Abstract: A need exists for a method to do monopulse tracking with a single beam phased array antenna. With a monopulse tracker antenna, the satellite, or moving target, will have a beacon signal that the tracker can acquire. The beacon signal may be a preamble in the transmitted signal from the satellite. The monopulse tracker antennas are scanned over the volume, minimizing the error signal. When the error signal is minimal, the antenna is pointed in the direction of the satellite or moving target. Because the tracker needs to know direction offsets in both azimuth and elevation planes, error signals from both planes are needed. The monopulse tracker antenna maintains a radio frequency link to the beacon signal, causing the antenna to lock in the direction of the satellite when the error signal is minimized to zero.

Abstract: A phased array antenna comprising: a substrate; a plurality of circular polarized wideband antenna elements disposed on the substrate, wherein each element comprises two orthogonal feeds; wherein the plurality of elements are organized into subarrays and physically oriented such that constituent elements of each subarray are sequentially rotated with respect to each other about respective axes that are perpendicular to a surface of the substrate so as to allow RHCP and LHCP transmission and reception; a phase shifter communicatively coupled to the feeds of all the elements and configured to electronically any dynamically compensate for phase regression or progression introduced by the sequential rotation of the elements without relying on physical transmission lines of different dimensions, and further configured to introduce a progressive phase shift across a beam steering plane to enable beam steering of the phased array antenna.

Abstract: A phased array antenna comprising: a substrate; a plurality of circular polarized wideband antenna elements disposed on the substrate, wherein each element comprises two orthogonal feeds; wherein the plurality of elements are organized into subarrays and physically oriented such that constituent elements of each subarray are sequentially rotated with respect to each other about respective axes that are perpendicular to a surface of the substrate so as to allow RHCP and LHCP transmission and reception; a phase shifter communicatively coupled to the feeds of all the elements and configured to electronically any dynamically compensate for phase regression or progression introduced by the sequential rotation of the elements without relying on physical transmission lines of different dimensions, and further configured to introduce a progressive phase shift across a beam steering plane to enable beam steering of the phased array antenna.

Abstract: A need exists for a method to do monopulse tracking with a single beam phased array antenna. With a monopulse tracker antenna, the satellite, or moving target, will have a beacon signal that the tracker can acquire. The beacon signal may be a preamble in the transmitted signal from the satellite. The monopulse tracker antennas are scanned over the volume, minimizing the error signal. When the error signal is minimal, the antenna is pointed in the direction of the satellite or moving target. Because the tracker needs to know direction offsets in both azimuth and elevation planes, error signals from both planes are needed. The monopulse tracker antenna maintains a radio frequency link to the beacon signal, causing the antenna to lock in the direction of the satellite when the error signal is minimized to zero.

Abstract: A method for autonomous systems comprising the steps of using a feedback circuit to provide power to an autonomous system, wherein the feedback circuit is configured to alternate between a first and second sources of power depending on availability of power; creating a delay in the circuit by electrically coupling the circuit to a comparator, a one-shot signal, and a low pass filter, wherein the delay is configured to last for a specified amount of time, and wherein the delay will prevent the power from uncontrolled back and forth oscillation between the first and second power sources.

Abstract: A system comprising a tether having two conductors, wherein one end is electrically coupled to a ground system and the other end is electrically coupled to an aerial system; the ground system comprising a power signal and a data signal, wherein the power signal and data signal are interfaced through a bias-tee circuit, the ground system further comprising a transient attenuation circuit; the aerial system comprising a bias-tee circuit and a transient attenuation circuit; the ground system configured to send and the aerial system configured to receive the power signal via the tether, and the ground system and the aerial system configured to send and receive the data signal via the tether.

Abstract: A method for autonomous systems comprising the steps of using a feedback circuit to provide power to an autonomous system, wherein the feedback circuit is configured to alternate between a first and second source of power depending on availability of power; creating a delay in the circuit by electrically coupling the circuit to a comparator, a one-shot signal, and a low pass filter, wherein the delay is configured to last for a specified amount of time, and wherein the delay will prevent the power from uncontrolled back and forth oscillation between the first and second power source.

Abstract: A system comprising a tether having two conductors, wherein one end is electrically coupled to a ground system and the other end is electrically coupled to an aerial system; the ground system comprising a power signal and a data signal, wherein the power signal and data signal are interfaced through a bias-tee circuit, the ground system further comprising a transient attenuation circuit; the aerial system comprising a bias-tee circuit and a transient attenuation circuit; the ground system configured to send and the aerial system configured to receive the power signal via the tether, and the ground system and the aerial system configured to send and receive the data signal via the tether.