Abstract: A first plurality of memory cells is in a first plane in a first column of the array. A second plurality of memory cells is in a second plane in the same column. The second plurality of memory cells are coupled to the first plurality of memory cells through a series connection of their source/drain regions.

Abstract: Embodiments of the invention provide devices or methods that include a status bit representing an inversion of stored data. New data is written to selected cells, the new data is selectively inverted, and the status bit is selectively toggled, based on a comparison between pre-existing data and new data associated with a write command. A benefit of embodiments of the invention is that fewer memory cells must be activated in many instances (when compared to conventional art approaches). Moreover, embodiments of the invention may also reduce the average amount of activation current required to write to variable resistive memory devices and other memory device types.

Abstract: An integrated circuit (10) comprises a plurality of non-volatile memory cells (14) and a charge distribution ramp rate control circuit (11). Each memory cell of the array (12) includes a charge storage region and a plurality of terminals. The charge distribution ramp rate control circuit includes a capacitor (62,116,144) having a first plate electrode coupled to at least one terminal of the plurality of terminals, and a second plate electrode. The charge distribution ramp rate control circuit further includes a bandgap generated current source (58,106,136) for providing a reference current to determine a ramp rate of a voltage at the at least one terminal.

Abstract: A non-volatile memory having a gate structure, a pair of storage units and two assist gates is provided. The gate structure is disposed on the substrate. The storage units are disposed on the sidewalls of the gate structure. The assist gates are disposed on the respective sides of the gate structure and adjacent to the storage units. Each assist gate is shared between two adjacent memory cells. The gate structure, the storage units and the assist gates are electrically isolated from one another.

Abstract: Systems and methods in accordance with various embodiments can provide for reduced program disturb in non-volatile semiconductor memory. In one embodiment, select memory cells such as those connected to a last word line of a NAND string are programmed using one or more program verify levels or voltages that are different than a corresponding level used to program other cells or word lines. One exemplary embodiment includes using a lower threshold voltage verify level for select physical states when programming the last word line to be programmed for a string during a program operation. Another embodiment includes applying a lower program voltage to program memory cells of the last word line to select physical states. Additional read levels are established for reading the states programmed using lower verify levels in some exemplary implementations.

Abstract: The present invention is to provide a logic based single-poly non-volatile memory cell which is compatible with the CMOS process, uses lower voltages for operating, and is more reliable in program, read, or erase operation. A non-volatile memory cell in accordance with the present invention comprises a program transistor with a program transistor source as a first program terminal; a select transistor with a select transistor gate as a select terminal and a select transistor drain as a second program terminal; and an erase transistor with an erase transistor source and an erase transistor drain connected as an erase terminal, wherein the erase transistor shares a floating gate with the program transistor and the drain program transistor is connected to the select transistor source. By employing the present invention, significant cost advantages in feature-rich semiconductor products, such as System-on-Chip (SoC) design, compared to conventional dual-poly floating gate embedded Flash memory are provided.

Abstract: A programming circuit and method to apply a controlled or predetermined voltage pulse for charge transfer to or from the floating gate of a non-volatile memory cell in an incremental manner to control the overall voltage across the gate oxide. Voltage above a transfer threshold voltage, such as above a tunneling threshold voltage, is applied in a stepwise charge transfer manner to or from the floating gate up to a voltage limit that is below the thin oxide damage threshold. Controlling the overall voltage avoids oxide breakdown and enhances reliability.

Abstract: A non-volatile memory device, and method of forming the same, increases or maximizes the performance of an ultramicro-structured device.

Abstract: A semiconductor memory device includes a memory cell, a word line, a bit line, a column gate, and a power supply decode circuit. The memory cell has a first MOS transistor including a charge accumulation layer and a control gate. The bit line is connected to a drain of the first MOS transistor and is applied with first voltage at the test operation time and at data program operation time. The column gate includes a second MOS transistor having current path connected to the bit line to transfer the first voltage to the bit line at the test operation time. The power supply decode circuit applies a second voltage to a gate of the second MOS transistor at the program operation time and applies a third voltage lower than the second voltage at the test operation time.

