Abstract: An object is to provide a semiconductor device having a novel structure. A first wiring; a second wiring; a third wiring, a fourth wiring; a first transistor including a first gate electrode, a first source electrode, and a first drain electrode; a second transistor including a second gate electrode, a second source electrode, and a second drain electrode are included. The first transistor is provided over a substrate including a semiconductor material and a second transistor includes an oxide semiconductor layer.

Abstract: Semiconductor memory devices are described. The semiconductor memory device includes a cell capacitor having a first terminal electrically connected to a storage node and a second terminal electrically connected to an internal node, an internal voltage generator configured to generate an internal voltage signal applied to the internal node in response to a power-up signal, and an initialization element configured to initialize the internal node in response to the power-up signal.

Abstract: An SRAM having two capacitors connected in series between respective bit storage nodes of each memory cell. The two inverters of the memory cell are powered by a positive voltage and a low voltage. The two capacitors are connected to each other at a common node. A leakage current generator is coupled to the common node. The leakage current generator supplies to the common node a leakage current to maintain a voltage which is approximately halfway between the voltages of the high and low SRAM supplies.

Abstract: The semiconductor device includes a memory cell including a first transistor including a first channel formation region, a first gate electrode, and first source and drain regions; a second transistor including a second channel formation region provided so as to overlap with at least part of either of the first source region or the first drain region, a second source electrode, a second drain electrode electrically connected to the first gate electrode, and a second gate electrode; and an insulating layer provided between the first transistor and the second transistor. In a period during which the second transistor needs in an off state, at least when a positive potential is supplied to the first source region or the first drain region, a negative potential is supplied to the second gate electrode.

Abstract: A semiconductor memory device includes a bit line; two or more word lines; and a memory cell including two or more sub memory cells that each include a transistor and a capacitor. One of a source and a drain of the transistor is connected to the bit line, the other of the source and the drain of the transistor is connected to the capacitor, a gate of the transistor is connected to one of the word lines, and each of the sub memory cells has a different capacitance of the capacitor.

Abstract: A semiconductor device includes a nonvolatile memory cell including a writing transistor including an oxide semiconductor, a reading transistor including a semiconductor material different from that of the writing transistor, and a capacitor. Data is written to the memory cell by turning on the writing transistor so that a potential is supplied to a node where a source 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 a predetermined potential is held in the node. Data is read out from the memory cell by supplying a precharge potential to a bit line, stopping the supply of the potential to the bit line, and determining whether the potential of the bit line is kept at the precharge potential or decreased.

Abstract: An object of the current invention is to provide DRAM that is not limited by capacitors.

Abstract: An object of one embodiment of the present invention is to miniaturize a semiconductor device. Another object of one embodiment of the present invention is to reduce the area of a driver circuit of a semiconductor device including a memory element. A plurality of cells in which the positions of input terminals and output terminals are fixed is arranged in a first direction, wirings each of which is electrically connected to the input terminal or the output terminal of each cell are stacked over the plurality of cells, and the wirings extend in the same direction as the first direction in which the cells are arranged; thus, a semiconductor device in which a driver circuit is miniaturized is provided.

Abstract: A system, method and apparatus for clock and power fault detection for a memory module is provided. In one embodiment, a system is provided. The system includes a voltage detection circuit and a clock detection circuit. The system further includes a controller coupled to the voltage detection circuit and the clock detection circuit. The system also includes a memory control state machine coupled to the controller. The system includes volatile memory coupled to the memory control state machine. The system further includes a battery and battery regulation circuitry coupled to the controller and the memory control state machine. The battery, battery regulation circuitry, volatile memory, memory control state machine, controller, clock detection circuit and voltage detection circuit are all collectively included in a unitary memory module.

