Abstract: A semiconductor memory device includes a plurality of word lines each of which are connected to a plurality of memory cells, a row control unit suitable for sequentially activating and precharging a word line corresponding to a target address and a predetermined (N) number of adjacent word lines during a target activation mode, and a mode exit control unit suitable for counting the number of activation operations by the row control unit during the target activation mode to determine whether or not to exit from the target activation mode.

Abstract: A semiconductor memory device in which capacitance of a capacitor is lower and integration degree is higher. A plurality of memory blocks is connected to one bit line BL_m. A memory block MB_n_m includes a sub bit line SBL_n_m, a write switch, and a plurality of memory cells. A sub bit line SBL_n+1_m adjacent to the sub bit line SBL_n_m is connected to an amplifier circuit AMP_n/n+1_m including two inverters and two selection switches. A circuit configuration of the amplifier circuit can be changed with the selection switches. The amplifier circuit is connected to the bit line BL_m through a read switch. Because of a sufficiently low capacitance of the sub bit line SBL_n_m, potential change due to electric charges of the capacitor in each memory cell can be amplified by the amplifier circuit AMP_n/n+1_m without an error, and the amplified data can be output to the bit line BL_m.

Abstract: Embodiments of the disclosure provide a method for backing up data in an SRAM device, and an SRAM device that includes a capacitive backup circuit for backing up data in an SRAM device. The method may include writing data to the SRAM cell by applying an input voltage to set an input node of cross-coupled inverters to a memory state. The method may also include backing up the data written to the SRAM cell by electrically coupling the input node to the capacitive backup circuit. The method may also include restoring the data stored in the capacitive backup circuit to the SRAM cell by electrically coupling the capacitive backup circuit to the input node.

Abstract: A memory device comprises: a memory cell array comprising first and second word lines located adjacent to each other, a first memory cell connected to the first word line, and a second memory cell connected to the second word line and located adjacent to the first memory cell; and a word line voltage supplying unit that transitions a word line voltage of the first word line from a first word line voltage to a second word line voltage, in response to a first control signal. A transition control unit generates the first control signal for controlling a pulse of the word line voltage of the first word line in a transition period from the first word line voltage to the second word line voltage in such a way that a transition waveform profile from the first word line voltage to the second word line voltage is different from a transition waveform profile from the second word line voltage to the first word line voltage.

Abstract: Embodiments of the disclosure provide a method for backing up data in an SRAM device, and an SRAM device that includes a capacitive backup circuit for backing up data in an SRAM device. The method may include writing data to the SRAM cell by applying an input voltage to set an input node of cross-coupled inverters to a memory state. The method may also include backing up the data written to the SRAM cell by electrically coupling the input node to the capacitive backup circuit. The method may also include restoring the data stored in the capacitive backup circuit to the SRAM cell by electrically coupling the capacitive backup circuit to the input node.

Abstract: Provided is a refresh method of a volatile memory device. The method includes: detecting a number of disturbances that affect a second memory area as the number of accesses to a first memory area is increased; outputting an alert signal from the volatile memory device to an outside of the volatile memory device when the detected number of disturbances reach a reference value; and performing a refresh operation on the second memory area in response to the alert signal.

Abstract: A semiconductor device which stores data by using a transistor whose leakage current between source and drain in an off state is small as a writing transistor. In a matrix including a plurality of memory cells in which a drain of the writing transistor is connected to a gate of a reading transistor and the drain of the writing transistor is connected to one electrode of a capacitor, a gate of the writing transistor is connected to a writing word line; a source of the writing transistor is connected to a writing bit line; and a source and a drain of the reading transistor are connected to a reading bit line and a bias line. In order to reduce the number of wirings, the writing bit line or the bias line is substituted for the reading bit line in another column.

Abstract: A memory integrated circuit device is provided. The device includes a plurality of regular address inputs and at least one spare address input configured for a selected mode or an unselected mode. The device includes a plurality of control inputs, a plurality of data inputs, and a plurality of data outputs. The device has a plurality of memory arrays. Each of the memory arrays comprises a plurality of memory cells. Each of the plurality of memory cells is coupled to a data input/output. The device has a spare group of memory cells comprising a plurality of spare memory cells. Each of the plurality of spare memory cells is externally (or internally) addressable using the address match table and configured with the spare address input; whereupon the spare address input is coupled to the address match table to access the spare memory cells.

