V772 circuit operation theory

V772 CRT Monitor Service Guide
Circuit Operation Theory

ACER V772 DEFLECTION CIRCUIT OPERATION THEORY

1. The Block Diagram of Deflection:

H-sync Digital Tilt Rotation
V-sync Controller Circuit C il

I2C BUS

AutoSync Deflection
Controller
IC TDA4856

Vertical
Deflection
Output Step Up
IC TDA4866 for B+ G1 & Spot Dynamic
Killer Circuit
Focus
H-SIZE
Compensation
Shut down
Circuit
G1
Dynamic
Regulation
Feedback

Horizontal
Deflection Output
Circuit

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2. Autosync Deflection Controller (TDA4856)

2.1 pin 1 is AFC feedback.
2.2 pin XRAY: if V XRAY > threshold (6.25V typical) switches the whole IC into protection mode.
2.3 pin 3,4,5,6,8 for B+ control function block.
2.4 pin 11(EWDRV) is a parabolic waveform used for pincushion correction
2.5 pin 16 generates video claming & blanking pulse.
2.6 pin 18,19 is I2C data.
2.7 pin 21 V-regulation.
2.8 the resistor from pin 28 (HREF) to ground determines the maximum oscillator frequency.
2.9 the resistor from pin 27 (HBUF) to pin 28 defines the frequency range.
2.10 pin 31 H-regulation.
2.11 pin 32 focus.

+48V

ZD204
+14V C205 + 30V
2.2U R205
50V 110K D201
(EL) 1N4148

R236
10 R203
1/2W 62K
(FS) VR201 R238 R257
HVADJ 12K 2.2K +14V
HDRV (OPEN)
+14V
EWDRV R206
C203 C226 + ZD201
R265 2200P 100U 12V
R267 JUMPER 100V 25V
V2 56K (PE) (EL)
100 HV-ADJ C222
V1 R204 1U
2.2K R222
R264 1/4W C202 50V 4.7K
100 0.01U (EL) C227 R221 1/4W
10K
PWM
+

VBL 100V 0.1U
R201 +C201 (PE) 50V
100 47U (D) Q201
HBL 50V H945
R202 (EL)
100 R237 R208
CLAMP 10K 1M
C204
+2.2U R216
15.8K
CLBL 16
HSYNC 15
VSYNC 14
VOUT1 13
VOUT2 12
EWDRV11

VCC10

50V (1%)
9

HDRV 8
GND 7

BDRV 6

BIN 5

BSENS 4

BOP 3
XRAY 2
HFLB 1

TP3 TP2
(EL)
i.c.

+48V
R217 R218
+14V IC201 100K 22.1K
TDA4856 R235 (1%) (1%)
17 HUNLOCK

10K
31 HSMOD
21 VSMOD
20 ASCOR

32 FOCUS
26 HPLL1

30 HPLL2
25 SGND
22 VAGC

29 HCAP
24 VCAP

27 HBUF

28 HREF
23 VREF
19 SDA
18 SCL

R270 HFLB
10K
R263
HULK 1K
FOCUS
SCL R214 HSMOD
R209 C207 1.27K R220
100 0.1U R213 (1%) JUMPER R262
SDA 100V 3.3K R215 (OPEN)
R210 C206 (PE) C208 2.67K C210 R268 R261
100 0.1U 0.1U C209 (1%) 0.01U C211 120K (OPEN) SC2
VSMOD 100V R212 8200P R266 2200P R260 D208
22.1K 100V 100V 100V 100V
R211 (PE) (1%) (PE) 8.2M (EPI) 390K (OPEN)
JUMPER (PE) (PE)
R258 SC1
(OPEN) D206
(OPEN)
SC0
D207
1N4148

Fig 2 Autosync Deflection Controller circuit

3. H-Driver & Output CKT:

3.1 HDRV signal comes from IC201 pin8, then goes into Q301, Q301 constitutes an inverting stage
and combines with T302 to drive Q302.
3.2 Q302, C306, C309, D305 constitute the H-output CKT with diode modulator mode.
3.3 Q324 & Q325 constitute a switch for lower frequency driver switching to cover the low hfe HOT
running under low frequency will occur poor-drive condition.

