Patents by Inventor John J. Parkes
John J. Parkes 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).
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Patent number: 11418161Abstract: A digital to analog converter (DAC) can include a current mode DAC to receive an OC word from digital logic indicating an amount of current to add to or remove from sources of respective transistors of an amplifier and generate a current based on the OC word, an active output stage including a positive current mirror and a negative current mirror to generate a positive current and a negative current based on at least a portion of the generated current, and a plurality of outputs including a plurality of sink outputs and a plurality of source outputs to provide the positive and negative currents to the sources of the respective transistors.Type: GrantFiled: March 27, 2018Date of Patent: August 16, 2022Assignee: Apple Inc.Inventors: John J. Parkes, Jr., Krzysztof Babinski
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Patent number: 11356126Abstract: An apparatus of user equipment (UE) includes a radio integrated circuit (IC), an adjustable external low noise amplifier (eLNA) external to the radio IC, and processing circuitry. The radio IC includes a receive signal circuit path including an adjustable gain internal low noise amplifier (iLNA), and a transmit signal circuit path including a digital-to-analog converter (DAC) circuit configured to convert digital signals to analog baseband signals for transmitting. The processing circuitry is configured to provide digital values of the digital signals to the DAC circuit and initiate adjusting gain of one or both of the iLNA and the eLNA according to the digital values.Type: GrantFiled: March 30, 2018Date of Patent: June 7, 2022Assignee: Intel CorporationInventors: Mohammed Alam, David Graham, Jorge Ivonnet, Hasham Khushk, James Gregory Mittel, John J. Parkes, Jr.
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Patent number: 11329650Abstract: An apparatus can include tracking circuitry coupled to a current source and configured to generate a reference voltage signal based on a reference current signal from the current source. The apparatus can include voltage regulator circuitry coupled to the tracking circuitry and configured to generate a voltage supply signal based on the reference voltage signal. The apparatus can further include amplifier circuitry configured to amplify an input signal based on the voltage supply signal. The reference voltage signal can track process and temperature variations associated with at least one field effect transistor within the tracking circuitry. The voltage regulator circuitry can be configured to operate with a closed loop gain higher than 1. The tracking circuitry includes a first transistor connected in parallel with a second transistor, the first and second transistors having a complimentary type with each other (e.g., NMOS and PMOS transistors).Type: GrantFiled: March 29, 2018Date of Patent: May 10, 2022Assignee: Intel CorporationInventors: John J. Parkes, Jr., Anamul Hoque
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Patent number: 11233536Abstract: A wireless communication device can include an antenna array configured to receive a plurality of radio frequency (RF) signals, RF circuitry, and digital baseband receive circuitry. The RF circuitry is configured to process the plurality of RF signals received via the antenna array to generate a single RF signal. The digital baseband receive circuitry is coupled to the RF circuitry and is configured to generate a downconverted signal based on the single RF signal, amplify the downconverted signal to generate an amplified downconverted signal, and convert the amplified downconverted signal to generate a digital output signal for processing by a wireless modem. The digital baseband receive circuitry further includes at least a first filtering system configured to filter the downconverted signal prior to amplification.Type: GrantFiled: March 28, 2018Date of Patent: January 25, 2022Assignee: Intel CorporationInventors: Mohammed Alam, Yiwen Chen, Ricardo Fernandez, John J. Parkes, Jr., James Riches, Werner Schelmbauer, Daniel Schwartz, Michael David Vicker, Dong-Jun Yang
