Abstract: Methods, systems, and apparatus, including computer program products for programming memory. In one aspect, a program circuit includes a first transistive element; a second transistive element coupled to a first end of the first transistive element; a burn subcircuit, the burn subcircuit including a third transistive element coupled to a fourth transistive element, where the drain of the third transistive element is coupled to a second end of the first transistive element, and the source of the third transistive element is coupled to the drain of the fourth transistive element; and a fifth transistive element coupled in parallel to the fourth transistive element. Control logic coupled to the first transistive element, the burn subcircuit, and the fourth transistive element selectively enables the second transistive element, selectively enables the fourth transistive element, and selectively enables the fifth transistive element to enable a read mode or a program mode.

Abstract: A circuit for processing a clock signal including first and second clock edges of different polarities, the circuit including an inverter for inverting a first clock edge to generate an inverted first clock edge and inverting a second clock edge to generate an inverted second clock edge; a first pass gate for receiving the inverted clock edge and outputting a first trigger signal of a first polarity; and a second pass gate for receiving the second clock edge and outputting a second trigger signal of the first polarity, wherein the second pass gate is controlled to open responsive to the inverted second clock edge; whereby the delay between the first clock edge and the first trigger signal is substantially equal to the delay between the second clock edge and second trigger signal.

Abstract: In a logic circuit where clock gating is performed, the standby power is reduced or malfunction is suppressed. The logic circuit includes a transistor which is in an off state where a potential difference exists between a source terminal and a drain terminal over a period during which a clock signal is not supplied. A channel formation region of the transistor is formed using an oxide semiconductor in which the hydrogen concentration is reduced. Specifically, the hydrogen concentration of the oxide semiconductor is 5×1019 (atoms/cm3) or lower. Thus, leakage current of the transistor can be reduced. As a result, in the logic circuit, reduction in standby power and suppression of malfunction can be achieved.

Abstract: A latch circuit. The latch circuit may include an input circuit, a precharge circuit, and a transfer circuit. The precharge circuit may precharge a first node during a first phase of a clock signal. Based on an input signal received at a first logic value, the input signal may drive the first node to a second logic value during the second clock phase. The transfer circuit may include a discharge circuit that is active during an evaluation phase beginning at a delay time subsequent to the clock signal entering the second phase and ending when the clock signal re-enters the first phase. The transfer circuit may also include pull-up and pull-down transistors, one of which may drive a logic value to a second node during the evaluation phase.

Abstract: A flip-flop circuit includes a precharge circuit that outputs a charge signal high when a received clock signal is LOW. A delay clock input circuit generates a delayed clock input controlled signal with the same value as an input signal when the clock signal is HIGH. A charge keeper circuit, upon receiving the charge signal and the delayed clock input controlled signal, generates a charge keeping signal, which equals the charged signal when the clock signal is LOW and equals the delayed clock input controlled signal when the clock signal is HIGH. A separator circuit can receive the charge keeping signal and clock signal and generate an inverted charge keeping signal. A storage circuit is configured to receive the inverted charge keeping signal, a present state signal, and inverted present state signal, and to generate a present state signal and an inverted present state signal.

Abstract: A pulsed latch circuit with conditional shutoff prevents an input node, such as a node receiving data, of the pulsed latch circuit, from latching data based on a delayed input control signal, such as an internal clocking signal, and based on a feedback latch state transition detection signal indicating that a current state of input data is stored in the latch. As such, two control conditions are used to shut down the latch. In one example, a condition generator detects when the latch has captured data correctly and outputs a signal to disable the input node. In addition, a variable delay circuit is used to adjust the width of the allowable input signal to set a worst case shutoff time. If data is latched early, a feedback latch state transition detection signal causes the input node to be disabled. If data is not latched early, the maximum allowable latch time is set by the variable delay circuit.

