Abstract: An apparatus is provided, by way of example, a heater for use in semiconductor processing equipment, that includes a base functional layer having at least one functional zone. A substrate is secured to the base functional layer, and a tuning layer is secured to the substrate opposite the base functional layer. The tuning layer includes a plurality of zones that is greater in number than the zones of the base functional layer, and the tuning layer has lower power than the base functional layer. Further, a component, such as a chuck by way of example, is secured to the tuning layer opposite the substrate. The substrate defines a thermal conductivity to dissipate a requisite amount of power from the base functional layer.

Abstract: A lighting device (100) arranged for rendering a light output is disclosed. The lighting device (100) comprises at least one light source (102) arranged for emitting light. The lighting device (100) further comprises a receiver (104) arranged for receiving at least one signal from at least one further device (110), which at least one signal is representative of a current location of the lighting device (100). The lighting device (100) further comprises a processor 106 arranged for controlling the light output of the at least one light source (102). The processor (106) is further arranged for determining the current location of the lighting device (100) based on the received at least one signal and for accessing a memory (108) storing associations between locations and light settings.

Abstract: A lighting network (110) includes at least one lighting unit (120, 200, 300, 600, 700, 800, 900). The lighting unit includes: a serial data input (121) receiving serial input data including at least first lighting data; first and second demultiplexed serial data outputs (123, 125); one or more individually addressable light sources (222, 322); one or more lighting drivers (250, 460, 650) receiving the first lighting data and in response thereto driving the individually addressable light source(s) to emit light; and a demultiplexer (124, 224, 324, 624). The demultiplexer demultiplexes at least a portion of the serial input data into first and second serial output data, and supplies the first serial output data to the first demultiplexed serial data output to be output from the first lighting unit, and the second serial output data to the second demultiplexed serial data output to be output from the first lighting unit.

Abstract: In various embodiments, one or more signals indicative of a shape formed by a flexible lighting strip (100) may be obtained, e.g., from one or more sensors (110) secured to the flexible lighting strip. One or more deformations in the flexible lighting strip may be detected based on the one or more signals. One or more light sources (102) may be selectively energized based on the one or more detected deformations. In some embodiments, one or more light sources contained in a first logical partition of the flexible lighting strip bound by at least one deformation may be energized to emit light having a first property. One or more light sources contained in a second logical partition of the flexible lighting strip separated from the first logical partition by at least one deformation may be energized to emit light having a second property different than the first property.

Abstract: A configuration system (100) for configuring a first device (130) in a lighting system is disclosed. The configuration system (100) comprises a memory (102) arranged for storing one or more light settings (110), which light settings (110) are defined by one or more light setting rules (112). The configuration system (100) further comprises a communication unit (104) arranged for communicating with the first device (130). The configuration system (100) further comprises a processor (106) arranged for identifying a device property (132) of the first device (130) based on information received from the first device (130) via the communication unit (104).

Abstract: A three dimensional [3D] video signal (41) is provided for transferring to a 3D destination device (50). Depth metadata is determined indicative of depths occurring in the 3D video data, which depth metadata includes a near value indicative of depths of video data nearest to a user. The 3D video signal, which comprises the 3D video data, now also includes the depth metadata. The 3D destination device (50) is enabled to retrieve the depth metadata, to provide auxiliary data, and to position the auxiliary data at an auxiliary depth in dependence of the retrieved metadata for displaying the auxiliary data in combination with the 3D video data such that obscuring the auxiliary data by said nearest video data, and/or disturbing effects at the boundary of the auxiliary data, is avoided.

Abstract: A method and system for performing a unit test in a self-contained environment. The system may include using an object relationship mapping file to generate data objects that can be used for code for a unit test without having to refer to a database to perform a unit test. The data objects may further provide for simultaneous unit tests and a self-contained environment to perform the unit tests to improve the quality and resources required to perform such unit tests. The system may perform the unit tests independent of access to a database.

