Abstract: A semiconductor memory device including: a package; a first semiconductor chip provided in the package; a first nonvolatile memory provided on the first semiconductor chip; a second semiconductor chip provided in the package; a second nonvolatile memory provided on the second semiconductor chip; a system bus provided in the package, the system bus connecting the first and second nonvolatile memories; a plurality of data terminals exposed to outside of the package, the data terminals being connected to the first and second nonvolatile memories through the system bus; and an enable terminal exposed to the outside of the package, the enable terminal being connected to the first and second nonvolatile memories.

Abstract: The present disclosure relates to memory arrays with read reference voltage cells. In particular the present disclosure relates to variable resistive memory cell apparatus and arrays that include a high resistance state reference memory cell and a low resistance state reference memory cell that provides a reliable average reference voltage on chip to compare to a read voltage of a selected memory cell and determine if the selected memory cell is in the high resistance state or low resistance state. These memory arrays are particularly suitable for use with spin-transfer torque memory cells and resolves many systematic issues related to generation of a reliable reference voltage.

Abstract: A method for a read-before-write functionality for a memory within a programmable logic device (PLD) is provided. The method begins when a read operation and a write operation are initiated through two different ports of a memory simultaneously to access the same address in the memory. In order to prevent the write operation from proceeding prior to the read operation, a read-before-write control logic is provided to the control block of the port that supports the write operation. Thus, the write operation is paused until the control block of the port that supports the write operation receives a signal from a read sense amplifier indicating that the read operation is complete. The read sense amplifier is capable of detecting the completion of a read operation by monitoring the voltage difference of the read bitline. When this voltage difference reaches a threshold value, the read sense amplifier triggers a write wordline signal.

Abstract: A method of for programming a push-pull memory cell to simultaneously program a p-channel non-volatile transistor and an n-channel non-volatile transistor includes driving to 0 v wordlines for any row in which programming of memory cells is to be inhibited; driving to a positive voltage wordlines any row in which programming of memory cells is to be performed; driving to a positive voltage the bitlines for any column in which programming of memory cells is to be inhibited; driving to a negative voltage the bitlines for any column in which programming of memory cells is to be performed; driving to one of 0 v and a negative voltage a center wordline for any row in which programming of memory cells is to be inhibited; and driving to one of 0 v and a positive voltage the center wordline for any row in which programming of memory cells is to be performed.

Abstract: A set of reference cells is used for sensing the data values stored at bit cells of a memory device. In response to an event, the reference cell providing the highest output of the set is selected as the reference cell to be used for subsequent memory access operations. The remaining reference cells are disabled so that they can recover back to or near their original non-degraded states. At each successive event, the set of reference cells can be reassessed to identify the reference cell that provides the highest output at that time and the memory device can be reconfigured to utilize the reference cell so identified. By utilizing the reference cell having the highest output to provide the read reference and disabling the remaining reference cells, the likelihood of the read reference falling below a minimum threshold can be reduced.

Abstract: A non-volatile semiconductor memory device includes a read voltage generating circuit, a flash cell fuse circuit and a row decoder. The read voltage generating circuit generates a read voltage in response to a read enable signal and a trim code. The flash cell fuse circuit generates the trim code in response to a cell selection signal and a fuse word-line enable signal, the fuse word-line enable signal being activated after the read enable signal by a first delay time. The row decoder decodes the read voltage in response to a row address signal to generate a decoded read voltage, and to provide the decoded read voltage to a memory cell array.

Abstract: A method for reading data in a nonvolatile memory at a power-on stage is provided and includes the following steps. Firstly, the data are read through a reference voltage. Next, a failure number is counted when reading the data has a fail result. Next, the reference voltage is adjusted when the failure number reaches a predetermined number. The effect effectively and exactly reading configuration information at a power-on stage is accomplished through the method.

Abstract: A semiconductor memory device comprises a plurality of banks including a plurality of mat rows, respectively, wherein the mat row includes a plurality of mats disposed in a same row, row decoder groups disposed between the banks and including row decoders that correspond to the mat rows, respectively, and common control blocks installed corresponding to a predetermined number of row decoders to simultaneously control the row decoders.

