or DEZ or EAN

This solution is advantageous because the entire code that defines a file is recorded, for example in text form or as an image or video. This text or image or video information can be converted into an analog format, in particular into an analog output format such as VGA. The analog signal can then in turn be redigitized, in particular recorded, and thus the optical image of the content or the optical reproduction of the code of the file can be stored digitally. Using OCR, this content can be processed in such a way that the file can be generated again using the extracted image information. Before the original file is created again, however, only image, text or video files are available. Furthermore, the present invention can relate to a method for providing a digital representation file, the representation file preferably holding the code, in particular the binary code, from which a digital output file consists, in a processing format, in particular in text form or as a QR code, at least having the steps:

generating analog signals, the analog signals representing the binary code of the digital output file,

converting the analog signals into digital data, the digital data being stored in the form of the representation file, the digital data representing the binary code,

Processing, in particular preparation, of the representation file for the reconstruction of the binary code.

Furthermore, the present invention can relate to a method for providing a digital representation file, the representation file preferably holding the code, in particular the binary code, from which a digital output file consists, in a processing format, in particular in text form or as a QR code, at least having the steps:

Processing, in particular preparation, of the representation file for the reconstruction of a form representing the binary code, in particular the code deviating from a binary code.

Additionally or alternatively, the method can include the step of storing the representation file. In addition or as an alternative, the method can have the step of copying the reconstructed binary code and/or transferring the reconstructed binary code to a file, in particular a further or different file.

The reconstructed binary code is preferably in a non-executable form.

The reconstructed binary code is preferably in the form of text, video and/or image

The reconstructed binary code is preferably in the form of a code that differs from a binary code, in particular ASCII or QR or HEX or DEZ or EAN, or is present as a binary code.

The method may further include the step of creating a digital file, wherein the binary code provided by the representation file is preferably used to create the digital file.

The digital output data, in particular the digital output file, has or preferably has a different file format than the representation file.

The data format of the representation file is preferably different from the data format category of the source file.

The output file is e.g. an image file, audio file, spreadsheet file, CAD file, database file, etc. The representation file is preferably a text file e.g. .doc, .docx, .pdf, .txt, etc.

However, it is also conceivable that the output file is a text file or image file and the representation file is a text file or image file.

Furthermore, the present invention may relate to a system. The system preferably has a data source for providing digital data, in particular encrypted digital data, in particular encrypted content, an analogization device for converting the digital data into analog signals and a digitization device for converting the analog signals into further digital data, in particular a representation file or multiple representation files, on.

A processing device is preferably provided for processing the further digital data, with the processing device particularly preferably having an OCR unit, with the OCR unit being able to identify preferably optical characters from the digital data.

The data source is preferably part of a computer or a server and/or the analogization device is preferably part of the computer or the server.

The digitizing device is preferably part of a further device, the further device being connected to the analogization device.

An energy supply device for operating the data source and the analogization device is preferably different from a further energy supply device by means of which the digitization device can be operated. The data source is preferably at least indirectly and preferably directly connected to the Internet. The digitization device is preferably separate from the Internet or only indirectly connected via the analogization device.

The further device preferably has a processor.

Furthermore, the present invention can relate to a vehicle which has the system according to the invention. This is advantageous because a communication device designed as a data source, in particular a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) for providing digital data, in particular encrypted digital data, in particular encrypted content, can be used to provide files, e.g. for updating the vehicle system . The vehicle preferably has an analogization device for converting the digital data into analog signals between the communication device and the processor device controlling one or more vehicle components. On the processor device side (and thus separated from the communication device by the analogization device), a digitization device for converting the analog signals into further digital data, in particular a representation file or a plurality of representation files, is preferably provided. The digitization device digitizes the signals provided by the analogization device. The processor device then uses the redigitized data or the content prepared by means of an OCR device. In both cases, there can be no executable file, which means that any malicious software that may have been injected is inactive.

The content of the file provided can preferably now be designed in such a way that only this one vehicle can interpret it. Since, for example, the file has a timestamp when it is received and the content must therefore have defined comparison information at defined points, since the content can only then be further processed by the processor unit.

Router having the system according to the present invention, wherein the router can have a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary Internet connection.

Power plant comprising the system according to the present invention, wherein the power plant, other than the vehicle, has a mobile internet connection (e.g. 3G, 4G,

5G, etc.) can also have a stationary internet connection.

Medical facility, in particular a hospital, having a system according to the present invention. The medical facility can have a mobile internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary internet connection.

Telecommunication device comprising a system according to the present invention.

The telecommunications device can have a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary Internet connection.

Financial transfer device comprising a system according to the present invention. The financial transfer device can have a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary Internet connection.

Transport system comprising a system according to the present invention. The transport system can have a mobile internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary internet connection.

Data management devices have a system according to the present invention. The data management device can have a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) and/or a stationary Internet connection. Furthermore, the present invention can relate to a system which has a processor device for operating or executing a sandbox, in particular a virtual machine, or a large number of sandboxes, in particular a large number of virtual machines, and the system has a communication device, in particular has a mobile Internet connection (e.g. 3G, 4G, 5G, etc.) and/or stationary Internet connection and/or network connection for providing digital data, in particular encrypted digital data, in particular encrypted content, with digital data, in particular one or a plurality of digital files can be fed to the processor device, wherein the digital data can be displayed and/or executed and/or simulated and/or processed by the processor device in the sandbox or virtual machine.

Analog image and/or video signals or digital image and/or video data are preferably generated in the sandbox or virtual machine, which have or represent or reproduce at least part of the content of the digital data, in particular a file.

The sandbox or virtual machine preferably has processing means, in particular control means for controlling one or more digital image output devices and/or for controlling one or more analog image output devices, in order to convert the displayed and/or executed and/or simulated and/or processed digital data into digital to convert and/or transfer and/or transform image and/or video data or analog image and/or video signals.

The digital data are preferably analyzed by the sandbox or the virtual machine or in the sandbox or the virtual machine with regard to one or more defined properties, in particular formatting and/or field links and/or table functions and/or image configurations and/or Control functions and/or authorizations and/or links etc. determined. The analysis results are particularly preferred in the form of a visual property representation, in particular formatting information and/or field linkage information and/or table function information and/or image configuration information and/or control function information and/or authorization information and/or links, in particular a code or multiple codes, in particular a QR code or several QR codes, reproduced or converted into a form that can be output optically, in particular one code or several codes, in particular one QR code or several QR codes.

It is alternatively possible that the formatting and/or field links and/or table functions and/or image configurations and/or control functions and/or authorizations and/or links are already part of the digital file in a form that can be output optically. This means that, for example, when the digital file is executed or displayed, the defined properties of the digital data, in particular of the respective digital file, can be output optically.

This is advantageous since any files can be regenerated from the digital image and/or video data or from the analog image and/or video signals. For example, the table values of table files can be recorded or taken over from the digital image and/or video data or from the analog image and/or video signals and a new table file can be filled with them. In addition, the digital image and/or video data or the analog image and/or video signals can preferably Property representation or the optically output form of the properties are evaluated or taken over and from this the respective properties are added to the table values, whereby preferably the new or a new table file can be additionally or alternatively provided with the properties or the properties can be supplemented which functionality, in particular the full functionality, of the original file represents or has, in particular without this new spreadsheet file being able to contain malicious code.

This can additionally or alternatively also be used or provided for text files, presentation files, combined text and table files, image files, appointment files, calendar files, contact files, in particular business card files, etc. Thus, for example, one or more of the following file types can be opened or executed or edited or displayed in the sandbox or the virtual machine, purely as an example.

One or at least one or exactly one sandbox or virtual machine is particularly preferably started or used or executed for a large number of email mailboxes, in particular for one mailbox or one mailbox each. A sandbox or a virtual machine is particularly preferably started or used or executed for each digital file or each email, whereby an email with one or more attachments can be regarded as a digital file in the light of the present invention as a digital file ( even if the email has 2 or more than 2 attachments). The sandbox or virtual machine is terminated or deleted or closed or shut down after the digital file has been displayed and/or executed and/or simulated and/or prepared. Sandboxes or virtual machines are therefore particularly preferably started or used or executed for several mailboxes, with the sandboxes or virtual machines being kept in a "standby" mode, especially after they have been started, until an e-mail is sent in the respective mailbox running in the sandbox or virtual machine. Additionally or alternatively, it is possible that one or one or more or the majority of the sandboxes or virtual machines leave the "standby" mode, in particular at specified or defined intervals, and the respective mailbox starts an email retrieval from a server. Leaving the "standby" mode can be done at the same time or at different times in the case of several sandboxes or virtual machines. A first number of sandboxes or virtual machines leaving the “standby” mode at the same time and further sandboxes or virtual machines leaving the “standby” mode at different points in time. Simultaneously is preferably to be understood as within 1 second. Alternatively, however, it is also possible for several mailboxes to be run in a sandbox or virtual machine. If several mailboxes are executed in a sandbox or virtual machine, mailboxes that are related to one another, in particular with regard to the same people and/or companies and/or a defined group of people, are preferably executed.

Alternatively, a sandbox or virtual machine may be launched or used or running for multiple digital files. After displaying and/or executing and/or simulating and/or rendering a digital file, the sandbox or virtual machine is used for displaying and/or executing and/or simulating and/or rendering one or more further digital files. The sandbox or a virtual machine is preferably terminated or deleted or closed or shut down after a defined number of displayed and/or executed and/or simulated and/or processed digital data (preferably measured in bytes) or digital files. Thus, according to the present invention, for example, content (eg an email) can be output in particular via an image/video interface (in particular analog interface) and the processing (in particular redigitizing) of the content information represented by the image/video signals can take place. This preferably has the effect that malicious code hidden in the digital data (email and/or files) can be filtered out.

For this purpose, the respective data, in particular a file, is preferably executed or displayed or output in a sandbox or virtual machine for generating the image/video signals. A separate sandbox or virtual machine is particularly preferably created or started or executed or operated or used for each file.

A sandbox or virtual machine is preferably assigned an unambiguously identified physical memory, in particular one or more portions of a specific physical memory, in particular an HDD or SDD hard disk. Particularly preferably, several or all of the physical memories started or used or executed for running mailboxes or virtual machines are assigned to each clearly identified physical memory, in particular one or more parts of a specific physical memory, in particular an HDD or SDD hard disk. The physical memory allocated to the sandboxes or virtual machines or the physical memory portions allocated to the sandboxes or virtual machines is preferably separated from the physical memory portions of the other sandboxes or virtual machines by at least one memory unit.

The respective sandbox or virtual machine is terminated or closed or destroyed preferably after the mailbox running in it has received or received or registered one or more defined emails. Defined emails can be, for example: email whose sender is unknown and/or html email and/or email which has an attachment, in particular an attachment with executable code and/or macro.

The respective sandbox or virtual machine is preferred after the mailbox executed in it preferably an email or exactly one email or a defined number of emails and/or a defined number of attachments, in particular of a defined type, in particular attachments with executable code and /or macro, and/or received or received or registered a defined number of emails that differ from a defined recipient list, and/or a defined number of unencrypted emails and/or a defined number of emails within a defined period of time terminated or closed or destroyed.

Preference is given to the clearly identified physical memory, in particular one or more parts of a specific physical memory, in particular an HDD or SDD hard disk, to which a terminated or closed or destroyed sandbox or virtual machine was assigned partially, in particular not completely, to a new sandbox or .assigned to a new virtual machine. Particular preference is given to the clearly identified physical memory, in particular one or more parts of a specific physical memory, in particular an HDD or SDD hard disk, to which a terminated or closed or destroyed sandbox or virtual machine was assigned at least partially to several new sandboxes or new virtual ones assigned to machines.

Furthermore, a new sandbox or virtual machine is preferably generated or started or executed for the same mailbox as a result of the arrival of an email in a mailbox executed in a sandbox or virtual machine. The computer unit for generating the sandboxes or virtual machines and for outputting the image/video signals is preferably provided or set up or installed or operated in front of one's own network or a local network. The computer unit for generating the sandboxes or virtual machines and for outputting the image/video signals can preferably be part of a local network, with incoming email messages being processed in the assigned sandbox or virtual machine before being output via a client of the local network, in particular processed and/or displayed and/or converted into image and/or video signals and/or executed.

The digital image and/or video signals preferably represent one or more screenshots, in particular of a defined area or of a number of defined areas.

CHARACTERS

1 only serves to define the terms analog signal and digital signal.

The signal shown in the left frame is an analog signal and the signal shown in the right frame is a digital signal.

An analog signal is a physical quantity that can assume continuous values over time as well as over the course of the size (amplitude).

A digital signal is a physical quantity that can only assume certain values in discrete value ranges. The values correspond to two different states.

At least the analog signals of the bit part combination representation type, the analog signals of the control representation type and the analog signals of the function processing type are to be understood as analog signals in the sense of this definition.

Fig. 2 shows an example of a system 1 according to the invention for converting digital output data 2 into analog signals 4 and for converting the analog signals 4 into digital result data 6, in particular a digital result file or digital result database entries, the digital output data 2 being a bit combination 8 of digital source data 10, in particular a digital file or a digital data stream. The system preferably comprises an output data processing processor 12 for generating a plurality of different analog signals 4 of bit part combination representation type. The bit combination 8 can be represented by a number of bit part combinations 14, with the number of bit part combinations 14 being drawn from the multiplicity of different analog signals 4 of the

Bit part combination representation type is represented, each analog signal 4 of the bit part combination representation type of the multiplicity of different analog signals 4 of the bit part combination representation type representing a defined bit part combination 16 of the plurality of bit part combinations 14, in particular directly or indirectly. The output data processing processor 12 preferably has at least one data interface 20 for receiving the digital output data 2 . Furthermore, the output data processing processor 12 preferably has at least one signal output 22 for outputting the analog signals 4 of the bit part combination representation type.

Furthermore, the system 1 also has, for example, a

input signal processing processor 24 for converting the analog signals 4 of the bit part combination representation type into the digital result data 6 . The input signal processing processor 24 preferably has at least one signal input 26 for receiving the signals transmitted via the at least one signal output 22 of the Output data processing processor 12 output analog signals 4 on. The content of the digital result data 6 is particularly preferably a result data set 32 , the result data set 32 being a digital representation of the analog signals 4 of the bit part combination representation type. The result data record 32 preferably represents at least the bit combination 8 of the digital source data 10 completely and particularly preferably has this. The bit sequences of the digital result data 6 and the digital source data 10 are different according to the invention. Bit sequence means the entire memory occupancy of the respective data.

