CXA1854AR Decoder/Driver/Timing Generator for Color LCD Panels For the availability of this product, please contact the sales office. Description The CXA1854AR is an IC designed exclusively to drive color LCD panels LCX009AK/AKB/LCX005BK/ BKB. This IC greatly reduces the number of circuits and parts required to drive LCD panels by incorporating RGB decoder functions for video signals, driver functions, and a timing generator for driving panels onto a single chip. Features • Color LCD panels LCX009AK/AKB/LCX005BK/BKB driver • Both NTSC/PAL compatible • Supports composite inputs, Y/C inputs and Y/color difference inputs • Band-pass filter, trap and delay line • Sharpness function • 2-point γ compensation circuits • R, B output delay time adjustment circuit (supports both right and left inversion) • Polarity reversed circuit / line inverted mode • Supports external RGB input • Supports line inversion • Supports AC drive for LCD panel during no signal Applications • Color LCD viewfinders • Liquid crystal projectors • Industrial monitors Structure Bipolar CMOS IC 64 pin LQFP (Plastic) Absolute Maximum Ratings (Ta = 25°C) • Supply voltage VCC1 – GND 6 • Supply voltage VCC2 – GND 14 • Supply voltage VDD – VSS 6 • Analog input pin voltage VINA –0.3 to VCC1 V V V V • Digital input pin voltage VIND –0.3 to VDD + 0.3 V • Operating temperature range Topr –15 to +70 °C • Storage temperature range Tstg –40 to +150 °C • Allowable power dissipation PD (Ta ≤ 70°C) 400 mW Operating conditions • Supply voltage VCC1 – GND • Supply voltage VCC2 – GND • Supply voltage LCX009 mode VDD – VSS LCX005 mode VDD – VSS 4.6 to 5.3 11.0 to 13.0 V V 4.5 to 5.5 2.7 to 5.5 V V 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– E95X01A73 CXA1854AR 40 39 38 37 36 35 34 VDD 41 RGT R OUT 42 TEST6 FB R 43 TEST7 G OUT 44 TEST8 FB G 45 +12V GND2 B OUT 46 FB B 47 +5V VCC2 BLKLIM 48 VCC1 REG Block Diagram 33 GND2 +5V REG. buf 1 VCC2 2 REGV buf buf V-SYNC SEP B-YIN 49 R-YIN 50 CLAMP INT/EXT DEMOD PAL SW POL SW HUE/RST 52 30 HD V-CTL COUNTER V-POS COUNTER EQP V-CTL DECODER H-CTL DECODER BGP CLP BLK AUX-V COUNTER DECODER RESET XCLR LPF COLOR 53 XVXO 54 31 VD V-POS RESET GEN PAL ID COUT 51 32 TEST5 APC VXO 28 HCK2 SUB BRIGHT MATRIX PS HUE H-POS COUNTER PLL COUNTER RGB GAIN CONTRAST ACC DET DECODER & H-TIMING PULSE GEN R-BRT 55 B-BRT 56 29 HCK1 27 HST1 26 TEST4 GAMMA COLOR CONT RGB KILLER BRIGHT RGB-GAIN 57 S/H FILT CAL GAMMA2 58 25 CLR FIELD & LINE CTL FRP SH1 SH2 SH3 SH4 SUB CONTRAST PAL PULSE ELIM & MODE SEL 23 VCK1 EXT SW GAMMA1 59 22 VCK2 PIC CONT BPF PULSE GEN V-TIMING HALF-H KILLER BRIGHT 60 AGG DET 24 EN 21 VST1 AGC CONTRAST 61 MASTER SUB CK CK H-SYNC DET H-SKEW DET DL 2 ACC AMP 20 TEST3 TEST S/R CIN 62 19 SLCK 1/7 SYNC SEP H. FILTER MODE SELECT CLAMP 18 TEST0 SPAL/DPAL/NTSC DL 1 PLL PHASE COMP 17 TEST1 VSS GND1 MODE1 11 12 13 14 15 16 TEST2 PICT 10 CKO AGCTC 9 CKI AGCADJ 8 VSS 7 RPD 6 EXT-B 5 EXT-G 4 EXT-R 3 MODE2 2 YIN GND1 1 SYNCIN B-GAIN 64 TRAP YC/YRB/COMP R-GAIN 63 –2– CXA1854AR Pin Description (H: Pull up, M: Intermediate setting, L: Pull down) Input pin for open status Pin No. Symbol I/O 1 SYNC IN I Sync input 2 Y IN I Y signal input 3 AGCADJ I AGC level adjustment 4 AGCTC O AGC time constant 5 PICT I Y signal frequency characteristics adjustment 6 GND1 7 MODE1 I Switches between NTSC (H), DPAL∗ (M) and SPAL∗ (L) M 8 MODE2 I Switches between composite (H), Y/color difference (M) and YC input (L) M 9 EXT-R I External digital input R (input conditions noted separately) 10 EXT-G I External digital input G (input conditions noted separately) 11 EXT-B I External digital input B (input conditions noted separately) 12 RPD O Phase comparator output 13 VSS 14 CKI I Oscillation cell input 15 CKO O Oscillation cell output 16 TEST2 I Test L 17 TEST1 I Test L 18 TEST0 I Test L 19 SLCK I Switches between LCX005BK (H) and LCX009AK (L) L 20 TEST3 O Leave this pin open. 21 VST1 O V start pulse 1 output 22 VCK2 O V clock pulse 2 output 23 VCK1 O V clock pulse 1 output 24 EN O EN pulse output 25 CLR O CLR pulse output 26 TEST4 O Leave this pin open. 27 HST1 O H start pulse 1 output 28 HCK2 O H clock pulse 2 output 29 HCK1 O H clock pulse 1 output 30 HD O HD pulse output 31 VD O VD pulse output 32 TEST5 I Leave this pin open. Description Analog 5V GND Digital GND L ∗ DPAL supports demodulation methods which use an external delay line during demodulation; SPAL supports methods which internally process chroma demodulation. –3– CXA1854AR Pin No. Symbol I/O Description Input pin for open status 33 VDD 34 RGT I Switches between Normal scan (H) and Reverse scan (L) H 35 TEST6 I Leave this pin open. H 36 TEST7 I Leave this pin open. H 37 TEST8 I Leave this pin open. H 38 GND2 39 R OUT O R output 40 FB R I R signal DC voltage feedback input 41 G OUT O G output 42 FB G I G signal DC voltage feedback input 43 B OUT O B output 44 FB B I B signal DC voltage feedback input 45 VCC2 46 BLKLIM 47 VCC1 48 REG O Constant voltage capacitor connection 49 B-YIN I B-Y demodulator input (or B-Y/color difference signal input) 50 R-YIN I R-Y demodulator input (or R-Y/color difference signal input) 51 COUT O Chroma signal output (for PAL 1HDL) 52 HUE/RST I Hue adjustment/system reset 53 COLOR I Color adjustment 54 XVXO I VXO crystal oscillator connection 55 R-BRT I R brightness adjustment 56 B-BRT I B brightness adjustment 57 RGB-GAIN I RGB gain adjustment 58 GAMMA2 I γ 2 adjustment 59 GAMMA1 I γ 1 adjustment 60 BRIGHT I Brightness adjustment 61 CONTRAST I Contrast adjustment 62 CIN I Chroma signal input 63 R-GAIN I R gain adjustment 64 B-GAIN I B gain adjustment Digital 5V power supply Analog 12V GND Analog 12V power supply I Black peak limiter level adjustment Analog 5V power supply –4– CXA1854AR Analog Block Pin Description Pin No. Symbol Pin voltage Equivalent circuit Description VCC1 Sync input. Normally inputs the Y signal. The standard signal input level is 0.5Vp-p (up to 100% white level from the sync chip). 200 1 SYNC IN 1 50p GND1 VCC1 2 YIN 3.2V Y signal input. The standard signal input level is 0.5Vp-p (up to 100% white level from the sync chip). Input at low impedance (75Ω or less). 2 1k GND1 50µA VCC1 40k 3 AGCADJ VCC1/2 AGC gain adjustment pin. 3 2k 2.5V GND1 VCC1 50µA 1k 4 AGCTC AGC detection filter connection. 