CXA2153S Preamplifier for High Resolution Computer Display Description The CXA2153S is a bipolar IC developed for high resolution computer displays. Features • Built-in wide-band amplifier: 180MHz@–3dB (Typ.) • Input dynamic range: 1.0Vp-p (Typ.) • High gain preamplifier (15dB) • R, G and B incorporated in a single package (SDIP 30 pins) • I2C bus control Contrast control R/G/B drive control Brightness control OSD contrast control 4-channel DAC control output • Built-in gamma function • Built-in high-speed ABL blanking • Built-in sync separator for Sync on Green • Built-in blanking mixing function (with blanking level fixed at 0.4V) • Built-in OSD mixing function • Video period detection function • Built-in VBLK synchronous DAC refresh system Applications High resolution computer displays 30 pin SDIP (Plastic) Absolute Maximum Ratings (Ta = 25°C, GND = 0V) • Supply voltage Vcc12 13 V Vcc5 5.5 V • Operating temperature Topr –20 to +75 °C • Storage temperature Tstg –65 to +150 °C • Allowable power dissipation 2.05 W PD • Pin voltage Vcc5 + 0.3V 1, 3, 4, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 (Pin) VREF (Pin 23) + 0.3V 18, 19, 20, 21, 25, 27, 29 (Pin) Recommended Operating Conditions Supply voltage Vcc12 12 ± 0.5 Vcc5 5 ± 0.25 V V Structure Bipolar silicon monolithic IC 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– E99X02A1Y-PS 16 17 7 1 ABL RIN –2– 3 6 BIN Bch Clamp Gch Sharpness Buffer Clamp BRIGHTNESS SYNC OFF SYNC SEP. Clamp SYNCOUT ROUT BLK GOUT BOUT 12 29 14 27 25 VDET LEVEL/VDET OFF Bch (Same as Rch) BLK AMP Blanking Mix Rch Gch (Same as Rch) OSD/OSD_BLK Mix Video Detector SHP GAIN/ SHP WIDTH Gain Control AMP G2 18 Gamma B_BKG 19 Rch GAMMA1/GAMMA2/GM OFF POL1/POL2 G_BKG 20 OSD GAIN R_BKG 21 GIN ABL Contrast Regulator VCC12 22 DRIVE D/A Converter VREF 23 LPF Latch 4 SCL I2C Bus Decoder SYNCIN SDA CXA2153S Block Diagram 8 OSD_BLK 9 OSD_R 10 OSD_G 11 OSD_B 15 VDET 13 CLP CXA2153S Pin Configuration RIN 1 30 VCC12 VCC5 2 29 ROUT GIN 3 28 GND_R SYNCIN 4 27 GOUT GND 5 26 GND_G BIN 6 25 BOUT ABL 7 24 GND_B OSD_BLK 8 23 VREF OSD_R 9 22 VCC12 OSD_G 10 21 R_BKG OSD_B 11 20 G_BKG SYNCOUT 12 19 B_BKG CLP 13 18 G2 BLK 14 17 SCL VDET 15 16 SDA –3– CXA2153S Pin Description Pin No. Symbol Pin voltage Equivalent circuit Description VCC 1k VCC VCC 1 3 6 RIN GIN BIN 3.1V (CLAMP) RGB signal inputs. Input via the capacitor. 1 3 1k 6 1k 2 Vcc5 5V 5V power supply. VCC VCC VCC 100 4 SYNCIN Sync-on-green signal input. Input via the capacitor. 2.9V 4 150 5 GND GND VCC VCC 500 5V VCC 2k 500 VCC 7 ABL 2.5V (when open) 10k ABL input. 7 20k 10k VCC VCC 8 5k OSD_BLK 8 30k –4– 5k OSD_BLK control input. VILMAX = 0.8V VIHMIN = 2.8V CXA2153S Pin No. Symbol Pin voltage Equivalent circuit Description VCC VCC VCC 9 10 11 OSD_R OSD_G OSD_B 5k OSD control input. VILMAX = 0.8V VIHMIN = 2.8V 5k 9 10 30k 11 VCC VCC VCC 100 VCC 5k 20k 12 SYNCOUT 12 200 200 Sync separator output of Syncon-green signal. I2C bus SOG off: Output at 0. Typ.: High = 4.2V Low = 0.2V (positive polarity) VCC VCC 13 Clamp pulse (positive polarity) input. VILMAX = 0.8V VIHMIN = 2.8V CLP 13 30k VCC VCC VCC 5k 14 BLK 14 30k –5– 5k Blanking pulse input. Set the V blanking pulse width to 300µs or more. VILMAX = 1.2V VIHMIN = 4.7V CXA2153S Pin No. Symbol Pin voltage Equivalent circuit Description VREF VCC VCC 10k 100 VCC 20k 15 Video detector