CXA1391Q/R Processing IC for Complementary Color Mosaic CCD Camera For the availability of this product, please contact the sales office. Description The CXA1391Q/R is a bipolar IC developed for signal processing in complementary color mosaic CCD cameras. CXA1391Q 64 pin QFP (Plastic) Features • Low power consumption (170mW) • Number of delay lines used for signal processing can be selected according to the system requirements • The LPF peripheral to 1H delay line is built in Absolute Maximum Ratings • Supply voltage Vcc • Storage temperature Tstg • Allowable power dissipation PD Structure Bipolar silicon monolithic IC DLC1 IN C1 GAIN DLCO OUT R MTX CLP C MPX1 CLP C MPX2 B MTX ID B GAIN B CONT R CONT R GAIN CLP C B CLP C G CLF C R C LEVEL 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 CLP (CLP4) CLP C YO 51 Y0 LPF Y0 Y1 LPF CLP (CLP2) 30 WB B 29 WB G 28 WB R R-r G-r B-r 2H APCN V-APCN LPF ADJ 1 59 LPF ADJ 2 60 LPF ADJ 3 61 23 CS GAIN V-APCN LPF YH0 V CC 62 CLP (CLP4) GC YH1 22 R – Y HUE 21 B – Y HUE 20 R – Y OUT 19 B – Y OUT 18 B – Y GAIN YH0 DLYH OUT YH OUT 1 YH OUT 2 TP 9 10 11 12 13 14 15 16 CS IN CLP C DLYH 8 CLP C CS 7 VAP SLICE 6 CLP C VAP 5 VAP GAIN 4 VAP OUT 3 CLP2 2 CLP4 1 DLYH IN 17 R – Y GAIN CLP C YH r DLYH GAIN CLP (CLP2) GC Y-r CONT 63 YH IN 64 25 YL OUT 24 CS OUT R-Y MTX R-Y B-Y Hue & GC – CS VAP MAX LPF CS-Y CS CLP (CLP4) 3H APCN YH1 26 GND 1 B-Y – – GND 2 58 KNEE Y2 GAIN 57 GC ABS CS-Y LPF G ch SLICE SLICE CLP CLP (CLP4) Y2 CLP V-APCN (CLP4) GC Y0 DLY2 IN 56 KNEE LPF Y2 Y1 CLP (CLP4) Y1 KNEE GC 27 C-r CONT r Y1 GAIN 54 R-r SLICE DLY1 OUT 53 DLY1 IN 55 31 WB DC YL MTX DLY0 OUT 52 CLP (CLP4) GC 32 C SLICE LPF B-r Y0 C0 CLP -CB B LPF (CLP2) CR G & Y MATRIX R WB AMP C1 MPX LPF G-r S1 IN 50 V °C WB CONTROL LPF R-WB G-WB B-WB C0 S2 IN 49 7 –55 to +150 690 mW (LQFP: Ta = 25°C, without P.C.B) Recommended Operating Conditions • Supply voltage Vcc 4.75 to 5.25 V • Ambient temperature Topr –20 to +75 °C Applications Complementary color mosaic CCD cameras Block Diagram and Pin Configuration (Top View) CXA1391R 64 pin LQFP (Plastic) Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits. –1– E89Z18-ST CXA1391Q/R Pin Description PIn No. Symbol Pin voltage Equivalent circuit Description 1 2.4k 1 CLP C YH 2.4k 800 1k 3 to 3.5V Capacitor connecting pin for YH clamp (Clamp at CLP2) 147 180µA 80µA 1k DL YH signal input pin (Input from 1H delay line) 147 2 DL YH IN 2 3.65V Sig: Typ. 200mV (Positive polarity) 5k 80µA 3 2.6k 3 CLP C DL YH 1k 2.6k 1k 147 Capacitor connecting pin for DL YH clamp (Clamp at CLP4) 2.6 to 3.8V 180µA 40µA 200 4 DL YH OUT DL YH signal output pin (To 1H delay line) 2.7 to 3.1V 4 400µA Note) Pin voltage for input and output pins indicate black level. –2– Sig: Typ. 400mV Max. 600mV (Negative polarity) CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 100 5 YH OUT1 YH1 signal output pin 1.9 to 2.3V Sig: Typ. 1V Max. 1.5V (Positive polarity) 5 160µA 100 6 YH OUT2 YH2 signal output pin 1.9 to 2.3V Sig: Typ. 1V Max. 1.5V (Positive polarity) 6 400µA 2.6 to 3.0V (YH) 7 TP TP OUT (adjusting pin) 1H mode: Outputs YH1–YH0 0H mode: Outputs Gch C-slice OUT (Mode selection is executed through Pin 8) 500 2.5 to 2.9V (G) 7 80µA 0V (0H Mode) 8 DL YH GAIN 1.8 to 5V (1H Mode) 54 Y1 GAIN 0V: Common control by Pin 57 1.8 to 5V Independent control 1k 30k 30k 40µA –3– 100k 147 8 54 100k DL YH signal gain control pin (For 1H delay line gain compensation of YH) TP (Pin 7) mode selection 0H Mode: 0V 1H Mode: 1.8 to 5V DLY1 signal gain control pin (1H delay line gain compensation) 0V: DLY1 signal gain control is executed in common with DLY2 signal gain control. 