Abstract: A memory system is provided forming a switch element having a first side and a second side, forming a cell transistor having a gate terminal, forming a memory cell, having the switch element and the cell transistor, with the gate terminal connected to the second side, connecting a word line and the memory cell at the first side, connecting a bit line and the memory cell, and connecting a reference source and the memory cell.

Abstract: A semiconductor memory cell, semiconductor memory devices comprising a plurality of the semiconductor memory cells, and methods of using the semiconductor memory cell and devices are described. A semiconductor memory cell includes a substrate having a first conductivity type; a first region embedded in the substrate at a first location of the substrate and having a second conductivity type; a second region embedded in the substrate at a second location of the substrate and have the second conductivity type, such that at least a portion of the substrate having the first conductivity type is located between the first and second locations and functions as a floating body to store data in volatile memory; a trapping layer positioned in between the first and second locations and above a surface of the substrate; the trapping layer comprising first and second storage locations being configured to store data as nonvolatile memory independently of one another; and a control gate positioned above the trapping layer.

Abstract: According to an embodiment, a nonvolatile semiconductor memory system includes: a nonvolatile semiconductor memory; and a memory controller having: a memory interface unit that inputs commands to the nonvolatile semiconductor memory and inputs or outputs data between the nonvolatile semiconductor memory; a memory that stores writing information indicating a memory cell transistor that is written the latest in each of the NAND cell units; and a processor that sets a read voltage based on the writing information to read out data from the memory cell transistors connected to a first word line; wherein a row controller is configured to set a plurality of levels of the read voltage to be applied to the first word line, with respect to one threshold for discriminating data stored in a memory cell transistors.

Abstract: The invention is directed to decreasing a circuit size of a system in which a plurality of devices or circuit blocks share and use one memory. A system is configured so that a memory block serves as a master and each of circuit blocks serves as a slave, and thus the slave side (the circuit blocks) receives necessary data from the memory block by only having decoders corresponding to addresses assigned thereto in advance and registers. In this case, since the registers have been also needed in a conventional system in order to hold data read out from a memory, the circuit size decreases in the whole system. Since this effect is enhanced in proportion to the number of the circuit blocks sharing the memory block, the effect is enhanced as the system size increases.

Abstract: Embodiments provide systems, methods, and apparatuses with a plurality of row lines and column lines arranged in a matrix, and at least one memory cell having an access transistor and a CMOS-compatible non-volatile storage element coupled to the access transistor in series. The CMOS-compatible non-volatile storage element includes a node and is configured to hold a charge corresponding to a n-bit binary value where n is an integer greater than 1. The access transistor has a word line gate coupled to a row line, a first node coupled to a column line, a second node coupled to a storage node, with the storage node connected to said node of the CMOS-compatible non-volatile storage element. Access circuitry coupled to the memory cell is configured to activate the memory cell and sense a resulting current corresponding to the n-bit binary value.

Abstract: A semiconductor memory device comprises a memory cell array and a forming controller. The memory cell array includes a plurality of first memory cells each having a structure in which dielectric material is sandwiched between two electrodes, and the memory cell array is divided into a plurality of areas capable of being designated. The forming controller controls to perform “forming” for the first memory cells in an area selectively designated from the plurality of areas of the memory cell array, and as a result of the forming, the first memory cells are changed to non-volatile second memory cells.

Abstract: A memory comprises a number of word lines in a first direction, a number of bit lines in a second direction, each coupled to at least one of the word lines, and a number of memory elements, each coupled to one of the word lines and one of the bit lines. Each memory element comprises a top electrode for connecting to a corresponding word line, a bottom electrode for connecting to a corresponding bit line, a resistive layer on the bottom electrode, and at least two separate liners, each liner having resistive materials on both ends of the liner and each liner coupled between the top electrode and the resistive layer.

Abstract: A non-volatile memory cell includes a volatile storage device that stores a corresponding logic state in response to electrical stimulus; and a shadow memory device coupled to the volatile storage device. The shadow memory device receives and stores the corresponding logic state in response to electrical stimulus. The shadow memory device includes a non-volatile nanotube switch that stores the corresponding state of the shadow device.

