Abstract: An emission reduction device for a CAN bus system. The device includes an evaluation block for evaluating signals that are transferred differentially on two bus lines, the evaluation block being designed to form the sum voltage of the differentially transferred signals, and a comparison block for comparing the sum voltage in such a way that the difference between the sum voltage for a dominant bus state and the sum voltage for a recessive bus state has a predetermined minimum value, the recessive bus state being overwritable by a dominant bus state. For the comparison, the comparison block is designed to modify at least one property of the transceiver device via a setting in a block of the transceiver device until the difference between the sum voltage for a dominant bus state and the sum voltage for a recessive bus state has the predetermined minimum value.

Abstract: Provided is a driver circuit that controls an output unit that switches whether or not to supply a current to an output line, in accordance with a potential difference between a first control signal to be input and a voltage of the output line. The driver circuit comprises a control line that transmits the first control signal to the output unit; a low potential line to which a predetermined reference potential is applied; a first connection switching unit that switches whether or not to connect the control line and the low potential line, in accordance with a second control signal; and a cutoff unit that is provided in series with the first connection switching unit between the control line and the low potential line and cuts off the control line and the low potential line based on a potential of the low potential line.

Abstract: A comparing device includes a first current generating circuit arranged to selectively generate a first current and a second current different from the first current, according to a first control signal. The comparing device also includes a comparing circuit having a common node coupled to the first current generating circuit for comparing a first input signal and a second input signal to generate an output signal according to the first current, the second current, and a second control signal. The second control signal and the first control signal are in-phase with each other.

Abstract: A device of analyzing at least one transistor includes a tester circuit, a measure device and a processor. The tester circuit is electrically connected to the transistor, the measure device is electrically connected to the transistor, and the processor is electrically connected to the measure device. The tester circuit is configured to test the transistor. The measure device is configured to receive a waveform from the transistor. The processor is configured to perform a curve-fitting on the waveform to get a transistor characteristic curve, to model the transistor characteristic curve to generate a transistor model, to simulate and regulate one or more parameters of the transistor model to create a new transistor model, and to extract slew rate data from the new transistor model.

Abstract: Disclosed are level shifters and methods of performing level shifting. In one embodiment, a level shifter is disclosed comprising an input, cross-coupled/latch circuitry, a first reference node, a second reference node, and output circuitry coupled between the cross-coupled/latch circuitry and an output, wherein the output circuitry sets the output signal to high based on rising edge of a second reference node and sets the output signal to low based on the rising edge of the first reference node. Further, the first reference node and the second reference node are symmetric nodes having signals that are inverse to each other.

Abstract: A state of one or more fuses can be determined using a common-gate FET device to read reference information and test information from a fuse bank. In an example, the FET device can be selectively diode-connected using a first switch that responds to a control signal, and a signal-storing capacitor can be connected to the gate terminal of the FET device. The capacitor can store information about a reference signal when the first switch is closed and a first input signal is applied at a source node of the FET device. When the first switch is open, a second input signal can be applied at the source node of the FET device, and an output signal at the drain node of the FET device can indicate a magnitude relationship between the first input signal and the reference signal. In an example, the second input signal can indicate a state of a fuse.

Abstract: In a semiconductor integrated circuit employing power gating, a control input signal is propagated to one or more first power switches through a first propagation path and to one or more second power switches through a second propagation path. A restoration determination circuit receives a first signal of the first propagation path and a second signal of the second propagation path and generates a control output signal. When the control signal performs restoration transition, the restoration determination circuit causes the control output signal to perform the restoration transition in accordance with a later timing of timings of restoration transitions of the first and second signals.

Abstract: A buffering device includes: a buffering circuit coupled between a first voltage source providing a first voltage level and a second voltage source providing a second voltage level, for selectively outputting an output signal with the first voltage level or the second voltage level according to an input signal; and a controlling circuit coupled to the buffering circuit, for generating a first control signal to disconnect the buffering circuit from the first voltage source and generating a second control signal to connect the buffering circuit to the second voltage source when the buffering circuit transits the output signal from the first voltage level to the second voltage level. The second voltage level is different from the first voltage level.

