Patent application number | Description | Published |
20080291735 | METHOD FOR USING TRANSITIONAL VOLTAGE DURING PROGRAMMING OF NON-VOLATILE STORAGE - 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. | 11-27-2008 |
20080291736 | NON-VOLATILE STORAGE SYSTEM WITH TRANSITIONAL VOLTAGE DURING PROGRAMMING - 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. | 11-27-2008 |
20090016113 | NON-DIFFUSION JUNCTION SPLIT-GATE NONVOLATILE MEMORY CELLS AND ARRAYS, METHODS OF PROGRAMMING, ERASING, AND READING THEREOF, AND METHODS OF MANUFACTURE - Nonvolatile flash memory systems and methods are disclosed having a semiconductor substrate of a first conductivity type, including non-diffused channel regions through which electron flow is induced by application of voltage to associated gate elements. A plurality of floating gates are spaced apart from one another and each insulated from the channel region. A plurality of control gates are spaced apart from one another and insulated from the channel region, with each control gate being located between a first floating gate and a second floating gate and capacitively coupled thereto to form a subcell. A plurality of spaced-apart assist gates are insulated from the channel region, with each assist gate being located between and insulated from adjacent subcells. The channel is formed of three regions, two beneath adjacent control gate elements as well as a third region between the first two and beneath an associated assist gate. | 01-15-2009 |
20090059660 | REDUCING THE IMPACT OF INTERFERENCE DURING PROGRAMMING - A system for programming non-volatile storage is proposed that reduces the impact of interference from the boosting of neighbors. Memory cells are divided into two or more groups. In one example, the memory cells are divided into odd and even memory cells; however, other groupings can also be used. Prior to a first trigger, a first group of memory cells are programmed together with a second group of memory cells. Subsequent to the first trigger and prior to a second trigger, the first group of memory cells are programmed separately from the second group of memory cells. Subsequent to the second trigger, the first group of memory cells are programmed together with the second group of memory cells. Before and after both triggers, the first group of memory cells are verified together with the second group of memory cells. | 03-05-2009 |
20090080245 | OFFSET NON-VOLATILE STORAGE - 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. | 03-26-2009 |
20090080263 | REDUCING PROGRAMMING VOLTAGE DIFFERENTIAL NONLINEARITY IN NON-VOLATILE STORAGE - A corrective action is taken to adjust for nonlinearities in a program voltage which is applied to a selected word line in a memory device. The nonlinearities result in a non-uniform program voltage step size which can cause over programming or slow programming. A digital to analog converter (DAC) which provides the program voltages can have a nonlinear output, such as when certain code words are input to the DAC. The memory device can be tested beforehand to determine where the nonlinearities occur, and configured to take corrective action when the corresponding code words are input. For example, the DAC may have a nonlinear output when a rollover code word is input, e.g., a when a string of least significant bits in successive code words change from 1's to 0's. The corrective action can include repeating a prior program pulse or adjusting a duration of a program pulse. | 03-26-2009 |
20090086542 | High Voltage Generation and Control in Source-Side Injection Programming of Non-Volatile Memory - Non-volatile memory is programmed using source side hot electron injection. To generate a high voltage bit line for programming, the bit line corresponding to a selected memory cell is charged to a first level using a first low voltage. A second low voltage is applied to unselected bit lines adjacent to the selected bit line after charging. Because of capacitive coupling between the adjacent bit lines and the selected bit line, the selected bit line is boosted above the first voltage level by application of the second low voltage to the unselected bit lines. The column control circuitry for such a memory array does not directly apply the high voltage and thus, can be designed to withstand lower operating voltages, permitting low operating voltage circuitry to be used. | 04-02-2009 |
20090161433 | Regulation of Source Potential to Combat Cell Source IR Drop - Techniques are presented for dealing with possible source line bias is an error introduced by a non-zero resistance in the ground loop of the read/write circuits of a non-volatile memory. The error is caused by a voltage drop across the resistance of the source path to the chip's ground when current flows. For this purpose, the memory device includes a source potential regulation circuit, including an active circuit element having a first input connected to a reference voltage and having a second input connected as a feedback loop that is connectable to the aggregate node from which the memory cells of a structural block have their current run to ground. A variation includes a non-linear resistive element connectable between the aggregate node and ground. | 06-25-2009 |
