qiang li
Broker in Malden, MA

2012008, Apr 12, 2012

Oct 6, 2011

13/267789

Morris P. Kesler - Bedford MA, US
Konrad Kulikowski - North Andover MA, US
Ron Fiorello - Tewksbury MA, US
Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Westford MA, US
Aristeidis Karalis - Boston MA, US
Andre B. Kurs - Chestnut Hill MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US
Eric R. Giler - Boston MA, US

H04N 5/63, H04N 5/64

348730, 348836, 348839, 348E05127, 348E05128

A wireless power television system includes a television electrically connected to a device magnetic resonator, wherein the device magnetic resonator is configured to wirelessly receive power when separated from a source magnetic resonator by more than 10 cm, and wherein the television is powered directly by power received wirelessly by the device magnetic resonator.

2012008, Apr 12, 2012

Oct 6, 2011

13/267792

Andrew J. Capanella - Somerville MA, US
Ron Fiorello - Tewksbury MA, US
Katherine L. Hall - Westford MA, US
Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Konrad Kulikowski - North Andover MA, US
Andre B. Kurs - Chestnut Hill MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US
Eric R. Giler - Boston MA, US
David Schatz - Needham MA, US

H02J 17/00

307104

A wireless power source station includes a solar panel generating an output DC voltage, power and control circuitry that receives the output DC voltage and generates an electronic drive signal at a frequency, f, and a source magnetic resonator that generates an oscillating magnetic near field in response to the electronic drive signal for providing power to electronic devices in a region around the solar panel.

8400017, Mar 19, 2013

Nov 5, 2009

12/612880

Andre B. Kurs - Chestnut Hill MA, US
Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Andrew J. Campanella - Waltham MA, US
Katherine L. Hall - Westford MA, US
Konrad J. Kulikowski - Somerville MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US

WiTricity Corporation - Watertown MA

H01F 37/00, H01F 38/00

307104

Described herein are improved configurations for wireless power transfer for computer peripherals, including a source magnetic resonator, integrated into a source station and connected to a power source and power and control circuitry; a device magnetic resonator, integrated into a computer peripheral; wherein power is transferred non-radiatively from the source magnetic resonator to the device magnetic resonator, and where the quality factors of the source and device resonators, Qand Q, satisfy the relationship, √{square root over (QQ)}>100.

8629578, Jan 14, 2014

Feb 21, 2013

13/773011

Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Arlington MA, US
Konrad J. Kulikowski - North Andover MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US

WiTricity Corporation - Watertown MA

H01F 37/00

307104

A wireless power transfer system for computer peripherals, includes a source magnetic resonator, integrated into a source station and connected to a power source and power and control circuitry, and a device magnetic resonator, integrated into a computer peripheral wherein power is transferred non-radiatively from the source magnetic resonator to the device magnetic resonator, and wherein the source magnetic resonator is configured to transfer power during predefined intervals.

2012009, Apr 19, 2012

Oct 6, 2011

13/267796

Andrew J. Campanella - Somerville MA, US
Qiang Li - Malden MA, US
Morris P. Kesler - Bedford MA, US
Katherine L. Hall - Westford MA, US
Aristeidis Karalis - Boston MA, US
Konrad Kulikowski - North Andover MA, US
Andre B. Kurs - Chestnut Hill MA, US
Marin Soljacic - Belmont MA, US
Eric R. Giler - Boston MA, US

H02J 17/00

307104

A wireless power service panel source includes power and control circuitry that receives power from a wired power connection at a position in a service panel, and generates an electronic drive signal at a frequency, f, and a source magnetic resonator configured to generate an oscillating magnetic field in response to the electronic drive signal, wherein the source magnetic resonator is configured to wirelessly transmit power to sensors in other positions within the service panel.

8618696, Dec 31, 2013

Feb 21, 2013

13/773022

Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Arlington MA, US
Konrad J. Kulikowski - North Andover MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US

WiTricity Corporation - Watertown MA

H01F 37/00

307104

A wireless power supply includes a source magnetic resonator, connected to a power source and configured to exchange power wirelessly via a wireless power transfer signal with at least one device magnetic resonator integrated into at least one peripheral component of a computer and a processor configured to adjust the operating point of the wireless power supply wherein power is transferred non-radiatively from the wireless power supply to the at least one device magnetic resonator and wherein the power supply forms a part of the computer.

2012009, Apr 19, 2012

Oct 6, 2011

13/267746

Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Westford MA, US
Morris P. Kesler - Bedford MA, US
Konrad Kulikowski - North Andover MA, US
Qiang Li - Malden MA, US
Eric R. Giler - Boston MA, US

H02J 7/00, H01F 38/00

320108, 307104

A wireless energy transfer system for energizing power tools includes at least one source resonator, configured to generate an oscillating magnetic field, and at least one power tool component attached to at least one device resonator, wherein the at least one device resonator is configured to wirelessly receive energy from the at least one source resonator via the oscillating magnetic field, and wherein the at least one power tool component can receive energy at multiple positions relative to the at least one source.

2012009, Apr 19, 2012

Oct 6, 2011

13/267782

Konrad Kulikowski - North Andover MA, US
Qiang Li - Malden MA, US
Andre B. Kurs - Chestnut Hill MA, US
Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Westford MA, US
Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Marin Soljacic - Belmont MA, US
Eric G. Giler - Boston MA, US
David Schatz - Needham MA, US

H02J 17/00

307104

A wireless power source includes a computer display comprising a planar source resonator configured to receive power from the display, wherein the source resonator generates an oscillating magnetic field in a region surrounding the display when the display is powered on, and the source resonator delivers useful power to at least one device resonator in the region surrounding the display.

8587155, Nov 19, 2013

Mar 10, 2010

12/720866

Eric R. Giler - Wellesley MA, US
Katherine L. Hall - Westford MA, US
Morris P. Kesler - Bedford MA, US
Marin Soljacic - Belmont MA, US
Aristeidis Karalis - Boston MA, US
Andre B. Kurs - Chestnut Hill MA, US
Qiang Li - Malden MA, US
Steven J. Ganem - Westwood MA, US

WiTricity Corporation - Watertown MA

H01F 27/42, H01F 37/00, H01F 38/00

307104

Described herein are improved configurations for a lighting system with wireless power transfer that includes a source high-Q magnetic resonator coupled to a power source and generating an oscillating magnetic field, at least one device high-Q magnetic resonator configured to convert said oscillating magnetic field to electrical energy used to power a light coupled to the at least one device resonator, and at least one repeater resonator, larger than the device resonator, wherein the repeater resonator is positioned further from the source resonator than the device resonator and improves the power transfer efficiency between the source resonator and the device resonator.

2012009, Apr 19, 2012

Oct 6, 2011

13/267766

Andrew J. Campanella - Somerville MA, US
Katherine L. Hall - Westford MA, US
Aristeidis Karalis - Boston MA, US
Morris P. Kesler - Bedford MA, US
Konrad Kulikowski - North Andover MA, US
Andre B. Kurs - Chestnut Hill MA, US
Qiang Li - Malden MA, US
Marin Soljacic - Belmont MA, US
Eric R. Giler - Boston MA, US
David Schatz - Needham MA, US

H02J 7/00

320108

A wireless charging pad includes a capacitively-loaded conducting loop source resonator, with a characteristic size, L, connected to a switching amplifier and configured to generate an oscillating magnetic field, wherein the conducting loop comprises multiple turns circumscribing an area, the conducting loop does not extend into the center of the circumscribed area, the source resonator delivers useful power to at least one device resonator with a characteristic size, L, and where L is larger than L