Abstract: A latching sense amplifier includes an input stage and an output stage. The output stage is coupled to the input stage. The output stage includes a first output node, a second output node, a pull-up circuit, and a pull-down circuit. The pull-up circuit includes a first transistor, a second transistor, and a latch circuit. The first transistor is configured to pull up the first output node. The second transistor is configured to pull up the second output node. The latch circuit is configured to control the first transistor and the second transistor. The pull-down circuit includes a latch circuit configured to pull-down the first output node based on a voltage of the second output node.

Abstract: Examples disclosed herein relate to set-reset (SR) latch circuits and methods for manufacturing the same. In some of the disclosed examples, a SR latch circuit includes an inverter storage loop for storing state information and a set of p-channel field-effect transistors (PFETs) for control circuitry. The PFETs may include first and second PFETs connected to a first node of the inverter storage loop, and third and fourth PFETs connected to a second node of the inverter storage loop. Gate terminals of the first and fourth PFETs may be connected to a first control input, and gate terminals of the second and third PFETs may be connected to a second control input.

Abstract: An apparatus includes a processor and a virtual address transformation unit coupled with the processor. The virtual address transformation unit includes a register. The virtual address transformation unit is configured to receive an indication of a virtual address and read, from the register, a current page size of a plurality of available page sizes. The virtual address transformation unit is also configured to determine a shift amount based, at least in part, on the current page size and perform a bit shift of the virtual address, wherein the virtual address is bit shifted by, at least, the determined shift amount.

Abstract: A latching sense amplifier includes an input stage and an output stage. The output stage is coupled to the input stage. The output stage includes a first output node, a second output node, a pull-up circuit, and a pull-down circuit. The pull-up circuit includes a first transistor, a second transistor, and a latch circuit. The first transistor is configured to pull up the first output node. The second transistor is configured to pull up the second output node. The latch circuit is configured to control the first transistor and the second transistor. The pull-down circuit includes a latch circuit configured to pull-down the first output node based on a voltage of the second output node.

Abstract: In described examples, an analog to digital converter (ADC) includes a flash ADC. The flash ADC generates a flash output in response to an input signal, and an error correction block generates a known pattern. A selector block is coupled to the flash ADC and the error correction block, and generates a plurality of selected signals in response to the flash output and the known pattern. A digital to analog converter (DAC) is coupled to the selector block, and generates a coarse analog signal in response to the plurality of selected signals. A residue amplifier is coupled to the DAC, and generates a residual analog signal in response to the coarse analog signal, the input signal and an analog PRBS (pseudo random binary sequence) signal. A residual ADC generates a residual code in response to the residual analog signal.

Abstract: An apparatus includes a processor and a virtual address transformation unit coupled with the processor. The virtual address transformation unit includes a register. The virtual address transformation unit is configured to receive an indication of a virtual address and read, from the register, a current page size of a plurality of available page sizes. The virtual address transformation unit is also configured to determine a shift amount based, at least in part, on the current page size and perform a bit shift of the virtual address, wherein the virtual address is bit shifted by, at least, the determined shift amount.

Abstract: A scan flip-flop circuit comprises a scan input sub-circuit and a selection sub-circuit. The scan input sub-circuit is configured to receive a scan input signal and a scan enable signal and, when the scan enable signal is activated, generate complementary scan input signals representing the scan input signal that are delayed relative to a transition of a clock input signal between two different logic levels. The selection sub-circuit is coupled to the scan input sub-circuit and configured to receive the complementary scan input signals and, based on the scan enable signal, output an inverted version of either the scan input signal or a data signal as a first selected input signal.

Abstract: Disclosed is a method for generating an oscillating signal and an oscillator circuit.

Abstract: A serial data transmission system, includes a transmitting terminal for transmitting a data, a receiving terminal for receiving the data transmitted by the transmitting terminal, a first connecting capacitor connected between the transmitting terminal and the receiving terminal, and a second connecting capacitor connected between the transmitting terminal and the receiving terminal, wherein the transmitting terminal comprises a transmitting terminal driver unit and an amplitude detection unit connected with the transmitting terminal driver unit, the transmitting terminal driver unit outputs a pair of differential signals, the amplitude detection unit detects an amplitude variation of the differential signals output by the transmitting terminal driver unit, and outputs an indication signal indicating whether the transmitting terminal and the receiving terminal are properly connected with each other. A serial data transmission method is further provided.

