Abstract: A first transistor, a second transistor, a third transistor, and a fourth transistor, their source terminals being grounded, are provided. Further, a first feedback circuit connected between a gate terminal and a drain terminal in the first transistor, and having first impedance, a second feedback circuit connected between a gate terminal and a drain terminal in the second transistor, and having the first impedance, a current source for outputting a current, a first load circuit connected between the drain terminal of the first transistor and a first output terminal of the current source, and having second impedance, and a second load circuit connected between the drain terminal of the second transistor and a second output terminal of the current source, and having the second impedance are provided.

Abstract: A sample and hold circuit including a charge path coupled to a voltage source. A first node of the charge path is located closer to the voltage source in the charge path than a second node of the charge path. The second node is coupled to an output of the sample and hold circuit to provide an output voltage. The sample and hold circuit includes a comparator circuit that compares the voltage of the first node and the voltage of the second node. When the comparator circuit determines that the voltage of the first node is a first condition with respect to a voltage of the second node, a voltage source provides a charging voltage on the first path to charge a first capacitor and a second capacitor to the charging voltage.

Abstract: A reference voltage generator has a first N type depletion MOS transistor configured to cause a constant current to flow, and a second N type depletion MOS transistor diode-connected to the first N type depletion MOS transistor and configured to generate a reference voltage based on the constant current. The first and second N type depletion MOS transistors have the same temperature coefficient of a threshold voltage. The first N type depletion MOS transistor has a buried channel into which arsenic impurities are diffused. The second N type depletion MOS transistor has a buried channel into which phosphorous impurities are diffused.

Abstract: A method and circuit are provided for implementing adaptive control for optimization of pulsed resonant drivers, and a design structure on which the subject circuit resides. Peak detectors are used to detect a positive or up level reached by a resonant clock and negative or down level reached by the resonant clock. Each detected levels is compared to a reference level to determine when to vary the turn off timing of a clock driver pull-up device and/or a clock driver pull-down device. A positive peak detector controls the turn off time of the pull-up device and a negative peak detector controls a turn off time of the pull-down device in the pulsed resonant driver.

Abstract: A method and circuit are provided for implementing adaptive control for optimization of pulsed resonant drivers, and a design structure on which the subject circuit resides. Peak detectors are used to detect a positive or up level reached by a resonant clock and negative or down level reached by the resonant clock. Each detected levels is compared to a reference level to determine when to vary the turn off timing of a clock driver pull-up device and/or a clock driver pull-down device. A positive peak detector controls the turn off time of the pull-up device and a negative peak detector controls a turn off time of the pull-down device in the pulsed resonant driver.

Abstract: An equalizer circuit includes an input terminal, a pull-up driving unit suitable for pull-up driving an output terminal based on a signal of the input terminal, a pull-down driving unit suitable for pull-down driving the output terminal, and a capacitor connected between the input terminal and the output terminal.

Abstract: The present invention relates to polymers comprising one or more (repeating) unit(s) of the formula (I), and at least one (repeating) unit(s) which is selected from repeating units of the formula (II), (III) and (IV); and polymers of the formula III, or IV and their use as organic semiconductor in organic devices, especially in organic photovoltaics (solar cells) and photodiodes, or in a device containing a diode and/or an organic field effect transistor. The polymers according to the invention have excellent solubility in organic solvents and excellent film-forming properties. In addition, high efficiency of energy conversion, excellent field-effect mobility, good on/off current ratios and/or excellent stability can be observed, when the polymers according to the invention are used in organic field effect transistors, organic photovoltaics (solar cells) and photodiodes.

Abstract: The even order harmonic distortion in a differential circuit is reduced or eliminated by treating the amplitude and phase mismatch sources that cause the distortion as impedance mismatches, and utilizing switched resistor circuitry that adjusts the load resistance to reduce the effects of the amplitude mismatch sources, and switched capacitor circuitry that adds shunt capacitance to reduce the effects of the phase mismatch sources.

