Abstract: Devices and techniques for host accelerated operations in managed NAND devices are described herein. A read request is received at a controller of a NAND device. Here, the read request includes a logical address and a physical address. A a verification component that corresponds to the physical address is retrieved a NAND array of the NAND device. A verification of the read request is computed using the logical address, the physical address, and the verification component. A read operation is then modified based on the verification.

Abstract: Apparatus and methods are disclosed, including providing available data operations for the storage system processor to a host processor, identifying data operations to be performed by the storage system processor, and assigning identified data operations to the storage system processor to reduce bus traffic between the host processor and the storage system processor, to improve host processor performance, and to reduce energy use by the host processor.

Abstract: Disclosed in some examples are systems, methods, memory devices, and machine readable mediums for a fast secure data destruction for NAND memory devices that renders data in a memory cell unreadable. Instead of going through all the erase phases, the memory device may remove sensitive data by performing only the pre-programming phase of the erase process. Thus, the NAND doesn't perform the second and third phases of the erase process. This is much faster and results in data that cannot be reconstructed. In some examples, because the erase pulse is not actually applied and because this is simply a programming operation, data may be rendered unreadable at a per-page level rather than a per-block level as in traditional erases.

Abstract: Disclosed in some examples are memory devices which feature customizable Single Level Cell (SLC) and Multiple Level Cell (MLC) configurations. The SLC memory cells serve as a high-speed cache providing SLC level performance with the storage capacity of a memory device with MLC memory cells. The proportion of cells configured as MLC vs the proportion that are configured as SLC storage may be configurable, and in some examples, the proportion may change during usage based upon configurable rules based upon memory device metrics. In some examples, when the device activity is below an activity threshold, the memory device may skip the SLC cache and place the data directly into the MLC storage to reduce power consumption.

Abstract: Devices and techniques to reduce corruption of received data during assembly are disclosed herein. A memory device can perform operations to store received data, including preloaded data, in a first mode until the received data exceeds a threshold amount, and to transition from the first mode to a second mode after the received data exceeds the threshold amount.

Abstract: Apparatus and methods are disclosed, including a memory device or a memory controller configured to determine that a condition has occurred that indicates a performance throttling operation, implement a performance throttling responsive to the determined condition, responsive to implementing the performance throttling, set a performance throttling status indicator in an exception event status attribute, receive a command from a host device across a memory device interface, perform the command, prepare a response to the command, the response including a flag indicating that the performance throttling status indicator is set in the exception event status attribute, and send the response to the host device. Methods of operation are disclosed, as well as machine-readable medium and other embodiments.

Abstract: Disclosed in some examples are systems, methods, memory devices, and machine readable mediums for a fast secure data destruction for NAND memory devices that renders data in a memory cell unreadable. Instead of going through all the erase phases, the memory device may remove sensitive data by performing only the pre-programming phase of the erase process. Thus, the NAND doesn't perform the second and third phases of the erase process. This is much faster and results in data that cannot be reconstructed. In some examples, because the erase pulse is not actually applied and because this is simply a programming operation, data may be rendered unreadable at a per-page level rather than a per-block level as in traditional erases.

Abstract: Apparatus and methods are disclosed, including providing available data operations for the storage system processor to a host processor, identifying data operations to be performed by the storage system processor, and assigning identified data operations to the storage system processor to reduce bus traffic between the host processor and the storage system processor, to improve host processor performance, and to reduce energy use by the host processor.

Abstract: Disclosed in some examples are memory devices which feature customizable Single Level Cell (SLC) and Multiple Level Cell (MLC) configurations. The SLC memory cells serve as a high-speed cache providing SLC level performance with the storage capacity of a memory device with MLC memory cells. The proportion of cells configured as MLC vs the proportion that are configured as SLC storage may be configurable, and in some examples, the proportion may change during usage based upon configurable rules based upon memory device metrics. In some examples, when the device activity is below an activity threshold, the memory device may skip the SLC cache and place the data directly into the MLC storage to reduce power consumption.

Abstract: Disclosed in some examples are systems, methods, memory devices, and machine readable mediums for a fast secure data destruction for NAND memory devices that renders data in a memory cell unreadable. Instead of going through all the erase phases, the memory device may remove sensitive data by performing only the pre-programming phase of the erase process. Thus, the NAND doesn't perform the second and third phases of the erase process. This is much faster and results in data that cannot be reconstructed. In some examples, because the erase pulse is not actually applied and because this is simply a programming operation, data may be rendered unreadable at a per-page level rather than a per-block level as in traditional erases.