Abstract: An apparatus and method of an electrically programmable and erasable non-volatile memory cell with a deep N-well to isolate the memory cell from the substrate is disclosed. In one embodiment, a non-volatile memory apparatus includes at least one non-volatile memory cell fabricated on a P substrate, with a deep N-well located in the P substrate, while a P-well and an N-well are located in the deep N-well. The memory cell further includes a PMOS transistor located in the N-well, in which the PMOS transistor includes a PMOS gate-oxide, and an NMOS capacitor located in the P-well. The NMOS capacitor includes an N+ coupling region located in the P-well, and an NMOS gate-oxide. The memory cell further includes a floating gate comprised of a poly-silicon gate overlying the PMOS transistor and the NMOS capacitor.

Abstract: An object of this invention is to provide a rewritable nonvolatile memory cell that can have a wide reading margin, and can control both a word line and a bit line by changing the level of Vcc. As a solution, a flip-flop is formed by cross (loop) connect of inverters including memory transistors that can control a threshold voltage by charge injection into the side spacer of the transistors. In the case of writing data to one memory transistor, a high voltage is supplied to a source of the memory transistor through a source line and a high voltage is supplied to a gate of the memory transistor through a load transistor of the other side inverter. In the case of erasing the written data, a high voltage is supplied to the source of the memory transistor through the source line.

Abstract: A memory system and methods of its operation are presented. The memory system includes a volatile buffer memory and a non-volatile memory circuit, where the non-volatile memory circuit has a first section, where data is stored in a binary format, and a second section, where data is stored in a multi-state format. When writing data to the non-volatile memory, the data is received from a host, stored in the buffer memory, transferred from the buffer memory to into read/write registers of the non-volatile memory circuit, and then written from the read/write registers to the first section of the non-volatile memory circuit using a binary write operation.

Abstract: A semiconductor device having an electrically erasable and programmable nonvolatile memory, for example, a rewritable nonvolatile memory including memory cells arranged in rows and columns and disposed to facilitate both flash erasure as well as selective erasure of individual units of plural memory cells. The semiconductor device which functions as a microcomputer chip also has a processing unit and includes an input terminal for receiving an operation mode signal for switching the microcomputer between a first operation mode in which the flash memory is rewritten under control of a processing unit and a second operation mode in which the flash memory is rewritten under control of separate writing circuit externally connectable to the microcomputer.

Abstract: An electrically erasable programmable read-only memory (EEPROM) with a ripple programming mode. Memory cells in an the EEPROM array include floating-gate transistors with control gates coupled to corresponding word lines, and drain electrodes coupled to corresponding bit lines. A memory cell is programmed by applying a high programming voltage to its control gate along with applying a high programming voltage to its drain. Multiple memory cells within a row can be programmed by applying the programming voltage to the word line of that row, during which multiple bit lines receive their programming voltage, without removing the word line programming voltage when changing the programming from one bit line to another.

Abstract: A non-volatile memory device having a hidden cell located separate from data storage cells, and a method of effectively managing an erase count of the non-volatile memory device. The method includes preparing the non-volatile memory device that includes a hidden cell located separate from data storage cells and is not accessible to users of the data storage cells, and increasing an erase count stored in an erase count storing region of the hidden cell corresponding to at least one erased data storage cell when the at least one data storage cell is erased.

Abstract: A nonvolatile static random access memory (SRAM) device includes a pair of cross-coupled, complementary metal oxide semiconductor (CMOS) inverters configured as a storage cell for a bit of data and a pair of magnetic spin transfer devices coupled to opposing sides of the storage cell. The magnetic spin transfer devices are configured to retain the storage cell data therein following removal of power to the SRAM device, and are further configured to initialize the storage cell with the retained data upon application of power to the SRAM device.

