Abstract: Some embodiments provide a circuit for accessing stored data in a configurable IC that includes several configurable circuits. The IC also includes several storage circuits. Each storage circuit has (1) several storage elements for storing data for the configurable circuits, and (2) output circuitry for outputting data stored in the storage elements. The output circuitry includes a first set of interconnects for receiving at least a first repeating periodic signal and for periodically outputting data from at least two storage elements to the configurable circuits.

Abstract: An input/output sense amplifier (IOSA) controller of a semiconductor memory device includes an auto pulse generator and a latch enable signal generating circuit. The auto pulse generator generates an auto pulse signal having a first pulse shape. The latch enable signal generating circuit generates a first latch enable signal having a second pulse shape in response to an auto pulse signal in normal mode, and generates a second latch enable signal having a level shape that is enabled for long duration in response to the write enable bar signal in test mode. Accordingly, the semiconductor memory device including the IOSA controller may safely test a characteristic of the IOSA.

Abstract: An over-driven access method and device for ferroelectric memory. When accessing the data stored in a ferroelectric memory, the invention further provides an over-driven current to slightly reduce/raise the voltages in bit lines BL and BL? to further enlarge the voltage difference therebetween after having raised the plate-line/bit-line voltage using the plate-line/bit-line driven method.

Abstract: A sense amplifier circuit provides for high speed sensing with a high speed read operation, with a low capacitance and a low resolution time. The sense amplifier circuit includes a latch circuit having a first inverter circuit and a second inverter circuit cross coupled with each other. The amplifier circuit includes a first discharge device and a second discharge device operatively coupled to the first inverter circuit and the second inverter circuit respectively. The amplifier circuit further includes a first PMOS transistor operatively coupled between the first discharge device and a bit line, and a second PMOS transistor operatively coupled between the second discharge device and a complementary bit line. The amplifier circuit further includes a first NMOS transistor operatively coupled between the first discharge device and a ground voltage, a second NMOS transistor operatively coupled between the second discharge device and the ground voltage.

Abstract: A high-voltage switch circuit includes an enable control circuit, a feedback circuit, a boosting circuit, and a high voltage switch. The enable control circuit precharges an output node to a set voltage in response to an enable signal. The feedback circuit supplies a feedback voltage to an input node in response to a switch control voltage generated from the output node when the output node is precharged. The boosting circuit boosts the feedback voltage and outputs a boosting voltage to the output node, in response to clock signals, thereby increasing the switch control voltage. The high voltage switch is turned on or off in response to the switch control voltage, and is turned on to receive a high voltage and output the received high voltage. The boosting circuit includes an amplification circuit of a cross-coupled type.

Abstract: Various embodiments of the present invention provide systems and circuits for processing information through comparison of input signals. For example, various embodiments of the present invention provide differential latch circuits. Such differential latch circuits include an input stage and a latch stage. The input stage provides an interim output that is available during a defined period, and the latch stage is operable to latch the temporary interim output during the defined period using a common clock.

Abstract: A semi-dual reference voltage data receiving apparatus includes a first input buffer, a second input buffer, and a phase detector wherein the first input buffer includes a first input receiving unit, a first sense amplifier, and a first current offset controlling unit. The first sense amplifier senses and amplifies the voltage difference between the voltage of a first terminal of a first input transistor and the voltage of a first terminal of a second input transistor. The first current offset controlling unit controls the offset of the current that flows through the second terminal of the second input transistor.

Abstract: A fast, accurate, low offset comparator may be configured with multiple gain stages. A low gain, low input impedance, and fully differential common-gate amplifier may be configured as a first stage in the multi-stage comparator, providing a wide bandwidth for small power consumption. The inputs of the comparator may comprise a pair of differential inputs at respective source terminals of gate-coupled metal oxide semiconductor (MOS) devices configured in the input stage of the common-gate amplifier. A pair of differential outputs of the first stage may be coupled to a pair of differential inputs of a second stage, which may be a differential input current-mirror amplifier that may perform differential to single-ended conversion.