Abstract: In one embodiment, a memory is provided that includes: a memory cell array adapted to be programmed with a positive voltage from a positive-negative node and to be erased with a negative voltage from the positive-negative node; a negative voltage blocking circuit; and a positive voltage source operable coupled to the negative voltage blocking circuit, the positive voltage source operable to provide the positive voltage to the positive-negative node through the negative voltage blocking circuit, wherein the negative voltage blocking circuit is adapted to prevent the negative voltage from coupling from the positive-negative node to the positive voltage source.

Abstract: A method for determining programming/erase conditions and a method for operating a charge-trapping semiconductor device are disclosed. Programming and erase conditions are determined such that a first net charge distribution variation profile, upon going from programmed to erased state, is substantially the opposite of a second net charge distribution variation profile, upon going from erased to programmed state.

Abstract: In a p-type flash memory array, separate programming and read bit lines are provided. The programming bit line is used only to program the floating gate transistors in the memory cells connected to that bit line. The read bit line is used only to read the state of a floating gate transistor in a selected memory cell connected to that bit line during the operation of the memory circuit. The resulting structure allows the use of low voltages during both programming and operation of the memory array. This makes possible the use of transistors in the memory array with feature sizes less than, for example, 0.18 microns. At the same time variable, unpredictable capacitances associated with each bit line in prior art p-type flash memory structures using comparable low programming voltages are eliminated when a particular memory cell attached to that bit line is being read out.

Abstract: Some embodiments include a device having memory cells coupled to a well of a semiconductor substrate, and a select transistor coupled between the memory cells and a bit line of the device. The device may have a first circuit to raise a well voltage of the well from a first well voltage level to a second well voltage level during an erase operation. The first circuit may hold the well at the second well voltage level for a time interval during the erase operation. The device may have a second circuit to raise a voltage of the gate of the select transistor from a first gate voltage level to a second gate voltage level, which may be lower than the second well voltage level. The second circuit may hold the gate at the second gate voltage level for a time interval during the erase operation. Other embodiments including additional apparatus, systems, and methods are disclosed.

Abstract: Shifts in the apparent charge stored on a floating gate (or other charge storing element) of a non-volatile memory cell can occur because of the coupling of an electric field based on the charge stored in adjacent floating gates (or other adjacent charge storing elements). To compensate for this coupling, the read or programming process for a given memory cell can take into account the programmed state of an adjacent memory cell. To determine whether compensation is needed, a process can be performed that includes sensing information about the programmed state of an adjacent memory cell (e.g., on an adjacent bit line or other location).

Abstract: A gated diode nonvolatile memory cell with a charge storage structure includes a diode structure with an additional gate terminal and a diffusion barrier structure between the diode nodes. Example embodiments include the individual memory cell, an array of such memory cells, methods of operating the memory cell or array of memory cells, and methods of manufacturing the same.

Abstract: Systems and methods in accordance with various embodiments can provide for reduced program disturb in non-volatile semiconductor memory. In one embodiment, select memory cells such as those connected to a last word line of a NAND string are programmed using one or more program verify levels or voltages that are different than a corresponding level used to program other cells or word lines. One exemplary embodiment includes using a lower threshold voltage verify level for select physical states when programming the last word line to be programmed for a string during a program operation. Another embodiment includes applying a lower program voltage to program memory cells of the last word line to select physical states. Additional read levels are established for reading the states programmed using lower verify levels in some exemplary implementations.

Abstract: A method of operating a non-volatile memory device includes maintaining a write voltage at a predetermined voltage level for programming and/or erasing a memory cell of the non-volatile memory device during a time between execution of consecutive write operations. For example, the write voltage may be activated at the predetermined voltage level responsive to an initial write command, and discharge of the write voltage may be prevented responsive to a signal indicating consecutive write commands. Related devices are also discussed.

Abstract: A method of programming a flash memory device includes charging selection lines with a first voltage while applying program data to bit lines to during a bit line setup interval, then activating a block word line to electrically connect the selection lines to corresponding word lines, and then applying a second voltage, greater than the first voltage, to a selected one of the selection lines. Related devices are also disclosed.

Abstract: A system and method are disclosed for providing EEPROM devices that combine the high endurance features of complex and expensive EEPROM devices and the low manufacturing costs of CMOS compatible EEPROM devices. A memory cell of the invention comprises a control capacitor, an erase capacitor, and a program capacitor, each of which comprises an NMOS transistor. The gates of the three NMOS transistors are connected together to form a floating gate. The drain of the NMOS transistor of the program capacitor is separately connected so that the program capacitor can also serve as a read transistor. A memory cell of the invention can be programmed or erased in an array of memory cells without disturbing the other memory cells in the array.

