A signal transmitting and receiving apparatus including: a first on-die termination circuit connected to a first pin through which a first signal is transmitted or received and, when enabled, the first on-die termination circuit is configured to provide a first termination resistance to a signal line connected to the first pin; a second on-die termination circuit connected to a second pin through which a second signal is transmitted or received and, when enabled, the second on-die termination circuit is configured to provide a second termination resistance to a signal line connected to the second pin; and an on-die termination control circuit configured to independently control an enable time and a disable time of each of the first on-die termination circuit and the second on-die termination circuit.

A processor circuit sends a read request. A clock signal of the processor circuit corresponds to a first counting value. A memory circuit stores data and sends a data strobe signal in response to the read request. The data strobe signal corresponds to a second counting value. The processor circuit includes a selector circuit and a feedback circuit. The selector circuit selects and outputs a flag signal from a plurality of flag control signals according to the second counting value. The feedback circuit generates an enable signal according to a set signal associated with the first counting value, the flag signal associated with the second counting value, and a data strobe gate signal, and generates the data strobe gate signal according to the enable signal and the data strobe signal. The processor circuit reads the data according to the data strobe gate signal.

Apparatuses including an impedance code selector are disclosed. An example apparatus according to the disclosure includes an impedance calibration circuit, an impedance code selector and a driver circuit in a data input/output circuit. The impedance calibration circuit provides a first impedance code. The impedance code selector provides either the first impedance code or a second impedance code. The driver circuit receives either the first impedance code or the second impedance code from the impedance code selector.

This document describes apparatuses and techniques for termination for single-ended (SE) mode operation of a memory device. In various aspects, a termination circuit can terminate an unused signal line of a differential pair to a ground or power rail using a switch element when operating in the SE mode. The termination circuit may also disconnect the unused signal line from a first input of a differential amplifier and connect a reference voltage to the first input of the differential amplifier. Based on the reference voltage, the differential amplifier amplifies an SE signal received using another signal line of the differential pair at a second input of the differential amplifier to provide a clock signal for memory operations. Thus, the termination circuit may reduce an amount by which noise associated with the unused signal line affects the differential amplifier when the memory device operates in SE mode.

A semiconductor system includes a controller configured to apply a command address, a first chip selection signal, and a second chip selection signal, and a semiconductor device including a first rank and a second rank configured to calibrate each termination resistance, based on the command address, the first chip selection signal, and the second chip selection signal.

A semiconductor die includes a first pin configured to output a first on-die termination (ODT) control signal to a second semiconductor die, the second semiconductor die comprising a plurality of second ODT circuits each having an ODT that is responsive to the first ODT control signal; and a second pin configured to receive a second ODT control signal output from the second semiconductor die, the semiconductor die comprising a plurality of first ODT circuits each having an ODT that is responsive to the second ODT control signal.

An integrated circuit with self-reference impedance includes an input/output pin provided for connection to an external impedance, a local impedance, a reference power circuit, a switching circuit, and a control circuit. The switching circuit is configured to conduct a connection between the input/output pin and the reference power circuit in a first state and to conduct a connection between the local impedance and the reference power circuit in a second state. The control circuit is configured to detect whether the external impedance is connected to the input/output pin or not and to generate a detection signal. The control circuit controls the switching circuit into the first state or the second state according to the detection signal. In the first state, the reference power circuit generates a reference signal according to the external impedance. In the second state, the reference power circuit generates the reference signal according to the local impedance.

A semiconductor storage device including an output pad, a first circuit connected to the output pad, a second circuit connected to the first circuit, a third circuit configured to output a first setting signal for controlling the first circuit accordance with a characteristic variation of the first circuit, and a fourth circuit configured to generate a second setting signal for controlling the second circuit in accordance with the first setting signal received from the third circuit and output the second setting signal to the second circuit.

Main wiring including a plurality of differential transmission lines for transmitting differential signals is formed on a motherboard. Termination resistors, provided at both ends of each of the plurality of differential transmission lines, connect the plurality of differential transmission lines to each other. A plurality of daughter boards are connected in parallel to each other via the main wiring. A line characteristic impedance of each differential transmission line is higher than a termination resistance value, which is a resistance value of the termination resistor.

In an integrated circuit component having a command interface to receive commands, a data interface to receive write data during a write-data reception interval, and first and second registers, control circuitry within the integrated circuit component responds to one or more of the commands by storing within the first register and the second register, respectively, a first control value that specifies a first termination to be applied to the data interface during the write-data reception interval, and a second control value that specifies a second termination to be applied to the data interface after the write-data reception interval transpires.