The invention: Video and audio playback system that uses a lowpower
laser to decode information digitally stored on reflective
disks.
The organization behind the invention:
The Philips Corporation, a Dutch electronics firm
The Development of Digital Systems
Since the advent of the computer age, it has been the goal of
many equipment manufacturers to provide reliable digital systems
for the storage and retrieval of video and audio programs. A need
for such devices was perceived for several reasons. Existing storage
media (movie film and 12-inch, vinyl, long-playing records) were
relatively large and cumbersome to manipulate and were prone to
degradation, breakage, and unwanted noise. Thus, during the late
1960’s, two different methods for storing video programs on disc
were invented. A mechanical system was demonstrated by the
Telefunken Company, while the Radio Corporation of America
(RCA) introduced an electrostatic device (a device that used static
electricity). The first commercially successful system, however, was
developed during the mid-1970’s by the Philips Corporation.
Philips devoted considerable resources to creating a digital video
system, read by light beams, which could reproduce an entire feature-
length film from one 12-inch videodisc. An integral part of this
innovation was the fabrication of a device small enough and fast
enough to read the vast amounts of greatly compacted data stored
on the 12-inch disc without introducing unwanted noise. Although
Philips was aware of the other formats, the company opted to use an
optical scanner with a small “semiconductor laser diode” to retrieve
the digital information. The laser diode is only a fraction of a millimeter
in size, operates quite efficiently with high amplitude and relatively
low power (0.1 watt), and can be used continuously. Because
this configuration operates at a high frequency, its informationcarrying
capacity is quite large.Although the digital videodisc system (called “laservision”) works
well, the low level of noise and the clear images offered by this system
were masked by the low quality of the conventional television
monitors on which they were viewed. Furthermore, the high price
of the playback systems and the discs made them noncompetitive
with the videocassette recorders (VCRs) that were then capturing
the market for home systems. VCRs had the additional advantage
that programs could be recorded or copied easily. The Philips Corporation
turned its attention to utilizing this technology in an area
where low noise levels and high quality would be more readily apparent—
audio disc systems. By 1979, they had perfected the basic
compact disc (CD) system, which soon revolutionized the world of
stereophonic home systems.
Reading Digital Discs with Laser Light
Digital signals (signals composed of numbers) are stored on
discs as “pits” impressed into the plastic disc and then coated with a
thin reflective layer of aluminum. A laser beam, manipulated by
delicate, fast-moving mirrors, tracks and reads the digital information
as changes in light intensity. These data are then converted to a
varying electrical signal that contains the video or audio information.
The data are then recovered by means of a sophisticated
pickup that consists of the semiconductor laser diode, a polarizing
beam splitter, an objective lens, a collective lens system, and a
photodiode receiver. The beam from the laser diode is focused by a
collimator lens (a lens that collects and focuses light) and then
passes through the polarizing beam splitter (PBS). This device acts
like a one-way mirror mounted at 45 degrees to the light path. Light
from the laser passes through the PBS as if it were a window, but the
light emerges in a polarized state (which means that the vibration of
the light takes place in only one plane). For the beam reflected from
the CD surface, however, the PBS acts like a mirror, since the reflected
beam has an opposite polarization. The light is thus deflected
toward the photodiode detector. The objective lens is needed
to focus the light onto the disc surface. On the outer surface of the
transparent disc, the main spot of light has a diameter of 0.8 millimeter,
which narrows to only 0.0017 millimeter at the reflective surface. At the surface, the spot is about three times the size of the microscopic
pits (0.0005 millimeter).
The data encoded on the disc determine the relative intensity of
the reflected light, on the basis of the presence or absence of pits.
When the reflected laser beam enters the photodiode, a modulated
light beam is changed into a digital signal that becomes an analog
(continuous) audio signal after several stages of signal processing
and error correction.
Consequences
The development of the semiconductor laser diode and associated
circuitry for reading stored information has made CD audio
systems practical and affordable. These systems can offer the quality
of a live musical performance with a clarity that is undisturbed
by noise and distortion. Digital systems also offer several other significant
advantages over analog devices. The dynamic range (the
difference between the softest and the loudest signals that can be
stored and reproduced) is considerably greater in digital systems. In
addition, digital systems can be copied precisely; the signal is not
degraded by copying, as is the case with analog systems. Finally,
error-correcting codes can be used to detect and correct errors in
transmitted or reproduced digital signals, allowing greater precision
and a higher-quality output sound.
Besides laser video systems, there are many other applications
for laser-read CDs. Compact disc read-only memory (CD-ROM) is
used to store computer text. One standard CD can store 500 megabytes
of information, which is about twenty times the storage of a
hard-disk drive on a typical home computer. Compact disc systems
can also be integrated with conventional televisions (called CD-V)
to present twenty minutes of sound and five minutes of sound with
picture. Finally, CD systems connected with a computer (CD-I) mix
audio, video, and computer programming. These devices allow the
user to stop at any point in the program, request more information,
and receive that information as sound with graphics, film clips, or
as text on the screen.
