M61303FP I2C BUS Controlled 3channel Video Pre-amplifier for LCD Display Monitor REJ03F0198-0200 Rev.2.00 Sep 14, 2006 Description M61303FP is integrated circuit for LCD display monitor. It is controlled I2C BUS and band wide is 180 MHz. It includes OSD blanking, OSD mixing, wide band amplifier, main/sub contrast, main/sub brightness, and 2 input routes. VCC voltage is 5 V and flat package is used. Then it is the suitable to LCD monitor. Features • Frequency band width: RGB 180 MHz (at −3 dB) OSD 80 MHz • Input: RGB input dynamic range Max 1 VP-P positive 2 input routes is changed by I2C BUS RGB OSD 3.5 VP-P to 5.0 VP-P (positive) OSD BLK 3.5 VP-P to 5.0 VP-P (positive) Output: RGB 2.2 VP-P (Max) OSD 2.0 VP-P (Max) Output dynamic range 0.5 to 2.2 V It can drive 14 pF • Contrast: Both of sub and main contrast are controlled by I2C BUS (8 bit). Control range: −15 dB to +15 dB. • Brightness: Both of sub and main contrast are controlled by I2C BUS (8 bit). Control range: 0.5 V to 2.2 V. • OSD adjust: 2 control ranges (Max 1 VP-P or Max 2 VP-P) are able to be changed by I2C BUS. Recommended Operating Conditions Supply voltage range: 4.7 V to 5.3 V Rated supply voltage: 5.0 V Consumption of electricity: 800 mW Rev.2.00 Sep 14, 2006 page 1 of 24 M61303FP Block Diagram R VCC1 (5 V) G VCC1 (5 V) B VCC1 (5 V) OSD BLK IN 41 36 31 27 R OSD IN 26 1 R VCC2 (5 V) R INPUT1 42 Clamp R INPUT2 40 Clamp Contrast R GND1 Input select 39 OSD 37 Clamp G INPUT2 35 Clamp Contrast G GND1 Input select 34 OSD 32 Clamp B INPUT2 30 Clamp Contrast B GND1 29 Input select Analog VCC (5 V) 14 Sub cont (8 bit) Main contrast 8 bit 13 Input select 1 bit Analog Gnd 16 Clamp Pulse IN Rev.2.00 Sep 14, 2006 page 2 of 24 OSD OSD SW (1 bit) OSD level (4 bit) Amp 5 G OUTPUT (2.2 VP-P) DAC Amp Clamp F/B R GND2 4 G VC C2 (5 V) Clamp F/B G sub BRT (8 bit) Sub cont (8 bit) B OSD IN 24 B INPUT1 3 Clamp F/B R sub BRT (8 bit) Sub cont (8 bit) G OSD IN 25 G INPUT1 2 R OUTPUT (2.2 VP-P) Amp 6 G GND2 8 B VCC2 (5 V) 9 B OUTPUT (2.2 VP-P) 10 B GND2 Main BRT (8 bit) B sub BRT (8 bit) 21 Digital VCC (5 V) Bus I/F 19 SDA 20 SCL 18 Digital GND M61303FP Pin Arrangement M61303FP R VCC2 1 42 R INPUT1 R OUTPUT 2 41 R VCC1 R GND2 3 40 R INPUT2 G VCC2 4 39 R GND1 G OUTPUT 5 38 GND G GND2 6 37 G INPUT1 GND 7 36 G VCC1 B VCC2 8 35 G INPUT2 B OUTPUT 9 34 G GND1 B GND2 10 33 GND GND 11 32 B INPUT1 GND 12 31 B VCC1 Analog Gnd 13 30 B INPUT2 Analog VCC 14 29 B GND1 GND 15 28 GND Clamp Pulse IN 16 27 OSD BLK IN GND 17 26 R OSD IN Digital GND 18 25 G OSD IN SDA 19 24 B OSD IN SCL 20 23 GND Digital VCC 21 22 GND (Top view) Outline: PRSP0042GB-B (42P9R-B) Rev.2.00 Sep 14, 2006 page 3 of 24 M61303FP Absolute Maximum Ratings (Ta = 25°C) Item Symbol Supply voltage VCC Ratings 6.0 Power dissipation Ambient temperature Storage temperature Recommended supply Pd Topr Tstg Vopr 2900 −20 to +85 −40 to +150 5.0 mW °C °C V Voltage range Vopr' 4.7 to 5.3 V Thermal Derating Curve 3.0 Power Dissipation Pd (mW) 2.9 2.0 1.5 1.0 0 −25 0 25 50 75 85 100 125 Ambient Temperature Ta (°C) Rev.2.00 Sep 14, 2006 page 4 of 24 150 Unit V M61303FP BUS Control Table (1) Slave address: D7 1 D6 0 D5 0 D4 0 D3 1 D2 0 D1 0 R/W 0 = 88H (2) Each function's sub address: Bit Sub Add. Main contrast 8 00H Sub contrast R 8 01H Sub contrast G 8 02H Sub contrast B 8 03H Main bright 8 04H Sub bright R 8 Sub bright G Function Data Byte D7 A07 0 A17 1 A27 1 A37 1 A47 1 D6 A06 1 A16 0 A26 0 A36 0 A46 0 D5 A05 0 A15 0 A25 0 A35 0 A45 0 D4 A04 0 A14 0 A24 0 A34 0 A44 0 D3 A03 0 A13 0 A23 0 A33 0 A43 0 D2 A02 0 A12 0 A22 0 A32 0 A42 0 D1 A01 0 A11 0 A21 0 A31 0 A41 0 D0 A00 0 A10 0 A20 0 A30 0 A40 0 05H A57 1 A56 0 A55 0 A54 0 A53 0 A52 0 A51 0 A50 0 8 06H Sub bright B 8 07H OSC level 4 08H INPUT SW 1 09H OSD SW 1 0AH A67 1 A77 1 ⎯ 0 ⎯ 0 ⎯ 0 A66 0 A76 0 ⎯ 0 ⎯ 0 ⎯ 0 A65 0 A75 0 ⎯ 0 ⎯ 0 ⎯ 0 A64 0 A74 