The multiplicity of different analog signals 18 of the bit part combination representation type comprises at least four different analog signals 4 des

Please part combination representation type. However, the plurality of different analog signals 18 of the bit-part combination representation type preferably comprises at least thirty-two different analog signals of the bit-part combination representation type. The output data processing processor 12 can have at least one signal output 22 for generating the multiplicity of different analog signals 18 of the bit part combination representation type, wherein the signal output 22 can preferably be supplied with a multiplicity of different combinations of at least voltage and current intensity. The different combinations of at least voltage and current intensity can be individual analog signals 4 or multiple signals 4 modulated on. The output data processing processor 12 for generating the multiplicity of different analog signals 18 of the bit part combination representation type preferably has a multiplicity of signal outputs 22, 23 that can be controlled independently of one another, with at least several signal outputs 22, 23 being able to be supplied by the output data processing processor 12 with a multiplicity of different combinations of voltage and current intensity. A large number of different combinations of voltage and current intensity per signal output 22, 23 particularly preferably comprises at least sixteen combinations and most preferably at least thirty-two different combinations, with at least several of the independently controllable signal outputs 22, 23 preferably being controllable at the same time in order to generate an analog signal 4 each or preferably at least several of the independently controllable signal outputs 22, 23 can be controlled at the same time to generate a modulated signal 4.

The digital result data 6 preferably have a result data format and the digital source data 10 preferably have a source data format, with the source data format and the result data format particularly preferably being different.

The input signal processing processor 24 has at least one input signal processing processor output 31 for outputting a digital representation of the analog signals 34 .

The input signal processing processor 24 and the

Output data processing processor 12 are arranged on a circuit board 38. In particular, due to the space-saving arrangement, e.g

Output data processing processor 12 to input signal processing processor 24 shorter than 100cm, in particular shorter than 20cm or shorter than 50mm or shorter than 10mm and most preferably shorter than 5mm.

The reference number 37 designates an analysis processor, in which case the analysis processor could also be provided as part of a function processor device 124 . The analysis processor 37 is preferably provided for analyzing the bit combination/s contained in the result data set 32 . The analysis is particularly preferred Analysis processor 37 the bit combination/s with regard to software, in particular with regard to malware.

An example of a method according to the invention can be seen schematically in FIGS. 3a-3d.

A method is thus shown for converting digital output data 2 into analog signals 4 and for converting the analog signals 4 into digital result data 6, in particular a digital result file or digital result database entries, the digital output data 2 being a bit combination 8 of digital source data 10, in particular a digital file or a digital data stream. The method preferably has the steps: generating a large number of different analog signals 4 of the bit-part combination representation type, in particular with an output data processing processor 12, the bit combination 8 being represented by a plurality of bit-part combinations 14, the plurality of bit-part combinations 14 being derived from the large number of different analog signals 18 of the bit-part combination representation type is represented, with each analog signal 4 of the bit-part combination representative type of the multiplicity of different analog signals 18 of the bit-part combination representative type representing a defined bit-part combination 16 of the plurality of bit-part combinations 14, in particular directly or indirectly. Purely as an example, therefore, the combination of bits and pieces 14 “1011” is named in FIG. 3a, which—as with regard to FIG. 2 - is first represented by analog signals and then used to generate digital data again. The bit part combination 14 "1011" then forms the first part of the result data record 32. The method thus also has the step of converting the analog signals 4 of the bit part combination representation type into the digital result data 6, in particular with an input signal processing processor 24. The digital result data 6 contains a result data record 32, with the result data record 32 being a digital representation 34 of the analog signals 4 of the bit-part combination representation type, with the result data record 32 fully representing and preferably having at least the bit combination 8 of the digital source data 10, with bit sequences of the digital Result data 6 and the digital source data 10 are different. After all the remaining bit part combinations 14 have first been analogized and then digitized again, the result data record 32 and thus the digital result data 6 are generated.

Furthermore, it can be seen that the input signal processing processor output 31 is preferably coupled to a storage medium 36 for the digital storage of data, in particular the digital result data 6 . According to the invention, there is preferably no digital data connection between the storage medium 36 and the output data processing processor 12 for the transmission of digital output data 2 or digital source data 10.

4 shows an example of the system 1 according to the invention, according to which it is possible for a user to examine or display the file structure and/or the securely stored digital result data 6 on the storage medium. Since FIG. 4 shows only a further development of the system 1 described with reference to FIGS. 2 and 3a-d, the statements relating to FIG. 2 and/or 3a-d can be transferred to the system described with reference to FIG. 4 or the system according to FIG. 4 can therefore be supplemented and vice versa.

The storage of the digital result data and/or the management of a data structure 7 or data properties, in particular the digital result data 6, is preferably carried out by a function processor device 124. Furthermore, according to this embodiment, a

Function output signal processing processor 134 for generating a multiplicity of different analog signals 136 of the function processing type for mapping the digital result data 6 and/or the data structure 7 is provided. The multiplicity of different analog signals 136 can be generated in at least four different states. Furthermore, a

Function data processing processor 138 for generating visualization data for visualizing a function processor control visualization 142, in particular a function processor control mask. the

Function processor control visualization 142 can be generated at least in part as a function of the function processing type analog signals 4 generated by function output signal processing processor 134 . In the example shown, the function processor control visualization 142 can be displayed or generated by means of a display, in particular a touch screen 110, of a terminal device 308, 508.

In addition to the bit combination 8 of the digital source data 10 , the result data record 32 can have metadata and/or visual representative data on the content of the digital output data 2 .

The at least one input device 110 can be used to manipulate the function processor control visualization 142 . A device or system according to FIG. 6 is preferably additionally provided for this purpose.

Consequently, the present solution can also be expanded to include the aspects of the solution shown in Fig. 6, whereby a control data processing processor 112 can be provided for generating a large number of different analog signals 114 of a control representative type as a function of digital control data 102, the digital control data 102 represent a multiplicity of different input commands 108 from at least one input device 110 . The multiplicity of different input commands 108 of the digital control data 102 are represented by a number of different analog signals 4 of the control representation type, it being possible for the multiplicity of different analog signals 114 to be generated in at least four states which are different from one another. Several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type preferably represents a defined input command 108, in particular directly or indirectly. The control data processing processor 112 can have at least one data interface 116 for receiving the digital control data 102 and the control data processing processor 112 can have at least one signal output 118 for outputting the analog signals 4 of the control representation type. Furthermore, one is particularly preferred

Control input signal processing processor 120 for converting the analog signals 4 of the control representative type into the digital result control data 106 for manipulating the digital result data 6, wherein the control input signal processing processor 120 has at least one signal input 122 for receiving the analog signals 4 output via the at least one signal output 118 of the control data processing processor 112. The digital result control data 106 is preferably a digital representation 107 of the analog signals 4 of the control representation type.

Control input signal processing processor 120 is preferably coupled at least indirectly to at least one function processor device 124, with control of function processor device 124 for executing at least one defined function 126 and preferably a large number of different functions 126, 128 in Dependence of the digital result control data 106 can be effected. The function processor device 124 can be, for example, a processor unit that accesses the storage medium 36 .

The function processor control visualization 142 and the control data processing processor 112 are connected to one another at least indirectly via the data interface 116 .

The digital result control data 106 can be generated for defined analog signals 4 of the control representation type. The defined analog signals 4 of the control representation type are particularly preferably assigned to the defined function 126 or the defined functions 126, 128 of the function processor device 124 or represent them. In addition, the function processor device 124 can be used to control one or more actuators, in particular motor(s), and/or to control one or more water supply device(s) 144 and/or a factory 146, in particular for the production of chemical base materials, a refinery or waste incineration or food production or medicines -/vaccine production, or several factories and/or a medical device 148 or several medical devices and/or a communication device 150 or several communication devices and/or an energy supply device 152, in particular solar power plant, coal-fired power plant, wind power plant, gas power plant, nuclear power plant, hydroelectric power plant or tidal power plant, or several energy supply devices and/or a production device 154, in particular an industrial robot, or a plurality of production devices and/or a vehicle 156, in particular a train, ship, car, truck, airplane, gondola, bus or similar the construction machine or several vehicles.

The system or the device according to FIG

Function Processor Control Visualization 142 use or control. The digital control data 102 can be generated as a function of the manipulation of the function processor control visualization 142 .

FIG. 5 shows a further example of the system 1 described in FIG. 4, as a result of which the features described with reference to FIG. 5 can also be transferred to the invention described in FIG. 4 or therefore supplemented and vice versa.

According to this example, an optical image 7 of the content of the source data 10, in particular at least part or a section of the content of the source data 10, is also generated and made usable or provided as digital output data 2 or transmitted to the output data processing processor 12. In addition, analog signals representing the image data representing the optical image 7 are generated by the output data processing processor 12 and are translated into digital data by the input signal processing processor 24 . The digital data by which the optical image 7 is represented is preferably added to the result data record 32 or to a further result data record 32 of the digital result data 6 as content. The result data record 32 or parts of the result data record 32, in particular the optical image 7, can be displayed via the partial system (134, 136, 138, 142) already described with regard to FIG transferred information, the digital-to-analog interface 134 and the analog-to-digital interface 138 are configured accordingly.

Fig. 6 shows an example of a system 100 for converting digital control data 102 into analog signals 4 of a control representative type and for converting the analog signals 4 of the control representative type into digital result control data 106, the digital control data 102 having a plurality of different input commands 108 from at least one input device 110 represent. Within the scope of the present invention, this system can be used analogously as a supplement to other systems and devices described herein or can be supplemented or provided for. The system 100 preferably has at least: A control data processing processor 112 for generating a multiplicity of different analog signals 114 of the control representation type, the multiplicity of different input commands 108 of the digital control data 102 being represented by a plurality of different analog signals 4 of the control representation type, the multiplicity of different analog signals 114 of the control representation type can preferably be generated in at least four different states. Several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type preferably represents a defined input command 108. The control data processing processor 112 preferably has at least one data interface 116 for receiving the digital control data 102, and the control data processing processor 112 preferably has at least one signal output 118 for outputting the drive representative type analog signals 4 . Furthermore, the system 100 has a drive input signal processing processor 120 for converting the analog signals 4 of the drive representation type into the digital result drive data 106 . The control input signal processing processor 120 has at least one signal input 122 for receiving the analog signals 4 of the control representation type output via the at least one signal output 118 of the control data processing processor 112, the digital result control data 106 being a digital representation 107 of the analog signals 4 of the control representation type.

Activation input signal processing processor 120 can be coupled at least indirectly to at least one function processor device 124, with function processor device 124 being able to be activated to execute at least one defined function 126 and preferably a large number of different functions 126, 128 as a function of digital result activation data 106. The digital result control data 106 can be generated for defined analog signals 4 of the control representation type.

The defined analog signals 4 of the control representation type are assigned to the defined function 126 or the defined functions 126, 128 of the function processor device 124 or represent them.

7 shows that the system 100 prefers a

function output signal processing processor 134 for generating a plurality of different function processing type analog signals 136 for mapping the driving of the function processor device 130 . The multiplicity of different analog signals 136 can preferably be generated in at least four different states. Furthermore, a

Function data processing processor 138 for generating visualization data 140 for visualizing a function processor control visualization 142, in particular a function processor control mask. the

Function processor control visualization 142 is preferably at least partially in Can be generated as a function of the analog signals 4 of the function processing type generated by the function output signal processing processor 138 . The at least one input device 110 can particularly preferably be used to manipulate the function processor control visualization 142 . An input device 110 within the meaning of the present disclosure (ie also in relation to all other inventions disclosed herein) can be understood as a touch screen, a computer mouse, a computer keyboard, a trackpad, controllers, a voice control and/or a gesture control. The digital control data 102 can preferably be generated as a function of the manipulation of the function processor control visualization 142, with the function processor control visualization 142 and the

Control data processing processor 112 are preferably connected to one another at least indirectly and particularly preferably directly via data interface 116.

Furthermore, FIG. 7 shows, purely by way of example, that the activation 130 of the function processor device 124 can be optically output as a function processor activation visualization 142a, in particular by means of a terminal device 308, 508. Furthermore, it can be seen that using an input device 110, the function processor control visualization 142a in a

Function processor control visualization 142b can be changed, whereby changed function processor control data or changed digital control data 102 for controlling the function processor device 124 are generated. 8a then shows that the changed digital control data 102 bring about a changed control 130 of the function processor device 124. FIG. The changed control 130 is then displayed again as a function processor control visualization 142a and can then be changed again in the sequence (cf. FIGS. 8a and 8b).

Figures 9a and 9b show purely schematically that the control data processing processor 112 and the

Control input signal processing processor 120 can be assigned to different devices (see FIG. 9a) and thereby form a first and second system part 101a and 101b. For example, the first system part 101a can have a terminal 308, 508 or be formed by it. In addition, the input device 110 can be part of the system part 101a or be connected to it. The second system part 101b can, for example, have the function processor device 124 or be formed by it. In addition, a machine device 144, 146, 148, 150, 152, 154, 156 can be part of the system part 101b or be connected to it.

Alternatively, the control data processing processor 112 and the control input signal processing processor 120 can be embodied as a common device, in particular arranged or embodied or produced on a common circuit board 38 .

A combination of the system 1 and the system 100 is shown purely by way of example in FIG. 10 . Thus, the system 100 can also have or form a system 1 according to one or more of FIGS. The system 100 can thus have an output data processing processor 12 for generating a plurality of different analog signals 18 of a bit-part combination representation type, wherein a bit combination 8 of source data 10 is preferably represented by a plurality of bit-part combinations 14, the plurality of bit-part combinations 14 preferably being represented by the plurality of different analog signals of the bit-part combination representation type 18 are represented. Particularly preferably, each analog signal 4 of the bit-part combination representation type of the multiplicity of different analog signals 18 of the bit-part combination representation type represents a defined one Request part combination 16 of the several request part combinations 14. The

Output data processing processor 12 preferably has at least one data interface 20 for receiving the digital output data 2 and the

Output data processing processor 12 has at least one signal output 22 for outputting the analog signals 4 of the bit part combination representation type. Furthermore, the system 100 has an input signal processing processor 24 for converting the analog signals 4 of the bit part combination representation type into the digital result data 6, wherein the input signal processing processor 24 has at least one signal input 26 for receiving the analog signals 4 output via the at least one signal output 22 of the output data processing processor 12, wherein the digital result data 6 preferably has a result data record 32 as its content. The result data set 32 can particularly preferably be a digital representation 34 of the analog signals 4 of the bit part combination representation type. The result data set 32 then represents at least the bit combination 8 of the digital source data 10 completely or particularly preferably has it completely. Bit sequences of the digital result data 6 and the digital source data 10 are preferably different according to the invention.

The multiplicity of different analog signals 18 of the bit-part combination representation type thus preferably comprises at least four different analog signals of the bit-part combination representation type. The plurality of different analog signals 18 of the bit-part combination representation type particularly preferably comprises at least thirty-two different analog signals of the bit-part combination representation type.