Abstract: A semiconductor memory device includes a memory cell array including a plurality of word lines, a plurality of bit lines including complementary pairs of bit lines, and a plurality of memory cells storing data; a sense amplifier coupled to the memory cell array and configured to sense voltage differences between the complementary pairs of bit lines and amplify the voltage differences; and at least one voltage driver configured to provide either a predetermined voltage or a first power supply voltage to the memory cell array to increase a sensing margin of the semiconductor memory device. The semiconductor memory device increases respective potential differences between complementary pairs of bit lines using a voltage isolated in the memory cell array.

Abstract: An integrated circuit memory device is disclosed. The memory device includes a memory core having a timing input to receive a clock signal. An interface couples to the memory core. The interface includes a receiver to receive a serial stream of write data bits and a sampler clocked by a strobe signal to generate serialized write data. The interface also includes a deserializer and control logic. The deserializer includes an input to receive the serialized write data and an output to generate parallel data responsive to a control signal generated by the control logic. In a first mode of operation, the control logic generates the control signal with respect to the clock signal. In a second mode of operation, the control logic generates the control signal with respect to the strobe signal.

Abstract: A semiconductor storage device has tunnel magnetoresistive elements in memory cells. The array includes a memory array having a plurality of memory cells; a plurality of read-word-lines and a plurality of write-word-lines; a plurality of read-bit-lines; a plurality of first write-bit-lines and a plurality of second write-bit-lines; a first driver; a read circuit; a second driver; and a write circuit. The memory cell has a mos transistor, of which one current electrode is coupled to the read-bit-line. A tunnel magnetoresistive element is coupled between a control electrode of the mos transistor and the read-word-line. A capacitive element is coupled to the tunnel magnetoresistive element and forms an RC circuit together with the tunnel magnetoresistive element.

Abstract: A memory apparatus is configured to generate refresh addresses with different values in response to one refresh command and an address, and perform a plurality of refresh operations with time differences in response to the refresh addresses. Herein, the refresh operations are performed within a refresh row cycle time.

Abstract: Provided is a semiconductor resistive memory device. The resistive memory device includes a plurality of unit cells. A source line and a data input/output line of the unit cells may be selectively connected to have a substantially same voltage level for equalization when the unit cells are in inactive or unselected state. The equalization may decrease current consumption and protect write error, and protect leakage current.

Abstract: A memory cell is provided with a transistor which includes source and drain electrodes formed in a semiconductor film by respectively N-doped and P-doped areas. The transistor includes first and second devices for generating a potential barrier in the semiconductor film. The two potential barriers are shifted laterally and are opposed to the passage of the charge carriers emitted by the nearest source/drain electrode. One of the devices for generating the potential barrier is electrically connected to the gate. The other of the devices for generating the potential barrier is electrically connected to the counter-electrode. The writing of a high state is carried out by imposing on the P-doped electrode a potential higher than that of the N-doped electrode and charging the capacitor formed between the gate and the semiconductor film. The resetting of the memory cell is obtained by discharging the capacitor.

Abstract: A driving method of a semiconductor device is provided. In a semiconductor device including a bit line, a selection line, a selection transistor, m (m is a natural number greater than or equal to 2) writing word lines, m reading word lines, a source line, and first to m-th memory cells, each memory cell includes a first transistor and a second transistor that holds charge accumulated in a capacitor. The second transistor includes a channel formed in an oxide semiconductor layer. In a driving method of a semiconductor device having the above structure, when writing to a memory cell is performed, the first transistor is turned on so that a first source terminal or a first drain terminal is set to a fixed potential; thus, a potential is stably written to the capacitor.

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: The semiconductor memory device includes: a memory circuit including a transistor including an oxide semiconductor in a semiconductor layer; a capacitor for storing electric charge for reading data retained in the memory circuit; a charge storage circuit for controlling storage of electric charge in the capacitor; a data detection circuit for controlling data reading; a timing control circuit for generating a first signal controlling storage of electric charge in the capacitor (storage is conducted with the charge storage circuit, and the first signal is generated with a second signal at a supply voltage and a third signal delayed from the second signal at the supply voltage in a period immediately after the supply of the supply voltage); an inverter circuit for outputting a potential obtained by inverting a potential of one electrode of the capacitor.