1.8 to 5V: DLY1 signal gain control is executed independently from DLY2 signal gain control. CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit 5V 9 1k CLP4 Description CLP4 pulse input pin (BLK clamp) (CMOS level input, VTH = 2.5V) 30k 0 9 5V 10 CLP2 pulse input pin (OPB clamp) (CMOS level input, VTH = 2.5V) 10 CLP2 40µA 0 431 V-APCN signal output pin∗ 11 VAP OUT 2.6 to 3.0V 11 Sig: Max. 1.2Vp-p 280µA 1k 147 12 VAP GAIN 1.8 to 5V (Control) 12 25k V-APCN signal output level adjustment pin 25k 40µA 2.6k 2.6k 1k 13 CLP C VAP Capacitor connecting pin for VAP clamp (Clamp at CLP4) 3.4 to 3.8V 147 147 180µA 12µA 13 ∗ V-APCN: Vertical Aperture Compensation –4– CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 1k 147 14 VAP SLICE 14 1.8 to 5V (Control) 30k V-APCN signal dark slice volume adjustment pin 30k 40µA 2.6k 2.6k 1k 15 CLP C CS Capacitor connecting pin for CS clamp (Clamp at CLP4) 3.5 to 3.7V 147 147 180µA 20µA 15 2.6k 2.6k 1k 147 16 CS IN C-Couple input 2.9 to 3.3V AGC CS signal input pin 16 147 Sig: Max. 1V 180µA –5– 20µA CXA1391Q/R PIn No. 17 18 Symbol Pin voltage R–Y GAIN 0V: R–G output 1.8 to 5V: R–Y output B–Y GAIN 0V: B–G output 1.8 to 5V: B–Y output Equivalent circuit 1k 30k Description R–Y signal output level adjustment pin Pin 20 Mode select 0V: R–G output 1.8 to 5V: R–Y output 100k 30k 100k 17 18 23 B–Y signal output level adjustment pin Pin 19 Mode select 0V: B–G output 1.8 to 5V: B–Y output 40µA 23 CS GAIN 19 B–Y OUT 20 R–Y OUT 1.8 to 5V (Control) V-APCN CS signal gain control pin B–Y signal output pin Sig: Typ. 590mVp-p 2.75 to 3.15V (Hue OFF) 2.35 to 2.75V (Hue ON) R–Y signal output pin Sig: Typ. 800mVp-p DLC0 signal output pin Sig: Typ. 200mVp-p Max. 600mVp-p (Positive polarity) 431 46 DLC0 OUT 1.8 to 2.2V 19 20 46 300µA 52 DLY0 OUT 53 DLY1 OUT 21 B–Y Hue 1.4 to 1.8V 53 DLY1 signal output pin Sig: Typ. 200mVp-p Max. 600mVp-p (Positive polarity) 2.8 to 3.2V 0V: Hue OFF 1k 30k 22 R–Y Hue DLY0 signal output pin Sig: Typ. 200mVp-p Max. 600mVp-p (Positive polarity) 52 0V: Hue OFF 30k 100k 147 B–Y hue control pin 80k R–Y hue control pin 40µA –6– 21 22 CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 431 CS signal output pin 24 CS OUT 1.5 to 1.8V 24 Sig: Max. 1V 200µA 431 25 YL OUT YL signal output pin 1.9 to 2.3V 25 80µA 26 GND GND1 1k 27 C-γ CONT 100k Chroma (R.G.B) γ curve adjustment pin 0V: Typ. γ curve 30k 30k 147 40µA 27 –7– CXA1391Q/R PIn No. 28 Symbol WB R Pin voltage Equivalent circuit Description R signal output pin WB Mode: Sig: Typ. 400mV γ Mode: Sig: Typ. 500mV 1.4 to 2V 431 G signal output pin WB Mode: Sig: Typ. 400mV γ Mode: Sig: Typ. 500mV 28 29 WB G 1.4 to 2V 29 30 200µA 30 WB B B signal output pin WB Mode: Sig: Typ. 400mV γ Mode: Sig: Typ. 500mV 1.4 to 2V 431 31 WB DC 1k 300 1.4 to 2V 200µA 100k 31 100k 32 C SLICE When connected to Vcc: Pins 28, 29 and 30 turn to γ mode. 1k 32 0V: Slice OFF When used as output pin, it is an Auto WB DC output pin. Pin 28, 29 and 30 turn to WB mode. 18k 18k Chroma (R.G.B) signals dark slice level adjustment pin 67µA 33 C LEVEL 1.8 to 5V (Control) Chroma (R.G.B) gain control pin (Chroma modulation factor control for all 3 channels) 1k 33 47 30k 47 C1 GAIN 30k 1.8 to 5V (Control) 40µA –8– DL C1 signal gain control pin (1H delay line gain compensation) CXA1391Q/R PIn No. 34 Symbol CLP C R Pin voltage Equivalent circuit Description Capacitor connecting pin for R WB amplifier clamp (Clamp at CLP2) 3.0 to 3.6V 2.2k 2.2k 1k 1k 35 CLP C G Capacitor connecting pin for G WB amplifier clamp (Clamp at CLP2) 147 3.0 to 3.6V 34 35 36 125µA 36 CLP C B 3.0 to 3.6V 37 R GAIN 1.8 to 5V (Control) 40µA Capacitor connecting pin for B WB amplifier clamp (Clamp at CLP2) Rch WB amplifier gain control pin (Pre-WB) 1k 147 37 40 15k 40 B GAIN 1.8 to 5V (Control) 38 R CONT 2.5 to 4.6V 15k 80µA 1k Bch WB amplifier gain control pin (Pre-WB) Rch WB amplifier gain control pin 147 38 39 39 B CONT 2.5 to 4.6V 10µA –9– Bch WB amplifier gain control pin CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 1k ID pulse (color discrimination pulse) input pin (CMOS level VIH = 2.5V) 30k 147 41 ID 5V 41 ID = L C0 → CR C1 → CB 0 40µA 1k ID = H C0 → CB C1 → CR 100k 1.8 to 5V (Control) 42 B MTX 0V (Preset) 15k 15k 80µA 43 CLP C MPX2 2.7 to 3.1V 147 42 1k 147 43 44 147 6k 44 CLP C MPX1 100k B signal operations MTX coefficient adjustment pin (Coefficient 0.22) Refer to Note 2. 