Abstract: A marching memory is disclosed having an array of memory units. Each memory unit has a sequence of bit level cells. Each bit-level cell has a transfer-transistor having a first main-electrode connected to a clock signal supply line through a first delay element, and a control-electrode connected to an output terminal of a first neighboring bit-level cell positioned at an input side of the array of the memory units, through a second delay element. Each bit-level cell also has a reset-transistor having a first main-electrode connected to a second main-electrode of the transfer-transistor, a control-electrode connected to the clock signal supply line, and a second main-electrode connected to the ground potential. Each bit-level cell also has a capacitor connected in parallel with the reset-transistor.

Abstract: A marching memory is disclosed having an array of memory units. Each memory unit has a sequence of bit level cells. Each bit-level cell has a transfer-transistor having a first main-electrode connected to a clock signal supply line through a first delay element, and a control-electrode connected to an output terminal of a first neighboring bit-level cell positioned at an input side of the array of the memory units, through a second delay element. Each bit-level cell also has a reset-transistor having a first main-electrode connected to a second main-electrode of the transfer-transistor, a control-electrode connected to the clock signal supply line, and a second main-electrode connected to the ground potential. Each bit-level cell also has a capacitor connected in parallel with the reset-transistor.

Abstract: A circuit is provided which is constituted by TFTs of one conductivity type, and which is capable of outputting signals of a normal amplitude. When an input clock signal CK1 becomes a high level, each of TFTs (101, 103) is turned on to settle at a low level the potential at a signal output section (Out). A pulse is then input to a signal input section (In) and becomes high level. The gate potential of TFT (102) is increased to (VDD?V thN) and the gate is floated. TFT (102) is thus turned on. Then CK1 becomes low level and each of TFTs (101, 103) is turned off. Simultaneously, CK3 becomes high level and the potential at the signal output section is increased. Simultaneously, the potential at the gate of TFT (102) is increased to a level equal to or higher than (VDD+V thN) by the function of capacitor (104), so that the high level appearing at the signal output section (Out) becomes equal to VDD.

Abstract: A driving device of a liquid crystal display (LCD) utilized for preventing noises of a clock signal from causing error operation of a shift register is disclosed. The driving device includes a shift register, a reception terminal, a noise elimination circuit and a control signal generation circuit. The reception terminal is utilized for receiving a first clock signal. The noise elimination circuit is coupled to the reception terminal, and is utilized for eliminating noises of the first clock signal and delaying the first clock signal for a preset time to generate a second clock signal. The control signal generation circuit is coupled to the reception terminal, the noise elimination circuit and the shift register, and is utilized for generating a first control signal and a second control signal to control the shift register.

Abstract: A shift register circuit including a logic circuit capable of controlling the threshold voltage of a transistor and outputting a signal corresponding to an input signal by changing only the potential of a back gate without changing the potential of a gate is provided. In a shift register circuit including a logic circuit with a first transistor and a second transistor having the same conductivity type, a first gate electrode of the first transistor is connected to a source electrode or a drain electrode of the first transistor, an input signal is supplied to a second gate electrode of the first transistor, a clock signal is supplied to a gate electrode of the second transistor, and the first gate electrode and the gate electrode are formed from the same layer.

Abstract: A shift register includes first type D latches in the odd-numbered stage and second type D latches in the even-numbered stage. A pass gate of the first type D latch and a memory controller of the second type D latch are made from a first conductivity type transistor, and a memory controller of the first type D latch and a pass gate of the second type D latch are made from a second conductivity type transistor.

Abstract: A stage circuit is capable of concurrently or progressively supplying scan signals. The stage circuit includes a progressive driver including a first transistor and a second transistor, and a concurrent driver including an 11th transistor and a 12th transistor. When the first transistor, the second transistor, the 11th transistor, and the 12th transistor are turned off, lower voltages than voltages applied to source electrodes are applied to gate electrodes such that the transistors can be stably turned off.

