Patent application number | Description | Published |
20100080218 | Protocol extensions in a display port compatible interface - Contents of extension packets of a DisplayPort specification are described that can permit a computer to control a target device. In one example, an extension packet controls the target device in at least one of power consumption, image rendering, and register updating. | 04-01-2010 |
20110196998 | PROTOCOL EXTENSIONS IN A DISPLAY PORT COMPATIBLE INTERFACE - A computer can control a target device using a packet format described herein. In one example, an extension packet controls the target device in at least one of power consumption, image rendering, and register updating. | 08-11-2011 |
20120117285 | PROTOCOL EXTENSIONS IN A DISPLAY PORT COMPATIBLE INTERFACE - A computer can control a target device using a packet format described herein. In one example, an extension packet controls the target device in at least one of power consumption, image rendering, and register updating. | 05-10-2012 |
20140002465 | METHOD AND APPARATUS FOR MANAGING IMAGE DATA FOR PRESENTATION ON A DISPLAY | 01-02-2014 |
20140002739 | METHOD AND APPARATUS FOR REDUCING POWER USAGE DURING VIDEO PRESENTATION ON A DISPLAY | 01-02-2014 |
20150279334 | METHOD AND APPARATUS FOR REDUCING POWER USAGE DURING VIDEO PRESENTATION ON A DISPLAY - An apparatus may include a link component and a display component. The link component may be operative to receive media content via data frames over a display interconnect, the data frames received periodically in succession at a first rate corresponding to a native frame rate of the media content. The display component may be operative to display the data frames in succession at a second rate corresponding to a native refresh rate of the display component, the display component operative to re-display data frames already shown to maintain the second rate when new data frames have not been received over the display interconnect. | 10-01-2015 |
Patent application number | Description | Published |
20110041608 | Proof mass for maximized, bi-directional and symmetric damping in high g-range acceleration sensors - A new high G-range damped acceleration sensor is proposed with a proof mass optimized for maximized, bi-directional and symmetrical damping to accommodate acceleration ranges above and beyond several thousand G's. In order to achieve the maximum, bi-directional and symmetrical damping, the high G-range acceleration sensor is designed to have minimum amount of mass in the proof mass while maximizing its surface areas. Such high G-range damped acceleration sensor can be applied to any application in which damping (or suppression of ringing) is desired at quite high frequencies. | 02-24-2011 |
20110068421 | Integrated MEMS and ESD protection devices - An electronic apparatus is provided that has a core, an electronic circuit in the core and a lid. An ESD protection device is in the lid. The ESD protection device is coupled to the electronic circuit. | 03-24-2011 |
20110138900 | Weatherized direct-mount absolute pressure sensor - A piezoresistive sensor assembly is provided that has a flex circuit having at least one air flow aperture formed therein. A sensor die is coupled to an absolute support and the flex circuit. The sensor die has a diaphragm that deflects in response to air flow that flows through the air flow aperture and is incident on the diaphragm. The sensor die includes one or more gages positioned on or in the diaphragm. | 06-16-2011 |
20120111703 | LOW-G MEMS ACCELERATION SWITCH - A motion-sensitive low-G MEMS acceleration switch, which is a MEMS switch that closes at low-g acceleration (e.g., sensitive to no more than 10 Gs), is proposed. Specifically, the low-G MEMS acceleration switch has a base, a sensor wafer with one or more proofmasses, an open circuit that includes two fixed electrodes, and a contact plate. During acceleration, one or more of the proofmasses move towards the base and connects the two fixed electrodes together, resulting in a closing of the circuit that detects the acceleration. Sensitivity to low-G acceleration is achieved by proper dimensioning of the proofmasses and one or more springs used to support the proofmasses in the switch. | 05-10-2012 |
20140291128 | LOW-G MEMS ACCELERATION SWITCH - A motion-sensitive low-G MEMS acceleration switch, which is a MEMS switch that closes at low-g acceleration (e.g., sensitive to no more than 10 Gs), is proposed. Specifically, the low-G MEMS acceleration switch has a base, a sensor wafer with one or more proofmasses, an open circuit that includes two fixed electrodes, and a contact plate. During acceleration, one or more of the proofmasses move towards the base and connects the two fixed electrodes together, resulting in a closing of the circuit that detects the acceleration. Sensitivity to low-G acceleration is achieved by proper dimensioning of the proofmasses and one or more springs used to support the proofmasses in the switch. | 10-02-2014 |
20150101413 | MICROELECTROMECHANICAL PRESSURE SENSORS - A pressure sensitive element is provided. In one embodiment the pressure sensitive element comprises: a diaphragm with a gage side and a back side and a rim surrounding the diaphragm; a pair of inner islands on the gage side of the diaphragm wherein the pair of inner islands are spaced to form a first gap between the pair of inner islands; a first freed gage spanning the first gap; at least one bridge to provide an electrical communication path between the rim and the first freed gage; an outer island on the gage side of the diaphragm wherein the outer island and the rim are spaced to form a second gap; and a second freed gage spanning the second gap. | 04-16-2015 |