Abstract: A flash memory array comprises a plurality of memory cells organized in a matrix of rows and columns. Each of the memory cells includes a floating gate memory transistor having a source region and a drain region, and a coupling capacitor electrically connected to the memory transistor. A plurality of word lines are each electrically connected to the capacitor in each of the memory cells in a respective row. A first set of bit lines are each electrically connected to the drain region of the memory transistor in each of the memory cells in a respective column. A plurality of high voltage access transistors are each electrically connected to a bit line in the first set of bit lines. A second set of bit lines are each electrically connected to the source region of the memory transistor in each of the memory cells in a respective column.

Abstract: Systems, methods, and memory device with row lines and column lines arranged in a matrix configuration with a memory cell coupled to one of the column lines and one of the row lines. The memory cell includes a storage capacitor with a first plate coupled to a storage node, a CMOS-compatible non-volatile storage element having a node coupled to the storage node and configured to hold a charge corresponding to a binary value, and an access transistor coupled to the storage node. The access transistor includes a word line gate, a first node, and a second node, the word line gate being coupled to the one of the plurality of row lines, the first node being coupled to the one of the plurality of column lines, the second node being coupled to the storage node and to said node of the CMOS-compatible non-volatile storage element.

Abstract: There is provided a technology which can allow a semiconductor chip formed with a nonvolatile memory to be sufficiently reduced in size. There is also provided a technology which can ensure the reliability of the nonvolatile memory. In a memory cell of the present invention, a boost gate electrode is formed over a control gate electrode via an insulating film. The boost gate electrode has the function of boosting a voltage applied to a memory gate electrode through capacitive coupling between the boost gate electrode and the memory gate electrode. That is, during a write operation or an erase operation to the memory cell, a high voltage is applied to the memory gate electrode and, to apply the high voltage to the memory gate electrode, the capacitive coupling using the boost gate electrode is subsidiarily used in the present invention.

Abstract: A memory system includes a memory and a memory controller operating to control the memory. The memory includes a random accessible memory including a memory cell array operable in a random access mode, a NAND flash memory, and a selection circuit making the memory controller operate either one of the random accessible memory or the NAND flash memory.

Abstract: Provided are a non-volatile memory device and a method of fabricating the same. The non-volatile memory device comprises: a control gate region formed by doping a semiconductor substrate with second impurities; an electron injection region formed by doping the semiconductor substrate with first impurities, where a top surface of the electron injection region includes a tip portion at an edge; a floating gate electrode covering at least a portion of the control gate region and the tip portion of the electron injection region; a first tunnel oxide layer interposed between the floating gate electrode and the control gate region; a second tunnel oxide layer interposed between the floating gate electrode and the electron injection region; a trench surrounding the electron injection region in the semiconductor substrate; and a device isolation layer pattern filled in the trench.

Abstract: A flash disk controller includes an input operable to receive analog signals from a flash memory die. The flash memory die includes multiple flash memory cells. The analog signals represent data values stored in the flash memory cells. An analog-to-digital conversion module is coupled to the input to convert received analog signals into digital data. A control module selects memory cells from which the input receives analog signals.

Abstract: A flash memory system includes a path selector to determine to write to a non-volatile memory, a volatile memory or both the non-volatile memory and the volatile memory when the flash memory system is to write data. A record is stored in the non-volatile memory which is updated the status of the non-volatile memory after each one or more writing operations. When the flash memory system is powered on after a power loss, it could be recovered to a command executed prior to the power loss or to any checkpoint prior to the power loss by using the record.

Abstract: A sense amplifier may be used to measure voltages and/or currents that represent logic levels stored in memory cells of memory devices. Accuracy and stability of such measurements may be improved by selective switching to isolate sense amplifiers from other portions of a circuit.

Abstract: A memory array is provided that includes a transistor having two active gates sharing a source, a drain, and a channel of the transistor. One of the active gates may be coupled to a volatile memory portion of a memory cell, such as a DRAM cell, and the other active gate may be coupled to a non-volatile memory portion, for example, a charge storage node such as a SONOS cell. Methods of operating the memory array are provided that include transferring data from the volatile memory portions to the non-volatile memory portions, transferring data from the non-volatile memory portions to the volatile memory portions, and erasing the non-volatile memory portions of a row of memory cells.

