TA8801AN ,VIDEO/CHROMA/DEFLECTION PROCESSOR IC FOR NTSC COLOR TVTA8801ANTA8801AN is an integrated circuit for NTSC color TV,which has a function of Video/Chroma/De ..
TA8804F ,FM DEMODULATION IC FOR BROADCASTING SATELLITE RECEIVERJAN-UQ-UZ 11:19 FR(hFfWiWh ELECTRONIC +9493593953 T-473 P.02 F-cetINTEGRATED CIRCUIT TA8804 FTOSHIB ..
TA8805F ,FOR LCD TVS, PIF AND SIF SYSTEMTA8805F,TA1207F TOSHIBA BIPOLAR LINEAR INTEGRATED CIRCUIT SILICON MONOLITHIC TA8805F,TA1207F FOR ..
TA8805F ,FOR LCD TVS, PIF AND SIF SYSTEMBLOCK DIAGRAM (TA8805F)
TA8814 ,COLOR TRANSIENT IMPROVOR IC FOR TV
TA8814N ,COLOR TRANSIENT IMPROVER IC FOR TVTA8814NTARR1ANHIVI I‘The TA8814N is an integrated circuit having thefollowing two functions in the ..
TC648VOA , Fan Speed Controller with Auto-Shutdown and Over-Temperature Alert
TC649EOA , PWM Fan Speed Controller with Auto-Shutdown and FanSense™ Technology
TC650AEVUA , Tiny Integrated Temperature Sensor & Brushless DC Fan Controller with Over-Temperature Alert
TC651CGVUA , Tiny Integrated Temperature Sensor & Brushless DC Fan Controller with Over-Temperature Alert
TC660COA , 100mA CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER
TC660COA , 100mA CHARGE PUMP DC-TO-DC VOLTAGE CONVERTER
TA8801AN
VIDEO/CHROMA/DEFLECTION PROCESSOR IC FOR NTSC COLOR TV
TOSHIBA
TOSHIBA BIPOLAR LINEAR INTEGRATED CIRCUIT SILICON MONOLITHIC
TA8801AN
TA8801AN
VlDEO/CHROMA/DEFLECTION PROCESSOR IC FOR NTSC COLOR TV
TA8801AN is an integrated circuit for NTSC color TV,
which has a function of Video/Chroma/Deflection
Processor inside a 36-pin shrink DIP plastic package. This
is most suitable for high-definition, large-screen
televisions.
FEATURES
Video section
Black stretch circuit
_-----" _
_----",
SDIP36-P-500-1.78
Contour improvement by built-in delay lines Weight : 2.98g (Typ.)
High-brightness color
DC restoration
On-screen-display section
OSD by digital R/G/B inputs
Picture mute
Contrast controllable
Deflection section
High-performance sync. separator circuit
Adjustment-free oscillator circuit based on count-down system
Horizontal phase adjustable
X-ray protection circuit
Chroma section
R-Y, B-Y axes demodulation
Automatic phase control (Adjustment-free)
TOSHIBA
BLOCK DIAGRAM
KILLER
TINT CONTROL
COLOR CONTROL
CONTRAST CONTROL
BRIGHTNESS CONTROL
SHARPNESS CONTROL
V/C/D/OSD Vcc
CHROMA INPUT
Y CLAMP
DL AUTO ADJ.
BLACK PEAK HOLD
Y INPUT
BLACK STRETCH
START POINT
DC RESTORATION
SYNC. SEPARATION INPUT
19 KILLER
CONTROL
CONTROL
BRIGHTNESS CLAMP
CONTRAST
PICTURE
CONTROL
DL AUTO
ADJ. DL
CORRECT ON
PULSE INSERT
APL DET.
BLACK PEAK
STRETCH
PEDESTAL
PEDESTAL
SMOOTHING
SEPARATION
INTERFACE
DIFFEREN-
BLK PULSE
INSERT
HIGH BRIGHT
SEPARATION
OUTPUT
FBP INPUT
APERTURE
COMPENSATOR
H.Ramp
32fH VCO
V. SYNC.
SEPARATION
VP OUTPUT
TA8801AN
OSD B INPUT
OSD G INPUT
OSD R INPUT
B-Y OUTPUT
G-Y OUTPUT
R-Y OUTPUT
-Y OUTPUT
SYNC. SEPARATION OUTPUT
FBP INPUT
H. OUT
DEF VCC
H. PHASE CONTROL
V. SYNC. SEPARATION FILTER
VP OUTPUT / OSD CONTRAST
TOSHIBA
TA8801AN
TERMINAL FUNCTION
['I',u. PIN NAME FUNCTION INTERFACE CIRCUIT
Cir) - .
Ci) 793C l TO COLOR
"' DIFFEREN-
. The terminal for vertical pulse TIAL
Vertical Pulse . OUTPUT
1 Out ut/OSD output. And OSD contrast IS )t--veou.m)r CIRCUIT
p adjusted by the DC voltage
Contrast . . . T .cl
supplied this terminal. , g OSD
m CONTRAST
s-'','. ic, i100
tXY r " r,] "A
2 Vertical Sync. The terminal for vertical sync. (é SYNCSEPARATION
Separation Filter separation filter. l
3 H. AFC Filter The terminal for horizontal AFC 5
filter. ,
The terminal for 32fH (503kHz)
ceramic resonator.
4 32f VCO
H CSB503F30 (Murata Manufacturing
Co. product) is recommended.
. . . Ci) 1:
Horizontal Phase Horizontal phase Is-adjusted by DC GY-- mm Cl
5 voltage supplied this terminal. 1; cl x
Control . . if T
The variable range IS 2.4ps (Typ.). ' o ip,
d7 T 4
Horizontal pulse is outputted from @
this terminal. Its amplitude is fit
7 Horizontal Pulse S.OVp.p (typ.) and duty is 43% ai'-"
Output (typ). Output form is emitter
follower. And keep the output Ci)-,
current less than 12mA. -?S-
TOSHIBA
TA8801AN
my PIN NAME FUNCTION INTERFACE CIRCUIT
The terminal for an overvoltage C6) gg
protection circuit. q S
The threshold level is 3.65V (typ.). ' '/2
8 X-ray Protection The horizontal output terminal (pin .
9) is pulled Low when a voltage
applied to this pin is greater than
the threshold level.
h . I f fl k I
9 FBP Input I e termma or ybac pu se
input.
The terminal for a sync. signal
10 Sync. Separation output. Output form is an open-
Output collector. And the current flowing
into is 0.15mA (typ.).
The terminal for -Y output.
Blanking can be disabled by
12 -Y Out ut connecting a resistor between this
p pin and GND and flowing a current
more than 0.2mA. And keep the
output current less than 2.5mA.
13 R-Y Output ":itLtr'ci,rt",tust.for color-difference
1: g: ttlt Keep the output current less than
p 4.8mA.
