Patents by Inventor Jens Tingleff

Jens Tingleff 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: 11743647
    Abstract: An integrated circuit connectable to a sensor includes a transconductance element and a current-input analog-to-digital converter (I-ADC). The transconductance element is connectable to the sensor and is configured to generate a current signal representative of an output of the sensor. The I-ADC is configured to sample and quantize the current signal to generate a corresponding digital sensor signal. The I-ADC includes a continuous-time (CT) integrator stage, a discrete-time (DT) integrator stage, and a feedback digital-to-analog converter (FB-DAC). The CT integrator stage is configured to receive the current output and the I-ADC is configured to generate the digital sensor signal based on an output of the CT integrator stage and an output of the DT integrator stage. The FB-DAC is configured to provide a feedback signal based on the digital sensor signal for adding to the current signal.
    Type: Grant
    Filed: December 10, 2019
    Date of Patent: August 29, 2023
    Assignee: KNOWLES ELECTRONICS, LLC.
    Inventors: Mohammad Shajaan, Kristian Hansen, Jens Tingleff, Henrik Thomsen, Claus Fürst
  • Publication number: 20220141586
    Abstract: An integrated circuit connectable to a sensor includes a transconductance element and a current-input analog-to-digital converter (I-ADC). The transconductance element is connectable to the sensor and is configured to generate a current signal representative of an output of the sensor. The I-ADC is configured to sample and quantize the current signal to generate a corresponding digital sensor signal. The I-ADC includes a continuous-time (CT) integrator stage, a discrete-time (DT) integrator stage, and a feedback digital-to-analog converter (FB-DAC). The CT integrator stage is configured to receive the current output and the I-ADC is configured to generate the digital sensor signal based on an output of the CT integrator stage and an output of the DT integrator stage. The FB-DAC is configured to provide a feedback signal based on the digital sensor signal for adding to the current signal.
    Type: Application
    Filed: December 10, 2019
    Publication date: May 5, 2022
    Inventors: Mohammad Shajaan, Kristian Hansen, Jens Tingleff, Henrik Thomsen, Claus Fürst
  • Patent number: 11254560
    Abstract: The present disclosure relates to an integrated circuit comprising a transconductance amplifier which is connectable to a microelectromechanical systems (MEMS) transducer. The transconductance amplifier comprises a first input coupled to a first current conveyor and a second input coupled to a second current conveyor for converting a single-ended or differential transducer signal voltage into an intermediate signal current representative of the transducer signal voltage through a shared reference resistor. The transconductance amplifier further comprises first and second output circuits coupled to the shared reference resistor and being configured to convert the intermediate current signal into a corresponding differential output current signal through first and second output terminals for driving a load.
    Type: Grant
    Filed: June 18, 2019
    Date of Patent: February 22, 2022
    Assignee: KNOWLES ELECTRONICS, LLC
    Inventors: Jens Tingleff, Claus Erdmann Fürst
  • Patent number: 11240600
    Abstract: A sensor signal processing circuit including a delta-sigma analog-to-digital converter (ADC) and a control circuit is disclosed. The circuit is configured to adaptively activate one or more segments of current elements for sequential sampling periods based on a digital signal input to a DAC, wherein less than N current elements are allocated to each segment, each current element in an active segment is enabled and either contributes to a feedback signal of the DAC or does not contribute to the feedback signal, and current elements not in an active segment are disabled. The circuit can be integrated with an acoustic or other sensor as part of a sensor assembly.
    Type: Grant
    Filed: November 12, 2020
    Date of Patent: February 1, 2022
    Assignee: KNOWLES ELECTRONICS, LLC
    Inventors: Mohammad Sadegh Mohammadi, Mohammad Shajaan, Claus Erdmann Furst, Jens Tingleff, Henrik Thomsen, Kristian Hansen
  • Patent number: 11095990
    Abstract: A microphone assembly comprising: a housing including a base, a cover, and a sound port; a MEMS transducer element disposed in the housing, the transducer element configured to convert sound into a microphone signal voltage at a transducer output; and a processing circuit. The processing circuit comprising a transconductance amplifier comprising an input node connected to the transducer output for receipt of the microphone signal voltage, the transconductance amplifier being configured to generate an amplified current signal representative of the microphone signal voltage in accordance with a predetermined transconductance of the transconductance amplifier; and an analog-to-digital converter comprising an input node connected to receive the amplified current signal, said analog-to-digital converter being configured to sample and quantize the amplified current signal to generate a corresponding digital microphone signal.