Abstract: Provided are a semiconductor memory device and a data write and read method thereof. The semiconductor memory device includes a write data controller, an address controller, and a read data controller. The write data controller writes data received with an address to a first memory cell corresponding to the address and simultaneously stores the data in a data register. The address controller decodes and stores the address in an address register. The read data controller outputs data from a second memory cell corresponding to an address received with a data read command if the received address is different from the address stored in the address register, and outputs the data stored in the data register if the received address is equal to the address stored in the address register.

Abstract: Embodiments of the invention relate to the testing and reduction of read disturb failures in a memory, e.g., an array of SRAM cells. A read disturb test mode may be added during wafer sort to identify any marginal memory cells that may fail read disturb, thus minimizing yield loss. The read disturb test mode may include first writing data to the memory. After a predetermined time period, the read disturb test mode reads data from the same memory, and compares the read data with the data previously written to the memory. A repair signal may be generated, when the read data is different from the data previously written to the memory. Additionally, a system may be implemented to reduce read disturb failures in the memory. The system may include a match logic circuit and a data selecting circuit. When a match condition is satisfied, data is read from a register that stores the previous written data, instead of from the memory. The match logic circuit may be selectively enabled or disabled.

Abstract: A static random access memory (SRAM) circuit includes first SRAM cell and a second SRAM cell that are configured to operate in a shared mode and/or an independent mode. In one example, a shared mode includes the sharing of a memory node of a first SRAM cell. In another example, an independent mode includes isolating a first SRAM cell from a second SRAM cell such that they operate independently.

Abstract: The data output circuit for a semiconductor memory apparatus includes a first control signal generating unit configured to generate a first control signal according to a row address and a read command; and a data selecting unit configured to select data from a data line corresponding to a presently selected unit data output mode among data lines according to the first control signal or a second control signal, and output the data.

Abstract: A ramp-down programming voltage is used to program a group of nonvolatile memory cells in parallel, step by step from a highest step to a lowest step. Overall programming time is improved when a conventional setup for program inhibit together with a verify after each program step are avoided. A program voltage estimate is provided for each cell indicating the programming voltage expected to program the cell to its target. Initially, all but those cells having estimates at or above the current program voltage step will be program-inhibited. Thereafter, with each descending program voltage step, additional cells will be un-inhibited. Once un-inhibited, a cell need not be re-inhibited even if programmed to its target. This is because subsequent program steps are at lower voltages and ineffective in programming the cell beyond its target. The un-inhibit operation in one implementation amounts to simply pulling the associated bit lines to ground.

Abstract: An array of non-volatile memory cells arranged in logical columns and logical rows, and associated circuitry to enable reading or writing one or more memory cells on a row in parallel. In some embodiments, the array of memory cells may include a phase change material. In some embodiments, the circuitry may include a write driver, a read driver, a sense amplifier, and circuitry to isolate the memory cells from the sense amplifier with extended refresh.

Abstract: A semiconductor memory device comprise a word line, a bit line intersecting the word line, a memory element arranged at intersections of the word line and the bit line and having different required time for a write operation according to a logical value of write data, a write driver supplying a write current to the bit line, a write control circuit controlling operations of the write driver, and a timing signal generation circuit supplying a timing signal to the write control circuit. The timing signal has a waveform including a pulse indicating a time of starting supplying the write current when a first logical level is to be written, a pulse indicating a time of ending supplying the write current if the first logical level is to be written, and a pulse indicating one of a time of starting supplying the write current and a time of ending supplying the write current when a second logical level is to be written.

