Abstract: A plurality of non-volatile storage elements on a common active layer are offset from neighbor non-volatile storage elements. This offsetting of non-volatile storage elements helps reduce interference from neighbor non-volatile storage elements. A method of manufacture is also described for fabricating the offset non-volatile storage elements.

Abstract: A set non-volatile storage elements are subjected to a programming process in order to store a set of data. During the programming process, one or more verification operations are performed to determine whether the non-volatile storage elements have reached their target condition to store the appropriate data. Decisions about whether to continue programming or whether the programming is successful are made based on whether overlapping groups of the non-volatile storage elements have less than a threshold number of non-volatile storage elements that are not properly programmed.

Abstract: Channel boosting is improved in non-volatile storage to reduce program disturb. A pre-charge module voltage source is used to pre-charge bit lines during a programming operation. The pre-charge module voltage source is coupled to a substrate channel via the bit lines to boost the channel. An additional source of boosting is provided by electromagnetically coupling a voltage from a conductive element to the bit lines and the channel. To achieve this, the bit lines and the channel are allowed to float together by disconnecting the bit lines from the voltage sources. The conductive element can be a source line, power supply line or substrate body, for instance, which receives an increasing voltage during the pre-charging and is proximate to the bit lines.

Abstract: A programming technique reduces program disturb in a set of non-volatile storage elements by programming using selected bit line patterns which increase the clamped boosting potential of an inhibited channel to avoid program disturb. One aspect groups alternate pairs of adjacent bit lines into first and second sets. Dual programming pulses are applied to a selected word line. The first set of bit lines is programmed during the first pulse, and the second set of bit lines is programmed during the second pulse. A verify operation is then performed for all bit lines. When a particular bit line is inhibited, at least one of its neighbor bit lines will also be inhibited so that the channel of the particular bit line will be sufficiently boosted. Another aspect programs every third bit line separately. A modified layout allows adjacent pairs of bit lines to be sensed using odd-even sensing circuitry.

Abstract: To program one or more non-volatile storage elements, a set of programming pulses are applied to at least one selected non-volatile storage element and one or more particular unselected non-volatile storage elements, for example, via a common word line. A boosting voltage is applied to other unselected non-volatile storage elements during the programming process in order to boost the channels of the unselected non-volatile storage elements so that programming will be inhibited. Each of the programming pulses has a first intermediate magnitude, a second intermediate magnitude and a third magnitude. In one embodiment, the first intermediate magnitude is similar to or the same as the boosting voltage. The second intermediate magnitude is greater than the first intermediate magnitude, but less then the third magnitude. Such an arrangement can reduce the effects of program disturb.

Abstract: A multiple pass programming scheme is optimized using capacitive coupling in the word line to word line direction during program-verify operations. A different pass voltage is used in different programming passes on an adjacent word line of a selected word line which is being verified. In particular, a lower pass voltage can be used in a first pass than in a second pass. The programming process may involve a word line look ahead or zigzag sequence in which WLn is programmed in a first pass, followed by WLn+1 in a first pass, followed by WLn in a second pass, followed by WLn+1 in a second pass. An initial programming pass may be performed before the first pass in which storage elements are programmed to an intermediate state and/or to a highest state.

Abstract: A nonvolatile memory array includes floating gates that have an inverted-T shape in cross section along a plane that is perpendicular to the direction along which floating cells are connected together to form a string. Adjacent strings are isolated by shallow trench isolation structures.

Abstract: Capacitive coupling from storage elements on adjacent bit lines is compensated by adjusting voltages applied to the adjacent bit lines. An initial rough read is performed to ascertain the data states of the bit line-adjacent storage elements, and during a subsequent fine read, bit line voltages are set based on the ascertained states and the current control gate read voltage which is applied to a selected word line. When the current control gate read voltage corresponds to a lower data state than the ascertained state of an adjacent storage element, a compensating bit line voltage is used. Compensation of coupling from a storage element on an adjacent word line can also be provided by applying different read pass voltages to the adjacent word line, and obtaining read data using a particular read pass voltage which is identified based on a data state of the word line-adjacent storage element.

Abstract: To program one or more non-volatile storage elements, a set of programming pulses are applied to at least one selected non-volatile storage element and one or more particular unselected non-volatile storage elements, for example, via a common word line. A boosting voltage is applied to other unselected non-volatile storage elements during the programming process in order to boost the channels of the unselected non-volatile storage elements so that programming will be inhibited. Each of the programming pulses has a first intermediate magnitude, a second intermediate magnitude and a third magnitude. In one embodiment, the first intermediate magnitude is similar to or the same as the boosting voltage. The second intermediate magnitude is greater than the first intermediate magnitude, but less then the third magnitude. Such an arrangement can reduce the effects of program disturb.

