Abstract: A variable resistance memory device comprises a memory cell comprising a variable resistance device and a select transistor connected in series to the variable resistance device. The variable resistance memory device further comprises a write driver for supplying a write voltage to opposite sides of the memory cell, and a feedback circuit for detecting a resistance change of the variable resistance device and controlling a gate voltage of the select transistor according to the detected resistance change.

Abstract: A phase change memory (PCM) cycle timer and associated method are disclosed. A system includes at least one reference phase change element (PCE). The system also includes a circuit that performs a write operation on the at least one reference PCE and substantially immediately thereafter continuously senses and returns a value of a resistance of the at least one reference PCE throughout a settling time of the at least one reference PCE.

Abstract: A memory array is characterized by a threshold definition, which includes threshold voltage ranges representing data values stored by a part of the memory array, and a set of sense windows separating the threshold voltage ranges. The threshold definition is varied, responsive to at least one of program operations and erase operations. Such operations change a distribution of the data values stored in the memory group.

Abstract: A semiconductor memory cell array includes a plurality of bit-lines, a plurality of word-lines, a plurality of memory cells, a plurality of dummy memory cells, a plurality of dummy bit-lines, and a plurality of dummy word-lines. The dummy bit-lines are in outer regions of the bit-lines. The dummy word-lines are in outer regions of the word-lines. The dummy bit-lines are maintained in a floating state. The dummy word-lines retain a turn-off voltage.

Abstract: A sense amplifier circuit according to some implementations includes a differential input stage to receive mirrored input currents and a transistor switch whose state is controlled by a signal applied to its gate. The sense amplifier circuit includes a pair of cross-coupled NMOS transistors and a pair of cross-coupled PMOS transistors to which the mirrored input currents are coupled and whose drain nodes are shorted when the transistor switch is in a conductive state. The sense amplifier is arranged to generate a digital output signal indicative of which of the input currents is larger.

Abstract: Determining that a first input of a sense amplifier is to receive information based upon a state of a storage cell during a first portion of a read cycle, and determining that a conductance at the first input is substantially equal to a conductance at a second input of the sense amplifier during the first portion. A plurality of NAND string modules are connected to a global bit line of a memory device that includes a memory column where a plurality of NAND strings and a buffer are formed.

Abstract: According to one embodiment, a semiconductor memory device includes a first cell array includes memory cells and reference cells, a second cell array located adjacent to the first cell array in a first direction, a third cell array located adjacent to the first cell array in a second direction crossing the first direction, a fourth cell array located adjacent to the second cell array in the second direction, and a sense amplifier connected to the first to fourth cell array and configured to compare a current through a memory cell with a current through a reference cell to determine the data of the memory cell. A reference cell is selected from a cell array which is diagonally opposite to a cell array as a read target.

Abstract: A read architecture for reading random access memory (RAM) cells includes a multi-level sense amplifier, the multi-level sense amplifier including a plurality of sense amplifiers, each sense amplifier having a respective sense threshold and a respective sense output, and a storage module coupled to the multi-level sense amplifier for storing the sense outputs of the multi-level sense amplifier. The storage module stores a first set of sense outputs corresponding to a first read of an RAM cell and stores a second set of sense outputs corresponding to a second read of the RAM cell. The architecture also includes a decision module for comparing the first and second set of sense outputs and determining a data state of the RAM cell based on the comparison.

Abstract: A system includes a first circuit and a second circuit that are constituted by a semiconductor device, the second circuit controlling the first circuit. The first circuit includes an interface unit that performs communication with the second circuit, a plurality of sense amplifiers including a first sense amplifier, each of the plurality of sense amplifiers performing communication with the interface unit, a first global bit line, a dummy global bit line, a plurality of first memory blocks, each of the first memory blocks including a first hierarchy switch that is connected to the first global bit line, a dummy memory block including a dummy hierarchy switch that is connected to the dummy global bit line, and a first dummy local bit line connected to the dummy global bit line, and a control circuit that controls the first hierarchy switches and the dummy hierarchy switch.