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 differential comparator is provided. The comparator receiving two differential signals and generating a comparison result represented by an output signal on one of two output terminals respectively on two current paths. The comparator comprises two pairs of latch transistors respectively disposed on the two current paths and two pairs of input transistors respectively disposed on the two current paths, wherein gates of the latch transistors on one of the current paths are commonly coupled to the output terminal between the latch transistors on the other current path, gates of the input transistors on one of the current paths respectively receives an input signal of one of the differential signals and a reference signal of the other differential signal and each of the input transistors is disposed between the output terminal and one of the latch transistors on the current path thereof.

Abstract: A differential current-sensing amplifier includes two inverters, two resistors, a NOR gate, and five switches. The first inverter has a first output; the second inverter has a second output. The first resistor is connected between the first inverter and ground; the second resistor is connected between the second inverter and ground. A current to be sensed is input between the first resistor and the first inverter; a reference current is input between the second resistor and the second inverter. The first switch is connected between the first output and ground, the second switch is connected between the second output and ground, and the third switch is connected between the first and the second inverters and power. The first and the second switches are turned off, and the third switch is turned on, to compare the current to be sensed in relation to the reference current.

Abstract: Sensing circuitry and a method of operating such sensing circuitry are provided. The sensing circuitry has voltage change detection circuitry for detecting a change in voltage on at least one input line and for producing at least one output signal indicative of that change during a sensing stage of operation. The voltage change detection circuitry comprises at least one latch transistor having a body region insulated from a substrate. Further, body biasing circuitry is provided which, prior to the sensing stage of operation, causes a voltage to be applied to the body region that is derived from the voltage on one of said at least one input lines. Then, during the sensing stage of operation, the body biasing circuitry causes the voltage of the body region to float. Such an arrangement enables removal of the history effect that can sometime affect such latch transistors, whilst alleviating power consumption and noise issues that can occur in certain known sensing circuits.

Abstract: In accordance with an embodiment of the present invention, a comparator system includes a plurality of multiplexers adapted to multiplex a number of differential input signals and a number of differential reference signals. A differencing circuit receives a differential input signal and a differential reference signal from the multiplexers and provides a differential output signal, which is used to provide a differential comparator output signal. A latch may be provided to perform differential-to-single ended conversion on the differential comparator output signal to provide a latch output signal. An output circuit may provide a registered digital output signal based on the latch output signal.

Abstract: A differential output circuit includes a bias circuit connected with a first voltage. An input circuit section includes first and second MOS transistors of a first conductive type, and the first and second MOS transistors are connected with the first voltage through the bias circuit, and gates of the first and second MOS transistors receive a differential input signal. Third and fourth MOS transistors of a second conductive type are connected with the first and second MOS transistors through first and second resistance elements, respectively, and connected with a second voltage. A first connection node between the first MOS transistor and the first resistance element is connected with a gate of the fourth MOS transistor, and a second connection node between the second MOS transistor and the second resistance element is connected with a gate of the third MOS transistor.

Abstract: A differential input circuit receives differential input signals at a pair of differential input terminals and produces a pair of first differential output signals. A sensing circuit senses at least one of the pair of first differential output signals reaching a certain voltage and provides an activation signal. A latch-type amplifier provides a pair of second differential output signals when activated in accordance with the activation signal. A cutoff circuit establishes connection between the differential input circuit and the latch-type amplifier and breaks connection between the differential input circuit and the latch-type amplifier in accordance with the activation signal.

Abstract: A circuit includes an input terminal, an output terminal and a latch. The input terminal receives an input signal. The latch is programmable with a value. The latch communicates the input signal to the output terminal in response to the circuit not being in a sleep mode and in response to the circuit being in the sleep mode, furnishes a second signal to the output terminal indicative of the value.

