Abstract: This invention provides a type of sense amplifier, a type of bit line circuit, a type of storage device, and a method for amplifying a read signal characterized by the fact that it has a small detection error of the read signal and has low power consumption. With bit lines (BL, BLZ) and input terminals (SA, SAZ) of the amplifier connected to each other by means of a CMOS switch circuit, as control signal ENN becomes high level, amplification of the read signal in the amplifier starts and, at the same time, the amplified signal is held. After a time delay determined by delay circuit U1 from the start of amplification of the read signal, control signal GEN1 and control signal GEN2 output from said delay circuit U1 are changed, and connection between the bit line and amplifier is cut off.

Abstract: An open-bit semiconductor memory device includes a plurality of memory cell arrays, wherein half of the memory cells in the memory cell array and half of the memory cells in the adjacent memory cell array store therein complementary data. The memory device further includes a pair of reference cell arrays sandwiching therebetween the memory cell arrays for supplying reference data for reading data from the memory cells in the adjacent memory cells. The reference cell array includes a plurality reference bit lines each connected to reference cells in number smaller than the number of memory cells connected to the bit line, and yet has a resistance and a capacitance equivalent to the resistance and the capacitance of the bit lines.

Abstract: In accordance with the present invention, a memory cell includes a non-volatile device and a SRAM cell. The SRAM cell includes first and second MOS transistors. The non-volatile device is a load to the SRAM cell. The memory cell may be adapted to operate differentially if a second SRAM cell and a second non-volatile device is disposed therein. If so adapted, the SRAM cells and/or the non-volatile devices when programmed store and supply complementary data. The non-volatile devices are erased prior to being programmed. Programming of the non-volatile devices may be done via hot-electron injection or Fowler-Nordheim tunneling. When a power failure occurs, the data stored in the SRAM are loaded in the non-volatile devices. After the power is restored, the data stored in the non-volatile devices are restored in the SRAM cells. The differential reading and wring of data reduces over-erase of the non-volatile devices.

Abstract: An exemplary sensing circuit for sensing the current drawn by a target memory cell comprises a first transistor connected across a first node and a second node, a load connected across the second node and a third node, and a voltage boosting circuit coupled to a supply voltage, wherein the voltage boosting circuit supplies a voltage at the third node which is greater than the supply voltage.

Abstract: Device and method for memory cell isolation. The memory cell includes a resistive component, such as a magnetic random access memory (MRAM) cell, and an isolation component, such as a four-layer diode. The memory cell may be included in a memory array. The method includes rapidly applying a forward bias across the isolation element to activate the isolation element.

Abstract: Apparatus and method for data sensing circuitry that uses averaging to sense small differences in signal levels representing data states. The apparatus periodically switches the coupling of input terminals and output terminals of an integrator circuit from a first configuration to a second configuration, where the second configuration changes the polarity of the integrator circuit from the first configuration. The output signals of the integrator circuit are periodically compared, and based on the comparison, output signals having a voltage representative of a value are generated. The values of the output signals are then averaged over time to determine the data state.

Abstract: A semiconductor memory device is capable of performing a faster operation by reducing a load applied to a subword selection line or driving a subword driver provided for each memory mat. In a drive method of subword drivers that are actuated in response to subword selection signals supplied through subword selection lines, the subword selection lines are branched according to the number of memory mats. Each subword selection signal has a polarity to a branching position and an inverted polarity from each branching position to each subword driver. The inverted subword selection signal together with a main word signal are calculated to operation in each subword driver and output as a subword drive signal. The plurality of subword drivers share an inverter circuit for inverting the main word signals so as to permit a simplified circuit configuration.

Abstract: Apparatus and method for data sensing circuitry that uses averaging to sense small differences in signal levels representing data states. The apparatus periodically switches the coupling of input terminals and output terminals of an integrator circuit from a first configuration to a second configuration, where the second configuration changes the polarity of the integrator circuit from the first configuration. The output signals of the integrator circuit are periodically compared, and based on the comparison, output signals having a voltage representative of a value are generated. The values of the output signals are then averaged over time to determine the data state.

Abstract: A single bit line reference signal path or line is used for both voltage subtraction and self-timing of a second sense that is longer than a first sense in a dual-sense, single-read memory cell. The self-timing mechanism includes an analog circuit.