Abstract: A semiconductor device includes a first mode and a second mode different from the first mode, includes a memory circuit including a first switch, a memory array, and a peripheral circuit. A first power source line is electrically coupled with an I/O circuit of the peripheral circuit and is supplied with a first voltage in the first mode. A second power source line is electrically coupled with a memory cell of the memory array, and supplied with a second voltage lower than the first voltage in the second mode.

Abstract: A bandgap reference circuit including a clamp circuit is provided. The bandgap reference circuit performs the calibration only for one time in a normal mode to store a control code of a reference generator of the clamp circuit. In a suspend mode, the control code is used for controlling the reference generator to cause the clamp circuit to provide a desired source voltage, and a bandgap reference voltage source is shut down to reduce the power consumption.

Abstract: A line receiver comprising a switched capacitor circuit and a buffer is described. The buffer may be configured to receive, through the switched capacitor circuit, an analog signal. In response, the buffer may provide an output signal to a load, such as an analog-to-digital converter. The switched capacitor circuit may be controlled by a control circuitry, and may charge at least one capacitive element to a desired reference voltage. The reference voltage may be selected so as to bias the buffer with a desired DC current, and consequently, to provide a desired degree if linearity. The line receiver may further comprise a bias circuit configured to generate the reference voltage needed to bias the buffer with the desired DC current.

Abstract: An Integrated Circuit (IC) as described herein may include a first logic circuit, a second logic circuit coupled to the first logic circuit via a level shifter, and a safe state circuit coupled to the first logic circuit and to a first input of a logic gate. For example, a second input of the logic gate may be coupled to an output of the level shifter, and an output of the logic gate may be coupled to the second logic circuit. The safe state circuit may further include a front-end portion; a reversible current mirror portion coupled to the front-end portion; and a voltage-level translation portion coupled to the reversible current mirror portion.

Abstract: Embodiments of the invention provide a method, system, and program product for predicting a delay of a critical path. In one embodiment, the invention provides a method of predicting a delay of at least one critical path of an integrated circuit, the method comprising: determining a delay of at least one ring oscillator on the integrated circuit; and calculating a predicted delay for the at least one critical path delay based on a delay of components of the critical path at a corner condition, a wire delay of the at least one critical path, a delay of the at least one ring oscillator at a corner condition, and the determined delay of the at least one ring oscillator.

Abstract: Apparatuses and methods for partial bit de-emphasis are provided. An example apparatus includes an output driver and control circuit. The output driver includes a pull-up circuit including one or more pull-up legs, and a pull-down circuit including one or more pull-down legs. The control circuit may be coupled to the output driver and configured to receive an input signal having a first logical value and a second logical value, and in response to determining the logical transition has occurred from the second logic value to the first logic value, cause the pull-up circuit and pull-down circuit respectively to enter a first state for a duration of a first portion of a bit period and to enter a second state for a duration of a second portion of the bit period preceding the first portion.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to circuits with logical back-gate switching and methods of operation. The circuit includes at least one front-gate contact and digital back-gate potentials for logical function implementation on a back side of at least one device. The digital back-gate potentials are switchable between two logic levels.

Abstract: A thin film transistor includes a gate electrode, a semiconductor layer, a source electrode, and a drain electrode. The semiconductor layer overlaps the gate electrode and includes a channel layer comprising an oxide semiconductor and an auxiliary layer comprising amorphous silicon. The source electrode and the drain electrode are separated from each other and connected to the semiconductor layer. A thin film transistor array panel and method of manufacturing same also is disclosed.

Abstract: Described is an apparatus which comprises: a first power supply; a second power supply lower than the first power supply; first and second transistors coupled in series and to be biased, the first and second transistors coupled to a pad; a first pull-up transistor coupled to the first power supply and to one of the first or second transistors; a pull-down transistor coupled to one of the first or second transistors; and a second pull-up transistor coupled to the second power supply, the pull-down transistor, and to one of the first or second transistors.