Abstract: In a semiconductor storage device, either two memory cell gates TG or a memory cell gate TG and a bit-line connecting gate SW are formed in every set of n-type doped regions OD at the intersections with word lines WL or bit-line selecting lines KS. A portion near the center of the set of n-type doped regions OD serves as a source/drain region shared by two gates, whereas portions near both ends thereof serve as source/drain regions for respective gates. Each of the source/drain regions is connected to a storage electrode SN of a memory cell capacitor via a storage contact CA or is connected to a sub bit line or a main bit line via a sub-bit-line contact CH and/or a via of a metal interconnection. A pattern formed of four memory cell gates TG and four bit-line connecting gates SW is repeated.

Abstract: Provided are a nonvolatile memory device and a method of operating the same. The nonvolatile memory device in accordance with an embodiment of the inventive concept may include a string select line; a ground select line; a dummy word line adjacent to the ground select line; a first word line adjacent to the dummy word line; and a second word line disposed between the string select line and the first word line. The nonvolatile memory device is configured to apply a voltage to the dummy word line. When programming a memory cell connected to the first word line, a first dummy word line voltage lower than a voltage applied to the second word line is applied to the dummy word line. When programming a memory cell connected to the second word line, a second dummy word line voltage between a voltage applied to the first word line and the first dummy word line voltage is applied to the dummy word line.

Abstract: Systems and methods of testing a reference cell in a memory array are disclosed. In a particular embodiment, a method includes coupling a first reference cell of a first reference cell pair of a memory array to a first input of a first sense amplifier of the memory array. The method also includes providing a reference signal to a second input of the first sense amplifier. The reference signal is associated with a second reference cell pair of the memory array.

Abstract: The present invention is directed to provide a semiconductor device having a dual-port memory circuit in which influence of placement of replica cells exerted on enlargement of chip area is reduced. A memory cell array of a dual-port memory circuit has: a first replica cell array used to respond to an instruction of reading operation from one of dual ports; and a second replica cell array used to respond to an instruction of reading operation from the other dual port. Each of the replica cell arrays has: replica bit lines obtained by mutually short-circuiting parallel lines having a length obtained by cutting, in half, an inversion bit line and a non-inversion bit line of complementary bit lines to which data input/output terminals of a memory cell are coupled; and replica cells coupled to the replica bit lines and having transistor placement equivalent to that of the memory cells.

Abstract: A system for displaying images is provided and includes a plurality of first signal lines, a plurality of second signal lines, a display area, and a first dummy line. The second signal lines are interlaced with the first signal lines. The display area comprises a plurality of display pixels. Each of the display pixels corresponds to the interlaced first signal line and second signal line. The first dummy line is disposed on a first side of the display area and interlaced with the second signal lines. A section of the first dummy line between every two adjacent second signal lines among the second signal lines has an opening.

Abstract: According to one embodiment, a nonvolatile semiconductor memory includes word lines, bit lines, memory cells, a dummy word line, a dummy bit line and dummy cells. The word lines and the bit lines cross. The memory cells are provided for each intersection of the word lines and bit lines. Each memory cell includes a first diode and a resistance change memory element. The dummy word line crosses the bit lines. The dummy bit line crosses the word lines. The dummy cells are provided at each intersection of the dummy word line and the bit lines, and at each intersection of the dummy bit line and the word lines. Each dummy cell includes a second diode.

Abstract: A sense amplifier circuit according to some implementations includes a differential input stage to receive mirrored input currents and a transistor switch whose state is controlled by a signal applied to its gate. The sense amplifier circuit includes a pair of cross-coupled NMOS transistors and a pair of cross-coupled PMOS transistors to which the mirrored input currents are coupled and whose drain nodes are shorted when the transistor switch is in a conductive state. The sense amplifier is arranged to generate a digital output signal indicative of which of the input currents is larger.

Abstract: According to one embodiment, a semiconductor integrated circuit includes first and second resistance change type memory element and first and second switches. The first resistance change type memory element includes a first terminal connected to a first power supply and a second terminal connected to a first node. The second resistance change type memory element includes a third terminal connected to the first node and a fourth terminal connected to a second power supply. The first switch includes one end of a first current path connected to a first program power supply and the other end of the first current path connected to the first node. The second switch includes one end of a second current path connected to the first node and the other end of the second current path connected to a second program power supply.

Abstract: A memory cell stores therein data, a dummy cell replicates an operation of the memory cell, a write control unit makes the dummy cell to perform writing in synchronization with write timing of the memory cell, and a row decoder performs opening and closing of a word line that performs a row selection of the memory cell based on a monitored result of a write condition of the dummy cell.