Abstract: One clock generator includes an oscillator block, a delay circuit, and an output block. The oscillator block provides a first clock of multiple phases. The delay circuit delays at least one of said multiple phases of said first clock to generate a second clock of multiple phases. The output block generates a third clock by selecting signals from said multiple phases of said second clock, wherein said third clock has non-harmonic relationship with said first clock. Another exemplary clock generator includes an oscillator block and an output block. The oscillator block includes an oscillator arranged to provide a first clock, and a delay locked loop arranged to generate a second clock according to said first clock. The output block generates a third clock by selecting signals from said multiple phases, wherein said third clock has non-harmonic relationship with said first clock.

Abstract: A semiconductor device includes a first semiconductor chip operating at a first power supply voltage and a second semiconductor chip operating at a second power supply voltage lower than the first power supply voltage to supply the second power supply voltage to the first semiconductor chip. The semiconductor chips according to the present invention are conveniently used for fabrication of the semiconductor device. The first semiconductor chip includes an output circuit including a first transistor and a second transistor, interconnected in series and turned on or off complementarily. The output circuit outputs a signal to a first external output terminal. The first semiconductor chip also includes a third transistor connected in series with the first and second transistors and having a gate electrode connected to a second output terminal.

Abstract: Power gating control and related circuitry for integrated circuits is described herein. A centralized power gating control circuit uses trigger circuits to control the on/off switching of power gating circuits distributed at different points in a chip, integrated circuit, module or block (collectively “IC”). The power gating circuits may include power gates partitioned for sleep and shutdown modes. The shutdown mode power gates may employ multi-level power gate architecture to minimize inrush current during power-up of the IC. Each level may be associated with or tied to a trigger circuit and activated based on a voltage level reaching the voltage threshold of the trigger circuit. The power gating control and related circuitry may be embedded in the IC.

Abstract: Some of the embodiments of the present disclosure provide a latching signal generator, comprising a plurality of inputs configured to receive a clock signal, latch input data, and latch data, wherein the latch input data and the latch data are associated with a latch and wherein the latching signal generator is configured; to provide a latching signal to a latch; and a determination circuit that is configured to cause the latching signal generator to provide the latching signal based on during an active cycle of the clock signal, in response to a determination that the input latch data is different than the latch data. Other embodiments are also described and claimed.

Abstract: A signal reception device is disclosed that is capable of detecting symbol synchronization timing with high precision in accordance with a condition of a propagation path even in an environment involving multi-path interference. The signal reception device adopts an OFCDM transmission scheme or a multi-carrier transmission scheme. The signal reception device includes a received signal information calculation unit to calculate received signal information representing a signal reception condition of a received signal; an output combination unit to combine correlation values in a predetermined section obtained by correlation detection based on the received signal information; and a symbol timing detection unit to detect a symbol synchronization timing based on the combined value.

Abstract: A logic circuit includes two two-terminal switching devices and receives first and second pulses as inputs. Each of the two devices has two different stable resistivity values for each applied voltage that is greater than a first threshold voltage (Vth1) and is smaller than a second threshold voltage (Vth2) that is larger than Vth1. Each switching device, when a voltage less than or equal to Vth1 is applied, becomes in a first state having the higher resistivity of the two resistivity values, whereas when a voltage more than or equal to Vth2 is applied, becomes in a second state having the lower resistivity of the two resistivity values. The two devices are connected in series in a direction with uniform polarity to each other. The first and second states are selectively generated in the first and second devices by a combination of inputs of the first and second pulses.

Abstract: A latch circuit includes: four or more gates; three input terminals and one or two output terminals which are connected to at least one of the four or more gates; a feedback circuit in which respective input terminals of the four or more gates are connected to output terminals of at least another two of the four gates; and a data inverting gate which, when all data input into the three input terminals is the same, outputs inverted data of the data from the output terminals, and when all the data input into the three input terminals is not the same, retains previous data.