Abstract: An integrated circuit and a manufacturing method thereof are provided. A chip size can be reduced by forming a memory device in which a ferroelectric capacitor region is laminated on a DRAM. The integrated circuit includes a cell array region having a capacitor, a peripheral circuit region, and a ferroelectric capacitor region being formed on an upper layer of the cell array region and the peripheral circuit region, and having a ferroelectric capacitor device.

Abstract: A semiconductor device including a nonvolatile memory cell in which a writing transistor which includes an oxide semiconductor, a reading transistor which includes a semiconductor material different from that of the writing transistor, and a capacitor are included is provided. Data is written to the memory cell by turning on the writing transistor and applying a potential to a node where a source electrode (or a drain electrode) of the writing transistor, one electrode of the capacitor, and a gate electrode of the reading transistor are electrically connected, and then turning off the writing transistor, so that the predetermined amount of charge is held in the node. Further, when a p-channel transistor is used as the reading transistor, a reading potential is a positive potential.

Abstract: A novel semiconductor memory device whose power consumption is low is provided. A source of a writing transistor WTr_n_m, a gate of a reading transistor RTr_n_m, and one electrode of a capacitor CS_n_m are connected to each other. A gate and a drain of the writing transistor WTr_n_m are connected to a writing word line WWL_n and a writing bit line WBL_m, respectively. The other electrode of the capacitor CS_n_m is connected to a reading word line RWL_n. A drain of the reading transistor RTr_n_m is connected to a reading bit line RBL_m. Here, the potential of the reading bit line RBL_m is input to an inverting amplifier circuit such as a flip-flop circuit FF_m to be inverted by the inverting amplifier circuit. This inverted potential is output to the writing bit line WBL_m.

Abstract: In a case where a DRAM and a ReRAM are mounted together, a manufacturing cost thereof is reduced while maintaining performance of a capacitance element and a variable resistance element. A semiconductor memory device includes a variable resistance element and a capacitance element. The variable resistance element has a cylinder type MIM structure with a first depth, and is designed for a variable resistance type memory. The capacitance element has a cylinder type MIM structure with a second depth deeper than the first depth, and is designed for a DRAM.

Abstract: Cross-point memory cells, non-volatile memory arrays, methods of reading a memory cell, methods of programming a memory cell, and methods of writing to and reading from a memory cell are described. In one embodiment, a cross-point memory cell includes a word line extending in a first direction, a bit line extending in a second direction different from the first direction, the bit line and the word line crossing without physically contacting each other, and a capacitor formed between the word line and the bit line where such cross. The capacitor comprises a dielectric material configured to prevent DC current from flowing from the word line to the bit line and from the bit line to the word line.

Abstract: A memory comprises a two dimensional array of memory cells. Each memory cell comprises a first transistor, a second transistor and a capacitor. A multi-bit datum is stored as one of a plurality of voltage signal levels driven over a vertical input signal line and further across a source and a drain of the first transistor to be stored onto a gate of the second transistor. The first transistor is selected by a horizontal WR control line. The gate of the second transistor is connected to a first terminal of the capacitor. A second terminal of the capacitor is connected to a horizontal RD control line. The RD control line is driven to couple the second transistor to drive a signal onto a vertical output signal line during a read of the stored signal on the gate.

Abstract: An integrated circuit which can be switched to a resting state and can be returned from the resting state rapidly is provided. An integrated circuit whose power consumption can be reduced without the decrease in operation speed is provided. A method for driving the integrated circuit is provided. The integrated circuit includes a first flip-flop and a second flip-flop including a nonvolatile memory circuit. In an operating state in which power is supplied, the first flip-flop retains data. In a resting state in which supply of power is stopped, the second flip-flop retains data. On transition from the operating state into the resting state, the data is transferred from the first flip-flop to the second flip-flop. On return from the resting state to the operating state, the data is transferred from the second flip-flop to the first flip-flop.

Abstract: Implementations disclosed herein may relate to a memory cell, such as a DRAM memory cell, for example.

