JP2021530883A - Hosted payload operation - Google Patents

Abstract

Methods for hosted payload operations include sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC) by the Hosted Payload (HoP) Operations Center (HOC). This method also includes sending an encrypted host command and an encrypted hosted command to the transporter by the host SOC. In addition, the method comprises reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command. Further, the method comprises transmitting host payload data to a host receive antenna by means of a host payload antenna. In addition, the method comprises transmitting the hosted payload data to the hosted receiving antenna and / or the hosted receiving antenna by the hosted payload antenna. The method also includes transmitting encrypted host telemetry and encrypted hosted telemetry to the host SOC by a telemetry transmitter on the transporter. Further, the method comprises transmitting encrypted hosted telemetry to the HOC by the host SOC. [Selection diagram] Fig. 2

Description

[0001] The present disclosure relates to payload operations. In particular, the present disclosure relates to hosted payload operations.

[0002] Currently, a typical payload operation of a transporter (eg, a satellite) has the ability to switch between input and output of the payload on the transporter. All of this switching to the payload is commanded and controlled by a single satellite controller with no resource allocation privacy.
Therefore, there is a need for an improved payload operation design that allows privacy in resource allocation to the payload.

The present disclosure relates to methods, systems, and devices for hosted payload operations. In one or more embodiments, the method for hosted payload operations involves sending encrypted hosted commands to the host spacecraft operations center (SOC) by the hosted payload (HoP) Operations Center (HOC). The method also includes sending an encrypted host command and an encrypted hosted command to the transporter by the host SOC. In one or more embodiments, the encrypted host command is encrypted using the first communication security (COMSEC) variety and the encrypted hosted command is encrypted using the second COMSEC variety. In addition, the method comprises decrypting an encrypted host command using a first COMSEC variety by a first communication security module on the transporter to generate an unencrypted host command. Further, the method comprises decrypting an encrypted hosted command using a second COMSEC variety by a second communication security module on the transporter to generate an unencrypted hosted command. The method also includes reconfiguring the host payload on the transporter according to the unencrypted host command. Further, the method comprises reconfiguring the hosted payload on the transporter according to the unencrypted hosted command. In addition, the method comprises transmitting host payload data to the host receive antenna by the host payload antenna on the transporter. The method also includes transmitting the hosted payload data to the hosted receiving antenna and / or the host receiving antenna by the hosted payload antenna on the transporter. In addition, the method encrypts unencrypted host telemetry from the host payload and unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety with the first communication security module, encrypted host telemetry and encryption. Includes producing hosted telemetry. The method also includes transmitting encrypted host telemetry and encrypted hosted telemetry to the host SOC by a telemetry transmitter on the transporter. In addition, the method involves sending encrypted hosted telemetry to the HOC by the host SOC.

In at least one embodiment, reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, and the like. Transponder gain setting, transponder limiter setting, transponder automatic level control setting, transponder phase setting, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one beam, transponder beam forming setting, at least one beam Includes adjusting the effective isotropic radiant power (EIRP), transponder channel, and / or beam steering of the.

In one or more embodiments, reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command is at least one antenna, at least one analog. Digital converter, at least one digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, and / or at least one Includes resetting the digital coupler.

In at least one embodiment, the transporter is a flight transporter. In one or more embodiments, the flight transporter is a satellite, aircraft, unmanned aerial vehicle (UAV), or spacecraft.

In one or more embodiments, the method further comprises encrypting the unencrypted hosted command by the HOC by utilizing a second COMSEC variety to create an encrypted hosted command. Further, the method involves creating an encrypted host command by encrypting the unencrypted host command by the host SOC by utilizing the first COMSEC variety.

In at least one embodiment, the method further comprises receiving an encrypted host command by a host command receiver on the transporter. The method also includes receiving an encrypted hosted command by a hosted command receiver on the transporter. In addition, the method comprises sending an encrypted host command to the first communication security module by the host command receiver. Further, the method comprises transmitting an encrypted hosted command to a second communication security module by a hosted command receiver.

In one or more embodiments, the method further comprises transmitting an unencrypted host command to the host payload by a first communication security module. The method also includes sending an unencrypted hosted command to the hosted payload by a second communication security module.

In at least one embodiment, the method further comprises transmitting unencrypted host telemetry to the first communication security module by means of a host payload. In some embodiments, the method further comprises transmitting unencrypted hosted telemetry to the first communication security module by means of a hosted payload.

In one or more embodiments, the method further comprises transmitting an encrypted host telemetry and an encrypted hosted telemetry to a telemetry transmitter by a first communication security module.

In at least one embodiment, the method decrypts the encrypted host telemetry by the host SOC, utilizing a first COMSEC variety and utilizing a database that does not have hosted information. Further includes generating unencrypted host telemetry. The method also includes decrypting encrypted hosted telemetry and generating unencrypted hosted telemetry by HOC using a first COMSEC variety and using a database that does not have host inverse transformation information.

In one or more embodiments, the method for hosted payload operation involves sending an encrypted hosted command to the Host Spacecraft Operations Center (SOC) by the HOC. The method further comprises sending an encrypted host command and an encrypted hosted command to the transporter by the host SOC. The method also includes decrypting the encrypted host command using the first COMSEC variety by the first communication security module to generate an unencrypted host command. In addition, the method comprises decrypting an encrypted hosted command using a second COMSEC variety by a second communication security module to generate an unencrypted hosted command. In addition, the method involves reconfiguring the host payload according to unencrypted host commands. The method also includes reconfiguring the hosted payload according to an unencrypted hosted command. The method also includes transmitting host payload data to the host receiving antenna by the host payload antenna on the carrier. Further, the method comprises transmitting the hosted payload data to the hosted receiving antenna and / or the host receiving antenna by the hosted payload antenna on the transporter. In addition, the method comprises using a first COMSEC variety to encrypt unencrypted host telemetry and generate encrypted host telemetry by a first communication security module. Further, the method comprises transmitting encrypted host telemetry to the host SOC by a host telemetry transmitter. The method also comprises using a second COMSEC variety to encrypt unencrypted hosted telemetry with a second communication security module to generate encrypted hosted telemetry. In addition, the method comprises transmitting encrypted hosted telemetry to the host SOC by a hosted telemetry transmitter. In addition, the method involves sending encrypted hosted telemetry to the HOC by the host SOC.

In at least one embodiment, the method for hosted payload operation involves sending an encrypted hosted command to the transporter by the Hosted Payload (HoP) Operations Center (HOC). This method further comprises sending an encrypted host command to the transporter by the host SOC. The method also includes decrypting an encrypted host command using a first COMSEC variety by a first communication security module on the transporter to generate an unencrypted host command. In addition, the method comprises decrypting an encrypted hosted command using a second COMSEC variety by a second communication security module on the transporter to generate an unencrypted hosted command. In addition, the method involves reconfiguring the host payload according to unencrypted host commands. In addition, the method involves reconfiguring the hosted payload according to an unencrypted hosted command. The method also includes transmitting host payload data to the host receive antenna by the host payload antenna on the transporter. Further, the method comprises transmitting the hosted payload data to the hosted receiving antenna and / or the host receiving antenna by the hosted payload antenna on the transporter. In addition, the method comprises using a first COMSEC variety to encrypt unencrypted host telemetry and generate encrypted host telemetry by a first communication security module. Further, the method comprises transmitting encrypted host telemetry to the host SOC by a host telemetry transmitter on the transporter. The method also comprises using a second COMSEC variety to encrypt unencrypted hosted telemetry with a second communication security module to generate encrypted hosted telemetry. Further, the method comprises transmitting encrypted hosted telemetry to the HOC by a hosted telemetry transmitter.

In one or more embodiments, the system for hosted payload operations provides a hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC). Be prepared. The system further comprises a host SOC for sending encrypted host commands and encrypted hosted commands to the transporter. In one or more embodiments, the encrypted host command is encrypted using the first communication security (COMSEC) variety and the encrypted hosted command is encrypted using the second COMSEC variety. The system also includes a first communication security module on the transporter for decrypting encrypted host commands and generating unencrypted host commands using the first COMSEC variety. In addition, the system includes a second communication security module on the transporter for decrypting encrypted hosted commands and generating unencrypted hosted commands using a second COMSEC variety. In addition, the system comprises a host payload on the transporter that is reconfigured according to the unencrypted host command. The system also includes a hosted payload on the transporter that is reconfigured according to the unencrypted hosted command. In addition, the system includes a host payload antenna on the transporter for transmitting host payload data to the host receive antenna. In addition, the system comprises a hosted payload antenna on the transporter for transmitting hosted payload data to the hosted receiving antenna and / or the host receiving antenna. The system encrypts the unencrypted host telemetry from the host payload and the unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety to generate the encrypted host telemetry and the encrypted hosted telemetry. It also has a first communication security module. In addition, the system includes a telemetry transmitter on the transporter for transmitting encrypted host telemetry and encrypted hosted telemetry to the host SOC. In addition, the system includes a host SOC for transmitting encrypted hosted telemetry to the HOC.

