Abstract: A magnetic random access memory (MRAM) includes a memory cell having a first transistor and a first magnetic tunneling junction (MTJ) layer, and a reference cell operable as a basis when reading data stored in the memory cell, the reference cell including second and third MTJ layers arranged in parallel to each other, and a second transistor connected in series to each of the second and third MTJ layers, the second transistor having a driving capability corresponding to twice a driving capability of the first transistor of the memory cell.

Abstract: Memory circuit and a tracking circuit thereof. The tracking circuit includes a dummy bit line (DBL). The tracking circuit further includes a first circuit to discharge the dummy bit line in response to a first signal and a wordline activation signal. The wordline activation signal causes activation of a memory cell. The tracking circuit also includes a second circuit which is responsive to discharge of the dummy bit line to enable access to the memory cell.

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: 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 timing control circuit comprises at least three current control units coupled in parallel between a first circuit and a second circuit node. The current control units each have an active mode and an inactive mode. The current control units are responsive to a timing trigger event to pass current whose magnitude is dependent on how many of the current control units are in the active mode. The current control units comprise a plurality of groups. Current control units within a same group are responsive to a change in a bit of a control value corresponding to that group to switch together between the active and inactive modes, such that the magnitude of the current is dependent on which of the groups are in the active mode. The signal timing in the associated circuit is varied in dependence on the magnitude of the current.

Abstract: A semiconductor memory cell array includes a plurality of bit-lines, a plurality of word-lines, a plurality of memory cells, a plurality of dummy memory cells, a plurality of dummy bit-lines, and a plurality of dummy word-lines. The dummy bit-lines are in outer regions of the bit-lines. The dummy word-lines are in outer regions of the word-lines. The dummy bit-lines are maintained in a floating state. The dummy word-lines retain a turn-off voltage.

Abstract: A data processing device according to the present invention comprises a nonvolatile memory and a trimming data read control circuit. The nonvolatile memory has a plurality of memory regions in which the same trimming data is stored. The trimming data read control circuit reads the trimming data from a random one of the plurality of memory regions.

Abstract: A semiconductor memory includes a real memory cull; 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: 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 reference voltage generation circuit includes a first node settable at a reference voltage to be any one of a plurality of voltage levels, a second node set at a pre-charge voltage, first and second switches connected in series between the first and second nodes, a plurality of capacitors, each capacitor comprising a first end connected to a connection node between the first and second switches and a second end settable at an independent voltage level, a switch controller configured to turn off the first switch and turn on the second switch in an initial state, and then to turn off the second switch, and then to turn on the first switch, and a voltage controller configured to individually set a voltage at the second end of each capacitor after the first switch is turned on.

Abstract: An array of SMT MRAM cells has a read reference circuit that provides a reference current that is the sum of a minimum current through a reference SMT MRAM cell programmed with a maximum resistance and a maximum current through an reference SMT MRAM cell programmed with a minimum resistance. The reference current forms an average reference voltage at the reference input of a sense amplifier for reading a data state from selected SMT MRAM cells of the array such that the reference SMT MRAM cells will not be disturbed during a read operation. The read reference circuit compensates for current mismatching in the reference current caused by a second order non matching effect.

Abstract: A semiconductor memory apparatus includes a sense amplifier coupled to a plurality of bit lines, a switching unit configured to cause the plurality of bit lines to be coupled to a first node in response to a switching signal, a mode selecting unit configured to selectively couple the first node to a pad or a ground terminal in response to a mode selection signal and a testing unit configured to supply current to the pad during a test mode.

Abstract: Embodiments of the invention relate generally to data storage and computer memory, and more particularly, to systems, integrated circuits and methods to compensate for defective memory in third dimension memory technology. In a specific embodiment, an integrated circuit is configured to compensate for defective memory cells. For example, the integrated circuit can include a memory having memory cells that are disposed in multiple layers of memory. It can also include a memory reclamation circuit configured to substitute a subset of the memory cells for one or more defective memory cells. At least one memory cell in the subset of the memory cells resides in a different plane in the memory than at least one of the one or more defective memory cells.