6k 2.7 to 3.1V 40µA – 10 – Capacitor connecting pin for MPX clamp (Clamp at CLP2) CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit 1k Description 100k 1.8 to 5V (Control) 45 R MTX 30k 0V (Preset) 300k 40µA 48 55 DLC1 IN C-Couple input 3.1 to 3.5V DLY1 IN C-Couple input 3.6 to 4.0V DLY2 IN C-Couple input 3.6 to 4.0V 2.6k 147 100k 45 2.6k DL C1 signal input pin Sig: Typ. 150mVp-p (Negative polarity) 1k 1k R signal operations MTX coefficient adjustment pin (Coefficient 0.617) Refer to Note 2. DL Y1 signal input pin Sig: Typ. 150mVp-p (Negative polarity) 147 48 55 56 56 11µA 150µA DL Y2 signal input pin Sig: Typ. 150mVp-p (Negative polarity) S2 signal input pin 147 49 S2 IN 1.9V 147 49 50 7.5k 40µA Sig: Typ. 500mV Max. 1500mV 40µA S1 signal input pin 1.9V – 11 – 40µA 40µA 40µA Sig: Typ. 500mV Max. 1500mV 40µA S1 IN 40µA 50 CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 1k 2.6k 147 51 CLP C Y0 1k Capacitor connecting pin for Y0 clamp (Clamp at CLP4) 3.3 to 3.7V 51 40µA 150µA 1k 1.8 to 5V (3H Mode) 57 DL Y2 signal gain control pin (1H delay line gain compensation) V-APCON mode selection 0V: 2H Mode 1.8 to 5V: 3H Mode 147 57 Y2 GAIN 15k 0V (2H Mode) 80µA 58 59 GND2 GND LPF Adj. 1 Connecting pin of the external resistor that determines the characteristics of the LPF for 1H DL. (External resistor in the range of 15 to 27kΩ) 1.8 to 2.2V 5k 20k 300 60 LPF Adj. 2 1.8 to 2.2V 10µA 59 60 – 12 – Connecting pin of the external resistor that determines the characteristics of the chroma LPF (LPF for R, G, B, CS). (External resistor in the range of 15 to 62kΩ) CXA1391Q/R PIn No. Symbol Pin voltage Equivalent circuit Description 1k 300 61 LPF Adj. 3 300 1.8 to 2.2V 10µA 61 120k 62 Connecting pin of the external resistor that determines the characteristics of the LPF for V-APCN. (External resistor in the range of 15 to 62kΩ) When connected to Vcc, the LPF for V-APCN turns OFF. Vcc Power supply 5V (Typ.) 1k 100k 0V (Typ. γ curve) 63 YH γ curve adjustment Y-γ CONT 1.8 to 5V (Control) 30k 30k 40µA 147 63 10k YH signal input 64 YH IN 0.95V Sig: Typ. 220mV Max. 660mV 64 – 13 – CXA1391Q/R Electrical Characteristics Item Symbol Conditions Min. Typ. Max. Unit 25 34.5 43 mA Current consumption ID S2–S1 Amp Gain SSG Input: S1 IN = –62.5mV, S2 IN = 62.5mV Calculations: DLC0 OUT/S1 IN –3 –1.95 –1 dB DLC1 gain control Max. Input: DLC1IN = 100mV Conditions: C1Gain = 5V DLC1H C-level = 5V Calculations: (WB-R/DLC1IN) –CG Note2) 6 7 9 dB Min. DLC1L Conditions: C1Gain = 0V (Others same as DLC1H) –2 –0.85 0 dB SAG Input: S1 IN = 500mV Calculations: DLY0OUT/S1 IN –15 –14 –13 dB Gch Y GY Input: S1 IN = S2 IN = 300mV Conditions: C-level = 5V Calculations: WB-G (ID = H, L average) 80 100 120 mV CR/Y GCR Input: S1 IN = S2 IN = 62.5mV Conditions: C-level = 5V Calculations: WB-G/GY (ID = L) 0.9 1 1.1 — –CB/Y GCB ID = H (Others same as GCR) –1.1 –1 –0.9 — Rch CR RCR Input: S1 IN = –62.5mV, S2 IN = 62.5mV Conditions: C-level = 5V Calculations: WB-R (ID = L) 70 85 100 mV Y (Preset) RYP Input: S1 IN = S2 IN = 500mV Conditions: C-level = 5V Calculations: WB-R/RCR (ID = H) 0.15 0.168 0.186 — Y (Max.) RYH RMTX = 5V (Others same as RYP) 0.22 0.25 0.27 — Y (Min.) RYL RMTX = 1.8V (Others same as RYP) 0.11 0.125 0.14 — Bch–CB BCB Input: S1 IN = 62.5mV, S2 IN = –62.5mV Conditions: C-level = 5V Calculations: WB-B (ID = H) 80 100 120 mV Y (Preset) BYP Input: S1 IN = S2 IN = 500mV Conditions: C-level = 5V Calculations: WB-B/BCB (ID = H) 0.2 0.22 0.24 — Y (Max.) BYH BMTX = 5V (Others same as BYP) 0.31 0.34 0.37 — Y (Min.) BYL BMTX =1.8V (Others same as BYP) 0.13 0.15 0.17 — S1+S2 Amp Chroma matrix (Gch) Note 3) Chroma matrix (Rch) Note 3) Chroma matrix (Bch) Note 3) – 14 – CXA1391Q/R Item Symbol Conditions Min. Typ. Max. Unit 7.5 