16 R Input The terminals for OSD signals input.
17 G Input The threshold voltage is 0.75V
18 B Input (typ.).
TOSHIBA
TA8801AN
my PIN NAME FUNCTION INTERFACE CIRCUIT
h I b d lt 3009
. . T e termina to e connecte a -
19 Killer Filter killer filter. ® L. PW .
op-.it- 330/1A
d, ' .
Th t . I t b t d fi
. e ermma o e connec e an o Y-
20 APC Filter APC filter. @ m? -
7: ji- Lr
The terminal to be connected a "iji,t. g
21 X'tal 3.58MH2 crystal resonator for the (i)) A S‘von m
VCXO. lt
. . c:
22 Tint Control The terminal forltint control. Cie)- if
Control voltage IS 0V to 5V. , :
The terminal for color control. "ii
Control voltage is 0V to 5V. Q 27kQ Cl
23 Color Control The voltage of this terminal turns Th-rf"] g
to low level while the color killer is cc a
1{27162 Cl
Th . I f l. Ca)---- F-t x
24 Contrast Control e termina or-contrast contro é) "WEVj A F.
Control voltage IS 0V to 5V. -. L:
I td) C) T:
25 Brightness The terminal for brightness control. ar
Control Control voltage is 0V to 5V. (is)- 2m it
TOSHIBA TA8801AN
my PIN NAME FUNCTION INTERFACE CIRCUIT
26 Sharpness The terminal for sharpness control.
Control Control voltage is 0V to 5V.
28 ACC The terminal to be connected the
ACC filter.
The terminal for chroma input. The
29 Chroma Input standard input level is 286mVp-p in
burst amplitude.
The terminal to be connected a Y
clamp filter.
Use a low leak capacitor for this
filter.
30 Y Clamp
The terminal to be connected a ji-
. . . ,2
Delay Time fil.t.er for a dtlay. time autematlc O 'h
. adjustment circuit for the internal 1 V
31 Automatic .
Adjustment delay line.
Use a low leak capacitor for this Ir
. _ JI.
filter. (é HORIZONTAL BLANKING
6 2001-06-25
TOSHIBA
TA8801AN
PIN NAME
FUNCTION
INTERFACE CIRCUIT
Black Peak Hold
The terminal for a filter to hold
black peak.
The voltage of this terminal can
control the gain of black stretch
amplifier.
When the voltage is higher than
pedestal level, the gain goes up
and when the voltage is lower, the
gain goes down.
Black stretch is turned off by
supplying 5V or more to this
terminal.
Y Input
The terminal for input of luminance
signal (negative sync., 1.0Vp_p). -Y
output turns out 4.0Vp-p with
contrast max.
Because the pedestal level is
clamped at the input pin, the
signal source's impedance must be
sufficiently low. The pedestal
voltage is clamped to 4.0V (typ.).
' C, II CLAMP PULSE
Black Stretch
Start Point
The terminal for setting the start
point of black stretch.
The higher the voltage of this
terminal is. The higher the start
point is.
DC Restoration
The terminal to adjust DC
restoration ratio.
The DC restoration ratio (TDC) is
determined by the equation below.
T - SkQ
DC'5k0+RQ
The smaller the value of external
resistance R, the greater the
amount of correction. You can
monitor a black-stretched Y signal
with the sync. signal eliminated by
x30+100[%]
leaving this terminal open.
TOSHIBA TA8801AN
['l:'). PIN NAME FUNCTION INTERFACE CIRCUIT
The terminal for input of the sync. Ci) '
separation circuit. i c:
Input a 2Vp-p video signal with W 5
. negative sync. Because the coupling 5009 H
36 1'r,tseparation capacitor also functions as a sync Cii) 'alt-AL,,,,,,',,
npu separation filter, make sure the 1: 12kQ
signal source's impedance is I, a,
sufficiently low. Use a low leak $1: "T-'
capacitor for coupling. d,
MAXIMUM RATINGS (Ta =25°C)
CHARACTERISTIC SYMBOL RATING UNIT
Supply Voltage VCC 15 V
Power Dissipation PDmax 1.8 (Note) W
Input Signal Voltage ein 5 Vp-p
Operating Temperature Top, - 20~65 ''C
Storage Temperature Tstg - 55--150 "C
(Note) When using this device at a temperature higher than 25°C, deduct 14.4mW from the
above rated value for each increment of 1°C.
ELECTRICAL CHARACTERISTICS
DC VOLTAGE CHARACTERISTICS (Unless otherwise specified Vcc=12V, H.VCC=9V, Ta =25°C)
PIN No. PIN NAME SYMBOL PIN VOLTAGE (V) MEASURING CONDITION
MIN. TYP. MAX.
1 VP output/OSD contrast V1 7.40 7.70 8.00 -
3 H AFC V3 7.00 7.50 8.00 -
4 32fH V4 5.70 6.00 6.30 -
5 Horizontal position adjustment V5 4.25 4.50 4.75 -
7 Horizontal output V7 2.30 2.50 2.70 -
9 Flyback pulse input V9 0.48 0.53 0.58 -
10 Sync separation output V10 - 9.00 - RL= 10kQ (to Va)
12 -Y output V12 6.90 7.20 7.50 -
13 R-Y output V13 7.00 7.50 8.00 -
14 G-Y output V14 7.00 7.50 8.00 -
15 B-Y output V15 7.00 7.50 8.00 -
19 Killer filter V19 7.70 7.90 8.10 With no input
20 APC filter V20 8.60 8.90 9.20 -
21 3.58MHz X'tal V21 5.75 5.95 6.15 With this terminal open
22 Tint control V22 2.30 2.50 2.70 -
8 2001-06-25
TOSHIBA
TA8801AN
PIN No. PIN NAME SYMBOL PIN VOLTAGE (V) MEASURING CONDITION
MIN. TYP. MAX.
23 Color control V23 2.30 2.50 2.70 Killer turned off
24 Contrast control V24 2.30 2.50 2.70 -
25 Bright control V25 - 2.50 - -
26 Picture quality adjustment V26 - 2.50 - -
28 ACC filter V28 10.60 11.30 12.00 With no input
29 Chroma input V29 4.50 4.70 4.90 -
30 Y clamp V30 5.40 6.40 7.40 Bright 2.5V/FBP inputted
31 Delay time automatic adjustment V31 6.60 7.40 8.20 -
32 Black peak hold V32 4.20 4.50 4.80 -
33 Bright input V33 3.80 4.00 4.20 -
34 Black stretch V34 3.80 4.00 4.20 -
35 DC restoration V35 3.80 4.00 4.20 -
36 Sync separation input V36 2.00 2.25 2.50 AC GND/FBP inputted
Current consumption
(Unless otherwise specified, Vcc=12V, HA/CC =9V at Ta =25°C)
PIN No. PIN NAME SYMBOL CURRENT CONSUMPTION (mA)
MIN. TYP. MAX.
