Abstract: Two-transistor FLOTOX EEPROM cells are collected to form an alterable unit such as a byte. Each of the two-transistor FLOTOX EEPROM cells has a bit line connected to a drain of a select transistor of each of the two-transistor FLOTOX EEPROM cells and a source line placed in parallel with the bit line and connected to a source of a floating gate transistor of each of the two-transistor FLOTOX EEPROM cells. In a program operation, the bit lines are connected to a very large programming voltage level and the source lines are connected to a punch through inhibit voltage level. The punch through inhibit voltage level is approximately one half the very large programming voltage level. The lower drain-to-source voltage level permits the select transistor and the floating gate transistor to have smaller channel lengths and therefore a lower drain-to-source breakdown voltage.

Abstract: A two transistor NOR flash memory cell has symmetrical source and drain structure manufactured by a NAND-based manufacturing process. The flash cell comprises a storage transistor made of a double-poly NMOS floating gate transistor and an access transistor made of a double-poly NMOS floating gate transistor, a poly1 NMOS transistor with poly1 and poly2 being shorted or a single-poly poly1 or poly2 NMOS transistor. The flash cell is programmed and erased by using a Fowler-Nordheim channel tunneling scheme. A NAND-based flash memory device includes an array of the flash cells arranged with parallel bit lines and source lines that are perpendicular to word lines. Write-row-decoder and read-row-decoder are designed for the flash memory device to provide appropriate voltages for the flash memory array in pre-program with verify, erase with verify, program and read operations in the unit of page, block, sector or chip.

Abstract: A nonvolatile memory array has nonvolatile memory cells arranged in rows and columns where each column has a bit line and source line associated with and in parallel with the nonvolatile memory cells. In programming the nonvolatile memory cell, approximately equal program voltage levels are applied to a drain and a source of a selected charge retaining transistor such that the difference in the voltage between the drain and the source of the selected charge retaining transistor is less than a drain to source breakdown voltage of the selected charge retaining transistor to prevent drain-to-source punch through. In programming or erasing the nonvolatile memory cell a control gate and a bulk program voltage level is applied to a control gate and bulk such that the magnitude of the control gate and bulk program voltage levels is less than a breakdown voltage level of peripheral circuitry.

Abstract: A NOR flash memory cell is formed of dual serially connected charge retaining transistors. A drain/source of a first of the dual charge retaining transistors connected to a local bit line and a source/drain of a second of the dual charge retaining transistors connected to a local source line. The drain/sources of the commonly connected dual serially connected charge retaining transistors are connected solely together. The drain/sources and source drains are formed in a diffusion well. In some embodiments, the diffusion well is formed in a deep diffusion well. The dual serially connected charge retaining transistors are N-channel or P-channel charge retaining transistors with the charge retaining layers being either floating gate or SONOS charge trapping layers. Selected charge retaining transistors are programmed by a combination of a band-to-band tunneling and a Fowler-Nordheim tunneling and erased by a Fowler Nordheim tunneling.

Abstract: A mask programmable NOR ROM circuit includes serially connected ROM transistors. A drain of a topmost ROM transistor is connected to a bit line and a source of a bottommost ROM transistor is connected to a source line. A source of one ROM transistor is solely connected with a drain of an immediately adjacent ROM transistor. The ROM transistors are programmed by placing a resist mask having openings for selectively modifying a first threshold voltage level of chosen ROM transistors by implanting a threshold voltage modifying impurity. A selected ROM transistor is read by connecting the source line to a sense amplifier circuit and setting the bit line to a read biasing voltage level. The gate of the selected ROM transistor is set to a moderately high read voltage level. The gates of all unselected ROM transistor is set to a very high read voltage level.

Abstract: A memory system includes a NAND flash memory, a NOR flash memory and a SRAM manufactured on a single chip. Both NAND and NOR memories are manufactured by the same NAND manufacturing process and NAND cells. The three memories share the same address bus, data bus, and pins of the single chip. The address bus is bi-directional for receiving codes, data and addresses and transmitting output. The data bus is also bi-directional for receiving and transmitting data. One external chip enable pin and one external output enable pin are shared by the three memories to reduce the number of pins required for the single chip. Both NAND and NOR memories have dual read page buffers and dual write page buffers for Read-While-Load and Write-While-Program operations to accelerate the read and write operations respectively. A memory-mapped method is used to select different memories, status registers and dual read or write page buffers.

