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| MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR DISCRIPTION M61301SP is Semiconductor Integrated Circuit for CRT Display Monitor. It includes OSD Blanking,OSD Mixing,Retrace Blanking,Wide Band Amplifre,Brightness Control. Main/Sub Contrast and OSD AdjustFunction can be controlled by I2C Bus. PIN CONFIGURATION FEATURES Frequency Band Width: RGB 150 MHz (at -3dB) OSD 80 MHz Input : RGB 0.7 Vp-p (Typ) OSD light 4 Vp-p minimum (positive) OSD harf 2.5Vp-p minimum (positive) 3.0Vp-p maximum (positive) BLK(for OSD) 3 Vp-p minimum (positive) Retrace BLK 3 Vp-p minimum (positive) Output : RGB 5.5 Vp-p (maximum) OSD 5 Vp-p (maximum) Main Contrast and Sub Contrast can be controlled by I2C Bus. Video response can be controlled by I2C Bus. Brightness OSD IN (R) OSD IN (B) OSD IN (G) OSD BLK IN INPUT (R) VCC 12V NC INPUT (B) GND INPUT (G) VCC 12V INPUT(SOG) SOG Sep OUT GND Clamp Pulse IN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 VCC 12V (R) OUTPUT(R) GND(R) VCC 12V (B) OUTPUT(B) GND(B) GND VCC 12V (G) OUTPUT(G) GND(G) Retrace BLK IN SDA SCL GND ABL IN VCC 5V Outside Package: 32P4B STRUCTURE Bipola Silicon Monolisic IC APPLICATION CRT Display Monitor 32 pin plastic SDIP RECOMMENDED OPERATING CONDITIONS Supply Voltage Range Rated Supply Voltage 11.5V~12.5V(V7,V12,V25,V29,V32) 4.5V~4.4V(V17) 12.0V(V7,V12,V25,V29,V32) 5.0V(V17) MAJOR SPECIFICATION Bus Controlled 3ch Video Pre-Amp with OSD Mixing Function and Video Response Function. MITSUBISHI 1 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Absolute Maximum Rating (Ambient temperature: 25 C) Parameter Supply voltage 12 Supply voltage 5 Power dissipation Ambient temperature Storage temperature Recommended supply 12 Recommended supply voltage range 12 voltage range 5 5 Symbol Vcc12 Vcc 5 Pd Topr Tstg Vopr 12 Vopr 5 Vopr' 12 Vopr' 5 jc Rating 13.0 6.0 2358 -20~ +75 -40~ +150 12.0 5.0 10.5~12.5 ( Typ 12.0V ) 4.5~5.5 ( Typ 5.0V ) 28 Unit V V mW C C V V V V C/W Case temperature Thermal Derating Curve 2800 2400 2358 2000 1600 1415 1200 800 400 attached board -20 0 25 50 75 100 125 150 Ambient temperature Ta( C) MITSUBISHI 2 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Fig. 1 Block Diagram MITSUBISHI 3 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR BUS CONTROL TABLE (1) Slave address: D7 D6 D5 D4 D3 D2 D1 R/W 1 0 0 0 1 0 0 0 =88H (2) Each function's sub address: NO. 1 2 3 4 5 6 function Main contrast Sub contrast R Sub contrast G Sub contrast B OSD level Video response bit 8 8 8 8 5 sub Data Byte(up:bit information down:preset) D6 A06 1 A16 0 A26 0 A36 0 0 0 D5 A05 0 A15 0 A25 0 A35 0 0 0 D4 A04 0 A14 0 A24 0 A34 0 A44 1 0 D3 A03 0 A13 0 A23 0 A33 0 A43 0 0 D2 A02 0 A12 0 A22 0 A32 0 A42 0 1 D1 A01 0 A11 0 A21 0 A31 0 A41 0 0 D0 A00 0 A10 0 A20 0 A30 0 A40 0 A50 0 add. D7 00H A07 0 01H 02H 03H 04H A17 1 A27 1 A37 1 0 0 3 05H A52 A51 MITSUBISHI 4 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR 2 I C BUS CONTROL SECTION SDA,SCL CHARACTERISTICS parameter symbol MIN -0.5 3.0 0 4.7 4.0 MAX 1.5 5.5 100 unit V V KHz us us min. input LOW voltage. max. input HIGH voltage. SCL clock frequency. Time the bus must be free before a new transmission can start. VIL VIH fSCL tBUF tHD:STA tLOW tHIGH tSU:STA tHD:DAT tSU:DAT tR tF tSU:STO 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. Srt up time for start condition. (Only relevant for a repeated start condition.) 