Abstract: A storage device includes a disk, a head configured to carry out data writing and data reading with respect to the disk, and including a heater that generates heat to cause the head to thermally expand towards the disk, a non-volatile semiconductor memory, and a controller configured to set an amount of expansion of the head, based on data read from the disk during a predetermined period of time after the storage device has been turned on, and write data from a host in the disk or the non-volatile semiconductor memory during the predetermined period of time, based on the amount of expansion.

Abstract: A storage device includes a first nonvolatile memory that includes memory cells, each capable of storing data of a first number of bits, a second nonvolatile memory of which memory capacity is larger than a memory capacity of the first nonvolatile memory, and a memory controller is configured to control the first nonvolatile memory to store data of a second number of bits that is smaller than the first number in each of at least a part of the memory cells according to a usage amount of the memory cells.

Abstract: A storage device includes a first non-volatile storage unit, a second non-volatile storage unit that includes a plurality of semiconductor memory blocks and is capable of executing data access at a speed faster than the first non-volatile storage unit, and a control unit configured to acquire an error value representing an amount of errors included in data read from a block of the second non-volatile storage unit, and carry out a backup of the data either in the first or second non-volatile storage unit, depending on the error value.

Abstract: A storage device includes a disk medium having a first recording region and a second recording region, a non-volatile semiconductor memory, and a controller. The controller is configured to write data of a first type into tracks of the first recording region that partially overlap with each other, to write for caching data of a second type into tracks of the second recording region, and to write for caching the data of the second type stored in the disk medium into the non-volatile semiconductor memory.

Abstract: A storage device includes a first nonvolatile memory that includes memory cells, each capable of storing data of a first number of bits, a second nonvolatile memory of which memory capacity is larger than a memory capacity of the first nonvolatile memory, and a memory controller is configured to control the first nonvolatile memory to store data of a second number of bits that is smaller than the first number in each of at least a part of the memory cells according to a usage amount of the memory cells.

Abstract: According to one embodiment, a storage device includes a first nonvolatile storing unit having a predefined first management area, and a second nonvolatile storing unit configured to process data at a higher rate than the first nonvolatile storing unit. The first nonvolatile storing unit stores, in the first management area, first management information associated with the first nonvolatile storing unit, and second management information associated with the second nonvolatile storing unit.

Abstract: According to one embodiment, a storage apparatus includes a first storage medium which is nonvolatile, a second storage medium which is nonvolatile, a cache controller, and a main controller. An access speed of the second storage medium is lower, and a storage capacity of the second storage medium is larger than the first storage medium. The main controller controls the cache controller and accesses the second storage medium based on an access request from a host apparatus. The cache controller writes, in a multiplexed manner, data to be stored in the first storage medium to at least two areas in which deterioration of storage performance has been detected based on a result of access to the first storage medium.

Abstract: Methods in accordance with the present invention can include determining a plurality of sets of write pre-compensation parameters. At baseline conditions, the hard disk drive can apply a first current and write pre-compensation parameters can be tuned to generate a desired write current waveform that can be applied to the read/write head to generate a magnetic field to define magnetization on the magnetic media. The hard disk drive can then apply a second current and write pre-compensation parameters can be tuned to generate the desired write current waveforms. A plurality of write pre-compensation parameters can then be generated based on the results for a plurality of corresponding temperatures and/or temperature ranges.

Abstract: Methods in accordance with the present invention can include determining a plurality of sets of write pre-compensation parameters. At baseline conditions, the hard disk drive can apply a first current and write pre-compensation parameters can be tuned to generate a desired write current waveform that can be applied to the read/write head to generate a magnetic field to define magnetization on the magnetic media. The hard disk drive can then apply a second current and write pre-compensation parameters can be tuned to generate the desired write current waveforms. A plurality of write pre-compensation parameters can then be generated based on the results for a plurality of corresponding temperatures and/or temperature ranges.

Abstract: Embodiments of the present invention relate to systems, methods, and computer readable media for calibrating storage devices such as hard drives. A testing system is connected to a group of storage devices that are being prepared for release and eventual sale. Alternately, a storage device may be connected to an end-user system for which it is in use. The storage devices are tested for head instability. A lower frequency test pattern is performed, which induces a stronger magnetic field. A measurement of servo gain control is taken while reading from a disk and compared to a baseline for servo gain control. If the variance is larger than a predetermined amount, then the read/write head is determined to be unstable.

Abstract: Embodiments of the present invention relate to systems, methods, and computer readable media for calibrating storage devices such as hard drives. A testing system is connected to a group of storage devices that are being prepared for release and eventual sale. Alternately, a storage device may be connected to an end-user system for which it is in use. The storage devices are tested for head instability. A lower frequency test pattern is performed, which induces a stronger magnetic field. A measurement of servo gain control is taken while reading from a disk and compared to a baseline for servo gain control. If the variance is larger than a predetermined amount, then the read/write head is determined to be unstable.