Abstract: A memory cell comprising an electrically floating body transistor including a source region, a drain region, a body region disposed therebetween, wherein the body region is electrically floating, and a gate disposed over the body region and separated therefrom by a gate dielectric. The memory cell includes a first data state representative of a first charge in the body region and a second data state representative of a second charge in the body region wherein the second charge is substantially provided by removing carriers from the body region through the gate. Thus, a memory cell may be programmed to a logic low by, for example, causing, forcing and/or inducing carriers in the floating body of the transistor to tunnel through or traverse the gate dielectric to the gate of the electrically floating body transistor (and, in many array configurations, the word line of a memory cell array).

Abstract: Methods of manufacturing a nitride trapping EEPROM flash memory are described where each memory cell uses Si-Fin to form a nitride trapping EEPROM flash cell in which the source region and drain region are undoped. Each adjacent poly-gate to a selected poly-gate in a row of nitride trapping memory cells is used to produce the inversion region that acts as a source region or a drain region for transferring of a required voltage, which conserves the density of a memory cell given that the source region and the drain region for each memory cell are not doped. The flash memory includes a plurality of polysilicon layers intersecting with a plurality of Si-Fin layers.

Abstract: An array structure of single-level poly NMOS EEPROM memory cells and method of operating the array is discussed implemented in a higher density embedded EEPROM layout that eliminates the use of high voltage transistors from the array core region. If they are utilized, the high voltage transistors are moved to row and column drivers in the periphery region to increase array density with little or no added process complexity to allow economic implementation of larger embedded SLP EEPROM arrays. During program or erase operations of the array, the method provides a programming voltage for the selected memory cells of the array, and a half-write (e.g., mid-level) voltage to the remaining unselected memory cells to avoid disturbing the unselected memory cells of the array.

Abstract: Suppressing a leakage current is required in a flash memory because the channel length is made shorter with a reduction in the memory cell size. In an AND type memory array having an assist electrode, although the memory cell area has been reduced by the field isolation using a MOS transistor, leakage current in the channel direction becomes greater with a reduction in the memory cell size, resulting in problems arising like deterioration of programming characteristics, an increase in the current consumption, and reading failure. To achieve the objective, in the present invention, electrical isolation is performed by controlling at least one assist electrode of the assist electrodes wired in parallel to be a negative voltage during program and read operations and by making the semiconductor substrate surface in the vicinity of the aforementioned assist electrode non-conductive.

Abstract: An SRAM cell includes: a first PMOS transistor having a source coupled to a supply voltage; a second PMOS transistor having a source coupled to the supply voltage, a drain coupled to a gate of the first PMOS transistor, and a gate coupled to a drain of the first PMOS transistor; a first write switch module coupled between the first PMOS transistor and a complementary supply voltage; a second write switch module coupled between the second PMOS transistor and the complementary supply voltage; and a read switch module coupled between the gate of the first PMOS transistor and a read bit line, wherein the first write switch module, the second write switch module, and the read switch module are controlled separately to write or read a logic value to or from one or more storage nodes at the drains of the first and second PMOS transistors.

Abstract: In a nonvolatile semiconductor memory device, a memory cell array has a plurality of nonvolatile memory cells arranged in a matrix. A selecting section selects as selection memory cells, at least two of the plurality of nonvolatile memory cells from the memory cell array. A write section applies to the selection memory cells, a gate voltage which increases step by step, until a threshold voltage of each of the selection memory cells reaches a target threshold voltage, such that the threshold voltage increases step-by-step.

Abstract: Provided is a nonvolatile memory with less element deterioration and good data retaining properties. In a nonvolatile memory formed by the manufacturing steps of a complementary type MISFET without adding thereto another additional step, erasing of data is carried out by applying 9V to an n type well, 9V to a p type semiconductor region, and ?9V to another p type semiconductor region and setting the source and drain of data writing and erasing MISFETs and data reading MISFETs at open potential to emit electrons from a gate electrode to a p well by FN tunneling. At this time, by applying a negative voltage to the p well having a capacitive element formed thereover and applying a positive voltage to the p well having the MISFETs formed thereover, a potential difference necessary for data erasing operation can be secured at a voltage low enough not to cause gate breakage.