output. I2C bus VDET off: Output at 0. VDET 15 200 200 VCC 16 I2C bus standard SDA (serial data) input/output. VILMAX = 1.5V VIHMIN = 3.5V VOLMAX = 0.4V 4k SDA 16 VCC 17 I2C bus standard SCL (serial clock) input. VILMAX = 1.5V VIHMIN = 3.5V 4k SCL 17 10k VREG VCC 21 20 19 18 R_BKG G_BKG B_BKG G2 100 VREG 1k BKG/G2 adjustment DAC outputs. The output DC is 1.5 to 5.5V. 21 20 19 18 100 22 30 Vcc12 12V 1k 12V power supply –6– CXA2153S Pin No. Symbol Pin voltage Equivalent circuit VCC12 23 VREF VCC12 9V 23 Band Gap 28 26 24 GND_R GND_G GND_B Description 0V 9V regulator. Connect with Vcc12 via a resistor of around 220Ω. It cannot be used as an external power supply. GNDs VCC12 VREG 29 27 25 ROUT GOUT BOUT VCC R, G and B signal outputs. 29 27 25 –7– CXA2153S I2C BUS Register Definitions Slave Address SLAVE RECEIVER: 40 (HEX) Register Table Sub Address BIT 7 BIT 6 BIT 5 BIT 4 BIT 3 00h CONTRAST 01h BRIGHTNESS 02h R_BKG 03h G_BKG 04h B_BKG 05h OSD GAIN 06h G2 07h R_DRV 08h G_DRV 09h B_DRV 0Ah ∗ 0Bh POL1 0Ch ∗ ∗ SHP WIDTH GAMMA1 ∗ POL2 BIT 2 BIT 1 BIT 0 SHP GAIN GAMMA2 VDET LVL VDET OFF SOG OFF GAM OFF 0 D R OFF ∗: Don't Care Sub Address 0000 CONTRAST (8) Controls the gain common to the R, G and B channels. Since control is performed by multiplying with R/G/B DRIVE, the white balance can be adjusted by R/G/B DRIVE and the luminance can be adjusted by CONTRAST. 0: Output level minimum (0Vp-p) 255: Output level maximum (4.4Vp-p; with 0.7Vp-p input) Sub Address 0001 BRIGHTNESS (8) Controls the black level common to the R, G and B channels. 0: Black level minimum (0.8V) 255: Black level maximum (2.9V) Sub Address 0010 R_BKG (8) Controls Pin 21 (R BACKGROUND) output voltage. 0: Output voltage minimum (1.5V) 255: Output voltage maximum (5.5V) Sub Address 0011 G_BKG (8) Controls Pin 20 (G BACKGROUND) output voltage. 0: Output voltage minimum (1.5V) 255: Output voltage maximum (5.5V) Sub Address 0100 B_BKG (8) Controls Pin 19 (B BACKGROUND) output voltage. 0: Output voltage minimum (1.5V) 255: Output voltage maximum (5.5V) –8– CXA2153S Sub Address 0101 OSD GAIN (8) Controls the OSD gain common to the R, G and B channels. Since control is performed by multiplying with R/G/B DRIVE, the video white balance and tracking are obtained. 0: Gain minimum (0Vp-p) 255: Gain maximum (4.5Vp-p) Sub Address 0110 G2 (8) Controls Pin 18 (G2) output voltage. 0: Output voltage minimum (1.5V) 255: Output voltage maximum (5.5V) Sub Address 0111 R_DRV (8) Controls the gain for the R channel. Control is performed by multiplying with CONTRAST. Use this for adjusting the white balance. 0: Output level minimum (0Vp-p) 255: Output level maximum (4.4Vp-p; with 0.7Vp-p input) Sub Address 1000 G_DRV (8) Controls the gain for the G channel. Control is performed by multiplying with CONTRAST. Use this for adjusting the white balance. 0: Output level minimum (0Vp-p) 255: Output level maximum (4.4Vp-p; with 0.7Vp-p input) Sub Address 1001 B_DRV (8) Controls the gain for the B channel. Control is performed by multiplying with CONTRAST. Use this for adjusting the white balance. 0: Output level minimum (0Vp-p) 255: Output level maximum (4.4Vp-p; with 0.7Vp-p input) Sub Address 1010 SHP WIDTH (2) Controls the sharpness time constant switching. 