4 20k GND1 VCC1 1k 47k 5 PICT VCC1/2 5 50µA GND1 –5– 2.5V Adjusts frequency characteristics of luminance signal. Increasing the voltage emphasizes contours. CXA1854AR Pin No. 9 Symbol Pin voltage EXT-R Equivalent circuit External digital signal input. There are two threshold values: Vth1 (approximately 1.2V) and Vth2 (approximately 2.2V). When one of the EXTRGB signals exceeds Vth1, all of the RGB outputs go to black level (black side clip level); when an input exceeds Vth2, only the corresponding output goes to white level (white side limiter level). VCC1 9 10 Description 200 10 EXT-G 11 GND1 11 EXT-B 39 R OUT 41 G OUT VCC2 VCC2 2 39 50 50 43 43 B OUT 40 FB R GND2 VCC2 40 42 RGB primary color signal output. 41 FB G Smoothing capacitor connection for the feedback circuit of RGB output DC level control. Use a low-leakage capacitor because of high impedance. 2k 42 44 44 GND2 FB B VCC1 50k 2k 46 BLKLIM Sets the RGB output amplitude (black-black) clip level. 46 GND1 VCC1 48 REG 4.2V 48 60k 40k GND1 –6– 40k Smoothing capacitor connection for the internally generated constant voltage source circuit. Connect a capacitor of 1µF or more. CXA1854AR Pin No. Symbol Pin voltage Equivalent circuit VCC1 49 B-YIN 49 200 50µA 50 50 2k R-YIN GND1 Description Color difference demodulation circuit inputs during DPAL mode. Leave this pin open for NTSC. Color difference signal is input respectively when Y/color difference input. (Standard input is 0.15Vp-p.) At this time, the bias is 3.5V. VCC1 51 COUT 2.3V Color adjusted chroma signal is output. When taking the chroma signal, connect to GND with a load resistor (approximately 5kΩ). 51 50µA GND1 VCC1 6k 100k 52 HUE/RST 3.2V 52 12k 5p 3.2V GND1 50µA Color phase adjustment pin during NTSC. Use for detective axis adjustment of the R-Y/B-Y axes during SPAL. Also doubles as the reset pin. The system is reset when this pin is connected to GND. VCC1 100k 53 COLOR 3.2V 53 Color adjustment. 25k 5p 3.2V GND1 50µA VCC1 2k 54 XVXO 3.5V 500 Crystal oscillator connection. 54 GND1 –7– CXA1854AR Pin No. 55 Symbol Pin voltage Equivalent circuit VCC1 RBRT VCC1/2 Fine adjustment for R and B signal brightness. 47k 55 3k 56 56 Description 2.5V BBRT GND1 VCC1 57 RGB-GAIN VCC1/2 47k Adjusts RGB output amplitude gain. 57 3k 2.5V GND1 VCC1 58 GAMMA2 VCC1/2 47k Adjusts voltage gain change point γ 2. 58 3k 2.5V GND1 VCC1 59 GAMMA1 VCC1/2 Adjusts voltage gain change point γ 1. 47k 59 3k 2.5V GND1 VCC1 60 BRIGHT VCC1/2 RGB output brightness adjustment. It does not influence the γ compensation curve. 47k 60 4k 2.5V GND1 –8– CXA1854AR Pin No. Symbol Pin voltage Equivalent circuit Description VCC1 61 CONTRAST VCC1/2 47k Contrast adjustment. 61 4k 2.5V GND1 VCC1 20k 62 500 CIN 15p 62 100µA 50µA Video signal input when using composite input. Chroma signal input when using Y/C input. Leave this pin open when Y/color difference input. GND1 VCC1 63 R-GAIN VCC1/2 47k 64 64 B-GAIN Fine adjustment for R and B signal contrast. 63 3k 2.5V GND1 –9– CXA1854AR Setting Conditions for Measuring Electrical Characteristics When measuring the DC characteristics, the TG block must be horizontally synchronized by performing Setting 2. Setting 2 must also be performed when measuring the AC characteristics. When measuring items with bands greater than 2MHz such as the Y frequency response or sharpness characteristics, settings 1 and 3 must also be performed and measurements made with the sample-and-hold circuit set to through status. Setting 1. System reset After turning on the power, set SW52 to ON and start up V52 from GND in order to activate the timing controller system reset. (See Fig. 1-1.) Setting 2. Horizontal AFC adjustment Input SIG6 (VL = 0mV) to (A) and adjust VR12 so that WL and WH of the TP12 output waveform are the same. (See Fig. 1-2.) Setting 3. S/H off Input the signals shown in Fig. 1-3 to Pins 16, 17, 18 and 19 in order to set the sample-and-hold circuit to through status. SIG6 VDD (VCC1) WS TP12 V52 (RESET) WL TR TR > 10µs WL = WH WH Fig. 1-1. System reset Fig. 1-2. Horizontal AFC adjustment VDD Pin 19 GND VDD Pin 18 GND VDD Pin 17 GND VDD Pin 16 GND Fig. 1-3. S/H off input pattern – 10 – CXA1854AR Electrical Characteristics – DC Characteristics (1) Unless otherwise specified, Setting 2 and the following setting conditions are required. VCC1 = 5.0V, VCC2 = 12.0V, GND1 = GND2 = GND, VDD = 5.0V, VSS = GND V3, V5, V46, V55, V56, V57, V58, V59, V60, V61, V63, V64 = 2.5V V52, V53 = 3.2V SW3, SW5, SW46, SW52, SW53, SW55, SW56, SW57, SW58, SW59, SW60, SW61, SW63, SW64 = ON Set SW7, SW8, SW9, SW10, SW11 and SW19 are setting A. Item Symbol Conditions Min. Typ. Max. Unit Power supply characteristics ICC11 Current consumption VCC1 Current consumption VCC2 Input SIG5 to (A) and SIG3 (0dB) to (B). Measure the ICC1 current value. COMP input mode 35 44 53 mA 34 42.5 51 mA ICC13 Input SIG5 to (A) and SIG5 to (F) and (G). Set SW8 to B. Measure the ICC1 current value. Y/color difference input mode 32 40 48 mA ICC2 Input SIG5 to (A) and SIG3 (0dB) to (B). Measure the ICC2 current value. 3 5.5 8 mA 7 10.5 14 mA 5 8 10.5 mA 2 3 4.5 mA ICC12 Input SIG5 to (A) and SIG3 (0dB) to (B). Set SW8 to C. Measure the ICC1 current value. Y/C input mode IDD1 Input SIG5 to (A) and SIG3 (0dB) to (B). Measure the IDD current value. LCX009 mode Current consumption VDD IDD2 Input SIG5 to (A) and SIG3 (0dB) to (B). Set SW19 to B. Measure the IDD current value. LCX005 mode IDD3 Input SIG5 to (A) and SIG3 (0dB) to (B). Set SW19 to B. Measure the IDD current value. VDD = 3.0V LCX005 mode – 11 – CXA1854AR Item Symbol Conditions Min. Typ. Max. Unit Digital block I/O characteristics Input current 1 Input current 2 High level output voltage Output pins except CKO and RPD Low level output voltage Output pins except CKO and RPD II1 II2 VOH1 VOL11 Input pin with pull-up resistor∗1 VIN = VSS Input pin with pull-down resistor∗2 VIN = VDD IOH = –2mA∗3 IOL = 2mA∗3 IOL = 500µA∗3 High level output voltage CKO pin VOH2 IOH = –3mA Low level output voltage CKO pin VOL2 IOL = 3mA High level output voltage RPD pin VOH3 IOH = –1mA Low level output voltage RPD pin VOL3 IOL = 1.5mA Output off leak current RPD pin IOFF High impedance status VOUT = VSS or VOUT = VDD CMOS input cell Low level input voltage VIL SLCK and RGT pins CMOS input cell Ternary input switching threshold voltage (MODE1/MODE2) –240 –100 –40 VDD = 3.0V –144 –60 –24 VDD = 5.0V 40 100 240 VDD = 3.0V 24 60 144 VDD = 5.0V VDD –0.8 VDD = 3.0V VDD –1.0 µA µA V VDD = 5.0V 0.5 VDD = 3.0V 0.6 V VOL12 High level input voltage VIH SLCK and RGT pins VDD = 5.0V 0.3 0.5VDD V 0.5VDD VDD –1.2 –40 V V V 1.0 V 40 µA 0.7VDD V 0.3VDD V MDTHL MODE M → L level threshold