Abstract: A magnetic random access memory (RAM) with a multi-bit cell array structure includes an access transistor formed on a substrate, first through third resistance-variable elements, and first through third current supplying lines. The first through third resistance-variable elements are disposed between a bit line and the access transistor, and electrically connected to each other. The first through third current supplying lines are stacked alternately with the first through third resistance-variable elements. The first through third resistance-variable elements have equal resistances.

Abstract: A nonvolatile memory device includes multiple first bit lines extending in a first direction, multiple word lines formed on the first bit lines and extending in a second direction different from the first direction, and multiple second bit lines, formed on the word lines and extending in the first direction. The nonvoliative memory device also includes multiple twin memory cells, each of which includes a first memory cell coupled between a first bit line and a word line and a second memory cell coupled between the word line and a second bit line. The first and second memory cells store different data.

Abstract: A programming method which controls the amount of a write current applied TO Phase-change Random Access Memory (PRAM), and a write driver circuit realizing the programming method. The programming method includes maintaining a ratio of a resistance of the PCM in the higher resistance state to a resistance of the phase change material (PCM) in the lower resistance state constant or substantially constant independent of an ambient temperature. The ratio may be maintained by increasing, decreasing or keeping the same a reset current and/or a set current.

Abstract: In one aspect, a semiconductor memory device includes a plurality of phase-change memory cells which are programmed according to a write current applied to the phase-change memory cells, a voltage boosting circuit which receives a first voltage and outputs a boosted voltage which is greater than the first voltage, and a write driver which receives the boosted voltage and which generates the write current from the boosted voltage. In another aspect, the write driver generates the write current corresponding to one of a set current pulse and a reset current pulse, and at least one of the set current pulse and the reset current pulse is gradually increased.

Abstract: A semiconductor memory device includes: phase-change memory cells whose states change to a set resistance state or a reset resistance state in response to an applied current pulse; a set pulse driving circuit outputting a set current pulse having first through n-th stages in response to a first control signal and a set control signal wherein current amounts of the first through n-th stages are sequentially reduced and are all greater than a reference current amount; a reset pulse driving circuit outputting a reset current pulse in response to a second control signal; a pull-down device activating the set pulse driving circuit and the reset pulse driving circuit in response to a third control signal; and a write driver control circuit outputting the first through third control signals in response to write data, a set pulse width control signal, and a reset pulse width control signal.

Abstract: A memory system includes a resistance variable memory device, and a memory controller for controlling the resistance variable memory device. The resistance variable memory device includes a memory cell connected to a bitline, a high voltage circuit adapted to generate a high voltage from an externally provided power source voltage, where the high voltage is higher than the power source voltage, a precharging circuit adapted to charge the bitline to the power source voltage and further charge the bitline to the high voltage, a bias circuit adapted to provide a read current to the bitline with using the high voltage, and a sense amplifier adapted to detect a voltage level of the bitline with using the high voltage.

Abstract: Embodiments of the invention provide a multi-layer semiconductor memory device and a related error checking and correction (ECC) method. The multi-layer semiconductor memory device includes first and second memory cell array layers, wherein the first memory cell array layer stores first payload data. The multi-layer semiconductor memory device also includes an ECC engine selectively connected to the second memory cell array layer and configured to receive the first payload data, generate first parity data corresponding to the first payload data, and store the first parity data exclusively in the second memory cell array layer.

Abstract: The present invention provides a nonvolatile memory device that uses a resistance material. The nonvolatile memory device includes: a stacked memory cell array having a plurality of memory cell layers stacked in a vertical direction, the stacked memory cell array having at least one memory cell group and at least one redundancy memory cell group; and a repair control circuit coupled to the stacked memory cell array, the repair control circuit configured to repair a defective one of the at least one memory cell group with a selected one of the at least one redundancy memory cell group. The features that enable repair improve the fabrication yield of the nonvolatile memory device.

Abstract: A nonvolatile memory device includes a stack-type memory cell array, a selection circuit and a read circuit. The memory cell array includes multiple memory cell layers and a reference cell layer, which are vertically laminated. Each of the memory cell layers includes multiple nonvolatile memory cells for storing data, and the reference cell layer includes multiple reference cells for storing reference data. The selection circuit selects a nonvolatile memory cell from the memory cell layers and at least one reference cell, corresponding to the selected nonvolatile memory cell, from the reference cell layer. The read circuit supplies a read bias to the selected nonvolatile memory cell and the selected reference cell corresponding to the selected nonvolatile memory cell, and reads data from the selected nonvolatile memory cell.

Abstract: A resistance semiconductor memory device of a three-dimensional stack structure, and a word line decoding method thereof, are provided.

Abstract: A semiconductor memory device and a dummy line biasing method in which in the semiconductor memory device of a diode structure including a plurality of memory cells each having one variable resistance device and one diode device, the memory device includes a plurality of normal word lines, a plurality of normal bit lines, at least one or more dummy word lines and at least one or more dummy bit lines. The plurality of normal word lines are each arrayed in a first direction as a length direction. The plurality of normal bit lines are each arrayed in a second direction as a width direction, intersected with the first direction, so that the plurality of normal bit lines are intersected with the normal word lines. At least one or more dummy word lines are arrayed in the same structure as the normal word lines in the first direction, the at least one or more dummy word lines having a constant level of applied voltage.

