Abstract: Some embodiments include apparatus and methods having dice arranged in a stack. The dice include at least a first die and a second die, and a connection coupled to the dice. The connection may be configured to transfer control information to the first die during an assignment of a first identification to the first die and to transfer the control information from the first die to the second die during an assignment of a second identification to the second die.

Abstract: A storage system includes a three-dimensional memory array that has multiple layers of non-volatile storage elements grouped into blocks. The blocks are grouped into bays. The storage system includes array lines of a first type in communication with storage elements, array lines of a second type in communication with storage elements, and sense amplifiers. Each block is geographically associated with two sense amplifiers and all blocks of a particular bay share a group of sense amplifiers associated with the blocks of the particular bay. The system includes multiple sets of local data lines in one or more routing metal layers below the three-dimensional memory array and multiple sets of global data lines in one or more top metal layers above the three-dimensional memory array. Each set of one or more blocks include one set of the local data lines. Each bay includes one set of global data lines that connect to the group of sense amplifiers associated with the blocks of the respective bay.

Abstract: A semiconductor device has a pair of gate electrodes extending adjacent to and non-parallel to each other, a source and/or drain region located between the pair of gate electrodes for forming a pair of transistors with the gate electrodes, and a contact electrode disposed between the pair of gate electrodes in contact with the source and/or drain region in a contact area so that the center of the contact area is shifted from the center of the source and/or drain region in a direction along which the distance between the pair of gate electrodes becomes greater.

Abstract: Provided are information storage devices using movement of magnetic domain walls and methods of operating information storage devices. An information storage device includes a magnetic track and an operating unit. The magnetic track includes a plurality of magnetic domains separated by magnetic domain walls. The size of the operating unit is sufficient to cover at least two adjacent magnetic domains. And, the operating unit may be configured to write/read information to/from a single magnetic domain as well as a plurality of magnetic domains of the magnetic track.

Abstract: A magnetic memory structure includes a memory track which has consecutive magnetic domains. Each of the magnetic domains has memory capacity of one bit. A first domain-wall injecting layer intersects and connects a terminal of the memory track and constantly stores a first binary data. A second domain-wall injecting layer against the first domain-wall injecting layer intersects and connects the terminal of the memory track and constantly stores a second binary data different from the first binary data. The memory track and one of the first domain-wall injecting layer and the second domain-wall injecting layer together form a domain wall.

Abstract: A high speed sensing scheme for a non-volatile memory array is disclosed. The memory array includes non volatile memory cells arranged in a complementary bitline configuration includes precharge circuits for precharging the bitlines to a first voltage level such as VSS, a reference circuits for applying a reference charge on the reference bitlines of the complementary bitline pairs, and bitline sense amplifiers for sensing a voltage differential between the complementary bitline pairs. A voltage on the data bitline being changed when a programmed non-volatile memory cell connected to an activated wordline couples the wordline voltage to the data bitline.

Abstract: A system, device and method for electrically addressing an element include providing a thermoelectric layer in proximity with an area to be addressed and positioning a probe in proximity of the thermoelectric layer. Electrical activity is induced in the thermoelectric layer by applying heat from the probe. A response is caused in the area to be addressed.

Abstract: A system and method to read and write data in magnetic random access memories are disclosed. In a particular embodiment, a device includes a spin transfer torque magnetic tunnel junction (STT-MTJ) element and a transistor with a first gate and a second gate coupled to the STT-MTJ element.

Abstract: A method for generating a variable pulse width signal on an integrated circuit (IC) chip, includes receiving a first clock signal on the IC chip and receiving a second clock signal on the IC chip having a variable delay relative to the first clock signal. A signal having a rising edge triggered by a rising edge of the first clock signal and a falling edge triggered by a rising edge of the second clock signal is output. The output signal is provided to circuitry on the chip, such as a magnetoresistive junction (MTJ) cell of a spin torque transfer magnetic random access memory (STT-MRAM).

Abstract: Using a shorter read pulse width may increase read window in some embodiments. This may allow the use of higher voltages with less likelihood of a read disturb where a bit unintentionally changes phase.

Abstract: Embodiments are directed to memory devices comprising a bipolar junction transistor having an emitter, a base and a collector; a first side of a resistance changing memory element coupled to the emitter of the bipolar junction transistor; and a MOSFET coupled to the base of the bipolar junction transistor.