    Type: Grant
    Filed: June 18, 2019
    Date of Patent: August 17, 2021
    Assignee: Knowles Electronics, LLC
    Inventors: Kristian Adelbert Hansen, Henrik Thomsen, Mohammad Shajaan, Jens Tingleff, Claus Erdmann Fürst
  • Publication number: 20200010315
    Abstract: The present disclosure relates to an integrated circuit comprising a transconductance amplifier which is connectable to a microelectromechanical systems (MEMS) transducer. The transconductance amplifier comprises a first input coupled to a first current conveyor and a second input coupled to a second current conveyor for converting a single-ended or differential transducer signal voltage into an intermediate signal current representative of the transducer signal voltage through a shared reference resistor. The transconductance amplifier further comprises first and second output circuits coupled to the shared reference resistor and being configured to convert the intermediate current signal into a corresponding differential output current signal through first and second output terminals for driving a load.
    Type: Application
    Filed: June 18, 2019
    Publication date: January 9, 2020
    Applicant: Knowles Electronics, LLC
    Inventors: Jens Tingleff, Claus Erdmann Fürst
  • Publication number: 20190387326
    Abstract: A microphone assembly comprising: a housing including a base, a cover, and a sound port; a MEMS transducer element disposed in the housing, the transducer element configured to convert sound into a microphone signal voltage at a transducer output; and a processing circuit. The processing circuit comprising a transconductance amplifier comprising an input node connected to the transducer output for receipt of the microphone signal voltage, the transconductance amplifier being configured to generate an amplified current signal representative of the microphone signal voltage in accordance with a predetermined transconductance of the transconductance amplifier; and an analog-to-digital converter comprising an input node connected to receive the amplified current signal, said analog-to-digital converter being configured to sample and quantize the amplified current signal to generate a corresponding digital microphone signal.
    Type: Application
    Filed: June 18, 2019
    Publication date: December 19, 2019
    Applicant: KNOWLES ELECTRONICS, LLC
    Inventors: Kristian Adelbert Hansen, Henrik Thomsen, Mohammad Shajaan, Jens Tingleff, Claus Erdmann Fürst
  • Patent number: 7949308
    Abstract: A radio receiver comprising: a frequency shifter for receiving a radio frequency signal including a wanted signal in a first frequency band and an interferer in a second frequency band overlapping the first frequency band, and for frequency shifting the radio frequency signal to form a frequency shifted signal, in which the first frequency band is shifted to a third frequency band below radio frequency and the second frequency band is shifted to a fourth frequency band; and a filter for receiving the frequency shifted signal and for attenuating the fourth frequency band relative to the parts of the third frequency band that do not include the fourth frequency band, wherein the filter is dynamically tuneable.
    Type: Grant
    Filed: August 12, 2009
    Date of Patent: May 24, 2011
    Assignee: Cambridge Silicon Radio Limited
    Inventor: Jens Tingleff
  • Publication number: 20100261436
    Abstract: A radio receiver comprising: a frequency shifter for receiving a radio frequency signal including a wanted signal in a first frequency band and an interferer in a second frequency band overlapping the first frequency band, and for frequency shifting the radio frequency signal to form a frequency shifted signal, in which the first frequency band is shifted to a third frequency band below radio frequency and the second frequency band is shifted to a fourth frequency band; and a filter for receiving the frequency shifted signal and for attenuating the fourth frequency band relative to the parts of the third frequency band that do not include the fourth frequency band, wherein the filter is dynamically tuneable.
    Type: Application
    Filed: August 12, 2009
    Publication date: October 14, 2010
    Applicant: CAMBRIDGE SILICON RADIO LIMITED
    Inventor: Jens Tingleff
  • Publication number: 20080316100
    Abstract: Signal reception apparatus comprising at least two antennas, receiver means having a first mode of operation for assessing the quality of received signals and a second mode of operation for processing received signals for identifying data carried therein, at least two signal paths connectable between the antennas and the receiver means and each capable of demodulating signals received by the antennas and switch means connected between the antennas and the signal paths, the apparatus having an assessment mode of operation in which each antenna is connected by the switch means to the receiver means via a single respective one of the signal paths and in which the receiver means operates in its first mode of operation to assess the quality of received signals from each antenna, and a normal mode of operation in which a single antenna is connected by the switch means to the receiver means via all of the signal paths and in which the receiver means operates in its second mode of operation for processing received si
    Type: Application
    Filed: February 21, 2006
    Publication date: December 25, 2008
    Applicant: CAMBRIDGE SILICON RADIO LIMITED
    Inventor: Jens Tingleff