Abstract: A semiconductor memory device includes a row address transition detector. The semiconductor memory device remedies a fault by replacing a column in a memory cell array with a redundancy bit line. The row address transition detector detects a change in a row address signal for selecting the row direction of the memory cell array. Only when a change in the row address signal is detected by the row address transition detector, the redundancy bit line is sensed.

Abstract: A semiconductor device of this invention includes an initialization circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, and a status setting unit for setting the status of the semiconductor device to “busy” during a period in which the initialization circuit performs initialization.

Abstract: A semiconductor device of this invention includes a first circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, a second circuit for controlling the output from the first circuit by activation or deactivation, and an activation control circuit for activating or deactivating the second circuit in accordance with external input.

Abstract: A semiconductor device comprises a first supply voltage pad arranged to apply a first supply voltage; and a second supply voltage pad arranged to apply a second supply voltage for execution of tests. A current detector is operative to detect a current caused from application of the second supply voltage to the second supply voltage pad. A controller is operative to cut off or suppress supply of the second supply voltage to the second supply voltage pad based on a detected output from the current detector.

Abstract: A semiconductor device of this invention includes an initialization circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, and a status setting unit for setting the status of the semiconductor device to “busy” during a period in which the initialization circuit performs initialization.

Abstract: A semiconductor device includes an internal power supply terminal for supplying an internal power supply voltage, an oscillator generating a clock pulse when the internal power supply voltage becomes higher than a first voltage, a charge pump circuit charge pumping upon receiving the clock pulse, a reference voltage generator using the output voltage from the charge pump circuit as a power supply, and a voltage monitor which uses the output voltage from the charge pump circuit as a power supply, has a comparator for comparing a divided voltage of the internal power supply voltage with the reference voltage, and outputs a first signal of a first logic level as the power-on reset signal when the internal power supply voltage is higher than a second voltage. With this arrangement, a power-on reset circuit with little variation in power-on monitoring level can be provided.

Abstract: A semiconductor device of this invention includes an initialization circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, and a status setting unit for setting the status of the semiconductor device to “busy” during a period in which the initialization circuit performs initialization.

Abstract: A power-on reset circuit has a power-on level detecting circuit which detects a power voltage to output a power-on reset signal and a delay circuit which delays the power-on reset signal output by the power-on level detecting circuit. Two chip address specifying pads are connected to the delay circuit. Delay time in the delay time is controlled according to a chip address supplied to these two pads.

Abstract: A semiconductor device includes an internal power supply terminal for supplying an internal power supply voltage, an oscillator generating a clock pulse when the internal power supply voltage becomes higher than a first voltage, a charge pump circuit charge pumping upon receiving the clock pulse, a reference voltage generator using the output voltage from the charge pump circuit as a power supply, and a voltage monitor which uses the output voltage from the charge pump circuit as a power supply, has a comparator for comparing a divided voltage of the internal power supply voltage with the reference voltage, and outputs a first signal of a first logic level as the power-on reset signal when the internal power supply voltage is higher than a second voltage. With this arrangement, a power-on reset circuit with little variation in power-on monitoring level can be provided.

Abstract: A semiconductor integrated circuit includes a limiter circuit for outputting a voltage determining flag in order to set a boosted voltage level of a booster circuit to be a predetermined value, and a monitoring circuit for monitoring a monitoring node of the limiter circuit to output a monitoring signal for the stabilization of a boosted voltage to a first external terminal. The monitoring circuit detects a first level change of the voltage determining flag from “H” to “L” after the starting of the operation of the limiter circuit, by means of a comparator, to which an external power supply voltage and external reference voltage supplied from second and third external terminals are given, and thereafter, outputs a monitoring signal for holding a constant logical level during the operation of the limiter circuit.

Abstract: A semiconductor device includes an internal power supply terminal for supplying an internal power supply voltage, an oscillator generating a clock pulse when the internal power supply voltage becomes higher than a first voltage, a charge pump circuit charge pumping upon receiving the clock pulse, a reference voltage generator using the output voltage from the charge pump circuit as a power supply, and a voltage monitor which uses the output voltage from the charge pump circuit as a power supply, has a comparator for comparing a divided voltage of the internal power supply voltage with the reference voltage, and outputs a first signal of a first logic level as the power-on reset signal when the internal power supply voltage is higher than a second voltage. With this arrangement, a power-on reset circuit with little variation in power-on monitoring level can be provided.

Abstract: A semiconductor device of this invention includes a first circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, a second circuit for controlling the output from the first circuit by activation or deactivation, and an activation control circuit for activating or deactivating the second circuit in accordance with external input.

