Abstract: A semiconductor memory device includes a bank, a data transfer line, a precharge control circuit, and a precharge line. The bank includes a multiplicity of cell mats arranged in a matrix form. Each of the cell mats has a plurality of unit cells. The data transfer line arranged between the cell mats transfers a data signal outputted from a selected cell mat among the cell mats. The precharge control circuit disposed on the edge of the bank controls the precharge of the data transfer line. The precharge line arranged between first and second cell mats transfers a precharge voltage to the precharge control circuit. The first and the second cell mats are disposed in the center of the bank.

Abstract: There is an internal voltage generating circuit for providing a stable high voltage by making a response time short. The internal voltage generating circuit includes a charge pump unit for generate a high voltage being higher than an external voltage in response to pumping control signals and a supply driving control signal; a pumping control signal generating unit for outputting the pumping control signals to the charge pump unit based on a driving signal; and a supply driving control unit for receiving the driving signal to generate the supply driving control signal to the charge pump unit.

Abstract: A latch structure includes a first inverter that includes a first PMOS transistor and a first NMOS transistor, and a second inverter that includes a second PMOS transistor and a second NMOS transistor, receives an output signal of the first inverter, and outputs an input signal to the first inverter. The sources of the first and second transistors of the same type are connected to a common straight source line.

Abstract: A circuit for outputting temperature data of a semiconductor memory apparatus includes a temperature detecting circuit that generates a temperature voltage corresponding to a change in temperature and outputs the temperature voltage, an A/D converter that converts the temperature voltage into a first temperature code and outputs it, and a temperature data correcting unit that outputs a second temperature code obtained by correcting an error of the first temperature code using a correction code.

Abstract: An impedance adjusting circuit includes: a first calibration resistor circuit configured to be calibrated with an external resistor and generate a first calibration code; a second calibration resistor circuit configured to be calibrated with the first calibration resistor circuit and generate a second calibration code, the second calibration resistor circuit being connected to a first node; and a transmission line circuit configured to be responsive to a control signal to connect the first node to a pin of a system employing the impedance adjusting circuit.

Abstract: A word line driver, a method for driving the word line driver, and a semiconductor memory device having the word line driver. The word line driver receives a main word line driving signal and a sub word line driving signal, to drive a word line with a word line driving signal, wherein the word line is driven concurrently with an activation of the main word line driving signal. The word line driver can reduce the unnecessary current consumption.

Abstract: A semiconductor memory device that prevents a power noise generated at a data input/output pad in a read operation from affecting a data strobe signal pad. The semiconductor memory device includes first power supply voltage pads for a data output circuit, a first power mesh, and a second power supply voltage pad for a data strobe signal output circuit. The first power mesh connects first power supply voltage pads to one another. The second power supply voltage pad is electrically separated from the first power mesh.

Abstract: Embodiments of the present invention are directed to provide an internal voltage generator of a semiconductor memory device for generating a predetermined stable level of an internal voltage. The semiconductor memory device includes a control signal generator, an internal voltage generator and an internal voltage compensator. The control signal generator generates a reference signal and a compensating signal which are corresponding to voltage level of the reference signal. The internal voltage generator generates an internal voltage in response to the reference signal. The internal voltage compensator compensates the internal voltage in response to the compensating signal.

Abstract: An input buffer includes a delay compensation unit for combining (a) a first signal obtained by buffering an input signal using another signal, which is out of phase with the input signal, with (b) a second signal obtained by buffering the input signal using a reference voltage signal, to output a third signal.

Abstract: A voltage generator includes a bias signal generator generating first to fourth bias signals using a reference voltage, the first to fourth bias signals having different voltage levels. A driving signal generator receives the first and third bias signals to generate a pull-up signal in response to a voltage level of an output terminal and receiving the second and fourth bias signals to generate a pull-down signal in response to a voltage level of the output terminal. A voltage driver pulls up and pulls down a voltage level of the output terminal in response to the respective pull-up and pull-down signals. An auxiliary driving controller disables the pull-up signal when the voltage level of the output terminal is greater than that of the reference voltage and the pull-down signal when the voltage level of the output terminal is less than that of the reference voltage.

