Abstract: The unintentional programming of an unselected (or inhibited) non-volatile storage element during a program operation that intends to program another non-volatile storage element is referred to as “program disturb.” A system is proposed for programming and/or reading non-volatile storage that reduces the effect of program disturb. In one embodiment, different verify levels are used for a particular word line (or other grouping of storage elements) during a programming process. In another embodiment, different compare levels are used for a particular word (or other grouping of storage elements) during a read process.

Abstract: In a non-volatile storage system, one or more substrate channel regions for an unselected NAND string are boosted during programming to inhibit program disturb. A voltage applied to one or more unselected word lines associated with at least a first channel region is increased during a program pulse time period in which a program pulse is applied to a selected word line. The increase can be gradual, in the form of a ramp, or step-wise. The boosting level of the first channel region can be maintained. The increase in the voltage applied to the one or more unselected word lines can vary with temperature as well. Before the program pulse time period, the voltage applied to the one or more unselected word lines can be ramped up at a faster rate for a second, adjacent channel region than for the first channel region, to help isolate the channel regions.

Abstract: Techniques are disclosed herein for programming memory arrays to achieve high program/erase cycle endurance. In some aspects, only selected word lines (WL) are programmed with other WLs remaining unprogrammed. As an example, only the even word lines are programmed with the odd WLs left unprogrammed. After all of the even word lines are programmed and the data block is to be programmed with new data, the block is erased. Later, only the odd word lines are programmed. The data may be transferred to a block that stores multiple bit per memory cell prior to the erase. In one aspect, the data is programmed in a checkerboard pattern with some memory cells programmed and others left unprogrammed. Later, after erasing the data, the previously unprogrammed part of the checkerboard pattern is programmed with remaining cells unprogrammed.

Abstract: Multiple programming processes are performed for a plurality of non-volatile storage elements. Each of the programming processes operate to program at least a subset of the non-volatile storage elements to a respective set of target conditions using program pulses. At least a subset of the programming processes include identifying a program pulse associated with achieving a particular result for a respective programming process and performing one or more sensing operations at one or more alternative results for the non-volatile storage elements. Subsequent programming process are adjusted based on a first alternative result and the identification of the program pulse if the one or more sensing operations determined that greater than a predetermined number of non-volatile storage elements achieved the first alternative result.

Abstract: Multiple programming processes are performed for a plurality of non-volatile storage elements. Each of the programming process operates to program at least a subset of the non-volatile storage elements to a set of target conditions using programming pulses. For at least a subset of the programming processes, a programming pulse associated with achieving an intermediate result for a respective programming process is identified, a pulse increment between programming pulses is decreased for the respective programming process while continuing the respective programming process to program non-volatile storage elements to the respective one or more targets and the identified programming pulse is used to adjust a starting programming voltage for a subsequent programming process.

Abstract: Data is programmed into and read from a set of target memory cells. When reading the data, temperature compensation is provided. The temperature compensation is based on temperature information and the state of one or more neighbor memory cells. In one embodiment, when data is read from set of target memory cells, the system senses the current temperature and determines the differences in temperature between the current temperature and the temperature at the time the data was programmed. If the difference in temperature is greater than a threshold, then the process of reading the data includes providing temperature compensation based on temperature information and neighbor state information. In one alternative, the decision to provide the temperature compensation can be triggered by conditions other than a temperature differential.

Abstract: The unintentional programming of an unselected (or inhibited) non-volatile storage element during a program operation that intends to program another non-volatile storage element is referred to as “program disturb.” A system is proposed for programming and/or reading non-volatile storage that reduces the effect of program disturb. In one embodiment, different verify levels are used for a particular word line (or other grouping of storage elements) during a programming process. In another embodiment, different compare levels are used for a particular word (or other grouping of storage elements) during a read process.

Abstract: Multiple programming processes are performed for a plurality of non-volatile storage elements. Each of the programming process operates to program at least a subset of the non-volatile storage elements to a set of target conditions using programming pulses. For at least a subset of the programming processes, a programming pulse associated with achieving an intermediate result for a respective programming process is identified, a pulse increment between programming pulses is decreased for the respective programming process while continuing the respective programming process to program non-volatile storage elements to the respective one or more targets and the identified programming pulse is used to adjust a starting programming voltage for a subsequent programming process.

Abstract: A method and non-volatile storage system are provided in which programming speed is increased by reducing the number of verify operations, while maintaining a narrow threshold voltage distribution. A programming scheme performs a verify operation at an offset level, before a verify level of a target data state is reached, such as to slow down programming. However, it is not necessary to perform verify operations at both the offset and target levels at all times. In a first programming phase, verify operations are performed for a given data state only at the target verify level. In a second programming phase, verify operations are performed for offset and target verify levels. In a third programming phase, verify operations are again performed only at the target verify level. Transitions between phases can be predetermined, based on programming pulse number, or adaptive.