20090323429 | PROGRAMMING ALGORITHM TO REDUCE DISTURB WITH MINIMAL EXTRA TIME PENALTY - Programming time is reduced in a non-volatile memory in a multi-pass programming process. In a first programming pass, high state cells are programmed by a sequence of program pulses to identify fast and slow high state cells, while lower state cells are locked out from programming. Once identified, the fast high state cells are temporarily locked out from programming while the slow high state cells continue being programmed to their final intended state. Further, the program pulses are sharply stepped up to program the slow high state cells. In a second programming pass, the fast high state cells are programmed along with the other, lower state cells, until they all reach their respective intended states. A time savings is realized compared to approaches in which all high state cells are programmed in the first programming pass. | 12-31-2009 |
20100006915 | DIELECTRIC LAYER ABOVE FLOATING GATE FOR REDUCING LEAKAGE CURRENT - A memory system is disclosed that includes a set of non-volatile storage elements. A given memory cell has a dielectric cap above the floating gate. In one embodiment, the dielectric cap resides between the floating gate and a conformal IPD layer. The dielectric cap reduces the leakage current between the floating gate and a control gate. The dielectric cap achieves this reduction by reducing the strength of the electric field at the top of the floating gate, which is where the electric field would be strongest without the dielectric cap for a floating gate having a narrow stem. | 01-14-2010 |
20100009503 | METHOD OF FORMING DIELECTRIC LAYER ABOVE FLOATING GATE FOR REDUCING LEAKAGE CURRENT - A method of fabricating a memory system is disclosed that includes a set of non-volatile storage elements. The method includes forming a floating gate having a top and at least two sides. A dielectric cap is formed at the top of the floating gate. An inter-gate dielectric layer is formed around the at least two sides of the floating gate and over the top of the dielectric cap. A control gate is formed over the top of the floating gate, the inter-gate dielectric layer separates the control gate from the floating gate. In one aspect, forming the dielectric cap includes implanting oxygen in the top of the floating gate and heating the floating gate to form the dielectric cap from the implanted oxygen and silicon from which the floating gate was formed. | 01-14-2010 |
20100220533 | NON-DIFFUSION JUNCTION SPLIT-GATE NONVOLATILE MEMORY CELLS AND ARRAYS, METHODS OF PROGRAMMING, ERASING, AND READING THEREOF, AND METHODS OF MANUFACTURE - Nonvolatile flash memory systems and methods are disclosed having a semiconductor substrate of a first conductivity type, including non-diffused channel regions through which electron flow is induced by application of voltage to associated gate elements. A plurality of floating gates are spaced apart from one another and each insulated from the channel region. A plurality of control gates are spaced apart from one another and insulated from the channel region, with each control gate being located between a first floating gate and a second floating gate and capacitively coupled thereto to form a subcell. A plurality of spaced-apart assist gates are insulated from the channel region, with each assist gate being located between and insulated from adjacent subcells. The channel is formed of three regions, two beneath adjacent control gate elements as well as a third region between the first two and beneath an associated assist gate. | 09-02-2010 |
20100259987 | Two Pass Erase For Non-Volatile Storage - Techniques are disclosed herein for erasing non-volatile memory cells. The memory cells are erased using a trial erase pulse. A suitable magnitude for a second pulse is determined based on the magnitude of the trial erase pulse and data collected about the threshold voltage distribution after the trial erase. The second erase pulse is used to erase the memory cells. In one implementation, the threshold voltages of the memory cells are not verified after the second erase. Soft programming after the second erase may be performed. The magnitude of the soft programming pulse may be determined based on the trial erase pulse. In one implementation, the memory cells' threshold voltages are not verified after the soft programming. Limiting the number of erase pulses and soft programming pulses saves time and power. Determining an appropriate magnitude for the second erase pulse minimizes or eliminates over-erasing. | 10-14-2010 |
20100259988 | OFFSET NON-VOLATILE STORAGE - 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. | 10-14-2010 |
20100259989 | OFFSET NON-VOLATILE STORAGE - 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. | 10-14-2010 |
20100261317 | OFFSET NON-VOLATILE STORAGE - 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. | 10-14-2010 |
20100277983 | Two Pass Erase For Non-Volatile Storage - Techniques are disclosed herein for erasing non-volatile memory cells. A subset of the memory cells are pre-conditioned prior to erase. The pre-conditioning alters the threshold voltage of the memory cells in a way that may help make later calculations more accurate. As an example, memory cells along a single word line might be pre-conditioned. After the pre-conditioning, the memory cells are erased using a trial erase pulse. A suitable magnitude for a second pulse is determined based on the magnitude of the trial erase pulse and data collected about the threshold voltage distribution after the trial erase. The second erase pulse is used to erase the memory cells. Determining an appropriate magnitude for the second erase pulse minimizes or eliminates over-erasing. | 11-04-2010 |