Abstract: A flip-flop for transmitting a scan input and data for scan-testing a semiconductor circuit is provided. The flip-flop includes a first pulse signal generator which generates a first pulse signal in response to a scan enable signal and an inversed scan input signal. A second pulse signal generator generates a second pulse signal in response to the scan enable signal and a scan input signal. A signal transmitter receives a data signal and transmits the data signal to a first node in response to either one of the first and second pulse signals. A signal latch unit receives the data signal transmitted to the first node, and latches and outputs the data signal in response to another one of the first and second pulse signals.

Abstract: A compound logic flip-flop. The flip-flop includes a plurality of input stages, wherein each of the input stages is coupled to receive at least one input signal and a clock signal. Each of the plurality of input (i.e. ‘master’) stages is configured to perform a corresponding input logic function during a first phase of a clock cycle and to store a result of the corresponding input logic function. The flip-flop further includes an output (i.e. ‘slave’) stage coupled to receive the clock signal and the results of the input logic functions from each of the plurality of input stages. The output stage is configured, during a second phase of the clock cycle, to logically combine the results of the input logic functions by performing an output logic function and provide an output signal based on a result of the output logic function.

Abstract: Various types of memory circuits are described. A memory circuit may include a state-storage feedback loop coupled to a clock input and to a data input. The data input is introduced into the feedback loop at multiple points, and propagated in parallel from those points to other points in the feedback loop.

Abstract: A latch circuit for retaining and transmitting an input data value is disclosed, along with a memory, and a method for retaining and transmitting data. The latch circuit includes a primary input for receiving a data value, an output for outputting the data value, a data transmission path including a transmitting device for transmitting the data value from the primary input to the output, a feedback loop for retaining the data value, the feedback loop including the transmitting device and a further device. The further device is configured to turn on in response to assertion of an activating signal and to turn off in response to no assertion of the activating signal.

Abstract: The invention provides a flip-flop. In one embodiment, the flip-flop receives a low swing clock signal, and comprises a first NMOS transistor, a first latch circuit, a second NMOS transistor, and a second latch circuit. The low swing clock signal is inverted to obtain an inverted low swing clock signal. The first NMOS transistor is coupled between a receiving node and a first node, and has a gate coupled to the inverted low swing clock signal. The first latch circuit is coupled between the first node and a second node. The second NMOS transistor is coupled between the second node and a third node. The second latch circuit is coupled between the third node and a fourth node, and generates an output signal on the fourth node.

Abstract: A clock gating cell that comprises a latch in communication with an input enable logic and an output logic circuit, wherein the latch includes a pull-up and/or a pull-down circuit at an input node of the output logic circuit and circuitry preventing premature charge or discharge of the output logic circuit input node by the pull-up and/or the pull-down circuit when the clock gating cell is enabled.

Abstract: A latch circuit includes a feed-forward circuit, a keeper circuit, and a feed-back circuit. The feed-forward circuit includes a first-inverting-stage with a first input and a first output, wherein the first-inverting-stage comprises a first clocked device, and a second-inverting-stage with a second input and a second output, wherein the second-inverting-stage comprises a second clocked device, and a keeper circuit. The first output is operatively connected to the second input. The keeper circuit is operatively connected to the first output, and the keeper circuit is driven from the second output. The feed-back circuit includes a third-inverting-stage with a third input and a third output, wherein the third input is operatively connected to the second output, and a fourth-inverting-stage with a fourth input and a fourth output. The fourth input is operatively connected to the third output. The fourth output is connected to the third input to form a storage node.

Abstract: A clock data recovery circuit. The clock data recovery circuit comprises a transmission line, a phase locked loop, a voltage controlled oscillator, a phase selector, and a D flip-flop. The transmission line receives an input signal. The phase locked loop receives the input signal via the transmission line and a reference clock and generates a first clock signal. The voltage controlled oscillator receives the input signal via the transmission line and a control voltage from an internal node of the phase locked loop, and generates a clock signal. The phase selector receives the input signal via the transmission line and the clock signal from the voltage controlled oscillator, and generates a clock output signal. The D flip-flop receives the input signal via the transmission line and the clock output signal, and generates a data output signal.