Abstract: A shift register circuit includes plural shift register stages for providing plural gate signals. Each shift register stage includes a driving unit, an input unit, a driving adjustment unit and a pull-down unit. The driving unit is utilized for outputting a gate signal according to a system clock and a driving control voltage. The input unit is put in use for outputting the driving control voltage according to an input control signal and a first input signal. The driving adjustment unit is employed for adjusting the driving control voltage according to a second input signal and a third input signal. The pull-down unit is used for pulling down the gate signal and the driving control voltage according to a fourth input signal.

Abstract: A level shift circuit includes: a first and a second output transistor outputting voltages derived from a first and a second power source voltage, respectively; a first and a second input transistor outputting, based on a first input pulse signal, a first voltage for turning ON the first output transistor and a second voltage for turning OFF the second output transistor, respectively; a third and a fourth input transistor outputting, based on a second input pulse signal, a third voltage for turning OFF the first output transistor and a fourth voltage for turning ON the second output transistor, respectively; a first bootstrap circuit enlarging an amplitude of the first voltage and supplying the same to the first output transistor; and a first voltage compensation circuit, based on a third input pulse signal, making, at an end timing of the first input pulse signal, a voltage change in a direction opposite to that of a voltage fluctuation caused in the first voltage due to a parasitic capacitance in the first

Abstract: The present invention relates to a shift register having a plurality of stages electrically coupled to each other in series. Each stage includes a first and second TFT transistor. The first TFT transistor has a get electrically coupled to the output of the immediately prior stage, a drain electrically coupled to the boost point of the stage, and a source configured to receive one of the first and second control signals. The second TFT transistor has a get electrically coupled to the output of the immediately next stage, a drain and a source electrically coupled the drain and the source of the first transistor, respectively.

Abstract: A gate driving circuit having improved driving capability and maintaining reliability even after a prolonged period of use includes a shift register having a plurality of stages cascaded to one another, each of the plurality of stages including a pull-up unit, a pull-down unit, a discharging unit, and a holding unit, wherein at least one of the discharging unit and the holding unit includes an amorphous silicon thin film transistor and a polysilicon thin film transistor connected in parallel to each other.

Abstract: A gate driving circuit that may be capable of improving driving margin and maintaining reliability even after long use, and a display device having the gate driving circuit. The gate driving circuit includes a shift register having a plurality of stages dependently connected to one another, wherein each stage includes a pull-up unit outputting a first clock signal as a gate signal in response to a signal of a first node, to which a first input signal is applied, a pull-down unit discharging the gate signal to a gate-off voltage in response to a second input signal, a discharging unit discharging the signal of the first node to the gate-off voltage in response to the second input signal, and a holding unit maintaining the signal of the first node at the gate-off voltage in response to a delay signal of the first clock signal.

Abstract: It discloses a shift register and a gate line driving device, relating to the technology field for a liquid crystal display, it is made to reduce the switching on errors for gate lines and improve the quality of the image. Said shift register includes: a first thin film transistor, a second thin film transistor, a third thin film transistor, a storage capacitor, a feedback module, and a switch module, wherein said feedback module is used to receive a trigger signal of the feedback module of the previous stage and a clock signal in order to pull up the level of the first node Qa as a pull up node, and to output a feedback signal to the shift register of the previous stage and output a trigger signal to the feedback module of the next stage, said switch module is used to maintain the output terminal of the shift register of the present stage at a low level when the shift register of the present stage does not operate. An embodiment of the present invention is applied to a liquid crystal display panel.

Abstract: The present invention relates to a shift register and a liquid crystal display using the same. The liquid crystal display includes a liquid crystal panel, a data driving circuit and a scanning driving circuit. The data driving circuit and the scanning driving circuit each include a shift register. The shift register includes a plurality of shift register units. Two adjacent shift register units respectively receive two inverse clock signals and a VGL signal. Each shift register unit includes a signal output circuit, a signal input circuit, a first logic converting circuit, and a second logic converting circuit. The present shift register and a liquid crystal display have simple structure.