20100332923 | SYSTEM AND METHOD RESPONSIVE TO A RATE OF CHANGE OF A PERFORMANCE PARAMETER OF A MEMORY - Systems and methods are disclosed that are responsive to a rate of change of a performance parameter of a memory. In a particular embodiment, a rate of change of a performance parameter of a non-volatile memory is determined. The rate of change is compared to a threshold, and an action is performed in response to determining that the rate of change satisfies the threshold. | 12-30-2010 |
20110075477 | REDUCING THE IMPACT OF INTERFERENCE DURING PROGRAMMING - A system for programming non-volatile storage is proposed that reduces the impact of interference from the boosting of neighbors. Memory cells are divided into two or more groups. In one example, the memory cells are divided into odd and even memory cells; however, other groupings can also be used. Prior to a first trigger, a first group of memory cells are programmed together with a second group of memory cells. Subsequent to the first trigger and prior to a second trigger, the first group of memory cells are programmed separately from the second group of memory cells. Subsequent to the second trigger, the first group of memory cells are programmed together with the second group of memory cells. Before and after both triggers, the first group of memory cells are verified together with the second group of memory cells. | 03-31-2011 |
20110134694 | High Voltage Generation And Control In Source-Side Injection Programming Of Non-Volatile Memory - Non-volatile memory is programmed using source side hot electron injection. To generate a high voltage bit line for programming, the bit line corresponding to a selected memory cell is charged to a first level using a first low voltage. A second low voltage is applied to unselected bit lines adjacent to the selected bit line after charging. Because of capacitive coupling between the adjacent bit lines and the selected bit line, the selected bit line is boosted above the first voltage level by application of the second low voltage to the unselected bit lines. The column control circuitry for such a memory array does not directly apply the high voltage and thus, can be designed to withstand lower operating voltages, permitting low operating voltage circuitry to be used. | 06-09-2011 |
20110260235 | P-TYPE CONTROL GATE IN NON-VOLATILE STORAGE AND METHODS FOR FORMING SAME - Non-voltage storage and techniques for fabricating non-volatile storage are disclosed. In some embodiments, at least a portion of the control gates of non-volatile storage elements are formed from p-type polysilicon. In one embodiment, a lower portion of the control gate is p-type polysilicon. The upper portion of the control gate could be p-type polysilicon, n-type polysilicon, metal, metal nitride, etc. P-type polysilicon in the control gate may not deplete even at high Vpgm. Therefore, a number of problems that could occur if the control gate depleted are mitigated. For example, a memory cell having a control gate that is at least partially p-type polysilicon might be programmed with a lower Vpgm than a memory cell formed from n-type polysilicon. | 10-27-2011 |
20110310671 | REDUCING THE IMPACT OF INTERFERENCE DURING PROGRAMMING - A system for programming non-volatile storage is proposed that reduces the impact of interference from the boosting of neighbors. Memory cells are divided into two or more groups. In one example, the memory cells are divided into odd and even memory cells; however, other groupings can also be used. Prior to a first trigger, a first group of memory cells are programmed together with a second group of memory cells. Subsequent to the first trigger and prior to a second trigger, the first group of memory cells are programmed separately from the second group of memory cells. Subsequent to the second trigger, the first group of memory cells are programmed together with the second group of memory cells. Before and after both triggers, the first group of memory cells are verified together with the second group of memory cells. | 12-22-2011 |
20120008384 | Detection of Word-Line Leakage in Memory Arrays - Techniques and corresponding circuitry are presented for the detection of wordline leakage in a memory array. In an exemplary embodiment, a capacitive voltage divider is used to translate the high voltage drop to low voltage drop that can be compared with a reference voltage to determine the voltage drop due to leakage. An on-chip self calibration method can help assure the accuracy of this technique for detecting leakage limit. | 01-12-2012 |
20120250414 | REDUCING NEIGHBOR READ DISTURB - Methods and devices for sensing non-volatile storage devices in a way that reduces read disturb are disclosed. Techniques are used to reduce read disturb on memory cells that are neighbors to selected memory cells. For example, on a NAND string, the memory cells that are next to the selected memory cell presently being read may benefit. In one embodiment, when reading memory cells on a selected word line WLn, Vread+Delta is applied to WLn+2 and WLn−2. Applying Vread+Delta to the second neighbor word line may reduce read disturb to memory cells on the neighbor word line WLn+1. | 10-04-2012 |