4.7 4.0 4.7 0 250 4.0 1000 300 - us us us us ns ns ns us 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. tR, tF tBUF VIL SDA VIH tHD:STA VIL SCL tSU:DAT tHD:DAT tSU:STA tSU:ST O VIH tLOW S tHIGH S P S MITSUBISHI 5 25 Supplementary Table1 Electrical Characteristics (Vcc= 12V,5V; Ta= 25 C unless otherwise specified) Input CTL voltage BUS CTL ( H ) Standard MIN TYP MAX 125 100 mA Note1 00H 01H 02H 03H 04H 05H No Unit Bright ABL 4.0 5.0 255 255 255 255 0 FFH FFH FFH FFH 00H 04H 4 Sub Sub Sub VIDEO Main cont cont cont OSD res cont R G B Adj ponse parameter Symbol Test Point(s) 16 13 5 234 SOG OSD ReT RGB In BLK OSD In CP In BLK In a a b SG5 a a b SG5 a 4.0 Variable 7 9 11 22 1 18 Remark 1 Circuit current1 Icc1 IA a 2 a 5.0 25 a a Circuit current2 Icc2 IB a 18 mA Note2 3 a 64H Output dynamic Vomax range OUT a 5.0 6.0 8.0 b SG5 a a b SG5 a 5.0 100 FFH - Vp-p Note3 4 Maximum input Vimax IN OUT a 1.6 a a 2.0 a 5.0 255 C8H b SG2 b SG2 - - Vp-p Note4 Variable 5 Maximum gain Gv OUT B SG1 a b SG5 a a 2.0 - 17.1 17.7 19.4 dB Note5 6 Relative maximum gain Gv - - 0.8 1.0 1.2 - Note6 7 Main contrast control characteristics 1 VC1 2.0 5.0 200 64H OUT b AG1 a a b SG5 a a - 15.0 16.5 19.0 dB Note7 8 Main contrast control relative characteristics 1 VC1 - - 0.8 1.0 1.2 - Note8 9 a a a a 2.0 5.0 100 Main contrast control characteristics 2 VC2 OUT b SG1 b SG5 - 9.0 10.5 13.0 dB Note9 10 Main contrast control relative characteristics 2 VC2 - - 0.8 1.0 1.2 - Note10 11 2.0 Main contrast control characteristics 3 VC3 OUT b SG1 a a b SG5 a a 5.0 - 14H 20 0.1 0.5 0.8 Vp-p Note11 12 a a a a Main contrast control relative characteristics3 VC3 - - FFH C8H C8H C8H 0.8 1.0 1.2 - Note12 13 Sub contrast control characteristics 1 VSC1 OUT b SG1 b SG5 - 2.0 5.0 255 200 200 200 - 15.5 16.5 19.0 dB Note13 14 Sub contrast control relative characteristics 1 VSC1 - - - - - FFH 64H 64H 64H 0.8 1.0 1.2 - Note14 15 a a Sub contrast control characteristics 2 VSC2 OUT b SG1 - b SG5 a - a - 2.0 5.0 255 100 100 100 - 9.0 12.0 13.0 dB Note15 16 Sub contrast control relative characteristics 2 VSC2 - - - - - - 0.8 1.0 1.2 - Note16 Input CTL voltage BUS CTL ( H ) Standard MIN TYP MAX 0.1 0.5 1.3 Vp-p Note17 00H 01H 02H 03H 04H 05H No Unit Bright ABL 2.0 5.0 FFH 14H 14H 14H 00H 04H 255 20 20 20 0 4 Sub Sub Sub VIDEO Main cont cont cont OSD res cont R G B Adj ponse parameter Symbol Test Point(s) 16 13 5 234 SOG OSD ReT RGB In BLK OSD In CP In BLK In a a a a b SG5 0.8 1.0 1.2 a 2.0 3.4 4.0 5.0 a - 7 9 11 22 1 18 Remark Sub contrast control 17 characteristics 3 VSC3 OUT b SG1 a a - 18 Sub contrast control relative characteristics 3 VSC3 - - Note18 19 Main/sub contrast control characteristics VMSC OUT b SG1 b SG5 C8H C8H C8H C8H 200 200 200 200 4.6 Vp-p Note19 20 a a 2.0 4.0 a a b SG5 FFH FFH FFH FFH 255 255 255 255 Main/sub contrast control relative characteristics VMSC 4.1 0.8 - - - - - - - 1.0 4.9 1.2 5.7 - Note20 21 characteristics 1 ABL1 - ABL control OUT b SG1 Vp-p Note21 22 ABL control relative characteristics 1 ABL1 - - 0.8 1.0 1.2 - Note22 23 characteristics 2 ABL2 2.0 - ABL control OUT b SG1 a a 2.0 a a b SG5 1.7 2.2 2.7 Vp-p Note23 24 ABL control relative characteristics2 ABL2 - - 0.8 1.0 1.2 - Note24 25 a a a a Brightness control characteristics 1 VB1 OUT a 4.0 5.0 b SG5 a a 2.0 5.0 - 3.3 3.7 4.1 V Note25 26 a a - Brightness control relative characteristics 1 VB1 - - -0.3 0 0.3 - Note26 27 Brightness control characteristics 2 VB2 OUT a b SG5 - 1.5 1.8 2.1 V Note27 28 - Brightness control relative characteristics 2 VB2 - - -0.3 0 0.3 - Note28 29 VB3 OUT a a a a a b SG5 - 1.0 5.0 0.5 0.9 1.1 V Note29 30 Brightness control characteristics 3 Brightness control relative characteristics 3 VB3 - - - - - - -0.3 0 0.3 - Note30 Frequency 31 characteristics 1 a a (f=50MHz) FC1 OUT b SG3 - a 5V a - a - Variable 5.0 Vari able -2.0 0 2.5 dB Note31 32 Frequency relative characteristics 1 (f=50MHz) FC1 - - - - - -1.0 0 