8.2 8.5 dB RCONT Max. RCH Input: DLC1IN = –200mV Conditions: C-level = 5V RCONT = 4.6V (ID = H) Calculations: WB-R/WB-RTyp. Note 4) WB-R Typ. is the tested output of WB-R when RCONT is set to 4V (Other inputs, conditions same as RCH) RCONT Min. RCL Test: RCONT = 2.5V (Others same as RCH) –8.4 –7.9 –7.4 dB BCONT Max. BCH Input: DLC1IN = 150mV Conditions: C-level = 5V BCONT = 4.6V (ID = L) Calculations: WB-B/WB-BTyp. Note 4) WB-B Typ. is the tested output of WB-B when BCONT is set to 4V (Other inputs, conditions same as BCH) 7.5 8.2 8.5 dB BCONT Min. BCL Test: BCONT = 2.5V (Others same as BCH) –8.4 –7.9 –7.4 dB RGH Input: DLC1IN = –200mV Conditions: RCONT = 2.5V RGAIN = 5V C-level = 5V (ID = H) Calculations: WB-R/WB-RMin. WB-R Min. is the tested WB-R, when tested under the same conditions as RCL. 8.6 9.2 — dB BGH Input: DLC1IN = 150mV Conditions: BCONT = 2.5V BGAIN = 5V C-level = 5V (ID = L) Calculations: WB-B/WB-BMin. WB-B Min. is the tested WB-B, when tested under the same conditions as BCL. 11.4 12.2 — dB WB GAIN RGAIN Max. BGAIN Max. – 15 – CXA1391Q/R Item Bch color difference matrix Note 5) Symbol Conditions Min. Typ. Max. Unit 0.4 0.44 0.48 — –0.24 –0.21 –0.17 — R–G OUT/ WB-B BMBY Input: S1IN = 200mV S2IN = 160mV DLC1IN = 220mV Conditions: C-γ CONT = WB DC = C-Slice = C-level = 5V RCONT = 2.5V BCONT = 4.6V (ID = L) Calculations: B–Y OUT/WB-B R–Y OUT/ WB-B BMRY Conditions: R–Y GAIN = 1.8V Calculations: R–Y OUT/WB-B (Others same as BMBY) BMG Conditions: BCONT = 4V 1. B–Y OUT is tested when B–Y gain = 0V and taken as A. (Other conditions are the same as BMBY) 2. B–Y OUT is tested when B–Y gain = 5V and taken as B. (Other conditions are the same as BMBY) Calculations: B/A 3.0 3.3 — — B–Y Hue Max. BMHH Conditions: B–Y HUE = 1.8V (Others same as BMBY) Calculations: R–Y OUT/B–Y Typ. 0.58 B–Y Typ. is the value of the tested B–Y OUT when B–Y hue=0V (Other conditions are the same as BMBY). Note 6) 0.68 — — B–Y Hue Min. BMHL B–Y HUE = 5V (Others same as BMHH) –0.67 –0.58 — GMR Input: S1IN = 830mV S2IN = 660mV DLC1IN = –230mV Conditions: WB-DC = C-level = 5V RCONT = BCONT = 2.5V 1. R–Y OUT is tested when R–Y gain = 0V and taken as A. 2. R–Y OUT is tested when R–Y gain = 1.8V and taken as B. Calculations: B/A 0.81 0.85 0.89 — GMB Input: (The same as GMR) Conditions: 1. B–Y OUT is tested when B–Y gain = 0V and taken as A. 2. B–Y OUT is tested when R–Y gain = 1.8V and taken as B. (Others same as GMR) Calculations: B/A 0.63 0.66 0.7 B–Y GAIN Max. R–Y/R–G Gch color difference matrix Note 5) B–Y/B–G – 16 – — — CXA1391Q/R Item Symbol Min. Typ. Max. Unit 0 5 15 mV Typ.–Min. CSLL Input: DLY1IN = –400mV Conditions: C-level = 5V Y1GAIN = 1.8V C-Slice = 1.8V (ID = H) Calculations: C-Slice Typ. -TP C-Slice Typ. is the TP output of C-Slice = 0V. Typ.–Max. CSLH Conditions: C-Slice =5V (Others same as CSLL) 95 120 145 mV C-γ CONT=0V γTyp. Gch-WB=400mV Input: DLY1IN = –200mV S1IN = S2IN = 500mV Conditions: Y1GAIN = 1.8V C-level is valied and adjusted to obtain 400mV at WB-G. After that C-level is fixed during test. WB-DC is set to OPEN during C-level adjusted and set to 5V during test. Calculations: WB-G is tested. 450 500 550 mV C-γ CONT=0V γL8 Gch-WB=800mV Input: DLY1IN = –400mV S1IN = S2IN = 1000mV Conditions: Same as γ Typ. Calculations: WB-G/γ Typ. 1.13 1.2 1.25 — C-γ CONT=0V γL1 Gch-WB=100mV Input: DLY1IN = –50mV S1IN = S2IN = 125mV (Others same as γL8) 0.36 0.4 0.44 — C-γ CONT=1.8V γM4 Gch-WB=400mV Input: DLY1IN = –200mV S1IN = S2IN = 500mV Conditions: Cγ CONT = 1.8V Calculations: WB-G/γ Typ. 0.9 1 1.1 — C-γ CONT=1.8V γM8 Gch-WB=800mV Input: DLY1IN = –400mV S1IN = S2IN = 1000mV (Others same as γM4) 1.13 1.2 1.25 — C-γ CONT=1.8V γM1 Gch-WB=100mV Input: DLY1IN = –50mV S1IN = S2IN = 125mV (Others same as γM4) 0.45 0.5 0.55 — C-γ CONT=5V γH4 Gch-WB=400mV Input: DLY1IN = –200mV S1IN = S2IN = 500mV Conditions: Cγ CONT = 1.8V Calculations: WB-G/γ Typ. 0.9 1 1.1 — C-γ CONT=5V γH8 Gch-WB=800mV Input: DLY1IN = –400mV S1IN = S2IN = 1000mV (Others same as γH4) 1.13 1.2 1.25 — C-γ CONT=5V γH1 Gch-WB=100mV Input: DLY1IN = –50mV S1IN = S2IN = 125mV (Others same as γH4) 0.26 0.3 0.35 — C-Slice Gch γ curve Conditions – 17 – CXA1391Q/R Item Symbol Yγ1.0 (Typ.) YγT Yγ2.0/Yγ1.0 Min. Typ. Max. Unit Input: YHIN = 220mV Calculations: DLYHOUT –440 –400 –360 mV Yγ2.0 Input: YHIN = 440mV Calculations: DLYHOUT/YγT 1.23 1.37 1.51 — Yγ0.5/Yγ1.0 Yγ0.5 Input: YHIN = 110mV Calculations: DLYHOUT/YγT 0.59 0.66 0.73 — Yγ0.5 (Max.)