Abstract: A flip-flop may include a first master stage for latching data, a second slave stage for latching data, and an input multiplexer circuit receiving, as input, data to be latched in the flip-flop. The multiplexer may have single clock phase. The first master stage may be clocked based upon a clock phase, whereas the second stage may be clocked based upon another clock phase.

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: Systems for displaying images are provided. An embodiment of such a system has a dynamic shift register. The dynamic shift register includes a sampling unit, a holding unit, and a first logic circuit. The sampling unit, which is coupled to an incoming signal and a first input terminal of the dynamic shift register, samples the incoming signal according to a first input signal received by the first input terminal to generate a sampled value. The holding unit, which is coupled to the sampling unit, is utilized to hold the sampled value. The first logic circuit, which is coupled to the holding unit and an output terminal of the dynamic shift register, generates an output signal according to the sampled value and a second input signal inputted into the first logic circuit.

Abstract: A dynamic clock feedback latch includes a feedback path that generates a data value on an output as a function of data inputs in response to a clock input going low and generates a latching value on the output after a delay from the clock input going high. A first transistor pre-charges a node high while the clock input is low. A second transistor provides a drain path for draining the node low from the pre-charged value while the clock input is high. The output controls a third transistor during the delay to drain the node to a low value if the data value is high and to retain the high value if the data value is low. The feedback path generates the predetermined latching value on the output after the delay to cause an inverted value of the data value to be latched onto the node.

Abstract: A semiconductor device includes a flip-flop circuit formed in a CMOS semiconductor integrated circuit. The flip-flop circuit includes at least a first clock generating inverter that generates a first clock signal and a second clock generating inverter that generates a second clock signal obtained by inverting the first clock signal, the first clock generating inverter and the second clock generating inverter are arranged so as to sandwich a latch unit, the latch unit including a master latch unit and a slave latch unit in the flip-flop circuit, the first clock generating inverter and a first other circuit in the flip-flop circuit are configured to share a source region, the first other circuit being adjacent to the first clock generating inverter, and the second clock generating inverter and a second other circuit in the flip-flop circuit are configured to share a source region, the second other circuit being adjacent to the second clock generating inverter.

Abstract: A system and method for improving the performance and efficiency of multi-clock-domain data transmission interfaces. The data transmission interface may include a modified slave latch which includes one or more clock splitters and one or more transmission gates may be used. By having such a configuration, space requirements are reduced and a reduction of the number of devices necessary for a multi-domain interface may be realized. The configuration may further allow for independent cycle stealing of N:1 and N:2 logical paths, thus allowing for timing resolution solutions that use fewer devices versus implementations that require the tuning of each individual bit in the cross-clock-domain interface. By implementing such a data transmission interface, space and power requirements may be reduced and timing criticalities may be more easily managed.

Abstract: An apparatus includes a first selector which selects a test data during a first operation mode, and selects a first input data during a second operation mode, a first latch circuit which latches an output signal of the first selector according to a first clock signal, a second selector which selects one from a second input data and an output signal of the first latch circuit, and a second latch circuit which latches the second input data sent from the second selector according to a second clock signal during the second operation mode, and passes through the output signal of the first latch circuit sent from the second selector during the first operation mode.

Abstract: Configurable time-borrowing flip-flops may be based on configurable pulse generation circuitry and pulse latches. The circuitry may use a self-timed architecture that controls the width of clock pulses that are generated so that the pulse latches that are controlled by the clock pulses exhibit a reduced risk of race through conditions. Latch circuitry may be provided that is based on a pulse latch and an additional latch connected in series with the pulse latch. In situations in which there is a potential for race through conditions on an integrated circuit, the additional latch may be switched into use to convert the latch circuitry into an edge-triggered flip flop. Clock trees may be provide with configurable shorting structures that help to reduce clock skew. Low-contention clock drivers may drive signals onto the clock tree paths.

Abstract: A flip-flop circuit having low power consumption includes a sensing circuit, and a clock generating circuit. The flip-flop is leading edge triggered and operates on an internally generated pseudo clock signal. The sensing circuit senses a change in an input signal and an output signal of the flip-flop. The clock generating circuit generates a pseudo clock signal with a sharp rise and fall based upon an external clock signal.