Abstract: Provided is a method of operating a semiconductor device, wherein an operating mode is set by adjusting timing of a voltage pulse or by adjusting a voltage level of the voltage pulse.

Abstract: A memory system includes a master device, such as a graphics controller or processor, and an integrated circuit memory device operable in a dual column addressing mode. The integrated circuit memory device includes an interface and column decoder to access a row of storage cells or a page in a memory bank. During a first mode of operation, a first row of storage cells in a first memory bank is accessible in response to a first column address. During a second mode of operation, a first plurality of storage cells in the first row of storage cells is accessible in response to a second column address during a column cycle time interval. A second plurality of storage cells in the first row of storage cells is accessible in response to a third column address during the column cycle time interval. The first and second pluralities of storage cells are concurrently accessible from the interface.

Abstract: Some embodiments regard a circuit comprising a memory cell, a first data line, a second data line, a sensing circuit coupled to the first data line and the second data line, a node selectively coupled to at least three voltage sources via at least three respective switches, a fourth switch, and a fifth switch. A first voltage source is configured to supply a retention voltage to the node via a first switch. A second voltage source is configured to supply a ground reference voltage to the node via a second switch, and a third voltage source is configured to supply a reference voltage to the node via a third switch. The fourth switch and fifth switch are configured to receive a respective first control signal and second control signal and to pass a voltage at the node to the respective first data line and second data line.

Abstract: A memory including a capacitor coupled to a write bit line or a word line and an initializer configured to initialize a voltage level at a first node between the capacitor and the write bit line or the word line. The memory further includes a controllable initial level adjuster configured to adjust a voltage level of a second node at one terminal of the capacitor in response to a pulse. The capacitor is configured to receive a boost signal at a third node at a terminal opposite the first node. The boost signal configured to change a voltage level of the write bit line or the word line in response to the boost signal.

Abstract: An object is to provide a semiconductor device in which lower power consumption is realized by lowering voltage for data writing without increase in types of power supply potentials. Another object is to provide a semiconductor device in which threshold voltage drop of a selection transistor is suppressed without increase in types of power supply potentials for data writing. A diode-connected transistor is electrically connected in series with a word line electrically connected to a gate of an n-channel selection transistor. A capacitor is provided between the word line and a bit line electrically connected to one of a source and a drain of the selection transistor; alternatively, the capacitance between the bit line and the word line is used. In data writing, the timing of selecting the word line is earlier than the timing of selecting the bit line.

Abstract: Power management of an embedded dynamic random access memory (eDRAM) using collected performance counter statistics to generating a set of one or more eDRAM effectiveness predictions. Using a set of one or more eDRAM effectiveness thresholds, each corresponding to one of the set of eDRAM effectiveness predictions, to determine whether at least one eDRAM effectiveness prediction has crossed over threshold. In the case that at least one eDRAM effectiveness prediction has crossed over its threshold, transitioning the eDRAM to a new power state. Power management is achieved by transitioning to a power-off state or self-refresh state and reducing the amount of power consumed by the eDRAM as compared to a power-on state.

Abstract: A device includes a first region including a plurality of first memory elements and a plurality of first vertical transistors, the first vertical transistors comprising a plurality of first selective transistors and a first switching transistor, each of the first selective transistors including an upper electrode coupled to a corresponding one of the first memory elements and a lower electrode, the first switching transistor including an upper electrode and a lower electrode coupled in common to the lower electrodes of the first selective transistors through a first signal line, a second region arranged to make a first line with the first region in a first direction and including a plurality of second memory elements and a plurality of second vertical transistors, the second vertical transistors comprising a plurality of second selective transistors and a second switching transistor, and a third region sandwiched between the first and the second regions.