Abstract: Data is written to a nonvolatile memory device having a memory region of four bits or larger in one memory cell sandwiched by a source and a drain with an improved accuracy. The nonvolatile memory device 100 includes four control gates 114 to 117 provided between a first and a second impurity-diffused regions 106a and 160b that are provided separately from the semiconductor substrate, and a memory cell including memory regions 106a to 106d that are counterpart of the control gates. A method for controlling the nonvolatile memory device 100 includes classifying the four control gates 114 to 100 into two groups of right and left sides, and then, applying a lower voltage to an impurity-diffused region that is further from a target memory region for injecting an electron and applying a higher voltage to an impurity-diffused region that is closer the target memory region, and moreover applying a higher voltage, the higher voltage being higher than voltages applied to other control gates.

Abstract: A single 4-transistor non-volatile memory (NVM) cell includes a shared static random access memory cell. The NVM cell utilizes a reverse Fowler-Nordheim tunneling programming technique that, in combination with the shared SRAM cell structure, allows an entire cell array to be programmed at two cycles. A single NVM cell approach with shared SRAM allows a 50% area reduction with an insignificant increase in program time.

Abstract: A PMOS transistor is programmed as a non-volatile memory element by operating the PMOS transistor in accumulation mode. This facilitates merging the source and drain regions to form a low-resistance path because most heating occurs on the channel side of the gate dielectric, rather than on the gate terminal side. In a particular embodiment, boron is used as the dopant. Boron has a higher diffusivity than arsenic or phosphorous, which are typical n-type dopants. Boron's higher diffusivity promotes merging the source and drain regions.

Abstract: A memory system includes memory cells arranged in sectors. A decoder corresponding to a sector disables memory cells having a defective top gate. The decoder may include a low voltage or high voltage latch for the disabling. A top gate handling algorithm is included. The memory system may include dynamic top gate coupling. A programming algorithm and waveforms with top gate handling is included.

Abstract: A non-volatile memory cell includes a floating gate transistor having a floating gate coupled to a metal layer capacitor defined in one or more metal layers. Within each metal layer, the metal layer capacitor includes a first plate coupled to the floating gate and a second plate separated from the first plate by a fringe capacitance junction.

Abstract: A memory device including a plurality of memory cells, each with a control gate NMOS transistor sharing a floating gate with a program/erase PMOS transistor which is, in turn, connected in series with an access PMOS transistor. The memory cells are formed in a common N-Well formed in a P-substrate, the NMOS transistor being formed in a p-doped pocket or base. The program/erase PMOS includes a gate, and first and second P+ doped regions formed in the N-Well, wherein the first P+ region is electrically connected to a corresponding bit line. The access PMOS includes a gate, and first and second P+ regions formed within the N-Well, wherein the first P+ region is electrically connected to the second P+ region of the program/erase PMOS, and the gate is electrically connected to a corresponding word line.

Abstract: There are many inventions described herein as well as many aspects and embodiments of those inventions, for example, circuitry and techniques for reading, writing and/or operating a semiconductor memory cells of a memory cell array, including electrically floating body transistors in which an electrical charge is stored in the body of the transistor. In one aspect, the present inventions are directed to one or more independently controllable parameters of a memory operation (for example, restore, write, refresh), to program or write a data state into a memory cell. In one embodiment, the parameter is the amount of time of programming or writing a predetermined data state into a memory cell. In another embodiment, the controllable parameter is the amplitude of the voltage of the control signals applied to the gate, drain region and/or source region during programming or writing a predetermined data state into a memory cell. Indeed, the controllable parameters may be both temporal and voltage amplitude.

Abstract: A semiconductor memory device comprises a memory cell unit including at least one memory cell having a structure with a floating gate and a control gate stacked via an insulator on a semiconductor substrate. A common source line is connected to one end of the memory cell unit. A bit line is connected to the other end of the memory cell unit. The control gate has at least an upper portion with a width along the gate length formed wider than the width of the floating gate.

Abstract: Disclosed is an SRAM including a latch circuit, first and second write transfer gates, first and second write buffer transistors, read driver transistor, and read transfer gate. A write path is formed by connecting first and second write transfer gates and first and second write buffer transistors to the latch circuit which stores data and the path is controlled by use of a word line and data write bit lines. Further, a read path is formed by connecting a read driver transistor and read transfer gate to the latch circuit and the path is controlled by use of the word line, read bit line and data of the latch circuit.