0: OFF 1: 25ns 2: 50ns 3: 100ns Sub Address 1010 SHP GAIN (4) Controls the sharpness gain. 0: Gain minimum (0dB) F: Gain maximum (6dB) ∗ Amplitude at SHP OFF is assumed to be 0dB. Sub Address 1011 POL1 (1) Controls the polarity of the correction at GAMMA1. 0: – correction 1: + correction Sub Address 1011 GAMMA1 (2) Controls the gain of the inflection point 1 (15 IRE) at GAMMA. 0: 0 IRE correction 3: 9 IRE correction Sub Address 1011 POL2 (1) Controls the polarity of the correction at GAMMA2. 0: – correction 1: + correction –9– CXA2153S Sub Address 1011 GAMMA2 (4) Controls the gain of the inflection point 2 (60 IRE) at GAMMA. 0: 0 IRE correction 7: 20 IRE correction Sub Address 1100 VDET LVL (1) Controls the signal detection (VDET) slice level. 0: Slice level (160mV when RIN or GIN or BIN) 1: Slice level (200mV when RIN or GIN or BIN) Sub Address 1100 VDET OFF (1) Controls the video detection output. 0: Output on 1: Output off Sub Address 1100 SOG OFF (1) Controls the sync separator output. 0: Output on 1: Output off Sub Address 1100 GM OFF (1) Controls the gamma function operation. 0: Gamma on 1: Gamma off Sub Address 1100 D R OFF (1) Controls the VBLK synchronous DAC refresh function. The operation of this function is set to OFF when the power is turned on. 0: Function operation on 1: Function operation off – 10 – CXA2153S I2C BUS Logic System No. Item Symbol Min. Typ. Max. Unit 1 High level input voltage VIH 3.0 — 5.0 V 2 Low level input voltage VIL 0 — 1.5 V 3 Low level output voltage SDA during current inflow of 3mA VOL 0 — 0.4 V 4 Maximum clock frequency fSCL 0 — 400 kHz 5 Minimum waiting time for data change 1.3 — — µs 6 Minimum waiting time for data transfer start 0.6 — — µs 7 Low level clock pulse width 1.3 — — µs 8 High level clock pulse width 0.6 — — µs 9 Minimum waiting time for start preparation 0.6 — — µs 10 Minimum data hold time 0 — 900 ns 11 Maximum data preparation time 100 — — ns 12 Rise time — — 1 µs 13 Fall time — — 300 ns 14 Minimum waiting time for stop preparation tBUF tHD; STA tLOW tHIGH tSU; STA tHD; DAT tSU; DAT tR tF tSU; STO 0.6 — — µs – 11 – CXA2153S Electrical Characteristics No. Measurement item Symbol Measurement contents Min. Typ. Max. Unit Vcc5 (5V) pin inflow current RGB signal input: None 38 55 73 mA Current consumption Icc2 (12V) Vcc12 (12V) pin inflow current RGB signal input: None 28 42 57 mA Current consumption Icc3 (12V OFF) Pin inflow current when 12V OFF RGB signal input: None 3.4 4.9 6.6 mA Measure input rise time (TR1), input fall time (TF1), input rise time (TR2) and input fall time (TF2), then substitute these values into the following equations. 0.9 1.96 3 1 Current consumption (5V) 2 3 Icc1 TR TR = √(TR22 – TR12), TF = √(TF22 – TF12) (Contrast = 7F, DRIVE = FF, BRIGHTNESS = 7F) 4 Pulse characteristics TR∗ ns TF∗ VIDEO amplitude 90% 1.6 3.1 4.6 4 4.4 4.8 –100 0 120 mVp-p Calculate the difference in the data obtained –180 in No.5 and No.6 between the channels. 0 180 TF VIDEO amplitude 0% 5 Contrast control 1 GCONT1 Measure the level of the output signal amplitude Vout when a 0.7Vp-p video signal is input. GCONT1: Contrast = DRIVE = FF GCONT2: Contrast = 00/DRIVE = FF Vp-p Input signal 0.7Vp-p 6 Contrast control 2 GCONT2 7 Relative contrast GCONGAP – 12 – mV CXA2153S No. Measurement item Symbol Measurement contents Min. Typ. Max. Unit Measure the level of the output signal amplitude Vout when a 0.7Vp-p video signal is input. Contrast = FF/DRIVE = 00 8 Drive control GDRV –100 Input signal 0 120 mVp-p 0.7Vp-p GOSD1 9 Measure the OSD level of the output signal when the OSD pulse is input. GOSD1: OSD = FF/DRIVE = FF GOSD2: OSD = 00/DRIVE = FF 4 4.57 5.15 Vp-p OSD period OSD gain control RGB output signal OSD level –330 0 360 mVp-p Calculate the difference in the data obtained –200 in No.9 between the channels. 