Abstract: Embodiments of the present invention are directed to provide an internal voltage generator of a semiconductor memory device for generating a predetermined stable level of an internal voltage. The semiconductor memory device includes a control signal generator, an internal voltage generator and an internal voltage compensator. The control signal generator generates a reference signal and a compensating signal which are corresponding to voltage level of the reference signal. The internal voltage generator generates an internal voltage in response to the reference signal. The internal voltage compensator compensates the internal voltage in response to the compensating signal.

Abstract: Disclosed are a power supply circuit for an oscillator of a semiconductor memory device and a voltage pumping device using the same. In the power supply circuit, a voltage divider divides a voltage between an external power supply and ground. A driver is controlled by a signal of the voltage divided by the voltage divider. The driver supplies an internal power supply voltage. A capacitor is coupled between the driver and the ground. As the level of an external power supply voltage is increased, a relatively low voltage is supplied to the oscillator to increase a cycle length of an output pulse signal of the oscillator. Therefore, an excessive increase in the internal power supply voltage due to over-pumping can be avoided and noise occurrence and electric current consumption can be reduced.

Abstract: The present invention provides voltage supplier for supplying an internal voltage with optimized drivability required for internal operation. The voltage supplier of a semiconductor memory device includes: an internal voltage detection means for detecting a voltage level of an internal voltage; a clock oscillation means for outputting a charge pumping clock signal; an internal voltage control means for controlling the clock oscillation means to be performed selectively in accordance with a data access mode or a non-data access mode; and a charge pumping means for outputting the internal voltage required for internal operation by pumping charges in response to the charge pumping clock signal.

Abstract: A semiconductor device and a layout method of the same reduce a mismatch in a semiconductor device. The semiconductor device includes a first transistor unit providing a first path of current and a second transistor unit designed in a mirror structure to the first transistor unit and providing a second path of current. The layout of the second transistor unit has a shape identical to the first transistor unit and shifted in a first direction. The layout of the semiconductor device reduces a mismatch of the transistors occurring when masks are combined, and thereby reduces their offset.

Abstract: A semiconductor memory device has a simple layout pattern of a sub hole region. The semiconductor memory device includes a segment input/output line, a first local input/output line and a second local input/output line corresponding to the segment input/output line, an input/output switch configured to selectively connect the segment input/output line and the first local input/output line in response to a first switch control signal, and a dummy input/output switch which is connected to a second local input/output line but is not connected to the segment input/output line.

Abstract: There is an internal voltage generating circuit for providing a stable internal voltage by supplying the internal voltage before a time point when it is used. The internal voltage generating circuit includes a charge pump unit for generating an internal voltage lower than an external voltage in response to pumping control signals and a supply driving control signal; a pumping control signal generating unit for outputting the pumping control signals to the charge pump unit based on a driving signal; and a supply driving control unit for receiving the driving signal to generate the supply driving control signal to the charge pump unit.

Abstract: An impedance adjusting circuit includes: a first calibration resistor circuit configured to be calibrated with an external resistor and generate a first calibration code; a second calibration resistor circuit configured to be calibrated with the first calibration resistor circuit and generate a second calibration code, the second calibration resistor circuit being connected to a first node; and a transmission line circuit configured to be responsive to a control signal to connect the first node to a pin of a system employing the impedance adjusting circuit.

Abstract: A semiconductor memory device employs a clamp for preventing latch up. For the purpose, the semiconductor memory device includes a precharging/equalizing unit for precharging and equalizing a pair of bit lines, and a control signal generating unit for producing a control signal which controls enable and disable of the precharging/equalizing unit, wherein the control signal generating unit includes a clamping unit to clamp its source voltage to a voltage level lower than that of its bulk bias.

Abstract: An internal voltage generator according to the present invention stably supplies an internal voltage regardless a level of power voltage input from a source external to a semiconductor memory device. The present invention includes a dead zone controller to generate a reference voltage, a high reference voltage and a low reference voltage based on an inputted power voltage; and an internal power generator to generate an internal power based on the reference voltage by comparing the internal power with the high reference voltage and the low reference voltage.

Abstract: Disclosed is a controller for driving current of a semiconductor device having an over-driving function, the controller comprising: a load means supplied with an internal voltage; a plurality of switching means, each of which has a first terminal connected to an external voltage and a second terminal connected to the load means, wherein at least one of the plurality of switching means is selectively turned on/off according to an voltage level of the external voltage.