Abstract: The invention relates to a method and apparatus providing a memory cell array in which each resistance memory cell is connected in series to a capacitive element. Access transistors are not necessary to perform read and write operations on the memory cell. In one exemplary embodiment, the capacitive element is a capacitor.

Abstract: Disclosed are methods and devices, among which is a device that includes a first semiconductor fin having a first gate, a second semiconductor fin adjacent the first semiconductor fin and having a second gate, and a third gate extending between the first semiconductor fin and the second semiconductor fin. In some embodiments, the third gate may not be electrically connected to the first gate or the second gate.

Abstract: A time delay is determined to cover a timing of a memory cell in a memory macro having a tracking circuit. Based on the time delay, a capacitance corresponding to the time delay is determined. A capacitor having the determined capacitance is utilized. The capacitor is coupled to a first data line of a tracking cell of the tracking circuit. A first transition of the first data line causes a first transition of a second data line of the memory cell.

Abstract: A random access memory (RAM) cell provides a control section and a storage section coupled to the storage section. The storage section includes complementary metal-oxide semiconductor (CMOS) transistors and the storage section is read by precharging the control section to a virtual drain voltage.

Abstract: To provide a semiconductor memory device storing data, in which a transistor whose leakage current between a source/drain in off state is small is used as a writing transistor. In a matrix of a memory unit formed of two memory cells, in each of which a drain of a writing transistor is connected to a gate of a reading transistor and one electrode of a capacitor, a gate of the writing transistor, and the other electrode of the capacitor in a first memory cell are connected to a first word line, and a second word line, respectively. In a second memory cell, a gate of the writing transistor, and the other electrode of the capacitor are connected to the second word line, and the first word line, respectively. Further, to increase the degree of integration, gates of the reading transistors of memory cells are disposed in a staggered configuration.

Abstract: A dynamic random access memory cell is disclosed that comprises a capacitive storage device and a write access transistor. The write access transistor is operatively coupled to the capacitive storage device and has a gate stack that comprises a high-K dielectric, wherein the high-K dielectric has a dielectric constant greater than a dielectric constant of silicon dioxide. Also disclosed are a memory array using the cells, a computing apparatus using the memory array, a method of storing data, and a method of manufacturing.

Abstract: A memory device includes memory cells, each of the memory cells having corresponding bit and word lines connected thereto for accessing the memory cells, a word line circuit coupled with at least one word line, and a bit line circuit coupled with at least one bit line. The memory device further includes at least one control circuit coupled with the bit and word line circuits. The control circuit is operative to cause state information to be stored in the memory cells. At least one switching element selectively connects the memory cells, the bit and word line circuits, and the control circuit to at least one power supply as a function of at least one control signal. The control circuit generates the control signal for disconnecting at least portions of the word line and bit line circuits from the power supply while state information is retained in the memory cells.

Abstract: Systems and methods for operating a nanometer-scale cantilever beam with a gate electrode. An example system includes a drive circuit coupled to the gate electrode where a drive signal from the circuit may cause the beam to oscillate at or near the beam's resonance frequency. The drive signal includes an AC component, and may include a DC component as well. An alternative example system includes a nanometer-scale cantilever beam, where the beam oscillates to contact a plurality of drain regions.

Abstract: A dynamic random access memory cell is disclosed that comprises a capacitive storage device and a write access transistor. The write access transistor is operatively coupled to the capacitive storage device and has a gate stack that comprises a high-K dielectric, wherein the high-K dielectric has a dielectric constant greater than a dielectric constant of silicon dioxide. Also disclosed are a memory array using the cells, a computing apparatus using the memory array, a method of storing data, and a method of manufacturing.

Abstract: A capacitive crossbar array includes a first set of conductors and a second set of conductors which intersect to form crosspoints. A nonlinear capacitive device is interposed between a first conductor within the first set and a second conductor within the second set at a crosspoint. The nonlinear capacitive device is configured to store information which is accessible through said first conductor and said second conductor. A method for utilizing a capacitive crossbar array is also provided.

