Abstract: There is described a driver circuit for a single wire protocol slave unit, the driver circuit comprising (a) at least one current mirror comprising a first transistor (MP1, MN3) and a second transistor (MP2, MN4), wherein the gate of both transistors is connected to a bias node (PBIAS, S2BIAS), and wherein the second transistor is adapted to conduct a mirror current (I2, IOUT) equal to a current (I1, I2) conducted by the first transistor multiplied by a predetermined factor, (b) a bias transistor (MP3, MN5) for selectively connecting and disconnecting the bias node to and from a predetermined potential (VDD, GND) in response to a control signal (ABUF, AN), and (c) a current boosting element for providing a boost current (I1P, I2P) to the bias node for a predetermined period of time when the control signal causes the bias transistor to disconnect the bias node from the predetermined potential. There is also described a universal integrated circuit card device comprising a driver circuit.

Abstract: There is described a driver circuit for a single wire protocol slave unit, the driver circuit comprising (a) at least one current mirror comprising a first transistor (MP1, MN3) and a second transistor (MP2, MN4), wherein the gate of both transistors is connected to a bias node (PBIAS, S2BIAS), and wherein the second transistor is adapted to conduct a mirror current (I2, IOUT) equal to a current (I1, I2) conducted by the first transistor multiplied by a predetermined factor, (b) a bias transistor (MP3, MN5) for selectively connecting and disconnecting the bias node to and from a predetermined potential (VDD, GND) in response to a control signal (ABUF, AN), and (c) a current boosting element for providing a boost current (I1P, I2P) to the bias node for a predetermined period of time when the control signal causes the bias transistor to disconnect the bias node from the predetermined potential. There is also described a universal integrated circuit card device comprising a driver circuit.

Abstract: A differential amplifier circuit comprises a differential pre-amplifying stage which is designed to allow an input signal with a first common mode voltage range, and to generate an output which has a narrower common mode voltage variation. This pre-amplifier stage is designed to accept a large common mode input voltage and to process the signal so that it can be amplified by a main amplifying stage which is designed to allow an input signal with a smaller common mode voltage range.

Abstract: A differential amplifier circuit comprises a differential pre-amplifying stage which is designed to allow an input signal with a first common mode voltage range, and to generate an output which has a narrower common mode voltage variation. This pre-amplifier stage is designed to accept a large common mode input voltage and to process the signal so that it can be amplified by a main amplifying stage which is designed to allow an input signal with a smaller common mode voltage range.

Abstract: A differential receiver includes a feedback circuit connected between an output node and one common node of the differential receiver to reduce the bandwidth and reject noise for a specific interval of time. In operation, a differential receiver bias current is controlled responsive to an output signal at the output node. Bias current is turned on during a steady-state mode with respect to the output signal, and is turned off, for a given delay period, in response to a transition mode with respect to the output signal.

Abstract: A voltage translator circuit for low level to high level voltage translation includes a plurality of transistors coupled to an inverter for receiving a common input signal at an input node of the plurality of transistors and passing a translated output signal to the output node of the plurality of transistors. A latch circuit is connected between a first node at the output node of the plurality of transistors and a second node that is connected to a feedback element at an input side of the plurality of transistors to form a feedback circuit that minimizes static power dissipation.

Abstract: The differential input receiver provides constant symmetrical hysteresis over a wide input signal range. The differential input receiver includes a pair of complementary differential comparators having common input terminals, a pair of series connected complementary current mirrors each having source terminals driven by the output terminals of the corresponding differential comparator, a pair of transistors connected in series across each differential pair transistor in each differential comparator to form a potential divider across it, and a pair of series connected inverting buffers connected to a common output of the differential comparators to provide the final output. The individual buffer outputs are fed back to the control terminals of the series connected transistors in a manner that provides positive feedback thereby providing equal rise-time, fall-delay and transition times in the output signal.

Abstract: The present invention provides a Differential Signaling line driver including a pre-emphasis circuit, which boosts the output drive current without any delay whenever there is a transition in the input signal to the driver, using the input signal itself to provide the pre-emphasis through a current steering circuit that switches the direction of drive currents to provide a differential output signal. A delayed signal is then used to disable the pre-emphasis after a short period.

Abstract: A configurable output buffer capable of providing differential drive having complementary pairs of CMOS transistors having a common output terminal and a common control terminal, and with the second terminal of each CMOS transistor connected to its corresponding supply terminal through a current source/sink.