Abstract: A method of operating a circuit includes receiving a first data signal at a first node. The first node is coupled to a second node to couple the first data signal to the second node. After coupling the first node to the second node, the second node is coupled to a third node to couple the first data signal to the third node. The first node is decoupled from the second node and a first step of latching the first data signal at the third node is performed, wherein the first step of latching is through the second node while the second node is coupled to the third node. The second node is decoupled from the third node and a second step of latching is performed wherein the first data signal latched at the third node while the second node is decoupled from the third node.

Abstract: Bistable circuit switching at the edges of a clock signal, including means for pre-charging an intermediate node of the circuit, delay means including a chain of inverters defining a time window around an edge of said clock signal, means for discharging the intermediate node controlled by at least one input data item making it possible to discharge the intermediate node for the duration of said time window, characterized in that the delay means include means for temporally adjusting the duration of the time window to the time for discharging the intermediate node through said discharge means.

Abstract: In a semiconductor integrated circuit device using a ZSCCMOS circuit, a combinational circuit includes a plurality of logic gate circuits, and receives an output of a data holding circuit. The data holding circuit can continue to hold data during cut-off of power supply, and when receiving a predetermined value as a control signal, outputs a predetermined fixed value. A logic gate circuit which outputs “L” when the output of the data holding circuit has the predetermined fixed value has power supply ends connected to a pseudo-power supply line VDDV and a low potential power supply line VSS. A logic gate circuit which outputs “H” when the output of the data holding circuit has the predetermined fixed value has power supply ends connected to a high potential power supply line VDD and a pseudo-power supply line VSSV.

Abstract: Latch circuit and clock signal dividing circuit comprises sequentially connected latch circuits. Each latch circuit has D-type latch with latch clock input, data input and data output. A difference detector is coupled to D-type latch, and has a difference output that provides a difference signal when data at input is different than data at output. Each latch circuit has an edge triggered gate that has gate clock input, output coupled to latch clock input and gate control input coupled to difference output of difference detector. In operation, when both a transition of clock signal supplied at gate clock input is detected by edge triggered gate, and the difference signal is provided to gate control input, will edge triggered gate allow an edge of a clock signal supplied at gate clock input to determine logic values supplied to latch clock input. As a result, data at input is transferred to output.

Abstract: A static latch includes a clock-based driver, an actuation circuit, and a weak latched unit. The clock-based driver includes first node, second node, a driving unit, first pass switch, and second pass switch. The driving unit drives the first node corresponding to first voltage in response to first level of an input signal and drives the second node having second voltage in response to second level of the input signal. The first pass switch drives an output node having a latched signal corresponding to the first voltage in response to the clock signal. The second pass switch drives the output node corresponding to the second voltage in response to the inverted clock signal. The actuation circuit drives the output node corresponding to the second voltage in response to the clock signal. The weak latch unit keeps the level of the latched signal when the static latch is disabled.

Abstract: Flip-flop circuits including a dynamic input unit and a control clock generator are provided. The dynamic input unit precharges an evaluation node to a power supply voltage in a first phase of a clock signal, selectively discharges the evaluation node based on input data in a second phase of the clock signal, and compensates for voltage drop of the evaluation node in response to a first control clock signal. The control clock generator generates the first control clock signal and a second control clock signal based on at least the clock signal.

Abstract: A flip-flop device for storing and outputting a data value includes a controllable memory element configured to be open as a function of a control pulse, a feedback means for comparing a data value present at the memory element and the data value output by the memory element, and for outputting a comparison signal, and a control pulse generator for generating the control pulse as a function of the comparison signal, so that the control pulse generator is put in an activated state when the comparison signal is high, so as to then, in the activated state, open the memory element in response to a clock event. The memory element will then be closed again when the comparison signal indicates that the same values are present at the output and at the input of the memory element.

