公开(公告)号：US09424893B2

公开(公告)日：2016-08-23

申请号：US14308593

申请日：2014-06-18

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D. A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, Jr.

IPC: G11C7/10 ,  G10K11/00 ,  G11C5/02 ,  G11C7/00 ,  G11C11/56 ,  G11C19/00 ,  G11C19/08 ,  G11C19/28 ,  G11C19/34 ,  G10K15/00

CPC classification number: G11C7/10 ,  G10K11/00 ,  G10K15/00 ,  G11C5/02 ,  G11C7/005 ,  G11C11/56 ,  G11C19/00 ,  G11C19/08 ,  G11C19/28 ,  G11C19/34

Abstract: The present disclosure provides systems and methods for storing, reading, and writing data using particle-based acoustic wave driven shift registers. The shift registers may physically shift particles along rows and/or columns of wells through the interactions of two parallel surfaces. A transducer may generate an acoustic wave to displace one or more of the two parallel surfaces. The particles may be transferred to and/or otherwise constrained by a buffer surface during at least a portion of the acoustic wave, such that the particles may be shifted during one or more cycles of the acoustic wave. In various embodiments, the amplitude of the acoustic wave may correspond to the spacing distance between each of the wells. The wells may be physical and/or potential wells.

公开(公告)号：US20160118036A1

公开(公告)日：2016-04-28

申请号：US14522452

申请日：2014-10-23

Applicant: Elwha LLC

Inventor： Jesse R. Cheatham, III ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Robert C. Petroski ,  Eric D. Rudder ,  Desney S. Tan ,  Clarence T. Tegreene ,  Charles Whitmer ,  Andrew Wilson ,  Jeannette M. Wing ,  Lowell L. Wood, JR. ,  Victoria Y.H. Wood

IPC: G10K11/178 ,  H04R27/00 ,  G10L15/02 ,  H04R1/32

CPC classification number: H04M11/025 ,  G06F3/011 ,  G06F3/017 ,  G06F3/167 ,  G10K11/178 ,  G10K2210/108 ,  H04L12/282 ,  H04M1/6033 ,  H04M3/205 ,  H04M3/42348 ,  H04M3/436 ,  H04M3/56 ,  H04M2203/2072 ,  H04M2203/60 ,  H04R1/323 ,  H04R1/326 ,  H04R27/00 ,  H04R2217/03 ,  H04R2227/003 ,  H04R2499/11 ,  H04S7/00 ,  H04S2420/01 ,  H04W4/33

Abstract: A hands-free intercom may include a user-tracking sensor, a directional microphone, a directional sound emitter, a display device, and/or a communication interface. The user-tracking sensor may determine a location of a user so the directional microphone can measure vocal emissions by the user and the directional sound emitter can deliver audio to the user. The hands-free intercom may provide privacy to the user. The hands-free intercom may prevent an eavesdropper from hearing the user's vocal emissions, for example, by canceling the vocal emissions at the eavesdropper's ear. The directional sound emitter may deliver out-of-phase sound to cancel the vocal emissions. The hands-free intercom may also, or instead, cancel ambient noise at the user's ear. The hands-free intercom may measure or predict a filtration of the sound to be canceled and compensate for the filtration when canceling the sound.

公开(公告)号：US09320174B2

公开(公告)日：2016-04-19

申请号：US14591342

申请日：2015-01-07

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D. A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, Jr.

IPC: H05K7/20 ,  G06F1/20

CPC classification number: H05K7/20409 ,  G06F1/203 ,  G06F1/206

Abstract: Described embodiments include a portable electronic device. The device includes a shell housing components of the portable electronic device having a heat-generating component. The device includes a heat-rejection element located at an exterior surface of the shell. The heat-rejection element is configured to reject heat received from the heat-generating component into an environment in thermal contact with the heat-rejection element. The device includes a controllable thermal coupler configured to regulate heat transfer to the heat-rejection element. The device includes an activity monitor configured to infer a user touch to the shell in response to a detected activity of the portable electronic device. The device includes a thermal manager configured to regulate heat transfer by the controllable thermal coupler to the heat-rejection element in response to the inferred user touch.