Abstract: A method for adaptively driving data transmission and a communication device using the same are provided. The proposed method includes following procedures. Detection result is generated after detecting a receiving signal on a receiving path of the communication device. Driving parameter is generated according to the detection result. Finally, a transmitting signal on a transmitting path is adjusted according to the driving parameter.

Abstract: A method for calibrating signal swing and a trip reference voltage. The signal swing of a system can be calibrated in a symmetric or asymmetric technique through adjustment of a drive parameter such as a supply voltage for a transmitter or a drive termination. The trip reference voltage of the system can also be calibrated in a symmetric or asymmetric technique through sampling of a data pattern to determine an ideal level of the trip reference voltage.

Abstract: A method for calibrating signal swing and a trip reference voltage. The signal swing of a system can be calibrated in a symmetric or asymmetric technique through adjustment of a drive parameter such as a supply voltage for a transmitter or a drive termination. The trip reference voltage of the system can also be calibrated in a symmetric or asymmetric technique through sampling of a data pattern to determine an ideal level of the trip reference voltage.

Abstract: A semiconductor apparatus includes an input terminal to which an input voltage is applied; an output terminal at which an output voltage is obtained; a power supply circuit unit configured to generate the output voltage from the input voltage, the output voltage having a value corresponding to a duty cycle of a voltage setting signal that is externally applied to the semiconductor apparatus; and a determination circuit unit determining whether the voltage setting signal has a predetermined signal level for the duration of a first predetermined time or longer. The determination circuit unit activates the power supply circuit unit when the voltage setting signal does not have the predetermined signal level for the duration of the first predetermined time or longer. The power supply circuit unit is deactivated when the voltage setting signal has the predetermined signal level for the duration of the first predetermined time or longer.

Abstract: The input interface for a transmit/receive radio station includes an input for receiving a signal either with a variable voltage over a pre-determined voltage range, or an open collector signal having a voltage (0V) corresponding to the low logic state; a first output for the variable voltage signal, and a second open collector output. The first and second outputs are connected to the same input and the input is connected to a reference potential through a first voltage divider bridge, the middle point of which is connected to the positive terminal of an open loop comparator, the output of which is connected to the second output.

Abstract: A circuit includes a digital-to-analog converter with non-uniform resolution for converting a digital signal into an analog signal. The digital-to-analog converter includes high-resolution circuitry, reduced-resolution circuitry coupled to the high-resolution circuitry and a switch coupled to the high-resolution circuitry and to the reduced-resolution circuitry. The switch couples one of the high-resolution circuitry and the reduced-resolution circuitry to an output node. The circuit also includes a decoder coupled to the switch. The decoder receives the digital signal to control the switch.

Abstract: An embodiment of a multiplying digital-to-analog converter (MDAC), an embodiment of a method for converting a digital signal to an analog signal, an embodiment of a pipelined analog-to-digital converter (ADC), and a method of converting an analog signal to a digital signal in a plurality of cascading stages.

Abstract: An integrated circuit (IC) includes a sensing circuit that outputs a sense signal. An external power supply may receive the sense signal and adjust a power supply voltage to the IC. The sensing circuit may comprise an oscillatory circuit that outputs a time-varying signal. The sense signal is based on the time-varying signal.

Abstract: The clock circuit of an integrated circuit operates with variations such as temperature, ground noise, and power noise. Various aspects of an improved clock integrated circuit address one or more of the variations in temperature, ground noise, and power noise.

Abstract: Provided is an offset-voltage calibration circuit. The circuit includes a comparator configured to receive at least two comparison voltages and output a result of a comparison between the comparison voltages, an up/down counter (UDC) configured to output an up-counting or down-counting output signal in response to an output signal of the comparator, and a current digital-to-analog converter (DAC) configured to control the amount of current supplied from a node to which the comparison voltage is applied, in response to the output signal of the UDC and control the magnitude of the comparison voltage.