Abstract: An object is to increase the retention characteristics of a memory device formed using a semiconductor with a wide bandgap, such as an oxide semiconductor. A transistor including a back gate (a back gate transistor) is inserted in series at one end of a bit line so that the back gate is constantly at a sufficiently negative potential. The minimum potential of the bit line is set higher than that of a word line. When power is turned off, the bit line is cut off by the back gate transistor, ensuring prevention of outflow of charge accumulated in the bit line. At this time, the potential of a source or a drain (bit line) of a cell transistor is sufficiently higher than that of a gate of the cell transistor (0 V), so that the cell transistor is put in a sufficiently off state; thus, data can be retained.

Abstract: A method and apparatus for modifying a reference voltage between refreshes in a memory device are disclosed. The memory array may include a plurality of memory cells. The memory device may also include a sense amplifier. The sense amplifier may be configured to read data from the plurality of memory cells using a reference voltage. The memory device may also include a sense amplifier reference voltage modification circuit. The sense amplifier reference voltage modification circuit may be configured to detect a triggering event and modify the reference voltage in response to detecting a triggering event.

Abstract: A method and apparatus for refreshing a row of a memory device prior to a scheduled refresh. A memory array may include a plurality of memory cells. The memory array may be configured to be refreshed at a first refresh time interval. The memory device may also include an intermediate refresh circuit. The intermediate refresh circuit may be configured to detect a triggering event and request a refresh for a row of the memory array in response to detecting a triggering event.

Abstract: A method of manufacturing a dynamic random access memory device is provided. The method includes testing a DRAM device using a testing process. The method includes identifying, under control by a computing device, a plurality of bad memory cells from the DRAM device and determining a list of addresses associated with the plurality of bad memory cells. The method includes sorting the list of addresses in either ascending or descending order and subjecting the information from the sorted list of address to a compression process, under control by the computing device, to provide a compressed format including a first content entry in the sorted list and a series of off-set values as provided by a recurrence relationship. The method also stores the compressed format into a non-volatile memory.

Abstract: A memory circuit is included. The memory circuit includes n field-effect transistors (n is a natural number of 2 or more) and n capacitors each including a pair of electrodes. A digital data signal is input to one of a source and a drain of the first field-effect transistor. One of a source and a drain of the k-th field-effect transistor (k is a natural number of greater than or equal to 2 and less than or equal to n) is electrically connected to the other of a source and a drain of the (k?1)-th field-effect transistor. One of the pair of electrodes of the m-th capacitor (m is a natural number of n or less) is electrically connected to the other of a source and a drain of the m-th field-effect transistor of the n field-effect transistors. At least two of the n capacitors have different capacitance values.

Abstract: A device includes a plurality of memory areas each including a plurality of memory cells required to perform refresh of information stored therein by a plurality of sense amplifiers, a first control circuit determining, in connection with one refresh requirement signal at a time, a number of refresh-target memory areas to produce a determined number, a second control circuit controlling, in accordance with the one refresh requirement signal at a time, refresh operation with respect to the refresh-target memory areas, and a third control circuit adjusting, in connection with the refresh operation, an active time-out time interval according to the determined number. The active time-out time interval indicates a time interval from a first time instant when the sense amplifiers are activated to a second time instant when word lines related to the refresh-target memory areas are inactivated.

Abstract: An object is to provide a signal processing circuit which can be manufactured without a complex manufacturing process and suppress power consumption. A storage element includes two logic elements (referred to as a first phase-inversion element and a second phase-inversion element) which invert a phase of an input signal and output the signal, a first selection transistor, and a second selection transistor. In the storage element, two pairs each having a transistor in which a channel is formed in an oxide semiconductor layer and a capacitor (a pair of a first transistor and a first capacitor, and a pair of a second transistor and a second capacitor) are provided. The storage element is used in a storage device such as a register or a cache memory included in a signal processing circuit.

Abstract: Power management of an embedded dynamic random access memory (eDRAM) by receiving an eDRAM power state transition event and determining both the current power state of the eDRAM and the next power state of the eDRAM from the power states of: a power-on state, a power-off state, and a self-refresh state. Using the current power state and the next power state to determine whether a power state transition is required, and, in the case that a power state transition is required, transition the eDRAM to the next power state. Power management is achieved because transitioning to a power-off state or self-refresh state reduces the amount of power consumed by the eDRAM as compared to the power-on state.

