Abstract: Some embodiments of the present invention provide a voltage-mode transmitter. The transmitter can include configuration circuitry, bias circuitry, and a set of driver slices. Each driver slice can include driver transistors which drive an output value. The outputs of each driver slice can be directly or capacitively coupled with the transmitter's outputs. Each driver slice can also include one or more impedance-matching transistors which are serially coupled to at least some of the driver transistors. The configuration circuitry can configure a subset of driver slices so that the down (or up) impedance of the transmitter is within a first tolerance of a desired impedance value. The bias circuitry can bias the one or more impedance-matching transistors in each driver slice in the subset of driver slices so that the up (or down) impedance is within a second tolerance of the down (or up) impedance.

Abstract: An impedance adjusting device includes a calibration unit configured to generate an impedance code for adjusting a termination impedance value, a plurality of termination units configured to be enabled by resistance selection information and terminate an interface node in response to the impedance code, a resistance providing unit coupled in parallel to the plurality of termination units and configured to provide a resistance in response to the resistance selection information, and a selection signal generation unit configured to generate the resistance selection information according to a target impedance value.

Abstract: Provided is a semiconductor integrated circuit according to an exemplary aspect of the present invention including first and second transmitter-receivers that execute transmission and reception of data through a signal line. The first transmitter-receiver includes a first termination circuit that includes a first resistor and a first switch, the first resistor being provided between a first power supply terminal and the signal line, the first switch controlling a current flowing through the first resistor to be turned on and off, and a control circuit that outputs a first control signal to the first termination circuit so that the first switch is turned on when the first transmitter-receiver receives data, the first switch is turned off when the first transmitter-receiver transmits the data, and the first switch is continuously on during a first predetermined period after receiving the data when the first transmitter-receiver further receives another data after receiving the data.

Abstract: A microprocessor control unit (MCU) is mounted on a printed circuit board. The MCU includes first and second clocked serial interface (CSI) circuits. The first CSI circuit is configured to serially transmit a first xCP packet to a first encoder circuit, which in turn is configured to generate an encoded first xCP packet as a function of the first xCP packet and a first clock signal. A first low voltage differential signal (LVDS) circuit is coupled to the first encoder circuit and configured to serially receive the encoded first xCP packet therefrom. The first LVDS circuit is configured to generate a first differential signal as a function of the encoded first xCP packet.

Abstract: A semiconductor device has multiple high-side field-effect transistors and multiple low-side field-effect transistors connected to a single output terminal to generate an output signal. A driver circuit outputs driving signals that turn the field-effect transistors on and off. The driving signal for the field-effect transistors on each side is conducted by a salicided gate line with salicide block areas that produce successive delays, causing the field-effect transistors to turn on sequentially. Alternatively, the transistors have different threshold voltages, or the driving signals for different transistors are output from drivers with different driving abilities, again causing the transistors to turn on sequentially. The output signal therefore rises and falls gradually, reducing electromagnetic interference.

Abstract: A semiconductor buffer circuit that operates stably against PVT fluctuation is disclosed. The disclosed semiconductor buffer unit of the present invention includes: a detecting block configured to generate a plurality of code signals by detecting an external voltage, using a plurality of reference voltages; and a buffer unit configured to receive an input signal and the plurality of code signals and, based on the code signals, to generate an output signal, wherein a consumption of a driving current of the buffer unit is controlled based on the code signals.

Abstract: Each of a plurality of memories includes a terminating resistor for preventing signal reflection, and a memory control circuit includes an ODT control circuit for driving the terminating resistor of each memory, and a selector for selecting, from memories except for a memory to be accessed, at least one memory for which driving of the terminating resistor is to be suppressed, in accordance with the memory to be accessed.

Abstract: Methods, devices, and systems are disclosed, including those for a buffer having pre-driver circuitry that provide voltages to thin-gate dielectric transistors. One such buffer may include a primary pull-up pre-driver operably coupled to a primary pull-up transistor; a secondary pull-up pre-driver operably coupled to a secondary pull-up transistor; a primary pull-down pre-driver operably coupled to a primary pull-down transistor; and a secondary pull-down pre-driver operably coupled to a secondary pull-down transistor. The pre-drivers may provide a sufficiently low voltage to a gate of a transistor operably coupled thereto so as to sustain a gate dielectric integrity of the transistor, wherein at least one of the primary pull-up pre-driver, the secondary pull-up pre-driver, primary pull-down pre-driver, and the secondary pull-down pre-driver is configured to provide a voltage greater than or equal to a ground voltage and less than or equal to a supply voltage.