Abstract: In the first read operation, a read current is supplied to TMR elements connected in parallel in one column or one block to detect initial data. Trial data is then written in a selected memory cell. At the same time of or in parallel with writing of the trial data, the second read operation is performed. In the second read operation, a read current is supplied to the TMR elements connected in parallel in one column or one block to read comparison data. Subsequently, the initial data is compared with the comparison data to determine the data value in the selected memory cell. Finally, rewrite operation is performed for the selected memory cell.

Abstract: A first decision process, which reads data from a memory cell under a first deciding condition to decide pass/fail and applies a signal to the memory cell to change an amount of charge stored in the memory cell if the data is decided as fail, and a second decision process, which reads the data from the memory cell under a second deciding condition that is relaxed rather than the first deciding condition to decide the pass/fail, are executed, and then the processes are repeated from the first decision process when the data is decided as fail in the second decision process.

Abstract: An electrically erasable charge trap nonvolatile memory cell has an initial threshold voltage, a program voltage that is higher than the initial threshold voltage, and an erase threshold voltage that is lower than the program threshold voltage but is higher than the initial threshold voltage. The programmed electrically erasable charge trap nonvolatile memory cells may be erased by applying an erase voltage for a time interval that is sufficient to lower the threshold voltage the transistor from a program threshold voltage to an erase threshold voltage that is lower than the program threshold voltage, but is higher than the initial threshold voltage. The time interval may be determined by repeatedly performing an endurance test using a time interval that is increased or decreased from an initial time interval, to obtain the time interval that meets an endurance specification, or allows a read to be performed successfully.

Abstract: An apparatus having an output register coupled to a content addressable memory (CAM) array. The output register may be configured to output data based on a delayed clock signal. A programmable delay circuit may be coupled to receive a reference clock signal and generate the delayed clock signal using one or more delay elements.

Abstract: Memory cells are disclosed comprising volatile and non-volatile portions, where the non-volatile portions provide storage of multiple non-volatile data states or bits per memory cell. Methods are provided for reading non-volatile data states from a non-volatile portion of a memory cell into a volatile portion.

Abstract: In a flash EEPROM system that is divided into separately erasable blocks of memory cells with multiple pages of user data being stored in each block, a count of the number of erase cycles that each block has endured is stored in one location within the block, such as in spare cells of only one page or distributed among header regions of multiple pages. The page or pages containing the block cycle count are initially read from each block that is being erased, the cycle count temporarily stored, the block erased and an updated cycle count is then written back into the block location. User data is then programmed into individual pages of the block as necessary. The user data is preferably stored in more than two states per memory cell storage element, in which case the cycle count can be stored in binary in a manner to speed up the erase process and reduce disturbing effects on the erased state that writing the updated cycle count can cause.

Abstract: A write-driver/read-amplifier circuit includes a write driver, a GIO equalize circuit and a read amplifier. When a current leaks from or to global data line, a signal applied to a logic gate attains L-level. As a result, the write driver and the GIO equalize circuit stop the operations so that a semiconductor memory device can prevent occurrence of an unnecessary leak current.

Abstract: A method for programming and erasing a memory array includes the step of adapting programming or erase pulses to the current state of the memory array. In one embodiment, the step of adapting includes the steps of determining the voltage level of the programming pulse used to program a fast bit of the memory array and setting an initial programming level of the memory array to a level in the general vicinity of the programming level of the fast bit. For erasure, the method includes the steps of determining erase conditions of the erase pulse used to erase a slowly erasing bit of said memory array and setting initial erase conditions of said memory array to the general vicinity of said erase conditions of said slowly erasing bit.

Abstract: A flash memory device and system include a boot block voltage pump for providing a word line voltage to the boot block of the flash memory. At least one additional voltage pump is provided to supply a word line voltage to the remaining memory blocks. The memory device can be operated according to a specification where data stored in the boot block can be read as valid data before data stored in other memory blocks can be validly read upon memory activation.

Abstract: A simply structured, and highly reliable semiconductor apparatus having a large storage capacity. The apparatus has a plurality of memory cells on one semiconductor substrate, each including a capacitor having first and second electrodes, and a switching device having a control terminal connected to a corresponding word line among a plurality of word lines, and a current channel connected between the first electrode and a corresponding bit line among a plurality of bit lines. When the semiconductor apparatus is in a first mode, an OFF potential of the word lines is set to be a first potential, when the semiconductor apparatus is in a second mode, an OFF potential of the word lines is set to be a second potential, and a current channel of the switching device is set in a direction vertical to the semiconductor substrate.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.