Abstract: This circuit is a back terminated transmission line driver which dissipates no outgoing power across its back terminating resistor by using both a voltage source and a current source.

Abstract: Methods and apparatus for providing either high-speed, or lower-speed, flexible inputs and outputs. An input and output structure having a high-speed input, a high-speed output, a low or moderate speed input, and an low or moderate speed output is provided. One of the input and output circuits are selected and the others are deselected. The high-speed input and output circuits are comparatively simple, in one example having only a clear signal for a control line input, and are able to interface to lower speed circuitry inside the core of an integrated circuit. The low or moderate speed input and output circuits are more flexible, for example, having preset, enable, and clear as control line inputs, and are able to support JTAG boundary testing. These parallel high and lower speed circuits are user selectable such that the input output structure is optimized between speed and functionality depending on the requirements of the application.

Abstract: A driving auxiliary circuit receiving an input voltage to control an output voltage of an operational amplifier via a first switch and a second switch is provided. A pull-low circuit turns on the first switch, including a first input terminal coupled to a high voltage source providing a high voltage and a first output terminal for controlling the voltage level of the output voltage. The output voltage is charged to be equal to the input voltage when the input voltage exceeds the output voltage. A pull-high circuit turns on the second switch, including a second input terminal coupled to the high voltage source providing the high voltage and a second output terminal for controlling the voltage level of the output voltage. The output voltage is discharged to be equal to the input voltage when the output voltage exceeds the input voltage.

Abstract: An electronic clamp is provided for an integrated circuit having a first voltage island (1) to which an output signal (clamp out) of the clamp is applied and a second voltage island (2) operative to produce an input signal (clamp in) to the clamp, where power to the second voltage island can be switched off to save power. The clamp comprises a latch (22) which stores or retains the clamp value (0 or 1) of the input signal (clamp in) during a reset period and clamps the output signal (clamp out) to the stored or retained value in response to a clamp enable signal, (clamp in) in order to protect the first voltage island from a non-stabilised input signal.

Abstract: Integrated circuits such as programmable logic devices are provided with hotsocket detection circuitry. The hotsocket detection circuitry monitors signals on data pins and power supply voltages. If the data pins become active before the power supply voltages have reached appropriate levels, a hotsocket condition is identified. When a hotsocket condition is identified, driver circuitry on the integrated circuit can be disabled by a hotsocket signal. The integrated circuit may include multiple blocks of input-output circuitry, each of which includes a local hotsocket circuit that uses global hotsocket and power-on-reset signals in disabling input-output circuitry in that input-output block. A power supply circuit in each input-output block may ensure that the local hotsocket circuit in that input-output block is powered.

Abstract: A communication system comprises a twisted pair communication link operably coupled to at least two driver stages for providing at least two independent input signals on the twisted pair communication link. The at least two independent input signals on the twisted pair communication link are summed and input to a comparator arranged to compare the summed signal to a reference value. The output of the comparator is input to the at least two driver stages. The outputs from the at least two driver stages are summed and fed back and summed with one or more of the independent input signals. In this manner, adverse effects due to non-ideal symmetry between components in a twisted pair communication link, such as a Controller Area Network system, are reduced.

Abstract: A repeater circuit. The repeater circuit includes two input circuits, two intermediate circuits, and two output circuits. Responsive to a transition of an input signal from one logic level to another level, one of the input circuits is activated. The corresponding intermediate circuit is activated corresponding to activation one of the input circuits, and in turn, the corresponding output circuit is activated, which then drives an output signal on an output node. After a delay, a feedback signal conveyed via a feedback path deactivates the corresponding intermediate circuit and the corresponding output circuit. After deactivation of the corresponding output circuit, a keeper circuit continues to provide the output signal on the output node. The other one of the two input circuits inhibits activation of the other one of the intermediate circuit responsive to the transition, which results in the other output circuit also being inhibited from activation.

Abstract: A semiconductor integrated circuit capable of reducing unnecessary current consumption includes a plurality of bus drive circuits for receiving data input, a common bus coupled to the bus drive circuits, and a bus holder coupled to the common bus. One of the bus drive circuits is selected as the selected bus drive circuit. When a logical value corresponding to the data input to be output is the same as a logical value that has been held by the bus holder and output to the common bus, the selected bus drive circuit stops outputting the logical value corresponding to the data input to the common bus. With this configuration, it is possible to eliminate the unnecessary output of the selected bus drive circuit, and to reduce unnecessary current consumption compared to the conventional semiconductor integrated circuit.

