ta1360ang TOSHIBA Semiconductor CORPORATION, ta1360ang Datasheet

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... TOSHIBA Bipolar Linear Integrated Circuit Silicon Monolithic YCbCr/YPbPr Signal and Sync Processor for Digital TV, Progressive Scan TV and Double Scan TV The TA1360ANG integrates an analog component signal (YCbCr/YPbPr) processor and sync processor in a 56-pin shrink DIP plastic package. The IC is ideal for digital TVs, progressive TVs, and double scan TVs ...

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... CP2 MATRIX CLAMP DRIVE MIXER SW/ BLUE BACK BLUE STRETCH CP2 S/H CUT OFF RGB CLAMP BRIGHTNESS RGB CONTRAST TA1360ANG CLAMP Y BLACK BLACK PEAK 2 BPH FILTER STRETCH DETECT BLACK LEVEL CORECTION DARK DARK AREA 1 DET DET FILTER DYNAMIC γ LIGHT ...

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... K 44 RGB GND TA1360ANG 43 R OUT 42 G OUT 41 B OUT 40 RGB V ANALOG OSD ANALOG OSD ANALOG OSD DAC2 (ACB pluse) 35 ANALOG ANALOG ANALOG GND 32 31 SDA 30 SCL TA1360ANG 2005-08-18 ...

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... TA1360ANG Input Signal/Output Signal Vp-p (including sync) at 100% color bar 700 mVp-p at 100% color bar for 700 mVp-p700 mVp-p at 100% color ...

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... TA1360ANG Input Signal/Output Signal 1 Vp-p (including sync) at 100% color bar 700 mVp-p at 100% color bar for 700 mVp-p700 mVp-p at 100% color bar for ...

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... VCO kΩ 10 kΩ TA1360ANG Input Signal/Output Signal Threshold : 0. Threshold : 0. Threshold : 0. Threshold : BPP 4 ⎯ ...

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... TA1360ANG Input Signal/Output Signal 19 At BUS control (horizontal frequency) : output voltage value 28 k/15 kHz : kHz : kHz : 7 k/45 kHz : pin 22 control, horizontal 4.5 V frequency and input voltage value ...

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... SCL 30 50 Ω 5 kΩ SDA 31 ACK ⎯ kΩ kΩ kΩ 500 Ω TA1360ANG Input Signal/Output Signal DC or SYNC OUT ⎯ 19 ⎯ ⎯ ⎯ 100 IRE: 0.7 Vp-p (not including sync ACB PULSE 2005-08-18 ...

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... TA1360ANG Input Signal/Output Signal 40 100 IRE: 0.7 Vp-p (not including sync) 44 ⎯ 40 100 IRE: 2.3 Vp-p Conditions: UNI-COLOR = max SUB-CONT = Cent 0.7 Vp-p 44 ⎯ Vp-p (typ ...

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... See pin 12. ⎯ 40 kΩ kΩ 1 kΩ 10 TA1360ANG Input Signal/Output Signal 0 Internal 1 1 VSM Mute 2 OSD, VSM Mute 0 Internal 1 1 Half Tone 2 V P-Mute ...

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... VSM GAIN DC REST RATE APL VS BSP B.L.C. D-ABL GAIN BL STRETCH POINT ABL GAIN STATIC γ GAIN-1 Y/C-DL1 BS-CHAR2 Y/C-DL2 YUV-IN H-OUT VP-OUT RGB-IN 11 TA1360ANG D1 D0 Preset SYNC-SW H-FREQ2 1000 0000 CLP-PHS 1000 0000 TEST 1000 0000 1000 0000 1000 0000 1000 ...

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... Outputs H/C-SYNC from pin 28, and ACB reference pulse from pin 36 when TEST is 01. Do not set TEST to 10/11 for that is shipment TEST Mode. Description / INPUT-2 (Y2 TA1360ANG Preset Value 33.75 kHz 41% INPUT-1 OPEN ON HD/VD CENTER 1.1-µs delay ACB ON (10 IRE) Internal Mode ± ...

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... Y/Pb/Pr: ITU-R BT 709 (1125/60/2:1) Ｙ-out gamma control: Y-outγ 0: OFF 1: ON Drive gain 1/2; DRIVE GAIN1/2 0000000: −5dB 1111111: +3dB DR-R Switches RGB drive gain base. (See Appendix 5.) DR-B/G Description 13 TA1360ANG Preset Value 32 H 1281 H CENTER, OFF P-MUTE 1 min CENTER ON C-MUTE ±0 deg CENTER ...

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... DC restoration rate correction point: DC REST POINT 000: 0% 111: 49% DC restoration correction rate: DC REST RATE 000: 100% 111: 135% (70%) DC restoration rate correction limit point: DC REST LIMIT 00: 67% 01: 77％ 10: 80% 11: 80% Description 14 TA1360ANG Preset Value CENTER CENTER min CENTER min CENTER 4.5 MHz OFF OFF 1 ...

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... When 00~10 is set, light area static Yγ and light dynamic Yγ according to light area is operated. OSD brightness: OSD BRIGHT 00: 5 IRE 01: 0 IRE 10: −5 IRE 11: −10 IRE OSD contrast: OSD-CONTRAST 00: min (1.7dB) 11: max (0dB) Description 15 TA1360ANG Preset Value CENTER 0 IRE OFF 3 IRE ON CENTER min CENTER ...

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... Y group delay correction; shoot balance correction. Y-GROUP DELAY 0000: Pre-shoot gain is lowered. (Overshoot gain is raised.) CORRECTION 1111: Overshoot gain is lowered. (Pre-shoot gain is raised.) White peak blue gain. WP BLUE GAIN 000: min (+3dB) 111: max (+10dB) Description 16 TA1360ANG Preset Value −10 ns min CENTER OFF CENTER min 2005-08-18 ...