Abstract: A 1/n-rate decision feedback equalizer (DFE) and method include a plurality of branches. Each branch includes a summer circuit configured to add a feedback signal to a received input, and a latch configured to receive an output of the summer circuit in accordance with a clock signal. A feedback circuit includes a multiplexer configured to receive as input, an output of each branch, the multiplexer having a clocked select input and configured to multiplex the output of each branch to assemble a full rate bit sequence, and a filter configured to provide cancellation of intersymbol interference (ISI) from the received input to be provided to the summer circuit of each branch.

Abstract: Apparatuses and methods are provided for a self-timed dynamic sense amplifier flop circuit, wherein a pulse generating circuit may be adapted to generate at least a first logic signal based, at least in part, on a first evaluation node signal, and a discharge path circuit comprising at least a first transistor within a first stack of transistors may be operatively responsive to the first timing signal.

Abstract: It is made possible to provide a flip-flop circuit capable of implementing the error correction function with a small area increase as far as possible and a pipeline system using such a flip-flop circuit. A flip-flop circuit includes: a flip-flop configured to operate based on a rising edge or a falling edge of a first clock signal; a decision circuit configured to compare an input of the flip-flop with an output thereof and output a request signal when the input of the flip-flop is different from the output thereof; and a control circuit configured to receive a second clock signal from outside and generate the first clock signal and a confirmation signal. When the request signal is sent from the decision circuit after the flip-flop has been activated, the control circuit inverts the first clock signal, sends the confirmation to the decision circuit, and makes the decision circuit cancel the request signal.

Abstract: A shift register capable of supplying only a necessary clock signal to a necessary unit register with simple constitution. A semiconductor device is provided with a shift register in which a plurality of stages of unit registers is connected, in which the unit register comprises a flip-flop circuit, a first switch and a second switch, a first clock signal line is electrically connected to the flip-flop circuit through the first switch, a second clock signal line is electrically connected to the flip-flop circuit through the second switch, the first switch is controlled to be on/off by an output signal from the flip-flop circuit, and the second switch is controlled to be on/off by an input signal to the flip-flop circuit.

Abstract: A method is disclosed that includes propagating data via a first data path of a sequential circuit element in response to a clock signal received at a single clocked transistor of the sequential circuit element. The method also includes retaining information related to the data propagated via the first path at a retention circuit element of a second data path, where the first data path includes a first transistor that is responsive to an output of the single clocked transistor. The first transistor has a higher current flow capacity than a second transistor associated with the second data path.

Abstract: A programmable phase frequency divider for space applications is implemented in CMOS technology, and includes a number of radiation hardened D-type flip flops. The radiation hardened D-type flip flop circuits are designed to keep running properly at GHz frequencies in the presence of single event upset (SEU) hits. The novel D-type flip flop circuits each have two pairs of complementary inputs and outputs and each consists of a master latch and a slave latch connected in tandem. The master and slave latches each consist of two latch half circuits having dual complementary inputs and outputs that are mutually interconnected in a dual interlocked cell (DICE) configuration, with the result that the D-type flip flop is immune to an SEU affecting at most one of the flip flop's four dual complementary data inputs.

Abstract: A radiation hardened master latch for use in a programmable phase frequency divider operating at GHz frequencies is implemented in deep submicron CMOS technology, and consists of two identical half circuits interconnected in a DICE-type configuration that makes the master latch immune to a single event upset (SEU) affecting at most one of its four data inputs. Each half circuit includes a clock input circuit with four sub-clock nodes each coupled by an inverter to a common clock input. The clock input circuit is configured to be redundant, such that the operation of the master latch half circuit is also immune to an SEU affecting at most one the inverters associated with the plurality of sub-clock nodes. The radiation hardened master latch resides in a design structure embodied in a machine readable medium storing information for designing, manufacturing and/or testing the master latch.

