Patent application number | Description | Published |
20100309720 | Structure and Method for Shuffling Data Within Non-Volatile Memory Devices - Techniques for the reading and writing of data in multi-state non-volatile memories are described. Data is written into the memory in a binary format, read into the data registers on the memory, and “folded” within the registers, and then written back into the memory in a multi-state format. In the folding operation, binary data from a single word line is folded into a multi-state format and, when rewritten in multi-state form, is written into a only a portion of another word line. A corresponding reading technique, where the data is “unfolded” is also described. The techniques further allow for the data to be encoded with an error correction code (ECC) on the controller that takes into account its eventual multi-state storage prior to transferring the data to the memory to be written in binary form. A register structure allowing such a “folding” operation is also presented. One set of embodiments include a local internal data bus that allows data to between the registers of different read/write stacks, where the internal bus can used in the internal data folding process. | 12-09-2010 |
20110002169 | Bad Column Management with Bit Information in Non-Volatile Memory Systems - Column based defect management techniques are presented. Each column of the memory has an associated isolation latch or register whose value indicates whether the column is defective, but in addition to this information, for columns marked as defective, additional information is used to indicate whether the column as a whole is to be treated as defective, or whether just individual bits of the column are defective. The defective elements can then be re-mapped to a redundant element at either the appropriate bit or column level based on the data. When a column is bad, but only on the bit level, the good bits can still be used for data, although this may be done at a penalty of under programming for some bits, as is described further below. A self contained Built In Self Test (BIST) flow constructed to collect the bit information through a set of column tests is also described. Based on this information, the bad bits can be extracted and re-grouped into bytes by the controller or on the memory to more efficiently use the column redundancy area. | 01-06-2011 |
20120113716 | Structure and Method for Shuffling Data Within Non-Volatile Memory Devices - Techniques for the reading and writing of data in multi-state non-volatile memories are described. Data is written into the memory in a binary format, read into the data registers on the memory, and “folded” within the registers, and then written back into the memory in a multi-state format. In the folding operation, binary data from a single word line is folded into a multi-state format and, when rewritten in multi-state form, is written into a only a portion of another word line. A corresponding reading technique, where the data is “unfolded” is also described. A register structure allowing such a “folding” operation is also presented. One set of embodiments include a local internal data bus that allows data to between the registers of different read/write stacks, where the internal bus can used in the internal data folding process. | 05-10-2012 |
20120297245 | Bad Column Management with Bit Information in Non-Volatile Memory Systems - Column based defect management techniques are presented. Each column of the memory has an associated isolation latch or register whose value indicates whether the column is defective, but in addition to this information, for columns marked as defective, additional information is used to indicate whether the column as a whole is to be treated as defective, or whether just individual bits of the column are defective. The defective elements can then be re-mapped to a redundant element at either the appropriate bit or column level based on the data. When a column is bad, but only on the bit level, the good bits can still be used for data. | 11-22-2012 |
20130100740 | Compact Sense Amplifier for Non-Volatile Memory Suitable for Quick Pass Write - A compact and versatile sense amp is presented. Among its other features this sense amp arrangement provides a way to pre-charge bit lines while doing data scanning. Another feature is that the sense amp circuit can provide a way to set three different bit line levels used in the quick pass write (QPW) technique using dynamic latch, where quick pass write is a technique where cells along a given word line selected for programming can be enabled, inhibited, or partially inhibited for programming. Also, it can provide a convenient way to measure the cell current. | 04-25-2013 |
20130100744 | Compact Sense Amplifier for Non-Volatile Memory - A compact and versatile sense amp is presented. Among its other features this sense amp arrangement provides a way to pre-charge bit lines while doing data scanning. Another feature is that the sense amp circuit can provide a way to set three different bit line levels used in the quick pass write (QPW) technique using dynamic latch, where quick pass write is a technique where cells along a given word line selected for programming can be enabled, inhibited, or partially inhibited for programming. Also, it can provide a convenient way to measure the cell current. | 04-25-2013 |
20140133229 | BIT LINE RESISTANCE COMPENSATION - Methods for compensating for variations in bit line resistance during sensing of memory cells are described. The variations in bit line resistance may occur die-to-die or plane-to-plane on the same die. In some embodiments, for each die or memory plane on a die, a plurality of bit line read voltages associated with a plurality of zones may be determined based on sensing criteria. The sensing criteria may comprise a number of fail bits. Each zone of the plurality of zones may be associated with a memory array region within a die or memory plane. Prior to performing a read or verify operation on a group of memory cells, a bit line read voltage used during sensing of the group of memory cells may be determined based on the plurality of bit line read voltages and a zone associated with the group of memory cells. | 05-15-2014 |
20140133230 | BIT LINE RESISTANCE COMPENSATION - Methods for compensating for variations in bit line resistance during sensing of memory cells are described. The variations in bit line resistance may occur die-to-die or plane-to-plane on the same die. In some embodiments, for each die or memory plane on a die, a plurality of bit line read voltages associated with a plurality of zones may be determined based on sensing criteria such as a number of fail bits. Each zone of the plurality of zones may be associated with a memory array region within a memory plane. Within each zone, different bit line read voltages may be applied to different bit line groupings in order to compensate for systematic variations in bit line resistance between neighboring bit lines due to the use of multiple patterning lithography techniques such as spacer-based double patterning. | 05-15-2014 |
20140133231 | BIT LINE RESISTANCE COMPENSATION - Methods for compensating for variations in bit line resistance in non-volatile memories are described. In some embodiments, use of multiple patterning lithography for forming bit lines may lead to systematic variations in bit line resistance between groups of bit lines within a memory array. For example, in some cases, every fourth bit line of four neighboring (or adjacent) bit lines may be formed differently than the other three bit lines within a group of four neighboring bit lines. In one embodiment, bit line segment swapping may be used between blocks within a memory array in order to mitigate variations in bit line resistance. In another embodiment, each group of adjacent bit line segments may be offset (or staggered) per block such that the local routing necessary to connect bit line segments into bit lines may be simplified. | 05-15-2014 |
20140219023 | Bad Column Management with Bit Information in Non-Volatile Memory Systems - Column based defect management techniques are presented. Each column of the memory has an associated isolation latch or register whose value indicates whether the column is defective, but in addition to this information, for columns marked as defective, additional information is used to indicate whether the column as a whole is to be treated as defective, or whether just individual bits of the column are defective. The defective elements can then be re-mapped to a redundant element at either the appropriate bit or column level based on the data. When a column is bad, but only on the bit level, the good bits can still be used for data, although this may be done at a penalty of under programming for some bits, as is described further below. A self contained Built In Self Test (BIST) flow constructed to collect the bit information through a set of column tests is also described. Based on this information, the bad bits can be extracted and re-grouped into bytes by the controller or on the memory to more efficiently use the column redundancy area. | 08-07-2014 |
20140269100 | SHARED BIT LINE STRING ARCHITECTURE - Methods for programming and reading memory cells using a shared bit line string architecture are described. In some embodiments, memory cells and select devices may correspond with transistors including a charge storage layer. In some cases, the charge storage layer may be conductive (e.g., a polysilicon layer as used in a floating gate device) or non-conductive (e.g., a silicon nitride layer as used in a SONOS device). In some embodiments, selection of a memory cell in a first string of a pair of strings may include setting an SEO transistor into a conducting state and setting an SGD line controlling drain-side select transistors to a voltage that is greater than a first threshold voltage associated with a first drain-side select transistor of the first string and less than a second threshold voltage associated with a second drain-side select transistor of a second string of the pair of strings. | 09-18-2014 |