Abstract: A memory circuit including a voltage divider with a first phase change memory (PCM) device and a second PCM device coupled to the first PCM device is described. In one embodiment, the first PCM device is in a set resistance state and the second PCM device is in a reset resistance state. Also, in one embodiment, the voltage divider further includes a first switch coupled to the first PCM device and a second switch coupled to the first switch and the second PCM device. In one embodiment, the memory circuit further includes a half latch coupled to the voltage divider and a cascade transistor coupled to the half latch and the voltage divider.

Abstract: A phase change memory device includes a signal generator configured to generate first and second sensing and amplifying enable signals which are sequentially activated during an activation period of a word line selection signal and each of which has a certain activation period length, a resistance sensor configured to sense a resistance value by applying a certain operation current to a phase change memory cell corresponding to the word line selection signal during an activation period of the first sensing and amplifying enable signal and a voltage level amplifier configured to logically determine a voltage level of the resistance sensing signal based on a voltage level of a logic reference signal during an activation period of the second sensing.

Abstract: The disclosed phase change random access memory apparatus is configured to program a predetermined phase change memory cell in the phase change memory apparatus in response to a plurality of write instructions applied at independent points of time.

Abstract: A test circuit transfers data, which is generated by current supplied from an external source, to a memory cell in response to a test mode signal.

Abstract: Embodiments of the present disclosure provide methods, devices, modules, and systems for reading non-volatile multilevel memory cells. One method includes receiving a request to read data stored in a first cell of a first word line, performing a read operation on an adjacent cell of a second word line in response to the request, determining whether the first cell is in a disturbed condition based on the read operation. The method includes reading data stored in the first cell in response to the read request by applying a read reference voltage to the first word line and adjusting a sensing parameter if the first cell is in the disturbed condition.

Abstract: A method and apparatus are described that efficiently program charge-trapping memory cells by dynamically switching sense amplifiers and corresponding drivers depending upon data to be programmed. When a number of sense amplifier/drivers can be operated simultaneously, cells to be programmed to a same level are selected and programmed simultaneously employing up to the number of simultaneously operable sense amplifier/drivers.

Abstract: A method of reducing coupling effect in a flash memory is disclosed. A neighboring page is read, and a flag is set active if the neighboring page is an interfering page. Data are read from the neighboring page at least two more times using at least two distinct read voltages respectively. The threshold-voltage distributions associated with an original page and the neighboring page are transferred according to the read data and the flag.

Abstract: A nonvolatile semiconductor storage device capable of storing a plurality of bits of data in one memory cell by assigning multivalued data having a higher-order bit selected from one of a pair of data in a first unit and a lower-order bit selected from the other of the pair of data to each threshold voltage of the memory cell, wherein in a first write operation that processes data in the first unit, the logic of one of the higher-order bit and the lower-order bit is fixed, and two pieces of multivalued data that maximize the difference between the threshold voltages are assigned, thereby storing one bit of input data in the one memory cell in a pseudo binary state, and in a second write operation that processes data in a second unit larger than the first unit, a plurality of bits of input data is stored in the one memory cell in a multivalued state, and parity data for error correction in the second unit is stored in the memory cell.

Abstract: A plurality of contact plugs to be connected to a drain region or a source region of each of transistors constituting a sub-word line driver that drives a sub-word line are formed, by using a SAC line technique of selectively etching an insulation layer that covers each of the transistors by using a mask having line-shaped openings provided across a portion in which the contact plugs of each of the transistors are to be formed.

Abstract: Methods of maintaining a state of a memory cell without interrupting access to the memory cell are provided, including applying a back bias to the cell to offset charge leakage out of a floating body of the cell, wherein a charge level of the floating body indicates a state of the memory cell; and accessing the cell.

Abstract: A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell; a first region in electrical contact with said floating body region; a second region in electrical contact with said floating body region and spaced apart from said first region; a gate positioned between said first and second regions; and a back-bias region configured to inject charge into or extract charge out of said floating body region to maintain said state of the memory cell. Application of back bias to the back bias region offsets charge leakage out of the floating body and performs a holding operation on the cell. The cell may be a multi-level cell. Arrays of memory cells are disclosed for making a memory device.

Abstract: A system embodiment comprises a nonvolatile memory device, a memory, and a controller. The nonvolatile memory device includes a plurality of nonvolatile memory cells. Each nonvolatile memory cell is adapted to store at least two bits. The memory is adapted to store a program when the system powers up. The controller is adapted to implement the program to provide instructions used to program and erase nonvolatile memory cells. A method embodiment comprises loading a program into memory upon powering up a memory system, and implementing the program using a controller, including programming and erasing multi-bit nonvolatile memory cells.