Abstract: Semiconductor memory having both volatile and non-volatile modes and methods of operation.

Abstract: A non-volatile static random access memory (NVSRAM) device includes a volatile circuit and a non-volatile circuit. Under normal operations when an external power is supplied, the volatile circuit can provide fast data access. When the power supply is somehow interrupted, the non-volatile circuit can provide data backup using an inverter circuit and a non-volatile erasable programmable memory (NVEPM) circuit, thereby retaining data previously stored in the volatile circuit.

Abstract: A semiconductor device includes: a first sector (12) having data that are all to be erased and having flash memory cells; a second sector (14) having data that are all to be retained and having flash memory cells; a sector select circuit (16) selecting a pair of sectors from among sectors during erasing the data in the first sector, said pair of sectors being the first sector and the second sector; and an SRAM array (storage) (30) retaining the data of the second sector. The present invention can provide a semiconductor device in which a reduced number of sector select circuits is used so that the area of memory cell array can be reduced and provide a method of controlling the semiconductor device.

Abstract: Systems, methods, and memory device with row lines and column lines arranged in a matrix configuration with a memory cell coupled to one of the column lines and one of the row lines. The memory cell includes a storage capacitor with a first plate coupled to a storage node, a CMOS-compatible non-volatile storage element having a node coupled to the storage node and configured to hold a charge corresponding to a binary value, and an access transistor coupled to the storage node. The access transistor includes a word line gate, a first node, and a second node, the word line gate being coupled to the one of the plurality of row lines, the first node being coupled to the one of the plurality of column lines, the second node being coupled to the storage node and to said node of the CMOS-compatible non-volatile storage element.

Abstract: A programmable non-volatile device is operated with a floating gate that functions as a FET gate that overlaps a portion of a source/drain region and allows for variable coupling through geometry and/or biasing conditions. This allows a programming voltage for the device to be imparted to the floating gate through variable capacitive coupling, thus changing the state of the device. Multi-state embodiments are also possible. The invention can be used in environments such as data encryption, reference trimming, manufacturing ID, security ID, and many other applications.

Abstract: Multi-bit flash memory devices are provided. The multi-bit flash memory device includes an array of memory cells and a page buffer block including page buffers. Each of the page buffers has a single latch structure and performs a write operation with respect to memory cells according to loaded data. A buffer random access memory (RAM) is configured to store program data provided from an external host device during a multi-bit program operation. Control logic is provided that is configured to control the page buffer block and the buffer RAM so that program data stored in the buffer RAM is reloaded into the page buffer block whenever data programmed before the multi-bit program operation is compared with data to be currently programmed. The control logic is configured to store data to be programmed next in the buffer RAM before the multi-bit program operation is completed.

Abstract: According to one embodiment, a semiconductor memory device includes a first memory, a second memory and a control circuit. The first memory includes a first bank number. The second memory includes a second bank number larger than the first bank number. The control circuit controls a precharge operation with respect to bit lines provided in the first and second memories. When performing, with respect to the first memory, a synchronous operation that is effected in synchronization with a clock, the control circuit changes over a second precharge operation to an operation time different from a first precharge operation during a period from the end of the initial first precharge operation to the start of the subsequent second precharge operation after receiving an address.

Abstract: A low voltage sensing scheme reduces active power down standby leakage current in a memory device. During memory's active power down state, the leak current may increase because of the use of P and Nsense amplifiers having low threshold voltages (Vth) for low Vcc sensing of data signals. A clamping device or diode is used between a Psense amplifier control line (e.g. ACT) and Vcc and/or between an Nsense amplifier control line (e.g. RNL*) and Vss (ground potential). The clamping diode is not enabled during normal memory operations, but is turned on during active power down mode to reduce leakage current through ACT and/or RNL* nodes. The clamping device connected to the ACT node may reduce the voltage on the ACT line during power down mode, whereas the clamping device connected to the RNL* node may increase the voltage on the RNL* line during power down mode to reduce sense amplifier leakage current through these nodes.