Abstract: An internal voltage generating circuit of a semiconductor device includes a normal reference voltage generating unit configured to generate a normal reference voltage having a constant voltage level without regard to PVT variations, a test reference voltage generating unit configured to generate a test reference voltage by dividing a voltage level between an external power supply voltage and the normal reference voltage at a set ratio, an operation reference voltage generating unit configured to generate an operation reference voltage by selecting one of the normal reference voltage and the test reference voltage in response to a test signal, and an internal voltage generating unit configured to generate an internal voltage whose voltage level is determined based on the level of the operation reference voltage.

Abstract: A clamping circuit clamps a voltage received by an n-type semiconductor region without using a Schottky transistor. The clamping circuit includes a current mirror as well as first and second bipolar transistors. The current mirror receives a first current and supplies a second current in response. The first current is received by the first bipolar transistor, and the second current is received by the second bipolar transistor. The difference between the base-emitter junction voltages of the first and second bipolar transistors, in part, defines the voltage at which the n-type region is clamped. To start-up the circuit properly, current is withdrawn from the base/gate terminals of the transistors disposed in the current mirror. The circuit optionally includes a pair of cross-coupled transistors to reduce the output impedance and improve the power supply rejection ratio.

Abstract: A high-speed differential comparator circuit is provided with an accurately adjustable threshold voltage. Differential reference voltage signals are provided to control the threshold voltage of the comparator. The common mode voltage of the reference signals preferably tracks the common mode voltage of the differential high-speed serial data signal being processed by the comparator circuit.

Abstract: An integrated circuit comprises a threshold generation circuitry for generating at least one differential voltage signal. The threshold generation circuitry comprises at least one common mode current generation circuit arranged to generate at least one common mode current signal, whereby said at least one common mode current signal is combined with at least one input current signal to produce a combined current signal comprising a combined signal common mode component. Conversion circuitry is arranged to receive the combined current signal and convert the combined current signal into the at least one differential voltage signal for use within the comparator circuit. The threshold generation circuitry further comprises feedback circuitry arranged to receive an indication of the combined signal common mode component, compare the received indication to a reference value, and regulate the at least one common mode current signal based at least partly on the comparison results.

Abstract: A first bias circuit outputs a first direct-current voltage to charge a first capacitor based on a clock signal. A second bias that outputs a second direct-current voltage to charge a second capacitor based on a clock signal. A first MOS transistor has a gate and a source. The first direct-current voltage is applied between the gate and the source of the first MOS transistor to bias the gate of the first MOS transistor. A second MOS transistor has a gate and a source, and a drain connected to the source of the first MOS transistor. The second direct-current voltage is applied between the gate and the source of the second MOS transistor to bias the gate of the second MOS transistor. A coupling capacitor has a first end connected to the source of the first MOS transistor, and a second end to which an alternating-current signal is input.

Abstract: A circuit for charging a battery may include a switch operable for conducting a current flowing through the switch, and a first amplifier coupled to the switch and operable for adjusting the current according to an amount of power dissipation associated with the switch.

Abstract: According to one embodiment, an interface comprises establishing a connection to a communicatee device, transmitting a connection maintenance signal to the communicatee device, and decreasing a maximum amplitude of the connection maintenance signal from a first amplitude, establishing a connection to the communicatee device again when communication is disabled, and transmitting the connection maintenance signal to the communicatee device, and setting the maximum amplitude of the connection maintenance signal to a second amplitude which is larger than the maximum value of the connection maintenance signal obtained when the communication is disabled by a predetermined value.

Abstract: An adaptive low noise offset subtraction pixel and method for adaptive low noise offset subtraction is disclosed. The pixel has a photosensitive element, a current offset memorization circuit and a current subtraction circuit. The current subtraction circuit coupled to the current offset memorization circuit, and comprises a transistor selected from a group consisting of a junction gate field-effect transistor, a bipolar transistor, a MOSFET transistor with a spiral channel, and a MOSFET transistor with a buried channel. The transistor configured to receive an offset current from the current offset memorization circuit and subtract the offset current from an output signal current received from the photosensitive element to provide an offset-free signal current and a shot noise limited subtraction current.

