1138 Chapter 30
glide laterally beneath the disc, moving in response to
tracking information and user access demands. Further-
more, the pickup must maintain focusing and tracking
even under adverse playing conditions such as a dirty
disc or impact and vibration.
To achieve sharp focus on the data surface and inten-
sity modulation, a laser is used as the light source. CD
pickups use an AlGaAs semiconductor laser irradiating
a coherent-phase laser beam with a 780 nm wavelength
(some manufacturers use 790 nm).
CD players can employ either single-beam or
three-beam pickups; three-beam designs are more prev-
alent. A three-beam pickup uses a center beam for
reading data and focusing, and two secondary beams for
tracking. The design of a three-beam pickup is shown in
Fig. 30-6. To generate additional beams, the laser light
passes through a diffraction grating, a screen with slits
spaced only a few laser wavelengths apart. As the beam
passes through the grating, the light diffracts; when the
resulting collection is again focused, it will appear as a
single bright centered beam with a series of succes-
sively less intense beams on either side. Three beams
from this diffraction pattern usefully strike the disc. As
discussed, when a laser spot strikes land, the smooth
interval between two pits, the light is almost totally
reflected; when it strikes a pit (seen as a bump by the
laser), destructive interference and diffraction causes
less light to be reflected into the pickup. The inten-
sity-modulated light is collected by the objective lens
and passes through the reading portion of the pickup.
In many three-beam designs, the property of astig-
matism is used to achieve auto-focusing. A cylindrical
lens is used to detect an out-of-focus condition. As the
distance between the objective lens and disc reflective
surface varies, the focal point of the optical system also
changes, and the image projected by the cylindrical lens
changes its shape, as shown in Fig. 30-7. That change in
the image on a four-quadrant photodiode generates the
focus correction signal. For example, if the disc were
too near to the pickup’s objective lens, the focal lengthFigure 30-5. CD player block diagram showing optical processing and output signal processing.CrystalEFM
demodulatorDemodulates
User EFM codes
bitsAmplifies signals
and reproduces
clock pulseKeeps the
laser output
the sameRotates the disc
at the regular
line speedAPCMotor Laser
pickupBeamsCompact disc
Pit
Laser beam
Focuses the beam on the disc
Sub-
beams Focus servo
Controls the beams
on the radial direction
Tracking servoPickup
servo
RF data
Moves the laser pickupRF amplifier
& PLL
Channel bit data Bit clockFrame
synchronizationFrame
clockAudio data ++
redundant
bits
Data memory
16 kbitsDe-interleaving and
circ decoding
for error correction
or compensationAbsorbs wow
and flutter and
arranges data in orderD/A
converterDigital
filtersClock
pulses
D/A
converterMotor drive
servo ControlsMicro
computerClock pulse
oscillation circuitConverts digital signal
into analog signalsLPFLPFRemoves clock
pulse componentsOperation
commandsOperationDisplayDisplay
commandsProgram
memoryCLV
servoBasic structure of a CD playerArranged
audio dataSeparated
audio signalsAnalog
audio signalsRight
outputLeft
output