6 DEF Vcc ICC 6pin 8.5 20.0 33.0
27 V/C/OSD Vcc ICC 27pin 43.5 56.5 93.0
AC CHARACTERISTICS (Unless otherwise specified, Vcc=12V, H.Vcc=9V, Ta =25°C)
Video and OSD section
TEST TEST
CHARACTERISTIC SYMBOL CIR- MIN. TYP. MAX. UNIT
CONDITION
Y Input Pedestal Clamp Voltage V33 1 (Note l) 3.8 4.0 4.2 V
TCL1 7.20 7.65 8.10
Input Pedestal Clamp Pulse Phase 1 (Note 2) #5
TCL2 8.35 8.80 9.25
DC Restoration Amp Gain AV35 1 (Note 3) 0.28 0.34 0.40
Black Stretch Amp Maximum Gain GVBE 1 (Note 4) 1.35 1.45 1.55
Y Input/Output Delay Time TY 1 (Note 5) 110 120 130 ns
Y Input Dynamic Range DR33 1 (Note 6) 0.9 1.1 1.3 Vp-p
G + 6.5 + 8.5 + 10.5
Sharpness Control Range SMAX 1 (Note 7) dB
GSMIN -2.5 -4.5 -6.5
Sharpness Control Center Characteristic GSCT 1 (Note 8) + 2.0 +3.5 + 5.0 dB
. VSTI 225 260 295
Black Stretch Start Point 1 (Note 9) mVp-p
VST2 385 420 455
9 2001-06-25
TEST TEST
CHARACTERISTIC SYMBOL CIR- MIN. TYP. MAX. UNIT
CUIT CONDITION
Black Peak Detection Period
. . TBpH 1 (Note 10) 20 22 24 H
(Other Than Horizontal Blanking Interval)
AC Gain Gv 1 (Note 11) 4.6 5.2 5.8
Frequency Characteristics Gf 1 (Note 12) -3 0 + 3 dB
Contrast Adjustment Voltage Range AVct 1 (Note 13) 0.29 0.44 0.66 V
Contrast Adjustment Center Voltage Vcto 1 (Note 14) 2.30 2.50 2.72 V
Brightness Adjustment Voltage Vbr 1 (Note 15) 2.2 2.5 2.8 V
Brightness Adjustment Sensitivity Gbr 1 (Note 16) - 1.5 - 1.7 - IS
DC Restoration TDC 1 (Note 17) - 0 50 mV
Minimum Output Vdo1 1 (Note 18) - 0.6 0.9 V
Maximum Output Vdo2 1 (Note 19) 8.3 8.7 - V
Vertical Blanking Output Level VV 1 (Note 20) 11.0 11.8 12.0 V
Sink Current During Vertical Blanking IV 1 (Note 21) 0.4 0.6 0.85 mA
High Bright Color Gain GHBC 1 (Note 22) 0.08 0.10 0.12
VDCY 4.3 4.6 4.9 V
OSD Output DC Voltage 2 (Note 23)
VDCC 4.7 5.0 5.3 V
OSD Output Maximum Voltage VOSDMAX (Note 24) 8.2 8.4 8.6 V
OSD Mode Switching Threshold Voltage VOSDSW (Note 25) 0.65 0.75 0.85 V
OSD High Voltage Switching Threshold Voltage Vospmsw (Note 26) 1.9 2.1 2.3 V
TR DY - 35 100
OSD Mode Switching Rise Time OS 2 (Note 27) ns
TROSDC - 45 100
. . . . tROSDY - 30 100
OSD Mode Switching Rise Transfer Time 2 (Note 28) ns
tROSDC - 40 100
z-F - 20 100
OSD Mode Switching Fall Time OSDY 2 (Note 29) ns
TFOSDC - 45 100
. . . tFOSDY - 25 100
OSD Mode Switching Fall Transfer Time 2 (Note 30) ns
tFOSDC - 45 100
OSD High Voltage Switching Rise Time TROSDH| 2 (Note 31) - 40 100 ns
OSD High Voltage Switching Rise Transfer Time tRQSDHI 2 (Note 32) - 50 100 ns
OSD High Voltage Switching Fall Time TFOSDH| 2 (Note 33) - 45 100 ns
OSD High Voltage Switching Fall Transfer Time tFOSDHI 2 (Note 34) - 50 100 ns
10 2001-06-25
TOSHIBA TA8801AN
Chroma section
TEST TEST
CHARACTERISTIC SYMBOL CIR- MIN. TYP. MAX. UNIT
CUIT CONDITION
F1 2.04 2.65 3.44
ACC Characteristic ea 3 (Note 35) 0.34 0.67 1.00 Vp-p
A 0.90 1.00 1.30
V23 2.30 2.50 2.72
Color Control Characteristic 3 (Note 36) V
AV23 0.29 0.44 0.66
V24 2.30 2.50 2.72
Contrast Control Characteristic AV24 3 (Note 37) 0.29 0.44 0.66 V
eu 15.9 18.0 20.1 dB
Maximum Input Level EMAX 3 (Note 38) 0.88 1.10 2.00 Vp-p
Killer On Input Level eBK 3 (Note 39) 1.12 2.24 5.62 mi/p-p
APC Frequency Control Sensitivity , 3 (Note 40) 1.0 1.7 2.9 Hz/mV
APC Pull-ln/Hold Range :12; 3 (Note 41) 250 500 1000 Hz
eR 1.72 2.23 2.90
Color-Difference Output Level e6 3 (Note 42) 0.63 0.82 1.06 Vp-p
ea 2.04 2.65 3.44
eR/eB 0.73 0.84 0.97
Color-Difference Output Relative Amplitude 3 (Note 43)
eeleB 0.26 0.31 0.36
6R - B 88 95 102
Color-Difference Output Relative Phase 3 (Note 44) tl
" - B 230 240 250
61 35 45 55
62 35 45 55 tl
Tint Control Characteristic t? 3 (Note 45) 80 90 100
V37 2.30 2.50 2.72 V
AV37 0.29 0.44 0.66
ER 3.65 4.45 5.56
Color-Difference Maximum Output Level EG 3 (Note 46) 1.35 1.65 2.06 Vp-p
EB 4.35 5.30 6.62
Residual Carrier Level 0149 3 (Note 47) - - 15 mi/p-p
Residual Harmonic Level U14eH 3 (Note 48) - - 75 mVp.p
11 2001-06-25
TOSHIBA TA8801AN
Deflection section
TEST TEST
CHARACTERISTIC SYMBOL CIR- MIN. TYP. MAX. UNIT
CONDITION
Sync Separation Input Sensitive Current IIN36 4 (Note 49) 15 25 40 pA
H. AFC Phase Detection Current IDET 4 (Note 50) 230 330 470 PA
Phase Detection Stop Period Tcog 4 (Note 51) - 258--6 - H
32fH VCO Oscillation Start Voltage VON 4 (Note 52) - - 4.0
Horizontal Output Start Voltage VHON 4 (Note 53) 4.3 4.9 5.3 V
Horizontal Free-Running Frequency fHO 4 (Note 54) 15.584 15.734 15.884 kHz
. I . I fHMAX 16.500 16.700 16.900
Horizontal Oscillation Frequency Variable Range 4 (Note 55) kHz
fHMIN 14.700 15.000 15.300
Horizontal Oscillation Control Sensitivity ,BH 4 (Note 56) 2.2 2.5 2.8 kHz/V
Horizontal Output Pulse Duty Cycle TH7 4 (Note 57) 41 43 45 %
. VH7 4.7 5.0 5.3 Hz
Horizontal Output Voltage 4 (Note 58)
VL7 - o 100 mV
Overvoltage Protection Detection Voltage VSON 4 (Note 59) 3.55 3.65 3.75 V
Overvoltage Protection Retention Voltage VH6 4 (Note 60) - - 2.5 V
Horizontal Sync Phase SPHI 4 (Note 61) 2.6 2.8 3.0 #5
Gate Pulse Start Phase GPI 4 (Note 62) 5.2 5.5 5.8 /IS
Gate Pulse Width GP2 4 (Note 63) 1.8 2.1 2.4 ,us
Horizontal Screen Phase Adjustment Variable
AGS 4 (Note 64) 2.2 2.4 2.7 ,us
Vertical Free-Running Frequency fvo 4 (Note 65) 48 53 58 Hz
. I Tr1 4 (Note 66) - 10 -
Vertical Output Pulse Width H
Tr2 4 (Note 67) - 10 -
. fpv1 - 224.5 -
Vertical PuII-In Range 4 (Note 68) H
fPV2 - 296.5 -
12 2001-06-25
TOSHIBA TA8801AN
TEST CONDITION
MEASUREMENT CONDITION (VCD-VCC = 12V, Ta = 25 t 3°C)