In at least one embodiment, the system for hosted payload operations comprises a hosted payload (HoP) Operations Center (HOC) for transmitting encrypted hosted commands to the Host Spacecraft Operations Center (SOC). .. The system further comprises a host SOC for sending encrypted host commands and encrypted hosted commands to the transporter. In one or more embodiments, the encrypted host command is encrypted using the first communication security (COMSEC) variety and the encrypted hosted command is encrypted using the second COMSEC variety. The system also includes a first communication security module for decrypting encrypted host commands and generating unencrypted host commands using the first COMSEC variety. In addition, the system includes a second communication security module for decrypting encrypted hosted commands and generating unencrypted hosted commands using a second COMSEC variety. In addition, the system includes a host payload that is reconfigured according to unencrypted host commands. The system also includes a hosted payload that is reconfigured according to unencrypted hosted commands. In addition, the system includes a host payload antenna on the transporter for transmitting host payload data to the host receive antenna. The system also includes a hosted payload antenna on the transporter for transmitting hosted payload data to the hosted receiving antenna and / or the host receiving antenna. In addition, the system comprises a first communication security module for encrypting unencrypted host telemetry using the first COMSEC variety and generating encrypted host telemetry. The system also includes a host telemetry transmitter for transmitting encrypted host telemetry to the host SOC. In addition, the system comprises a second communication security module for encrypting unencrypted hosted telemetry using a second COMSEC variety and generating encrypted hosted telemetry. The system also includes a hosted telemetry transmitter for transmitting encrypted hosted telemetry to the host SOC. In addition, the system includes a host SOC for transmitting encrypted hosted telemetry to the HOC.

In at least one embodiment, the system for hosted payload operations comprises a hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the transporter. The system further comprises a host SOC for sending encrypted host commands to the transporter. In one or more embodiments, the encrypted host command is encrypted using the first communication security (COMSEC) variety and the encrypted hosted command is encrypted using the second COMSEC variety. The system also includes a first communication security module on the transport body for decrypting encrypted host commands and generating unencrypted host commands using a first communication security (COMSEC) variety. In addition, the system includes a second communication security module on the transporter for decrypting encrypted hosted commands and generating unencrypted hosted commands using a second COMSEC variety. In addition, the system includes a host payload that is reconfigured according to unencrypted host commands. The system also includes a hosted payload that is reconfigured according to unencrypted hosted commands. In addition, the system includes a host payload antenna on the transporter for transmitting host payload data to the host receive antenna. In addition, the system comprises a hosted payload antenna on the transporter for transmitting hosted payload data to the hosted receiving antenna and / or the host receiving antenna. The system also includes a first communication security module for encrypting unencrypted host telemetry using the first COMSEC variety and generating encrypted host telemetry. In addition, the system includes a host telemetry transmitter on the transporter for transmitting encrypted host telemetry to the host SOC. The system also includes a second communication security module for encrypting unencrypted hosted telemetry using a second COMSEC variety and generating encrypted hosted telemetry. In addition, the system comprises a hosted telemetry transmitter for transmitting encrypted hosted telemetry to the HOC.

These features, functions, and advantages can be realized individually in the various embodiments of the present disclosure or combined in yet another embodiment.

The above-mentioned features, aspects, and advantages of the present disclosure, as well as other features, aspects, and advantages, are provided in accordance with the following "forms for carrying out the invention", the accompanying claims, and the accompanying drawings. , Will be understood more deeply.

FIG. 5 illustrates a simplified architecture of the disclosed system for hosted payload operations according to at least one embodiment of the present disclosure. According to at least one embodiment of the present disclosure, the host user has an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted (encrypted using the second COMSEC variety). FIG. 5 illustrates a disclosed system for hosted payload operations in which commands are sent to the carrier and both host telemetry and hosted telemetry are encrypted using the first COMSEC variety. According to at least one embodiment of the present disclosure, the host user has an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted (encrypted using the second COMSEC variety). Shows a flow diagram of the disclosed method for hosted payload operations in which commands are sent to the carrier and both host telemetry and hosted telemetry are encrypted using the first COMSEC variety. According to at least one embodiment of the present disclosure, a host user transports an encrypted host command (encrypted using a first COMSEC variety) and an encrypted hosted command (encrypted using a second COMSEC variety). Shows a flow diagram of the disclosed method for hosted payload operations that is transmitted to the body and both the host telemetry and the hosted telemetry are encrypted using the first COMSEC variety. According to at least one embodiment of the present disclosure, a host user transports an encrypted host command (encrypted using a first COMSEC variety) and an encrypted hosted command (encrypted using a second COMSEC variety). Shows a flow diagram of the disclosed method for hosted payload operations that is transmitted to the body and both the host telemetry and the hosted telemetry are encrypted using the first COMSEC variety. According to at least one embodiment of the present disclosure, the host user has an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted (encrypted using the second COMSEC variety). A disclosed system for hosted payload operations that sends commands to the carrier and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. It is a figure which shows. According to at least one embodiment of the present disclosure, the host user has an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted (encrypted using the second COMSEC variety). Of the disclosed method for hosted payload operations, where the command is sent to the transporter and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. The flow chart is shown. According to at least one embodiment of the present disclosure, the host user transports an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted command (encrypted using the second COMSEC variety). A flow diagram of the disclosed method for hosted payload operations that is transmitted to the body and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. show. According to at least one embodiment of the present disclosure, the host user transports an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted command (encrypted using the second COMSEC variety). A flow diagram of the disclosed method for hosted payload operations that is transmitted to the body and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. show. According to at least one embodiment of the present disclosure, the host user transports an encrypted host command (encrypted using the first COMSEC variety) and an encrypted hosted command (encrypted using the second COMSEC variety). A flow diagram of the disclosed method for hosted payload operations that is transmitted to the body and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. show. According to at least one embodiment of the present disclosure, the host user sends an encrypted host command (encrypted using the first COMSEC variety) to the transporter, and the hosted user uses the second COMSEC variety. Hosted payload operation that sends an encrypted hosted command (encrypted) to the transporter, and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. It is a figure which shows the disclosure system for. According to at least one embodiment of the present disclosure, the host user sends an encrypted host command (encrypted using the first COMSEC variety) to the transporter, and the hosted user uses the second COMSEC variety. Hosted payload operation that sends an encrypted hosted command (encrypted) to the transporter, and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. It is a flow chart of the disclosed method for. According to at least one embodiment of the present disclosure, the host user sends an encrypted host command (encrypted using the first COMSEC variety) to the transport, and the hosted user encrypts (encrypted using the second COMSEC variety). Encrypted) For hosted payload operations where the hosted command is sent to the transporter and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. It is a flow chart of the disclosed method. According to at least one embodiment of the present disclosure, the host user sends an encrypted host command (encrypted using the first COMSEC variety) to the transport, and the hosted user encrypts (encrypted using the second COMSEC variety). Encrypted) For hosted payload operations where the hosted command is sent to the transporter and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. It is a flow chart of the disclosed method.

The methods and devices disclosed herein provide an operating system for hosted payload operations. The system of the present disclosure allows a plurality of operators of a transporter to share the transporter's resources privately.

As mentioned above, a typical payload operation of a transporter (eg, a satellite) is now capable of performing switching between input and output of the payload on the transporter. All this switching to the payload is commanded and controlled by a single satellite controller with no resource allocation privacy.

The disclosed system allows for private allocation and control of transporter resources, which allows private, dynamic and demand-based resources (eg, host payload and / or hosted). The ability to distribute the payload) is given to the user of the transporter.

