Abstract: SRAM cells and SRAM cell arrays are described. In one embodiment, an SRAM cell includes a first inverter and a second inverter cross-coupled with the first inverter to form a first data storage node and a complimentary second data storage node for latching a value. The SRAM cell further includes a first pass-gate transistor and a switch transistor. A first source/drain of the first pass-gate transistor is coupled to the first data storage node, and a second source/drain of the first pass-gate transistor is coupled to a first bit line. The first source/drain of the switch transistor is coupled to the gate of the first pass-gate transistor.

Abstract: In embodiments of the present invention improved capabilities are described for a Radio Frequency identification (RFID) tag that includes an OTP-based hardened memory system for the RFID tag.

Abstract: A mutltiport memory cell having improved density area is disclosed. The memory cell includes a data storing component, a first memory access component coupled to a first side of the data storing component, a second memory access component coupled to a second side of the data storing component, first and second bit lines coupled to the first memory access component, first and second bit lines coupled to the second memory access component, first and second write lines coupled to the first memory access component and first and second write lines coupled to the second memory access component. The multiport memory cell also includes a read/write assist transistor, coupled to load transistors of the data storing component, that during read operations is activated for the duration of the read operation and during write operations is activated to impress the desired voltage level before or after one or more memory access components activated as a part of the write operation are deactivated.

Abstract: A semiconductor device avoids the disturb problem and the collision between write and read operations in a DP-SRAM cell or a 2P-SRAM cell. The semiconductor device 1 includes a write word line WLA and a read word line WLB each coupled to memory cells 3. A read operation activates the read word line WLB corresponding to the selected memory cell 3. A write operation activates the write word line WLA corresponding to the selected memory cell 3. The selected write word line WLA is activated after activation of the selected read word line WLB in an operation cycle that performs both read and write operations.

Abstract: One embodiment provides, in a sense amplifier for an electronic memory array in which a selected memory cell drives a developing voltage differential according to a logic state of the memory cell, a method to store the logic state. The method includes poising source voltages of first and second transistors at levels offset, respectively, by threshold voltages of the first and second transistors. The method also includes applying the voltage differential between a gate of the first transistor and a gate of the second transistor, the first and second transistors configured to oppose each other in a cross-coupled inverter stage of the sense amplifier.

Abstract: A method for providing a SRAM cell having a dedicated read port separated from a write port includes providing a first and a second bit-line placed in parallel forming a complementary bit-line pair for the dedicated read port, and providing a third and a fourth bit-line placed in parallel forming a complementary bit-line pair for the write port. The method further includes providing a positive voltage supply line disposed between a first and a second ground line placed in parallel, providing a first and a second metal line adjacently flanking and in parallel to the first bit-line, and providing a third and a fourth metal line adjacently flanking and in parallel to the second bit-line to provide a new SRAM cell structure having a balanced read and write operation speed and an improved noise margin.

Abstract: A device includes a substrate and a dual port static random access memory cell. The substrate includes an N-well region, a first P-well region and a second P-well region. The first and second P-well regions are arranged on opposite sides of the N-well region and spaced apart along a width direction. The static random access memory cell includes first and second pull-up transistors that are provided in the N-well region, a first pair of pull-down transistors and a first pair of access transistors provided in the first P-well region, and a second pair of pull-down transistors and a second pair of access transistors provided in the second P-well region. Each of the first pair and the second pair of pull-down transistors includes a first pull-down transistor and a second pull-down transistor. Active regions of the first pull-down transistor and the second pull-down transistor are spaced apart along the width direction.

Abstract: Methods and systems to provide a multi-Vcc environment, such as to selectively boost an operating voltage of a logic block and/or provide a level-shifted control to the logic block. A multi-Vcc environment may be implemented to isolate a Vmin-limiting logic block from a single-Vcc environment, such as to reduce Vmin and/or improve energy efficiency in the single-Vcc environment. The logic block may include bit cells of a register file, a low-level processor cache, and/or other memory system. A cell Vcc may be boosted during a read mode and/or write wordlines (WWLs) and/or read wordlines (RWLs) may be asserted with boost. A wordline decoder may include a voltage level shifter with differential split-level logic, and a dynamic NAND, which may include NAND logic, a keeper circuit, and logic to delay a keeper control based on a delay of the level shifter to reduce contention during an initial NAND evaluation phase.

