Abstract: A SRAM of complete CMOS type having its memory cell composed of six MISFETs, in which a pair of local wiring lines for connecting the input/output terminals of CMOS inverters are formed of a refractory metal silicide layer formed over a first conducting layer constituting the individual gate electrodes of the drive MISFETs, the transfer MISFETs and the load MISFETs of the memory cell and in which a reference voltage line formed over the local wiring lines is arranged to be superposed over the local wiring lines to form a capacity element. Moreover, the capacity element is formed between the local wiring lines and the first conducting layer by superposing the local wiring lines over the first conducting layer. Moreover, the local wiring lines are formed by using resistance lowering means such as silicification. In addition, there are made common the means for lowering the resistance of the gate electrode of the transfer MISFETs and the means for forming the local wiring lines.

Abstract: A combination mode a data transfer for a transfer source and a transfer destination is previously defined by a value of resource select information of a control register (CHCRn). An address comparator circuit (SACn, DACn) has judging logic specified by the defined contents and detects, depending on its logical structure, a data transfer address error in the data transfer controller (8) on the basis of such logical structure, in accordance with resource select information and the transfer source address and transfer destination address of the address registers (SARn, DARn). Since the data transfer is started only when the resource select information matches with the setting information of both address registers, high reliability can be assured for memory protection in the data transfer operation by the data transfer controller.

Abstract: There is produced a first internal voltage having a difference relative to a power supply voltage, the difference being substantially equal to a threshold voltage of an address selection MOSFET of a dynamic memory cell. The first voltage is supplied to a sense amplifier as an operating voltage on a high-level side thereof. There is produced a second internal voltage having a predetermined difference relative to a circuit ground potential. The second voltage is supplied to the sense amplifier as an operating voltage on a low-level side thereof. A write signal having a high level corresponding to the first internal voltage and a low level corresponding to the second internal voltage is generated by a write amplifier to be transferred to a pair of complementary data lines connected to the dynamic memory cell. A high level, e.g., the power supply voltage representing a selection level and a low level, e.g.

Abstract: In a semiconductor memory device having a plurality of memory cells in which each memory cell is formed of an address selection MOSFET and an information storing capacitor and the plate voltage consisting of an intermediate potential is supplied to the common electrode of the information storing capacitor, the memory access is enabled by detecting indirect that the plate voltage has reached the predetermined potential near the intermediate potential with the voltage detecting circuit or timer circuit, inhibiting the selecting operation of the word lines or precharging the pair bit lines to the intermediate potential when the plate voltage is lower than the predetermined potential, and then canceling the above inhibit condition after the plate voltage has reached the predetermined potential.

Abstract: In a process for the fabrication of a semiconductor integrated circuit using a double-side mirror-polished wafer or the like, at the portion of a notch 10 of a notched wafer 1, a chamfered angle &thgr;11 of the first chamfered portion 11 formed at the inner periphery of the first primary surface 3 is set smaller than the chamfered angle &thgr;12 of the second notch chamfered portion 12 of the second primary surface 4 and the chamfered width L11 is set larger than the chamfered width L12, whereby the obverse and reverse of the wafer are discriminated by optically discriminating the first notch chamfered portion and the second notch chamfered portion using reflected light, thereby making it certain to fabricate IC on the surface of the wafer and to use the reverse for its handling.

Abstract: A control of a flash memory includes control for supplying a pulse-shaped voltage to each of non-volatile memory cells until a threshold voltage of the non-volatile memory cell having a first threshold voltage is changed to a second threshold voltage. The control involves a first write mode (coarse write) in which the amount of change in threshold voltage of each non-volatile memory cell, which is varied each time the pulse-shaped voltage is applied, is relatively rendered high, and a second write mode (high-accuracy write) in which the amount of change in threshold voltage thereof is relatively rendered low. As compared with the high-accuracy mode, the number of pulses required to change the threshold voltage of each memory cell is smaller than that in the coarse write mode. Therefore, the number of verify operations at the time that the coarse write mode is used, is small and hence the entire write operation can be speeded up.