NOTE ITEM SYMBOL SW & VR MODE
MEASUREMENT METHOD
SW02SW24SW26SW32SW33 VR24 VR26
1 Y input V33 ON ON OFF A A Max. Open (1) Set Y input AC GND.
pedestal (2) Set sync. separation input AC GND.
clamp (3) Connect 10k0 between the vertical sync
voltage separation filter terminal (pin 2) and H.Vcc
(to set the V. free-run to 262.5H).
(4) Measure the DC voltage on pin 33.
Y input TCL1 t t (1) Adjust VRH15 so that the HIGH level width
pedestal of the waveform on pin9 is ll/rs.
clamp pulse (2) Observe the waveform on pin33.
phase 20m Vcc
(iiy-"17iC-2y'
TCL2 i-, TCL2 -i-m,' I
Waveform on pin 33 i-TCLI -"I t
Waveform on NB
DC AV35 t t (1) Under Note 1's condition adjust V meter to
transmission set pA meter reading 0A.
rate - +
compensa-
tion amp pzA meter v meter
gain J
(2) While changing V meter's value, measure
the variation of -Y output in picture period.
When A total zero
Y out ut When changed
Cd,'),',',':',,, 0.1 to 0.2V
Waveform on In AV f-
(3) AV35--dv w" 0.1 w" Y Gain (Gv)
Black stretch GVBE t f (1) Input a 0.1Vp.p, 500kHz sine wave into the
amp. Y input. . Pin 32 Pin 32
maXImum (2) Apply 4.2V to pIn 34.
gain (3) Measure the amplitude on pin 35 is >
under condition A. NA Np-p)] u; 3
(4) Measure the amplitude under J l
condition B. [VB (Vp-p)]. A B
(5) GVBE =VB =.VA
Y input/ TY OFF t (1) Input 2T pulse into Y input.
output delay (2) Measure the delay time between Y input
time (pin 33) and -Y output (pin 12).
Y input DR33 ON Min. (1) Connect the power supply to pin 33.
dynamic (2) While raising the voltage from the value
range measured in Note l, measure the voltage
where -Y output voltage (pin 12) stops
increasing. [V]
DR33 = V - V33
TOSHIBA TA8801AN
MEASUREMENT CONDITION (VCD-VCC= 12V, Ta=25i3°C)
NOTE ITEM SYMBOL SW & VR MODE
MEASUREMENT METHOD
SW02SW24SW26SW32SW33 VR24 VR26
7 Sharpness GSMAX ON ON ON A B Max. Max. (1) Input a 50mVp_p sine wave into Y input.
control (2) Set the Sharpness control to the maximum.
range (3) Measure the Y output amplitude at 10kHz
[V10K] and 2.4MHz [VpK] and calculate.
GSMAx=20€og (VPK/V10K)
GSMIN t t t t t t Min. (1) Input a 50mVp-p sine wave into Y input.
(2) Set the Sharpness control to the minimum.
(3) Measure the Y output amplitude at 10kHz
[V10K] and 2.4MHz [VpK] and calculate.
GSMIN =208og (VPK/V10K)
8 Sharpness GSCT t t t t t t Adj. (1) Input a 50mVp-p sine wave into Y input.
control (2) Set the sharpness control to center (2.5V).
center (3) Measure the Y output amplitude at 10kHz
characteristic [V10K] and 2.4MHz [VpK] and calculate.
GSCT= 20tog (WW V10K)
9 Black stretch VSTI OFF t OFF t A 1 Open (1) Connect the power supply to pin 33.
start point (2) While raising the supply voltage from the
voltage obtained in Note 1, measure the
variation of voltage on pin 33 and read VST.
(3) Do (2) when the voltage of pin M is Note
1's voltage [V5T1] and Note 1 plus 0.5V
[VST2]-
Pin 35
VST2 Pin 32 =5v
........ l” Intersecting point of extended
/ 5 lines of black-stretch part
A _ Pin32=3v
, Pin 33
’v1' VST
10 Black peak TBpH ON t t B t 1 t (1) Set Y input and sync. separation input AC
detection GND.
period (2) Observe the waveform on pin 32.
(other than _
. Horizontal
horizontal
blanking pu se TBPH
interval)
258--259 20H
14 2001-06-25
TOSHIBA
TA8801AN
SYMBOL
MEASUREMENT CONDITION (VCDA/CC= 12V, Ta=25i3°C)
SW & VR MODE
MEASUREMENT METHOD
AC gain
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Input a 10kHz, 0.3Vp_p sine wave
into pin 33.
(3) Measure the amplitude on pin 12.
(4) GV = V12 (Vp.p) / 0.3
Frequency
characteris-
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Input a 0.3Vp-p sine wave into pin
(3) Adjust sharpness so that the
amplitude of Y output for 10kHz
input is same as for 2.4MHz input.
(4) Measure the amplitude of Y output
for 100kHz input [V12100kH21 and
for 6MHz input [V125MHZ].
(5) Gf = 20fog (V126MHZ + V12100kHZ)
Contrast
adj ustment
voltage
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Input a 10kHz, 0.3Vp-p sine wave
into pin 33.
(3) Consider that the maximum
contrast is 100% and the minimum
contrast is 0%, then measure the
difference of contrast control
voltage between 10% and 90%.