0 200 0.8 0.95 GOSD2 10 Relative OSD OSDGAP VBRT1 11 Brightness control Measure the black level of the RGB output signal. VBRT1: Brightness = 00 VBRT2: Brightness = FF 0.6 V RGB output signal Black level VBRT2 mV 2.5 2.93 3.28 GND 12 Relative brightness VBRTGAP Calculate the difference in the data obtained –200 in No.11 between the channels. 0 200 mV Measure the BLK level of the output signal when a BLK pulse is input. 13 BLK level 0.13 0.43 0.74 VBLK BLK level GND – 13 – V CXA2153S No. Measurement item Sync separator output rise delay Symbol Measurement contents Sync-IN SDLYR Min. Typ. Max. Unit 6.5 8.5 11 Vth = 50% 14 Fall Delay Rise Delay ns Vth = 50% Sync separator output fall delay SDLYF Sync-OUT 6.5 8.8 11 3.9 4 — Sync separator output Sync-Hi 15 Sync separator output V Sync-Lo Sync-Lo Sync-Hi — 0.2 0.45 — — 7.2 10 GND Sync separator 16 capacity VDET output rise delay SyncChk Gradually reduce the sync level when the duty is cycle 4.8% and 22.7% from 0.3Vp-p 0.24 and measure the sync level at which the sync signals can be separated. RGB input DDLYR 5.5 0.7Vp-p Vth = 50% 17 Rise Delay VDET output fall delay Vp-p Vth = 50% DDLYF ns Fall Delay 8.5 11.9 15.5 VDET output VDET-Hi VDET output 4 4.1 — 18 VDET output V VDET-Lo VDET-Lo VDET-Hi GND – 14 – — 0.25 0.4 CXA2153S No. Measurement item DAC output voltage (BKG = 00) Symbol VBKG1 Measurement contents Measure the DAC output voltage (Pin 20) when BKG = 00/FF. Min. Typ. Max. Unit 1.25 1.45 1.67 19 V DAC output voltage (BKG = FF) VBKG2 5.45 5.7 5.95 3.35 3.8 4.4 0.3 0.4 0.5 0.3 0.4 0.5 0.6 0.8 1.0 0.5 0.65 0.8 Input the crosshatch signal of Dot Clock 100MHz/ 0.7p-p to the RGB inputs, and measure the VDET output amplitude. VDET LEVEL = 0 20 VDET output amplitude VDET Input signal Vp-p 0.7Vp-p 10ns Sharpness gain 1 SHP1 21 Sharpness gain 2 SHP2 Input a 10MHz sin wave to RGB at an amplitude of 0.1Vp-p, and measure the output level. (CONTRAST: 7F/DRIVE: FF/ABL: 5V) SHP1: SHP GAIN = F/SHP SW = 0 SHP2: SHP GAIN = 0/SHP SW = 3 SHP3: SHP GAIN = F/SHP SW = 3 Input signal Sharpness gain 3 GAM2 22 Gamma correction GAM3 GAM4 Vp-p 0.1Vp-p CLP potential (approximately 3.1V) SHP3 GAM1 10ns Input 15 [IRE] and 60 [IRE] amplitude signals (100 [IRE] = 0.7Vp-p) to the RGB inputs, and measure the output amplitude. GAM1: GAMMA1 = 3/POL1 = 1, Vin = 0.105Vp-p GAM2: GAMMA1 = 3/POL1 = 0, Vin = 0.105Vp-p GAM3: GAMMA2 = F/POL2 = 1, Vin = 0.42Vp-p GAM4: GAMMA2 = F/POL2 = 0, Vin = 0.42Vp-p (CONTRAST: 7F/DRIVE: FF/ABL: 5V) – 15 – 0.05 0.15 0.25 Vp-p 1.8 2.1 2.4 0.8 1.0 1.25 CXA2153S Control Characteristics OSD GAIN Control Characteristics 5.0 4.5 4.5 4.0 4.0 3.5 3.5 Output level [Vp-p] Output level [Vp-p] CONTRAST Control Characteristics 5.0 3.0 2.5 2.0 1.5 3.0 2.5 2.0 1.5 1.0 1.0 0.5 0.5 0 0 32 64 96 0 128 160 192 224 256 0 32 64 CONTRAST data 96 128 160 192 224 256 OSD GAIN data DRIVE Control Characteristics BRIGHTNESS Control Characteristics 3.0 5.0 4.5 2.5 3.5 Output voltage [V] Output level [Vp-p] 4.0 3.0 2.5 2.0 1.5 2.0 1.5 