0 ⎯ 0 ⎯ 0 ⎯ 0 A63 0 A73 0 A83 0 ⎯ 0 ⎯ 0 A62 0 A72 0 A82 0 ⎯ 0 ⎯ 0 A61 0 A71 0 A81 0 ⎯ 0 ⎯ 0 A60 0 A70 0 A80 0 A90 0 AA0 0 Rev.2.00 Sep 14, 2006 page 5 of 24 M61303FP I2C BUS Control Section SDA, SCL Characteristics Item Min. input LOW voltage Max. input HIGH voltage SCL clock frequency Time the bus must be free before a new transmission can start Hold time start condition. After this period the first clock pulse is generated The LOW period of the clock The HIGH period of the clock Set up time for start condition (Only relevant for a repeated start condition) Hold time DATA Set-up time DATA Rise time of both SDA and SCL lines Fall time of both SDA and SCL lines Set-up time for stop condition Symbol VIL VIH fSCL tBUF tHD:STA tLOW tHIGH tSU:STA tHD:DAT tSU:DAT tr tf tSU:STO Min. −0.5 3.0 0 4.7 4.0 4.7 4.0 4.7 0 250 ⎯ ⎯ 4.0 Max. 1.5 5.5 100 ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ 1000 300 ⎯ tr, tf Unit V V kHz μs μs μs μs μs μs ns ns ns μs tBUF VIL SDA VIH tHD: STA tSU: DAT tHD: DAT tSU: STA tSU: STO VIL SCL VIH tLOW S Rev.2.00 Sep 14, 2006 page 6 of 24 tHIGH S P S M61303FP Electrical Characteristics If SW connect is not designated RGB Input SW: SW (30, 35, 40) = a (b) SW (32, 37, 42) = b (a), SW (2, 5, 9, 16, 19, 20, 24, 25, 26, 27) = a (VCC = 5 V, Ta = 25°C) Limits Item ICC1 ⎯ Output dynamic range Vomax 2.2 Maximum input1 Vimax1 1.0 Circuit current1 Maximum input2 Vimax2 1.0 Maximum gain GV Relative maximum gain Main contrast control characteristics1 Main contrast control characteristics2 Main contrast control characteristics3 Sub contrast control characteristics1 Sub contrast control characteristics2 Sub contrast control characteristics3 Main/sub contrast control characteristics Main brightness control characteristics1 Main brightness control characteristics2 Sub brightness control characteristics1 Sub brightness control characteristics2 Sub brightness control characteristics3 Frequency characteristics1 (50 MHz-2 VP-P) Frequency relative characteristics1 (180 MHz-2 VP-P) Frequency characteristics2 (50 MHz-2 VP-P) Frequency relative characteristics2 (50 MHz-2 VP-P) Frequency characteristics3 (180 MHz-1 VP-P) BUS CTL (H) Test Point Symbol Min. Typ. Max. Unit (s) ΔGV VC1 VC2 155 ⎯ ⎯ ⎯ 185 ⎯ ⎯ ⎯ 11.9 13.9 15.9 0.8 6.4 2.3 1.0 7.9 4.1 1.2 9.4 5.9 mA IA VP-P OUT RGB Input Signal ⎯ SG2 SW Connect RGB Input SW = a (All) ⎯ VP-P IN OUT SG2 Amplitude Variable VP-P IN OUT SG2 Amplitude Variable SW (30, 35, 40) = b SW (32, 37, 42) = a dB OUT SG1 ⎯ ⎯ dB dB ⎯ OUT OUT 00H 01H Main Sub Cont Cont 1 02H Sub Cont 2 03H Sub Cont 3 04H Main brt 05H Sub brt 1 06H Sub brt 2 07H Sub brt 3 08H 09H OSD Input Adj SW A6H A6H A6H A6H 00H 00H 00H 00H 00H 166 166 166 166 0 0 0 0 0 vari- vari- vari- vari- able able able able 7FH 7FH 7FH 7FH 40H 7FH 7FH 7FH 127 127 127 127 64 127 127 127 ⎯ VSC1 VSC2 VSC3 VMSC VB1 VB2 0.2 6.3 2.6 0.2 1.7 1.3 0.4 0.4 7.8 4.3 0.4 2.0 1.7 0.6 0.6 FFH FFH FFH 255 255 255 255 ⎯ ⎯ ⎯ ⎯ ⎯ SG1 C8H 7FH 7FH 7FH 200 127 127 127 ⎯ ⎯ ⎯ ⎯ 64H SG1 9.4 6.0 0.6 2.3 2.0 0.8 VP-P OUT SG1 OUT SG1 dB dB OUT ⎯ VP-P OUT SG1 V OUT OUT ⎯ 7FH C8H C8H C8H 127 200 200 200 64H 64H 64H 100 100 100 00H 00H 00H 0 0 0 A6H A6H A6H A6H 166 166 166 166 A6H A6H A6H A6H 7FH 166 166 166 166 127 SG1 SG1 V 00H 0 VP-P OUT ⎯ RGB Input SW = a (All) ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ 00H ⎯ 0 VSB1 VSB2 VSB3 FC1 1.7 1.3 0.7 −3.0 2.2 1.7 1.0 0 2.6 2.0 1.3 3.0 V V V dB OUT OUT OUT OUT ⎯ ⎯ −4.0 −3.0 1.0 dB OUT SG3 ΔFC2 −1.0 0 1.0 dB ⎯ ⎯ FC3 −1.0 0 1.0 dB OUT SG3 Frequency relative characteristics3 (180 MHz-1 VP-P) ΔFC3 −1.0 0 1.0 dB ⎯ ⎯ Frequency characteristics4 FC4 −4.0 −3.0 1.0 dB OUT SG3 SW (2, 5, 9) = b ΔFC4 −1.0 1.0 dB ⎯ ⎯ ⎯ dB 255 7FH 7FH 7FH 127 127 127 00H 00H 00H 0 0 0 ⎯ ⎯ ⎯ 40H 7FH 7FH 7FH 00H 64 127 127 127 0 A6H 37H (180 MHz-2 VP-P-Cap) Rev.2.00 Sep 14, 2006 page 7 of 24 FFH 255 