Abstract: A refresh address is generated with a refresh period for refreshing a memory device with refresh leveraging. A respective refresh is performed on a weak cell having a first address when the refresh address is a second address instead of on a first strong cell having the second address. A respective refresh is performed on one of the first strong cell or a second strong cell having a third address when the refresh address is the third address. Address information is stored for only one of the first, second, and third addresses such that memory capacity may be reduced. In alternative aspects, a respective refresh is performed on one of a weak cell, a first strong cell, or a second strong cell depending on a flag when the refresh address is any of at least one predetermined address to result in refresh leveraging.

Abstract: A semiconductor memory device includes a plurality of memory cell blocks including a first memory cell block having bit lines, an edge sense amplifier block including edge sense amplifiers coupled to a portion of the bit lines of the first memory cell block, and a balancing capacitor unit coupled to the edge sense amplifiers.

Abstract: A 2.5D or 3D repair architecture includes a logic die, and a memory die. In the 2.5D architecture, the logic die and memory die are mounted on an interposer. In the 3D architecture, the memory die is mounted on the logic die. The logic has a control logic wrapped with a processor wrapper. The processor wrapper enables testing components of the control logic. The control logic further comprises a wide input/output controller, a built-in-repair analyzer (BIRA), and a repair controller. A method utilizing the repair architecture provides for repairing failed columns and rows of a memory device.

Abstract: A method for storing data. The method includes providing an addressable memory including a memory space, wherein the memory space includes a plurality of memory cells. The method includes configuring the addressable memory such that a majority of the plurality of memory cells in the memory space stores internal data values in a preferred bias condition when a first external data state of one or more external data states is written to the memory space, wherein the first external data state is opposite the preferred bias condition.

Abstract: A charge/discharge circuit is configured to directly charge a storage system using a power source under a power-on stage and to charge the storage system using power pre-stored in a capacitor under a power-off stage. With the aid of the charge/discharge circuit, an access speed of the storage system is prevented from being slowed down by attaching the large capacitance of the capacitor, and data accuracy of the storage system is prevented from being affected by sudden loss of power supply of the power source.

Abstract: An apparatus including a memory module and power converter and method of operating the same. In one embodiment, the apparatus includes a memory module, located on a circuit board, configured to operate from a first voltage and a second voltage being a multiple of the first voltage. The apparatus also includes a power converter employing a switched-capacitor power train, located on the circuit board, configured to provide the second voltage for the memory module from the first voltage.

Abstract: A memcapacitor device includes a pair of opposing conductive electrodes. A semiconductive material including mobile dopants within a dielectric and a mobile dopant barrier dielectric material are received between the pair of opposing conductive electrodes. The semiconductive material and the barrier dielectric material are of different composition relative one another which is at least characterized by at least one different atomic element. One of the semiconductive material and the barrier dielectric material is closer to one of the pair of electrodes than is the other of the semiconductive material and the barrier dielectric material. The other of the semiconductive material and the barrier dielectric material is closer to the other of the pair of electrodes than is the one of the semiconductive material and the barrier dielectric material. Other implementations are disclosed, including field effect transistors, memory arrays, and methods.

Abstract: A technology is a semiconductor cell and a semiconductor device capable of reducing the coupling capacitance between adjacent bit lines by forming a bit line junction region in a separated island shape when forming a buried bit line, thereby improving characteristics of the semiconductor devices. The semiconductor cell includes a transistor including a gate and a gate junction region, a plurality of buried bit lines disposed to intersect the gate, and a plurality of bit line junction regions, each bit line junction region having an island shape formed between the buried bit lines and connected to the buried bit line.

Abstract: A data processing circuit includes a data processing unit including two signal-conversion circuits and controlled switches connected to inputs and outputs of the conversion circuits. The data processing unit further includes a binary signal inlet, a binary signal outlet, and a memory unit. The memory unit includes capacitors each storing a binary piece of data. The capacitors are connected to a memory bus via switches. The bus is connected to the processing unit. In response to control signals provided to the controlled switches, the data processing unit performs at least the following operations: writing a binary datum in a capacitor, reading from a capacitor a binary datum stored therein and applying the datum to an output, and logically combining binary data stored in at least two capacitors.