20120300550 | Ramping Pass Voltage To Enhance Channel Boost In Memory Device, With Optional Temperature Compensation - 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. | 11-29-2012 |
20130028021 | Simultaneous Sensing of Multiple Wordlines and Detection of NAND Failures - Techniques for a post-write read are presented. In an exemplary embodiment, a combined simultaneous sensing of multiple word lines is used in order to identify a problem in one or more of these word lines. That is, sensing voltages are concurrently applied to the control gates of more than one memory cell whose resultant conductance is measured on the same bit line. The combined sensing result is use for measuring certain statistics of the cell voltage distribution (CVD) of multiple word lines and comparing it to the expected value. In case the measured statistics are different than expected, this may indicate that one or more of the sensed word lines may exhibit a failure and more thorough examination of the group of word lines can be performed. | 01-31-2013 |
20130070524 | ON CHIP DYNAMIC READ FOR NON-VOLATILE STORAGE - Dynamically determining read levels on chip (e.g., memory die) is disclosed herein. One method comprises reading a group of non-volatile storage elements on a memory die at a first set of read levels. Results of the two most recent of the read levels are stored on the memory die. A count of how many of the non-volatile storage elements in the group showed a different result between the reads for the two most recent read levels is determined. The determining is performed on the memory die using the results stored on the memory die. A dynamic read level is determined for distinguishing between a first pair of adjacent data states of the plurality of data states based on the read level when the count reaches a pre-determined criterion. Note that the read level may be dynamically determined on the memory die. | 03-21-2013 |
20130128666 | Scrub Techniques for Use with Dynamic Read - The decision on whether to refresh or retire a memory block is based on the set of dynamic read values being used. In a memory system using a table of dynamic read values, the table is configured to include how to handle read error (retire, refresh) in addition to the read parameters for the different dynamic read cases. In a refinement, the read case number can used to prioritize blocks selected for refresh or retire. In cases where the read scrub is to be made more precise, multiple dynamic read cases can be applied. Further, which cases are applied can be intelligently selected. | 05-23-2013 |
20130148425 | ON CHIP DYNAMIC READ FOR NON-VOLATILE STORAGE - Dynamically determining read levels on chip (e.g., memory die) is disclosed herein. One method comprises reading a group of non-volatile storage elements on a memory die at a first set of read levels. Results of the two most recent of the read levels are stored on the memory die. A count of how many of the non-volatile storage elements in the group showed a different result between the reads for the two most recent read levels is determined. The determining is performed on the memory die using the results stored on the memory die. A dynamic read level is determined for distinguishing between a first pair of adjacent data states of the plurality of data states based on the read level when the count reaches a pre-determined criterion. Note that the read level may be dynamically determined on the memory die. | 06-13-2013 |
20130219107 | WRITE ABORT RECOVERY THROUGH INTERMEDIATE STATE SHIFTING - A memory system or flash card may include a multi-level cell block with multiple states. Before the upper page is written, an intermediate state may be shifted to prevent or minimize overlapping of the states from the corresponding lower page. A write abort during the writing of the upper page will not result in a loss of data from the corresponding lower page. | 08-22-2013 |
20130314987 | Ramping Pass Voltage To Enhance Channel Boost In Memory Device - In a non-volatile storage system, first and second substrate channel regions for an unselected NAND string are boosted during programming to inhibit program disturb. The first and second substrate channel regions are created on either side of an isolation word line. During a program pulse time period in which a program pulse is applied to a selected word line, a voltage applied to an unselected word line which extends directly over the second channel region is stepped up to a respective pre-program pulse voltage, at a faster rate at which a voltage applied to an unselected word line which extends directly over the first channel region is stepped up to a respective pre-program pulse voltage. This helps improve the isolation between the channel regions. | 11-28-2013 |
20130336059 | BLOCK LEVEL GRADING FOR RELIABILITY AND YIELD IMPROVEMENT - A system for grading blocks may be used to improve memory usage. Blocks of memory, such as on a flash card, may be graded on a sliding scale that may identify a level of “goodness” or a level of “badness” for each block rather than a binary good or bad identification. This grading system may utilize at least three tiers of grades which may improve efficiency by better utilizing each block based on the individual grades for each block. The block leveling grading system may be used for optimizing the competing needs of minimizing yield loss while minimizing testing defect escapes. | 12-19-2013 |