Abstract: Embodiments provide input/output devices having programmable logic that is programmable to operate input/output devices in one of two drive modes. In various embodiments, to operate an input/output device in a first drive mode, logic circuitry is programmable to couple a reference voltage to a gate of a transistor element of an output driver. In various embodiments, to operate an input/output device in a second drive mode, the logic circuitry is programmable to couple a bias voltage to the gate of the transistor element of the output driver. In various embodiments, the logic circuitry may also be programmable to couple one of a plurality of data inputs to the output driver to operate an input/output device in either a single-ended mode or a differential mode.

Abstract: In a semiconductor device having a terminal connected to an internal portion, a termination circuit for providing on-die termination for the terminal of the device. The termination circuit comprises a plurality of transistors, including at least one NMOS transistor and at least one PMOS transistor, connected between the terminal and a power supply; and control circuitry for driving a gate of each of NMOS transistor with a corresponding NMOS gate voltage and for driving a gate of each PMOS transistor with a corresponding PMOS gate voltage, the control circuitry being configured to control the NMOS and PMOS gate voltages so as to place the transistors in an ohmic region of operation when on-die termination is enabled. The power supply supplies a voltage that is less than each said NMOS gate voltage and greater than each said PMOS gate voltage.

Abstract: A current source and a method for designing the current source are provided. The current source is designed by a recursive rule and enables controllable delay lines to provide linear delay and occupy smaller area than conventional controllable delay lines with thermometer code current sources do.

Abstract: Low-power routing multiplexers that reduce static and dynamic power consumption are provided. A variety of different techniques are used to reduce power consumption of the routing multiplexers without significantly increasing their size. For example, power consumption of the routing multiplexers may be reduced by reducing short-circuit currents, reducing leakage currents, limiting voltage swing, and recycling charge within the multiplexer. Multiple power reduction techniques may be combined into a single routing multiplexer design. Low-power routing multiplexers may also be designed to operate in selectable modes, such as, a high-speed, high-power mode and a low-speed, low-power mode.

Abstract: A method and circuitry for calibration of the output impedance of output driver circuits in an integrated circuit is disclosed. The output drivers within an area on the integrated circuit are defined as a group, and an output model indicative of the operation of the output drivers and used to calibrate their output impedances is provided proximate to the output drivers. A state machine is used to query each output model, and to set the proper output enable signals for the enable transistors in the output drivers in each group so as to calibrate their output impedances. By decentralizing the output models, the process used to form the output models will, due to proximity to the output drivers in each group, be indicative of the process used to form the output drivers. Thus, when each group of output drivers is calibrated, the output models used for each will compensate for process variations as may occur across the surface of the integrated circuit.

Abstract: A floating driving circuit according to the present invention comprises an input circuit to receive an input signal. A latch circuit receives a trigger signal for generating a latch signal. The latch signal is used to turn on/off a switch. A coupling capacitor is connected between the input circuit and the latch circuit to generate the trigger signal in response to the input signal. A diode is connected from a voltage source to a floating supply terminal of the latch circuit for charging a capacitor. The capacitor is coupled between the floating supply terminal and a floating ground terminal of the latch circuit to provide a supply voltage to the latch circuit. The latch circuit is controlled by the input signal via the coupling capacitor.

Abstract: A system having an input and output buffer includes a dynamic driver reference generator to generate dynamic driver reference signals based on a data signal and an IO buffer supply voltage, a level shifter to generate level shifted signals based, in part, on the dynamic driver reference signals, and a driver having at least one stress transistor. The driver dynamically adjusts a voltage across the stress transistor based on at least one of dynamic driver reference signals, the level shifted signals, and a current state of an IO pad.

Abstract: According to various embodiments, a differential transmitter includes a driver and a predriver. In various embodiments, the predriver may include pull-up transistors and pull-down transistors configured in various ways to produce a staged output signal during a pull-up transition, wherein the higher bits of the input signal are switched slower in comparison with the lower bits of the input signal, while at the same time maintaining the simultaneous pull-down transition among all the bits. In various embodiments, the staged output of a predriver may further be dynamically disabled during a deemphasis exit transition. Other embodiments may be described and claimed.

Abstract: An output buffer circuit has a variable output drive strength, depending on a buffer enable signal. Multiple output buffer circuits have a variable combined output drive strength, depending on a set of buffer enable signals.

Abstract: An output driver of a semiconductor device includes driving transistors and a body bias providing unit. The driving transistors are coupled in parallel and configured to drive an output terminal. The body bias providing unit is configured to supply the driving transistors with respective body biases of at least two levels.

