JP2020526992A5 - - Google Patents

Description

It will be apparent to those skilled in the art that various changes may be made to this disclosure without departing from the spirit and scope of this disclosure, and therefore this disclosure is specifically disclosed herein. Other embodiments are included, but only as shown in the appended claims.
[Item 1]
A method for creating a high-speed, large-capacity dedicated viral molecular network.
Orbit time slot encrypting digital signals and
A method comprising putting the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame to create a TDMA signal.
[Item 2]
The method of item 1, further comprising up-converting the TDMA signal to form a radio frequency (RF) signal.
[Item 3]
The method of item 2, wherein the up-conversion comprises modulating the TDMA signal with a high-speed digital signal such that the RF signal is formed.
[Item 4]
The method of item 2 or 3, further comprising creating a millimeter wave RF signal from the RF signal.
[Item 5]
The method of item 4, wherein producing the millimeter wave RF signal comprises creating the millimeter wave RF signal having an RF frequency of 30 GHz to 3,300 GHz.
[Item 6]
The method of item 4 or 5, wherein producing the millimeter wave RF signal comprises up-converting and amplifying the RF signal.
[Item 7]
The method of item 5 or 6, wherein producing the millimeter wave RF signal comprises transmitting the millimeter wave RF signal.
[Item 8]
7. The method of item 7, further comprising receiving the transmitted millimeter wave RF signal.
[Item 9]
8. The method of item 8, wherein receiving the transmitted millimeter-wave RF signal down-converts the transmitted millimeter-wave RF signal.
[Item 10]
9. The method of item 9, wherein down-converting the transmitted millimeter-wave RF signal comprises demodulating the TDMA signal with the high-speed digital signal.
[Item 11]
The method according to any one of items 7 to 10, wherein transmitting the millimeter wave RF signal includes transmitting and receiving the transmitted millimeter wave RF signal between gyro traveling wave amplifiers.
[Item 12]
The method of item 11, wherein transmitting and receiving the transmitted millimeter wave RF signal comprises transmitting and receiving the transmitted millimeter wave RF signal between high output power gyro traveling wave amplifiers.
[Item 13]
The method of item 11 or 12, wherein transmitting and receiving the transmitted millimeter wave RF signal comprises transmitting and receiving the transmitted millimeter wave RF signal between gyro traveling wave tube amplifiers.
[Item 14]
To provide an application programming interface (API) for an interface with a software application, wherein the API is configured to facilitate the reception of data.
Encapsulating the received data in at least one fixed cell frame,
Processing at least one fixed cell frame above, and
It further comprises at least one of transmitting at least one processed fixed cell frame to the orbit time slot via an attosecond multiplexer.
Described in any one of the preceding items, wherein the orbital time slot is configured to transmit the fixed cell frame to the viral molecular network at a rate of terabit / sec via the orbital time slot digital signal. the method of.
[Item 15]
A system for creating a high-speed, large-capacity, dedicated viral molecular network, comprising the means for performing the method described in any one of the preceding items.
[Item 16]
A wireless communication device configured to create a high-speed, large-capacity dedicated viral molecular network.
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A time division multiple access (TDMA) circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
A device comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 17]
The device of item 16, wherein the millimeter wave RF signal has an RF frequency of 30 GHz to 3,300 GHz.
[Item 18]
A method for operating within a viral molecular network,
Connecting the data cell frame from at least one communication device to the receiver device,
A method comprising storing, reading, and mapping the data cell frame to an Internet Protocol (IP) address.
[Item 19]
18. The method of item 18, further comprising linking the data port communicably with the communication device and the receiver device.
[Item 20]
The method according to item 18 or 19, wherein the data port is an optical fiber data port.
[Item 21]
The connection of the data cell frame includes connecting the data cell frame from the communication device to the receiver device via a mapping circuit, and the data cell frame is stored, read, and mapped. This involves storing, reading, and mapping the data cell frame to the IP address via a processor, the mapping circuit, the processor, and the data port being linked to a common data bus. The method according to any one of items 18 to 20.
[Item 22]
The method of any one of items 18-21, further comprising configuring the data port to transmit and receive millimeter-wave radio frequency (RF) signals having a frequency of 30 GHz to 3,300 GHz.
[Item 23]
A system for operating within a viral molecular network, comprising means for performing the method according to any one of items 18-22.
[Item 24]
A method for operating within a viral molecular network,
Amplifying and outputting millimeter-wave RF signals in the range of 1.5 watts to 10,000 watts,
A method comprising amplifying a millimeter wave radio frequency (RF) signal having a frequency of 30 GHz to 3,330 GHz.