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.

Abstract: The present invention provides a semiconductor memory and a control method therefor, the semiconductor device including a first current-voltage conversion circuit (16) connected to a core cell (12) provided in a nonvolatile memory cell array (10), a second current-voltage conversion circuit (26) connected to a reference cell (22) through a reference cell data line (24), a sense amplifier (18) sensing an output from the first current-voltage conversion circuit and an output from the second current-voltage conversion circuit, a compare circuit (28) comparing a voltage level at the reference cell data line with a predefined voltage level, and a charging circuit (30) 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: Over-erasure induced noise on a data line in a nonvolatile memory that couples into an adjacent data line is mitigated by using twisted data lines and differential sensing amplifiers. Noise coupled into data lines is compensated by similar noise coupled into reference data lines and cancelled in the differential sensing amplifiers.

Abstract: Provided is a memory circuit including: memory cells (A) arranged in columns and rows; memory cells (B) each provided for each of the rows for storing information indicative of whether writing into the memory cells (A) of the each of the rows has been completed or not; and a circuit for selecting one of the rows by utilizing the information stored in the memory cells (B). The memory circuit writes information into the memory cell (B) upon completion of writing into the memory cells (A) of a given one of the rows. By utilizing a change in the information stored in the memory cell (B), the given one of the rows is switched from a selected state to a non-selected state, and a next row is switched from the non-selected state to the selected state so that writing is enabled. The operation is repeated to thereby sequentially select a row to be written.

Abstract: A nonvolatile memory device includes one or more reference cell transistors, one or more memory cell transistors, and a current source circuit including three or more field effect transistors that have gates thereof connected together, the three or more field effect transistors including two or more field effect transistors and another field effect transistor, currents flowing through the two or more field effect transistors being combined to flow through the one or more reference cell transistors, and another field effect transistor having a drain thereof connected to one of the one or more memory cell transistors.

Abstract: The present invention is directed to provide a semiconductor device having a dual-port memory circuit in which influence of placement of replica cells exerted on enlargement of chip area is reduced. A memory cell array of a dual-port memory circuit has: a first replica cell array used to respond to an instruction of reading operation from one of dual ports; and a second replica cell array used to respond to an instruction of reading operation from the other dual port. Each of the replica cell arrays has: replica bit lines obtained by mutually short-circuiting parallel lines having a length obtained by cutting, in half, an inversion bit line and a non-inversion bit line of complementary bit lines to which data input/output terminals of a memory cell are coupled; and replica cells coupled to the replica bit lines and having transistor placement equivalent to that of the memory cells.

Abstract: A semiconductor apparatus with an open bit line structure includes a memory bank including a plurality of memory cell blocks and dummy mats, in which a plurality of bit lines are formed, a bit line sense amplifier configured to be arranged between the plurality of memory cell blocks and the dummy mats, compare a voltage difference between a bit line and a complementary bit line, and amplify the difference, and a dummy word line driving unit configured to selectively activate a dummy word line of the dummy mat in response to a test mode.

Abstract: In a 4F2 memory cell designed using an SGT as a vertical transistor, a bit line has a high resistance because it is comprised of a diffusion layer underneath a pillar-shaped silicon layer, which causes a problem of slowdown in memory operation speed. The present invention provides a semiconductor storage device comprising an SGT-based 4F2 memory cell, wherein a bit line-backing cell having the same structure as that of a memory cell is inserted into a memory cell array to allow a first bit line composed of a diffusion layer to be backed with a low-resistance second bit line through the bit line backing cell, so as to provide a substantially low-resistance bit line, while suppressing an increase in area of the memory cell array.

Abstract: A memory chip includes memory cells storing data to be read, at least one reference cell having a reference cell current level, at least one reference gate voltage memory cell storing a reference gate voltage value and a read circuit to read the memory cells with a fixed gate voltage with respect to at least one reference cell activated at a voltage having its associated stored reference gate voltage value.