Abstract: A digital circuit with adaptive resistance to single event upset. A novel transient filter is placed within the feedback loop of each latch in the digital circuit to reject pulses having a width less than T, where T is the longest anticipated duration of transients. The transient filter includes a first logic element having a controllable inertial delay and a second logic element coupled to an output of the first logic element. A first controller provides a control voltage VcR to each first logic element to control a rise time of the first logic element to be equal to T. A second controller provides a control voltage VcF to each first logic element to control a fall time of the first logic element to be equal to T.

Abstract: On an interface between LSIs, boards, devices (units), and others, the data transfer efficiency per signal line is improved. A shift circuit 710-0 shifts a piece of digital signal D1(0) for output as three digital signals D1S(00) to (02). An analog conversion circuit 720-0 converts the three digital signals D1S(00) to (02) into a piece of analog signal A2(0) for transfer. A digital conversion circuit 730-0 converts the piece of analog signal A2(0) into three digital signals D3(00) to (02). A selection circuit 740-0 makes a sequential selection from the three digital signals D3(00) to (02) to output a piece of digital signal D4(0).

Abstract: A semiconductor device includes a first semiconductor chip operating at a first power supply voltage and a second semiconductor chip operating at a second power supply voltage lower than the first power supply voltage to supply the second power supply voltage to the first semiconductor chip. The semiconductor chips according to the present invention are conveniently used for fabrication of the semiconductor device. The first semiconductor chip includes an output circuit including a first transistor and a second transistor, interconnected in series and turned on or off complementarily. The output circuit outputs a signal to a first external output terminal. The first semiconductor chip also includes a third transistor connected in series with the first and second transistors and having a gate electrode connected to a second output terminal.

Abstract: The invention includes a two terminal switching device having two stable resistivity values for each applied voltage, which when a voltage of not more than a first threshold voltage (Vth1) is applied, becomes in a first state having a higher resistivity, whereas when a larger second threshold voltage (Vth2) or more is applied, becomes in a second state having a lower resistivity; a resistance connected in series to the switching device; a terminal for applying a bias voltage (Vt) to both ends of a series circuit of the switching device and the resistance; a first pulse inputting terminal; and a second pulse inputting terminal. The invention provides a simple realization of a flip-flop circuit for a sequential logic circuit.

Abstract: Observability and controllability in a test of an analog LSI are increased. Analog signals input from input terminals IN1 to IN3 are supplied to diffusion layer regions 221, 223 and 225 via transistors 301 to 303, and are accumulated as electric charge. A clock signal is applied to signal lines 121 and 122 alternately connected to gate electrodes 211 to 216, thus allowing the accumulated electric charge to be transferred to the right direction. Electric charge/voltage conversion amplifiers 411 to 413 are connected to the diffusion layer regions 221, 223 and 225, and the accumulated electric charge is converted into voltage and is output to output terminals VOUT1 to VOUT3 as analog signals. A scan-in terminal Sin is connected to a diffusion layer region 220, and a scan-out terminal Sout is connected to the diffusion layer region 225 via an electric charge/voltage conversion amplifier 401.

Abstract: A power supply circuit includes a first voltage regulator to generate a first supply voltage for a first circuit of a phase-locked loop and a second voltage regulator to generate a second supply voltage for a second circuit of the phase-locked loop. The first and second supply voltages are independently generated by the first and second voltage regulators based on the same reference signal. The first circuit may be a charge pump and the second circuit may be a voltage-controlled oscillator. Different circuits may be supplied with the independently generated supply voltages in alternative embodiments.

Abstract: An input latch circuit of a semiconductor device includes a setup time adjusting unit configured to selectively delay a clock signal and a hold time adjusting unit configured to selectively delay an input signal. The input latch circuit also includes a latch unit configured to latch an output signal of the hold time adjusting unit according to an output signal of the setup time adjusting unit. The input latch circuit changes and delays the clock signal and the input signal by cutting a fuse within the setup time adjusting unit and the hold time adjusting unit without requiring a change to a circuit in order to adjust a setup time and a hold time.