Abstract: A semiconductor device of this invention includes an initialization circuit for initializing a predetermined circuit in accordance with the level of a power source voltage, and a status setting unit for setting the status of the semiconductor device to “busy” during a period in which the initialization circuit performs initialization.

Abstract: A drain-side select gate line is set to VSG1 (>VDD) capable of sufficiently transferring VDD (time t1). Since all word lines in the selected block are set to Vread, VDD is applied to the channels of all memory cells in the cell units. After this, the drain-side select gate line is set to VSG2, and a program potential Vpgm is applied to the selected word line (times t2 to t3). Since VSG2 is sufficiently low, all drain-side select gate transistors are kept off, and the channel potentials of memory cells in all cell units are boosted. After this, since the drain-side select gate line is set to VSG3, the channel of the selected memory cell is set to 0V (time t4).

Abstract: A semiconductor integrated circuit includes a limiter circuit for outputting a voltage determining flag in order to set a boosted voltage level of a booster circuit to be a predetermined value, and a monitoring circuit for monitoring a monitoring node of the limiter circuit to output a monitoring signal for the stabilization of a boosted voltage to a first external terminal. The monitoring circuit detects a first level change of the voltage determining flag from “H” to “L” after the starting of the operation of the limiter circuit, by means of a comparator, to which an external power supply voltage and external reference voltage supplied from second and third external terminals are given, and thereafter, outputs a monitoring signal for holding a constant logical level during the operation of the limiter circuit.

Abstract: A semiconductor integrated circuit includes a limiter circuit for outputting a voltage determining flag in order to set a boosted voltage level of a booster circuit to be a predetermined value, and a monitoring circuit for monitoring a monitoring node of the limiter circuit to output a monitoring signal for the stabilization of a boosted voltage to a first external terminal. The monitoring circuit detects a first level change of the voltage determining flag from “H” to “L” after the starting of the operation of the limiter circuit, by means of a comparator, to which an external power supply voltage and external reference voltage supplied from second and third external terminals are given, and thereafter, outputs a monitoring signal for holding a constant logical level during the operation of the limiter circuit.

Abstract: A semiconductor device includes an internal power supply terminal for supplying an internal power supply voltage, an oscillator generating a clock pulse when the internal power supply voltage becomes higher than a first voltage, a charge pump circuit charge pumping upon receiving the clock pulse, a reference voltage generator using the output voltage from the charge pump circuit as a power supply, and a voltage monitor which uses the output voltage from the charge pump circuit as a power supply, has a comparator for comparing a divided voltage of the internal power supply voltage with the reference voltage, and outputs a first signal of a first logic level as the power-on reset signal when the internal power supply voltage is higher than a second voltage. With this arrangement, a power-on reset circuit with little variation in power-on monitoring level can be provided.

Abstract: According to the present invention, the semiconductor integrated circuit including the reference current generating circuit free from both the influence of a power supply voltage and the influence of the variation of the threshold voltage of the transistors related to the generation of the reference current. In the reference current generating circuit, a P-channel MOS transistor (Qp1), a N-channel MOS transistor (Qn1), a resistor element (R1), and a N-channel MOS transistor (Qn2) are connected in series between the power supply voltage and the ground. The gate and the drain of the N-channel MOS transistor (Qn2) are connected by a short circuit to output the reference current Iref from a transistor (Qn6) through the resistor element.

Abstract: According to the present invention, the semiconductor integrated circuit including the reference current generating circuit free from both the influence of a power supply voltage and the influence of the variation of the threshold voltage of the transistors related to the generation of the reference current. In the reference current generating circuit, a P-channel MOS transistor (Qp1), a N-channel MOS transistor (Qn1), a resistor element (R1), and a N-channel MOS transistor (Qn2) are connected in series between the power supply voltage and the ground. The gate and the drain of the N-channel MOS transistor (Qn2) are connected by a short circuit to output the reference current Iref from a transistor (Qn6) through the resistor element.

Abstract: A drain-side select gate line is set to VSG1 (>VDD) capable of sufficiently transferring VDD (time t1). Since all word lines in the selected block are set to Vread, VDD is applied to the channels of all memory cells in the cell units. After this, the drain-side select gate line is set to VSG2, and a program potential Vpgm is applied to the selected word line (times t2 to t3). Since VSG2 is sufficiently low, all drain-side select gate transistors are kept off, and the channel potentials of memory cells in all cell units are boosted. After this, since the drain-side select gate line is set to VSG3, the channel of the selected memory cell is set to 0V (time t4).