Abstract: A semiconductor memory device comprises. word lines; global bit lines intersecting with the word lines; local bit lines partitioned into N (N is an integer greater than or equal to two) sections along the global bit lines and aligned with a same pitch as the global bit lines; N memory cell arrays each including memory cells each having cylindrical capacitor structure formed at intersections of the word lines and the local bit lines and being arranged corresponding to the sections of the local bit lines; local sense amplifiers for amplifying a signal read out from a selected memory cell to the local bit line and for outputting the signal to the global bit line; and global sense amplifiers for coupling the signal transmitted from the local sense amplifier corresponding to the selected memory cell through the global bit line to an external data line.

Abstract: In a large scale integrated DRAM in pursuit of micro fabrication, data line-word line coupling capacitances are unbalanced between paired data lines. An imbalance in data line-word line means generation of large noise when the data lines are subjected to amplification, which is highly likely invite deterioration of very small signals on the data lines and erroneous amplification of data. One or a few each of a plurality of word lines connected to a plurality of memory cells connected to one data line are alternately connected to subword driver arrays arranged on the opposing sides of a memory array. Positive and negative word line noise components cancel each other in the subword drivers when the data lines are subjected to amplification, so that the word line noise can be reduced. Therefore, signals read out by sense amplifiers can be prevented from deterioration thereby to increase the reliability of memory operation.

Abstract: A semiconductor device includes a plurality of word lines, a plurality of bit lines, a plurality of memory cells provided at the intersections of the plurality of word lines and the plurality of bit lines and each of that includes a MIS transistor and a memory element, a decoder circuit for selecting a plurality of word lines, and a sense-amplifier circuit for determining information that is read from any of the plurality of memory cells to any of the plurality of bit lines, wherein a twist connector for switching the wiring order of the plurality of word lines is provided and level-stabilizing circuits, for supplying the potential level of a non-selected state to the plurality of word lines in the non-selected state are arranged in the area below the twist connector.

Abstract: A memory circuit of the invention comprises N look-up tables for implementing a desired logic function of L inputs/M outputs by partitioning a memory cell array including a plurality of memory cells into portions each corresponding to at least a predetermined number of input/output paths; a decode circuit for selecting one of the N look-up tables by decoding a look-up table select signal and for selecting M memory cells to be accessed included in the selected look-up table by decoding an L-bit logic input signal of the logic function; and a select connect circuit for selectively connecting the input/output paths of the M memory cells to be accessed with an input/output bus for transmitting an M-bit logic output signal of the logic function in response to a decoded result of the decode circuit.

Abstract: To increase the quantity of stored charges of memory cells by a simple configuration to improve the operating margin, and to allow dummy cells to be unnecessary to improve the operating margin of a DRAM without increasing the power consumption and/or the chip area. A voltage of a common plate line is changed from a first voltage to a second voltage lower than the first voltage while a word line is a third voltage which makes the word line a selected state. The voltage of the word line is changed into a fourth voltage which makes the memory cell a non-selected state and is lower than the third voltage and higher than a fifth voltage which makes the word line a non-selected state, and the voltage of the plate line is changed into the first voltage after the voltage of the word line has been changed into the fourth voltage.

Abstract: A semiconductor memory device includes a plurality of input/output (I/O) ports, a plurality of memory cell arrays and a region configurator. The region configurator is adapted to hold share region information about at least one share region. In the memory cell arrays, at least one share region accessible through the I/O ports is configured on the basis of the share region information.

Abstract: A semiconductor memory device comprises: word lines; global bit lines intersecting therewith; local bit lines partitioned into N sections along the global bit lines and aligned with a same pitch as the global bit lines; N memory cell arrays each of which includes memory cells each having a vertical transistor structure connected to the local bit lines at a lower portion and each being formed at an intersection of the word line and the local bit line, and is arranged corresponding to each section of the local bit lines; local sense amplifiers for amplifying a signal read out from a selected memory cell to the local bit line and for outputting the signal to the global bit line; and global sense amplifiers for coupling the signal transmitted from the local sense amplifier corresponding to the selected memory cell through the global bit line to an external data line.