Abstract: A circuit comprises a first read bit line, a second read bit line, and a sense amplifier. First and second read bit lines couple a plurality of memory cells and a reference cell of a memory array, respectively. The sense amplifier is configured to receive the first read bit line as a first input and the second read bit line as a second input. When a memory cell of the first plurality of memory cells is read, the memory cell is read activated, the first reference cell is configured to be off, the second reference cell is configured to be on, and the sense amplifier is configured to provide an output reflecting a data logic stored in the memory cell based on a voltage difference between a first voltage of the first read bit line and a second voltage of the second read bit line.

Abstract: A memory wherein the bit reliability of the memory cells can be dynamically varied depending on the application or the memory status, the operation stability is ensured, and thereby a low power consumption and a high reliability are realized. Either a mode (a 1-bit/1-cell mode) in which one bit is composed of one memory cell or a mode (a 1-bit/n-cell mode) in which one bit is composed of n (n is two or more) connected memory cells is dynamically selected. When the 1-bit/n-cell mode is selected, the read/write stability of one bit is enhanced, the cell current during read is increased (read is speeded up), and a bit error, if occurs, is self-corrected. Especially, a pair of CMOS transistors and a control line for performing control so as to permit the CMOS transistors to conduct are added between the data holding nodes of n adjacent memory cells. With this, the word line (WL) is controlled, and thereby the operation stability is further improved.

Abstract: A data sensing method for sensing storage data stored in a memory cell includes the steps of: biasing a sensing node and a reference node to a first voltage in response to a first control signal; discharging the sensing node and the reference node via the memory cell and a reference memory cell, respectively; enabling a latch circuit to amplify a voltage difference between the sensing node and the reference node.

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: An SRAM delay circuit that tracks bitcell characteristics. A circuit is disclosed that includes an input node for receiving an input signal; a reference node for capturing a reference current from a plurality of reference cells; a capacitance network having a discharge that is controlled by the reference current; and an output circuit that outputs the input signal with a delay, wherein the delay is controlled by the discharge of the capacitance network.

Abstract: A phase change memory (PCM) cycle timer and associated method are disclosed. A system includes at least one reference phase change element (PCE). The system also includes a circuit that performs a write operation on the at least one reference PCE and substantially immediately thereafter continuously senses and returns a value of a resistance of the at least one reference PCE throughout a settling time of the at least one reference PCE.

Abstract: Input/Output circuitry employs thin-film switching devices to drive output signals from an integrated circuit to an external device and to receive input signals from an external device. Three terminal ovonic threshold switches (3T OTS) may be employed to drive input and output signals.

Abstract: Method and device for controlling a memory access and correspondingly configured semiconductor memory A method and a device for controlling a memory access of a memory comprising memory cells are described. A completion of the memory access is determined by means of at least one dummy bit line. The at least one dummy bit line is connected to a plurality of memory cells of the memory cells of the memory such that a content of the at least one memory cell can be read out via the at least one dummy bit line. The at least one memory cell can be set to a predetermined potential. Each of said plurality of memory cells is connected to the at least one dummy bit line and to at least one dummy word line such that each of said plurality of memory cells can be set to the predetermined potential by means of the at least one dummy bit line and by means of the at least one dummy word line.

Abstract: In a 4F2 memory cell designed using an SGT as a vertical transistor, a bit line has a high resistance because it is comprised of a diffusion layer underneath a pillar-shaped silicon layer, which causes a problem of slowdown in memory operation speed. The present invention provides a semiconductor storage device comprising an SGT-based 4F2 memory cell, wherein a bit line-backing cell having the same structure as that of a memory cell is inserted into a memory cell array to allow a first bit line composed of a diffusion layer to be backed with a low-resistance second bit line through the bit line backing cell, so as to provide a substantially low-resistance bit line, while suppressing an increase in area of the memory cell array.

