Abstract: To provide a semiconductor device which can write and read a desired potential. The semiconductor device includes a first transistor (Tr), a second Tr, and a capacitor. In the semiconductor device, operation of writing data is performed by a first step and a second step. In the first step, a low voltage is applied to a bit line and a first wiring to turn on the first Tr and the second Tr. In the second step, a first voltage is applied to the first wiring, and application of the low voltage to the bit line is stopped. Operation of reading the data is performed by a third step and a fourth step. In the third step, a high voltage is applied to the first wiring. In the fourth step, application of the high voltage to the first wiring is stopped, and a low voltage is applied to a capacitor line.

Abstract: A system includes: a controller, a first memory module connected to the controller through a first data bus, and a second memory module connected to the controller through a second data bus, wherein the first memory module includes: first and second memory chips; a first data terminal connected to the first data bus, and a first switch unit that electrical connects the first data terminal with either the first memory chip and the second memory chip, and the second module includes: third and fourth memory chips; a second data terminal connected to the second data bus, and a second switch unit that switches over electrical connection of the second data terminal with either the third memory chip or the fourth memory chip.

Abstract: According to one embodiment, a memory includes a memory cell array including blocks arranged in a column direction, first and second main global conductive lines each extending from a first end to a second end of the memory cell array in the column direction, a first resistance change element connected between the first and second main global conductive lines inside the memory cell array, a first reference global conductive line extending from the first end to the second end of the memory cell array in the column direction, and a second resistance change element connected to the reference global conductive line outside the memory cell array.

Abstract: A nonvolatile semiconductor device which can be driven at low voltage is provided. A nonvolatile semiconductor device with low power consumption is provided. A Schmitt trigger NAND circuit and a Schmitt trigger inverter are included. Data is held in a period when the supply of power supply voltage is continued, and a potential corresponding to the data is stored at a node electrically connected to a capacitor before a period when the supply of power supply voltage is stopped. By utilizing a change in channel resistance of a transistor whose gate is connected to the node, the data is restored in response to the restart of the supply of power supply voltage.

Abstract: According to one embodiment, a resistance change type memory includes a first and a second bit lines, a memory cell connected between the first and second bit lines and including a variable resistance element as a memory element and a first select element including a first control terminal connected to a word line, and an auxiliary circuit connected to the first bit line and including a second select element including a second control terminal connected to a control line. When data is read from the memory cell, a first current in a read current supplied to the first bit line is supplied to the memory element and the first select element, and a second current in the read current is supplied to the second select element.

Abstract: According to one embodiment, a memory includes a resistance change element connected between first and second conductive lines, a write buffer which writes data in the resistance change element by flowing a write current to the resistance change element through the first and second conductive lines in a writing, a current/voltage converter which converts the write current into a sense voltage, the converter provided in the write buffer, the write buffer being non-activated when the sense voltage is larger than a first threshold value.

Abstract: A control circuit, on selecting a memory cell as a selected memory cell to perform a write operation, before executing the write operation, applies a first voltage to the selected memory cell via a first line and a second line to perform a first read operation. The control circuit, when judged that a result of the first read operation does not match write data intended to be written, executes the write operation. The control circuit, when judged that a result of the first read operation matches write data intended to be written, omits a voltage application operation for the write operation. The first voltage is larger than a second voltage which is applied to the selected memory cell via the first line and the second line in a second read operation, the second read operation acting as a normal read operation for reading held data of the memory cell.

Abstract: According to one embodiment, a resistance change memory includes the following configuration. A first inverter includes first input and first output terminals and first and second voltage terminals. A second inverter includes second input and second output terminals and third and fourth voltage terminals. The second input terminal is connected to the first output terminal. The second output terminal is connected to the first input terminal. First and second transistors are connected to the first and second output terminals, respectively. Third and fourth transistors are connected to the first and third voltage terminals, respectively. A fifth transistor is connected between the first voltage terminal and the first memory cell. A sixth transistor is connected to the third voltage terminal. A controller turns on the first and second transistors, after turning off the fifth and sixth transistors.