Abstract: A nonvolatile memory structure with pairs of serially connected select transistors connected to the top and optionally to the bottom of NAND series strings of groups of the dual-sided charge-trapping nonvolatile memory cells for controlling connection of the NAND series string to an associated bit line. A first of the serially connected select transistors has an implant to make a threshold voltage of the implanted first serially connected select transistor different from a non-implanted second serially connected select transistor. The pair of serially connected top select transistors is connected to a first of two associated bit lines. Optionally, the NAND nonvolatile memory strings further is connected a pair of serially connected bottom select transistors that is connected to the second associated bit line.

Abstract: A method and apparatus for operating an array block of dual charge retaining transistor NOR flash memory cells by erasing the dual charge retaining transistor NOR flash memory cells to set their threshold voltage levels to prevent leakage current from corrupting data during a read operation. Erasure of the array block of NOR flash memory cells begins by selecting one of block section of the array block and erasing, erase verifying, over-erase verifying, and programming iteratively until the charge retaining transistors have their threshold voltages between the lower limit and the upper limit of the first program state. Other block sections are iteratively selected and erased, erased verified, over-erase verified, and programmed repeatedly until the charge retaining transistors have their threshold voltages between the lower limit and the upper limit of the first program state until the entire block has been erased and reprogrammed to a positive threshold level.

Abstract: A nonvolatile memory structure with pairs of serially connected threshold voltage adjustable select transistors connected to the top and optionally to the bottom of NAND series strings of groups of the dual-sided charge-trapping nonvolatile memory cells for controlling connection of the NAND series string to an associated bit line. A first of the threshold voltage adjustable select transistors has its threshold voltage level adjusted to a first threshold voltage level and a second of the threshold voltage adjustable select transistors adjusted to a second threshold voltage level. The pair of serially connected threshold voltage adjustable select transistors is connected to a first of two associated bit lines. The NAND nonvolatile memory strings further is connected to a pair of serially connected threshold voltage adjustable bottom select transistors that is connected to the second associated bit line.

Abstract: A nonvolatile memory array includes a plurality of dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells arranged in rows and columns. The dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells on each column form at least one grouping that is arranged in a NAND series string of dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells. Each NAND series string has a top select transistor and a bottom select transistor. Pairs of braided bit lines are connected in a braided columnar bit line structure such that each column of the dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells is connected to an associated pair of braided bit lines.

Abstract: An apparatus and method for operating an array of NOR connected flash nonvolatile memory cells erases the array in increments of a page, block, sector, or the entire array while minimizing sub-threshold leakage current through unselected nonvolatile memory cells. The apparatus has a row decoder circuit and a source decoder circuit for selecting the nonvolatile memory cells for providing biasing conditions for reading, programming, verifying, and erasing the selected nonvolatile memory cells while minimizing sub-threshold leakage current through unselected nonvolatile memory cells.

Abstract: An apparatus and method for operating an array of NOR connected flash nonvolatile memory cells erases the array in increments of a page, block, sector, or the entire array while minimizing operational disturbances and providing bias operating conditions to prevent gate to source breakdown in peripheral devices. The apparatus has a row decoder circuit and a source decoder circuit for selecting the nonvolatile memory cells for providing biasing conditions for reading, programming, verifying, and erasing the selected nonvolatile memory cells while minimizing operational disturbances and preventing gate to source breakdown in peripheral devices.

Abstract: A nonvolatile memory device includes an array of EEPROM configured nonvolatile memory cells each having a floating gate memory transistor for storing a digital datum and a floating gate select transistor for activating the floating gate memory transistor for reading, programming, and erasing. The nonvolatile memory device has a row decoder to transfer the operational biasing voltage levels to word lines connected to the floating gate memory transistors for reading, programming, verifying, and erasing the selected nonvolatile memory cells. The nonvolatile memory device has a select gate decoder circuit transfers select gate control biasing voltages to the select gate control lines connected to the control gate of the floating gate select transistor for reading, programming, verifying, and erasing the floating gate memory transistor of the selected nonvolatile memory cells.

Abstract: A nonvolatile memory device includes a nonvolatile memory array including a plurality of charge retaining transistors arranged in rows and columns. The device has a plurality source lines formed in parallel with the bit lines associated with each column. Row decode/driver circuits are connected to blocks of the charge retaining transistors for controlling the application of the necessary read, program, and erase signals. Erase count registers, each of the erase count registers associated with one block of the array of the charge retaining transistors for storing an erase count for the associated block for determining whether a refresh operation is to be executed. Groupings on each column of the array of charge retaining transistors are connected as NAND series strings where each NAND string has a select gating charge retaining transistor connected to the top charge retaining transistor for connecting the NAND series string to the bit lines.