1.0 1.0 0.5 0 0 32 64 0.5 96 128 160 192 224 256 DRIVE data 0 90 5.5 80 5.0 70 4.5 60 50 40 30 3.5 3.0 2.5 2.0 10 1.5 2 3 ABL pin voltage [V] 4 128 160 192 224 256 4.0 20 1 96 RGB BKG/G2 Control Characteristics 6.0 Output voltage [V] RGB output amplitude [%] ABL Control Characteristics 0 64 BRIGHTNESS data 100 0 32 1.0 5 – 16 – 0 32 64 96 128 160 192 224 256 Control data CXA2153S Frequency Characteristic 14 12 10 Output gain [dB] 8 6 4 2 0 –2 –4 1 10 100 Input frequency [MHz] – 17 – 1000 CXA2153S Electrical Characteristics Measurement Circuit 47µF 0.1µF 12V 1 RIN VCC12 30 2 VCC5 ROUT 29 3 GIN 4 SYNCIN 5 GND 6 BIN BOUT 25 7 ABL GND_B 24 8 OSD_BLK 47µF 75 0.1µF Rch Output 5V 0.1µF GND_R 28 0.1µF 75 Gch Output GOUT 27 0.1µF 75 GND_G 26 Bch Output 0.1µF 75 0.1µF 10µF VREF 23 220 OSD_R VCC12 22 10 OSD_G R_BKG 21 11 OSD_B G_BKG 20 9 47µF 12V 0.1µF DAC Output SYNC SEP Output B_BKG 19 12 SYNCOUT 13 CLP G2 18 14 BLK SCL 17 220 VDET Output SDA 16 15 VDET 220 – 18 – I2C Bus CXA2153S Electrical Characteristics Measurement Circuit (Frequency Response) 1k 47µF 0.1µF 12V 1 RIN VCC12 30 2 VCC5 ROUT 29 3 GIN 4 SYNCIN 5 GND 6 BIN BOUT 25 7 ABL GND_B 24 8 OSD_BLK 47µF 75 5V 1k 0.1µF Rch Output 0.1µF GND_R 28 0.1µF 75 Gch Output GOUT 27 0.1µF 1k GND_G 26 Bch Output 0.1µF 75 5V 0.1µF 10µF VREF 23 220 OSD_R VCC12 22 10 OSD_G R_BKG 21 11 OSD_B G_BKG 20 9 VREF 47µF 12V 0.1µF DAC Output SYNC SEP Output B_BKG 19 12 SYNCOUT 13 CLP G2 18 14 BLK SCL 17 220 VDET Output SDA 16 15 VDET 220 – 19 – I2C Bus CXA2153S Application Circuit 47µF 0.1µF Rch Input 12V 1 RIN VCC12 30 2 VCC5 ROUT 29 3 GIN 4 SYNCIN 5 GND 6 BIN BOUT 25 7 ABL GND_B 24 8 OSD_BLK 47µF 75 0.1µF Rch Output 0.1µF Gch Input GND_R 28 0.1µF Gch Output 75 GOUT 27 0.1µF GND_G 26 Bch Input Bch Output 0.1µF 75 0.1µF 10µF VREF 23 220 OSD_R VCC12 22 10 OSD_G R_BKG 21 11 OSD_B G_BKG 20 9 47µF 12V 0.1µF DAC Output SYNC SEP Output B_BKG 19 12 SYNCOUT 13 CLP G2 18 14 BLK SCL 17 220 VDET Output I2C Bus SDA 16 15 VDET 220 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. – 20 – CXA2153S Description of Operation 1. Sharpness function The RGB signals input to Pins 5, 7 and 10 are mixed at a ratio of 0.6G + 0.3R + 0.1B to form the Y signal. The high-frequency component is removed from this Y signal by a differentiation circuit, and the amplitude is controlled by a gain control circuit. The signal which undergoes gain control (sharpness component) has its amplitude clipped by a limiter circuit and is then added to the R, G and B signals. SHP GAIN = 0 (HEX) or SHP OFF = 1 No sharpness component Section not sent to RGB output because of the limiter 100% Limiter level = 30% (Typ.) SHP GAIN = F (HEX) 100% 10% 25ns (T SW = 1) ∗ The output level when RIN = GIN = BIN = 0.7Vp-p is set to 100%. 50ns (T SW = 2) 100ns (T SW = 3) 2. VBLK synchronous DAC refresh system The VBLK signal is removed from the composite BLK signal which has been input to Pin 14, and the data for each control DAC is overwritten all at once in synchronization with this VBLK signal. The received I2C bus data is held by a latch until the next VBLK signal arrives. As a result, I2C bus data transmission from the microcomputer is timing-free. Set the width of the V blanking pulse which is input to Pin 14 to 300µs or more. (See the next page) 3. Gamma correction function Using the output obtained when 700mVp-p RGB signals