Abstract: A memory cell array includes a bit line, a complementary bit line, a first operation voltage supply circuit, a second operation voltage supply circuit, a first memory cell and a second memory cell. The first operation voltage supply circuit is electrically coupled to the bit line and the complementary bit line and used for supplying a first operation voltage. The second operation voltage supply circuit is electrically coupled to the bit line and the complementary bit line and used for supplying a second operation voltage. The first memory cell is electrically coupled to the bit line and the complementary bit line and used for receiving the first operation voltage. The second memory cell is electrically coupled to the bit line and the complementary bit line and used for receiving the second operation voltage. The first and second memory cells are located in a same column in the memory cell array.

Abstract: One or more embodiments of 8T NVSRAM cell are provided for improving NVSRAM memory architecture with reduced cell size as opposed to the prior art of 12T NVSRAM cell. This novel 8T NVSRAM cell uses one step Write operation under either a FN-channel write scheme to increase a paired flash transistor Vt values in positive direction with a desired ?Vt12 ?1V or a FN-edge write scheme to decrease the Vt values in negative direction with a similar desired ?Vt12?1V to write the ?Vt12 into the paired flash transistors within 1-10 ms without requiring a pre-erase step. There is no need of Program-Inhibit Voltage (SBPI) to inhibit non-select flash transistor from programming. In addition, this 8T NVSRAM cell uses DRAM-like charge-sensing scheme to detect the ?V on Q and QB nodes of SRAM in which is coupled and generated from the ?Vt12 stored in MC1 and MC2 flash transistors.

Abstract: A memory cell is provided. The memory cell comprises a write port and a read port. The write port comprises a pair of cross-coupled inverters and a plurality of metal lines. The first inverter comprises a first pull-up device and a first pull-down device. The second inverter comprises a second pull-up device and a second pull-down device. The metal lines comprise a Vcc conductor line, a first Vss conductor line, and a second Vss conductor line. The first pull-down device has a source terminal coupled to the first Vss line. The second pull-down device has a source terminal coupled to the second Vss line. The read port comprises a cascaded device, a read word line, read bit line and a third Vss conductor line. The cascaded device comprises a read pull-down device and a read pass device. The read pull-down device has a source terminal coupled to the third Vss conductor line. The read pass device has a drain terminal coupled to the read bit line.

Abstract: The present invention discloses a circuit for improving process robustness of sub-threshold SRAM memory cells, which serves as an auxiliary circuit for a sub-threshold SRAM memory cell. The output of the circuit is connected to the PMOS tube of the sub-threshold SRAM memory cell and the substrate of a PMOS tube in the circuit. The circuit comprises a detection circuit for threshold voltage of PMOS tube and a differential input and single-ended output amplifier. The circuit changes the substrate voltage of the PMOS tubes in the sub-threshold SRAM memory cell and the substrate voltage of the PMOS tube in the circuit in a self-adapting manner by detecting threshold voltage fluctuations of PMOS tubes and NMOS tubes resulted from process fluctuations and thereby regulate the threshold voltages of the PMOS tubes, so that the threshold voltage of PMOS tubes matches the threshold voltage of NMOS tubes.

Abstract: In a method, various operations are performed based on a voltage line coupled with a plurality of memory cells. Storage nodes of the plurality of memory cells are caused to change to a first logical value. Another first logical value is applied to a plurality of data lines. Each data line of the plurality of data lines carries data for each memory cell of the plurality of memory cells. A control line of the plurality of memory cells is activated. A first voltage value is applied to the voltage line. The first voltage value causes the another first logical value on the plurality of data lines to be transferred to the storage nodes of the plurality of memory cells.

