A master-slave flip-flop includes a first latch, a second latch and a tristate driver. The first latch has a combined input/output that is coupled with a common node, a pm output, and an nm output. The tristate driver has pm and nm inputs coupled with the pm and nm outputs of the first latch, and a tristate output coupled with the common node. A pm input signal prevents the tristate driver from pulling the common node high, and an nm input signal prevents the tristate driver from pulling the common node low. The second latch is directly coupled with the common node. The first latch generates an nm signal and a pm signal in response to a signal on the first latch clk input and a state of the common node, wherein the pm signal and the nm signal have opposite polarities when the signal on the first latch clk input has a first value, and equal polarities when the signal on the first latch clk input has a second value.

A master-slave flip-flop includes a first latch, a second latch and a tristate driver. The first latch has a combined input/output that is coupled with a common node, a pm output, and an nm output. The tristate driver has pm and nm inputs coupled with the pm and nm outputs of the first latch, and a tristate output coupled with the common node. A pm input signal prevents the tristate driver from pulling the common node high, and an nm input signal prevents the tristate driver from pulling the common node low. The second latch is directly coupled with the common node. The first latch generates an nm signal and a pm signal in response to a signal on the first latch clk input and a state of the common node, wherein the pm signal and the nm signal have opposite polarities when the signal on the first latch clk input has a first value, and equal polarities when the signal on the first latch clk input has a second value.

A latch array including a row of master latches coupled to columns of slave latches. Each master latch includes an OR-AND-Inverter (OAI) gate cross-coupled with a NAND gate to receive and latch an input data, and each slave latch includes an AND-OR-Inverter (AOI) gate cross-coupled with a NOR gate to receive and latch the data from the master latch, and an inverter including an input coupled to the AOI gate and an output to produce an output data based on the input data. Alternatively, each master latch includes an AND-OR-Inverter (AOI) gate cross-coupled with a NOR gate to receive and latch an input data, and each slave latch includes an OR-AND-Inverter (OAI) gate cross-coupled with a NAND gate to receive and latch the data from the master latch, and an inverter including an input coupled to the OAI gate and an output to produce an output data.

A latch array including a row of master latches coupled to columns of slave latches. Each master latch includes an OR-AND-Inverter (OAI) gate cross-coupled with a NAND gate to receive and latch an input data, and each slave latch includes an AND-OR-Inverter (AOI) gate cross-coupled with a NOR gate to receive and latch the data from the master latch, and an inverter including an input coupled to the AOI gate and an output to produce an output data based on the input data. Alternatively, each master latch includes an AND-OR-Inverter (AOI) gate cross-coupled with a NOR gate to receive and latch an input data, and each slave latch includes an OR-AND-Inverter (OAI) gate cross-coupled with a NAND gate to receive and latch the data from the master latch, and an inverter including an input coupled to the OAI gate and an output to produce an output data.

Disclosed is a transmitter which includes a channel driver that includes a pull-up transistor and a pull-down transistor connected between a power node and a ground node and outputs a voltage between the pull-up transistor and the pull-down transistor as a transmit signal, and a pre-driver that controls the pull-up transistor and the pull-down transistor in response to a driving signal and controls the channel driver such that the transmit signal is overshot at a rising edge of the driving signal and the transmit signal is undershot at a falling edge of the driving signal.

Disclosed is a transmitter which includes a channel driver that includes a pull-up transistor and a pull-down transistor connected between a power node and a ground node and outputs a voltage between the pull-up transistor and the pull-down transistor as a transmit signal, and a pre-driver that controls the pull-up transistor and the pull-down transistor in response to a driving signal and controls the channel driver such that the transmit signal is overshot at a rising edge of the driving signal and the transmit signal is undershot at a falling edge of the driving signal.

A power-on reset circuit 10 has: an enhancement-type PMOS transistor P1 whose source is connected to VDD and whose drain is connected to node VJG; a depletion-type NMOS transistor D1 whose drain is connected to the node VJG; a first resistor portion having resistors R1, R2 that are connected in series, and whose one end is connected to a source of the depletion-type NMOS transistor D1, and whose another end is connected to GND, and at which a region between the resistors R1, R2 is connected to a gate of the enhancement-type PMOS transistor P1; and an inverter whose input is connected to the node VJG, and that outputs a reset signal.

A power-on reset circuit 10 has: an enhancement-type PMOS transistor P1 whose source is connected to VDD and whose drain is connected to node VJG; a depletion-type NMOS transistor D1 whose drain is connected to the node VJG; a first resistor portion having resistors R1, R2 that are connected in series, and whose one end is connected to a source of the depletion-type NMOS transistor D1, and whose another end is connected to GND, and at which a region between the resistors R1, R2 is connected to a gate of the enhancement-type PMOS transistor P1; and an inverter whose input is connected to the node VJG, and that outputs a reset signal.

The present application discloses an interface transformer. The interface transformer includes a first clock generator, a combinational circuit, and a second clock generator. The first clock generator generates an intermediate clock signal according to an input clock signal. A rising edge of the input clock signal precedes a rising edge of the intermediate clock signal, and a falling edge of the intermediate clock signal precedes a falling edge of the input clock signal. The combinational circuit generates a mask clock signal by delaying the intermediate clock signal. The second clock generator generates a transformed clock signal according to the input clock signal and the mask clock signal. The transformed clock signal has two pulses within a cycle of the input clock signal.

The present application discloses an interface transformer. The interface transformer includes a first clock generator, a combinational circuit, and a second clock generator. The first clock generator generates an intermediate clock signal according to an input clock signal. A rising edge of the input clock signal precedes a rising edge of the intermediate clock signal, and a falling edge of the intermediate clock signal precedes a falling edge of the input clock signal. The combinational circuit generates a mask clock signal by delaying the intermediate clock signal. The second clock generator generates a transformed clock signal according to the input clock signal and the mask clock signal. The transformed clock signal has two pulses within a cycle of the input clock signal.