SKYERA, INC. Patent applications |
Patent application number | Title | Published |
20150138717 | SYSTEMS AND METHODS FOR SECURING HIGH DENSITY SSDS - In various embodiments, a high-density solid-state storage unit includes a base section and a cassette section having plurality of flash cards. The cassette section can be removably attached to the base section to provide security of data stored on the plurality of flash cards. The cassette section provides for physical security of the flash cards in part through packaging of the enclosure and energy transfer to the base station. The cassette section further provides for security of the data stored on the flash cards in part through a trusted platform module (TPM) embodied as a removable module connected to a universal serial bus (USB) style connector. | 05-21-2015 |
20150138716 | SYSTEMS AND METHODS FOR PACKAGING HIGH DENSITY SSDS - In various embodiments, a high-density solid-state storage unit includes a base section and a cassette section having plurality of flash cards. The cassette section can be removably attached to the base section to provide security of data stored on the plurality of flash cards. The cassette section provides for physical security of the flash cards in part through packaging of the enclosure and energy transfer to the base station. The cassette section further provides for security of the data stored on the flash cards in part through a trusted platform module (TPM) embodied as a removable module connected to a universal serial bus (USB) style connector. | 05-21-2015 |
20150134881 | APPARATUS AND METHOD FOR ACCESSING A NON-VOLATILE MEMORY BLADE USING MULTIPLE CONTROLLERS IN A NON-VOLATILE MEMORY BASED STORAGE DEVICE - Various systems, methods, apparatuses, and computer-readable media. for accessing a storage device are described. In certain example embodiments, an active/active fault tolerant storage device comprising two or more controllers may be implemented. In one embodiment, each controller may be coupled to the non-volatile memory (NVM) blades comprising the non-volatile memory (NVM) storage medium. In one example implementation, a standardized protocol, such as Peripheral Component Interconnect Express protocol may be used for communicating amongst the various components of the controller and also the NVM storage medium. | 05-14-2015 |
20150134880 | APPARATUS AND METHOD FOR ROUTING INFORMATION IN A NON-VOLATILE MEMORY-BASED STORAGE DEVICE - Various systems, methods, apparatuses, and computer-readable media for accessing a storage device are described. In certain example embodiments, an active/active fault-tolerant storage device comprising two or more controllers may be implemented. In one aspect, each controller may have two or more processing entities for distributing the processing of the I/O requests. In one embodiment, the configuration of the components, modules and the controller board may be arranged in a manner to enhance heat dissipation, reduce power consumption, spread the power and work load, and reduce latency. In one embodiment, each controller may be coupled to the non-volatile memory (NVM) blades comprising the non-volatile memory (NVM) storage medium. In one example implementation, a standardized protocol, such as the Peripheral Component Interconnect Express protocol may be used for communicating amongst the various components of the controller and also the NVM storage medium. | 05-14-2015 |
20150121025 | WRITABLE CLONE DATA STRUCTURE - A memory system including parent data and clone data is disclosed, where the clone data represents a clone of the parent data. The system determines whether clone data to be accessed is different from corresponding data in the parent. The system also determines a physical location of the data to be accessed based on whether the data to be accessed is different from the corresponding parent data. The system also accesses the data based on the physical location. | 04-30-2015 |
20150074358 | HIGH PERFORMANCE SYSTEM PROVIDING SELECTIVE MERGING OF DATAFRAME SEGMENTS IN HARDWARE - A method of writing data to a range of logical blocks in a storage medium includes: receiving a command including a starting logical block address, a value indicating a range of logical block addresses to be written, and a logical block of data; storing the logical block in a first temporary storage; generating a logical page by duplicating the logical block a plurality of times corresponding to a number of logical blocks in a logical page and transporting the generated logical page to a second temporary storage and storing the generated logical page in the second temporary storage; writing the generated logical page from the second temporary storage into the storage medium beginning from the starting logical block address; and performing a read-modify-write operation if the first write operation does not begin on a logical page boundary or the last write operation does not end on a logical page boundary. | 03-12-2015 |