Abstract: A method of operating a non-volatile memory can include backing-up first data successfully programmed to a first target page of a non-volatile memory to provide local back-up data. A determination can be made that programming of second data to the first target page has failed and the local back-up data can be programmed to a second target page in a second block of the non-volatile memory.

Abstract: An integrated circuit includes a plurality of tiles. One tile is a master tile. Other tiles contain writable registers of memory structures. Information for configuring circuitry of the tile is stored in the register in the tile. An individual one of the registers can be written via the master tile. Each memory structure of a register includes a non-volatile floating gate cell (that stores the configuration information) as well as a volatile cell. All transistors have the same gate insulator thickness. Although a programming pulse signal is applied to all memory structures, the state of the non-volatile cell of a memory structure is only changed if the state stored by the associated non-volatile cell differs from the state stored by the volatile cell. Floating gates are automatically refreshed by the programming pulse signal. By storing configuration information in each tile, inefficiencies associated with using blocks of non-volatile memory are avoided.

Abstract: Systems and processes may use a first memory, a second memory, and a memory controller. The second memory is at least as large as a block of the first memory. Data is received and stored in the second memory for further writing to the second memory.

Abstract: A memory includes many memory regions. The memory regions have multiple multi-level cells. Each memory region includes a first bit line, a second bit line, a data buffer and a protecting unit. The first bit line is coupled to a first column of the multi-level cells. The second bit line is coupled to a second column of the multi-level cells. The data buffer is coupled to the first bit line and the second bit line and for storing data to be programmed into the multi-level cells. The protecting unit is coupled to the first bit line, the second bit line and the data buffer and is for preventing a programming error from occurring.

Abstract: Embodiments disclosed herein generally relate to switches that utilize micro-electromechanical systems (MEMS). By replacing transistors in many devices with switches such as MEMS switches, the devices may be used for logic applications. MEMS switches may be used in devices such as FPGAs, NAND devices, nvSRAM devices, AMS chips and general memory logic devices. The benefit of utilizing MEMS devices in place of transistors is that the transistors utilize more space on the chip. Additionally, the MEMS devices can be formed in the BEOL without having any negative impacts on the FEOL or necessitating the use of additional layers within the chip.

Abstract: Non-volatile (NV) semiconductor memories and methods of operating the same to reduce or eliminate a need for an external capacitance are provided. In one embodiment, the memory includes a memory cell comprising a random access memory (RAM) portion and a NV memory portion, and the method comprises steps of: (i) initially erasing the NV memory portion; and (ii) on detecting a drop in power supplied to the memory, programming the NV memory portion with data from the RAM portion while powering the memory from a capacitor. On restoration of power data is recalled from the NV memory portion into the RAM portion, and the NV memory portion erased. Preferably, the capacitor is integrally formed on a single substrate with the NV memory portion and RAM portion. More preferably, the capacitor comprises intrinsic capacitance between elements of the memory formed on the substrate. Other embodiments are also disclosed.

Abstract: Methods and apparatuses for programming non-volatile semiconductor memory devices by using modulated pulses are disclosed. An apparatus may have a pulse generator, to create a sequence of pulses and set a threshold voltage of a non-volatile memory cell, and a pulse coupler. The apparatus may have a threshold verifier capable of verifying that the threshold voltage is set within an acceptable voltage range of a target threshold voltage. A pulse width modulator in some apparatuses may modulate the pulse durations early in the sequence when programming fast bits and late in the sequence when programming slow bits. An apparatus may generate a sequence of pulses, apply the sequence of pulses to a memory cell to set a threshold voltage of the memory cell, and modulate one or more of pulses in the sequence the parameters of pulse duration, pulse separation time, and step voltage magnitude.

Abstract: Silicon-oxide-nitride-oxide-silicon SONOS-type devices (or BE-SONOS) fabricated in Silicon-On-Insulator (SOI) technology for nonvolatile implementations. An ultra-thin tunnel oxide can be implemented providing for very fast program/erase operations, supported by refresh operations as used in classical DRAM technology. The memory arrays are arranged in divided bit line architectures. A gate injection, DRAM cell is described with no tunnel oxide.