Abstract: According to one embodiment, a resistance change memory includes a memory cell, a sense amplifier and a global bit line. The memory cell is disposed at a location where a local bit line and a word line intersect each other. The memory cell is connected to both the local bit line and the word line. The sense amplifier reads data stored on the memory cell by supplying a read current to the memory cell. The global bit line is connected between the local bit line and the sense amplifier. The global bit line feeds the read current supplied by the sense amplifier to the local bit line. The sense amplifier charges the global bit line, before the local bit line and the global bit line are connected to each other.

Abstract: According to one embodiment, a memory device includes a memory cell, a sense amplifier, and a resistor. The sense amplifier includes a first input and a second input, outputs a signal in accordance with a difference between the first and second inputs, and is selectively coupled at a second input to the memory cell. The resistor is in a first path between the first input of the sense amplifier and a ground node.

Abstract: Systems and methods of synchronous memories and synchronous memory operation are disclosed. According to one illustrative implementation, a memory device is disclosed comprising memory circuitry having a memory output, the memory circuitry including a sense amplifier having a first output and a second output, a first data path coupled to the first output of the sense amplifier, the first data path including 2 latches/registers, and a second data path coupled to the second output of the sense amplifier, the second data path including a plurality latches/registers. In further implementations, various control circuitry, connections and control signals may be utilized to operate the latches/registers in the first and second data paths according to specified configurations, control, modes, latency and/or timing domain information, to achieve, for example, pipelined output latching and/or double data rate output.

Abstract: According to one embodiment, a magnetoresistive element comprises a storage layer having perpendicular magnetic anisotropy with respect to a film plane and having a variable direction of magnetization, a reference layer having perpendicular magnetic anisotropy with respect to the film plane and having an invariable direction of magnetization, a tunnel barrier layer formed between the storage layer and the reference layer and containing O, and an underlayer formed on a side of the storage layer opposite to the tunnel barrier layer. The reference layer comprises a first reference layer formed on the tunnel barrier layer side and a second reference layer formed opposite the tunnel barrier layer. The second reference layer has a higher standard electrode potential than the underlayer.

Abstract: According to one embodiment, a power supply circuit includes a first circuit connected to a first line, to which a power supply voltage is applied, and a second line, and a power supply clamp circuit connected to the first and second lines. The power supply clamp circuit includes a current path circuit which connects the first and the second lines to each other, and a control circuit which outputs a control signal to the current path circuit. The current path circuit includes a transistor and a diode group. The power supply clamp circuit is driven during a period in which a first voltage is applied to the first line and controls a potential of the first line so as to become a potential lower than the first voltage.

Abstract: According to one embodiment, a semiconductor memory device includes first word lines connected to a memory cell array, second word lines connected to a redundancy area, a first row decoder configured to perform selecting from the first word lines based on a row address, a judgment circuit configured to determine whether or not a replacement operation with the redundancy area is needed based on a redundancy address included in the row address, and a second row decoder configured to perform selecting from the second word lines. The row address includes a first row address and a second row address input in order in a time-sharing method. The first row address includes all of the redundancy address.

Abstract: According to one embodiment, a semiconductor memory device includes a memory cell array, a buffer configured to hold data input to an input/output circuit and to hold data read from the memory cell array, and a controller configured to receive a first command and an address from the outside and to read data, in response to the first command, from a memory cell group coupled to a selected word line designated by the address to the buffer. The controller receives a second command which is input after the first command and indicates a last command of a group of commands including write commands and/or read commands, and starts a write operation from the buffer to the memory cell array in response to the second command.

Abstract: According to one embodiment, a memory device includes a memory cell, a sense amplifier, unit structures and a reference signal generator. Each structure includes a first end, a first transistor, a first local line, a variable resistance element, a second transistor, a second local line, and a third transistor coupled in series. The reference signal generator includes first to fourth global lines, and first and second ones of the unit structures. The first unit structure is coupled at the first end to the first global line and coupled at the second end to the third global line. The second unit structure is coupled at the first end to the fourth global line and coupled at the second end to the second global line.

Abstract: A semiconductor integrated circuit system includes a phase-change line including a first phase-change area constituting a first memory cell and a second phase-change area constituting a second memory cell, a write current providing unit configured to phase-change a selected one of the first and second phase-change areas, and a phase-change compensation unit configured to restore the other of the first and second phase-change areas by compensating for a dummy phase-change caused in the other phase-change area due to a phase-change of the selected phase-change area.