It should be noted that the host payload and / or hosted payload of the disclosed system for private allocation and control of transporter resources may employ a variety of different types of transponders. be. For example, it includes, but is limited to, various different types of digital transponders, various different types of analog transponders (eg, conventional repeater transponders), and combinations of various different types of analog transponders and digital transponders. Not necessarily, various different types of transponders can be used.

In the present disclosure, the in-band frequency band (s) is a frequency band (s) used for transmitting payload data (for example, host payload data and / or hosted payload data). Refers to the same frequency band (s) as above, and the out-of-band frequency band (s) is used for transmitting payload data (for example, host payload data and / or hosted payload data). It should be noted that it refers to a frequency band (s) that are not the same as the frequency band (s).

[0033] In the following description, a number of details are specified to provide a more comprehensive description of the system. However, it will be apparent to those skilled in the art that the disclosed system can be practiced without such specific details. In addition, the well-known features are not explained in detail so as not to make the system unnecessarily confusing.

In this document, embodiments of the present disclosure may be described in terms of functional and / or logical components and various processing steps. It should be recognized that such components can be implemented by any number of hardware, software, and / or firmware components configured to perform a particular function. For example, in one embodiment of the present disclosure, various integrated circuit components (eg, memory elements, digital signal processing elements, logic elements, look-up tables, etc.) may be used, such components being one or more processors. Can perform a wide variety of functions under the control of a microprocessor, or other control device. In addition, one of ordinary skill in the art will recognize that embodiments of the present disclosure may be practiced in collaboration with other components, and that the systems described herein are merely exemplary embodiments of the present disclosure. Will be done.

For the sake of brevity, this document does not elaborate on conventional techniques and components of satellite communication systems, as well as other functional aspects of the system (and the individual operating components of this system). There is. In addition, the various illustrated connection lines contained herein are intended to represent exemplary functional relationships and / or physical connections between the various elements. It should be noted that in one embodiment of the present disclosure, a number of alternative or additional functional associations or physical connections may be presented.

FIG. 1 shows a simplified architecture of the disclosed system for hosted payload operations according to at least one embodiment of the present disclosure. This figure shows a simplified diagram of one of several feasible hosted payload settings. In detail, this figure shows the space segment 110 and the ground segment 120. Space segment 110 represents a transporter. A variety of different types of transporters, including but not limited to flight transporters, can be used as transporters. In addition, a variety of different types of flight transporters can be used as transporters, including but not limited to satellites, aircraft, unmanned aerial vehicles (UAVs), and spacecraft.

It should be noted that when a satellite is used as a transporter, the satellite typically comprises a computer controlled system. Satellites generally include a bus 130 and a payload (eg, a host payload and one or more hosted payloads) 140. Bus 130 may include a system that controls satellites, which includes components. These systems perform tasks such as power generation and power control, thermal control, telemetry, attitude control, orbit control, and other suitable operations.

The satellite payload 140 provides functionality to the satellite user. Payload 140 may include antennas, transponders, and other suitable devices. For example, with respect to communications, satellite payload 140 may be used to provide internet access, telephone communications, radio, television, and other types of communications. It should be noted that in one or more embodiments, the payload 140 includes a plurality of separate payloads (host payload and one or more hosted payloads).

[0039] The payload 140 of the satellite can be used by various entities. For example, the payload 140 may be used by a host user, a hosted user (s), other customers, or any combination thereof.

For example, the host user may lease different parts of the payload (eg, hosted payload (s) 140) to different customers (eg, hosted user (s)). In one example, a group of antenna beams generated by a satellite payload (eg, hosted payload (s) 140) may be leased to one customer, while a second group of antenna beams may be leased to a second customer. .. In another example, a group of antenna beams generated by the satellite payload (eg, host payload) 140 may be available to the satellite host user, while a second of the antenna beams generated by the payload (eg, hosted payload) 140. Group can be leased to a customer (eg, a hosted user). In yet another example, some or all of the antenna beam generated by the satellite payload (eg, hosted payload (s) 140) may be shared by one customer and a second customer. When a satellite is shared by various users, even if a plurality of users have a shared communication link with the satellite (for example, interface A), each user provides an individual communication link with the satellite (for example, interfaces A and D). You may have.

Leasing a satellite to a plurality of customers (eg, hosted users) can increase the revenue that satellite users (eg, host users) can earn. In addition, the customer may use a subset of the satellite's total resources at a cost less than the cost of the customer purchasing and operating the satellite, building and operating the satellite, or leasing the entire satellite.

With reference to FIG. 1 again, the ground segment 120 is a host spacecraft operations center (SOC) (eg, a ground station associated with the control of a satellite's host payload) 150 and one or more hosted payloads (HoP). ) Operations center (HOC (s)) (eg, ground station (s) related to control of satellite hosted payload) 160.

FIG. 1 shows several different feasible communication links (ie, interfaces A to D). It should be noted that the disclosed system may employ some or all of these communication links shown. Interface A, which may include multiple links, is an out-of-band command and telemetry link for commanding the satellite from the host SOC150. Interface B, which may include a plurality of links, is a communication link between the bus 130 and the payload 140. Interface B can be used to control essential items (such as power). Information that can be communicated from bus 130 to payload 140 via interface B can include, but is not limited to, time, position estimation table (ephemeris), and payload commands. Information that can be communicated from the payload 140 to the bus 130 via interface B may include, but is not limited to, payload telemetry.

Interface C, which may include multiple links, is an in-band command and telemetry link for the bus and / or payload. Interface D, which may include multiple links, is a command and telemetry link for commanding the satellite from the HOC (s) 160. Interface E may include multiple links between hosts SOC150 and HOC160.

FIG. 2 shows an encrypted host command (encrypted using a first COMSEC variety) and a (second COMSEC variety) used by a host user (ie, host SOC) 250 according to at least one embodiment of the present disclosure. A disclosed system for hosted payload operations in which an encrypted hosted command (encrypted) is sent to the transporter, and both host telemetry and hosted telemetry are encrypted using the first COMSEC variety. It is FIG. 200 which shows. In this figure, the transporter 210, the host SOC250, and the HOC260 are illustrated.

In the operation, the HOC260 encrypts the unencrypted hosted command (ie, the unencrypted HoP CMD) by utilizing the second COMSEC variety to create the encrypted hosted command (ie, the encrypted HoP CMD). Hosted commands are commands used to configure the hosted payload 205 utilized by HOC260. The host SOC250 encrypts the unencrypted host command (ie, the unencrypted host CMD) by utilizing the first COMSEC variety to create the encrypted host command (ie, the encrypted host CMD). The host command is a command used to set the host payload 206 utilized by the host SOC250.

[0047] In FIG. 2, the terrestrial antenna of the host SOC250 is depicted as being placed immediately next to its operation building, but in other embodiments, the terrestrial antenna of the host SOC250 is far away from its operation building. Note that it may be located (for example, the ground antenna may be located in a different country than the operation building).

It should also be noted that the first COMSEC variety may include at least one encryption key and / or at least one algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm). Furthermore, it should be noted that the second COMSEC variety may include at least one encryption key and / or at least one encryption algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm).

The HOC260 then sends an encrypted hosted command to the host SOC250 215. After receiving the encrypted hosted command, the host SOC 250 transmits the encrypted host command to the transporter 210 220, and also transmits the encrypted hosted command 225. The host SOC250 utilizes an out-of-band frequency band (s) (ie, a frequency band that is not the same as the frequency band used to transmit payload data (s) (s)). 220, 225 to send commands and encrypted hosted commands. The host command receiver 235 on the transporter 210 receives the encrypted host command. In addition, the hosted command receiver 245 on the transporter 210 receives the encrypted hosted command.

The host command receiver 235 then transmits an encrypted host command to the first communication security module 262. The first communication security module 262 uses the first COMSEC variety (that is, COMSEC variety 1) to decrypt the encrypted host command and generate the unencrypted host command.

It should be noted that the first communication security module 262 may include one or more modules. In addition, the first communication security module 262 may include one or more processors.

The hosted command receiver 245 then transmits an encrypted hosted command to the second communication security module 265. The second communication security module 265 uses the second COMSEC variety (that is, COMSEC variety 2) to decrypt the encrypted hosted command and generate the unencrypted hosted command.

It should be noted that the second communication security module 265 may include one or more modules. In addition, the second communication security module 265 may include one or more processors.