Abstract: Method and apparatus for outputting data from a memory array having a plurality of non-volatile memory cells arranged into rows and columns. In accordance with various embodiments, charge is stored in a volatile memory cell connected to the memory array, and the stored charge is subsequently discharged from the volatile memory cell through a selected column. In some embodiments, the volatile memory cell is a dynamic random access memory (DRAM) cell from a row of said cells with each DRAM cell along the row coupled to a respective column in the memory array, and each column of non-volatile memory cells comprises Flash memory cells connected in a NAND configuration.

Abstract: The chip area of a semiconductor device including a nonvolatile memory is reduced. The semiconductor device includes a first memory cell and a second memory cell which are formed on the principal surface of a substrate, and arranged adjacent to each other. In a principal surface of the substrate, active regions which are electrically isolated from each other are arranged. In the first active region, the capacitor element of the first memory cell is arranged, while the capacitor element of the second memory cell is arranged in the fourth active region. In the second active region, the respective write/erase elements of the first and second memory cells are both arranged. Further, in the third active region, the respective read elements of the first and second memory cells are both arranged.

Abstract: A NAND flash memory device having a bit line and a plurality of storage cells coupled thereto. Programming circuitry is coupled to the plurality of storage cells concurrently to program two or more of the storage cells in different NAND strings associated with the same bit line.

Abstract: Techniques for providing floating body memory devices are disclosed. In one particular exemplary embodiment, the techniques may be realized as a semiconductor device comprising a floating gate, a control gate disposed over the floating gate, a body region that is electrically floating, wherein the body region is configured so that material forming the body region is contained under at least one lateral boundary of the floating gate, and a source region and a drain region adjacent the body region.

Abstract: A semiconductor device includes a sense amplifier and a decoder provided on a semiconductor substrate together with memory cells provided above the sense amplifier and the decoder. Each of the memory cells includes a channel region, in which current flows in a direction perpendicular to a surface of the semiconductor substrate, a charge accumulation region provided along the channel region, and an insulator film provided between the channel region and the charge accumulation region.

Abstract: A nonvolatile memory device including one resistor and one transistor. The resistor may correspond to a resistance layer electrically connected to a first impurity region and a second impurity region of the transistor.

Abstract: The invention provides a method of updating a stored data value in a non-volatile memory. The method includes reading the stored data value from the non-volatile memory; reading a stored differential value from a volatile memory; receiving an updated data value; calculating a calculated differential value from the difference between the updated data value and the sum of the stored data value and the stored differential value; comparing the calculated differential value with a threshold differential value; and writing the updated data value to the non-volatile memory if the calculated differential value exceeds the threshold differential value. The invention further provides a related memory system.

Abstract: Semiconductor memory having both volatile and non-volatile modes and methods of operation.

Abstract: A non-volatile DRAM cell includes a pass-gate transistor and a cell capacitor. A read operation of the non-volatile cell begins by positively charging the cell capacitor. A cell capacitor of an associated dummy non-volatile DRAM cell is fully charged. The pass-gate transistor is activated and if the pass-gate transistor is erased it does not turn on and if it is programmed, it turns on. Charge is shared on the complementary pair of pre-charged bit lines connected to the non-volatile DRAM cell and its associated Dummy non-volatile DRAM cell. A sense amplifier detects the difference in to the data state stored in the pass-gate transistor. The program and erase of the non-volatile DRAM cell is accomplished Gate-induced drain-lowering (GIDL) assisted band-to-band tunneling and Fowler-Nordheim tunneling respectively. Programming or erasing a selected row of cells does not affect the data states of the cells in the unselected rows.

Abstract: A device can include 1) a sustained or constantly powered low leakage latch to and from which a volatile state is uploaded and downloaded, respectively, based on an active-to-low signal, and 2) an intermittently powered or de-powerable memory element, coupled to the low leakage latch, from which and to which the volatile state is uploaded and downloaded, respectively, based on the active-to-low signal and a de-powerable voltage across the de-powerable memory element is powered and un-powered, respectively.