SW7, SW8 = B 0.2VDD 0.3VDD 0.4VDD V MDTHH MODE M → H level threshold SW7, SW8 = B 0.6VDD 0.7VDD 0.8VDD V ∗1 Input pins with pull-up resistors: RGT, TEST6, TEST7, TEST8 ∗2 Input pins with pull-down resistors: SLCK, TEST0, TEST1, TEST2, TEST5 ∗3 Output pins except CKO and RPD: HD, VD, VST1, VCK1, VCK2, CLR, EN, HST1, HCK1, HCK2, TEST3, TEST4 – 12 – CXA1854AR Electrical Characteristics – AC Characteristics (1) Unless otherwise specified, Setting 2 and the following setting conditions are required. Vcc1 = 5.0V, Vcc2 = 12.0V, GND1 = GND2 = GND, (VDD = 5.0V, VSS = GND) V5, V55, V56, V57, V60, V61, V63, V64 = 2.5V V3, V58 = 0V V46, V59 = 5.0V V52, V53 = 3.2V SW3, SW5, SW46, SW52, SW53, SW55, SW56, SW57, SW58, SW59, SW60, SW61, SW63, SW64 = ON Set SW7, SW8, SW9, SW10, SW11 and SW19 are setting A. Unless otherwise specified, measure the non-reversed outputs for TP39, TP41 and TP43. Item Symbol Conditions Min. Typ. Max. Unit Y signal block Video maximum gain GV FCYYC Y signal frequency Characteristics FCYCMN FCYCMP Sharpness characteristics MAX Sharpness characteristics MIN Input SIG5 to (A) and measure the ratio between the output amplitude (white-black) and input amplitude at TP41. Assume the output amplitude at TP41 when SIG2 (0dB, no burst, 100kHz) is input to (A) as 0dB. Vary the frequency of the input signal to obtain the frequency with an output amplitude of –3dB. Settings 1 and 3 are required. 13.5 16.5 19.5 dB Y/C input, SW8 = C 5.0 MHz Composite input (NTSC) 2.5 MHz Composite input (PAL), SW7 = C 3.0 MHz Assume the output amplitude at TP41 when SIG8 (100kHz) is input to (A) as 0dB. Obtain the output amplitude ratio for the input SIG8 (2.0MHz). GSHPMXC V5 = 4.0V Settings 1 and 3 are required. Composite input 7 12 dB Assume the output amplitude at TP41 when SIG8 (100kHz) is input to (A) as 0dB. Obtain the output amplitude ratio for the input SIG8 (2.5MHz). GSHPMXY V5 = 4.0V, SW8 = C Settings 1 and 3 are required. Y/C input 10 16 dB Assume the output amplitude at TP41 when SIG8 (100kHz) is input to (A) as 0dB. Obtain the output amplitude ratio for the input SIG8 (2.0MHz). GSHPMNC V5 = 0V Settings 1 and 3 are required. Composite input –1 2 dB Assume the output amplitude at TP41 when SIG8 (100kHz) is input to (A) as 0dB. Obtain the output amplitude ratio for the input SIG8 (2.5MHz). GSHPMNY V5 = 0V, SW8 = C Settings 1 and 3 are required. Y/C input 1 4 dB – 13 – CXA1854AR Item Symbol Conditions Min. Typ. Max. Unit –4 –2.5 –1 dB GAPL10 Adjust the output amplitude at TP41 when SIG1 (APL: 50%) is input to (A) to 1.5Vp-p with V61. Assume this as 0dB, and obtain the TP41 output amplitude ratio when input SIG1 (APL: 10%) is input. V3 = 2.5V, V60 = 3.5V 1 2.5 4 dB GCNTMX Input SIG5 to (A) and obtain the ratio between the TP41 output amplitude when V61 = 2.5V and the TP41 output amplitude when V61 = 5V. 2 5 Contrast GCNTMN characteristics MIN Input SIG5 to (A) and obtain the ratio between the TP41 output amplitude when V61 = 2.5V and the TP41 output amplitude when V61 = 1V. Carrier leak (residual carrier) Input SIG3 (0dB) to (A) and (B). Adjust the chroma signal phase so that the amplitude (black – white) at TP43 is at a maximum. Using a spectrum analyzer, measure the input and the 3.58MHz or 4.43MHz component, and obtain CRRLK = 150mV × 10 ∆d/20 using their difference ∆d. SW7 = A for NTSC measurement, and C for PAL measurement. AGC characteristics GAPL90 Adjust the output amplitude at TP41 when SIG1 (APL: 50%) is input to (A) to 1.5Vp-p with V61. Assume this as 0 dB, and obtain the TP41 output amplitude ratio when input SIG1 (APL: 90%) is input. V3 = 2.5V, V60 = 3.5V APL = 90% APL = 10% Contrast characteristics MAX CRRLK TDYYC Y signal I/O delay time TDYCMN TDYCMP Input SIG6 (VL = 150mV) to (A). Measure the delay time from the rising edge of the input signal to the rising edge of the non-reversed output. V5 = 2V – 14 – –10 dB –6 dB 30 mVpp Y/C input SW8 = C 250 400 550 ns Composite input (NTSC) 630 780 930 ns Composite input (PAL), SW7 = C 610 760 910 ns CXA1854AR Electrical Characteristics – AC Characteristics (2) Item Symbol Conditions Min. Typ. Max. Unit Chroma signal block ACC1N ACC amplitude characteristics 1 ACC1P ACC2N ACC amplitude characteristics 2 ACC2P FAPCNU FAPCND APC pull-in range FAPCPU FAPCPD Color adjustment characteristics MAX GCOLMX Color adjustment characteristics MIN GCOLMN HUE adjustment range MAX TNTMX HUE adjustment range MIN TNTMN ACKN Killer operation input level ACKP Input SIG6 (VL = 0mV) to (A) and SIG3 (0dB/+6dB/–20dB, 3.58MHz burst/chroma phase = 180°, or 4.43MHz burst/chroma phase = ±135°) to (B). Measure the output amplitude at TP51, assuming the output corresponding to 0dB, +6dB and –20dB as V0, V1 and V2, respectively. ACC1 = 20log (V1/V0) ACC2 = 20log (V2/V0) Input SIG6 (VL = 0mV) to (A) and SIG3 (0dB, 3.58MHz burst/chroma phase = 180°, or 4.43MHz burst/chroma phase = ±135°) to (B), and measure the output amplitude at TP43. Changing the SIG3 burst frequency, mesure the frequency fl which TP43 output changes (the killer mode is canceled). (The crystal parallel floating capacitance is 2pF or less) NTSC: FAPCN = fl – 3579545Hz PAL: FAPCP = fl – 4433619Hz NTSC –3 0 +3 dB PAL SW7 = C –3 0 +3 dB NTSC –3 0 +3 dB PAL SW7 = C –3 0 +3 dB NTSC upper limit CL = 20pF 350 NTSC lower limit CL = 20pF PAL upper limit SW7 = C CL = 16pF PAL lower limit SW7 = C CL = 16pF Input SIG6 (VL = 0mV) to (A) and SIG3 (0dB, 3.58MHz burst/chroma phase = 180°) to (B). Assume the chroma amplitude when V53 = 3.2V, 5V and 2.1V as V0, V1 and V2, respectively, and calculate GCOLMX = 20log (V1/V0) and GCOLMN = 20log (V2/V0). Input SIG6 (VL = 0mV) to (A) and SIG3 (0 dB) to (B). Assume the phase at which the output amplitude at TP43 reaches a minimum when V53 = 3.2V, 5V and 1.6V as θ0, θ1 and θ2, respectively, and calculate TNTMX = θ1 – θ0 and TNTMN = θ2 – θ0. Input SIG6 (VL = 0mV) to (A) and SIG3 (level variable, 3.58MHz burst/chroma phase = 180°, or 4.43MHz burst/chroma phase = ±135°) to (B), and measure the output amplitude at TP43. Gradually reduce the SIG3 amplitude and measure the level at which the killer operation is activated. – 15 – Hz –350 350 Hz –350 3 Hz 5.5 –20 Hz dB –15 30 dB deg –30 deg NTSC –36 –30 dB PAL SW7 = C –33 –27 dB CXA1854AR Item Demodulation output amplitude ratio (NTSC) Demodulation output phase difference (NTSC) Demodulation output amplitude ratio (PAL) Demodulation output phase difference (PAL) Symbol VRBN VGBN θRBN θGBN VRBP VGBP θRBP