/ Yγ1.0 YγH Input: YHIN = 110mV Conditions: Yγ CONT = 1.8V Calculations: DLYHOUT/YγT 0.64 0.71 0.78 — Yγ0.5 (Min.)/ Yγ1.0 YγL Input: YHIN = 110mV Conditions: Yγ CONT = 5V Calculations: DLYHOUT/YγT 0.54 0.6 0.66 — TP (YH) TPY Input: YHIN = 220mV Conditions: DLYHGAIN = 1.8V Calculations: TP/DLYHOUT –5 –4 –3 dB TP (DLYH) TPDY Input: DLYHIN = YγT × 0.7 Conditions: Same as TPY Calculations: TP/–DLYHOUT –5 –4 –3 dB TPG Input: S1IN = S2IN = 500mV DLY1IN = 200mV Conditions: Y1GAIN = 1.8V Calculations: TP/WB-G –2 0 2 dB YLG Input: YHIN = 220mV DLYHIN = – [YγT × –3.5dB] Conditions: DLYHGAIN = 1.8V Calculations: TP is tested to check that the signal level is below 0mV in relation to black level. Note 8) — — 3.5 dB YHG Input: YHIN = 220mV DLYHIN = – [YγT × –12dB] Conditions: DLYHGAIN = 5V Calculations: TPTP is tested to check that the signal level is over 0mV in relation to black level. Note 8) 12 — — dB Chroma level Max./Min. GCL Input: DLC1IN = 200mV Conditions: 1. WB-G is tested when C-level = 5V and taken as GC-level Min. 2. WB-G is tested when C-level = 1.8V and taken as GC-level Max. (Both 1 and 2 test at ID-H.) Calculations: GC-level Max. / GC-level Min. 1.55 1.65 1.75 — WB DC WDDC Test: WB-DC 1.4 1.6 2 V Yγ TP TP (GWBS) Min. Gain YH AMP Max. Gain Conditions – 18 – Note 7) CXA1391Q/R Item Conditions Min. Typ. Max. Unit YLR Input: S1IN = 150mV S2IN = 450mV Conditions: C-γ CONT = WB DC = C-Slice = C-level = 5V RCONT = 4.6V BCONT = 2.5V BGAIN = 1.8V (ID = L) Calculations: YLOUT/WB-R 0.27 0.3 0.34 — YLB Input: S1IN = 200mV S2IN = 160mV DLC1IN = 220mV Conditions: C-γ CONT = WB DC = C-Slice = C-level = 5V RCONT = 2.5V BCONT = 4.6V (ID = L) Calculations: YLOUT/WB-B 0.08 0.1 0.12 — YLG Input: S1IN = 830mV S2IN = 660mV DLC1IN = –230mV Conditions: WB-DC = C-level = 5V RCONT = BCONT = 2.5V Calculations: YLOUT/WB-G 0.54 0.6 0.66 — YHOUT1 (OH mode) YH1Z Input: YHIN = 220mV Calculations: YHOUT1 is tested. 900 1000 1100 mV YHOUT1 1H/0H YH1O Input: DLYHIN = – (YγT × –4dB) Conditions: DLYHGAIN = 1.8V Calculations: YHOUT1/YH1Z Note 8) –1 0 1 dB YHOUT2 (0H) /YHOUT1 YH2Z Input: YHIN = 220mV Calculations: YHOUT2/YH1Z –1 0 1 dB YH2O Input: YHIN = 220mV Conditions: DLYHGAIN = 1.8V Calculations: YHOUT2/YHOUT2Typ. YHOUT2Typ. is YHOUT2 output tested at YH2Z. –6.5 –6 –5.5 dB VAPT Input: S1IN = S2IN = 125mV Conditions: VAP GAIN = 1.8V VAP Slice = 1.8V Y2 GAIN = 1.8V Calculations: VAP OUT is tested. –250 –200 –150 mV VS Input: S1IN = S2IN = 1000mV Conditions: Y2 GAIN = 1.8V 1. VAP OUT is tested when VAP Slice=1.8V and taken as SMin. 2. VAP OUT is tested when VAP Slice=5V and taken as SMax. Calculations: SMax.–SMin. Note 10) 256 320 384 mV YLOUT/ RγOUT Symbol YL Note 5) YLOUT/ BγOUT YLOUT/ GγOUT YHOUT2 (1H) /YHOUT1 VAP Typ. Note 9) VAP Slice Note 9) – 19 – CXA1391Q/R Item Min. Symbol Conditions Min. Typ. Max. Unit DY1L Input: S1IN = S2IN = 500mV DLY1IN = –200mV Conditions: VAP GAIN = VAP Slice = Y1GAIN = 1.8V Calculations: VAP-OUT is tested to check that the signal level is over 0mV in relation to black level. — — 0 dB DY1H Input: S1IN = S2IN = 500mV DLY1IN = –110mV Conditions: VAP GAIN = VAP Slice = 1.8V Y1GAIN = 5V Calculations: VAP-OUT is tested to check that the signal level is below 0mV in relation to black level. 