Abstract: A semiconductor memory device comprises word lines, global bit lines intersecting with the word lines; local bit lines partitioned into N sections along the global bit lines and aligned with a same pitch as the global bit lines; N memory cell arrays each including memory cells formed at intersections of the word lines and the local bit lines and being arranged corresponding to the sections of the local bit lines; local sense amplifiers for amplifying a signal read out from a selected memory cell to the local bit line and for outputting the signal to the global bit line; global sense amplifiers for amplifying the signal transmitted from the local sense amplifier corresponding to the selected memory cell through the global bit line and for selectively coupling the signal to an external data line.

Abstract: A semiconductor memory device includes a memory cell having an FET of a floating body type, and a capacitor for storing a data charge; a bit line to which the source or the drain of the FET is connected; a precharging device for performing precharge control so that the bit line has a predetermined precharge voltage; a sense amplifier for amplifying and storing the potential of the bit line, which is set in accordance with the data charge read from the memory cell; a switching device, provided between the bit line and the sense amplifier, for performing selective connection therebetween; and a control part for controlling the precharging device, the sense amplifier, and the switching device. Except for each period for performing data reading or writing, the control part makes the precharging device perform the precharge control and makes the switching device disconnect the bit line from the sense amplifier.

Abstract: A synchronous DRAM is provided which includes arrangements for operations of power supply circuitry based upon whether the DRAM is in a power down mode or not. In one embodiment, a first power supply circuit and a second power supply circuit are provided which both receive externally supplied voltages and output internal supply voltages. The first power supply circuit is not in operation when a semiconductor device of the synchronous DRAM is in a power down mode. However, the second power supply circuit is continuously in operation during the power down mode. In another arrangement, the operation of a voltage limiter circuit is controlled based on whether or not the DRAM is in a power down mode.

Abstract: A single-ended sense amplifier circuit comprises first and second MOS transistors and first and second voltage setting circuits. The first MOS transistor supplies a predetermined voltage to the bit line and switches connection between the bit line and a sense node in response to a control voltage, and the second MOS transistor having a gate connected to the sense node amplifies a signal transmitted from the bit line via the first MOS transistor. The first voltage setting circuit sets the bit line to a first voltage, and the second voltage setting circuit sets the sense node to a second voltage. In the sense amplifier circuit, after setting the bit line and the sense node to respective voltages, the bit line is driven in a charge distributing mode via the first MOS transistor so that a signal voltage at the sense node is amplified by the second MOS transistor.

Abstract: A semiconductor memory device comprises a memory cell array, first and second bit lines, first and second amplifiers, and a sense amplifier control circuit. An amplifying element in the first sense amplifier amplifiers the signal of the first bit line and converts it into an output current. The second bit line is selectively connected to the first bit line via the first sense amplifier. A signal voltage decision unit in the second sense amplifier determines the signal level of the second bit line being supplied with the output current. The sense amplifier control circuit controls connection between the amplifying element and the unit in accordance with a determination timing, which switches the above connection from a connected state to a disconnected state at a first timing in a normal operation and switches in the same manner at a delayed second timing in a refresh operation.

Abstract: A single-ended sense amplifier circuit amplifies a signal of a memory cell and transmitted through a bit line, and comprises first and second MOS transistors. The first MOS transistor supplies a predetermined voltage to the bit line and controls connection between the bit line and a sense node in response to a control voltage, and the second MOS transistor has a gate connected to the sense node and amplifies a signal transmitted from the bit line via the first MOS transistor. The predetermined voltage is supplied to the bit line before read operation and is set to a value such that a required voltage difference at the sense node between high and low level data of the memory cell can be obtained near a changing point between a charge transfer mode and a charge distributing mode within a range of a read voltage of the memory cell.