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Fig 3 HDRV & output circuit

4. Dynamic focus CKT
According to the CRT spec
H dynamic focus Vpp = 300 V
V dynamic focus Vpp = 130 V

4-1 Vertical dynamic focus
The signal from IC201 (pin 32) is a vertical frequency parabolic waveform.
Q321: an inverting amplifier stage.

4-2 Horizontal dynamic focus:
The waveform of C313 (CS-2, CS-1) is a horizontal frequency parabolic waveform, and is amplified by
T304.

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+14V

R391 DAF
1K
CS-2
+ C346 + C327 C329
22U R351 10U R373 0.033U
16V 68K 50V 150 R327 400V
(EL) (EL) 1/2W 10 (MPE)
1W
(FS)
R352 T304
3.9K
3 2 R379
FOCUS Q321 1K
BF423 2W
4 1
CS-1
19.20113.001

C328
R353 470P
560K 1KV
1/4W (D)

-190V

Fig 4 Dynamic Focus circuit

5. Brightness & spot killer CKT.

5.1 G1 CKT
The bright control signal from UC controller is about 0 ~ 5V, when the voltage of bright control signal
decreases, the current flow through R241 increases and the voltage of G1 increases.

5.2 Blanking CKT
To avoid the disturbed picture display on the screen, we have to blank the monitor in the following
situations.
(1) when display mode is changed.
(2) when the monitor enter the power saving mode.
(3) blank the vertical retrace line
when the " blank" signal becomes "high" Q208 "ON" , Q203 "OFF".G1 voltage is about ( -190 *
R271/(R271+R241)) ≒ -184V. The signal which is IC201 (pin 16) is inverted and amplified by Q202,
and coupling to G1.During the vertical retrace interval , the G1 voltage will be drop down about 48V.

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+45V
+6.5V

R231 R232
100 5.6K
1/4W 1/2W

CLAMP
ZD203 R240
R254
5.1V 3.3K
2.7K

Q208 + C224
Q202
H945 0.22U
H945 C223
R255 250V
(EL) R239 0.01U
BLANK BRITE Q203
6.8K 50V
10K BF423
(D)
R256
G1
HULK
10K
R241 R271
R269
100K 1M
1K
1/2W 1/2W

-190V

Fig5 Brightness & Spot killer circuit

6. BDRV and step-up CKT
6.1 The "BDRV" signal from TDA4856 pin6 is a square waveform. It is inverted and amplified by
Q201, Q311 and Q312 constitute a buffer stage.
6.2 Q325, L301, D318, C323 is step-up circuit B+ = 45 * ( Ton + Toff ) / Toff.

B+ +45V

C334
R333 1000P C322
10 1KV (OPEN) L301
1W (D) 100V 900UH
(PE) 19.40195.001
+14V
A Q311
H945
D318
UG4D
+ C323
4.7U Q325
250V IRF630 R370
(EL) R371 47
PWM
10K
Q312
A733

Fig 6 BDRV & Step-up circuit

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7. HV Shutdown Circuit

The IC201 pin2 (XRAY) provides a voltage detector with a threshold. If the voltage at pin XRAY
exceeds this threshold (6.25v typical) the pins HDRV, BDRV, VOUT1 and VOUT2 are floating.
When anode voltage increases, the voltage at FBT (pin3) increases, the voltage at IC201 pin2 increases.
The shutdown voltage is about 28KV.

C204
+2.2U R216
15.8K
50V (1%) TP3 TP2
CLBL 16
HSYNC 15
VSYNC 14
VOUT1 13
VOUT2 12
EWDRV11

VCC 10

9

HDRV 8
GND 7

BDRV 6

BIN 5

BSENS 4

BOP 3
XRAY 2
HFLB 1
(EL)
+48V
i.c.