Abstract: A semiconductor integrated circuit includes a pre driver unit configured to receive a pre drive signal and a driving force control signal and output a main drive signal; a main driver unit configured to receive the main drive signal and output output data to an output terminal; a terminal connecting unit configured to receive a determination signal and connect to or disconnect from the output terminal in response to the determination signal; a terminal sensing unit configured to sense the output terminal and output a terminal state signal; and a driving force determining unit configured to receive a reset signal and the terminal state signal and output the driving force control signal.

Abstract: A line driver for a communications system requiring multiple power sources for different modes of operation comprises a current source and a voltage source coupled in parallel with the current source. The current source has a first terminal and a second terminal. The line driver further comprises a first source resistor coupled to the first terminal of the current source and a second source resistor coupled to the second terminal of the current source. The current source provides a driving current and the voltage source provides a driving voltage at the same time during operations of the communications system.

Abstract: A circuit for calibrating impedance includes an enable signal generator, a code generator and a connection controller. The enable signal generator generates an enable signal in response to a chip selection signal. The code generator generates an impedance calibration code in response to the enable signal by using an external resistance coupled to an electrode. The connection controller controls connection between the code generator and the electrode in response to the enable signal.

Abstract: In a driver circuit 10 for outputting a simulated signal simulating an input signal subjected to transmission loss, corresponding to the input signal, the driver circuit 10 comprises: a main driver 18 which receives the input signal and outputs an output signal corresponding to the input signal; a sub driver 20 which receives the input signal and outputs an output signal given by inverting the input signal; a high frequency emphasizing circuit 22 which receives the input signal of the sub driver 20 and outputs an output signal having the high frequency of the input signal of the sub driver 20 emphasized; and an addition unit 24 which outputs the simulated signal given by adding the output signal of the main driver 18 and the output signal of the high frequency emphasizing circuit 22.

Abstract: An apparatus includes a digital interface circuit configured to provide a digital interface. The digital interface is configurable based on a mode of operation of the digital interface circuit. The apparatus also includes input and output level-shift circuits. The input level-shift circuit is configured to shift a voltage level of an input signal for the digital interface circuit. The output level-shift circuit is configured to shift a voltage level of an output signal from the digital interface circuit. The input level-shifting and the output level-shifting are based on first and second level-shift input voltages. The apparatus further includes a mode detector configured to identify at least two modes of operation for the digital interface circuit based on the first and second level-shift input voltages. For example, the digital interface circuit could be configured to function as a serial or parallel interface depending on which level-shift input voltage is greater.

Abstract: To provide an output driver that outputs read data to outside and a mode register that sets a swing capability of the output driver. A transition start timing of the read data driven by the output driver is made relatively earlier when a swing capability of the output driver set by the mode register is set to be relatively large, and the transition start timing is relatively delayed when the swing capability of the output driver set by the mode register is set to be relatively small. With this configuration, a timing when the read data exceeds a threshold level can be caused to coincide with a desired timing regardless of the swing capability of the output driver.

Abstract: A bus driver has a ground terminal and a first and a second terminal. In a first operation mode the bus driver provides at the first terminal a first output voltage comprising a first data signal; and at the second terminal the bus driver provides a second output voltage comprising a second data signal. In a second operation mode the bus driver provides at the first terminal a first output voltage comprising a third data signal; and at the second terminal the bus driver provides a second output voltage, wherein a curve of the second output voltage is synchronous however inverted in relation to a curve of the first output voltage. An engine comprises a bus driver as set out above.

Abstract: A receiver particularly suited for an M-BUS is described. During transmission, the receiver is disabled. After each transmission, nodes and states in the receiver are set to prepare the receiver to receive a signal. Once data is sensed, a feedback loop clips the input signal to the receiver to limit the swing of the input signal. The line of the power supply at the lower potential is modulated, rather than modulating the line at the higher potential, for the transmission of data.