1.0 dB Note32 Input CTL voltage BUS CTL ( H ) Standard MIN TYP MAX -3.0 0 3.0 dB Note33 00H 01H 02H 03H 04H 05H No Unit Bright ABL Variable Sub Sub Sub VIDEO Main cont cont cont OSD res cont R G B Adj ponse Varia FFH FFH FFH 00H 04H ble 255 255 255 0 4 parameter Symbol Test Point(s) 16 13 5 234 SOG OSD ReT RGB In BLK OSD In CP In BLK In a a 5.0 a a a 5V -1.0 Variable 7 9 11 22 1 18 Remark 33 Frequency characteristics 1 (f=200MHz) FC1' OUT b SG3 0 1.0 a 5.0 -3.0 3.0 a a a dB 34 Frequency relative characteristics 1 (f=200MHz) FC1' - - Note34 35 -1.0 - Frequency characteristics 2 (f=200MHz) FC2 OUT b SG3 a 5V 0 5.0 dB Note35 36 Frequency relative characteristics 2 (f200MHz) FC2 - - 1.0 dB Note36 37 Variable Crosstalk 1 (f=50MHz) a a 5.0 a a a 5V a 5V a Variable CT1 a 5.0 a a 2 b SG3 OUT(29) 6 a OUT(32) 11a FFH 255 - -25 -20 dB Note37 38 Crosstalk 1 (f=200MHz) a Variable CT1' 2 b SG3 OUT(29) 6 a OUT(32) 11a - -20 -15 dB Note38 39 a a a Crosstalk 2 (f=50MHz) 5.0 a Variable CT2 2a OUT(29) 6 b SG3 OUT(35) 11a a 5V a 5V a 5.0 a a 5V a Variable - -25 -20 dB Note39 40 Crosstalk 2 (f=200MHz) a a 5.0 a a CT2' 2a OUT(29) 6 b SG3 OUT(35) 11a - -20 -15 dB Note40 41 Crosstalk 3 (f=50MHz) a Variable CT3 a 5.0 a a 2a OUT(32) 6 a OUT(35) 11b SG3 - -25 -20 dB Note41 42 Crosstalk 3 (f=200MHz) a 5V a 5V a Variable CT3' a a a 2a OUT(32) 6 a OUT(35) 11b SG3 - -20 -15 dB Note42 Pulse 43 characteristics 1 (4Vp-p) Tr OUT b SG1 5.0 a a a 5V a a b SG5 a a Variable Variable Varia ble 2.2 2.8 nS Note43 44 Pulse characteristics 2 (4Vp-p) Tf OUT b SG1 a a 5.0 Varia ble - 2.2 2.8 nS Note44 45 Clamp pulse threshold voltage VthCP OUT b SG1 a Variable 2.0 5.0 FFH 255 1.0 1.5 2.0 V Note45 Clamp pulse 46 minimum width WCP a a a a b SG5 b SG5 a a OUT b SG1 b SG5 a 2.0 5.0 0.2 - - uS Note46 47 Pedestal voltage temperature characteristics 1 PDCH OUT b SG1 a a 2.0 5.0 -3.0 0 0.3 V Note47 48 Pedestal voltage temperature characteristics 2 PDCL OUT b SG1 a a 2.0 5.0 -3.0 0 0.3 V Note48 Input CTL voltage BUS CTL ( H ) Standard MIN TYP MAX 3.0 6.0 ns Note49 00H 01H 02H 03H 04H 05H No Unit Bright ABL 2.0 5.0 255 255 255 255 8 FFH FFH FFH FFH 08H 04H 4 Sub Sub Sub VIDEO Main cont cont cont OSD res cont R G B Adj ponse parameter Symbol Test Point(s) 16 13 5 234 SOG OSD ReT RGB In BLK OSD In CP In BLK In a b SG6 a a b SG6 a a 2.0 5.0 3.0 6.0 b SG6 a a 2.0 5.0 5.6 6.4 0.8 1.0 b SG5 0FH 15 7 9 11 22 1 18 Remark 49 OSD pulse characteristics 1 OTr OUT a b SG5 b SG5 7.2 08H 8 50 a OSD pulse characteristics 2 OTf OUT a ns Note50 51 OSD adjust control characteristics 1 Oaj1 OUT a b SG6 - Vp-p Note51 52 characteristics 1 b SG6 a a 2.0 5.0 08H 8 OSD adjust control relative Oaj1 - - 1.2 - Note52 53 Oaj2 OUT a b SG6 a 2.0 5.0 - b SG5 3.4 4.0 4.6 Vp-p Note53 54 OSD adjust control characteristics 2 OSD adjust control relative characteristics 2 Oaj2 - - - 0.8 1.0 1.2 - Note54 55 - Oaj3 a OUT a b SG6 b SG6 b SG5 00H 0 0 0.7 1.2 Vp-p Note55 OSD adjust control characteristics 3 OSD adjust control relative 56 characteristics 3 Oaj3 - - 0.8 1.0 1.2 - Note56 57 Variable OSD input threshold voltage 1 VthOSD1 OUT a b SG6 Variable b SG6 a a 2.0 5.0 b SG5 a a 2.0 5.0 b SG5 a a 2.0 5.0 b SG5 a a b SG5 a a b b SG7 SG5 Variable a a a 2.0 5.0 b SG6 b SG5 08H 8 3.1 3.5 3.9 V Note57 58 OSD input threshold voltage 2 VthOSD2 OUT a 08H 8 1.5 2.0 2.5 V Note58 59 Variable OSD BLK input threshold VthBLK voltage OUT a b SG6 3V b SG1 b SG6 b SG6 a a b SG6 3V b SG6 b SG6 00H 0 2.2 2.7 3.2 V Note59 OSD half adjust control 60 characteristics 1 Ohaj1 OUT a 0FH 15 3.7 4.3 4.9 Vp-p Note60 61 OSD half adjust control characteristics 2 Ohaj2 OUT a 2.0 5.0 08H 8 1.9 2.5 3.0 Vp-p Note61 62 Retrace BLK i nput threshold