Contrast
adj ustment
center
voltage
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Measure the contrast control
voltage for 50%.
Brightness
adjustment
voltage
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Measure the voltage at the
brightness terminal.
TOSHIBA
TA8801AN
SYMBOL
MEASUREMENT CONDITION (VCDA/cc= 12V, Ta=25i3°C)
SW & VR MODE
MEASUREMENT METHOD
Brightness
adj ustment
sensitivity
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Raise the voltage at the brightness
terminal by 1V.
(3) Measure the picture-period voltage
on pin 12. (V12H)
(4) Gbr= (V12H - 6.8)
restoration
(1) Adjust brightness so that the
picture-period voltage on pin 12 is
(2) Input a stairstep signal into pins 33
and 36.
(3) Adjust contrast so that the
amplitude of stairstep output from
pin 12 is 1.25V.
(4) Measure the variation of point A
when APL is varied from 10% to
Output signal on pin 12
TOSHIBA
TA8801AN
MEASUREMENT CONDITION (VCDA/CC= 12V, Ta=25i3°C)
NOTE ITEM SYMBOL SW & VR MODE
MEASUREMENT METHOD
SW02SW16SW17SW18SW24SW25SW33 VR24 VR25
18 Minimum Vdo1 A ON ON ON ON ON A Max. Adj. (1)Apply 0V to pin 25.
output (2) Measure the DC voltage (V30) on
pin 30.
(3)Apply a DC voltage (V30) to pin 30.
(4)While varying the DC voltage on
pin 33, measure the maximum of
the picture-period voltage on pin 12.
(Vd02)
(5)Apply 5V to pin 25.
(6) Repeat (2) and (3).
(7) While varying the DC voltage on
pin 33, measure the minimum of
19 Maximum Vdo2 the picture-period voltage on pin
output 12. (Vdo1)
20 Vertical VV B 1 t 1 f 1 1 t t (1) Adjust brightness so that the
blanking picture-period voltage on pin 12 is
pulse 6.8V.
output (2) Measure the voltage of the vertical
level blanking pulse on pin12.
21 Sink IV t t t t t t t t t (1) Adjust brightness so that the
current picture-period voltage on pin 12 is
during 6.8V.
vertical (2) Connect pin 12 to GND via 16kQ.
blanking (3) Measure the voltage on pin 12
during vertical blanking interval.
(V128LK)
(4) ls/mums/ui")
17 2001-06-25
TOSHIBA
TA8801AN
MEASUREMENT CONDITION (VCDA/cc= 12V, Ta=25i3°C)
NOTE ITEM SYMBOL SW & VR MODE
MEASUREMENT METHOD
SW02SW16SW17SW18SW24SW25SW33 VR24 VR25
22 High bright GHBC B ON ON ON ON ON A Max. Adj. (1) Set pin 33 AC GND.
color gain (2) Adjust brightness so that the
picture-period voltage on pin 12 is
(3) Input a rainbow color bar of thu/p-p
into pin 29.
(4) Input a sync. separation pulse into
pin 36.
(5) Measure the amplitude at the R-Y
terminal (pin 13) shown in Figure A.
(6) Measure the amplitude at the Y
output terminal (pin 12) shown in
Figure B. (V12)
(7) GH.B.C-- (V12) - (V13)
1 Measuring point
Measuring point
(Figure B) Output waveform on pin 12
23 OSD VDcy A ON ON ON OFF 1 f Open Min. (1)Apply 1.5V to pin 16.
output DC or or or (2) Measure the picture-period voltage
voltage VDCC OFF OFF OFF on pin 12. (VDcy)
(3) Measure the DC voltages on pins
13, 14, and 15. (VDCC)
(4) For pin 17 and 18, repeat (1)~(3).
24 OSD VOSD A ON ON ON OFF ON A Open Min. (1)Apply 12V to pin l.
output MAX or or or (2) Apply 5V to pin16.
maximum OFF OFF OFF (3) Measure the DC voltage on pin 13.
voltage (VOSDMAX)
(4) For pin 17 (measuring at pin 14) and
pin 18 (measuring at pin 15), repeat
(1)-(3).
25 OSD mode vows t t t t t t t t t (1) Increase the voltage of pin 16 from
switching w 0V.
threshold (2) Measure the voltage on pin 16 at
voltage which the picture-period voltage on
pin 12 changes.
(3) Measure the voltage on pin 16 at
which the DC voltages on pins 13,
14 and 15 change.
(4) For pin 17 and pin18, repeat
(1)H3).
TOSHIBA
TA8801AN
MEASUREMENT CONDITION (VCD-VCC= 12V, Ta=25i3°C)
NOTE ITEM SYMBOL SW & VR MODE
MEASUREMENT METHOD
SW02SW16SW17SW18SW24SW25SW33 VR24 VR25
26 OSD HIGH Vosm-us t t t t t t t t t (1) Decrease the voltage of pin 16
voltage w from 5V.
switching (2) Measure the voltage on pin 16 at
threshold which the DC voltage on pin 13
voltage changes.
(3) For pin 17 (at which voltage on
pin 14 changes) and pin 18 (at
which voltage on pin 15 changes),
repeat (1) and (2).
27 OSD mode TROSDY A ON ON ON OFF ON A Open Adj. (1) Adjust brightness so that the
switching TROSDC or or or picture-period voltage on pin 12 is
rise time OFF OFF OFF 6.8V.
(2) Input the signal in Figure A of
1.4Vp-p into pin 16.
28 OSD mode tPROSDY (3) Measure TROSDY. tPFOSDY.
switching tPROSDC TFOSDY and tPFOSDY on pin12
rise according to Figure B.
transfer (4) Measure TROSDC. tPROSDc,
time rFospc and tPFOSDc on pins 13,
29 OSD mode TFOSDY 14 and 15 according to Figure B.
switching TFOSDC (5) In the same way, measure the
fall time rise/fall times in (3) and (4) after
applying the signal in (2) into
pins 17 and 18, respectively.
30 OSD mode tPFOSDy
switching tPFOSDC
fall transfer
31 OSD HIGH TRQSDH| t t t t t t t t Min. (1) Input the signal in Figure A of
voltage 4.2Vp-p into pin 16.
switching (2) Measure rOSDHI, tPROSDHI,
rise time rOSDHI, and tPFOSDHI on pin 13
according to Figure C.
32 OSD HIGH tROSDHI (3) Input the signal in (1) into pin 17.
voltage (4) Repeat (2) on pin 14.
switching (5) Input the signal in (1) into pin 18.
rise (6) Repeat (2) on pin 15.
transfer
33 OSD HIGH TFOSDHI
voltage
switching
fall time
M OSD HIGH tPFOSDHI
voltage
switching
fall transfer
MEASUREMENT CONDITION (ch.Vcc=12V, Ta:25 13°C)
NOTE ITEM SYMBOL 5W 8: VR MODE
SW19 SW22 SW23 SW24 5293 Sng VRZZ VR23 VR24
M EASUREMENT METHOD
35 ACC F1 Open 0N Open ON A A Variable — Max. (1) Input rainbow color bar into chroma input
characteristic ea I (Chroma amplitude is equal burst amplitude.)