The first communication security module 262 then sends an unencrypted host command to the host payload 206 270. The second communication security module 265 sends an unencrypted hosted command to the hosted payload 205 275. The host payload 206 is reconfigured according to the unencrypted host command and the hosted payload 205 is reconfigured according to the unencrypted hosted command. The host payload antenna 207 then transmits host payload data (eg, as one or more antenna beams 208) to the terrestrial host receive antenna 285. The hosted payload antenna 280 then transmits the hosted payload data (eg, as one or more antenna beams 281 and / or 208) to the ground hosted receiving antenna 290 and / or the host receiving antenna 285.

FIG. 2 shows antenna beams 208, 281 including a plurality of circular spot beams, but in other embodiments, the number of antenna beams 208, 281 is greater or less than that shown in FIG. Beams may include (eg, antenna beams 208, 281 may contain only a single beam), and antenna beams 208, 281 may include beams of a different shape than the circular spot beam shown in FIG. It should also be noted (eg, antenna beams 208, 281 may include elliptical beams and / or shaped beams of various different shapes).

[0056] In one or more embodiments, the host payload antenna 207 and the hosted payload antenna 280 may include one or more reflector dishes including, but not limited to, parabolic reflectors and / or molded reflectors. It should be noted. In some embodiments, the host payload antenna 207 and the hosted payload antenna 280 may include one or more multifeed antenna arrays.

[0057] Host payload 206 transmits unencrypted host telemetry (ie, unencrypted host TLM, which is telemetry data associated with payload 206 utilized by host SOC250) to first communication security module 262. .. Hosted payload 205 transmits unencrypted hosted telemetry (ie, unencrypted HoP TLM, which is telemetry data associated with payload 205 utilized by HOC260) to first communication security module 262. The first communication security module 262 then utilizes the first COMSEC variety to encrypt the unencrypted host telemetry and the unencrypted hosted telemetry, and the encrypted telemetry (ie, the encrypted host telemetry and the encrypted hosted telemetry). TLM) is generated.

The first communication security module 262 then transmits the encrypted telemetry to the telemetry transmitter 294 293. The telemetry transmitter 294 then transmits the encrypted telemetry to the host SOC250 295. The telemetry transmitter 294 transmits encrypted telemetry using an out-of-band frequency band (s) 295. The host SOC 250 then utilizes the first COMSEC variety to decrypt the encrypted telemetry and generate the unencrypted telemetry. Host SOC250 then utilizes a database that contains host payload inverse conversion information but not hosted payload inverse conversion information (ie, a database that does not have hosted payload inverse conversion information) to read unencrypted telemetry and payload. Identify telemetry data associated with the portion utilized by the 205 host SOC250.

The host SOC 250 then transmits the encrypted telemetry to the HOC 260 299. The HOC260 then utilizes the first COMSEC variety to decrypt the encrypted telemetry and generate the unencrypted telemetry. The HOC260 then utilizes a database that includes hosted payload inverse conversion information but not host payload inverse conversion information (ie, a database that does not have host payload inverse conversion information) to read unencrypted telemetry and payload 205. Identify the telemetry data associated with the portion utilized by the HOC260.

[0060] FIGS. 3A, 3B, and 3C collectively show an encrypted host command (encrypted using a first COMSEC variety) and a (second COMSEC variety) by a host user according to at least one embodiment of the present disclosure. (Encrypted using) Encrypted hosted commands are sent to the transporter, and both host telemetry and hosted telemetry are encrypted using the first COMSEC variety, disclosure for hosted payload operations. The flow chart of the method is shown. At the beginning 300 of this method, the Hosted Payload (HoP) Operations Center (HOC) encrypts the unencrypted hosted command by utilizing the second COMSEC variety to create the encrypted hosted command 305. The HOC then sends an encrypted hosted command to the Host Spacecraft Operations Center (SOC) 310. The host SOC encrypts the unencrypted host command by using the first COMSEC variety and creates the encrypted host command 315. The host SOC then sends an encrypted host command and an encrypted hosted command to the transporter (out of band) 320.

The host command receiver on the transporter then receives the encrypted host command 325. In addition, the hosted command receiver on the transporter receives the encrypted hosted command 330. The host command receiver sends an encrypted host command to the first communication security module 335. The hosted command receiver sends an encrypted hosted command to the second communication security module 340. The first communication security module then uses the first COMSEC variety to decrypt the encrypted host command and generate the unencrypted host command 345. The second communication security module then utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate the unencrypted hosted command 350.

The first communication security module then sends an unencrypted host command to the host payload 355. The second communication security module then sends an unencrypted hosted command to the hosted payload 360. The host payload is then reconfigured according to the unencrypted host command and the hosted payload is reconfigured according to the unencrypted hosted command 365. The host payload antenna on the carrier then sends the host payload data to the host receive antenna, and the hosted payload antenna on the carrier then sends the hosted payload data to the hosted receive antenna and / or the host receive antenna 370.

The host payload then sends the unencrypted host telemetry to the first communication security module, and the hosted payload sends the unencrypted hosted telemetry to the first communication security module 375. The first communication security module then uses the first COMSEC variety to encrypt the unencrypted host telemetry and the unencrypted hosted telemetry to generate the encrypted host telemetry and the encrypted hosted telemetry 380. The first communication security module then transmits the encrypted host telemetry and the encrypted hosted telemetry to the telemetry transmitter 385. The telemetry transmitter then transmits the encrypted host telemetry and the encrypted hosted telemetry to the host SOC 390. The host SOC then utilizes the first COMSEC variety to decrypt the encrypted host telemetry and generate the unencrypted host telemetry 395.

[0064] The host SOC transmits encrypted hosted telemetry to the HOC 396. The HOC then utilizes the first COMSEC variety to decrypt the encrypted hosted telemetry and generate the unencrypted hosted telemetry 397. Then the method ends 398.

FIG. 4 shows an encrypted host command (encrypted using a first COMSEC variety) and a (second COMSEC variety) used by a host user (ie, host SOC) 450 according to at least one embodiment of the present disclosure. Hosted payload that sends an encrypted hosted command (encrypted) to the carrier, and the host telemetry is encrypted using the first COMSEC variety and the hosted telemetry is encrypted using the second COMSEC variety. FIG. 400 shows a disclosed system for operation. In this figure, the transporter 410, the host SOC450, and the HOC460 are illustrated.

In the operation, the HOC460 encrypts the unencrypted hosted command (ie, the unencrypted HoP CMD) by utilizing the second COMSEC variety to create the encrypted hosted command (ie, the encrypted HoP CMD). Hosted commands are commands used to configure the hosted payload 405 utilized by the HOC460. The host SOC450 encrypts the unencrypted host command (ie, the unencrypted host CMD) by utilizing the first COMSEC variety to create the encrypted host command (ie, the encrypted host CMD). The host command is a command used to configure the host payload 406 utilized by the host SOC450.

[0067] In FIG. 4, the terrestrial antenna of the host SOC450 is depicted as being placed immediately next to its operation building, but in other embodiments, the terrestrial antenna of the host SOC450 is far away from its operation building. It should be noted that the ground antenna may be located in a different country from the operation building (for example, the ground antenna may be located in a different country).

It should also be noted that the first COMSEC variety may include at least one encryption key and / or at least one algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm). Furthermore, it should be noted that the second COMSEC variety may include at least one encryption key and / or at least one encryption algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm).

The HOC460 then sends an encrypted hosted command to the host SOC450 415. After receiving the encrypted hosted command, the host SOC 450 transmits the encrypted host command to the transporter 410, 420, and transmits the encrypted hosted command 425. The host SOC450 utilizes an out-of-band frequency band (s) (that is, a frequency band (s) that is not the same as the frequency band used to transmit payload data (s)). Sending commands and encrypted hosted commands 420, 425. The host command receiver 435 on the transporter 410 receives the encrypted host command. In addition, the hosted command receiver 445 on the transporter 410 receives the encrypted hosted command.

The host command receiver 435 then transmits an encrypted host command to the first communication security module 462. The first communication security module 462 uses the first COMSEC variety (that is, COMSEC variety 1) to decrypt the encrypted host command and generate the unencrypted host command.

It should be noted that the first communication security module 462 may include one or more modules. In addition, the first communication security module 462 may include one or more processors.

The hosted command receiver 445 then transmits an encrypted hosted command to the second communication security module 465. The second communication security module 465 uses the second COMSEC variety (that is, COMSEC variety 2) to decrypt the encrypted hosted command and generate the unencrypted hosted command.