R217 R218
IC201 100K 22.1K
TDA4856 (1%) (1%)
17 HUNLOCK

31 HSMOD
21 VSMOD
20 ASCOR

32 FOCUS
26 HPLL1

30 HPLL2
25 SGND
22 VAGC

29 HCAP
24 VCAP

27 HBUF

28 HREF
23 VREF
19 SDA
18 SCL

Fig 7 HV- shutdown CKT

8.Horizontal linearity CKT

V772 Cs control truth table
Frequency range SC0 SC1 SC2 Cs Capacitor
Fh＜ 36K 0 0 0 C310+C311+C312+C313
36K＜Fh＜40K 0 0 1 C310+C311+C312
40K＜Fh＜51K 1 0 1 C310+C312
51K ＜Fh＜62K 1 0 1 C310+C312
62K ＜Fh＜72K 1 1 1 C310

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T301
19.70066.001
D
1
*
(RED)
DYH+
B+ A 15
2
DYH-
12
(WHT)
L304
10UH 16
B 19.50051.051
+6.5V
2 3 R322
10
2W D322 5
8

1N4148
R309 3
220
2W 5 4 Q322
H945
H-LIN 4
C321 R319
D312 560P Q324 10K 6
RGP10J 1KV C2235 C330
(OPEN) 9
50V
(D)
B
CS-2
C313 C312 C311
0.15U 0.33 1.0U +14V
250V 250V 250V
(MPP) (MPP) (MPP)
R316
C310 Q307 4.7K
0.3U Q308 IRF640
400V R338 IRF630 R320
(MPP) 100K 100K
1/4W 1/4W A D309
FR155
R317 C316
47K 0.047U
50V SC0
A (D) Q303 R315
H945 47K

R324 C317 D310
47K 0.047U FR155 SC1
50V Q304 R325
(D) R326 H945 47K
Q309 4.7K
IRF630
R321
100K A
1/4W +14V
D311 R312
C315 FR155 4.7K
R313 0.047U
47K 50V
(D) SC2
CS-1 Q305 R311
H945 47K

Fig 8 Linear circuit

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9. ABL CIRCUIT
When the beam current is over the limited current, the ABL circuit will pull down the
voltage of the video preamp (pin 10) to reduce the gain of video amplifier.

T301
19.70066.001

1

(RED)

15
2

12
(WHT)
16
ABLADJ
8 R308 D306 R310
10K 1N4148 1.5K
5 C324 1/2W
3 1500P ABL
100V R314
(PE) D307 6.8K
1N4148
4
6
9

Fig 9 ABL circuit

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10. TILT CKT

We can rotate raster clockwise or counterclockwise by changing the direction of the current flow
through the tilt coil.
When the voltage of MP202 (pin3) is larger than 8V, the current flows from Q205 to Tilt coil, other
wise, the current flows from tilt coil to Q206

+6.5V
+14V +14V
MP202
3P
Q207 1
R247 H945 R249
2.2K (OPEN) 2
+5V Q205 1/4W
H945 3
R246 R245 TILT-COIL
R243 10K 10K
(OPEN) + C228
Q206 2.2U
A733 50V
Q204 (EL)
TILT H945 + 2.2U
C225
R244 Q210
2.2K 50V A733
(EL)

Fig 10 TILT circuit

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11. Vertical Output Circuit

This vertical driver IC circuit is a half bridge configuration
The signals from TDA4856 OSC IC to TDA4863AJ

IC202
TDA4863AJ
-8.5V +14V

V-OUT
GND
C217

VP2
VP3
VP1
INN
INP
470U R227
16V 0.22
+ 1/2W

7
6
5
4
3
2
1
R228 (EL)
(FS)
1K
V1
C213
V2 D202 + 1000U
1N4003 25V
R229 (EL)
1K (105C)
C219 C218 R224 + C214
5600P 5600P R253 5.6 100U
100V 100V 180 DYV+ 1/4W 35V ZD202
(PE) (PE) R250 1/4W R251 R252 (EL) 20V
1.8K 1.8K 180
DYV- C216
C220 1/4W 0.1U
0.1U 100V R226 R274
100V (PE) 270 33K
(PE)
V+
C215 R275
470U 27K
R225 16V
1 + (EL)
1/2W
TR201
100

