Abstract: A communications transceiver is implemented by modifying a GPS user equipment. In a data reception mode, a communications signal that has a carrier frequency outside the L-band, and that has been phase modulated by a PN code and by data encoded therein, is received from a conventional L-band GPS antenna. The signal is downconverted to the L-band input frequency of the GPS transceiver, and subjected to automatic gain control. The GPS transceiver software is modified so as to recognize and replicate the PN code, and to demodulate the data-bearing signal. In the data transmission mode, the data to be transmitted are modulated onto the selected PN code sequence. The data-modulated PN signal is converted to a non L-band transmission frequency. Normal operation of the GPS transceiver navigation functions is maintained in parallel with the communications functions.

Abstract: A communications transceiver is implemented by modifying a GPS user equipment. In a data reception mode, a communications signal that has a carrier frequency outside the L-band, and that has been phase modulated by a PN code and by data encoded therein, is received from a conventional L-band GPS antenna. The signal is downconverted to the L-band input frequency of the GPS transceiver, and subjected to automatic gain control. The GPS transceiver software is modified so as to recognize and replicate the PN code, and to demodulate the data-bearing signal. In the data transmission mode, the data to be transmitted are modulated onto the selected PN code sequence. The data-modulated PN signal is converted to a non L-band transmission frequency. Normal operation of the GPS transceiver navigation functions is maintained in parallel with the communications functions.

Abstract: Multipath propagation detection can be accomplished using first and second spaced antennas which receive a carrier signal from a moving radiation source and produce a carrier phase difference representative of the location of the source; a difference signal representative of the difference between the measured carrier phase difference and a predetermined phase difference for the source in that location is generated; and the presence of multipath distortion in that difference signal is determined. Furthermore, when a multiplicity of source signals are tracked as in reception of navigation signals from the Global Positioning Satellite System, the receiver may be programmed to eliminate or suppress errors arising from measurements that have been distorted by multipath propagation.

Abstract: A receiver system on a mobile host vehicle platform includes an inertial sensor embedded in an antenna groundplane that supports an array of antenna elements. The beamformer within the receiver system determines the beamforming weights by incorporating inertially-generated signals representative of the attitude of the receiver system and location data identifying the location of GPS satellites. As the host vehicle moves, the beamformer generates the appropriate gain pattern based on the inertial data of the current attitude and the GPS location data. The beamformer, in particular, performs a spatial filtering function that is characterized by high-gain profiles in the direction of transmission of selected ones of the GPS terminals, thereby effectively suppressing signals originating from jammers and other sources of RFI.

Abstract: A GPS transfer initialization system for initializing a mobile unit from a base unit, includes a GPS receiver in the mobile unit for receiving a GPS signal including a time register, a frequency register, and a GPS reference oscillator for generating a GPS carrier signal of a first frequency; a mobile transmitter/receiver circuit on the mobile unit responsive to the GPS carrier signal, for generating and transmitting a transfer carrier signal of a second frequency that is a multiple of the first frequency; a base transmitter/receiver circuit on the base unit including a GPS calibrated frequency and time reference for providing a GPS calibrated signal of a third frequency; an error detection circuit for comparing the GPS calibrated signal and the transfer carder signal to generate a frequency error signal determined from the difference between them and representative of the error in the frequency of the GPS reference oscillator; and an error correction circuit responsive to the GPS calibrated frequency and tim