Patents by Inventor John Cangeme

John Cangeme has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Patent number: 11522525
    Abstract: A finite impulse response (FIR) filter including an input of the FIR filter that receives an RF input signal, a clock input configured to receive a clock signal, an output of the FIR filter that provides a filtered output signal, a plurality of signal paths including a plurality of sample-and-hold circuits and a plurality of multipliers arranged in parallel, each signal path including a respective sample-and-hold circuit and a respective multiplier being configured to receive the RF input signal and the clock signal to provide a modulated output signal, an adder configured to receive n modulated output signals from the plurality of signal paths and combine the n modulated output signals to produce the filtered output signal, and a controller.
    Type: Grant
    Filed: May 28, 2020
    Date of Patent: December 6, 2022
    Assignee: RAYTHEON COMPANY
    Inventors: Ajay Subramanian, Zhaoyang C. Wang, Matthew A. Morton, Jack Holloway, John Cangeme
  • Publication number: 20210376818
    Abstract: A finite impulse response (FIR) filter including an input of the FIR filter that receives an RF input signal, a clock input configured to receive a clock signal, an output of the FIR filter that provides a filtered output signal, a plurality of signal paths including a plurality of sample-and-hold circuits and a plurality of multipliers arranged in parallel, each signal path including a respective sample-and-hold circuit and a respective multiplier being configured to receive the RF input signal and the clock signal to provide a modulated output signal, an adder configured to receive n modulated output signals from the plurality of signal paths and combine the n modulated output signals to produce the filtered output signal, and a controller.
    Type: Application
    Filed: May 28, 2020
    Publication date: December 2, 2021
    Inventors: Ajay Subramanian, Zhaoyang C. Wang, Matthew A. Morton, Jack Holloway, John Cangeme
  • Patent number: 10393859
    Abstract: Method and apparatus for leakage signal cancellation in a simultaneous transmit and receive RF system includes: generating a digital transmit signal for transmission from the system; receiving a receive signal produced by reflection of the transmit signal from an object or generated by a second RF system; adaptively filtering the transmit signal by an adaptive finite input response (FIR) filter; calculating filter coefficients for the adaptive FIR filter in real-time at a different sampling rate; adaptively inputting the calculated filter coefficients to the adaptive FIR filter to generate a cancellation signal in real-time; and applying the cancellation signal to the receive signal to cancel leakage in the receive signal to generate an optimum receive signal.
    Type: Grant
    Filed: October 17, 2016
    Date of Patent: August 27, 2019
    Assignee: RAYTHEON COMPANY
    Inventors: Harry B. Marr, John P. Gianvittorio, Jeffrey Caldwell, Samuel E. Parker, John Cangeme
  • Publication number: 20180106884
    Abstract: Method and apparatus for leakage signal cancellation in a simultaneous transmit and receive RF system includes: generating a digital transmit signal for transmission from the system; receiving a receive signal produced by reflection of the transmit signal from an object or generated by a second RF system; adaptively filtering the transmit signal by an adaptive finite input response (FIR) filter; calculating filter coefficients for the adaptive FIR filter in real-time at a different sampling rate; adaptively inputting the calculated filter coefficients to the adaptive FIR filter to generate a cancellation signal in real-time; and applying the cancellation signal to the receive signal to cancel leakage in the receive signal to generate an optimum receive signal.
    Type: Application
    Filed: October 17, 2016
    Publication date: April 19, 2018
    Inventors: Harry B. Marr, John P. Gianvittorio, Jeffrey Caldwell, Samuel E. Parker, John Cangeme
  • Patent number: 9571134
    Abstract: A transmit drive circuit with high signal to noise and frequency agility. In one embodiment, a transmit circuit includes a digital to analog converter, an amplifier, and a signal to noise enhancer, the signal to noise enhancer being a nonlinear passive device that attenuates low-power signals while transmitting high power signals with little loss. The signal to noise enhancer may be fabricated as a thin film of yttrium iron garnet (YIG) epitaxially grown on a gadolinium gallium garnet (GGG) substrate, the GGG substrate secured to a microwave transmission line from the input to the output of the signal to noise enhancer, such that the thin film of yttrium iron garnet is close to the transmission line.
    Type: Grant
    Filed: December 4, 2014
    Date of Patent: February 14, 2017
    Assignee: RAYTHEON COMPANY
    Inventors: Tina P. Srivastava, Matthew A. Morton, John Cangeme
  • Patent number: 9520909
    Abstract: A transmit drive circuit with high signal to noise and frequency agility. In one embodiment, a transmit circuit includes a digital to analog converter, an amplifier, and a signal to noise enhancer, the signal to noise enhancer being a nonlinear passive device that attenuates low-power signals while transmitting high power signals with little loss. The signal to noise enhancer may be fabricated as a thin film of yttrium iron garnet (YIG) epitaxially grown on a gadolinium gallium garnet (GGG) substrate, the GGG substrate secured to a microwave transmission line from the input to the output of the signal to noise enhancer, such that the thin film of yttrium iron garnet is close to the transmission line.
    Type: Grant
    Filed: December 4, 2014
    Date of Patent: December 13, 2016
    Assignee: RAYTHEON COMPANY
    Inventors: Tina P. Srivastava, Matthew A. Morton, John Cangeme
  • Publication number: 20160164552
    Abstract: A transmit drive circuit with high signal to noise and frequency agility. In one embodiment, a transmit circuit includes a digital to analog converter, an amplifier, and a signal to noise enhancer, the signal to noise enhancer being a nonlinear passive device that attenuates low-power signals while transmitting high power signals with little loss. The signal to noise enhancer may be fabricated as a thin film of yttrium iron garnet (YIG) epitaxially grown on a gadolinium gallium garnet (GGG) substrate, the GGG substrate secured to a microwave transmission line from the input to the output of the signal to noise enhancer, such that the thin film of yttrium iron garnet is close to the transmission line.