Abstract: A flip-flop circuit is provided with an improved robustness to radiation induced soft errors. The flip-flop cell comprises the following elements. A transfer unit for receiving at least one data signal and at least one clock signal, a storage unit coupled to the transfer unit and a buffer unit coupled to the storage unit. The transfer unit includes a plurality of input nodes adapted to receive said at least one data signal and said at least one clock signal; a first output node for providing a sampled data signal in response to said at least one clock signal and said at least one data signal; and a second output node for providing a sampled inverse data signal, the sampled inverse data signal provided in response to said at least one clock signal and said at least one data signal. The storage unit comprises a first and a second storage nodes configured to receive and store the sampled data signal and the sampled inverse data signal.

Abstract: In a method and apparatus for data retention, a first latch latches a data input and a second latch that is coupled to the first latch retains the data input while the first latch is inoperative in a standby power mode. The second latch includes a second latch inverter having an inverter input and an inverter output. A switching circuit, which may be implemented as a tristate inverter, is coupled to the inverter output, the inverter input, and a retention signal. The switching circuit is operable in the standby power mode to assert a logic state at the inverter input responsive to the retention signal. The logic state is in accordance with the data input retained in the standby power mode. A standby power source is operable to provide power in the standby power mode to the second latch inverter, the switching circuit and the retention input.

Abstract: In particular embodiments, an apparatus includes a first transistor connected at the gate to a first input signal voltage and a second transistor connected at the gate to a second input signal voltage. The apparatus further includes a deactivation element coupled to the transistors, the deactivation element being operable to deactivate the first and second transistors by selectively transmitting a deactivation current to a first terminal of the first transistor and a second terminal of the second transistor thereby raising a voltage on the first and second terminals to a value large enough to deactivate the first and second transistors. In particular embodiments, activating the first or second transistor transmits a signal from the apparatus and deactivating the first and second transistors prevents the signal from being transmitted from the apparatus.

Abstract: A radiation hardened master latch for use in a programmable phase frequency divider operating at GHz frequencies is implemented in deep submicron CMOS technology, and consists of two identical half circuits interconnected in a DICE-type configuration that makes the master latch immune to a single event upset (SEU) affecting at most one of its four data inputs. Each half circuit includes a clock input circuit with four sub-clock nodes each coupled by an inverter to a common clock input. The clock input circuit is configured to be redundant, such that the operation of the master latch half circuit is also immune to an SEU affecting at most one the inverters associated with the plurality of sub-clock nodes. The radiation hardened master latch resides in a design structure embodied in a machine readable medium storing information for designing, manufacturing and/or testing the master latch.

Abstract: An input circuit comprising a level-determining unit and an output unit is provided. In a first period controlled by a first enable signal, the level-determining unit receives an input signal at an input terminal of the input circuit and determines a voltage level of the input signal. The output unit is coupled to the input terminal. In the first period, the output unit outputs the input signal with the determined voltage level at an output terminal of the input circuit to serve as an output signal. In a second period following the first period, the output unit latches the determined voltage level of the input signal according to a second enable signal and outputs the input signal with the determined voltage level at the output terminal to serve as the output signal.

Abstract: An limited-switch dynamic logic (LSDL) circuit provides reduced power consumption by reducing clock power dissipation. By clocking LSDL gates with a clock signal having a reduced voltage swing in the evaluation phase, the LSDL gates are permitted to operate, while reducing the clock power consumption dramatically. Since clock power consumption dominates in LSDL circuits, the reduction in clock power dissipation results in a significant reduction in overall circuit power consumption. The reduced swing clock is produced at a plurality of local clock buffers by supplying the local clock buffers with an extra power supply rail that is switched onto the clock distribution lines by the local clock buffers in response to the full-swing evaluate phase clock received from the global clock distribution network by the local clock buffers.

Abstract: A flip-flop is provided for minimizing an input-output (D-Q) delay. The flip-flop includes a pull-up unit that receives a signal from a first node, is connected between a power voltage source and a second node, and pulls-up a voltage of the second node. A pull-down unit receives the signal from the first node, is connected between a ground voltage source and the second node, and pulls-down the voltage of the second node. A latch unit is connected to the second node and latches and outputs a signal transferred to the second node. The pull-up unit pulls-up the second node in response to one of a clock signal and a pulse signal, and the pull-down unit pulls-down the second node in response to the other one of the clock signal and the pulse signal.