Abstract: The digital signal processor is for correcting a DC output at an output terminal of an internal circuit of an analog circuit device. The digital signal processor includes a digital register for storing a digital value, a D/A converter for converting the digital value stored in the digital register into an analog voltage and applying the converted analog voltage to the output terminal as the DC output, a polarity determining circuit which outputs a first signal when an analog DC voltage at a reference correction point different from the output terminal in the internal circuit is higher than a predetermined threshold value and otherwise outputs a second signal, and an updating function configured to monotonously increase or decrease the digital value stored in the digital register while a predetermined one of the first and second signals is outputted from the polarity determining circuit.

Abstract: An output circuit of a semiconductor device includes a signal selector configured to receive first and second input data signals and sequentially outputting the first and second input data signals in response to a phase signal; and an output level controller configured to control a voltage level of an output signal of the signal selector based on the first and second input data signals.

Abstract: Methods and systems for offset compensation using calibration are provided. Embodiments enable offset compensation using non-uniform calibration. Embodiments enable calibration schemes configurable according to the probability distribution function (PDF) of the random offset. Embodiments enable calibration schemes configurable with multiple levels of calibration resolution according to the PDF of the random offset. Embodiments enable calibration schemes configurable with multiple calibration step values according to the PDF of the random offset. Embodiments can be implemented for various types of random offset, including, without limitation, Gaussian-, Bernoulli-, uniformly-, Chi-, exponentially-, Gamma-, and Pareto-distributed offset.

Abstract: A USB chip having a self-calibration circuit is provided. The USB chip includes a comparing circuit, a digital circuit and an adjustable current output device. A close-loop structure is provided to monitor an output voltage level of the USB chip and then an output current is dynamically adjusted to calibrate the output voltage level.

Abstract: The present invention provides a method and apparatus for dynamically correcting overshoot and undershoot errors in an analog integrated circuit by improving the reaction time (?t) of the analog integrated circuit. Equivalently, an error correction circuit is disclosed present invention is only activated to reduce overshoot and undershoot errors by increasing the bandwidth of the integrated circuit when either undershoot or overshoot errors are detected.

Abstract: Methods and systems for offset compensation using calibration are provided. Embodiments enable offset compensation using non-uniform calibration. Embodiments enable calibration schemes configurable according to the probability distribution function (PDF) of the random offset. Embodiments enable calibration schemes configurable with multiple levels of calibration resolution according to the PDF of the random offset. Embodiments enable calibration schemes configurable with multiple calibration step values according to the PDF of the random offset. Embodiments can be implemented for various types of random offset, including, without limitation, Gaussian-, Bernoulli-, uniformly-, Chi-, exponentially-, Gamma-, and Pareto-distributed offset.

Abstract: A transceiver that reduces power consumption when data is transferred between devices in different modes. The transceiver is arranged in a first node and in a second node, which communicate between each other. A first control unit generates a first signal transmitted from the first node in predetermined time intervals during a first period that establishes an environment for communication between the first node and the second node. The second node transmits a second signal transmitted in response to the first signal. The first control unit generates a third signal upon detection of the second signal. A second control unit gradually decreases amplitude of the first signal based on the third signal to set the amplitude of the first signal to a predetermined amplitude so that the second node is receivable of the first signal.

Abstract: The present invention relates to a gate driving circuit, comprising a driver control circuit, a voltage following bias circuit, a pull up circuit and a MOS transistor. The driver control circuit receives an active signal and generates a pull up signal or a pull down signal. In case of the pull up signal, the MOS transistor is turned to the OFF state by the pull up circuit, and there is no current for the output load device. In case of the pull down signal, the MOS transistor is turned to the ON state by the voltage following bias circuit. The driving voltage for the gate of the MOS transistor has a constant voltage drop according to the external supply voltage. Therefore, the gate driving circuit of the present invention provides a constant current for the output load device.

Abstract: A high sensitivity, three-dimensional gamma ray detection and imaging system is provided. The system uses the Compton double scatter technique with recoil electron tracking. The system preferably includes two detector subassemblies; a silicon microstrip hodoscope and a calorimeter. In this system the incoming photon Compton scatters in the hodoscope. The second scatter layer is the calorimeter where the scattered gamma ray is totally absorbed. The recoil electron in the hodoscope is tracked through several detector planes until it stops. The x and y position signals from the first two planes of the electron track determine the direction of the recoil electron while the energy loss from all planes determines the energy of the recoil electron.

