Abstract :
Modulation coding, to limit the number of consecutive zeros in a data stream, is essential in digital magnetic recording/playback systems. Additionally, such systems require error-correction coding to ensure that the decoded output matches the recorder input, even if noise is present. Typically, these two coding steps have been performed independently, although various methods of combining them into one step have recently appeared. Another recent development is two-dimensional modulation codes, which meet runlength constraints using several parallel recording tracks, significantly increasing channel capacity. The article combines these two ideas. Previous techniques (both block and trellis structures) for combining error correction and modulation coding are surveyed, with discussion of their applicability in the two-dimensional case. One approach, based on trellis-coded modulation, is explored in detail, and a class of codes is developed which exploits the increased capacity to achieve good error-correcting ability at the same rate as common non-error-correcting one-dimensional codes
Keywords :
block codes; digital magnetic recording; error correction codes; runlength codes; trellis coded modulation; block codes; block structures; channel capacity; data stream; decoded output; digital magnetic recording/playback systems; error-correcting 2D modulation codes; error-correction coding; modulation coding; noise; parallel recording tracks; recorder input; runlength coding; runlength constraints; trellis coding; trellis structures; trellis-coded modulation; two-dimensional modulation codes; Channel capacity; Decoding; Digital recording; Impedance matching; Magnetic heads; Magnetic noise; Magnetic recording; Modulation coding; Saturation magnetization; Synchronization;
