Abstract: In conventional liquid crystal display controllers such as for portable telephone sets, the display is reduced in the stand-by state but the liquid crystal display duty is not changed, i.e., even the common electrodes of the rows that are not producing display are scanned, and the consumption of electric power is not decreased to a sufficient degree in the stand-by state. A liquid crystal display controller (2) includes a drive duty selection register (34) capable of being rewritten by a microprocessor (1), and a drive bias selection register (32). When the display is changed from the whole display on a liquid crystal display panel (3) to a partial display on part of the rows only, the preset values of the drive duty selection register and of the drive bias selection register are changed, so that the display is selectively produced on a portion of the liquid crystal display panel at a low voltage with a low-duty drive.

Abstract: Disclosed here is a nonvolatile semiconductor memory device used to prevent data loss that might occur in unselected memory cells due to a disturbance that might occur during programming/erasing in/from those memory cells. In the nonvolatile semiconductor memory device, the number of programming/erasing operations performed in a data storage block over a programming/erasing unit of the subject nonvolatile memory is recorded in an erasing/programming counter EW CT provided in each data storage block. When the value of the erasing/programming counter reaches a predetermined value, the data storage block corresponding to the erasing/programming counter is refreshed. In the refreshing operation, the data in the data storage block is stored in a temporary storing region provided in the data storage block, then the data in a temporary storing region of the data storage area is erased and the data stored temporarily is programmed in the data storage block again.

Abstract: A write bit line and a read bit line are provided separately for a memory cell. A source line connecting to the memory cell is formed of a source impurity region the same in conductivity type as a substrate region. A memory cell transistor and the source impurity region are connected by a metal interconnection line of a low resistance. A rise in the source line potential can be prevented, and a memory cell current can reliably be generated according to storage data. Further, fast data reading can be achieved. Additionally, by performing precharging and data amplification in a unit of read bit line, the load of the read bit line can be alleviated to achieve fast reading. An accessing time of a non-volatile semiconductor memory device that uses a variable resistance element as a storage element is reduced without increasing the current consumption.

Abstract: A method of manufacturing a semiconductor device is provided that can suppress impurity concentration reduction in a doped channel region arising from formation of a gate insulating film. With a silicon oxide film (20) and a silicon nitride film (21) being formed, p-type impurity ions (23.sub.1, 23.sub.2) are implanted in a Y direction from diagonally above. As for an implant angle .alpha. of the ion implantation, an implant angle is adopted that satisfies the relationship tan?1 (W2/T)<??tan?1 (W1/T), where W1 is an interval between a first portion (211) and a fourth portion (214) and an interval between a third portion (213) and a sixth portion (216); W2 is an interval between a second portion (212) and a fifth portion (215); T is a total film thickness of the silicon oxide film (20) and the silicon nitride film (21).

Abstract: A gate electrode is provided such that both ends thereof in a gate width direction are projected from an active region in plane view. Partial trench isolation insulation films are provided in a surface of an SOI substrate corresponding to lower parts of the both ends, and body contact regions are provided in the surface of the SOI substrate outside the both ends of the gate electrode in the gate width direction so as to be adjacent to the respective partial trench isolation insulation films. The body contact region and a body region are electrically connected through an SOI layer (well region) under the partial trench isolation insulation film. In addition, a source tie region in which P type impurity is doped in a relatively high concentration is provided in the surface of a source region in the vicinity of the center of the gate electrode in the gate width direction.

Abstract: In the process of manufacturing a semiconductor device, a first layer is formed on a substrate, and the first layer and the substrate are etched to form a trench. The inner wall of the trench is thermally oxidized. On the substrate, including inside the trench, is deposited a first conductive film having a thickness equal to or larger than one half of the width of the trench. The first conductive film on the first layer is removed by chemical mechanical polishing such that the first conductive film remains in only the trench. The height of the first conductive film in the trench is adjusted to be lower than a surface of the substrate by anisotropically etching the first conductive film. An insulating film is deposited on the substrate by chemical vapor deposition to cover an upper surface of the first conductive film in the trench. The insulating film is flattened by chemical mechanical polishing, and the first layer is removed.

Abstract: A finger length a1 of a transistor P11 is longer than a finger length A1 of a transistor P1, and a finger length b1 of a transistor N11 is longer than a finger length B1 of a transistor N1. The finger length b1 of the transistor N11 is shorter than the finger length A1 of the transistor P1, and the relation: a1>A1>b1>B1 is established. In a relation between an I/O section and a logic circuit section, as for MOS transistor of the same conductive type, a finger length of a MOS transistor constituting the logic circuit section is set so as to be longer than a finger length of a MOS transistor constituting the I/O section.

Abstract: According to a method of erasing data in a non-volatile semiconductor memory device, block-round type overerase verify is performed. Specifically, overerase verify and write back are performed sequentially from a first address to a last address. That is, even when a write back pulse is applied after a certain address is selected and verify is performed, address increment from one address to another is performed, regardless of whether verify has been performed or not. Therefore, it is not that the same address is cumulatively rewritten, but write back to a memory cell corresponding to a defective address is sequentially and gradually performed. Accordingly, as write to a memory cell in an overerased state can evenly be performed, influence by off-leakage is suppressed, and a memory cell having threshold voltage distribution with less variation can be implemented.

