Abstract: According to one embodiment, a semiconductor storage device includes cells, and a sense amplifier. Each of the cells is connected to a bit line. The sense amplifier reads out data. The sense amplifier includes a first transistor to third transistor, and a switch. The first transistor has one end of a current path, the other end, and a gate. The second transistor has one end, and the other end. The second transistor has one of a first and a second supply ability. The third transistor has one end, and the other end. The third transistor has one of a third and a fourth supply ability. The switch grounds the second and the third transistors. The sense amplifier turns off the first transistor after transferring the data to an outside, and supplies the second signal to the switch to set gates of the second transistor and third transistor to ground.

Abstract: Disclosed herein is a semiconductor device comprising complementary pair of bit lines, memory cells connected to the bit lines, dummy cells having the same structure as the memory cells, a differential sense amplifier, an equalizing circuit equalizing potentials of the bit lines, and a control circuit. The memory cells are disconnected from the bit lines and the dummy cells are connected to the bit lines, and subsequently the bit lines are equalized by the equalizing circuit. When accessing a selected memory cell, the equalizing circuit is inactivated, a corresponding dummy cell is disconnected from the bit line, and subsequently the selected memory cell is connected to the bit line. Thereafter, the sense amplifier is activated so that potentials of the bit lines are amplified respectively.

Abstract: A semiconductor memory device includes a memory cell array block including a plurality of memory cells each including a data holding circuit configured to store data using a first and a second circuit elements and a transistor configured to connect the data holding circuit and a bit line together, sense amplifiers connected to bit lines directly or via switches, and a dummy memory cell array including a plurality of dummy memory cells each having the same circuit configuration as that of the memory cell with respect to the element size and the layout configuration. The plurality of dummy memory cells each include at least one inverter circuit configuration, and are connected together by the inverter circuits being connected together in series. An output signal of the inverter circuit of one in the final stage of the dummy memory cells is an activation signal for the sense amplifiers.

Abstract: A memory cell array includes a plurality of normal word lines arranged at a first pitch, a plurality of repair word lines arranged at a second pitch, and a dummy boundary word line configured to be arranged between an outermost normal word line and an outermost repair word line.

Abstract: Provided is a resistive memory apparatus including a plurality of memory areas each including a main memory cell array coupled to a plurality of word lines and a reference cell array coupled to a plurality of reference word lines. Each of the memory areas shares a bit line driver/sinker with an adjacent memory area.

Abstract: A write-tracking circuit for a writable memory array has one or more dummy memory cells and is configured to write different values to the one or more dummy memory cells. Durations of pulses applied to word lines of the memory array during write operations are controlled based on durations of writing the different values to the one or more dummy memory cells. In at least some embodiments, the write-tracking circuit is configured to write the different values to the one or more dummy memory cells during a single write operation. In at least some embodiments, the write-tracking circuit is configured to write the different values to at least one of the one or more dummy memory cells during different write operations.

Abstract: A semiconductor memory includes a real memory cell; a sense amplifier configured to amplify data read from the real memory cell in response to activation of a sense amplifier enable signal; a replica circuit including a plurality of replica units connected in series, each of replica units including a plurality of dummy memory cells connected in parallel, wherein one of dummy memory cells of one of replica units is accessed in response to data which is read from one of dummy memory cells of one of replica units of a prior stage; and an operation control circuit configured to activate a dummy access signal to access one of dummy memory cells of one of replica units of a first stage in response to a read command, and to activate the sense amplifier enable signal in response to data read from one of replica units of a last stage.

Abstract: Included are reference cells each including a variable resistance element which reversibly changes between a predetermined low resistance state LR and a predetermined high resistance state HR according to an application of an electric signal, a comparator which compares resistance values of the reference cells, a pulse generation circuit which generates an electric signal for setting the reference cells to LR or HR, and a control circuit which controls operations where application of the generated electric signal to one of the reference cells corresponding to a comparison result of the comparator and application of a new electric signal generated by the pulse generation circuit to one of the reference cells corresponding to a new comparison result of the comparator are repeated, and then one of the reference cells corresponding to a final comparison result of the comparator is connected to an output terminal.

Abstract: An analog-to-digital conversion window is defined by reference voltages stored in reference memory cells of a memory device. A first reference voltage is read to define an upper limit of the conversion window and a second reference voltage is read to define a lower limit of the conversion window. An analog voltage representing a digital bit pattern is read from a memory cell and converted to the digital bit pattern by an analog-to-digital conversion process using the conversion window as the limits for the sampling process. This scheme helps in real time tracking of the ADC window with changes in the program window of the memory array.