Abstract: A high frequency divider involves a plurality of differential latches. Each latch includes a pair of cross-coupled P-channel transistors and a variable resistance element. The latch is controlled to have a lower output resistance at high operating frequencies by setting a multi-bit digital control value supplied to the variable resistance element. Controlling the latch to have a reduced output resistance at high frequencies allows the 3 dB bandwidth of the latch to be maintained over a wide operating frequency range. The variable resistance element is disposed between the two differential output nodes of the latch such that appreciable DC bias current does not flow across the variable resistance element. As a consequence, good output signal voltage swing is maintained at high frequencies, and divider current consumption does not increase appreciably at high frequencies as compared to output signal swing degradation and current consumption increases in a conventional differential latch divider.

Abstract: A first frequency dividing circuit and a second frequency dividing circuit are provided, and these circuits frequency-divide two-phase external clocks injected from an external part, to output four-phase clocks with phase guarantee. Each of the frequency dividing circuits includes a mixer, an adding circuit, and a phase circuit. The first frequency dividing circuit and the second frequency dividing circuit are coupled in loop shape via a first coupling circuit and a second coupling circuit. The first coupling circuit receives a first output signal of the first frequency dividing circuit to output a second external input signal to the second frequency dividing circuit, and the second coupling circuit receives a second output signal of the second frequency dividing circuit to output a first external input signal to the first frequency dividing circuit, and a clock frequency dividing circuit with a high loop gain and a wide lock range can be realized.

Abstract: Example embodiments relate to an electronic circuit, for example, a flip-flop circuit, a pipeline circuit including the flip-flop circuit and a method for operating the flip-flop circuit. A flip-flop circuit may include a precharge transistor configured to precharge an internal node to a first power supply voltage in response to a clock signal, a first pull-down unit configured to pull down a voltage of the internal node to a second power supply voltage, a pull-up transistor configured to pull up a voltage of an output node to the first power supply voltage in response to the voltage of the internal node, and a second pull-down unit configured to pull down the voltage of the output node to the second power supply voltage. The pipeline circuit may include a pulse generating circuit, a first flip-flop group, a combination logic circuit, and a second flip-flop group.

Abstract: A synchronizer circuit includes a master stage and a slave stage. The master stage may include a first master latch coupled to receive a data input signal, and a clock signal. The master stage may also include a second master latch coupled to receive the data input signal, and a delayed version of the clock signal. The master stage may further include a pull-up circuit that may drive an output line of the master stage depending upon an output of each of the first master latch and the second master latch. The slave stage may include a slave latch having an input coupled to the output line of the master stage. The slave stage may provide an output data signal that corresponds to the captured input data signal and is synchronized to the receiving clock signal.

Abstract: A frequency divider includes a transmission gate, a first inverter, a first switch circuit, a second switch circuit, and a second inverter. The transmission gate transmits a clock signal according to an inverted enable signal. The first inverter inverts the clock signal outputted from the transmission gate. The first switch circuit generates a first control signal according to the inverted clock signal and an output signal of the frequency divider. The second switch circuit generates a second control signal according to the clock signal, the inverted clock signal, and the first control signal. The second inverter inverts the second control signal to generate the output signal. The frequency of the clock signal is a multiple of the frequency of the output signal.

Abstract: It is an object to suppress deterioration in characteristics of a transistor in a driver cricuit. A driver circuit includes a first transistor, a second transistor including a gate and one of a source and a drain to which a second signal is inputted, a third transistor whose gate is electrically connected to one of a source and a drain of the first transistor and which controls whether a voltage state of an output signal is set or not by being turned on/off, and a fourth transistor whose gate is electrically connected to the other of the source and the drain of the second transistor and which controls whether a voltage state of an output signal is set or not by being turned on/off.

Abstract: A circuit has first latch, a second latch, a coupling circuit, and a power down circuit. The first latch has an input/output coupled to a data node. The second latch has an input/output. The coupling circuit is coupled between the input/output of the second latch and the data node. The coupling circuit is enabled during a normal operation of the circuit and disabled during a power down mode of the circuit. The power down control circuit is for disabling the first latch during the power down mode and for a time period after a transition from the power down mode to the normal operation. This allows the second latch to set the state of the first latch when transitioning from the power down mode to the normal mode. Thus normal operation can be fast, and the power down mode can have low leakage current.

Abstract: There is provided a semiconductor device having: a latch circuit (103, 104) having a plurality of data holding nodes; a first capacitance element (C) connected to the first data holding node (A) included in the plurality of data holding nodes; and a first switch element (SW2) provided between the first data holding node (A) and the first capacitance element (C).