Abstract: A single-poly EEPROM memory device comprises source and drain regions in a semiconductor body, a floating gate overlying a portion of the source and drain regions, which defines a source-to-floating gate capacitance and a drain-to-floating gate capacitance, wherein the source-to-floating gate capacitance is substantially greater than the drain-to-floating gate capacitance. The source-to-floating gate capacitance is, for example, at least about three times greater than the drain-to-floating gate capacitance to enable the memory device to be electrically programmed or erased by applying a potential between a source electrode and a drain electrode without using a control gate.

Abstract: Methods and apparatuses for programming a single-poly pFET-based nonvolatile memory cell bias the cell so that band-to-band tunneling (BTBT) is induced and electrons generated by the BTBT are injected onto a floating gate of the cell. Following a predetermined event, the single-poly pFET is biased to induce impact-ionized hot-electron injection (IHEI). The predetermined event may be, for example, the expiration of a predetermined time period or a determination that a channel has been formed by the BTBT injection process that is sufficiently conducting to support IHEI. Employing BTBT permits a previously overerased or stuck bit to be “unstuck” or “removed” and thus be made usable (i.e., able to be programmed) again.

Abstract: Methods and apparatuses for programming a single-poly pFET-based nonvolatile memory cell bias the cell so that band-to-band tunneling (BTBT) is induced and electrons generated by the BTBT are injected onto a floating gate of the cell. Following a predetermined event, the single-poly pFET is biased to induce impact-ionized hot-electron injection (IHEI). The predetermined event may be, for example, the expiration of a predetermined time period or a determination that a channel has been formed by the BTBT injection process that is sufficiently conducting to support IHEI. Employing BTBT permits a previously overerased or stuck bit to be “unstuck” or “removed” and thus be made usable (i.e., able to be programmed) again.

Abstract: A method of operating a non-volatile memory comprising a substrate, a gate, a charge-trapping layer, a source region and a drain region is provided. The charge-trapping layer close to the source region is an auxiliary charge region and the charge-trapping layer close to the drain region is a data storage region. Before prosecuting the operation, electrons have been injected into the auxiliary charge region. When prosecuting the programming operation, a first voltage is applied to the gate, a second voltage is applied to the source region, a third voltage is applied to the drain region and a fourth voltage is applied to the substrate. The first voltage is bigger than the fourth voltage, the third voltage is bigger than the second voltage, and the second voltage is bigger than the fourth voltage to initiate a channel initiated secondary hot electron injection to inject electrons into the data storage region.

Abstract: A drive circuit 22 controls voltages applied to a substrate 1, selection gates SG0 and SG1, a local bit line LB2, and a control gate CGn. By respectively applying a negative voltage to the control gate CGn, a positive voltage to the selection gate SG0, a voltage lower than the voltage applied to the selection gate SG0 to the selection gate SG1, and a positive voltage to the local bit line LB2, the drive circuit 22 controls so that electrons are selectively drawn out of a floating gate FG3 to the local bit line LB2 by F-N tunneling during writing operation. Sufficient operation margin is obtained even when memory cells are miniaturized.

Abstract: Methods and apparatuses for programming a single-poly pFET-based nonvolatile memory cell bias the cell so that band-to-band tunneling (BTBT) is induced and electrons generated by the BTBT are injected onto a floating gate of the cell. Following a predetermined event, the single-poly pFET is biased to induce impact-ionized hot-electron injection (IHEI). The predetermined event may be, for example, the expiration of a predetermined time period or a determination that a channel has been formed by the BTBT injection process that is sufficiently conducting to support IHEI. Employing BTBT permits a previously overerased or stuck bit to be “unstuck” or “removed” and thus be made usable (i.e., able to be programmed) again.

Abstract: A set of non-volatile storage elements is divided into subsets for soft programming in order to more fully soft-program slower soft programming elements. The entire set of elements is soft-programmed until verified as soft programmed (or until a first subset of elements is verified as soft programmed while excluding a second subset from verification). After the set is verified as soft programmed, a first subset of elements is inhibited from further soft programming while additional soft programming is carried out on a second subset of elements. The second subset can include slower soft programming elements. The second subset can then undergo soft programming verification while excluding the first subset from verification. Soft programming and verifying for the second subset can continue until it is verified as soft programmed. Different step sizes can be used for increasing the size of the soft programming signal, depending on which subset is being soft programmed and verified.