Abstract: A semiconductor integrated circuit device, has a first variable resistor element and a second variable resistor element whose resistances are changed complementarily depending on a current; and a current path switching circuit that supplies said current from a power supply by switching between current paths according to whether a normal operation mode or a read mode is input externally, wherein said power supply is turned off and then turned on again in said normal operation mode, and in this state, data corresponding to the relationship between the magnitudes of the resistances of said first variable resistor element and said second variable resistor element is read in said read mode.

Abstract: A method and apparatus are disclosed for generating multiple separate analog signals using a single microcontroller output pin. The microcontroller generates a waveform that is used to concurrently generate multiple separate analog signals. The microcontroller outputs a waveform that includes a first signal from one of the microcontroller's output pins. The first signal is used to produce a first analog signal. The microcontroller then outputs a delineating signal, as part of the waveform, from the microcontroller's output pin. The delineating signal indicates the start of a next signal in the waveform. The microcontroller then outputs a second signal, as part of the waveform, from its output pin. The second signal is used to produce a second analog signal. The waveform includes the first signal that is followed by the delineating signal that is followed by the second signal.

Abstract: Techniques are provided to hardware debug a programmable logic integrated circuit that includes a hardware intellectual property block (HIP). The HIP includes a logic circuit and state machine(s). The state machine outputs state machine information depending on selected signals within the logic circuit. The HIP block can also output data from a number of internal registers/flip-flops. Optional data registering logic can capture the state machine information and output it to a data bus.

Abstract: A circuit for generating a ternary signal that receives a binary input-control signal and a binary reset signal and outputs a ternary signal. The circuit includes first to third transistors, each source terminal thereof is respectively connected to the three power supplies, and a sequential circuit that outputs control signals controlling the transistors. The sequential circuit outputs control signals that make the first and the third transistors be switched in a complementary manner in an initial state, and make the second and the third transistors be switched in a state that it is released from the initial state.

Abstract: A microcomputer includes a circuit block; a nonvolatile memory configured to store optimization data for optimization of an operation of the microcomputer; and an optimization circuit configured to read out memory optimization data as a part of the optimization data from the nonvolatile memory in synchronization with a first frequency clock signal as an first clock signal to optimize an operation of the nonvolatile memory, and then to read out circuit block optimization data as another part of the optimization data from the nonvolatile memory in synchronization with a second frequency clock signal as the first clock signal to optimize an operation of the circuit block. The frequency of the first frequency clock signal is lower than that of the second frequency clock signal.

Abstract: Systems and methods for multi-state switch networks and multi-state LED networks are provided. Systems and methods for maintaining the brightness of LEDs in multi-state LED networks are also provided. The multi-state networks contain control circuitry that can output a single control signal that is able to drive a pair of diodes in three different states. In a network of 2*N diodes, N wires are sufficient to drive the diodes in 3N different states. The control circuitry may also include a pulse-width modulator that controls the perceived brightness of the LEDs in a multi-state LED network in response to a voltage level of the power source.

Abstract: A clock input/output device has three-state inverters Iv1 to Iv3 and an inverter Iv4, which cooperate to make equal the on-state resistance through a supply-voltage-side (VDD-side) transistor and the on-state resistance through a ground-voltage-side (0-side) transistor so as to make equal to VDD/2 the threshold voltage with reference to which the clock input/output device evaluates the input thereto to determine whether or not to change the state of the output thereof.

Abstract: By mounting, on a semiconductor integrated circuit, a clock stability waiting circuit 4 for deciding whether a clock signal generated by a high speed clock generating circuit 2 is stable or not, a scan pass control circuit 7 capable of switching a scan pass structure based on a signal output from the clock stability waiting circuit 4 and an activation control circuit 6 capable of switching an order circuit to be activated based on the signal output from the clock stability waiting circuit 4, it is possible to carry out a parallel test in a stability waiting time having a high speed clock. Moreover, it is possible to externally monitor a signal capable of deciding a stability of a high speed clock. Therefore, it is easy to decide whether a failure is caused by a high speed clock generating portion or an internal circuit.

Abstract: A flip-flop includes a first circuit receiving a clock signal and the first signal and transitioning the first and second output signals to a first level when the clock signal goes to an active level, and a second circuit transitioning the first signal to the first level after the first and second output signals go to the first level. The first circuit transfers first and second input signals to the first and second output terminals from first and second input terminals when the clock signal is at the active level and the first signal is at the first level.

