CD-RW

CD-RW (Compact Disc-ReWritable) is a digital optical disc storage format introduced in 1997. A CD-RW compact disc (CD-RWs) can be written, read, erased, and re-written.

CD-RWs, as opposed to CDs, require specialized readers that have sensitive laser optics. Consequently, CD-RWs cannot be read in many CD readers built prior to the introduction of CD-RW. CD-ROM drives with a "MultiRead" certification are compatible.

CD-RWs must be erased or blanked before reuse. Erasure methods include full blanking where the entire surface of the disc is erased and fast blanking where only metadata areas, such as PMA, TOC and pregap, are cleared. Fast blanking is quicker and usually sufficient to allow rewriting the disc. Full blanking removes all traces of the previous data[1], and is often used for confidentiality purposes.

CD-RWs can sustain fewer re-writes compared to other storage media (ca. 1,000 compared up to 100,000). Ideal use is for test discs (e.g. for CD authoring), temporary backups, and as a middle-ground between online and offline storage schemes.

CD-MO

Before CD-RW technology, in 1990 a standard for magneto-optical recordable and erasable CDs called CD-MO was introduced and set in the Orange Book, part 1 as a CD with a magneto-optical recording layer. The CD-MO standard allowed for an optional non-erasable zone on the disc that could be read by CD-ROM units.

Data recording (and erasing) was achieved by heating the magneto-optical layer's material (e.g. DyFeCo or less often TbFeCo or GdFeCo) to its Curie point and then using a magnetic field to write the new data, in a manner essentially identical to Sony's MiniDisc and other magneto-optical formats. Reading the discs relied on the Kerr effect a major format flaw. The rewrite could only be read in special drives and was incompatible with non-magneto-optical enabled drives. The format was never released commercially,[2] mostly because of incompatibility with standard CD reading units. Early CD-R media contained a similar compatibility flaw.

Since the CD-MO was otherwise identical to CDs, the format still adopted a spiral-groove recording scheme, rendering the disc poorly suited as a removable medium for repeated, small-scale deletions and recordings. Some magneto-optical drives and media with the same form factor don't have this limitation. Unlike modern CD-RWs, CD-MO allowed for hybrid discs containing both an unmodifiable, pressed section, readable in standard drives, and a writable MO section.

The early introduction and no standards for disc recording software, file systems, and formats, physical incompatibility, coupled with more economical CD-R discs, led to abandoning the format.[3][4] Other magneto-optical media, unbound by limitations of the typical CD-ROM filesystems, replaced the CD-MO.

Mechanism of action

Rewritable media can, with suitable hardware, be re-written up to 100 000 times. The CD-RW is based on phase change technology, with a degree of reflection at 15–25%,[5] compared to 40–70% for CD-R discs.[5] The properties of the medium and the write and erase procedure is defined in the Orange Book Part III.

To maintain a precise rotation speed, tracks have a slight superimposed sinusoidal excursion of 0.3 µm at a frequency of 22.05 kHz.[5] In addition a 1 kHz frequency modulation is applied to provide the recorder with an absolute time reference.[5] Groove width is 0.6 µm and pitch of 1.6 µm.[5]

The media for CD-RW has the same layers as CD-R media. The reflective layer is, however, a silver-indium-antimony-tellurium (AgInSbTe) alloy with a polycrystalline structure and reflective properties in its original state. When writing the laser beam uses its maximum power (8 - 14 mW)[5] to heat the material to 500–700 °C causing material liquefaction. In this state, the alloy loses its polycrystalline structure and reflectivity and assumes an amorphous state. The lost reflectivity serves the same function as bumps on manufactured CDs and the opaque spots on a CD-R are read as a "0".[6] The polycrystalline state of the disc forms the trenches, which are read as "1".[6] The scanning signal when reading is created by strong or weak reflection of the laser beam. To erase the disc, the write beam heats the amorphous regions with low power to about 200 °C. The alloy is not melted, but returns to the polycrystalline state and is again reflective.

Authoring

Data structure on a CD-RW

During and after a disc authoring the distribution of data on the CD-RW varies. The following areas are present:

  • PCA: The Power Calibration Area is used to determine the correct power level for the laser.
  • PMA: The Program Memory Area of a CDRW is a record of the data recorded on an unfinished or unfinalized disc. It is used as a transition TOC while the session is still open. PMA records may contain information on up to 99 audio tracks and their start and stop times (CD-DA), or sector addresses for the start of data files for each session on a data CD.
  • PA: The Program Area contains the audio tracks or data files.
  • SUA: The System User Area The PCA and the PMA grouped together are sometimes denoted as the System User Area.

Each session on a multi-session disc has a corresponding lead-in, PMA, PA and lead-out. When the session is closed TOC information in the PMA is written into a lead-in area and the PCA and PMA are logically eliminated. The lead-out is created to mark the end of the data in the session.

