Brian M Scally, 54218 Main St, Kirkland, WA 98033

7965503, Jun 21, 2011

Jun 27, 2007

12/451867

Mark Alan Yoder - Carmel IN, US
Brian Michael Scally - Jamestown IN, US

Thomson Licensing - Boulogne-Billancourt

H05K 7/20

361692, 36167951, 36167933, 36167948, 361695, 165121, 165122, 454184

A fan [] and storage device [] mounting assembly [] for an electronic device comprises a base [] having opposing front [] and rear [] walls. The rear wall [] has a plurality of ventilation openings [] provided therein. A support [] has a fan [] mount [] arranged adjacent to the front wall [] and substantially perpendicular thereto and a storage device [] receiving opening [] arranged between the fan mount [] and the ventilation openings [.

2002008, Jun 27, 2002

Dec 18, 2001

10/023252

Brian Scally - Damascus MD, US

KONINKLIJKE PHILIPS ELECTRONICS N.V.

H04N005/92
H04N007/04
H04N007/06
H04N007/08
H04N005/781

386/095000, 386/111000, 386/125000

The invention provides for a compressed-data processing arrangement () comprising buffer means () for receiving a stream of compressed data () and de-multiplexing means () for retrieving navigation information embedded within the compressed data, wherein the said buffer means comprises a common buffer () and further including pointer memory means () for storing a plurality of pointers arranged to identify sectors of data in the said common buffer () for the delivery of data to decoding means (-).

7930712, Apr 19, 2011

Sep 20, 2002

10/209165

Kuriacose Joseph - Gaithersburg MD, US
Walter Kepley - Gaithersburg MD, US
Brian Michael Scally - Damascus MD, US

The DIRECTV Group, Inc. - El Segundo CA

H04N 7/167

725 31, 725 25, 725 26, 725 27, 725 28, 725 29, 725 30, 725 86, 725101, 380211, 380212, 713150

An apparatus and method for processing content signals received from a plurality of different, and possibly dissimilar, signal sources, such as different satellite networks, and providing a display based on the content of those signals. The apparatus includes a tuner/demodulator for receiving content signals and demodulating the received content signals as programming bitstreams, and one or more access control devices for descrambling any conditional access present in the demodulated programming bitstreams. The apparatus further includes a processor, such as a system chip, which is responsible for all command and control functions. The system chip evaluates conditional access to determine whether the bitstream needs decryption, descrambling, or both, and processes a bitstream from one of the multiple signal sources for display on a suitable output device.

2017019, Jul 6, 2017

Dec 13, 2016

15/376844

- Menlo Park CA, US
Tristan Thomas Trutna - Seattle WA, US
David R. Perek - Bellevue WA, US
Brian Michael Scally - Seattle WA, US

G02B 27/00
G06F 1/16

A virtual reality (VR) headset includes an electronic display element that outputs image light via a plurality of sub-pixels that are separated from each other by a dark space. To mask the dark space between adjacent sub-pixels in the electronic display element, an optics block (e.g., a lens) in the VR headset oscillates or the electronic display element oscillates. For example, a piezoelectric material is coupled to the electronic display element or to the optics block. When a voltage is applied to the piezoelectric material, vibration of the piezoelectric material causes oscillation of the electronic display element or the optics block. The oscillation generates blur spots in the image light that mask the dark space between adjacent sub-pixels, with each blur spot corresponding to a blurred image of a sub-pixel in the image light.

2017017, Jun 22, 2017

Dec 16, 2016

15/381896

- Menlo Park CA, US
Eric Michael Whitmire - Redmond WA, US
Brian Michael Scally - Seattle WA, US

A61B 3/113
A61B 5/00
A61B 5/04

A wearable eye tracking system includes a pair of looping coils in a Helmholtz configuration and an additional looping coil. In one configuration, areas enclosed by the pair of looping coils in the Helmholtz configuration are in parallel with each other, while an area enclosed by the additional looping coil is offset from (i.e., not parallel with) the areas enclosed by the pair of looping coils. In this configuration, the pair of looping coils generates uniform magnetic fields between the two areas of the pair of looping coils in a first direction orthogonal to the areas of the pair of looping coils, and the additional looping coil generates additional non-uniform (or divergent) magnetic fields in a second direction transversal to the first direction.

2017017, Jun 22, 2017

Dec 18, 2015

14/975465

- Menlo Park CA, US
Tristan Thomas Trutna - Seattle WA, US
David R. Perek - Bellevue WA, US
Brian Michael Scally - Seattle WA, US

G01B 7/16
A61F 9/02
A41D 19/00
G01L 1/22

A deformation sensing fabric comprises a fabric substrate comprising a first fabric layer and a first conductive element woven into the first fabric layer. The first conductive element outputs a first instrumented signal, responsive to an applied stimulus signal, indicative of a measure of change in an electrical property of the first conductive element in response to a strain applied to the fabric substrate along a long-axis of the first conductive element. The first conductive element is instrumented by a measurement system which stimulates the first conductive element and measures an electrical property of the first conductive element.

2017017, Jun 22, 2017

Dec 16, 2016

15/382496

- Menlo Park CA, US
Tristan Thomas Trutna - Seattle WA, US
David R. Perek - Bellevue WA, US
Brian Michael Scally - Seattle WA, US

G01L 1/14
G06F 3/01
G01B 7/16

A deformation sensing apparatus comprises an elastic substrate, a conductive element, and an additional conductive element. The conductive element includes conductive joints that are separated from each other by resolving elements along a length of the conductive element. Different combinations of conductive joints and resolving elements correspond to different segments of the deformation sensing apparatus. Based on a change in capacitance between a conductive joint and the additional conductive element when a strain is applied to the deformation sensing apparatus, the deformation sensing apparatus generates a signal that allows determination of how the strain deforms the deformation sensing apparatus.

2017016, Jun 15, 2017

Dec 15, 2016

15/380127

- Menlo Park CA, US
Tristan Thomas Trutna - Seattle WA, US
David R. Perek - Bellevue WA, US
Brian Michael Scally - Seattle WA, US

G06F 3/01
G06T 19/00
A61B 5/11

A kinesthetic sensor measure angular displacement of body parts of users by measuring a density of substances contained in a conduit of the kinesthetic sensor. For example, the kinesthetic sensor measures the density of substance including in a conduit by transmitting a signal into the conduit and measuring the signal after the signal passes through the conduit and one or more substances included in the conduit. Based on the density of the one or more substances included in the conduit from the measured signal, an angular displacement of a user's body part proximate to the kinesthetic sensor is determined. Kinesthetic sensors may use different architectures such as an open-loop, a closed-loop architecture, or an architecture using blood vessels as conduits. Additionally, kinesthetic sensors can be flexible to conform to physical contours of different body parts.