Abstract: An exemplary shift register includes a plurality of shift register units, each of which includes an output circuit, an input circuit, and a logic circuit. The output circuit includes a clock transistor, a voltage stabilizing transistor, and an input circuit for receiving signals output by a previous shift register unit. The logic circuit receives signals output by the input circuit. When the input circuit outputs signals to switch on the clock transistor, the logic circuit outputs a low level voltage signal to shut off the voltage stabilizing transistor. Thus, the output circuit outputs signals via the clock circuit. On the other hand, when the input circuit outputs signals to shut off the clock transistor, the logic circuit outputs a high level voltage signal to turn on the voltage stabilizing transistor, so as to maintain the output circuit to output low level voltage signal.

Abstract: A digital logic circuit includes a plurality of transistors of a same conduction type. In at least one embodiment, a first transistor has a source, gate and drain connected to a first circuit node, a second circuit node and a first power supply line, respectively. A second transistor has a source, gate and drain connected to the second node, the first node and the first supply line, respectively. A third transistor has a drain connected to the first node. A fourth transistor has a gate and drain connected to a third circuit node and the second circuit node, respectively. A fifth transistor has a gate and drain connected to the first and third nodes, respectively. Such a circuit may be used, for example, as a latch in a shift register of an active matrix addressing arrangement.

Abstract: A driving circuit for a flat panel display device includes a generation unit for generating n-phase form generation clocks; and a plurality of shift register stages for sequentially generating a plurality gate signals to a plurality of gate lines using the n-phase form generation clocks, one of the shift register stage including first and second output terminals for outputting first and second switching signals, respectively, using an output signal of one of the preceding shift register stages and an output signal of one of the subsequent shift register stages; a first transistor connected to the first output terminal for receiving one of the n-phase form generation clocks; and a second transistor connected to the second output terminal and the first transistor, wherein each gate line is connected to a node between the first and second transistors.

Abstract: The present invention relates to a shift register having a plurality of stages electrically coupled to each other in series. Each stage includes a first and second TFT transistor. The first TFT transistor has a get electrically coupled to the output of the immediately prior stage, a drain electrically coupled to the boost point of the stage, and a source configured to receive one of the first and second control signals. The second TFT transistor has a get electrically coupled to the output of the immediately next stage, a drain and a source electrically coupled the drain and the source of the first transistor, respectively.

Abstract: An asynchronous logic family of circuits which communicate on delay-insensitive flow-controlled channels with 4-phase handshakes and 1 of N encoding, compute output data directly from input data using domino logic, and use the state-holding ability of the domino logic to implement pipelining without additional latches.

Abstract: A shift register including shift register units substantially cascaded is disclosed. Each shift register unit is controlled by first and second clock signals opposite to each other for generating an output signal. Each shift register unit includes first and second switch devices and first and second devices. The first switch device provides the output signal through an output node. The first driving device drives the first switch device according to a first input signal to activate the output signal. The second driving device provides a first voltage signal, according to the first clock signal, to drive the first switch device and de-activate the output signal. When the first switch device de-activates the output signal, the second switch device provides the second voltage signal to the output node according to the second clock signal. A level of the first voltage signal is lower than a level of the second voltage signal.

Abstract: An exemplary shift register (20) includes a plurality of shift register units (200) connected one by one. Each of the shift register units includes a clock signal input terminal (TS), a reverse clock signal input terminal (TSB), a high level signal input terminal (VH), a low level signal input terminal (VL), an output terminal (VOUT), a reverse output terminal (VOUTB), a first input terminal (VIN1), a second input terminal (VIN2), a common node (P), a first switch circuit (31) providing a high level signal to the common node, a second switch circuit (32) providing a low level signal to the common node, a third switch circuit (33) providing a clock signal to the output terminal, a fourth switch circuit (34) providing a low level signal to the output terminal, and an inverter (36) connected between the output terminal and the reverse output terminal.