Abstract: An integrated circuit including a global supply bus, a gated supply bus, a functional circuit coupled to the gated supply bus, a programmable device that stores a programmed control parameter, and a digital power gating system. The digital power gating system includes gating devices and a power gating control system. Each gating device is coupled between the global and gated supply buses and each has a control terminal. The power gating control system controls a digital control value to control activation of the gating devices. The power gating control system is configured to perform a power gating operation by adjusting the digital control value to control a voltage of the gated supply bus relative to the voltage of the global supply bus. The power gating operation may be adjusted using the programmed control parameter. The programmable device may be a fuse array or a memory programmed with programmed control parameter.

Abstract: A transmission arrangement is disclosed having an amplifier which is set up to amplify a transmission signal and to provide it as an amplified transmission signal in differential form, an analysis circuit for determining a property of the amplified transmission signal, and a differential feedback path which is set up to supply the amplified transmission signal to the analysis circuit in differential form.

Abstract: A transceiver is connectable to a cable with at least three wires. The transceiver may include a controlled output stage including a high-side leg, having two P-type transistors coupled in series and having a common current terminal, coupled between an output pin and a positive supply pin. The P-type transistors have body regions coupled to the common current terminal of the high-side leg. A low-side leg, includes two N-type transistors coupled in series and having a common current terminal, coupled between the output pin and a negative supply pin. The N-type transistors have body regions coupled to the common current terminal of the low-side leg. The protection circuit also includes a voltage clamper coupled between the common current terminals.

Abstract: A buck converter is disclosed comprising a series combination of high-side and low-side switches, and including a protection switch in anti-series with the high-side switch. The protection switch is controlled by means of a shutter switch, which is powered from the output of the converter and gated from the half bridge node of the converter. Also disclosed is a photovoltaic system comprising such a buck converter and a solar panel.

Abstract: An interface module for a logic circuit block comprising a processing module, the interface module comprising a control interface for communicating one or more control messages; a data interface for accessing a data storage device; an interface logic block; and a core interface to the processing module, the core interface being connected to the interface logic block for communicating signals between the interface logic block and the processing module. The interface logic block is adapted to receive one or more incoming control message via the control interface; process the one or more control messages including accessing a data storage device via the data interface, initiating processing by the processing module via the core interface, receiving one or more signals from the processing module via the core interface; and to output one or more outgoing control message via the control interface.

Abstract: Disclosed are an inverter, a NAND gate, and a NOR gate. The inverter includes: a pull-up unit constituted by a second thin film transistor outputting a first power voltage to an output terminal according to a voltage applied to a gate; a pull-down unit constituted by a fifth thin film transistor outputting a ground voltage to the output terminal according to an input signal applied to a gate; and a pull-up driver applying a second power voltage or the ground voltage to the gate of the second thin film transistor according to the input signal.

Abstract: A programming element including a first transistor, a second transistor, and a capacitor between a logic circuit using a semiconductor element and a power supply is provided. In the programming element, a node where a drain electrode of the first transistor, a gate electrode of the second transistor, and one of electrodes of the capacitor are electrically connected to each other is formed. A potential can be supplied to each of a source electrode of the first transistor and the other of the electrodes of the capacitor. The power supply and the logic circuit are electrically connected to each other through a source electrode and a drain electrode of the second transistor. A connection state between the power supply and the logic circuit is controlled in accordance with the state of the second transistor.

Abstract: A semiconductor apparatus includes a pulse generation unit configured to detect a transition of an input signal and generate a preliminary pulse signal, and an error elimination unit configured to determine error of the preliminary pulse signal and output a signal as a pulse signal.

Abstract: A semiconductor device includes a first input buffer adjusting a logic threshold voltage, a first replica circuit, a first reference voltage generating circuit, and a first comparator circuit. The first replica circuit is identical in circuit configuration to the first input buffer. The first replica circuit has an input and an output connected to the input. The first replica circuit generates the logic threshold voltage as an output voltage. The first reference voltage generating circuit generates a first reference voltage. The first comparator circuit compares the logic threshold voltage as an output voltage of the first replica circuit to the first reference voltage to generate a first threshold adjustment signal. The first comparator circuit supplies the first threshold adjustment signal to the first input buffer and the first replica circuit. The first threshold adjustment signal allows the first input buffer to adjust the logic threshold voltage.