Abstract: Separate read and write ports in a memory system allow simultaneous access to a memory cell array by read and write operations. A single cycle operation of a central processing unit coupled to a memory array depends on a memory access capability providing simultaneous reading and writing to different locations. A pair of pull-down transistor stacks connected to memory cell latch loops allows a single selected pull-down stack of the pair to toggle a memory cell latch loop to a desired data content without any requirement for a precharge scheme. A single pull-down stack of transistors connected to a memory cell latch loop provides a read port with low input loading. A sense amplifier provides a mid-supply-level precharging capability provided by a feedback device within a front-end inversion stage. When not in a feedback mode, the front-end inversion stage cascaded with a second inversion stage provides a rapid read response.

Abstract: A circuit and method includes first circuits powered by a first supply voltage and second circuits powered by a second supply voltage. A level shifter is coupled between the first circuits and the second circuits. The level shifter is configured to select a supply voltage output for a circuit including one of the first supply voltage and the second supply voltage in accordance an input signal, where the input signal depends on at least one of an operation to be performed and component performing the operation.

Abstract: In a method of writing information into and reading information from an information storage element which includes a strip-shaped ferromagnetic material layer, a first electrode disposed at an end of the ferromagnetic material layer, a second electrode disposed at another end of the ferromagnetic material layer, and an antiferromagnetic region composed of an antiferromagnetic material and disposed in contact with at least a part of the ferromagnetic material layer, the method includes the steps of applying a current between the first electrode and the second electrode to cause a current-induced domain wall motion; in the ferromagnetic material layer, writing a magnetization state into a magnetization region as information or reading a magnetization state from a magnetization region as information; and eliminating or decreasing exchange coupling between the ferromagnetic material layer and the antiferromagnetic region at the time of the motion of a domain wall.

Abstract: A semiconductor memory device is capable of simultaneously carrying out a first operation and a second operation. The semiconductor memory device includes first and second control circuits, a select control circuit, and a select circuit. The first control circuit controls the first operation according to a first address signal and outputs a read start signal when the reading of the data is started. The second control circuit controls the second operation according to a second address signal and outputs a sequence flag when the first and second addresses coincide with each other. The select control circuit generates a select control signal. The select control signal is asserted if the second operation is carried out. The first control circuit instructs the select circuit to select the sequence flag if the select control signal is asserted or the data if the select control signal is negated.

Abstract: A nonvolatile ferroelectric memory immediately outputs data stored in a page buffer without performing a cell access operation when a page buffer is accessed. Since a block page address region and a column page address region are arranged in less significant bit region, and a row address region is arranged in more significant bit region, the cell operation is not performed in the access of the page address buffer, thereby improving reliability of the cell and reducing power consumption.

Abstract: Implementations are presented herein that relate to a memory cell, a memory device, a device and a method of accessing a memory cell.

Abstract: For one disclosed embodiment, an apparatus may comprise a first die including a first plurality of memory cells for a memory array and a second die including a second plurality of memory cells for the memory array. The second die may include a shared line for the memory array to conduct digital signals for memory cells of both the first and second plurality of memory cells. Other embodiments are also disclosed.

Abstract: A semiconductor memory device having a memory cell array, an input buffer, an output buffer, and an input-output control circuit that receives a write control signal and controls the input and output buffers. The output buffer generates a commencement signal indicating commencement of output. A mask generating circuit generates a mask signal with delayed active-to-inactive transitions from the commencement signal. A masking circuit passes the write control signal to the input-output control circuit while the mask signal is inactive, and holds the write control signal in the write-disabling state while the mask signal is active. The mask signal prevents unintended writing of data in the memory cell array when the write control signal is contaminated by noise from the output buffer.

Abstract: Methods of executing a multi-page copyback program in a non-volatile memory device are provided, where the non-volatile memory device includes a memory having a plurality of memory blocks. A page of data of the memory block having a first address is replaced responsive to a generated multi-page copyback program command. It is determined if the first address of the page of data is the same as a stored address of the page at which the failure was detected. The first address is incremented if it is determined that the first address and the stored address are not the same. The pages of data are replaced, the addressed are compared and the addresses are incremented until it is determined that the incremented address and the stored address are the same. Related devices and systems are also provided herein.

