Patent application number | Description | Published |
20080230894 | Carbon nanotubes for active direct and indirect cooling of electronics device - A system for cooling a semiconductor device is disclosed. The system includes a lid encasing the semiconductor device, a first plurality of carbon nanotubes disposed within the lid, and a fluid system configured to pass a fluid through the lid. Furthermore, a second system for cooling a semiconductor device is disclosed. The second system includes a lid, a first plurality of carbon nanotubes disposed within the lid, and a fluid system configured to pass a fluid through the lid. The lid is configured to be mounted over and encase the semiconductor device. Additionally, a method for cooling a semiconductor device is disclosed. The method includes disposing a first plurality of carbon nanotubes within a lid, mounting the lid over the semiconductor device, and passing a fluid through the lid. | 09-25-2008 |
20100032141 | COOLING SYSTEM UTILIZING CARBON NANOTUBES FOR COOLING OF ELECTRICAL SYSTEMS - A cooling system to cool the airflow through a electrical system includes a CNT heat exchanger module disposed within a housing of the electrical system, a cooling device configured to receive a coolant, a unit board disposed within the housing of the electrical system, and an air flow device configured to pass air across at least a portion of the unit board and at least a portion of the CNT heat exchanger module. The CNT heat exchanger module includes a member having a hole defined therethrough and a plurality of carbon nanotubes (CNTs) attached to the member. The coolant is propagated through the hole in the member so as to dissipate the heat generated by the electrical system. | 02-11-2010 |
20100175851 | MODULAR ABSORPTION HEAT SINK DEVICES FOR PASSIVE COOLING OF SERVERS AND OTHER ELECTRONICS - A passive heat sink for cooling an electronic component such as a high-performance processor. The heat sink includes a shell with a surface that is positionable adjacent a heat generating surface of the electronic component. The shell includes a heat exchanger portion with cooling fins extending outward and positioned in a fan-provided airflow. A generator compartment is provided within the shell with a generator vessel for containing an absorbent, and the generator compartment is maintained at a pressure lower than ambient. The generator compartment conducts heat away from the electronic component to the absorbent in the generator vessel. An absorber compartment, at a pressure lower than the generator compartment, is provided within the shell above the generator compartment, and, in use, an absorption refrigeration cycle contained within the shell is activated by heat from the electronic component. A bubble pump moves absorbent from the generator compartment to the absorber compartment. | 07-15-2010 |
20120327590 | MODULAR ABSORPTION HEAT SINK DEVICES FOR PASSIVE COOLING OF SERVERS AND OTHER ELECTRONICS - A passive heat sink for cooling an electronic component such as a high-performance processor. The heat sink includes a shell with a surface that is positionable adjacent a heat generating surface of the electronic component. The shell includes a heat exchanger portion with cooling fins extending outward and positioned in a fan-provided airflow. A generator compartment is provided within the shell with a generator vessel for containing an absorbent, and the generator compartment is maintained at a pressure lower than ambient. The generator compartment conducts heat away from the electronic component to the absorbent in the generator vessel. An absorber compartment, at a pressure lower than the generator compartment, is provided within the shell above the generator compartment, and, in use, an absorption refrigeration cycle contained within the shell is activated by heat from the electronic component. A bubble pump moves absorbent from the generator compartment to the absorber compartment. | 12-27-2012 |
Patent application number | Description | Published |
20110128699 | COOLING SERVERS IN A DATA CENTER USING FANS EXTERNAL TO SERVERS - To avoid the need to operate in-chassis fans to cool rack-mounted servers in a data center, the data center is arranged into a hot aisle and a cold aisle. The cold aisle is adjacent to a first side of the rack mounted servers and receives cold air from a cold air supply unit. The hot aisle is adjacent to a second side of the rack-mounted servers and has a lower pressure than the cold aisle. Because of the pressure difference between the cold aisle and the hot aisle, cold air flows through the rack-mounted servers, cooling electronic equipment therein, into the hot aisle. Control systems are used to obtain sufficient cooling. | 06-02-2011 |
20110154842 | COOLING COMPUTING DEVICES IN A DATA CENTER WITH AMBIENT AIR COOLED USING HEAT FROM THE COMPUTING DEVICES - To reduce power consumption and more efficiently cool computing devices in a data center, an air supply unit supplies air from outside the data center to an air handling unit, which cools servers within the data center using the supplied air. Using air from outside the data center, rather than recirculating and cooling air from within the data center, reduces the power consumption of the data center. In an embodiment, a chiller and/or an evaporative cooling system are coupled to the air supply unit to allow further cooling of the outside air before it is circulated. Heat generated by the servers within the data center is collected, for example using thermal pathways coupled to server components, and used by the chiller in an absorption or adsorption process to further reduce power consumption of the data center and allow the air handling unit to further cool the outside air. | 06-30-2011 |
20120215359 | ADAPTIVE FAN CONTROL BASED ON SERVER CONFIGURATION - A server or other computing system contains a plurality of heat-generating electrical components and one or more cooling fans to dissipate heat from those components during operation. The fans are controlled by one or more fan controllers, which are programmed with an adaptive control algorithm to change the speed of each system cooling fan based on the needs of the components. The adaptive control algorithm is selected based on a detected configuration of the system's components, which may be detected upon startup of the system. During operation, a fan controller receives the component temperatures from one or more sensor and uses the algorithm to determine the fan speed. Thus, the system variably controls the speed of the fans based on the configuration of components housed in the server unit and on the current temperature of the components. | 08-23-2012 |