[Item 25]
24. The method of item 24, wherein the amplification and output of the millimeter wave RF signal is accomplished via a high output power gyro traveling wave amplifier.
[Item 26]
A system for operating within a viral molecular network, comprising means for performing the method according to item 24 or 25.
[Item 27]
An amplifier configured to operate within a viral molecular network, wherein the amplifier is:
Configured to amplify and output millimeter-wave RF signals in the range of 1.5 watts to 10,000 watts, and further to amplify millimeter-wave radio frequency (RF) signals with frequencies in the range of 30 GHz to 3,330 GHz. Amplifiers, including configured gyro traveling wave amplifiers.
[Item 28]
The amplifier according to item 27, wherein the gyro traveling wave amplifier includes a high output power gyro traveling wave amplifier.
[Item 29]
28. The method of item 27 or 28, wherein the gyro traveling wave amplifier comprises a gyro traveling wave tube amplifier.
[Item 30]
A method for operating within a viral molecular network,
To send and receive millimeter-wave radio frequency (RF) signals with RF frequencies of 30 GHz to 3,300 GHz via millimeter RF signal antenna amplifier repeaters.
A method comprising attaching the millimeter wave RF signal antenna amplifier repeater to a structure.
[Item 31]
The mounting is on and in-glass used for mounting the millimeter wave RF signal antenna amplifier repeater to the structure by wall mounting, window mounting, or for panels, counters, surfaces, and other structures. 30. The method of item 30, comprising mounting on / plastic / wood or other types of materials, mounting by door mounting, mounting by ceiling mounting, or a combination thereof.
[Item 32]
A system for operating within a viral molecular network, comprising means for performing the method according to item 30 or 31.
[Item 33]
A millimeter RF signal antenna amplifier repeater that operates within a viral molecular network.
A millimeter-wave antenna configured to send and receive millimeter-wave radio frequency (RF) signals with an RF frequency of 30 GHz to 3,300 GHz.
With hardware configured to attach the antenna to a structure, the hardware is wall mounted; on and in glass / plastic / used for panels, counters, surfaces, and other structures. A millimeter RF signal antenna amplifier repeater selected from the group consisting of wooden or other types of materials; window-mounted; door-mounted; ceiling-mounted; or a combination thereof.
[Item 34]
Atomic clock and synchronization method for operating in a viral molecular network.
Synchronizing with a shared atomic oscillation clock source,
Including generating a synchronous digital signal, the digital signal controls at least one of a clock frequency and a digital timing signal.
Unit phase lock type network and
With computing and communication devices connected to the above viral molecular network,
With a gyro traveling wave amplifier,
A method configured to extend to fiber optic terminals and their respective oscillator circuits connected to each fiber optic terminal.
[Item 35]
Generating the synchronous digital signal includes generating the synchronous digital signal configured to extend control of at least one of the clock frequency and digital timing signals to a high output power gyro traveling wave amplifier. , Item 34.
[Item 36]
The generation of the synchronous digital signal comprises generating the synchronous digital signal configured to extend control of at least one of a clock frequency and a digital timing signal to a gyro traveling wave tube amplifier. 34 or 35.
[Item 37]
A synchronous digital signal configured such that generating the synchronous digital signal extends control of at least one of a clock frequency and a digital timing signal to at least one of a device and an integrated circuit chip. The method according to any one of items 34 to 36, which comprises generating.
[Item 38]
The generation of the synchronous digital signal extends control of at least one of the clock frequency and digital timing signals to a wireless communication device configured to create a fast, large capacity dedicated viral molecular network. The wireless communication device comprises generating the synchronous digital signal configured in.
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A TDMA circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
37. The method of item 37, comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 39]
The generation of the synchronous digital signal extends control of at least one of the clock frequency and digital timing signals to an integrated circuit chip configured to create a fast, large capacity dedicated viral molecular network. The device comprises generating the synchronous digital signal configured in.
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A TDMA circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
37. The method of item 37 or 38, comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 40]
An atomic clock and synchronization system for operating within a viral molecular network, comprising means for performing the method according to any one of items 34-39.
[Item 41]
An atomic clock and synchronization system configured to operate within a viral molecular network, wherein the atomic clock and synchronization system
Atomic oscillator and
Clock signal distribution system and
A digital transmission layer configured to synchronize with a common atomic oscillation clock source,
It comprises a processor configured to generate a synchronous digital signal, wherein the digital signal controls at least one of a clock frequency and a digital timing signal.