5 — — dB — — 0 dB 5 — — 90 120 150 mV — 0 0.05 — — — 490 mV DLY1 gain Note 11) Max. Min. DY2L DLY2 gain Note 11) Input: S1IN = S2IN = –167mV DLY2IN = –66.7mV Conditions: VAP GAIN = VAP Slice = Y1GAIN = Y2GAIN = 1.8V Calculations: VAP-OUT is tested to check that the signal level is over 0mV in relation to black level. Input: S1IN = S2IN = –167mV DLY2IN = –37.5mV Conditions: Y2GAIN = 5V (Others same as DY2L) Calculations: VAP-OUT is tested to check that the signal level is below 0mV in relation to black level. Max. DY2H VCS Typ. VCST VCS Min. VCSL VCS Max. VCSH Conditions: CS GAIN = 1.8V (Others same as VCSL) 4.4 VCS Typ. CST Input: CS-IN = 500mV 440 CS Note 12) Input: S1IN = S2IN = 167mV Conditions: Y1GAIN = Y2GAIN = 1.8V CS GAIN = 5V Calculations: CS OUT is tested. Conditions: CS GAIN = 0V (Others same as VCST) Calculations: CS OUT/VCST – 20 – 465 dB CXA1391Q/R Note 1) For pins without specific instructions regarding input, feed the DC value shown on the Test Circuit. Calculations are mentioned utilizing the pin name or the electrical characteristics symbols. Otherwise, for exceptional notations explanatory notes, are given with every case. Note 2) In this item, the gain of DLC1 amplifier exclusively is calculated. CG is the gain of the system from DLC1 IN to WB-R from which DLC1 GC amplifier gain has been excluded. —CG calculating method— In the actual calculation, the system on C0 side is utilized. Input: S1IN = –62.5mV S2IN = 62.5mV Condition: Same as DLC1H Calculations: CG = 20log (WB-R/DLC0OUT) Note 3) Chroma matrix operations R = 2 [CR + αY] G = Y – (CR + CB) B = 2 [CB + ß (Y – C)] α: Control with RMTX (Preset 0.167) ß: Control with BMTX (Preset 0.22) Note 4) With the typical gain taken when R CONT is at 4V, compare with the gain during Max. and Min. The same for B CONT. Note 5) Adjustment and testing is performed so that signals are output only for each of R, G, B channels respectively. Note 6) Comparison with B–Y OUT when R–Y HUE = 0V (HUE OFF). The same for B–Y HUE. Note 7) The compensation of difference in gain of YH0 andYH1 is as follows. 1) At DLYH GAIN = 1.8V, DLYH amplifier gain is 3dB. 2) Test DLYH OUT (tested at YrT) when YH IN = 220mV signal is input. 3) The difference in gain between YH0 and YH1 is compensated by inputting the signal as –3dB to DLYH IN. Note 8) The amplifier input is varied and the gain confirmed. Note 9) VAP (Vertical Aperture Compensation) Note 10) Dark slice variable volume. (Output level difference between the value slice volume at Max. and slice volume at Min.) Note 11) Utilizing V-APCN 2H mode, DLY1 amplifier exclusive gain is obtained through operations. However, as the amplifier gain cannot be tested directly, only the upper and lower limits of the gain control are checked according to the following method. (a) Lower limit check S1 IN = S2 IN = 500mV (At that time KNEE circuit input turns to 200mV) DLY1 IN = –200mV (For others refer to the conditions chart) In this condition, if we have VAP OUT ≥ 0, this indicates that DLY1 amplifier is below 0dB. (b) Upper limit check S1 IN = S2 IN = 500mV DLY1 IN = –110mV (in (a) the –5dB of –200mV) In this condition, if we have VAP OUT ≤ 0, this indicates that DLY1 amplifier is above 5dB. Note 12) CS (Chroma Suppress) – 21 – CXA1391Q/R Timing Chart for Testing Input waveform Differs with each test 30µ 30µ 30µ 30µ DLYH IN CS IN DLC1 IN S1 5V tD 0V 5V 2µ 2µ CLP2 0V 5µ 5µ 5V 2µ CLP4 2µ 0V 15µ 15µ Output waveform Output signal DLYH OUT YH OUT1 YH OUT2 TP VAP_OUT B – Y OUT R – Y OUT CS OUT YL OUT WB_R WB_G WB_B DLC0 OUT DLY0 OUT DLY1 OUT – 22 – S2 DLY1 IN DLY2 IN YH IN 10 62k 62k 27k 0.1 64 YH IN 63 Y-r CONT 62 V CC 61 LPF ADJ 3 60 LPF ADJ 2 59 LPF ADJ 1 58 GND 2 57 0.1 Y2 GAIN 56 0.1 DLY2 IN 55 DLY1 IN 54 Y1 GAIN 53 DLY1 OUT 52 DLY0 OUT 51 CLP C YO 50 S1 IN 49 S2 IN Note 1) µF is unit of capacitor Note 2) indicates testing pin. (AC, DC test) Note 3) Input pin DC value indicates input signal black level. Note 4) indicate relay, side, normal close. DC 0.95V 0V 5V 5V 62k 0V 0V DC 1.9V DC 1.9V 1 C0 47 Y0 CLP (CLP2) GC GC LPF 