It should be noted that the second communication security module 465 may include one or more modules. In addition, the second communication security module 465 may include one or more processors.

The first communication security module 462 then sends an unencrypted host command to the host payload 406 470. The second communication security module 465 sends an unencrypted hosted command to the hosted payload 405 475. The host payload 406 is reconfigured according to the unencrypted host command and the hosted payload 405 is reconfigured according to the unencrypted hosted command. The host payload antenna 407 then transmits host payload data (eg, as one or more antenna beams 408) to the terrestrial host receive antenna 485. The hosted payload antenna 480 then transmits the hosted payload data (eg, as one or more antenna beams 481 and / or 408) to the ground hosted receiving antenna 490 and / or the host receiving antenna 485.

[0075] FIG. 4 shows antenna beams 408, 481 including a plurality of circular spot beams, but in other embodiments, the number of antenna beams 408, 481 is more or less than that shown in FIG. It can contain a number of beams (eg, antenna beams 408, 481 can contain only a single beam) and can contain beams of a different shape than the circular spot beam shown in FIG. 4 (eg, antennas). It should also be noted that beams 408, 481 may include elliptical beams and / or shaped beams of various different shapes).

[0076] In one or more embodiments, the host payload antenna 407 and the hosted payload antenna 480 may include one or more reflector dishes including, but not limited to, parabolic reflectors and / or molded reflectors. It should be noted that. In some embodiments, the host payload antenna 407 and the hosted payload antenna 480 may include one or more multifeed antenna arrays.

[0077] Host payload 406 transmits unencrypted host telemetry (ie, unencrypted host TLM, which is telemetry data associated with host payload 406 utilized by host SOC450) to first communication security module 462. 491. The first communication security module 462 then utilizes the first COMSEC variety to encrypt the unencrypted host telemetry and generate the encrypted host telemetry (ie, the encrypted host TLM).

[0078] Hosted payload 405 transmits unencrypted hosted telemetry (ie, unencrypted HoP TLM, which is telemetry data associated with payload 405 utilized by HOC460) to the second communication security module 465. The second communication security module 465 then utilizes the second COMSEC variety to encrypt the unencrypted hosted telemetry to generate the encrypted hosted telemetry (ie, the encrypted HoP TLM).

The first communication security module 462 then transmits the encrypted host telemetry to the host telemetry transmitter 494 493. The host telemetry transmitter 494 then transmits the encrypted host telemetry to the host SOC 450 495. The telemetry transmitter 494 transmits encrypted host telemetry using an out-of-band frequency band (s). The host SOC 450 then utilizes the first COMSEC variety to decrypt the encrypted host telemetry and generate the unencrypted host telemetry.

The second communication security module 465 then transmits the encrypted hosted telemetry to the hosted telemetry transmitter 498 496. The hosted telemetry transmitter 498 then transmits the encrypted hosted telemetry to the host SOC 450 497. The telemetry transmitter 498 transmits encrypted hosted telemetry using an out-of-band frequency band (s). Host SOC450 then sends encrypted hosted telemetry to HOC460 499. The HOC460 then utilizes a second COMSEC variety to decrypt encrypted hosted telemetry to generate unencrypted hosted telemetry.

[0081] FIGS. 5A, 5B, 5C, and 5D collectively show an encrypted host command (encrypted using a first COMSEC variety) and an encrypted host command (encrypted using a first COMSEC variety) according to at least one embodiment of the present disclosure. An encrypted hosted command (encrypted using the 2COMSEC variety) is sent to the payload, and the host telemetry is encrypted using the 1st COMSEC variety and the hosted telemetry is encrypted using the 2nd COMSEC variety. The flow diagram of the disclosed method for hosted payload operation is shown. At the start of this method 500, the Hosted Payload (HoP) Operations Center (HOC) encrypts the unencrypted hosted command by utilizing the second COMSEC variety to create the encrypted hosted command 505. The HOC then sends an encrypted hosted command to the Host Spacecraft Operations Center (SOC) 510. The host SOC encrypts the unencrypted host command by using the first COMSEC variety and creates the encrypted host command 515. The host SOC then sends an encrypted host command and an encrypted hosted command to the transporter (out of band) at 520.

Next, the host command receiver on the transporter receives the encrypted host command 525. In addition, the hosted command receiver on the transporter receives the encrypted hosted command 530. The host command receiver sends an encrypted host command to the first communication security module 535. The hosted command receiver sends an encrypted hosted command to the second communication security module 540. The first communication security module then uses the first COMSEC variety to decrypt the encrypted host command and generate the unencrypted host command 545. The second communication security module then utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate the unencrypted hosted command 550.

The first communication security module then sends an unencrypted host command to the host payload 555. The second communication security module then sends an unencrypted hosted command to the hosted payload 560. The host payload is then reconfigured according to the unencrypted host command and the hosted payload is reconfigured according to the unencrypted hosted command 565. The host payload antenna on the carrier then sends the host payload data to the host receive antenna, and the hosted payload antenna on the carrier then sends the hosted payload data to the hosted receive antenna and / or the host receive antenna 570.

The host payload then sends the unencrypted host telemetry to the first communication security module 575. The first communication security module then uses the first COMSEC variety to encrypt the unencrypted host telemetry and generate the encrypted host telemetry 580. The first communication security module then transmits the encrypted host telemetry to the host telemetry transmitter 585. The host telemetry transmitter then transmits the encrypted host telemetry to the host SOC 590. The host SOC then uses the first COMSEC variety to decrypt the encrypted host telemetry and generate the unencrypted host telemetry 591.

The hosted payload transmits unencrypted hosted telemetry to the second communication security module 592. The second communication security module then uses the second COMSEC variety to encrypt the unencrypted hosted telemetry and generate the encrypted hosted telemetry 593. The second communication security module then sends the encrypted hosted telemetry to the hosted telemetry transmitter 594. The hosted telemetry transmitter then transmits the encrypted hosted telemetry to the host SOC 595. The host SOC then sends the encrypted hosted telemetry to the HOC 596. The HOC then utilizes the second COMSEC variety to decrypt the encrypted hosted telemetry to generate the unencrypted hosted telemetry 597. Then the method ends 598.

FIG. 6 shows that the host user (ie, host SOC) 650, according to at least one embodiment of the present disclosure, sends an encrypted host command (encrypted using the first COMSEC variety) to the carrier. The hosted user (ie HOC) 660 sends an encrypted hosted command (encrypted using the second COMSEC variety) to the transporter, and the host telemetry is encrypted using the first COMSEC variety, and the hosted telemetry FIG. 600 shows a disclosed system for hosted payload operations that is encrypted using a second COMSEC variety. In this figure, the transporter 610, the host SOC650, and the HOC660 are illustrated.

In operation, the HOC660 encrypts the unencrypted hosted command (ie, the unencrypted HoP CMD) by utilizing the second COMSEC variety to create the encrypted hosted command (ie, the encrypted HoP CMD). Hosted commands are commands used to configure the hosted payload 605 utilized by the HOC 660. The host SOC650 encrypts the unencrypted host command (ie, the unencrypted host CMD) by utilizing the first COMSEC variety to create the encrypted host command (ie, the encrypted host CMD). The host command is a command used to configure the host payload 606 utilized by the host SOC650.

[0088] In FIG. 6, the terrestrial antenna of the host SOC650 is depicted as being placed immediately next to its operation building, but in other embodiments, the terrestrial antenna of the host SOC650 is far away from its operation building. It should be noted that the ground antenna may be located in a different country from the operation building (for example, the ground antenna may be located in a different country).

It should also be noted that the first COMSEC variety may include at least one encryption key and / or at least one algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm). Furthermore, it should be noted that the second COMSEC variety may include at least one encryption key and / or at least one encryption algorithm (eg, a type 1 encryption algorithm or a type 2 encryption algorithm).

[0090] Host SOC650 sends an encrypted host command to transporter 610 620. The host SOC650 utilizes an out-of-band frequency band (s) (ie, a frequency band that is not the same as the frequency band used to transmit payload data (s) (s)). Send a command 620.

[0091] The HOC 660 sends an encrypted hosted command to the transporter 610 625. The HOC 660 transmits an encrypted hosted command using an out-of-band frequency band (s).

