Page History

h6. {color:#000000}Optical discs used originally for  storing and playback sound tracks but is developed later to store data,  rewrite-ability and much more features, and is the basic and popular form of data storage even when memory sticks or external hard drive are developed strongly. We will have a look at 3 most popular type: CD, DVD and Blu-ray Disc{color}

h1. Physical Detail


!600px-CD_layers.svg.png|align=right,width=235,height=235!
{color:#000000}A standard disc is 1.2mm thick, 15-20grams in weight, diameter of 120mm. It consists of 4 layers as stated from the figure: a polycarbonate layer that contain data, aluminum or gold layer for reflective{color} {color:#000000}purpose, film/lacquer layer to provide protection to previous important parts and the most outer layer used for label printing.{color}

{color:#000000}From the center outward, components are: the center spindle hole  (15 mm), the first-transition area (clamping ring), the clamping area  (stacking ring), the second-transition area (mirror band), the program  (data) area, and the rim{color}
{color:#000000}Data is represented as tiny indentations known as "pits", encoded in a  spiral track moulded into the top of the polycarbonate layer. The areas  between pits are known as "lands".{color}



ㅤ

ㅤ                                                                                                                                           
{align:right}Figure 1. CD layers.

                                                                                                                       [http://en.wikipedia.org/wiki/Compact_Disc|http://en.wikipedia.org/wiki/Compact_Disc]


{align}







































_                                                                                                                                                                                                                               _




h2. {color:#000000}CD{color}

{color:#000000}The elongated bumps that make up the track are each 0.5 µm wide,  a minimum of 0.83 µm long and 125 nm high. They look something like this:{color}

!cd-crosssection.gif! !cd-bumps.gif!

         {color:#999999} {color} {color:#999999}{_}Figure 2. Cross section of a CD. Copied from{_}{color}{color:#999999}_                                                          Figure 3. CD bumps. Copied from{_}{color}


{color:#999999}_     _{color} {color:#999999}_[http://electronics.howstuffworks.com/cd1.htm]_{color} {color:#999999}_                                 _{color} {color:#999999}_[http://electronics.howstuffworks.com/cd1.htm]_{color} {color:#999999}_              _{color}                             

{color:#000000}You will often read about  "pits" on a CD instead of bumps. They appear as pits on the aluminum  side, but on the side the laser reads from, they are bumps.{color}

{color:#000000}The  incredibly small dimensions of the bumps make the spiral track on a CD  extremely long. If you could lift the data track off a CD and stretch it  out into a straight line, it would be 0.5 microns wide and 5 km long{color}

h2. {color:#000000}DVD{color}

A spiral data track which is 740 nanometers apart from the next stays in each writable layer of DVD. The tracks are composed of the elongated bumps whose size is 320 nanometers wide, 400 nanometers long and 120 nanometers high each at minimum.


                                                                                                                                        




                                                                                    !dvd1.jpg|align=left!




h3. DVD Video

Before movies are stored on the disc, they are encoded to MPEG-2 format first which is widely accepted and a international standard. When you buy a DVD player, it already contains a MPEG-2 decoder used to immediately uncompress the encoded data while you are watching the movie.



Here are the typical contents of a DVD movie:
* The DVD can contains 133  minutes of high-resolution video, in letterbox or pan-and-scan format,  with 720 dots of horizontal resolution ( The MPEG-2 format compresses the video with a typical ratio of 40:1)
* It can present the soundtrack in eight languages utilizing 5.1 channel Dolby digital {color:#000000}surround sound{color}
* It supports audience with subtitles in up to 32 languages

\\
\\
\\

{color:#999999}{_}Figure 4. DVD pits layout. Reprinted from{_}{color}


[http://electronics.howstuffworks.com/dvd2.htm|http://electronics.howstuffworks.com/dvd2.htm]












































h3. DVD Audio

DVD can take a higher sampling rate than CD so DVD quality is much  better than CD in recordings. About 74 minutes of songs can be stored in  CDs. By being able to sample the signal at higher rate, DVD can store a  much better quality of the same amount of music compared to CDs. The  highest quality level is 192kHZ/24-bit audio. A longer amount of time of  music can be stored in DVD by decreasing the quality of the songs. To  decrease the quality, sampling rate or the accuracy need to be lowered.  For example, at 96kHZ/24-bit music, DVD can hold a longer amount of  music which is up to two hours of 6-channel and its quality is still  better than CD at the same level. Below is the chart that shows us the  sampling rate and accuracy for CD recordings and  the maximum sampling  rate and accuracy for DVD recordings

                                                                                                        !dvd 2.gif|border=1!

