Abstract: A system and method of creating an extra redundancy in a RAID system is disclosed. In one embodiment, one or more RAID arrays are created. Each RAID array comprises a plurality of disk drives. Further, a respective dedicated hot spare is created for each RAID array. Furthermore, data is copied from each RAID array to the respective dedicated hot spare using a copyback process based on a predetermined controller usage threshold value.

Abstract: A hierarchical interface module includes an assessment unit configured to identify a hierarchical implementation incompatibility of an integrated circuit (IC) partitioned block. Additionally, the hierarchical interface module includes an interface unit configured to substitute a directly registered hierarchical interface structure for the hierarchical implementation incompatibility of the IC partitioned block. A method of interfacing hierarchically and a hierarchical implementation system are also included.

Abstract: Hardware-based methods and apparatus are provided for inter-track interference mitigation in magnetic recording systems. Inter-track interference (ITI) cancellation data is stored in a memory of a read channel of a magnetic recording system. The memory can be in a write data path or a read data path of the read channel. The inter-track interference cancellation data is optionally provided to an inter-track interference mitigation circuit using at least a portion of a write data path, for example, based on a control signal. The storage of the inter-track interference cancellation data can be in response to a second control signal.

Abstract: Techniques using scalable storage devices represent a plurality of host-accessible storage devices as a single logical interface, conceptually aggregating storage implemented by the devices. A primary agent of the devices accepts storage requests from the host using a host-interface protocol, processing the requests internally and/or forwarding the requests as sub-requests to secondary agents of the storage devices using a peer-to-peer protocol. The secondary agents accept and process the sub-requests, and report sub-status information for each of the sub-requests to the primary agent and/or the host. The primary agent optionally accumulates the sub-statuses into an overall status for providing to the host. Peer-to-peer communication between the agents is optionally used to communicate redundancy information during host accesses and/or failure recoveries. Various failure recovery techniques reallocate storage, reassign agents, recover data via redundancy information, or any combination thereof.

Abstract: A data storage system with redundant SSD cache includes an SSD cache organized into logical stripes, each logical stripe having several logical blocks. The logical blocks of each stripe are organized into logical data blocks and one logical parity block. Data may be written to the SSD cache by performing an exclusive disjunction operation on the logical parity block, the new data and the existing data in logical stripe to update the parity block, then writing the new data over the existing data in a logical data block in the same logical stripe.

Abstract: Described embodiments generate tasks corresponding to each packet received by a network processor. A destination processing module receives a task and determines, based on the task size, a queue in which to store the task, and whether the task is larger than space available within a current memory block of the queue. If the task is larger, an address of a next memory block in a memory is determined, and the address is provided to a source processing module of the task. The source processing module writes the task to the memory based on a provided offset address and the address of the next memory block, if provided. If a task is written to more than one memory block, the destination processing module preloads the address of the next memory block to a local memory to process queued tasks without stalling to retrieve the address of the next memory block.

Abstract: The present disclosure relates to an apparatus for fastening a power semiconductor using an integral springy (elastic) clip, capable of fixing a power semiconductor, such as a diode and a MOSFET, using elasticity of a U-shaped clip by integrally molding the clip onto a housing of a plastic module. The apparatus includes an elastic (springy) clip integrally molded onto a lower surface of the housing and downwardly curved into a U-like shape in a bridge module in which a bridge of the power semiconductor protrudes through a through hole of the housing to be connected to a printed circuit board, whereby the power semiconductor is fixed by a force that the housing presses the power semiconductor.

Abstract: Various embodiments of the present invention provide systems and methods for data processing system. As one example, a data processing circuit is described that includes an analog to digital converter, an online timing loop, and an offline timing loop. The analog to digital converter receives an analog input and provides a first series of data samples Each bit of the first series of data samples corresponds to the analog input at a time controlled by an updated sampling clock. The online timing loop modifies the updated sampling clock based at least in part upon a processed version of the first series of data samples.

Abstract: Clock control circuitry for an integrated circuit, a method of testing an integrated circuit having a clock gate, an integrated circuit and a library of cells including the clock control circuitry are provided. In one embodiment, the integrated circuit includes: (1) a clock gate configured to apply a clock signal to at least a first scan chain of the integrated circuit, (2) combinational logic coupled to an input of the clock gate and (3) Design-for-Test logic located external to the combinational logic and coupled to the clock gate and a first cell of a second scan chain of the integrated circuit, the Design-for-Test logic configured to control operation of the clock gate based on a logic value of the first cell.

Abstract: An integrated circuit power supply decoupling circuit includes a capacitor and a protection circuit. The capacitor has a first terminal and a second terminal. The protection circuit includes a first transistor having a first conduction path, and a second transistor having a second conduction path. One terminal of the first conduction path is connected to the first terminal of the capacitor, and another terminal of the first conduction path is connected to a first power supply rail. One terminal of the second conduction path is connected to the second terminal of the capacitor, and another terminal of the second conduction path is connected to a second power supply rail.

Abstract: An apparatus comprising a first sub-arbiter circuit and a second sub-arbiter circuit. The first sub-arbiter circuit may be configured to determine a winning channel from a plurality of channel requests based on a first criteria. The second sub-arbiter circuit may be configured to determine a winning channel received from the plurality of channel requests based on a second criteria. The second sub-arbiter may also be configured to optimize the order of the winning channels from the first sub-arbiter by overriding the first sub-arbiter if the second criteria creates a more efficient data transfer.