Abstract: A Magnetic Random Access Memory (MRAM), in which very little current flows through MTJ elements and very little voltage is applied across them, the MRAM being provided with sense-amplifiers capable of amplifying the potential difference between their corresponding pairs of bit lines at high speed. This is accomplished by a sense amplifier including CMOS inverters cross-connected or connected in loop, a P-channel MOS transistor for shutting the power off during standby, and N-channel MOS transistors for initializing the output of the sense amplifier during standby. A ground terminal of the inverter is connected to a bit line through a transistor of a bit switch, and a ground terminal of the inverter is connected to a bit line through a transistor of a bit switch.

Abstract: An input circuit is provided that can identify three states of an external signal without complicated voltage adjustment and that can reduce the power consumption in a standby state.

Abstract: An analog voltage latch for use in a controller for controlling a motor equipped electric bicycle, includes a window comparator for comparing an analog voltage latch output and an analog input voltage to produce a comparison result, an S-R latch for producing HIGH or LOW according to the comparison result, a selector for selecting an operation, an up/down counter for counting up or down according to the HIGH or LOW from the S-R latch, and holding the counted result according to the selector result, and a DA converter for converting the counted result to analog signal.

Abstract: Provided is an amplifier circuit having a constant output swing range and a stable delay time, where the amplifier circuit includes a first bias unit, a second bias unit, a comparison unit, and an amplifier unit, and the first bias unit responds to an internal reference signal with a predetermined voltage level and maintains constant the amount of a first current, and the second bias unit receives an external reference signal, responds to a control voltage, and controls the amount of a second current to be the same as the amount of the first current, and the comparison unit compares a voltage level of a first node with a voltage level of a second node, and controls a voltage level of the control voltage according to the comparison result, and the amplifier unit compares a voltage level of an external input signal with a voltage level of the external reference signal, amplifies and outputs a voltage difference between the two compared signals, responds to the control voltage, and controls the amount of a third

Abstract: A flip-flop circuit capable of inhibiting current consumption as well as the circuit scale from increase is provided. This flip-flop circuit comprises a first latch circuit including first and second inverter circuits. A first power supply line capable of switching a supplied potential between a fixing potential supplied for fixing the potentials of output nodes of the first and second inverter circuits and a floating potential supplied for floating the potentials of the output nodes of the first and second inverter circuits is connected to the first latch circuit.

Abstract: An over-driven access method and device for ferroelectric memory. When accessing the data stored in a ferroelectric memory, the invention further provides an over-driven current to slightly reduce/raise the voltages in bit lines BL and BL? to further enlarge the voltage difference therebetween after having raised the plate-line/bit-line voltage using the plate-line/bit-line driven method.

Abstract: In a latch circuit having a bistable pair of cross connected transistors of a first polarity and a third transistor of a second polarity, a current signal greater than a bias current is received at a latch circuit port, amplified with the third transistor, and applied to the latch circuit port. This decreases the time in which the latch circuit port receiving the current signal greater than the bias current reaches a steady state voltage.

Abstract: A sense amplifier circuit provides for high speed sensing with a high speed read operation, with a low capacitance and a low resolution time. The sense amplifier circuit includes a latch circuit having a first inverter circuit and a second inverter circuit cross coupled with each other. The amplifier circuit includes a first discharge device and a second discharge device operatively coupled to the first inverter circuit and the second inverter circuit respectively. The amplifier circuit further includes a first PMOS transistor operatively coupled between the first discharge device and a bit line, and a second PMOS transistor operatively coupled between the second discharge device and a complementary bit line. The amplifier circuit further includes a first NMOS transistor operatively coupled between the first discharge device and a ground voltage, a second NMOS transistor operatively coupled between the second discharge device and the ground voltage.

Abstract: In accordance with some embodiments, a current-balanced logic circuit includes a first sense amplifier, a second sense amplifier, and a current-source transistor which provides bias current to the first and second sense amplifiers. The first and second sense amplifiers are alternately activated by first and second differential clock signals, and when activated convert data received on differential input lines into logical values for storage in respective storage circuits. The storage circuits may be flip-flops, latches, keeper circuits, or other circuits for storing data.