A B (2) Adjust tint so that 6th bar of B-Y Is the
maximum.
(3) Measure B-Y amplitude for vaw input with
killer off (SW19 : B). [ea]
(4) Measure B—Y amplitude for 100 and 300mm,.p
[F1 and F2]
Calculate :
A: F1/ F2
U15 B'Y IVp-p]
S 100 300 v29
Chroma input [mvp.p]
TOSHIBA
36 Color control V23 Open 1‘ 1‘ T 1‘ T ‘ ’1‘ Variable ‘|‘ (1) Input 100mvp_p rainbow coIor bar into chroma
characteristic AV23 input. (Chroma amplitude is equal burst
amplitude.)
(2] Adjust tint so that 6th bar of B-Y is the
maximum.
(3) Adjust color and measure V23 and AVza
according to following figure.
U15 B
v23 . v23
’1‘" Color terminal m
TA8801AN - 20
TA8801AN
MEASUREMENT CONDITION (VCD-VCC=12V, Ta :2513°C)
NOTE ITEM SYMBOL 5W & VR MODE
MEASUREMENT METHOD
SW19 SW22 SW23 SW24 5295 Sng VRZZ VR23 VR24
37 Contrast V24 Open ON ON ON A A Variable Max. Variable (1) Input IOOmVp_p rainbow color bar into chroma
control AV24 input.
characteristic eu (2) Adjust tint so that 5th bar of B—Y is maximum.
(3) Adjust contrast and measure V24 and AV24
according to following figure.
(4) Measure F1 and F2, then calcuiate :
eu = 20€og (F1 IFz)
m5 B-Y [VW]
' Contrast terminal
i v24 V24 [V]
”a AVza uh
TOSHIBA
38 Maximum EMAX Open ON Open ON A A Variable — Min. (1) Input rainbow color bar into chroma input with
input level burst fixed to SOOmVp.p.
(2) Adjust tint so that 61h bar of B-Y is maximum.
(3) While varying chroma amplitude from 200r1r1Vp.p
to 1.5Vp.p, measure EMAx according to
following figure.
U15 B-Y le_p]
100% \‘ncIination
,'90% inclination
EMAX Chroma input [mm]
39 Killer 0N EBK T Open 1‘ Open * -— — — — (1) Input rainbow color bar into chroma input.
input level (Chroma and burst have same amplitude.)
(2} Decreasing input amplitude, then measure the
amplitude at which B-Y signal disappears. IeBKl
TA8801AN - 21
TA8801AN
MEASUREMENT CONDITION (Vco_Vcc=12V, Ta:2513°C)
NOTE ITEM SYMBOL SW & VR MODE
SW19 SW22 SW23 SW24 5293 Sng VR22 VR23 VR24
MEASU REMENT METHOD
40 AFC frequency 16‘ 1‘ 1‘ 1‘ 1‘ B — — — — (1) No signal inputted into chroma input.
control (2) Measure fo at pin 21.
sensitivity (3} Measure the pin 20 voltage for f0. [V20]
(4} Measure the frequency for V20 +50mV and
Vzo—SOmV. [h and f_]
Calculate :
[3: (h. -f-)/100
\‘21 [H2]
TOSHIBA
41 AFC pull-in/ fPH Open Open Open * A A Input 3.58MH2 sine wave into chroma input.
hold range pr (2 While bringing chroma frequency close to
fHH 3.58MH2 from upper and lower side, measure
fHL the frequency at which 81W mode turns to
color mode. [pr and pr1
While increasing and decreasing (hroma
frequency from 3.58MHz, measure the
frequency at which color mode turns to B/W
mode. [fHH and mu
42 Color 911 1 ON 1‘ ON 1 1‘ Variable 1‘ Max (1 Input 100mvp.p rainbow color bar into chroma
differential as input.
output levei es (2 Adjust tint so that one bar is maximum at R-Y,
B-Y and G-Y each.
Measure the amplitudes of R-Y, B-Y and G-Y at
maximum bars. [e3, eg and ee]
43 Color eR/ea ‘|‘ 1‘ 1‘ 1 A A ’1‘ 1‘ T CaIculate :
differential egleB sales and eelea
Output relative
amplitude
44 Cofor 61:43 Open Open ON ON A A — Max. Variable (1 Input a 100mvp.p, 95" red signal into chroma
differential 06-8 input.
output relative (2) Increase burst phase to make the B-Y
phase waveform flat on pin 15.
This phase is 65.
Decrease burst phase to make the R-Y
waveiorm flat on pin13.
This phase is 6R.
Increase burst phase to make the G-Y
waveform flat on pin 14.
This phase is HG-
(5) Calculate :
6R-B = 65 - an
66-8 = 350 — (BG— 83)
TA8801AN — 22
TA8801AN
SYMBOL
MEASUREMENT CONDITION (VCD.VC(:= 12V, Ta :25 i3°C)
SW & VR MODE
MEASUREMENT METHOD
Ti nt control
characteristic
Variable
Variable
Input 100mVp.p, 3.58MH2 sine wave into
Chroma input.
While varying tint control voltage, measure the
B-Y amplitude (A3_y).
And max. of Agar is AB-Ym-
Calculate :
x : Aa-Y I AB-Ym"
fl = cos“)(
And draw a following graph of tint control
characteristics.
Read 91, .92, V37 and AV37.
And calculate :
3 = 51 - 62
- v 7 - v
—»;A\?37;«— Tint terminal [v]
Co! or
differential
maximum
output level
Variabie
Input rainbow color bar into chroma input
with its burst fixed 100mVp_p.
Adjust tint so that one bar of B—Y at which its
amplitude is measured becomes maximum.
While varying chroma amplitude, measure the
BAY amplitude on pin 15.
Draw a following graph and read E3.
For R-Y and G-Y, repeat (2)~(4). These are ER
and E5.
1/ e-v V _
'5 I ”1 1mm inclination
90% inclination
Ea v29
Chroma input ImVp-p]
TA8801AN — 23
TOSHIBA
TA8801AN
MEASUREMENT CONDITION (VCD.Vcc=12V, Ta=25i3“C)
NOTE ITEM SYMBOL SW 8: VR MODE
MEASUREMENT METHOD
SW19 SW22 SW23 SW24 529a Sng VR22 VR23 VR24
47 Residual U139 A 1‘ Open Open 1 T 1‘ — — (1) Input rainbow cotor bar into chroma input
carrier level U149 with its burst and chroma 100va.
U159 (2} While adjusting tint, measure the maximum
leak from color subcarrier to color difference
output on pin 13, 14 and 15. These are ”Be:
U149 and v15e.