Abstract: Devices and techniques to reduce corruption of received data during assembly are disclosed herein. A memory device can perform operations to store received data, including preloaded data, in a first mode until the received data exceeds a threshold amount, and to transition from the first mode to a second mode after the received data exceeds the threshold amount.

Abstract: Disclosed in some examples are systems, methods, memory devices, and machine readable mediums for a fast secure data destruction for NAND memory devices that renders data in a memory cell unreadable. Instead of going through all the erase phases, the memory device may remove sensitive data by performing only the pre-programming phase of the erase process. Thus, the NAND doesn't perform the second and third phases of the erase process. This is much faster and results in data that cannot be reconstructed. In some examples, because the erase pulse is not actually applied and because this is simply a programming operation, data may be rendered unreadable at a per-page level rather than a per-block level as in traditional erases.

Abstract: Disclosed in some examples are methods, systems, and machine readable mediums that dynamically adjust the size of an L2P cache in a memory device in response to observed operational conditions. The L2P cache may borrow memory space from a donor memory location, such as a read or write buffer. For example, if the system notices a high amount of read requests, the system may increase the size of the L2P cache at the expense of the write buffer (which may be decreased). Likewise, if the system notices a high amount of write requests, the system may increase the size of the L2P cache at the expense of the read buffer (which may be decreased).

Abstract: Apparatus and methods are disclosed, including enabling communication between a memory controller and multiple memory devices of a storage system using a storage-system interface, the multiple memory devices each comprising a device controller and a group of non-volatile memory cells, and compressing data using at least one of the device controllers prior to transfer over the storage-system interface to improve an effective internal data transmission speed of the storage system.

Abstract: Devices and techniques for memory constrained translation table management are disclosed herein. A level of a translation table is logically segmented into multiple segments. Here, a bottom level of the translation table includes a logical to physical address pairing for a portion of a storage device and other levels of the translation table include references within the translation table. The multiple segments are written to the storage device. A first segment of the multiple segments is loaded to byte-addressable memory. A request for an address translation is received and determined to be for an address referred to by a second segment of the multiple segments. The first segment is then replaced with the second segment in the byte-addressable memory and the request is fulfilled using the second segment to locate a lower level of the translation table that includes the address translation.

Abstract: Devices and techniques are disclosed herein for providing an improved Replay Protected Memory Block (RPMB) data frame and command queue for communication between a host device and a memory device.

Abstract: Apparatus and methods are disclosed including a memory device or a memory controller configured to receive, from a host device over a host interface, a request for a device descriptor of a memory device, and to send to the host, over the host interface, the device descriptor, the device descriptor including voltage supply capability fields that are set to indicate supported voltages of the memory device, the supported voltages selected from a plurality of discrete voltages. The host device can utilize the supported voltages to supply an appropriate voltage to the memory device. Methods of operation are disclosed, as well as machine-readable medium, a host computing device, and other embodiments.

Abstract: Disclosed in some examples are methods, systems, and machine readable mediums that dynamically adjust the size of an L2P cache in a memory device in response to observed operational conditions. The L2P cache may borrow memory space from a donor memory location, such as a read or write buffer. For example, if the system notices a high amount of read requests, the system may increase the size of the L2P cache at the expense of the write buffer (which may be decreased). Likewise, if the system notices a high amount of write requests, the system may increase the size of the L2P cache at the expense of the read buffer (which may be decreased).

Abstract: Apparatus and methods are disclosed, including maintaining a first group of tagged data from a host device at contiguous physical locations on a group of non-volatile memory cells of a storage system during system management operations on the group of non-volatile memory cells including the first group of tagged data while the first group of tagged data remains stored on the storage system and prioritizing, in the storage system, commands associated with the first group of tagged data.

Abstract: Devices and techniques for host accelerated operations in managed NAND devices are described herein. A host logical-to-physical (L2P) table of the NAND device has an associated map. Entries in the map correspond to one or more logical addresses (LA) and indicate whether the host L2P table is current for those LAs. If the table is not current, then a request will bypass the host L2P table, using a standard device L2P lookup instead. Otherwise, the host L2P table can be used.