| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 327215000 | Having at least two cross-coupling paths | 50 |
| 20100109733 | Analog Comparators in a Control System - An apparatus is disclosed that includes first and second circuits coupled together via a bus, an input pin configured to receive an analog input signal, a digital-to-analog (DAC) convertor configured to convert a multibit reference signal into an analog reference signal, a comparator circuit coupled to the bus, an output of the DAC and to the input pin. The comparator circuit is configured to receive the analog reference signal from the DAC and the analog input signal, and configured to generate a first digital signal set to a first state if the analog reference signal is greater in magnitude than the analog input signal, or set to a second state if analog reference signal is lower in magnitude than the analog input signal. The comparator circuit is also configured to transmit the first digital signal to the first circuit via the bus. The first circuit in turn is configured to receive the first digital signal. In response to receiving the first digital signal, the first circuit is configured to generate a second digital signal set to the first or second state depending on whether the received first digital signal is set to the first or second state. The second circuit is configured to receive the second digital signal from the first circuit via the bus. | 05-06-2010 |
| 20110121878 | NONVOLATILE LATCH CIRCUIT AND LOGIC CIRCUIT, AND SEMICONDUCTOR DEVICE USING THE SAME - To provide a novel nonvolatile latch circuit and a semiconductor device using the nonvolatile latch circuit, a nonvolatile latch circuit includes a latch portion having a loop structure where an output of a first element is electrically connected to an input of a second element, and an output of the second element is electrically connected to an input of the first element; and a data holding portion for holding data of the latch portion. In the data holding portion, a transistor using an oxide semiconductor as a semiconductor material for forming a channel formation region is used as a switching element. In addition, an inverter electrically connected to a source electrode or a drain electrode of the transistor is included. With the transistor, data held in the latch portion can be written into a gate capacitor of the inverter or a capacitor which is separately provided. | 05-26-2011 |
| 20110133806 | INTEGRATED CLOCK GATING CELL FOR CIRCUITS WITH DOUBLE EDGE TRIGGERED FLIP-FLOPS - A double edge triggered circuit includes a clock gater responsive to a clock signal and an enable signal to output a gated clock signal, a first double edge triggered flip-flop that launches a data signal in response to the gated clock signal, and a second double edge triggered flip-flop that captures the data signal in response to the clock signal, wherein the clock gater stops the gated clock signal at a first logic value when the enable signal is at a first logic state, and the clock gater switches the gated clock signal from the first logic value at a next clock edge when the enable signal is at a second logic state. | 06-09-2011 |
| 20110181331 | INTEGRATED CIRCUIT WITH LEAKAGE REDUCTION IN STATIC NETS - A method for reducing leakage current of a delay line on a static net is provided. The static net provides a signal communication path between a data output of a first flip-flop and a data input of a second flip-flop via the delay line. The delay line is designed using standard cells but the standard cells are selected based on leakage power consumption in order to reduce the leakage power consumption of the delay line. | 07-28-2011 |
| 20120154009 | LATCH CIRCUITRY - A latch circuit comprises: a cross latch having a first node and a second node, a first transistor, a second transistor, a third transistor, a first current source, and a second current source. A third terminal of the first transistor and of the second transistor receives a first input signal and a second input signal, respectively. A first terminal of the first transistor and of the second transistor is coupled to the first node and the second node, respectively. A first terminal of the third transistor is coupled to the second terminal of the first transistor and of the second transistor. The first current source is coupled to the first node and affects a transition of a first output signal. The second current source is coupled to the second node and affects a transition of a second output signal. | 06-21-2012 |
| 20120206182 | Low-Clock-Energy, Fully-Static Latch Circuit - One embodiment of the present invention sets forth a technique for capturing and holding a level of an input signal using a low-clock-energy latch circuit that is fully static. The clock is only coupled to a first clock-activated pull-up or pull-down transistor and a second clock-activated pull-down or pull-up transistor. The level of the input signal is captured by a storage sub-circuit on one of the rising or the falling clock edge and stored to generate an output signal until the clock transitions. The level of the input signal is propagated to the output signal when the storage sub-circuit is not enabled. The storage sub-circuit is enabled and disabled by the first clock-activated transistor and a propagation sub-circuit is activated and deactivated by the second clock-activated transistor. | 08-16-2012 |