Abstract: A driver circuit for a digital signal transmitting bus includes a main switch. The main switch is connected to the bus, is controllable by the digital signal to be transmitted, and has one on-switching state in which it has maximum electrical conductivity, one off-switching state in which it has minimum electrical conductivity and at least one intermediate switching state with an electrical conductivity between the minimum and maximum conductivity. The digital signal has a first logic state and a second logic state, the first logic state controls the main switch to be in the on-switching state and the second logic state controls the main switch to be in the off-switching state. The main switch is in the intermediate switching state during switching from the on-switching state to the off-switching state and/or vice versa.

Abstract: There is disclosed a switching arrangement comprising a switch with a plurality of individually controllable elementary switches connected in parallel between a first supply rail and a second supply rail. Each of the elementary switches can be in either one of a closed state and an open state independently of the others. A controller is adapted to dynamically control the closing or opening of the elementary switches, depending on the intensity of a current flowing through the switch. The number of elementary switches in the closed state is variable. The higher is the intensity of the current, the higher the number of elementary switches in the closed state. Thus, the impedance of the switch decreases when the current increases, and vice versa, and the voltage drop across the switch may be kept substantially constant.

Abstract: A termination impedance apparatus includes a variable pull-up resistor, a variable pull-down resistor, and a small-signal calibration circuit. The variable pull-up resistor is coupled between a first power supply voltage terminal and an output terminal. The variable pull-down resistor is coupled between the output terminal and a second power supply voltage terminal. The small-signal calibration circuit is for calibrating the variable pull-up resistor and the variable pull-down resistor to achieve a desired small-signal impedance.

Abstract: A low voltage differential signal driving circuit including positive and negative differential output terminals, an automatic level selector, an output level detector and a transition accelerator. The positive and negative differential output terminals provide a transmission interface with a differential output signal for transmission of a data signal. The automatic level selector outputs a reference voltage corresponding to the transmission interface. The output level detector generates a low-high (or high-low) transition acceleration control signal based on the data signal, the reference voltage, and VTXP signal at the positive differential output terminal (or VTXN signal at the negative differential output terminal).

Abstract: An inverter is capable of improving the reliability of driving. The inverter includes a first transistor and a second transistor. The first transistor is coupled between a first power source and an output terminal of the inverter, and has a first gate electrode coupled to a first input terminal of the inverter and a second gate electrode coupled to a third power source. The second transistor is coupled between the output terminal and a second power source, and has a first gate electrode coupled to a second input terminal of the inverter and a second gate electrode coupled to the third power source.

Abstract: A termination circuit includes: a pull-up termination unit configured to pull-up terminate an interface node in response to a pull-up signal; a pull-down termination unit configured to pull-down terminate the interface node in response to a pull-down signal; one or more pull-up resistors connected to the interface node and enabled to affect termination resistance in response to a pull-up setting value when a termination signal is activated; and one or more pull-down resistors connected to the interface node and enabled to affect termination resistance in response to a pull-down setting value when the termination signal is activated.

Abstract: A differential receiver for receiving differential signals including a positive signal and a negative signal and generating an output signal is provided. The differential receiver includes a first comparator configured to compare the positive signal and the negative signal and generate a first signal that is asserted when a difference between the positive signal and the negative signal is larger than a positive offset voltage; a second comparator configured to compare the positive signal and the negative signal and generate a second signal that is asserted when the difference between the positive signal and the negative signal is smaller than a negative offset voltage; a logic gate configured to generate a third signal that is asserted when the first signal and the second signal are negated; and an output circuit configured to generate the output signal based on the first to third signals.

Abstract: A calibration circuit includes an amplifier, a current steering digital-to-analog converter (DAC), a comparator, a slew calibration network, and an on-die termination (ODT) network. The amplifier generally has a first input, a second input, and an output. The first input generally receives a reference signal. The current steering digital-to-analog converter (DAC) generally has a first input coupled to the output of the amplifier, a first output coupled to the second input of the amplifier, and a second output coupled to a circuit node. The comparator generally has a first input receiving the reference signal, a second input coupled to the circuit node, and an output at which an output of the calibration circuit may be presented. The slew calibration network is generally coupled to the circuit node and configured to adjust a slew rate of the calibration circuit. The on-die termination (ODT) network is generally coupled to the circuit node.