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 data input circuit of a nonvolatile memory device includes a redundancy multiplexer configured to selectively output normal data and redundancy data to an internal global data line in response to a redundancy signal, a plurality of pipe registers coupled to the internal global data line and configured to latch normal data or redundancy data received through the internal global data line in response to a plurality of respective latch signals, and an output multiplexer configured to sequentially output the latched data in response to a plurality of selection signals.

Abstract: Disclosed herein is a semiconductor device comprising complementary pair of bit lines, memory cells connected to the bit lines, dummy cells having the same structure as the memory cells, a differential sense amplifier, an equalizing circuit equalizing potentials of the bit lines, and a control circuit. The memory cells are disconnected from the bit lines and the dummy cells are connected to the bit lines, and subsequently the bit lines are equalized by the equalizing circuit. When accessing a selected memory cell, the equalizing circuit is inactivated, a corresponding dummy cell is disconnected from the bit line, and subsequently the selected memory cell is connected to the bit line. Thereafter, the sense amplifier is activated so that potentials of the bit lines are amplified respectively.

Abstract: A method and apparatus for management worn resistive memory cells are presented. A normal read mode or worn memory cell detecting mode are used depending on the wear state of a resistive memory cell. A detection reference point is changed upon wear indication to detect the resistance of the resistive memory cell. The resistance of the resistive memory cell is detected using the changed detection reference point to determine whether or not the resistive memory cell is worn by comparing the detected resistance to a wear reference level.

Abstract: Memory circuits and systems are provided. One memory circuit includes an active memory device, an inactive memory device, and a sense amplifier coupled between the active memory device and the inactive memory device. A reference current is coupled between the inactive memory device and the sense amplifier. The active memory device and the inactive memory device are the same type of memory device and the inactive memory device is a reference device with respect to the active memory device's current. A memory system includes a plurality of the above memory circuit coupled to one another. Methods for sensing current in a memory circuit are also provided. One method includes supplying power to a first memory device and comparing the amount of current in the first memory device and a reference current coupled to a second memory device that is the same type of memory device as the first memory device.

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 semiconductor memory device includes a count clock generation unit for generating a count clock in response to a clock signal and a dummy count clock, a column address generation unit for generating a column address in response to the count clock, and a Y decoder for sending data, stored in a page buffer unit, to a data line in response to the column address.

Abstract: An integrated circuit bit line driver system includes a plurality of bit line drivers coupled to respective bit lines of an array of non-volatile memory cells. Each of the bit line drivers includes a bias transistor through which an input signal is coupled to the respective bit line. The bit line driver system includes a bias voltage circuit that generates a bias voltage that is coupled to the respective gates of the bias transistors. The bias voltage circuit initially accelerates the charging of the transistor gates, and subsequently completes charging the gates at a slower rate. The bias voltage is generated using a diode-coupled transistor having electrical characteristics the match those of the bias transistors so that the bias voltage varies with process or temperature variations of the integrated circuit in the same manner as the threshold voltage of the bias transistors vary with process or temperature variations.

Abstract: A memory element in which the temperature coefficient of a memory cell substantially matches the temperature coefficient of a reference cell and tuning either the temperature coefficient of a memory cell to substantially match the temperature coefficient of the reference cell provides for improved precision of sensing or reading memory element states, particularly so as to minimize the affect of temperature variations on reading and sensing states.

Abstract: A memory device comprises a memory cell array, a first and a second pre-charging switch circuits, a selecting circuit, an auxiliary memory cell array, a dynamic voltage controller and a sense amplifier. The auxiliary memory cell array comprises an auxiliary read bit line and a plurality of memory cells arranged in a column and electrically connected to the auxiliary read bit line. The second pre-charging switch circuit determines whether or not to supply a reference voltage to each of the aforementioned memory cells according to a pre-charging control signal. The dynamic voltage controller determines whether or not to supply a voltage to the auxiliary read bit line according to the voltage level of the output signal of the selecting circuit. The sense amplifier compares the voltage levels of the output signal of the selecting circuit and the voltage on the auxiliary read bit line to output a sensing result accordingly.

Abstract: A semiconductor storage device includes a first cell array including a plurality of memory cells that are connected to a first word line and each of which is connected to each member of a first pair of bit lines. The semiconductor storage device also includes a second cell array including a plurality of memory cells that are connected to a second word line and each of which is connected to each member of a second pair of bit lines. The semiconductor storage device further includes a redundant cell array including a plurality of memory cells that are connected to a word line different from the first and the second word lines and each of which is connected to one member of the first pair of bit lines and to one member of the second pair of bit lines.