Abstract: A semiconductor integrated circuit system includes a phase-change line including a first phase-change area constituting a first memory cell and a second phase-change area constituting a second memory cell, a write current providing unit configured to phase-change a selected one of the first and second phase-change areas, and a phase-change compensation unit configured to restore the other of the first and second phase-change areas by compensating for a dummy phase-change caused in the other phase-change area due to a phase-change of the selected phase-change area.

Abstract: A semiconductor integrated circuit includes a reference voltage generation circuit configured to generate a reference voltage, and a voltage changing circuit configured to generate a second voltage from a first voltage based on a difference between the second voltage and the reference voltage and apply the second voltage to a load capacitance. The reference voltage generation circuit includes a variable current source and a capacitor which are connected in series and is configured to change the reference voltage linearly.

Abstract: This disclosure concerns memory kink checking. One embodiment includes selectively applying one of a plurality of voltages to a first data line according to a programming status of a first memory cell, wherein the first memory cell is coupled to the first data line and to a selected access line. An effect on a second data line is determined, due at least in part to the voltage applied to the first data line and a capacitive coupling between at least the first data line and the second data line, wherein the second data line is coupled to a second memory cell, the second memory cell is adjacent to the first memory cell, and the second memory cell is coupled to the selected access line. A kink correction is applied to the second data line, responsive to the determined effect, during a subsequent programming pulse applied to the second memory cell.

Abstract: According to one embodiment, a semiconductor memory device includes a NAND string and a sense amplifier. The NAND string includes a memory cell transistor to be capable of holding any of three or more levels of values. The NAND string includes one end connected to a bit line and the other end connected to a source line. The sense amplifier connects the bit line. A first voltage is applied to the source line when a first read voltage is applied to a selected word line connected to a selected memory cell transistor. A second voltage is applied to the source line when a second read voltage is applied to the selected word line. The first voltage is higher than the second voltage. The first read voltage is the lowest voltage of a plurality of read voltage. The second read voltage is higher than the first read voltage.

Abstract: Methods, devices, and systems for data modulation for groups of memory cells. Data modulation for groups of memory cells can include modulating N units of data to a combination of programmed states. Each memory cell of a group of G number of memory cells can be programmed to one of M number of programmed states, where M is greater than a minimum number of programmed states needed to store N/G units of data in one memory cell, and where the programmed state of each memory cell of the group is one of the combination of programmed states.

Abstract: A non-volatile semiconductor memory device includes first through third memory strings, a first word line group shared by first and second memory strings and a second word line group shared by second and third memory strings, the first and second word line groups extending in a first direction and disposed adjacent to each other in a second direction that is perpendicular to the first direction. The first word line group includes laminated first word lines with each upper first word line extending in the first direction less than the first word line directly below, and the second word line group includes laminated second word lines with each upper second word line extending in the first direction less than the second word line directly below.

Abstract: A memory device includes an array of memory cells arranged as a plurality of rows and columns, each row being coupled to an associated read word line, and each column forming at least one column group, where the memory cells of each column group are coupled to an associated read bit line. Each column group includes circuitry to precharge the associated read bit line to a first voltage level prior to the read operation. Each memory cell has coupling circuitry connected between the associated read bit line and a second voltage level different to the first voltage level. During read operation the coupling circuitry associated with the activated memory cell selectively discharges the associated read bit line towards the second voltage level dependent on the data value stored within that activated memory cell. The clamping circuitry connects the associated read bit line to the second voltage level.

Abstract: A memory includes an array of memory cells including rows and columns. The memory includes circuitry coupled to the word lines applying a first bias voltage to a first set of spaced-apart locations on a word line or word lines in the array, while applying a second bias voltage different than the first bias voltage, to a second set of spaced-apart locations on the word line or word lines, locations in the first set of spaced-apart locations being interleaved among locations in the second set of spaced-apart locations, whereby current flow is induced between locations in the first and second sets of locations that cause heating of the word line or word lines.

Abstract: A nonvolatile semiconductor memory device according to an embodiment includes a memory string having a plurality of electrically rewritable memory transistors connected in series therein. The memory string includes a first semiconductor layer including a columnar portion extending in a perpendicular direction to a substrate; a tunnel insulating film formed surrounding a side surface of the columnar portion; a charge storage film formed surrounding the tunnel insulating film; a block insulating film formed surrounding the charge storage film; and a plurality of first conductive layers formed surrounding the block insulating film and disposed with a certain spacing along the perpendicular direction. The charge storage film includes a first charge storage film having a conducting property and located in contact with the tunnel insulating film; and a second charge storage film having an insulating property and formed between the first charge storage film and the block insulating film.