θGBP Conditions Input SIG6 (VL = 0mV) to (A) and SIG3 (0dB, 3.58MHz) to (B) and change the chroma phase. Assume the maximum amplitude at TP39 as VR, the maximum amplitude at TP41 as VG, and the maximum amplitude at TP43 as VB, and calculate VRBN = VR/VB and VGBN = VG/VB. V60 = 3.5V Input SIG6 (VL = 0mV) to (A) and SIG3 (0dB, 3.58MHz) to (B) and change the chroma phase. Assume the phase at which the maximum amplitude at TP39, TP41 and TP43 as θR, θG and θB, respectively, and calculate θRBN = θR – θB and θGBN = θG – θB. V60 = 3.5V Input SIG6 (VL = 0mV) to (A) and SIG3 (0 dB, 4.43MHz) to (B) and change the chroma phase. Assume the maximum amplitude at TP39 as VR, the maximum amplitude at TP41 as VG, and the maximum amplitude at TP43 as VB, and calculate VRBP = VR/VB and VGBP = VG/VB. V60 = 3.5V, SW7 = C Input SIG6 (VL = 0mV) to (A) and SIG3 (0 dB, 4.43MHz) to (B) and change the chroma phase. Assume the phase at which the maximum amplitude at TP39, TP41 and TP43 as θR, θG and θB, respectively, and calculate θRBP = θR – θB and θGBP = θG – θB. V60 = 3.5 V, SW7 = C – 16 – Min. Typ. Max. Unit 0.53 0.63 0.73 0.25 0.32 0.39 99 109 119 deg 230 242 254 deg 0.65 0.75 0.85 0.33 0.40 0.47 80 90 100 deg 232 244 256 deg CXA1854AR Electrical Characteristics – AC Characteristics (3) Item Symbol Conditions Min. Typ. Max. Unit RGB signal output characteristics RGB output DC voltage RGB output DC voltage difference VOUT Input SIG6 (VL = 0mV) to (A). Adjust V60 so that the output (black-black) at TP41 is 9Vp-p and measure the DC voltage at TP39, TP41 and TP43. ∆VOUT Input SIG6 (VL = 0mV) to (A). Adjust V60 so that the output (black-black) at TP41 is 9Vp-p, measure the DC voltage at TP39, TP41 and TP43, and obtain the maximum difference between these values. BRTMX Input SIG6 (VL = 0mV) to (A) and measure the output (black-black) at TP39, TP41 and TP43 when V60 = 0V. BRTMN Input SIG6 (VL = 0mV) to (A) and measure the output (black-black) at TP39, TP41 and TP43 when V60 = 5V. SBBRT Input SIG6 (VL = 0mV) to (A) and measure the difference between the outputs (black-black) at TP39 and TP43 and the output (black-black) at TP41 when V55 and V56 = 1V and when V55 and V56 = 4V. ±2 SBCNT Input SIG5 to (A) and measure the difference between the outputs (white-black) at TP39 and TP43 and the output (white-black) at TP41 when V63 and V64 = 1V and when V63 and V64 = 4V. ±2 ∆G (NR) Input SIG5 to (A) and obtain the gain difference between the non-reversed output amplitudes (white-black) and the reversed output amplitudes at TP39, TP41 and TP43. 5.85 6.05 6.25 V 0 100 mV V 9.0 Amount of change in brightness Amount of change in sub-brightness Amount of change in sub-contrast Difference in RGB reversed/ non-reversed gain 3.0 V V ±4 dB –0.6 0 0.6 dB 21.5 25.5 29.5 dB 9.5 12.5 15.5 dB 18.5 23.5 26.5 dB 2.0 V γ characteristics Gγ1 γ gain Gγ2 Gγ3 V γ 1MN V γ 1 adjustment variable range V γ 1MX V γ 2MN V γ 2 adjustment variable range V γ 2MX Input SIG9 to (A) and adjust the non-reversed output amplitude (white-black) at TP41 to 4Vp-p with V61. Calculate the following: G γ 1 = 20log (VG1/0.0357) G γ 2 = 20log (VG2/0.0357) G γ 3 = 20log (VG3/0.0357) (See Fig. 6 for definitions of VG1, VG2 and VG3.) Input SIG4 to (A) and adjust the output amplitude (whiteblack) at TP41 to 4Vp-p with V61 when V57 and V58 = 0V and V59 = 5V. Measure the point where the gain of the non-reversed output at TP41 changes and the voltage difference V γ 1 between this output and VCC2/2 when V59 = 0V and when V59 = 2.7V. V γ 1MN when V59 = 0V, and V γ 1MX when V59 = 2.7V (See Fig. 7.) Input SIG4 to (A) and adjust the output amplitude (whiteblack) at TP41 to 4Vp-p with V61 when V57 and V58 = 0V. Measure the point where the gain of the non-reversed output at TP41 changes and the voltage difference V γ 2 between this output and VCC2/2 when V58 = 5V and when V58 = 1.5V. V γ 2MN when V58 = 5V and V γ 2MX when V58 = 1.5V. (See Fig. 7.) – 17 – V 3.5 0.9 2.0 V V CXA1854AR Electrical Characteristics – AC Characteristics (4) Item Symbol Conditions Min. Typ. Max. Unit Sync separation, TG block Sync separation input voltage sensitivity VSSEP TDHDH HD output delay time TDHDL HPLLN Horizontal pull-in range HPLLP Input SIG6 (VL = 0mV, WS = 4.7µs, VS variable) to (A) and confirm that it is synchronized with the output at TP30. Gradually reduce the VS of SIG6 from 143mV and obtain the VS at which input and output become non-synchronized. Input SIG6 (VL = 0mV, VS = 143mV, WS = 4.7µs) to (A) and measure the delay time with the output at TP30. TDHDH is from the falling edge of the input sync signal to the rising edge of TP30, and TDHDL from the rising edge of the input sync signal to the falling edge of TP30. 40 60 mV 2.9 3.2 3.5 µs 4.4 4.7 5.0 µs Input SIG6 (VL = 0mV, VS = 143mV, WS = 4.7µs, horizontal frequency variable) to (A) and confirm that NTSC ±500 it is synchronized with the output at TP30. Obtain the frequency fH where the input and output are synchronized by changing the horizontal frequency PAL ±500 of SIG6 from the non-synchronized condition. SW7 = C HPLLN = fH – 15734, HPLLP = fH – 15625 Hz Hz External I/O characteristics External RGB input threshold voltage VT1EXT VT2EXT Propagation delay time between external RGB input and output Black level voltage during external RGB input White level voltage during external RGB input TD1EXT TD2EXT Input SIG6 (VL = 0mV) to (A) and SIG7 (VL variable) to (C), (D) and (E). Raise the amplitude from 0 V and assume the voltage, where the outputs at TP39, TP41 and TP43 go to black level as VT1EXT. Then raise the amplitude further and assume the voltage where these outputs go to white level as VT2EXT. SW9 = B, SW10 = B, SW11 = B Input SIG6 (VL = 0 mV) to (A) and SIG7 (VL = 3 V) to (C), (D) and (E), and adjust the output amplitudes at TP39, TP41 and TP43 to 2.0V with V57. Measure the rise delay time TD1EXTand the fall delay time TD2EXT. SW9 = B, SW10 = B, SW11 = B (See Fig. 2.) EXTBK Input SIG6 (VL = 0mV) to (A) and SIG7 (VL = 1.7V) to (C), (D) and (E), and measure the difference from the black level of the outputs at TP39, TP41 and TP43. SW9 = B, SW10 = B, SW11 = B EXTWT Input SIG6 (VL = 0mV) to (A) and SIG7 (VL = 2.7V) to (C), (D) and (E), and measure the difference from the black level of the outputs at TP39, TP41 and TP43. SW9 = B, SW10 = B, SW11 = B – 18 – 1.0 1.2 1.4 V 2.0 2.2 2.4 V 100 200 300 ns 100 200 300 ns 0 V 1.8 2.2 V CXA1854AR Electrical Characteristics – AC Characteristics (5) Item Symbol