Abstract: Each of the programming processes operate to program at least a subset of the non-volatile storage elements to a respective set of target conditions using program pulses. At least a subset of the programming processes include identifying a program pulse associated with achieving a particular result for a respective programming process and performing one or more sensing operations at one or more alternative results for the non-volatile storage elements. Subsequent programming process are adjusted based on a first alternative result and the identification of the program pulse if the one or more sensing operations determined that greater than a predetermined number of non-volatile storage elements achieved the first alternative result. Subsequent programming process are adjusted based on the identification of the program pulse if the one or more sensing operations determined that less than a required number of non-volatile storage elements achieved any of the alternative results.

Abstract: When erasing non-volatile storage, a verification process is used between erase operations to determine whether the non-volatile storage has been successfully erased. The verification process includes separately performing verification for different subsets of the non-volatile storage elements.

Abstract: Data is programmed into and read from a set of target memory cells. When reading the data, temperature compensation is provided. The temperature compensation is based on temperature information and the state of one or more neighbor memory cells. In one embodiment, when data is read from set of target memory cells, the system senses the current temperature and determines the differences in temperature between the current temperature and the temperature at the time the data was programmed. If the difference in temperature is greater than a threshold, then the process of reading the data includes providing temperature compensation based on temperature information and neighbor state information. In one alternative, the decision to provide the temperature compensation can be triggered by conditions other than a temperature differential.

Abstract: A non-volatile memory has its cells' thresholds programmed within any one of a first set of voltage bands partitioned by a first set of reference thresholds across a threshold window. Hard bits are obtained when read relative to the first set of reference thresholds. The cells are read at a higher resolution relative to a second set of reference thresholds so as to provide additional soft bits for error correction. The soft bits are generated by a combination of a first modulation of voltage on a current word line WLn and a second modulation of voltage on an adjacent word line WLn+1, as in a reading scheme known as “Direct-Lookahead (DLA)”.

Abstract: A non-volatile memory has its cells' thresholds programmed within any one of a first set of voltage bands partitioned by a first set of reference thresholds across a threshold window. The cells are read at a higher resolution relative to a second set of reference thresholds so as to provide additional soft bits for error correction. The reference thresholds of the second set are set up to be non-uniformly distributed on the threshold window so as to provide higher resolution at designated regions. At the same time they are conducive to be read in groups for soft bits to be read bit-by-bit systematically with a simple algorithm and read circuit and using a minimum of data latches. This is accomplished by relaxing the requirement that the first set of reference threshold is a subset of the second set and that the resulting soft bits are symmetrically distributed about the hard bits.

Abstract: Techniques are disclosed herein for programming memory arrays to achieve high program/erase cycle endurance. In some aspects, only selected word lines (WL) are programmed with other WLs remaining unprogrammed. As an example, only the even word lines are programmed with the odd WLs left unprogrammed. After all of the even word lines are programmed and the data block is to be programmed with new data, the block is erased. Later, only the odd word lines are programmed. The data may be transferred to a block that stores multiple bit per memory cell prior to the erase. In one aspect, the data is programmed in a checkerboard pattern with some memory cells programmed and others left unprogrammed. Later, after erasing the data, the previously unprogrammed part of the checkerboard pattern is programmed with remaining cells unprogrammed.

Abstract: A non-volatile semiconductor storage system is programmed in a manner that reduces program disturb by applying a higher boosting voltage on one or more word lines that are connected to non-volatile storage elements that may be partially programmed.

Abstract: A non-volatile semiconductor storage system is programmed in a manner that reduces program disturb by applying a higher boosting voltage on one or more word lines that are connected to non-volatile storage elements that may be partially programmed.

Abstract: A method for creating NAND flash memory. Source implantations are performed at a first implantation angle to areas between stacked gate structures of a NAND string. Drain implantations are performed at a second implantation angle to areas between the stacked gate structures. The source implantation can include n-type and p-type materials implanted under different angles, and the drain implantation can include n-type and p-type materials implanted under different angles. Or, the source implantation can include multiple n-type implantations under different angles, and the drain implantation can include multiple n-type implantations under different angles.

Abstract: Techniques are disclosed herein for programming memory arrays to achieve high program/erase cycle endurance. In some aspects, only selected word lines (WL) are programmed with other WLs remaining unprogrammed. As an example, only the even word lines are programmed with the odd WLs left unprogrammed. After all of the even word lines are programmed and the data block is to be programmed with new data, the block is erased. Later, only the odd word lines are programmed. The data may be transferred to a block that stores multiple bit per memory cell prior to the erase. In one aspect, the data is programmed in a checkerboard pattern with some memory cells programmed and others left unprogrammed. Later, after erasing the data, the previously unprogrammed part of the checkerboard pattern is programmed with remaining cells unprogrammed.

Abstract: Coupling effects between adjacent floating gates in a non-volatile storage device are reduced in a multi-pass programming operation, while reducing program data storage requirements. In one approach, storage elements are programmed in an out of sequence or zigzag word line order. A particular word line is programmed with a coarse program pass, after which another word line is programmed with a fine program pass, after which the particular word line is read. The particular word line is read before another word line is programmed with a coarse program pass which causes coupling interference to storage elements of the particular word line. The read data is subsequently used to perform a fine program pass for the particular word line. This avoids the need to store program data of multiple word lines concurrently, so that storage hardware can be reduced in size along with power consumption.