Noam Katz161 Gardner Rd, Brookline, MA 02445

2019018, Jun 13, 2019

Feb 15, 2019

16/277148

- Watertown MA, US
Noam Katz - Lincoln RI, US
Andre B. Kurs - Chestnut Hill MA, US
Christopher Buenrostro - Lexington MA, US
Simon Verghese - Arlington MA, US
Morris P. Kesler - Bedford MA, US
Katherine L. Hall - Arlington MA, US
Herbert Toby Lou - Berkeley CA, US

H02J 50/60
B60L 53/12
H01F 38/14
B60L 53/38
G01V 3/08
B60L 53/36
H02J 7/02
G01R 29/08
H02J 50/50
H02J 50/12
G01V 3/10
H02J 5/00
B60L 53/65

The disclosure features apparatus, methods, and systems for wireless power transfer that include a power source featuring at least one resonator, a power receiver featuring at least one resonator, a first detector featuring one or more loops of conductive material and configured to generate an electrical signal based on a magnetic field between the power source and the power receiver, a second detector featuring conductive material, and control electronics coupled to the first and second detectors, where during operation, the control electronics are configured to measure the electrical signal of the first detector and compare the measured electrical signal of the first detector to baseline electrical information for the first detector to determine information about whether debris is positioned between the power source and the power receiver.

2018032, Nov 15, 2018

Jul 3, 2018

16/026123

- Watertown MA, US
Noam Katz - Lincoln RI, US
Nathaniel Endale Atnafu - Cambridge MA, US

G01V 3/08
H02J 50/80
H02J 50/12
H02J 50/60
H02J 7/02
H02J 5/00
G01V 3/10
B60L 11/18
H02J 50/70

Systems and methods for detecting foreign object debris around a wireless power transfer system include a plurality of detectors, each detector featuring one or more loops of conducting material, and a controller configured to measure at least one of a voltage and a current in each detector and to determine, based on the measurements, whether foreign object debris is present around the wireless power transfer system, where at least some of the plurality of detectors include a first number of loops of the conducting material, and at least some of the plurality of detectors include a second number of loops of the conducting material larger than the first number.

2018024, Aug 23, 2018

Apr 19, 2018

15/956791

- Watertown MA, US
Arunanshu M. Roy - Cambridge MA, US
Noam Katz - Lincoln RI, US
Andre B. Kurs - Chestnut Hill MA, US
Morris P. Kesler - Bedford MA, US

H02J 5/00
H04B 5/00
H02J 7/02
H02J 50/90
H02J 50/70
H02J 50/40
H02J 50/12
H01F 38/14

The disclosure features wireless energy transfer sources that include at least two source resonators and a power source, where: each of the at least two source resonators has a nominal impedance when a device resonator is not positioned on or near any of the at least two source resonators, the nominal impedances of each of the at least two source resonators varying by 10% or less from one another; and the at least two source resonators are configured so that during operation of the wireless energy transfer source, when a device resonator is positioned on or near a first one of the at least two source resonators: (a) the impedance of the first source resonator is reduced to a value smaller than the nominal impedances of each of the other resonators by a factor of 2 or more.

2018024, Aug 23, 2018

Apr 19, 2018

15/956797

- Watertown MA, US
Arunanshu M. Roy - Cambridge MA, US
Noam Katz - Lincoln RI, US
Andre B. Kurs - Chestnut Hill MA, US
Morris P. Kesler - Bedford MA, US

H02J 5/00
H04B 5/00
H02J 7/02
H02J 50/90
H02J 50/70
H02J 50/40
H02J 50/12
H01F 38/14

The disclosure features wireless energy transfer sources that include at least two source resonators and a power source, where: each of the at least two source resonators has a nominal impedance when a device resonator is not positioned on or near any of the at least two source resonators, the nominal impedances of each of the at least two source resonators varying by 10% or less from one another; and the at least two source resonators are configured so that during operation of the wireless energy transfer source, when a device resonator is positioned on or near a first one of the at least two source resonators: (a) the impedance of the first source resonator is reduced to a value smaller than the nominal impedances of each of the other resonators by a factor of 2 or more.