Abstract: A resistance random access memory (RRAM) having a source line shared structure and an associated data access method. The RRAM, in which a write operation of writing data of first state and second state to a selected memory cell is performed through first and second write paths having mutually opposite directions, includes word lines, bit lines, a memory cell array and a plurality of source lines. The memory cell array includes a plurality of memory cells each constructed of an access transistor coupled to a resistive memory device. The memory cells are disposed in a matrix of rows and columns and located at each intersection of a word line and a bit line. Each of the plurality of source lines is disposed between a pair of word lines and in the same direction as the word lines. A positive voltage is applied to a source line in a memory cell write operation.

Abstract: A memory cell of a resistive semiconductor memory device, a resistive semiconductor memory device having a three-dimensional stack structure, and related methods are provided. The memory cell of a resistive semiconductor memory device includes a twin cell, wherein the twin cell stores data values representing one bit of data. The twin cell includes a main unit cell connected to a main bit line and a word line, and a sub unit cell connected to a sub bit line and the word line. Also, the main unit cell includes a first variable resistor and a first diode, and the sub unit cell includes a second variable resistor and a second diode.

Abstract: A non-volatile memory device, in which data values are determined by polarities at cell terminals, includes a memory cell array. The memory cell array is divided into multiple sub cell arrays, each sub cell array including at least one input/output line and an X-decoder/driver. First input/output lines included in different sub cell arrays may be simultaneously activated and bias voltages may be applied to the activated first input/output lines in accordance with the data values. The non-volatile memory device may be a bi-directional resistive random access memory (RRAM).

Abstract: A method of biasing a memory cell array during a data writing operation and a semiconductor memory device, in which the semiconductor memory device includes: a memory cell array including a plurality of memory cells in which a first terminal of a memory cell is connected to a corresponding first line among a plurality of first lines and a second terminal of a memory cell is connected to a corresponding second line among a plurality of second lines; and a bias circuit for biasing a selected second line to a first voltage and non-selected second lines to a second voltage.

Abstract: A non-volatile memory device is employed in which data values are determined by the polarities at both ends of a cell, The non-volatile memory device includes a first decoder which decodes a plurality of predetermined bit values of a row address into a first address and is disposed in a row direction of a memory cell array; a second decoder which decodes the other bit values of the row address into a second address and is disposed in a column direction of the memory cell array; and a driver which applies bias voltages to a word line which corresponds to the first address or the second address in accordance with the data values. By including first and second decoders and decoding a row address in two steps, a bi-directional RRAM according to the present invention can perform addressing at high speeds while reducing chip size.

Abstract: Phase-changeable random access memory (PRAM) devices include a plurality of rows and columns of PRAM memory cells therein and at least one local bit line electrically coupled to a column of the PRAM memory cells. First and second bit line selection circuits are provided to increase the rate at which the at least one local bit line can be accessed and driven with a bit line signal. These first and second bit line selection circuits are configured to electrically connect first and second ends of the at least one local bit line to a global bit line during an operation to read data from a selected one of the PRAM memory cells in the column.

Abstract: An integrated circuit memory device includes an array of nonvolatile memory cells (e.g., variable resistance cells) having a first plurality of lines electrically coupled to memory cells therein. A read/write control circuit is provided. The read/write control circuit includes a read/write merge circuit and a column selection circuit. The read/write control circuit, which is configured to drive a selected one of the first plurality of lines with unequal write and read voltages during respective write and read operations, includes a compensating unit. This compensating unit is configured to provide a read compensation current to the selected one of the first plurality of lines circuit during the read operation.

Abstract: A non-volatile memory device includes a memory cell array including a memory cell array having word lines, bit lines, and non-volatile memory cells, each non-volatile memory cell having a variable resistive material and an access element connected between the corresponding word line and the corresponding bit line. The variable resistive material has a resistance level that varies according to data to be stored. A selection circuit selects at least one non-volatile memory cell in which data will be written. An adaptive write circuit/method supplies a write bias to the selected non-volatile memory cell through the bit line connected to the selected non-volatile memory cell to write data in the selected non-volatile memory cell and varies (e.g., increases) the write bias until the resistance level of the selected non-volatile memory cell varies.

Abstract: Disclosed is a phase-changeable memory device and a related method of reading data. The memory device is comprised of memory cells, a high voltage circuit, a precharging circuit, a bias circuit, and a sense amplifier. Each memory cell includes a phase-changeable material and a diode connected to a bitline. The high voltage circuit provides a high voltage from a power source. The precharging circuit raises the bitline up to the high voltage after charging the bitline up to the power source voltage. The bias circuit supplies a read current to the bitline by means of the high voltage. The sense amplifier compares a voltage of the bitline with a reference voltage by means of the high voltage, and reads data from the memory cell. The memory device is able to reduce the burden on the high voltage circuit during the precharging operation, thus assuring a sufficient sensing margin during the sensing operation.