are input as a reference (100 [IRE]), the ±9 [IRE] (GAMMA1) and ±20 [IRE] (GAMMA2) waveforms can be corrected at the 15 [IRE] and 60 [IRE] inflection points, respectively. The polarity switching gain can be controlled separately for each point, enabling correction broken at two points. The I2C bus controls the polarity switching and gain correction. GAMMA1 GAMMA2 +20 [IRE] –20 [IRE] 100 [IRE] 100 [IRE] +9 [IRE] –9 [IRE] 0 15 [IRE] 100 [IRE] 0 – 21 – 60 [IRE] 100 [IRE] CXA2153S VBLK Synchronous DAC Refresh System VBLK Transmission period Bus data transmission Data group (2) Data group (1) Data group (3) enable DAC refresh enable signal disable DAC refresh signal The latest data which was sent before VBLK is written to the DAC. In this case the data in (1) is written. The DAC is not rewritten while the bus data in the VBLK period is being transmitted. The transmitted data is held. The data in (3) written. The data in (2) written, if (3) is not transmitted. The VBLK signal is extracted from the composite BLK signal which has been input to Pin 14, and the DAC data for each control is rewritten all at once in synchronization with this VBLK signal. The received I2C bus data is held by a latch until the next VBLK signal arrives. Therefore, I2C bus data transmission from the microcomputer is timing-free. Set the width of the V blanking pulse which is input to Pin 14 to 300µs or more. Operation during power saving (Pin 22, VCC12 OFF) Only the sync separator function operates. All the other functions are shut down. – 22 – CXA2153S Notes on Operation 1. 2. 3. Set the output for ROUT, GOUT and BOUT for reception at high impedance. Make the wiring from ROUT, GOUT and BOUT to the power amplifier as short as possible. Connect the Vcc5, Vcc12 and VREF decoupling capacitors so that the ceramic capacitor and electrolytic capacitor are connected in parallel and the distance from the IC is less than 3mm. 4. Connect the clamp capacitors for RIN, GIN and BIN so that the distance from the IC is as short as possible. 5. Input the signals to RIN, GIN and BIN at low impedance via a clamp capacitor. 6. Set the output to OFF when the VDET/CSYNC output is not used. (Otherwise, this may cause the crosstalk to deteriorate.) 7. The VREF output cannot be used as an external power supply. 8. Turn the power on in the order of 5V → 12V, and off in the order of 12V → 5V. (Be sure to observe this order particularly during power-off, otherwise spots may remain on the screen.) 9. When applying blanking to the video period, the blanking pulse input to the BLK pin should have a high level of 4.7V or more. 10. When not using the sync separation function, connect the Sync In pin to GND through a capacitor, and set SOG_OFF = 1 (bus setting). 11. When there is no clamp pulse input to Pin 13 (CLP), the output potential rises. Always input a clamp pulse. – 23 – CXA2153S Package Outline Unit: mm + 0.1 .05 0.25 – 0 30PIN SDIP (PLASTIC) + 0.4 26.9 – 0.1 30 + 0.3 8.5 – 0.1 10.16 16 0° to 15° 15 1 + 0.4 3.7 – 0.1 0.5 MIN 1.778 0.5 ± 0.1 3.0 MIN Two kinds of package surface: 1.All mat surface type. 2.All mirror surface type. 0.9 ± 0.15 PACKAGE STRUCTURE MOLDING COMPOUND EPOXY RESIN PALLADIUM PLATING SONY CODE SDIP-30P-01 LEAD TREATMENT EIAJ CODE P-SDIP30-8.5x26.9-1.778 LEAD MATERIAL COPPER ALLOY PACKAGE MASS 1.8g JEDEC CODE – 24 – Sony Corporation