48 0.1 DLCO OUT LPF 2 r 3 YH0 0.1 4 LPF – 3H APCN – LPF CLP (CLP4) Y2 YH1 44 CLP (CLP4) LPF 45 CLP (CLP4) Y1 Y0 GC 46 0.1 V 5 CLP (CLP4) 42 0V 41 ID 40 0V 38 4V WB CONTROL 39 4V 37 6 GC LPF 7 YH1 YH0 2H APCN – Y0 Y1 8 ABS 0V 9 CLP4 V-APCN CS-Y 11 CLP2 10 GC 0V 12 36 0.1V 0.1V 0.1V LPF LPF 0V CS CS VAP MAX C0 CLP -CB B LPF (CLP2) CR G MATRIX WB AMP & Y C1 MPX R LPF 43 0.1 V 0.1 13 CLP C G 34 CLP (CLP2) 35 0V 14 15 33 0.1 0V 16 0.1 YL MTX 0V CLP C MPX2 Y2 Y1 KNEE V-APCN YH OUT 2 DLC1 IN CLP C YH B MTX Y0 KNEE TP C1 GAIN DLYH IN ID CLP V-APCN (CLP4) DLYH GAIN CLP (CLP4) DC 3.65VCLP C DLYH B GAIN CLP4 CLP C MPX1 YH OUT 1 B CONT CLP2 0V VAP OUT KNEE R CONT G ch SLICE SLICE CLP GC 0.1 CLP C VAP R GAIN VAP GAIN CLP C B CS-Y CLP (CLP4) R MTX DLYH OUT R-r CLF C R R-WB G-WB B-WB SLICE r R-r G-r B-r B-Y R-Y MTX R-Y B-Y Hue & GC VAP SLICE – 23 – CLP C CS C LEVEL B-r G-r CS IN Test Circuit (Typ. setting) 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 R-Y GAIN B-Y GAIN B-Y OUT R-Y OUT B-Y HUE R-Y HUE CS GAIN CS OUT YL OUT GND 1 C-r CONT WB R WB G WB B WB DC C SLICE V V 0V 0V 0V 0V 0V 0V 5V 0V CXA1391Q/R CXA1391Q/R Standard Control Characteristics (Vcc = 5V, Ta = 25°C) C1 GAIN control characteristics R-MTX coefficient 3 0.3 GAIN converted into unit GAIN 2 0.2 Preset 1 2 3 4 0.1 5 0 2 3 C1 GAIN voltage (V) 4 5 R-MTX voltage (V) B-MTX coefficient R GAIN control characteristics 7 0.4 6 0.3 GAIN 5 Preset 4 0.2 3 0.1 0 2 3 4 2 5 0 B-MTX voltage (V) 2 3 4 5 R GAIN voltage (V) B GAIN control characteristics R/B CONT control characteristics 10 3 8 1/GAIN GAIN 2 6 1 4 2 2 3 4 2 5 3 4 R/B CONT voltage (V) B GAIN voltage (V) – 24 – 5 CXA1391Q/R C-SLICE control characteristics C-SLICE control characteristics 150 1.5 BLACK DC difference between sliced signal and during sliced OFF (mV) GAIN 100 1 50 0.5 0 2 3 4 2 5 3 4 5 C-LEVEL voltage (V) C-SLICE power supply (V) R–Y/B–Y GAIN control characteristics R–Y/B–Y HUE control characteristics 3 40° 30° 20° 2 GAIN 10° 0° –10° 1 –20° –30° 2 3 4 2 5 3 4 5 R–Y/B–Y GAIN voltage (V) R–Y/B–Y HUE voltage (V) Y1/Y2 GAIN control characteristics CS GAIN control characteristics 3 400 CS output during S1 = S2 = 125mV input (3H_Mode) 300 (mV) GAIN 2 200 1 100 2 3 4 5 Y1/Y2 GAIN voltage (V) 2 3 4 CS GAIN voltage (V) – 25 – 5 CXA1391Q/R DLYH GAIN control characteristics VAP control characteristics 400 15 VAP_OUT output during S1 = S2 = 250mV input (3H_Mode) 300 GAIN (dB) VAP OUT (mV) 10 5 200 100 0 0 2 3 4 DLYH GAIN voltage (V) 5 VAP SLICE control characteristics (mV) 300 200 100 VAP GAIN = 0V Diminution of VAP OUT output level 2 3 4 VAP SLICE voltage (V) 5 – 26 – 2 3 4 VAP GAIN voltage (V) 5 CXA1391Q/R Standard Design Data Chroma γ curve (standardize) 1.2 γ output (standardize) 1.0 0.8 0.6 1 2 0.4 3 Standardize at typical input (400mV) 1: C – γ CONT=1.6V (Max.) 2: C – γ CONT=0V (Typ.) 1: C – γ CONT=5V (Min.) 0.2 0.2 0.4 0.6 0.8 1.0 1.2 1.4 γ input (standardize) 1.6 1.8 2.0 2.2 YH γ curve (standardize) (mV) 1.4 γ output (standardize) 1.2 1.0 0.8 0.6 1 2 0.4 3 Standardize at typical input (220mV) 1: Y – γ CONT=1.6V (Max.) 2: Y – γ CONT=0V (Typ.) 1: Y – γ CONT=5V (Min.) 0.2 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 γ input (standardize) 1.8 2.0 2.2 V-APCN Knee (standardize) (mV) Knee output (standardize) 1.0 0.8 0.6 0.4 0.2 Standardize at typical input (S1 = S2 = 500mV) 0.2 0.4 0.6 0.8 1.0 1.2 Knee input (standardize) – 27 – 1.4 1.6 1.8 2.0 CXA1391Q/R Pre-Filter Adjust characteristics DL Y0 out S1, S2 → DL C0 out <Cut Off> (fc: –3dB) 250 2.5 fc (MHz) 3.0 200 2.0 1.5 150 100 10k 1.0 15k 20k 25k 30k 10k REXT [LPF ADJ1 (59PIN) ] (Ω) 15k 20k 25k 30k REXT [LPF ADJ1 (59PIN) ] (Ω) Chroma Adjust characteristics <Group Delay> S1, S2 → R–Y out B–Y out 800 τD (nsec) 600 400 200 10k 20k 30k 40k 50k 60k 70k 80k 60k 70k 80k REXT [LPF ADJ2 (60PIN) ] (Ω) <Cut Off> (fc: –3dB) 1.5 fc (MHz) τD (nsec) <Group Delay> 300 1.0 0.5 10k 20k 30k 40k 50k REXT [LPF