Coding and Signal Processing for Magnetic Recording SystemsBane Vasic, Erozan M. Kurtas CRC Press, 9 nov. 2004 - 700 pages Implementing new architectures and designs for the magnetic recording read channel have been pushed to the limits of modern integrated circuit manufacturing technology. This book reviews advanced coding and signal processing techniques and architectures for magnetic recording systems. Beginning with the basic principles, it examines read/write operations, data organization, head positioning, sensing, timing recovery, data detection, and error correction. It also provides an in-depth treatment of all recording channel subsystems inside a read channel and hard disk drive controller. The final section reviews new trends in coding, particularly emerging codes for recording channels. |
Table des matières
2-1 | |
Chapter 3 The Physics of Optical Recording | 3-1 |
Chapter 4 Head Design Techniques for Recording Devices | 4-1 |
Chapter 5 Modeling the Recording Channel | 5-1 |
Chapter 6 Signal and Noise Generation for Magnetic Recording Channel Simulations | 6-1 |
Chapter 7 Statistical Analysis of Digital Signals and Systems | 7-1 |
Chapter 8 Partial Response Equalization with Application to High Density Magnetic Recording Channels | 8-1 |
Chapter 9 An Introduction to ErrorCorrecting Codes | 9-1 |
Chapter 23 CapacityApproaching Codes for Partial Response Channels | 23-1 |
Chapter 24 Coding and Detection for Multitrack Systems | 24-1 |
Chapter 25 TwoDimensional Data Detection and Error Control | 25-1 |
Chapter 26 Adaptive Timing Recovery for Partial Response Channels | 26-1 |
Chapter 27 Interpolated Timing Recovery | 27-1 |
Chapter 28 Adaptive Equalization Architectures for Partial Response Channels | 28-1 |
Chapter 29 Head Position Estimation | 29-1 |
Chapter 30 Servo Signal Processing | 30-1 |
Chapter 10 MessagePassing Algorithm | 10-1 |
Chapter 11 Modulation Codes for Storage Systems | 11-1 |
Chapter 12 Information Theory of Magnetic Recording Channels | 12-1 |
Chapter 13 Capacity of Partial Response Channels | 13-1 |
Chapter 14 Recording Physics and Organization of Data on a Disk | 14-1 |
Chapter 15 Read Channels for Hard Drives | 15-1 |
Chapter 16 An Overview of Hard Drive Controller Functionality | 16-1 |
Chapter 17 Runlength Limited Sequences | 17-1 |
Chapter 18 Maximum Transition Run Coding | 18-1 |
Chapter 19 Spectrum Shaping Codes | 19-1 |
Chapter 20 Introduction to Constrained Binary Codes with Error Correction Capability | 20-1 |
Chapter 21 Constrained Coding and ErrorControl Coding | 21-1 |
Chapter 22 Convolutional Codes for PartialResponse Channels | 22-1 |
Chapter 31 Evaluation of Thermal Asperity in Magnetic Recording | 31-1 |
Chapter 32 Data Detection | 32-1 |
Chapter 33 Detection Methods for Datadependent Noise in Storage Channels | 33-1 |
Chapter 34 ReadWrite Channel Implementation | 34-1 |
Chapter 35 Turbo Codes | 35-1 |
Chapter 36 An Introduction to LDPC Codes | 36-1 |
Chapter 37 Concatenated SingleParity Check Codes for HighDensity Digital Recording Systems | 37-1 |
Chapter 38 Structured LowDensity ParityCheck Codes | 38-1 |
Chapter 39 Turbo Coding for Multitrack Recording Channels | 39-1 |
I-1 | |
Back Cover | I-15 |
Autres éditions - Tout afficher
Coding and Signal Processing for Magnetic Recording Systems Bane Vasic,Erozan M. Kurtas Aucun aperçu disponible - 2004 |
Coding and Signal Processing for Magnetic Recording Systems Bane Vasic,Erozan M. Kurtas Aucun aperçu disponible - 2004 |
Expressions et termes fréquents
achieve additive algorithm applications assume AWGN binary block bound called capacity codes codeword Communications complexity compute concatenated considered constraint construction controller convolutional correction corresponding decoding defined denotes density detection detector disk distance drive effect encoder equalizer Equation error estimate event example field Figure filter frequency function gain given graph head IEEE Trans implementation increase information rates input introduced iterative LDPC codes length limited linear longitudinal loop magnetic recording matrix maximum medium memory method node noise obtained operation optical output parameters parity partial response path performance perpendicular phase position present probability produce pulse received recording channels reference represents samples scheme sequence servo signal simulation storage symbol techniques Theory track transition trellis turbo codes vector Viterbi write zero