TOSHIBA
48 Residual U13He 1‘ T T ON T 1 1L Max. Min. (1} Input rainbow color bar into chroma input
harmonic level U14He with its burst and chroma iOOmVM.
v15He Max. (2) While adjusting tint, measure the maximum
residual harmonic level on pin 13, 14 and 15.
These are 0131.19, U14He and U15He~
49 Sync . I|N35 ON ON OFF ON ON ON ON OFF A WM Pin 36 \éthle decreasinghV frfim 3\:1
separatlon own, measure t e va ue 0
input sensitive @ G c: ®at which the frequency
current ' E of the waveform on pin 1
changes from 297H to
Pin1 Pin 27
Q—D—Wv—O
10m (VIC/OSD Vcc)
SO H.AFC phase IDET OFF OFF 1 T T T 1‘ 1‘ OFF (1) Measure the DC voltage
detection .®°'1/‘IF “"35 Signal on pin 3 with no load
99mm“ and then set V to above
current
(Sync separation voltage.
C: nput) (2) Input following signal
:1 into pin 36 and observe
'- v the pin 3 waveform
,1; (3) Caiculate :
'DET=V1+WQ l/tAl IDET=V1 +1kfl [,uA}
1 ~—-—ss.s,5—-
0.5vp_p
pin 36 Input signal? _, __ 4-7115
pin3 waveform
(Do not apply V/C/OSD VCCJ
5“ PhaSE_ Tc03 T 0N T T T T T ’1‘ T 0.1,“; pin“
detection stop @_"__U
period 2VFHJ
1}” Pin 5 Composite video signal
(1) Apply a 60Hz composlte video signal to pin 36.
(2) Measure the phase det. stop period by pin 3
waveform.
TA8801AN — 24
TA8801AN
SYMBOL
MEASUREMENT CONDITION (DEF Vcc: 9V. Ta = 25 i 3"C)
SW & VR MODE
SW7A SW8 SW9
MEASUREMENT METHOD
32fH VCO
oscillation
start voltage
OFF 1‘ OFF
Check to see that an
oscillation waveform
®pears at pin 4 (32fo
3 VCO) when 4V is applied to
,1 pin 6 (DEF Vcc).
503m 3500 (Do not apply V/C/OSD '
wflm Vcc.)
Probe observation
Horizontal
output start
voltage
OFF ON OFF
pins (95; While raising V, measure the
ch value of V at which a
v horizontal pulse (its frequency
is LSkHz : 1kHz) is generated
from pin 7.
3900. (Do not apply VlC/OSD Vcc.)
Horizontal
free-running
frequency
Measure the-oscillation frequency on pin?
(horizontal output).
Horizontal
osciliation
frequency
variable range
Measure the oscillation frequency on pfn7 when
pin3 is connected to H.Vcc via 10kQ,
Measure the oscillation frequency on pin? when
pin3 is connected to GND via Bakfl.
Horizontal
oscillation
control
sensit vity
(‘1) Measure the voltage on pin3 at which the
horizontal oscilla ing frequency is 15.734kHz.
(2) While varying p|n3 voltage £0.05V from
above voltage, measure the H osc, frequency.
(3) Caiculate frequency change rate.
Horizontal
output pulse
duty cycle
While observing the waveform on pin 7, measure
t1 and 1.2.
t1 -—--—- t2
T = x100
7 t1+12 [%}
Horizontal
Output voltage
Measure the HIGH-Ievel voltage of the output
waveform on pin 7.
Measure the LOW-Ievel voltage of the output
waveform on pin 7.
TA8801AN - 25
TOSHIBA
TA8801AN
SYMBOL
MEASUREMENT CON DITION (DEF Vcc=9V, Ta=25 13°C)
SW 8: UR MODE
MEASUREMENT METHOD
Overvoltage
protection
detection
voltage
While increasing the pin8
voltage. measure the voltage
at which horizontal output
pulse from pin? disappears.
(Horizontal
output)
Overvoltage
protection
retention
voltage
(1) Apply a voltage of 4V to nine to make H out
pulse disappear and then remove the power
supply.
(ZJWhen setting the pin 6 voltage to
2.5V once, and to 9.0V again,
> check to see that H out does not
«J, appear.
Horizontal
sync phase
(1) Input 3 foliowing signal
into pin 36.
(2) Mea3ure the difference of
phase between pin 10's
Output and FBP.
Signal
generator
®I Pin.6
1am (DEF vcc)
Input signal 53.5!“
(pin 36} 0.5Vp_p 4.7/15
Sync separation ou1put all
(Pin 10)
Measure this width.
FBT Input
(Pin 9)
Horizontal outpu‘l m
(Pin?!
TA8801AN - 26
TOSHIBA
TA8801AN
SYMBOL
MEASUREMENT CONDITION (DEF Vcc = 9V, Ta = 25 i 3T)
SW 81 VR MODE
MEASUREMENT NI ETHOD
Gate puise
start phase
Gate pulse
pulse width
01 F . (1) Input a following signal
a ’1 P236 W into pin 35.
9”"ermr (2) Measure the difference of
. Pin6 phase between pin 10 and
w 10m (DEF.VCC) pin 19 and purse width on
sun. Pin27 pin19.
G—vw—Q
(wuoso vcc)
Input signal 63.5;1: 4"
(Signal generator) 0.5V“): H 4-7/15—‘Lp
Sync separation output
(Pin 10) 'J L]
K‘xller 5P1 r— sz Ll:-
(Pin 19) [J
HarIzontal
screen phase
adjustment
variable range
(1) Same as Note 63‘s (1).
(2) While varying VRDS from minimum to
maximum, measure the change of PE? phase.
. 63.5,«5
Sync separauon outpu:
(Pin 10)
VRDS —.+ k—AGS
Flyback when at minimum .J
putse input (GNU)
(Pin 9) when at maximum
(DEF Vcc)
Vertical free—
running
frequency
0,1,“; Measure the oscillation
.—l® I—J frequency on pin1
Pin 27
Q—Nw—O
10kfl (VICIOSD Vcc)
TA8801AN - 27
TOSHIBA
TA8801AN
NOTE ITEM
MEASUREMENT CONDITION (H.Vcc= 9V, Ta=2533°Q
5W & VR MODE
M EASUREMENT METHOD
SW3 SW9 SW10 SW35
pulse width
66 Vertical output
T T T OFF 10k!)
®—~w—o Pin 27
(wcroso vcc)
E : T 1
Open ’
Measure Tn from the waveform on pin 1.
’I‘ T T T 1am
Measure Trz from the waveform on pin 1.
68 Vertical puH-in
1‘ 1‘ T T (1) Input a EOHz composite video signal into pin 36
(sync. separa‘lion input)‘
(2) Whiie varying the vertical frequency in 0.5H
steps, measure the vertical pull-in range.
TA8801AN — 23
TOSHIBA
TA8801AN
TOSHIBA
TEST CIRCUIT1.
Video section
TA8801AN
$119 We c.