able 55 (180 MHz-2 VP-P-Cap) FFH 255 vari- 166 0 FFH 127 ⎯ FC2 1.0 7FH ⎯ −1.0 0 ⎯ ⎯ SG3 ⎯ ⎯ 100 VC3 Remark ⎯ FFH ΔFC1 Frequency relative characteristics4 ⎯ 0AH OSD SW A6H 166 ⎯ ⎯ reference M61303FP Electrical Characteristics (cont.) Limits Item BUS CTL (H) Symbol Min. Typ. Max. Unit ⎯ −35 −30 dB Test Point (s) RGB Input Signal OUT (2) OUT (5) OUT (9) OUT (2) OUT (5) OUT (9) OUT (2) OUT (5) OUT (9) OUT (2) OUT (5) OUT (9) SG3 00H 01H Main Sub Cont Cont SW Connect 1 SW (42) = b, Other SW = a A6H A6H 02H Sub Cont 2 A6H 03H 04H Sub Main Cont brt 3 A6H 40H 05H Sub brt 1 7FH 06H Sub brt 2 7FH 07H Sub brt 3 7FH SW (37) = b, Other SW = a 166 SW (32) = b, Other SW = a 166 166 127 127 127 08H 09H 0AH OSD Input OSD Adj SW SW 00H 00H 0 0 ⎯ Remark refer- Crosstalk1 input1-2 50 MHz-1 INCT1 Crosstalk1' input1-2 50 MHz-1 INCT1' ⎯ −15 −10 dB Crosstalk2 input1-2 50 MHz-2 INCT2 ⎯ −35 −30 dB Crosstalk2' input1-2 50 MHz-2 INCT2' ⎯ −15 −10 dB Crosstalk1 between RGB ch 50 MHz-1 Crosstalk1' between RGB ch 180 MHz-1 Crosstalk2 between RGB ch 50 MHz-2 Crosstalk2' between RGB ch 180 MHz-2 Crosstalk3 between RGB ch 50 MHz-3 Crosstalk3' between RGB ch 50 MHz-3 Pulse characteristics Tr1 Relative pulse characteristics Tr1 Pulse characteristics Tf1 Relative pulse characteristics Tf1 Pulse characteristics Tr2 Relative pulse characteristics Tr2 Pulse characteristics Tf2 Relative pulse characteristics Tf2 Clamp pulse threshold voltage Clamp pulse minimum width OSD pulse characteristics Tr OSD pulse characteristics Tf OSD adjust control characteristics1 OSD adjust control characteristics2 OSD adjust control relative characteristics2 OSD adjust control characteristics3 OSD adjust control relative characteristics3 OSD adjust control characteristics4 OSD adjust control characteristics5 OSD adjust control relative characteristics5 CHCT1 ⎯ −25 −20 dB OUT SG3 CHCT1' ⎯ −15 −10 dB OUT SG3 CHCT2 ⎯ −25 −20 dB OUT SG3 CHCT2' ⎯ −15 −10 dB OUT SG3 CHCT3 ⎯ −25 −20 dB OUT SG3 CHCT3' ⎯ −15 −10 dB OUT SG3 Tr1 ⎯ 1.1 ⎯ ns OUT SG1 −0.8 0.0 0.8 ns ⎯ ⎯ 1.1 ⎯ ⎯ OUT SG1 −0.8 0.0 0.8 ⎯ ⎯ ⎯ 2.0 ⎯ ns OUT SG1 SW (2, 5, 9) = b −0.8 0.0 0.8 ns ⎯ ⎯ ⎯ 2.0 ⎯ ⎯ OUT SG1 SW (2, 5, 9) = b ΔTf2 −0.8 0.0 0.8 ⎯ ⎯ ⎯ ⎯ VthCP 1.5 2.0 2.5 V OUT SG1 ⎯ ⎯ WCP 0.2 0.5 ⎯ μs OUT SG1 ⎯ ⎯ OTr ⎯ 3.0 6.0 ns OUT ⎯ SW (24, 25, 26, 27) = b ΔTr1 Tf1 ΔTf1 Tr2 ΔTr2 Tf2 ⎯ ⎯ ⎯ SG3 3.0 6.0 ns ⎯ ⎯ Oaj1 0 0 0.2 VP-P OUT ⎯ 1.2 1.5 ΔOaj2 0.75 1.0 1.25 Oaj3 1.8 ΔOaj3 Oaj4 Oaj5 ΔOaj5 2.1 2.5 0.75 1.0 1.25 0 0.4 0 0.6 0.2 0.8 0.75 1.0 1.25 Rev.2.00 Sep 14, 2006 page 8 of 24 VP-P OUT ence SW (40) = b, Other SW = a SW (35) = b, Other SW = a SW (30) = b, Other SW = a 01H SW (42) = b, Other SW = a ⎯ 1 SG3 ⎯ 0.9 64 SG3 OTf Oaj2 166 ⎯ SW (37) = b, Other SW = a SW (32) = b, Other SW = a ⎯ 00H 00H 00H 00H 40H 7FH 7FH 7FH 0FH 00H refer- 0 0 0 0 64 127 127 127 15 0 ence A6H A6H A6H A6H 00H 00H ⎯ 166 166 166 166 0 0 01H 00H 1 0 ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ VP-P OUT ⎯ 0FH 00H ⎯ 15 0 ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ VP-P OUT ⎯ 00H 01H ⎯ 0 1 01H 01H 1 1 ⎯ ⎯ VP-P ⎯ OUT ⎯ ⎯ ⎯ ⎯ ⎯ M61303FP Electrical Characteristics (cont.) Limits Item BUS CTL (H) Test Point (s) RGB Input Signal VP-P OUT ⎯ ⎯ Symbol Min. Typ. Max. Unit 0.9 1.2 1.5 SW Connect SW (24, 25, 26, 27) = b 00H 01H Main Sub Cont Cont 1 A6H A6H 02H Sub Cont 2 A6H 03H Sub Cont 3 A6H 04H Main brt 40H 05H Sub brt 1 7FH 06H Sub brt 2 7FH 07H Sub brt 3 7FH 166 166 166 64 127 127 127 08H 09H 0AH OSD Input OSD Adj SW SW 0FH Remark 01H ⎯ OSD adjust control characteristics6 OSD adjust control relative characteristics6 OSD BLK characteristics Oaj6 OSD BLK relative characteristics ΔOBLK −0.15 0.0 0.15 V ⎯ ⎯ OSD input threshold voltage VthOSD 2.0 V OUT ⎯ OSD BLK input threshold voltage VthBLK 2.0 2.5 3.0 V OUT SG1 SW (27) = b Pin 19 Input current H I19H −1.0 0.0 ⎯ μA I19 ⎯ SW (19) = b V19 = 5 V Pin 19 Input