Abstract: A method for a read-before-write functionality for a memory within a programmable logic device (PLD) is provided. The method begins when a read operation and a write operation are initiated through two different ports of a memory simultaneously to access the same address in the memory. In order to prevent the write operation from proceeding prior to the read operation, a read-before-write control logic is provided to the control block of the port that supports the write operation. Thus, the write operation is paused until the control block of the port that supports the write operation receives a signal from a read sense amplifier indicating that the read operation is complete. The read sense amplifier is capable of detecting the completion of a read operation by monitoring the voltage difference of the read bitline. When this voltage difference reaches a threshold value, the read sense amplifier triggers a write wordline signal.

Abstract: Disclosed herein is a semiconductor memory device which can simultaneously perform a read access and a write access independently. The semiconductor memory device according to the present invention can access a plurality of data through the global sense amplifying unit and the global bit line, and enables the read controller and the write controller to independently control the global bit line and the bit line sense amplifying unit to be connected to each other to thereby perform the read access and the write access simultaneously.

Abstract: A non-volatile memory device may include a plurality of data cells, each data cell of the plurality of data cells programmed to have a first resistance variation among a plurality of first resistance variations; and a plurality of reference cells, each reference cell of the plurality of reference cells programmed to have a second resistance variation among a plurality of second resistance variations. A change in a resistance of the data cells is used to identify a level of data programmed to memory. Because the resistance variation of the data cells may change with time or due to changes in temperature, a reference cell is also included in the non-volatile memory device. The reference cell is used for effective reading of the data value of a corresponding data cell. A storage system may include the non-volatile memory device.

Abstract: A magnetic memory cell array device can include a first current source line extending between pluralities of first and second memory cells configured for respective simultaneous programming and configured to conduct adequate programming current for writing one of the pluralities of first and second memory cells, a first current source transistor coupled to the first current source line and to a word line, a programming conductor coupled to the first current source transistor and extending across bit lines coupled to the one of the pluralities of first and second memory cells, configured to conduct the programming current across the bit lines, a second current source transistor coupled to the programming conductor and configured to switch the programming current from the programming conductor to a second current source transistor output, a second current source line extending adjacent the one of the pluralities of first and second memory cells opposite the first current source line, a first bias circuit config

Abstract: A writing circuit for a phase change memory is provided. The writing circuit comprises a driving current generating circuit, a first switch device, a first memory cell and a second switch device. The driving current generating circuit provides a writing current to the first memory cell. The first switch device is coupled to the driving current generating circuit. The first memory cell is coupled between the first switch device and the second switch device. The second switch device is coupled between the first memory cell and a ground, wherein when the driving current generating circuit outputs the writing current to the first memory cell, the second switch device is turned on after the first switch device has been turned on for a first predetermined time period.

Abstract: The present invention is related to a composite flash memory device comprises a plural sector flash memory array which is divided to plural sector that is a minimum erasing unit of the flash memory device, a flash memory array storing control commands which control a total system of the composite flash memory device and/or the only composite flash memory device in and sharing I/O line of the plural sector flash memory array, the read operation of the flash memory array is enable when the plural sector flash memory array is gained access.

Abstract: Operating voltages to a group of memory cells in an array are supplied via access lines such as word lines and bit lines. The capacitance of associated nodes of the memory cells can latch some of these voltages. Memory operation can continue using the latched voltages even when the access lines are disconnected. In a memory have an array of NAND chains, the capacitance of the channel of each NAND chain can latch a voltage to either enable or inhibit programming. The bit lines can then be disconnected during programming of the group and be used for another memory operation. In one embodiment, the bit lines are precharged for the next verifying step of the same group. In another embodiment, two groups of memory cells are being programmed contemporarily, so that while one group is being programmed, the other group can be verified with the use of the bit lines.