20140281691 | MASS STORAGE DEVICE AND METHOD OF OPERATING THE SAME TO STORE PARITY DATA - A mass storage memory device is disclosed. The device includes a plurality of blades where two blades are used to store parity data corresponding to data stored in the other blades. The device also includes a controller configured to write data to the blades along stripes extending from the other blades to the two blades, where the parity data within a stripe is based on the data written to the other blades in the stripe, and wherein the parity data includes two or more types of parity data. | 09-18-2014 |
20140281360 | APPARATUS AND METHOD FOR INSERTION AND DELETION IN MULTI-DIMENSIONAL TO LINEAR ADDRESS SPACE TRANSLATION - A translation system can translate a storage request to a physical address using fields as keys to traverse a map of nodes with node entries. A node entry can include a link to a next node or a physical address. Using a portion of the key as noted in node metadata, a node entry can be determined. When adding node entries to a node, a node utilization can exceed a threshold value. A new node can be created such that node entries are split between the original and new node. Node metadata of the parent node, new node and original node can be revised to identify which parts of the key are used to identify a node entry. When removing node entries from a node, node utilization can cross a minimum threshold value. Node entries from the node can be merged with a sibling, or the map can be rebalanced. | 09-18-2014 |
20140281359 | APPARATUS AND METHOD FOR REFERENCING DENSE AND SPARSE INFORMATION IN MULTI-DIMENSIONAL TO LINEAR ADDRESS SPACE TRANSLATION - A translation system can translate a storage request having multiple fields to a physical address using the fields as keys to traverse a map. The map can be made of nodes that include one or more node entries. The node entries can be stored in a hashed storage area or sorted storage area of a node. A hashed storage area can enable a quick lookup of densely addressed information by using a portion of the key to determine a location of a node entry. A sorted storage area can enable compact storage of sparse information by storing node entries that currently exist and allowing the entries to be searched. By offering both types of storage in a node, a node can be optimized for both dense and sparse information. A node entry can include a link to a next node or the physical address for the storage request. | 09-18-2014 |
20140281315 | MASS STORAGE DEVICE AND METHOD OF OPERATING THE SAME TO BACK UP DATA STORED IN VOLATILE MEMORY - A mass storage memory device is disclosed. The device includes a nonvolatile memory, a volatile memory configured to store logical to physical (L2P) data associating logical addresses of data stored in the nonvolatile memory with physical locations of the nonvolatile memory at which the data is stored, and a controller. The controller writes L2P data in the nonvolatile memory so the L2P data can be preserved through a power failure. The controller also writes L2P data stored in the nonvolatile memory to the volatile memory to rebuild the L2P table. | 09-18-2014 |
20140281313 | APPARATUS AND METHOD FOR CLONING AND SNAPSHOTTING IN MULTI-DIMENSIONAL TO LINEAR ADDRESS SPACE TRANSLATION - A translation system can translate a storage request to a physical address using fields as keys to traverse a map of nodes with node entries. A node entry can include a link to a next node or a physical address. Using a portion of the key as noted in node metadata, a node entry can be determined. When snapshotting a dataset, a snapshot value can be updated in a root node entry. New data can be added under the new snaphsot value, preventing overwriting of the prior data, providing deduplication and quick snapshotting. When cloning a dataset, a new root node entry can be made for the clone. The new root entry can reference the original root entry of the original dataset. Metadata of nodes of the clone branch can identify whether the current branch contains updated data or whether the data exists off of the original root entry. | 09-18-2014 |
20140281312 | APPARATUS AND METHOD FOR TRANSLATION FROM MULTI-DIMENSIONAL TOLINEAR ADDRESS SPACE IN STORAGE - A translation system can translate a storage request having multiple fields to a physical address using the fields as keys to traverse a map. By using a map table, multiple storage services can be condensed into a single map traversal. The map can be made of nodes that include one or more node entries. The node entries can be stored in a hashed storage area or sorted storage area of a node. A node entry of root nodes or inner nodes can include a link to a next node. A node entry of a leaf node can include a physical address. Using the request fields as a key to a node, a node entry can be determined. A pointer in a root node entry or inner node entry can be followed to a next node. A physical address in a leaf node can be the translation of the storage request. | 09-18-2014 |
20140281216 | VERTICALLY INTEGRATED STORAGE - Various systems, methods, apparatuses, and computer-readable media for accessing a storage device are described. Techniques are described for vertically integrating the various software functions and hardware functions for accessing storage hardware. In some embodiments, the system is implemented using non-volatile memory. | 09-18-2014 |