公开(公告)号：US20160093051A1

公开(公告)日：2016-03-31

申请号：US14496037

申请日：2014-09-25

Applicant: Elwha LLC

Inventor： Jesse R. Cheatham, III ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Robert C. Petroski ,  Eric D. Rudder ,  Desney S. Tan ,  Clarence T. Tegreene ,  Charles Whitmer ,  Andrew Wilson ,  Jeannette M. Wing ,  Lowell L. Wood, JR. ,  Victoria Y.H. Wood

IPC: G06T7/00 ,  G06K9/00 ,  G06T7/20

CPC classification number: G06T7/0042 ,  A63F13/215 ,  A63F13/424 ,  A63F13/428 ,  G01S13/862 ,  G01S15/003 ,  G01S15/025 ,  G01S15/58 ,  G01S15/74 ,  G01S15/87 ,  G01S15/89 ,  G06K9/00201 ,  G06K9/00362 ,  G06K9/00375 ,  G06K9/3233 ,  G06T7/11 ,  G06T7/207 ,  G06T2207/10028 ,  G06T2207/10132 ,  G06T2207/20016 ,  G06T2207/20212 ,  G06T2207/30196

Abstract: The present disclosure provides systems and methods for using two imaging modalities for imaging an object at two different resolutions. For example, the system may utilize a first modality (e.g., ultrasound or electromagnetic radiation) to generate image data at a first resolution. The system may then utilize the other modality to generate image data of portions of interest at a second resolution that is higher than the first resolution. In another embodiment, one imaging modality may be used to resolve an ambiguity, such as ghost images, in image data generated using another imaging modality.

Abstract translation: 本公开提供了使用两种成像模态来以两种不同分辨率成像对象的系统和方法。 例如，系统可以利用第一模态（例如，超声波或电磁辐射）以第一分辨率产生图像数据。 然后，该系统可以利用其他模态以高于第一分辨率的第二分辨率生成感兴趣部分的图像数据。 在另一个实施例中，可以使用一种成像模态来解析在使用另一成像模态生成的图像数据中的模糊性，例如重影图像。

公开(公告)号：US09291399B2

公开(公告)日：2016-03-22

申请号：US13800597

申请日：2013-03-13

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D. A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, Jr.

IPC: H05K7/20 ,  F28D15/06 ,  G06F1/20 ,  H04M1/725 ,  H01L23/34

CPC classification number: H05K7/2039 ,  F28D15/06 ,  G06F1/203 ,  G06F1/206 ,  H01L23/34 ,  H01L2924/0002 ,  H04M1/725 ,  H04M2250/12 ,  H01L2924/00

Abstract: Described embodiments include a portable electronic device. The device includes a shell housing components of the portable electronic device having a heat-generating component. The device includes a heat-rejection element located at an exterior surface of the shell. The heat-rejection element is configured to reject heat received from the heat-generating component into an environment in thermal contact with the heat-rejection element. The device includes a controllable thermal coupler configured to regulate heat transfer to the heat-rejection element. The device includes a proximity sensor configured to determine a location of a user touch to the shell relative to the location of the heat-rejection element. The device includes a thermal manager configured to regulate heat transfer by the controllable thermal coupler to the heat-rejection element in response to the determined location of the user touch relative to the location of the heat-rejection element.

Abstract translation: 所描述的实施例包括便携式电子设备。 该装置包括容纳具有发热部件的便携式电子装置的部件的外壳。 该装置包括位于外壳外表面的排热元件。 散热元件构造成将从发热部件接收的热量排斥到与散热元件热接触的环境中。 该装置包括可控制的热耦合器，其被配置为调节对散热元件的传热。 该装置包括接近传感器，该接近传感器被配置成确定用户触摸壳体相对于排热元件的位置的位置。 该装置包括热管理器，其构造成响应于用户触摸相对于排热元件的位置的确定的位置来调节由可控热耦合器到排热元件的热​​传递。

公开(公告)号：US20150371715A1

公开(公告)日：2015-12-24

申请号：US14308596

申请日：2014-06-18

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D.A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, Jr.