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... V-BPP Example of Format/V (H)-Frequency Start Phase Stop Phase 1100 H 730 H 600 H V-BLK P. (C.BLK P.) 545 H +20 H 500 H 290 H 240 H ⎯ ⎯ 17 TA1360ANG 28.125 31.5 33.75 37.9 15.75 31.5 33.75 45 1125P/30 Hz (33.75 kHz) 750P/60 Hz (45 kHz) (750P/50Hz(37.5 kHz)) 625P/50 Hz (31.5 kHz) SVGA/60 Hz(37.9 kHz) 1125I/50 Hz (28.125 kHz) 1125I/60 Hz (33.75 kHz) 525P/60 Hz (31.5 kHz) PAL/SECAM/50 Hz (15.625 kHz), 100 Hz (31 ...

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... Ys1/Ys2 blends OSD-IN and main halftone signal P-Mute > Analog RGB-IN Full-screen-mute process is executed on main signal and analog RGB-IN by BUS. Insert OSD-IN by Ys1/Ys2. P-Mute > Analog RGB-IN P-Mute and halftone process is executed on the main signal by pin Y Analog RGB-IN is inserted by Ys3, and OSD-IN by Ys1/Ys2. P-Mute > Analog RGB-IN 18 TA1360ANG . 2005-08-18 ...

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... NG (no signal (signal detected) RGB-IN Detects signal when all three inputs are AC signals. Small signals or signals like DC voltage are not detected. Detects SYNC-IN self-check; detects input of pin 14. SYNC- (no signal (signal detected) Drive Gain1 Drive Gain2 Function 19 TA1360ANG 2005-08-18 ...

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... SDA SCL SDA must not be changed Acknowledgement SDA from transmitter SDA from receiver SCL from master Bus Stop condition SDA may be changed Clock pulse for acknowledgement 20 TA1360ANG A0 W/R 0 0/1 High impedance at bit 9 Low impedance only at bit 9 2005-08-18 ...

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... LOW ⎯ t 4.0 HIGH ⎯ t 4.7 SU;STA ⎯ t 350 HD;DAT ⎯ t 250 SU;DAT ⎯ t 4.0 SU;STO ⎯ t 4.7 BUF 21 TA1360ANG A P Transmit data bit MSB Max Unit 1.0 V Vcc V 0.4 V µ 100 kHz ⎯ µs ⎯ µs ⎯ µs ⎯ µs ⎯ ...

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... T stg min 8.5 8.7 typ. 8.8 9.0 max 9.1 9.3 3378 Printed Circuit Board B Printed Circuit Board C 2717 2551 2297 1848 1735 Printed Circuit Board 150 Ambient temperature Ta (°C) 22 TA1360ANG Unit PCB 0.3 V 3378 mW 27.0 mW/°C − °C −55 to 150 °C 8.7 V 9.0 9.3 2005-08-18 ...

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... Horizontal output 6.0 V (typ.) POR release voltage (BUS operation) 4.6 V (typ.) Logic operation 1.3 V (typ.) Figure B Timing chart that indicates the timing from power-on till horizontal output. ( C°) / DEF/DAC TA1360ANG t 2005-08-18 ...

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... H-AFC H-BLK OSD VSM MUTE BLK P-MUTE HALF TONE V CC Test Symbol Min Typ. Max Circuit ⎯ I 19.2 24.0 28.2 CC1 ⎯ I 48.8 61.0 67.8 CC2 ⎯ I 21.3 25.0 29.4 CC3 ⎯ I 36.8 46.0 51.1 CC4 24 TA1360ANG Min Typ. Max Unit 8.5 8.8 9.1 V 8.7 9.0 9.3 1.8 2.0 2.2 ⎯ ⎯ 1.0 Vp-p ⎯ ⎯ 0.7 ⎯ MHz ⎯ 2.0 5 0.9 1.0 1.1 Vp-p 4.2 5 ...

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... V 2.2 2.5 2.8 23 ⎯ V 3.65 3.95 4.25 33 ⎯ V 3.65 3.95 4.25 34 ⎯ V 3.65 3.95 4.25 35 ⎯ V 3.65 3.95 4.25 37 ⎯ V 3.65 3.95 4.25 38 ⎯ V 3.65 3.95 4.25 39 ⎯ V 4.2 5.2 6.2 46 ⎯ V 4.2 5.2 6.2 47 ⎯ V 4.2 5.2 6.2 48 ⎯ ⎯ V 0.1 0.2 49 ⎯ ⎯ V 0.1 0.2 50 ⎯ ⎯ V 0.1 0.2 51 ⎯ ⎯ V 0.1 0.2 52 ⎯ V 6.1 6.35 6.6 53 ⎯ V 4.1 4.3 4.5 54 ⎯ V 4.8 5.0 5 TA1360ANG Unit V 2005-08-18 ...

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... ADT 100 ⎯ (Note P17) ADT 135 ⎯ ADT 65 ⎯ V DT0 (Note P18) ⎯ V DT1 ⎯ P DTL60 ⎯ P DTL75 (Note P19) ⎯ P DTL87 ⎯ P DTL100 26 TA1360ANG Min Typ. Max Unit 0.7 1.0 1.5 Vp-p − 2.4 2.8 3 IRE IRE ...

