Abstract: A terrestrial communication systems, specifically a signal collision avoidance system between a terrestrial transmitter and an airborne receiver, is disclosed. The terrestrial communication system includes an electronic processor configured to determine a receive frequency from a nearby airborne receiver, determine a transmit frequency from a communicatively coupled terrestrial transmitter, and modify the transmit frequency of the terrestrial transmitter based on the determined receive frequency and transmit frequency. To modify the transmit frequency, the electronic processor compares the receive frequency and the transmit frequency to determine a channel type. Based on the determined channel type, including co-channel and adjacent-channel, the electronic processor modifies a spectrum signature of the transmit frequency so that the transmit frequency does not interfere with the receive frequency of the airborne receiver.

Abstract: A terrestrial communication systems, specifically a signal collision avoidance system between a terrestrial transmitter and an airborne receiver, is disclosed. The terrestrial communication system includes an electronic processor configured to determine a receive frequency from a nearby airborne receiver, determine a transmit frequency from a communicatively coupled terrestrial transmitter, and modify the transmit frequency of the terrestrial transmitter based on the determined receive frequency and transmit frequency. To modify the transmit frequency, the electronic processor compares the receive frequency and the transmit frequency to determine a channel type. Based on the determined channel type, including co-channel and adjacent-channel, the electronic processor modifies a spectrum signature of the transmit frequency so that the transmit frequency does not interfere with the receive frequency of the airborne receiver.

Abstract: A network system for controlling a vehicle speed includes a server, a satellite, and a control device for monitoring and modifying a speed of the vehicle. The server receives information relating to at least one travel condition, calculates a target speed based on the at least one travel condition, and transmits one or more commands indicative of the target speed. The satellite is communicatively coupled to the server and receives the command(s) indicative of the target speed. The control device includes a speed sensor generating a signal indicative of a sensed vehicle speed, a receiver communicatively coupled to the satellite and receiving the command(s) indicative of the target speed, and a controller. The controller calculates a difference between the target speed and the sensed vehicle speed, and modifies operation of a prime mover and/or traction elements to cause the sensed vehicle speed to match the target speed.

Abstract: Systems and methods for exchanging data over a network are described. One method includes receiving, from a computing device via a physical network port, a request to forward network traffic, the request including a network domain identifier and a user identifier. The method includes retrieving, from a database storing user information, a user profile based on the user identifier. The method includes determining whether the traffic forwarding request is valid based on the user profile. The method includes, when the traffic forwarding request is valid, provisioning, on the network, an application service virtual circuit between a local virtual port of a communication interface coupled to the electronic processor and a peer port at a remote communication endpoint. The method includes forwarding the network traffic from the computing device to the remote communication end point via the application service virtual circuit.

Abstract: A system includes a modulator, a beam former, earth equipment, and a spotbeam satellite. The modulator is configured to receive localized content, generate N localized content delivery platform frames from the localized content, and generate intermediate frequency (IF) carriers that are modulated with the N localized content delivery platform frames. The beam former is configured to process the IF carriers to enable beamforming in a satellite service band. The earth equipment is configured to frequency translate the IF carriers that are processed into feederlink signals in a feederlink band, and transmit the feederlink signals. The spotbeam satellite is configured to receive the feederlink signals, generate a multicast transmission by frequency translating the feederlink signals to the satellite service band, and transmit the multicast transmission to form N spotbeams, N being an integer greater than zero.

Abstract: Devices and methods for exchanging data over a network are described. One device includes a communication interface and an electronic processor coupled to the communication interface. The electronic processor is configured to receive, via the communication interface, at least one network message including a payload associated with an IoT device. The electronic processor is configured to retrieve a data exchange policy for the IoT device. The electronic processor is configured to determine whether the payload is valid based on the data exchange policy. The electronic processor is configured to in response to determining that the payload is invalid, process the at least one network message based on the data exchange policy.