Abstract: A system and method for reducing power consumption within a flip-flop circuit on a semiconductor chip. A gated input clock signal is received by a slave latch. The gated input clock is derived from an ungated input clock signal and a clock gating condition. The clock gating condition determines when an input data signal of the flip-flop and the stored internal state of the slave latch have the same logic value, such as only a logic low value. If they have the same value, toggling of the ungated input clock signal is not received by the slave latch, signal switching of internal nodes of the slave latch is reduced, and power consumption is reduced.

Abstract: A system for storing state values during standby mode operation comprises a master flip flop that receives and stores state information during active mode operation and an associated slave flip flop that receives and stores state information during active mode and standby mode operation. The system further comprises a standby mode control circuit to control the state of the master and slave flip flops during active and standby mode operation based on at least two control signals. A first transfer gate determines the current flow to and from the master flip flop based on the output of the standby mode control circuit. Similarly, a second transfer gate determines current flow to and from the slave flip flop based on the output of the standby mode control circuit. A first power supply powers the master flip flop during active mode operation.

Abstract: A DFLOP circuit for an EAIC system includes a resolver. The resolver includes a signal transmission controller that is activated under the control of an internal clock signal to receive and transmit an input signal, and a precharge unit that is activated in response to the internal clock signal to precharge an output node of the signal transmission controller.

Abstract: A buffer circuit having an input terminal and an output terminal comprises a first inverter having an input node coupled to the input terminal and an output node coupled to the output terminal, a second inverter having an input node coupled to a reference voltage and an output node, a third inverter having an input node coupled to the output terminal and an output node coupled to the output node of the second inverter, a fourth inverter having an input node coupled to the output node of the second inverter and an output node coupled to the output terminal, a fifth inverter having an input node and an output node coupled to the output terminal, a sixth inverter having an input node and an output node coupled to the output node of the second inverter, a first resistive element is coupled between the output terminal and the input node of the fifth inverter, and a second resistive element is coupled between the output node of the second inverter and the input node of the sixth inverter.

Abstract: A flip-flop circuit with an internal level shifter includes an input stage, a clock input stage, an output stage and a level shifting stage. The output stage generates an output signal based on an input signal received by the input stage and a clock signal received by the clock input stage. The level shifting stage shifts-up the voltage level of the output signal.

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 semiconductor integrated circuit comprises: a latch circuit constituted with a drive inverter and a feedback inverter so as to be connected in a cyclic form, wherein at least one of the drive inverter and the feedback inverter comprises a MOS transistor; and a current source connected to at least one of latch nodes of the latch unit. The magnitude relation of electric current flown in the MOS transistor and electric current flown in the current source is judged based on presence or absence of inversions in data values latched in the latch node.

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 double-triggered logic circuit is a composite circuitry consisting of a plurality of PMOS, NMOS, inverters and a signal line. It includes an AND logic circuit and a XNOR logic circuit to generate an adjustable pulse mode to solve the problem of threshold voltage loss.

Abstract: “An active-load dominant circuit for common-mode glitch interference cancellation, biased between a first voltage potential and a second voltage potential with an accompanying common-mode glitch interferer. The active-load dominant circuit includes a pair of pull-up networks and a pair of active-load networks. The common-mode glitch interferer is cancelled out due to a symmetric structure of the pair of pull-up networks. At least one set signal and at least one reset signal are provided to a latch in response to a clock signal or a complemented clock signal. At least one of the set signal and the reset signal can be pulled up to the first voltage potential or pulled down to the second voltage potential. The voltage difference of the set signal and the reset signal is large enough for a latch.

Abstract: A frequency divider has an inverting unit and a plurality of switch inverters in series. Each switch inverter comprises two inphase switches and is controlled by a clock. The two inphase switches of each switch inverter are respectively supplied by a first voltage and a second voltage, while any two switch inverters in series are respectively controlled by two inverted clocks. The two inphase switches are selectively turned on and off synchronously.

Abstract: Various systems and methods for comparing signals are disclosed herein. For example, some embodiments of the present invention provide comparator circuits with a preamplifier circuit, a latch circuit and a current re-use circuit. The current re-use circuit applies a current to the preamplifier circuit during a transparent phase, and applies a similar current to the latch circuit during a latch phase.

Abstract: State storage circuitry is described comprising a master-slave latch having tristate inverter circuitry 2 at its functional input and tristate scan signal insertion circuitry 12 for inserting scan data. The tristate scan signal insertion circuitry 12 is controlled by a first clock signal nclk and a second clock signal bclk. The tristate inverter circuitry 2 is controlled by a third clock signal nfclk and a fourth clock signal flck. The clock generating circuitry holds the third and fourth clock signals at fixed values which tristate the tristate inverter circuitry 2 when in scan mode. This moves scan control logic out of the function path comprising the tristate inverter circuitry into the clock control circuitry.

