Grundig CUC 7303 Serviceanleitung Seite 31

CUC 7303
3.8 RGB Signal Path
For contrast control of the RGB signals, IC850-(23) generates a
variable control voltage for the contrast controlling amplifier at
IC150-(25). Because too high a beam current may cause damage to
the picture tube, the beam current is limited by this IC. The internal peak
beam current limiting function is carried out in the peak white limiting
stage. If the RGB signal exceeds 2.6V
function starts working and reduces the contrast. The external peak
beam current limiting threshold is 2V
The average beam current limiting function reduces the setting voltages
at IC150-(25) for the contrast.
After the brightness amplifier, the RGB signals leave the IC150 and are
passed on to the cathode amplifiers on the CRT base panel.
3.9 Generation of the Horizontal and Vertical Sync Signals
The TV signal processor IC150-(13,15) is connected to the CCVS
signal from the IF and from the EURO-AV socket. Following an internal
colour trap where the colour information is filtered off the CCVS signal,
the resulting Y-signal now divides into two paths. In one path the signal
is passed on for further processing, and in the other, the signal is
applied to the sync separator.
The sync separator produces the horizontal and the vertical synchro-
nising pulses from the Y-signal. The horizontal synchronising signal is
passed on to the ϕ1 phase control, the vertical synchronising pulse is
used to start the line counter for vertical synchronisation.
3,58
MHz
4,43 4,43
MHz MHz
Chroma-Signal
Farbkontrast vom
Prozessor
Colour Contrast
from Processor
Luminanzsignal
Luminance Signal
RGB intern
Internal RGB
RGB von Scart
oder Videotext
RGB from Scart
or Videotext
22
23
24
RGB extern
External RGB
GRUNDIG Service
, the internal peak white limiting
pp
approximately.
pp
34
35 H/2
Farb-Oszillator
PAL-Schalter
Colour Oscillator
PAL Switch
33
Burst
PLL
(R-Y)
26
(B-Y)
21 25
Data Kontrast
Contrast
3.10 Line Oscillator
With this IC concept, the line frequency is generated completely inside
the line oscillator. The IC is not connected to external components so
that it is not necessary to adjust the free running horizontal and the free
running vertical frequency.
3.11 ϕ1 Phase Control
The ϕ1 phase control stage is for controlling the frequency. This stage
adjusts the frequency of the line oscillator to that of the line synchro-
nising pulse. For this, the frequency of the line synchronising pulse is
compared with the line oscillator frequency.
A ϕ1 phase control stage defines the time constant of the control
voltage which is fed out at IC150-(40). The control voltage shifts the line
oscillator until the frequencies are equal.
3.12 ϕ2 Phase Control
The ϕ2 phase control stage is for controlling the phase position of the
line drive pulse. This determines the phase off-set between the line
synchronising pulses and the actual position of the electron beam.
Dependent on the circuit components and the beam current, the delay
time between the external signal, the trigger signal and the actual
reaction of the line output stage is different. These differences are
compensated for by the ϕ2 control.
To identify the position of the electron beam the line flyback pulse from
the line output transformer is applied to IC150-(38). From the oscillator
signal and the line flyback pulse the ϕ2 controlling stage produces a
control voltage at IC150-(39) which is filtered by CC166.
TDA4662
TDA4665 (OIRT/FR)
30
Delay
+
31
Delay
+
Spitzenweiß
Begrenzung
Peak White
Limiting
17
Helligkeit
Brightness
Schaltungsbeschreibung / Circuit Description
Farbdemodulation
Colour Demodulation
29
(R-Y)
R
RGB
Matrix
G
28
(B-Y)
Y B
RGB-Ausgangsverstärker
RGB Output Amplifier
20
19
RGB zur
18
Bildrohrplatte
RGB to the
CRT panel
2 - 11