Abstract: A non-volatile memory device includes addressable sectors and an ancillary volatile memory array. The ancillary volatile memory array stores protection information in the addressable sectors that is not accessible to users of the memory. The protection information is downloaded in the memory array at every power-on of the memory device. The memory array includes at least two additional columns containing preset logic information physically adjacent to the columns containing the downloaded information. A logic circuit is input with the logic information read from the additional check columns for checking the integrity of the preset logic information content of the check columns. An integrity check signal is output by the logic circuit.

Abstract: An embodiment of the present invention includes a nonvolatile memory system comprising nonvolatile memory for storing sector information, the nonvolatile memory being organized into blocks with each block including a plurality of sectors, each sector identified by a logical block address and for storing sector information. A controller is coupled to the nonvolatile memory for writing sector information to the latter and for updating the sector information, wherein upon updating sector information, the controller writes to the next free or available sector(s) of a block such that upon multiple re-writes or updating of sector information, a plurality of blocks are substantially filled with sector information and upon such time, the controller rearranges the updated sector information in sequential order based on their respective logical block addresses thereby increasing system performance and improving manufacturing costs of the controller.

Abstract: The non-volatile memory cell is comprised of the series integration of a fixed threshold element and a bistable element. The fixed threshold element is formed over a substrate with a gate insulator layer and an access gate having a nitride layer. The bistable element is formed adjacent to the fixed threshold element by a tunnel insulator over the substrate, a charge trapping layer over the tunnel insulator, a charge blocking layer over the trapping layer, and a control gate, having a nitride layer, over the charge blocking layer. In one embodiment, the gate insulator, tunnel insulator and charge trapping layers are all SiON with thicknesses that depend on the designed programming voltage. The control gate can be formed overlapping the access gate or the access gate can be formed overlapping the control gate.

Abstract: Solid state storage devices and methods for operation of solid state storage devices are disclosed. In one such method, a master memory controller is comprised of a plurality of memory communication channels. At least one of the memory communication channels is used to communicate with one or more slave memory controllers. The master and slave memory controllers can operate in a parallel operation mode to communicate with a plurality of memory devices coupled to the memory communication channels of each memory controller.

Abstract: Methods for sensing, method for programming, memory devices, and memory systems are disclosed. In one such method for sensing, a counting circuit generates a count output and a translated count output. The count output is converted into a time varying voltage that biases a word line coupled to memory cells being sensed. Target data for each memory cell is stored in a data cache associated with that particular memory cell. When it is detected that a memory cell has turned on, the translated count output associated with the count output that is indicative of the voltage level that turned on the memory cell is compared to the target data. The comparison determines the state of the memory cell.

Abstract: Methods for small unit internal verify read operation and a memory device are disclosed. In one such method, expected data is programmed into a grouping of columns of memory cells (e.g., memory block). Mask data is loaded into a third dynamic data cache of three dynamic data caches. The expected data is loaded into a second data cache. After a read operation of programmed columns of memory cells, the read data is compared to the expected data and error bit indicators are stored in the second data cache in the error bit locations. The second data cache is masked with the mask data so that only those error bits that are unmasked are counted. If the number of unmasked error bit indicators is greater than a threshold, the memory block is marked as unusable.

Abstract: Memory arrays and methods of their formation are disclosed. One such memory array has memory-cell strings are formed adjacent to separated substantially vertical, adjacent semiconductor structures, where the separated semiconductor structures couple the memory cells of the respective strings in series. For some embodiments, two dielectric pillars may be formed from a dielectric formed in a single opening, where each of the dielectric pillars has a pair of memory-cell strings adjacent thereto and where at least one memory cell of one of the strings on one of the pillars and at least one memory cell of one of the strings on the other pillar are commonly coupled to an access line.

Abstract: Methods of programming a memory, memory devices, and systems are disclosed, for example. In one such method, each data line of a memory to be programmed is biased differently depending upon whether one or more of the data lines adjacent the data line are inhibited. In one such system, a connection circuit provides data corresponding to the inhibit status of a target data line to page buffers associated with data lines adjacent to the target data line.

Abstract: A multiple partition memory and architecture for concurrent operations reduces circuit overhead by providing a common read sense amplifier and program path for multiple partitions. Long separate datalines for read and algorithm operations allow concurrent operation and blockout of multiple operations in a single block of the memory.