Abstract: A large scale memory array includes a uniform pattern of uniformly sized dummy bit cells and active bit cells. Sub-arrays within the large scale memory array are separated by the dummy bit cells. Signal distribution circuitry is formed with a width or height corresponding to the width or height of the dummy bit cells so that the signal distribution circuitry occupies the same footprint as the dummy bit cells without disrupting the uniform pattern across the large scale array. Edge dummy cells of a similar size or larger than the standard size bit cells may be placed around the edge of the large scale array to further reduce pattern loading affects.

Abstract: A memory with extra digit lines in full size end arrays with an open digit architecture, which can use the extra digit lines to form repair cells. In one example, folded digit sense amplifiers are connected to an end array with an open digit architecture such that each sense amplifier corresponds to a group of four digit lines. Two digit lines of the group connect to two open digit sense amplifiers and the other two digit lines connect to the corresponding folded digit sense amplifier. A repair method can be performed on memories including the end arrays with folded digit sense amplifiers. A row in a core array including a replaceable IO is activated and a row in an end array is activated. The repair cells in the end array can be sensed by the folded digit sense amplifiers to generate a replacement IO, which is selected rather than the replaceable IO.

Abstract: According to one embodiment, semiconductor memory device includes: semiconductor substrate; parallel first lines stacked on substrate; parallel second lines intersecting first lines; memory cell array including memory cells at intersections of first and second lines and each including variable resistance element and selecting element series-connected together; first control circuit provided in second region of substrate adjoining first region immediately under array; second control circuit provided in first region of substrate; and dummy lines formed in same layer as second lines, such that they intersect first lines in region above first control circuit. First control circuit applies first voltage to selected first line. Second control circuit applies second voltage lower than first voltage to selected second line, and to dummy lines, third voltage by which potential difference applied to memory cells at intersections of selected first line and dummy lines becomes lower than on-voltage of selecting element.

Abstract: Systems and methods of testing a reference cell in a memory array are disclosed. In a particular embodiment, a method of testing a reference cell in a memory array includes coupling a first reference cell of a first reference cell pair of the memory array to a first input of a first sense amplifier of the memory array. The method also includes providing a reference signal to a second input of the first sense amplifier. The reference signal is associated with a second reference cell pair of the memory array.

Abstract: A semiconductor memory device includes two memory cell arrays, a sense amplifier shared by the two memory cell arrays; and a control circuit configured to control data readout from the two memory cell arrays. Each memory cell array includes word lines, two or more bit lines, a dummy word line, memory cells provided at intersections of the bit lines and the word lines, and dummy cells provided at intersections of selected bit lines and the dummy word line. When the control circuit reads data from one memory cell array, the control circuit activates the dummy word line included in the other memory cell array and generates, with the dummy cell included in the other memory cell array, a reference level of the sense amplifier.

Abstract: An integrated circuit comprises a memory array and a bias circuit. The memory array comprises a plurality of memory cells arranged in a grid of rows and columns. A first conductor is coupled to a power supply voltage terminal of each of the plurality of memory cells. A second conductor is coupled to receive a power supply voltage. The memory array also includes a plurality of dummy cells. A transistor of one or more of the plurality of dummy cells has a first current electrode coupled to the first conductor, a second current electrode coupled to the second conductor, and a control electrode. The bias circuit is coupled to the control electrode of the transistor.

Abstract: According to one embodiment, a dummy cell simulates an operation of a memory cell. A main dummy bit line transmits a signal read out from the dummy cell. An inverter makes a sense amplifier circuit to operate based on a potential of the main dummy bit line. n (n is a positive integer) number of auxiliary dummy bit lines are provided. A switching element connects at least one of the n number of auxiliary dummy bit lines to the main dummy bit line.

Abstract: A non-volatile memory and method for controlling the same prevents a faulty operation from being generated in a read operation, resulting in increase in operation reliability. The non-volatile memory device includes a cell array configured to include a plurality of unit cells in which a read or write operation of data is achieved in a unit cell in response to a variation of resistance, a reference cell array configured to include a plurality of reference cells, each of which has the same structure as that of the unit cell, a global reference current generation circuit configured to generate a global reference current corresponding to a position of the reference cell so as to verify data stored in the reference cell array, and a sense-amplifier configured to compare a current flowing in the reference cell array with the global reference current during a write verification operation of the reference cell array, and thus sense data.