Abstract: Methods and systems for a high-density, low-cost, CMOS compatible memory may comprise a memory cell on a chip, the memory cell comprising: a plurality of capacitor/switch pairs, where for each pair comprising a switch and a capacitor, a source terminal of the switch is coupled to a gate terminal of the capacitor. The memory cell may also comprise a reset transistor, a biasing circuit, and a source follower. A drain terminal of each switch may be coupled to a floating node that couples a source terminal of the reset transistor and a gate terminal of the source follower. Drain and source terminals of each of the switches of the plurality of capacitor/switch pairs may be coupled to ground. A number of the plurality of capacitor/switch pairs may indicate a number of bits in the memory. The biasing circuit may comprise a current mirror. A bit-line for the memory cell may be coupled to a source terminal of the source follower. The bit-line may comprise a metal trace.

Abstract: To increase a storage capacity of a memory module per unit area, and to provide a memory module with low power consumption, a transistor formed using an oxide semiconductor film, a silicon carbide film, a gallium nitride film, or the like, which is highly purified and has a wide band gap of 2.5 eV or higher is used for a DRAM, so that a retention period of potentials in a capacitor can be extended. Further, a memory cell has n capacitors with different capacitances and the n capacitors are each connected to a corresponding one of n data lines, so that a variety of the storage capacitances can be obtained and multilevel data can be stored. The capacitors may be stacked for reducing the area of the memory cell.

Abstract: A memory device which can reduce power consumption and a driving method thereof are disclosed. In a memory element including an inverter and the like, a capacitor for holding data and a capacitor switching element for controlling store and release of charge in the capacitor are provided. The capacitor switching element is designed so that the off-state current is sufficiently low. Therefore, even when power supply of the inverter is stopped after charge corresponding to data is stored in the capacitor, data can be held for a long period of time. In order to return data, potentials of output and input terminals of the inverter are set to a precharge potential, then charge in the capacitor is released, and power is supplied to the inverter. A switching element for supplying the precharge potential may be provided.

Abstract: One embodiment relates to a memory device including a plurality of memory units tiled together to form a memory array. A memory unit includes a plurality of memory cells, which include respective capacitors and respective transistors, disposed on a semiconductor substrate. The capacitors include respective lower plates disposed in a conductive region in the semiconductor substrate. A wordline extends over the conductive region, and a contact couples the wordline to the conductive region so as to couple the wordline to the lower plates of the respective capacitors. The respective transistors are arranged so successive gates of the transistors are arranged on alternating sides of the wordline.

Abstract: A semiconductor device which is capable of high-speed writing with less power consumption and suitable for multi-leveled memory, and verifying operation. A memory cell included in the semiconductor device included a transistor formed using an oxide semiconductor and a transistor formed using a material other than an oxide semiconductor. A variation in threshold value of the memory cells is derived before data of a data buffer is written by using a writing circuit. Data in which the variation in threshold value is compensated with respect to the data of the data buffer is written to the memory cell.

Abstract: A structure for storing a native binary code in an integrated circuit, including an array of planar MIM capacitors above an insulating layer formed above a copper metallization network, wherein at least one metallization portion is present under each MIM capacitor. The size of the portion(s) is selected so that from 25 to 75% of the MIM capacitors have a breakdown voltage smaller by at least 10% than that of the other MIM capacitors.

Abstract: A memory device includes a first memory circuit including a silicon transistor, a selection circuit including a silicon transistor, and a second memory circuit including oxide semiconductor transistors and a storage capacitor, in which one terminal of the storage capacitor is connected to a portion where two oxide semiconductor transistors are connected in series, an output of the second memory circuit is connected to a second input terminal of the selection circuit, and an input of the second memory circuit is connected to a first input terminal of the selection circuit or an output terminal of the first memory circuit.

Abstract: A system is provided for transmitting signals. The system includes a ground-referenced single-ended signaling (GRS) driver circuit that is configured to pre-charge a first capacitor to store a first charge between a first output node and a first reference node based on a first input data signal during a first pre-charge phase and drive an output signal relative to a ground network based on the first charge during a first drive phase. A control circuit is configured to generate a first set of control signals based on the first input data signal and a first clock signal, where the first set of control signals causes the first GRS driver circuit to operate in either the first pre-charge phase or in the first drive phase.