Conditions Min. Typ. Max. Unit Filter characteristics F0BPFN BPF center frequency F0BPFP Amount of BPF attenuation ATBPF ATRAPN Amount of TRAP attenuation ATRAPP R-Y, B-Y and LPF characteristics DEMLP Input SIG6 (VL =0 mV) to (A) and SIG2 (0dB, frequency variable) to (B). Obtain frequencies fc1 and fc2 which reduce the output amplitude by 3dB from the maximum output at TP51 by changing the frequency, and calculate F0BPF = (fc1 + fc2)/2. Settings 1 and 3 are required. NTSC 3.33 3.58 3.83 MHz PAL 4.13 SW7 = C 4.43 4.73 MHz –3 –1 dB –23 –15 dB –3 –1 dB –20 –15 dB NTSC –35 dB PAL SW7 = C –35 dB 1.2 MHz 30 ns 25 ns 10 ns 53 % Input SIG6 (VL = 0mV) to (A) and SIG2 2.78MHz (0dB, frequency variable) to (B). NTSC Assume TP51 when the center 1.50MHz frequency is input as 0dB and measure the output level at TP51 when the 3.23MHz PAL frequencies noted on the right are SW7 = C 2.00MHz input. Settings 1 and 3 are required. Input SIG2 (0dB, 3.58MHz, 4.43MHz) to (A) and measure the output at TP41 with a spectrum analyzer. Assume the output during Y/C mode (SW8 = A) as 0dB and measure the amount of attenuation during COMP mode (SW8 = C). Settings 1 and 3 are required. Input SIG6 (VL = 0mV) to (A) and SIG2 (amplitude 100mV, frequency variable) to (F) and (G). Assume the output amplitude at TP41 when 100kHz is input as 0dB, and measure the frequency which attenuates the output amplitude by –3dB. –7 –8 0.6 0.8 Digital block I/O characteristics Input SIG6 (VL = 0mV) to (A). Load 30pF (See Fig. 4.) V3, V46, V58, V59 = 2.5V Output transition time (Note 3 pins) tTLH Cross-point time difference ∆T Input SIG6 (VL = 0 mV) to (A). Load 30pF (see Fig. 5.) HCK1/HCK2 V3, V46, V58, V59 = 2.5V DTYHC Input SIG6 (VL = 0mV) to (A). Measure the HCK1 and HCK2 output duty. Load 30pF V3, V46, V58, V59 = 2.5V HCK duty tTHL – 19 – 47 50 CXA1854AR Description of Electrical Characteristics Measurement Methods 3V CMAX Chroma output SIG7 GND 2V TP39, 41, 43 non-reversed output 1V CMAX – 3dB BPF center frequency fc1 + fc2 2 FOBPF = TD1EXT TD2EXT fc1 Fig. 2. Measuring the delay between external RGB input and output tTLH fc2 f Fig. 3. BPF center frequency ∆T tTHL 90% 50% 10% ∆T Fig. 4. Output transition time measurement condition Fig. 5. Cross-point time difference measurement condition White peak limiter White White 1/2 VCC2 Non-reversed output Non-reversed output 1/2 VCC2 Gγ3 Gγ2 Black Gγ1 Vγ1 Vγ2 Black Input Input Fig. 6. γ characteristics measurement condition – 20 – Fig. 7. γ adjustment variable range CXA1854AR Input Waveforms (1) SG No. Waveform APL variable, 5-step waveform 0.357V APL10% 0.143V 0.179V SIG1 APL50% 0.357V APL90% Sine wave video signal with burst. (Amplitude and frequency are variable.) 0.15V SIG2 0.15V VSWEEP 0.143V Chroma signal:Burst, chroma frequency (3.579545MHz, 4.433619MHz) Chroma phase and burst frequency variable SIG3 0.15V 0.143V Lamp waveform 0.357V SIG4 0.143V 1H 5-step waveform 0.15V SIG5 0.143V – 21 – CXA1854AR Input Waveforms (2) SG No. Waveform VL SIG6 VS WS fH VL amplitude is variable. VS variable: 143mV unless otherwise specified WS variable:4.7µs unless otherwise specified fH variable: 15.734kHz (NTSC) or 15.625kHz (PAL) unless otherwise specified 5µs 30µs GND VL VL amplitude is variable. SIG7 SYNC timing 0.075V SIG8 0.175V Frequency variable 0.143V 10-step waveform SIG9 0.357V 0.143V – 22 – CXA1854AR Electrical Characteristics Measurement Circuit +VCC1 +5V +VCC2 +12V TP43 +VCC1 +5V TP39 TP41 100p 100p 47µ A 330k 330k 1µ 47µ 0.1µ 1µ 1µ 330k 0.1µ 1µ SW46 V46 47µ 100p 0.1µ A A SW52 SW53 CL ∗1 SW58 SW59 VDD RGT TEST6 TEST7 TEST8 GND 2 R OUT FB R G OUT FB G FB B B OUT VCC2 CLR 25 TP25 EN 24 TP24 58 GAMMA2 VCK1 23 TP23 59 GAMMA1 VCK2 22 TP22 60 BRIGHT VST1 21 TP21 CXA1854AR +5V 10k TEST3 20 B SW19 A SLCK 19 62 CIN 63 R-GAIN TEST0 18 S18 64 B-GAIN TEST1 17 S17 3 1µ 8 9 10 11 12 13 14 15 16 SW7 (A) SW3 SW5 V3 V5 (C) (D) (E) A +5V AC C B B SW810k 3.3µ 1k TEST2 7 CKO 6 CKI 5 1µ VSS 4 RPD 2 EXT-B 1 EXT-G SW64 TP26 56 B-BRT SW11 V64 TEST4 26 61 CONTRAST (B) SW63 TP27 55 R-BRT SW10 V63 HST1 27 MODE2 SW61 TP28 54 XVXO EXT-R SW60 V61 HCK2 28 57 RGB-GAIN SW57 V60 TP29 53 COLOR SW9 V59 HCK1 29 MODE1 V58 TP30 52 HUE/RST GND1 V57 SW56 TP31 HD 30 PICT V56 SW55 VD 31 51 COUT AGCTC V55 50 R-YIN AGCADJ V53 BLKLIM REG 4.7k V52 TEST5 32 49 B-YIN 1µ YIN TP51 (F) 1µ SYNCIN (G) VCC1 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 +12V ∗2 10k 47k 0.01µ ∗1 Used crystal: KINSEKI CX-5F Frequency deviation: within ±30ppm, frequency temperature characteristics: within ±30ppm During NTSC: 3.579545MHz, load capacity: 16pF, CL = 20pF During PAL: 4.433619MHz, load capacity: 16pF, CL = 16pF Measure under the condition that the crystal parallel floating capacitance is within 2pF. ∗2 Vari-cap diode: 1T369 (SONY) ∗3 L value: 10µH when using the LCX005 4.7µH when using the LCX009 – 23 – S16 30p 33k 3300p S19 L∗3 220p 10k VR12 CXA1854AR Description of Operation The CXA1854AR incorporates the three functions of an RGB decoder block, an RGB driver block and a timing generator (TG) block onto a single chip using BiCMOS technology. This section describes these functions and their mutual relationship. 1) Description of the overall configuration CXA1854AR Corresponding LCD panels Y SYNC C RGB driver R OUT G OUT B OUT FRP RGB decoder EXT-R EXT-G EXT-B SYNC BLK RPD TG 3.58MHz or 4.43MHz HCK1 HCK2 HST1 VCK1 VCK2 VST1 CLR ENB LCX009AK/AKB 1.8cm 180K dots LCX005BK/BKB 1.4cm 113K dots CKI R-Y B-Y R G B VCO 2) Description of RGB decoder block operation • Input mode switching Signal input: Composite input, (MODE2). During composite input: During Y/C input: During Y/color difference input: Y/C input and Y/color difference input switching is supported by Pin 8 The composite signal is input to Pins 1, 2 and 62. The Y signal is input to Pins 1 and 2, and the C signal to Pin 62. The Y signal is input to Pins 1 and 2, the R-Y signal to Pin 50, and the B-Y signal to Pin 49. (Chroma signal input (delay line output) is also used during PAL, but is switched with the MODE1 setting.) Recommended input signal voltages for each mode are shown in the Pin Description table. The Y signal enters the TRAP circuit in composite mode, but through operation is performed in all other modes. Also, the picture center frequency is set separately for composite input and Y/C input. (See the AC Characteristics tables.) • NTSC/PAL switching NTSC and PAL (DPAL using an external delay line and SPAL) are switched by MODE1. The built-in TRAP and