Abstract: One-transistor memory devices facilitate nonvolatile data storage through the manipulation of oxygen vacancies within a trapping layer of a field-effect transistor (FET), thereby providing control and variation of threshold voltages of the transistor. Various threshold voltages may be assigned a data value, providing the ability to store one or more bits of data in a single memory cell. To control the threshold voltage, the oxygen vacancies may be manipulated by trapping electrons within the vacancies, freeing trapped electrons from the vacancies, moving the vacancies within the trapping layer and annihilating the vacancies.

Abstract: Memories and their memory arrays are disclosed. One such memory array has a string of series-coupled memory cells, a non-programmable select gate coupled in series to a first end of the string of series-coupled memory cells, and a programmable select gate coupled in series to a second end of the string of series-coupled memory cells.

Abstract: A mass storage device, system, and method for operating a mass storage device are disclosed. In one such mass storage device, a host bus adaptor emulates a SATA mass storage device over a PCIe interface with a host system. The host system generates commands with the PCIe mass storage device in the same format as if communicating with a SATA mass storage device. The PCIe mass storage device responds in the same SATA format.

Abstract: Methods of programming memory cells are disclosed. In at least one embodiment, programming is accomplished by applying a first set of programming pulses to program to an initial threshold voltage, and applying a second set of programming pulses to program to a final threshold voltage.

Abstract: Methods for programming a memory device, memory devices configured to perform the disclosed programming methods, and memory systems having a memory device configured to perform the disclosed programming methods are provided. According to at least one such method, multiple pages of memory cells are inhibited during a programming operation such that memory cells enabled for programming are separated by two or more inhibited memory cells of the same row of memory cells regardless of the intended pattern of data states to be programmed into that row of memory cells.

Abstract: Methods for multiple level program verify, memory devices, and memory systems are provided. In one such method, a series of programming pulses are applied to a memory cell to be programmed. A program verify pulse, at an initial program verify voltage, is applied to the memory cell after each programming pulse. The initial program verify voltage is a verify voltage that has been increased by a quick charge loss voltage. The quick charge loss voltage is subtracted from the initial program verify voltage after either a programming pulse has reached a certain reference voltage or a quantity of programming pulses has reached a pulse count threshold.

Abstract: A programming method and memory structure for preventing punch-through in a short channel source-side select gate structure includes adjusting voltages on the selected and unselected bitlines, and the program, pass, and select gate voltages.

Abstract: Voltage switches, memory devices, memory systems, and methods for switching are disclosed. One such voltage switch uses a pair of switch circuits coupled in series, each switch circuit being driven by a level shift circuit. Each switch circuit uses a group of series coupled transistors with a parallel control transistor where the number of transistors in each group may be determined by an expected switch input voltage and a maximum allowable voltage drop for each transistor. A voltage of a particular state of an enable signal is shifted up to the switch input voltage by the level shift circuits. The particular state of the enable signal turns on the voltage switch such that the switch output voltage is substantially equal to the switch input voltage.

Abstract: Memory devices where ends of series-coupled strings of memory cells are selectively coupled to different bit lines may facilitate increased memory densities, reduced fabrication steps and faster read operations when compared to traditional NAND memory array architectures. Programming and erasing of the memory cells can be accomplished in the same manner as a traditional NAND memory array. However, reading of the memory cells may be accomplished using charge sharing techniques similar to read operations in a DRAM device or by using one bit line as a ground node for sensing current flow through the strings. The use of bit lines for virtual grounding is further suitable to other array architectures.

Abstract: Clock synchronization and skew adjustment circuits that utilize differing unit delay elements in their delay lines in either a graduated or a stepped unit time delay arrangement are for synchronizing with a clock signal. These graduated or a stepped unit time delays allow reduction in the number of the fine unit delay elements of the delay lines by placing a fine delay element granularity at the most critical timings to sense and adjust for the portion of the clock signal time period that are high speed or critical.

Abstract: Methods for reducing quick charge loss effects, methods for programming, memory devices, memory devices, and memory systems are disclosed. In one such method, a programming pulse is applied to the word line to increase the threshold voltage of the memory cells being programmed. A negative voltage pulse is applied to the word line after the programming pulse to force any electrons trapped in the tunnel oxide of memory cells being programmed back into the tunnel region. After the negative pulse, a program verify operation is performed.