Abstract: Disclosed is a fractional bandgap circuit and method to provide a same reference voltage value in a variety of circumstances of operation, including variations in manufacturing process, temperature, and a supply voltage. The disclosed fractional bandgap circuit and method also allows for low supply voltage operation within a compact layout area.

Abstract: An input power on a tag is monitored. An input impedance of the tag is adjusted based on the monitored input power to increase a backscatter level of the tag. In one embodiment, an output voltage of a rectifier device is monitored. An input power to the tag is determined based on the output voltage. An input impedance of the tag is adjusted based on the input power to increase the backscatter level of the tag.

Abstract: A method of programming one-time programmable (OTP) memory cells in an array is described. Each memory cell has a MOSFET programming element and a MOSFET pass transistor, the MOSFET pass transistor having a gate electrode over a channel region between two source/drain regions, and the MOSFET programming element having a gate electrode over a channel region contiguous to a source/drain region either part of, or connected to, one of the two source/drains associated with the MOSFET pass transistor. The other source/drain region of the MOSFET pass transistor is coupled to a bit line. The memory cell is programmed by setting a first voltage of a first polarity on the gate electrode of the pass transistor to electrically connect the source/drain regions of the pass transistor; setting a second voltage of the first polarity on the gate electrode of the programming element; and setting a third voltage of a second polarity on the bit line.

Abstract: A circuit arrangement and method of reading the logic state of a memory cell in an array of semiconductor memory cells. A data memory cell selected from the array drives a current on a first data bit line in a read operation. A reference memory cell corresponding to the memory cell is activated after the memory cell is selected, the reference memory cell driving a current through the reference data line at a greater rate than that of the corresponding memory cell regardless of the logic state of the memory cell. A sense amplifier connected to the data line and a reference data line determines the logic state of the selected memory cell. A delay circuit activates the reference memory cell after the memory cell is selected and enables the sense amplifier after the reference memory cell has been activated.

Abstract: An input power on a tag is monitored. An input impedance of the tag is adjusted based on the monitored input power to increase a backscatter level of the tag. In one embodiment, an output voltage of a rectifier device is monitored. An input power to the tag is determined based on the output voltage. An input impedance of the tag is adjusted based on the input power to increase the backscatter level of the tag.

Abstract: Disclosed is a fractional bandgap circuit and method to provide a same reference voltage value in a variety of circumstances of operation, including variations in manufacturing process, temperature, and a supply voltage. The disclosed fractional bandgap circuit and method also allows for low supply voltage operation within a compact layout area.

Abstract: Methods, apparatuses, and system for performing at least one of error correction or error detection are described. In one embodiment, a radio frequency identification (RFID) tag receives a signal activating or interrogating the tag. The tag includes memory that stores data associated with the tag. The tag performs at least one of error detection or error correction on the stored data. The error detection includes detecting, by the tag, that one or more bits of the stored data are inflicted with an error. The error correction includes correcting the erroneous bit if the error affects less than a predetermined number of the bits of the stored data. The tag transmits the stored data to a reader in response to the detection or correction. The reader can analyze the stored data for additional information about the error or provide the stored data to another computing system that performs the analysis.

Abstract: A circuit arrangement and method of reading the logic state of a memory cell in an array of semiconductor memory cells. A data memory cell selected from the array drives a current on a first data bit line in a read operation. A reference memory cell corresponding to the memory cell is activated after the memory cell is selected, the reference memory cell driving a current through the reference data line at a greater rate than that of the corresponding memory cell regardless of the logic state of the memory cell. A sense amplifier connected to the data line and a reference data line determines the logic state of the selected memory cell. A delay circuit activates the reference memory cell after the memory cell is selected and enables the sense amplifier after the reference memory cell has been activated.

Abstract: A method of programming one-time programmable (OTP) memory cells in an array is described. Each memory cell has a MOSFET programming element and a MOSFET pass transistor, the MOSFET pass transistor having a gate electrode over a channel region between two source/drain regions, and the MOSFET programming element having a gate electrode over a channel region contiguous to a source/drain region either part of, or connected to, one of the two source/drains associated with the MOSFET pass transistor. The other source/drain region of the MOSFET pass transistor is coupled to a bit line. The memory cell is programmed by setting a first voltage of a first polarity on the gate electrode of the pass transistor to electrically connect the source/drain regions of the pass transistor; setting a second voltage of the first polarity on the gate electrode of the programming element; and setting a third voltage of a second polarity on the bit line.

Abstract: A Power-on Reset circuit is described. The Power-on Reset is formed by two comparators and a latch circuit. The Power-on Reset circuit will de-assert the reset state once the supply voltage reaches a first reference point and re-assert the reset state once the supply voltage drops below a second reference point. The Power-on Reset circuit disclosed further includes circuits to initialize properly and to ensure the regulator voltage and the bandgap voltages are stable and above the ground level voltage.

Abstract: Systems and methods are provided for staining tissue with multiple biologically specific heavy metal stains and then performing X-ray imaging, either in projection or tomography modes, using either a plurality of illumination energies or an energy sensitive detection scheme. The resulting energy-weighted measurements can then be used to decompose the resulting images into quantitative images of the distribution of stains. The decomposed images may be false-colored and recombined to make virtual X-ray histology images. The techniques thereby allow for effective differentiation between two or more X-ray dyes, which had previously been unattainable in 3D imaging, particularly 3D imaging of features at the micron resolution scale. While techniques are described in certain example implementations, such as with microtomography, the techniques are scalable to larger fields of view, allowing for use in 3D color, X-ray virtual histology of pathology specimens.

