Abstract: An uninterruptible power supply system includes an input configured to couple to a power source, an output configured to couple to a system load, a battery, power circuitry coupled to the input, the output, and the battery, and configured to transfer power from the input to the output and to transfer power from the battery to the output, a test load, a test switch coupled to the battery and the test load and configured to selectively couple the battery to the test load, a voltage monitor coupled to the battery and configured to provide an indication of a voltage provided by the battery, and a processor coupled to the test switch and the voltage monitor and configured to effect a first partial-discharge test on the battery by actuating the test switch to couple the battery to the test load to partially discharge the battery, and by using information from the voltage monitor regarding the voltage provided by the battery at different times during the test before a complete discharge of the battery to determine a

Abstract: Disclosed are systems, methods and devices, including a method that includes receiving information about one or more transactions, each transaction including a respective sale of at least one first item selected by a customer and an offer of cross-sale of at least one second item offered to the customer, the information about each of the transactions including information about an outcome of the respective offer of cross-sales. The method further includes determining effectiveness measures based on the received information, with each of the effectiveness measures being associated with at least one of a plurality of combinations of at least one purchasable item and a corresponding offer of cross-sale of at least another purchasable item. The effectiveness measures are representative of a likelihood of the corresponding offer of the cross-sale being accepted when offered in combination with the respective at least one purchasable item.

Abstract: The present invention relates to a liquid sensor for locating in a liquid. The liquid sensor includes a level sensor including one or more sensing stations located between a head and a tail of the liquid sensor. The liquid sensor is suitable for sensing the liquid level. The liquid sensor further includes a depth sensor for sensing the depth of the tail in the liquid. The liquid sensor is particularly suited to pumping station applications.

Abstract: A surface relief structure includes a recording medium configured to be structurally modified when exposed to interfering and non-interfering portions of radiation beams, the structurally modified recording medium including, when viewed in a two-dimensional cross-section along one of the axes of the recording medium a plurality of equally spaced steps of fine-sized periodicity superimposed upon a plurality of deep depressions of substantially coarse-sized periodicity. The structurally modified recording medium is configured to produce in reflection single and multiple colors in a broad spectral range when illuminated by a source of light.

Abstract: Described herein is a housing comprising an inside and at least one sidewall, wherein the at least one sidewall comprises inner and outer surfaces. An etch stop deposit is disposed over at least a portion of the housing, and a diaphragm material deposit is disposed over at least a portion of the etch stop deposit.

Abstract: Described herein is a sensor assembly that can be calibrated after manufacture and a method for calibrating that assembly. The assembly comprises a sense element, microprocessor and a protection circuit. The assembly can use pins on the existing connector to input calibration data. The present invention also is a method of calibrating sensor outputs using an assembly that contains a protection circuit to prevent the sensor assembly from electrostatic discharge and high and reverse voltage.

Abstract: Described herein is the sense element assembly for a capacitive pressure sensor and method for creating same that has increased sensitivity despite the parasitic capacitance that is created. The capacitive sensor element assembly, comprises a first semiconductive layer, and a first conductive layer, a first dielectric layer into which a cavity has been formed, the dielectric layer lying between the first semiconductive layer and the first conductive layer, wherein an electrical connection is made to the second conductive layer. A preferred method for fabricating a capacitive sensor assembly of the present invention comprises the steps of forming a dielectric layer on top of a conductive handle wafer; creating at least one cavity in the dielectric layer, bonding a thin semiconductive layer to the dielectric layer and connecting an operational amplifier to the input of the capacitive sensor assembly to overcome the parasitic capacitance formed during fabrication.

Abstract: A power reduction system includes a central server and a plurality of power reduction devices. The central server of the power reduction aggregation system includes: a network interface configured to transmit and receive information to and from a communication network; a power grid status module coupled to the network interface and configured to transmit a power status message to the network, via the network interface, toward at least two power reduction devices connected to the network; and a power savings compensation module configured to determine an aggregate compensation earned for providing an aggregate energy reduction induced by the at least two power reduction devices in response to receiving the power status message, and further configured to determine individual portions of the aggregate compensation associated with each of the at least two power reduction devices.