Abstract: A multi-port memory cell is disclosed that includes first and second cross-coupled inverter circuits. The input node of each inverter circuit is coupled to the output node of the other inverter circuit to receive the inverted output of the other inverter circuit. The multi-port memory cell includes a first pair of access transistors of a first type, each coupled to the input node of a respective one of the first and second inverter circuits. The multi-port memory cell also includes a second pair of access transistors of the second type, each coupled to the input of a respective one of the first and second inverter circuits. The multi-port cell exhibits advantages in layout compactness and SEU tolerance.

Abstract: In one embodiment, an integrated circuit includes at least one logic circuit supplied by a first supply voltage and at least one memory circuit coupled to the logic circuit and supplied by a second supply voltage. The memory circuit is configured to be read and written responsive to the logic circuit even if the first supply voltage is less than the second supply voltage during use. In another embodiment, a method includes a logic circuit reading a memory cell, the logic circuit supplied by a first supply voltage; and the memory cell responding to the read using signals that are referenced to the first supply voltage, wherein the memory cell is supplied with a second supply voltage that is greater than the first supply voltage during use.

Abstract: Methods and apparatus for providing single finFET and multiple finFET SRAM arrays on a single integrated circuit are provided. A first single port SRAM array of a plurality of first bit cells is described, each first bit cell having a y pitch Y1 and an X pitch X1, the ratio of X1 to Y1 being greater than or equal to 2, each bit cell further having single fin finFET transistors to form a 6T SRAM cell and a first voltage control circuit; and a second single port SRAM array of a plurality of second bit cells, each second bit cell having a y pitch Y2 and an X pitch X2, the ratio of X2 to Y2 being greater than or equal to 3, each of the plurality of second bit cells comprising a 6T SRAM cell wherein the ratio of X2 to X1 is greater than about 1.1.

Abstract: A semiconductor storage device includes a memory cell array, a plurality of word lines, a plurality of bit lines, a first gate wiring element 3a, 3b, a second gate wiring element 3c, 3d, a first connector 5a, 5b, and a second connector 5c, 5d. Each memory cell 10 has first and second sets having a driver transistor 11, a load transistor 12, and an access transistor 13. The word lines are arranged in parallel to each other along a first direction. The bit lines are arranged in parallel to each other along a second direction perpendicular to the first direction. The first gate wiring element comprises a gate electrode of the first driver transistor and the first load transistor, and has a rectangular shape having straight line on opposite sides. The second gate wiring element comprises a gate electrode of the access transistor and has a rectangular shape having straight line on opposite sides.

Abstract: A static random access memory structure is provided. The static random access memory structure includes a storage region having a first storage node and a second storage node which is complementary to the first storage node. The static random access memory structure also includes a reading region having a first reading transfer gate and a second reading transfer gate, and a reading word line electrically connecting with the gate of the first reading transfer gate and the gate of the second reading transfer gate. Further, the static random access memory structure includes a writing region independent of the reading region having a first writing transfer gate and a second writing transfer gate and a writing word line electrically connecting with the gate of the first writing transfer gate and the gate of the second transfer gate.

Abstract: Disclosed are devices, systems and/or methods relating to an eight transistor (8T) static random access memory (SRAM) cell, according to one or more embodiments. In one embodiment, an SRAM storage cell is disclosed comprising a word line, a write column select line, a cross-coupled data latch, and a first NMOS switch device serially coupled to a second NMOS switch device. In this embodiment, the gate node of the first NMOS switch device is coupled to the word line, a source node of the first NMOS switch device is coupled to the cross-coupled data latch, a gate node of the second NMOS switch device is coupled to the write column select line, and a source node of the second NMOS switch device is coupled to the cross-coupled data latch.