Abstract: Apparatus are disclosed, such as those involving a transmitter circuit that is configured to generate multi-level signals based on a plurality of data digits. One such transmitter circuit includes a signal output and an encoder configured to provide control signals based at least partially on the plurality of data digits. The transmitter circuit also includes a first set of switches configured to receive one or more of the control signals, and to selectively conduct a first or second voltage reference to the signal output. The transmitter circuit further includes first and second voltage drop circuits that provide third and fourth voltage references, respectively. The third and fourth voltage references have voltage levels between those of the first and second voltage references. The transmitter circuit also includes a second set of switches configured to receive one or more of the control signals, and selectively conduct the third or fourth voltage reference to the signal output.

Abstract: An advanced repeater with duty cycle adjustment. In accordance with a first embodiment of the present invention, an advanced repeater includes an output stage for driving an output signal line responsive to an input signal and a plurality of active devices for selectably adjusting a duty cycle of the signal. The advanced repeater may further include circuitry for producing a delayed version of the signal.

Abstract: A semiconductor device is provided. A pull-up slew rate controller receives a first driving control signal generated in a first mode of operation, a second driving control signal generated in a second mode of operation, and data, and upon a first transition of the data, sequentially activates the data and a first pull-up delayed signal having different delay times in the first mode of operation and sequentially activates the data and the first to third pull-up delayed signals having different delay times in the second mode of operation. A pull-up driving unit sequentially pulls a data output terminal up in response to the data and the first to third pull-up delayed signals.

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 buffer circuit outputs a low voltage and high voltages as opposed logic signals and a first high voltage and a second high voltage that is higher than the first high voltage as the high voltages.

Abstract: A semiconductor device is able to terminate internal transmission lines and including a pre-driving unit configured to generate a pull-up driving signal and a pull-down driving signal corresponding to an output data signal, and transfer the pull-up driving signal and the pull-down driving signal to a first transmission line and a second transmission line, respectively, a main driving unit configured to drive an output data in response to the pull-up driving signal and the pull-down driving signal transferred through the first transmission line and the second transmission line and a termination unit configured to be supplied with a termination voltage to terminate the first transmission line and the second transmission line.

Abstract: Methods, devices, and systems are disclosed, including those for a buffer having pre-driver circuitry configured to provide voltages to thin-gate dielectric transistors. One such buffer may comprise a plurality of pre-drivers wherein each pre-driver of the plurality of pre-drivers is operably coupled to a transistor of a plurality of transistors. The buffer may further comprise one or more clamping devices, wherein at least one transistor of the plurality of transistors has a gate coupled to at least one clamping device of the one or more clamping devices.

Abstract: An edge rate suppression circuit arrangement is provided for operation with an open drain bus. The circuit arrangement includes a variable resistive circuit having an input for receiving a variable voltage signal and an output coupled to the open drain bus, and a control circuit configured to operate the variable resistive circuit. The control circuit operates the variable resistive circuit in respective high and low resistance states in response to the variable voltage signal.

Abstract: Provided is a semiconductor integrated circuit according to an exemplary aspect of the present invention including a data transmitting circuit that transmits data in parallel through a plurality of signal lines and a data receiving circuit that receives the data. The data transmitting circuit includes a plurality of data output circuits that output the data in a data transmission mode or set an output to a high impedance state in a HiZ mode, a plurality of data selection circuits that select one of the data and fixed data and output the selected data to the data output circuits, and a control circuit that controls the data output circuits to output the fixed data during a period between a time when a mode is switched from the HiZ mode to the data transmission mode and a time when the data output circuits start to output the data.

Abstract: A semiconductor device adjusting an impedance level of an output buffer, includes a replica buffer circuit including a circuit configuration substantially identical to the output buffer, a counter circuit changing an impedance code to vary an impedance level of the replica buffer, a latch circuit temporarily holding the impedance code in response to a control signal, and an end-determining circuit producing the control signal in response to a lapse of a predetermined period from issuance of a calibration command, irrespective of a fact that the replica buffer has not yet reached a desirable impedance level.

Abstract: An output driver circuit includes a pre-driver unit and a first driving unit. The pre-driver unit is configured to generate a driving selection signal and a driving signal from a pre-driving signal in response to a group selection signal and a code signal. The first driving unit is configured to drive a data pad in response to the driving selection signal and the driving signal.