VthRET voltag OUT a 2.0 5.0 00H 0 1.0 1.5 2.0 V Note62 63 SOG input maximum noize SS - NV S on G IN Sync OUT voltage a a a b SG4 Variable 2.0 5.0 - - 0.03 Vp-p Note63 64 SOG minimum SS - SV input voltage a a S on G IN Sync OUT a a a b SG4 Variable 2.0 5.0 0.2 - - Vp-p Note64 Input CTL voltage BUS CTL ( H ) Standard MIN TYP MAX 4.5 4.9 5.0 V Note65 00H 01H 02H 03H 04H 05H No Unit Bright ABL 2.0 5.0 Sub Sub Sub VIDEO Main cont cont cont OSD res cont R G B Adj ponse parameter Symbol Test Point(s) 16 13 5 234 SOG OSD ReT RGB In BLK OSD In CP In BLK In a a a a b SG4 b SG4 2.0 5.0 0 0.3 0.6 b SG4 2.0 5.0 0 60 b SG4 2.0 5.0 0 a 4.0 5.0 255 255 255 255 0 FFH FFH FFH FFH 00H 04H 4 7 9 11 22 1 18 Remark 65 Sync Output Hi Level a a a a V VSH Sync OUT a 66 Sync Output Lo Level a a a a 90 VSL Sync OUT a Note66 67 Sync Output Delay Time1 a a a a 60 TDS-F Sync OUT a ns Note67 68 Sync Output Delay Time2 a a a b SG5 TDS-R Sync OUT - a 90 ns Note68 69 Icc (power save mode) Iccps Ips a 22 30 mA Note69 spot killer 70 function voltage a a a a b SG5 skv Vcc (12V) b SG1 2.0 5.0 255 255 255 255 0 5.0 100 255 255 255 0 64H FFH FFH FFH 00H 00H 0 FFH FFH FFH FFH 00H 04H 4 8.9 7.0 1.5 20.0 15.0 9.5 0.0 0.0 10.0 3.0 33.0 20.0 9.9 VDC Note70 1.5 Tr 0.0 Tf 13.0 Tr 7.0 Tf % Note72 % Note71 71 a a a a 2.0 Video response control1 PS1 OUT b SG1 a a a b SG5 a a 2.0 5.0 100 255 255 255 0 a b SG5 a a 2.0 5.0 100 255 255 255 0 64H FFH FFH FFH 00H 04H 4 b SG5 72 Video response control2 PS2 OUT b SG1 Tr Tf 73 Video response control3 PS3 OUT b SG1 64H FFH FFH FFH 00H 07H 7 % Note73 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note1) Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IA. Measuring conditions are as listed in supplementary Table. Measured with a current meter at test point IB. Decrease V1 gradually, and measure the voltage when the bottom of waveform output is distorted. The voltage is called VCL. Next, increase V1 gradually, and measure the voltage when the top of waveform output is distorted. The voltage is called VOH. Voltagr Vomax is calculated by the equation below: Vomax = VOH - VOL (V) Note2) Note3) VOH 5.0 Waveform output VOL 0.0 Note4) Increase the input signal(SG2) amplitude gradually, starting from 700mVp-p. Measure the amplitude of the input signal when the output signal starts becoming distorted. Input SG1, and read the amplitude output at OUT(24,28,31). The amplitude is called VOUT(24,28,31).Maximum gain GV is calculated by the equation below: VOUT GV=20 LOG 0.7 (dB) Note5) Note6) Relative maximum gain GV is calculated by the equation below: GV=VOUT(24)/VOUT(18), VOUT(28)/VOUT(31), VOUT(31)/VOUT(24) Measuring the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31). Main contrast conrol characteristics VC1 is calculated by the equation below: VOUT VC1=20 LOG (dB) 0.7 Note7) Note8) Relative characteristics VC1 is calculated by the equation below: VC1=VOUT(24)/VOUT(28) , VOUT(28)/VOUT(31) , VOUT(31)/VOUT(24) Note9) Measuring condition and procedure are the same as described in Note7. Note10) Measuring condition and procedure are the same as described in Note8. Note11) Measuring condition and procedure are the same as described in Note7. Note12) Measuring condition and procedure are the same as described in Note8. MITSUBISHI 11 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note13) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31). Sub contrast conrol characteristics VSC1 is calculated by the equation below: VOUT VSC1=20 LOG (dB) 0.7 Note14) Relative characteristics VSC1 is calculated by the equation below: VSC1=VOUT(24)/VOUT(28) , VOUT(28)/VOUT(31) , VOUT(31)/VOUT(24) Note15) Measuring condition and procedure are