Fig11 Vertical output circuit

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Switching Power Supply Operation Theory
1. General Specification
Input Voltage: 90~264VAC (FULL RANGE)
Input Frequency: 47~63Hz
Output Requirement: Dc Output

+6V
+13V
+78V
+45V
-10V

2. Block Diagram

DEGAUSS
CIRCUIT

OUTPUT
RECTIFIER ISOLATION RECTIFIER
AC RFI SWITCHING AND
INPUT FILTER & ELEMENT TRANSFOR OUTPUT
FILTER -MER FILTER

FEEDBACK
CONTROL POWER
CIRCUIT SAVING
CONTROL

3. Circuit Operation Theorem
3.1 RFI FILTER
L
C603
L602 2200P L603
C601 250V
3 4 0.47U (Y)
R601
250V
(X) C602
1 2 2200P L604
250V
(Y)
N

FG

This circuit designed to inhibit electric and magnetic interference for meet FCC, VDE, VCCI standard
requirements.

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3.2 Rectifier and filter
L D602~D605
3 20D6 * 4
~
4 1
AC INPUT - +
C612
~2 + 220U DC OUTPUT
400V
N (EL)

When power switch is turn on, the AC voltage is Rectifier and filter by D603~D606, C612. The DC
output voltage will be 1.4*(ac input)

3.3 switching Element and isolation transformer

T601 FR701 C53
B61 6 11 (SHORT)
R604 C613
82K 0.01U
2W 1KV ZD601
(D)
C50 (OPEN)
12

C614 D610 D613
(OPEN) UF4007 (OPEN)
FR702
10
C51 L606 1
(SHORT)
(BEAD)
D608 L608
C608
47U RGP10D (BEAD)
25V 8
(EL) C624
220P
Q602 1KV
FS14SM-12 (D)

L607 15
(BEAD) R619
R608 D614 470
20K UF4007 2W 18
R607 *
0.15
2W 16
FR704
9 13 (SHORT) EGP30B
R611
1K

In a flyback converter operated in the discontinuous mode, the energy stored in the flyback
transformer(actually an inductor) must be zero at the beginning and end of each switching
period.
During the "ON" time, energy taken from the input is stored in the transformer when

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the switching transistor turn-off, this stored energy is all delivered to the output.

3.4 Output Rectifier and filter
The structure of each output is illustrated as below

T601 D1 L1

+ +
C1 C2

since the transformer T601 acts as a storing energy inductance, diode D1 and capacitor C1 are to
produce a dc output and additional L1, C2 to suppress high-frequency switching spikes.

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3.5 Control circuit

1N4004 C625 R607
(OPEN) 0.15
2W

7 6
8
VREF VCC OUT R611
3 1K
R613 R614 D611 IC601 ISSEN
36K 100K 1N4148 UC3842 *
4
R/C
COMP FB GND
C615 D612
2200P 1 2 5
1N4148 C619 ZD602
50V IC603 *
(PE) MCR100-3 24V
0.022U A
C620
50V
C618 R622 820P
C617 (D)
R612 + 4.7U 0.01U 510 50V
47 50V 50V (D)
R615
(D) K G +C627
(EL) 51K R620 10U
10K 50V
(EL)

C616 R616
0.01U
10K
100V M603 +6.5VA

(PE)
R738
82
1/2W
ZD603
4 1
5.1V
M604

The current mode control IC UC3842 is used in the switching power supply which function of each
pin
described as follows.
pin 1 : Error amplifier output pin 5 : Ground
pin 2 : Error amplifier reverse input pin 6 : Output
pin 3 : Current sense pin 7 : VCC
pin 4 : OSC sawtooth pin 8 : Reference Voltage:5V

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When power is initially applied to the circuit, capacitor C626 charges through R624, R623, ZD601.
When the voltage across C607 reaches a level of 16V, IC601 is turn-on the +5Vdc will be
set up at pin8 then R613, C615 generate a fixed frequency sawtooth wave to pin4, at this time
MOSFET will be driver by pin6 with square wave the pulse width of square wave is decided by
pin2, pin3 is current feedback control, It will to sense MOSFET current. The D613, D612, R614,
C617 are soft start components to avoid the duty too large when power starts up.

