Abstract: Methods and systems for unmanned aerial vehicles are provided. One method includes receiving, by a control system, sensor data from a mobile ground-based platform and sensor data from a ground-based radar surveillance system, the control system configured to communicate with a first UAV and a second UAV; detecting, by the control system, an object likely to impede the second UAV flight within a flight path, the object detected based on the sensor data received from the mobile ground-based platform, the ground-based radar surveillance system or both the ground-based radar surveillance system and the mobile ground-based platform; generating, by the control system, an indicator indicating an object in the flight path; and transmitting, by the control system, the indicator to the first UAV.

Abstract: A communications ecosystem and related methods of operation include an ecosystem safety level (ESL), a plurality of vehicles or systems, each vehicle or system having an individual safety level (ISL), a control system operable to determine whether the ISL for each vehicle or system meets or exceeds the ESL, and one or more communications links between any first vehicle or system having a first ISL that does not meet or exceed the ESL and a second vehicle or system with a second ISL that does meet or exceed the ESL such that the first vehicle or system operates at the second ISL.

Abstract: A communications ecosystem and related methods of operation include an ecosystem safety level (ESL), a plurality of vehicles or systems, each vehicle or system having an individual safety level (ISL), a control system operable to determine whether the ISL for each vehicle or system meets or exceeds the ESL, and one or more communications links between any first vehicle or system having a first ISL that does not meet or exceed the ESL and a second vehicle or system with a second ISL that does meet or exceed the ESL such that the first vehicle or system operates at the second ISL.

Abstract: Methods and systems for unmanned aerial vehicles are provided. One method includes receiving, by a control system, sensor data from a mobile ground-based platform and sensor data from a ground-based radar surveillance system, the control system configured to communicate with a first UAV and a second UAV; detecting, by the control system, an object likely to impede the second UAV flight within a flight path, the object detected based on the sensor data received from the mobile ground-based platform, the ground-based radar surveillance system or both the ground-based radar surveillance system and the mobile ground-based platform; generating, by the control system, an indicator indicating an object in the flight path; and transmitting, by the control system, the indicator to the first UAV.

Abstract: An unmanned aerial system (UAS) position reporting system may include an air traffic control reporting system (ATC-RS) coupled with a ground control station (GCS) of a UAS and at least one remote terminal. The ATC-RS may include an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) transceiver and one or more telecommunications modems. The ATC-RS may receive position data of at least one UAS in an airspace from the GCS and the at least one remote terminal and selectively communicate the position of the at least one UAS in the airspace to a civilian air traffic control center (ATC), to a military command and control (C2) communication center, or to both through the ADS-B and TIS-B transceiver. The ATC-RS may display the position of the at least one UAS in the airspace on a display screen coupled with the ATC-RS.

Abstract: Bi-directional personal communication systems and processes may be utilized to control unmanned systems. Such systems and processes may enable operator interface with unmanned systems as a replacement or a supplement to use of specialized hardware and rich, graphical interfaces. The bi-directional communication systems and methods also may be integrated as a subsystem within a ground control station. The system may include a personal communications device with a native interface for an operator to select command, control and/or communication (C3) messages to interact with the unmanned system, and a communication link operable to send the C3 messages selected by the operator to the unmanned system, wherein the unmanned system includes a receiver that receives the C3 messages over the communication link and an onboard computing device that processes and responds to the C3 messages received by the receiver.

Abstract: An unmanned aerial system (UAS) position reporting system may include an air traffic control reporting system (ATC-RS) coupled with a ground control station (GCS) of a UAS and at least one network-connected remote terminal. The ATC-RS may include an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) transceiver and one or more telecommunications modems. The ATC-RS may receive position data of at least one UAS in an airspace from the GCS and the at least one network-connected remote terminal and selectively communicate the position of the at least one UAS in the airspace to a civilian air traffic control center (ATC), to a military command and control (C2) communication center, or to both through the ADS-B and TIS-B transceiver. The ATC-RS may display the position of the at least one UAS in the airspace on a display screen coupled with the ATC-RS.