the same as described in Note13. Note16) Measuring condition and procedure are the same as described in Note14. Note17) Measuring condition and procedure are the same as described in Note13. Note18) Measuring condition and procedure are the same as described in Note14. Note19) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31). Main/Sub contrast conrol characteristics VMSC1 is calculated by the equation below: VOUT VMSC1=20 LOG (dB) 0.7 Note20) Relative characteristics VMSC1 is calculated by the equation below: VMSC=VOUT(24)/VOUT(28) , VOUT(28)/VOUT(31) , VOUT(31)/VOUT(24) Note21) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31), and is ttreated as ABL1. Note22) Relative characteristics ABL1 is calculated by the equation below: ABL1=VOUT(24)/VOUT(28) , VOUT(28)/VOUT(31) , VOUT(31)/VOUT(24) Note23) Measuring condition and procedure are the same as described in Note21. Note24) Measuring condition and procedure are the same as described in Note22. Note25) Measure the DC voltage at OUT(24,28,31) with a voltmeter. The measured value is called VOUT(24,28,31), and is ttreated as VB1. Note26) Relative characteristics VB1 is calculated by the difference in the output between the channels. VB1=VOUT(24)-VOUT(28) , VOUT(28)-VOUT(31) , VOUT(31)-VOUT(24) Note27) Measuring condition and procedure are the same as described in Note25. Note28) Measuring condition and procedure are the same as described in Note26. Note29) Measuring condition and procedure are the same as described in Note25. Note30) Measuring condition and procedure are the same as described in Note26. MITSUBISHI 12 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note31) First, SG3 to 1MHz is as input signal. Input a resister that is about 2K to offer the voltage at input pins(6,9,11) in order that the bottom of input signal is 2.5V. Control the main contrast in order that the amplitude of sine wave output is 4.0Vp-p. Control the brightness in order that the bottom of sine wave output is 2.0Vp-p. By the same way, measure the output amplitude when SG3 to 50MHz is as input signal. The measured value is called VOUT(24,28,31). Frequency characteristics FC1(24,28,31) is calculated by the equation below: FC1=20 LOG VOUT Vp-p output amplitude when inputed SG3(1MHz) : 4.0Vp-p (dB) Note32) Relative characteristics FC1 is calculated by the difference in the output between the channels. Note33) Measuring condition and procedure are the same as described in Note31,expect SG3 to 150MHz. Note34) Relative characteristics FC1' is calculated by the difference in the output between the channels. Note35) SG3 to 1MHz is as input signal. Control the main contrast in order that the amplitude of sine wave output is 1.0Vp-p. By the same way, measure the output amplitude when SG3 to150MHz is as input signal. The measured value is called VOUT(24,28,31). Frequency characteristics FC2(24,28,31) is calculated by the equation below: FC2=20 LOG VOUT Vp-p output amplitude when inputed SG3(1MHz) : 4.0Vp-p (dB) Note36) Relative characteristics FC2 is calculated by the difference in the output between the channels. Note37) Input SG3 (50MHz) to pin2 only, and then measure the waveform amplitude output at OUT(24,28,31).The measured value is called VOUT(24,28,31). Crosstalk CT1 is calculated by the equation below: CT1=20 LOG VOUT(24,28) VOUT(31) (dB) Note38) Measuring condition and procedure are the same as described in Note37,expect SG3 to 150MHz. Note39) Input SG3 (50MHz) to pin6 only, and then measure the waveform amplitude output at OUT(24,28,31).The measured value is called VOUT(24,28,31). Crosstalk CT2 is calculated by the equation below: CT2=20 LOG VOUT(24,31) VOUT(28) (dB) Note40) Measuring