Abstract: A semiconductor memory device for sensing voltages of bit lines in high speed includes: a first bit line pair to a fourth bit line pair each coupled to a different unit cell array; a bit line sense amplifying unit coupled to the first bit line pair to the fourth bit line pair for amplifying data transmitted through the first bit line pair to the fourth bit line pair; and a switching block for connecting one of the first bit line pair to the fourth bit line pair with the bit line sense amplifying unit in response to a control signal.

Abstract: A reference voltage selecting unit selectively outputs a first external reference voltage and a second external reference voltage as a selection reference voltage in accordance with whether to perform a wafer test. An address buffer generates an internal address by buffering an external address in accordance with the selection reference voltage. A command buffer generates an internal command by buffering an external command in accordance with the selection reference voltage. A data buffer generates internal data by buffering an external data in accordance with the second external reference voltage.

Abstract: A semiconductor memory device that includes a first high voltage oscillator configured to generate a first control pulse in response to a first enable signal, a level shifter configured to generate a high voltage control pulse by boosting a level of the first control pulse using a source high voltage, and a first high voltage generator configured to generate a high voltage by boosting an external power supply voltage in response to the high voltage control pulse.

Abstract: A semiconductor memory device is capable of reducing a test time by sharing input pins of addresses for the test, thereby reducing test costs also. The semiconductor memory device includes first and second address buffer units. The first address buffer unit is configured to transmit a plurality of normal addresses to an internal circuit and store one or more of the received normal addresses. The second address buffer unit is configured to transmit one or more external bank addresses to the internal circuit as internal bank addresses in a normal mode and transmit addresses stored in the first address buffer unit to the internal circuit as the internal bank addresses in a test mode.

Abstract: A semiconductor device includes an internal circuit configured to receive a first power supply voltage applied via a first power input terminal through a first power supply path and receive an internal power supply voltage to perform a predetermined circuit operation and an internal power supply voltage generator configured to receive a second power supply voltage for a power circuit applied via a second power input terminal through a second power supply path and generate the internal power supply voltage, wherein the second power supply path is separated from the first power supply path.

Abstract: A semiconductor memory device is capable of measuring internal voltages via a shared pad to reduce a chip size. The semiconductor memory device includes a selector and a monitoring pad. The selector is configured to select one of a plurality of internal signals in response to a test signal and output the selected internal signal. The monitoring pad is configured to output an output signal of the selector to an outside of the semiconductor memory device.

Abstract: A circuit for generating a voltage of a semiconductor memory apparatus includes a control unit that outputs a driving control signal in response to an enable signal and a burn-in signal, a first voltage generating unit that generates and outputs a first voltage in response to the enable signal, and a voltage maintaining unit that maintains the first voltage in response to the driving control signal.

Abstract: A semiconductor memory device can stabilize a voltage level of a normal driving voltage terminal in a normal driving operation, which is performed after an overdriving operation, even when an overdriving voltage is unstable due to environmental factors of the semiconductor memory device in the overdriving operation. The semiconductor memory device includes a bit line sense amplifier for performing an amplification operation using a normal driving voltage or an overdriving voltage to sense and amplify data applied to bit lines, a normal driving voltage compensator configured to drive a normal driving voltage terminal according to a voltage level of the normal driving voltage terminal and target normal driving voltage levels, and a discharge enable signal generator configured to generate a discharge enable signal by adjusting an activation period of the discharge enable signal according to the overdriving voltage.

Abstract: A semiconductor memory apparatus includes: a driving controller that decodes bank activating signals to generate a plurality of driving control signals, activates some of the driving control signals, and outputs the activated driving signals; and a plurality of internal voltage generators each of which outputs an internal voltage in response to a reference voltage and the corresponding driving control signal and is disposed between two different banks among a plurality of banks.

Abstract: A semiconductor device in which a decoupling capacitor is formed by supplying different power levels to a guard ring device is disclosed. The semiconductor device includes a guard ring, having conductive rings, which surrounds a memory chip. The conductive rings are stacked in a multiplayer structure, and insulation layers are formed between the conductive rings. Voltages of different levels are applied to adjacent conductive rings.

