A semiconductor device includes a first chip and a second chip. The first chip includes a first circuit having a first output terminal. The second chip includes a second circuit having a second output terminal, which is electrically connected to the first output terminal via a first signal line. When the first chip and the second chip receive a first command, the second circuit calibrates an output impedance at the second output terminal through a first calibration operation based on an output impedance at the first output terminal.

An input/output driving circuit may include a pad, an open-drain driving circuit, a high-voltage protection unit and a control unit. The pad is for transmitting and receiving signals. The open-drain driving circuit may output a transmission signal to the pad. The high-voltage protection unit may input a received signal from the pad. The control unit may control the open-drain driving circuit and the high-voltage protection unit. The control unit may include a gate control logic, a transmission control logic and an inverter. The gate control logic may receive a voltage of the pad and output a feedback voltage to the open-drain driving circuit. The transmission control logic may receive a clock signal and an enable signal, and transfer a first control signal to the open-drain driving circuit. The inverter may invert the enable signal and transfer an inverted enable signal to the gate control logic.

A nonvolatile memory device includes a first memory structure. The first memory structure includes first through N-th memory dies that may be connected to an external memory controller via a first channel. N is a natural number equal to or greater than two. At least one of the first through N-th memory dies is configured to be used as a first representative die that performs an on-die termination (ODT) operation while a data write operation is performed for one of the first through N-th memory dies.

Memory including an array of memory cells might include an input buffer having calibration circuitry, a first input, a second input, and an output; and calibration logic having an input selectively connected to the output of the input buffer and comprising an output connected to the calibration circuitry, wherein the calibration logic is configured to cause the memory to determine whether the input buffer exhibits offset while a particular voltage level is applied to the first and second inputs of the input buffer, and, in response to determining that the selected input buffer exhibits offset, apply an adjustment to the calibration circuitry while the particular voltage level is applied to the first and second inputs until a logic level of the output of the selected input buffer transitions.

An apparatus is provided, where the apparatus includes a first transistor coupled between a supply node and an output node; a resistor and a second transistor coupled in series between the output node and a ground terminal; a circuitry to receive data, and to output a first control signal and a second control signal to respectively control the first transistor and the second transistor, wherein an output signal at the output node is indicative of the data, and wherein the first transistor is a N-type transistor.

A semiconductor memory device has an output driving circuit. The output driving circuit includes a pull-down driver and a gate control logic. The pull-down driver includes first and second transistors. The first and second transistors are coupled between a pad and a ground node. The gate control logic includes third and fourth transistors. The third and fourth transistors are coupled between a pad and a first supply voltage node. The gate control logic is configured to receive a voltage of the pad and output a feedback voltage. The first transistor is controlled by the feedback voltage. The second and third transistors are controlled by the first supply voltage. The fourth transistor is controlled by the voltage of the pad.

A semiconductor device which includes a termination circuit coupled to a first pad and suitable for providing a termination resistance according to a first control code and a second control code during a normal operation in which data are input and output through the first pad; a stress replica circuit suitable for replicating a stress applied to the termination circuit during the normal operation and for generating a detection code during a second calibration mode; a first calibration circuit suitable for adjusting the first control code to match an impedance of a resistor part coupled to a second pad to an external resistor during a first calibration mode; and a second calibration circuit suitable for generating the second control code by adjusting the first control code according to the detection code during the second calibration mode.

A semiconductor system includes a semiconductor apparatus and an external apparatus. The semiconductor apparatus includes a calibration code generating circuit, a code shifting circuit, and a main driver. The calibration code generating circuit performs a calibration operation to generate a calibration code. The code shifting circuit changes, based on a shifting control signal, a value of the calibration code. A resistance value of the main driver may be set on the basis of the calibration code and a shifted calibration code. The external apparatus generates the shifting control signal based on the resistance value of the main driver.

A semiconductor system includes a semiconductor apparatus and an external apparatus. The semiconductor apparatus includes a calibration code generating circuit, a code shifting circuit, and a main driver. The calibration code generating circuit performs a calibration operation to generate a calibration code. The code shifting circuit changes, based on a shifting control signal, a value of the calibration code. A resistance value of the main driver may be set on the basis of the calibration code and a shifted calibration code. The external apparatus generates the shifting control signal based on the resistance value of the main driver.

The present disclosure generally relates to apparatuses and methods for transmission line termination. In one embodiment an apparatus includes a stack of uniform memory dies and a storage controller. Each uniform memory die in the stack of uniform memory dies couples to a transmission line in series through wire bonds to form a transmission path. Each memory die includes an on-die termination resistance circuit connected to the transmission line. The on-die termination resistance circuit provides a minimum termination resistance. The storage controller addresses a target uniform memory die of the stack of uniform memory dies for an operation. The storage controller enables the on-die termination resistance circuits of a plurality of uniform memory dies along the transmission path. The storage controller transmits a data signal for the operation to the target uniform memory die with the on-die termination resistance circuit enabled for the plurality of uniform memory dies.