Abstract: A shift register of the present disclosure switches on and off various transistors in order to reduce power consumption. A high input voltage source and a low input voltage source of the shift register are spaced apart from each other so as to reduce signal noise distortion between the voltage sources. The shift register may be employed in a liquid crystal display (LCD).

Abstract: A shift register includes a plurality of stages to output a plurality of output signals, in sequence. Each of the stages includes a driving part and a discharging part. The driving part outputs an output signal of a present stage based on one of a start signal and an output signal of a previous stage, and a clock signal. The discharging part discharges the output signal of the present stage. The discharging part includes a discharge transistor and an auxiliary transistor. The discharge transistor has a gate electrode receiving an output signal of a next stage. The auxiliary transistor has a gate electrode receiving the output signal of the next stage. The auxiliary transistor is electrically connected in series to the discharge transistor. Therefore, the chance of a malfunction is decreased, and image display quality of the display device is improved.

Abstract: It is provided a method of controlling a shift register in which a plurality of transfer unit circuits, each having a storage unit and a writing unit, are connected in series. The storage unit has a hold gate and stores a logical level of a pulse when the hold gate is in an active state, and the writing unit has a writing gate and stores a pulse in the storage unit when the writing gate is in an active state.

Abstract: A pre-charge circuit includes a receiving module, an enabling module, and a reset module. The receiving module receives the received driving signal of the pre-charge circuit and outputs the receiving driving signal according to a control signal. The enabling module outputs a pre-charge signal when receiving the driving signal. The reset module is electrically coupled between the receiving module and the enabling module for receiving a reset signal to reset the pre-charge signal.

Abstract: A display having a shift register circuit capable of suppressing increase of power consumption is provided. This display comprises a shift register circuit including a shift register circuit portion including a first circuit portion having a second transistor turned on in response to a first signal and a second circuit portion having a sixth transistor turned on in response to a second signal providing an ON-state period not overlapping with an ON-state period of the second transistor and an input signal switching circuit portion for switching the first and second signals supplied to the second and sixth transistors respectively.

Abstract: A gate driving circuit having improved driving capability and maintaining reliability even after a prolonged period of use includes a shift register having a plurality of stages cascaded to one another, each of the plurality of stages including a pull-up unit, a pull-down unit, a discharging unit, and a holding unit, wherein at least one of the discharging unit and the holding unit includes an amorphous silicon thin film transistor and a polysilicon thin film transistor connected in parallel to each other.

Abstract: Malfunction caused by leakage current of the transistor is prevented in the shift register in which the signal can be shifted bi-directionally. The bi-directional unit shift register includes a transistor Q1 between a clock terminal CK and an output terminal OUT, a transistor Q2 for discharging the output terminal OUT, and transistors Q3, Q4 for providing first and second voltage signals Vn, Vr, which are complementary to each other, to the first node or a gate node of the transistor Q1. Furthermore, a transistor Q5, having a gate connected to a second node or a gate node of the transistor Q2, for discharging the first node is arranged.

Abstract: A shift register comprising at least one shift register unit. The shift register unit comprises an input unit, at least one first TFT, and at least one second TFT. The input unit receives an input signal from the input terminal and outputs a switching control signal in accordance with a first clock signal. The gate of the first TFT is for receiving the switching control signal, the drain of the first TFT is for receiving a second clock signal, and the source of the first TFT is coupled to the output terminal. The gate and drain of the second TFT are coupled to the output terminal, and the source of the second TFT is coupled to the input unit.