Abstract: A semiconductor memory device includes a plurality of memory cell transistors arranged in a matrix and each configured to store data, and a test circuit configured to output to outside the semiconductor memory device an output signal indicative of an amount of test current flowing through a selected one of the plurality of memory cell transistors, wherein the test circuit includes a plurality of reference cell transistors employed to successively produce varying amounts of currents, a comparison circuit configured to successively compare the amount of test current with each of the varying amounts of currents, and a code generating circuit configured to generate a code indicative of a result of the successive comparisons performed by the comparison circuit, wherein the code is output as the output signal.

Abstract: A regular capacitor is saturated by an electric charge of a regular memory cell holding a high logic level and is not saturated by an electric charge from the regular memory cell holding a low logic level. A reference capacitor is saturated by the electric charge from a reference memory cell holding the high logic level. A differential sense amplifier differentially amplifies a difference between a regular read voltage read from the regular capacitor and a voltage which is lower by a first voltage than a reference read voltage being a saturation voltage read from the reference capacitor, and generates logic of data held in the memory cell. Accordingly, a difference between the reference voltage and the read voltage corresponding to the low logic level can be made relatively large. As a result, it is possible to improve a read margin.

Abstract: A fuse circuit includes a fuse unit configured to drive an output terminal via a current path including a fuse in response to a fuse enable signal; and a comparison unit configured to be activated in response to an activation signal for comparing a reference voltage having a predetermined level with a voltage level of the output terminal to generate a fuse state signal.

Abstract: A sense amplifier comprises a sense node, a reference node, a memory input stage circuit, a reference input stage circuit, an output stage circuit, and a shielding circuit. The memory input stage circuit comprises first input node for maintaining a first sense voltage established by a cell current and establishes a second sense voltage on the sense node in response to the first sense voltage. The reference input stage circuit comprises an output node and a second input node, which is for maintaining a first reference voltage established by the reference current and establishes a second reference voltage on the reference node in response to the first reference voltage. The output stage circuit obtains a sense result in response to the second reference voltage and the second sense voltage. The first shielding circuit shields the output node from being interfered with the second reference voltage on the reference node.

Abstract: An apparatus and associated method for generating a reference voltage with dummy resistive sense element regions. A first resistance distribution is obtained for a first dummy region of resistance sense elements and a second resistance distribution is obtained for a second dummy region of resistive sense elements. A user resistive sense element from a user region is assigned to a selected resistive sense element of one of the first or second dummy regions in relation to the first and second resistance distributions.

Abstract: A method and apparatus for reading data from a non-volatile memory cell. In some embodiments, a cross-point array of non-volatile memory cells is arranged into rows and columns that are each controlled by a line driver. A read circuit is provided that is capable of reading a logical state of a predetermined memory cell by differentiating a non-integrated first reference value from a non-integrated second reference value. Further, each reference value is measured immediately after configuring the column corresponding to the predetermined memory cell to produce a first and second amount of current.

Abstract: A voltage sensing circuit, which is capable of controlling a pumping voltage to be stably generated in a low voltage environment, is provided. The voltage sensing circuit includes a current mirror having first and second terminals, a first switching element configured to control current on the first terminal of the current mirror by a reference voltage, a second switching element configured to control current from the second terminal of the current mirror in response to a pumping voltage, and a third switching element configured to control current sources of the first and second switching elements to receive a negative voltage.

Abstract: A semiconductor memory device having the mismatch cell makes a capacitance difference between a bit line pair relatively large during a read operation using at least one dummy memory cell as a mismatch cell selected together with a corresponding memory cell. Therefore, data of a semiconductor memory device may be detected more easily.