| 20130076421 | ELECTRONIC CIRCUIT AND METHOD FOR STATE RETENTION POWER GATING - A method and a electronic circuit, the method includes: sending to a switching circuit, to a state retention power gating (SRPG) circuit and to a first power source a control signal indicating that the SRPG circuit should operate in a functional mode; coupling, by the switching circuit, a third power grid to a first power grid; supplying power from the first power source to the SRPG circuit via the first power grid, the switching circuit and the third power grid; supplying power from a second power source to a second circuit via a second power grid; sending to the switching circuit, to the SRPG circuit and to the first power source a control signal indicating that the SRPG circuit should operate in a state retention mode; coupling, by the switching circuit, the third power grid to the second power grid; supplying power from the second power source to the SRPG circuit via the second power grid, the switching circuit and the third power grid; supplying power from the second power source to the second circuit via the second power grid; and storing, by the SRPG state information. | 03-28-2013 |
| 20130214839 | SINGLE-TRIGGER LOW-ENERGY FLIP-FLOP CIRCUIT - One embodiment of the present invention sets forth a technique for technique for capturing and storing a level of an input signal using a single-trigger low-energy flip-flop circuit that is fully-static and insensitive to fabrication process variations. The single-trigger low-energy flip-flop circuit presents only three transistor gate loads to the clock signal and none of the internal nodes toggle when the input signal remains constant. The output signal Q is set or reset at the rising clock edge using a single-trigger sub-circuit. A set or reset may be armed while the clock signal is low, and the set or reset is triggered at the rising edge of the clock. | 08-22-2013 |
| 20130234771 | PHYSICAL UNCLONABLE FUNCTION - A physical unclonable function is provided | 09-12-2013 |
| 20130293274 | BIT GENERATION APPARATUS AND BIT GENERATION METHOD - A bit generation apparatus includes a glitch generation circuit that generates glitch signals which include a plurality of pulses, and T-FF bit generation circuits which input the glitch signals, and based on either rising edges or falling edges of the plurality of pulses included in the glitch signals, generate a bit value of either 0 or 1. Each of the T-FF bit generation circuits generates a respective bit value based on either the parity of the number of rising edges or the parity of the number of falling edges of the plurality of pulses. As a result of employment of the T-FF bit generation circuits, circuits that are conventionally required but not essential for the glitch become unnecessary. This serves to prevent expansion in circuit scale and increase in processing time of bit generation for the bit generation circuit. | 11-07-2013 |
| 20140111263 | SHIFTER CAN AVOID UTILIZING PARTIAL PULSE - A shifter that can avoid utilizing a partial pulse, comprising: at least one shifting stage, for receiving an external clock signal or a command triggering clock signal to generate sampling signals according a command signal; and a command triggering clock signal generating circuit, for generating the command triggering clock signal according to the command signal. The shifting stage utilizes the external clock signal to generate the sampling signal but does not utilize the command triggering clock signal to generate the sampling signal, if the command triggering clock signal may have a partial pulse for a cycle that the shifting stage generates the sampling signal. | 04-24-2014 |
| 20140203857 | VARIABLE DELAY AND SETUP TIME FLIP-FLOP - An apparatus is provided. The apparatus includes a flip-flop including an input configured to receive a setup time and delay control (SDC) signal, and an output buffer including first and second conductive paths. The second conductive path is non-conductive when the SDC signal has a first value at the input and is conductive when the SDC signal has a second value at the input. The apparatus includes a propagation delay sensor configured to estimate a propagation delay of the flip-flop, and, when the estimated propagation delay exceeds a threshold, supply the SDC signal having the second value to the input of the flip-flop. | 07-24-2014 |