Abstract: A system of interconnected chips comprising a multi-chip module (MCM) includes a first processor chip, a system function chip, and an MCM package configured to include the first processor chip and the system function chip. The first processor chip is configured to include a first ground-referenced single-ended signaling (GRS) interface circuit. The system function chip is configured to include a second GRS interface circuit. A first set of electrical traces are fabricated within the MCM package and coupled to the first GRS interface circuit and to the second GRS interface circuit. The first GRS interface circuit and second GRS interface circuit together provide a communication channel between the first processor chip and the system function chip.

Abstract: Disclosed is a pulsed sense amplifier approach for resolving data on a bit line.

Abstract: A memory device with a novel structure that is suitable for a register file is provided. The memory device includes a first memory circuit and a second memory circuit. The first memory circuit includes a first logic element and a second logic element each of which is configured to perform logic inversion, a selection circuit, a first switch, a second switch, and a third switch. The second memory circuit includes a first transistor in which a channel formation region is provided in an oxide semiconductor film, a second transistor, and a capacitor to which a potential is supplied through the first transistor.

Abstract: A system includes a control circuit and first, second, and third ground-referenced single-ended signaling (GRS) driver circuits that are each coupled to an output signal. The control circuit is configured to generate a first, second, and third set of control signals that are each based on a respective phase of a clock signal. Each GRS driver circuit is configured to pre-charge a capacitor to store a charge based on the respective set of control signals during at least one phase of the clock signal and drive the output signal relative to a ground network by discharging the charge during a respective phase of the clock signal.

Abstract: In a conventional DRAM, when the capacitance of a capacitor is reduced, an error of reading data easily occurs. A plurality of cells are connected to one bit line MBL_m. Each cell includes a sub bit line SBL_n_m and 4 to 64 memory cells (a memory cell CL_n_m—1 or the like). Further, each cell includes selection transistors STr1—n—m and STr2—n—m and an amplifier circuit AMP_n_m that is a complementary inverter or the like is connected to the selection transistor STr2—n—m. Since parasitic capacitance of the sub bit line SBL_n_m is sufficiently small, potential change due to electric charge in a capacitor of each memory cell can be amplified by the amplifier circuit AMP_n_m without an error, and can be output to the bit line.

Abstract: A system and method are provided for reading ferroelectric memories in a manner that does away with a conventional requirement for inclusion of a charge or sense amplifier associated with each ferroelectric memory cell. Simple circuits are employed for modulating an AC signal that is generated and input, including wirelessly, to the circuits where a capacitance of a ferroelectric capacitor acts as a filter. Depending upon whether the ferroelectric memory (capacitor) is charged or discharged, it will have a different capacitance, which will affect the impedance that the signal sees. An ability to remotely read that signal difference, as an indication of capacitance, rather than an indication of charge, is provided to expand the use of ferroelectric memories to a broader spectrum of applications including use in RFID tags.

Abstract: The data in a volatile memory may conventionally be lost even in case of a very short time power down or supply voltage drop such as an outage or sag. In view of the foregoing, an object is to extend data retention time even with a volatile memory for high-speed data processing. Data retention time can be extended by backing up the data content stored in the volatile memory in a memory including a capacitor and an oxide semiconductor transistor.

Abstract: A memory device and method of making the memory device. Memory device may include a storage transistor at a surface of a substrate. The storage transistor comprises a body portion between first and second source/drain regions, wherein the source/drain regions are regions of a first conductivity type. The storage transistor also comprises a gate structure that wraps at least partially around the body portion in at least two spatial planes. A bit line is connected to the first source/drain region and a word line is connected to the gate structure.

Abstract: A memory cell and method for operating a memory cell including a bidirectional access device and memory element electrically coupled in series. The bidirectional access device includes a tunneling capacitance. The memory element programmable to a first and second state by application of a first and second write voltage opposite in polarity to one another. The memory element has a lower capacitance in the first state than the second state. A read unit senses a transient read current due to a voltage drop upon application of a read voltage. Determining if the memory element is the first or second state is based on whether the read current is greater or less than a sense threshold. The sense threshold is based on a capacitance ratio between the first and second state.