Abstract: A nonvolatile semiconductor memory recovers variation in the threshold of a memory cell due to disturbance related to a word line. The nonvolatile memory continuously performs many writing operations without carrying out single-sector erasing after each writing operation, performing the additional writing operations quicker than the usual writing operation, and lightening the burden imposed on software for use in additional writing. The data stored in a designated sector is read out before being saved in a register, and the selected sector is subjected to single-sector erasing when a predetermined command is given. Then write expected value data is formed from the saved data and data to be additionally written, completing the writing operation.

Abstract: A control of a flash memory includes control for supplying a pulse-shaped voltage to each of non-volatile memory cells until a threshold voltage of the non-volatile memory cell having a first threshold voltage is changed to a second threshold voltage. The control involves a first write mode (coarse write) in which the amount of change in threshold voltage of each non-volatile memory cell, which is varied each time the pulse-shaped voltage is applied, is relatively rendered high, and a second write mode (high-accuracy write) in which the amount of change in threshold voltage thereof is relatively rendered low. As compared with the high-accuracy mode, the number of pulses required to change the threshold voltage of each memory cell is smaller than that in the coarse write mode. Therefore, the number of verify operations at the time that the coarse write mode is used, is small and hence the entire write operation can be speeded up.

Abstract: A resin-encapsulated semiconductor package and a packaging structure, make it possible to provide for a high density mounting arrangement. Specifically, outer leads protrude from the two long sides of a rectangular package. The inner leads in the package, connected to the outer leads protruding from one long side, are connected through wires to the bonding pads of a semiconductor chip encapsulated in the package, whereas the inner leads in the package, connected to the outer leads protruding from the other long side, are in an electrically floating state in the package. The semiconductor packages are arranged in a direction on a card-shaped mounting board, and the opposed outer leads of adjoining semiconductor packages are electrically connected by wiring on the mounting board. The wirings are laid below the semiconductor packages so that they extend generally linearly.

Abstract: A bootstrap circuit is provided for a word line selector for setting word lines connected with dynamic memory cells at a select level corresponding to a first voltage and a nonselect level corresponding to a second voltage. The bootstrap circuit generates a bootstrap voltage which is given a difference substantially equal to the threshold voltage of address select MOSFETs with respect to the high level of bit lines connected with the memory cells, and feeds the bootstrap voltage to the selected word lines. The bootstrap circuit is activated in synchronism with a clock signal at a timing corresponding to an action mode designated by a command in an SDRAM before a precharge action, thereby changing the select level of the word lines from the first voltage to the bootstrap voltage.

Abstract: Disclosed is a packaged semiconductor device, e.g., of the lead-on-chip type, having reduced thickness, by providing only an adhesive (without a base film) between inner lead portions of the leads and the semiconductor chip to adhere the inner-lead portions to the chip. The adhesive can cover a dicing area of the semiconductor chip, and, in general, can cover edge parts of the chip (and extend beyond the edge of the chip) to prevent short-circuits between the inner lead portions and the semiconductor chip. The outer lead portions have a lower outer end part and a part, closer to the package body, which extends upward obliquely; has stopper members on the obliquely extending part; and has an obliquely extending part with a greater width than a width of the outer end parts of the outer lead portions, to facilitate stacking of packaged semiconductor chips on each other, e.g., for mounting on a printed circuit board. Packaged semiconductor chips having, e.g.

Abstract: A semiconductor memory is provided with a main amplifier circuit that is capable of selectively driving and precharging two I/O buses in conjunction with a write amplifier. The main amplifier circuit includes a separation and precharge section and an activation section. The activation section drives a signal for activating the first section to precharge the two I/O signals only when the two I/O buses are not being separated. The main amplifier circuit also includes both a main output bus and a test output bus. In so doing, the semiconductor memory can operate in a normal mode and a test mode. In the test mode, twice as many memory cells of the semiconductor memory can be accessed simultaneously, thereby reducing test time. The semiconductor memory, which can be one of many different data widths, has different sized output buses associated with each data width. Output buses with a relatively large capacitance can be produced with a large width, giving them a relatively small resistance.

