Patents by Inventor Hannah Clevenson

Hannah Clevenson 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: 12027779
    Abstract: An antenna system has a two-dimensional field of view, yet can be implemented on a surface, such as on electronic or photonic integrated circuits. The antenna system includes an array of antennas disposed in a predetermined non-linear pattern and a two-dimensional beamforming network (BFN). The antenna system can be steered/selectively beamformed in two dimensions through beam port selection. The beamforming network is disposed entirely on a single first surface. The beamforming network has a one-dimensional array-side interface disposed on the first surface and a one-dimensional beam-side interface disposed on the first surface. The antennas of the array of antennas are individually communicably coupled to the array-side interface. Segments of the beam-side interface map to respective pixels in the two-dimensional field of view.
    Type: Grant
    Filed: July 10, 2023
    Date of Patent: July 2, 2024
    Assignee: The Charles Stark Draper Laboratory, Inc.
    Inventors: Julian A. Brown, Benjamin F. Lane, Hannah Clevenson, Lucas D. Benney, Michael G. Moebius, Robin M. A. Dawson, Steven J. Spector
  • Patent number: 11699862
    Abstract: An antenna system has a two-dimensional field of view, yet can be implemented on a surface, such as on electronic or photonic integrated circuits. The antenna system includes an array of antennas disposed in a predetermined non-linear pattern and a two-dimensional beamforming network (BFN). The antenna system can be steered/selectively beamformed in two dimensions through beam port selection. The beamforming network is disposed entirely on a single first surface. The beamforming network has a one-dimensional array-side interface disposed on the first surface and a one-dimensional beam-side interface disposed on the first surface. The antennas of the array of antennas are individually communicably coupled to the array-side interface. Segments of the beam-side interface map to respective pixels in the two-dimensional field of view.
    Type: Grant
    Filed: August 20, 2021
    Date of Patent: July 11, 2023
    Assignee: The Charles Stark Draper Laboratory, Inc.
    Inventors: Julian A. Brown, Benjamin F. Lane, Hannah Clevenson, Lucas D. Benney, Michael G. Moebius, Robin M. A. Dawson, Steven J. Spector
  • Patent number: 11346904
    Abstract: A magnetometer containing a crystal sensor with solid-state defects senses the magnitude and direction of a magnetic field. The solid-state defects in the crystal sensor absorb microwave and optical energy to transition between several energy states while emitting light intensity indicative of their spin states. The magnetic field alters the spin-state transitions of the solid-state defects by amounts depending on the solid-state defects' orientations with respect to the magnetic field. The optical read out, reporting the spin state of an ensemble of solid-state defects from one particular orientation class, can be used to lock microwave signals to the resonances associated with the spin-state transitions. The frequencies of the locked microwave signals can be used to reconstruct the magnetic field vector.
    Type: Grant
    Filed: July 6, 2020
    Date of Patent: May 31, 2022
    Assignee: Massachusetts Institute of Technology
    Inventors: Linh M. Pham, Kerry Alexander Johnson, Carson Arthur Teale, Hannah A. Clevenson, Danielle Ann Braje, Christopher Michael McNally, John Francis Barry
  • Publication number: 20220059950
    Abstract: An antenna system has a two-dimensional field of view, yet can be implemented on a surface, such as on electronic or photonic integrated circuits. The antenna system includes an array of antennas disposed in a predetermined non-linear pattern and a two-dimensional beamforming network (BFN). The antenna system can be steered/selectively beamformed in two dimensions through beam port selection. The beamforming network is disposed entirely on a single first surface. The beamforming network has a one-dimensional array-side interface disposed on the first surface and a one-dimensional beam-side interface disposed on the first surface. The antennas of the array of antennas are individually communicably coupled to the array-side interface. Segments of the beam-side interface map to respective pixels in the two-dimensional field of view.
    Type: Application
    Filed: August 20, 2021
    Publication date: February 24, 2022
    Inventors: Julian A. Brown, Benjamin F. Lane, Hannah Clevenson, Lucas D. Benney, Michael G. Moebius, Robin M. A. Dawson, Steven J. Spector
  • Patent number: 10895542
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Grant
    Filed: May 11, 2020
    Date of Patent: January 19, 2021
    Assignee: Massachusetts Institute of Technology
    Inventors: Hannah A. Clevenson, Dirk Englund
  • Publication number: 20210011098
    Abstract: A magnetometer containing a crystal sensor with solid-state defects senses the magnitude and direction of a magnetic field. The solid-state defects in the crystal sensor absorb microwave and optical energy to transition between several energy states while emitting light intensity indicative of their spin states. The magnetic field alters the spin-state transitions of the solid-state defects by amounts depending on the solid-state defects' orientations with respect to the magnetic field. The optical read out, reporting the spin state of an ensemble of solid-state defects from one particular orientation class, can be used to lock microwave signals to the resonances associated with the spin-state transitions. The frequencies of the locked microwave signals can be used to reconstruct the magnetic field vector.