The output data processing processor 12 for generating the multiplicity of different analog signals 18 of the bit part combination representation type has at least one signal output 22, wherein the signal output 22 can be supplied with a multiplicity of different combinations of at least voltage and current intensity, with the different combinations of at least voltage and current intensity preferably being analog individual signals or are modulated analog multiple signals. The output data processing processor 12 for generating the multiplicity of different analog signals 18 of the bit part combination representation type particularly preferably has a multiplicity of signal outputs 22, 23 that can be controlled independently of one another, with at least several signal outputs 22, 23 being able to be supplied by the output data processing processor 12 with a multiplicity of different combinations of voltage and current intensity, wherein a plurality of different combinations of voltage and current per signal output 22, 23 comprises at least sixteen combinations and wherein a plurality of different combinations of voltage and current per signal output 22, 23 comprises at least thirty-two different combinations. At least several of the signal outputs 22, 23 that can be controlled independently of one another can preferably be controlled simultaneously to generate one signal 4 each, or at least several of the signal outputs 22, 23 that can be controlled independently of one another can preferably be controlled simultaneously to generate a modulated signal 4. The digital result data 6 preferably have a result data format and the digital source data 10 preferably have a source data format, with the source data format and the result data format particularly preferably being different. The input signal processing processor 24 preferably has at least one input signal processing processor output 31 for outputting the digital representation 34 of the analog signals 4 . The input signal processing processor output 31 is preferably coupled to a storage medium 36 for digitally storing the digital result data 6 . According to the invention, there is preferably no digital between the storage medium 36 and the output data processing processor 12 Data connection provided for the transmission of digital output data 2 or there is no digital data connection.

The input signal processing processor 24 and the output data processing processor 12 and/or the driving data processing processor 112 and the driving input signal processing processor 120 and/or the function output signal processing processor 134 and the

Functional data processing processors 138 are preferably arranged or formed or provided or produced on a circuit board 38 .

It applies to all embodiments and inventions of the present disclosure that the output data processing processor 12 and the control data processing processor 112 and/or the function data processing processor 138 can be formed by a single processor or a single processor device. Additionally or alternatively, the input signal processing processor 24 and the control input signal processing processor 120 and/or the function output signal processing processor 134 can be formed by a single processor or a single processor device.

The path 5 of the analog signals 4 of the bit part combination representation type from the output data processing processor 12 to the input signal processing processor 24 is preferably shorter than 100 cm, in particular shorter than 20 cm or preferably shorter than 50 mm or particularly preferably shorter than 10 mm or most preferably shorter than 5 mm.

In general terms, Figures 6 to 9 thus describe at least one method for converting digital control data 102 into analog signals 4 of a control representative type and for converting analog signals 4 of the control representative type into digital result control data 106, the digital control data 102 containing a large number of different input commands 108 from represent at least one input device 110. The method preferably has at least the following steps: Generating a large number of different analog signals 4 of the control representation type, in particular with a control data processing processor 12, the large number of different input commands 108 of the digital control data 102 being represented by a number of different analog signals 4 of the control representation type, wherein the multiplicity of different analog signals 114 of the control representation type are generated in at least four different states, with several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type representing a defined input command 108, in particular directly or indirectly, and converting the analog signals 4 of the drive representation type into the digital result drive data 106, in particular with a drive input signal processing processor 120, wherein the digital result driving data 106 is a digital representation 107 of the analog signals 4 of the driving representation type. Furthermore, the method can have the step of activating at least one defined function 126 and preferably a large number of different functions 128 as a function of the digital result activation data 106 . The digital result control data 106 are preferably generated for defined analog signals 4 of the control representation type. The defined analog signals 4 of the control representation type are assigned to the defined function 126 or the defined functions 126, 128 of the function processor device 124 or represent them.

The object represented by FIG. 10 can also be used as a passivation system 200 for converting digital output data 2 into digital result data 6, the digital Result data 6 representing the digital output data 2 in a non-executable state, and for manipulating the digital result data 6 in the non-executable state, the digital output data 2 representing a bit combination 8 of digital source data 10, in particular a digital file or a digital data stream. The passivation system 200 preferably has: An output data processing processor 12 for generating a large number of different analog signals 18 of a bit part combination representation type, the bit combination 8 being represented by a plurality of bit part combinations 14, the plurality of bit part combinations 14 being represented by the large number of different analog signals 18 of the bit part combination representation type , wherein each analog signal 4 of the bit-part combination representative type of the multiplicity of different analog signals 18 of the bit-part combination representative type represents a defined bit-part combination 16 of the plurality of bit-part combinations 14, in particular directly or indirectly, wherein the output data processing processor 12 has at least one data interface 20 for receiving the digital output data 2, wherein the Output data processing processor 12 has at least one signal output 22 for outputting the analog signals 4 d it has a bit-part combination representation type, an input signal processing processor 24 for converting the analog signals 4 of the bit-part combination representation type into the digital result data 6, wherein the input signal processing processor 24 has at least one signal input 26 for receiving the analog signals 4 of the bit-part combination representation type output via the at least one signal output 22 of the output data processing processor 12, wherein the digital result data 6 contain a result data record 32, with the result data record 32 being a digital representation 34 of the analog signals 4 of the bit part combination representation type, with the result data record 32 fully representing and preferably having at least the bit combination 8 of the digital source data 10, with bit sequences of the digital result data 6 and the digital source data 10 are different, a control data processing processor 112 for generating a plurality of subs Various analog signals 114 of a control representation type as a function of digital control data 102, the digital control data 102 representing a large number of different input commands 108 from at least one input device 110, the large number of different input commands 108 of the digital control data 102 being represented by a number of different analog signals 4 of the control representation type where the multiplicity of different analog signals 114 of the control representation type can be generated in at least four mutually different states, with several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type representing a defined input command 108, in particular directly or indirectly, wherein the control data processing processor 112 has at least one data interface 116 for receiving the digital control data 102, with de r control data processing processor 112 has at least one signal output 118 for outputting the analog signals 4 of the control representation type, a control input signal processing processor 120 for converting the analog signals 4 of the control representation type into the digital result control data 106 for manipulating the digital result data 6, the

Control input signal processing processor 120 has at least one signal input 122 for receiving the analog signals 4 of the control representation type output via the at least one signal output 118 of the control data processing processor 112, wherein the digital result control data 106 has a digital representation 107 of at least part of the analog signals 4 of the control representation type, the control input signal processing processor 120 being coupled at least indirectly to a function processor device 124 for executing or effecting at least one function 126 and preferably a plurality of functions 126, 128.

The activation of the function processor device 124 for executing at least one defined function 126 and preferably a multiplicity of different functions 126, 128 can preferably be brought about as a function of the digital result activation data 106.

The digital result control data 106 can preferably be generated for defined analog signals 4 of the control representation type. The defined analog signals 4 of the control representation type are preferably assigned to the defined function 126 or the defined functions 126, 128 of the function processor device 124 or represent them.

Furthermore, a function output signal processing processor 134 for generating a multiplicity of different analog signals 136 of the function processing type for mapping the control of the function processor device 124 can be provided. The multiplicity of different analog signals 136 can preferably be generated in at least four different states. A function data processing processor 138 for generating visualization data for visualizing a function processor control visualization 142, in particular a function processor control mask, is preferably provided. The function processor control visualization 142 can preferably be generated as a function processor control mask. the

Function processor control visualization 142 can preferably be generated at least partially as a function of the analog signals 4 of the function processing type generated by the function output signal processing processor 134 . A manipulation of the function processor control visualization 142 can preferably be brought about by the at least one input device 110a and preferably by a plurality of input devices 110a and 110b. The digital control data 102 can preferably be generated as a function of the manipulation of the function processor control visualization 142 . The function processor control visualization 142 and the

Activation data processing processors 112 are preferably connected to one another at least indirectly via data interface 116.

The defined analog signals 4 of the control representation type are preferably assigned to the digital result control data 106 via an assignment unit 190, in particular an assignment list or assignment table. Of the

Functional data processing processor 138 is preferably part of system 100 for converting digital drive data 102 into analog signals 4 of a drive representation type and for converting analog signals 4 of drive representation type into digital result drive data 106 or more preferably is part of access system 304. Of the

Functional output signal processing processor 138 is preferably a part of the system 100 for converting digital drive data 102 into analog signals 4 of a drive representation type and for converting the analog signals 4 of the drive representation type into digital result drive data 106 or more preferably is part of the data and/or program system 306. For analog signals 4 of the control representation type, to which no digital result control data 106 is assigned, preferably no result control data 106 can be generated or exclusion result data can be generated, with the exclusion result data being a Represent documentation of the signal transmission event, in particular with information on the analog signals 4 of the control representative type.

In general, Fig. 10 thus describes various aspects and features and functions and components of an example of a method for converting digital output data 2 into digital result data 6, the digital result data 6 representing the digital output data 2 in a non-executable state, and for manipulating the digital result data 6 in the non-executable state, the digital output data 2 representing a bit combination 8 of digital source data 10, in particular a digital file or a digital data stream. The method preferably has at least the following steps: Generating a multiplicity of different analog signals 18 of a bit part combination representation type, in particular with a

Output data processing processor 12, the bit combination 8 being represented by a plurality of bit-part combinations 14, the plurality of bit-part combinations 14 being represented by the multiplicity of different analog signals 18 of the bit-part combination representation type, with each analog signal 4 of the bit-part combination representation type of the multiplicity of different analog signals 14 of the bit-part combination representation type having a defined bit-part combination 16 of the multiple bit-part combinations 14, in particular directly or indirectly, and converting the analog signals 4 of the bit-part combination representation type into the digital result data 6, in particular with an input signal processing processor 24, the digital result data 6 having a result data record 32 as its content, the result data record 32 being a digital Representation 34 of the analog signals 4 of the bit part combination representation type, the result data set 32 at least the Bit combination 8 of the digital source data 10 is fully represented and preferably has, with bit sequences of the digital result data 6 and the digital source data 109 being different, and generating a large number of different analog signals 114 of a control representation type as a function of digital control data 2, in particular with a control data processing processor 112, wherein the digital control data 2 represent a multiplicity of different input commands 108 from at least one input device 110, the multiplicity of different input commands 108 of the digital control data 2 being represented by a plurality of different analog signals 4 of the control representation type, the multiplicity of different analog signals 114 of the control representation type in at least four different states are generated, with several or each analog signal 4 of the control representative type of the plurality of different a Analog signals 114 of the control representation type represent a defined input command 108, in particular directly or indirectly, and converting the analog signals 4 of the control representation type into the digital result control data 106 for manipulating the result data 6, in particular with a control input signal processing processor 120, the digital result control data 106 being a digital representation 107 of at least some of the analog signals 2 are of the control representative type, and control of at least the defined function 126 and preferably the large number of different functions 126, 128 as a function of the digital result control data 106, the defined function 106 at least or precisely manipulating the result data 6 includes.

The digital control result data 106 can preferably be generated for defined analog signals 4 of the control representative type. The defined analog signals 4 of the control representation type are preferably assigned to the defined function 126 or the defined functions 126, 128 or represent them.

Furthermore, the method can additionally or alternatively also include the step of generating a large number of different analog signals 136 of a function processing type for mapping the actuation of the defined function 126, with the multiplicity of different analog signals 116 of the function processing type being generated in at least four different states, and the step of generating visualization data 140 for visualizing a function processor actuation visualization 142, in particular a function processor actuation mask, with the

Function processor control visualization 142 is generated at least partially as a function of the generated analog signals 4 of the function processing type, with a manipulation of the function processor control visualization 142 being effected by the at least one input device 110, with the digital control data being generated as a function of the manipulation of the function processor control visualization 142.

Fig. 11 describes a system 300. This system preferably has at least one access system 304 connected to a network 302, in particular the Internet, in particular an access server, and at least one data and/or program system 306, in particular a data and/or program server , Wherein the data and/or programming system 306 particularly preferably has no data connection for exchanging digital signals with the access system 302. Furthermore, the system 300 has a system 100 for converting digital control data 102 into analog signals 4 of a control representative type and for converting the analog signals 4 of the control representative type into digital result control data 106, the digital control data 102 having a large number of different input commands 108 from at least one input device 110, in particular an input device 110 of a terminal 308. Alternatively, the system 300 may only include the components of the system 100. Furthermore, the system 300 preferably has a control data processing processor 112 for generating a large number of different analog signals 4 of a control representation type, the large number of different input commands 108 of the digital control data 102 being represented by a number of different analog signals 4 of the control representation type, the large number of different analog signals 114 of the control representation type can be generated in at least four mutually different states, with several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type representing a defined input command 108, in particular directly or indirectly. Control data processing processor 112 preferably has at least one data interface 116 for receiving digital control data 102, control data processing processor 112 having at least one signal output 118 for outputting analog signals 4 of the control representative type. Furthermore, the system 300 has a control input signal processing processor 120 for converting the analog signals 4 of the control representation type into the digital result control data 106, wherein the control input signal processing processor 120 has at least one signal input 122 for receiving the signals of the control representation type output via the at least one signal output 118 of the control data processing processor 112, wherein the digital result control data 106 is particularly preferably a digital representation 107 of the analog signals 4 of the control representation type. The data and/or program system 306 and the access system 304 are preferably coupled to one another via the system 100 for converting digital control data 102 into analog signals 4 of a control representation type and for converting the analog signals 4 of the control representation type into digital result control data 106, with the access system 304 via the network 302, in particular the Internet, with the end device 308, in particular mobile phones, laptops, desktop computers, tablet PCs and/or IoT devices, such as refrigerators, barriers, household appliances, motor vehicles, or infrastructure facilities such as traffic lights, locks, signal boxes or lighting, in particular street lighting, a data exchange can be effected. The digital control data 102 can be transmitted from the access system 304 to the control data processing processor 112, preferably depending on the data exchange with the terminal 308, the digital result control data 106 being receivable from the data and/or program system 306, with one

Function processor device 124 of the data and/or programming system 306 at least one defined function 126 and preferably a large number of different functions 126, 128 can be effected or executed as a function of the digital result control data 106.