Abstract: A lookup table with low power consumption is provided. The lookup table includes a memory element including a transistor and a capacitor. A drain of the transistor is connected to one electrode of a capacitor and the input of an inverter, and a source is connected to a first wiring. The other electrode of the capacitor is connected to a second wiring. In such a memory element, the potential of the second wiring is complementary to the potential of the first wiring when writing data; accordingly, the potential of the drain of the transistor, i.e., the potential of the input of the inverter can be higher than the high potential of the inverter. Thus, shoot-through current of the inverter at this time can be significantly reduced. As a result, power consumption in a standby state can be significantly reduced.

Abstract: To provide a memory element which keeps a stored logic state even without supply of power. To increase an effect of reducing power consumption by facilitating stop of supply of power to the memory element for a short time. Data (potential) held in a node in a logic circuit can be swiftly saved on a node where one of a source and a drain of the transistor and one electrode of the capacitor included in a memory circuit are connected by lowering a potential of the other electrode of a capacitor before a transistor is turned on. By making a potential of the other electrode of the capacitor when the transistor is in an off state higher than a potential of the other electrode of the capacitor when the transistor is in an on state, a potential of the node can be reliably held even without supply of power.

Abstract: It is an object to provide a memory device for which a complex manufacturing process is not necessary and whose power consumption can be suppressed and a signal processing circuit including the memory device. In a memory element including a phase-inversion element by which the phase of an input signal is inverted and the signal is output such as an inverter or a clocked inverter, a capacitor which holds data and a switching element which controls storing and releasing of electric charge in the capacitor are provided. For the switching element, a transistor including an oxide semiconductor in a channel formation region is used. The memory element is applied to a memory device such as a register or a cache memory included in a signal processing circuit.

Abstract: A matrix is formed using a plurality of memory cells in each of which a drain of the writing transistor is connected to a gate of a reading transistor and one electrode of a capacitor. A gate of the writing transistor, a source of the writing transistor, a source of the reading transistor, and a drain of the reading transistor are connected to a writing word line, a writing bit line, a reading bit line, and a bias line, respectively. The other electrode of the capacitor is connected to a reading word line. In order to decrease the number of wirings, the writing bit line is substituted for the reading bit line. The reading bit line is formed so as to be embedded in a groove-like opening formed over a substrate.

Abstract: An integrated circuit includes: a resistive memory having an array of resistive memory cells; a memory controller that controls operation of the resistive memory in accordance with external commands from an external device; and a memory scheduler coupled to the resistive memory and to the memory controller. The memory scheduler schedules internal maintenance operations within the resistive memory in response to trigger conditions indicated by at least one sensor signal or external command. The operation of the memory scheduler and performance of the internal maintenance operations are transparent to the external device and, optionally, transparent to the memory controller.

Abstract: A driving method by which stored data can be retained even with no power supply and the number of writing operations is not limited is provided. The variation of a writing potential to a memory element is suppressed to improve the reliability according to a new driving method. According to the driving method of a semiconductor device, in writing data, the writing potential is increased step-by-step while verifying the reading current, and the result of the reading current is used for the writing current. That is, data writing is performed while verifying whether data writing is performed with an accurate potential. Accordingly, data writing can be performed with high reliability.

Abstract: A storage device in which held voltage is prevented from decreasing due to feedthrough in writing data to the storage device at high voltage is provided. The storage device includes a write circuit, a bit line, a word line, a transistor, and a capacitor. A gate of the transistor is electrically connected to the word line. One of a source and a drain of the transistor is electrically connected to the bit line. The other of the source and the drain of the transistor is electrically connected to one terminal of the capacitor. The other terminal of the capacitor is electrically connected to a ground. The write circuit includes an element holding write voltage and a circuit gradually decreasing voltage from the element holding write voltage. The write voltage is output from the write circuit to the word line.