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Patent number: 11146276Abstract: A wireless communication device can include an antenna configured to sense a radio frequency (RF) signal. The wireless communication device can include signal estimation circuitry configured to generate estimates of amplitude and frequency for unmodulated spurs within the RF signal. The wireless communication device can further include multi-tone generator circuitry coupled to the signal estimation circuitry and configured to generate a composite spur cancellation signal based on the estimates of amplitude and frequency for unmodulated spurs within the RF signal. The wireless communication device can further include adder circuitry configured to subtract the spur cancellation signal from the RF signal to generate a spur cancelled signal.Type: GrantFiled: March 30, 2018Date of Patent: October 12, 2021Assignee: Intel CorporationInventors: Niranjan Karandikar, Mohammed Alam, Gregory Chance, Armando Cova, Michael Milyard, John J. Parkes, Jr., Ashoke Ravi, Daniel Schwartz, Dong-Jun Yang
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Publication number: 20210067163Abstract: A wireless communication device can include an antenna configured to sense a radio frequency (RF) signal. The wireless communication device can include signal estimation circuitry configured to generate estimates of amplitude and frequency for unmodulated spurs within the RF signal. The wireless communication device can further include multi-tone generator circuitry coupled to the signal estimation circuitry and configured to generate a composite spur cancellation signal based on the estimates of amplitude and frequency for unmodulated spurs within the RF signal. The wireless communication device can further include adder circuitry configured to subtract the spur cancellation signal from the RF signal to generate a spur cancelled signal.Type: ApplicationFiled: March 30, 2018Publication date: March 4, 2021Inventors: Niranjan Karandikar, Mohammed Alam, Gregory Chance, Armando Cova, Michael Milyard, John J. Parkes, JR., Ashoke Ravi, Daniel Schwartz, Dong-Jun Yang
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Publication number: 20200395906Abstract: A digital to analog converter (DAC) can include a current mode DAC to receive an OC word from digital logic indicating an amount of current to add to or remove from sources of respective transistors of an amplifier and generate a current based on the OC word, an active output stage including a positive current mirror and a negative current mirror to generate a positive current and a negative current based on at least a portion of the generated current, and a plurality of outputs including a plurality of sink outputs and a plurality of source outputs to provide the positive and negative currents to the sources of the respective transistors.Type: ApplicationFiled: March 27, 2018Publication date: December 17, 2020Inventors: John J. PARKES, Jr., Krzysztof BABINSKI
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Publication number: 20200358463Abstract: An apparatus of user equipment (UE) includes a radio integrated circuit (IC), an adjustable external low noise amplifier (eLNA) external to the radio IC, and processing circuitry. The radio IC includes a receive signal circuit path including an adjustable gain internal low noise amplifier (iLNA), and a transmit signal circuit path including a digital-to-analog converter (DAC) circuit configured to convert digital signals to analog baseband signals for transmitting. The processing circuitry is configured to provide digital values of the digital signals to the DAC circuit and initiate adjusting gain of one or both of the iLNA and the eLNA according to the digital values.Type: ApplicationFiled: March 30, 2018Publication date: November 12, 2020Inventors: Mohammed ALAM, David GRAHAM, Jorge IVONNET, Hasham KHUSHK, James Gregory MITTEL, John J. PARKES, JR.