Functional output signal processing processor 138 is preferably a part of the system 100 for converting digital drive data 102 into analog signals 4 of a drive representation type and for converting the analog signals 4 of the drive representation type into digital result drive data 106 or more preferably is part of the data and/or program system 306. For analog signals 4 of the control representation type, to which no digital result control data 106 is assigned, preferably no result control data 106 can be generated or exclusion result data can be generated, with the exclusion result data documenting the signal transmission event, in particular with information about the analog signals 4 of the drive representation type. Furthermore, an update or reconfiguration unit can be provided for converting digital configuration output data into update or reconfiguration data, the digital configuration output data representing a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream, the update or reconfiguration unit at least has: A configuration output data processing processor for generating a large number of different analog signals of a configuration bit part combination representation type, the configuration bit combination of the digital configuration data being represented by a plurality of configuration bit part combinations, the configuration bit combination preferably being the content of the digital configuration output data, with the multiple configuration bit-part combinations from the plurality of different analog signals of the configuration ration bit part combination representation type is represented, the plurality of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the plurality of different analog signals of the configuration bit part combination representation type a defined configuration bit part combination of the plurality of configuration bit part combinations, in particular directly or indirectly, wherein the configuration output data processing processor has at least one data interface for receiving the digital configuration output data, wherein the configuration output data processing processor has at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration input signal processing processor for converting the analog Configuration Request Signals combination representation type into digital configuration result data, the configuration input signal processing processor having at least one signal input for receiving the analog signals of the configuration bit part combination representation type output via the at least one signal output of the configuration output data processing processor, update or reconfiguration data for updating or Reconfiguring the function processor device can be generated. Furthermore, an update or reconfiguration data generation processor can be provided, wherein the update or reconfiguration data generation processor can convert configuration bit part combinations of the digital result data into a predetermined order by means of allocation data for generating the update or reconfiguration data. The assignment data is preferably provided in a data store that can be accessed by the update or reconfiguration data generation processor. A large number of assignment data can be provided, with a mechanism for selecting the assignment data preferably being stored. The mechanism is preferably designed to bring about the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

In general, FIG. 11 thus relates to a method for controlling a data and/or program system 306, the data and/or program system 306 particularly preferably not being connected to an access system 304 via a data connection for exchanging digital signals. The method preferably has the steps: generating a large number of different analog signals 102 of a control representation type, in particular with a control data processing processor 112, the large number of different input commands 108 of the digital control data 102 being represented by a number of different analog signals 4 of the control representation type, the large number of different analog signals 114 of the driving representative type are generated in at least four mutually different states, with a plurality or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type represents a defined input command 108, in particular directly or indirectly, and converting the analog signals 4 of the control representation type into digital result control data 106, in particular with a control input signal processing processor 120, the digital result control data 106 are a digital representation 107 of the analog signals 4 of the control representation type, from the access system 304 via the network 302, in particular the Internet, to the end device, in particular mobile phones, laptops, desktop computers, tablet PCs and/or IoT devices such as refrigerators, barriers, household appliances , Motor vehicles, or infrastructure facilities such as traffic lights, locks, signal boxes or lighting, in particular street lighting, a data exchange is effected, with the access system 304 depending on the data n exchange with the terminal 308, the digital control data 102 for generating the multiplicity of different analog signals 114 of the control representative type are transmitted, the digital result control data 106 being received by the data and/or program system 306, a function processor device 124 of the data and/or Prague ramm system 306 causes or executes at least one defined function 126 and preferably a large number of different functions 126, 128 as a function of the digital result control data 106.

Fig. 12 shows an example of a machine system 400 according to the invention. The machine system 400 preferably has at least one machine device 144, 146, 148, 150, 152, 154, 156 controlled by a function processor device 124, with the function processor device 124 preferably being part of the machine device 144, 146, 148, 150, 152, 154, 156. Machine system 400 also preferably has a system 100 for converting digital control data 102 into analog signals 4 of a control representative type and for converting analog signals 4 of the control representative type into digital result control data 106, with digital control data 102 having a large number of different input commands 108 from at least one Input device 110, in particular an input device 110 of a terminal 308 represent. The system 100 preferably has: A control data processing processor 112 for generating a large number of different analog signals 4 of the control representation type, the large number of different input commands 108 of the digital control data 102 being represented by a plurality of different analog signals 4 of the control representation type, the large number of different analog signals 114 of the control representative type can be generated in at least four different states, with several or each analog signal 4 of the control representative type of the large number of different analog signals 114 of the control representative type representing a defined input command 108, in particular directly or indirectly, with the control data processing processor 112 having at least one data interface 116 for reception of the digital control data 102, wherein the control data processing processor 112 has at least one signal output 11 8 for outputting the analog signals 4 of the control representation type, a control input signal processing processor 120 for converting the analog signals 4 of the control representation type into the digital result control data 106, the control input signal processing processor 120 having at least one signal input 122 for receiving the analog signals output via the at least one signal output 118 of the control data processing processor 120 Signals 4 of the control representation type, the digital result control data 106 being a digital representation 107 of the analog signals 4 of the control representation type, with an input data interface, in particular an input device 110, of the System 100 for converting digital control data 102 into analog signals 4 of a control representative type and for converting analog signals 4 of the control representative type into digital result control data 106 and preferably a large number of different functions 126, 128 of the machine device 144, 146, 148, 150, 152, 154, 156 can be brought about or executed or controlled or triggered or deactivated or activated depending on the digital result control data 106.

Functional output signal processing processor 138 is preferably a part of the system 100 for converting digital drive data 102 into analog signals 4 of a drive representation type and for converting the analog signals 4 of the drive representation type into digital result drive data 106 or more preferably is part of the data and/or program system 306. For analog signals 4 of the control representation type, to which no digital result control data 106 is assigned, preferably no result control data 106 can be generated or exclusion result data can be generated, with the exclusion result data being a Represent documentation of the signal transmission event, in particular with information on the analog signals 4 of the control representative type. Furthermore, an update or reconfiguration unit can be provided for converting digital configuration output data into update or reconfiguration data, the digital configuration output data representing a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream, the update or reconfiguration unit at least has: A configuration output data processing processor for generating a large number of different analog signals of a configuration bit part combination representation type, the configuration bit combination of the digital configuration data being represented by a plurality of configuration bit part combinations, the configuration bit combination preferably being the content of the digital configuration output data, with the multiple configuration bit-part combinations from the plurality of different analog signals of the configuration ration bit part combination representation type is represented, the plurality of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the plurality of different analog signals of the configuration bit part combination representation type a defined configuration bit part combination of the plurality of configuration bit part combinations, in particular directly or indirectly, wherein the configuration output data processing processor has at least one data interface for receiving the digital configuration output data, wherein the configuration output data processing processor has at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration input signal processing processor for converting the analog Configuration Request Signals combination representation type into digital configuration result data, the configuration input signal processing processor having at least one signal input for receiving the analog signals of the configuration bit part combination representation type output via the at least one signal output of the configuration output data processing processor, update or reconfiguration data for updating or Reconfiguring the function processor device can be generated. Furthermore, an update or reconfiguration data generation processor can be provided, wherein the update or reconfiguration data generation processor can convert configuration bit part combinations of the digital result data into a predetermined order by means of allocation data for generating the update or reconfiguration data. The assignment data is preferably provided in a data store that can be accessed by the update or reconfiguration data generation processor. A large number of assignment data can be provided, with a mechanism for selecting the assignment data preferably being stored. The mechanism is preferably designed to bring about the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

The input data interface is preferably an input device, a computer or an access system, in particular an access server. The machine device is a motor vehicle, in particular in a car, truck, airplane or boat, a multi-axis robot, a production plant or a printing shop.

The function processor device 124 can be configured, for example, to control a machine device, in particular one or more actuators, in particular motor(s), and/or to control one or more water supply device(s) 144. Additionally or alternatively, the machine facility can be a factory 146, in particular for the production of chemical raw materials, refinery or waste incineration or food production or drug/vaccine production, or several factories and/or a medical device 148 or several medical devices and/or a communication device 150 or several communication devices and/or an energy supply device 152, in particular a solar power plant, Coal power plant, wind power plant, gas power plant, nuclear power plant, hydroelectric power plant or tidal power plant, or multiple energy supply facilities and/or a production device 154, in particular an industrial robot, or multiple production devices and/or a vehicle 156, in particular a train, ship, car, truck, airplane, gondola, Bus or construction machine or several vehicles. Alternatively, the function processor device 124 can also be part of the respective machine device.

Fig. 12 thus generally describes a method according to the invention for controlling a machine system 400. The method preferably has at least the following steps: Generating a large number of different analog signals 4 of a control representation type, with a large number of different input commands 108 digital control data 102 being replaced by a number of different analog signals 4 of the control representation type are represented, with the multiplicity of different analog signals 114 of the control representation type being generated in at least four different states, with several or each analog signal 4 of the control representation type of the multiplicity of different analog signals 114 of the control representation type receiving a defined input command 108, in particular directly or indirectly , represents, converting the drive representation type analog signals 4 into the digital result drive data 106, wherein the digital result drive data 106 en 106 are a digital representation 107 of the analog signals 4 of the control representation type, with the digital control data 102 for generating the large number of different analog signals 114 of the control representation type being transmitted or supplied or generated via an input data interface, in particular the input device 110, with machine equipment 144 , 146, 148, 150, 152, 154, 156 the digital result control data are preferably received, with a function processor device 124 of the machine device 144, 146, 148, 150, 152, 154, 156 at least one defined function 126 and preferably a large number of different functions 126, 128 depending on the digital result control data 106 is effected or executed or controlled or triggered or deactivated or activated.

13a schematically shows the state of the art with regard to the transmission of malicious code by email.

13b schematically shows an example of a computer unit according to the invention.

The computer unit according to the invention preferably has at least one processor and a physical data memory (in particular HDD or SDD). The processor preferably executes a large number of sandboxes or virtual machines, in particular preferably one sandbox or virtual machine for each mailbox. With regard to incoming HTML emails or text emails or file attachments (e.g. .doc, .txt, .docx, .pdf, etc.) in the mailboxes, image/video signals (preferably analogue) or image/video data (digital) are preferably generated ( marked as "optical detection" in the illustration). The generated image/video signals (preferably analog) or image/video data (digital) are then processed using OCR processing, in particular the image content represented by the image/video signals (preferably analog) or image/video data (digital), in particular text , extracted or recorded or made manageable. The extracted or recorded or manageable text can be stored in a file or as a file. Additionally or alternatively, format data can be recorded and saved using OCR processing. Format data are particularly preferably stored together with the extracted or recorded text or made manageable, in particular stored in a file or as a file. The extraction or recording or making it manageable and/or storing is preferably effected by means of a further processor device, which is characterized by “translation and storage”.

The image content represented by the image/video signals (preferably analog) or image/video data (digital), in particular text, can preferably be displayed to a user, in particular in a local network, via a client or a preview of the “translation and storage" generated file can be optically output or displayed to the user via the client. Additionally or alternatively, the user can be shown or output a notification about the receipt or the extraction or recording or making manageable and/or saving of an e-mail or file attachment.

Particularly preferably, as a result of the displayed image content or the displayed preview or the output or displayed message, the user can call up the original message and/or cause the extracted or recorded or made manageable file to be saved and/or transmit the saved file (the previously extracted or recorded or made manageable data) in the local network and / or to the client.

Figures 14 to 17b show different examples and characteristics of an email transmission system 500. The email system 500 has at least: an email data interface 501, the email data interface 501 being designed at least for receiving email data 509, and a system 560 for converting digital email output data 502 into analog signals 4 and for converting the analog signals 4 into digital email result data 506, in particular a digital result file or digital result database entries, with the digital email output data 502 representing at least an optically mappable part 511 of a content of digital source data 510, with the digital Source data 510 represent or form the e-mail data 509, in particular e-mail text data and/or e-mail image data and/or e-mail attachment data, with the system for converting the digital e-mail output data 502 into the analog signals 4 and for converting the analog signals 4 into the dig Italian email result data 506 has at least: An email output data processing processor 512 for generating a multiplicity of different analog signals 4 of the content part representation type, with content part representation data 521 being represented by the multiplicity of different analog signals 514 of the content part representation type, with the content part representation data 521 having at least one optically mappable part 511 of the content of the digital source data 510, the email

Output data processing processor 512 has at least one signal output 522 for outputting the analog signals 4 of the content representation type, an e-mail input signal processing processor 524 for converting the analog signals 4 of the content part representation type into the digital e-mail result data 506, the e-mail input signal processing processor 524 having at least one signal input 526 for receiving the signals of the partial content representation type output via the at least one signal output 522 of the email output data processing processor 512, the digital email result data 506 containing an email result data record 532, the email result data record 532 being a digital representation 534 of the analog signals 4 of the partial content representation type , wherein the e-mail result data set 532 represents at least an optically mappable part 511 of the content of the digital source data 510 and preferably has an e-mail output data generation proc essor 550, whereby the email Output data generation processor 550, the email data 509 received via the email data interface 501 can be converted into the digital email output data 502.

Bit sequences of the digital email result data 506 and the digital source data 510 are preferably different according to the invention.

The partial content representation data 521 preferably each represent a one-dimensional or two-dimensional pixel arrangement of at least part of the content of the source data 510 or the entire source data 510. The digital email output data can preferably be divided into a plurality of partial image data 515, with at least some of the partial image data 515 each having a pixel area of at least 640x480 pixels and preferably at least 1280 ^c 720 pixels or more preferably at least 1920 ^c 1080 pixels, wherein the respective partial image data 515 are represented by content part representation data, wherein the content part representation data 521 are represented by the plurality of different analog signals 514 of the content part representation type. The email output data generation processor 550 is preferably configured to generate the content part representation data 521 .

The e-mail output data generation processor 550 is particularly preferably configured to generate the partial content representation data 521 in the form of at least one optical partial image, in particular the multiple partial image data 515, of the opened and/or executed e-mail data 509.

A plurality of content part representation data 521 can preferably be generated, should a plurality of content part representation data 521 be required for the complete representation of the optically mappable part 511 of the content of the digital source data 510 . The e-mail output data processing processor 550 preferably has at least one data interface 520 for receiving the digital e-mail output data 502. The e-mail output data generation processor 550 is preferably configured to analyze the digital e-mail output data 502 for one or more defined properties.

The email output data processing processor 550 is preferably configured to generate an optical property representation 580 for an analysis result regarding the one or more defined properties.

The email raw data generation processor 550 is preferably configured to launch and/or use and/or run multiple sandboxes 590 .

The email output data generation processor 550 can preferably start and/or use and/or execute at least one sandbox 590 for different email data.

The sandbox 590 can preferably be terminated or deleted or closed or shut down after the email data has been displayed and/or executed and/or simulated and/or prepared by the email output data generation processor 550 .

The e-mail output data generation processor 550 is preferably configured such that it starts and/or uses and/or executes at least one sandbox 590 for a plurality of e-mail mailboxes.

The sandboxes 590 can preferably be kept in a “standby” mode until email data reaches the email mailbox executed in the respective sandbox.

The email output data generation processor 550 is preferably configured such that one or one or more or the plurality of the sandboxes 590 are defined in FIG Leave the “standby” mode at intervals and the respective mailbox starts an email retrieval via the email data interface 501 from an email server 595.