    Type: Application
    Filed: July 6, 2020
    Publication date: January 14, 2021
    Inventors: Linh M. Pham, Kerry Alexander Johnson, Carson Arthur TEALE, Hannah A. CLEVENSON, Danielle Ann Braje, Christopher Michael MCNALLY, John Francis BARRY
  • Publication number: 20200300792
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Application
    Filed: May 11, 2020
    Publication date: September 24, 2020
    Inventors: Hannah A. CLEVENSON, Dirk Englund
  • Patent number: 10712408
    Abstract: A magnetometer containing a crystal sensor with solid-state defects senses the magnitude and direction of a magnetic field. The solid-state defects in the crystal sensor absorb microwave and optical energy to transition between several energy states while emitting light intensity indicative of their spin states. The magnetic field alters the spin-state transitions of the solid-state defects by amounts depending on the solid-state defects' orientations with respect to the magnetic field. The optical read out, reporting the spin state of an ensemble of solid-state defects from one particular orientation class, can be used to lock microwave signals to the resonances associated with the spin-state transitions. The frequencies of the locked microwave signals can be used to reconstruct the magnetic field vector.
    Type: Grant
    Filed: November 8, 2017
    Date of Patent: July 14, 2020
    Assignee: Massachusetts Institute of Technology
    Inventors: Linh M. Pham, Carson Arthur Teale, Hannah A. Clevenson, Kerry Alexander Johnson, Christopher Michael McNally, John Francis Barry, Danielle Ann Braje
  • Patent number: 10648933
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Grant
    Filed: December 26, 2018
    Date of Patent: May 12, 2020
    Assignee: Massachusetts Institute of Technology
    Inventors: Hannah A. Clevenson, Dirk Robert Englund
  • Publication number: 20190145919
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Application
    Filed: December 26, 2018
    Publication date: May 16, 2019
    Inventors: Hannah A. Clevenson, Dirk Robert Englund
  • Patent number: 10197515
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Grant
    Filed: July 8, 2014
    Date of Patent: February 5, 2019
    Assignee: Massachusetts Institute of Technology
    Inventors: Hannah A. Clevenson, Dirk Robert Englund
  • Publication number: 20180136291
    Abstract: A magnetometer containing a crystal sensor with solid-state defects senses the magnitude and direction of a magnetic field. The solid-state defects in the crystal sensor absorb microwave and optical energy to transition between several energy states while emitting light intensity indicative of their spin states. The magnetic field alters the spin-state transitions of the solid-state defects by amounts depending on the solid-state defects' orientations with respect to the magnetic field. The optical read out, reporting the spin state of an ensemble of solid-state defects from one particular orientation class, can be used to lock microwave signals to the resonances associated with the spin-state transitions. The frequencies of the locked microwave signals can be used to reconstruct the magnetic field vector.
    Type: Application
    Filed: November 8, 2017
    Publication date: May 17, 2018
    Inventors: Linh M. Pham, Kerry Alexander Johnson, Carson Arthur Teale, Hannah A. Clevenson, Danielle Ann Braje, Christopher Michael McNally, John Francis Barry
  • Publication number: 20150192532
    Abstract: A light-trapping geometry enhances the sensitivity of strain, temperature, and/or electromagnetic field measurements using nitrogen vacancies in bulk diamond, which have exterior dimensions on the order of millimeters. In an example light-trapping geometry, a laser beam enters the bulk diamond, which may be at room temperature, through a facet or notch. The beam propagates along a path inside the bulk diamond that includes many total internal reflections off the diamond's surfaces. The NVs inside the bulk diamonds absorb the beam as it propagates. Photodetectors measure the transmitted beam or fluorescence emitted by the NVs. The resulting transmission or emission spectrum represents the NVs' quantum mechanical states, which in turn vary with temperature, magnetic field strength, electric field strength, strain/pressure, etc.
    Type: Application
    Filed: July 8, 2014
    Publication date: July 9, 2015
    Applicant: Massachusetts Institute of Technology
    Inventors: Hannah A. Clevenson, Dirk Robert Englund