Abstract: An adjustable impedance circuit includes a calibration module, an impedance module, a first switch module and a second switch module. The calibration module is arranged to generate a calibration signal. The impedance module has a plurality of impedance elements. The first switch module is coupled to the calibration module, and is arranged to receive the calibration signal and make a first portion of the impedance elements be selectively coupled between a differential input port and at least one reference voltage according to the calibration signal. The second switch module is coupled to a common-mode voltage output node, and is arranged to receive a control signal and make a second portion of the impedance elements be selectively coupled between the common-mode voltage output node and the differential input port according to the control signal.

Abstract: Described herein is a low-voltage circuit with an inductor tail and a common mode feedback loop for amplitude and current control. A first transistor pair can receive clock inputs, and a second transistor pair can receive data inputs and output the data to a logic gate. A tail inductor can be coupled to the first transistor pair to suppress high frequency common mode bounce induced by clock transitions in independent common emitter branches. A common mode feedback loop can be provided to maintain a constant average current. The common mode feedback loop and the tail inductor can together function in the same way as a tail current source at low frequencies and high frequencies respectively.

Abstract: Electrical networks are formed to produce an approximation of at least one desired performance characteristic, based on the recognition that fabrication variations introduce slight differences in electronic sub-networks which were intended to be identical. These fabrication differences are turned to an advantage by providing a pool of sub-networks, and then selectively connecting particular combinations of these sub-networks to implement networks that approximate the desired performance characteristics. The sub-networks are of like kind (e.g., resistors) and have a like measure.

Abstract: A low supply voltage logic circuit includes a first current source operable to generate a first current dependent on a first control signal and to generate a first leakage current. A second current source is operable to generate a second current dependent on a second control signal and to generate a second leakage current. A third current source has a third current path between the output terminal and the first supply voltage terminal and is operable to generate a third current through the third current path to compensate for the second leakage current. A fourth current source has a fourth current path between the output terminal and the second supply voltage terminal and is operable to generate a fourth current through the fourth current path to compensate for the first leakage current.

Abstract: A driver circuit for a digital signal transmitting bus includes a main switch. The main switch is connected to the bus, is controllable by the digital signal to be transmitted, and has one on-switching state in which it has maximum electrical conductivity, one off-switching state in which it has minimum electrical conductivity and at least one intermediate switching state with an electrical conductivity between the minimum and maximum conductivity. The digital signal has a first logic state and a second logic state, the first logic state controls the main switch to be in the on-switching state and the second logic state controls the main switch to be in the off-switching state. The main switch is in the intermediate switching state during switching from the on-switching state to the off-switching state and/or vice versa.

Abstract: A low leakage logic circuit. The low leakage logic circuit includes a control circuit for logic circuit. The control circuit has a first transistor, a second transistor, a third transistor, a first diode, a first resistor and a second resistor. When the control circuit is ON, a first circuit path in the logic circuit is supplied with a first voltage from the source terminal of the third transistor. This voltage acts as a logic output and has the ability to source current at output terminal of the logic circuit. When the control circuit is OFF, a second circuit path in the logic circuit is supplied with a second voltage from the control circuit which is lower than the turn-on voltage of the second circuit path. This voltage is insufficient to turn ON the logic circuit, hence no current flows into the logic circuit.

Abstract: A low supply voltage logic circuit includes a first current source operable to generate a first current dependent on a first control signal and to generate a first leakage current. A second current source is operable to generate a second current dependent on a second control signal and to generate a second leakage current. A third current source has a third current path between the output terminal and the first supply voltage terminal and is operable to generate a third current through the third current path to compensate for the second leakage current. A fourth current source has a fourth current path between the output terminal and the second supply voltage terminal and is operable to generate a fourth current through the fourth current path to compensate for the first leakage current.

Abstract: The present invention provides embodiments of an apparatus that includes a pad configurable for connection to a voltage source that provides a first voltage and a buffer connected to the pad. The buffer includes a plurality of transistors that have nominal breakdown voltages that are less than the first voltage. The buffer is configured to maintain voltage differentials on the plurality of transistors that are less than the break-down voltage of the plurality of transistors during pull-down of a pad voltage from the first voltage to a selected low voltage level or during pull-up of the pad voltage from the selected low voltage level to the first voltage.