BPF center frequencies are switched automatically according to the external crystal. The center frequency is stabilized by the APC operation. The R-Y demodulation detective axis is set internally to 90° during SPAL/DPAL. However, optimally adjust the demodulation phase axis with the HUE adjustment pin. • Video AGC/ACC circuit Different AGC characteristics are obtained depending on the APL level of the luminance signal. The gain for the luminance signal is adjusted with the average value. The sync amplitude of the burst signal output is detected and used to adjust the ACC amplifier gain. – 24 – CXA1854AR • VXO, APC detection The VXO local oscillation circuit is crystal oscillation circuit. The phases of the input burst signal and the VXO oscillator output are compared in the APC detection block, and the detective output is used to form a PLL loop that controls the VXO oscillation frequency, which means that the need for adjustments is eliminated. In addition, the filter f0 is automatically adjusted, since the BPF and TRAP center frequency is feedback controlled by VXO. • Crystal oscillator for the XVXO pin connection A 3.579545MHz crystal vibrator is connected to the XVXO pin during NTSC, and a 4.433619MHz crystal vibrator during PAL. (Use KINSEKI CX-5F crystal vibrator with a load capacity of 16pF, frequency deviation within ±30ppm, and frequency temperature characteristics within ±30ppm.) • External inputs Digital input with two thresholds is optimal for multiplexed character output to screens. When one of the RGB inputs is higher than the lower threshold Vth1, all RGB outputs go to black level. When the higher threshold Vth2 is exceeded, the output for only the signal in question goes to white level, while the other outputs remain at black level. Externally connect a pull-down resistor (10kΩ or more). 3) Description of RGB driver block operation γ1 B γ2 A B γ1 A Output γ2 Output Output • 2-point γ compensation circuit In order to support the characteristic of LCD panels, the I/O characteristics are as shown in Fig. 1. The voltage at γ gain change point A can be changed to that shown in Fig. 2 by adjusting the GAMMA1 pin (Pin 59). Also, the voltage at the γ 2 gain change point can be changed to that shown in Fig. 3 by adjusting the GAMMA2 pin (Pin 58). The drive for LCD panels can be optimized by adjusting the overall gain with these two gain change points and the RGB-GAIN pin (Pin 57). γ2 γ1 B A Input Input Input Fig. 1 Fig. 2 Fig. 3 – 25 – CXA1854AR • Sample-and-hold circuit As the LCD panels sample-and-hold RGB signals simultaneously, RGB signal output from CXA1854R must be synchronized to LCD panel drive pulses and sample-and-hold performed. Sample-and-hold is performed by receiving the SH1 to SH4 pulses from the TG block. Since LCD panels perform color coding using an RGB delta arrangement, each horizontal line must be compensated by 1.5 dots. This relationship is reversed during right/left inversion. These timing pulses are generated by the TG block. Accordingly, RGB signals are each sampled-and-held at the optimal timing and output by the RGB driver block. Normal scan S/H B S/H R G S/H S/H S/H Reverse scan HCK HCK SH3 SH2 SH1 SH1 SH4 SH4 SH2 SH3 S/H SH2 SH1 SH3 SH4 Example of sample-and-hold circuits and S/H timing • RGB output RGB outputs (Pins 39, 41, and 43) are reversed each horizontal line by the FRP pulse supplied from the TG block as shown in the figure below. Feedback is applied so that the center voltage of the output signal matches the reference voltage (VCC2 + GND1)/2. In addition, the white level output is clipped by the Vsig center voltage level, and the black level output is clipped by the limiter operation point that is adjusted at the BLKLIM pin (Pin 46). Video IN FRP Black level limiter (reversed side) RGB OUT waveform Vsig center voltage Black level limiter (non-reversed side) – 26 – CXA1854AR 4) Description of TG block operation This section describes the main functions of the TG block. (See individual description materials for details.) • PLL circuit block The PLL circuit block contains a phase comparator and frequency division counter circuit in order to accurately align the timing, and performs PLL operation by externally connecting a VCO circuit. The average voltage of the RPD pin (Pin 12) is locked roughly in the center by adjusting it to VDD/2. (See the attached Application Circuit for the external circuit diagram. The 1T369 is recommended as the vari-cap diode used in the VCO circuit.) • SYNC detection circuit This circuit separates the input SYNC signal into HSYNC and VSYNC, and recognizes the EVEN and ODD fields and line numbers, etc. This circuit is necessary for the reasons (1) and (2). (1) Shifts 1.5 dots each horizontal line for the RGB delta arrangement. (2) Field recognition and accurate line number recognition for changing the eliminated lines for each EVEN and ODD field and smoothing the picture during PAL. In addition, if the SYNC waveform is not detected for more than a certain interval, the unit shifts automatically to the free running state and the LCD panel is driven by self oscillation. • Pulse generator block The pulse generator circuit is synchronized to the previously mentioned SYNC detection circuit and PLL circuit, and generates the pulses necessary to drive the LCD panel. (The main output pulse timings are shown for each mode in a later section.) At the same time, the pulse generator circuit also generates the BGP, BLK and other waveforms for the RGB decoder. Therefore, TG block PLL circuit operation is necessary for RGB decoder functions. • AC drive during no signal HST1, HCK1, HCK2, FRP, VST1, VCK1, VCK2, HD and VD are made to run free so that the LCD panel is AC driven even when there is no composite sync from the SYNC pin. During this time, the HSYNC separation circuit stops and the PLL counter is made to run free. In addition, the reference pulse for generates VD and VST, and the auxiliary V counter creates the reference pulse for generates VD and VST. The VSYNC separation circuit is also stopped and The period of the V counter is designed to be 269H for NTSC and 321H for PAL. When there is no VSYNC during 269H or 321H, the free running state is assumed. In addition, RPD is kept at high impedance in order to prevent the AFC circuit from producing a phase error due to phase comparison when there is no signal. • AFC circuit (702/1050fh generation) A fully synchronized AFC circuit is built