Abstract: A semiconductor memory device includes a memory cell array that is capable of storing data in a nonvolatile manner, and a control section that controls data access to the memory cell array. The memory cell array stores the same data redundantly in a plurality of pages. The control section executes a reading operation on the plurality of pages that store the same data redundantly to read the data. The data that is stored redundantly may be management data or user data.

Abstract: A nonvolatile semiconductor memory device includes a control circuit configured to control a soft program operation of setting nonvolatile memory cells to a first threshold voltage distribution state of the nonvolatile memory cells. When a characteristic of the nonvolatile memory cells is in a first state, the control circuit executes the soft program operation by applying a first voltage for setting the nonvolatile memory cells to the first threshold voltage distribution state to first word lines, and applying a second voltage higher than the first voltage to a second word line. When the characteristic of the nonvolatile memory cells is in a second state, the control circuit executes the soft program operation by applying a third voltage equal to or lower than the first voltage to the first word lines and applying a fourth voltage lower than the second voltage to the second word line.

Abstract: Different back bias (or body bias) conditions are applied to a non-volatile storage system during different program verify operations of a programming operation. A back bias may be applied during verify of an intermediate state (e.g., a lower page, middle page). The intermediate state is a state that exists during a program operation, but is not one of the final states. A lower back bias or no back bias is applied during verify of a final state (e.g., an upper page). Thus, a different back bias may be used when verifying an intermediate state than the back bias used when verifying a final state. Using the back bias makes it easier to verify a low VTH, such as a negative VTH. Also, using the back bias is effective at dealing with sense amplifier headroom issues.

Abstract: A method of optimizing solid state drive (SSD) soft retry voltages comprises limiting a number of voltage reads and properly spacing and determining the reference voltage at which each voltage is read based on desired Bit Error Rate (BER) and channel throughput. The method determines each reference voltage for a number of soft retry voltage reads based on a hard decision read. The spacing between each read reference voltage is constant since each SSD type requires a number of reads for an accurate presentation of soft retry voltages. The voltage distance between each successive read is limited to a multiple of the constant spacing while the multiple is based on success or failure of the first read. The method determines a limited number of reads, the constant spacing between reads, and a desired reference voltage for each read, thereby increasing valuable throughput of the channel and decreasing BER.

Abstract: A non-volatile semiconductor memory device includes a memory cell configured to allow electrical writing and erasing, a bit line configured to transmit a potential corresponding to data stored in the memory cell in a column direction, a sense amplifier circuit configured to detect a potential of the bit line, and a bit line coupling circuit coupled between the bit line and the sense amplifier circuit. The bit line coupling circuit includes a first bit line coupling transistor in an outer layout area of the bit line coupling circuit and a second bit line coupling transistor in an inner layout area of the bit line coupling circuit. The first bit line coupling transistor has a longer distance in a channel length direction or in a channel width direction between an impurity diffused layer coupled to the bit line and an element isolation area than the second bit line coupling transistor.

Abstract: According to one embodiment, a non-volatile semiconductor memory device which is provided with a memory cell array, bit lines, word lines, and a sense amplifier circuit is presented. The memory cell array includes memory cells. The bit lines are electrically connected to the memory cells. The word lines are electrically connected to gates of the non-volatile memory cells. The sense amplifier circuit includes sense amplifiers which are electrically connected to the bit lines. Each of the sense amplifiers includes a latch circuit which is capable of holding data, and a detection circuit. The sense amplifiers are configured to apply any one of a first voltage and a second voltage higher than the first voltage to the bit lines respectively. The sense amplifiers apply any one of the first voltage and the second voltage s a third voltage to the bit lines, and apply the third voltage to the detection circuit.