Abstract: First and second memory cell arrays are adjacent in a first direction. First and second areas are positioned adjacent to one and the other side of the first memory array in a second direction. Third and fourth areas are positioned adjacent to one and the other side of the second memory array in a second direction. A sense amplifier is arranged in the first area and a current sink is arranged in the fourth area. The sense amplifier compares a read current which flows into the current sink via a memory cell in the first memory cell array and the second area from the sense amplifier with a reference current which flows into the current sink via the third area and a reference memory cell in the second memory cell array from the sense amplifier.

Abstract: A semiconductor device includes a bit line connected to a plurality of memory cells in a memory block and a sense amplifier having a first node connected to the bit line and a second node, which is not connected to any bit line. The second node has a capacitive load less than that of the bit line. The sense amplifier amplifies a first data using a voltage difference between the first node and the second node caused by a charge sharing operation, and a second data using a capacitive mismatch between the first node and the second node.

Abstract: A resistance change memory includes two memory cell arrays each including a plurality of memory cells, the memory cells including variable resistive elements, two reference cell arrays provided to correspond to the two memory cell arrays, respectively, and each including a plurality of reference cells, the reference cells having a reference value, and a sense amplifier shared by the two memory cell arrays and detecting data in an accessed memory cell by use of a reference cell array corresponding to a second memory cell array different from a first memory cell array including the accessed memory cell. In reading the data, a particular reference cell in one reference cell array is always activated for an address space based on one memory cell array as a unit.

Abstract: An output current of a memory cell is sensed by a sensing circuit for distinguishing a program state and an erase state of the memory cell. The sensing circuit includes a reference transistor, a P-type MOSFET, and an N-type MOSFET. The P-type MOSFET has a gate connected to a memory cell for receiving an output current of the memory cell. The N-type MOSFET has a drain connected to a drain of the first P-type MOSFET, and has a source connected to ground. The inverter has an input terminal connected to the drain of the first N-type MOSFET. The voltage at an output terminal of the inverter is used for indicating the program state or the erase state of the memory cell. The reference transistor has a gate connected to a reference signal, and has a drain connected to the gate of the P-type MOSFET.

Abstract: Methods and apparatuses for reduction of Read Disturb errors in a NAND FLASH memory system utilizing modified or extra FLASH memory cells.

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 circuit for generating a reference voltage includes at least one reference cell, a reference cell write driver, a reference cell sense amplifier, and a voltage compensation unit. The reference cell is a variable resistance memory cell. The reference cell write driver writes data to the reference cell. The reference cell sense amplifier reads out the data stored in the reference cell on the basis of a predetermined reference voltage. A voltage compensation unit outputs a compensation reference voltage by controlling the reference voltage in accordance with the output value of the sense amplifier.

Abstract: A sensing characteristic evaluating apparatus for a semiconductor device includes a test current supply unit configured to supply a test current to an input/output line during a test mode for evaluating a sensing characteristic, and a sensing amplifying circuit configured to receive the test current from the input/output line, to compare and amplify a sensing input voltage corresponding to the test current with a reference voltage, and to output an amplified voltage as a sensing output voltage.

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 magnetic storage device includes a plurality of MRAM memory cells connected to a data transfer line, a clamp transistor connected between the data transfer line and a reading signal line and configured to fixedly hold the potential of the data transfer line, and a reading circuit which is connected to the reading signal line and which reads the storage information of the memory cell. The reading circuit includes a hold switch connected between the reading signal line and a reading node N and configured to hold the potential of the node N, a capacitor connected between the node N and a ground end, a precharging switch connected between the node N and a power source and configured to charge the capacitor, and an inverter to which the potential of the node N is input to generate a digital signal.

Abstract: Source-side sensing techniques described herein determine the data value stored in a memory cell based on the difference in current between the read current from the source terminal of the memory cell and a sink current drawn from the read current. The sink current is drawn in response to a magnitude of an operating voltage between first and second nodes. During a first time interval, the operating voltage is set in response to a magnitude of the reference current using a feedback path. During a second time interval following the first time interval, the operating voltage is held independent of the feedback path. The data value stored in the memory cell is determined based on a difference in current between the read current and the sink current during the second time interval.