Abstract: A semiconductor integrated circuit includes non-volatile memory elements (PM1, PM2), each of which has a first source electrode, a first drain electrode, a floating gate electrode and a control gate electrode and is capable of having different threshold voltages, and read transistor elements (DM1, DM2), each of which has a second source electrode and a second drain electrode and is capable of having different mutual conductances according to the threshold voltage of the non-volatile memory element. The read transistor element has a switching state according to the electron injection state or the electron emission state, in other words, the writing state or the erasing state of the floating gate electrode. In a read operation, it is not necessary to cause a channel current to flow according to the threshold voltage of the non-volatile memory element.

Abstract: Methods of manufacturing a nitride trapping EEPROM flash memory are described where each memory cell uses Si-FIN to form a nitride trapping EEPROM flash cell in which the source region and drain region are undoped. Each adjacent poly-gate to a selected poly-gate in a row of nitride trapping memory cells is used to produce the inversion region that acts as a source region or a drain region for transferring of a required voltage, which conserves the density of a memory cell given that the source region and the drain region for each memory cell are not doped. The flash memory includes a plurality of polysilicon layers intersecting with a plurality of Si-FIN layers.

Abstract: A nonvolatile memory cell is provided. The memory cell includes a storage transistor and an injector in a well of an n-type conductivity. The well is formed in a semiconductor substrate of a p-type conductivity. The storage transistor comprises a source, a drain, a channel, and a charge storage region. The source and the drain are formed in the well and having the p-type conductivity with the channel of the well defined therebetween. The charge storage region is disposed over and insulated from the channel region by an insulator. Further provided are methods operating the memory cell, including means for injecting electrons from the channel through the insulator onto the charge storage region and means for injecting holes from the injector through the well through the channel through the insulator onto the charge storage region. The memory cell can be implemented in a conventional logic CMOS process.

Abstract: A method of operating on a plurality of non-volatile multi-level memory cells is disclosed. The memory cells have at least a first, second, third and fourth program level. Each of program levels corresponds to a different binary state and has a voltage threshold distribution. A constant operating voltage is maintained on the memory cells and the voltage threshold distribution of the memory cell is controlled by varying a pulse width of a programming pulse applied to each memory cell.

Abstract: An apparatus and method for storing information are provided, including using an integrated circuit including a transistor having a channel, a gate oxide layer, a gate electrode, and a modifiable gate stack layer. To store information, the on-resistance of the transistor is changed by causing a non-charge-storage based physical change in the modifiable gate stack layer.

Abstract: An array of flash memory cells includes a first sector comprising a plurality of rows wherein each row is connected to a control-gate line, a first row comprising a first flash memory cell in the first sector, a first control-gate line connecting control-gates of flash memory cells in the first row, a second row in the first sector and comprising a second flash memory cell sharing a common source-line and a same bit-line with the first flash memory cell, a second control-gate line connecting control-gates of memory cells in the second row wherein the first and the second control-gate lines are disconnected from each other, a second sector comprising a plurality of rows wherein each row is connected to a control-gate line, and a positive high-voltage (HV) driver connected to the first control-gate line in the first sector and a control-gate line in the second sector.

Abstract: An EPROM cell includes a semiconductor substrate, having source and drain regions, a floating gate, including a semiconductive polysilicon layer electrically interconnected with a first metal layer, and a control gate, including a second metal layer. The floating gate is disposed adjacent to the source and drain regions and separated from the semiconductor substrate by a first dielectric layer, and the second metal layer of the control gate is capacitively coupled to the first metal layer with a second dielectric layer therebetween.

Abstract: A method and apparatus are provided for high performance, high voltage memory operations on selected memory cells (200) of a semiconductor memory device (100). A high voltage generator (106) during program or erase operations provides a continuous high voltage level (702) on selected word lines (502) and maintains a continuous high voltage level supply to a bit line decoder (120) which sequentially provides the high voltage level (706) to a first portion of bit lines (504) and discharges (708) those bit lines (504) before providing the high voltage level to a second portion (710).