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Publication number: 20200336144Abstract: An apparatus can include tracking circuitry coupled to a current source and configured to generate a reference voltage signal based on a reference current signal from the current source. The apparatus can include voltage regulator circuitry coupled to the tracking circuitry and configured to generate a voltage supply signal based on the reference voltage signal. The apparatus can further include amplifier circuitry configured to amplify an input signal based on the voltage supply signal. The reference voltage signal can track process and temperature variations associated with at least one field effect transistor within the tracking circuitry. The voltage regulator circuitry can be configured to operate with a closed loop gain higher than 1. The tracking circuitry includes a first transistor connected in parallel with a second transistor, the first and second transistors having a complimentary type with each other (e.g., NMOS and PMOS transistors).Type: ApplicationFiled: March 29, 2018Publication date: October 22, 2020Inventors: John J. Parkes, JR., Anamul Hoque
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Publication number: 20200321994Abstract: A wireless communication device can include an antenna array configured to receive a plurality of radio frequency (RF) signals, RF circuitry, and digital baseband receive circuitry. The RF circuitry is configured to process the plurality of RF signals received via the antenna array to generate a single RF signal. The digital baseband receive circuitry is coupled to the RF circuitry and is configured to generate a downconverted signal based on the single RF signal, amplify the downconverted signal to generate an amplified downconverted signal, and convert the amplified downconverted signal to generate a digital output signal for processing by a wireless modem. The digital baseband receive circuitry further includes at least a first filtering system configured to filter the downconverted signal prior to amplification.Type: ApplicationFiled: March 28, 2018Publication date: October 8, 2020Inventors: Mohammed Alam, Yiwen Chen, Ricardo Fernandez, John J. Parkes, JR., James Riches, Werner Schelmbauer, Daniel Schwartz, Michael David Vicker, Dong-Jun Yang
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Patent number: 7937058Abstract: A digital tuning system (250) for changing a cutoff frequency of an analog filter (132) includes digital synthesizers (292 and 294) for producing a two-tone calibration signal (196) applied to an input of the filter after a quality factor of the filter is increased. The filter includes at least one R/C circuit with two resistors (304 and 306) for changing the quality factor and arrays (308 and 310) of capacitors for changing the cutoff frequency. The amplitude of the magnitude responses (409 and 411) of the filter to each tone (405 and 407) is measured by a two discrete Fourier transform single-frequency bin power detection circuits (253 and 254) while the filter is sequenced through a plurality of capacitance settings. An optimal capacitance for the R/C circuit is selected by comparing, to a pre-selected value, a difference between the responses of the filter to each tone, for each capacitance setting.Type: GrantFiled: October 18, 2006Date of Patent: May 3, 2011Assignee: Freescale Semiconductor, Inc.Inventors: Mahibur Rahman, John J. Parkes, Jr., James J. Riches
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Patent number: 7847524Abstract: A circuit includes a voltage regulator (208) for outputting a voltage at a regulated level, a protection circuit (260), and a load circuit (210) coupled to the voltage regulator. The protection circuit includes means for preventing the voltage regulator from outputting a voltage at a level higher than the regulated level during a start-up period of the voltage regulator.Type: GrantFiled: January 21, 2010Date of Patent: December 7, 2010Assignee: Freescale Semiconductor, Inc.Inventors: John J. Parkes, Jr., Kai Zhong
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Publication number: 20100172163Abstract: A circuit includes a voltage regulator (208) for outputting a voltage at a regulated level, a protection circuit (260), and a load circuit (210) coupled to the voltage regulator. The protection circuit includes means for preventing the voltage regulator from outputting a voltage at a level higher than the regulated level during a start-up period of the voltage regulator.Type: ApplicationFiled: January 21, 2010Publication date: July 8, 2010Applicant: Freescale Semiconductor, Inc.Inventors: John J. Parkes, JR., Kai Zhong
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Patent number: 7723962Abstract: A circuit includes a voltage regulator (208) for outputting a voltage at a regulated level, a protection circuit (260), and a load circuit (210) coupled to the voltage regulator. The protection circuit includes means for preventing the voltage regulator from outputting a voltage at a level higher than the regulated level during a start-up period of the voltage regulator.Type: GrantFiled: March 23, 2007Date of Patent: May 25, 2010Assignee: Freescale Semiconductor, Inc.Inventors: John J. Parkes, Jr., Kai Zhong
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Patent number: 7629711Abstract: An integrated circuit package (202) includes a voltage regulator (208) and a power-out pin (236) for coupling to a load circuit (210) via a connection (234) external to the integrated circuit package and for coupling to an output (230) of the voltage regulator via a connection (224, 228, 226 and 231) internal to the integrated circuit package. The internal connection has a series resistance that causes a voltage drop due to a load current. The voltage regulator compensates for the voltage drop in the internal connection using a current feedback circuit, in which the current fed back is proportional to the voltage drop caused by the series resistance of the internal connection.Type: GrantFiled: March 23, 2007Date of Patent: December 8, 2009Assignee: Freescale Semiconductor, Inc.Inventors: Kai Zhong, John J. Parkes, Jr.