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... Pins 49, 50, 51 SR50 ⎯ SR51 ⎯ (Note P25) ⎯ ⎯ ⎯ ⎯ ⎯ (Note P26) ⎯ ⎯ AMIN ⎯ BMIN (Note P27) ⎯ AMAX ⎯ BMAX 27 TA1360ANG Min Typ. Max Unit 10.5 13 9.5 12 MHz 5 7.2 7.8 3.5 4.5 6.3 ⎯ 0.01 0. 17.5 19 −4 −0.6 2.5 15 17.5 19 − ...

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... Y detail control range G YDCEN G Test Test Condition Circuit ⎯ CDE00 ⎯ CDE01 (Note P28) ⎯ CDE10 ⎯ CDE11 ⎯ ⎯ ⎯ ⎯ (Note P29) ⎯ YDMIN 28 TA1360ANG Min Typ. Max Unit MHz ...

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... GC BDY2 (Note S02) ⎯ GC RDY1 ⎯ GC RDY2 ⎯ G Y00 ⎯ G Y01 ⎯ G CBB ⎯ G PBB (Note S03) ⎯ G PBR ⎯ G CRR ⎯ G PRB ⎯ G PRR 29 TA1360ANG Min Typ. Max Unit 0.7 0.9 1.0 Vp-p 0.7 0.9 1 −37 −33 −29 ° −36 −32 −28 3.6 4.5 5.4 4.6 5.8 7.0 MHz 3.6 4.5 5.4 4.6 5 ...

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... GrC01 Green stretch GrC10 GrC11 GrD01 GrD10 GrD11 GrE01 GrE10 GrE11 Test Test Condition Min Circuit ⎯ 0.98 ⎯ 0.95 ⎯ 0.93 ⎯ 1.01 ⎯ 1.05 ⎯ 1.12 ⎯ 1.10 ⎯ (Note S04) 1.23 ⎯ 1.35 ⎯ 1.09 ⎯ 1.21 ⎯ 1.32 ⎯ 0.98 ⎯ 0.95 ⎯ 0.93 30 TA1360ANG Typ. Max Unit 1 1.02 1 1.05 1 1.07 1.05 1.10 1.1 1.15 1.19 1.26 1.14 1.18 times 1.27 1.31 1.42 1.49 1.13 1.17 1.25 1.29 1.39 1.46 1 1.02 1 1.05 1 1.07 2005-08-18 ...

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... A03) GY ⎯ GHT BY ⎯ V γ1 ⎯ V γ2 (Note A04) ⎯ V γ3 ⎯ ∆ γ ⎯ CLT 0 (Note A05) ⎯ CLT 1 ⎯ HBC (Note A06 TA1360ANG Min Typ. Max Unit 14.5 16.0 17.5 dB 3.0 4.0 5.0 dB −35 −22 −17 109 111.5 114 ° 98.5 101 103 0.86 0.90 0.94 0.65 ...

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... T09) ⎯ td OFF ⎯ ∆v su+ ⎯ ⎯ ∆ vsu− ⎯ CUT+ ⎯ ⎯ CUT− ∆V ⎯ #41 ⎯ ∆V ⎯ #42 ∆V ⎯ #43 ∆V ⎯ ⎯ OUT 32 TA1360ANG Min Typ. Max Unit 3.08 3.45 3.90 times 3.08 3.45 3.90 3.08 3.45 3.90 0.94 1.00 1.06 0.94 1.00 1.06 ⎯ ⎯ MHz 30 60 ⎯ ⎯ ...

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... P1 ⎯ P2 ⎯ P3 ⎯ P4 (Note T13) ⎯ P5 ⎯ P6 ⎯ P7 ⎯ P8 ⎯ G1 ⎯ G2 ⎯ G3 ⎯ G4 (Note T14) ⎯ G5 ⎯ G6 ⎯ G7 ⎯ TA1360ANG Min Typ. Max Unit 2.5 3.0 3.5 −5.5 −5.0 −4.5 2.5 3.0 3.5 −5.5 −5.0 −4.5 2.5 3.0 3.5 −5.5 −5.0 −4.5 2.5 3.0 3.5 −5.5 −5.0 −4.5 dB 2.5 3.0 3.5 −5.5 −5.0 −4.5 2 ...

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... ACBG ⎯ ACBB ⎯ ACB1R ⎯ ⎯ ACB1B (Note T18) ⎯ ACB2R ⎯ ⎯ ACB2B ⎯ ACB3R ⎯ ⎯ ACB3B ⎯ ⎯ IK (Note T19) G ⎯ ⎯ in+ (Note T20) ⎯ in− 34 TA1360ANG Min Typ. Max Unit 2.15 2.40 2.65 0.30 0.80 1.30 0.30 0.80 1.30 0.30 0.80 1.30 V 2.15 2.40 2.65 0.30 0.80 1.30 0.30 0.80 1.30 0.30 0.80 1.30 2.15 2.40 2. IRE ...

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... RYS ⎯ 1 (Note T27) ⎯ 2 ⎯ OSDR ⎯ (Note T28) OSDG ⎯ OSDB ⎯ ⎯ ⎯ ⎯ OSDR ⎯ At −3dB OSDG ⎯ OSDB ⎯ 39 ⎯ ⎯ 38 ⎯ TA1360ANG Min Typ. Max Unit 3.03 3.40 3.83 times 3.03 3.40 3.83 3.03 3.40 3.83 0.94 1.00 1.06 ⎯ 0.94 1.00 1.06 ⎯ ⎯ MHz ⎯ ...