20130341700 | P-TYPE CONTROL GATE IN NON-VOLATILE STORAGE - Non-voltage storage and techniques for fabricating non-volatile storage are disclosed. In some embodiments, at least a portion of the control gates of non-volatile storage elements are formed from p-type polysilicon. In one embodiment, a lower portion of the control gate is p-type polysilicon. The upper portion of the control gate could be p-type polysilicon, n-type polysilicon, metal, metal nitride, etc. P-type polysilicon in the control gate may not deplete even at high Vpgm. Therefore, a number of problems that could occur if the control gate depleted are mitigated. For example, a memory cell having a control gate that is at least partially p-type polysilicon might be programmed with a lower Vpgm than a memory cell formed from n-type polysilicon. | 12-26-2013 |
20130346805 | FLASH MEMORY WITH TARGETED READ SCRUB ALGORITHM - A method and system have been described for counteracting and correcting for read disturb effects in blocks of flash memory. The method may include the step of a controller of the memory system performing a read scrub scan on only a portion of one targeted word line in a block at desired intervals. The controller may calculate whether a read scrub scan is necessary based on a probabilistic determination that is calculated in response to each received host read command. The controller may then place a block associated with the targeted word line into a refresh queue if a number of errors are detected in the targeted word line that meets or exceeds a predetermined threshold. The block refresh process may include copying the data from the block into a new block during a background operation. | 12-26-2013 |
20140029357 | Non-Volatile Memory and Method with Peak Current Control - A non-volatile memory with multiple memory dice manages simultaneous operations so as to not exceed a system power capacity. A load signal bus is pulled up with a strength proportional to the system power capacity. Each die has a driver to pull down the bus by an amount corresponding to its degree of power need as estimated by a state machine of the die. The bus therefore provides a load signal that serves as arbitration between the system power capacity and the cumulative loads of the individual dice. The load signal is therefore at a high state when the system power capacity is not exceeded; otherwise it is at a low state. When a die wishes to perform an operation and requests a certain amount of power, it drives the bus accordingly and its state machine either proceeds with the operation or not, depending on the load signal. | 01-30-2014 |
20140040681 | DEVICE BASED WEAR LEVELING - A system for improving the management and usage of blocks based on intrinsic endurance may be used to improve memory usage for flash memory, such as a memory card. The overall card endurance may be extended by cycling blocks with higher intrinsic endurance over the lowest endurance target of the worst block. This may be accomplished by managing blocks with different intrinsic endurance values internally or by partitioning the blocks with different intrinsic endurance values externally for different usage. | 02-06-2014 |
20140063940 | ON CHIP DYNAMIC READ LEVEL SCAN AND ERROR DETECTION FOR NONVOLATILE STORAGE - Techniques for efficiently programming non-volatile storage are disclosed. A second page of data may efficiently be programmed into memory cells that already store a first page. Data may be efficiently transferred from single bit cells to multi-bit cells. Memory cells are read using at least two different read levels. The results are compared to determine a count how many memory cells showed a different result between the two reads. If the count is less than a threshold, then data from the memory cells is stored into a set of data latches without attempting to correct for misreads. If the count is not less than the threshold, then data from the memory cells is stored into the set of data latches with attempting to correct for misreads. A programming operation may be performed based on the data stored in the set of data latches. | 03-06-2014 |
20140075252 | Erased Page Confirmation in Multilevel Memory - In a multi-level cell memory array, a flag that indicates that a logical page is unwritten is subject to a two-step verification. In a first verification step, the logical page is read, and ECC decoding is applied. If the first verification step indicates that the logical page is unwritten, then a second verification step counts the number of cells that are not in an unwritten condition. | 03-13-2014 |
20140098610 | Erased State Reading - Memory cells that are indicated as being erased but are suspected of being partially programmed may be subject to a verification scheme that first performs a conventional read and then, if the conventional read does not indicate partial programming, performs a second read using lower read-pass voltage on at least one neighboring word line. | 04-10-2014 |