condition and procedure are the same as described in Note39,expect SG3 to 150MHz. Note41) Input SG3 (50MHz) to pin11 only, and then measure the waveform amplitude output at OUT(24,28,31).The measured value is called VOUT(24,28,31). Crosstalk CT2 is calculated by the equation below: VOUT(28,31) CT3=20 LOG VOUT(24) (dB) Note42) Measuring condition and procedure are the same as described in Note41,expect SG3 to 150MHz. MITSUBISHI 13 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note43) Control the main contrast (00H) in order that the amplitude of output signal is 4.0Vp-p. Control the brightness (V1) in order that the Black level of output signal is 2.0V. Measure the time needed for the input pulse to rise from 10 % to 90 % (Tr1) and for the output pulse to rise from 10 % to 90 % (Tr2) with an active prove. Pulse characteristics Tr is calculated by the equations below : 2 2 Tr = (Tr2) - (Tr1) (nsec) Note44) Measure the time needed for the input pulseto fall from 90 % to 10 % (Tf1) and for the output pulse to fall from 90 % to 10 % (Tf2) with an active prove. Pulse characteristics Tf is calculated by the equations below : 2 2 Tf = (Tf2) - (Tf1) (nsec) 100% 90% 10% 0% Tr1 or Tr2 Tf1 or Tf2 Note45) Turn down the SG5 input level gradually from 5.0Vp-p, monitoring the waveform output. Measure the top level of input pulse when the output pedestal voltage turn decrease with unstable. Note46) Decrease the SG5 pulse width gradually from 0.5us, monitoring the output. Measure the SG5 pulse width (a point of 1.5V) when the output pedestal voltage turn decrease with unstable. Note47) Measure the pedestal voltage at 25 C. The measured value is called PDC1. Measure the pedestal voltage at temperature of -20 C. The measured value is called PDC2. Pedestal voltage temperature characteristics 1 is calculated by the equation below: PDCH=PDC1-PDC2 Note48) Measure the pedestal voltage at 25 C. The measured value is called PDC1. Measure the pedestal voltage at temperature of 75 C. The measured value is called PDC3. Pedestal voltage temperature characteristics 2 is calculated by the equation below: PDCL=PDC1-PDC3 MITSUBISHI 14 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note49) Measure the time needed for the output pulse to rise from 10% to 90%(OTR) with an active prove. Note50) Measure the time needed for the output pulse to fall from 90% to 10% (OTF) with an active prove. Note51) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31), and is treated as Oaj1. Note52) Relative characteristics Oaj1 is calculated by the equation below: Oaj1=VOUT(24)/VOUT(28), VOUT(28)/VOUT(31), VOUT(31)/VOUT(24) Note53) Measuring condition and procedure are the same as described in Note51. Note54) Measuring condition and procedure are the same as described in Note52. Note55) Measuring condition and procedure are the same as described in Note51. Note56) Measuring condition and procedure are the same as described in Note52. Note57) Reduce the SG6 input level gradually, monitoring output. Measure the SG6 level when the output reaches 65~75% of first voltage. The measured value is called VthOSD1. Note58) Reduce the SG6 input level gradually, monitoring output. Measure the SG6 level when the output reaches 0V. The measured value is called VthOSD2. Note59) Confirm that output signal is being blanked by the SG6 at the time. Monitoring to output signal, decreasing the level of SG6. Measure the top level of SG6 when the blanking period is disappeared. The measured value is called VthBLK. Note60) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31), and is treated as Ohaj1. Note61) Measure the amplitude output at OUT(24,28,31). The measured value is