Title :
Adaptive continuous-time equalization and FDTS/DF sequence detection
Author :
Bracken, Kimberly C. ; Zayed, Hazim M. ; Carley, L. Richard
Author_Institution :
Dept. of Electr. & Comput. Eng., Carnegie Mellon Univ., Pittsburgh, PA, USA
fDate :
11/1/1995 12:00:00 AM
Abstract :
An adaptive analog continuous-time forward equalizer and a Fixed Delay Tree Search with Decision Feedback (FDTS/DF) detector can be used to implement high speed low power sequence detection for a magnetic recording system. An analog continuous-time forward equalizer offers a low power, high speed solution to the equalization problem, although it cannot achieve the degree of pulse shape control provided by a long FIR filter. However, an FDTS/DF detector can be easily adapted to cope with the resulting imprecisely equalized pulses. Earlier work demonstrated the suitability of a Complex Graphic Equalizer (CGE) for the adaptive continuous time forward equalizer. System simulations indicated the viability of a CGE-FDTS/DF detector in a 2/3(1,7) coded channel. New results explore the performance of a CGE-FDTS/DF system for an 8/9(0,3) coded channel. Additionally, the feasibility of a CGE-EPR4 detection system is demonstrated
Keywords :
adaptive equalisers; adaptive signal detection; continuous time systems; decision feedback equalisers; delay circuits; equalisers; magnetic recording; tree searching; 2/3(1,7) coded channel; 8/9(0,3) coded channel; CGE-FDTS/DF detector; Complex Graphic Equalizer; Fixed Delay Tree Search with Decision Feedback detector; adaptive analog continuous-time forward equalizer; high speed low power sequence detection; magnetic recording; pulse shape control; simulation; Adaptive equalizers; Band pass filters; Detectors; Error analysis; Feedback; Finite impulse response filter; Magnetic recording; Magnetic separation; Maximum likelihood detection; Pulse shaping methods;
Journal_Title :
Magnetics, IEEE Transactions on