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... Pin 51 ⎯ Pin 50 ⎯ RYS1 ⎯ RYS1 ⎯ RYS1 ⎯ FYS1 ⎯ RYS1 ⎯ RYS1 (Note T33) ⎯ RYS2 ⎯ RYS2 ⎯ RYS2 ⎯ FYS2 ⎯ RYS2 ⎯ RYS2 ⎯ 1 ⎯ 2 (Note T34) ⎯ 3 ⎯ TA1360ANG Min Typ. Max Unit 2.45 2.70 2.95 Vp-p 2.45 2.70 2.95 2.45 2.70 2.95 1.30 1.45 1.60 1.30 1.45 1.60 V 1.30 1.45 1.60 0.58 0.64 0.71 0.58 0.64 0.71 0.58 0.64 0.71 0.47 0.53 0.59 0.47 ...

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... T36) ⎯ min ⎯ max ⎯ BLγ1 ⎯ BLγ2 (Note T37) ⎯ BLγ3 ⎯ BLγ4 ⎯ ⎯ (Note T38) ⎯ 37 TA1360ANG Min Typ. Max Unit −7 −6 −5 −7 −6 −5 −7 −6 −5 −4 −3 −2 −4 −3 −2 − ...

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... HBP s11b ⎯ V (Note HA10) thFBP ⎯ V Pin 21: Monitor, V voltage VCO CC ⎯ V Pin 26: Monitor, V voltage HON CC ⎯ V Pin 26: Monitor, V voltage HOFF CC ⎯ (Note HB01) ⎯ TA1360ANG Min Typ. Max Unit µs 0.55 0.65 0.75 µs 0.58 0.68 0.78 ⎯ 0.5 2 ⎯ 99.5 98 47.5 52.5 57 ...

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... TEST = (00), DAC1 = (1) 1L ⎯ TEST = (00), DAC2 = (1) 2H ⎯ TEST = (00), DAC2 = (0) 2L ⎯ VP (Note V01) W ⎯ VPt0 ⎯ VPt1 ⎯ VPt2 ⎯ ⎯ VPt3 ⎯ VPt4 ⎯ VPt5 ⎯ VPt6 ⎯ (Note V02) VPULL 39 TA1360ANG Min Typ. Max Unit 15.59 15.75 15.91 27.90 28.125 28.35 31.19 31.5 31.82 kHz 33.41 33.75 34.09 37.60 37.9 38.40 44.52 45.0 45.48 14.58 14.88 15.18 16.52 16.85 17.18 25.91 26.44 26 ...

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... TA1360ANG Min Typ. Max Unit 1099.5 1100.5 1101 729.5 730.5 731.5 49.5 50.5 51.5 599.5 600.5 601.5 H 49.5 50.5 51.5 544.5 545 ...

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... Pin 27 input current 41 TA1360ANG Min Typ. Max Unit ...

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... Set black stretch point 1 to OFF (000), and measure #56 amplitude V 4. Set black stretch point 1 to 001 (black stretch ON), and measure #56 amplitude V 5. Calculate GBS using a following equation. GBS = 20 × V ± 3°C) Test Method (Test condition #56 ÷ [dB TA1360ANG . B 2005-08-18 ...

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... shown in the figure below. Also BST1 BST2 using following equations. BST2 [V] − V [V] 0 [V] − V [V]) ÷ × 100 (IRE) BST1 56 Z [V] − V [V]) ÷ × 100 (IRE) BST2 BST2 S2 56 TA1360ANG S1 #3 2005-08-18 ...

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... V P BS2 11 0.7 V p-p 0.3 V p-p #3 waveform (linearity V ± 3 ° C) Test Method (Test condition (APL 0%), and shown in the figure below. (Monitor input 00 ) × 100 /V P43 ) × 100 /V P43 LINEARITY APL 100% APL 0% TA1360ANG + 1.0 V (APL ∆ V *** #43 (R OUT) 2005-08-18 ...

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... S2 and S4 obtained from the plot in black stretch start BSC1 BSC2 and P using following equation. BSC1 BSC2 , BSC3 BSC4 BSC5 and P BSC6. [V] − V [V]) ÷ 1.0 × 100 [(IRE BSC2 # 0 BSC1 S4 Black stretch characteristic switch ON TA1360ANG and V ) and calculate BSC6 2005-08-18 ...

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... V ± 3 ° C) Test Method (Test condition SW2A A PS2 µ Ａ mmeter and and V (DV ), between V and − TA1360ANG . 11 (DV ), and between 2005-08-18 ...

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... D.ABL sensitivity is set to minimum (00) and maximum (11) can be plotted as figure shown below. 3. Measure gradients SDAMIN and SDAMAX using the figure below. = ∆ Y/ ∆ DAMIN # V ± 3 ° C) Test Method (Test condition ∆ Y/ ∆ X DAMAX 10% ∆ Y 100% 10% ∆ X TA1360ANG #53 2005-08-18 ...

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... Set black level correction [18 [04], determine DC change VBLC [V], and calculate BLC [V] using the following equation BLC = (VBLC/VB)] × 100 [(IRE)] Black level correction OFF Black level correction V ± 3 ° C) Test Method (Test condition #43 VBLC VB TA1360ANG 2005-08-18 ...

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... V and plot voltage change of #43 picture period. Take 0 for V [ pin voltage of pin 3) 3 [V] + 0.7 V and plot voltage change of #43 picture period. [ using the following equation. DGP [V])/0.7 [V] × 100 3 ON OFF + 0.7V VDGP (100 IRE) TA1360ANG [ voltage [V] 2005-08-18 ...

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... PS1 is VDGP [V], and calculate the following equations. VDDGMAX − VDDGMIN = A VDDGMIN − VDDGV GDDGMAX = 20 og #43 voltage [V] VDDGMAX VDDGMIN VDDGV V ± 3 ° C) Test Method (Test condition [V [B/(B-A)] [dB] OFF ON VDDGMAX − VDDGMIN = A VDDGMIN − VDDGV = voltage [ VDGP (100IRE) TA1360ANG 2005-08-18 ...