902:): 'lf)'
gdtytrtri)
v02): 0an;
grf 2'2 UM"
VZEID "tt'T
mm vzsm 'd1irtel-e--g
- ' "ms
EZEID drr'Ut
trteoy-hys, try
vszlm Fg?h,-(ii'.
a '-t, SEA) PT
dr/L'D
- - [ti
grft't
00m ML y
so', s".et
tly-e h' 3
_- N O
C-y-co
:2)-~u
a Cry-s
- Ciy----a
co Gt ml s
CY , mrs
tX) SHIl
t5'til
ttdull ELCIU
0052 con
Ci?, E
ofr0'0
17'001
q ll m
LOX 5503
055905 {5055 drftrtl o
"' ms's (
V508 V503
-.rh..-
N y. > In
If! '7 .
o .n 'te
L D tr,
'h _ -
' g . $5
52 trqiu 1'flla, 5% a
131” auam 5
sum Sle g
29 2001-06-25
SZ'QO'lOOZ
OE - NV l088V1
['1 10km ““7
HU’IOL
502_ 3 o—g
2.2/1: 5W2
CD3A RD3A
0.013”
am 3900 5:31PM]
s—‘W—ml—G
3—! u.
0.01;»
pm-LNV—(q:
4300 39051
R078 RD7A
5 .1 k0.
DS‘BVJ.
cc21A gr?
10H) 2.2.HF
nczo cczoA _
Co - .
|—....
“’ 0.013;”
.u 6250
JD v90:
uonsas aso
'ZLIFDXD 1.531.
NVlO88V_L
VEIHSOJ.
SZ'QO'lOOZ
IE " NVLDRBVL
ASLSLJSZ
vnms runs
1‘} mma sun
dEZlDHVfiDJ.
AS AVE
——_+..-__C
CD3A RDBA
1/” 5‘
o‘nggflp 503F30
CUE“ ,mom
0.01,“?
S—M—Lw—G
9.013 mm
530 n 3909
Ir vaaz
mu 3—K.)— :
088VJ.
0.1/1F
NOIJNHVdBS DNAS
AS L8 1352
RCZO - ..
CCJDA '
0.004711F
(cm: (09
.3 I—-
'IVND{5 VWO‘EHZJ .LSEnEmQ IEUBJS
R098 n‘onsyr
ncwc , w
S—MN—o o—Mh—-
mokfl 2 100m
uogpas ewoup
'wnaur.) 1531
NVlO88V_L
VEIHSOJ.
TOSHIBA
TEST CIRCUIT4.
Deflection section
VICIOSD
vcc 12v
iil NM
:In'OOl
TA880‘IAN
U DEF Vcc 9"
(9) Q9 T 6? Q3) Q9 (‘3) 0.9 0.9 Q9
l Md Dvmu EILCIH
h V903 t
cum “MS
vothuU’lOl
amid .
vsou ms 1
6 H T uzrs
ig:," MS - SHtl
+ - 'Us E
m (HE 'tl
U068U0t'
1no "H
UO vsux drdr
O—n—N _
INM i”? T
31m: 5
uvgr 5 90:10 LL]
sum smun
ZSC1815Y
TA8801AN
TA8801AN — 32
TOSHIBA TA8801AN
SIGNAL FOR MEASUREMENT
I 20ps 20pa l
20ps 20ps
50% -.-.-.-.-.-.V - - -.-.-.-.-.-.-.-.l-.-
__4.__|__
33 2001-06-25
TOSHIBA
TA8801AN
APPLICATION CIRCUIT
VIDEO SIGNAL INPUT
-''A'W"-tisj:
2.2,,Fu)ksr-ai
13m 10m 0.01/1F
mm mm 0.01/1F
13km 10m 0.01/1F
- 13kf2 10m 0.01m
13kg 10k0 (h01PF
10pF X'tal
I-(ii)
(h01pFo-'r-t
47prF 737E
TRF2096
' 22pF 43pF
0.01/1F
" K,'",??
_ " Itg
0.12/1F f‘
" 's?..).,
0.1m 22pf
0.1,uF 10k!)
'-iic-'i;rHEi
0.1/1F
39—0 OSD B INPUT
@—0 OSD G INPUT
Ciiy-o OSD R INPUT
3—0 B-Y OUTPUT
@—O try OUTPUT
@—O R-Y OUTPUT
@—0 -Y OUTPUT
001/11: 3909
5.st 1 pl:
Ci) l Itt --a-'
10 -o SYNC SEPARATION OUTPUT
-o Few INPUT
8 -o X-RAY
0.01/1F
47/11:
0.01/1F
Irst F30 10m 7
CO-Bl-ee.,-;
-o VP OUTPUT
10kQ 10kQ
TOSHIBA TA8801AN
PACKAGE DIMENSIONS
SDlP36-P-500-1.78 Unit n mm
mm 19 g,
I-tI-ll-tr-II-lf-lt-lt-ll-Ir-er-Tr-tr-lr-lr"") .3..I
C) M. 5
uJclclL.uL-lctcJciclt..-lclLuLuclulclclcl N 2
l 18 0
4 33.3MAX y
- 32.8uHh2 "
n I I T “W3 m
I _U_ |le. 4H 3
s , 0.
£32? A ' A ' “SHE v 9.333%
Weight : Nome (Typ.)
35 2001-06-25
TOSHIBA TA8801AN
RESTRICTIONS ON PRODUCT USE
000707EBA
OTOSHIBA is continually working to improve the quality and reliability of its products.
Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent
electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer,
when utilizing TOSHIBA products, to comply with the standards of safety in making a safe
design for the entire system, and to avoid situations in which a malfunction or failure of such
TOSHIBA products could cause loss of human life, bodily injury or damage to property.
In developing your designs, please ensure that TOSHIBA products are used within specified
operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please
keep in mind the precautions and conditions set forth in the "Handling Guide for
Semiconductor Devices," or "TOSHIBA Semiconductor Reliability Handbook" etc..
OThe TOSHIBA products listed in this document are intended for usage in general electronics
applications (computer, personal equipment, office equipment, measuring equipment, industrial
robotics, domestic appliances, etc.). These TOSHIBA products are neither intended nor
warranted for usage in equipment that requires extraordinarily high quality and/or reliability or
a malfunction or failure of which may cause loss of human life or bodily injury ("Unintended
Usage"). Unintended Usage include atomic energy control instruments, airplane or spaceship
instruments, transportation instruments, traffic signal instruments, combustion control
instruments, medical instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA
products listed in this document shall be made at the customer's own risk.
0 The products described in this document are subject to the foreign exchange and foreign trade
OThe information contained herein is presented only as a guide for the applications of our
products. No responsibility is assumed by TOSHIBA CORPORATION for any infringements of
intellectual property or other rights of the third parties which may result from its use. No
license is granted by implication or otherwise under any intellectual property or other rights of
TOSHIBA CORPORATION or others.
0 The information contained herein is subject to change without notice.
36 2001-06-25
:
www.loq.com
.