| 20140240019 | CURRENT MODE LOGIC LATCH - A current mode logic latch may include a sample stage and a hold stage, the hold stage comprising first and second stage transistors, first and second hold stage current sources, and a hold stage switch. The first hold stage transistor may be coupled at its drain terminal to the drain terminal of a first sample stage transistor. | 08-28-2014 |
| 20150022251 | NONVOLATILE LATCH CIRCUIT AND LOGIC CIRCUIT, AND SEMICONDUCTOR DEVICE USING THE SAME - To provide a novel nonvolatile latch circuit and a semiconductor device using the nonvolatile latch circuit, a nonvolatile latch circuit includes a latch portion having a loop structure where an output of a first element is electrically connected to an input of a second element, and an output of the second element is electrically connected to an input of the first element; and a data holding portion for holding data of the latch portion. In the data holding portion, a transistor using an oxide semiconductor as a semiconductor material for forming a channel formation region is used as a switching element. In addition, an inverter electrically connected to a source electrode or a drain electrode of the transistor is included. With the transistor, data held in the latch portion can be written into a gate capacitor of the inverter or a capacitor which is separately provided. | 01-22-2015 |
| 20150145577 | INTEGRATED CLOCK GATER (ICG) USING CLOCK CASCODE COMPLIMENTARY SWITCH LOGIC - Inventive aspects include an integrated clock gater (ICG) circuit having clocked complimentary voltage switched logic (CICG) that delivers high performance while maintaining low power consumption characteristics. The CICG circuit provides a small enable setup time and a small clock-to-enabled-clock delay. A significant reduction in clock power consumption is achieved in both enabled and disabled modes, but particularly in the disabled mode. Complimentary latches work in tandem to latch different voltage levels at different nodes depending on the voltage level of the received clock signal and whether or not an enable signal is asserted. An inverter takes the voltage level from one of the nodes, inverts it, and outputs a gated clock signal. The gated clock signal may be active or quiescent depending on the various voltage levels. Time is “borrowed” from an evaluation window and added to a setup time to provide greater tolerances for receiving the enable signal. | 05-28-2015 |
| 20160164502 | SYSTEM AND METHOD FOR REDUCING METASTABILITY IN CMOS FLIP-FLOPS - A circuit and method for reducing metastability of a CMOS SR flip flop is provided. The circuit comprises a first switching module and a second switching module that are operatively coupled to a first and second output terminal of the CMOS SR flip-flop. The method includes injecting current onto the first and second output terminals of the CMOS SR flip-flop at mutually opposite directions during permissible mid-range voltages of the output terminals. Further, the method includes driving the output terminals of the CMOS SR flip-flop into the predetermined state of zero and predetermined stable state of Vdd by utilizing the currents injected onto the output terminals. As a result, the metastable point of the CMOS flip-flop is diverted from the corresponding metastable voltage and thereby reduces the metastability of the CMOS SR flip-flop. | 06-09-2016 |
| 327217000 | RS or RST type input | 1 |
| 20090174453 | System and Method of Conditional Control of Latch Circuit Devices - A circuit device includes a first input to receive a reset control signal and a second input coupled to an output of a latch. The circuit device also includes a logic circuit adapted to conditionally reset the latch based on a state of the output in response to receiving the reset control signal. | 07-09-2009 |
| 327218000 | D type input | 31 |
| 20080258790 | Systems and Devices for Sub-threshold Data Capture - Various systems and methods for capturing data are disclosed. For example, some embodiments of the present invention provide differential jam latches. Such differential jam latches include a data input, a latch input, and an output. Further, such differential jam latches include a PMOS stage and an NMOS stage. The PMOS stage includes a first PMOS transistor, a second PMOS transistor, a third PMOS transistor and a fourth PMOS transistor. The gate of the first PMOS transistor and the gate of the second PMOS transistor are electrically coupled to an inverted version of the latch input. The gate of the third PMOS transistor is electrically coupled to the data input, and the gate of the fourth PMOS transistor is electrically coupled to an inverted version of the data input. The NMOS stage includes a first NMOS transistor, a second NMOS transistor, a third NMOS transistor and a fourth NMOS transistor. The gate of the first NMOS transistor and the gate of the second NMOS transistor are electrically coupled to the latch input. The gate of the third NMOS transistor is electrically coupled to the data input, and the gate of the fourth NMOS transistor is electrically coupled to an inverted version of the data input. In addition, the jam latches include two inverters. The PMOS stage is electrically coupled to a first node and a second node, and the NMOS stage is electrically coupled to the first node and the second node. The first inverter drives an inverted version of the signal on the first node to the second node, and the second inverter drives an inverted version of the signal on the second node to the first node. | 10-23-2008 |