Abstract: Systems and methods for exchanging data over a network are described. One method includes receiving, from a computing device via a physical network port, a request to forward network traffic, the request including a network domain identifier and a user identifier. The method includes retrieving, from a database storing user information, a user profile based on the user identifier. The method includes determining whether the traffic forwarding request is valid based on the user profile. The method includes, when the traffic forwarding request is valid, provisioning, on the network, an application service virtual circuit between a local virtual port of a communication interface coupled to the electronic processor and a peer port at a remote communication endpoint. The method includes forwarding the network traffic from the computing device to the remote communication end point via the application service virtual circuit.

Abstract: A system includes a modulator, a beam former, earth equipment, and a spotbeam satellite. The modulator is configured to receive localized content, generate N localized content delivery platform frames from the localized content, and generate intermediate frequency (IF) carriers that are modulated with the N localized content delivery platform frames. The beam former is configured to process the IF carriers to enable beamforming in a satellite service band. The earth equipment is configured to frequency translate the IF carriers that are processed into feederlink signals in a feederlink band, and transmit the feederlink signals. The spotbeam satellite is configured to receive the feederlink signals, generate a multicast transmission by frequency translating the feederlink signals to the satellite service band, and transmit the multicast transmission to form N spotbeams, N being an integer greater than zero.

Abstract: A network system for controlling a vehicle speed includes a server, a satellite, and a control device for monitoring and modifying a speed of the vehicle. The server receives information relating to at least one travel condition, calculates a target speed based on the at least one travel condition, and transmits one or more commands indicative of the target speed. The satellite is communicatively coupled to the server and receives the command(s) indicative of the target speed. The control device includes a speed sensor generating a signal indicative of a sensed vehicle speed, a receiver communicatively coupled to the satellite and receiving the command(s) indicative of the target speed, and a controller. The controller calculates a difference between the target speed and the sensed vehicle speed, and modifies operation of a prime mover and/or traction elements to cause the sensed vehicle speed to match the target speed.

Abstract: A gatekeeper device delegates an ability to access a resource to an access device by transmitting metadata, which includes access information for accessing the resource. The access device uses the metadata to retrieve the associated resource from a resource server. By transmitting the metadata in lieu of the resource, flexible use of the resources is implemented while enabling compliance with various restriction schemes. The system may condition the delegation or transfer of resource access on one or more factors, such as proximity between the gatekeeper device and the access devices. Using information about an access device, the resource server may optimize the resources for the receiving access device.

Abstract: A gatekeeper device delegates an ability to access a resource to an access device by transmitting metadata, which includes access information for accessing the resource. The access device uses the metadata to retrieve the associated resource from a resource server. By transmitting the metadata in lieu of the resource, flexible use of the resources is implemented while enabling compliance with various restriction schemes. The system may condition the delegation or transfer of resource access on one or more factors, such as proximity between the gatekeeper device and the access devices. Using information about an access device, the resource server may optimize the resources for the receiving access device.

Abstract: A gatekeeper device delegates an ability to access a resource to an access device by transmitting metadata, which includes access information for accessing the resource. The access device uses the metadata to retrieve the associated resource from a resource server. By transmitting the metadata in lieu of the resource, flexible use of the resources is implemented while enabling compliance with various restriction schemes. The system may condition the delegation or transfer of resource access on one or more factors, such as proximity between the gatekeeper device and the access devices. Using information about an access device, the resource server may optimize the resources for the receiving access device.

Abstract: A gatekeeper device delegates an ability to access a resource to an access device by transmitting metadata, which includes access information for accessing the resource. The access device uses the metadata to retrieve the associated resource from a resource server. By transmitting the metadata in lieu of the resource, flexible use of the resources is implemented while enabling compliance with various restriction schemes. The system may condition the delegation or transfer of resource access on one or more factors, such as proximity between the gatekeeper device and the access devices. Using information about an access device, the resource server may optimize the resources for the receiving access device.