The e-mail output data generation processor 550 is preferably configured such that each sandbox 590 can be assigned a uniquely identified physical memory, in particular one or more portions of a specific physical memory 536, in particular an HDD or SDD hard disk.

The email output data generation processor 550 is preferably configured to assign the physical memory to the sandboxes 590 in such a way that the physical memory portions of the physical memory 536 assigned to the respective sandboxes 590 are each separated from one another by at least one physical memory unit and preferably a plurality of physical memory units.

The email output data generation processor 550 is preferably configured so that the uniquely identified physical memory, in particular one or more parts of a specific physical memory 536, in particular an HDD or SDD hard disk, to which a terminated or closed or destroyed sandbox 590 was assigned partially, in particular not completely, at least one new sandbox 590 and preferably several new sandboxes 590 can be assigned.

At least part of the email result data record 532 can preferably be made available by the email input signal processing processor 524 or by a function processor device 525 for optical output to a terminal device 508.

The terminal 508 is preferably configured to provide the email data 509 based on the part of the email result data record 532 provided, in particular to transmit the email data 509 to the terminal 532, with the email data 509 being obtainable from the email server 595 and/or with the email data 509 can be obtained from the storage medium 536 or server system 536.

Additionally or alternatively, the system 500 can have a system 1 for converting digital output data 2 into analog signals 4 and for converting the analog signals 4 into digital result data 6, in particular a digital result file or digital result database entries, the digital output data 2 having a bit combination of 8 represent digital email attachment data 10, wherein the system 1 for converting digital output data 2 into analog signals 4 and for converting the analog signals 4 into digital result data 6 has at least: An output data processing processor 12 for generating a large number of different analog signals 4 of a bit part combination representation type, wherein the Bit combination 8 is represented by a plurality of bit part combinations 14, with the plurality of bit part combinations 14 being represented by the plurality of different analog signals 18 of the bit part combination representation type, with each analog signal 4 of the bi part combination representation type of the large number of different analog signals 18 of the bit part combination representation type represents a defined bit part combination 16 of the plurality of bit part combinations 14, in particular directly or indirectly, with the output data processing processor 12 having at least one data interface 20 for receiving the digital output data 2, with the output data processing processor 12 having at least one signal output 22 for outputs the analog signals 4 of the bit-part combination representation type, an input signal processing processor 24 for converting the analog signals 4 of the bit-part combination representation type into the digital result data 6, the input signal processing processor 24 having at least one signal input 26 for receiving the signals via the at least one signal output 22 of the output data processing processor 12, the digital result data 6 containing a result data set 32, the result data set 32 being a digital representation 34 of the analog signals 4 of the bit part combination representation type, the result data set 32 representing at least the bit combination 8 of the digital email attachment data 10 in full and preferably having bit sequences of the digital result data 6 and the digital email attachment data 10 being different.

In general, Figures 14 to 17b describe an email processing method that has at least the following steps: receiving email data 509, in particular via an email data interface 501, generating a large number of different analog signals 4 of a content part representation type, whereby from the large number of different analog signals 4 of the content part representation type content part representation data 521 are represented, wherein the content partial representation data 521 represents at least one optically reproducible part 511 of a content of digital source data 510, wherein the digital source data 510 represents the e-mail data 509, in particular e-mail text data and/or e-mail image data and/or e-mail attachment data, or is formed by the e-mail data 509 , converting the analog signals 4 of the content part representation type into digital e-mail result data 506, the digital e-mail result data 506 having an e-mail result data record 532 as content n, wherein the e-mail result data record 532 is a digital representation 534 of the analog signals 4 of the content part representation type, wherein the e-mail result data record 532 represents and preferably has at least one optically mappable part 511 of the content of the digital source data 510 and storing the e-mail result data 506.

For example, FIG. 14 shows the handling of a short email, which in this case has no attachment. The digital output data 502 represent the email text ("Dear Lisa..."), the email text is assigned, e.g. pixel by pixel, to analog signals and the analog signals are then converted into digital result data 506 according to the stored assignment, which represent the pixel arrangement of the original email .

15 shows that the digital result data 506 can be further processed. In the example shown, there is an OCR unit 570 for converting the digital result data 506 generated as a digital image 569 of the email into characters 571 that can be researched and/or manipulated and/or marked, in particular text.

FIG. 16 shows an example of how very long text in an email can be processed by breaking it down into partial image data 515 . Furthermore, it can be seen from this representation that properties of the e-mail data, in particular the e-mail text data and/or the e-mail attachment data, can be generated in the form of machine-readable codes 580 . Even malicious code represented by the code 580 cannot cause any damage on the part of the storage medium 36, 536, since a defined number or defined functions or a range of functions is preferably specified that can be executed at all as a result of instructions. Furthermore, due to the digital-analog-digital barrier on the part of the storage medium 36, 536, malware cannot reload any further malware.

17a and 17b show schematically that the content of the email file attachment can be opened in a sandbox 590, for example, in order to generate an image or screenshot of it. The image or screenshot can then be converted and transmitted via the digital-analog-digital interface (512, 524). Any malicious code contained in the digital output data initially representing the image or screenshot is thereby "filtered out". The entire email attachment file can also be transmitted via a system 1 (according to FIGS. 2 to 5) for converting digital output data into analog signals and for converting the analog signals into digital result data. In FIG. 17a, the image or screenshot and the transmitted email file are each stored as digital result data. In Fig. 17b, the image or the screenshot and the transmitted email file are added to common digital result data, in particular as the content of a result data record 32 or several result data records 32.

Reference List

1 System for converting 28 variety of different digital output data into receivable analog signals analog signals and for converting the analog signals bit part combination representation type into digital result data

30 mapping unit for mapping the

2 digital output data received analog signals to defined bit part combinations

4 analog signals

31 data output or

5 signal path input signal processing process

6 digital result data sensor output

7 Data structure / data properties 32 Result data set

8 bit combination 34 digital representation of analog

signals

9 image / screenshot

36 storage medium, in particular

10 source data disk

12 output 37 analysis processor data processing processor

38 circuit board

14 multiple bit part combinations

16 defined bit part combination

100 system for converting

17 Entirety of the digital control data in analog bit combinations signals of a

18 variety of different analog driving representative type and signals of converting the analog signals

Bit part combination representation type of driving representation type into digital result driving data

19 assignment unit for assigning defined bit part combinations to 101a first system part defined analog signals 101b second system part

20 data interface for receiving 102 digital control data of the digital output data

106 digital result control data

22 signal output for outputting the analog signals 107 digital representation of the analog signals of the

23 further potential outputs for control representation type Output of further analog signals 108 input command

24 input signal 110 input device processing processor

112 control data

26 signal input processing processor

27 further potential inputs for receiving 114 a large number of different analog signals of the control representation type Variety of different analog signals that can be received 154 production device

156 drive representative type vehicle

180 allocation unit for allocation data interface of the digital signal output result control data the defined analog signals of the further potential signal outputs control representation type control input 190 allocation unit for allocation signal processing processor of the defined analog signals signal input of the control representation type the digital result control data further potential signal inputs function processor device

200 passivation system defined function potential further function

300 system, in particular server control of the client system

Function processor device or activation processor of the 302 network Function processor device 304 Access system Signal path 306 Data and/or program system Function output 308 Terminal signal processing processor Numerous different analog signals of the 400 machine system

Function processing type variety of different

500 e-mail transmission system of receivable analog signals of the function processing type 501 e-mail data interface function data 502 digital e-mail output data processing processor

506 digital email result data way

508 terminal visualization data

509 email data function processor control visualization 509a attachment data water supply device 510 digital source data factory 511 optically imageable part medical device 512 email output data processing processor communication device

514 of the plurality of different power supply means of content part representation type analog signals Subimage data analog signals and for converting the analog signals

Data interface into digital email result data

Content parts representative data 566 content analyzable digital email

Signal output result data

Signal input 569 image of the email, purely digital image of the pixels

Email input signal processing processor 570 OCR unit for handling the in the digital result data

Function processor device contained characters

E-mail result record 571 characters of the e-mail manageable digital partial representation made digital representation 580 optical

property representation,

Storage medium or, in particular, machine-readable server system or server code, such as GR code

Email outbound 590 sandbox or virtual machine generation processor

595 email servers

System for converting digital email source data into

Claims

Expectations

1. E-mail transmission system (500), having at least one e-mail data interface (501), wherein the e-mail data interface (501) is designed at least to receive e-mail data (509), a system (560) for converting digital e-mail output data (502) into analog signals (4) and for converting the analog signals (4) into digital email result data (506), in particular a digital result file or digital

Result database entries, the digital email source data (502) representing at least one optically mappable part (511) of a content of digital source data (510), the digital source data (510) being the email data (509), in particular email text data and/or email image data and/or E-mail attachment data, representing or forming, the system for converting the digital e-mail output data (502) into the analog signals (4) and for converting the analog signals (4) into the digital e-mail result data (506) having at least one e-mail output data processing processor (512) for generating a multiplicity of different analog signals (4) of the content part representation type, wherein content part representation data (521) are represented from the multiplicity of different analog signals (514) of the content part representation type, the content part representation data (521) having at least one optically imageable part (511) of the content of the digital source data (510) representi eren, wherein the e-mail output data processing processor (512) has at least one signal output (522) for outputting the analog signals (4) of the content representation type, an e-mail input signal processing processor (524) for converting the analog signals (4) of the content part representation type into the digital e-mail Result data (506), the e-mail input signal processing processor (524) having at least one signal input (526) for receiving the signals of the content part representation type output via the at least one signal output (522) of the e-mail output data processing processor (512), the digital e-mail result data ( 506) have an e-mail result data record (532) as its content, the e-mail result data record (532) being a digital representation (534) of the analog signals (4) of the content part representation type, the e-mail result data record (532) having at least one optically mappable part (511) of the content of the digital source data (510) represents and bev preferably has an e-mail output data generation processor (550), the e-mail output data generation processor (550) being able to convert the e-mail data (509) received via the e-mail data interface (501) into the digital e-mail output data (502).

2. E-mail transmission system according to claim 1, characterized in that

Bit sequences of the digital email result data (506) and the digital source data (510) are different.

3. E-mail transmission system according to claim 2, characterized in that the content part representation data (521) each represent a one-dimensional or two-dimensional pixel arrangement of at least part of the content of the source data (510).

4. E-mail transmission system according to Claim 3, characterized in that the digital e-mail output data can be divided into a plurality of partial image data (515), with at least some of the partial image data (515) each having a pixel area of at least ^640x480 pixels and preferably of at least 1280 x 720 pixels or of more preferably at least 1920 ^c represent 1080 pixels, the respective partial image data (515) being represented by content part representation data, the content part representation data (521) being represented by the plurality of different analog signals (514) of the content part representation type.

5. E-mail delivery system according to claim 4, characterized in that the e-mail output data generation processor (550) is configured to generate the content part representation data (521).

6. E-mail transmission system according to Claim 5, characterized in that the e-mail output data generation processor (550) for generating the partial content representation data (521) in the form of at least one optical partial image, in particular at least one of the plurality of partial image data (515), of the opened and/or executed e-mail data (509) is configured.

7. E-mail transmission system according to claim 5 or 6, characterized in that several content part representation data (521) can be generated, should several content part representation data (521) be required for the complete representation of the optically mappable part (511) of the content of the digital source data (510).

8. Email transmission system according to one of claims 5 to 7, characterized in that the e-mail output data processing processor (550) has at least one data interface (520) for receiving the digital e-mail output data (502).

9. E-mail transmission system according to one of claims 5 to 8, characterized in that the e-mail output data generation processor (550) is configured to analyze the digital e-mail output data (502) with regard to one or more defined properties.

10. E-mail transmission system according to claim 9, characterized in that the e-mail output data processing processor (550) is configured to generate an optical property representation (580) for an analysis result with regard to the one or more defined properties.

11. E-mail transmission system according to one of claims 5 to 10, characterized in that the e-mail output data generation processor (550) is configured to start and/or use and/or run a plurality of sandboxes (590).

12. E-mail transmission system according to claim 11, characterized in that at least one sandbox (590) can be started and/or used and/or executed by the e-mail output data generation processor (550) for different e-mail data.

13. Email transmission system according to claim 12, characterized in that the sandbox (590) can be terminated or deleted or closed or shut down after the email data has been displayed and/or executed and/or simulated and/or prepared by the email output data generation processor (550).

14. E-mail transmission system according to one of claims 11 to 13, characterized in that the e-mail output data generation processor (550) is configured to start and/or use and/or execute at least one sandbox (590) for a plurality of e-mail mailboxes.

15. E-mail transmission system according to claim 14, characterized in that the sandboxes (590) are kept in a "standby" mode until e-mail data reach the e-mail mailbox executed in the respective sandbox.

16. E-mail transmission system according to claim 15, characterized in that the e-mail output data generation processor (550) is configured so that one or one or more or the majority of the sandboxes (590) leave the "standby" mode at defined intervals and the respective mailbox requests an e-mail via the e-mail data interface (501) from an e-mail server ( 595) starts.

17. E-mail transmission system according to one of claims 11 to 16, characterized in that the e-mail output data generation processor (550) is configured such that each sandbox (590) has a clearly identified physical memory, in particular one or more portions of a specific physical memory (536), in particular an HDD or SDD hard disk, can be assigned.

18. E-mail transmission system according to claim 17, characterized in that the e-mail output data generation processor (550) is configured to allocate the physical memory to the sandboxes (590) in such a way that the physical memory portions of the physical memory ( 536) are each separated from one another by at least one physical storage unit and preferably by a plurality of physical storage units.

19. E-mail transmission system according to one of claims 17 or 18, characterized in that the e-mail output data generation processor (550) is configured such that the clearly identified physical memory, in particular one or more parts of a specific physical memory (536), in particular an HDD or SDD Hard disk to which a finished or closed or destroyed sandbox (590) was assigned partially, in particular not completely, can be assigned to at least one new sandbox (590) and preferably to several new sandboxes (590).

20. E-mail transmission system according to one of Claims 5 to 19, characterized in that at least part of the e-mail result data record (532) can be made available by the e-mail input signal processing processor (524) or by a function processor device (525) for optical output to a terminal device (508). .

21. E-mail transmission system according to claim 20, characterized in that the terminal (508) is configured to provide the e-mail data (509), in particular the e-mail data (509) to the terminal (532) to transmit, wherein the e-mail data (509) can be obtained from the e-mail server (595) and/or wherein the e-mail data (509) can be obtained from the storage medium (536) or server system (536).