Abstract: An antifuse according to an embodiment of the invention herein can include a depletion mode metal oxide semiconductor field effect transistor (“MOSFET”) having a conduction channel and a metal gate overlying the conduction channel. A cathode and an anode of the antifuse can be electrically coupled to the gate and spaced apart from one another in a direction the gate extends, such that the antifuse is programmable by driving a programming current between the cathode and the anode to cause material of the metal gate to migrate away. The gate may be configured such that, under appropriate biasing conditions, when the antifuse is unprogrammed, the conduction channel is turned on unless a voltage above a first threshold voltage is applied to the gate to turn off the conduction channel. The gate can be configured such that when the antifuse has been programmed, the conduction channel remains turned on even if a voltage above the first threshold voltage is applied between the gate and a source region of the MOSFET.

Abstract: A memory device includes sections arranged between a global bit line and a complementary global bit line, and having a section control unit disposed between first and second memory cell groups and connected between the global bit line and the complementary global bit line to provide a first read signal and a second read signal. A signal converter receives the first and second read signals and generates a stable controlled read signal indicative of a data value stored in the memory cell. A latch unit receives and latches the controlled read signal provided by the signal converter to generate a latched read signal.

Abstract: In an embodiment of the invention, a flip-flop circuit contains a 2-input multiplexer, a master latch, a transfer gate and a slave latch. The scan enable control signals SE and SEN of the multiplexer determine whether data or scan data is input to the master latch. Clock signals CKT and CLKZ and retention control signals RET and RETN determine when the master latch is latched. The slave latch is configured to receive the output of the master latch, a second data bit D2, the clock signals CKT and CLN, the retain control signals RET and RETN, the slave control signals SS and SSN. The signals CKT, CLKZ, RET, RETN, SS, SSN and PREN determine whether the output of the master latch or the second data bit D2 is latched in the slave latch. Control signals RET and RETN determine when data is stored in the slave latch during retention mode.

Abstract: A semiconductor device avoids the disturb problem and the collision between write and read operations in a DP-SRAM cell or a 2P-SRAM cell. The semiconductor device 1 includes a write word line WLA and a read word line WLB each coupled to memory cells 3. A read operation activates the read word line WLB corresponding to the selected memory cell 3. A write operation activates the write word line WLA corresponding to the selected memory cell 3. The selected write word line WLA is activated after activation of the selected read word line WLB in an operation cycle that performs both read and write operations.

Abstract: In embodiments of the invention, a memory circuit includes a static random access memory (SRAM), rows of M sense amplifiers, a global read precharge tracking control circuit controlling a precharge of global read lines, a sense amplifier output tracking circuit generating a reset sense amplifier signal for the sense amplifier control circuits, and a read delay circuit generating a trigger signal for the global read precharge tracking control circuit and the sense amplifier output tracking circuit and performing a fixed delay tracking of a read operation in a read cycle. A dummy global read line is coupled to the global read precharge tracking control circuit and returns from a half way to the top of the SRAM forming a tracking dummy global read line that determines a completion of the precharge of the global read lines before the sense amplifiers start discharging the global read lines in the read cycle.

Abstract: A system on chip includes an SRAM. The SRAM includes at least one memory cell and a peripheral circuit accessing the at least memory cell. A first power circuit is configured to supply a first driving voltage to the at least one memory cell. A second power circuit is configured to supply a second driving voltage to the peripheral circuit. The SRAM further includes an auto power switch that selects the higher of the first driving voltage and the second driving voltage and supplies the selected voltage to the at least one memory cell.

Abstract: A device and a method for controlling an SRAM-type device, including: a bistable circuit and two switching circuits respectively connecting two access terminals of the bistable circuit to two complementary bit lines in a first direction, each switching circuit including a first switch and a second switch in series between one of the bit lines and one of the access terminals, the control terminal of the second switch being connected to a word control line in the first direction; and a third switch between the midpoint of the series connection and a terminal of application of a reference potential, a control terminal of the third switch being connected to the other one of the access terminals.