The host command receiver 635 on the transporter 610 receives the encrypted host command. In addition, the hosted command receiver 645 on the transporter 610 receives the encrypted hosted command.

[093] The host command receiver 635 then transmits an encrypted host command to the first communication security module 662, 652. The first communication security module 662 decrypts the encrypted host command by using the first COMSEC variety (that is, COMSEC variety 1) and generates the unencrypted host command.

It should be noted that the first communication security module 662 may include one or more modules. In addition, the first communication security module 662 may include one or more processors.

[0995] The hosted command receiver 645 then transmits an encrypted hosted command to the second communication security module 665. The second communication security module 665 uses the second COMSEC variety (that is, COMSEC variety 2) to decrypt the encrypted hosted command and generate the unencrypted hosted command.

It should be noted that the second communication security module 665 may include one or more modules. In addition, the second communication security module 665 may include one or more processors.

[097] The first communication security module 662 then sends an unencrypted host command to the host payload 606, 670. The second communication security module 665 sends an unencrypted hosted command to the hosted payload 605 675. The host payload 606 is reconfigured according to the unencrypted host command and the hosted payload 605 is reconfigured according to the unencrypted hosted command. The host payload antenna 607 then transmits host payload data (eg, as one or more antenna beams 608) to the terrestrial host receive antenna 685. The hosted payload antenna 680 then transmits the hosted payload data (eg, as one or more antenna beams 681 and / or 608) to the ground hosted receiving antenna 690 and / or the host receiving antenna 685.

FIG. 6 shows antenna beams 608, 681 including a plurality of circular spot beams, but in other embodiments, antenna beams 608, 681 are more or less than those shown in FIG. It can contain a number of beams (eg, antenna beams 608, 681 can contain only a single beam) and can contain beams of a different shape than the circular spot beam shown in FIG. 6 (eg, antennas). It should also be noted that the beams 608, 681 may include elliptical beams and / or shaped beams of various different shapes).

[00099] In one or more embodiments, the host payload antenna 607 and the hosted payload antenna 680 may include one or more reflector dishes including, but not limited to, parabolic reflectors and / or molded reflectors. It should be noted that. In some embodiments, the host payload antenna 607 and the hosted payload antenna 680 may include one or more multifeed antenna arrays.

[00100] Host payload 606 transmits unencrypted host telemetry (ie, unencrypted host TLM, which is telemetry data associated with payload 606 utilized by host SOC650) to first communication security module 662 691. .. The first communication security module 662 then uses the first COMSEC variety to encrypt the unencrypted host telemetry and generate the encrypted host telemetry (ie, the encrypted host TLM).

The hosted payload 605 transmits unencrypted hosted telemetry (ie, unencrypted HoP TLM, which is telemetry data associated with the payload 605 utilized by the HOC 660) to the second communication security module 665. The second communication security module 665 then utilizes the second COMSEC variety to encrypt the unencrypted hosted telemetry to generate the encrypted hosted telemetry (ie, the encrypted HoP TLM).

The first communication security module 662 then transmits the encrypted host telemetry to the host telemetry transmitter 694 693. The host telemetry transmitter 694 then transmits the encrypted host telemetry to the host SOC 650 695. The telemetry transmitter 694 transmits encrypted host telemetry using an out-of-band frequency band (s). The host SOC650 then utilizes the first COMSEC variety to decrypt the encrypted host telemetry and generate the unencrypted host telemetry.

The second communication security module 665 then transmits the encrypted hosted telemetry to the hosted telemetry transmitter 698 696. The hosted telemetry transmitter 698 then transmits the encrypted hosted telemetry to the HOC660 697. The telemetry transmitter 698 transmits encrypted hosted telemetry using an out-of-band frequency band (s). The HOC660 then utilizes a second COMSEC variety to decrypt encrypted hosted telemetry to generate unencrypted hosted telemetry.

[00104] FIGS. 7A, 7B, and 7C collectively transmit an encrypted host command (encrypted using the first COMSEC variety) to the carrier according to at least one embodiment of the present disclosure. The hosted user then sends an encrypted hosted command (encrypted using the second COMSEC variety) to the transporter, the host telemetry is encrypted using the first COMSEC variety, and the hosted telemetry is the second COMSEC variety. Shows a flow diagram of the disclosed method for hosted payload operations, which is encrypted using. At the start of this method 700, the Hosted Payload (HoP) Operations Center (HOC) encrypts the unencrypted hosted command by utilizing the second COMSEC variety to create the encrypted hosted command 705. The HOC then sends an encrypted hosted command to the transporter (out of band) at 710. Host Spacecraft Operations Center (SOC) encrypts unencrypted host commands by utilizing the first COMSEC variety and creates encrypted host commands 715. The host SOC then sends an encrypted host command to the transporter (out of band) at 720.

Next, the host command receiver on the transporter receives the encrypted host command 725. In addition, the hosted command receiver on the transporter receives the encrypted hosted command at 730. The host command receiver sends an encrypted host command to the first communication security module 735. The hosted command receiver sends an encrypted hosted command to the second communication security module 740. The first communication security module then uses the first COMSEC variety to decrypt the encrypted host command and generate the unencrypted host command 745. The second communication security module then utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate the unencrypted hosted command 750.

The first communication security module then sends an unencrypted host command to the host payload 755. The second communication security module then sends an unencrypted hosted command to the hosted payload 760. The host payload is then reconfigured according to the unencrypted host command and the hosted payload is reconfigured according to the unencrypted hosted command 765. The host payload antenna on the carrier then sends the host payload data to the host receive antenna, and the hosted payload antenna on the carrier then sends the hosted payload data to the hosted receive antenna and / or the host receive antenna 770.

The host payload then transmits unencrypted host telemetry to the first communication security module 775. The first communication security module then uses the first COMSEC variety to encrypt the unencrypted host telemetry and generate the encrypted host telemetry 780. The first communication security module then sends the encrypted host telemetry to the host telemetry transmitter 785. The host telemetry transmitter then transmits the encrypted host telemetry to the host SOC 790. The host SOC then uses the first COMSEC variety to decrypt the encrypted host telemetry and generate the unencrypted host telemetry 791.

The hosted payload sends unencrypted hosted telemetry to the second communication security module 792. The second communication security module then uses the second COMSEC variety to encrypt the unencrypted hosted telemetry and generate the encrypted hosted telemetry 793. The second communication security module then sends the encrypted hosted telemetry to the hosted telemetry transmitter 794. The hosted telemetry transmitter then transmits the encrypted hosted telemetry to the HOC 795. The HOC then utilizes a second COMSEC variety to decrypt the encrypted hosted telemetry to produce the unencrypted hosted telemetry 796. Then the method ends 797.

Although specific embodiments have been illustrated and described, it should be understood that the above description is not intended to limit the scope of these embodiments. Although this document discloses and describes embodiments and variations of many aspects of the present disclosure, such disclosure is provided for illustration and illustration purposes only. Therefore, various changes and modifications can be made without departing from the claims.

If the methods described above indicate that certain events occur in a certain order, those skilled in the art benefiting from this disclosure may modify this order, such modifications. It will be recognized that it follows a variant of the disclosure. Moreover, the method can be performed not only partially, if possible, simultaneously in parallel processes, but also continuously. In addition, many or few parts of the method may be implemented.

[00111] Therefore, the embodiment is for exemplifying alternative examples, modifications, and equivalents that may be included in the claims.

Although this document has disclosed certain exemplary embodiments and methods, variations of such embodiments and methods will not deviate from the above disclosures without departing from the essence and scope of the disclosed technical field. And it can be obvious to those skilled in the art that modifications can be made. There are many other examples in the disclosed technical field, and each example differs from the others only in its details. Therefore, the disclosed technology is intended to be limited only to the extent required by the accompanying claims and the rules and principles of applicable law.