Abstract: In some embodiments, a receiver latch circuit, includes a dynamic latch having at least one input terminal to receive an input data signal and at least one latch terminal. The dynamic latch is adapted to generate an amplified output data signal based at least in part on the input data signal. The dynamic latch includes at least one capacitor, coupled between the at least one input terminal and the at least one latch terminal, to reduce intersymbol interference in the input data signal.

Abstract: In a latch circuit having a bistable pair of cross connected transistors of a first polarity and a third transistor of a second polarity, a current signal greater than a bias current is received at a latch circuit port, amplified with the third transistor, and applied to the latch circuit port. This decreases the time in which the latch circuit port receiving the current signal greater than the bias current reaches a steady state voltage.

Abstract: Some embodiments provide a circuit for accessing stored data in a configurable IC that includes several configurable circuits. The IC also includes several storage circuits. Each storage circuit has (1) several storage elements for storing data for the configurable circuits, and (2) output circuitry for outputting data stored in the storage elements. The output circuitry includes a first set of interconnects for receiving at least a first repeating periodic signal and for periodically outputting data from at least two storage elements to the configurable circuits.

Abstract: A sense amplifier based flip flop and method thereof are provided. The example sense amplifier-based flip-flop may include a first current passing unit receiving a first clock signal with a first delay, the first current passing unit configured to pass current from a first node to a ground terminal if the applied first clock signal is set to a first logic level and not to pass current from the first node to the ground terminal if the applied first clock signal is set to a second logic level and a second current passing unit receiving a second clock signal with a second delay, the second delay and the first delay not being the same, the second current passing unit configured to pass current from a second node to the ground terminal if the applied second clock signal is set to the first logic level and not to pass current from the second node to the ground terminal if the applied second clock signal is set to the second logic level.

Abstract: A differential sense amplifier is described that can be configured as a preamplifier or a latch circuit as triggered by a clock signal connected to a switch circuit. When the clock signal is set at a first signal level, the switch circuit in the differential sense amplifier is activated so that the differential sense amplifier is configured as a preamplifier with a positive feedback circuit. When the clock signal is set at a second signal level, the switch circuit in the differential sense amplifier is deactivated so that the differential sense amplifier is configured as the latch circuit. For one read cycle, the differential sense amplifier operates first as the preamplifier and then as the latch circuit.

Abstract: An over-driven access method and device for ferroelectric memory. When accessing the data stored in a ferroelectric memory, the invention further provides an over-driven current to slightly reduce/raise the voltages in bit lines BL and BL? to further enlarge the voltage difference therebetween after having raised the plate-line/bit-line voltage using the plate-line/bit-line driven method.

Abstract: A sense amplifier circuit includes a first double-gate metal oxide semiconductor field effect transistor (DGMOSFET) having a first gate defining a first input to the circuit, a second gate and an output being coupled to a first output of the circuit and a second DGMOSFET having a first gate defining a second input of the circuit, a second gate connected to the output of the first DGMOSFET and an output connected to the second gate of the first DGMOSFET, the output of the second DGMOSFET being coupled to a second output of the circuit.

Abstract: A flip-flop circuit includes a differential stage coupled to a latch stage. The differential stage comprises cross-coupled dynamic logic and only provides a single output to the latch stage. During an evaluation phase, the state of a data input signal is sensed. Depending upon the state of the data input signal, either an output side or reference side of the differential stage is discharged. Also, during the evaluation phase, the latch stage write port is enabled while feedback is disabled, and the flip flop thereby samples and stores an output signal from the output side of the differential stage. Upon initiation of the next precharge phase, the latch stage write port is disabled and feedback is enabled, thereby retaining its present state. Only a single side of the differential stage is used to drive the latch stage and the differential stage may be implemented in an asymmetric fashion.

Abstract: A latch type sense amplifier includes a latch unit, an amplifying unit and a circuit module for charging or discharging the latch unit. The latch unit is configured by two sets of serially coupled PMOS and NMOS transistors, whose gates and drains are cross-coupled. The amplifying unit is coupled between the latch unit and a complementary power supply for controlling the latch unit in response to a bit line signal and a complementary bit line signal. The circuit module is designed to charge or discharge the data storage node and the complementary data storage node of the latch unit in response to the bit line signal and the complementary bit line signal, without using a current path across the NMOS transistors therein, such that the data storage node and the complementary data storage node are charged or discharged in a manner insensitive to a mismatch between the two NMOS transistors.