Abstract: A NOR flash nonvolatile memory device provides the memory cell size and a low current program process of a NAND flash nonvolatile memory device and the fast, asynchronous random access of a NOR flash nonvolatile memory device. The NOR flash nonvolatile memory device has an array of NOR flash nonvolatile memory circuits. Each NOR flash nonvolatile memory circuit includes a plurality of charge retaining transistors serially connected in a NAND string. A drain of a topmost charge retaining transistor is connected to a bit line associated with the serially connected charge retaining transistors and a source of a bottommost charge retaining transistor is connected to a source line associated with the charge retaining transistors. Each control gate of the charge retaining transistors on each row is commonly connected to a word line. The charge retaining transistors are programmed and erased with a Fowler-Nordheim tunneling process.

Abstract: A single polycrystalline silicon floating gate nonvolatile memory cell has a MOS capacitor and a storage MOS transistor fabricated with dimensions that allow fabrication using current low voltage logic integrated circuit process. The MOS capacitor has a first plate connected to a gate of the storage MOS transistor to form a floating gate node. The physical size of the MOS capacitor is relatively large (approximately 10 time greater) when compared to a physical size of the storage MOS transistor to establish a large coupling ratio (approximately 90% between the second plate of the MOS capacitor and the floating gate node. When a voltage is applied to the second plate of the MOS capacitor and a voltage applied to the source region or drain region of the MOS transistor establishes a voltage field within the gate oxide of the MOS transistor such that Fowler-Nordheim edge tunnel is initiated.

Abstract: A nonvolatile SRAM circuit has an SRAM cell and one or two FLOTOX EEPROM cells connected to the data storage terminals of the SRAM cell. In programming to a first data level, the threshold voltage of a FLOTOX EEPROM transistor is brought to a programmed voltage level greater than a read voltage level and erasing to a second data level, the threshold voltage of the FLOTOX EEPROM transistor is brought to an erased voltage level less than the read voltage level. The nonvolatile SRAM array provides for restoring data to an SRAM cell from a FLOTOX EEPROM memory cell(s) at a power initiation and storing data to the FLOTOX EEPROM memory cell(s) to the SRAM cell at power termination. A power detection circuit for providing signals indicating power initiation and power termination to instigate restoration and storing of data between an SRAM cell and a FLOTOX EEPROM cell(s).

Abstract: A nonvolatile memory array includes a plurality of dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells arranged in rows and columns. The dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells on each column form at least one grouping that is arranged in a NAND series string of dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells. Each NAND series string has a top select transistor and a bottom select transistor. Pairs of braided bit lines are connected in a braided columnar bit line structure such that each column of the dual-sided charge-trapping dual-sided charge-trapping nonvolatile memory cells is connected to an associated pair of braided bit lines.

Abstract: A nonvolatile memory structure with pairs of serially connected select transistors connected to the top and optionally to the bottom of NAND series strings of groups of the dual-sided charge-trapping nonvolatile memory cells for controlling connection of the NAND series string to an associated bit line. A first of the serially connected select transistors has an implant to make a threshold voltage of the implanted first serially connected select transistor different from a non-implanted second serially connected select transistor. The pair of serially connected top select transistors is connected to a first of two associated bit lines. Optionally, the NAND nonvolatile memory strings further is connected a pair of serially connected bottom select transistors that is connected to the second associated bit line.

Abstract: A flash memory having over-erased cells eliminated and comprising adjustable erase and program conditions. The maximum and minimum threshold voltages of the cells are measured during the whole erase and program operations. The over-erased cells are shut down by applying a word line voltage lower than the minimum threshold voltage measured previously. Pre-program and repair operations for the over-erased cell are eliminated. Low read voltage is achieved. The erase and program conditions for the gate, source, drain voltage, width of a pulse, and number of pulses are adjustable in accordance with the threshold voltage to optimize the performance. A lookup table stores the relevant gate, source, drain voltage, width of a pulse, and number of pulses with respect to the threshold voltage for the adjustable conditions. The benefits achieved by the operation of the flash memory include high efficiency, long endurance, narrow threshold voltage distribution, low power consumption, and low process-sensitivity.