Abstract: A three dimensional [3D] video signal is processed in a video device (50). The device has generating means (52) for generating an output signal for transferring the video data via a high-speed digital interface like HDMI to a 3D display, which selectively generate a 3D display signal for displaying the 3D video data on a 3D display operative in a 3D mode, a 2D display signal for displaying 2D video data on the 3D display operative in a 2D mode, or a pseudo 2D display signal by including 2D video data in the output signal for displaying the 2D video data on the 3D display operative in the 3D mode. Processing means (53) detect a request to display 2D video data on the 3D display, while the 3D display is operative in the 3D mode, and, in response to the detection, the generating means are set to generate the pseudo 2D display signal for maintaining the 3D mode of the 3D display.

Abstract: A device and method process graphics to be overlayed over video for three-dimensional display. The video includes a series of video frames updated at a video rate, including main video frames and additional video frames. A first buffer buffers a first part of the overlay information to be overlayed over the main video frames. A second buffer buffers a second part of the overlay information to be overlayed over the additional video frames. For each video frame, the first part of the overlay information or the second part of the overlay information is copied to a frame-accurate area copier. The first part of the overlay information or the second part of the overlay information is output according to whether a current video frame is a main video frame or an additional video frame. The first part of the overlay information and the second part of the overlay information are updated at an overlay rate. The overlay rate is different than the video rate.

Abstract: Disclosed are methods and apparatus for lighting control. For example, a user may commission a touch-controlled luminaire (106) to emit light output having various lighting properties dependent on a manner in which the touch-controlled luminaire is touched subsequently. In particular, a user may use an electronic mobile device (102) such as a smart phone, tablet computer, or a wearable computing device (e.g., computing glasses, smart watches) to associate a touch event profile indicative of a manner in which a touch-controlled luminaire was touched (e.g., tapped, swiped, etc.) with a lighting control action. The user may then provide that association to the touch-controlled luminaire. When the touch-controlled luminaire is later touched in the same manner, it may adjust its light output in accordance with the lighting control action. Operation and commission of gesture-controlled luminaires (706) is also described herein.

Abstract: A system for transferring 3D video information has a transmitter (100) to broadcast a signal (104) to a receiver (110). The 3D video information includes auxiliary data for display in an overlay area on the 3D video data, like subtitles. The 3D video data has a left view and a right view arranged in a 2D frame in a main arrangement, e.g. side-by-side. An auxiliary left and right view of the auxiliary data are arranged in an auxiliary data stream according to a 2D transmission format in an auxiliary arrangement that corresponds to the main arrangement, e.g. also side-by-side. In addition, a 2D version of the auxiliary data and auxiliary disparity data indicative of the disparity to be applied to the 2D version of auxiliary data when overlayed on the left view and the right view is included in the transport stream. Advantageously the receiver may use a suitable version of the auxiliary data based on the receiver processing architecture.

Abstract: Disclosed are lighting devices (102), luminaires, lighting systems, lighting modules (104), and methods of controlling the same are taught herein. In various embodiments, a lighting device (102) may include a light source such as an LED (118) configured to emit light towards a targeted portion (106) of a surface (108). An LED driver (120) may be configured energize the LED in response to a compensated signal (132). A light sensor (122) may be configured to measure light reflected from the targeted portion of the surface and to generate a reflected light signal (128) that represents one or more properties of the reflected light. A controller (116) may be operably coupled with the LED driver and the light sensor. The controller may be configured to generate the compensated signal based on the reflected light signal and an input signal (130) that represents one or more desired properties of light to be reflected from the targeted portion of the surface.

Abstract: A non-transitory three-dimensional image signal includes a first image component, a second component for creating a three-dimensional image in combination with the first image component, and a text component that includes text-based subtitles and/or presentation graphics-based bitmap images for including in the three-dimensional image. A shared Z-location component includes Z-location information describing the depth location of the text component within the three-dimensional image. The signal is rendered by rendering the three-dimensional image from the first image component and the second component. The rendering includes rendering the text-based subtitles and/or presentation graphics-based bitmap images in the three-dimensional image. Further, the rendering of the text component includes adjusting the depth location of the text-based subtitles and/or presentation graphics-based bitmap images based on the shared Z-location component.