Abstract: A semiconductor device according to the present invention comprises a first semiconductor integrated circuit 11 having a predetermined function, the first semiconductor integrated circuit outputting a required output signal, a second semiconductor integrated circuit 12 in which a plurality of MOS elements (PMOS transistor or NMOS transistor) for independently switching to and from a conducted state and a non-conducted state in accordance with a plurality of gate signals each having a different timing is provided and the plurality of MOS elements is connected in parallel to an output or an input of the first semiconductor integrated circuit, and a pulse generating circuit 13 for generating and outputting the plurality of gate signals ?i (i=1, 2, 3) each having a different timing with respect to the plurality of MOS elements in the second semiconductor integrated circuit.

Abstract: A driver circuit includes a set of selectable drivers each having an individual drive capability, the drivers being selectable such that i) when a subset of the drivers is selected, a signal will be driven by the drivers at a first drive level, and ii) when the subset of the drivers and at least one additional driver is selected, signal will be driven by the drivers at a level that is greater than the first level by a level of drive provided by the least one additional driver.

Abstract: This disclosure uses a differential sensing and TSV timing control scheme for 3D-IC, which includes a first chip layer of the stacked device having a detecting circuits and a relative high ability driver horizontally coupled to the detecting circuits. A sensing circuit is coupled to the detecting circuits by a horizontal line, a first differential signal driver is coupled to the sensing circuit, horizontally. The Nth chip layer of the stacked device includes a Nth relative high ability driver and a Nth differential signal driver formed on the Nth chip layer. The Nth relative high ability driver is vertically coupled to the first relative high ability driver through one relative low loading TSV and (N?2) TSVs to act as dummy loadings. The TSV and (N?2) TSVs penetrate the stacked device from Nth chip layer to first chip layer. The TSV shares same configuration with the (N?2) TSVs.

Abstract: An input circuit, includes a first buffer circuit whose output is couple to an output signal terminal of the input circuit, and whose input is coupled to an input signal terminal of the input circuit, a second buffer circuit, a third buffer circuit, a first differential amplification circuit whose first input is coupled to a first external power source terminal, whose second input is coupled to an output of the second buffer circuit, and whose output is coupled to an input of the second buffer circuit, a second differential amplification circuit whose first input is coupled to a second external power source terminal, whose second input is coupled to an output of the third buffer circuit, and whose output is coupled to an input of the third buffer circuit, a first resistance whose one end is coupled to the output of the first differential amplification circuit, and whose another end is coupled between the input signal terminal of the input circuit and the input of the first buffer circuit, a second resistance

Abstract: A data transmission system includes a transmitter including a drive unit outputting complementary signals to first and second transmission lines according to data for transmission, and a receptor including first and second termination resistors, and a receiver circuit. One ends of the first and second termination resistors are respectively connected to first and second nodes that are connected to first and second transmission lines and other ends of the first and second termination resistors are connected in common to a third node. The receiver circuit supplies a current to the third node and outputs received data corresponding to data for transmission, in accordance with a potential difference between the first and second nodes.

Abstract: A current drive circuit allows for a reduction in chip size and prevents an output current from decreasing. The current drive circuit has an output terminal connected to a first resistor. The first resistor is connected to a second resistor and the drain of a first transistor. The gate of the first transistor is connected to the gate of a second transistor, a grounded first current source, and the source of a third transistor. A second current source and the third transistor are connected to a power supply line. The second current source is connected to the gate of the third transistor, the drain of a fourth transistor, the drain of a fifth transistor, and a second resistor. When the voltage decreases, the on resistance of the fourth transistor increases, the fifth transistor is then connected in series to the second transistor, which increases the gate voltage of the first transistor.

Abstract: A method and circuit of a biased input buffer is described to maximize the quality in the output signals. The input buffer includes a first stage for receiving differential input signals and generating differential internal signals as biased in response to an averaging of the differential internal signals. The input buffer further includes a second stage coupled to the differential internal signals and configured to generate differential output signals. A memory device includes a memory array with the respective input buffer. Differential input signals are received and differential internal signals are generated as biased in response to an averaging of the differential internal signals. Differential output signals are generated in a second stage from the differential internal signals.