Abstract: A method of testing a tristate element by applying a given value to the tristate, applying an opposite value to a keeper element connected at an output of the tristate, capturing a first value at a downstream position of the tristate, evaluating a second value at the output of the tristate using the first value, comparing the second value to the opposite value, and producing a failure code for the tristate when the second value is not equal to the opposite value. Then, applying the opposite value to the tristate, applying the given value to the keeper element, capturing the first value, evaluating the second value using the first value, comparing the second value to the given value, and producing a failure code for the tristate when the second value is not equal to the given value. A passing code for the tristate is produced when a failure code has not been produced.

Abstract: A dual edge triggered flip flop can pass data values on a clock rising or falling edge. The dual edge triggered flip flop can be operated at half the clock speed of a single edge triggered flip flop and produce substantially the same throughput. The dual edge triggered flip flop may use less power than a single edge triggered flip flop due at least in part to the construction of an intermediate gate as a data interlock gate. The dual edge triggered flip flop may contain a plurality of master nodes, and is soft error hardened compared to a single edge triggered flip flop.

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: A scan flip-flop circuit including a data input, a scan input, a data output, a flip-flop, a multiplexer and a delay element is provided. The multiplexer allows selection of either the scan input or the data input for presentation at the input of the flip-flop. The flip-flop provides an output signal at the output of the scan flip-flop. The delay element is in a signal path between the scan input and the input of the flip-flop, and provides a signal propagation delay between the scan input and the input of the flip-flop. The delay between the scan input and the input of the flip-flop is substantially larger than the signal propagation delay between the data input and the input of the flip-flop. The delay in the scan path reduces the need for external buffers to avoid hold-time violations during scan testing of integrated circuits.

Abstract: A latch circuit (1) comprising a first input device (10a) in a first branch (4a) and a second input device (10b) in a second branch (4b). The latch circuit comprises a first estimator unit (40a) adapted to generate a first estimate of a current generated by the first input device (10a) and a second estimator unit (40b) adapted to generate a second estimate of a current generated by the second input device (10b). The latch circuit further comprises a control-voltage unit (50) operatively connected to the first and the second estimator unit (40a, 40b). The control-voltage unit is adapted to generate a control voltage based on a sum of the first estimate and the second estimate. Further, the latch circuit (1) comprises a first and a second voltage-controlled current unit (30a, 30b) adapted to generate currents at least based on the control voltage. The first voltage-controlled current unit (30a) is operatively connected to the first branch (4a).

Abstract: A disclosed embodiment is a data retention flip flop comprising master and slave circuits that are configured to be turned off when a single sleep mode signal is activated. The disclosed embodiment also comprises an always-on balloon circuit coupled to the master circuit, where the always-on balloon circuit includes a common sub-circuit shared with the master circuit. The master circuit writes into the always-on balloon circuit when the single sleep mode signal is activated, and the master circuit reads from the always-on balloon circuit when the single sleep mode signal is deactivated. The always-on balloon circuits comprises high threshold voltage transistors, while the slave circuit comprises low threshold voltage transistors. The master and slave circuits have no leakage current, or substantially no leakage current, after the single sleep mode signal is activated.

Abstract: In a method and system for data retention, a data input is latched by a first latch. A second latch coupled to the first latch receives the data input for retention while the first latch is inoperative in a standby power mode. The first latch receives power from a first power line that is switched off during the standby power mode. The second latch receives power from a second power line. A controller receives a clock input and a retention signal and provides a clock output to the first latch and the second latch. A change in the retention signal is indicative of a transition to the standby power mode. The controller continues to hold the clock output at a predefined voltage level and the second latch continues to receive power from the second power line in the standby power mode, thereby retaining the data input.

Abstract: An edge triggered flip-flop including at least one inverter and at least one transmission gate section. Each transmission gate section includes an upper part having a first transmission gate and a second transmission gate connected in series, the first transmission gate being controlled in accordance with a clock signal, and the second transmission gate being controlled in accordance with an enable clock signal. Each transmission gate section also includes a lower part having a third transmission gate and a fourth transmission gate connected in series, the third transmission gate being controlled complementarily to the first transmission gate in accordance with the clock signal, and the fourth transmission gate being controlled complementarily to the second transmission gate in accordance with the enable clock signal.