Abstract: Disclosed are methods and apparatus for lighting control. Presence of an optical element (110, 310, 312, 710A-E, 712, 810) is identified over one or more LEDs (323, 327) and at least one property of the optical element is identified. At least one property of light output of light sources associated with and/or covered by the optical element is adjusted based on the property of the optical element.

Abstract: Disclosed is a lighting unit (10) that utilizes sensor data to select a fade-in or fade-out profile for one or more light sources (12). The lighting unit includes a clock module (20), an ambient light level sensor (18), and a controller (16). The controller receives ambient light level data from the ambient light level sensor and time of day data from the clock module, and utilizes the received information to automatically select a fade-in or fade-out profile. The controller can also use the received ambient light level data to calibrate the clock module.

Abstract: A three dimensional [3D] video signal is processed in a video device (50). The device has generating means (52) for generating an output signal for transferring the video data via a high-speed digital interface like HDMI to a 3D display, which selectively generate a 3D display signal for displaying the 3D video data on a 3D display operative in a 3D mode, a 2D display signal for displaying 2D video data on the 3D display operative in a 2D mode, or a pseudo 2D display signal by including 2D video data in the output signal for displaying the 2D video data on the 3D display operative in the 3D mode. Processing means (53) detect a request to display 2D video data on the 3D display, while the 3D display is operative in the 3D mode, and, in response to the detection, the generating means are set to generate the pseudo 2D display signal for maintaining the 3D mode of the 3D display.

Abstract: Methods and apparatus for detection and notification of pressure waves are described herein. A lighting unit (100) may include one or more light sources (104) such as LEDs, a pressure wave sensor (106), a communication interface (108), and a controller (102) operably coupled with the one or more LEDs, the pressure wave sensor, and the communication interface. In various embodiments, the controller may be configured to receive a signal from the pressure wave sensor, the signal representative of one or more pressure waves detected by the pressure wave sensor. The controller may be configured to determine, based on the signal received from the pressure wave sensor, that the detected one or more pressure waves satisfy a predetermined criterion. The controller may be configured to transmit, to one or more remote lighting units via the communication interface, notification that the predetermined criterion has been satisfied.

Abstract: A method of decoding and outputting video information suitable for three-dimensional [3D] display, the video information comprising encoded main video information suitable for displaying on a 2D display and encoded additional video information for enabling three-dimensional [3D] display, the method comprising: receiving or generating three-dimensional [3D] overlay information to be overlayed over the video information; buffering a first part of the overlay information to be overlayed over the main video information in a first buffer; buffering a second part of overlay information to be overlayed over the additional video information in a second buffer; decoding the main video information and the additional video information and generating as a series of time interleaved video frames, each outputted video frame being either main video frame or additional video frame; determining a type of an video frame to be outputted being either a main video frame or an additional video frame; overlaying either first or sec

Abstract: A coded light device comprising a light source configured to emit coded light, an identifier detection unit configured to detect a product identifier, and a processing unit having a code generator configured to generate a product-related code on basis of the product identifier, and a light source controller configured to control the light source to emit the product-related code by coding its light output.

Abstract: Illumination systems, flexible lighting apparatus and/or lighting control methods are described herein. In various embodiments, one or more signals indicative of a shape formed by a flexible substrate (104, 204, 304, 504, 604) of a flexible lighting apparatus (100, 200, 300, 600) may be obtained from a plurality of sensors (110, 210, 310) associated with the flexible lighting apparatus. One or more lengths of the flexible substrate along the one or more axes may be detected based on the one or more signals provided by the plurality of sensors. One or more LEDs (or more generally, light sources) (102, 202, 302, 502) disposed along the one or more axes of the flexible substrate may be energized to emit light having one or more lighting properties selected based on the detected one or more lengths.