Abstract: The problem to be solved by of this claimed application is solved by providing an interface circuit and a signal output adjusting method that are capable of adjusting amplitude of a transmission-side signal by taking attenuation of a transmission path into consideration. In a transmission-side circuit part of an interface circuit 100, a repetitive signal 111 having constant amplitude is sent out to a transmission path 123 through an output buffer circuit 117 that is configured of a CML circuit at the time of testing. In a reception-side circuit part 102, a determining circuit 135 compares the amplitude of the input signal 131 with each of a plurality of reference voltages Vref1 to Vrefn in comparators 1321 to 132n to obtain a comparison result. And, a voltage controlling circuit 119 of a transmission-side circuit part 101 makes the setting of the amplitude by appropriately controlling a constant current value of the CML circuit, thereby enabling the low consumption power to be realized.

Abstract: Systems and methods for aligning the phase of a PLL with an incoming data signal. In one embodiment, when a data signal is received in a PLL, a phase perturbation signal is generated and injected into the PLL. The PLL then performs a phase alignment procedure to lock on to the received data signal. The phase perturbation signal is a damped sinusoidal oscillation that is injected into the PLL when each of a plurality of data packets is received. The perturbation signal has an amplitude sufficient to bump the PLL out of a quasi-stable state around 180 degrees out of phase with the incoming data signal, but is damped to less than a degree of phase shift within 30 ns of being injected.

Abstract: A signal receiver circuit includes a first level detector for offset-controlling a first output node in response to a pair of first reference signals. A second level detector offset-controls a second output node in response to a pair of second reference signals.

Abstract: A voltage reference circuit receives an input voltage at a first port and a time varying input signal at a second port. The voltage reference circuit includes a switching circuit that is responsive to the first and second ports, and that generates an AC signal from the input voltage. The voltage reference circuit further includes a voltage multiplier circuit, coupled to the switching circuit to receive the AC signal and to create a DC signal with a selected voltage level. The voltage reference circuit further includes a plurality of voltage reference modules, coupled together to form a voltage reference stack, and coupled to the voltage multiplier circuit to receive the selected voltage level and output a precise reference voltage.

Abstract: A contention-free keeper circuit including a keeper circuit having a first node and a second node, is provided. The contention-free keeper circuit may further include a delay element for providing time delay. The contention-free keeper circuit may further include a high-to-low contention element coupled between the first node and a first supply, and coupled to the delay element output. The contention-free keeper circuit may further include a low-to-high contention elimination element coupled between the first node and a second supply, and coupled to the delay element output, (i) wherein responsive to a low-to-high transition at the first node and the time delay, the low-to-high contention elimination element eliminates a low-to-high contention within the keeper circuit, and (ii) wherein responsive to a high-to-low signal transition at the first node and the time delay, the high-to-low contention elimination element eliminates a high-to-low contention within the keeper circuit.

Abstract: A method, apparatus, and computer program product in a data processing system for testing differential clock or oscillator signals. A method is comprised of the following steps: A first single-ended receiver is connected to a positive leg of a differential pair, and a second single-ended receiver is connected to a negative leg of the differential pair. An output of the first single-ended receiver is inverted and delayed before being input into a first RS Flip-Flop. An output of the second single-ended receiver is delayed before being input into a second RS Flip-Flop. An output of a differential receiver is inverted and input into the first and second RS Flip Flops as reset signals. Then a Wire OK signal is output indicating the condition of the legs of the differential pair.

Abstract: In general, the embodiments introduce a pre-charge state between an idle state (when no data in being transmitted) and an active state (when data is being transmitted). In the pre-charge state, both differential signals are pre-charged to the common mode voltage, which is also the crossover voltage. Similarly, an additional pre-charge state is inserted between the active state and the idle state when the signals transition from active to idle. Because both signals for each bit, including the first and last bits, are being driven from the same voltage level, the quality of the first and last bits are improved to be similar in quality to the middle bits.