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... V ± 3 ° C) Test Method (Test condition [B/(B - A)] [dB] #43 voltage [V] OFF ON VSGMAX − VSOFF2 = A #3 voltage [ VDGP (100IRE) [(VSGMIN − VSGOFF1)/(VSGOFF2 − VSGOFF1)] [dB] l #43 voltage [V] OFF VSGOFF2 − VSGOFF1 ON VSGMIN − VSGOFF1 #3 voltage [ VDGP (100IRE) TA1360ANG 2005-08-18 ...

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... Take 0 for pin voltage of pin 3) 3 [V] + 0.7 [V], and plot the voltage change of #43 picture period. [ [V])/0.7 [V] × 100 (IRE OFF #3 voltage [ VLGP (100IRE) TA1360ANG 3 2005-08-18 ...

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... VLDGMAX [V] using the following equations. VLDGMAX − VLDGOFF2 = A VLDGOFF2 − VLDGOFF1 = B GLDG = 20 × og #43 voltage [V] VLDGMAX VLDGOFF2 VLDGOFF1 V ± 3 ° C) Test Method (Test condition [B/(B − A)] l VLDGMAX − VLDGOFF2 = A ON VLDGOFF2 − VLDGOFF1 = B OFF #3 voltage [V] V VLGP + 0 (100IRE) TA1360ANG 2005-08-18 ...

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... Test Method (Test condition [B/(B − A)] [dB] l #43 voltage [V] VLSGMAX − VLDGOFF2 = A ON VLSGOFF2 − VLSGOFF1 = B OFF #3 voltage [V] V VLGP + 0 (100IRE) [B/(B − C)] [dB] l #43 voltage [V] VLSGMIN − VLDGOFF2 = C ON VLSGOFF2 − VLSGOFF1 = B OFF #3 voltage [ 0.7 V VLGP (100IRE) TA1360ANG 2005-08-18 ...

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... Input the signal whose picture period amplitude is 0. shown in the figure below. 2. Measure #1 pin voltage DAMIN, DACEN, and DAMAX [V] when dark area detection sensitivity [1D] is set to MIN [00], CEN [04] and MAX [07 V ± 3 ° C) Test Method (Test condition 0. DAMIN ･ CEN ･ MAX [V] TA1360ANG 2005-08-18 ...

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... V, DC restoration correction rate 3 . DT4 , and ADT using following equations. 135 65 [V] − V [V]) ÷ 0.1 [V] DT2 DT1 [V] − V [V]) ÷ 0.1 [V] DT3 DT1 [V] − V [V]) ÷ 0.1 [V]) DT2 DT4 Picture period #43 waveform TA1360ANG + 0 [V] and V DT2 DT3 V DT1 V V DT2 DT3 V DT4 2005-08-18 ...

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... V, and adjust unicolor so that DC level is + 1.0. 3 using the following equations. DT1 − V )/1 V] × 100% 56 − V )/1 V] × 100 restoration rate correction point 000 DC restoration rate correction point 111 DC restoration correction rate 000 V SP1 #56 TA1360ANG . Plot relation between # Plot relation between #56 3 2005-08-18 ...

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... Test Method (Test condition and P using following equations. DTL60 DTL75 DTL87 DTL100 − V )/1.0] × 100% L60 56 − V )/1.0] × 100% L75 56 − V )/1.0] × 100% L87 56 − V )/1.0] × 100% L100 L60 L100 V V L75 L87 TA1360ANG 100% (00) 87% (01) 73% (10) 60% (11) #56 2005-08-18 ...

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... Vp-p) to TPA as shown in the figure below. 2. Set sharpness [09] to MIN [00] and MAX [80]. Monitor #43, measure DC level VRDCMIN and VRDCMAX [V]. Calculate VRDC [V] using the following equation. VRDC = VRDCMIN − VRDCMAX [ V ± 3 ° C) Test Method (Test condition 0.2 V #43 VRDC * TA1360ANG 2005-08-18 ...

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... AP00 using the following equations. , measure V AP01 . MIN01 , measure V AP10 . MIN10 , measure V AP11 . MIN11 ÷ [dB] MAX*** 100 ÷ [dB] MIN*** 100 TA1360ANG . 100 , measure the amplitude V , MAX00 , MIN00 /V and MAX01 MIN01 /V and MAX10 MIN10 /V and MAX11 MIN11 2005-08-18 ...

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... Note: When a spectrum analyzer is used, measure gain for low frequency V ± 3 ° C) Test Method (Test condition measure #43 amplitude V AP00 using the following equations. , measure V AP01 , measure V AP10 , measure V AP11 ÷ [dB] CEN*** 100 TA1360ANG , CEN00 and calculate CEN01 and calculate CEN10 and calculate CEN11 2005-08-18 ...

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... SRTMAX01 SRTMAX01 /V and SRTMIN10 SRTMAX10 SRTMAX10 /V and SRTMIN11 SRTMAX11 SRTMAX11 l [ ((V /T )/(V /T SRTMAX00 SRTMAX00 SRTMIN00 SRTMIN00 l [(V /T )/(V /T SRTMAX01 SRTMAX01 SRTMIN01 SRTMIN01 l [(V /T )/(V /T SRTMAX10 SRTMAX10 SRTMIN10 SRTMIN10 l [(V /T )/(V /T SRTMAX11 SRTMAX11 SRTMIN11 SRTMIN11 T *** 20% V *** 20% TA1360ANG . )) )] )] )] 100% 2005-08-18 ...