Abstract: A non-volatile memory comprising a NOR block with a first sub-block independently addressable from a second sub-block, the two sub-blocks sharing a physical substrate of the NOR block, and a first memory to store execution status information to reflect an erase status of the first sub-block. A method to selectively erase the first sub-block while inhibiting the second sub-block from erasing, comprising updating execution status information associated with the first sub-block and resuming erasing upon an occurrence of an interruption event depending on the indication of the execution status information.

Abstract: An erase operation for non-volatile memory includes first and second phases. The first phase applies a series of voltage pulses to a substrate, where each erase pulse is followed by a verify operation. The verify operation uses a verify level which is offset higher from a final desired threshold voltage level. The erase pulses step up in amplitude until a maximum level is reached, at which point additional erase pulses at the maximum level are applied. The first phase ends when the verify operation passes. The second phase applies one or more extra erase pulses which are higher in amplitude than the last erase pulse in the first phase and which are not followed by a verify operation. This avoids the need to perform a verify operation at deep, negative threshold voltages levels, which can cause charge trapping which reduces write-erase endurance, while still achieving the desired deep erase.

Abstract: Coupling effects between adjacent floating gates in a non-volatile storage device are reduced in a multi-pass programming operation, while reducing program data storage requirements. In one approach, storage elements are programmed in an out of sequence or zigzag word line order. A particular word line is programmed with a coarse program pass, after which another word line is programmed with a fine program pass, after which the particular word line is read. The particular word line is read before another word line is programmed with a coarse program pass which causes coupling interference to storage elements of the particular word line. The read data is subsequently used to perform a fine program pass for the particular word line. This avoids the need to store program data of multiple word lines concurrently, so that storage hardware can be reduced in size along with power consumption.

Abstract: This disclosure is related to systems and methods for low wear operation of solid state memory, such as a flash memory. In one example, a controller is coupled to a memory and adapted to dynamically adjust programming thresholds over the course of usage of the data storage device such that a signal-to-noise ratio from reading data stored in the data storage cells is no less than a minimum amount needed to recover the data using an enhanced error detection capability.

Abstract: A method is used in securely erasing flash-based memory. A new version of data is received for a logical location of a flash-based memory. An old version of the data of the logical location is stored in a first physical location in the flash-based memory. The old version of the data is caused to be subject to an obscure operation. The new version of the data is caused to be stored in a second physical location in the flash-based memory.

Abstract: A nonvolatile semiconductor storage device including a NAND cell unit having a first and a second select gate transistor, a plurality of memory cell transistors series connected between the first and second select gate transistors that are coupled to corresponding word lines, and a peripheral circuit erase verifying the NAND cell unit by turning on the first and second select gate transistors, applying a predetermined voltage level on the source line, detecting a voltage level of the bit line at once under a state where a voltage level applied on one or more of the word lines coupled to the memory cell transistors relatively closer to the second select gate transistor is arranged higher than that applied on one or more of the word lines coupled to the memory cell transistors relatively closer to the first select gate transistor, and verifying data erase based on the detected voltage.

Abstract: A programming technique reduces program disturb in a set of non-volatile storage elements by programming using selected bit line patterns which increase the clamped boosting potential of an inhibited channel to avoid program disturb. One aspect groups alternate pairs of adjacent bit lines into first and second sets. Dual programming pulses are applied to a selected word line. The first set of bit lines is programmed during the first pulse, and the second set of bit lines is programmed during the second pulse. A verify operation is then performed for all bit lines. When a particular bit line is inhibited, at least one of its neighbor bit lines will also be inhibited so that the channel of the particular bit line will be sufficiently boosted. Another aspect programs every third bit line separately. A modified layout allows adjacent pairs of bit lines to be sensed using odd-even sensing circuitry.

Abstract: A memory system includes a nonvolatile semiconductor memory which includes a first original block composed of n (n being natural number) write unit areas and a first subblock composed of a plurality of write unit areas. A controller writes data having one of first to p-th (p being natural number smaller than n) addresses into the first original block. The controller writes data which has a first write address of one of the first to p-th addresses into the first subblock when the controller receives request to write data having the first write address and data having the first write address exists in the first original block.

Abstract: In one embodiment, a bit-line interface is disclosed. The bit-line interface has a multiplexer having a plurality of bit-line outputs, and a write path coupled to a multiplexer signal input. The bit-line interface also has a read path coupled to the multiplexer signal input, wherein the read path and the write path share at least one component.