Abstract: A semiconductor memory device can stabilize a voltage level of a normal driving voltage terminal in a normal driving operation, which is performed after an overdriving operation, even when an overdriving voltage is unstable due to environmental factors of the semiconductor memory device in the overdriving operation. The semiconductor memory device includes a bit line sense amplifier for performing an amplification operation using a normal driving voltage or an overdriving voltage to sense and amplify data applied to bit lines, a normal driving voltage compensator configured to drive a normal driving voltage terminal according to a voltage level of the normal driving voltage terminal and target normal driving voltage levels, and a discharge enable signal generator configured to generate a discharge enable signal by adjusting an activation period of the discharge enable signal according to the overdriving voltage.

Abstract: A circuit for generating a voltage of a semiconductor memory apparatus includes a control unit that outputs a driving control signal in response to an enable signal and a burn-in signal, a first voltage generating unit that generates and outputs a first voltage in response to the enable signal, and a voltage maintaining unit that maintains the first voltage in response to the driving control signal.

Abstract: A semiconductor memory device includes a bit line sense amplifying block that senses and amplifies bit line data. A first driving block drives a pull up power line of the bit line sense amplifying block using a voltage applied to a normal driving voltage terminal. A second driving block drives the normal driving voltage terminal using an over driving voltage. An over driving signal generation block generates an over driving signal that defines an over driving interval in response to an active command. An external power supply voltage level detection block detects a voltage level of the external power supply voltage. A selective output block selectively outputs the over driving signal in response to an output signal of the external power supply voltage level detection block, wherein an output signal of the selective output block controls the second driving block.

Abstract: An internal voltage generating circuit of a semiconductor memory apparatus includes a first voltage generating unit to output a first output voltage to a common node, the first output voltage is generated in response to a first reference voltage, and a second voltage generating unit to output a second output voltage to the common node, the second output voltage is generated in response to a second reference voltage.

Abstract: A semiconductor memory apparatus includes an active signal generation unit that generates a plurality of active signals having different enable timings in response to a refresh signal, a precharge signal generation unit that delays at least one of the active signals to generate at least one precharge signal for enabling at least two equalizer signals at the same time, and a sense amplifier driver control unit that generates the plurality of equalizer signals for controlling individual sense amplifier drivers in response to the plurality of active signals and the precharge signal.

Abstract: An over-driver control signal generating apparatus includes a pulse generating unit for generating a pulse signal having a pulse width corresponding to a desired over-driving interval in response to an over-driving signal; a supply voltage level detecting unit for detecting a voltage level of a supply voltage to generate a detecting signal; and a selecting unit for outputting the pulse signal as a bit line over-driver control signal in response to the detecting signal.

Abstract: A charge driving circuit and a discharge driving circuit occupy a relatively small area and maintain driving force in a semiconductor memory device having a plurality of banks. The semiconductor memory device includes multiple banks, a common discharge level detector configured to detect a voltage level of internal voltage terminals on the basis of a first target level in response to active signals corresponding to the respective banks, and a discharge drivers assigned to the respective banks. The discharge drivers are configured to drive the internal voltage terminals to be discharged in response to the respective active signals and respective discharge control signals outputted from the common discharge level detector.

Abstract: A voltage sensing circuit is capable of controlling a pumping voltage to be stably generated in a low voltage environment. The voltage sensing circuit includes a current mirror having first and second terminals, a first switching element configured to control current on the first terminal of the current mirror by a reference voltage, a second switching element configured to control current from the second terminal of the current mirror in response to a pumping voltage, and a third switching element configured to control current sources of the first and second switching elements to receive a negative voltage.

Abstract: Semiconductor memory device and method of operating the same includes an enable signal generator configured to generate first and second enable signals having activation timings determined in response to activation of an active command, the first enable signal being deactivated after a first time from a deactivation timing of the active command, and the second enable signal being deactivated after a second time longer than the first time from the deactivation timing of the active command. Internal voltage generators are configured to generate internal voltages. At least one of the internal voltage generators is turned on/off in response to the first enable signal, and at least one other of the internal voltage generators is turned on/off in response to the second enable signals.

Abstract: A semiconductor memory device includes a voltage detector configured to detect a level of an external power supply voltage and an internal voltage generator configured to generate an internal voltage in response to an active signal and drive an internal voltage terminal with a driving ability corresponding to an output signal of the voltage detector. A method for operating the semiconductor memory device includes detecting a level of an external power supply voltage, based on a first target level, to output a detection signal; and generating an internal voltage in response to an active signal, and driving an internal voltage terminal with a driving ability corresponding to the detection signal.