Abstract: A differential output circuit includes first and second inputs, first and second outputs, a resistor element connected between the outputs, first and second N-channel MISFETs, and first and second P-channel MISFETs. The inputs respectively receive first and second complementary input signals. The first N-channel MISFET has a source connected to the first input, a gate receiving a power supply potential, and a drain connected to the first output. The second N-channel MISFET has a source connected to the second input, a gate receiving the power supply potential, and a drain connected to the second output. The first P-channel MISFET has a source receiving the power supply potential, a gate connected to the second input, and a drain connected to the first output. The second P-channel MISFET has a source receiving the power supply potential, a gate connected to the first input, and a drain connected to the second output.

Abstract: Returning to FIG. 2, sense circuit 201 represents the circuit that must sense the signaling on an interconnect. NMOS device 202 is always on so that there is a continuous path to ground whenever PMOS driver 204 is on. Since leakage power is an order of magnitude less than static and dynamic power it can be omitted for clarity, although it should be noted that dynamic power increases with respect to line length since the interconnect capacitance increases as line length increases. Static power is due to flow of static current across the two resistances shown in FIG. 2, interconnect resistance 206 and the resistance of transistors 102 and 104 from FIG. 1, represented by the resistance of equivalent NMOS transistor 208 of FIG. 2.

Abstract: A method and system for pre-charging and biasing a latch-type sense amplifier are described. According to an embodiment of the invention, the data latch portion of the latch-type sense amplifier includes two cross-coupled inverters having two output nodes, and two input nodes. The input nodes of the data-latch are connected to a pair of complementary bit-lines via bias control transistors. The bias control transistors are to pre-charge the input nodes based on the voltage levels of the bit-lines so as to bias the voltage levels at the input nodes in a direction the input nodes will seek upon activation of the sense amplifier.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: A differential amplifier circuit has a latch unit and a differential input portion. A minute current is kept to flow through the differential input portion. Therefore, the differential amplifier circuit can accurately amplify even a signal high in speed and small in amplitude.

Abstract: A system and method is disclosed for providing a clock and data recovery circuit that comprises a low jitter data receiver. The low jitter data receiver comprises a phase interpolator, an amplifier unit and a data sampling comparator. The phase interpolator and the amplifier unit provide the data sampling comparator with a single ended clock signal that is relatively immune to power supply noise. The data sampling comparator samples an input data stream with minimal jitter due to power supply noise. The data sampling comparator consumes less static power than a current mode logic D flip flop and also has output levels that are compatible with complementary metal oxide semiconductor (CMOS) logic.

Abstract: An amplifier circuit includes an amplifier section (700), an equalization section (770), and an activation section (720). The P-channel transistors (702, 704) of the amplifier section are coupled to a supply terminal (802). The N-channel transistors (706, 708) of the amplifier section are coupled between the P-channel transistors and the first and second input terminals (760, 762), respectively. In the activation section, first and second pull down transistors (722, 724) are coupled between the first and second input terminals, respectively, and a second power supply terminal (726), and third pull down transistor between the first and second input terminals. The control gates of the first, second and third pull down transistors are coupled to each other. In operation, a voltage signal applied to the first and second input terminals is amplified by the N-channel transistors. A control signal is then applied to couple the first and second input terminals to a supply voltage.

Abstract: A circuit for driving a pair of input signals to form driven output signals while reducing the amount of skew between the driven output signals. In one embodiment, a driver circuit includes a first set of drivers connected in series and receiving the first input signal to produce a first output signal; a second set of drivers connected in series and receiving the second input signal to produce a second output signal; a first transmission gate connecting an input of one of the drivers from the first set of drivers to an output of one of the drivers of the second set of inverters; and a second transmission gate connecting an input of one of the drivers from the second set of drivers to an output of one of the drivers of the first set of drivers. Each transmission gate may be provided with a control for enabling or disabling the transmission gate, thereby permitting the selective application of the de-skew function of the circuit and providing for reduced power consumption when the de-skew function is disabled.