2018010, Apr 12, 2018

Dec 11, 2017

15/837904

- Watertown MA, US
Morris P. Kesler - Bedford MA, US
Noam Katz - Lincoln RI, US
Matthew Dillon - Hingham MA, US
Herbert Toby Lou - Berkeley CA, US

G05F 1/625
H02J 5/00
H02J 7/02
B60L 11/18
G05F 1/66
H02J 50/12
H02J 50/50
H02J 50/80

The disclosure features wireless power transfer systems that include a power transmitting apparatus configured to wirelessly transmit power, a power receiving apparatus connected to an electrical load and configured to receive power from the power transmitting apparatus, and a controller connected to the power transmitting apparatus and configured to receive information about a phase difference between output voltage and current waveforms in a power source of the power transmitting apparatus, and to adjust a frequency of the transmitted power based on the measured phase difference.

2017009, Apr 6, 2017

Oct 6, 2016

15/287596

- Watertown MA, US
Dustin J. Alinger - Boston MA, US
Karl Twelker - Somerville MA, US
Oguz Atasoy - Watertown MA, US
Shrenik Vora - Philadelphia PA, US
Noam Katz - Lincoln RI, US

G06K 19/07
H02J 50/12

The disclosure features wireless power transmitters configured to detect a radio frequency identification (RFID) tag, the transmitters including a transmitter resonator, a transmitter impedance matching network coupled to the transmitter resonator, an amplifier coupled to the transmitter impedance matching network, a detection subsystem connected to the transmitter resonator, and a controller coupled to the amplifier and to the detection subsystem and configured so that during operation of the transmitter, the controller is configured to control the transmitter resonator, the amplifier, and the impedance matching network to cycle the transmitter between a power transmission mode and a RFID tag detection mode.

2017002, Jan 26, 2017

Oct 7, 2016

15/287971

- Watertown MA, US
Noam Katz - Norwood MA, US
Andre B. Kurs - Chestnut Hill MA, US
Christopher Buenrostro - Lexington MA, US
Simon Verghese - Arlington MA, US
Morris P. Kesler - Bedford MA, US
Katherine L. Hall - Arlington MA, US
Herbert Toby Lou - Carlisle MA, US

H02J 50/60
H02J 50/12
H01F 38/14
H02J 7/02
G01V 3/10
B60L 11/18

The disclosure features apparatus, methods, and systems for wireless power transfer that include a power source featuring at least one resonator, a power receiver featuring at least one resonator, a first detector featuring one or more loops of conductive material and configured to generate an electrical signal based on a magnetic field between the power source and the power receiver, a second detector featuring conductive material, and control electronics coupled to the first and second detectors, where during operation, the control electronics are configured to measure the electrical signal of the first detector and compare the measured electrical signal of the first detector to baseline electrical information for the first detector to determine information about whether debris is positioned between the power source and the power receiver.

2015037, Dec 24, 2015

Jun 19, 2015

14/745041

- Watertown MA, US
Arunanshu M. Roy - Cambridge MA, US
Noam Katz - Norwood MA, US
Andre B. Kurs - Chestnut Hill MA, US
Morris P. Kesler - Bedford MA, US

H02J 5/00

The disclosure features wireless energy transfer sources that include at least two source resonators and a power source, where: each of the at least two source resonators has a nominal impedance when a device resonator is not positioned on or near any of the at least two source resonators, the nominal impedances of each of the at least two source resonators varying by 10% or less from one another; and the at least two source resonators are configured so that during operation of the wireless energy transfer source, when a device resonator is positioned on or near a first one of the at least two source resonators: (a) the impedance of the first source resonator is reduced to a value smaller than the nominal impedances of each of the other resonators by a factor of 2 or more.