Abstract: An adaptive clock recovery (ACR) system has a first closed-loop control processor (e.g., a first proportional-integral (PI) processor) that processes an input phase signal indicative of jittery packet arrival times to generate a mean phase reference. The input phase signal is compared to the mean phase reference to generate delay-offset values that are indicative of the delay-floor corresponding to the packet arrival times. The mean phase reference and the delay-offset values are used to generate offset-compensated phase values corresponding to the delay-floor. The ACR system also has a second closed-loop control processor (e.g., a second PI processor) that smoothes the offset-compensated phase values to generate an output phase signal that can be used to generate a relatively phase stable recovered clock signal, even during periods of varying network load that adversely affect the uniformity of the packet arrival times.

Abstract: Various embodiments of the present invention provide systems and methods for signal offset cancellation. For example, a method for error cancellation is disclosed. The method includes: receiving an input signal that includes a second order error component; applying a transfer function to the processed input to reduce the second order error component; and providing an output signal that is the result of applying the transfer function to the input signal.

Abstract: Various embodiments of the present invention provide systems and methods for timing recovery. As an example, timing recovery circuits include: a first digital interpolation circuit, a second digital interpolation circuit, a phase selection circuit, and a sampling clock rotation circuit. The first digital interpolation circuit is operable to receive a data input and to provide a first interpolated output corresponding to a first phase, and the second digital interpolation circuit is operable to receive the data input and to provide a second interpolated output corresponding to a second phase. The phase selection circuit operable to select the first phase for processing, and the sampling clock rotation circuit is operable to move a sampling clock away from the first phase.

Abstract: Methods and circuits comprising a reliability measurement unit (RMU) for generating log-likelihood ratio (LLR) values corresponding to 1T for use in a soft output Viterbi algorithm (“SOVA”) decoder. The RMU operates with an nT clock signal. 1T signals generated by an add, compare, select circuit (ACS) of the SOVA generates 1T decision data and a path equivalency detector generates 1T path equivalency information for 1T SOVA decoding and applies the 1T data to the RMU operating with an nT clock frequency (1/n'th that of the 1T clock signal). The nT RMU receives a plurality of 1T inputs on each nT clock signal pulse and generates 1T LLR information for use by the SOVA decoder. Other components of the SOVA may also operate using the nT clock signal pulse or may operate using a 1T clock signal.

Abstract: Methods and structure described herein provide for adjusting an error correction capability of an LDPC error correction code. For example, the system of one embodiment includes a decoder adapted to decode data that has been encoded with a LDPC error correction code. The system also includes a detector communicatively coupled to the decoder and adapted to estimate bit values in the data prior to decoding by the decoder. The detector is further adapted to change bit values based on bit value estimations to reduce the error correction capability of the LDPC error correction code. The reduction in error correction capability is adjustable such that sector failure rates of storage devices may be incrementally analyzed.

Abstract: An apparatus having a first circuit and a second circuit is disclosed. The first circuit may be configured to (i) generate second Galois Field elements by performing a first Galois Field inversion on first Galois Field elements, the first Galois Field inversion being different from a second Galois Field inversion defined by an Advanced Encryption Standard and (ii) generate third Galois Field elements by multiplying the second Galois Field elements by an inverse of a predetermined matrix. The second circuit may be configured to (i) generate fourth Galois Field elements by processing the third Galois Field elements in a current encryption round while in a non-skip mode, (ii) generate fifth Galois Field elements by multiplying the fourth Galois Field elements by the predetermined matrix and (iii) present the fifth Galois Field elements as updated versions of the first Galois Field elements in advance of a next encryption round.

Abstract: An apparatus for performing sequence detection on a stream of incoming bits comprises a memory and circuitry coupled to the memory. The circuitry is operative, for each bit of the stream of incoming bits, to overwrite a first binary number presently stored in the memory with a second binary number, and to provide an output indicative of when the second binary number is equal to a predetermined value. The output indicative of when the second binary number is equal to the predetermined value is, in turn, indicative of when a binary number constructed by the stream of incoming bits is divisible by a prescribed integer.

Abstract: Systems and devices are disclosed that can be aimed by external adjustment devices/features/means without the need to open the sealed LED module. Heat from the LEDs and/or LED mounting assembly can be transferred to the outside air while the module is tilted, e.g., up to 15 degrees, or more, from vertical. Additionally, the modular structure of the inground LED light can allow for upgrade/renewal of associated electronics with only minor disassembly. Moreover, the thermal dissipation/management afforded by the designs of embodiments can allow for an increase of the LED useful service life. The sealing of the inground light unit can preclude the chance of an end user (e.g., service technician) from causing the unit to leak and thereby cause premature failure.

Abstract: A method of manufacturing an electronic circuit employing a flexible ramptime limit and an electronic circuit are disclosed. In one embodiment, the method includes: (1) physically synthesizing a logical representation of an electronic circuit employing flexible ramptime limits, (2) performing a timing test on the physically synthesized electronic circuit employing the flexible ramptime limits and a processor and (3) determining if there is a violation of the flexible ramptime limits.