Abstract: A method and apparatus for a structure of a flip-flop that is tolerant to the noise pulses occurring due to the presence of crosstalk faults by sampling the input data multiple times before and after the active clock edge. The final stored value at the flip-flop is determined by the resolution of a counter circuit residing in the flip-flop, which is activated at the change of the sampled input data. This counter based resolution mechanism allows for the detection and filtering of the noise pulse induced at the input of the flip-flop due to a crosstalk fault.

Abstract: A bistable flip-flop device is provided that is triggered on the edges of a clock signal. The device has an active mode in which it is electrically powered and an inactive mode. The device includes a chain of inverters controlled by a clock signal, storage means for storing the state of the device in the active mode, and retention means for storing the state of the device in the inactive mode. The device includes a continuously-powered bistable structure that integrates the retention means and part of the storage means. The bistable structure includes a single isolation switch connected to the inverter chain and controlled by a standby logic signal that is representative of the active or inactive mode.

Abstract: Disclosed are embodiments of a design structure for a voltage level shifter circuit that operates without forward biasing junction diodes, regardless of the sequence in which different power supplies are powered up. The circuit embodiments incorporate a pair of series connected switches (e.g., transistors) between an input terminal and a voltage adjusting circuit. Each switch is controlled by a different supply voltage from a different power supply. Only when both power supplies are powered-up and the different supply voltages are received at both switches will a first signal generated using one of the supply voltages be passed to a voltage adjusting circuit and thereafter converted into a second signal representative of the first signal, but generated using the second supply voltage. Incorporation of the pair of series connected switches into the voltage level shifter circuit prevents forward biasing of junction diodes in the circuit and thereby prevents current leakage from the power supplies.

Abstract: A method of testing connectivity through a plurality of dual purpose current mode logic (“CML”) latch circuits connected in a series is provided. Each of the CML latch circuits are operable to latch at least one output signal at a timing in accordance with at least one clock signal and having a mode control device for operating the CML latch circuit as a buffer amplifier when the at least one clock signal is inactive. The method comprises the steps of activating the mode control devices of each of the CML latches to operate each of the CML latches as a buffer; inputting a first signal to a first CML latch of the series; latching an output signal of a second CML latch of the series, the second CML latch being connected at a point in the series downstream from the first CML latch; and determining whether the output signal changes in accordance with a change in the first signal.

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: An apparatus comprises a first stage, a second stage, and a switch circuit. The first stage and the second stage are coupled between a first reference voltage and a second reference voltage. The first stage has a first input end for receiving an input signal and a first output end for outputting a first output signal. The second stage has a second input end for receiving the first output signal from the first output end of the first stage and a second output end for outputting a second output signal. The switch circuit is coupled between the second stage and at least one of the first reference voltage and the second reference voltage for receiving a power control signal and for turning on or turning off according to the power control signal such that the current leakage of the second stage is reduced.

Abstract: A latch circuit comprising, a differential input with a non-inverting input (D+) and an inverting input (D?). The latch further comprises a differential output with a non-inverting output (Q+) and an inverting output (Q?). One of the outputs (Q?) is coupled to one of the inputs input (D+) having an opposite polarity. The latch further comprises a control input for receiving a control signal (VcM) for determining a threshold for an input signal (In) such that if the input signal is at larger than the threshold the non-inverting output is in a HIGH logic state and in a LOW state if the input signal is smaller than the threshold.

Abstract: Circuitry for latching receives an input signal and a control signal and provides an output signal. In one embodiment, the setup time (t(SL) and t(SH)) of the input signal with reference to the control signal is to the first edge of the control signal, the holding time (t(HL) and t(HH)) of the input signal with reference to the control signal is independent of the second edge of the control signal, and the output signal goes to a predetermined state in response to the second edge of the control signal. In one embodiment, the control signal may be a clock. The circuitry for latching may be used with static circuits and/or with dynamic circuits.