    Type: Application
    Filed: December 4, 2014
    Publication date: June 9, 2016
    Inventors: Tina P. Srivastava, Matthew A. Morton, John Cangeme
  • Patent number: 7250902
    Abstract: A method and apparatus for generating accurate estimates of a radar target's azimuth and elevation angles for a phased-phased array rotating radar. Scan modulated coherently integrated (SMCI) monopulse curves are generated from a measured one-way transmit antenna pattern and three receive antenna patterns. The SMCI monopulse curves are calculated in advance for the expected beam steers. To utilize the SMCI monopulse curves, two-way Sum, Delta-Azimuth and Delta-Elevation target returns are coherently integrated, the target's monopulse ratios calculated, and the SMCI monopulse curves or polynomials used to calculate the target's U-offset and V-offset sine-space angles, which are added to the radar's beam steer to get an improved estimate of the target's sine-space angular position denoted as Utgt and Vtgt. A coordinate system transformation transforms Utgt and Vtgt to azimuth and elevation angles in a non-rotating coordinate system.
    Type: Grant
    Filed: July 19, 2005
    Date of Patent: July 31, 2007
    Assignee: Raytheon Company
    Inventors: David V. Manoogian, Gerald M. Pitstick, John Cangeme
  • Publication number: 20070018882
    Abstract: A method and apparatus for generating accurate estimates of a radar target's azimuth and elevation angles for a phased-phased array rotating radar. Scan modulated coherently integrated (SMCI) monopulse curves are generated from a measured one-way transmit antenna pattern and three receive antenna patterns. The SMCI monopulse curves are calculated in advance for the expected beam steers. To utilize the SMCI monopulse curves, two-way Sum, Delta-Azimuth and Delta-Elevation target returns are coherently integrated, the target's monopulse ratios calculated, and the SMCI monopulse curves or polynomials used to calculate the target's U-offset and V-offset sine-space angles, which are added to the radar's beam steer to get an improved estimate of the target's sine-space angular position denoted as Utgt and Vtgt. A coordinate system transformation transforms Utgt and Vtgt to azimuth and elevation angles in a non-rotating coordinate system.
    Type: Application
    Filed: July 19, 2005
    Publication date: January 25, 2007
    Inventors: David Manoogian, Gerald Pitstick, John Cangeme
  • Patent number: 7095987
    Abstract: A first downlink transmission beam and a second downlink transmission beam is determined based on a received user-derived signal. The first downlink transmission beam is substantially uncorrelated with the second downlink transmission beam. The first downlink transmission beam is associated with a portion within a first sector. The second downlink transmission beam is associated with a portion within a second sector. A first signal is diversity encoded to produce a first diversity-encoded signal. A second signal is diversity encoded to produce a second diversity-encoded signal. The first diversity-encoded signal is sent over the first downlink transmission beam. The second diversity-encoded signal is sent over the second downlink transmission beam.
    Type: Grant
    Filed: November 15, 2001
    Date of Patent: August 22, 2006
    Assignee: Texas Instruments Incorporated
    Inventors: Louis R Brothers, Jr., John Cangeme, Alexander Flaig, Samuel J MacMullan, H. Vincent Poor, Tandhoni S Rao, Stuart C Schwartz, Triveni N Upadhyay
  • Patent number: 6930637
    Abstract: Method and apparatus for high resolution tracking via mono-pulse beam-forming in a communication system in which the capacity and range of mobile or fixed wireless communication base stations are improved by implementing a single or multiple antenna beam per signal path. Adaptive beam-forming based on up-link direction-of arrival estimation can be performed without using the above-mentioned computationally intensive techniques.
    Type: Grant
    Filed: November 13, 2002
    Date of Patent: August 16, 2005
    Assignee: Texas Instruments Incorporated
    Inventors: Louis R. Brothers, Jr., John Cangeme, Alexander Flaig, Samuel J. MacMullen, H. Vincent Poor, Tandhoni S. Rao, Stuart C. Schwartz, Triveni N. Upadhyay
  • Publication number: 20040046695
    Abstract: Method and apparatus for high resolution tracking via mono-pulse beam-forming in a communication system in which the capacity and range of mobile or fixed wireless communication base stations are improved by implementing a single or multiple antenna beam per signal path. Adaptive beam-forming based on up-link direction-of arrival estimation can be performed without using the above-mentioned computationally intensive techniques.
    Type: Application
    Filed: November 13, 2002
    Publication date: March 11, 2004
    Inventors: Louis R. Brothers, John Cangeme, Alexander Flaig, Samuel J. Macmullan, H. Vincent Poor, Tandhoni S. Rao, Stuart C. Schwartz, Triveni N. Upadhyay
  • Publication number: 20030092379
    Abstract: A first downlink transmission beam and a second downlink transmission beam is determined based on a received user-derived signal. The first downlink transmission beam is substantially uncorrelated with the second downlink transmission beam. The first downlink transmission beam is associated with a portion within a first sector. The second downlink transmission beam is associated with a portion within a second sector. A first signal is diversity encoded to produce a first diversity-encoded signal. A second signal is diversity encoded to produce a second diversity-encoded signal. The first diversity-encoded signal is sent over the first downlink transmission beam. The second diversity-encoded signal is sent over the second downlink transmission beam.
    Type: Application
    Filed: November 15, 2001
    Publication date: May 15, 2003
    Inventors: Louis R. Brothers, John Cangeme, Alexander Flaig, Samuel J. MacMullan, H V Poor, Tandhoni S. Rao, Stuart C. Schwartz, Triveni N. Upadhyay