Abstract: Described herein is a method for integrating MEMS with submicron semiconductor electrical circuits such as CMOS to provide more complex signal processing, on-chip calibration and integration with RF technologies. A MEMS sensor is provided having an upper layer, an insulating layer into which a cavity has been formed and a handle layer. The upper layer acts as both the substrate of the semiconductor electrical circuit and as the active MEMS element. The remainder of the circuitry is fabricated either in or on the upper layer. In a preferred method of the present invention a first wafer assembly and a second wafer assembly are fabricated such that a MEMS sensor and the substrate of at least one semiconductive electrical circuit is formed.

Abstract: An apparatus for and method of storing video data comprising receiving an MPEG video stream comprising I-frames and P-frames, separating the I-frames from the P-frames, storing the I-frames and the P-frames separately, and providing information so that the I-frames and the P-frames can be combined to produce a full-motion video.

Abstract: “Electromagnetic spring” characteristics can be obtained in a voice coil actuator by deliberately selecting some or all of geometry, location of the housing, field assembly and coils, and/or magnitude and direction of the current applied to the coils; for example, predetermined bidirectional spring characteristics can be provided by appropriate deliberate selection of the relative dimensions of the housing and field assembly, and the spring characteristics can be further altered though the addition of structures, such as a radially magnetized magnet, or a soft magnetic extension, positioned at an end of the housing, and/or by applying current of a selected magnitude and direction to the coil assembly.

Abstract: A data center cooling solution providing techniques for using baffles, doors and roof sections to prevent warm air from being entrained into a cold aisle in a data center, wherein the data center generally contains an air cooling system and a raised floor structure. The raised floor structure is configured to deliver cool air into the data center through a plurality of grates and perforated tiles in the floor. Electronic equipment racks are disposed around the grates and perforated tiles, such that the front faces of the equipment racks face the grates and perforated tiles. A collection of baffles, doors or roof sections inhibit the mixing of the cool air delivered by the air cooling system and the warm air exhausted by the electronic equipment.

Abstract: A system includes a substantially sealed, substantially airtight cabinet sized for housing a vertical array of heat-producing units, the cabinet having an exterior shell and the system including an interior divider wall disposed inside the cabinet, the shell and divider wall providing an equipment chamber adapted to support the array such that the array cooperates with the shell and divider wall in use to define a first plenum, the first plenum having a first inlet defined by the divider wall for receiving a flow of cooling gas and having a first outlet defined by a plurality of openings through the array whereby the first plenum communicates with the openings in use to exhaust substantially all of the flow of cooling fluid through the openings and hence through the array, wherein the divider wall is configured to allow the first inlet to admit the gas to the first plenum in a substantially horizontal direction.

Abstract: A wireless data transmission system incorporates a process sensor providing an output for process monitoring data with a transmitter connected to the output of the sensor and transmitting the data in time gated intervals. A receiver receives the data from the transmitter and a determination is made if new data is received at a gated time interval. A processor connected to the receiver calculates process parameters based on the data received and a set of the calculated process parameters is stored. The processor estimates process parameters based on the stored set of calculated process parameters responsive to a signal from the determination that data packets have not been received at the gated interval. The process parameters front actual data, if present, or from the estimates made by the processor are then output for process control. A counter responsive to the determination of lost data, provides an emergency stop signal upon reaching a predetermined number of counts.

Abstract: Described herein is the sensor assembly and method for rapidly obtaining accurate readings of a variable. The sensor assembly comprises a plurality of sensors which are connected to a microcontroller that processes the signals of the individual transducers to the microcontroller. The microcontroller contains software that maximizes the refresh rate and/or minimizes the time it takes to process the outputs of each of the transducers. The microcontroller that is coupled to the sensor assembly selectively measures the outputs of each transducer so as to speed up the refresh rate of the sensor.

Abstract: A heatsink includes a thermally conductive body including a plurality of fins configured to conduct and dissipate heat. The body is configured to receive a circuit board containing heat-producing electrical components along a width of the body. The heatsink further includes a pivot mechanism pivotally coupled to the body and configured and disposed to contact the heat-producing electrical components. The heatsink further includes a bias device connected to the body and the pivot mechanism and configured to change from a first state to a second state to cause the pivot mechanism to rotate relative to the body to move a contact portion of the pivot mechanism toward the body. The heatsink is configured to receive the heat-producing electrical components between the contact portion of the pivot mechanism and the body, and the bias device is configured to bias the contact portion of the pivot mechanism to urge the heat-producing electrical components against the body when the bias device is in the second state.