Abstract: A semiconductor device includes plural memory cells each having a first inverter and a second inverter, with an input of the first inverter being coupled to an output of the second inverter and an input of the second inverter being coupled to an output of the first inverter. The first and second inverters have drive transistors supplied with a source voltage where the source voltage is raised in response to a level shift of a control signal supplied to a switch of a control circuit. The control circuit further includes a resistance element in parallel with a MOS transistor connected as a diode.

Abstract: A storage cell is provided with improved robustness to soft errors. The storage cell comprises complementary core storage nodes and complementary outer storage nodes. The outer storage nodes act to limit feedback between the core storage nodes and are capable of restoring the logical state of the core storage nodes in the event of a soft error. Similarly the core storage nodes act to limit feedback between the outer storage nodes with the same effect. This cell has advantages compared with other robust storage cells in that there are only two paths between the supply voltage and ground which limits the leakage power. An SRAM cell utilizing the proposed storage cell can be realized with two access transistors configured to selectively couple complementary storage nodes to a corresponding bitline. A flip-flop can be realized with a variety of transfer gates which selectively couple data into the proposed storage cell.

Abstract: Disclosed are apparatus and devices for programming and operating a programmable memory array portion coupled with a leakage reduction circuit. At the leakage reduction circuit, a frame bias signal that indicates a majority state of the memory array portion can be received. During idle states of the programmable memory array portion, at least one shared bit line of the memory array portion can be selectively biased based on the received frame bias signal. In one aspect, a first one of two bit lines is biased to a first state, while the second one of the two bits lines is biased to a second state that is opposite the first state. In a further aspect, the first state is a same state as the majority state of the memory array portion.

Abstract: A device can include a plurality of memory cells, each memory cell including at least one latch circuit coupled between two data nodes, a first nonvolatile section coupled to a first data node, and a second nonvolatile section coupled to a second data node; and each nonvolatile section including at least one switch element in series with a programmable nonvolatile element, the switch element configured to couple the nonvolatile element to the corresponding data node during a high reliability read operation of the memory cell.

Abstract: A semiconductor integrated circuit which can respond to changes of the amount of retained data at the time of standby is provided. The semiconductor integrated circuit comprises a logic circuit (logic) and plural SRAM modules. The plural SRAM modules perform power control independently of the logic circuit, and an independent power control is performed among the plural SRAM modules. Specifically, one terminal and the other terminal of a potential control circuit of each SRAM module are coupled to a cell array and a local power line, respectively. The local power line of one SRAM module and the local power line of the other SRAM module share a shared local power line. A power switch of one SRAM module and a power switch of the other SRAM module are coupled in common to the shared local power line.

Abstract: Embodiments disclosed include memory bitcell clusters employing localized generation of complementary bitlines to reduce memory area. The memory bitcell clusters disclosed may be static random access memory (SRAM) used as central processing unit (CPU) register files. The memory bitcell clusters disclosed include a plurality of memory bitcells that share a common bitline. To reduce area required to provide complementary bitlines for the memory bitcells, the memory bitcell clusters include a localized inverter circuit. The localized inverter circuit is configured to invert a common bitline localized to the memory bitcells to provide a complementary bitline for the memory bitcells in the memory bitcell cluster. Because the inverter circuit is localized to the memory bitcells, a track in a semiconductor die for the complementary bitline does not extend beyond the memory bitcell cluster, minimizing the complexity of the memory bitcell cluster by reducing a number of bitline tracks used by half.

Abstract: Disclosed are a memory system and an associated operating method. In the system, a first memory array comprises first memory cells requiring a range of time delays between wordline activating and bitline sensing. A delay signal generator delays an input signal by a selected time delay (i.e., a long time delay corresponding to statistically slow memory cells) and outputs a delay signal for read operation timing to ensure read functionality for statistically slow and faster memory cells. To accomplish this, the delay signal generator comprises a second memory array having second memory cells with the same design as the first memory cells. Transistors within the second memory cells are controlled by a lower gate voltage than transistors within the first memory cells in order to mimic the effect of higher threshold voltages, which result in longer time delays and which can be associated with the statistically slow first memory cells.