Unit phase lock type network and
With a gyro traveling wave amplifier,
A system configured to extend to an optical fiber terminal and each oscillator circuit connected to each optical fiber terminal.
[Item 42]
The system according to item 41, wherein the gyro traveling wave amplifier includes a high output power gyro traveling wave amplifier.
[Item 43]
The system according to item 41 or 42, wherein the gyro traveling wave amplifier comprises a gyro traveling wave tube amplifier.
[Item 44]
The digital signal is configured to extend control of at least one of the clock frequency and digital timing signals to a wireless communication device configured to create a fast, large capacity dedicated viral molecular network. The communication device is
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A TDMA circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
The system according to any one of items 41 to 43, comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 45]
The digital signal is configured to extend control of at least one of the clock frequency and digital timing signals to an integrated circuit chip configured to create a fast, large capacity dedicated viral molecular network. but,
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A TDMA circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
The system according to any one of items 41 to 44, comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 46]
Analyzing the operational status of multiple devices operating on millimeter-wave radio frequency (RF) signals with frequencies between 30 GHz and 3,300 GHz, a network management method configured to operate within a viral molecular network. Network management methods, including.
[Item 47]
A network management system for operating within a viral molecular network, comprising means for performing the method of item 46.
[Item 48]
A network management system configured to operate within a viral molecular network, wherein the network management system operates on a plurality of devices operating on a millimeter-wave radio frequency (RF) signal having a frequency of 30 GHz to 3,300 GHz. A network management system with a processor configured to analyze status.
[Item 49]
A method for creating a high-speed, large-capacity dedicated viral molecular network.
To provide an application programming interface (API) to facilitate the reception of data,
Modulating the above received data and
Creating a millimeter-wave RF signal from the above modulated data
A method comprising sending and receiving the millimeter wave RF signal with a high power gyro traveling wave amplifier in the network.
[Item 50]
49. The method of item 49, wherein producing the millimeter wave RF signal comprises creating the millimeter wave RF signal having an RF frequency of 30 GHz to 3,300 GHz.
[Item 51]
49. The method of item 49 or 50, wherein producing the millimeter wave RF signal comprises transmitting the millimeter wave RF signal.
[Item 52]
51. The method of item 51, further comprising receiving the transmitted millimeter wave RF signal.
[Item 53]
52. The method of item 52, further comprising demodulating the received millimeter wave RF signal.
[Item 54]
Encapsulating the received data in at least one fixed cell frame,
Processing at least one fixed cell frame above, and
Further comprising at least one of transmitting at least one processed fixed cell frame to the orbit time slot.
The item 49 to 53, wherein the circuit time slot is configured to transmit the fixed cell frame to the viral molecular network at a rate of terabit / sec via the circuit time slot digital signal. The method described.
[Item 55]
54. The method of item 54, further comprising encrypting at least one fixed cell frame.
[Item 56]
54. The method of item 54 or 55, further comprising encrypting the received data.
[Item 57]
56. The method of item 56, wherein encrypting the received data comprises encrypting end-user application data.
[Item 58]
The method of any one of items 49-57, wherein providing the API comprises providing the API for interfacing with a software application.
[Item 59]
A system for creating a high-speed, large-capacity dedicated viral molecular network comprising means for carrying out the method according to any one of items 49-58.
[Item 60]
A wireless communication device configured to create a high-speed, large-capacity dedicated viral molecular network.
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
It is a data bus configured to transmit the fixed cell frame to the orbit time slot, and the orbit time slot transmits the fixed cell frame to the orbit time slot digital signal at a speed of terabit / sec. A data bus that is configured to transmit to a molecular network,
A local oscillator with a phase-locked loop circuit configuration and
A modem that modulates and demodulates the above data,
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
A wireless communication device comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between high power gyro traveling wave amplifiers in the network.
[Item 61]
The device of item 60, wherein the millimeter wave RF signal has an RF frequency of 30 GHz to 3,300 GHz.
[Item 62]
60 or 61. The device of item 60 or 61, further comprising an encryption system configured to encrypt end-user application data, said received data, and at least one of said cell frames.
[Item 63]
A method for facilitating data communication over a high-speed, large-capacity dedicated viral molecular network.
To transmit the first millimeter wave RF signal to the high power gyro traveling wave amplifier in the above network,
A method comprising receiving a second millimeter wave RF signal from the high power gyro traveling wave amplifier.