[00111] Therefore, the embodiment is for exemplifying alternative examples, modifications, and equivalents that may be included in the claims. The present invention also includes aspects described below.
(Aspect 1)
A method for hosted payload operations,
Sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC) through the Hosted Payload (HoP) Operations Center (HOC),
By transmitting the encrypted host command and the encrypted hosted command to the transporter by the host SOC.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, to be sent to the transporter.
The first communication security module on the transporter uses the first COMSEC variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module on the transporter utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
To reconfigure the host payload on the transporter according to the unencrypted host command,
Reconfiguring the hosted payload on the transporter according to the unencrypted hosted command,
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry from the host payload and the unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety, and the encrypted host telemetry and the encrypted hosted. Generating telemetry and
The telemetry transmitter on the transporter transmits the encrypted host telemetry and the encrypted hosted telemetry to the host SOC.
Including transmitting the encrypted hosted telemetry to the HOC by the host SOC.
Method.
(Aspect 2)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. The method of aspect 1, comprising adjusting at least one of at least one effective isotropic radiant power (EIRP), transponder channel, or beam steering of one beam.
(Aspect 3)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. The method according to aspect 1, comprising resetting one.
(Aspect 4)
The method according to aspect 1, wherein the transporter is a flight transporter.
(Aspect 5)
The method of aspect 4, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft.
(Aspect 6)
The HOC encrypts the unencrypted hosted command by utilizing the second COMSEC variety to create the encrypted hosted command.
The method according to aspect 1, further comprising encrypting the unencrypted host command by the host SOC by utilizing the first COMSEC variety to create the encrypted host command.
(Aspect 7)
Receiving the encrypted host command by the host command receiver on the transporter
Receiving the encrypted hosted command by the hosted command receiver on the transporter
Sending the encrypted host command to the first communication security module by the host command receiver, and
The method of aspect 1, further comprising transmitting the encrypted hosted command to the second communication security module by the hosted command receiver.
(Aspect 8)
Sending the unencrypted host command to the host payload by the first communication security module, and
The method of aspect 1, further comprising transmitting the unencrypted hosted command to the hosted payload by the second communication security module.
(Aspect 9)
By transmitting the unencrypted host telemetry to the first communication security module by the host payload,
The method of aspect 1, further comprising transmitting the unencrypted hosted telemetry to the first communication security module by the hosted payload.
(Aspect 10)
The method according to aspect 1, further comprising transmitting the encrypted host telemetry and the encrypted hosted telemetry to the telemetry transmitter by the first communication security module.
(Aspect 11)
Decrypting the encrypted host telemetry and generating the unencrypted host telemetry by the host SOC using the first COMSEC variety and using a database having no hosted inverse transformation information.
Further, by the HOC, the encrypted hosted telemetry is decrypted and the unencrypted hosted telemetry is generated by utilizing the first COMSEC variety and using a database having no host inverse transformation information. The method according to aspect 1, comprising.
(Aspect 12)
A method for hosted payload operations,
Sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC) through the Hosted Payload (HoP) Operations Center (HOC),
By transmitting the encrypted host command and the encrypted hosted command to the transporter by the host SOC.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, to be sent to the transporter.
The first communication security module uses the first COMSEC variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module uses the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
Reconfiguring the host payload according to the unencrypted host command
Reconfiguring the hosted payload according to the unencrypted hosted command
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry by utilizing the first COMSEC variety to generate the encrypted host telemetry.
To transmit the encrypted host telemetry to the host SOC by the host telemetry transmitter,
The second communication security module encrypts the unencrypted hosted telemetry by utilizing the second COMSEC variety to generate the encrypted hosted telemetry.
Sending the encrypted hosted telemetry to the host SOC by a hosted telemetry transmitter and
Including transmitting the encrypted hosted telemetry to the HOC by the host SOC.
Method.
(Aspect 13)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. 12. The method of aspect 12, comprising adjusting at least one of at least one effective isotropic radiation power (EIRP), transponder channel, or beam steering of one beam.
(Aspect 14)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. The method of aspect 12, comprising resetting one.
(Aspect 15)
The method according to aspect 12, wherein the transporter is a flight transporter.
(Aspect 16)
The method of aspect 15, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft.
(Aspect 17)
A method for hosted payload operations,
Sending encrypted hosted commands to the transporter by the Hosted Payload (HoP) Operations Center (HOC) and
Including sending an encrypted host command to the transporter by the Host Spacecraft Operations Center (SOC).
The encrypted host command is encrypted using the first communication security (COMSEC) variety, the encrypted hosted command is encrypted using the second COMSEC variety, and further.
The first communication security module on the transporter uses the first communication security (COMSEC) variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module on the transporter utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
Reconfiguring the host payload according to the unencrypted host command
Reconfiguring the hosted payload according to the unencrypted hosted command
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry by utilizing the first COMSEC variety to generate the encrypted host telemetry.
The host telemetry transmitter on the transporter transmits the encrypted host telemetry to the host SOC.
The second communication security module encrypts the unencrypted hosted telemetry by utilizing the second COMSEC variety to generate the encrypted hosted telemetry.
The hosted telemetry transmitter comprises transmitting the encrypted hosted telemetry to the HOC.
Method.
(Aspect 18)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. 17. The method of aspect 17, comprising adjusting at least one of at least one effective isotropic radiant power (EIRP), transponder channel, or beam steering of one beam.
(Aspect 19)
Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. 17. The method of aspect 17, comprising resetting one.
(Aspect 20)
The transporter is a flight transporter
The method of aspect 17, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft.
(Aspect 21)
A system for hosted payload operations
A hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC).
The host SOC sends an encrypted host command and the encrypted hosted command to the transporter.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, HOC and
A first communication security module on the transporter for decrypting the encrypted host command and generating an unencrypted host command using the first COMSEC variety.
A second communication security module on the transporter for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
The host payload on the transporter, which is reconfigured according to the unencrypted host command,
With the hosted payload on the transporter, which is reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry from the host payload and the unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety, and encrypts the encrypted host telemetry and encryption. Hosted telemetry is generated and the system further
A telemetry transmitter on the transporter for transmitting the encrypted host telemetry and the encrypted hosted telemetry to the host SOC.
The host SOC transmits the encrypted hosted telemetry to the HOC.
system.
(Aspect 22)
A system for hosted payload operations
A hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC).
The host SOC sends an encrypted host command and the encrypted hosted command to the transporter.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, HOC and
A first communication security module for decrypting the encrypted host command and generating an unencrypted host command using the first COMSEC variety.
A second communication security module for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
With the host payload reconfigured according to the unencrypted host command,
With the hosted payload reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module uses the first COMSEC variety to encrypt unencrypted host telemetry to generate encrypted host telemetry, and the system further adds.
A host telemetry transmitter for transmitting the encrypted host telemetry to the host SOC is provided.
The second communication security module uses a second COMSEC variety to encrypt unencrypted hosted telemetry to generate encrypted hosted telemetry, and the system further
A hosted telemetry transmitter for transmitting the encrypted hosted telemetry to the host SOC is provided.
The host SOC transmits the encrypted hosted telemetry to the HOC.
system.
(Aspect 23)
A system for hosted payload operations
With the Hosted Payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the transporter,
Equipped with a host spacecraft operation center (SOC) for sending encrypted host commands to the transporter
The encrypted host command is encrypted using a first communication security (COMSEC) variety, the encrypted hosted command is encrypted using a second COMSEC variety, and the system is further enhanced.
A first communication security module on the transporter for decrypting the encrypted host command and generating an unencrypted host command using the first communication security (COMSEC) variety.
A second communication security module on the transporter for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
With the host payload reconfigured according to the unencrypted host command,
With the hosted payload reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module uses the first COMSEC variety to encrypt unencrypted host telemetry to generate encrypted host telemetry, and the system further adds.
A host telemetry transmitter on the transporter for transmitting the encrypted host telemetry to the host SOC.
The second communication security module uses the second COMSEC variety to encrypt unencrypted hosted telemetry to generate encrypted hosted telemetry.
The host telemetry transmitter transmits the encrypted hosted telemetry to the HOC.
system.