called VOUT(24,28,31), and is treated as Ohaj2. Note62) Confirm that output signal is being blanked by the SG7 at the time. Monitoring to output signal, decreasing the level of SG7. Measure the top level of SG7 when the blanking period is disappeared. The measured value is called VthRET. Note63) The sync's amplitude of SG4 be changed all white into all black, increase from 0Vp-p to 0.03Vp-p. No pulse output permitted. Note64) The sync's amplitude of SG4 be changed all white or all black, decrease from 0.3Vp-p to 0.2Vp-p. Confirm no malfunction produced by noise. Note65) Measure the high voltage at SyncOUT. The measured value is treated as VSH. Note66) Measure the low voltage at SyncOUT. The measured value is treated as VSL. Note67) SyncOUT becomes High with sink part of SG4. Measure the time needed for the rear edge of SG4 sink to fall from 50 % and for SyncOUT to rise from 50 % with an active prove. The measured value is treated as TDS-F ,less than 90nsec. MITSUBISHI 15 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Note68) Measure the time needed for the rear edge of SG4 sink to rise from 50 % and for Sync OUT to fall from 50 % with an active prove. The measured value is treated as TDS-R ,less than 90nsec. SG4 Pedestal voltage sync (50%) (50%) Sync OUT TDS-F TDS-R Note69) No input at the Vcc of 12V when same condition by Note2 . Measure the AC current at Vcc(5V). The measured value is treated as Iccps. Note70) The Vcc of 12V be changed all white into all black, increase from 12V to 0V. Measure the DC voltage at the Vcc When no output signal at R, G and Bout. The measured value is treated as skv. Note71) Measure the output amplitude at video response control is Minimum. The measured value is treated as M. Measure the overshoot quantity at pulse to rise and fall. The measured value is treated as M1 and M2. PS1 is calculated by the equations below. PS1= ( M1 or M2(24, 28, 31) - M(24, 28, 31) M(24, 28, 31) ) X 100 (%) Note71) Measure the output amplitude at video response control is Typical. The measured value is treated as M. Measure the overshoot quantity at pulse to rise and fall. The measured value is treated as M1 and M2. PS2 is calculated by the equations below. PS2= ( M1 or M2(24, 28, 31) - M(24, 28, 31) M(24, 28, 31) ) X 100 (%) Note71) Measure the output amplitude at video response control is Maximum. The measured value is treated as M. Measure the overshoot quantity at pulse to rise and fall. The measured value is treated as M1 and M2. PS3 is calculated by the equations below. PS3= ( M1 or M2(24, 28, 31) - M(24, 28, 31) M(24, 28, 31) ) X 100 (%) MITSUBISHI 16 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR SG No. INPUT SIGNAL 33us SG1 Video signal (all white) SG2 Video signal (step wave) SG3 Sine wave (for freq. char.) 8us Pulse with amplirude of 0.7Vp-p (f=30KHz). Video width of 25us. (75 % ) 0.7VPP 0.7VP-P (Amplitude is partially variable.) Sine wave amplitude of 0.7Vp-p. f=1MHz,50MHz,150MHz(variable) Video width of 25us. (75 % ) SG4 Videosignal (all white,all black) 3us 0.5us 0.7VP-P all white or all black variable. 0.3VPP Sync's amplitude is variable. Pulse width and amplitude are variable. 5VTTL SG5 Clamp pulse SG6 OSD pulse 5us 5VTTL Amplitude is partially variable. SG7 BLK pulse 5us 5VTTL Amplitude is partially variable. *)f=30KHz MITSUBISHI 17 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR TEST CIRCUIT + + + MITSUBISHI 18 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Terminal Description No. Name DC Voltage (V) peripheral Circuit Remark It is recommended that the 35K IC be used between pedestal voltage 2V and 3V. 1 Main Brightness 1 Input pulses 2 OSD IN (R) 1K 4.0~5V(light) 2.5~3V(half) 1.5V~GND 3 OSD IN (B) Connected to GND if not used. 4 OSD IN (G) 0.5mA 3.5V 2.0V Input pulses R G 3.7~5V 1.7V~GND Connected to GND if 5 OSD BLK IN 5 B 0.4mA 2.7V not used. Clamped to about 2.5 V 2K 2K due to clamp pulses from pin 19. 