in. PLL error signal is generated at the following timing. The phase comparison output of the entire bottom of SYNC and the internal H counter becomes RPD. RPD output is converted to DC error with the lag-lead filter, and then it changes the vari-cap diode capacitance and the oscillation frequency is stabilized at 702fh in the LCX005BK/BKB and 1050fh in the LCX009AK/AKB. 4.7µs SYNC VDD RPD VDD/2 0V SYNC center – 27 – CXA1854AR 5) Description of TG block mode settings • SLCK: Selects the driven LCD panel. L Selects the LCX009 H Selects the LCX005 Note) The VCO frequency varies depending on the used panel. VCO center frequency LCX005 (702fh) LCX009 (1050fh) NTSC 11.06MHz NTSC 16.52MHz PAL 10.97MHz PAL 16.41MHz The external VCO circuit diagram is shown in the Application Circuit. Recommended value: L value LCX005: 10µH, LCX009: 4.7µH • RGT: Switches the horizontal scan direction. H Normal scan mode L Reverse scan mode The HST1, HCK1 and HCK2 timing are switched by the RGT selection. The timing of the internal sample-and-hold pulse is also switched at the same time. Connect the panel RGT pin directly, as it does not support output. • MODE1/MODE2: Sets the type of video signal input. MODE1 MODE2 H NTSC H Composite input M D-PAL M Y/color difference input L SPAL L Y/C input Signal input connections for each mode are noted in the RGB decoder block. – 28 – CXA1854AR LCX009AK/AKB and LCX005BK/BKB Color Coding Diagram The delta arrangement is used for the color coding in the LCD panels with which this IC is compatible. Note that the shaded region within the diagram is not displayed. LCX009AK/AKB pixel arrangement dummy1 to 4 dummy1 dummy2 B R Vline1 Vline2 R G B R Vline3 R G R Vline225 dummy3 G B R B R B R G G R G B G B R R G G R B B G B R G R B G G R R G B B B G B R R G G B 14 B G R B G G B G B R G R G B B 225 228 G R R 800 R B B G G R G R R B B R G R G 2 R B B G R R G R B B B G R G R B G R G R B R B G R B R dummy5 to 8 R G B R Photo-shielding area G B R G B G R B R B G B G R B R R G R G HSW268 G B B R area G G Display R B B R R B G B G R B HSW267 G R B G R G R B R B G R B R B G B G R B G B G R HSW2 G R B G R G R B R B G R B R B G B G R B Vline224 B G R G R B HSW1 R G 1 13 827 LCX005BK/BKB pixel arrangement dummy1 HSW1 HSW2 HSW3 HSW174 HSW175 dummy1 dummy2 R Vline1 Vline2 G B R Vline3 R G B R Vline218 R G B R R B G G B R G B R G R G B R G R G B R G B R R B G G G R B B B G R R R B G B G G R B B R B G B G R B 218 222 R G B R 2 R B G R G B G R B R G R B G B R B G R G B G R B R B Photo-shielding area R G B R B G G B area R Display R B R G B G B R B G R B R B G G B G R B G B G R R G R B G R G R B B R B G R B R B G G B G R B dummy3 B G R R G R B Vline217 B dummy2 to 5 B R G B 2 dummy4 R 3 G B R G B R G B 521 537 – 29 – R G B R G B R 13 CXA1854AR Application Circuit – NTSC (COMP and Y/C input) +VCC1 +5V To panel +VCC2 +12V Blue +VDD +5V Red Green 0.1µ 47µ 1µ 1µ 47µ 0.1µ 1µ 47µ 0.1µ 1µ 330k 0.01µ 330k 47k 330k B-LIM 20pF COLOR 47k 0.01µ 0.01µ VDD RGT TEST6 TEST7 GND 2 TEST8 FB R G OUT FB G B OUT FB B VCC2 R OUT CLR 25 CXA1854AR 57 RGB-GAIN VCK1 23 59 GAMMA1 VCK2 22 60 BRIGHT VST1 21 TEST3 20 61 CONTRAST SLCK 19 64 B-GAIN TEST1 17 5 1µ Y/C 6 7 8 9 10 11 12 13 14 15 16 1µ COMP +VCC2 +12V COMP/Y IN 10k Y/C 3300p ∗2 10k COMP 3.3µ 009 30p 33k C IN 005 L∗3 1k 220p +VDD +5V +VDD +5V TEST2 4 CKO 3 CKI 2 VSS 1 RPD 0.01µ EXT-B 0.01µ EXT-G 47k TEST0 18 10k 47k 0.01µ 63 R-GAIN 10k 47k 0.01µ To panel EN 24 58 GAMMA2 EXT-R PIC 0.01µ 56 B-BRT MODE2 AGC 0.01µ TEST4 26 10k B-G 0.01µ HST1 27 55 R-BRT 62 CIN 47k R-G 0.01µ HCK2 28 GND1 CONT 47k 0.01µ 53 COLOR 54 XVXO MODE1 BRT 47k ∗1 HCK1 29 PICT GAM1 47k HD 30 52 HUE/RST AGCTC GAM2 47k VD 31 AGCADJ RGB 50 R-YIN YIN B-BRT 47k 0.01µ TEST5 32 SYNCIN R-BRT 47k 47k BLKLIM REG 0.01µ HUE 49 B-YIN 51 COUT 1.7k 47k VCC1 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 47k 0.01µ ∗1 Used crystal: KINSEKI CX-5F Frequency deviation: within ±30ppm, frequency temperature characteristics: within ±30ppm 3.579545MHz, load capacity: 16pF ∗2 Vari-cap diode: 1T369 (SONY) ∗3 L value: 10µH when using the LCX005 4.7µH when using the LCX009 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 30 – CXA1854AR Application Circuit – PAL (COMP and Y/C input) To panel +VCC1 +5V +VCC2 +12V Blue Green +VDD +5V Red 0.1µ 47µ 1µ 1µ 47µ 0.1µ 1µ 47µ 0.1µ 1µ 330k 0.01µ 330k 47k 330k B-LIM VDD RGT TEST7 TEST6 TEST8 GND 2 R OUT FB R G OUT FB G B OUT FB B VCC2 VCC1 BLKLIM REG 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 TEST5 32 49 B-YIN 1.7k 0.01µ 16pF COLOR 47k 47k 47k 0.01µ 0.01µ 58 GAMMA2 VCK1 23 59 GAMMA1 VCK2 22 60 BRIGHT VST1 21 TEST3 20 61 CONTRAST 0.01µ SLCK 19 64 B-GAIN TEST1 17 4 5 6 7 8 9 10 11 12 13 14 15 16 1µ Y/C 1µ COMP +VCC2 +12V COMP/Y IN 10k Y/C 3300p 009 30p 33k C IN 005 L∗3 1k 220p +VDD +5V +VDD +5V TEST2 3 CKO 2 CKI 1 VSS 0.01µ RPD 0.01µ EXT-G 47k TEST0 18 EXT-B 47k 0.01µ 63 R-GAIN 10k 47k 0.01µ 10k PIC 0.01µ EXT-R AGC 0.01µ To panel EN 24 MODE2 B-G CLR 25 CXA1854AR 57 RGB-GAIN 62 CIN 47k R-G 56 B-BRT 0.01µ 10k CONT 47k TEST4 26 MODE1 BRT 47k HST1 27 55 R-BRT GND1 GAM1 HCK2 28 54 XVXO PICT GAM2 47k HCK1 29 AGCTC RGB 47k 0.01µ 52 HUE/RST 53 COLOR AGCADJ B-BRT 47k ∗1 HD 30 YIN R-BRT 0.01µ VD 31 51 COUT SYNCIN HUE 47k 50 R-YIN ∗2 10k COMP 47k 3.3µ 0.01µ ∗1 Used crystal: KINSEKI CX-5F Frequency deviation: within ±30ppm, frequency temperature characteristics: within ±30ppm 4.433619MHz, load capacity: 16pF ∗2 Vari-cap diode: 1T369 (SONY) ∗3 L value: 10µH when using the LCX005 4.7µH when using the LCX009 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 31 – CXA1854AR Application Circuit – Y/color difference input (NTSC/PAL) To panel +VCC2 +12V +VCC1 +5V Blue Green +VDD +5V Red 0.1µ 47µ 1µ 1µ 47µ 0.1µ 1µ 0.1µ 330k 47µ 330k 47k 0.01µ 1µ 330k B-LIM R-YIN B-YIN VDD RGT TEST6 TEST7 GND 2 TEST8 R OUT FB R G OUT FB G B OUT FB B VCC2 BLKLIM REG VCC1 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 1µ TEST5 32 49 B-YIN TEST3 20 61 CONTRAST SLCK 19 62 CIN 63 R-GAIN TEST0 18 64 B-GAIN TEST1 17 0.01µ 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1µ 1µ +VCC2 +12V 33k 10k 3300p ∗1 10k NTSC 3.3µ 009 30p Y IN PAL 005 L∗2 1k 220p +VDD +5V +VDD +5V TEST2 0.01µ CKO 47k 0.01µ VST1 21 CKI 47k 0.01µ VCK2 22 60 BRIGHT VSS PIC 47k 0.01µ 59 GAMMA1 RPD AGC 47k 0.01µ VCK1 23 EXT-B B-G 47k 0.01µ 58 GAMMA2 EXT-G R-G 47k 0.01µ To panel EN 24 10k BRT CONT 47k 0.01µ CLR 25 CXA1854AR 57 RGB-GAIN EXT-R GAM1 47k 56 B-BRT 10k GAM2 47k 0.01µ MODE2 RGB 0.01µ HST1 27 TEST4 