Abstract: An impedance matching circuit has a number of buffers each having a variable impedance circuit. A variable impedance sense control block has an impedance code as an output. A sequencing circuit couples the impedance code of the variable impedance sense control block to the variable impedance circuit of each of the buffers.

Abstract: In one embodiment, a receiver circuit is provide that may receive either a differential input or a single-ended input corresponding to an interface. The receiver circuit may include at least two current sources to control a gain of an amplification stage in the receiver. If the receiver circuit is receiving a differential input, one of the current sources may be used. If the receiver circuit is receiving a single-ended input, both of the current sources may be used. A larger gain may thus be provided for the single-ended input as compared to the differential input.

Abstract: With an offset circuit including transistors of the same conductivity type, offset of an input signal is performed. Then, the input signal after the offset is supplied to a logic circuit including transistors of the same conductivity type as that of the offset circuit, thereby H and L levels of the input signal can be shifted at the same time. Further, since the offset circuit and the logic circuit are formed using the transistors of the same conductivity type, a display device can be manufactured at a low cost.

Abstract: Embodiments of the invention include a common mode cancellation circuit and method for correcting signal skew in a differential circuit. According to one embodiment, an op amp circuit is used to correct the mismatch between transmission line lengths in the differential circuit. The CMCC can be embodied as an ASIC and added on to an existing differential signaling systems to correct and compensate for board wiring skew or other causes of phase misalignment. The result is restoration of the cross-over intersection of the plus and minus signals of the differential pair closer to the common voltage level point, as if the signals had been in phase.

Abstract: A data output circuit includes a plurality of drivers configured to be turned on/off according to impedance codes to output data to an output node. The impedance codes are divided into a first group having a value to turn on the drivers, and a second group having a value to turn off the drivers, and at least some of the drivers controlled by the second group are turned on during a pre-emphasis period.

Abstract: A semiconductor device includes: a driver that receives a power supply voltage and drives an external load with a driving capability; a measurement unit that measures a level of the power supply voltage; a code table that stores the level of the power supply voltage and code information for determining the driving capability of the driver; and a controller that reads the code information in accordance with the level of a measured power supply voltage in reference to the code table and controls the driving capability of the driver in accordance with the code information.

Abstract: According to one general aspect, an output driver configured to drive output signals from a core device may include a voltage convertor, an output stage, and a biasing unit. In various embodiments, the output driver is configured to operate in either a core device voltage mode or a high voltage mode. In some embodiments, the voltage convertor may be configured to receive a pair of differential input signals from a core device, wherein a maximum voltage of the input signals is equivalent to a core device voltage, and convert the input signals to a pair of intermediate input signals. In one embodiment, when in high voltage mode, the maximum voltage of the intermediate input signals may be equivalent to a high voltage that is higher than the core device voltage.

Abstract: In a bridge adder circuit, a first and a second complementary pair of current mirrors is connected between the input terminals and a positive and a negative supply voltage bus, respectively, to control a first and a second push-pull output stage. The outputs of the push-pull output stages are connected to the respective inputs through first resistors and to a common output node through second resistors. As a result, a universal circuit element for a multivalued logic element, such as ternary logic or 5-valued logic is provided.

Abstract: A buffer apparatus for a communications bus comprises a driver circuit having an output. An amplifier circuit having an input is coupled to the output of the driver circuit. The driver circuit is arranged to generate, when in use, a drive signal having a waveform that comprises a step therein so as to substantially suppress generation by the amplifier circuit of a portion of an oscillation of an output signal.

Abstract: It is presented a gate driver circuit for driving an electric switch, the switch being arranged to control a main current using a gate signal. The gate driver circuit comprises: a non-linear capacitor means having a lower capacitance when an applied voltage is under a threshold voltage and a higher capacitance when an applied voltage is over the threshold voltage, wherein the non-linear capacitor is arranged to be connected between a high voltage connection point of the switch and a connection point for the gate signal; a current change rate sensor, the current change rate sensor being configured to detect changes in a main current of the electric switch and to control a gate signal of the electric switch depending on the current change; a gate buffer; and at least one current source, arranged to drive the gate buffer. The current change rate sensor is connected to control the current source to thereby control the gate signal of the electric switch.