current L I19L 0.6 2.0 μA I19 ⎯ SW (19) = b V19 = 0 V Pin 20 Input current H I20H −1.0 0.0 ⎯ μA I20 ⎯ SW (20) = b V20 = 5 V Pin 20 Input current L I20L 0.6 2.0 μA I20 ⎯ SW (20) = b V20 = 0 V Pin 24, 25, 26 Input current H IOSDH −2.0 −1.3 ⎯ mA ⎯ SW (24, 25, 26) = b VOSD = 5 V ⎯ Pin 24, 25, 26 Input current L IOSDL 1.3 2.0 mA I24 I25 I26 I24 I25 I26 ⎯ SW (24, 25, 26) = b VOSD = 0 V ⎯ Pin 27 Input current H I27H −2.0 −1.3 ⎯ mA I27 ⎯ SW (27) = b V27 = 5 V Pin 27 Input current L I27L 2.0 mA I27 ⎯ SW (27) = b V27 = 0 V ΔOaj6 0.75 1.0 1.25 ⎯ OBLK 0.0 VP-P OUT ⎯ ⎯ ⎯ ⎯ 0.1 0.3 2.5 1.3 3.0 166 ⎯ 15 ⎯ ⎯ ⎯ 1 ⎯ ⎯ ⎯ SW (24, 25, 26) = a SW (27) = b ⎯ SW (24, 25, 26, 27) = a 0FH 00H 15 0 ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ ⎯ Electrical Characteristics Test Method ICC1 Circuit Current1 Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IA. Vomax Output Dynamic Range Decrease main bat or sub bat gradually, and measure the voltage when the bottom of waveform output is distorted. The voltage is called VOL. Next, increase V30 gradually, and measure the voltage when the top of waveform output is distorted. The voltage is called VOH. Voltage Vomax is calculated by the equation below: Vomax = VOH − VOL (V) VOH Waveform output VOL 0.0 Rev.2.00 Sep 14, 2006 page 9 of 24 M61303FP Vimax1 Maximum Input1 Increase the input signal (SG2) at Input1 amplitude gradually, starting from 700 mVP-P. Measure the amplitude of the input signal when the output signal starts becoming distorted. Vimax2 Maximum Input2 Increase the input signal (SG2) at Input amplitude gradually, starting from 700 mVP-P. Measure the amplitude of the input signal when the output signal starts becoming distorted. GV Maximum Gain Input SG1, and read the amplitude output at OUT (2, 5, 9). The amplitude is called VOUT (2, 5, 9). Maximum gain GV is calculated by the equation below: GV = 20log VOUT 0.7 (dB) ΔGV Relative Maximum Gain Relative maximum gain ΔGV is calculated by the equation below: ΔGV = VOUT (2) / VOUT (5), VOUT (5) / VOUT (9), VOUT (9) / VOUT (2) VC1 Main Contrast Control Characteristics1 Measuring the amplitude output at OUT (2, 5, 9). The measured value is called VOUT (2, 5, 9). VC1 = 20log VOUT 0.7 (dB) VC2 Main Contrast Control Characteristics2 Measuring condition and procedure are the same as described in VC1. VC3 Main Contrast Control Characteristics3 Measuring condition and procedure are the same as described in VC1. VSC1 Sub Contrast Control Characteristics1 Measuring condition and procedure are the same as described in VC1. VSC2 Sub Contrast Control Characteristics2 Measuring condition and procedure are the same as described in VC1. VSC3 Sub Contrast Control Characteristics3 Measuring condition and procedure are the same as described in VC1. VMSC Main/sub Contrast Control Characteristics Measuring condition and procedure are the same as described in VC1. Rev.2.00 Sep 14, 2006 page 10 of 24 M61303FP VB1 Main Brightness Control Characteristics1 Measure the DC voltage output at OUT (2, 5, 9). The measured value is called VB1. VB2 Main Brightness Control Characteristics2 Measuring condition and procedure are the same as described in VB1. VSB1 Sub Brightness Control Characteristics1 Measuring condition and procedure are the same as described in VB1. VSB2 Sub Brightness Control Characteristics2 Measuring condition and procedure are the same as described in VB1. VSB3 Sub Brightness Control Characteristics3 Measuring condition and procedure are the same as described in VB1. FC1 Frequency Characteristics1 (50 MHz-2 VP-P) First, SG3 to 1 MHz is as input signal. Control the main contrast in order that the amplitude of sine wave output is 2.0 VP-P. Control the brightness in order that the bottom of sine wave output is 1.0 V. By the same way, measure the output amplitude when SG3 to 50 MHz is as input signal. The