Abstract: A semiconductor memory device comprises a memory cell array and a sense amplifier circuit. The memory cell array includes a first NMOS transistor which has a gate electrode connected to a word line and has one source/drain region connected to a bit line. The sense amplifier circuit includes a second NMOS transistor which has a gate electrode connected to the bit line and has one source/drain region connected to a predetermined voltage. In the semiconductor memory device, each of the first and second MOS transistors is a floating body type NMOS transistor, and the predetermined voltage is supplied to the bit line at least in a precharge operation, thereby preventing characteristic deterioration due to accumulation of holes in the floating body.

Abstract: A semiconductor memory device comprises a memory cell array and a forming controller. The memory cell array includes a plurality of first memory cells each having a structure in which dielectric material is sandwiched between two electrodes, and the memory cell array is divided into a plurality of areas capable of being designated. The forming controller controls to perform “forming” for the first memory cells in an area selectively designated from the plurality of areas of the memory cell array, and as a result of the forming, the first memory cells are changed to non-volatile second memory cells.

Abstract: A semiconductor circuit of the invention comprises: a memory cell array including a plurality of memory cells formed at intersections between a plurality of word lines and a plurality of bit lines; a plurality of sense amplifiers each for amplifying data of the memory cell connected to a selected word line through the bit line; a plurality of data holding circuits each for holding data transferred from the plurality of sense amplifiers; and a plurality of selectors each for selecting a data holding circuit from a unit group including a predetermined number of the data holding circuits based on logic input data, and for externally connecting one end of the selected data holding circuit.

Abstract: A semiconductor memory device (e.g. DRAM) is constituted of a memory cell array including a plurality of memory cells, a plurality of word line drivers, a plurality of sense amplifiers, and a plurality of dummy capacitors. The memory cells, each of which includes a transistor and a capacitor, are positioned at intersections between the word lines and the bit lines. The first electrodes of the capacitors are connected to the transistors in the memory cells. The first electrodes of the dummy capacitors are connected together and are supplied with a second potential (e.g. VDD or VSS). The second electrodes of the dummy capacitors are connected together with the second electrodes of the capacitors of the memory cells and are supplied with a first potential (e.g. VPL). The dummy capacitors serve as smoothing capacitances for the plate voltage VPL so as to reduce plate noise.

Abstract: In a memory array structured of memory cells using a storage circuit STC and a comparator CP, either one electrode of a source electrode or a drain electrode of a transistor, whose gate electrode is connected to a search line, of a plurality of transistors structuring the comparator CP is connected to a match line HMLr precharged to a high voltage. Further, a match detector MDr is arranged on a match line LMLr precharged to a low voltage to discriminate a comparison signal voltage generated at the match line according to the comparison result of data. According to such memory array structure and operation, comparison operation can be performed at low power and at high speed while influence of search-line noise is avoided in a match line pair. Therefore, a low power content addressable memory which allows search operation at high speed can be realized.

Abstract: There is achieved a high-integrated and high-speed nonvolatile memory which can stabilize an operation of a phase-change memory for a short operation cycle time. A latch is provided in a write driver. A change to a high-resistance state of a phase-change element is performed per column cycle by a write-enable signal, and a change to a low-resistance state thereof is performed after a pre-charge command is inputted and concurrently with deactivation of a pre-charge signal. Thereby, a write time to a memory cell in which phase-change resistance is changed to a low-resistance state, and a period from a write operation for changing the phase-change resistance to a high-resistance state to a read operation to the above memory cell can be lengthened without extending the column cycle time, so that the stable write operation is achieved.

Abstract: A semiconductor memory device of the invention comprises unit blocks into which the memory cell array is divided, rows of sense amplifiers arranged at one end and the other end of the plurality of bit lines in the unit block, switch means for switching a connection state between the unit block and the row of sense amplifiers attached to the unit block; and control means for controlling the switch means so as to form a transfer path from the row of sense amplifiers attached to a predetermined the unit block leading to the row of sense amplifiers as a saving destination not attached to the predetermined the unit block. This row of sense amplifiers attached to the predetermined the unit block functions as a cache memory.