Abstract: A NAND flash memory unit, an operating method and a reading method are provided. The NAND flash memory unit includes a plurality of gate layers, a tunnel layer, a charge trapping layer, a conductor layer and a second dielectric layer. A first dielectric layer is included between two adjacent gate layers among the gate layers. The tunnel layer, the charge trapping layer, the conductor layer, and the second dielectric layer penetrate the gate layers. The charge trapping layer is disposed between the tunnel layer and the gate layers, and the second dielectric layer is disposed between the conductor layer and the tunnel layer. Therefore, an erasing speed may be increased; the charge trapping layer may be repaired; the controllability of the gate layers may be increased.

Abstract: Memory devices, memory cell strings and methods of operating memory devices are shown. Configurations described include directly coupling an elongated body region to a source line. Configurations and methods shown should provide a reliable bias to a body region for memory operations such as erasing.

Abstract: A memory system includes a plurality of memory devices having data terminals that are commonly connected to a memory controller. Each of the memory devices includes a data output circuit that outputs read data that is read from a memory cell array in response to a read command to the data terminal, and an output-timing adjustment circuit that adjusts an output timing of read data that is output from the data output circuit. The memory controller sets an adjustment amount of adjustment performed by an output-timing adjustment circuit such that delay times from when the read command is issued until when the read data is received match in the memory devices, by issuing a setting command to each of the memory devices.

Abstract: According to one embodiment, a semiconductor memory device includes n (n being a natural number of 2 or more) data retention circuits connected to a data input/output terminal; n buses connected respectively to the n data retention circuits; m×n data latch circuits connected to the buses, with m (m being a natural number of 2 or more) data latch circuits being connected per one of the buses; and a selection circuit configured to simultaneously perform data transfer from/to the data retention circuits for a plurality of the data latch circuits in units of a group including the plurality of the data latch circuits, the data latch circuits being divided into the groups so that not all the data latch circuits connected to the same bus are included in the same group.

Abstract: A semiconductor device includes an output circuit having a plurality of unit buffer circuits, an impedance of each unit buffer circuit of the plurality of unit buffer circuits being adjustable, a control circuit configured to selectively activate one or more unit buffer circuits of the plurality of unit buffer circuits, and an impedance adjustment unit configured to adjust the impedance of each of the unit buffer circuits of the plurality of unit buffer circuits. The impedance adjustment unit includes a first power line, a replica circuit, and a load current generation circuit. The replica circuit and the load current generation circuit are coupled in common to the first power line, the replica circuit has a replica impedance that is substantially equal to the impedance of the output circuit, and the load current generation circuit changes current flowing therethrough.

Abstract: A semiconductor memory device comprises: a plurality of on-die termination circuits connected to each of a plurality of input/output pads; and a control circuit for controlling the on-die termination circuit. The on-die termination circuit comprises: a pull-up element connected between a first terminal and an output terminal; and a pull-down element connected between the output terminal and a second terminal. The pull-up element is driven by a first pull-up element driver, and the pull-down element is driven by a first pull-down element driver. The control circuit activates a plurality of the on-die termination circuits at different timings.

Abstract: A domain crossing circuit of a semiconductor apparatus includes a delay-locked loop block configured to generate a delay-locked loop clock signal in response to a clock signal and a clock enable signal; a clock enable block configured to generate the clock enable signal in response to the clock signal and a read command signal; and a command pass block configured to perform primary latency control according to the clock signal and secondary latency control according to the delay-locked loop clock signal, for the read command signal generated in response to a strobe signal, and generate a latency signal.

Abstract: Disclosed herein is an apparatus that includes a first semiconductor chip including a first electrode, and a second semiconductor chip including a second electrode connected to the first electrode. One of the first and second semiconductor chips includes a first temperature sensor circuit generating a first detection signal, the first detection signal taking a first level when a temperature is equal to or higher than a first temperature, the first detection signal taking a second level when the temperature is lower than the first temperature; and a first delay code generation circuit outputting a first delay code signal in response to the first level of the first detection signal, and outputting a second delay code signal different from the first delay code signal in response to the second level of the first detection signal.

Abstract: Disclosed herein is an apparatus that includes: a plurality of memory banks each including a plurality of memory cells; a plurality of redundant circuits each allocated to an associated one of the plurality of memory banks to replace a defective memory cell among the plurality of memory cells included in the associated memory bank; a plurality of roll call circuits allocated to an associated one of the plurality of memory banks to generate a roll call data when an address corresponding to the defective memory cell is supplied; and a plurality of data buses commonly allocated to the plurality of memory banks. The roll call circuits output the roll call data to the plurality of data buses in parallel.