Abstract: A memory system, comprising an array of storage elements divided into logical blocks and pages within said logical blocks and a managing circuit is provided. The managing circuit is in communication with said array of storage elements and performs programming and reading operations. The programming operations include programming a plurality of multi-state storage data. The reading operations include defining an retention margin between adjacent data thresholds, determining whether bits are present in a portion of the data retention margin, and if the number of bits in the portion of retention margin exceeds a threshold, generating an error.

Abstract: A non-volatile storage system corrects over programmed memory cells by selectively performing one or more erase operations on a subset of non-volatile storage elements that are connected to a common word line (or other type of control line).

Abstract: A non-volatile storage system can selectively perform one or more erase operations on a subset of non-volatile storage elements that are connected to a common word line (or other type of control line) without intentionally erasing other non-volatile storage elements that are connected to the common word line (or other type of control line) but not in the subset.

Abstract: A non-volatile storage system performs programming for a plurality of non-volatile storage elements and selectively performs re-erasing of at least a subset of the non-volatile storage elements that were supposed to remain erased, without intentionally erasing programmed data.

Abstract: The process for programming a set of memory cells is improved by adapting the programming process based on behavior of the memory cells. For example, a set of program pulses is applied to the word line for a set of flash memory cells. A determination is made as to which memory cells are easier to program and which memory cells are harder to program. Bit line voltages (or other parameters) can be adjusted based on the determination of which memory cells are easier to program and which memory cells are harder to program. The programming process will then continue with the adjusted bit line voltages (or other parameters).

Abstract: Channel boosting is improved in non-volatile storage to reduce program disturb. A pre-charge module voltage source is used to pre-charge bit lines during a programming operation. The pre-charge module voltage source is coupled to a substrate channel via the bit lines to boost the channel. An additional source of boosting is provided by electromagnetically coupling a voltage from a conductive element to the bit lines and the channel. To achieve this, the bit lines and the channel are allowed to float together by disconnecting the bit lines from the voltage sources. The conductive element can be a source line, power supply line or substrate body, for instance, which receives an increasing voltage during the pre-charging and is proximate to the bit lines.

Abstract: Program disturb is reduced in non-volatile storage by boosting unselected NAND strings in an array so that a source side channel, on a source side of a selected word line, is boosted before a drain side channel, on a drain side of the selected word line. In one approach, a first boost mode is used when the selected word line is a lower or intermediate word line. In the first boost mode, boosting of the source and drain side channels is initiated concurrently. A second boost mode is used when the selected word line is a higher word line. In the second boost mode, boosting of the source side channel occurs early relative to the boosting of the drain side channel. Either boost mode include an isolation voltage which tends to isolate the source and drain side channels from one another.

Abstract: Non-volatile storage with reduced program disturb is provided by boosting unselected NAND strings in an array so that a source side channel, on a source side of a selected word line, is boosted before a drain side channel, on a drain side of the selected word line. In one approach, a first boost mode is used when the selected word line is a lower or intermediate word line. In the first boost mode, boosting of the source and drain side channels is initiated concurrently. A second boost mode is used when the selected word line is a higher word line. In the second boost mode, boosting of the source side channel occurs early relative to the boosting of the drain side channel. Either boost mode include an isolation voltage which tends to isolate the source and drain side channels from one another.

Abstract: Optimized verify and read pass voltages are obtained to improve read accuracy in a non-volatile storage device. The optimized voltages account for changes in unselected storage element resistance when the storage elements become programmed. This change in resistance is referred to as a front pattern effect. In one approach, the verify pass voltage is higher than the read pass voltage, and a common verify voltage is applied on the source and drain sides of a selected word line. In other approaches, different verify pass voltages are applied on the source and drain sides of the selected word line. An optimization process can include determining a metric for different sets of verify and read pass voltages. The metric can indicate threshold voltage width, read errors or a decoding time or number of iterations of an ECC decoding engine.

Abstract: Data verification in a memory device using a portion of a data retention margin is provided. A bit count is read from the region to determine whether errors will result in the memory. A read in one or more retention margin portions is performed after the normal program verify sequence and if the number of bits in these regions is more than a pre-set the memory will fail verify status. A method of verifying data in a memory device includes the steps of: defining an retention margin between adjacent data thresholds; programming the memory device with data; determining whether bits are present in the data retention margin; and if the number of bits in the retention margin exceeds a threshold, generating an error.

Abstract: The present invention presents a scheme for sensing memory cells. Selected memory cells are discharged through their channels to ground and then have a voltage level placed on the traditional source and another voltage level placed on the control gate, and allowing the cell bit line to charge up. The bit line of the memory cell will then charge up until the bit line voltage becomes sufficiently high to shut off any further cell conduction. The rise of the bit line voltage will occur at a rate and to a level dependent upon the data state of the cell, and the cell will then shut off when the bit line reaches a high enough level such that the body effect affected memory cell threshold is reached, at which point the current essentially shuts off. A particular embodiment performs multiple such sensing sub-operations, each with a different control gate voltage, but with multiple states being sensed in each operation by charging the previously discharged cells up through their source.