Abstract: A circuit arrangement with a gate driver circuit for a power transistor is disclosed which is suitable for low voltage applications, permitting a rail-to-rail output without a loss in speed/bandwidth, which is very simple, low cost, low current and area efficient. The gate driver circuit comprises a drain follower with a MOS driver transistor having the gate connected to an interconnection node of a capacitive divider. A first capacitor of the capacitive divider is connected between the drain and the gate and a second capacitor is connected between the gate and an input of the gate driver circuit. The gate driver has the required low impedance for driving the gate of the power transistor.

Abstract: In a step-up booster circuit, a number of pump circuits are connected in series. Pump control signals are outputted from a pump control circuit, and the pump circuits accordingly generate a required raised voltage by stepping up voltages of signals inputted to the respective pump circuits. The step-up circuit includes an activation control circuit which generates a pump activation signal in accordance with provided signals, which direct operation of the step-up circuit. The pump control circuit controls output of the pump control signals in accordance with a voltage of the pump activation signal.

Abstract: A semiconductor device of the invention comprises a logic circuit to which a power supply voltage, a sub-power supply voltage lower than the power supply voltage, a ground voltage and a sub-ground voltage higher than the ground voltage are supplied; a main power supply line supplying the power supply voltage; and a main ground line supplying the ground voltage. A unit circuit constituting the logic circuit includes first to third PMOS transistors and first to third PMOS transistors. The third PMOS transistor is connected between sources of the first and second PMOS transistors, the main power supply line is connected to its one node, and the sub-power supply voltage is generated at its other node. The third NMOS transistor is connected between sources of the first and second NMOS transistors, the main ground line is connected to its one node, and the sub-ground voltage is generated at its other node.

Abstract: Bias current generation circuits and systems are disclosed. In one embodiment, a bias current generation system comprises a current generation circuit generating a first current based on a first voltage and an external resistor, a current mirror forwarding a second current proportional to the first current, and one or more bias current generation circuits with each circuit generating a bias current based on a second voltage over a resistance of a transistor device, where the transistor device is maintained in a triode region using a third voltage associated with the second current and where the resistance of the transistor device shares characteristics of a resistance of the external resistor.

Abstract: A duty cycle bounding circuit for restoring the unbounded duty cycle of a periodic signal such as a forwarded clock signal. The duty cycle bounding circuit comprises a state holding logic element, such as a C-element, and a delay line. The delay line feeds back an inverted version of the output of the state holding logic element to an input of the state holding logic element. The periodic signal is applied to another input of the state holding logic element.

Abstract: The disclosure relates to phase shifting in Delay Locked Loops (DLLs) and Phase-Locked Loops (PLLs). A charge pump in the DLL or PLL includes a capacitor connected in parallel to an output node. A primary current switching circuit charges the capacitor with a source current and discharges the capacitor with a sink current. A supplemental source circuit sources a positive phase shift producing current which has a range of magnitudes. A magnitude of the positive phase shift producing current is determined by at least one source selection signal. A supplemental sink circuit for sources a negative phase shift producing current which has a range of magnitudes. A magnitude of the negative phase shift producing current is determined by at least one sink selection signal.

Abstract: A level shifter includes a first level shift module for producing a shifted signal by adjusting a direct current (DC) level of an input signal by a first bias voltage having a first polarity. A second level shift module produces an output signal by adjusting a DC level of the shifted signal by a second bias voltage having a second polarity. The first polarity is opposite to the second polarity and the sum of the first bias voltage and the second bias voltage is a non-zero voltage.

Abstract: A low-leakage circuit includes first, second, and third transistors, which may be P-channel or N-channel FETs. The first transistor provides an output current when enabled and presents low leakage current when disabled. The second transistor enables or disables the first transistor. The third transistor connects or isolates the first transistor to/from a predetermined voltage (e.g., VDD or VSS). The circuit may further include a pass transistor that provides a reference voltage to the source of the first transistor when the first transistor is disabled. In an ON state, the first transistor provides the output current, and the second and third transistors do not impact performance. In an OFF state, the second and third transistors are used to provide appropriate voltages to the first transistor to place it in a low-leakage state. The first, second, and third transistors may be used for a low-leakage current source within a current mirror, an amplifier stage, and so on.

Abstract: A delay locked loop circuit for a semiconductor memory apparatus includes a duty cycle correcting part that corrects and outputs duty cycles of internal clocks. A clock pulse width detecting part detects a pulse width of an external clock and outputs a pulse width detecting signal. A driving part divides a phase of the output of the duty cycle correcting part, adjusts a pulse width of at least one of two signals, which are obtained by dividing the phase, in accordance with the pulse width detecting signal, and outputs the two signals as delay locked loop clocks.