[Item 64]
63. The method of item 63, wherein transmitting the first millimeter wave RF signal comprises transmitting the first millimeter wave RF signal having an RF frequency of 30 GHz to 3,300 GHz.
[Item 65]
63 or 64. The method of item 63 or 64, wherein transmitting the first millimeter wave RF signal comprises modulating the first millimeter wave RF signal.
[Item 66]
In any one of items 63 to 65, the reception of the second millimeter wave RF signal includes receiving the second millimeter wave RF signal having an RF frequency of 30 GHz to 3,300 GHz. The method described.
[Item 67]
The method according to any one of items 63 to 66, wherein receiving the second millimeter wave RF signal comprises demodulating the second millimeter wave RF signal.
[Item 68]
Encapsulating the received data in at least one fixed cell frame,
Processing at least one fixed cell frame above, and
Further comprising at least one of transmitting at least one processed fixed cell frame to the orbit time slot.
The item 63 to 67, wherein the orbital time slot is configured to transmit the fixed cell frame to the viral molecular network at a rate of terabit / sec via the orbital time slot digital signal. The method described.
[Item 69]
68. The method of item 68, further comprising encrypting at least one fixed cell frame.
[Item 70]
68 or 69. The method of item 68 or 69, wherein transmitting the first millimeter wave RF signal comprises modulating the received data to produce the first millimeter wave RF signal.
[Item 71]
The method of any one of items 68-70, wherein receiving the second millimeter wave RF signal comprises demodulating the received data.
[Item 72]
A system for facilitating data communication over a high-speed, large-capacity dedicated viral molecular network, comprising means for performing the method according to any one of items 63-71.
[Item 73]
An integrated circuit chip configured to facilitate data communication over a high-speed, large-capacity dedicated viral molecular network.
A self-raming protocol configured to encapsulate data within at least one fixed cell frame,
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot,
A modem that modulates and demodulates the above data,
A radio frequency (RF) up / down converter, amplifier, and receiver configured to transmit and receive millimeter wave RF signals communicating with a high power gyro traveling wave amplifier in the network.
An integrated circuit chip in which the millimeter wave RF signal has an RF frequency of 30 GHz to 3,300 GHz.
[Item 74]
73. The integrated circuit chip of item 73, further comprising an encryption system configured to encrypt at least one of the end-user application data, the data, and the cell frame.
[Item 75]
A method for operating within a viral molecular network,
Receiving high power millimeter RF signals and
Amplifying the received high power millimeter RF signal, including
A method in which receiving and amplifying are performed via a gyro traveling wave amplifier.
[Item 76]
75. The method of item 75, further comprising outputting the amplified high power millimeter RF signal.
[Item 77]
76. The method of item 76, wherein outputting the amplified high power millimeter RF signal comprises outputting the amplified high power millimeter RF signal via a gyro traveling wave amplifier.
[Item 78]
The method according to any one of items 75 to 77, wherein receiving the high power millimeter RF signal comprises receiving the high power millimeter RF signal having an RF frequency of 30 GHz to 3,300 GHz.
[Item 79]
A system for operating within a viral molecular network, comprising means for performing the method according to any one of items 75-78.
[Item 80]
An amplifier configured to operate within a viral molecular network, wherein the amplifier is:
An amplifier comprising a gyro traveling wave amplifier configured to receive, amplify, and output a high power millimeter RF signal having an RF frequency of 30 GHz to 3,330 GHz.
[Item 81]
A method for atomic clocks and synchronization within viral molecular networks,
Synchronizing the circuit configuration frequencies of multiple devices in the above network
A method comprising controlling the circuit constituent frequencies of the device.
[Item 82]
A system for atomic clocks and synchronization within a viral molecular network, comprising means for carrying out the method of item 81.
[Item 83]
An atomic clock and synchronization system that operates within a viral molecular network and is configured to synchronize and control all of the digital and analog circuit components frequencies of all devices and systems in the network.
[Item 84]
A method for operating millimeter RF signal antenna repeaters within a viral molecular network.
To provide the above millimeter RF signal antenna amplifier repeater,
A method comprising attaching the millimeter RF signal antenna amplifier repeater to a structure.
[Item 85]
The mounting of the millimeter RF signal antenna amplifier repeater can be either wall mounting or window mounting of the millimeter RF signal antenna amplifier repeater to the structure, panels, counters, surfaces, and other structures. 84, which comprises attaching to on-and-in-glass / plastic / wooden or other types of materials used in, mounting by door mounting, mounting by ceiling mounting, or a combination thereof. Method.