Abstract: A memory may include word lines; bit lines; cells provided corresponding to intersections between the word lines and the bit lines; sense amplifiers detecting data; a column decoder selecting a certain bit line for the sense amplifiers to output read data or receive write data; a row decoder configured to select a certain word line; a charge pump supplying power to the sense amplifiers, the column decoder, and the row decoder; a logic circuit controlling the sense amplifiers, the column decoder, and the row decoder based on an address selecting the memory cells; a first power source input applying a voltage to the logic circuit; and a second power source input applying a voltage higher than a voltage of the first power source input to the charge pump, and to supply power to the charge pump at least at a data reading time and a data writing time.

Abstract: An integrated circuit device includes an embedded memory having a plurality of memory macros and a built-in-self-test (BIST) circuit coupled to the plurality of memory macros for simultaneous operation of the memory macros, wherein the BIST circuit is configured to select from the memory macros' data outputs an individual memory macro's data output for analysis while the memory macros are operated simultaneously.

Abstract: A semiconductor memory device that does not delay read/write access due to a refresh and can be interface compatible with a high-speed SRAM such as a QDR SRAM, comprises a plurality of subarrays each having a plurality of dynamic memory cells; at least one cache memory for the plurality of subarrays; a circuit to check whether data read from the subarray selected by a read address is present in the cache memory or not; and a circuit performing control so that the check result indicates that the data is present in the cache memory, the data is read from the cache memory and refreshing of the subarray is performed concurrently with a read cycle.

Abstract: Disclosed is a semiconductor memory device having memory cells that are in need of refresh for data retention, includes control circuits for necessarily generating the refresh immediately before the read/write operation, and for setting the latency to a first fixed value at all times, for the first mode during the testing, and for necessarily generating the refresh immediately after the read/write operation, and for setting the latency to a second fixed value at all times, for the second mode during the testing.

Abstract: An apparatus, system, and computer-implemented method for controlling data transfer between a plurality of serial data link interfaces and a plurality of memory banks in a semiconductor memory is disclosed. In one example, a flash memory device with multiple links and memory banks, where the links are independent of the banks, is disclosed. The flash memory devices may be cascaded in a daisy-chain configuration using echo signal lines to serially communicate between memory devices. In addition, a virtual multiple link configuration is described wherein a single link is used to emulate multiple links.

Abstract: A memory device is provided which has: a memory cell to store data; a word line to select the memory cell; a bit line connectable to the selected memory cell; a precharge power supply to supply a precharge voltage to the bit line; a precharge circuit to connect or disconnect the precharge power supply to or from the bit line; and a current limiting element to control the magnitude of a current flowing between the precharge power supply and the bit line at least by two steps according to an operation status.

Abstract: A method of writing data in a phase change memory includes; receiving write data to be written to a selected phase change memory cell in the plurality of phase change memory cells, sensing data stored in the selected phase change memory cell, determining whether or not the sensed data is equal to the write data, and if the sensed data is not equal to the write data, iteratively applying a write current to the selected phase change memory cell, wherein a resistance state of the phase change memory cell is changed by heat corresponding to a level of the write current, and the level of the write current is changed between successive iterative applications.

Abstract: One embodiment of the invention relates to a method for conditioning resistive memory cells of a memory array with a number of reliable resistance ranges, where each reliable resistance range corresponds to a different data state. In the method, group of at least one resistive memory cell is accessed, which group includes at least one unreliable cell. At least one pulse is applied to the at least one unreliable cell to shift at least one resistance respectively associated with the at least one unreliable cell to the highest of the reliable resistance ranges. Other methods and systems are also disclosed.

Abstract: A computational memory device includes an array of memory cells arranged in rows and columns, and a pair of read word lines associated with each row of the array. The array is configured to implement, for a given cycle, either a read operation of data contained in a single selected row, or one of a plurality of different bit wise logical operations on data contained in multiple selected rows.

Abstract: An embodiment of a method for driving a phase change memory, comprising counting an access number of a phase change memory, wherein the access number is the number of times that the phase change memory has been accessed; refreshing the phase change memory when the number of times is large than a predetermined number.