Abstract: In one aspect, a multiplexer array is described. The multiplexer array includes (1) a first multiplexer coupled to a first address line, where the first multiplexer includes a first plurality of memory devices and (2) a first plurality of input logic devices coupled to the first multiplexer, a first plurality of data lines, and a plurality of bitlines. Each input logic device of the first plurality of input logic devices is coupled to a respective memory device of the first plurality of memory devices and includes a first input terminal and a second input terminal, where, for each input logic device, the first input terminal is coupled to a respective data line of the first plurality of data lines and the second input terminal is coupled to a respective bitline of the plurality of bitlines. Embodiments of methods of programming a multiplexer array are also described.

Abstract: A system is provided for multi-rank, partial-width memory modules. A memory controller is provided. Additionally, a memory bus is provided. Further, a memory module with a plurality of ranks of memory circuits is provided, the memory module including a first number of data pins that is less than a second number of data pins of the memory bus.

Abstract: A bit-line sense amplifier includes a latching unit and a control unit. The latching unit has a plurality of field effect transistors coupled between first and second bit lines. The control unit controls application of a bias voltage to a set of the field effect transistors such that respective pre-charge voltages are generated at the first and second bit lines with drain currents flowing in the field effect transistors during a pre-charge time period, without a bit line bias voltage and with a minimized number of transistors.

Abstract: A semiconductor memory device includes n stages of memory cell units, sense amplifier units, and shift registers. N units of the shift registers are connected to one another on the left end sides. The signal processing units and the reversed signal processing units are disposed adjacent to one another in each of the n units of the shift registers. The signal processing units located on the odd-numbered positions counted from the input end side are connected to one another. The reversed signal processing units located on the even-numbered positions counted from the input end side are connected to one another. The signal processing units located on the end opposite to the input end side are connected to the reversed signal processing units located on the end opposite to the input end side. Each of the signal processing units includes the logic circuit unit and the flip-flop while each of the reversed signal processing units includes the reversed logic circuit unit and the reversed flip-flop.

Abstract: A memory error signal detecting system including a signal extracting circuit, a flip-flop, a latch circuit, and a light sign is provided. The signal extracting circuit receives a memory error signal to output a pulse signal when the memory error signal switches from a first level to a second level. When the preset end of the flip-flop receives the pulse signal, and the maintaining time of the pulse signal is maintained for a predetermine time, the flip-flop output end is set to a high voltage level. The latch circuit determines whether to output the state of the flip-flop output according to the reset signal. The light sign operates according to the state of an output end of the latch circuit. Furthermore, a computer apparatus including the memory error signal detecting system is also provided.

Abstract: A semiconductor memory device is provided that is capable of reading out mode register information stored in a register adapted for LPDDR2 (Low Power DDR2), through DQ pads. The semiconductor memory device includes a mode register control unit configured to receive address signals, a mode register write signal and a mode register read signal and generate a flag signal and at least one output information signal, and a global I/O line latch unit for transferring the output information signal to a global I/O line in response to the flag signal.

Abstract: A semiconductor device includes internal voltage generating circuits, a switching circuit, load circuits, a control circuit. Each of the plurality of load circuits is supplied with voltage through the switching circuit from any one of the plurality of internal voltage generating circuits. The control circuit defines connecting combinations by the switch circuit. The control circuit supplies a control signal to the switch circuit, based on the control signal corresponding to the definitions of the connecting combinations. The control circuit allows switching the connecting combinations when the semiconductor device tests in a test mode. The control circuit prohibits switching the connecting combinations in a non-test mode. The switch circuit connects between each of m of the internal voltage generating circuits and each of n of the load circuits through a connecting combination which is selected, based on the control signal, from mn of the connecting combinations.

Abstract: Some embodiments regard a circuit comprising a pre-charge circuit and a latch circuit. The pre-charge circuit charges a voltage node to a pre-determined voltage level based on which the latch circuit generates a feedback signal to stop the pre-charge circuit from charging.

Abstract: A memory architecture includes a plurality of local input and output circuitries, with each local input and output circuitry associated with at least one memory bank. The memory architecture also includes a global input and output circuitry, which includes a plurality of global sub-write circuitries, is coupled to the plurality of local input and output circuitries One global sub-write circuitry is enabled and provides a write-data to a selected local input and output circuitry.