Abstract: A track and hold circuit (1) comprising:—a linear amplifier (2) receiving a differential analog signal (D+, D?) and being controlled by a first binary clock signal (H+) having a first phase,—the linear amplifier (2) providing a feed-forward input signal substantially equal with the differential analog signal (D+, D?) to a pseudo latch circuit (3) in the first phase of the first binary clock signal (H+), said pseudo latch circuit (3) being controlled by a second binary clock signal (H?) for memorizing the input signal and providing a differential output signal (LD+, LD?) substantially equal with the input signal during a second phase of the first binary clock signal (H?), the second binary clock signal being substantially in antiphase with the first binary clock signal (H+).

Abstract: A tracking data cell (10) comprising:—a pair of track and hold circuits (1, 1?) coupled to a first multiplexer (5),—a clock signal (H+, H?) being inputted substantially in anti-phase in the respective track and hold circuits (1, 1?) for determining a receipt of a data signal (D+, D?) having a rate, —said track and hold circuits (1, 1?) providing an output signal (O) having a substantially half rate.

Abstract: A semiconductor integrated circuit according to the present invention comprises a latch circuit, a retaining circuit, and a feedback circuit, wherein the latch circuit inputs therein an input data signal, a clock signal and a feedback signal and outputs an output data signal, the retaining circuit retains the output data signal, and the feedback circuit inputs therein the input data signal and the output data signal to thereby generate the feedback signal based on logic combinations of the input data signal and the output data signal, and an internal operation of the latch circuit is turned on/off by means of the feedback signal.

Abstract: A pulse duty deterioration detection circuit with a high monitoring precision is easily provided. The pulse duty deterioration detection circuit comprises a delay circuit comprised of a general-purpose gate circuit which generates a delayed synchronous to-be-monitored clock by delaying the to-be-monitored clock by a predetermined time, a latch circuit which detects based on the to-be-monitored clock and the delayed synchronous to-be-monitored clock that a value of a decrease in a pulse width to be determined by a pulse duty of the to-be-monitored clock becomes smaller than the predetermined time, and a flip-flop circuit which samples an output signal of the latch circuit based on the to-be-monitored clock.

Abstract: A level-shifter architecture with high-voltage driving capability and extremely low power consumption, exploiting dynamic control of the charge on the gate electrodes of the high-voltage output transistors, is provided. The architecture can be integrated in CMOS technology and can be applied to various applications, including monolithic integration of high-voltage display driver circuits in battery-powered applications.

Abstract: A tristable latch circuit fabricated utilizing standard MOS process technology includes a biasing element for identically biasing the MOS transistors in triode (as opposed to saturation) to implement a third stable operating point.

Abstract: Integrated circuit device that uses tristate switching means to disconnect input/output pins from input buffers during a power down mode, thereby preventing current leakage through partially turned on MOS transistors inside input buffers. A transition detection means connected between the input/output pins and the controlling inputs of the tristate switching means monitors electronic signal at the input/output pins while the chip is in a power-down mode and turns on the tristate switching means when a signal transition is detected.

Abstract: An integrated circuit is provided which includes a multi-state circuit with a first PMOS transistor and a first NMOS transistor. In an active mode, the multi-state circuit is operable to switch between a first state in which the first PMOS transistor is turned on and the first NMOS transistor is turned off and a second state in which the first PMOS transistor is turned off and the first NMOS transistor is turned on. A power source NMOS transistor has a drain connected to a supply voltage terminal and has a source connected to a source of the first PMOS transistor. A power source PMOS transistor has a drain connected to a an effective ground terminal and has a source connected to a source of the first NMOS transistor.

Abstract: A level-shifter architecture with high-voltage driving capability and extremely low power consumption, exploiting dynamic control of the charge on the gate electrodes of the high-voltage output transistors, is provided. The architecture can be integrated in CMOS technology and can be applied to various applications, including monolithic integration of high-voltage display driver circuits in battery-powered applications.