Abstract: A MOS transistor including a source region, a drain region, and a gate electrode has first and second partial isolation regions in one-end gate region and the other-end gate region, respectively, with a first tap region provided adjacent to the first partial isolation region, and a second tap region provided adjacent to the second partial isolation region. A full isolation region is provided in the whole area around the first and second partial isolation regions, first and second tap regions, and source and drain regions.

Abstract: The invention provides a semiconductor chip manufacturing method including the steps of: forming a concave portion extended in the thickness direction of a semiconductor substrate which has a front surface and a rear surface and has a function device formed on the front surface, from the front surface; forming an oxidation preventive film made of an inert first metal material by supplying the first metal material onto the inner wall surface of the concave portion; supplying a second metal material containing a metal which is oxidized more easily than the first metal material to the inside of the concave portion after the step of forming the oxidation preventive film; electrically connecting the second metal material supplied to the inside of the concave portion and the function device; and thinning the semiconductor substrate so that the thickness thereof becomes thinner than the depth of the concave portion by removing the semiconductor substrate from the rear surface while leaving the oxidation preventive f

Abstract: A method of manufacturing a semiconductor integrated circuit device is provided including forming a first insulating film comprised of fluorine-containing silicon oxide over a main surface of a semiconductor substrate is formed together with forming a second insulating film comprising silicon oxide as a major component, forming a third insulating film comprising silicon carbide as a major component, and forming a fourth insulating film comprised of fluorine-containing silicon oxide. The fourth insulating film is removed at a wiring groove-forming region thereof by dry etching using a first photoresist film as a mask. A first conductive layer is buried inside the wiring groove and the first conductive layer is removed from outside of the wiring groove by a chemical mechanical polishing method, thereby forming a first wiring including the first conductive layer inside the wiring groove.

Abstract: The quality of a non-leaded semiconductor device is to be improved. The semiconductor device comprises a sealing body for sealing a semiconductor chip with resin, a tab disposed in the interior of the sealing body, suspension leads for supporting the tab, plural leads having respective to-be-connected surfaces exposed to outer edge portions of a back surface of the sealing body, and plural wires for connecting pads formed on the semiconductor chip and the leads with each other. End portions of the suspending leads positioned in an outer periphery portion of the sealing body are not exposed to the back surface of the sealing body, but are covered with the sealing body. Therefore, stand-off portions of the suspending leads are not formed in resin molding.

Abstract: A nonvolatile memory apparatus which need not compare an access address with a faulty address every time for rescuing from any fault is to be provided. The apparatus has memory arrays, data registers for inputting and outputting data to and from the memory arrays, and control circuits. The control circuits, after transferring a plurality of sets of data from the memory arrays to the data registers in response to an instruction to read data, take out rescuing data out of the plurality of sets of data transferred to the data registers, and perform processing to replace with the taken-out rescuing data corresponding faulty addresses on the data register to enable the data on the data register to be supplied to the outside. When any faulty data in the read data are to be replaced with rescuing data on any data register to which data have been transferred from any memory array, read access addresses need not be checked whether or not they are faulty every time an access address is supplied from outside.

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: An AND flash memory of the type wherein a memory cell is constituted of n-type semiconductor regions (a source and a drain) formed in a p-type well of a semiconductor substrate and three gates (including a floating gate, a control gate and a selective gate) is manufactured. In the manufacture, arsenic (As) is introduced into a p-type well in the vicinity of one of side walls of the selective gate to form n-type semiconductor regions (a source and a drain). Thereafter, to cope with a drain disturb problem, the substrate is thermally treated by use of an ISSG (In-Situ Steam Generation) oxidation method so that a first gate, insulating film disposed in the vicinity of one of side walls, at which the n-type semiconductor regions have been formed, is formed thick.

Abstract: A nonvolatile memory device of the present invention performs a programming operation by accumulating a charge in certain capacitance which is provided for each programming memory cell and injecting hot electrons generated when the charge is discharged via the memory cell into a floating gate. Thus, a variation in a programming characteristic of the nonvolatile semiconductor memory device is reduced, thereby realizing high-speed programming operation.

Abstract: An object is to provide a video recording/playing apparatus for facilitating recording/playing of motion pictures.

Abstract: In the formation of a halftone type phase shift mask, a reactive gas introduction inlet and an inert gas introduction inlet are provided so as to introduce the respective gases separately and by using a reactive low throw sputtering method a molybdenum silicide based phase shifter film is formed. Thereby, it becomes possible to provide a halftone type phase shift mask, which is applicable to an ArF laser or to a KrF laser, by using molybdenum silicide based materials.

Abstract: It is aimed at being capable of easily changing a power supply startup procedure and complying with various display devices. A power supply circuit is provided between an instruction register of a liquid crystal driver and a power supply unit. The power supply unit is not directly supplied with a setting value registered to the instruction register from a microprocessor unit. The microprocessor unit writes setting values to the instruction register without need for the time axis. To turn on the power, the time is measured inside the power supply sequencer. Set values are sequentially input to the power supply unit. The instruction register should be also capable of registering an input timing.

Abstract: To realize etching with a high selection ratio and a high accuracy in fabrication of an LSI, the composition of dissociated species of a reaction gas is accurately controlled when dry-etching a thin film on a semiconductor substrate by causing an inert gas excited to a metastable state in a plasma and a flon gas to interact with each other and selectively obtaining desired dissociated species.