| 20090033394 | Data retention in operational and sleep modes - A circuit is disclosed for retaining a signal value during a sleep mode while a portion of said circuit is powered down comprising: a clock signal input operable to receive a clock signal; at least one latch clocked by said clock signal; a data input, a data output and a forward data path therebetween, wherein a signal value is operable to be received at said data input, is clocked through said at least one latch and passes to said data output along said forward data path; at least one of said at least one latch comprises a retention latch operable to retain a signal value during said sleep mode, said retention latch not being located on said forward data path; and a tristateable device, said tristateable device being arranged between said forward data path and said retention latch and being operable to selectively isolate said retention latch from said forward data path in response to receipt of a first sleep signal; wherein in response to receipt of a second sleep signal, said second sleep signal being received after said first sleep signal, said circuit is operable to enter said sleep mode such that a voltage difference across said portion of said circuit is reduced such that said portion of said circuit is powered down, and a voltage difference across said retention latch and said tristateable device is maintained. | 02-05-2009 |
| 20090085629 | DUAL EDGE TRIGGERED FLIP FLOPS - An implicitly pulsed dual edge triggered pulsed latch. The implicitly pulsed latch includes an overlapping clock generator and a transparency circuit designed to cause a transparent latch circuit to become transparent on each edge of a clock signal. A logic value on the input node of the latch is transferred to the output node of the latch in response to each clock edge transition. An explicitly pulsed dual edge triggered pulsed latch including a pulse generator and a transparent latch circuit. The explicitly pulsed latch includes a symmetrical pulse generator designed to cause the latch circuit to pass a logic value from the input node of the latch to the output node of the latch in response to a pulse on the clock node. | 04-02-2009 |
| 20090115482 | STORAGE ELEMENTS USING NANOTUBE SWITCHING ELEMENTS - Data storage circuits and components of such circuits constructed using nanotube switching elements. The storage circuits may be stand-alone devices or cells incorporated into other devices or circuits. The data storage circuits include or can be used in latches, master-slave flip-flops, digital logic circuits, memory devices and other circuits. In one aspect of the invention, a master-slave flip-flop is constructed using one or more nanotube switching element-based storage devices. The master storage element or the slave storage element or both may be constructed using nanotube switching elements, for example, using two nanotube switching element-based inverters. The storage elements may be volatile or non-volatile. An equilibration device is provided for protecting the stored data from fluctuations on the inputs. Input buffers and output buffers for data storage circuits of the invention may also be constructed using nanotube switching elements. | 05-07-2009 |
| 20090184744 | DRIVING CONFIGURATION OF A SWITCH - A driving circuit of a switch includes first and second transistors connected in series to each other and to relative intrinsic diodes in antiseries and driven by a driving device that includes at least one first and one second output terminal connected to the switch to supply it with a first control signal for driving the switch in a first working state and a second control signal for driving the switch in a second working state. At least one latch circuit coupled between respective common gate and source terminals of the first and second transistors supplies the common gate terminal with the first and second control signals, respectively, according to the working state to turn off and turn on the first and second transistors. The latch circuit comprises at least one flip-flop coupled to the common source terminal and having a reset terminal coupled to the first output terminal of the driving device and to the common source terminal by means of a reset resistance, a set terminal coupled to the second output terminal of the driving device and to the common source terminal by means of a set resistance and an output terminal coupled to the common gate terminal. The latch circuit further includes an activation circuit connected to the set and reset terminals of the flip-flop and to the common source terminal in order to dynamically short-circuit the set and reset resistances during the falling edges of the signal applied to the switch. | 07-23-2009 |
