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0.7 GB 9 GB 30~50 GB

HOLOGRAPHIC VERSATILE DISC

Presented By:

Muragesh S KabbinakantimathUSN:4GM09EC408

1. INTRODUCTION

2. UNDERLYING TECHNOLOGY- HOLOGRAPHY

3. RECORDING DATA

4. READING DATA

5. HVD- STRUCTURE

6. COMPARISON

7. TYPES : WORM & RW

8. REFERENCES

Next-Next Generation Technology Scientist J. V. Heerden came up with this idea in 1960 Media type : Ultra-high density optical disc Encoding : MPEG-2, MPEG-4 AVC (H.264), and VC-1 Capacity theoretically up to 3.9 TB Developed by HSD Forum Usage :Data storage,

:High-definition video & the possibility of ultra high

definition video

Data transfer rate : 1gbps.

The technology permits over 10 kilobits of data to be written and read in parallel with a single flash.

Most optical storage devices, such as a standard CD saves one bit per pulse. HVDs manage to store 60,000 bits per pulse in the same place.

1 HVD = 5800 CDs = 830 DVD =160 BLU-RAY

Black and white photograph Contains Intensity distribution

Color photograph Intensity and wavelength

Hologram Intensity, phase, and sometimes wavelength

INVENTED BY

SCIENTIST

GABOR IN 1947.

CONTAINS

INFORMATION

ABOUT AMPLITUDE

AND PHASE OF

OBJECT WAVE.

Translates electronic data (0's and 1's) into optical pattern of light and dark pixels.

Data is arranged in an array similar to a checkerboard of usually 1M (million) bits.

By varying the angle of the reference beam,wavelength or media position, many holograms can be stored in the same volume of storage material.

HVD uses a technology called 'collinear holography,'

Two laser rays, one blue-green and one red are used.

The role of the blue-green laser is to read the data encoded in the form of laser interference fringes from the holographic layer.

The red laser serves the purpose of a reference beam and also to read the servo info from the aluminum layer.

1. Green writing/reading laser (532 nm)2. Red positioning/addressing laser (650 nm)3. Hologram (data)4. Polycarbon layer5. Photopolymeric layer (data-containing layer)6. Distance layers7. Dichroic layer (reflecting green light)8. Aluminium reflective layer (reflecting red light)9. Transparent baseP. PIT

Parameters DVD BLU-RAY HVDcapacity 4.7 GB 25 GB 3.9 TB

Laser wave length

650 nm(red)

405 nm(blue)

532 nm (green)

Disc diameter 120 mm 120 mm 120 mm

Hard coating no yes yes

Data transfer rate (raw data)

11.08 mbps

36 mbps 1 gbps

Data transfer rate (audio/video)

10.08 mbps

54 mbps 1 gbps

It has been estimated that the books in the U.S. Library of Congress, the largest library in the world , could be stored on

six HVDs.

The pictures of every landmass on Earth - like the ones shown in

Google Earth - can be stored on two HVDs.

With MPEG4 ASP encoding, a HVD can hold anywhere between 4,600-11,900 hours of video, which is enough for non-stop playing for a year.

A blue-green argon laser Beam splitters to spilt the laser beams Mirrors to direct the laser beams LCD panels (spatial light modulator) Lenses to focus the laser beams Lithium-niobate crystals or photopolymers and Charge-coupled device (CCD) cameras.

1) Large Data Density/ Capacity

2) Better Reliability

3) High Transfer Rates & Short Access Times

4) Fault And Damage Tolerance

Which Are Not Available Simultaneously With Any Other Storage

Technology.

Video-On-Demand

Portable Computing

MultimediaConsumer Audio/Video

Psaltis, D. Mok, F. Holographic memories. Scientific American

Encyclopedia of Optical Engineering www.ibm.com - IBM Research Press Resources Holographic

Storage

www.howstuffworks.com www.hvd-forum.org

HVD will soon replace previous DVDs. It is currently supported by more than 170 of the world's leading

consumer electronics, personal computer, recording media, video game and music companies.

The format also has broad support from the major movie studios as a successor to today's DVD format.