Abstract: A semiconductor memory device includes: a plurality of mats; a plurality of sense amplifier regions disposed on a side of the plurality of mats; and a plurality of main bit lines overlapping with a plurality of secondary bit lines, respectively, in regions for the plurality of mats, wherein the plurality of main bit lines and the plurality of secondary bit lines are formed in regions for the plurality of mats and the plurality of sense amplifier regions.

Abstract: An object is to provide a semiconductor device with a novel structure in which stored data can be retained even when power is not supplied, and does not have a limitation on the number of times of writing operations. A semiconductor device includes a source-bit line, a first signal line, a second signal line, a word line, and a memory cell connected between the source-bit lines. The memory cell includes a first transistor, a second transistor, and a capacitor. The second transistor is formed including an oxide semiconductor material. A gate electrode of the first transistor, one of a source and drain electrodes, and one of electrodes of the capacitor are electrically connected to one another. The source-bit line and a source electrode of the first transistor are electrically connected to each other. Another source-bit line adjacent to the above source-bit line and a drain electrode of the first transistor are electrically connected to each other.

Abstract: An embedded memory system includes an array of random access memory (RAM) cells, on the same substrate as an array of logic transistors. Each RAM cell includes an access transistor and a capacitor structure. The capacitor structure is fabricated by forming a metal-insulator-metal capacitor in a dielectric layer. The embedded RAM system includes fewer metal layers in the memory region than in the logic region.

Abstract: A capacitor-less memory cell, memory device, system and process of forming the capacitor-less memory cell includes forming the memory cell in an active area of a substantially physically isolated portion of the bulk semiconductor substrate. A pass transistor is formed on the active area for coupling with a word line. The capacitor-less memory cell further includes a read/write enable transistor vertically configured along at least one vertical side of the active area and operable during a reading of a logic state with the logic state being stored as charge in a floating body area of the active area, causing different determinable threshold voltages for the pass transistor.

Abstract: An object is to provide a semiconductor device which includes a memory cell capable of holding accurate data even when the data is multilevel data. The semiconductor device includes a memory cell holding data in a node to which one of a source and a drain of a transistor whose channel region is formed from an oxide semiconductor. Note that the value of off-state current (leakage current) of the transistor is extremely small. Thus, after being set to have a predetermined value, the potential of the node can be kept constant or substantially constant by turning the transistor off. In this manner, accurate data can be stored in the memory cell.

Abstract: It is an object to provide a semiconductor device with a novel structure in which stored data can be held even when power is not supplied, and does not have a limitation on the number of writing operations. A semiconductor device includes a plurality of memory cells each including a transistor including a first semiconductor material, a transistor including a second semiconductor material that is different from the first semiconductor material, and a capacitor, and a potential switching circuit having a function of supplying a power supply potential to a source line in a writing period. Thus, power consumption of the semiconductor device can be sufficiently suppressed.

Abstract: A ferroelectric capacitor comprising a transistor layer superimposed on a semiconductor substrate, a ferroelectric capacitor layer provided superior to the transistor layer, a wiring layer provided superior to the ferroelectric capacitor layer, and a passivation film. Further, at least one layer of barrier film capable of inhibiting penetration of moisture and hydrogen into the underlayer is provided between the ferroelectric capacitor layer and the passivation film, and the passivation film is characterized by containing a novolac resin.

Abstract: A semiconductor memory device includes a memory cell array having plural memory cells that require a refresh operation when retaining data; a read/write control unit that performs read-access or write-access of memory cell address specified for the memory cell array based on instructions from the outside; a refresh control unit that performs hidden-refresh of memory cells without control from the outside; and a schedule control unit that makes the refresh control unit perform hidden-refresh after the read/write control unit read-accesses the memory cell array, and that also makes the refresh control unit perform hidden-refresh before the read/write access control unit performs write-access.