| 20090195285 | SEMICONDUCTOR INTEGRATED CIRCUIT - A semiconductor integrated circuit is provided with one or more flip-flop circuits ( | 08-06-2009 |
| 20090273383 | Logic circuit having gated clock buffer - A logic circuit includes a gated clock buffer including a control node, being set in either a first state or a second state in response to an input signal applied to the control node, outputting an input clock signal supplied as an output signal in the first state, and fixing an output signal to a constant value in the second state, a plurality of scan flip-flops receiving the output signal of the gated clock buffer, and included in at least part of a scan chain, and a combinational logic circuit coupled to at least one of the plurality of scan flip-flops. | 11-05-2009 |
| 20090302915 | Low Power and Full Rail-to-Rail Swing Pseudo CML Latch - The incorporation of MOS (metal oxide semiconductor) switches in the first stage of a CML latch, which act to bring about a significant savings in current usage, and thus lower power, as well as full rail-to-rail output swing. This/these switch(es) are also used to deactivate the first stage of the circuit during the second half of a timing clock cycle, so as to permit the first stage to be activated only during the first half of a clock cycle. “Cross-coupled” inverter(s) are also used in the second stage of the circuit to provide acceptable “rail-to-rail” output voltage differential “swing” using less current. In addition, the second stage also has MOSFET switch(es) which activate only during the second half of a timing clock cycle and are deactivated during the first half of a clock cycle, which requires use of less current and thus reduces power consumption. | 12-10-2009 |
| 20090302916 | Low Power and Full Swing Pseudo CML Latched Logic-Gates - “Negative And” (NAND) logic gate metal oxide semiconductor field effect transistor (MOSFET) switch(es) incorporated in the first stage of a “pseudo” current mode logic (CML) latch to provide a low-resistance (or high-resistance) circuit path to the output depending on the input voltage. This/these switch(es) are also used to deactivate the first stage of the circuit during the second half of a timing clock cycle, so as to permit the first stage to be activated only during the first half of a clock cycle. “Cross-coupled” inverter(s) are also used in the second stage of the circuit to provide acceptable “rail-to-rail” output voltage differential “swing” using less current. In addition, the second stage also has MOSFET switch(es) which activate only during the second half of a timing clock cycle and are deactivated during the first half of a clock cycle, which requires use of less current and thus reduces power consumption. | 12-10-2009 |
| 20100013535 | LATCH CIRCUIT - A latch circuit includes a data input/output unit configured to form a current path through a first node in response to an input data to output an output data, a holding unit configured to form a current path through a second node in response to the output data to store the output data, and a clock input unit coupled to the first and second nodes in parallel in response to a clock. | 01-21-2010 |
| 20100033223 | FLIP-FLOP CIRCUIT - A D-flip-flop includes a data input terminal for receiving a data signal, a clock input terminal for receiving a clock signal, a reset input terminal for receiving a reset signal, an output terminal for latching the data signal received through the data input terminal and outputting it as an output data signal in synchronism with the clock signal, and an inverted output terminal for outputting an inverted output data signal, obtained by inverting the output data signal output from the output terminal. The inverted output terminal is connected to the data input terminal. The clock signal output section includes an XNOR circuit and an OR circuit, and outputs the clock signal to the clock input terminal of the D-flip-flop in synchronism with the rise of the clock signal only when the data signal has changed. | 02-11-2010 |
| 20100156495 | LATCH CIRCUIT AND CLOCK SIGNAL DIVIDING CIRCUIT - 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. | 06-24-2010 |
| 20100176860 | Clocked D-type Flip Flop circuit - A clocked D-type Flip-Flop circuit has a transmission gate to admit an input data and to provide an intermediate output to a clock-controlled inverter based on the clock signals. The clock-controlled inverter is used as a latch for latching the output signal from the transmission gate and releases the latched signal by the same clock signals to an output inverter. The output of the output inverter is the Q terminal of the Flip-Flop circuit. Another output inverter is used to invert the signal from the Q terminal into a complementary output signal. In one of the embodiments of the present invention, another transmission gate is used to condition the complementary output signal. | 07-15-2010 |