20140281167 | COMPRESSOR RESOURCES FOR HIGH DENSITY STORAGE UNITS - In various embodiments, a high-density solid-state storage unit includes a plurality of flash cards. Each flash card has a flash controller that incorporates one or more resources for facilitating compression and decompression operations. In one aspect, data reduction and data reconstruction operations can be performed in-line as data is stored to and retrieved from flash memory. In another aspect, data reduction and data reconstruction operations can be performed as a service. Any one of the plurality of flash cards can be used to provide data reduction or data reconstruction services on demand for any type of data, including system data, libraries, and firmware code. | 09-18-2014 |
20140280356 | APPARATUS AND METHOD FOR USING FIELDS IN N-SPACE TRANSLATION OF STORAGE REQUESTS - A translation system can translate a request having multiple fields to a physical address using the fields as indexes to a multi-dimensional graph. A field or portion of a field can represent a location along an axis. When combined together, the fields can represent a point in n-space, where n is the number of axes. In some embodiments, a nearest neighbor calculation can be sufficient along an axis. Therefore, a point in n-space defined by the fields can be translated along an axis until a nearest neighbor entry is determined. When the entry is determined, the entry can be accessed to determine a correct response to the translation request. | 09-18-2014 |
20140268536 | HIGH DENSITY SERVER STORAGE UNIT - A rack mountable 1U storage unit includes a plurality of memory modules arranged in two groups. The storage unit also has control circuitry. The memory modules have a dedicated exhaust channel to draw heat away from the memory modules. The exhaust channel for the memory modules is disposed over and is physically separated from the exhaust channel for the control circuitry. The storage unit can accommodate up to 42 memory modules due to a unique method of placing the individual memory modules. | 09-18-2014 |
20140240913 | THERMAL REGULATION FOR SOLID STATE MEMORY - A chassis for a storage system contains a digital chamber that houses conventional electronic components and a thermal chamber that houses non-volatile solid state memory such as flash memory. A temperature regulating system monitors temperature within the digital chamber to keep the components therein below their maximum junction temperature. The temperature regulating system tightly regulates the temperature of solid state memory chips to within a nominal operating temperature range selected to extend the lifetime and/or improve the endurance and reliability of the solid state memory. The temperature regulating system may regulate different memory chips to different nominal temperatures based on the operations being performed and lifetime factors for the memory chips including current health and prior use. | 08-28-2014 |
20140067984 | Integrated Storage and Switching for Memory Systems - An integrated networked storage and switching apparatus comprises one or more flash memory controllers, a system controller, and a network switch integrated within a common chassis. The integration of storage and switching enables the components to share a common power supply and temperature regulation system, achieving efficient use of available space and power, and eliminating added complexity of external cables between the switch a storage devices. Additionally, the architecture enables substantial flexibility and optimization of network traffic policies for both network and storage-related traffic. | 03-06-2014 |
20140063722 | MOTHERBOARD WITH CARD GUIDE CUTOUTS - A system for mounting a flash blade in a storage system includes a motherboard with a series of card guide cutouts for aligning flash blades. A flash blade can be aligned perpendicular to the motherboard and aligned parallel to adjacent flash blades by inserting the flash blade into one of the card guide cutouts and connecting the flash blade to a connector at one end of the cutout. This beneficially aligns the flash blade while making efficient use of the available vertical space within a chassis. The flash blade can also extend through the cutout to the other side of the motherboard. The efficient use of vertical space enables an increase in the number of solid state memory can be added to the flash blade relative to conventional designs, thereby improving capacity. | 03-06-2014 |
20140063721 | CHASSIS WITH SEPARATE THERMAL CHAMBER FOR SOLID STATE MEMORY - A chassis for a network storage system contains a first thermal chamber that houses conventional electronic components and a second thermal chamber that houses non-volatile solid state memory such as flash memory. A cooling system keeps the electronics in first thermal chamber below their maximum junction temperature. Meanwhile, a temperature regulating system maintains the solid state memory in the second thermal chamber within a range of a preferred operating temperature selected to extend the lifetime and/or improve the reliability of the solid state memory. Thus, the chassis provides dual zone temperature control to improve performance of the network storage system. | 03-06-2014 |