Abstract: A system includes a remotely-operated ground vehicle having first and second lift members, a first lift mechanism coupled to the first lift member, and a second lift mechanism coupled to the second lift member, where the first and second lift mechanisms are positioned at different angles with respect to a ground surface. The first and second lift members may be positioned at opposite sides of a front end of the vehicle and may be controlled by a single motor. The lift mechanisms may have a body portion including first and second prongs separated by an opening, with a plurality of magnets embedded within the body portion near the intersection of the first and second prongs. A communication relay may be secured to each lift mechanism via the opening and a magnetic coupling between the magnets embedded within the body portion and magnets embedded within the communication relay.

Abstract: A system includes a first drive module connected to a first end of a linkage arm and a second drive module connected to a second end of the linkage arm. Two magnetic wheels are connected to each of the first and second drive modules. The first and second drive modules may be independently controlled or controlled using a coordinated controller. The linkage arm may include a first linkage arm portion having at least one degree of freedom with respect to a connected second linkage arm portion, which may be connected via a hinged or ball-joint connection. One or both ends of the linkage arm may have at least one degree of freedom with respect to its respectively connected drive module. Additional linkage arms and drive modules may be connected to form a multi-segment system.

Abstract: In one preferred embodiment, the present invention provides an adaptive electronic camouflage platform comprising electronic paper panels conformed to the exterior surface of the vehicle; one or more cameras for sampling images of the local environment surrounding the platform; and a processor for analyzing the sampled images, generating synthesized camouflage patterns corresponding to the sampled images and controlling the display of the synthesized camouflage patterns on the electronic paper panels.

Abstract: A method of maintaining an ad hoc communications network between a base and a mobile platform as the mobile platform moves over a surface comprising the following steps: providing a radio relay device; physically coupling a deployer to the mobile platform, wherein the deployer is configured to releasably stow the radio relay device; sending video data from the mobile platform to the base; monitoring the strength of a network signal received over time at the mobile platform and issuing a weak-link warning when the highest signal strength received at the mobile platform drops below a threshold value; calculating video throughput data metrics based on video data received at the base over time, and issuing an imminent link-failure alert when the metrics reach a predefined condition; and deploying the relay device from the deployer to the surface after the weak-link warning and the imminent link-failure alert are issued.

Abstract: A method involves using a first lift mechanism coupled to a remotely-operated ground vehicle to engage a first communication relay and position it at a first angle above a ground surface. A second lift mechanism coupled to the remotely-operated ground vehicle is then used to engage a second communication relay. With a single motion by the remotely-operated ground vehicle, the second communication relay is positioned at a second angle above the ground surface and the first communication relay at a third angle above the ground surface. The third angle is greater than both the first angle and the second angle. The second angle is greater than or equal to the first angle. The first communication relay may then be deployed by the remotely-operated ground vehicle at a first location and the second communication relay may be deployed at a second location.

Abstract: A relay device deployment system comprising: a deployer configured to be mounted on a mobile platform; a node radio mounted to the deployer; a self-righting, self-contained, wireless relay device releasably stowed in the deployer, a deployment mechanism mounted to the deployer; and a processor mounted inside the deployer. The processor is operatively coupled to the node radio and the deployment mechanism. The node radio is configured to operate as a node in the network. The deployment mechanism is configured to deploy the relay device. The processor is configured to monitor the network's strength and to send a signal to the deployment mechanism to deploy the relay device when the network strength drops below a threshold value. The relay device comprises an extendable antenna. The relay device is configured to be deployed from the deployer to a support surface and to operate as a node in an ad hoc telecommunications network.

Abstract: A relay apparatus comprising a housing having a bottom surface, a radio, and a processor, both mounted within the housing. A self-righting mechanism is mounted to the housing such that the self-righting mechanism is configured to reposition the housing from any initial position to an upright position so that the housing rests on the bottom surface. The radio is configured to relay RF signals and to operate as a node in an ad hoc telecommunications network. The processor is operatively coupled to the radio and the self-righting mechanism.

Abstract: A radio relay comprising: a housing configured to be released from a mobile platform onto a support surface; a radio mounted within the housing, wherein the radio is configured to relay radio frequency (RF) signals and to operate as a node in a telecommunications network; a first antenna mast having a proximal end and a distal end, wherein the proximal end is rotatably coupled to the housing; a first antenna element operatively coupled to the radio and mechanically coupled to the distal end; and an antenna mast rotation mechanism mounted within the housing and the proximal end such that the antenna mast rotation mechanism is configured to upwardly rotate the first antenna mast to a raised position such that the first antenna mast is substantially parallel to the ambient gravity vector.

Abstract: A system includes a first device having a first transceiver and a first device electrode pair connected to the first transceiver, and a second device having a second transceiver and a second device electrode pair connected to the second transceiver. The second device electrode pair is located relative to the first device electrode pair such that the first device electrode pair and the second device electrode pair form a capacitive network. The first transceiver and second transceiver are each configured to receive a plurality of bits, encode each bit of the plurality of bits, and DC balance and transmit each of the plurality of encoded bits over the capacitive network. Methods for use with the system are provided for encoding and transmitting data, as well as receiving and decoding the encoded data.

Abstract: A system includes a substrate having a first side and a second side, more than one optical sources, wherein at least one optical source is coupled to the first side and at least one optical source is coupled to the second side, a power source operatively connected to the optical sources, a switch connected to the power source, and an RF receiver connected to the switch. The optical sources may be LEDs and may operate within the visible or infrared spectrum. The system may include an enclosure that is configured to be attached to antenna masts of a radio relay device. The enclosure may have windows to allow light from the optical sources to pass unobstructed through the enclosure. In some embodiments, the system is contained within the radio relay device. The system may be remotely controlled to illuminate a distant object or structure.

Abstract: A relay device deployment system comprising: a deployer, a wireless relay device, a node radio, a deployment mechanism, and a processor. The deployer is configured to be mounted on a mobile platform and to deploy the relay device to a support surface. The relay device comprises dual rotatable antennas and operates as a node in an ad hoc telecommunications network. The node radio has dual antennas and is also configured to operate as a node in the network. The deployment mechanism is configured to deploy the relay device when the network strength drops below a threshold value as monitored by the processor.