3.6 Feedback circuit
This power supply is a primary feedback circuit. It used IC601 for voltage regulation
, The output voltage differential signal will be detected and sensed to the pin2 of UC3842 for
comparison then the duty cycle of MOSFET will be decided to control the output voltage.

0.15
(OPEN) 50V (D) 2W

7 6 1

8 R611

VREF VCC OUT 1K
3

R614 D612 IC601 ISSEN

100K 1N4148 UC3842B

4
R/C
ZD602
COMP FB GND
24V
D613
1 2 5
1N4148

C619

0.022U
C620
50V
C617 C618 820P
+ (D)
10U 0.01U 50V
50V 50V (D)
(EL) (D)
R615

560K

C609 (EL)
+

0.22U 50V

R616 VR601 R617

57.6K * 2K 9.09K

R618
(OPEN)
* *

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3.7 DEGAUSS CIRCUIT
+12V
RL601
4 3 1
DEGAUSS
D740
1N4148
6 5 2
R741
2.2K

Q740
H945

TR602
2R9M

M602
B53 2P
2

1

L610
L611
3T
3T

L603 L604
180UH 180UH
C604
(OPEN)
250V
(Y)

This circuit has the function of auto degaussing and manual degaussing. When power supply is
switched ON it is auto degaussing stage. When user make the selection of the manual degaussing
function in OSD, the degaussing current will flow through coil to degauss the screen of monitor.
TR602 is a PTCR to control degaussing coil current

3.8 power saving control

Mode H-sync V-sync LED Power Rating
Normal Normal Normal Green 100﹪
Stand-by None Normal Amber ≦ 5W
Suspend Normal None Amber ≦ 5W
Off None None Amber ≦ 5W

When both of the H-sync and V-sync are none, the power supply +14v output will be cut-off.
The power input will be under 5W.
When the H-sync or V-sync is none, the power supply +14v output will be cut-off. The power input
will be under 5W.

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30. Video CKT

V772 VIDEO C.K.T. BLOCK DIAGRAM：

31. OSD Preamp CKT:

(a) AS shown in the block diagram:
The R/G/B signals will generate an enough amplitude of Vpp to show up on the
CRT screen after the amplification of two amplifiers. The first one, preamp CKT,
process the signal and mix up the OSD, and the second one does the power
amplification.

(b) OSD preamp IC101, LM1269, will output the R.G.B signals separated. The R.G, B
driver will control the gain of these three guns individually to approach the white
balance of CRT.

(c) The signal H-Blank is to let the output of LM1269 down to 0.2V while non-display
duration. Then the CRT driver CKT will generate a level higher than Black Level. (i.e.
SYNC TIP), therefore the video signal will be blanked in order to prevent the fold over
to occure while adjusting H-phase. Besides, the SYNC TIP is used for
the DC Restoration of cascode CKT.
(d) LM1269 is equipped with OSD mixer, when signal CUT is Low, the output of
LM1269 is video signal when signal CUT goes high, the output will be OSD signal.

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32. CRT DRIVER CKT:
Output stage adopts CRT driver LM2468 to amplify the signal which has been
recessed by LM1269 to a enough amplitude of Vpp, then display on the CRT. The IC
contains three high input impedance, wide band amplifiers which directly drive the
RGB cathodes of a CRT. The gain of each channel is internally set at -15 and can
drive CRT capacitive loads as well as resistive loads presented by other application
limited only by the package’s power dissipation.
33. DC Restore CKT:
(a) The video signal amplified by the output stage is coupled to CRT by way of AC
coupling. So DC restoration CKT is needed to do the white balance adjustment.