Abstract: A system includes a first circuit and a second circuit that are constituted by a semiconductor device, the second circuit controlling the first circuit. The first circuit includes an interface unit that performs communication with the second circuit, a plurality of sense amplifiers including a first sense amplifier, each of the plurality of sense amplifiers performing communication with the interface unit, a first global bit line, a dummy global bit line, a plurality of first memory blocks, each of the first memory blocks including a first hierarchy switch that is connected to the first global bit line, a dummy memory block including a dummy hierarchy switch that is connected to the dummy global bit line, and a first dummy local bit line connected to the dummy global bit line, and a control circuit that controls the first hierarchy switches and the dummy hierarchy switch.

Abstract: A semiconductor memory device includes: a first word line and a second word line; a plurality of first SRAM cells; a plurality of second SRAM cells; and a mediating cell. Each first SRAM cell includes the first word line and the second word line and is connected to the first word line. Each second SRAM cell includes the first word line and the second word line and is connected to the second word line. The mediating cell is arranged between and adjacent to one first SRAM cell and one second SRAM cell and is connected to the first word line and the second word line. In the mediating cell and the plurality of first SRAM cells, cells adjacent to each other share a contact for the first word line. In the mediating cell and the plurality of second SRAM cells, cells adjacent to each other share a contact for the second word line.

Abstract: A readout circuit has a sense amplifier to compare a cell current which changes according to whether a memory cell is on or off to a reference current to output a comparison signal of a first logic value upon detecting that the cell current is smaller than the reference current, and to output a comparison signal of a second logic value upon detecting that the cell current is greater than the reference current, the readout circuit outputting a data output signal depending upon an output of the sense amplifier. The reference current is set to be greater than a middle value between a first cell current, which flows when the memory cell is in an off-state, and a second cell current, which flows when the memory cell is in an on-state, the reference current is greater than the first cell current and is smaller than the second cell current.

Abstract: Systems and methods are disclosed for providing selective threshold voltage characteristics via use of MOS transistors having differential threshold voltages. In one exemplary embodiment, there is provided a metal oxide semiconductor device comprising a substrate of semiconductor material having a source region, a drain region and a channel region therebetween, an insulating layer over the channel region, and a gate portion of the insulating layer. Moreover, with regard to the device, the shape of the insulating layer and/or the shape or implantation of a junction region are of varied dimension as between the gate-to-drain and gate-to-source junctions to provide differential threshold voltages between them.

Abstract: A bulk-driven current-sense amplifier and an amplifier operating method are disclosed. The bulk-driven current-sense amplifier includes a differential amplifier, a first driver, and a second driver. The first driver is coupled to the differential amplifier, and a first node is formed at a connectivity segment of the first driver. The second drive is coupled to the differential amplifier, and a second node is formed at a connectivity segment of the second driver. When a first switch of the first driver and a second switch of the second driver are turned on, the differential amplifier charges the first node and the second node. When the charging is completed, the first node and the second node respectively have a different stabilized potential according to currents separately flowing through a first memory unit of the first driver and a second memory unit of the second drive, and the differential amplifier generates a voltage.

Abstract: A memory device includes: a memory unit in which an electric charge discharging rate between two electrodes is different in accordance with logic of stored information; a sense amplifier that detects the logic of the information by comparing a discharge electric potential of a wiring to which one electrode of the memory unit is connected with a reference electric potential; and a replica circuit that has a replica unit emulating the memory unit and controls a sense timing of the sense amplifier in accordance with a discharge rate of the replica unit.

Abstract: A semiconductor memory apparatus includes a memory cell, a data transfer unit configured to adjust an access to the memory cell according to a voltage level of a selection signal, a selection signal output unit configured to output the selection signal having a first control voltage level in a data write mode and a second control voltage level in a data read mode. A data detection unit may also be configured to detect a voltage formed by a sensing current supplied to the memory cell through the data transfer unit in the data read mode, and output read data according to the detection result, wherein the second control voltage level is lower than the first control voltage level.