                                                                                                 {color:#999999}_   Figure 5. Comparison of a raw audio signal to the CD audio and DVD audio output._{color}

{color:#999999}_                                                                                                        Reprinted from{_}{color} {color:#999999}_[http://electronics.howstuffworks.com/dvd5.htm]_{color}


The sampling frequency specifies how often a signal is sampled meaning how many times a signal is sampled per second. The accuracy of the sampling process is determined by the number of bits because the sampled values are converted into binary. The amount of information in every sampling is determined by the number of bits. The more bits we have, the higher the accuracy. The quality of the music at 8-bit system is not good. Therefore, the music is often coded on the disc in 16 bits system.




h2. {color:#000000}Blu-ray Disc{color}


!blu-ray-5.gif|align=right!























{align}* *Blu-ray disc* (*BD*) uses a *blue laser* to read and write data. A blue laser has a *shorter wavelength* (*405 nanometers*)  than a red laser (650 nanometers). The smaller beam reading information recorded in pits that are  only *0.15 microns* (µm) (1 micron = 10^-6\^ meters) long \-\- more than twice as small as the pits on a DVD. Plus, Blu-ray has reduced the *track pitch* from 0.74 microns to *0.32 microns*.  The smaller pits, smaller beam and shorter track pitch together enable a  single-layer Blu-ray disc to hold more than 25 GB of information \-\-  about five times the amount of information that can be stored on a DVD.ㅤ

ㅤ
* Each Blu-ray disc is about *1.2 millimeters* in thickness. Having a polycarbonate layer on top of the data can cause a  problem called *birefringence*,  in which the substrate layer refracts the laser light into two separate  beams. If the beam is split too widely, the disc cannot be read. Also,  if the DVD surface is not exactly flat, and is therefore not exactly  perpendicular to the beam, it can lead to a problem known as *disc tilt*, in which the laser beam is distorted.











{align}
{align:right}Figure 6. Building a Blu-ray Disc.

Reprinted from [http://electronics.howstuffworks.com/blu-ray1.htm]

{align}
ㅤ

ㅤ
{tip}


h5. _Fun facts: The name_

_The Blu-ray name is a combination of "blue", for the color of the  laser that is used, and "ray", for optical ray. The "e" in "blue" was  purposefully left off, according to the manufacturers, because an  everyday word cannot be_ *{_}trademarked{_}{*}_._{tip}


h2. {color:#000000}How optical discs are read{color}

!Comparison_CD_DVD_HDDVD_BD.svg.png|width=724,,height=364!

Figure 7. Comparison of how different types of dics are read. Reprinted from [http://en.wikipedia.org/wiki/File:Comparison_CD_DVD_HDDVD_BD.svg]




ㅤ













{color:#000000}The common principle for optical discs is the reflection of laser in interaction with the polycarbonate data surface. The change in height  between pits and lands results in a difference in the way the light is  reflected. By measuring the intensity change with a photo-diode, the data can be read from the disc. {color} 
{multimedia:name=dvd-read.swf|width=880|height=300|autostart=true}
Figure 8. How data is read inside DVD player. Reprinted from [http://electronics.howstuffworks.com/hd-dvd.htm]




ㅤ








{color:#000000}Each string of 1s and 0s  corresponds to an electrical signal (a voltage). The DAC  (digital-to-analog converter) turns the numbers into voltages.{color}

{color:#000000}A compact disc is scanned by a laser beam. The laser's light is reflected from a land to a photo-electric cell.. The cell emits (give or send out) current and a 1 is registered. When the beam shines on a pit, half of the light is reflected from the surface and half from the depth of the pit. The interference between the two reflected beams eliminates the original beam. The photo\- electric cell emits no current, and a 0 is registered{color}.

ㅤ

ㅤ



{noformat}
REFERENCE:

* CD Wikipedia http://en.wikipedia.org/wiki/Compact_Disc
* DVD Wikipedia http://en.wikipedia.org/wiki/DVD
* Bluray Wikipedia http://en.wikipedia.org/wiki/Blu-ray_Disc
* CD HowStuffWork http://electronics.howstuffworks.com/cd.htm
* DVD HowStuffWork http://electronics.howstuffworks.com/dvd.htm
* Bluray HowStuffWork http://electronics.howstuffworks.com/blu-ray.htm
{noformat}