(b) This DC restoration circuit adopts SYNC TIP CLAMP, in the duration of
SYNC TIP the capacitor charges, and the capacitor discharge in the other time.
The Black Level is kept to the level of DC restoration set by UC.

34. ABL CKT: (Auto Brightness Limit)

ABL is a protection circuit. When the anode current goes higher than the setting
value of ABL circuit. ABL will pull down the voltage of contrast to limit the anode
current. This is helpful to protect CRT.

35. H-BLANK CKT:

Affair the collect pulse comes from FBT being shaped and inverted, it will be sent
to preamp CKT and used as the H-Blank.

36. Brightness, V-blank, change mode blank, spot killer CKT:

(a) About the cut off voltage , while the voltage, cathode to G1 , over the cut off ,
voltage, the picture will disappear, If cut off voltage of the CRT is
set at 110V and the black level of cathode is 60v, the picture won’t show,
the signals higher the black level once the G1 voltage is lower than-50v.
(b) As described above, we may using the voltage control G1 as the brightness
control. Generally the G1 control range is about 10~15V if the raster
brightness is form 0 to 0.8 ft-L.
(c) Similarly, we may overlap a negative pulse of vertical duration on the G1
voltage to prevent the vertical retrace line from showing on the picture , This
is to keep the voltage cathode to G1 over the cut off voltage during the
period of vertical retrace.

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(d) In order to avoid the picture occur transiently while change mode, pull
down the G1 voltage and let the voltage cathode to G1 over CUT OFF voltage.
This will make the picture blanking.
(e) While monitor turned off , the discharge speed of high voltage circuit is slow
since there is no deflection scan act on the electronic beam, a spot which will
destroy the phosphor of CRT. So the SPOT KILLER circuit will generate a
negative voltage higher than CUT OFF to the G1 to beam this is to protect
the CRT.

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ACER V772 MICROCONTROLLER CIRCUIT OPERATION THEORY

1. Introduction:
This model, V772, will support powerful OSD function to help end user fine adjustment. The
Microcontroller circuit of the V772 can determine what mode it is by detecting the frequency of
horizontal and vertical synchronous and the polarity of horizontal synchronous, and provide DC
voltages to control the picture and save the adjusted value into the EEPROM by using the OSD,
"On Screen Display control", that means the user can get any information of the picture display or
adjust it and save the status values into the EEPROM by choosing and pressing the proper key
according to the indication of the OSD. In addition, user can press i-key to do auto-calibration.

2. Block diagram :
The major parts of V772 Microcontroller circuit are MCU, EEPROM, OSD IC, and Auto
Calibration Module. The circuit block diagram is shown as below.

MCU(MTV112)
Detecting the Degaussing
Hsync input signals Blanking
Vsync of H,Vsync & SC0 - SC2
H-polarity H-polarity. OSD IC
EEPROM Display OSD
Preset mode data, and output
User saved mode data. Searching for PWM to video
the same saved circuit
mode timing PWM
Reset circuit with the input To deflection
output circuit
12MHz Crystal signals and
circuit get the data. AP3113
DCLK
Auto HBNK
Control Panel DATA Calibration VBNK
Checking if the Module RGB
5 keys input
i-key
valid key be pressed Signal
Left,Right,Enter,Exit and do key function.
PC
(UART) External RS232
adjustment auto alignment
function program

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3.MCU and the peripheral circuit operation theory:

3-1.MCU function:
The MCU is MTV112, it is an 87C51 with PWM output controlled microcontroller, after
power on, the reset circuit output a "High" to "Low" signal (>40mS) and the 12MHz crystal
oscillated circuit working, the MCU begin to manages the following functions,
(1) To detect mode and output proper SC0, SC1 and SC2 to deflection circuit.
(2) To check if there is the same saved mode in the EEPROM and get the data to transfer into
DC voltages by PWM output and RC filter circuits to control the picture, color, contrast
and brightness.
(3) To check if there is the valid key be pressed and do the key function.
(4) To memorize mode timings and any adjustable parameters of the picture into EEPROM.
(5) To output data to OSD IC for making an "on screen display control" menu.
(6) The inner registers and PWM output of MCU can be controlled by the external PC
alignment program.
(7) To calibrate the size, position, and geometry of the picture by pressing i-key. It will be
placed right size and position.