Abstract: A dynamic flip-flop circuit which outputs an output signal on which a digital data signal is reflected based on a clock, includes: a first control stage configured to output a signal having a level inverted from that of the digital data signal within a period within which the clock has a second level; a second control stage configured to output a signal of a first level within the period within which the clock has the second level and a signal of a level within another period within which the clock has the first level; a third control stage configured to output an output signal of the first level within a period within which the signal outputted from the second control stage has the second level; and a phase adjustment circuit configured to adjust the phase to produce a second clock and supply the second clock to the third control stage.

Abstract: The semiconductor integrated circuit device employs on the same silicon substrate a plurality of kinds of MOS transistors with different magnitudes of tunnel current flowing either between the source and gate or between the drain and gate thereof. These MOS transistors include tunnel-current increased MOS transistors at least one of which is for use in constituting a main circuit of the device. The plurality of kinds of MOS transistors also include tunnel-current reduced or depleted MOS transistors at least one of which is for use with a control circuit. This control circuit is inserted between the main circuit and at least one of the two power supply units.

Abstract: Clock gating circuits are disclosed in the present disclosure. Also disclosed herein are methods for designing clock gating circuits in the early stages of manufacturing. In one embodiment of a method for designing a clock gating circuit, the method comprises providing a schematic layout of a D-type flip-flop, wherein the flip-flop has a reset terminal and two latches. The method further comprises modifying the layout of the flip-flop to create a clock gating circuit.

Abstract: A shift register capable of supplying only a necessary clock signal to a necessary unit register with simple constitution. A semiconductor device is provided with a shift register in which a plurality of stages of unit registers is connected, in which the unit register comprises a flip-flop circuit, a first switch and a second switch, a first clock signal line is electrically connected to the flip-flop circuit through the first switch, a second clock signal line is electrically connected to the flip-flop circuit through the second switch, the first switch is controlled to be on/off by an output signal from the flip-flop circuit, and the second switch is controlled to be on/off by an input signal to the flip-flop circuit.

Abstract: A method for power consumption reduction in a limited-switch dynamic logic (LSDL) circuit provides reduced power consumption by reducing clock power dissipation. By clocking LSDL gates with a clock signal having a reduced voltage swing in the evaluation phase, the LSDL gates are permitted to operate, while reducing the clock power consumption dramatically. Since clock power consumption dominates in LSDL circuits, the reduction in clock power dissipation results in a significant reduction in overall circuit power consumption. The reduced swing clock is produced at a plurality of local clock buffers by supplying the local clock buffers with an extra power supply rail that is switched onto the clock distribution lines by the local clock buffers in response to the full-swing evaluate phase clock received from the global clock distribution network by the local clock buffers.

Abstract: A D flip-flop with a reduced power product or reduced clock line capacitance is disclosed. The flip-flop includes a half-static slave stage or a master stage with clock gating by the input and output. The half-static slave stage an output inverter and a feedback element consisting of a single switching transistor having a gate connected to the output of the flip-flop and the input of the inverter as its load. The clock gating circuit, which may comprise an XNOR gate, reduces the frequency of switching events by permitting clock pulses to pass into the master or slave stage only when the input and output of the flip-flop are at the same logical state.

Abstract: Disclosed is a multi-threshold CMOS (MTCMOS) flip-flop circuit. The MTCMOS flip-flop circuit includes a data input unit including an inverter for receiving an input data signal, inverting the input data signal and then outputting an inverted data signal; a clock signal generator including an inverter for receiving an input clock signal and a logic gate for generating a pulsed clock for latching the inverted data signal at a rising time of the input clock signal; a data transmitting unit including a switch for receiving the data signal output from the data input unit to selectively output the inverted data signal and controlling transmission of data based on the pulsed clock; and a data latch and output unit including a feedback inverter having a feedback path used for data latch so as to receive the inverted data signal and generate an output Q.