Abstract: A sense amplifier includes a first inverter including a first input node and a first output node, the first input node coupled to a first bitline through a first capacitor, the first output node coupled to a second bitline through a second capacitor, a second inverter including a second input node and a second output node, the second input node coupled to the second bitline through the second capacitor, the second output node to the first bitline through the first capacitor, a first transmission gate switch coupled between the first input node and the second input node, a second transmission gate switch coupled between a first common node of the first and second inverters and a second common node of the first and second inverters. The sense amplifier is maintained at a maximum gain point in a read cycle.

Abstract: A domino static random access memory (SRAM) having one or more SRAM memory cells connected with a local bit line is disclosed. The SRAM may include a global bit line, a first precharge device connected between a voltage supply and the local bit line, and a second precharge device connected between the voltage supply and the global bit line. In addition the SRAM may include a global bit line discharge logic connected with the global bit line and the local bit line. The global bit line discharge logic is adapted to draw the global bit line to a voltage below a precharge voltage and above a ground voltage during a read operation.

Abstract: A circuit is in a memory macro and comprises a write path, a read path, a selection circuit, and a clock generator circuit. The write path includes a first signal generated based on a first edge of a clock signal in a write operation of the memory macro. The read path includes a second signal generated based on a first edge of the clock signal in a read operation of the memory macro. The selection circuit is configured to select the first signal as a third signal in the write operation of the memory macro, and to select the second signal as the third signal in the read operation of the memory macro. The clock generator circuit is configured to generate a second edge of the clock signal in the write operation or in the read operation based on the third signal.

Abstract: A circuit comprises a first data line, a second data line, a charging circuit, a first circuit, a second circuit, a first switching circuit, and a second switching circuit. The charging circuit and the first circuit are each coupled with the first data and the second data line. The first switching circuit is coupled between the first data line and a first node of the second circuit. The second switching circuit is coupled between the second data line and a second node of the second circuit. The data on the first node or the second node represents data in a single-ended circuit. Data on both the first node and the second node represent data in a differential circuit.

Abstract: A static memory and a static memory cell are provided. The static memory cell includes a first transistor, a second transistor, a third transistor, a fourth transistor, a fifth transistor, a sixth transistor, a first switch, a second switch, a third switch, a first pull-down switch, and a second pull-down switch. When a data writing operation is performed, the latching capability of the latch circuit constituted by the first to the sixth transistors is disabled by turning off the second transistor or the fifth transistor, so that the speed of the data writing operation is increased and the data writing performance is improved. The first switch and the second switch provide a path for reading or writing data, and the third switch is coupled to a bit line for receiving data from or transmitting data to the bit line.

Abstract: SRAM cells and SRAM cell arrays are described. In one embodiment, an SRAM cell includes a first inverter and a second inverter cross-coupled with the first inverter to form a first data storage node and a complimentary second data storage node for latching a value. The SRAM cell further includes a first pass-gate transistor and a switch transistor. A first source/drain of the first pass-gate transistor is coupled to the first data storage node, and a second source/drain of the first pass-gate transistor is coupled to a first bit line. The first source/drain of the switch transistor is coupled to the gate of the first pass-gate transistor.

Abstract: A Static Random Access Memory (SRAM) cell includes a first long boundary and a second long boundary parallel to a first direction, and a first short boundary and a second short boundary parallel to a second direction perpendicular to the first direction. The first and the second long boundaries are longer than, and form a rectangle with, the first and the second short boundaries. A CVss line carrying a VSS power supply voltage crosses the first long boundary and the second long boundary. The CVss line is parallel to the second direction. A bit-line and a bit-line bar are on opposite sides of the CVss line. The bit-line and the bit-line bar are configured to carry complementary bit-line signals.

Abstract: A register file employing a shared supply structure to improve the minimum supply voltage.