12 August 2009
Laser-diode recording process
The invention: Video and audio playback system that uses a lowpower
laser to decode information digitally stored on reflective
disks.
The organization behind the invention:
The Philips Corporation, a Dutch electronics firm
The Development of Digital Systems
Since the advent of the computer age, it has been the goal of
many equipment manufacturers to provide reliable digital systems
for the storage and retrieval of video and audio programs. A need
for such devices was perceived for several reasons. Existing storage
media (movie film and 12-inch, vinyl, long-playing records) were
relatively large and cumbersome to manipulate and were prone to
degradation, breakage, and unwanted noise. Thus, during the late
1960’s, two different methods for storing video programs on disc
were invented. A mechanical system was demonstrated by the
Telefunken Company, while the Radio Corporation of America
(RCA) introduced an electrostatic device (a device that used static
electricity). The first commercially successful system, however, was
developed during the mid-1970’s by the Philips Corporation.
Philips devoted considerable resources to creating a digital video
system, read by light beams, which could reproduce an entire feature-
length film from one 12-inch videodisc. An integral part of this
innovation was the fabrication of a device small enough and fast
enough to read the vast amounts of greatly compacted data stored
on the 12-inch disc without introducing unwanted noise. Although
Philips was aware of the other formats, the company opted to use an
optical scanner with a small “semiconductor laser diode” to retrieve
the digital information. The laser diode is only a fraction of a millimeter
in size, operates quite efficiently with high amplitude and relatively
low power (0.1 watt), and can be used continuously. Because
this configuration operates at a high frequency, its informationcarrying
capacity is quite large.Although the digital videodisc system (called “laservision”) works
well, the low level of noise and the clear images offered by this system
were masked by the low quality of the conventional television
monitors on which they were viewed. Furthermore, the high price
of the playback systems and the discs made them noncompetitive
with the videocassette recorders (VCRs) that were then capturing
the market for home systems. VCRs had the additional advantage
that programs could be recorded or copied easily. The Philips Corporation
turned its attention to utilizing this technology in an area
where low noise levels and high quality would be more readily apparent—
audio disc systems. By 1979, they had perfected the basic
compact disc (CD) system, which soon revolutionized the world of
stereophonic home systems.
Reading Digital Discs with Laser Light
Digital signals (signals composed of numbers) are stored on
discs as “pits” impressed into the plastic disc and then coated with a
thin reflective layer of aluminum. A laser beam, manipulated by
delicate, fast-moving mirrors, tracks and reads the digital information
as changes in light intensity. These data are then converted to a
varying electrical signal that contains the video or audio information.
The data are then recovered by means of a sophisticated
pickup that consists of the semiconductor laser diode, a polarizing
beam splitter, an objective lens, a collective lens system, and a
photodiode receiver. The beam from the laser diode is focused by a
collimator lens (a lens that collects and focuses light) and then
passes through the polarizing beam splitter (PBS). This device acts
like a one-way mirror mounted at 45 degrees to the light path. Light
from the laser passes through the PBS as if it were a window, but the
light emerges in a polarized state (which means that the vibration of
the light takes place in only one plane). For the beam reflected from
the CD surface, however, the PBS acts like a mirror, since the reflected
beam has an opposite polarization. The light is thus deflected
toward the photodiode detector. The objective lens is needed
to focus the light onto the disc surface. On the outer surface of the
transparent disc, the main spot of light has a diameter of 0.8 millimeter,
which narrows to only 0.0017 millimeter at the reflective surface. At the surface, the spot is about three times the size of the microscopic
pits (0.0005 millimeter).
The data encoded on the disc determine the relative intensity of
the reflected light, on the basis of the presence or absence of pits.
When the reflected laser beam enters the photodiode, a modulated
light beam is changed into a digital signal that becomes an analog
(continuous) audio signal after several stages of signal processing
and error correction.
Consequences
The development of the semiconductor laser diode and associated
circuitry for reading stored information has made CD audio
systems practical and affordable. These systems can offer the quality
of a live musical performance with a clarity that is undisturbed
by noise and distortion. Digital systems also offer several other significant
advantages over analog devices. The dynamic range (the
difference between the softest and the loudest signals that can be
stored and reproduced) is considerably greater in digital systems. In
addition, digital systems can be copied precisely; the signal is not
degraded by copying, as is the case with analog systems. Finally,
error-correcting codes can be used to detect and correct errors in
transmitted or reproduced digital signals, allowing greater precision
and a higher-quality output sound.
Besides laser video systems, there are many other applications
for laser-read CDs. Compact disc read-only memory (CD-ROM) is
used to store computer text. One standard CD can store 500 megabytes
of information, which is about twenty times the storage of a
hard-disk drive on a typical home computer. Compact disc systems
can also be integrated with conventional televisions (called CD-V)
to present twenty minutes of sound and five minutes of sound with
picture. Finally, CD systems connected with a computer (CD-I) mix
audio, video, and computer programming. These devices allow the
user to stop at any point in the program, request more information,
and receive that information as sound with graphics, film clips, or
as text on the screen.
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