measured value is called VOUT (2, 5, 9). Frequency characteristics FC1 (2, 5, 9) is calculated by the equation below: FC1 = 20log VOUT VP-P Output amplitude when inputted SG3 (1 MHz): 2.0 VP-P (dB) ΔFC1 Frequency Relative Characteristics1 (180 MHz-2 VP-P) Relative characteristics ΔFC1 is calculated by the difference in the output between the channels. FC2 Frequency Characteristics2 (50 MHz-2 VP-P) Measuring condition and procedure are the same as described in FC1, expect SG3. ΔFC2 Frequency Relative Characteristics2 (50 MHz-2 VP-P) Relative characteristics ΔFC2 is calculated by the difference in the output between the channels. FC3 Frequency Characteristics3 (180 MHz-1 VP-P) SG3 to 1 MHz is as input signal. Control the main contrast in order that the amplitude of sine wave output is 1.0 VP-P. By the same way, measure the output amplitude when SG3 to 180 MHz is as input signal. ΔFC3 Frequency Relative Characteristics3 (180 MHz-1 VP-P) Relative characteristics ΔFC3 is calculated by the difference in the output between the channels. FC4 Frequency Characteristics4 (180 MHz-2 VP-P-Cap) Change OUT SW from a to b. Measuring condition and procedure are the same as described in FC1. ΔFC4 Frequency Relative Characteristics4 (180 MHz-2 VP-P-Cap) Relative characteristics ΔFC4 is calculated by the difference in the output between the channels. Rev.2.00 Sep 14, 2006 page 11 of 24 M61303FP INCT1 Crosstalk1 Input1-2 50 MHz-1 Input SG3 (50 MHz) to pin 42 only, set Input SW of I2C BUS to 0 and then measure the waveform amplitude output at OUT (2). The measured value is called VOUT (2). On equal terms set Input SW of I2C BUS to 1. And then measure the waveform amplitude output at OUT (2)'. Crosstalk INCT1 is calculated by the equation below: INCT1 = 20log VOUT (2)' VOUT (2) (dB) Similarly measure the waveform amplitude output at OUT (5) when signal input only pin 37 and OUT when signal input only pin 32 and calculate crosstalk. INCT1' Crosstalk1' Input1-2 50 MHz-1 Measuring condition and procedure are the same as described in INCT1, expect SG3 to 180 MHz. INCT2 Crosstalk2 Input1-2 50 MHz-1 Input SG3 (50 MHz) to pin 40 only, set Input SW of I2C BUS to 1 and then measure the waveform amplitude output at OUT (2). The measured value is called VOUT (2). On equal terms set Input SW of I2C BUS to 0. And then measure the waveform amplitude output at OUT (2)'. Crosstalk INCT2 is calculated by the equation below: INCT2 = 20log VOUT (2)' VOUT (2) (dB) Similarly measure the waveform amplitude output at OUT (5) when signal input only pin 35 and OUT when signal input only pin 30 and calculate crosstalk. INCT2' Crosstalk2' Input1-2 50 MHz-1 Measuring condition and procedure are the same as described in INCT2, expect SG3 to 180 MHz. CHCT1 Crosstalk1 between RGB Ch 50 MHz-1 Input SG3 (50 MHz) to pin 42 only, and then measure the waveform amplitude output at OUT (2, 5, 9). The measured value is called VOUT (2, 5, 9). Crosstalk CHCT1 is calculated by the equation below: CHCT1 = 20log VOUT (5, 9) VOUT (2) (dB) CHCT1' Crosstalk1' between RGB Ch 180 MHz-1 Measuring condition and procedure are the same as described in CHCT1, expect SG3 to 180 MHz. CHCT2 Crosstalk2 between RGB Ch 50 MHz-2 Input SG3 (50 MHz) to pin 37 only, and then measure the waveform amplitude output at OUT (2, 5, 9). The measured value is called VOUT (2, 5, 9). Crosstalk CHCT2 is calculated by the equation below: CHCT2 = 20log VOUT (2, 9) VOUT (5) (dB) CHCT2' Crosstalk2' between RGB Ch 180 MHz-2 Measuring condition and procedure are the same as described in CHCT2, expect SG3 to 180 MHz. CHCT3 Crosstalk3 between RGB Ch 50 MHz-3 Input SG3 (50 MHz) to pin 32 only, and then measure the waveform amplitude output at OUT (2, 5, 9). The measured value is called VOUT (2, 5, 9). Crosstalk CHCT3 is calculated by the equation below: CHCT3 = 20log VOUT (2, 