Abstract: Described examples include sensing circuits and reference voltage generators for providing a reference voltage to a sensing circuit. The sensing circuits may sense a state of a memory cell, which may be a PCM memory cell. The sensing circuits may include a cascode transistor. Examples of reference voltage generators may include a global reference voltage generator coupled to multiple bank reference voltage generators which may reduce an output resistance of the voltage generator routing.

Abstract: A memory device includes a memory array comprising a plurality of memory cells, a plurality of sense amplifiers configured to sense data stored in the memory cells of the memory array, a dummy wordline coupled to respective enable inputs of the sense amplifiers, a dummy wordline return, a dummy bitline, a dummy sense amplifier having an input coupled to the dummy bitline, and control circuitry coupled to the output of the dummy sense amplifier and the dummy wordline return. The control circuitry has a first configuration for generating a reset signal based at least in part on a signal at the output of the dummy sense amplifier in a read mode of operation, and has a second configuration different than the first configuration for generating the reset signal based at least in part on a signal on the dummy wordline return in a write mode of operation.

Abstract: According to one embodiment, a semiconductor memory device includes a plurality of first interconnects which extend in a first direction and are arranged in a second direction perpendicular to the first direction, a plurality of second interconnects which extend in the second direction and are arranged in the first direction, and a plurality of first storage modules which are formed in regions where the first interconnects and the second interconnects cross. The semiconductor memory device further comprises a first interconnect control module which supplies a voltage to the first interconnects, detects a first current flowing in the first interconnects, and outputs a first voltage corresponding to the first current, a reference voltage generator module which generates a second voltage based on a second current, and a regulator which generates a third voltage based on the first voltage and the second voltage.

Abstract: A multi-state current-switching magnetic memory element includes a stack of magnetic tunneling junction (MTJ) separated by a non-magnetic layer for storing more than one bit of information, wherein different levels of current applied to the memory element cause switching to different states.

Abstract: A system and method to select a reference cell is disclosed. In a particular embodiment, a method is disclosed that includes receiving an address corresponding to a bit cell within a first bank of a memory. The method also includes accessing a second reference cell of a second bank of the memory in response to a first reference cell in the first bank being indicated as bypassed.

Abstract: The control circuit selects, as the first reference cell, the first memory cell having a maximum reading current supplied by turning on the first select transistor in a state in which resistance values of the first memory cells are all increased. The control circuit selects, as the second reference cell, the second memory cell having a maximum reading current supplied by turning on the second select transistor in a state in which resistance values of the second memory cells are all increased. The first reference-current setting circuit sets, as the first reference current, a current obtained by adding a first adjusting current to the reading current of the first reference cell. The second reference-current setting circuit sets, as the second reference current, a current obtained by adding a second adjusting current to the reading current of the second reference cell.

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 main bit line is disposed between a reference main bit line and core main bit lines. A selection transistor disposed between a sub bit line connected to a cell and the main bit line can switch between a conductive state and a non-conductive state independently of other selection transistors. A dummy main bit line can be set to ground potential by a shield grounding section, and can be used as a shield line of the reference main bit line.

Abstract: Systems, methods, and devices are disclosed, including an electronic device that includes a first data location, a quantizing circuit, and a reference current source, all coupled to an electrical conductor. The reference current source may include a current mirror with a side coupled to the electrical conductor and a second data location coupled to another side of the current mirror.

Abstract: The present invention discloses a reference cell circuit which is applied to a non-volatile memory. The reference cell circuit includes a reference cell array, a first current mirror circuit, and a second current mirror circuit. The reference cell array includes at least one row of floating gate transistors. The first current mirror circuit is arranged to generate a mirror current according to a reference current generated by the reference cell array. The second current mirror circuit is arranged to receive the mirror current and generate an adjusted reference current according to the mirror current and a selected one of a plurality of enable signals, wherein the plurality of enable signals correspond to a plurality operations of the non-volatile memory and the adjusted reference current is arranged to determine logical state of a plurality of memory cells of the non-volatile memory.

Abstract: A nonvolatile memory device comprises a nonvolatile cell array comprising a memory cell and a reference cell, a clamping circuit electrically connected to the memory cell and configured to clamp a voltage applied to a data sensing line during a read operation, and a clamping voltage generation unit configured to generate a clamping voltage responsive to a first voltage having a level based on the reference cell, and to feed back the clamping voltage to the clamping circuit.