Abstract: A fault tolerant driver circuit includes a data output driver that receives an enable input and that includes a transistor formed on an isolation well. A well bias circuit provides a first well bias to the isolation well. The well bias circuit includes voltage-controlled impedances that are controlled by a voltage of the data output line, the enable input and a supply voltage. The voltage-controlled impedances connect the first well bias alternatively to: a common conductor through a first impedance when the supply voltage is ON and the enable input is ON; and a second impedance when the supply voltage is on and enable is OFF.

Abstract: The serial interface operable, for example, to facilitate high speed differential data transfer between integrated circuits provides level shifting of an incoming data signal using a switched capacitor technique which level shifts the common mode voltage with minimal attenuation and minimal reduction of bandwidths. The serial interface also includes a DC offset correction loop of the input data receiver path. The level shifting circuit operates by sensing the incoming common mode voltage of a differential data signal with a resistor divider and sampling the difference between the measured input common mode voltage and desired input differential voltages generated by a differential DAC in the DC offset correction loop on two small capacitors.

Abstract: High-speed serial interface (“HSSI”) transceiver circuitry (e.g., on a programmable logic device (“PLD”) integrated circuit) includes input buffer circuitry with adaptive equalization capability. The transceiver circuitry also includes an output driver, which may include pre-emphasis capability (preferably controllably settable). Selectively usable loop-back circuitry is provided for allowing the output signal of the input buffer to be applied substantially directly to the output driver. The loop-back circuitry may include a loop-back driver, which may be turned on substantially only when needed for loop-back operations.

Abstract: An electronic device designed to transport digital information (“0”, “1”) over long distances, including a transmitter generating current pulses and at least one assembly of receivers converting the received current pulses into logic pulses which are compatible with the operation of standard electronic logic circuits. Each receiver includes a pair of magnetoresistive stacks containing at least one hard ferromagnetic layer and one soft ferromagnetic layer separated by a non-ferromagnetic interlayer, the hard layer of each of the magnetoresistive stacks being pinned in a magnetic orientation perpendicular to an easy-magnetization axis which is used as a reference for the soft layer of the same stack. The soft layer of each magnetoresistive stack has a magnetic orientation which can be modulated by the magnetic field generated by current pulses delivered by the transmitter so as to cause modification of the transverse resistance of the stack sufficient to trigger an electrical signal.

Abstract: System and method for providing live insertion. According to an embodiment, the present invention provides an integrated circuit. The integrated circuit includes a first port configured to be electrically coupled to a pad. The first port includes a first connection, a second connection, and a third connection. The integrated circuit also includes a first resistor having a first terminal and a second terminal. Additionally, the integrated circuit includes a second resistor having a third terminal and a forth terminal. The integrated circuit additionally includes a voltage source configured to provided a first voltage. The integrated circuit further includes a first PMOS transistor having a first gate terminal, a first drain terminal and a first source terminal. In addition, the integrated circuit includes a second PMOS transistor having a second gate terminal, a second drain terminal, and a second source terminal.

Abstract: A semiconductor integrated circuit capable of maintaining characteristics of transistors in a circuit including a plurality of cascade connected transistors. The circuit includes an inverter which has a series connection of P-MOS transistors and a pair of N-MOS transistors. The P-MOS transistor is connected to a high potential source VH and the N-MOS transistor is connected to a low potential source VL. The gate of each MOS transistor is connected to an input signal line. The inverter circuit further includes a P-MOS transistor connected between a node and input signal line, and an N-MOS transistor connected between a node of the N-MOS transistors and the input signal line. The gates of the P-MOS transistor and the N-MOS transistor are connected to an output signal line of the inverter circuit.

Abstract: A method for sharing charge between IO circuits, the method includes providing an integrated circuit that comprises multiple IO circuits, each comprising an IO pad. The method is characterized by including: determining to share a charge between multiple IO circuits; and sharing charge between the multiple IO circuits by coupling the multiple IO circuits to a shared circuit that is characterized by a state that reflects multiple iterations of sharing charge operations.

Abstract: An electronic integrated circuit includes a signal path connected between the functional logic (15) thereof and an external output terminal. The signal path includes a switch (S), a bus holder circuit (121B), and an output buffer (19).