Abstract: Disclosed are methods, circuits, devices and systems for operating one or more non-volatile memory (NVM) cells within an array of NVM cells. According to embodiments, there may be provided a nonvolatile memory (NVM) device comprising an array of NVM data cells including one or more border/periphery data cells and one or more non-periphery cells. Array control circuitry may be adapted to gauge a state of the one or more periphery data cells differently than non-periphery data cells.

Abstract: A semiconductor device includes a global bit line, a dummy global bit line that is shorter than the global bit line, a sense amplifier that amplifies a potential difference between the global bit line and the dummy global bit line, a plurality of memory blocks each including a hierarchy switch and a local bit line that is connected to the global bit line via the hierarchy switch, a dummy memory block that includes a dummy hierarchy switch and a dummy local bit line that is connected to the dummy global bit line via the dummy hierarchy switch, and a control circuit that activates any one of hierarchy switches and the dummy hierarchy switch. With this configuration, it is possible to obtain the same memory capacity between a memory mat located at an edge and the other memory mat.

Abstract: A memory arrangement including a memory block and a controller. The memory block comprises a plurality of memory cells, wherein each memory cell operable to store one of a plurality of different levels of charge. The controller is configured to write (i) a first reference signal threshold into a first memory cell and (ii) a second reference signal threshold into a second memory cell. The first reference signal threshold corresponds to a first level of charge of the plurality of different levels of charge, and the second reference signal threshold corresponds to a second level of charge of the plurality of different levels of charge. Each of the first level of charge and the second level of charge is used to calibrate a read back of any of the one of the plurality of different levels of charge stored among the plurality of memory cells in the memory block.

Abstract: A resistive memory device comprises a memory cell array comprising a plurality of memory units. The memory device performs a refresh read operation to check a condition of each of the memory units. Then, it determines whether to refresh each memory unit based on data read by performing the refresh read operation, and refreshes the memory unit according to a result of the determination. The refresh read operation uses a reference resistance with a smaller margin from a resistance distribution than a normal read operation.

Abstract: The present disclosure includes devices and methods for operating resistance variable memory. One device embodiment includes an array of memory cells wherein a number of the cells are commonly coupled to a select line, the number cells including a number of data cells programmable within a number of target threshold resistance (Rt) ranges which correspond to a number of data states, and a number of reference cells interleaved with the data cells and programmable within the number of target Rt ranges. The aforementioned device embodiment also includes control circuitry coupled to the array and configured to sense a level associated with at least one data cell and at least one reference cell, and compare the sensed level associated with the at least one data cell with the sensed level associated with the at least one reference cell to determine a data state of the at least one data cell.

Abstract: A circuit includes a reference data line configured to receive a reference voltage value, a memory cell, a data line coupled to the memory cell and configured to have a data logic value associated with data stored in the memory cell, a first circuit coupled to the reference data line and to the data line, and an output node configured to selectively receive the data logic value from the data line or receive the data logic value through the first circuit, based on the reference voltage value and a trip point used to trigger the first circuit to provide the data logic value through the first circuit.

Abstract: Memories, systems, and methods for repairing are provided. A memory with extra digit lines in end arrays with an open digit architecture, which can use the extra digit lines to form repair cells. In one example, folded digit sense amplifiers are connected to an end array with an open digit architecture such that each sense amplifier corresponds to a group of four adjacent digit lines. Two digit lines of the group connect to two open digit sense amplifiers and the other two digit lines connect to the corresponding folded digit sense amplifier. To repair memories including folded digit end arrays, a row in a core array that includes a replaceable IO is activated and a row in an end array is activated. The repair cells in the end array can be sensed by the folded digit sense amplifiers to generate a replacement IO, which is selected rather than the replaceable IO.

Abstract: The present invention provides a semiconductor memory and a control method therefor, the semiconductor device including a first current-voltage conversion circuit connected to a core cell provided in a nonvolatile memory cell array, a second current-voltage conversion circuit connected to a reference cell through a reference cell data line, a sense amplifier sensing an output from the first current-voltage conversion circuit and an output from the second current-voltage conversion circuit, a compare circuit comparing a voltage level at the reference cell data line with a predefined voltage level, and a charging circuit charging the reference cell data line, if the voltage level at the reference cell data line is lower than the predefined voltage level during pre-charging the reference cell data line. According to the present invention, the pre-charging period of the reference cell data line can be shortened, and the data read time can be shortened.

