CD-ROM
CD-ROM (Compact
Disc, read-only-memory) is an
adaptation of the CD that is
designed to store computer data in
the form of text and graphics, as
well as hi-fi stereo sound.
The original data format standard
was defined by Philips and Sony in
the 1983 Yellow Book. Other
standards are used in conjunction
with it to define directory and file
structures, including ISO 9660, HFS
(Hierarchal File System, for
Macintosh computers), and Hybrid HFS-ISO.
Format of the CD-ROM is the same as
for audio CDs: a standard CD is 120
mm (4.75 inches) in diameter and 1.2
mm (0.05 inches) thick and is
composed of a polycarbonate plastic
substrate (underlayer - this is the
main body of the disc), one or more
thin reflective metal (usually
aluminum) layers, and a lacquer
coating.
The Yellow Book specifications were
so general that there was some fear
in the industry that multiple
incompatible and proprietary formats
would be created. In order to
prevent such an occurrence,
representatives from industry
leaders met at the High Sierra Hotel
in Lake Tahoe to collaborate on a
common standard.
Nicknamed the High Sierra Format,
this version was later modified to
become ISO 9660. Today, CD-ROMs are
standardized and will work in any
standard CD-ROM drive. CD-ROM drives
can also read audio compact discs
for music, although CD players
cannot read CD-ROM discs.
CD-ROM Data Storage
Although the disc media and the
drives of the CD and CD-ROM are, in
principle, the same, there is a
difference in the way data storage
is organized. Two new sectors were
defined, Mode 1 for storing computer
data and Mode 2 for compressed audio
or video/graphic data.
CD-ROM Mode 1
CD-ROM Mode 1 is the mode used for
CD-ROMs that carry data and
applications only. In order to
access the thousands of data files
that may be present on this type of
CD, precise addressing is necessary.
Data is laid out in nearly the same
way as it is on audio disks: data is
stored in sectors (the smallest
separately addressable block of
information), which each hold 2,352
bytes of data, with an additional
number of bytes used for error
detection and correction, as well as
control structures.
For mode 1 CD-ROM data storage, the
sectors are further broken down, and
2,048 used for the expected data,
while the other 304 bytes are
devoted to extra error detection and
correction code, because CD-ROMs are
not as fault tolerant as audio CDs.
There are 75 sectors per second on
the disk, which yields a disc
capacity of 681,984,000 bytes
(650MB) and a single speed transfer
rate of 150 KBps, with higher rates
for faster CD-ROM drives. Drive
speed is expressed as multiples of
the single speed transfer rate, as
2X, 4X, 6X, and so on.
Most drives support CD-ROM, XA
(Extended Architecture) and Photo-CD
(including multiple session discs).
CD-ROM Mode 2
CD-ROM Mode 2 is used for compressed
audio/video information and uses
only two layers of error detection
and correction, the same as the
CD-DA.
Therefore, all 2,336 bytes of data
behind the sync and header bytes are
for user data. Although the sectors
of CD-DA, CD-ROM Mode 1 and Mode 2
are the same size, the amount of
data that can be stored varies
considerably because of the use of
sync and header bytes, error
correction and detection. The Mode 2
format offers a flexible method for
storing graphics and video.
It allows different kinds of data to
be mixed together, and became the
basis for CD-ROM XA. Mode 2 can be
read by normal CD-ROM drives, in
conjunction with the appropriate
drivers.
Data Encoding and Reading
The CD-ROM, like other CD
adaptations, has data encoded in a
spiral track beginning at the center
and ending at the outermost edge of
the disc. The spiral track holds
approximately 650 MB of data. That's
about 5.5 billion bits.
The distance between two rows of
pits, measured from the center of
one track to the center of the next
track is referred to as track pitch.
The track pitch can range from 1.5
to 1.7 microns, but in most cases is
1.6 microns.
Constant Linear Velocity (CLV) is
the principle by which data is read
from a CD-ROM. This principal states
that the read head must interact
with the data track at a constant
rate, whether it is accessing data
from the inner or outermost portions
of the disc. This is affected by
varying the rotation speed of the
disc, from 500 rpm at the center, to
200 rpm at the outside. In a music
CD, data is read sequentially, so
rotation speed is not an issue.
The CD-ROM, on the other hand, must
read in random patterns, which
necessitates constantly shifting
rotation speeds.
Pauses in the read function are
audible, and some of the faster
drives can be quite noisy because of
it.
http://www.justvb.net/it/