Abstract: A shift register and a shift register apparatus are provided. The shift register includes a plurality of shift register apparatus, and each shift register apparatus comprises a pre-charge circuit, a pull-up circuit and a pull-down circuit. The pre-charge circuit is used for sampling an input signal according to a first clock signal and a second clock signal respectively and generate a first charging signal and a second charging signal respectively. The pull-up circuit is coupled to the pre-charge circuit. The pull-up circuit receives the third clock signal and the first charging signal to output an output signal accordingly. The pull-down circuit is coupled to the pre-charge circuit and the pull-up circuit. The pull-down circuit receives the fourth clock signal and the second charging signal to decide whether to couple the output signal to a common potential.

Abstract: A shift register includes a plurality of register stages. Each register stage includes an output circuit, a first switching circuit and a second switching circuit. The output circuit is capable of outputting a first driving signal. The first switching circuit is used to pull down the output circuit into a low voltage level when the output circuit is not outputting the first driving signal. The second switching circuit is capable of receiving an input signal. The first switching circuit holds electric charges by the parasitical capacitor resident in the transistor in order to keep the first switching circuit in a turn-on state when the output circuit is not outputting the first driving signal.

Abstract: An exemplary shift register includes a plurality of shift register units, each of which includes an output circuit, an input circuit, and a logic circuit. The output circuit includes a clock transistor, a voltage stabilizing transistor, and an input circuit for receiving signals output by a previous shift register unit. The logic circuit receives signals output by the input circuit. When the input circuit outputs signals to switch on the clock transistor, the logic circuit outputs a low level voltage signal to shut off the voltage stabilizing transistor. Thus, the output circuit outputs signals via the clock circuit. On the other hand, when the input circuit outputs signals to shut off the clock transistor, the logic circuit outputs a high level voltage signal to turn on the voltage stabilizing transistor, so as to maintain the output circuit to output low level voltage signal.

Abstract: A shift register includes, in the output stage, a first transistor connected between an output terminal and a first clock terminal and a second transistor connected between the output terminal and a first power terminal. Third and fourth transistors constitute an inverter which inverses the level of the gate of the second transistor and outputs it to the gate of the first transistor. An isolation circuit formed by fifth and sixth transistors is provided between the gate of the first transistor and the gate of the fourth transistor. The fifth transistor is diode-connected. When the gate of the first transistor becomes higher than the gate of the fourth transistor, the first and fourth transistors are electrically isolated from each other.

Abstract: Each stage of a shift register circuit has a first input (Rn?1) connected to the output of the preceding stage, a drive transistor (Tdrive)for coupling a first clocked power line voltage (Pn) to the output (Rn) of the stage, a compensation capacitor (C1) for compensating for the effects of a parasitic capacitance of the drive transistor, a first bootstrap capacitor (C2) connected between the gate of the drive transistor and the output (Rn) of the stage; and an input transistor (Tin1) for charging the first bootstrap capacitor (C2) and controlled by the first input (Rn?1). Each stage has an input section (10) coupled to the output (Rn?2) of the stage two stages before the stage having a second bootstrap capacitor (C3) connected between the gate of the input transistor (Tin1) and the first input (Rn?1). The use of two bootstrapping capacitors makes the circuit less sensitive to threshold voltage levels or variations, and enables implementation using amorphous silicon technology.

Abstract: A disable circuit for using in a dynamic shift register unit comprising: a first input, a second input, an output, a first reference line for receiving a first supply voltage, a second reference line for receiving a second supply voltage, and six transistors. The disable circuit is capable of being coupled with a dynamic shift register unit having an input for receiving an input pulse and an output for outputting a shifted pulse. The disable circuit generates an output signal during an input pulse period or an output pulse period for the dynamic shift register unit, wherein the input pulse period and the output pulse period are responsive to a first input pulsed signal from the first input and a second input pulsed signal from the second input, respectively.

Abstract: A high voltage shift register stage which directly accepts low voltage clock signal inputs without using clock buffers. In particular, a shift register stage circuit is adapted to operate with a low voltage swing clock signal, with the stage circuit having a single state node, a, driven directly. This arrangement allows for reduced power consumption and higher operating speeds.