| 20100301915 | LATCH WITH SINGLE CLOCKED DEVICE - A D-latch circuit includes a feed forward circuit, a full keeper circuit, and an output buffer circuit. The feed forward circuit inputs a clock signal and a data signal. The feed forward circuit is connected to an input of the full keeper circuit. The feed forward circuit is connected to an output of the full keeper circuit and an input of the output buffer circuit. The output buffer circuit outputs an output signal. The D-latch consists of a single clocked device that switches with the clock signal. | 12-02-2010 |
| 20110133807 | DIFFERENTIAL LATCH, DIFFERENTIAL FLIP-FLOP, LSI, DIFFERENTIAL LATCH CONFIGURATION METHOD, AND DIFFERENTIAL FLIP-FLOP CONFIGURATION METHOD - A differential latch comprising a data holding transistor, the differential latch comprising: a resetting transistor that is connected to a gate electrode of the data holding transistor and is controlled by a reset signal; and a switching transistor that is connected to the gate electrode of the data holding transistor and is controlled by a switch signal, being an inverted version of the reset signal. | 06-09-2011 |
| 20110241745 | FLIP-FLOP CIRCUIT AND LEAKAGE CURRENT SUPPRESSION CIRCUIT UTILIZED IN A FLIP-FLOP CIRCUIT - A flip-flop circuit includes a D flip-flop and a leakage current suppression circuit. The D flip-flop receives an input signal and a clock signal, and outputs a voltage of the input signal at a rising or falling edge of the clock signal as an output signal. The leakage current suppression circuit detects an output error caused by the leakage current flowing through at least a floating node of the D flip-flop and compensates for the leakage current to correct the output error. The leakage current suppression circuit includes a detection circuit and a compensation circuit. The detection circuit receives the output signal and clock signal and detects whether the output error has occurred to generate a detection result. The compensation circuit compensates for the leakage current according to the detection result to correct the output error. | 10-06-2011 |
| 20110254605 | HIGH SPEED DUAL MODULUS PRESCALER - A high speed dual modulus prescaler aims to be used on a frequency synthesizer of wireless communication systems to divide frequency of input signals. The high speed dual modulus prescaler includes a first D flip-flop, a second D flip-flop and a main control transistor. The main control transistor switches connection of the first D flip-flop and second D flip-flop. The main control transistor provides an OR gate state and an AND gate state to form an OR gate circuit and an AND gate circuit in the prescaler. Thereby the number of transistors in the prescaler can be reduced to increase operation speed and lower power consumption. | 10-20-2011 |
| 20120001669 | LOW-POWER DUAL-EDGE-TRIGGERED STORAGE CELL WITH SCAN TEST SUPPORT AND CLOCK GATING CIRCUIT THEREFOR - A storage cell having a pulse generator and a storage element is proposed. The storage element input is connected to receive a data input signal. The storage element output is connected to provide a data output signal. The storage element is operable in one of a data retention state and a data transfer state in response to a storage control signal received from the pulse generator. The pulse generator is connected to receive a clock signal with rising and falling clock signal edges and is adapted to provide control pulses in the storage control signal. Each control pulse has a leading edge and a trailing edge. The control pulses have a polarity suited to invoke the data transfer state on their leading edges. The novel feature is that the pulse generator is adapted to initiate a rising-edge control pulse when receiving a rising clock signal edge and to initiate a falling-edge control pulse when receiving a falling clock signal edge. In this way, a dual-edge-triggered flip-flop may be made using only combinatorial logic circuitry and one level- or single-edge-triggered storage element. The storage cell has low power consumption, facilitates scan testing and can be used by existing design tools and test equipment. | 01-05-2012 |
| 20120062298 | FLIP-FLOP ARCHITECTURE FOR MITIGATING HOLD CLOSURE - A circuit for mitigating hold closure. The circuit includes a flip-flop having a clock input and an output. The circuit also includes a multiplexer. The multiplexer includes a select input coupled to the clock input of the flip-flop. The multiplexer also includes a first data input coupled to the output of the flip-flop. Further, the multiplexer includes an output coupled to a second data input of the multiplexer. | 03-15-2012 |
