Abstract: A sense amplifier, which is intended to reduce the output response time after it has received a small voltage difference until it delivers amplified output signals, consists of a latch circuit made up of a pair of CMOS inverters, a pair of NMOS transistors connected in parallel to the latch circuit, and a current source connected in series to the latch circuit and NMOS transistor pair. The NMOS transistors amplify a small voltage difference of input signals, and the inverters of the latch circuit further amplify the resulting voltage difference to produce the output signals. Based on a small voltage difference of input signals being amplified in two stages and the amplifying circuit being 2-stage serial connection of the current source and the NMOS transistor or CMOS inverter, the delay time of output response can be reduced.

Abstract: A sense amplifier, which is intended to reduce the output response time after it has received a small voltage difference until it delivers amplified output signals, consists of a latch circuit made up of a pair of CMOS inverters, a pair of NMOS transistors connected in parallel to the latch circuit, and a current source connected in series to the latch circuit and NMOS transistor pair. The NMOS transistors amplify a small voltage difference of input signals, and the inverters of the latch circuit further amplify the resulting voltage difference to produce the output signals. Based on is a small voltage difference of input signals being amplified in two stages and the amplifying circuit being a 2-stage serial connection of the current source and the NMOS transistor or CMOS inverter, the delay time of output response can be reduced.

Abstract: A semiconductor memory device is provided which is able to supply data at high speed to a microprocessor (MPU) without being affected by the dispersion of power supply voltage, temperature and production process conditions. A semiconductor chip includes an address buffer, a decoder, a word driver, data lines, a sense amplifier, a main amplifier, an output buffer, and a PLL to which an external clock is applied. The PLL generates controls signals .PHI..sub.1 through .PHI..sub.7 with their phases shifted in turn, and supplies them to those internal circuits ranging from the address buffer to the output buffer. The PLL can control the phases of these control signals to be constant without being affected by the variations of temperature and power supply voltage. Thus, the internal circuits are precharged or equalized by the control signals, and then operated by the control signals to amplify data signal in turn.

Abstract: A sense amplifier, which is intended to reduce the output response time after it has received a small voltage difference until it delivers amplified output signals, consists of a latch circuit made up of a pair of CMOS inverters, a pair of NMOS transistors connected in parallel to the latch circuit, and a current source connected in series to the latch circuit and NMOS transistor pair. The NMOS transistors amplify a small voltage difference of input signals, and the inverters of the latch circuit further amplify the resulting voltage difference to produce the output signals. Based on is a small voltage difference of input signals being amplified in two stages and the amplifying circuit being of 2-stage serial connection of the current source and the NMOS transistor or CMOS inverter, the delay time of output response can be reduced.

Abstract: A semiconductor memory device is provided which is able to supply data at high speed to a microprocessor (MPU) without being affected by the dispersion of power supply voltage, temperature and production process conditions. A semiconductor chip includes an address buffer, a decoder, a word driver, data lines, a sense amplifier, a main amplifier, an output buffer, and a PLL to which an external clock is applied. The PLL generates controls signals .PHI..sub.1 through .PHI..sub.7 with their phases shifted in turn, and supplies them to those internal circuits ranging from the address buffer to the output buffer. The PLL can control the phases of these control signals to be constant without being affected by the variations of temperature and power supply voltage. Thus, the internal circuits are precharged or equalized by the control signals, and then operated by the control signals to amplify data signal in turn.

Abstract: A semiconductor static memory device, which has an increased storage capacity without imposing an increased access time, includes first, second and third metallic layers. To begin, word lines for the transfer MOSFETS are formed of the same polysilicon layer used to form the gate electrodes of the transfer MOSFETs of the memory device. A metallic layer of the first layer is used for local word lines, with the polysilicon word lines and local word lines being connected at their ends or inside of cell arrays. A metallic layer of the second layer is used for bit layers, and a metallic layer of the third layer is used for main word lines. Consequently, the word lines have a decreased time constant, allowing fast memory access. Each of sense amplifiers used in the memory device are formed with MOSFETs, which are disposed divisionally in adjacent locations. Preferably the gate electrodes of the divided MOSFETs are located symmetrically.

Abstract: In a semiconductor memory device, amplification of data is realized with a high speed without influences of fluctuations at fabrication. Potentials of a common data line pair are set at a reference voltage by current negative feedback of differential amplifiers. In this way signal amplitude in the common data line pair is decreased. A current from a memory cell is transformed into a voltage by transistors in a negative feedback loop. Even if there are fluctuations or an offset voltage in the differential amplifiers, it is possible to decrease the signal amplitude in the common data line pair and to realize a high speed data amplification with low electric power consumption.

Abstract: A semiconductor static memory device, which has an increased storage capacity without imposing an increased access time, includes first, second and third metallic layers. To begin, word lines for the transfer MOSFETS are formed of the same polysilicon layer used to form the gate electrodes of the transfer MOSFETs of the memory device. A metallic layer of the first layer is used for local word lines, with the polysilicon word lines and local word lines being connected at their ends or inside of cell arrays. A metallic layer of the second layer is used for bit layers, and a metallic layer of the third layer is used for main word lines. Consequently, the word lines have a decreased time constant, allowing fast memory access. Each of sense amplifiers used in the memory device are formed with MOSFETs, which are disposed divisionally in adjacent locations. Preferably the gate electrodes of the divided MOSFETs are located symmetrically.