ADJ2 (60PIN) ] (Ω) – 28 – CXA1391Q/R CS-VAP Adjust characteristics (S1, S2 → CS OUT) <Group Delay> 800 τD (nsec) 600 400 10k 20k 30k 40k 50k 60k 70k 80k 60k 70k 80k REXT [LPF ADJ2 (60 PIN) ] (Ω) <Cut Off> (fc: –3dB) fc (MHz) 1.5 1.0 0.5 10k 20k 30k 40k 50k REXT [LPF ADJ2 (60 PIN) ] (Ω) – 29 – CXA1391Q/R CS-Y LPF Adjust characteristics (CS IN → CS OUT) <Group Delay> 600 τD (nsec) 400 200 10k 20k 30k 40k 50k 60k 70k REXT [LPF ADJ2 (60 PIN) ] (Ω) <Cut Off> (fc: –3dB) 2.0 fc (MHz) 1.5 1.0 0.5 10k 20k 30k 40k 50k 60k REXT [LPF ADJ2 (60 PIN) ] (Ω) VAP LPF Adjust characteristics – 30 – 70k 80k 80k CXA1391Q/R VAP LPF Adjust characteristics (S1, S2 → VAP OUT) <Group Delay> 600 τD (nsec) 400 200 10k 20k 30k 40k 50k 60k 70k 80k REXT [LPF ADJ3 (61 PIN) ] (Ω) <Cut Off> (fc: –3dB) 1.5 fc (MHz) 1.0 0.5 10k 20k 30k 40k 50k REXT [LPF ADJ3 (61 PIN) ] (Ω) – 31 – 60k 70k 80k 5V GND 19 42 XSP1 2 1 3 XSHP XSHD CLP4 XSP2 XSP1 XSH1 XSH2 48 XSH2 TG CLP1 8 9 BFG CLP2 ID PBLK 7 6 5 LPF DL 4 10 11 HD.VD CL 12 CLP1 13 PBLK 14 WND 15 47 F1-CLP VG-OUT 16 46 F2-CLP IRIS-OUT 17 45 F3-CLP IRIS-CLP 18 43 GND 44 FSHI CS-AGCSL 5V SG BLK BF SYNC LALT WND CXA1391 Q/R 4fSC 64 LPF IHDL 2 3 YH-IN 1 CONT 63 YGAM- 4 8 YR YG YB CONTROLLER FOR TITLER CR CG CB DL 7 6 5 9 10 11 12 LPF 14 13 15 16 17 18 19 13 14 10 11 12 R-Y 20 OUT B-Y HUE 21 R-Y HUE 22 VCS-GAIN 23 61 LPF-ADJ3 62 V CC YL-OUT 25 CS-OUT 24 GND 26 LPF-ADJ1 DLYH-GAIN 60 LPF-ADJ2 59 58 GND CGAM-CONT 27 57 Y2-GAIN DET-CLP 20 WB-R 28 41 XSP2 WB-G 29 56 DLY2-IN IRIS-GC 22 IRIS-LEVEL 21 55 DLY1-IN C- 32 SLICE WB-DC 31 33 34 36 35 WB-B 30 39 V CC 1 CXA1390 Q/R 38 37 39 40 41 43 42 44 54 Y1-GAIN 5V DETECTOR DET- 24 OUT V CC 2 23 40 XSP3 38 DATA-IN YHCLP DLYH-IN 37 PG-IN OUT 53 DLY1-OUT 52 DLY0- 45 46 47 48 49 50 B-CLP CS-IN 51 YOCLP S1-IN DLYH-OUT G-CLP R-Y GAIN 25 26 27 28 S2-IN DLYH-CLP 29 DLC1-IN YH-OUT1 CLP4 XSH1 C1-GAIN YH-OUT2 XSHD GY-OUT R-MIX DLCO-OUT TP XSHP DC-OUT MPX1-CLP CLP4 31 30 CLP2 AGC-SEL F2-OUT MPX2-CLP VAP-OUT AGC-MAX F3-OUT ID B-MTX VAP-GAIN AGC-CONT CS-CLP B-GAIN VAP-CLP OPIN-N CS-CCD-SL B-CONT VAP-SLICE OP-OUT F1-OUT OPIN-P CS-CCD-GC AGC-OUT CS-OUT AGC-CLP DETLEVEL CS-AGC-GC R-CONT R-GAIN CS-CLP R-CLP B-Y GAIN 32 9 15 16 8 7 6 5 CXA1393AN/AM 17 18 19 4 3 2 1 CLP 48 B-Y 20 21 22 23 24 LPF 2 1 47 B-Y IN 46 B-LEVEL 45 CLP2 44 CLP4 43 AGND 42 YL-YH IN 41 YL-YH CLP 40 YH-IN 39 YH-CLP 38 NOISE-SLICE 37 YTBLK 5V 3 4 7 6 5 CXA1392 Q/R 5V 8 9 WC 24 VIDEO-OUT 21 SETUP- 23 CLP V-OUT 22 25 26 10 11 12 MODE 13 CS-AGC 14 CS-Y 15 C-OUT 16 AV CC 17 C-IN 18 DGND 19 CHROMA-OUT 20 27 28 29 31 30 32 33 34 35 36 R-Y IN 33 R-Y CLP 34 4FSC C LEVEL B-Y OUT DL DV CC 35 CLP4 LALT 36 W/B CONTROLLER DR-OUT DY-OUT NC IHDL DB-IN CT-BLK DB-OUT DR-IN YT-BLK SHPLEVEL DLE BFG IHDL YR-IN GND DY-CLP DLD SHP-CLP1 Y-LEVEL NC IHDL YB-IN CG-IN SHP-CLP2 BF CCD YT-GC CB-IN DY-IN SHP-OUT CT-GC CR-IN YG-IN FADER-MODE HYSCONT TH-CONT COMP-IN COMPOUT – 32 – V CC SETUP FADER-SIG FSC-OUT SYNC SYNC-LEVEL CBLK CTBLK CXA Series System Diagram BPF 5V C Vid Y CXA1391Q/R CXA1391Q/R Package Outline Unit: mm CXA1391Q 64PIN QFP(PLASTIC) 23.9 ± 0.4 + 0.4 20.0 – 0.1 + 0.1 0.15 – 0.05 51 0.15 64 20 1 16.3 32 + 0.4 14.0 – 0.1 52 17.9 ± 0.4 33 + 0.2 0.1 – 0.05 0.8 ± 0.2 19 + 0.35 2.75 – 0.15 + 0.15 0.4 – 0.1 1.0 ± 0.12 M PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE QFP–64P–L01 LEAD TREATMENT EIAJ CODE ∗ QFP064–P–1420 LEAD MATERIAL SOLDER/PALLADIUM PLATING COPPER /42 ALLOY PACKAGE WEIGHT 1.5g JEDEC CODE CXA1391R 64PIN LQFP (PLASTIC) 12.0 ± 0.2 ∗ 10.0 ± 0.1 48 33 32 64 17 (0.22) 0.5 ± 0.2 (11.0) 49 A 1 0.5 ± 0.08 + 0.08 0.18 – 0.03 16 + 0.2 1.5 – 0.1 + 0.05 0.127 – 0.02 0.1 0° to 10° 0.5 ± 0.2 0.1 ± 0.1 NOTE: Dimension “∗” does not include mold protrusion. DETAIL A PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY / PHENOL RESIN SONY CODE LQFP-64P-L01 LEAD TREATMENT SOLDER PLATING EIAJ CODE ∗QFP064-P-1010-A LEAD MATERIAL 42 ALLOY PACKAGE WEIGHT 0.3g JEDEC CODE – 33 –