Abstract: The digital duty cycle correction circuit according to the present invention includes a first conversion circuit for buffering an internal clock output from a delay locked loop (DLL), converting the buffered internal clock into first and second clocks through first and second terminals, delaying the second clock according to voltage supplied to the second terminal through a capacitor, converting the delayed second clock into a first signal, and converting the first clock into a third clock, which rises at a falling edge of the first clock and falls at a rising edge of the first signal; and a second conversion circuit for converting the third clock into an output clock, which rises at a falling edge of the third clock and falls at a rising edge of the third clock.

Abstract: An apparatus including a first circuit, a second circuit and a third circuit. The first circuit may be configured to (a) receive (i) a plurality of input signals and (ii) a clock signal and (b) present (i) a plurality of low-swing differential signals and (ii) a full-swing differential signal. The second circuit may be configured to (a) receive (i) the plurality of low-swing differential signals, (ii) the full-swing differential signal and (iii) the clock signal and (b) present a plurality of output signals. The third circuit may be configured to communicate the plurality of low-swing differential signals and the full-swing differential signal from the first circuit to the second circuit. The third circuit may be further configured to generate a local clock in response to the full-swing differential signal.

Abstract: Provided is a grid-type high-speed clock signal distribution network capable of reducing a difference in amplitude of a standing wave on a transmission line and of supplying a signal from any position. The network for transmitting the clock signal is such that ends of the differential signal transmission line are connected via an inductor, a low-amplitude segment is eliminated by a phase shift in the inductor and a standing wave of substantially uniform phase and amplitude is produced, wherein the number of lines connected to the grid point is made the same for entire grid points.

Abstract: The invention relates to electronic integrated circuits capable of operating either in active mode or in standby mode and to have, in standby mode, a very low current consumption. According to the invention, the leakage current of a power transistor inserted in series between a supply terminal and an active circuit is controlled by a gate reverse overbias in the following manner: a first reference transistor, and a second reference transistor identical to the first, are biased with the same gate reverse overbias voltage as the power transistor, the first transistor having its source linked to the supply terminal, and the second reference transistor having its source linked to its drain. The leakage currents in these two transistors are compared, and it is considered that the optimal bias of the gate is obtained when the leakage currents are equal. Applications to circuits supplied by a battery or a cell (portable telephones, cameras, portable computers, etc.).

Abstract: A semiconductor integrated circuit device includes: a first bias generating circuit, a second bias generating circuit and a control circuit. The first bias generating circuit generates a first substrate bias voltage of a P-channel transistor. The second bias generating circuit generates a second substrate bias voltage of N-channel transistor. The control circuit controls the first bias generating circuit and the second bias generating circuit independently on the basis of operating states of circuits to which the first substrate bias voltage and the second substrate bias voltage are applied.

Abstract: An apparatus, method and system are described for providing a low power replica biased regulated supply voltage without the size requirements of using a large resistor coupled between the source of a master transistor and ground. Instead, a source of a replica transistor diode may be biased with a bias voltage, and the gate and drain of the diode may be biased with a current bias. Additional descriptions provide the supply voltage without the size requirements of a resistor coupled between a source of one or more pass transistors and ground. Instead, the source of the pass transistor(s) may be biased with a “leaker” current.

Abstract: A power-down biasing circuit includes a current source connected to a drain of a first NMOS transistor through a first switch. A gate of the first NMOS transistor is connected to the current source, and a source of the first NMOS transistor is connected to ground. A first pre-chargeable capacitor is connected between the gate of the first NMOS transistor and ground. A plurality of NMOS transistors form a current multiplier and have gates connected to the current reference. A plurality of current mirrors are connected to drains of the plurality of NMOS transistors and to output switches.

Abstract: A method and apparatus for power supply rejection in a reference voltage circuit using a variable resistance circuit.

Abstract: Provided is a band gap constant-voltage circuit capable of achieving a quick startup time to thereby preventing an output voltage from being stabilized at 0 V due to noise or the like even under the normal condition. The band gap constant-voltage circuit according to the present invention includes: an output voltage detecting circuit for monitoring a voltage at an output terminal; and a current source which has a current value controlled through an output of the output voltage detecting circuit, in which the current source supplies a bipolar transistor constituting a level shifter circuit with a current when the voltage at the output terminal is lower than a predetermined voltage.

Abstract: A band gap reference circuit is configured by connecting an emitter of a transistor, having the base and the collector thereof grounded, to an internal circuit, and by connecting an emitter of another transistor, having the base and the collector thereof grounded, to the internal circuit via a resistor having a positive temperature dependence with respect to the absolute temperature, so as to ensure that a constant output current with a small temperature dependence can be generated, without providing any voltage-current conversion circuit and without generating a constant output voltage, while suppressing expansion in the circuit scale but based on a circuit configuration allowing lowering in the power source voltage.

Abstract: An integrated circuit with a signal bus formed by the cell abutment of logic cells. The integrated circuit comprises at least two logic cells. The signal bus is formed by cell abutment of the at least two logic cells. The signal bus is configured to receive a signal and to distribute the signal to each of the at least two logic cells.