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... V . Set input amplitude to 0.7 Vp-p, and VSM gain to OFF (000). Measure 111 . l (V /0.7) [dB] 000 l (V /0.02) [dB] 001 l (V /0.02) [dB] 010 l (V /0.02) [dB] 011 l (V /0.02) [dB] 100 l (V /0.02) [dB] 101 l (V /0.02) [dB] 110 l (V /0.02) [dB] 111 to TPA. VSM and V [Vp-p] as shown in the figure below TA1360ANG , 001 2005-08-18 ...

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... Determine YDLA, YDLB, and YDLC using the following equations. YDLA = YDL01 − YDL00 YDLB = YDL10 − YDL00 YDLC = YDL11 − YDL00 V ± 3 ° C) Test Method (Test condition pulse Approximately 0.7 Vp-p #3 50% YDL00 YDL01 YDL10 YDL11 TA1360ANG #43 50% 2005-08-18 ...

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... Note: Sine wave input starts and ends within the picture period such as a burst signal. The wave is not continuous V ± 3 ° C) Test Method (Test condition Signal Signal B . BMIN . BMAX [dB] AMIN AMIN A Signal /S ) [dB] C BMIN [dB] AMAX [dB] BMAX B S AMAX Signal D TA1360ANG BMIN S BMAX 2005-08-18 ...

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... When APACON peak frequency is 13.5 M (00), 9.5 M (01), 6.4 M (10), and 4.5 M (11), calculate and G CDE01 CDE10 BLK picture period period V ± 3 ° C) Test Method (Test condition − G CDEMIN00 respectively using above equation. CDE11 Output gain [dB] 0.2 Vp-p 0dB TA1360ANG . CDEMIN . CDEMAX , CDE00 max min Input frequency [MHz] 2005-08-18 ...

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... Set low frequency area to 0dB, and measure each peak level G 5. Set Y detail control to center (1000), and measure peak level G 6. Set Y detail control to minimum (0000), and measure peak level V ± 3 ° C) Test Method (Test condition YDMAX . YDCEN . YDMIN TA1360ANG 2005-08-18 ...

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... Calculate G and SR01CEN G . SR01MAX ± 3 ° C) Test Method (Test condition × og B00CEN l (SB00MAX/SSB00MIN). and G . SB01CEN SB01MAX l (SB00MAX/SSB00MIN). T *** Gradient S *** = V *** /T *** 20% 20% TA1360ANG l (SB00CEN/SB00MIN) and , and S as R00CEN R00MAX l (SB00CEN/SB00MIN) and 100% V *** 2005-08-18 ...

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... Calculate the following equations × BDY1 7. Input 100-kHz sync signal to TP5, and repeat the procedure above. Calculate the following equations × RDY1 V ± 3 ° × (VBDY1/VBDY0), GC (VBDY2/VBDY0) BDY2 = 20 × (VRDY1/VRDY0), GC (VRDY2/VBDY0) RDY2 TA1360ANG 2005-08-18 ...

Page 70

... Calculate the following equations × Y00 = 20 × CBB = 20 × PBR = 20 × CRR = 20 × PRR V ± 3 ° × (VY00/0.2), G (VY01/0.2) Y01 = 20 × (VB00/0.2), G (VBB01/0.2), PBB (VBR01/0. × og (VR00/02 (VRB01/0.2), PRB (VRR01/0.2) TA1360ANG 2005-08-18 ...

Page 71

... GrC11 = C00 C00 D10 D11 GrD10 = GrD11 = D00 D00 E10 E11 GrE10 = GrE11= E00 E00 0.05 Vp-p ±0 Vp-p −0.05 Vp-p −0.087 Vp-p −0.1 Vp-p ±0 Vp-p −0.07 Vp-p −0.122 Vp-p −0.122 Vp-p −0.14 Vp 150° 210° 240° 270° 180° TA1360ANG 2005-08-18 ...

Page 72

... uCYMAX respectively. 4. Determine unicolor amplitude ratio between maximum and minimum in decibels. (∆V ) uCY 5. Repeat the steps above with the following pins: Input (picture period amplitude 0.2 Vp-p) from pin 4, and measure pin 41. TA1360ANG , and V uCYCNT uCYMIN 2005-08-18 ...

Page 73

... Apply 1 pin 52 from external power supply. 4. Measure pin 43 output picture period amplitude vHTBRY. = vHTBRY/vHTARY 5. Calculate GHT RY 6. Repeat the steps above and measure pin 42. = vHTBGY/vHTAGY Calculate GHT GY 7. Repeat the steps above and measure pin 4. Calculate GHT vHTBBY/vHTABY. TA1360ANG 、 and V CCYCNT CCYMIN = BY 2005-08-18 ...

Page 74

... Measure #43 output signal amplitude levels and chart a characteristic diagram. Determine Vγ where γ starts applying and gradient ∆ at γ ON when linearity at γ 3. OFF is 1. #43 output amplitude γOFF Vγ TA1360ANG γON #5 input amplitude 2005-08-18 ...

Page 75

... Input signal 2 (picture period amplitude = 0.28 Vp-p) from pin Adjust color so that pin 41 output picture period amplitude is 1.2 Vp-p. 3. Set subaddress (0B) data to (80) and measure pin 41 output signal picture period amplitude (1.2 − Calculate the following equation. HBC 1 41 TA1360ANG )/1.2 2005-08-18 ...

Page 76

... Vp-p) from pin /0.2 G /0 MHz, picture period amplitude = 0.7 Vp-p) from pin 3. 0 fY1 and G against each input with f fY15 fY30 TA1360ANG , V , and YDC1 = MHz, Calculate the 0 , and V . YDC15 YDC30 2005-08-18 ...