Abstract: A semiconductor memory cell array includes a plurality of bit-lines, a plurality of word-lines, a plurality of memory cells, a plurality of dummy memory cells, a plurality of dummy bit-lines, and a plurality of dummy word-lines. The dummy bit-lines are in outer regions of the bit-lines. The dummy word-lines are in outer regions of the word-lines. The dummy bit-lines are maintained in a floating state.

Abstract: A semiconductor device to improve layout uniformity may include an active region formed in a substrate, a dummy active region formed in the substrate and separated from the active region, a word line crossing over the active region, and a dummy word line. The dummy word line is formed over the dummy active region to overlap at least part of the dummy active region and may have an end positioned within the dummy active region.

Abstract: A method is for reading a first bit cell of a static random access memory in which the static random access memory has a first plurality of bit cells including the first bit cell. Each bit cell of the first plurality of bit cells includes a cross coupled pair of inverters for storing a logic state, optimized for being written, and powered by a read voltage during a read of the first plurality of bit cells. Each bit cell of the first plurality of bit cells is coupled to a true read bit line and a true write bit line, and a second plurality of bit cells is coupled to a complementary read bit line and a complementary write bit line. The true and complementary read bit lines are precharged to a precharge voltage of about half the read voltage. The true read bit line is predisposed to a logic low condition.

Abstract: Herein, a voltage sensing circuit, which is capable of controlling a pumping voltage to be stably generated in a low voltage environment, is provided. The voltage sensing circuit includes a current mirror having first and second terminals, a first switching element configured to control current on the first terminal of the current mirror by a reference voltage, a second switching element configured to control current from the second terminal of the current mirror in response to a pumping voltage, and a third switching element configured to control current sources of the first and second switching elements to receive a negative voltage.

Abstract: A circuit comprises a first read bit line, a second read bit line, and a sense amplifier. First and second read bit lines couple a plurality of memory cells and a reference cell of a memory array, respectively. The sense amplifier is configured to receive the first read bit line as a first input and the second read bit line as a second input. When a memory cell of the first plurality of memory cells is read, the memory cell is read activated, the first reference cell is configured to be off, the second reference cell is configured to be on, and the sense amplifier is configured to provide an output reflecting a data logic stored in the memory cell based on a voltage difference between a first voltage of the first read bit line and a second voltage of the second read bit line.

Abstract: A device, and a corresponding method of implementation, for SRAM memory information storage are provided. The device is powered by a supply voltage and includes an array of base cells organized in base columns, and at least one mirror column of at least one mirror cell liable to simulate the behavior of the cells in a base column. The device further includes Emulation means, in a mirror column, of the most restricting cell in a base column, Means for varying a mirror power supply voltage for the mirror column, and Means for copying the mirror power supply voltage in the emulated base column.

Abstract: A resistance-based memory with a reduced voltage I/O device is disclosed. In a particular embodiment, a circuit includes a data path including a first resistive memory cell and a first load transistor. A reference path includes a second resistive memory cell and a second load transistor. The first load transistor and the second load transistor are input and output (I/O) transistors adapted to operate at a load supply voltage similar to a core supply voltage of a core transistor within the circuit.

Abstract: A current-sense amplifier with low-offset adjustment and a low-offset adjustment method thereof are disclosed. The current-sense amplifier includes a sensing unit, an equalizing unit and a bias compensation unit. The sensing unit includes a sense amplifier, a latch circuit, a first precharged bit line, and a second precharged bit line. The equalizing unit is electrically connected to the first and the second precharged bit line for regulating a voltage of the first precharged bit line and a voltage of the second precharged bit line to the same electric potential. The bias compensation unit is electrically connected to the sense amplifier for compensating an input offset voltage of the current-sense amplifier.

Abstract: A magnetic random access memory (MRAM) includes a memory cell having a first transistor and a first magnetic tunneling junction (MTJ) layer, and a reference cell operable as a basis when reading data stored in the memory cell, the reference cell including second and third MTJ layers arranged in parallel to each other, and a second transistor connected in series to each of the second and third MTJ layers, the second transistor having a driving capability corresponding to twice a driving capability of the first transistor of the memory cell.