Abstract: In general, in one aspect, the disclosure describes an apparatus comprising a low leakage latch to store a state of a circuit during inactive periods. The state is transferred to the low leakage latch upon receipt of an inactive pulse. A buffer is used to receive the state from an output of the low leakage latch and to isolate the state. State restore circuitry is used to restore the state to the circuit when the circuit returns to an active mode. The state restore circuitry is used to receive the isolated state and to restore the state upon receipt of an active pulse.

Abstract: The present invention includes a radiation hardened sequential circuit, such as a bistable circuit, flip-flop or other suitable design that presents substantial immunity to ionizing radiation while simultaneously maintaining a low operating voltage. In one embodiment, the circuit includes a plurality of logic elements that operate on relatively low voltage, and a master and slave latches each having storage elements that operate on a relatively high voltage.

Abstract: A circuit having a local power block for leakage reduction is disclosed. The circuit has a first portion and a second portion. The first portion is configured to operate at a substantially greater operating frequency than the operating frequency of the second portion. The second portion has a local power block configured to decouple the second portion if the second portion is inactive to reduce leakage current associated with the second portion without sacrificing performance of the first portion.

Abstract: A system and method for reducing power consumption within a flip-flop circuit on a semiconductor chip. A gated input clock signal is received by a slave latch. The gated input clock is derived from an ungated input clock signal and a clock gating condition. The clock gating condition determines when an input data signal of the flip-flop and the stored internal state of the slave latch have the same logic value, such as only a logic low value. If they have the same value, toggling of the ungated input clock signal is not received by the slave latch, signal switching of internal nodes of the slave latch is reduced, and power consumption is reduced.

Abstract: A flip-flop has a first latch and a second latch. The first latch has a first feedback circuit and a first selecting circuit which selects one of a first data input signal and an output signal of the first feedback circuit, based on the logic level of a first clock signal. The second latch has a second feedback circuit and a second selecting circuit which selects an output signal of the first latch and an output signal of the second feedback circuit based on the inverted logic level in case of the first latch. The first feedback circuit has a third selecting circuit which selects one of an output signal of the first latch and a second data input signal based on the logic level of a second clock signal, and outputs a signal selected by the third selecting circuit to the first selecting circuit.

Abstract: Provided is a low-power clock gating circuit using a Multi-Threshold CMOS (MTCMOS) technique. The low-power clock gating circuit includes a latch circuit of an input stage and an AND gate circuit of an output stage, in which power consumption caused by leakage current in the clock gating circuit is reduced in a sleep mode, and supply of a clock to a unused device of a targeted logic circuit is prevented by the control of a clock enable signal in an active mode, thereby reducing power consumption. The low-power clock gating circuit using an MTCMOS technique uses devices having a low threshold voltage and devices having a high threshold voltage, which makes it possible to implement a high-speed, low-power circuit, unlike a conventional clock gating circuit using a single threshold voltage.

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: A circuit has a master latch having an input for receiving an input data signal, and an output. A slave latch has a first input coupled to the output of the master latch, and an output for providing an output data signal. A non-volatile storage element stores a predetermined value. The non-volatile storage element has an output coupled to the first input of the slave latch. The output data signal corresponds to one of either the input data signal or the predetermined value stored by the non-volatile storage element in response to a control signal.

Abstract: An edge triggered system is provided having a data and scan input includes a latch device having a clock input and an AND gate, coupled to the latch device, structured and arranged to receive a first clock signal and an inverted clock signal to generate a clock to the clock input. A process for operating an edge triggered system having a data and scan input includes forwarding a first clock signal to an input of an AND gate. The method includes inverting a second clock signal forwarded to another input of the AND gate and generating a clock input for a latch device from the AND gate.

Abstract: An integrated circuit (500) includes an array of standard cells including at least a first and a second standard cell (501-504). At least one device in the first standard cell is directly coupled to at least one device in the second standard cell by a gate electrode layer (515) of the integrated circuit. The array of standard cells can implement flip-flops which significantly decrease the switching capacitance.

Abstract: A storage device and methods thereof are disclosed. The device includes a clock control module and a latch. During normal operation, the clock control module provides a periodic clock signal to a clock input of the latch, allowing the latch to operate normally. In a low power mode of operation, the clock control module provides a constant signal to the clock input of the latch so that the latch retains stored data during the low power mode of operation. The storage device can also include a power control module that provides a first power level to the latch in the normal mode of operation and a second power level during the second mode of operation.

Abstract: The present invention improves a frequency divider circuit so that the frequency divider further obtains a capability of operating an injection-locking frequency division without changing or adding any component; and, the frequency divider operates under low voltage and low power consumption yet in high frequency, where the present invention can be use in related fields of radio frequency and optoelectronic communication.