| 20120068751 | High-speed latch circuit - A high-speed latch circuit includes a latching unit for latching an inputted signal, a signal input unit connected to the latching unit and a clock control unit connected to the signal input unit. The clock control unit includes a first switch element, a second switch element connected to the first switch element and an inverter connected to the second switch element. The first switch element and the inverter are both connected to a clock signal input end. The high-speed latch circuit of the present invention has a simple circuit structure, shortens the triggering time of the signal and reduces chances of wrong triggering. | 03-22-2012 |
| 20120133407 | SEMICONDUCTOR INTEGRATED CIRCUIT - An input buffer chooses, in accordance with first control clocks, to output an input data signal or output a high-impedance signal. A master flip-flop chooses, in accordance with second control clocks, to output a data signal received from the input buffer or retain a currently output data signal. A master-slave switch chooses, in accordance with the second control clocks, to output a high-impedance signal or output a data signal received from the master flip-flop. A slave flip-flop chooses, in accordance with the second control clocks, to retain a currently output data signal or output a data signal received from the master-slave switch. A clock buffer inputs the second control clocks, and generates and outputs the first control clocks. | 05-31-2012 |
| 20120133408 | RACE FREE SEMI-DYNAMIC D-TYPE FLIP-FLOP - Some of the embodiments of the present disclosure provide a D-type flip-flop, comprising a first latch configured to generate a sample enable signal, based on logical states of an input signal, and generate a sampled signal, based on logical states of the input signal and the sample enable signal; and a second latch configured to generate an output signal responsively to the sampled signal. Other embodiments are also described and claimed. | 05-31-2012 |
| 20130021078 | LATCH CIRCUIT WITH A BRIDGING DEVICE - One embodiment of the present invention sets forth a technique for capturing and holding a level of an input signal using a latch circuit that presents a low number of loads to the clock signal. The clock is only coupled to a bridging transistor and a pair of clock-activated pull-down or pull-up transistors. The level of the input signal is propagated to the output signal when the storage sub-circuit is not enabled. The storage sub-circuit is enabled by the bridging transistor and a propagation sub-circuit is activated and deactivated by the pair of clock-activated transistors. | 01-24-2013 |
| 20130076422 | Reduced Frequency Clock Delivery with Local Recovery - Circuits and methods for full rate data reception and transmission using half-frequency clock signals are disclosed. In one embodiment, a flop circuit includes a data input, a data output, and a clock input. The clock signal has a first frequency, while the flop circuit is configured to output data at a rate corresponding to a second frequency. In one embodiment, the second frequency is twice the first frequency. The flop circuit is configured to transmit a first data bit responsive to a first edge (e.g., a rising edge) of the clock signal and a second data bit responsive to a second edge (e.g., a falling edge) of the clock signal that is the next edge following the first edge. Accordingly, the flop circuit may effectively operate at the second frequency utilizing the clock signal at the first lower frequency. | 03-28-2013 |
| 20140145773 | SEMICONDUCTOR INTEGRATED CIRCUIT HAVING BACK-GATE-VOLTAGE CONTROL CIRCUIT - A semiconductor integrated circuit includes a latch circuit, a data applying circuit configured to apply data to an input node of the latch circuit at timing responsive to a synchronizing signal, and a back-gate-voltage control circuit configured to change a back-gate voltage of at least one transistor in an inverter included in the latch circuit at timing responsive to the synchronizing signal. | 05-29-2014 |
| 20140361821 | Low Power High Speed Quadrature Generator - An apparatus comprising a latch comprising a differential inverter configured to receive a differential input signal and generate a differential output signal, a pair of cross-coupled inverters coupled to the differential inverter, and a first clock switch configured to couple the differential inverter to a voltage source, a second clock switch configured to couple the differential inverter to a ground, wherein the first clock switch and the second clock switch are configured to receive a differential clock signal, and wherein the first clock switch and the second clock switch are both open or both closed depending on the differential clock signal, a second latch, wherein the first latch and the second latch are configured as a frequency divider, and a logic circuit coupled to each latch, wherein the logic circuits are configured to generate both an in-phase reference output signal and a quadrature output signal. | 12-11-2014 |