20140215128 | ADAPTIVE INITIAL PROGRAM VOLTAGE FOR NON-VOLATILE MEMORY - When programming a set of non-volatile storage elements using a multi-stage programming process, a series of programming pulses are used for each stage. The magnitude of the initial program pulse for the current stage being performed is dynamically set as a function of the number of program pulses used for the same stage of the multi-stage programming process when programming non-volatile storage elements connected to on one or more previously programmed word lines. | 07-31-2014 |
20140254262 | INTERNAL DATA LOAD FOR NON-VOLATILE STORAGE - Techniques are disclosed herein for performing an Internal Data Load (IDL) to sense non-volatile storage elements. Read pass voltages that are applied to the two neighbor word lines to a selected word line may be adjusted to result in a more accurate IDL. The read pass voltage for one neighbor may be increased by some delta voltage, whereas the read pass voltage for the other neighbor may be decreased by the same delta voltage. In one aspect, programming of an upper page of data into a word line that neighbors a target word line is halted to allow lower page data in the target memory cells to be read using an IDL and preserved in data latches while programming the upper page in the neighbor word completes. Preservation of the lower page data provides for a cleaner lower page when later programming the upper page into the target memory cells. | 09-11-2014 |
20140254264 | Defect Or Program Disturb Detection With Full Data Recovery Capability - A programming operation for a set of non-volatile storage elements determines whether the storage elements have been programmed properly after a program-verify test is passed and a program status=pass is issued. Write data is reconstructed from sets of latches associated with the storage elements using logical operations optionally one or more reconstruction read operations. Normal read operations are also performed to obtain read data. A number of mismatches between the read data and the reconstructed write data is determined, and determination is made as to whether re-writing of the write data is required based on the number of the mismatches. | 09-11-2014 |
20140254272 | SIMULTANEOUS SENSING OF MULTIPLE WORDLINES AND DETECTION OF NAND FAILURES - Techniques for a post-write read are presented. In an exemplary embodiment, a combined simultaneous sensing of multiple word lines is used in order to identify a problem in one or more of these word lines. That is, sensing voltages are concurrently applied to the control gates of more than one memory cell whose resultant conductance is measured on the same bit line. The combined sensing result is use for measuring certain statistics of the cell voltage distribution (CVD) of multiple word lines and comparing it to the expected value. In case the measured statistics are different than expected, this may indicate that one or more of the sensed word lines may exhibit a failure and more thorough examination of the group of word lines can be performed. | 09-11-2014 |
20140347925 | INTERNAL DATA LOAD FOR NON-VOLATILE STORAGE - Techniques are disclosed herein for performing an Internal Data Load (IDL) to sense non-volatile storage elements. Read pass voltages that are applied to the two neighbor word lines to a selected word line may be adjusted to result in a more accurate IDL. The read pass voltage for one neighbor may be increased by some delta voltage, whereas the read pass voltage for the other neighbor may be decreased by the same delta voltage. In one aspect, programming of an upper page of data into a word line that neighbors a target word line is halted to allow lower page data in the target memory cells to be read using an IDL and preserved in data latches while programming the upper page in the neighbor word completes. Preservation of the lower page data provides for a cleaner lower page when later programming the upper page into the target memory cells. | 11-27-2014 |
20150023116 | NON-VOLATILE MEMORY AND METHOD WITH PEAK CURRENT CONTROL - A non-volatile memory with multiple memory dice manages simultaneous operations so as to not exceed a system power capacity. A load signal bus is pulled up with a strength proportional to the system power capacity. Each die has a driver to pull down the bus by an amount corresponding to its degree of power need as estimated by a state machine of the die. The bus therefore provides a load signal that serves as arbitration between the system power capacity and the cumulative loads of the individual dice. The load signal is therefore at a high state when the system power capacity is not exceeded; otherwise it is at a low state. When a die wishes to perform an operation and requests a certain amount of power, it drives the bus accordingly and its state machine either proceeds with the operation or not, depending on the load signal. | 01-22-2015 |
20150058698 | DATA RECOVERY FROM BLOCKS WITH GATE SHORTS - A storage module may include a NAND-type flash memory array and one or more controllers configured to increase gate bias voltage levels applied to gates in the memory array to overcome possible gate shorts and recover data identified as being uncorrectable. The increased gate bias voltages may be applied to gates of a single type of transistor or to different types of transistors in the memory array, including drain select transistors, source select transistors, or floating gate transistors. | 02-26-2015 |