Patent application number | Description | Published |
20080317160 | CODE-MODULATED PATH-SHARING MULTI-SIGNAL SYSTEMS - Described herein are code-modulated multi-signal systems. In one embodiment, a multi-signal system receives multiple input signals and code-modulates each input signal with a unique code to distinguish the input signal from the other input signals. The input signals may come from multiple antennas, multiple sensors, multiple channels, etc. The code-modulated signals are then combined into a combined signal that is sent through shared blocks and/or transmitted across a shared medium in a shared path. After shared processing and/or shared transmission, the individual signals are recovered using matched filters. Each matched filter contains a code corresponding to one of the unique codes for recovering the corresponding signal from the combined signal. The recovered signals may then be inputted to additional processors for further processing. | 12-25-2008 |
20090021307 | MULTI-BAND, INDUCTOR RE-USE LOW NOISE AMPLIFIER - Described herein are multi-band LNAs that reuse inductors for different frequency bands to minimize chip area. In an embodiment, a multi-band LNA is capable of operating in a narrowband (NB) and a wideband (WB) while reusing at least one input impedance matching inductor and at least one load inductor for both bands. The reuse of inductors results in a more efficient use of chip area. In an exemplary embodiment, the LNA comprises a common source transistor and a common gate transistor. In this embodiment, the LNA operates in a common source configuration using the common source transistor to amplify input signals in the NB, and operates in a common gate configuration using the common gate transistor to amplify input signals in the WB. The LNA reuses an input impedance matching inductor and a load inductor in both configurations, and thus both bands. | 01-22-2009 |
20090075613 | DISTRIBUTED RF FRONT-END FOR UWB RECEIVERS - Described herein are ultra wide-band distributed RF (UWB-DRF) front-end receivers comprising composite cells distributed along transmission lines, where each composite cell comprises a low-noise amplifier (LNA) merged with a mixer. By merging the LNA and the mixer in each composite cell, the power consumption and chip area of the RF front-end is reduced. Further, the distributed architecture of the RF front-end allows it to operate over a wide bandwidth by absorbing the parasitic capacitances of the composite cells into the transmission lines of the RF-front end. Embodiments of the RF front-end provide wideband flat gain, low noise figure (NF), wideband linearity, and wideband matching at the inputs of the RF front-end. In an embodiment, a programmable resistance at the termination of the RF transmission line allows the RF front-end to trade off a few decibels of mismatch at the RF input for higher gain and lower NF. | 03-19-2009 |
20090088115 | Novel Distributed Direct Conversion Receiver (DDCR) for UWB Systems - A novel DDCR RF front-end for use in UWB applications combining a distributed approach which provides wideband functionality of the RF front-end with I-Q requirement of DCRs. The distributed architecture uses composite cells of a merged LNA and mixer along the input RF T-line. | 04-02-2009 |
20120038499 | SIGNAL STATISTICS AND COMPRESSION-BASED ANALOG-TO-DIGITAL CONVERTERS - A method of adaptively and losslessly quantizing an analog signal to a digital signal in an analog-to-digital converter (ADC), is disclosed. According to one embodiment, the quantizing is based on one or more of an instantaneous amplitude of the analog signal, frequencies of the analog signal, and patterned contents of the analog signal, and the method comprises sampling the analog signal; quanitizing the analog signal by a quantizer core, wherein the quantizer core comprises a digital-to-analog converter (DAC), a comparator, and a voltage reference, wherein the quantization is one of efficient lossless and adaptive compression quantization, or a traditional quantization method; determining by an analog compression engine (ACE) whether the sampled analog signal is above or below a defined threshold, wherein the defined threshold includes one or more of an amplitude threshold, a frequency threshold, and a patterned adaptive threshold; adaptively manipulating the sampled signal mathematically through at least one of the DAC or voltage reference of the quantizer core; and outputting the digital signal. | 02-16-2012 |
20130321080 | CMOS Linear Differential Distributed Amplifier and Distributed Active Balun - A CMOS distributed amplifier with distributed active input balun is disclosed. Each g | 12-05-2013 |
20130322469 | MULTI-CHANNEL CODE-DIVISION MULTIPLEXING IN FRONT-END INTEGRATED CIRCUITS - A code-division multiplexing (CDM) system utilized in multi-channel (MC) front-end integrated circuits to significantly reduce the power consumption of such systems. The CDM system extends data compression advantages to uncorrelated and weakly correlated MC signals through the introduction of a new Multi-Channel Signal Binning and Multiplexing (MCSBM) method and architecture. The method achieves significant reductions in power consumption in comparison to a conventional time-division multiplexing quantizer, while adding only a modest amount of overhead and complexity. Systems and methods permit architects to fabricate MC integrated circuits with ultra low power consumption and small chip area. Another embodiment relates to the system's compressor organizing samples of the input signal in such a way that the downstream analog-to-digital converter quantizes the higher variance samples with a higher resolution compared to the resolution it uses to quantize other samples with lower variance. | 12-05-2013 |