3-2.How to detect mode timing:
Only when the mode timing input is stable, we can adjust the picture and check the
horizontal and vertical sync frequency by the OSD menu, and the mode timing input mean the
horizontal sync signal and the vertical sync signal.

(1) The vertical sync frequency measurement:
We use the base timer, it can generate a count during a fixed time, this fixed time is
12/12MHz and we call it "Time base", so when the first vertical sync generated, we enable
the base timer, and the next vertical sync generated, we disable the base timer, and we only
need to calculate how many counts are during a vertical sync period. The formula is
Vertical sync frequency
= FV
= 1 / Vertical sync period
= 1 / [Counts * (Time base)]
==> Vertical sync frequency = 1000000 / Counts

(2) The horizontal sync frequency measurement:
We use the event counter for calculating how many counts are during a long fixed time,
because the vertical sync period is longer than the horizontal sync period, we can enable the
event counter when the first vertical sync generated and disable the event counter when the
next vertical sync generated, this time, we can get the horizontal sync counts during a vertical
sync period.

The formula is Horizontal sync frequency
= FH
= Horizontal sync counts / Vertical sync period
==> Horizontal sync frequency
= Horizontal sync Counts / Vertical sync period

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3-3.What are the valid key functions for user:
There are four keys on V772 control panel. They are "Left," "Right," "Enter," and "Exit."
There are used for OSD controlling. "Enter" for entering sub-menu of main menu, "Exit"
for escaping to main menu from sub-menu or leaving OSD menu, and "Left," "Right" for
adjusting the bar value.
Except the OSD basic key functions, the user can only press "Right" for brightness
adjustment, or "Left" for contrast adjustment.

3-4.How to memorize the timing and adjusted data:
The EEPROM of V772 is 24C08, it has 1024 bytes memory size and communicates with
MCU by two wires of I2C bus, one wire is "SCL," the other is "SDA".
The MCU send clock and data to EEPROM to do "Write" function and send clock and
receive data from EEPROM to do "Read" function by these two wires.
We define three parts of storage area. One is for the storage of the factory preset data,
another is for saving user adjusted data, the other is for common settings area where stored
the data of the OSD color temperature settings, contrast and brightness value.

3-5.How to display the OSD menu:
The OSD IC of V772 is AP3122 which is developed by vender, it receives the data of the
OSD fonts and attribute what we want to display on the screen from the MCU by 2 wires of
communication, and exports OSD window data and PWM volume to the VIDEO circuit, the
block diagram is shown as below,

MCU(MTV112) OSD IC (AP3114)
SDA
(1)Send data to Shift receiving Output to
PWM
RAM for OSD SCL register and decoder. output the VIDEO circu
fonts or
attribute.
(2)Send data to
Control RAM Fonts ROUT
Control
registers register generator GOUT
for PWM ouput s BOUT
or OSD window FBKGC
VSYNC
VCO circuit
HSYNC
(H-BLANK,HBNK)

3-6.How to execute the auto alignment function:
The MCU MTV112 supports the UART function, it has 2 I/O serious ports, one is the
receiver, the other is the transmitter, they are connected with an interface to PC and PC can
execute alignment program by RS232 communication to send the formatted data to the MCU
for adjusting any adjustable parameters of the picture and saving the adjusted values into

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EEPROM. By this way, we can get the products with the same quality and reduce the
manufacturing time.

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V772 circuit operation theory

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