Abstract: One disclosed method comprises drawing current from a termination voltage supply and through a termination voltage delivery network by termination circuitry in response to a first signal on one or more lines terminated by the termination circuitry, shunting current from the termination voltage supply and through the termination voltage delivery network in response to a second signal on one or more terminated lines, and helping to reduce the shunted current for extended shunting.

Abstract: A booster includes a boosting circuit and a feedback control circuit. The boosting circuit is used to boost an input voltage into a predetermined output voltage; the feedback control circuit detects the output voltage of the boosting circuit and stops boosting the voltage when the output voltage is higher than a predetermined value so as to prevent additional power consumption of a battery and increase transferring efficiency.

Abstract: The amplitude expansion circuit as a main part of a drive circuit includes: a VM DC power supply line to which a voltage VM is applied; a VH DC power supply line to which a voltage VH roughly twice as high as the voltage VM is applied; an inverter circuit receiving a pulse signal oscillating between the ground voltage and the voltage VM; another inverter circuit receiving a pulse signal oscillating between the voltage VM and the voltage VH in correspondence with the oscillation of the voltage level of the above pulse signal; a p-channel MOSFET having a gate receiving an output from the inverter circuit; another p-channel MOSFET having a gate connected to the VM DC power supply line; an n-channel MOSFET having a gate connected to the VM DC power supply line; and another n-channel MOSFET having a gate receiving an output from the other inverter circuit. A common connection node of the p-channel MOSFET and the n-channel MOSFET works as the output terminal of the amplitude expansion circuit.

Abstract: In general, the embodiments introduce a pre-charge state between an idle state (when no data in being transmitted) and an active state (when data is being transmitted). In the pre-charge state, both differential signals are pre-charged to the common mode voltage, which is also the crossover voltage. Similarly, an additional pre-charge state is inserted between the active state and the idle state when the signals transition from active to idle. Because both signals for each bit, including the first and last bits, are being driven from the same voltage level, the quality of the first and last bits are improved to be similar in quality to the middle bits.

Abstract: An amplification circuit of the present invention includes a first MOS transistor having a gate to which a first input terminal for inputting a positive logic input signal or a reference potential is connected and a drain to which a first load is connected, a second MOS transistor having a gate to which a second input terminal for inputting a negative logic input signal, which composes differential input signals with the positive logic signal, or the reference potential is connected and a drain to which an output terminal and a second load are connected, and pairing up with the first MOS transistor, and a current source to which sources of the first and second MOS transistors are connected, for supplying a constant current when the difference in voltage between the first and second input terminals is in a predetermined range, and varying the current to be supplied when the difference in voltage is beyond the predetermined range.

Abstract: Method and apparatus are provided for processing a wide dynamic range analog signal which comprises a compressive nonlinear transfer function responsive to the average amplitude of the signal without feedback along the signal path. The invention employs frequency selective filtering and expansion of the compressed signal. The invention is applicable to any analog signal system having a plurality of channels carrying related signal information.

Abstract: A circuit for limiting loss in a second circuit. The circuit may include a first timer, a second timer and one or more logic gates. The first timer may produce a first output in a given state if the duration of a pulse for use with the second circuit reaches a first predetermined amount of time, where the first predetermined amount of time is related to a parameter of the second circuit. The second timer may produce a second output in the given state if the first timer does not produce the first output in the given state when the duration of the pulse reaches a second predetermined amount of time. The one or more logic gates may have an output that is the same as the pulse unless and until the output of the first timer or the second timer is in the given state, at which time, the output of the one or more logic gates is forced to a non-pulsed state.

Abstract: A test on a desired internal voltage is easily and accurately conducted without increasing current dissipation or the number of pads. A driving circuit receiving a reference voltage from a reference voltage generating circuit has a high input impedance and low output impedance, and generates a voltage substantially at the same voltage level as the reference voltage received, and transmits the generated voltage to a pad with a current driving capability larger than the driving current capability of the reference voltage generating circuit.