Abstract: A shift register without a feedback signal of a post-stage shift register utilizing a latch mechanism and a clock signal to control the voltage of an output of the shift register is provided. The shift register reduces the transistor size and the circuit layout area. The shift register also improves the issue the overlapping between two adjacent shift registers to reduce the after-image of a liquid crystal display.

Abstract: A shift register has multiple stages each of which includes a pull-up part to generate a current gate line driving signal having a first state in response to a first control signal and a clock signal, a pull-down part to generate the current gate line driving signal having a second state in response to a second control signal, a pull-up driver to generate the first control signal to control the pull-up part in response to a previous gate line driving signal provided from a previous stage, a following gate line driving signal provided from a following stage, and an input voltage signal externally provided, and a pull-down driver to generate the second control signal to control the pull-down part in response to a third control signal provided from the pull-up driver and the input voltage signal, in which the second control signal swings between first and second voltage levels in association with the input voltage signal that swings between predetermined voltage levels.

Abstract: In a shift register circuit included in a driver circuit for driving an active matrix circuit in an active matrix type display device, a plurality of serial-connected registers constructing register lines are arranged to construct a redundancy shift register circuit. Whether or not each register line has defect is examined by detecting an output of a last register of each register line, then the register line having defect is detected by the examination, a normal register line is selected by a shift register selecting switch, and the serial-connected registers of the selected register line are used in the shift register circuit.

Abstract: Each of stages RS(1), RS(2), . . . of a shift register is constituted by six TFTs. A ratio of a channel width and a channel length (W/L) of each of these TFTs 1 to 6 is set in accordance with a transistor characteristic of each TFT in such a manner that the shift register normally operates for a long time even at a high temperature.

Abstract: A circuit for limiting loss in a second circuit. The circuit may include a first timer, a second timer and one or more logic gates. The first timer may produce a first output in a given state if the duration of a pulse for use with the second circuit reaches a first predetermined amount of time, where the first predetermined amount of time is related to a parameter of the second circuit. The second timer may produce a second output in the given state if the first timer does not produce the first output in the given state when the duration of the pulse reaches a second predetermined amount of time. The one or more logic gates may have an output that is the same as the pulse unless and until the output of the first timer or the second timer is in the given state, at which time, the output of the one or more logic gates is forced to a non-pulsed state.

Abstract: A shift register includes a plurality of shift register stages having inputs and outputs coupled to form a chain. Each stage includes enable and disable control inputs, with an output of a selected one of the stages coupled to the enable input of a stage a selected number of stages ahead in the chain and to the disable input of a stage a selected number of stages behind in the chain.

Abstract: The present invention describes a circuit (10) and associated method of operation for implementing bit reversals and shifts of an input data. The circuit (10) includes a plurality of input lines (12), a plurality of output lines (14), a plurality of shifting transistors (16), a plurality of bit reversal transistors (20), control lines (18) and (22) for each, and a controller (24). The plurality of shifting transistors (16) operably couple the input lines (12) to the output lines (14) such that the controller (24) may selectively operate the shifting transistors (22) to produce shifted outputs of the input data D.sub.0 through D.sub.3 on the output lines (14). The controller (24) selectively operates the bit reversal transistors (20) to produce a bit reversed representation of the input data on the output lines (14). Precharge circuit (30) precharges the output lines (14) so that they may be statically driven. The circuit (10) may include multiplexors (25), (26), and (27) to enable arithmetic shifts.

Abstract: A shift register which is stably operable even under low power voltage and including a first transfer gate NTM1 connected to a data input terminal DIN1, second and third transfer gates NTM2 and NTM3 connected in series to a ground line, a pair of inverters IVM1 and IVM2 connected in the opposite orientation between the output terminals of the first and third gates, and fourth and fifth transfer gates NTS1 and NTS2 connected in parallel with respect to the outputs of the pair of inverters IVM1 and IVM2. The shift register further includes a pair of inverters IVS1 and IVS2 connected in the opposite orientation between the output terminals of the fourth and fifth gates. The gate terminal of the second gate is connected to the data input terminal, a first clock signal MCLK is input into the gate terminals of the first and third gates, and a second clock signal SCLK, in which the phase differs from the first clock signal, is input into the gate terminals of the fourth and fifth gates.