Speed specifications

Specification[7] Logo Speed
(Original, "slow") 1×, 2×, 4×
High Speed 8×, 10×, 12×
Ultra Speed 16×, 20×, 24×
Ultra Speed+ 32×
Philips created the "High-Speed" CD-RW logo for media that supports writing speeds above 4×.

Details

Like a CD-R, a CD-RW has hardcoded speed specifications which limit recording speeds to fairly restrictive ranges. Unlike a CD-R, a CD-RW has a minimum writing speed under which the discs cannot be recorded, based on the phase change material's heating and cooling time constants and the required laser energy levels.

Since the CD-RW discs need to be blanked before recording data, writing too slowly or with too low energy on a high speed unblanked disc will cause the phase change layer to cool before blanking is achieved, preventing the data from being written.

Similarly, using inappropriately high amounts of laser energy will cause the material to overheat and be "insensitive" to the data, a situation typical of slower discs used in a high powered and fast specification drive.

Adaption and support

For these reasons, older CD-RW drives that lack appropriate firmware and hardware are not compatible with newer, high-speed CD-RW discs, while newer drives can record to older CD-RW discs, provided their firmware correct speed, delay, and power settings can be appropriately set.

The actual reading speed of CD-RW discs, however, is not directly correlated or bound to speed specification, but depends primarily on the reading drive's capabilities.

Many half-height CD and DVD writers released between 2004 and 2010, including the TSSTcorp SH-M522 combo drive (2004), Pioneer DVR-110D (2005)[8], Hitachi-LG GSA-4167 (2005)[9], TSSTcorp SH-S182/S183 (2006) and SH-S203/TS-H653B (2007) have officially adapted support for CD-RW UltraSpeed Plus (32× Z-CLV), while more recent DVD writers such as the SH-224DB (2013) and Blu-Ray writers such as the LG BE16NU50 (2016) have downgraded the backwards compatibility to CD-RW UltraSpeed (24× Z-CLV).[10][11]

Slim type optical drives are subject to physical limitations, thus are not able to attain rotation speeds of half-height (desktop) optical drives. They usually support CD-RW writing speeds of 16× Z-CLV in zones of 10× CLV and 16× CLV.[10][11]

See Also

gollark: It can use an optimized search process to try and find proofs if they exist, but otherwise it has to fallback to brute force, so your compiles can be fast iff your program is right.
gollark: The Macron compiler is somewhat slow as a result.
gollark: It basically just iterates through all possible proofs, and sees if one of them proves that the program is sound and safe.
gollark: Macron is maximally safe in all ways, yes.
gollark: nim_irl_ish_kind_of

References

  1. van Hove, Peter (2012 or earlier). "Quick erased (blanked) CD-RW vs. DVD-RW vs. DVD+RW, what's recoverable and how". IsoBuster. Archived from the original on 2012-09-24. Retrieved 2020-07-19. Check date values in: |date= (help)
  2. Upgrading and repairing PCs By Scott Mueller, page 739: "The Orange Book comes in three parts: Part I describes a format called CD-MO (magneto-optical), which was to be a rewritable format but was withdrawn before any products really came to market"
  3. "Wayback Machine" (PDF). 6 February 2012. Archived from the original (PDF) on 6 April 2008. Retrieved 10 April 2018.
  4. http://scp.s-scptuj.mb.edus.si/~murkos/Teorija%20in%20vaje/RSM/techref%20-%20%20HW%20za%20PCje%20-%20film%20Modherboard,%20IDE,Modem.BIOS,opti%E8ni%20diski%20-%20CD%20ob%20knjigi%20OPRAVKA%20RA%C8%20MRE%8EA/Chapter13.pdf%5B%5D
  5. "Archived copy". Archived from the original on 2012-07-09. Retrieved 2011-05-15.CS1 maint: archived copy as title (link) CS1 maint: BOT: original-url status unknown (link)
  6. "How CD Burners Work". howstuffworks.com. 1 August 2001. Retrieved 10 April 2018.
  7. Pioneer DVR-110D DVD Multi writer specification sheet
  8. "GSA-4167B Super Multi DVD Drive – Owner's Manual" (PDF). Hitachi-LG Data Storage. 2005. Archived (PDF) from the original on 2020-08-09. Retrieved 2020-08-09.
  9. Archive of discontinued Hitachi-LG Data Storage optical drives
  10. Archive of TSSTcorp optical drive manuals
  • Bennett, Hugh. "CD-E: Call it Erasable, Call it Rewritable, but will it Fly?" CD-ROM Professional Sept. 1996: 28+
  • Bennett, Hugh. Understanding CD-R & CD-RW. Cupertino: Optical Storage Technology Association, Jan. 2003.
  • Steinmetz, Ralf and Nahrstedt, Klara. "Multimedia Fundamentals Volume 1: Media Coding and Content Processing", ISBN 0-13-031399-8.

This article is based on material taken from the Free On-line Dictionary of Computing prior to 1 November 2008 and incorporated under the "relicensing" terms of the GFDL, version 1.3 or later.

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