22. Email transmission system according to one of claims 5 to 19, characterized in that a system (1) for converting digital output data (2) into analog signals (4) and for converting the analog signals (4) into digital result data (6), in particular a digital result file or digital result database entries, the digital output data (2) representing a bit combination (8) of digital email attachment data (10), the system (1) for converting digital output data (2) into analog signals (4) and for converting the analog signals (4) into digital result data (6) at least has: an output data processing processor (12) for generating a multiplicity of different analog signals (4) of a bit-part combination representation type, the bit combination (8) being represented by a plurality of bit-part combinations (14). is, wherein the multiple bit part combinations (14) from the large number of different analog signals (18) of the B it part combination representation type, each analog signal (4) of the bit part combination representation type of the multiplicity of different analog signals (18) of the bit part combination representation type representing a defined bit part combination (16) of the several bit part combinations (14), in particular directly or indirectly, with the output data processing processor (12) at least has a data interface (20) for receiving the digital output data (2), the output data processing processor (12) having at least one signal output (22) for outputting the analog signals (4) of the bit part combination representation type, an input signal processing processor (24) for converting the analog signals ( 4) of the bit part combination representation type in the digital result data (6), the input signal processing processor (24) having at least one signal input (26) for receiving the at least one signal output (22) of the output data processor has analog signals (4) output by the processing processor (12), the digital result data (6) containing a result data set (32), the result data set (32) being a digital representation (34) of the analog signals (4) of the bit part combination representation type, wherein the result data set (32) fully represents and preferably has at least the bit combination (8) of the digital email attachment data (10), bit sequences of the digital result data (6) and the digital email attachment data (10) being different.

23. Email processing method, at least comprising the steps

Receiving email data (509), in particular via an email data interface (501),

Generating a multiplicity of different analog signals (4) of a content part representation type, wherein content part representation data (521) are represented by the multiplicity of different analog signals (4) of the content part representation type, wherein the content part representation data (521) contains at least one optically reproducible part (511) of a content of digital represent source data (510), the digital source data (510) representing the email data (509), in particular email text data and/or email image data and/or email attachment data, or being formed by the email data (509),

Converting the analog signals (4) of the content part representation type into digital e-mail result data (506), the digital e-mail result data (506) containing an e-mail result data record (532), the e-mail result data record (532) having a digital representation ( 534) of the analog signals (4) of the content part representation type, the email result data record (532) representing and preferably having at least one optically mappable part (511) of the content of the digital source data (510).

Saving the email result data (506).

24. System (1) for converting digital output data (2) into analog signals (4) and for converting the analog signals (4) into digital result data (6), in particular a digital result file or digital result database entries, the digital output data (2 ) represent a bit combination (8) of digital source data (10), in particular a digital file or a digital data stream, having an output data processing processor (12) for generating a large number of different analog signals (4) of a bit part combination representation type, the bit combination (8) being represented by a plurality of Bit part combinations (14) is represented, wherein the plurality of bit part combinations (14) is represented by the plurality of different analog signals (4) of the bit part combination representation type, each analog signal (4) of the bit part combination representation type of the plurality of different analog signals (4) of the bit part combination representation type being one defined bit part combination (16) of the several bit part combinations (14), in particular directly or indirectly, with the output data processing processor (12) having at least one data interface (20) for receiving the digital output data (2), with the output data processing processor (12) having at least one signal output (22) for outputting the analog signals (4) of the bit part combination representation type, an input signal processing processor (24) for converting the analog signals (4) of the bit part combination representation type into the digital result data (6), the input signal processing processor (24) having at least one signal input (26) for receiving the analog signals (4) output via the at least one signal output (22) of the output data processing processor (12), the digital result data (6) containing a result data record (32), the result data record (32) being a digital representation of the anal ogen signals (4) of the bit part combination representation type, the result data set (32) representing at least the bit combination (8) of the digital source data (10) in full and preferably having it, bit sequences of the digital result data (6) and the digital source data (10) being different .

The system of claim 24, characterized in that the plurality of different analog signals (18) of the bit-part combination representation type comprises at least four different analog signals (4) of the bit-part combination representation type.

The system of claim 25, characterized in that said plurality of different bit-part combination representation type analog signals (18) comprises at least thirty-two different bit-part combination representation type analog signals.

27. System according to claim 26, characterized in that the output data processing processor (12) for generating the multiplicity of different analog signals (18) of the bit part combination representation type has at least one signal output (22), the signal output (22) having a multiplicity of different combinations of at least Voltage and current can be applied.

28. System according to claim 27, characterized in that the different combinations of at least voltage and current are analogue individual signals (4) or modulated multiple signals (4).

29. System according to claim 26, characterized in that the output data processing processor (12) for generating the multiplicity of different analog signals (18) of the bit part combination representation type has a multiplicity of independently controllable signal outputs (22, 23), with at least several signal outputs (22, 23) can each be subjected to a large number of different combinations of voltage and current intensity by the output data processing processor (12).

30. System according to claim 29, characterized in that a large number of different combinations of voltage and current per signal output (22, 23) comprises at least sixteen combinations.

31. System according to claim 30, characterized in that a large number of different combinations of voltage and current per signal output (22, 23) comprises at least thirty-two different combinations.

32. System according to claim 30 or 31, characterized in that at least several of the signal outputs (22, 23) that can be controlled independently of one another can be controlled simultaneously to generate one analog signal (4) each, or at least several of the signal outputs (22, 23 ) can be controlled at the same time as generating a modulated signal (4).

33. System according to one of claims 27 to 32, characterized in that the digital result data (6) have a result data format and the digital source data (10) have a source data format, the source data format and the result data format being different.

34. System according to any one of claims 27 to 33, characterized in that the input signal processing processor (24) has at least one input signal processing processor output (31) for outputting a digital representation of the analog signals (34).

35. System according to claim 34, characterized in that the input signal processing processor output (31) is coupled to a storage medium (36) for the digital storage of data, in particular the digital result data (6).

36. System according to claim 35, characterized in that there is preferably no digital data connection between the storage medium (36) and the output data processing processor (12) for the transmission of digital output data (2) or digital source data (10).

37. System according to any one of claims 27 to 36, characterized in that the input signal processing processor (24) and the output data processing processor (12) are arranged on a circuit board.

38. System according to claim 37, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 100 cm.

39. System according to claim 38, characterized in that the path (5) of the analogue signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 20 cm.

40. System according to claim 39, characterized in that the path (5) of the analogue signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 50 mm.

41. System according to claim 40, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 10 mm.

42. System according to claim 41, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 5 mm.

43. System according to any of claims 35 to 42, characterized in that a drive data processing processor (112) for generating a plurality of different analog signals (114) of a drive representation type in dependence of digital control data (102) is provided, the digital control data (102) representing a large number of different input commands (108) from at least one input device (110), the large number of different input commands (108) of the digital control data (102) being represented by a number of different analog signals (4) of the control representation type are represented, wherein the multiplicity of different analog signals (114) can be generated in at least four mutually different states, wherein several or each analog signal (4) of the control representation type of the multiplicity of different analog signals (114) of the control representation type one defined input command (108), in particular directly or indirectly, with the control data processing processor (112) having at least one data interface (116) for receiving the digital control data (102), with the control data processing processor (112) having at least one signal has a signal output (118) for outputting the analog signals (4) of the control representation type, and a control input signal processing processor (120) for converting the analog signals (4) of the control representation type into the digital result control data (106) for manipulating the digital result data (6), wherein the control input signal processing processor (120) has at least one signal input (122) for receiving the analog signals (4) output via the at least one signal output (118) of the control data processing processor (112), the digital control result data (106) having a digital representation (107) of the analog signals (4) of the driving representative type.

44. System according to claim 43, characterized in that the control input signal processing processor (120) is at least indirectly coupled to at least one function processor device (124), the control of the function processor device (124) for executing at least one defined function (126) and preferably a large number different functions (126, 128) depending on the digital result control data (106) can be effected.

45. System according to one of claims 43 or 44, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

46. System according to claim 45, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (126, 128) of the function processor device (124) or represent them.

47. System according to one of claims 44 to 46, characterized in that a function output signal processing processor (134) is provided for generating a multiplicity of different analog signals (136) of the function processing type for mapping the activation of the function processor device (124).

48. System according to claim 47, characterized in that the plurality of different analog signals (136) can be generated in at least four different states.

49. System according to one of Claims 47 or 48, characterized in that a function data processing processor (124) is provided for generating visualization data for visualizing a function processor control visualization (142), in particular a function processor control mask.

50. System according to claim 49, characterized in that the function processor control visualization (142) can be generated at least partially as a function of the analog signals (4) of the function processing type generated by the function output signal processing processor (134).

51. System according to claim 50, characterized in that the function processor control visualization (142) can be manipulated by the at least one input device (110).

52. System according to claim 51, characterized in that the digital control data (102) can be generated as a function of the manipulation of the function processor control visualization (142).

53. System according to claim 52, characterized in that the function processor control visualization (142) and the

Control data processing processor (112) are connected to one another at least indirectly via the data interface (116).

54. System according to any one of claims 44 to 53, characterized in that the function processor device (124) for activating one or more actuators, in particular motor(s), and/or for activating one or more water supply device(s) (144) and/or a factory (146), in particular for the production of chemical base materials, a refinery or waste incineration or food production or drug/vaccine production, or several factories and/or a medical device (148) or several medical devices and/or a communication device (150) or several communication devices and/or an energy supply device (152), in particular solar power plant, coal power plant, wind power plant, gas power plant , nuclear power plant, hydroelectric power plant or tidal power plant, or several energy supply facilities and/or a production device (154), in particular an industrial robot, or several production devices and/or a vehicle (156), in particular a train, ship, car, truck, airplane, gondola, bus O the construction machine or several vehicles.

55. System according to any one of claims 43 to 54, characterized in that the result data record (32) has metadata and/or visual representative data on the content of the digital output data (2) in addition to the bit combination (8) of the digital source data (10).

56. A method for converting digital output data (2) into analog signals (4) and for converting the analog signals (4) into digital result data (6), in particular a digital result file or digital

Result database entries, the digital output data representing a bit combination (8) of digital source data (10), in particular a digital file or a digital data stream, having the steps

Generating a multiplicity of different analog signals (4) of the bit-part combination representation type, in particular with an output data processing processor (12), the bit combination (8) being represented by a plurality of bit-part combinations (14), the several bit-part combinations (14) being derived from the multiplicity of different analog signals ( 18) of the bit-part combination representation type is represented, with each analog signal (4) of the bit-part combination representation type of the multiplicity of different analog signals (18) of the bit-part combination representation type representing a defined bit-part combination (16) of the plurality of bit-part combinations (14), in particular directly or indirectly,

Converting the analog signals (4) of the bit part combination representation type into the digital result data (6), in particular with an input signal processing processor (24), the digital result data (6) containing a result data set (32), wherein the result data set (32) is a digital representation (34) of the analog signals (4) of the bit part combination representation type, wherein the result data set (32) fully represents and preferably has at least the bit combination (8) of the digital source data (10), bit sequences of the digital Result data (6) and the digital source data (10) are different.

57. System (100) for converting digital drive data (102) into analog signals (4) of a drive representative type and for converting the analog signals (4) of the drive representative type into digital result drive data (106), the digital drive data (102) having a plurality of different input commands (108) from at least one input device (110), having a control data processing processor (112) for generating a multiplicity of different analog signals (114) of the control representation type, the multiplicity of different input commands (108) of the digital control data (102) being represented by a plurality different analog signals (4) of the control representation type are represented, the multiplicity of different analog signals (114) of the control representation type being able to be generated in at least four different states, with several or each analog signal (4) of the control representation type of the multiplicity of different from analog signals (114) of the control representation type, represents a defined input command (108), in particular directly or indirectly, the control data processing processor (112) having at least one data interface (116) for receiving the digital control data (102), the control data processing processor (112) has at least one signal output (118) for outputting the analog signals (4) of the control representation type, a control input signal processing processor (120) for converting the analog signals (4) of the control representation type into the digital result control data (106), the control input signal processing processor (120) having at least one signal input (122) for receiving the analog signals (4) of the control representation type output via the at least one signal output (118) of the control data processing processor (112), the digital result control data (106) having a digital representation (107) of the an alogen signals (4) is of the driving representative type.

58. System according to claim 57, characterized in that the control input signal processing processor (120) is coupled at least indirectly to at least one function processor device (124), wherein the function processor device (124) can be activated to execute at least one defined function (126) and preferably a large number of different functions (126, 128) as a function of the digital result activation data (106).

59. System according to one of claims 57 or 58, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

60. System according to claim 59, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (126, 128) of the function processor device (124) or represent them.

61. System according to one of Claims 58 to 60, characterized in that a function output signal processing processor (134) is provided for generating a multiplicity of different analog signals (136) of the function processing type for mapping the activation of the function processor device (130).

62. System according to claim 61, characterized in that the plurality of different analog signals (136) can be generated in at least four different states.

63. System according to one of Claims 61 or 62, characterized in that a function data processing processor (138) is provided for generating visualization data (140) for visualizing a function processor control visualization (142), in particular a function processor control mask.

64. System according to claim 63, characterized in that the function processor control visualization (142) can be generated at least partially as a function of the analog signals (4) of the function processing type generated by the function output signal processing processor (138).

65. System according to claim 64, characterized in that the function processor control visualization (142) can be manipulated by the at least one input device (110).

66. System according to claim 65, characterized in that the digital control data (102) can be generated depending on the manipulation of the function processor control visualization (142).

67. System according to claim 66, characterized in that the function processor control visualization (142) and the

68. System according to one of Claims 65 to 67, characterized in that an output data processing processor (12) is provided for generating a large number of different analog signals (18) of a bit-part combination representation type, with a bit combination (8) of source data (10) being replaced by a plurality of bit-part combinations (14) is represented, wherein the plurality of bit-part combinations (14) is represented by the plurality of different analog signals of the bit-part combination representation type (18), each analog signal (4) of the bit-part combination representation type of the plurality of different analog signals (18) of the bit-part combination representation type having a defined bit-part combination ( 16) of the plurality of bit part combinations (14), in particular directly represented, the output data processing processor (12) having at least one data interface (20) for receiving the digital output data (2), the output data processing processor (12) mi at least one signal output (22) for outputting the analog signals (4) of the bit part combination representation type, and an input signal processing processor (24) for converting the analog signals (4) of the bit part combination representation type into the digital result data (6), the input signal processing processor (24) has at least one signal input (26) for receiving the analog signals (4) output via the at least one signal output (22) of the output data processing processor (12), the digital result data (6) containing a result data record (32), the result data record ( 32) is a digital representation (34) of the analog signals (4) of the bit part combination representation type, the result data set (32) fully representing and preferably having at least the bit combination (8) of the digital source data (10), bit sequences of the digital result data (6) and the digital source data (10) are different are.