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Publication number: 20080231240Abstract: A circuit includes a voltage regulator (208) for outputting a voltage at a regulated level, a protection circuit (260), and a load circuit (210) coupled to the voltage regulator. The protection circuit includes means for preventing the voltage regulator from outputting a voltage at a level higher than the regulated level during a start-up period of the voltage regulator.Type: ApplicationFiled: March 23, 2007Publication date: September 25, 2008Applicant: Freescale Semiconductor, Inc.Inventors: John J. PARKES, Jr., Kai Zhong
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Publication number: 20080231243Abstract: An integrated circuit package (202) includes a voltage regulator (208) and a power-out pin (236) for coupling to a load circuit (210) via a connection (234) external to the integrated circuit package and for coupling to an output (230) of the voltage regulator via a connection (224, 228, 226 and 231) internal to the integrated circuit package. The internal connection has a series resistance that causes a voltage drop due to a load current. The voltage regulator compensates for the voltage drop in the internal connection using a current feedback circuit, in which the current fed back is proportional to the voltage drop caused by the series resistance of the internal connection.Type: ApplicationFiled: March 23, 2007Publication date: September 25, 2008Applicant: Freescale Semiconductor, Inc.Inventors: Kai Zhong, John J. Parkes
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Publication number: 20080165041Abstract: A digital-to-analog converter adapted for use as a feedback converter in a continuous time sigma delta analog-to-digital converter. The digital-to-analog converter has a discrete time digital signal input accepting digital signal samples that are synchronized with an assertion of a first data clock signal and a discrete time clock generator that generates an output pulse in response to receiving an assertion of the first data clock. The output pulse is asserted for a fixed duration that is independent of a jitter of the first data clock. The digital-to-analog converter also includes a continuous time analog output that produces, during assertion of the output pulse, a continuous time analog output signal having a magnitude corresponding to the digital signal samples.Type: ApplicationFiled: January 10, 2007Publication date: July 10, 2008Applicant: Freescale Semiconductor, Inc.Inventors: John J. Parkes, James G. Mittel, James J. Riches
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Patent number: 7397291Abstract: A digital-to-analog converter adapted for use as a feedback converter in a continuous time sigma delta analog-to-digital converter. The digital-to-analog converter has a discrete time digital signal input accepting digital signal samples that are synchronized with an assertion of a first data clock signal and a discrete time clock generator that generates an output pulse in response to receiving an assertion of the first data clock. The output pulse is asserted for a fixed duration that is independent of a jitter of the first data clock. The digital-to-analog converter also includes a continuous time analog output that produces, during assertion of the output pulse, a continuous time analog output signal having a magnitude corresponding to the digital signal samples.Type: GrantFiled: January 10, 2007Date of Patent: July 8, 2008Assignee: Freescale Semiconductor, Inc.Inventors: John J. Parkes, Jr., James G. Mittel, James J. Riches
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Publication number: 20080096514Abstract: A digital tuning system (250) for changing a cutoff frequency of an analog filter (132) includes digital synthesizers (292 and 294) for producing a two-tone calibration signal (196) applied to an input of the filter after a quality factor of the filter is increased. The filter includes at least one R/C circuit with two resistors (304 and 306) for changing the quality factor and arrays (308 and 310) of capacitors for changing the cutoff frequency. The amplitude of the magnitude responses (409 and 411) of the filter to each tone (405 and 407) is measured by a two discrete Fourier transform single-frequency bin power detection circuits (253 and 254) while the filter is sequenced through a plurality of capacitance settings. An optimal capacitance for the R/C circuit is selected by comparing, to a pre-selected value, a difference between the responses of the filter to each tone, for each capacitance setting.Type: ApplicationFiled: October 18, 2006Publication date: April 24, 2008Applicant: Freescale Semiconductor, Inc.Inventors: Mahibur Rahman, John J. Parkes, James J. Riches