Abstract: A magnetic field sensor includes: a Hall element; a voltage amplifier for amplifying an output voltage from the Hall element so as to output an amplified signal; a voltage comparison circuit for receiving the amplified signal; a switch circuit provided between the voltage amplifier and the voltage comparison circuit for inverting a polarity of the amplified signal; and a latch circuit for holding an output signal from the voltage comparison circuit. The voltage comparison circuit inverts a polarity of a hysteresis voltage that determines a reference value of a magnetic field intensity in response to a first synchronizing signal, which triggers a detection of a magnetic field, and a second synchronizing signal following the first synchronizing signal.

Abstract: A self-determining control circuit is configured to assume one of several states depending upon the interconnections of its input and output terminals. The self-determining circuit is enabled to sense which, if any, of its input and output have been interconnected and assume its proper state of operation. For example, a self-determining integrated circuit may have four input terminals (e.g., terminals 1, 2, 3, 4) and four output terminals (e.g., terminals A, B, C, D). The circuit may sense that a particular input terminal is directly connected with a particular output terminal (e.g., input terminal 2 is shorted to output terminal D) and operate under one set of parameters. If, however, the control circuit senses that a different set of terminals are interconnected (e.g., input terminal 4 with output terminal B), then the control circuit may operation under a different set of parameters.

Abstract: A method and a device generate a reference voltage for discriminating between the logic states of a data signal received at a receiving end. A transmitting device transmits a continuous clock signal with a constant pulse period duration and a symmetrical sequence of low and high clock signal states in such a way that, at the receiver end, the clock signal has the same low and high voltage levels as the received data signal and it is subject to the same system-governed variations as the received data signal. An integrator at the receiver end receives and integrates the clock signal, and the integrated value becomes the reference voltage for the receiver unit.

Abstract: A voltage differential sensing circuit and methods of operation are disclosed for use in a memory device. The sensing circuit utilizes the inherent delay during sensing, i.e., the period between when an enable signal is enabled and when data is valid, by pulling a node of a transition logic circuit to a midpoint voltage. As the node of the transition logic circuit starts at a midpoint voltage, the voltage swing to valid data is faster because the output no longer needs to swing from rail to rail as before.

Abstract: An apparatus comprising a first circuit and a second circuit. The first circuit may be configured to generate one or more first control signals in response to (i) a clock signal and (ii) one or more second control signals. The second circuit may be (i) coupled to the first circuit via one or more path circuits and (ii) configured to present an output signal in response to the one or more first control signals. All of the one or more first control signals may have a preferred edge skew.

Abstract: A method for fabricating IC devices including both rising edge-triggered circuits (e.g., flip-flops or latches) and falling edge-triggered circuits in which a clock signal line is selectively inverted by an on-chip clock signal inverting circuit and applied to one or the other circuit types during test modes. The clock signal inverting circuit is implemented as a two-input exclusive-OR gate, or using a multiplexer. The method includes placing and routing the selected circuit type (i.e., rising or falling edge) such that clock skew is minimized.

Abstract: An improved pre-driver circuit 33, which uses only three additional components to bypass the back-gate current blocking diodes for increased circuit speed during normal operation, while reducing the Ioff current and satisfying over-voltage tolerant specification. This unique circuit uses the pre-driver's tri-state input signal to control the pull-up path of the pre-driver circuit's upper output (UOP) transistor 3010.

Abstract: A logic circuit with improved performance when operating at the limits of the transistor's bandwidth. In particular, a latch includes a clocked trans-admittance stage circuit for receiving a voltage and producing a current output, and an active load, such as a trans-impedance stage circuit, connected to receive as input the current output of the trans-admittance stage circuit and produce a voltage input to the trans-admittance stage. The circuit output is taken from the output of the trans-admittance stage. Two independent trans-admittance and trans-impedance stages may be combined as a single latch pair. One or more latch pairs may be arranged in series as a cascaded chain and connected to the output current of a clocked trans-admittance stage latch to form a register.

Abstract: The present invention relates to a latch including two first N-channel transistors connected to a low supply potential and controlled by a clock signal; two second transistors respectively connecting the two first transistors to an inverted output terminal and to a non-inverted output terminal and respectively controlled by a data line and a complementary data line; two third P-channel transistors respectively coupling the two second transistors to a high supply potential and cross-controlled by the output terminals; and circuitry for maintaining the states of the output terminals when the first transistors are non-conductive.