26 10k B-BRT 47k 54 XVXO 55 R-BRT MODE1 R-BRT 0.01µ HCK2 28 GND1 47k 47k HCK1 29 53 COLOR PICT COLOR 52 HUE/RST AGCTC 0.01µ AGCADJ HUE HD 30 YIN 1.7k 47k VD 31 51 COUT SYNCIN 1µ 50 R-YIN 47k 0.01µ ∗1 Vari-cap diode: 1T369 (SONY) ∗2 L value: 10µH when using the LCX005 4.7µH when using the LCX009 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 32 – – 33 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 2.0µs (22fh) 693 702 1 EVEN FIELD 11 21 ODD LINE 31 3.0µs (33fh) 41 Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 683 4.5µs (50fh) 4.7µs (52fh) 673 HD 663 4.7µs (52fh) 653 (BLK) SYNC CLK LCX005 Horizontal Direction Timing Chart (NTSC, PAL) 51 71 0.5µs (6fh) 18.5fh 23.5fh 61 13fh 81 RGT: H (Normal scan) Composite In 91 CXA1854AR 683 – 34 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 702 1 ODD FIELD 11 21 31 EVEN LINE 3.0µs (33fh) 41 Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. EVEN FIELD 2.0µs (22fh) 693 4.5µs (50fh) 4.7µs (52fh) 673 HD 663 4.7µs (52fh) 653 (BLK) SYNC CLK LCX005 Horizontal Direction Timing Chart (NTSC, PAL) 51 71 0.5µs (6fh) 18.0fh 22fh 61 13fh 81 RGT: H (Normal scan) Composite In 91 CXA1854AR – 35 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 2.0µs (22fh) 693 702 1 EVEN FIELD 11 21 31 ODD LINE 3.0µs (34fh) 41 Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 683 4.5µs (50fh) 4.7µs (52fh) 673 HD 663 4.7µs (52fh) 653 (BLK) SYNC CLK LCX005 Horizontal Direction Timing Chart (NTSC, PAL) 51 71 0.5µs (5fh) 18.0fh 23fh 61 13fh 81 RGT: L (Reverse scan) Composite In 91 CXA1854AR – 36 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 2.0µs (22fh) 693 702 1 EVEN FIELD 11 21 31 EVEN LINE 41 3.0µs (34fh) Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 683 4.5µs (50fh) 4.7µs (52fh) 673 HD 663 4.7µs (52fh) 653 (BLK) SYNC CLK LCX005 Horizontal Direction Timing Chart (NTSC, PAL) 51 71 0.5µs (5fh) 18.5fh 24.5fh 61 13fh 81 RGT: L (Reverse scan) Composite In 91 CXA1854AR – 37 – VRST (Internal pulse) VD FLD (Internal pulse) FRP (Internal pulse) CLR EN HST FRP (Internal pulse) VCK2 VCK1 VST (BLK) SYNC (VD) HD 3.0H 20H 3.0H 1 Display start 20 1 2 3 45 67 8 12 3 4 ODD FIELD 12H 13 243 3.0H 3.0H 20H 3.0H 11.5H Display start 12 34 56 78 1 23 4 275 EVEN FIELD 263 Note) The second and fourth rows of the timing chart "VD" and "BLK" are pulses indicated as a reference and are not pulses output from pins. (1F inversion) 505 3.0H LCX005 Vertical Direction Timing Chart (NTSC) CXA1854AR – 38 – VRST (Internal pulse) VD FLD (Internal pulse) FRP (Internal pulse) CLR EN HST FRP (Internal pulse) VCK2 VCK1 VST (BLK) SYNC (VD) HD 2.5H 25H 2.5H 14.5H ODD FIELD 1 Display start 26 1 2 3 4 56 78 1 2 3 4 56 1 2 3 4 5 6 7 8 1 2 34 16 1 2 3 4 5 6 78 288 2.5H 2.5H 25H 2.5H 14H EVEN FIELD 314 Note) The second and fourth rows of the timing chart "VD" and "BLK" are pulses indicated as a reference and are not pulses output from pins. (1F inversion) 1 2 3456 78 600 2.5H LCX005 Vertical Direction Timing Chart (PAL) Display start 1 2 3 45 6 7 8 1 2 3 4 5 6 1 2 3 1 23 4 328 6, 8 decimation CXA1854AR 1001 1021 – 39 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 1041 2.0µs (33fh) 1031 1050 1 11 21 31 41 EVEN FIELD ODD LINE 3.0µs (50fh) Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 4.7µs (78fh) 1011 4.5µs (73fh) 991 HD 981 4.7µs (78fh) 971 (BLK) SYNC CLK LCX009 Horizontal Direction Timing Chart (NTSC, PAL) 51 0.5µs (8fh) 61 43.5fh 71 20.5fh 81 91 RGT: H (Normal scan) Composite In 12fh 101 111 CXA1854AR 1001 1021 – 40 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 1041 2.0µs (33fh) 1031 1050 1 11 21 31 41 ODD FIELD EVEN LINE 3.0µs (50fh) Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. EVEN FIELD 4.7µs (78fh) 1011 4.5µs (73fh) 991 HD 981 4.7µs (78fh) 971 (BLK) SYNC CLK LCX009 Horizontal Direction Timing Chart (NTSC, PAL) 51 71 43.0fh 0.5µs (8fh) 61 19fh 81 91 RGT: H (Normal scan) Composite In 12fh 101 111 CXA1854AR 1001 1021 – 41 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 1041 2.0µs (33fh) 1031 1050 1 11 21 31 41 EVEN FIELD ODD LINE 3.0µs (51fh) Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 4.7µs (78fh) 1011 4.5µs (73fh) 991 HD 981 4.7µs (78fh) 971 (BLK) SYNC CLK LCX009 Horizontal Direction Timing Chart (NTSC, PAL) 51 0.5µs (7fh) 61 43.0fh 71 20fh 81 91 RGT: L (Reverse scan) Composite In 12fh 101 111 CXA1854AR 1001 1021 – 42 – EN (PAL) CLR VCK2 VCK1 FRP (Internal pulse) HCK2 HCK1 HST 1041 2.0µs (33fh) 1031 1050 1 11 21 31 41 EVEN FIELD EVEN LINE 3.0µs (51fh) Note) During Y/C input, the HST timing is delayed 6fh from the above timing. The third row of the timing chart "BLK" is a pulse indicated as a reference and is not a pulse output from pins. FRP polarity is not specified. ODD FIELD 4.7µs (78fh) 1011 4.5µs (73fh) 991 HD 981 4.7µs (78fh) 971 (BLK) SYNC CLK LCX009 Horizontal Direction Timing Chart (NTSC, PAL) 51 0.5µs (7fh) 61 43.0fh 71 21.5fh 81 91 RGT: L (Reverse scan) Composite In 12fh 101 111 CXA1854AR – 43 – (1F inversion) 505 3.0H 3.0H 20H 3.0H 1 9H 20 Display start ODD FIELD 1 23 45 67 8 1 2 34 10 243 3.0H 3.0H 20H 3.0H 8.5H Display start 12 34 56 78 12 3 4 272 EVEN FIELD 263 Note) The second and fourth rows of the timing chart "VD" and "BLK" are pulses indicated as a reference and are not pulses output from pins. VRST (Internal pulse) VD FLD (Internal pulse) FRP (Internal pulse) CLR EN HST FRP (Internal pulse) VCK2 VCK1 VST (BLK) SYNC (VD) HD LCX009 Vertical Direction Timing Chart (NTSC) CXA1854AR – 44 – 2.5H (1F inversion) 1 2 3 45 6 7 8 600 2.5H 25H 2.5H 10.5H 5.5H 12 Display start 26 1 2 3 4 5 6 7 8 1 2 34 56 12 34 5 6 7 81 1 23 4 ODD FIELD 1 288 2.5H 25H 2.5H 1 23 456 78 2.5H 314 EVEN FIELD 10.0H 6.0H Note) The second and fourth rows of the timing chart "VD" and "BLK" are pulses indicated as a reference and are not pulses output from pins. VRST (Internal pulse) VD FLD (Internal pulse) FRP (Internal pulse) CLR EN HST FRP (Internal pulse) VCK2 VCK1 VST (BLK) SYNC (VD) HD LCX009 Vertical Direction Timing Chart (PAL) Display start 1 2 3 4 5 6 7 8 1 2 34 5 6 12 3 12 34 324 6, 8 decimation CXA1854AR CXA1854AR Package Outline Unit: mm 64PIN LQFP (PLASTIC) 12.0 ± 0.2 10.0 ± 0.2 0.15 ± 0.05 48 0.1 33 49 32 A 64 17 1 1.25 16 + 0.08 0.18 – 0.03 0.5 1.7 MAX 0.1 M 0° to 10° 0.5 ± 0.2 (0.5) 0.1 ± 0.1 DETAIL A PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SOLDER PLATING SONY CODE LQFP-64P-L061 LEAD TREATMENT EIAJ CODE LQFP064-P-1010-AY LEAD MATERIAL 42 ALLOY PACKAGE WEIGHT 0.3g JEDEC CODE – 45 –