Abstract: Low-power routing multiplexers that reduce static and dynamic power consumption are provided. A variety of different techniques are used to reduce power consumption of the routing multiplexers without significantly increasing their size. For example, power consumption of the routing multiplexers may be reduced by reducing short-circuit currents, reducing leakage currents, limiting voltage swing, and recycling charge within the multiplexer. Multiple power reduction techniques may be combined into a single routing multiplexer design. Low-power routing multiplexers may also be designed to operate in selectable modes, such as, a high-speed, high-power mode and a low-speed, low-power mode.

Abstract: A high load driving device is disclosed. The driving device comprises an inverter receiving a digital voltage. The inverter reverses the digital voltage, and then sends out it. The output terminal of the inverter is coupled to a capacitor, a first P-type field-effect transistor (FET), a second P-type FET, a first N-type FET, and a third N-type FET. A push-up circuit is composed of these transistors and a second N-type FET and coupled to a P-type push-up FET. A load is coupled to a high voltage through the P-type push-up FET. When the digital voltage rises from a low level to a high level, the push-up circuit utilizes the original voltage drop of the capacitor to control the P-type push-up FET, whereby the gate voltage of the P-type push-up FET is at a low stabilization voltage that is lower than the ground potential. Then, the load is driven rapidly.

Abstract: A buffer device coupled to at least one input/output port of an integrated circuit has a plurality of control inputs configured to receive configuration programming information. The at least one input/output circuit is capable of: (a) being configured in a directional sense of communication by the configuration programming information, (b) being configured as an input circuit which can be further configured to provide input logic switching level thresholds according to the configuration programming information, and (c) being configured as at least one output circuit which can be further configured to provide an output drive strength according to the configuration programming information.

Abstract: A circuit includes first transistors and a comparator. The comparator compares a reference signal and a signal that is based on conductive states of the first transistors. A control circuit generates first control signals based on an output signal of the comparator. The conductive states of the first transistors are determined based on the first control signals. An arithmetic circuit performs an arithmetic function based on the first control signals and second control signals to generate calibration signals. Second transistors provide a termination impedance at an external terminal of the circuit that is based on the calibration signals.

Abstract: An output buffer includes inverters, a delay circuit for delaying an input signal, buffers and switches. The output buffer transmits a logic signal to a transmission path and, in accordance with an amount of signal attenuation in the transmission path, creates a waveform including four or more kinds of signal voltages. The buffers are redundantly connected in parallel, and the number of buffers concurrently turn ON is controlled by respective switches provided in series with output resistors of the buffers. By selecting the buffers of switches which are turned ON, the preemphasis amount and a number of preemphasis taps are adjusted through a selector logic selection signal so that the preemphasis amount is made variable and the ON resistance of the buffers is made constant.

Abstract: Apparatus and methods advantageously maintain transistors of open-drain differential pairs biased in the saturation region when “active,” rather in than the triode or linear region. The biasing techniques are effective over a broad range of process, voltage, and temperature (PVT) variations. By controlling a high voltage level used to drive the gate of a transistor of the differential pair, the biasing of the transistor in the saturation region is maintained. In one embodiment, the low voltage level used to cut off the transistor of the differential pair is also controlled. These techniques advantageously permit differential drivers to exhibit relatively large output swings, relatively high edge rates, relatively high return loss, and relatively good efficiency.

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 data output driving circuit includes a plurality of driving units that are set to have different impedance values from one another, and the number of driving units is less than the number of a plurality of required driving impedance values such that the driving units can obtain the plurality of required driving impedance values by a combination thereof, and a driving control unit that independently controls the operation of the plurality of driving units so as to obtain the plurality of driving impedance values required.

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: Long existing performance, noise, and power consumption problems of known output drivers are solved by using n-channel transistors as pull up transistors and/or p-channel transistors as pull down transistors for high performance output drivers. On-die termination-circuit-branches provide effective anti-reflection functions for multiple chips connected to the same transmission line(s).

Abstract: Long existing performance, noise, and power consumption problems of known output drivers are solved by using n-channel transistors as pull up transistors and/or p-channel transistors as pull down transistors for high performance output drivers. In combination with RC termination circuits, output drivers of the present invention can be fully compatible with HSTL, SSTL, GTL, BTL, SATA, PCIe, LVDS, MIPI, MDDI or other partial voltage interfaces.

Abstract: Long existing performance, noise, and power consumption problems of known output drivers are solved by using n-channel transistors as pull up transistors and/or p-channel transistors as pull down transistors for high performance output drivers. In combination with RC termination circuits, output drivers of the present invention can be fully compatible with HSTL, SSTL, GTL, BTL, SATA, PCIe, LVDS, MIPI, MDDI or other partial voltage interfaces.

