A MOS IC logic cell includes a plurality of gate interconnects extending on tracks in a first direction. The logic cell includes intra-cell routing interconnects coupled to at least a subset of the gate interconnects. The intra-cell routing interconnects include intra-cell Mx layer interconnects on an Mx layer extending in the first direction. The Mx layer is a lowest metal layer for PG extending in the first direction. The intra-cell Mx layer interconnects extend in the first direction over at least a subset of the tracks excluding every m.sup.th track, where 2≤m<P.sub.PG and P.sub.PG is a PG grid pitch. A MOS IC may include at least one MOS IC logic cell, and may further include a first set of PG Mx layer interconnects extending in the first direction over the at least one logic cell. The first set of PG Mx layer interconnects have the pitch P.sub.PG>m*P.

An off chip driver circuit includes a first power rail, a second power rail, an input/output pad, a pull-up circuit, a pull-down circuit. The pull-up circuit is configured to selectively activate at least one of charging paths between the first power rail and the input/output pad. The pull-up circuit includes a first resistor and PMOS transistors arranged on the charging paths, and the first resistor is coupled between the first power rail and the PMOS transistors. The pull-down circuit is configured to selectively activate at least one of discharging paths between the second power rail and the input/output pad. The pull-down circuit includes a second resistor and NMOS transistors arranged on the discharging paths, and the second resistor is coupled between the second power rail and the NMOS transistors.

The amplitude voltage of a signal input to a level shifter can be increased and then output by the level shifter circuit. Specifically, the amplitude voltage of the signal input to the level shifter can be increased to be output. This decreases the amplitude voltage of a circuit (a shift register circuit, a decoder circuit, or the like) which outputs the signal input to the level shifter. Consequently, power consumption of the circuit can be reduced. Alternatively, a voltage applied to a transistor included in the circuit can be reduced. This can suppress degradation of the transistor or damage to the transistor.

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.

The amplitude voltage of a signal input to a level shifter can be increased and then output by the level shifter circuit. Specifically, the amplitude voltage of the signal input to the level shifter can be increased to be output. This decreases the amplitude voltage of a circuit (a shift register circuit, a decoder circuit, or the like) which outputs the signal input to the level shifter. Consequently, power consumption of the circuit can be reduced. Alternatively, a voltage applied to a transistor included in the circuit can be reduced. This can suppress degradation of the transistor or damage to the transistor.

An integrated circuit, a control method, and a system are provided, to improve reliability of the integrated circuit. The integrated circuit mainly includes a power supply pin (P1), a configuration pin (P4, P5), a switchable pull-up resistor (KR1, KR2), and a control unit (2011). The integrated circuit can provide a control signal for a target chip (202) by using the configuration pin (P4, P5) of the integrated circuit. In the integrated circuit, a first end of the switchable pull-up resistor (KR1, KR2) is connected to the power supply pin (P1), a second end of the switchable pull-up resistor (KR1, KR2) is connected to the configuration pin (P4, P5), and a control end of the switchable pull-up resistor (KR1, KR2) is connected to the control unit (2011). The power supply pin (P1) can receive a power supply voltage of the integrated circuit.

An impedance calibration circuit includes a first code generation circuit connected to a first reference resistor, and configured to generate a first code for forming a resistance based on the first reference resistor, by using the first reference resistor; a second code generation circuit configured to form a resistance of a second reference resistor less than the resistance of the first reference resistor, based on the first code, and generate a second code by using the second reference resistor; and a target impedance code generation circuit configured to generate a target impedance code based on the first code, the second code, and a target impedance value, and form an impedance having the target impedance value in a termination driver connected to the impedance calibration circuit, based on the target impedance code.

To provide a hysteresis comparator having a small circuit area and low power consumption. The hysteresis comparator includes a comparator, a switch, a first capacitor, a second capacitor, and a logic circuit. A first terminal of the switch is electrically connected to one of a pair of conductive regions of the first capacitor, one of a pair of conductive regions of the second capacitor, and a first input terminal of the comparator. An output terminal of the comparator is electrically connected to an input terminal of the logic circuit. An output terminal of the logic circuit is electrically connected to the other of the pair of conductive regions of the second capacitor. The logic circuit has a function of generating an inverted signal of a signal input to the input terminal of the logic circuit and outputting the inverted signal to the output terminal of the logic circuit. A reference potential is input to the first input terminal of the comparator and the reference potential is held by the switch. Due to change in the potential of the output terminal of the comparator, the reference potential is changed by capacitive coupling of the second capacitor.

A differential communication driver circuit includes a drive unit that drives differential signal lines connected via capacitors by a source current and a sink current. When a noise detection unit detects that in-phase noise is applied to the differential signal lines, a drive assisting unit maintains an amplitude of a differential signal output to the differential signal lines by increasing a current drive capability of the sink current.

The present invention discloses a differential signal amplification circuit as well as a digital isolator and a digital receiver applying the differential signal amplification circuit, wherein the differential signal amplification circuit includes a multi-stage differential amplifier and a common-mode transient adaptive biasing circuit. The common-mode transient adaptive biasing circuit is configured to detect a positive or negative common-mode transient interference signal at a positive input terminal and a negative input terminal, and provide a biasing current of a differential amplifier of at least one stage above a second stage when the positive or negative common-mode transient interference signals are detected. With the technical solutions of the present invention, abnormal signal transmission caused by the common-mode interference signals can be suppressed.