6 9 11 INPUT (R) Input at low impedance. INPUT (B) INPUT (G) 2.5 2.5V CP 0.3mA 7 12 VCC 12 Vcc MITSUBISHI 19 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR No. Name DC Voltage (V) peripheral Circuit Remark 8 10 15 19 26 NC GND GND 13 INPUT (S on G) When open ~ 2.5V ~ 3.2V 1K 500 SYNC ON VIDEO input pin. Sync is negative. input signal at Pin7, compare with the reference voltage of internal circuit in order to separate sync signal from Sync on Green signal. 7 18 Sync signal output pin, Being of open collector output type. 14 S on G Sep OUT Input pulses 41K 2.5~5V 0.5V maximum Input at low impedance. 2.2V 0.15mA 16 Clamp Pulse IN 19 17 VCC (5V) MITSUBISHI 20 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR No. Name DC Voltage (V) peripheral Circuit Remark ABL(Automatic Beam Limitter) input pin. Recommended voltage range is 0 to 5V. When ABL function is not used, set to 5V. 2.5V 20K 18 ABL IN When open 2.5V 1.2K 1.2K 30K 0.5mA 15 SCL of I C BUS (Serial clock line) 50K VTH=2.3V 2 20 SCL 20 2K 3V 50K SDA of I C BUS (Serial data line) VTH=2.3V 2 21 SDA 21 2K 3V Input pulses 50K R G B 2.5~5V 0.5V maximum Connected to GND if not used. 22 Retrace BLK IN 22 2.25V MITSUBISHI 21 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR No. 23 27 30 Name GND (B) GND (G) GND (R) DC Voltage (V) peripheral Circuit Remark GND of Rch, Gch and Bch 0 50 A resistor is needed on the GND side. Set discretionally to maximum 24 28 31 25 OUTPUT (B) OUTPUT (G) OUTPUT (R) Variable 50 7 mA, depending on the required driving capacity. Used to supply power to 12 29 32 VCC 2 Impre ssed output emitter follower only. MITSUBISHI 22 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Electrical Chracteristics Main Contrast Control Characteristics Sub Contrast Control Characteristics 6 6 4 4 2 2 Sub Contrast : MAX 000H FFH Main Contrast Control Data OSD Adjust Control Characteristics 000H Main Contrast : MAX Sub Contrast Control Data ABL Characteristics FFH 6 6 4 4 2 2 Main Contrast : MAX Sub Contrast : MAX 0 0H 6 OSD Adjust Control Data Brightness Control Characteristics FH 0 0 ABL Control Voltage(VDC) Sync separate input min sync width 5 12 (Video Duty=75 % ) 4 8 Sync separate normal operating range 2 1u 4 7 100K 00 Brightness Control Voltage(VDC) 5 IN 0 input amplitude(Vp-p) 0.5 MITSUBISHI 23 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR Application Method for M61301SP CLAMP PULSE INPUT Clamp pulse width is recommended above 15 KHz, 1.0 usec above 30 KHz, 0.5 usec above 64 KHz, 0.3 usec . 19 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 Fig. shown right is recommended. Notice of application Make the nearest distance between output pin and pull down resister. Recommended pedestal voltage of IC output signal is 2V. ~ MITSUBISHI 24 25 MITSUBISHI< LINEAR IC > M61301SP BUS CONTROLLED 3CH VIDEO PRE-AMP FOR CRT DISPLAY MONITOR APPLICATION 110V EXAMPLE CRT Cut Off Adjj DAC IC 5VTTL BLK IN (for retrace) SDA 4.7u 0.01u 4.7u 1K 0.01u 4.7u 1K 0.01u 1K 0 ~ 5V SCL ABL IN 17 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 M61301SP 1 2 3 4 5 6 7 8 9 10 11 0.01u 1u 47u 3.3u 0.01u 75 5VTTL 5VTTL 5VTTL 5VTTL 2.5VTTL 2.5VTTL 2.5VTTL 3.3u 0.01u 75 75 0.01u 12 13 14 100K 15 16 1K NC 0.01uu 3.3u 47u 0~5V Sync Sep OUT ClampPulse IN BLK IN (for OSD) OSD IN (G) OSD IN (B) OSD IN (R) 12V 0.01u 47u 5V INPUT (R) INPUT (B) INPUT (G) SONG INPUT MITSUBISHI 25 25 |
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