Claims (23)

A method for hosted payload operations,
Sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC) through the Hosted Payload (HoP) Operations Center (HOC),
By transmitting the encrypted host command and the encrypted hosted command to the transporter by the host SOC.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, to be sent to the transporter.
The first communication security module on the transporter uses the first COMSEC variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module on the transporter utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
To reconfigure the host payload on the transporter according to the unencrypted host command,
Reconfiguring the hosted payload on the transporter according to the unencrypted hosted command,
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry from the host payload and the unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety, and the encrypted host telemetry and the encrypted hosted. Generating telemetry and
The telemetry transmitter on the transporter transmits the encrypted host telemetry and the encrypted hosted telemetry to the host SOC.
Including transmitting the encrypted hosted telemetry to the HOC by the host SOC.
Method. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. The method of claim 1, comprising adjusting at least one of at least one effective isotropic radiant power (EIRP), transponder channel, or beam steering of one beam. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. The method of claim 1, comprising resetting one. The method according to claim 1, wherein the transporter is a flight transporter. The method of claim 4, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft. The HOC encrypts the unencrypted hosted command by utilizing the second COMSEC variety to create the encrypted hosted command.
The method of claim 1, further comprising encrypting the unencrypted host command by the host SOC by utilizing the first COMSEC variety to create the encrypted host command. Receiving the encrypted host command by the host command receiver on the transporter
Receiving the encrypted hosted command by the hosted command receiver on the transporter
Sending the encrypted host command to the first communication security module by the host command receiver, and
The method of claim 1, further comprising transmitting the encrypted hosted command to the second communication security module by the hosted command receiver. Sending the unencrypted host command to the host payload by the first communication security module, and
The method of claim 1, further comprising transmitting the unencrypted hosted command to the hosted payload by the second communication security module. By transmitting the unencrypted host telemetry to the first communication security module by the host payload,
The method of claim 1, further comprising transmitting the unencrypted hosted telemetry to the first communication security module by the hosted payload. The method of claim 1, further comprising transmitting the encrypted host telemetry and the encrypted hosted telemetry to the telemetry transmitter by the first communication security module. Decrypting the encrypted host telemetry and generating the unencrypted host telemetry by the host SOC using the first COMSEC variety and using a database that does not have hosted inverse transformation information.
Further, by the HOC, the encrypted hosted telemetry is decrypted and the unencrypted hosted telemetry is generated by utilizing the first COMSEC variety and using a database having no host inverse transformation information. The method according to claim 1, which includes. A method for hosted payload operations,
Sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC) through the Hosted Payload (HoP) Operations Center (HOC),
By transmitting the encrypted host command and the encrypted hosted command to the transporter by the host SOC.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, to be sent to the transporter.
The first communication security module uses the first COMSEC variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module uses the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
Reconfiguring the host payload according to the unencrypted host command
Reconfiguring the hosted payload according to the unencrypted hosted command
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry by utilizing the first COMSEC variety to generate the encrypted host telemetry.
To transmit the encrypted host telemetry to the host SOC by the host telemetry transmitter,
The second communication security module encrypts the unencrypted hosted telemetry by utilizing the second COMSEC variety to generate the encrypted hosted telemetry.
Sending the encrypted hosted telemetry to the host SOC by a hosted telemetry transmitter and
Including transmitting the encrypted hosted telemetry to the HOC by the host SOC.
Method. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. 12. The method of claim 12, comprising adjusting at least one of at least one effective isotropic radiant power (EIRP), transponder channel, or beam steering of one beam. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. The method of claim 12, comprising resetting one. 12. The method of claim 12, wherein the transporter is a flight transporter. 15. The method of claim 15, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft. A method for hosted payload operations,
Sending encrypted hosted commands to the transporter by the Hosted Payload (HoP) Operations Center (HOC) and
Including sending an encrypted host command to the transporter by the Host Spacecraft Operations Center (SOC).
The encrypted host command is encrypted using the first communication security (COMSEC) variety, the encrypted hosted command is encrypted using the second COMSEC variety, and further.
The first communication security module on the transporter uses the first communication security (COMSEC) variety to decrypt the encrypted host command and generate an unencrypted host command.
The second communication security module on the transporter utilizes the second COMSEC variety to decrypt the encrypted hosted command and generate an unencrypted hosted command.
Reconfiguring the host payload according to the unencrypted host command
Reconfiguring the hosted payload according to the unencrypted hosted command
The host payload antenna on the transporter transmits the host payload data to the host receiving antenna.
The hosted payload antenna on the transporter transmits the hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry by utilizing the first COMSEC variety to generate the encrypted host telemetry.
The host telemetry transmitter on the transporter transmits the encrypted host telemetry to the host SOC.
The second communication security module encrypts the unencrypted hosted telemetry by utilizing the second COMSEC variety to generate the encrypted hosted telemetry.
The hosted telemetry transmitter comprises transmitting the encrypted hosted telemetry to the HOC.
Method. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be transponder power, transponder spectrum monitoring, transponder connection, transponder gain setting, transponder limiter. Settings, transponder automatic level control settings, transponder phase settings, internal gain generation, at least one beam bandwidth, at least one frequency band of at least one of the at least one beam, transponder beam forming settings, at least the above. 17. The method of claim 17, comprising adjusting at least one of at least one effective isotropic radiant power (EIRP), transponder channel, or beam steering of one beam. Reconfiguring the host payload according to the unencrypted host command and reconfiguring the hosted payload according to the unencrypted hosted command can be at least one antenna, at least one analog-to-digital converter, at least one. At least one of a digital-to-analog converter, at least one beamformer, at least one digital channelizer, at least one demodulator, at least one modulator, at least one digital switch matrix, or at least one digital coupler. The method of claim 17, comprising resetting one. The transporter is a flight transporter
17. The method of claim 17, wherein the flight transporter is one of a satellite, an aircraft, an unmanned aerial vehicle (UAV), or a spacecraft. A system for hosted payload operations
A hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC).
The host SOC sends an encrypted host command and the encrypted hosted command to the transporter.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, HOC and
A first communication security module on the transporter for decrypting the encrypted host command and generating an unencrypted host command using the first COMSEC variety.
A second communication security module on the transporter for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
The host payload on the transporter, which is reconfigured according to the unencrypted host command,
With the hosted payload on the transporter, which is reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module encrypts the unencrypted host telemetry from the host payload and the unencrypted hosted telemetry from the hosted payload by utilizing the first COMSEC variety, and encrypts the encrypted host telemetry and encryption. Hosted telemetry is generated and the system further
A telemetry transmitter on the transporter for transmitting the encrypted host telemetry and the encrypted hosted telemetry to the host SOC.
The host SOC transmits the encrypted hosted telemetry to the HOC.
system. A system for hosted payload operations
A hosted payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the Host Spacecraft Operations Center (SOC).
The host SOC sends an encrypted host command and the encrypted hosted command to the transporter.
The encrypted host command is encrypted using the first communication security (COMSEC) variety, and the encrypted hosted command is encrypted using the second COMSEC variety, HOC and
A first communication security module for decrypting the encrypted host command and generating an unencrypted host command using the first COMSEC variety.
A second communication security module for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
With the host payload reconfigured according to the unencrypted host command,
With the hosted payload reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module uses the first COMSEC variety to encrypt unencrypted host telemetry to generate encrypted host telemetry, and the system further adds.
A host telemetry transmitter for transmitting the encrypted host telemetry to the host SOC is provided.
The second communication security module uses a second COMSEC variety to encrypt unencrypted hosted telemetry to generate encrypted hosted telemetry, and the system further
A hosted telemetry transmitter for transmitting the encrypted hosted telemetry to the host SOC is provided.
The host SOC transmits the encrypted hosted telemetry to the HOC.
system. A system for hosted payload operations
With the Hosted Payload (HoP) Operations Center (HOC) for sending encrypted hosted commands to the transporter,
Equipped with a host spacecraft operation center (SOC) for sending encrypted host commands to the transporter
The encrypted host command is encrypted using a first communication security (COMSEC) variety, the encrypted hosted command is encrypted using a second COMSEC variety, and the system is further enhanced.
A first communication security module on the transporter for decrypting the encrypted host command and generating an unencrypted host command using the first communication security (COMSEC) variety.
A second communication security module on the transporter for decrypting the encrypted hosted command and generating an unencrypted hosted command using the second COMSEC variety.
With the host payload reconfigured according to the unencrypted host command,
With the hosted payload reconfigured according to the unencrypted hosted command,
A host payload antenna on the transporter for transmitting host payload data to the host receiving antenna,
A hosted payload antenna on the transporter for transmitting hosted payload data to at least one of the hosted receiving antenna and the host receiving antenna.
The first communication security module uses the first COMSEC variety to encrypt unencrypted host telemetry to generate encrypted host telemetry, and the system further adds.
A host telemetry transmitter on the transporter for transmitting the encrypted host telemetry to the host SOC.
The second communication security module uses the second COMSEC variety to encrypt unencrypted hosted telemetry to generate encrypted hosted telemetry.
The host telemetry transmitter transmits the encrypted hosted telemetry to the HOC.
system.

Images