Abstract: A method for limiting writing of data to a specific memory cell without disconnecting a wiring of a memory cell array or placing a prober in contact with a memory cell, a row, or a column is provided. Row address data and column address data of a memory cell to which data cannot be written are stored in a register. Enable data which controls data writing is stored in the register. Next, in order to write data to a memory cell, row address data and column address data of a memory cell to which data is written, writing enable data, and the like are output from a logic circuit; thus, writing of data to a memory cell corresponding to the address data stored in the register is inhibited.

Abstract: According to one embodiment, a memory includes a memory cell array with banks, each bank including rows, a first word lines provided in corresponding to the rows, an address latch circuit which latches a first row address signal, a row decoder which activates one of the first word lines, and a control circuit which is configured to execute a first operation which activates one of the banks based on a bank address signal when a first command is loaded, and a second operation which latches the first row address signal in the address latch circuit, and execute a third operation which activates one of the first word lines by the row decoder based on a second row address signal and the first row address signal latched in the address latch circuit when a second command is loaded after the first command.

Abstract: A device and a method for a sense circuit have been disclosed. In an implementation, the sense circuit includes a sense amplifier and at least one decoupling device. The decoupling device is coupled to the sense amplifier through at least one reference line. The sense amplifier reads a data value and the decoupling device decouples the sense amplifier from a power supply during a read operation.

Abstract: In an exemplary aspect, the present invention provides a semiconductor memory device including sense amplifiers that drive bit lines to which memory cells are connected, and driver transistors that supply a power supply to the sense amplifiers, wherein the sense amplifiers are arranged in rows and constitutes a first sense-amplifier row in which transistors of a first conductive type are arranged and a second sense-amplifier row in which transistors of a second conductive type are arranged, and the driver transistors constitutes at least one transistor row including a first driver transistor of the first conductive type corresponding to the first sense-amplifier row and a second driver transistor of the second conductive type corresponding to the second sense-amplifier row between the first sense-amplifier row and the second sense-amplifier row.

Abstract: A method for accessing a semiconductor device having a memory array, includes receiving a chip select signal, receiving a command signal and an address signal, receiving a verification signal, calculating an error signal based on the address signal, the command signal, and the verification signal, generating an internal chip select signal based on the received chip select signal if the error signal indicates no error, and generating an external alert signal if the error signal indicates an error.

Abstract: During a command/address calibration mode, a memory controller may transmit multiple cycles of test patterns as signals to a memory device. Each cycle of test pattern signals may be transmitted at an adjusted relative phase with respect to a clock also transmitted to the memory device. The memory device may input the test pattern signals at a timing determined by the clock, such as rising and/or falling edges of the clock. The test pattern as input by the memory device may be sent to the memory controller to determine if the test pattern was successfully transmitted to the memory device during the cycle. Multiple cycles of test pattern transmissions are evaluated to determine a relative phase of command/address signals with respect to the clock for transmission during operation of the system.

Abstract: A blending device is shown and described. The blending device may include a blending container and a power source operatively connected to the blending container. The power source may be configured to supply power to the blending container. The blending container may also include a feature that is powered by the power source.

Abstract: Apparatus (1) for admixing additives to a medium to be pumped, comprising at least one gear pump (2) for pumping a medium to be pumped, said gear pump (2) comprising at least one shaft (3) having a first driving torque; at least one injector (5) for introducing an additive into a medium to be pumped; at least one screw conveyor (6) for mixing said additive with said medium to be pumped, said screw conveyor having a second driving torque, and, characterized in that, the shaft (3) and the screw conveyor (6) are functionally connected, such that the first driving torque and the second driving torque are coupled.

Abstract: Methods are provided for achieving dynamic mixing of two or more fluid streams using a mixing device. The methods include providing at least two integrated concentric contours that are configured to simultaneously direct fluid flow and transform the kinetic energy level of the first and second fluid streams, and directing fluid flow through the at least two integrated concentric contours such that, in two adjacent contours, the first and second fluid streams are input in opposite directions. As a result, the physical effects acting on each stream of each contour are combined, increasing the kinetic energy of the mix and transforming the mix from a first kinetic energy level to a second kinetic energy level, where the second kinetic energy level is greater than the first kinetic energy level.