Abstract: The circuit device has a plurality of cascaded stages. Each cascaded stage includes several partial stages and has at most two capacitors (C.sub.n1, C.sub.nB) and at most seven transistors (T.sub.n1, T.sub.n2, T.sub.n3, T.sub.n4, T.sub.n5, T.sub.n6, T.sub.n7). The circuit device includes a device for controlling the cascaded stages with four periodic clock signals (.PHI..sub.1, .PHI..sub.2, .PHI..sub.3, .sub.101 .sub.4) phase-shifted about 90.degree. relative to each other such that each of the cascaded stages is controlled by a respective assigned one of four predetermined sets of two of the four periodic clock signals and the same one of the four predetermined set repeats every fifth cascaded stage. Each cascaded stage includes an output stage (12, 12') including a bootstrap-capacitor (C.sub.nB) and three transistors (T.sub.n5, T.sub.n6, T.sub.n7) electrically connected to the bootstrap-capacitor (C.sub.nB); and a charging and discharging stage (11) for the bootstrap-capacitor (C.sub.nB).

Abstract: A flip-flop of a master-slave type of a CMOS structure having no P channel transistor between nodes of the master flip-flop and of the slave flip-flop is provided. Only one P channel MOS transistor is existent in a route of the current controlling a rise time and a trail time of output signals, so that it is possible to function at a high speed.

Abstract: A logic circuit includes pull-up and pull-down transistors and a capacitance, the principal conducting paths of the transistors and the capacitance being coupled in series between a first supply bus and a source of time varying potential. The pull-up transistor is coupled to the capacitance and the capacitance is coupled to the time varying potential. First and second logic signals are applied to the control electrodes of the first and second transistors respectively. The time varying potential is arranged to limit the charge passed by the pull-up transistor permitting use of a relatively small pull-down transistor. The time varying potential has an amplitude sufficiently large to tend to stress the pull-up transistor if such transistor is non conducting. A selectively conductive element (diode) is coupled between a point of clamping potential and the interconnection of the pull-up transistor and capacitance.

Abstract: A semiconductor integrated circuit comprises a three-valued logic circuit connected to receive an output signal of a logic circuit to receive at one input a control clock signal and at the other input an input signal, and a flip-flop circuit composed of a clocked inverter to receive the output signal of the three-valued logic circuit, and another inverter.

Abstract: A frequency divide by n circuit, where n is an odd number, which includes means for splitting an incoming clock signal of frequency "f" into two non-overlapping complementary clock signals of frequency "f" and a shift register circuit. The shift register circuit is coupled to the signal splitting means and generates an output clock signal of frequency f/n in response to the two complementary clock signals. The output clock signal has a duty cycle equal to ((n-1)/2+D.sub.in)/n where D.sub.in is the duty cycle of the incoming clock signal. The output duty cycle is substantially independent of processing and operating conditions.

Abstract: A shift register comprising a plurality of memory cells serially coupled together along a signal bus. Each one of the plurality of memory cells comprises a first amplifier, fed by an input logic signal, for amplifying and inverting the logic state of the input logic signal. A first storage section is included for either enabling storage in the first storage section of an electric charge corresponding to the voltage level of the amplified and inverted input logic signal, or disabling storage in the first storage section of the electric charge, selectively in response to a first control signal. The stored electric charge is converted to an intermediate logic signal having a predetermined voltage level. Each memory cell additionally includes a second amplifier, fed by the intermediate logic signal, for amplifying and inverting the logic state of the intermediate logic signal.