5) VOUT (9) (dB) CHCT3' Crosstalk3' between RGB Ch 50 MHz-3 Measuring condition and procedure are the same as described in CHCT3, expect SG3 to 180 MHz. Rev.2.00 Sep 14, 2006 page 12 of 24 M61303FP Tr1 Pulse Characteristics1 Tr1 Control the contrast in order that the amplitude of output signal is 2.0 VP-P. Control the brightness in order that the Black level of output signal is 1.0 V. Measure the time needed for the input pulse to rise from 10% to 90% (Trin) and for the output pulse to rise from 10% to 90% (Trout) with an active probe. Pulse characteristics Tr1 is calculated by the equations below: Tr1 = √ (Trin)2 − (Trout)2 (ns) ΔTr1 Relative Pulse Characteristics1 Tr1 Relative Pulse characteristics ΔTr1 is calculated by the equation below: ΔTr1 = VOUT (2) − VOUT (5), VOUT (5) − VOUT (9), VOUT (9) − VOUT (2) Tf1 Pulse Characteristics1 Tf1 Measure the time needed for the input pulse to fall from 90% to 10% (Tfin) and for the output pulse to fall from 90% to 10% (Tfout) with an active probe. Pulse characteristics Tf1 is calculated by the equations below: Tf1 = √ (Tfin)2 − (Tfout)2 (ns) ΔTf1 Relative Pulse Characteristics1 Tf1 Relative Pulse characteristics ΔTf1 is calculated by the equation below: ΔTf1 = VOUT (2) − VOUT (5), VOUT (5) − VOUT (9), VOUT (9) − VOUT (2) 100% 90% 10% 0% Trin or Trout Tfin or Tfout Tr2 Pulse Characteristics2 Tr2 Change SW (2, 5, 9) from (a) to (b). Measuring condition and procedure are the same as described in Tr1. ΔTr2 Relative Pulse Characteristics2 Tr2 Measuring condition and procedure are the same as described in ΔTr1, except of SW (2, 5, 9) condition. Tf2 Pulse Characteristics2 Tf2 Change SW (2, 5, 9) from (a) to (b). Measuring condition and procedure are the same as described in Tf1. ΔTf2 Relative Pulse Characteristics2 Tf2 Measuring condition and procedure are the same as described in ΔTf1, except of SW (2, 5, 9) condition. Rev.2.00 Sep 14, 2006 page 13 of 24 M61303FP VthCP Clamp Pulse Threshold Voltage Reduce the SG4 input level gradually from 5.0 VP-P, monitoring the waveform output. Measure the top level of input pulse when the output pedestal voltage turn decrease with unstable. WCP Clamp Pulse Minimum Width Decrease the SG4 pulse width gradually from 0.5 μs, monitoring the output. Measure the SG4 pulse width (a point of 1.5 V) when the output pedestal voltage turn decrease with unstable. OTr OSD Pulse Characteristics Tr Measure the time needed for the output pulse to rise from 10% to 90% (OTr) with an active probe. OTf OSD Pulse Characteristics Tf Measure the time needed for the output pulse to fall from 90% to 10% (OTf) with an active probe. Oaj1 OSD Adjust Control Characteristics1 Measure the amplitude output at OUT (2, 5, 9). The measured value is called VOUT (2, 5, 9), and is treated as Oaj1. Oaj2 OSD Adjust Control Characteristics2 Measuring condition and procedure are the same as described in Oaj1. ΔOaj2 OSD Adjust Control Relative Characteristics2 Relative characteristics ΔOaj2 is calculated by the equation below: ΔOaj2 = VOUT (2) / VOUT (5), VOUT (5) / VOUT (9), VOUT (9) / VOUT (2) Oaj3 OSD Adjust Control Characteristics3 Measuring condition and procedure are the same as described in Oaj1. ΔOaj3 OSD Adjust Control Relative Characteristics3 Measuring condition and procedure are the same as described in ΔOaj2. Oaj4 OSD Adjust Control Characteristics4 Measuring condition and procedure are the same as described in Oaj1. Oaj5 OSD Adjust Control Characteristics5 Measuring condition and procedure are the same as described in Oaj1. ΔOaj5 OSD Adjust Control Relative Characteristics5 Measuring condition and procedure are the same as described in ΔOaj2. Oaj6 OSD Adjust Control Characteristics6 Measuring condition and procedure are the same as described in Oaj1. ΔOaj6 OSD Adjust Control Relative Characteristics6 Measuring condition and procedure