Abstract: A comparator is constituted such that a hit signal .phi.hit is high, before hit check is established in each way of an address array, and such that the hit signal goes low, when a mishit has been established. When a clock frequency is relatively high, the address array is activated by the first clock signal, and thereafter, all ways of a data array are activated by the second clock signal before the hit check in the address array is established. When the hit check has been established, data read from a way in the data array which has hit is immediately outputted onto a data line and an operation in the way which has mishit is stopped. This novel constitution realizes a high-speed cache operation. When the clock frequency is relatively low, only a way in the data array that has hit is activated after completion of the hit check, thereby reducing power consumption at a low-speed operation.

Abstract: Two memory cells in different memory arrays are simultaneously selected in accordance with the designation of a specific write operation mode to associate a logic 1 of a write signal with a state in which an electric charge exists in each capacitor. Further, a logic 0 of the write signal is associated with a state in which no electric charge exists in the capacitor to write the same write signal. Two dynamic memory cells in different memory arrays are simultaneously selected in accordance with the designation of a specific read operation mode to associate a state in which an electric charge exists in a capacitor of each dynamic memory cell with a logic 1 of a read signal and associate a state in which no electric charge exists in the capacitor with a logic 0 of the read signal in response to a write operation. Thus, the logics 1 of the two read signals are preferentially output.

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: In a nonvolatile semiconductor memory in which multiple-value information is stored in one memory cell by setting a plurality of threshold values, data is successively read from word lines while continuously changing the word-line read level from a lowest level to a highest level, and the next bit line is selectively precharged in accordance with the data stored in latch means for storing read data.

Abstract: A nonvolatile semiconductor memory recovers variation in the threshold of a memory cell due to disturbance related to a word line. The nonvolatile memory continuously performs many writing operations without carrying out single-sector erasing after each writing operation, performing the additional writing operations quicker than the usual writing operation, and lightening the burden imposed on software for use in additional writing. The data stored in a designated sector is read out before being saved in a register, and the selected sector is subjected to single-sector erasing when a predetermined command is given. Then write expected value data is formed from the saved data and data to be additionally written, completing the writing operation.

Abstract: A nonvolatile semiconductor memory recovers variation in the threshold of a memory cell due to disturbance related to a word line. The nonvolatile memory continuously performs many writing operations without carrying out single-sector erasing after each writing operation, performing the additional writing operations quicker than the usual writing operation, and lightening the burden imposed on software for use in additional writing. The data stored in a designated sector is read out before being saved in a register, and the selected sector is subjected to single-sector erasing when a predetermined command is given. Then write expected value data is formed from the saved data and data to be additionally written, completing the writing operation.

Abstract: A nonvolatile semiconductor memory device has a plurality of p well regions in a memory cell array region. P well region is independently provided for each erase block. Each p well region is connected to a common well/source line driver, respectively. Well/source line driver is connected to a well/source power supply and a well/block decoder. Therefore, a nonvolatile semiconductor memory device which can inhibit a well disturbance in erase operation can be provided.

Abstract: Within an EEPROM having a memory array in which the electrically erasable nonvolatile storage elements are arranged in a matrix form, an erasing control circuit is included, which performs at least the read out operation one time on the corresponding memory cells after an erasing operation is performed in connection therewith in accordance with externally supplied erasing operation instructions. The erasing operation is automatically performed by the internal erasing control circuit while the EEPROM is electrically isolated from the microprocessor in response to instructions from the microprocessor. The control by the microprocessor requires only a slightly short period of time during which the erasing commencement is instructed while the EEPROM remains in the system during the erasing operation.