Abstract: Apparatus and methods for providing multi-mode clock signals are disclosed. In some embodiments, a multi-mode driver configured to receive a first clock signal, and to selectively output a different clock signal in response to one or more signals from a controller is provided. The driver can include an H-bridge circuit without substantial increases in the size of the design area. Advantageously, lower jitter and improved impedance matching can be accomplished.

Abstract: To reduce a leakage current of a transistor so that malfunction of a logic circuit can be suppressed. The logic circuit includes a transistor which includes an oxide semiconductor layer having a function of a channel formation layer and in which an off current is 1×10?13 A or less per micrometer in channel width. A first signal, a second signal, and a third signal that is a clock signal are input as input signals. A fourth signal and a fifth signal whose voltage states are set in accordance with the first to third signals which have been input are output as output signals.

Abstract: A semiconductor device includes a plurality of core chips and an interface chip stacked together. Each of the core chips and the interface chip includes plural through silicon vias that penetrate a semiconductor substrate and a bidirectional buffer circuit that drives the through silicon vias. The interface chip also includes a logic-level holding circuit that holds a logic level of the through silicon vias. The bidirectional buffer circuit includes an input buffer and an output buffer. The driving capability of a first inverter of the logic-level holding circuit is smaller than the driving capability of the output buffer of the bidirectional buffer circuit.

Abstract: An embodiment of the invention relates to a driver adapted to provide a drive signal with an adjustable waveform for an external bridge to control EMI. The driver includes a detector configured to measure a switching characteristic of a switch in the external bridge to produce the drive signal with an adjustable waveform characteristic. The driver includes an adjustable circuit element to adjust the waveform characteristic in response to the measured switching characteristic. The measured switching characteristic may be a derivative of a voltage of the switch in the bridge such as a derivative of a drain-to-source voltage of a half-bridge circuit. The driver may be formed with an amplifier with an adjustable gain controlled by the signal produced by the detector. The adjustable gain amplifier may be formed with a transistor coupled in series with a leg of a current mirror.

Abstract: Input signals from a signal input terminal are input to a logic circuit, and a control signal corresponding to states of the input signals is output. The control signal is supplied to an output circuit, a plurality of transistors are controlled, and a drive signal is output corresponding to states of the transistors. In the logic circuit, the logic is switched according to the polarity of the setting signal which is input to a logic setting terminal, and a control signal corresponding to the input signal is changed.

Abstract: A transmission apparatus for differential communication includes a driver bridge circuit and a pair of noise protection circuits. The driver bridge circuit includes four output devices that are independently connected between each of a pair of transmission lines and a power line or a ground line. Each noise protection circuit is provided to a corresponding transmission lines. Each noise protection circuit includes a ground potential detector and an impedance controller. The ground potential detector detects a potential of the corresponding transmission line with respect to the ground line. The impedance controller causes an impedance of the corresponding transmission line with respect to the ground line to become equal to an impedance of the other transmission line with respect to the ground line, when the detected potential becomes outside a predetermined potential range.

Abstract: A memory controller that controls termination in a memory device. The memory controller includes a data interface, command/address interface and termination control output. The data interface outputs write data onto a data line coupled to a data input of the memory device, and the command/address interfaces outputs, onto a command/address path coupled to the memory device, information that indicates whether the write data is to be received within the memory device.

Abstract: A data transmitting system is provided that includes a transmitter that suppresses coupling noise by being operated using a differential voltage driving scheme at the time of transmitting data and being operated using a common voltage driving scheme by equalizing potential of a pair of transmission lines during a transition interval; and a receiver that is connected to the transmitter through the pair of transmission lines and recovers the data by sensing the voltage difference in signals of the pair of transmission lines.

Abstract: A high-density semiconductor device includes a first input/output line connected among a plurality of banks on a core area storing data, so that it transmits data, a second input/output line connected to a data pad capable of performing data input/output operations at a Peri-area, so that it transmits data, a first repeater connected between the first input/output line and the second input/output line, for transmitting data of the first input/output line to the second input/output line in response to a read enable signal enabled by a read command, and a second repeater connected between the first input/output line and the second input/output line, for transmitting data of the second input/output line to the first input/output line in response to a write enable signal enabled by a write command.