are the same as described ΔOaj2. Rev.2.00 Sep 14, 2006 page 14 of 24 M61303FP OBLK OSD BLK Characteristics Measuring the amplitude output at OUT (2, 5, 9). The measured value is called OBLK. ΔOBLK OSD BLK Relative Characteristics Relative OSD BLK characteristics ΔOBLK is calculated by the equation below: ΔOBLK = VOUT (2) / VOUT (5), VOUT (5) / VOUT (9), VOUT (9) / VOUT (2) VthOSD OSD Input Threshold Voltage Reduce the SG5 input level gradually, monitoring output. Measure the SG5 level when the output reaches 0 V. The measured value is called VthOSD. VthBLK OSD BLK Input Threshold Voltage Confirm that output signal is being blanked by the SG5 at the time. Monitoring to output signal, decreasing the level of SG5. Measure the top level of SG6 when the blanking period is disappeared. The measured value is called VthBLK. I19H Pin 19 Input Current H Supply 5 V to V19, and then measure input current into pin 19. I19L Pin 19 Input Current L Supply 0 V to V19, and then measure input current into pin 19. I20H Pin 20 Input Current H Supply 5 V to V20, and then measure input current into pin 20. I20L Pin 20 Input Current L Supply 0 V to V20, and then measure input current into pin 20. IOSDH Pin 24, 25, 26 Input Current H Supply 5 V to V (24, 25, 26) and then measure input current into pin (24, 25, 26) IOSDL Pin 24, 25, 26 Input Current L Supply 0 V to V (24, 25, 26) and then measure input current into pin (24, 25, 26) I27H Pin 27 Input Current H Supply 5 V to V27, and then measure input current into pin 27. I27L Pin 27 Input Current L Supply 0 V to V27, and then measure input current into pin 27. Rev.2.00 Sep 14, 2006 page 15 of 24 M61303FP Input Signal SG No. Signals Pulse with amplitude of 0.7 VP-P (f = 30 kHz). Video width of 25 μs. (75%) 33 μs SG1 Video signal (all white) 8 μs 0.7 VP-P Amplitude is partially variable SG2 Video signal (step wave) 0.7 VP-P SG3 Sine wave (for free. char.) Sine wave amplitude of 0.7 VP-P f = 1 MHz, 50 MHz, 150 MHz (variable) Pulse width and amplitude are variable. 0.5 μs SG4 Clamp pulse 5 VTTL SG5 OSD pulse 5 VTTL 5 μs Note: fH = 30 kHz Rev.2.00 Sep 14, 2006 page 16 of 24 Amplitude is partially variable. M61303FP Test Circuit SG5 V OSD SG1 SG2 SG3 5V A IA I27 I26 A I25 A I24 A A abc abc abc abc 0.01 μF 3.3 μF + + + 220 IN (32) IN + 47 μF 47 μF 42 41 40 R IN 5V R IN 5V 39 GND GND R OUT GND 1 2 38 3 5V 4 47 μF + 5 47 μF 37 36 35 G IN 5V G IN G OUT GND GND 6 7 5V 8 34 33 GND GND 32 31 30 B IN 5V B IN B OUT GND GND GND GND 9 10 11 47 μF + SW5 b 12 13 29 a a 27 5V 14 26 15 16 17 C/P IN SG4 18 23 19 a SW16 b A 22 20 a b I19 A SDA b V19 b I20 A SCL V21 OUT (9) : Measure point Condenser: 0.01 μF (unless otherwise specified.) Rev.2.00 Sep 14, 2006 page 17 of 24 5V 21 14 pF 10 1k 14 pF 10 14 pF 10 1k 1k OUT (5) 24 47 μF + V16 OUT (2) 25 R G B GND GND OSD OSD OSD GND C/P GND GND SDA SCL a SW9 b 28 GND GND BLK 47 μF + SW2 a 220 IN (30) IN + IN 220 + IN 220 SW24 b SW25 a SW32 0.01 μF 3.3 μF 0.01 μF SW35 b SW26 a SW27 b 3.3 μF a 0.01 μF b SW37 3.3 μF 3.3 μF SW40 3.3 μF SW42 0.01 μF a 0.01 μF b + a + b + a M61303FP Typical Characteristics Main Contrast Control Characteristics Sub Contrast Control Characteristics 3 Input 0.7 VP-P Pedestal revel is 1 VDC Sub contrast FFH 2.2 2 7FH 1 00H Main contrast FFH 2.2 2 7FH 1 00H FFH Main Contrast Control Data Sub Contrast Control Data Main Brightness Control Characteristics Sub Brightness Control Characteristics 3 3 Sub brightness FFH 2.2 2 7FH 00H 1 0.5 0 00H FFH Main Brightness Control Data 2.5 2.0 OSD SW: 0 1.5 1.0 OSD SW: 1 0.5 0 00H FFH OSD Adjust Control Data Rev.2.00 Sep 14, 2006 page 18 of 24 2.2 2 Main brightness 7FH 1 0.5 00H 0 00H FFH Sub Brightness Control Data OSD Adjust Control Characteristics Output Amplitude (VP-P) Input 0.7 VP-P Pedestal revel is 1 VDC 0 00H FFH Output DC Voltage (VDC) Output DC Voltage (VDC) 0 00H Output Amplitude (VP-P) Output Amplitude (VP-P) 3 M61303FP Application Method Clamp Pulse Input Clamp pulse width is recommended above 15 kHz, 1.0 μs above 30 kHz, 0.5 μs above 64 kHz, 0.3 μs. The clamp pulse circuit in ordinary set is a long round about way, and beside high voltage, sometimes connected to external terminal, it is very easy affected by large surge. Therefore, the figure shown right is recommended. 