IPC: G11C19/00 ,  G10K11/18

CPC classification number: G11C19/00 ,  G10K11/18 ,  G10K15/00

Abstract: The present disclosure provides systems and methods for storing, reading, and writing data using particle-based acoustic wave driven shift registers. The shift registers may physically shift particles along rows and/or columns of wells through the interactions of two parallel surfaces. A transducer may generate an acoustic wave to displace one or more of the two parallel surfaces. The particles may be transferred to and/or otherwise constrained by a buffer surface during at least a portion of the acoustic wave, such that the particles may be shifted during one or more cycles of the acoustic wave. In various embodiments, the amplitude of the acoustic wave may correspond to the spacing distance between each of the wells. The wells may be physical and/or potential wells.

Abstract translation: 本公开提供了使用基于粒子的声波驱动移位寄存器来存储，读取和写入数据的系统和方法。 移位寄存器可以通过两个平行表面的相互作用来物理地沿着井和/或列的井移动颗粒。 换能器可以产生声波以移动两个平行表面中的一个或多个。 在声波的至少一部分期间，颗粒可以被转移到和/或以其它方式被缓冲表面约束，使得在声波的一个或多个循环期间颗粒可能被移位。 在各种实施例中，声波的幅度可以对应于每个孔之间的间隔距离。 井可以是物理和/或潜在井。

公开(公告)号：US20150371687A1

公开(公告)日：2015-12-24

申请号：US14308593

申请日：2014-06-18

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D.A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, JR.

IPC: G11C7/10 ,  G11C5/02 ,  G10K11/00

CPC classification number: G11C7/10 ,  G10K11/00 ,  G10K15/00 ,  G11C5/02 ,  G11C7/005 ,  G11C11/56 ,  G11C19/00 ,  G11C19/08 ,  G11C19/28 ,  G11C19/34

Abstract: The present disclosure provides systems and methods for storing, reading, and writing data using particle-based acoustic wave driven shift registers. The shift registers may physically shift particles along rows and/or columns of wells through the interactions of two parallel surfaces. A transducer may generate an acoustic wave to displace one or more of the two parallel surfaces. The particles may be transferred to and/or otherwise constrained by a buffer surface during at least a portion of the acoustic wave, such that the particles may be shifted during one or more cycles of the acoustic wave. In various embodiments, the amplitude of the acoustic wave may correspond to the spacing distance between each of the wells. The wells may be physical and/or potential wells.

公开(公告)号：US20150357044A1

公开(公告)日：2015-12-10

申请号：US14296080

申请日：2014-06-04

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D.A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, JR.

IPC: G11C19/28

CPC classification number: G11C19/282 ,  G11C11/56 ,  G11C19/28 ,  G11C19/287

Abstract: The present disclosure provides systems and methods for storing, reading, and writing data using particle-based acoustic wave driven shift registers. The shift registers may physically shift particles along rows and/or columns of wells through the interactions of two parallel surfaces. A transducer may generate an acoustic wave to displace one or more of the two parallel surfaces. The particles may be transferred to and/or otherwise constrained by a buffer surface during at least a portion of the acoustic wave, such that the particles may be shifted during one or more cycles of the acoustic wave. In various embodiments, the amplitude of the acoustic wave may correspond to the spacing distance between each of the wells. The wells may be physical and/or potential wells.