Abstract: A method of comparing signals includes obtaining first and second signals to be compared and first and second offset cancellation signals, combining the first offset cancellation signal with the first signal to be compared to form a first combined signal and combining the second offset cancellation signal with the second signal to be compared to form a second combined signal, comparing the combined first signal with the combined second signal, and producing an output indicating which of the combined first signal or the combined second signal is greater.

Abstract: A sense amplifier latch that is operable to interface with high common-mode input voltages with wide ranges for all process variations. The sense amplifier latch comprises a cross-coupled latch having first and second rail signals; a pre-charge device; an equalization device; pass devices for enabling input devices to receive pad and reference inputs. In the present invention, the input devices comprise push-pull impedance dividers are used to preserve the input difference voltage while dramatically lowering the common-mode output voltage. The outputs of the impedance dividers are fed to the cross-coupled latch of the sense amplifier using n-channel pass gates.

Abstract: A latch-type level converter has a signal-input transistor, a latch, and a clock-input transistor. The signal-input transistor, which is a high-voltage transistor, receives an input signal, and the latch holds data of the input signal received by the signal-input transistor. The clock-input transistor controls the operation in accordance with a clock. According to the latch-type level converter, not only can low-amplitude signals be accurately amplified, but also input signals having a common-mode voltage higher than the supply voltage can be received.

Abstract: A bit-line sense amplifier is disclosed that includes switching elements to sequentially modify the sense amplifier to a negative feedback differential amplifier, a normal differential amplifier, a positive feedback differential amplifier, and a cross-coupled latch, in that order. The sense amplifier sensing data on a pair of bit-lines in a semiconductor memory; and a transistor is connected between one of the differential amplifiers and a common current source. The transistor has a resistance which is variable depending on a potential of an output of one of the differential amplifiers or remains constant by a different power source.

Abstract: A sense amplifier circuit comprises (1) an isolation device comprising a control terminal and first and second terminals, the first terminal of the isolation device coupled to a signal line, (2) a gated diode comprising first and second terminals, the first terminal of the gated diode coupled to the second terminal of the isolation device, and the second terminal of the gated diode coupled to a set line; and (3) control circuitry coupled to the control terminal of the isolation device and adapted to control voltage on the control terminal of the isolation device in order to enable and disable the isolation device. A latch circuit further comprises a precharge device comprising a control terminal and first and second terminals, the first terminal of the precharge device coupled to a power supply voltage, and the second terminal of the precharge device coupled to the first terminal of the isolation device.

Abstract: The present invention provides a clock signal input circuit that is able to provide inverse internal clock signals generated by the same input buffer as the address and data signals which exhibit reduced skew. When a skewed external noninverse clock signal and a corresponding external inverse clock signal are passed through respective reference voltage input buffers there is no reduction in skew between the two internal signals. In a preferred embodiment, the invention provides back to back inverters connected to both lines carrying the noninverted and inverted internal clock signals. The slower internal clock signal has an extra inverter driving it when it switches states and the faster internal clock signal has an extra inverter fighting it when it switches states. The skew of the two signals is reduced, allowing for faster operation of the integrated circuit and a reduction in misread data signals.

Abstract: An oscillator delay stage is described. The oscillator delay stage includes at least one differential input; a pair of single ended inverters for each differential input; and, a differential output. With respect to the pair of single ended inverters for each differential input, each pair of single ended inverters further include for their corresponding differential input: i) a first single ended inverter whose input is coupled to a + input of the corresponding differential input; and, ii) a second single ended inverter whose input is coupled to a ? input of the corresponding differential input. With respect to the differential output, the differential input further includes: i) a + output that is coupled to each said second single ended inverter output; ii) a ? output that is coupled to each said first single ended inverter output.

Abstract: Method and apparatus for an ultra-drowsy circuit for use in lower power operational modes are described.