[Item 86]
84 or 85, wherein providing the millimeter RF signal antenna amplifier repeater comprises providing the millimeter RF signal antenna amplifier repeater that receives an RF signal having an RF frequency of 30 GHz to 3,300 GHz. The method described.
[Item 87]
A system for operating a millimeter RF signal antenna amplifier repeater within a viral molecular network, comprising means for performing the method according to any one of items 84-86.
[Item 88]
Sending and receiving millimeter-wave radio frequency (RF) signals with RF frequencies from 30 GHz to 3,300 GHz, operating within viral molecular networks, wall-mounted; window-mounted; on panels, counters, surfaces, and other structures On-and-in-glass / plastic / wooden or other types of materials used; door-mounted; and ceiling-mounted millimeter RF signal antenna amplifier repeaters.
[Item 89]
An integrated circuit chip configured to create a high-speed, large-capacity dedicated viral molecular network.
An application programming interface (API) configured to interface with a software application communicatively linked to the device, wherein the API is configured to facilitate the reception of data. Interface and
A synchronous self-raming protocol configured to encapsulate the above data in at least one fixed cell frame.
With an attosecond multiplexer configured to handle the above fixed cell frames,
A data bus configured to transmit the fixed cell frame to the orbit time slot via an at-second multiplexer, the orbit time slot terabiting the fixed cell frame via the orbit time slot digital signal. With a data bus configured to transmit to the viral molecular network at a rate of / sec.
A local oscillator with a phase-locked loop circuit configuration and
An encryption circuit configured to encrypt the orbital time slot digital signal,
A TDMA circuit configured to put the encrypted orbit time slot digital signal into a time division multiple access (TDMA) frame and thereby create a TDMA signal.
A modem configured to modulate and demodulate the TDMA signal with a high speed digital signal between a radio frequency (RF) up-converter and a down-converter.
With an RF amplifier configured to create millimeter-wave RF signals,
With an RF receiver configured to receive millimeter-wave RF signals,
An integrated circuit chip comprising a millimeter wave antenna configured to send and receive millimeter wave RF signals between the outputs of a high output power gyro traveling wave amplifier.
[Item 90]
The device of item 89, wherein the millimeter wave RF signal has an RF frequency of 30 GHz to 3,300 GHz.

Claims (12)

A method of transmitting data over a network
A step of receiving a data packet in a device, wherein the device includes an integrated circuit and an application programming interface (API), which further allows the data packet to interface with a software application.
The stage of authenticating the data packet by the integrated circuit and
The stage of encapsulating the data packet in a fixed cell frame by the integrated circuit, and
A step of transmitting the fixed cell frame to the network by the integrated circuit, wherein the fixed cell frame is a time division multiple access (TDMA) frame.
A method. The method of claim 1, wherein the software application provides an executable software code for authenticating and encrypting the data packet, the executable software code being executed by the integrated circuit. The method of claim 1 or 2, wherein the integrated circuit is coupled with a high speed digital modulator / demodulator. The method of any one of claims 1 to 3, wherein the integrated circuit is coupled with a clock and a synchronization module. The method according to any one of claims 1 to 4, wherein the integrated circuit is coupled to a network management module. The method of any one of claims 1-5, wherein the integrated circuit is coupled to a transmitter / receiver configured to transmit and receive radio frequency (RF) millimeter waves. The method of claim 6, wherein the RF millimeter wave has a frequency between 30 GHz and 3300 GHz. The method of claim 6 or 7, wherein the RF millimeter wave is transmitted between the gyro traveling wave amplifier and the RF millimeter antenna repeater amplifier. An integrated circuit that transmits data over a network
With memory configured to store software applications,
An application programming interface (API) configured to allow data access to the software application, and
With clock and synchronization modules,
Network management module and
With a transmitter / receiver configured to transmit and receive radio frequency (RF) millimeter waves,
The integrated circuit is configured to receive data packets via the transmitter / receiver and is further configured to encapsulate the data packets within a fixed cell frame using the software application. Accessed by the data packet using the API, the software application is configured to authenticate the data packet.
Integrated circuit. The integrated circuit of claim 9, wherein the RF millimeter wave has a frequency between 30 GHz and 3300 GHz. The integrated circuit of claim 9 or 10, wherein the transmitter / receiver is further configured to transmit the fixed cell frame to the network. The integrated circuit according to any one of claims 9 to 11, wherein the transmitter / receiver is further configured to transmit the RF millimeter wave between a gyro traveling wave amplifier and an RF millimeter antenna repeater amplifier.