公开(公告)号：US20150253424A1

公开(公告)日：2015-09-10

申请号：US14203401

申请日：2014-03-10

Applicant: Elwha LLC

Inventor： Jesse R. Cheatham, III ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Robert C. Petroski ,  Eric D. Rudder ,  Desney S. Tan ,  Clarence T. Tegreene ,  Charles Whitmer ,  Andrew Wilson ,  Jeannette M. Wing ,  Lowell L. Wood, JR. ,  Victoria Y.H. Wood

IPC: G01S15/42 ,  G01S7/539 ,  G01S15/89

CPC classification number: G01S15/89 ,  G01S5/18 ,  G01S7/52003 ,  G01S15/08 ,  G01S15/46 ,  G01S15/74 ,  G01S15/876

Abstract: The present disclosure provides systems and methods associated with determining position and/or movement information using ultrasound. A system may include one or more ultrasonic transmitters and/or receivers. An ultrasonic transmitter may be configured to transmit ultrasound into a region bounded by one or more surfaces. The ultrasonic receiver may receive direct ultrasonic reflections and/or rebounded ultrasonic reflections from one or more objects within the region. A mapping or positioning system may generate positional data associated with one or more of the object(s) based on the direct ultrasonic reflection(s) and/or the rebounded ultrasonic reflection(s). The mapping or positioning system may generate enhanced positional data by combining the direct positional data and the rebounded positional data.

Abstract translation: 本公开提供与使用超声波确定位置和/或移动信息相关联的系统和方法。 系统可以包括一个或多个超声波发射器和/或接收器。 超声波发射器可以被配置为将超声波传输到由一个或多个表面限定的区域中。 超声波接收器可以从该区域内的一个或多个物体接收直接超声波反射和/或反射的超声波反射。 映射或定位系统可以基于直接超声波反射和/或反弹的超声波反射来生成与一个或多个对象相关联的位置数据。 映射或定位系统可以通过组合直接位置数据和反弹位置数据来生成增强的位置数据。

公开(公告)号：US08971043B2

公开(公告)日：2015-03-03

申请号：US13800725

申请日：2013-03-13

Applicant: Elwha LLC

Inventor： Philip Lionel Barnes ,  Hon Wah Chin ,  Howard Lee Davidson ,  Kimberly D. A. Hallman ,  Roderick A. Hyde ,  Muriel Y. Ishikawa ,  Jordin T. Kare ,  Brian Lee ,  Richard T. Lord ,  Robert W. Lord ,  Craig J. Mundie ,  Nathan P. Myhrvold ,  Nicholas F. Pasch ,  Eric D. Rudder ,  Clarence T. Tegreene ,  Marc Tremblay ,  David B. Tuckerman ,  Charles Whitmer ,  Lowell L. Wood, Jr.

IPC: H05K7/20

CPC classification number: H05K7/20409 ,  G06F1/203 ,  G06F1/206

Abstract: Described embodiments include a portable electronic device. The device includes a shell housing components of the portable electronic device having a heat-generating component. The device includes a heat-rejection element located at an exterior surface of the shell. The heat-rejection element is configured to reject heat received from the heat-generating component into an environment in thermal contact with the heat-rejection element. The device includes a controllable thermal coupler configured to regulate heat transfer to the heat-rejection element. The device includes an activity monitor configured to infer a user touch to the shell in response to a detected activity of the portable electronic device. The device includes a thermal manager configured to regulate heat transfer by the controllable thermal coupler to the heat-rejection element in response to the inferred user touch.

Abstract translation: 所描述的实施例包括便携式电子设备。 该装置包括容纳具有发热部件的便携式电子装置的部件的外壳。 该装置包括位于外壳外表面的排热元件。 散热元件构造成将从发热部件接收的热量排斥到与散热元件热接触的环境中。 该装置包括可控制的热耦合器，其被配置为调节对散热元件的传热。 该设备包括活动监视器，其被配置为响应于检测到的便携式电子设备的活动来推断对壳的用户触摸。 该装置包括热管理器，其构造成响应于推断的用户触摸来调节由可控热耦合器到排热元件的热​​传递。