Abstract: A method of programming a nonvolatile memory device includes performing a first LSB program operation on memory cells coupled to a selected word line in order to store least significant bit (LSB) data in the memory cells, performing a first most significant bit (MSB) program operation on the memory cells coupled to the selected word line, such that threshold voltages of the memory cells rise up to a temporary target voltage less than a target voltage, performing a second most significant bit (MSB) program operation on memory cells coupled to a neighboring word line neighboring the selected word line in order to store most significant bit (MSB) data in the corresponding memory cells, and performing a third most significant bit (MSB) program operation, after performing the second most significant bit (MSB) program operation, on the memory cells on which the first most significant bit (MSB) program operation has been performed, such that the threshold voltages of the memory cells coupled to the selected word lin

Abstract: A device for storing data using nanoparticle shuttle memory having a nanotube. The nanotube has a first end and a second end. A first electrode is electrically connected to the first end of the nanotube. A second electrode is electrically connected to the second end of the nanotube. The nanotube has an enclosed nanoparticle shuttle. A switched voltage source is electrically connected to the first electrode and the second electrode, whereby a voltage may be controllably applied across the nanotube. A resistance meter is also connected to the first electrode and the second electrode, whereby the electrical resistance across the nanotube can be determined.

Abstract: A data transfer circuit includes: an asynchronous memory to which transfer data is written from a first clock domain with a first clock and from which the written transfer data is read to a second clock domain with a second clock; a scan flip-flop whose input terminal is connected to a first position located on a data path, of the transfer data, from the asynchronous memory to the second clock domain, and whose output terminal is connected to a second position located on a data path, of the transfer data, from the asynchronous memory to the first position; and a clock selector which selects a clock to drive the scan flip-flop from the first clock and the second clock.

Abstract: A semiconductor integrated circuit has a central processing unit and a rewritable nonvolatile memory area disposed In an address space of the central processing unit. The nonvolatile memory area has a first nonvolatile memory area and a second nonvolatile memory area, which memorize information depending on the difference of threshold voltages. The first nonvolatile memory area has the maximum variation width of a threshold voltage for memorizing information set larger than that of the second nonvolatile memory area. When the maximum variation width of the threshold voltage for memorizing information is larger, since stress to a memory cell owing to a rewrite operation of memory information becomes larger, it is inferior In a point of guaranteeing the number of times of rewrite operation; however, since a read current becomes larger, a read speed of memory information can be expedited.

Abstract: A low power memory array column redundancy mechanism includes a memory unit having a memory array and a multiplexer unit. The memory array includes a plurality of columns, which includes a plurality of data columns and one or more unused columns. The multiplexer unit may selectively provide a constant value to the one or more unused columns of the memory array, and provide write data to the plurality of data columns during each write operation of the plurality of columns.

Abstract: A semiconductor memory device can automatically control signal transmission power on-chip based on a wireless signal transmission. The semiconductor memory device can have a multi-chip stack structure. A power initializing method of the semiconductor memory device can comprise providing a test signal generated by a signal-providing chip to a first chip, checking whether the test signal provided to the first chip has an error, providing the checking result to the signal-providing chip, setting the power of a first signal provided to the first chip according to the checking result, and setting the power of a signal provided to a second chip adjacent to the first chip and close to the signal-providing chip using the power of the first signal.

Abstract: Error detection circuitry is provided on a programmable logic resource. Programmable logic resource configuration data is loaded into a cyclic redundancy check (CRC) module where a checksum calculation may be performed. In one embodiment, the checksum may be compared to an expected value, which is a precomputed checksum on data prior to being programmed into or while data is being programmed into a programmable logic resource. In another embodiment, the expected value may be included in the checksum calculation. An output indicating whether an error is detected may be generated depending on the relationship between the checksum and the expected value, or on the value of the checksum. This output may be sent to an output pin that is accessible by user logic.

Abstract: A highly reliable large capacity phase change memory module is realized. A semiconductor device according to the present invention includes a memory array having a structure in which a storage layer using a chalcogenide material and a memory cell constituted of a diode are stacked, and an initialization condition and a rewriting condition are changed in accordance with the layer where a selected memory cell is located. A current mirror circuit is selected in accordance with an operation, and at the same time, the initialization condition and the rewriting condition (here, reset condition) are changed in accordance with the operation by a control mechanism of the reset current in a voltage selection circuit and a current mirror circuit.

Abstract: Methods and apparatus to improve throughput in memory devices are described. In one embodiment, memory throughput is increased via fine granularity of precharge management. In an embodiment, three separate precharge timings may be used, e.g., optimized per memory bank, per memory bank group, and/or per a memory device. Other embodiments are also disclosed and claimed.