16 Notice of Application 1. Recommended pedestal voltage of IC output signal is l V. 2. This IC has 2 Input routes. When the 2 Input signal input at different timing, clamp pulses which synchronize with selected signals is needed. In this case, it is necessary to change clamp pulses by the outside circuit. 3. Connect coupling cap (0.01 μ) as nearer as can to VCC pin. If not response of waveform is getting wrong. Rev.2.00 Sep 14, 2006 page 19 of 24 M61303FP Application Example R INPUT1 G INPUT2 INPUT1 B INPUT2 INPUT1 5 VTTL INPUT2 OSD BLK IN 5 VTTL R OSD IN 5 VTTL 75 3.3 μF 75 3.3 μF + + + + + + 47 μF 47 μF 40 39 38 37 36 35 34 33 5 VTTL B OSD IN 220 47 μF 41 G OSD IN 75 3.3 μF + 42 75 3.3 μF + 75 3.3 μF + 75 3.3 μF 32 31 220 220 220 30 29 28 27 26 25 24 23 22 13 14 15 16 17 18 19 20 21 M61303FP 1 2 3 4 5 6 7 8 9 10 11 12 100 + 10 1k R OUTPUT 10 1k G OUTPUT 5V Rev.2.00 Sep 14, 2006 page 20 of 24 10 100 + + 47 μF + + 47 μF 47 μF SCL SDA 47 μF 47 μF 1k B OUTPUT Clamp Pulse IN 1k Condenser: 0.01 μF (unless otherwise specified.) M61303FP Pin Description Pin No. 1 4 8 2 5 9 Name R VCC2 G VCC2 B VCC2 OUTPUT (R) OUTPUT (G) OUTPUT (B) DC Voltage (V) 5 Peripheral Circuit ⎯ Function ⎯ ⎯ Pull down about 1 k for valance control Tr and Tf 2 20 Ω 20 mA 3 6 10 13 14 16 GND ⎯ ⎯ GND ⎯ ⎯ Analog VCC 5 ⎯ ⎯ Clamp Pulse In ⎯ R GND 2 G GND 2 B GND 2 Analog Gnd more than 200 ns 21 k 2.5 to 5 V 0.5 V to GND 16 Input at low impedance. 1k 2.0 V Rev.2.00 Sep 14, 2006 page 21 of 24 2.0 V 0.2 mA M61303FP Pin Description (cont.) Pin No. 18 19 Name Digital GND SDA DC Voltage (V) GND ⎯ Peripheral Circuit ⎯ Function ⎯ SDA for I2C (Serial data line) VTH = 2.3 V 50 k 19 2k 3V 20 SCL ⎯ SCL of I2C (Serial clock line) VTH = 2.3 V 50 k 20 2k 3V 21 24 25 26 Digital VCC B OSD IN G OSD IN R OSD IN ⎯ 5V ⎯ ⎯ Input pulses 3.5 to 5 V 1.0 V to GND 24 1k 1k 2.5 V Rev.2.00 Sep 14, 2006 page 22 of 24 2.5 V M61303FP Pin Description (cont.) Pin No. 27 Name OSD BLK IN DC Voltage (V) ⎯ Peripheral Circuit Function Input pulses 3.5 to 5 V 1.0 V to GND 27 Connected to GND if not used. 1k 330 2.5 V 2.5 V 1.5 mA 29 34 39 30 32 35 37 40 42 B GND 1 G GND 1 R GND 1 GND B INPUT 2 B INPUT 1 G INPUT 2 G INPUT 1 R INPUT 2 R INPUT 1 2.1 V ⎯ 2k ⎯ Clamped to about 2.1 V due to clamp pulses from pin 16. Input at low impedance. 2k 30 50 CP 0.3 mA 2.0 V 0 (off) 3.5 V (on) 31 36 41 7 11 12 15 17 22 23 28 33 38 B VCC1 G VCC1 R VCC1 5 ⎯ ⎯ NC ⎯ ⎯ Connect GND for radiation of heat Rev.2.00 Sep 14, 2006 page 23 of 24 M61303FP Package Dimensions JEITA Package Code P-HSSOP42-8.4x17.5-0.80 RENESAS Code PRSP0042GB-B Previous Code 42P9R-B MASS[Typ.] 0.7g F 22 42 E1 E *1 HE D2 c 21 Index mark Reference Symbol D A *2 L 1 NOTE) 1. DIMENSIONS "*1" AND "*2" DO NOT INCLUDE MOLD FLASH. 2. DIMENSION "*3" DOES NOT INCLUDE TRIM OFFSET. *3 e y bp x A2 Detail F Rev.2.00 Sep 14, 2006 page 24 of 24 A1 D E A2 A A1 bp c HE e x y L D2 E1 Dimension in Millimeters Min Nom Max 17.3 17.5 17.7 8.2 8.4 8.6 2.0 2.2 0.1 0.2 0 0.27 0.32 0.37 0.23 0.25 0.3 0° 10° 11.63 11.93 12.23 0.8 0.12 0.10 0.3 0.5 0.7 5.8 6.0 6.2 3.8 4.0 4.2 Sales Strategic Planning Div. Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan Keep safety first in your circuit designs! 1. Renesas Technology Corp. puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of nonflammable material or (iii) prevention against any malfunction or mishap. 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