The system of claim 68, characterized in that the plurality of different bit-part combination representation type analog signals (18) comprises at least four different bit-part combination representation type analog signals.

The system of claim 69, characterized in that the plurality of different bit-part combination representation-type analog signals (18) comprises at least thirty-two different bit-part combination representation-type analog signals.

71. System according to claim 69 or claim 70, characterized in that the output data processing processor (12) for generating the multiplicity of different analog signals (18) of the bit part combination representation type has at least one signal output (22), the signal output (22) having a multiplicity of different combinations from at least voltage and current can be acted upon.

72. System according to claim 71, characterized in that the different combinations of at least voltage and current are analog individual signals or modulated multiple signals.

73. System according to claim 70, characterized in that the output data processing processor (12) for generating the multiplicity of different analog signals (18) of the bit part combination representation type has a multiplicity of independently controllable signal outputs (22, 23), with at least several signal outputs (22, 23) can each be subjected to a large number of different combinations of voltage and current intensity by the output data processing processor (12).

74. System according to claim 73, characterized in that a large number of different combinations of voltage and current intensity per signal output (22, 23) comprises at least sixteen combinations.

75. System according to claim 74, characterized in that a large number of different combinations of voltage and current per signal output (22, 23) comprises at least thirty-two different combinations.

76. System according to claim 74 or 75, characterized in that at least several of the independently controllable signal outputs (22, 23) can be controlled simultaneously to generate one signal (4) each, or at least several of the independently controllable signal outputs (22, 23) can be controlled simultaneously to generate a modulated signal (4).

77. System according to one of claims 71 to 76, characterized in that the digital result data (6) have a result data format and the digital source data (10) have a source data format, the source data format and the result data format being different.

78. System according to any one of claims 71 to 77, characterized in that the input signal processing processor (24) has at least one input signal processing processor output (31) for outputting the digital representation (34) of the analog signals (4).

79. System according to claim 78, characterized in that the input signal processing processor output (31) is coupled to a storage medium (36) for digitally storing the digital result data (6).

80. System according to claim 79, characterized in that there is preferably no digital data connection between the storage medium (36) and the output data processing processor (12) for the transmission of digital output data (2).

81. System according to any one of claims 71 to 80, characterized in that the input signal processing processor (24) and the

Output data processing processor (12) and/or the control data processing processor (112) and the control input signal processing processor (120) and/or the function output signal processing processor (134) and the function data processing processor (138) are arranged on a circuit board (38).

82. System according to claim 81, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 100 cm.

83. System according to claim 82, characterized in that the path (5) of the analogue signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 20 cm.

84. System according to claim 83, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 50 mm.

85. System according to claim 84, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 10 mm.

86. System according to claim 85, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 5 mm.

87. A method for converting digital control data (102) into analog signals (4) of a control representation type and for converting the analog signals (4) of the control representation type into digital result control data (106), the digital control data (102) having a plurality of different input commands ( 108) represent at least one input device (110), at least comprising the steps

Generating a large number of different analog signals (4) of the control representation type, in particular with a control data processing processor (12), the large number of different input commands (108) of the digital control data (102) being represented by a number of different analog signals (4) of the control representation type, the A large number of different analog signals (114) of the control representation type are generated in at least four different states, with several or each analog signal (4) of the control representation type of the large number of different analog signals (114) of the control representation type sending a defined input command (108), in particular directly or indirectly , represents,

Converting the analog signals (4) of the control representation type into the digital result control data (106), in particular with a control input signal processing processor (120), the digital result control data (106) being a digital representation (107) of the analog signals (4) of the control representation type.

88. The method according to claim 87, characterized by the step:

Activation of at least one defined function (126) and preferably a multiplicity of different functions (128) as a function of the digital result activation data (106).

89. The method as claimed in claim 88, characterized in that the digital result control data (106) are generated for defined analog signals (4) of the control representation type.

90. The method according to claim 89, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (126, 128) of the function processor device (124) or represent them.

91. Passivation system (200) for converting digital output data (2) into digital result data (6), the digital result data (6) representing the digital output data (2) in a non-executable state, and for manipulating the digital result data (6) in the non-executable state, the digital output data (2) representing a bit combination (8) of digital source data (10), in particular a digital file or a digital data stream, having an output data processing processor (12) for generating a large number of different analog signals (18) a bit-part combination representation type, wherein the bit combination (8) is represented by a plurality of bit-part combinations (14), the plurality of bit-part combinations (14) being represented by the plurality of different analog signals (18) of the bit-part combination representation type, each analog signal (4) of the bit-part combination representation type of the plurality difference Licher analog signals (18) of the bit part combination representation type represent a defined bit part combination (16) of the plurality of bit part combinations (14), in particular directly or indirectly, wherein the output data processing processor (12) has at least one data interface (20) for receiving the digital output data (2), wherein the output data processing processor (12) has at least one signal output (22) for outputting the analog signals (4) of the bit-part combination representation type, an input signal processing processor (24) for converting the analog signals (4) of the bit-part combination representation type into the digital result data (6), wherein the input signal processing processor (24) has at least one signal input (26) for receiving the analog signals (4) of the bit part combination representation type output via the at least one signal output (22) of the output data processing processor (12), the digital result data (6) having a result data record (32) content, the result data set (32) being a digital representation (34) of the analog signals (4) of the bit part combination representation type, the result data set (32) fully representing and preferably having at least the bit combination (8) of the digital source data (10), wherein bit sequences of the digital result data (6) and the digital source data (10) are different, a control data processing processor (112) for generating a multiplicity of different analog signals (114) of a control representation type as a function of digital control data (102), the digital control data ( 102) a variety of different input commands (108) from at least one input device (110), the multiplicity of different input commands (108) of the digital control data (102) being represented by a plurality of different analog signals (4) of the control representation type, the multiplicity of different analog signals (114 ) of the control representation type can be generated in at least four different states, with several or each analog signal (4) of the control representation type of the plurality of different analog signals (114) of the control representation type representing a defined input command (108), in particular directly or indirectly, the control data processing processor (112) has at least one data interface (116) for receiving the digital control data (102), the control data processing processor (112) having at least one signal output (118) for outputting the analog signals (4) of the control representation ntanztyp, a control input signal processing processor (120) for converting the analog signals (4) of the control representation type into the digital result control data (106) for manipulating the digital result data (6), wherein the control input signal processing processor (120) has at least one signal input (122) for receiving the via has the at least one signal output (118) of the control data processing processor (112) output analog signals (4) of the control representation type, wherein the digital result control data (106) is a digital representation (107) of at least part of the analog signals (4) of the control representation type, wherein the control input signal processing processor (120) at least indirectly with a function processor device (124) for executing or effecting at least one function (126) and preferably a plurality of functions (126, 128).

92. Passivation system according to claim 91, characterized in that the function processor device (124) can be activated to execute at least one defined function (126) and preferably a large number of different functions (126, 128) as a function of the digital result activation data (106).

93. System according to claim 92, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

94. System according to claim 93, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (128) of the function processor device or represent them.

95. System according to one of Claims 92 to 94, characterized in that a function output signal processing processor (134) is provided for generating a multiplicity of different analog signals (4) of the function processing type for mapping the activation of the function processor device (124).

96. System according to claim 95, characterized in that the multiplicity of different analog signals (136) can be generated in at least four different states.

97. System according to one of Claims 95 or 96, characterized in that a function data processing processor (138) is provided for generating visualization data for visualizing a function processor control visualization (142), in particular a function processor control mask.

98. System according to claim 97, characterized in that the function processor control visualization (142) can be generated as a function processor control mask.

99. System according to claim 97 or 98, characterized in that the function processor control visualization (142) can be generated at least partially as a function of the analog signals (4) of the function processing type generated by the function output signal processing processor (134).

100. System according to claim 99, characterized in that the function processor control visualization (142) can be manipulated by the at least one input device (110).

101. System according to claim 100, characterized in that the digital control data (102) can be generated as a function of the manipulation of the function processor control visualization (142).

102. System according to claim 101, characterized in that the function processor control visualization (142) and the

103. System according to one of claims 91 to 102, characterized in that the plurality of different analog signals (18) of the bit-part combination representation type comprises at least four different analog signals (4) of the bit-part combination representation type.

The system according to claim 103, characterized in that the plurality of different analog signals (18) of the bit-part combination representation type comprises at least thirty-two different analog signals (4) of the bit-part combination representation type.

105. System according to claim 103 or claim 104, characterized in that the output data processing processor (12) for generating the plurality of different analog signals (18) of the bit part combination representation type has at least one signal output (22), the signal output (22) having a plurality of different combinations from at least voltage and current can be acted upon.

106. System according to claim 105, characterized in that the different combinations of at least voltage and current are analog individual signals (4) or modulated multiple signals (4).

107. System according to claim 104, characterized in that the output data processing processor (12) for generating the multiplicity of different analog signals (18) of the bit part combination representation type has a multiplicity of signal outputs (22, 23) which can be controlled independently of one another, with at least several signal outputs (22, 23) can each be subjected to a large number of different combinations of voltage and current intensity by the output data processing processor (12).

108. System according to claim 107, characterized in that a large number of different combinations of voltage and current intensity per signal output (22, 23) comprises at least sixteen combinations.

109. System according to claim 108, characterized in that a large number of different combinations of voltage and current intensity per signal output (22, 23) comprises at least thirty-two different combinations.

110. System according to claim 108 or 109, characterized in that at least several of the signal outputs (22, 23) that can be controlled independently of one another can be controlled simultaneously to generate one analog signal each, or at least several of the signal outputs that can be controlled independently of one another simultaneously to generate a modulated analog signal (4) are controllable.

111. System according to one of claims 91 to 110, characterized in that the digital result data (6) have a result data format and the digital source data (10) have a source data format, the source data format and the result data format being different.

112. System according to one of Claims 91 to 111, characterized in that the input signal processing processor (24) has at least one input signal processing processor output (31) for outputting the digital result data (6).

113. System according to claim 112, characterized in that the input signal processing processor output (31) is coupled to a storage medium (36) for digitally storing the digital result data (6).

114. System according to claim 113, characterized in that between the storage medium (36) and the output data processing processor (12) there is preferably no digital data connection for the transmission of digital output data (2).

115. System according to any one of claims 91 to 114, characterized in that the input signal processing processor (24) and the

Output data processing processor (12) are arranged on a circuit board (38).

116. System according to claim 115, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 100 cm

117. System according to claim 116, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 20 cm

118. System according to claim 117, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 50 mm.

119. System according to claim 118, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 10 mm.

120. System according to claim 118, characterized in that the path (5) of the analog signals (4) of the bit part combination representation type from the output data processing processor (12) to the input signal processing processor (24) is shorter than 5 mm.

121. Method for converting digital output data (2) into digital

Result data (6), the digital result data (6) representing the digital output data (2) in a non-executable state, and for manipulating the digital result data (6) in the non-executable state, the digital output data (2) containing a bit combination (8 ) digital source data (10), in particular a digital file or a digital data stream represent having the steps:

Generating a multiplicity of different analog signals (18) of a bit-part combination representation type, in particular with an output data processing processor (12), the bit combination (8) being represented by a plurality of bit-part combinations (14), the several bit-part combinations (14) being derived from the multiplicity of different analog signals (18 ) of the bit-part combination representation type is represented, with each analog signal (4) of the bit-part combination representation type of the multiplicity of different analog signals (14) of the bit-part combination representation type representing a defined bit-part combination (16) of the plurality of bit-part combinations (14), in particular directly or indirectly,

Converting the analog signals (4) of the bit part combination representation type into the digital result data (6), in particular with an input signal processing processor (24), the digital result data (6) containing a result data set (32), the result data set (32) having a digital representation (34) of the analog signals (4) of the bit part combination representation type, the result data record (32) fully representing and preferably having at least the bit combination (8) of the digital source data (10), bit sequences of the digital result data (6) and the digital source data ( 109 are different,

Generating a large number of different analog signals (114) of a control representative type as a function of digital control data (2), in particular with a control data processing processor (112), the digital control data (2) containing a large number of different input commands (108) from at least one input device (110 ) represent, wherein the plurality of different input commands (108) of the digital control data (2) are represented by a plurality of different analog signals (4) of the control representative type, wherein the plurality of different analog signals (114) of the control representative type are generated in at least four mutually different states, wherein several or each analog signal (4) of the control representative type of the multiplicity of different analog signals (114) of the control representative type represents a defined input command (108), in particular directly or indirectly,

Converting the analog signals (4) of the control representation type into the digital result control data (106) for manipulating the result data (6), in particular with a control input signal processing processor (120), the digital result control data (106) being a digital representation (107) of at least part of the analog signals (2) are of the driving representative type, Activation of at least the defined function (126) and preferably the multiplicity of different functions (126, 128) as a function of the digital result activation data (106), the defined function (106) comprising at least or precisely the manipulation of the result data (6).

122. The method as claimed in claim 121, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

123. The method according to claim 122, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (126, 128) or represent them.

124. The method according to any one of claims 121 to 123, characterized by the steps

Generating a plurality of different analog signals (136) of a functional processing type for mapping the driving of the defined function (126), wherein the plurality of different analog signals (116) of the functional processing type are generated in at least four mutually different states,

Generating visualization data (140) for visualizing a function processor control visualization (142), in particular a function processor control mask, with the function processor control visualization (142) being generated at least partially as a function of the generated analog signals (4) of the function processing type, with manipulation of the function processor control visualization (142) being at least one input device (110) is effected, the digital control data being generated as a function of the manipulation of the function processor control visualization (142).

125. System (300), having at least one access system (304), in particular an access server, connected to a network (302), in particular the Internet, and at least one data and/or program system (306), in particular a data and/or or program server, wherein the data and/or program system (306) has no data connection for exchanging digital signals with the access system (302), and a system (100) for converting digital drive data (102) into analog signals (4) of a drive representation type and for converting the analog signals (4) of the drive representation type into digital result drive data (106), the digital drive data (102) having a plurality of different input commands (108) from represent at least one input device (110), in particular an input device (110) of a terminal (308), having a control data processing processor (112) for generating a multiplicity of different analog signals (4) of a control representation type, the multiplicity of different input commands (108) of the digital control data (102) are represented by a plurality of different analog signals (4) of the control representation type, the multiplicity of different analog signals (114) of the control representation type being able to be generated in at least four different states, wherein a plurality or each analog signal (4) of the control representation type of the A large number of different analog signals (114) of the control representation type represent a defined input command (108), in particular directly or indirectly, the control data processing processor (112) having at least one data interface (116) for receiving the digital control data (102), wherein the control data processing processor (112) has at least one signal output (118) for outputting the analog signals (4) of the control representation type, a control input signal processing processor (120) for converting the analog signals (4) of the control representation type into the digital result control data ( 106), wherein the control input signal processing processor (120) has at least one signal input (122) for receiving the signals of the control representation type output via the at least one signal output (118) of the control data processing processor (112), the digital result control data (106) having a digital representation (107) the analog signals (4) are of the drive representation type, wherein the data and/or program system (306) and the access system (304) via the system (100) for converting digital drive data (102) into analog signals (4) of a drive representation type and to convert the analog Signals (4) of the control representation type are coupled to one another in digital result control data (106), with the access system (304) via the network (302), in particular the Internet, using the end device (308), in particular mobile phones, laptops, desktop computers, tablet PCs and/or or IoT devices, such as refrigerators, barriers, household appliances, motor vehicles, or infrastructure facilities, such as traffic lights, locks, signal boxes or lighting, in particular street lighting, a data exchange can be effected, with the access system (304) depending on the data exchange with the terminal ( 308) the digital control data (102) can be transmitted to the control data processing processor (112), the digital result control data (106) being able to be received from the data and/or program system (306), a function processor device (124) of the data and/or or Prague ramm system (306) at least one defined function (126) and preferred a large number of different functions (126, 128) can be effected or executed as a function of the digital result control data (106).