Abstract: One embodiment of the present invention sets forth a synchronous two-port static random access memory (SRAM) design with the area efficiency of a one-port SRAM. By restricting both access ports to an edge-triggered, synchronous clocking regime, the internal timing of the SRAM can be optimized to allow high-performance double-pumped access to the SRAM storage cells. By double-pumping the SRAM storage cells, one read access and one write access are possible per clock cycle, allowing the SRAM to present two external ports, each capable of performing one transaction per clock cycle.

Abstract: A semiconductor memory device comprises a one-transistor (1-T) field effect transistor (FET) type ferroelectric device connected between a pair of bit lines and controlled by a word line, where a different channel resistance is induced to a channel region depending on a polarity state of a ferroelectric layer; a plurality of access transistors connected between the ferroelectric device and the pair of bit lines; and a plurality of port word lines configured to select the plurality of access transistors.

Abstract: Integrated circuits such as programmable logic device integrated circuits are provided that have memory arrays that may be configured for true dual port operation or simple dual port operation. The memory arrays include memory cells arranged in rows and columns and associated row address lines and data lines. Sense amplifiers and write drivers are used for reading and writing data. Precharge drivers are used to precharge the data lines prior to read operations. Configurable multiplexer circuitry in the array has read paths through which data is provided to the sense amplifiers from the memory cells. The multiplexer circuitry has write paths through which data from the write drivers is written into the memory cells. The read paths and the write paths contain no more than a single pass gate each. Each precharge driver may be connected to a respective one of the data lines with no intervening pass gates.

Abstract: With this flash memory, because a plurality of memory blocks are formed on a surface of a single P-type well, a layout area can be made small. Further, when erasing data for a memory block to be erased, a voltage of the P-type well is applied to all word lines of a memory block to be not erased. Consequently, the voltage of the P-type well and the voltage of all word lines of the memory block to be not erased change at the same time. With this, it is possible to prevent a threshold voltage for the memory block to be not erased from changing.

Abstract: In a non-volatile memory storage system such as a flash EEPROM system, a controller switches the manner in which data sectors are mapped into blocks and metablocks of the memory in response to host programming and controller data consolidation patterns, in order to improve performance and reduce wear. Data are programmed into the memory with different degrees of parallelism.

Abstract: Various techniques are described to test memory arrays of a programmable logic device (PLD). In one example, a PLD includes a first memory array. The PLD also includes a plurality of sense amplifiers adapted to read a plurality of data values stored by the first memory array and provide a plurality of data signals corresponding to the data values. The PLD further includes a test circuit adapted to test the first memory array. The test circuit is coupled with the sense amplifiers and adapted to compare the data signals with a test signal to provide a pass/fail signal. In addition, the PLD includes a second memory array. The PLD also includes a data shift register adapted to test the second memory array.

Abstract: A computational system comprising a controller and a multi-plane solid state memory device accessible to the controller is disclosed. The controller is configured to provide access to a virtual block having a virtual block address that represents a first block from a first plane of the multi-plane solid state memory device and represents a second block from a second plane of the multi-plane solid state memory device.

Abstract: A flash memory device and a method of programming the same are disclosed. The flash memory device includes an array of memory cells intersected by a plurality of bit lines and a plurality of word lines. A page buffer circuit includes a plurality of latches coupled to an even virtual bit line and an odd virtual bitline. The page buffer circuit is configured to load data into the array of memory cells responsive to a select circuit, which is structured to electrically couple at least some of the bit lines to the plurality of latches of the page buffer circuit.

Abstract: A semiconductor memory such as a dynamic RAM having memory mats each divided into a plurality of units or sub-memory mats. Each sub-memory mat comprises: a memory array having sub-word lines and sub-bit lines intersecting orthogonally and dynamic memory cells located in lattice fashion at the intersection points between the intersecting sub-word and sub-bit lines; a sub-word line driver including unit sub-word line driving circuits corresponding to the sub-word lines; a sense amplifier including unit amplifier circuits and column selection switches corresponding to the sub-bit lines; and sub-common I/O lines to which designated sub-bit lines are connected selectively via the column selection switches. The sub-memory mats are arranged in lattice fashion.