Abstract: An unmanned aerial system (UAS) position reporting system may include an air traffic control reporting system (ATC-RS) coupled with a ground control station (GCS) of an unmanned aerial system. The ATC-RS may include an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) transceiver and one or more telecommunications modems. The ATC-RS may be adapted to receive position data of the UAS in an airspace from the GCS and to selectively communicate the position of the UAS in the airspace to a civilian air traffic control center (ATC), to a military command and control (C2) communication center, or to both the civilian ATC and the military C2 communication center through the ADS-B and TIS-B transceiver. The ATC-RS may also be adapted to display the position of the UAS in the airspace on a display screen coupled with the ATC-RS.

Abstract: In various implementations, systems and processes may be utilized to reduce the affect of latency in teleoperated cameras. For example, various processes may be utilized to determine latency periods and generate user interfaces based on the latency periods and/or inputs provided to the systems.

Abstract: Systems and methods for communication in enclosed areas. Implementations may include a high-frequency (HF) conversion side including an HF modulator and HF demodulator which is coupled with an HF antenna. A medium-frequency (MF) conversion side including an MF modulator and an MF demodulator which is coupled with an MF antenna may also be included. The HF conversion side may be coupled to the MF conversion side at the HF demodulator and the HF modulator. The HF conversion side may be physically separate from the MF conversion side.

Abstract: An unmanned aerial system (UAS) position reporting system may include an air traffic control reporting system (ATC-RS) coupled with a ground control station (GCS) of an unmanned aerial system. The ATC-RS may include an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) transceiver and one or more telecommunications modems. The ATC-RS may be adapted to receive position data of the UAS in an airspace from the GCS and to selectively communicate the position of the UAS in the airspace to a civilian air traffic control center (ATC), to a military command and control (C2) communication center, or to both the civilian ATC and the military C2 communication center through the ADS-B and TIS-B transceiver. The ATC-RS may also be adapted to display the position of the UAS in the airspace on a display screen coupled with the ATC-RS.

Abstract: Methods of communicating the location of an unmanned aerial system (UAS). Implementations of the method may include receiving position data for a UAS with an air traffic control reporting system (ATC-RS) from a ground control station (GCS) in communication with the UAS, where the ATC-RS and the GCS are coupled together and located on the ground. The method may include transmitting the position data using one or more telecommunication modems included in the ATC-RS to an air traffic control center (ATC) and transmitting the position data using an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) receiver to one or more aircraft.

Abstract: An unmanned aerial system (UAS) position reporting system. Implementations may include an air traffic control reporting system (ATC-RS) coupled with a ground control station (GCS) of an unmanned aerial system where the ATC-RS includes an automatic dependent surveillance broadcast (ADS-B) and a traffic information services broadcast (TIS-B) transceiver and one or more telecommunications modems. The ATC-RS may be adapted to receive position data of the UAS in an airspace from the GCS and communicate the position of the UAS in the airspace to a civilian air traffic control center (ATC) or to a military command and control (C2) communication center through an ADS-B signal or through a TIS-B signal through the ADS-B and TIS-B transceiver. The ATC-RS may also be adapted to display the position of the UAS in the airspace on one or more display screens coupled with the ATC-RS.

Abstract: An omnidirectional antenna system. Implementations may include an antenna having a wire loop and a single ferrite rod loop. The single ferrite rod loop may be oriented substantially parallel to a plane formed by the wire loop. The single ferrite rod loop may include a plurality of windings and a ferrite rod having a length and two ends. The two ends of the ferrite rod may be substantially centered relative to the wire loop. The plurality of windings may be distributed across a majority of the length of the ferrite rod.

Abstract: Methods of communicating the location of an unmanned aerial system (UAS). Implementations of the method may include receiving position data for a UAS with an air traffic control reporting system (ATC-RS) from a ground control station (GCS) in communication with the UAS, where the ATC-RS and the GCS are coupled together and located on the ground. The method may include transmitting the position data using one or more telecommunication modems included in the ATC-RS to an air traffic control center (ATC) and transmitting the position data using an automatic dependent surveillance broadcast (ADS-B) and traffic information services broadcast (TIS-B) receiver to one or more aircraft.