Abstract: A tag communication method includes providing a tag reader operating at a first frequency and having transmit and receive antenna ports, providing a frequency converter module having transmit and receive plugs adapted to directly mate with the transmit and receive ports, and directly mating the transmit plug with the transmit port and the receive plug with the receive port. A transmit signal at the first frequency is received from the reader by the converter module by way of the directly mated transmit plug and converted to a second frequency differing from the first frequency to provide a converted transmit signal which is transmitted to the tag. A receive signal is received from the tag at the second frequency and converted to the first frequency to provide a converted receive signal which is applied by the conversion module to the reader by way of the directly mated receive plug.

Abstract: A reader includes a single receiver circuit and a switching circuit coupled to the single receiver circuit. A first antenna connection is coupled to the switching circuit, wherein the first antenna connection is configured to receive a first signal from a source of radio frequency waves. A second antenna connection is coupled to the switching circuit, and the second antenna connection is configured to receive a second signal from the source of radio frequency waves. A processor is configured to determine angle of arrival information in accordance with the first and second signals. The processor is further configured to determine relative phase information in accordance with the first and second signals. Additionally, the processor is configured to localize the source of radio frequency waves in accordance with the angle of arrival information. The switching circuit includes a multiplexer selectively coupling the first and second antenna connections to the single receiver circuit.

Abstract: A tag communication method includes providing a tag reader operating at a first frequency and having transmit and receive antenna ports, providing a frequency converter module having transmit and receive plugs adapted to directly mate with the transmit and receive ports, and directly mating the transmit plug with the transmit port and the receive plug with the receive port. A transmit signal at the first frequency is received from the reader by the converter module by way of the directly mated transmit plug and converted to a second frequency differing from the first frequency to provide a converted transmit signal which is transmitted to the tag. A receive signal is received from the tag at the second frequency and converted to the first frequency to provide a converted receive signal which is applied by the conversion module to the reader by way of the directly mated receive plug.

Abstract: A tag communication method includes providing a tag reader operating at a first frequency and having transmit and receive antenna ports, providing a frequency converter module having transmit and receive plugs adapted to directly mate with the transmit and receive ports, and directly mating the transmit plug with the transmit port and the receive plug with the receive port. A transmit signal at the first frequency is received from the reader by the converter module by way of the directly mated transmit plug and converted to a second frequency differing from the first frequency to provide a converted transmit signal which is transmitted to the tag. A receive signal is received from the tag at the second frequency and converted to the first frequency to provide a converted receive signal which is applied by the conversion module to the reader by way of the directly mated receive plug.

Abstract: The present invention utilizes the main Java package (javax.jcr.binary) for saving the node property path and other relevant retrieving information within the serialized XML node files so that the intended large binary data remains inside the content repository while the corresponding node is being serialized. A data centric application which requires processing of the serialized XML node file can then deal with a much reduced sized XML file. This can improve the performance greatly in terms of memory usage and processing speed for XML processors such as DOM. During the consuming phase of the data centric applications, the binary data property is streamed from its source JCR repository into the target repository by looking up its original property path and other retrieving information.

Abstract: A reader includes a single receiver circuit and a switching circuit coupled to the single receiver circuit. A first antenna connection is coupled to the switching circuit, wherein the first antenna connection is configured to receive a first signal from a source of radio frequency waves. A second antenna connection is coupled to the switching circuit and configured to receive a second signal from the source of radio frequency waves. A processor is configured to determine angle of arrival information in accordance with the first and second signals. The processor is further configured to determine relative phase information in accordance with the first and second signals. Additionally, the processor is configured to localize the source of radio frequency waves in accordance with the angle of arrival information. The switching circuit includes a multiplexer selectively coupling the first and second antenna connections to the single receiver circuit.

Abstract: A brake pad assembly is provided that includes a backing plate including a first surface, a second surface opposite to the first surface, and at least one opening. Also included are a friction material associated with the backing plate and a shim plate having a first shim surface and a second shim surface, and a tab projecting from the second shim surface. The shim plate is securely fastened to the backing plate by inserting the tab into the opening such that the friction material, when plastic, embeds the tab inside the opening by flowing through the opening, and subsequently hardens around the tab.

Abstract: An optical transceiver device including a modulating assembly. In contrast with conventional transceivers, the optical transceiver device uses a modulating assembly rather than a laser. The modulating assembly is located within the transceiver itself and includes first and second collimating lenses, first and second mirrors, and a p-i-n diode. An optical signal that has not yet been modulated is introduced into the modulating assembly via the first collimating lens, and is redirected toward the p-i-n diode via the first mirror. Depending on the voltage state of the diode, the light signal is either transmitted through the diode or prevented from passing, which results in modulation of the signal for data transmission. The modulated signal passes through the modulating assembly and is reflected by the second mirror toward the second collimating lens, through which it passes before exiting the transceiver.

Abstract: A method and system for enabling auto shut-off of programming of a non-volatile memory cell is disclosed. The system includes a memory array having a plurality of memory cells, each cell storing one bit of data. During the programming process, programming signals are applied to the target memory cells. A predefined period of time after the programming signals are applied, the auto shut-off system begins sensing an output signal from the memory cell. After the system detects an output signal from the memory cell, the system waits for a second predefined period of time before turning off the programming voltages. The system may be configured to sense an output voltage from the memory cell. The system then compares the output voltage to a reference voltage in order to detect when the cell is programmed. Alternatively, the system may sense an output current from the memory cell. The system then compares the output current to a reference current to detect when the cell is programmed.