Abstract: A static RAM includes: a plurality of word lines; a plurality of pairs of local bit lines; a plurality of memory cells arranged in correspondence with intersections of the plurality of pairs of local bit lines and the plurality of word lines; a capacitance shared circuit arranged for each of the plurality of pairs of local bit lines; a common connection line connecting the plurality of capacitance shared circuits; and a pair of global bit lines connected to the plurality of pairs of local bit lines, wherein the capacitance shared circuit includes two N-channel transistors connected between the pair of local bit lines and the common connection line corresponding to each other.

Abstract: A memory circuit includes a controlled current source coupled to an input to a nonvolatile cell, and a second controlled current source coupled to a volatile cell, the volatile cell coupled to receive current from the controlled current source via the nonvolatile cell.

Abstract: An IC that includes a memory cell and a pass gate coupled to the memory cell, where the pass gate includes a PMOS transistor, is described. In one implementation, the PMOS transistor has a negative threshold voltage. In one implementation, the memory cell includes thick oxide transistors.

Abstract: A sectioned bit line of an SRAM memory device, an SRAM memory device having a sectioned bit line, and associated systems and methods are described, including embodiments having sectioned bit lines with hierarchical aspects. In one illustrative implementation, each sectioned bit line may comprise a local bit line, a memory cell connected to the local bit line, and a pass gate coupled to the local bit line, wherein the pass gate is configured to be coupled to a global bit line. Further, in some embodiments, the sectioned bit lines are arranged in hierarchical arrays. In other implementations, SRAM memory devices may be configured involving sectioned bit lines (including hierarchical) and a global bit line wherein the pass gates are configured to connect and isolate the sectioned bit line and the global bit line.

Abstract: A memory bit cell includes a latch, a write port coupled to the latch, and a read port coupled to the latch. The write port includes a first set of devices having a first threshold voltage and a second set of devices having a second threshold voltage that is greater than the first threshold voltage. The read port includes a third set of devices having a third threshold voltage that is less than the first threshold voltage.

Abstract: Memory elements are provided that exhibit immunity to soft error upset events when subjected to radiation strikes such as high-energy atomic particle strikes. Each memory element may each have four inverter-like transistor pairs that form a bistable element, a pair of address transistors, and a pair of relatively weak transistors connected between two of the inverters that create a common output node which is resistant to rapid changes to its state. The transistors may be connected in a pattern that forms a bistable memory element that is resistant to soft error upset events due to radiation strikes. Data may be loaded into and read out of the memory element using the address transistor pair.

Abstract: The gate tunnel leakage current is increased in the up-to-date process, so that it is necessary to reduce the gate tunnel leakage current in the LSI which is driven by a battery for use in a cellular phone and which needs to be in a standby mode at a low leakage current. In a semiconductor integrated circuit device, the ground source electrode lines of logic and memory circuits are kept at a ground potential in an active mode, and are kept at a voltage higher than the ground potential in an unselected standby mode. The gate tunnel leakage current can be reduced without destroying data.

Abstract: A bit line driver for a static random access memory (SRAM) cell including: a first voltage supply for supplying a first voltage; a second voltage supply for supplying a second voltage that is less than the first voltage; a write circuit to drive a bit line and an inverse bit line when writing to the SRAM cell; and a pre-charge circuit to pre-charge the bit line and the inverse bit line before reading the content of the SRAM cell. The bit line driver supplies a voltage less than the first voltage by a threshold voltage of one transistor to the bit line or the inverse bit line when the bit line driver drives the bit line or the inverse bit line to a high state.

Abstract: In described embodiments, a memory circuit includes a static random access memory (SRAM) including N banks of memory cells, rows of M sense amplifiers, a controlled feedback latch storing a previous state of input data in a read cycle, a pull down select block coupled to the controlled feedback latch and the dummy sense amplifier, a dummy output latch coupled to the pull-down select block to store the read data, and a SRAM reset generation circuit coupled to the sense amplifier control circuits and the controlled feedback latch. The dummy output latch is a latch that is the same as a sense amplifier latch used in the local input/output circuit, thereby, no margin is involved between a reset of the sense amplifiers and the read data latched at the dummy output latch in the read cycle.