Abstract: The present disclosure has been worked out to provide a buffer circuit and a control method thereof capable of controlling the timing at which the output switching element is changed from an OFF state to an ON state, and preventing the output characteristic from becoming unstable. The buffer circuit includes: a driving portion 20 driving output switching elements M1 and M2; a detecting portion 30 detecting that the voltage values of control terminals of the output switching elements M1 and M2 have exceeded the threshold voltage value; an auxiliary driving portion 40 being connected to the driving portion 20 and changing driving capability of the output switching elements M1 and M2 in accordance with the result of detection by the detecting portion 30.

Abstract: A semiconductor device includes a first circuit block, a second circuit block, and a data bus. The data bus is coupled between the first and second circuit blocks. A first data inverter on the data bus inverts a selected segment of data that is transferred onto the data bus. A second data inverter at an end of the data bus re-inverts the selected segment of data before the data is transferred off the data bus. The data that is transferred onto the data is not analyzed in order to determine the selected segment of data that is inverted.

Abstract: An impedance adjusting circuit that includes an external terminal to which an external resistor is connected, a first transistor array of a first conductivity type that is connected in parallel between the external terminal and a first power supply terminal and changes a voltage of the external terminal by adjusting an impedance in response to a first control signal, a second transistor array of a second conductivity type that is connected in parallel between the external terminal and a second power supply terminal and changes the voltage of the external terminal by adjusting the impedance in response to a second control signal, and a control circuit that specifies the first control signal according to a comparison result between the voltage of the external terminal and a reference voltage and specifies the second control signal in a different period from a period to specify the first control signal.

Abstract: An output driver of a semiconductor device includes driving transistors and a body bias providing unit. The driving transistors are coupled in parallel and configured to drive an output terminal. The body bias providing unit is configured to supply the driving transistors with respective body biases of at least two levels.

Abstract: An object of the present invention is to realize reduction in an area of an output stage driver in an interface circuit that switches between two transmission systems. The interface circuit has two driver circuits and a drive control circuit that can switch between two driving systems that are a voltage driving system and a current driving system. The two driver circuits are connected to a power supply potential via the drive control circuit. Two input signals and inverted logic signals of the input signals are inputted via a selection circuit. According to a control signal inputted into the drive control circuit, the interface circuit switches between the voltage-driving type single-ended transmission system and current driving type differential transmission system.

Abstract: A transistor gate driving circuit is developed for power saving. It includes a first high-side transistor, a second high-side transistor and a low-side transistor. A voltage clamp device is connected to the gate terminal of the first high-side transistor to limit the maximum output voltage. A detection circuit is coupled to detect a feedback signal of the power converter. The feedback signal is correlated to the output load of the power converter. The detection circuit will generate a disable signal in response to the level of the feedback signal. The disable signal is coupled to disable the second high-side transistor once the level of the feedback signal is lower than a threshold.

Abstract: In an I/O circuit, noise reduction and power savings are achieved by providing feedback from the output of the I/O driver to control the current through the pre-driver and thereby the current through the driver transistors after a non-zero time delay following a low to high or high to low data signal change.

Abstract: The on-die termination circuit of the present invention includes a main resistance circuit and an adjustment circuit. The main resistance circuit is provided with a resistance element and a transistor that is turned OFF when the on-die termination circuit is to be placed in the OFF state and turned ON when the on-die termination circuit is to be placed in the ON state. The adjustment circuit is provided with transistors that are both connected together in parallel and connected in parallel to the main resistance circuit, and that are turned ON or OFF when the on-die termination circuit is placed in the ON state so as to adjust the termination resistance of the entire on-die termination circuit.

Abstract: The present invention discloses a capacitive high-side switch driver for a power converter. The capacitive high-side switch driver according to the present invention includes an inverter and two alternately conducting totem-pole buffers with complementary duty cycles. The duty cycles alternate in response to an input signal. The capacitive high-side switch driver further includes a low-side transistor and a high-side transistor. Once the low-side transistor is turned on, a bootstrap capacitor is charged to create a floating voltage via a charge-pump diode to supply power for the high-side switch driver. To supply additional power for the high-side switch driver, differential signals are produced to further charge the bootstrap capacitor via a bridge rectifier. The capacitive high-side switch driver utilizes a programmable load to provide variable impedance. Furthermore, an under-voltage protector supervises the supply voltage to ensure a reliable gate driving voltage.