Page 77

... V in decibels (∆V uMAX uMIN , V , and V respectively. brMAX brCNT brMIN . = −20 × og [2.3/(0.2 × n41 −20 × og [2.3/(0.2 × n42 −20 × og [2.3/(0.2 × n43 100 kHz, picture period amplitude 0.2 Vp-p) from pin v41B/v41A HT1 = v41C/v41A HT2 TA1360ANG ) u ) wps2 . bps 2005-08-18 ...

Page 78

... Apply signal shown in the figure (A) below to pin 24 (BLK input), and measure td td OFF (A) Appling signal to pin 24 (B) Output signal from pins 41, 42, and 43 78 Test Method of output signals from pins 41, 42, and 43 shown in the figure (B) below. 63.5 µ TA1360ANG and ON td OFF 2005-08-18 ...

Page 79

... B3− in decibels when subaddress (0E) data is set to (81), and subaddress (0D) data G3− in decibels when subaddress (0D) data is set to (81), and subaddress (0E) data R2− = 0.2 V/I (Ω) in53 in − Ammeter (µA) TA1360ANG and G1+ and DR in B1+ B1− and DR in G2+ G2− B2+ R1+ B3+ G3+ ...

Page 80

... Vp-p) from pin −20 × (vACL2/vACL1) = −20 × (vACL3/vACL1) = VABL2 − VABL1 ABL = VABL6 − VABL1 P5 = VABL3 − VABL1 ABL = VABL7 − VABL1 P6 = VABL4 − VABL1 ABL = VABL8 − VABL1 P7 = VABL5 − VABL1 ABL = VABL9 − VABL1 P8 TA1360ANG 2005-08-18 ...

Page 81

... V 81 Test Method = VABL11 − VABL10 = VABL12 − VABL10 = VABL13 − VABL10 = VABL14 − VABL10 = VABL15 − VABL10 = VABL16 − VABL10 = VABL17 − VABL10 = VABL18 − VABL10 , V 43R 42R , V , and V . 43G 42G 41G , V , and V . 43B 42B 41B TA1360ANG , and V . 41R 2005-08-18 ...

Page 82

... Also determine ratios of gradients at Y-OUT ON to Y-OUT OFF in decibel. (∆1, ∆2, and ∆3) 100 IRE 82 Test Method Output amplitude (Y-OUT) ∆3 γ2 ∆2 γ1 ∆1 Note: Solid line indicates gamma OFF. Dotted line indicates gamma ON. TA1360ANG 2.3 Vp-p Input amplitude 2005-08-18 ...

Page 83

... Note: Calculate white-peak blue start point in IRE as setting positive amplitude at pedestal level of output signal to 2.3 Vp-p = 100 IRE. Output 83 Test Method using the figure below. and BS . PCNT Pmax ) using the figure below. GCNT and BS ). Gmin Gmax (Output from pin 41) Start point TA1360ANG ON OFF Input amplitude 2005-08-18 ...

Page 84

... Set subaddress (02) data to (80), and repeat the step 5 above: VACB2R, VACB2G, and VACB2B. 7. Set subaddress (02) data to (C0), and repeat the step 5 above: VACB3R, VACB3G, and VACB3B. 84 Test Method = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 ACB insertion pulse V ･ BLK period 1H 2H TA1360ANG 3H 4H 2005-08-18 ...

Page 85

... Vp-p) from pin 3. Control drive 0 = (#45VBLK+) − (#45VBLK) = (#45VBLK−) + (#45VBLK) = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 35 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 TA1360ANG 2005-08-18 ...

Page 86

... Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 35. 0 (maximum, center, and minimum) respectively. uTXR = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 (maximum, center, and minimum) brTX TA1360ANG 2005-08-18 ...

Page 87

... Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 39 v43R/0 v42G/0 v41B/0.2 OSDG OSDB = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 TA1360ANG 2005-08-18 ...

Page 88

... Vp-p) from pin 39. 0 (11), (10), (01), and (00) respectively. uOSDR (11), (10), (01), and (00). Input from pin 37, and measure pin 41, VuOSDB uOSDG = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 Data (38 brOSD0 Data (78 brOSD1 Data (B8 brOSD2 Data (F8 brOSD3 TA1360ANG 2005-08-18 ...

Page 89

... OSDACL3 、 OSDACL4 Change subaddress (07) data to (80), and repeat the steps above to measure OSDACL3 and OSDACL4. 89 Test Method = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 3. Control drive 0 = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 39 −20 × (vOSDACL2/vOSDACL1 −20 × (vOSDACL3/vOSDACL1) 2 TA1360ANG 2005-08-18 ...

Page 90

... Apply 5-V external voltage to pin 51, and repeat the steps above: α41OSD2, α42OSD2, and α43OSD2. 16. Apply 5-V external voltage to pins 50 and 51, and repeat the steps above: α41OSD3, α42OSD3, and α43OSD3. 90 Test Method = 100 kHz, picture period amplitude = 0.2 Vp-p) from pin 100 kHz, picture period amplitude = 0.2 Vp-p) from pins 37, 38, and 39. 0 TA1360ANG 2005-08-18 ...

Page 91

... OFF according to the figure below. (BLG 8. Set subaddress (15) data to (04), and repeat the step 7 above. (BLG Note: Calculate blue stretch start point in IRE as setting positive amplitude at pedestal level of output signal to 2.3 Vp-p = 100 IRE. Output amplitude 91 TA1360ANG Test Method ). min ) max ) ...

Page 92

... ON according to the figure below. Calculate pin 41 output amplitude in IRE as setting positive amplitude at pedestal level of output signal to 2.3 Vp-p = 100 IRE. 6. Set subaddress (1A) data to (C4), (C8), and (CC). Repeat the step 5 above. (BLγ2, BLγ3, and BLγ4) Output amplitude 92 Test Method BLγ Intersection poiint TA1360ANG Blue stretch γ OFF Blue stretch γ ON Input amplitude 2005-08-18 ...