126. System according to claim 125, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

127. System according to claim 126, characterized in that the defined analog signals (4) of the control representation type are assigned to the defined function (126) or the defined functions (126, 128) of the function processor device (124) or represent them.

128. System according to one of claims 125 to 127, characterized in that a function output signal processing processor (134) is provided for generating a multiplicity of different analog signals (136) of the function processing type for mapping the control of the function processor device (124).

129. System according to claim 128, characterized in that the plurality of different analog signals (136) can be generated in at least four different states.

130. System according to one of Claims 128 or 129, characterized in that a function data processing processor (138) is provided for generating visualization data for visualizing a function processor control visualization (142), in particular a function processor control mask.

131. System according to claim 130, characterized in that the function processor control visualization (142) can be generated as a function processor control mask.

132. System according to claim 130 or 131, characterized in that the function processor control visualization (142) can be generated at least partially as a function of the analog signals (4) of the function processing type generated by the function output signal processing processor (134).

133. System according to claim 132, characterized in that the function processor control visualization (142) can be manipulated by the at least one input device (110).

134. System according to claim 133, characterized in that the digital control data (102) can be generated as a function of the manipulation of the function processor control visualization (142).

135. System according to any one of claims 132 to 134, characterized in that the function processor control visualization (142) and the

136. System according to one of Claims 126 to 135, characterized in that the defined analog signals (4) of the control representation type are assigned to the digital result control data (106) via an assignment unit (190), in particular an assignment list or assignment table.

137. System according to one of Claims 130 to 136, characterized in that the functional data processing processor (138) is part of the system (100) for converting digital control data (102) into analog signals (4) of a control representation type and for converting the analog signals (4 ) of the drive representation type into digital result drive data (106) or part of the access system (304).

138. System according to one of claims 128 to 137, characterized in that the function output signal processing processor (138) is a part of the system (100) for converting digital drive data (102) into analog signals (4) of a drive representation type and for converting the analog signals ( 4) of the drive representation type in digital result drive data (106) or part of the data and/or programming system (306).

139. System according to one of Claims 126 to 138, characterized in that no result control data (106) is assigned to analog signals (4) of the control representation type to which no digital result control data (106) are assigned. can be generated or exclusion result data can be generated, the exclusion result data representing documentation of the signal transmission event, in particular with information on the analog signals (4) of the control representative type.

140. System according to one of Claims 126 to 139, characterized in that an update or reconfiguration unit is provided for converting digital configuration output data into update or reconfiguration data, the digital configuration output data being a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream, wherein the update or reconfiguration unit has at least: a configuration output data processing processor for generating a multiplicity of different analog signals of a configuration bit part combination representation type, wherein the configuration bit combination of the digital configuration data is represented by a plurality of configuration bit part combinations, wherein the Configuration bit combination is preferred content of the digital configuration output data, the multiple configuration bit subcombination en is represented by the multiplicity of different analog signals of the configuration bit part combination representation type, the multiplicity of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the multiplicity of different analog signals of the configuration bit part combination representation type having a defined configuration Bit part combination of the multiple configuration bit part combinations, in particular directly or indirectly, represented, wherein the configuration output data processing processor has at least one data interface for receiving the digital configuration output data, wherein the configuration output data processing processor has at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration input signal processing proc essor for converting the analog signals of the configuration bit part combination representation type into digital configuration result data, the configuration input signal processing processor having at least one signal input for receiving the analog signals of the configuration bit part combination representation type output via the at least one signal output of the configuration output data processing processor, wherein the digital configuration - Result data update or reconfiguration data can be generated for updating or reconfiguring the function processor device.

141. System according to claim 140, characterized in that an update or reconfiguration data generation processor is provided, wherein the update or reconfiguration data generation processor can transfer configuration bit part combinations of the digital result data for generating the update or reconfiguration data into a predetermined order by means of assignment data.

142. System according to claim 141, characterized in that the assignment data are provided in a data memory which can be accessed by the update or reconfiguration data generation processor.

143. System according to claim 142, characterized in that a large number of assignment data is provided, with a mechanism for selecting the assignment data being stored.

144. System according to claim 143, characterized in that the mechanism is designed to effect the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

145. Method for controlling a data and/or program system (306), wherein the data and/or program system (306) is not connected to an access system (304) via a data connection for exchanging digital signals, comprising the steps:

Generating a large number of different analog signals (102) of a control representation type, in particular with a control data processing processor (112), the large number of different input commands (108) of the digital control data (102) being represented by a number of different analog signals (4) of the control representation type, the A large number of different analog signals (114) of the control representation type are generated in at least four different states, with several or each analog signal (4) of the control representation type of the large number of different analog signals (114) of the control representation type sending a defined input command (108), in particular directly or indirectly , represents,

Converting the analog signals (4) of the control representation type into digital result control data (106), in particular with a control input signal processing processor (120), the digital result control data (106) being a digital representation (107) of the analog signals (4) of the control representation type, from the access system (304) via the network (302), in particular the Internet, to the end device, in particular mobile phones, laptops, desktop computers, tablet PCs and/or IoT devices such as refrigerators, barriers, household appliances, motor vehicles or infrastructure facilities such as Traffic lights, locks, interlockings or lighting, in particular street lighting, a data exchange is effected, with the access system (304) depending on the data exchange with the terminal (308) the digital control data (102) for generating the large number of different analog signals (114) of the control representation type are transmitted, the digital result control data (106) being received by the data and/or program system (306), with at least one defined function ( 126) and preferably a large number of different functions (126, 128) depending on the digital supplement ebnisansteuerdaten (106) is effected or executed.

146. Machine system (400) having at least one machine device (144, 146, 148, 150, 152, 154, 156) controlled by a function processor device (124), the function processor device (124) preferably being part of the machine device (144, 146,

148, 150, 152, 154, 156), and a system (100) for converting digital drive data (102) into analog signals (4) of a drive representation type and for converting the analog signals (4) of the drive representation type into digital result drive data (106 ), wherein the digital control data (102) represent a large number of different input commands (108) from at least one input device (110), in particular an input device (110) of a terminal (308), having a control data processing processor (112) for generating a large number different analog signals (4) of the control representation type, wherein the plurality of different input commands (108) of the digital control data (102) are represented by a plurality of different analog signals (4) of the control representation type, wherein the plurality of different analog signals (114) of the control representation type are divided into at least four mutually different states can be generated, where several or each analog signal (4) of the control representative type of the multiplicity of different analog signals (114) of the control representative type represents a defined input command (108), in particular directly or indirectly, wherein the control data processing processor (112) has at least one data interface (116) for receiving the digital control data (102), wherein the control data processing processor (112) has at least one signal output (118) for outputting the analog signals (4) of the control representation type, a control input signal processing processor (120) for converting the analog signals (4) of the control representation type into the digital result control data ( 106), wherein the control input signal processing processor (120) has at least one signal input (122) for receiving the analog signals (4) of the control representation type output via the at least one signal output (118) of the control data processing processor (120), the digital result control data (106) having a digital representation (107 ) of the analog signals (4) of the control representation type, via an input data interface, in particular an input device (110), of the system (100) for converting digital control data (102) into analog signals (4) of a control representation type and for converting the analog signals (4) of the control representation type in digital result control data (106), the digital control data (102) can be transmitted or fed to the control data processing processor (112), with at least one defined function (126) and preferably a large number of different functions ( 126, 128) of the machine device (144, 146, 148, 150, 152, 154, 156) can be brought about or executed or controlled or triggered or deactivated or activated depending on the digital result control data (106).

147. System according to claim 146, characterized in that the digital result control data (106) can be generated for defined analog signals (4) of the control representation type.

148. System according to claim 147, characterized in that the defined analog signals of the control representation type are assigned to the defined function or the defined functions of the function processor device or represent them.

149. System according to one of claims 147 or 148, characterized in that a function output signal processing processor is provided for generating a multiplicity of different analog signals of the function processing type for mapping the activation of the function processor device.

150. System according to claim 149, characterized in that the multiplicity of different analog signals can be generated in at least four different states.

151. System according to any one of claims 149 or 150, characterized in that a function data processing processor is provided for generating visualization data for visualizing a function processor control visualization, in particular a function processor control mask.

152. System according to claim 151, characterized in that the function processor control visualization can be generated as a function processor control mask.

153. System according to claim 151 or 152, characterized in that the function processor control visualization can be generated at least partially as a function of the analog signals of the function processing type generated by the function output signal processing processor.

154. System according to claim 153, characterized in that the function processor control visualization can be manipulated by the at least one input device.

155. System according to claim 154, characterized in that the digital control data can be generated as a function of the manipulation of the function processor control visualization.

156. System according to one of Claims 153 to 155, characterized in that the function processor control visualization and the control data processing processor are connected to one another at least indirectly via the data interface.

157. System according to one of Claims 147 to 156, characterized in that the defined analog signals of the control representation type are assigned to the digital result control data via an assignment unit, in particular an assignment list or assignment table.

158. System according to any one of claims 151 to 157, characterized in that the functional data processing processor is part of the system for converting digital drive data into analog signals of a drive representation type and for converting the analog signals of the drive representation type into digital result drive data or part of the access system.

159. System according to one of claims 149 to 158, characterized in that the function output signal processing processor is part of the system for converting digital drive data into analog signals of a drive representation type and for converting the analog signals of the drive representation type into digital result drive data or a part of the data and/or or program system is.

160. System according to one of Claims 147 to 159, characterized in that no result control data can be generated or exclusion result data can be generated for analog signals of the control representation type to which no digital result control data is assigned, the exclusion result data being documentation of the signal transmission event, in particular with information on the drive representation type analog signals.

161. System according to one of Claims 147 to 160, characterized in that an update or reconfiguration unit is provided for converting digital configuration output data into update or reconfiguration data, the digital configuration output data being a bit combination of digital configuration source data, in particular a digital configuration file or a digital configuration data stream, wherein the update or reconfiguration unit has at least: a configuration output data processing processor for generating a multiplicity of different analog signals of a configuration bit part combination representation type, wherein the configuration bit combination of the digital configuration data is represented by a plurality of configuration bit part combinations, wherein the Configuration bit combination is preferred content of the digital configuration output data, the multiple configuration bit part combinations is represented by the multiplicity of different analog signals of the configuration bit part combination representation type, the multiplicity of analog signals representing a plurality of configuration bit part combinations of the configuration bit combination, each analog signal of the configuration bit part combination representation type of the multiplicity of different analog signals of the configuration bit part combination representation type a defined configuration bit part combination of the plurality of configuration bit part combinations, in particular directly or indirectly, with the configuration output data processing processor having at least one data interface for receiving the digital configuration output data, wherein the configuration output data processing processor has at least one signal output for outputting the analog signals of the configuration bit part combination representation type, a configuration input signal processing processor for converting the analog signals of the configuration bit part combination representation type into digital configuration result data, wherein the configuration input signal processing processor has at least one signal input for receiving the via has the at least one signal output of the configuration output data processing processor output analog signals of the configuration bit part combination representation type, wherein update or reconfiguration data for updating or reconfiguring the function processor device can be generated from the digital configuration result data.

162. System according to claim 161, characterized in that an update or reconfiguration data generation processor is provided, wherein the update or reconfiguration data generation processor can transfer configuration bit part combinations of the digital result data to generate the update or reconfiguration data in a predetermined order by means of assignment data.

163. System according to claim 162, characterized in that the allocation data is provided in a data memory which can be accessed by the update or reconfiguration data generation processor.

164. System according to claim 163, characterized in that a large number of allocation data is provided, with a mechanism for selecting the allocation data being stored.

165. System according to claim 164, characterized in that the mechanism is designed to effect the selection of the assignment data as a function of reference data, in particular the time and/or the date and/or result control data.

166. System according to one of Claims 146 to 165, characterized in that the input data interface is an input device, a computer or an access system, in particular an access server.

167. System according to any one of claims 146 to 166, characterized in that the machine device is a motor vehicle, in particular in a car, truck, airplane or boat, a multi-axis robot, a production plant or a printing shop.

168. A method for controlling a machine system (400), at least comprising the steps of: generating a large number of different analog signals (4) of a control representative type, a large number of different input commands (108) of digital control data (102) being replaced by a number of different analog signals (4) of the control representation type are represented, wherein the plurality of different analog signals (114) of the control representation type are generated in at least four mutually different states, wherein several or each analog signal (4) of the control representation type of the plurality of different analog signals (114) of the control representation type sends a defined input command (108 ), in particular directly or indirectly, represented,

Converting the analog signals (4) of the control representation type into the digital result control data (106), the digital result control data (106) being a digital representation (107) of the analog signals (4) of the control representation type, with an input data interface, in particular the input device 110, the digital control data (102) for generating the plurality of different analog signals (114) of the control representative type are transmitted or supplied or generated, the digital result control data preferably being received by the machine device (144, 146, 148, 150, 152, 154, 156). , wherein at least one defined function (126) and preferably a large number of different functions (126, 128) are processed by a function processor device (124) of the machine device (144, 146, 148, 150, 152, 154, 156) as a function of the digital result control data (106 ) effected or executed or driven or triggered or deactivated or is activated.

169. Device according to one of Claims 24 to 75, characterized in that an analysis of the bit combination contained in the result data set can be effected for the detection of software components.

170. Device according to claim 169, characterized in that an analysis processor is provided for carrying out the analysis.

171. Device according to claim 169 or 170, characterized in that the software components are malware or malware components.

172. Method according to claim 76, characterized in that the bit combination contained in the result data set is analyzed with regard to software components.

173. The method according to claim 172, characterized in that the malware or malware components are.