| 20150008969 | SEMICONDUCTOR INTEGRATED CIRCUIT - According to one embodiment, a semiconductor integrated circuit includes a clock signal transmission path configured to transmit a clock signal and a data transmission path configured to transmit data. The clock signal transmission path has a first and a second clock signal transmission line configured to transmit a clock signal and a complementary clock signal. The data transmission path has a first and a second data transmission line configured to transmit data and complementary data. Each transmission path has an amplifier circuit of each signal and a level adjustment circuit for reducing amplitude of output from the amplifier circuit. | 01-08-2015 |
| 20150035575 | DATA OUTPUT CIRCUITS - Data output circuits are provided. The data output circuit includes a latch control signal generator and a data output portion. The latch control signal generator generates an input pulse signal and a latch control signal i, and the latch control signal includes a pulse whose width is controlled to have a predetermined time period. The data output portion latches a data loaded on an input/output (I/O) line during a pulse width period of the latch control signal to generate a latch data. Moreover, the data output portion buffers the latch data according to an output control signal generated from a read command signal to output the buffered latch data as an output data. | 02-05-2015 |
| 20150042390 | DUAL-PORT POSITIVE LEVEL SENSITIVE DATA RETENTION LATCH - In an embodiment of the invention, a dual-port positive level sensitive data retention latch contains a clocked inverter and a dual-port latch. Data is clocked through the clocked inverter when clock signal CKT goes high, CLKZ goes low and retention control signal RET is low. The dual-port latch is configured to receive the output of the clocked inverter, a second data bit D | 02-12-2015 |
| 20150091627 | VARIABILITY RESISTANT CIRCUIT ELEMENT AND SIGNAL PROCESSING METHOD - A sequential circuit arrangement and method are provided in which a latch input signal and a latched version of the input signal are compared to derive a difference signal. This difference signal can detect when changes in the input are not propagated to the output. A second logic gate arrangement derives an error signal from the product of difference signal and a delayed version of the difference signal. This means that normal operation of the circuit is not detected as an error—only when the latched output fails to follow the input after the normally expected delay is the error signal created. The latch element output or an inverted version of the latch element output is selected in dependence on the error signal. | 04-02-2015 |
| 20160065189 | RECEIVER CIRCUIT AND SEMICONDUCTOR INTEGRATED CIRCUIT - A receiver circuit includes: a plurality of first holding circuits respectively latching a plurality of reception data pieces on the basis of a same clock signal; a comparison circuit respectively comparing first reception data pieces and second reception data pieces after a certain time elapses since the latch of the plurality of first holding circuits, the first reception date pieces being respectively latched by the plurality of first holding circuits, the second reception data pieces being respectively input to the plurality of first holding circuits; and a plurality of second holding circuits respectively latching the first reception data pieces when a first output signal of the comparison circuit indicates that the first reception data pieces and the second reception data pieces are identical. | 03-03-2016 |
| 327219000 | Particular device at input, output, or in cross-coupling path | 2 |
| 20140077856 | INTEGRATED CIRCUIT DEVICE AND METHOD FOR SELF-HEATING AN INTEGRATED CIRCUIT DEVICE - An integrated circuit device comprises a first clock signal source, arranged to provide at least one first clock signal; a second clock signal source, arranged to provide at least one second clock signal different from the at least one first clock signal; and a plurality of sequential logic cells, at least one of the plurality connected to receive, in a first mode, the at least one first clock signal or at least one clock signal derived from the at least one first clock signal, and to receive, in a second mode, the at least one second clock signal or at least one clock signal derived from the at least one second clock signal; wherein in the second mode the at least one second clock signal is adapted to the at least one of the plurality of sequential logic cells to generate in at least a portion of the integrated circuit device a current consumption when the at least one first clock signal is not a toggling signal. | 03-20-2014 |
| 327222000 | Resistor in cross-coupling path | 1 |
| 20080284481 | Cross-point latch and method of operating the same - Provided is a cross-point latch and a method of operating the cross-point latch. The cross-point latch includes a signal line, two control lines crossing the signal line, and unipolar switches disposed at crossing points between the signal line and the control lines. | 11-20-2008 |