Abstract: A memory cell is provided at an intersection of a word line and a bit line, and a dummy cell is provided at an intersection of a dummy word line and a dummy bit line. A delay circuit delays a signal read into the dummy bit line to generate a sense amplifier activating signal. A sense amplifier circuit starts an operation based on a change in the sense amplifier activating signal, and detects/amplifies a signal read out from the memory cell into the bit line. The delay circuit is configured having a first logical gate circuit and a second logical gate circuit alternately cascade-connected. A second delay time is longer than a first delay time, the second delay time being a time required for an output signal of the second logical gate circuit to switch from a first logical state to a second logical state, and a first delay time being a time required for an output signal of the first logical gate circuit to switch from a first logical state to a second logical state.

Abstract: A memory device includes a memory array comprising memory cells, sense amplifiers configured to sense data stored in the memory cells of the memory array, and control circuitry configured to generate a plurality of separate sense amplifier control signals for application to respective control inputs of respective ones of the sense amplifiers. For example, the memory device may comprise a row of dummy memory cells each coupled to a dummy wordline. In such an arrangement, the control circuitry may comprise a plurality of logic gates coupled to respective ones of the dummy memory cells, with each such logic gate configured to generate a corresponding one of the separate sense amplifier control signals for a corresponding one of the sense amplifiers as a function of a data transition at a bitline of the corresponding dummy memory cell. The separate sense amplifier control signals may comprise respective sense amplifier enable signals.

Abstract: An entry including multiple bits of unit cells each storing data bit is coupled to a match line. The match line is supplied with a charging current having a restricted current value smaller than a match line current flowing in a one-bit miss state in one entry, but larger than a match line current flowing in an all-bit match state in one entry. A precharge voltage level of a match line is restricted to a voltage level of half a power supply voltage or smaller. Power consumption in a search cycle of a content addressable memory can be reduced, and a search operation speed can be increased.

Abstract: A method and apparatus for management worn resistive memory cells are presented. A normal read mode or worn memory cell detecting mode are used depending on the wear state of a resistive memory cell. A detection reference point is changed upon wear indication to detect the resistance of the resistive memory cell. The resistance of the resistive memory cell is detected using the changed detection reference point to determine whether or not the resistive memory cell is worn by comparing the detected resistance to a wear reference level.

Abstract: A method of setting a reference current of a nonvolatile memory device comprises measuring a noise characteristic of each of multiple reference cells, and selecting at least one of the reference cells as a reference cell for generating a reference current according to the measured noise characteristics.

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 high speed voltage mode sensing is provided for a digital multibit non-volatile memory integrated system. An embodiment has a local source follower stage followed by a high speed common source stage. Another embodiment has a local source follower stage followed by a high speed source follower stage. Another embodiment has a common source stage followed by a source follower. An auto zeroing scheme is used. A capacitor sensing scheme is used. Multilevel parallel operation is described.

Abstract: A semiconductor device includes a data memory cell for storing data; a reference data memory cell for storing reference data to be compared with the data; an inverted data memory cell for storing inverted data of the reference data; a sense amplifier unit; and a data output unit. In a first retrieving process, the sense amplifier unit differentially amplifies the data and the reference data, and adjusts an output thereof when a voltage difference between the data and the reference data becomes a predetermined retrievable voltage difference. In a second retrieving process, the sense amplifier unit differentially amplifies the data and the inverted data, and adjusts an output thereof when a voltage difference between the data and the inverted data becomes the predetermined retrievable voltage difference. The data output unit determines and outputs the data according to a result of the first retrieving process and the second retrieving process.

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 resistance based memory sensing circuit has reference current transistors feeding a reference node and a read current transistor feeding a sense node, each transistor has a substrate body at a regular substrate voltage during a stand-by mode and biased during a sensing mode at a body bias voltage lower than the regular substrate voltage. In one option the body bias voltage is determined by a reference voltage on the reference node. The substrate body at the regular substrate voltage causes the transistors to have a regular threshold voltage, and the substrate body at the body bias voltage causes the transistors to have a sense mode threshold voltage, lower than the regular threshold voltage.