Page 93

... IRE (0.857 Vp-p). Then, compare to the plot in the step 2, calculate a point where a gradient changes (WPL1). 5. Repeat the step 4 above by changing subaddress (19) data to (83) and (86). Calculate points where gradients change (WPL2, WPL3). 93 Test Method 80 ns Figure output amplitude Data 87 Data 86 WPL3 Data 83 WPL2 Data 80 WPL1 # 3 input amplitude Figure B TA1360ANG 2005-08-18 ...

Page 94

... Set subaddress (00) data to 40H. sync phase 2. Input signal B (as shown in the figure below 16. 3. Monitor # 16 (Sync input) and #20 (AFC filter) waveforms. Measure phase difference (HD Test Conditions 29.36 µs 0.285 V 0.593 µ 31.75 µs Signal B 1.5 V 2.35 µ #20 waveform 94 TA1360ANG ). 2005-08-18 ...

Page 95

... B. 31.75 µs 1 (SYNC_OFF_00 − SYNC_TIP_00)/0.286 × 100 thS00 = (SYNC_OFF_01 − SYNC_TIP_01)/0.286 × 100 = (SYNC_OFF_10 − SYNC_TIP_10)/0.286 × 100 = (SYNC_OFF_11 − SYNC_TIP_11)/0.286 × 100 1H 40IRE (= 286 mVp-p) 95 TA1360ANG 0.08H Sync separation level Sync tip level 2005-08-18 ...

Page 96

... Change slave address (01) data from 80H to FEH, and measure phase change amount ∆H of #24 (H-OUT) waveform. SFT+ Signal B #24 waveform Data: 00H #24 waveform Data: 80H #24 waveform Data: FEH Test Conditions . thHD 31.75 µs V thDH 2.35 µs 31.75 µs 1.5 V 2.35 µs ∆H SFT− ∆H SFT+ 96 TA1360ANG SFT− 2005-08-18 ...

Page 97

... Apply no signal input to TP16. 6. Measure #18 clamp pulse phase (CP #24. Signal B #18 waveform #24 waveform #18 waveform Test Conditions 31.75 µs 1.5 V 2.35 µs ∆H# width ( 31.75 µs 1.5 V 2.35 µs CP S0/1 CP V0 TA1360ANG ), width (CP ), and output level S0 PW0 ), ( and output level ( relation to V2 2005-08-18 ...

Page 98

... Input signal B (as shown in the figure below) to TP16. 3. Increase amplitude of FBP signal to be input to #24 (FBP input) from 0 Vp-p. When #26 (H-OUT) phase locks with that of signal B, measure #24 input amplitude V Test Conditions 31.5 µs 4.13 µs HBP HBP S**a 31.75 µs 1.5 V 2.35 µs 98 TA1360ANG and HBP ) in relation S00a S00b S**b . thFBP 2005-08-18 ...

Page 99

... MAX , F37K , F37K , F45K , and F45K MIN MAX MIN MAX + 0.05 V, and V − 0. 20. Measure frequencies FA and FB according and Low (V26 ) of #26 (H-OUT) output waveform TA1360ANG and TH ) using the following MIN ) MAX , F31K , F31K , F33K , MIN MAX MIN . ...

Page 100

... Input signal F (shown in the figure below 15. 3. Increase signal-F cycle from 30H. Measure the cycle (T TP 27. Signal F (TP 15 waveform input) #24 input waveform TP 27 waveform Test Conditions 2.35 µs 29.63 µs 5.6 µs VPw VPt ) when phase locks with that of VPULL 3H T VPULL 100 TA1360ANG GND 2005-08-18 ...

Page 101

... Test Conditions and VBPP according to #2 output waveform VBPP , VBPP , VBPP , VBPP and VBPP as in the step 3 above 262.5H to 1125H VBPP VBPP E according to #43 output waveform. 3H 1125H VBLK 101 TA1360ANG , VBPP , VBPP , VBPP , and MIN 2005-08-18 ...

Page 102

... Video signal (2) Input signal 1 (3) Input signal 2 (4) Input signal 3 Figure T-1 Signals for Text/Color Difference Signal 2 63.5 µs Sine wave of frequency f Amplitude A Sine wave of frequency f 102 TA1360ANG 0 0 2005-08-18 ...

Page 103

... Input signal 4 50 (2) 0% 10% 50% 90% 100 (3) 0% 10% 50% 90% 100% Figure T-2 Test Pulses for Text/Color Difference Signal 2 63.5 µs 20 µs 20 µ τ τ τ τ 103 TA1360ANG 2005-08-18 ...

Page 104

... TP23a TP21 TP20 A B TP18 TP27 TP23b 1200 pF 1200 TC4538BP 1000 pF 1000 pF 31.5/33.75 kHz TA1360ANG TC4538BP kHz 2005-08-18 ...

Page 105

... Mylar capacitor M A Application of H-FREQ switching (31.5 k/33.75 k/45 kHz) B Tr. A H-FREQ 31.5 kHz L 33.75 kHz L 45 kHz H *: Don’t care TA1360ANG Pin 13 voltage Pin 22 voltage 2005-08-18 ...

Page 106

... ACB Application Circuit + CLAMP p-p CRT G B 0~3.0 V (DC) 106 TA1360ANG CRT CRT B 2005-08-18 ...

Page 107

... Package Dimensions Weight: 5.55 g (typ.) 107 TA1360ANG 2005-08-18 ...

Page 108

... TA1360ANG 2005-08-18 ...