Abstract: A system and method for calibrating bias in a data transmission system including a calibrated bias having impedance calibration for accommodating parameter variations in the data transmission system. A current mirror receives and balances bias currents between the calibrated bias and an output driver from the data transmission system. A digital compensation logic circuit is connected to the calibrated bias to adjust the calibrated bias for variations in parameters causing a current tail effect. A calibration logic circuit adjusts calibration due to variations in operational parameters, such that the tail current variations are minimized.

Abstract: An embodiment includes an impedance calibration circuit having a calibrator configured to compare voltage levels at an external node and an internal node of the impedance calibration circuit and to generate an output based on the comparison. The calibrator further includes respective filters coupled between the external node and a first input of the comparator, and between the internal node and a second input of the comparator. The filters are configured for symmetric noise injection into the comparator from a chip ground line to which a programmable resistor at the internal node is coupled.

Abstract: A semiconductor device includes a first input buffer adjusting a logic threshold voltage, a first replica circuit, a first reference voltage generating circuit, and a first comparator circuit. The first replica circuit is identical in circuit configuration to the first input buffer. The first replica circuit has an input and an output connected to the input. The first replica circuit generates the logic threshold voltage as an output voltage. The first reference voltage generating circuit generates a first reference voltage. The first comparator circuit compares the logic threshold voltage as an output voltage of the first replica circuit to the first reference voltage to generate a first threshold adjustment signal. The first comparator circuit supplies the first threshold adjustment signal to the first input buffer and the first replica circuit. The first threshold adjustment signal allows the first input buffer to adjust the logic threshold voltage.

Abstract: Disclosed is a circuit for adjusting a voltage supplied to an IC by a power supply circuit that produces a regulated-output voltage based on an output-control signal generated by a resistive voltage divider. The circuit includes a PVT detector configured to generate an interface control signal and an interface circuit (i) connected to PVT detector and to the resistive voltage divider and (ii) configured to adjust its resistance in response to the interface control signal. Adjusting the resistance of the interface circuit causes the voltage of the output-control signal to be adjusted, thus causing the power supply circuit to adjust the regulated output voltage.

Abstract: A circuit for restraining a shoot through current comprises a master selecting unit and a logic unit. The master selecting unit receives an input signal, and outputs first and second master selecting signals. The logic unit comprises first and second logic elements which generate first and second control signals for controlling two transistor switches connected in series. The first and second logic elements change the logic states of the first and second control signals according to the first and second master selecting signals. When the input signal is at a first logic level, the first logic element acquires a control privilege to change the logic state of the first control signal and trigger the second logic element to change the logic state of the second control signal. When the input signal is at a second logic, the second logic element acquires the control privilege.

Abstract: In accordance with this invention the above and other problems are solved by a switching apparatus and method that uses a switching circuit having a pair of parallel solid-state diodes (e.g., PN diodes), one of which is connected to a transistor (e.g., power MOSFET or IGBT), to switch a capacitor in or out of a variable capacitance element of an impedance matching network. Charging a body capacitance of the transistor reverse biases one of the two diodes so as to isolate the transistor from the RF signal enabling a low-cost high capacitance transistor to be used. Multiple such switching circuits and capacitors are connected in parallel to provide variable impedance for the purpose of impedance matching.

Abstract: A latch circuit includes a first tri-state inverter configured to invert an input voltage in response to a pulse and to output the inverted voltage to a first node, a second tri-state inverter connected between the first node and a second node and to invert a voltage of the second node in response to an inverted pulse being an inverted version of the pulse, and a variable inversion unit connected between the first node and the second node. The variable inversion unit adjusts a logical threshold value according to a logical value corresponding to a voltage of the first node and inverts a voltage of the first node based upon the adjusted logical threshold value, the logical threshold value indicating a voltage for discriminating the logical value.

Abstract: A semiconductor device includes a primary voltage rail, a secondary voltage rail, a plurality of transistors coupled between the primary and secondary voltage rails, and control logic operable to enable a first subset of the plurality of transistors to couple the primary voltage rail to the secondary voltage rail. During a steady state condition, the first subset comprises less than all of the plurality of transistors.