Abstract: A memory circuit includes a first memory cell node capacitor, a first memory cell node transistor, a second memory cell node having a second memory cell node capacitor and a second memory cell node transistor, and a pre-charging circuit for pre-charging the first and second memory cell nodes to first and second voltage levels, respectively. The circuit includes a reference memory cell having first and second reference cell transistors with an equalizing transistor between, and a sense amplifier that detects a potential difference between reference bit lines from the reference memory cell and the first or second memory cell node, respectively. The reference cell transistors and equalizing transistor perform a first voltage equalization of the memory cell nodes at a predetermined voltage and a second voltage equalization of the memory cell nodes based on first or second reference signals respectively input to the first or second reference cell transistor.

Abstract: Resistance memory cells of MRAM arrays are designated as reference cells and programmed to binary 0 and binary 1 states, reference cells from one MRAM array at binary 0 and at binary 1 are concurrently accessed to obtain a reference voltage to read resistance memory cells of another MRAM array, reference cells from the other MRAM array at binary 0 and binary 1 are concurrently accessed to obtain a reference voltage to read resistance memory cells of the one MRAM array.

Abstract: A memory module can include a plurality of dynamic memory devices that each can include a dynamic memory cell array with respective regions therein, where the plurality of dynamic memory devices can be configured to operate the respective regions responsive to a command. A DRAM management unit can be on the module and coupled to the plurality of dynamic memory devices, and can include a memory device operational parameter storage circuit that is configured to store memory device operational parameters for the respective regions to affect operation of the respective regions responsive to the command.

Abstract: A device includes first memory blocks each including a first local bit line, first memory cells connected to the first local bit line and a first hierarchy switch connected between a first global bit line and the first local bit line, a dummy global bit line connected to the second node of a first sense amplifier, a dummy block including a dummy local bit line, dummy memory cells connected to the dummy local bit line and a dummy hierarchy switch connected between the dummy global bit line and the dummy local bit line, and a control circuit supplied with address information and configured to respond to the address information designating any one of the first memory blocks to turn ON each of the dummy hierarchy switch of the dummy block and the first hierarchy switch of one of the first memory blocks designated by the address information.

Abstract: A memory apparatus includes: a plurality of memory cells which includes a first resistance change element; and a read-out circuit which determines the size of a resistance value of the first resistance change element by comparing the resistance state of a memory cell selected among the plurality of memory cells to the resistance state of a reference memory cell, wherein the reference memory cell includes a second resistance change element, a resistance value of the second resistance change element with respect to an applied voltage is smaller than that in a high resistance state of the first resistance change element, and the second resistance change element shows the same resistance change characteristic as the first resistance change element.

Abstract: Some embodiments of the invention relate to a sense amplifier configured to determine the slope of a bitline charging voltage and to utilize the determined slope in combination with a voltage level sensing scheme to aid in reading data from a memory cell associated with the bitline. In particular, a sense amplifier circuit is configured to determine a slope of a bit line charging voltage and based upon the determined slope to adjust the slope of the bitline voltage (e.g., by adding a dynamic slope dependent current to a memory cell current configured to charge the bitline) provided to a sense amplifier. By adjusting the slope of the bitline voltage, the charging speed of memory cells in a low resistive state (e.g., having a high cell current and therefore a good SNR) can be increased.

Abstract: Apparatuses and methods for improved memory cycle times are disclosed. An example apparatus may include first and second lines and a sense amplifier. The sense amplifier is directly coupled to the first and second lines. The sense amplifier may sense a differential signal between the first and second lines and amplify the same. An example method may include accessing a first memory cell coupled to a first line of a pair of lines and accessing a second memory cell coupled to a second line of the pair of lines. A differential is sensed between the pair of lines with a sense amplifier coupled directly to the pair of lines, and the sensed differential is amplified. The sense amplifier is coupled to an input/output bus to provide the amplified sensed differential to the input/output bus.

Abstract: A semiconductor memory device has: memory blocks; and a local bus connected to the memory blocks. Each memory block has: switches respectively provided between bit line pairs and the local bus and each of which is turned ON in response to a selection signal; a dummy local bus; first and second control circuits. The local bus and the dummy local bus are precharged to a first potential before a read operation. In the read operation, the first control circuit outputs the selection signal to a selected switch to electrically connect a selected bit line pair and the local bus, while the second control circuit supplies a second potential lower than the first potential to the dummy local bus. The first control circuit stops outputting the selection signal when a potential of the dummy local bus is decreased to a predetermined set potential that is between the first and second potentials.

Abstract: A voltage regulator for a memory that regulates a voltage provided to the memory cells based on a measured leakage current from a second set of memory cells. In one embodiment, based on the measured leakage current, the voltage to the cells is raised or lowered to control the amount of leakage current from the cells.