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| TENTATIVE DATA SHEET 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR DESCRIPTION M52780 - XXXSP is the I2C BUS controlled Semiconductor Integrated Circuit with 150MHz range 3ch Amp and Letter Indication Controller which function in range 30MHz~80MHz. VIDEO Pre-Amp includes ,in each channel , Retrace Blanking, Wide Range Amp,Brightness Control,and Bus Controlled Main Sub Contrast ,OSD Adjust Control,5ch D/A Output,and OSD Controller. Letter Indicate Controller can indicate Characters,such as Chinese character , Hiragana letter , Katakana letter ,English letter , Number letter , and so on. Therefore it is the most suitable for High Resolution Display Monitor. PIN CONFIGURATION FEATURES [Pre - Amp] *Frequency Band Width:RGB 150 MHz *Input :RGB 0.7 Vp-p(Typ) :Retrace BLK 3.0 Vp-p minimum(Positive) *Output :RGB 4.5 Vp-p(Max) :OSD 4.5 Vp-p(Max) *Contrast Control includes Main Control which change 3ch at the same time and Sub Control which change each channel independently. OSD Adjust has Main Control only. *Both can be controlled by I2C BUS. *Include Internal and External Pedestal Clamp Circuit. [D/A] *Output 0 ~ 5V (5ch) [OSD Controller] *Screen composition 24 letters x 12 lines *Number of characters displayed Max 288 letters *Character composition 12 x 18 dots *Characters available 256 kinds *Character sizes available 4(vertical)x 4(horizontal) *Display locations available Horizontal direction 1000 locations Vertical direction 1023 locations *Blinking Character units Cycle : division of vertical synchronization signal into 64 or 32 Duty : 25%, 50%, or 75% *Coloring Character color Character units Background coloring Character units Matrix-outline(shadow)coloring 8 colors (RGB output) Specified by register Border coloring 8 colors (RGB output) Specified by register Raster coloring 8 colors (RGB output) Specified by register *Blanking Blanking off Character size blanking Border size blanking Matrix-outline size blanking All blanking(all raster area) *Display RAM erase function *Display input frequency range 30MHz~80MHz R IN GND1(R) Vcc 1(9V) G IN SOG IN GND1(G) B IN GND1(B) CP OUT Vcc(digital;5V) SOG OUT V IN H IN SDA SCL GND2(Digital) 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 CAP NC Vcc 2(9V) R OUT GND G OUT ABL B OUT Ret. BLK IN D/A OUT 5 D/A OUT 4 D/A OUT 3 D/A OUT 2 D/A OUT 1 Clamp puls in AUTO CLEAR 32 pin plastic SDIP M52780-XXXSP PACKAGE:32P4B APPLICATION CRT DISPLAY MONITOR RECOMMENDED OPERATING CONDITIONS Supply Voltage Range Rated Supply Voltage 8.5~9.5V(Analog Part) 4.75~5.25V(Logic Part) 9.0V(Analog Part) 5.0V (Logic Part) MAJOR SPECIFICATION I2C BUS Controlled 3ch Video Pre-Amp with OSD Controller MITSUBISHI 1 38 Retrace Blanking 24 Vcc 9V SUB CONTRAST OSD MIX AMP 29 R OUTPUT CLAMP F/B 28 MAIN CONTRAST RETRACE BLANKING 3 R OSD R INPUT Block Diagram 1 CLAMP TENTATIVE 2 SUB CONT(8bit) G OSD OSD MIX AMP 27 G OUTPUT G INPUT SUB CONTRAST MAIN CONTRAST RETRACE BLANKING 4 CLAMP 6 CLAMP F/B SUB CONT(8bit) B OSD OSD MIX 25 B OUTPUT 32 CLAMP F/B 31 NC B INPUT SUB CONTRAST AMP MAIN CONTRAST I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI OSD BLK. OSD LEVEL 4bit Main CONTRAST 8bit OSD OUT R G B R SUB CONT 8bit OSD CONTROLLER BLOCK G SUB CONT 8bit B SUB CONT 8bit 9 19 20 21 22 23 12 DAC 17 13 7 CLAMP RETRACE BLANKING 8 SUB CONT(8bit) Contrast(ABL) 26 IN 5 Sync On Green Sep 10 BUS I/F Vcc 5V (DIGITAL) 14 SDA 15 SCL 16 G INPUT SOG Sep OUT 11 18 MITSUBISHI M52780-XXXSP 2 AUTO CLEAR H PULSE IN Clamp Pulse IN 30 Vcc=9V V PULSE IN CPOUT DAC output for cut-off Adj 38 1999. 7.27 CPOUT H PULSE IN V PULSE IN TENTATIVE FROM BUS I/F IN OSD CONTROLLER BLOCK Input control circuit Clock oscillatrion circuit for display Change Polarity Change Synchronous Signal TO OSD MIX OSD BLK R OSD G OSD B OSD Date control circuit Timing generator H counter Display location detection circuit Address control circuit Polarity switching circuit I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI Reading address control circuit Brinking circuit Shift register Display control circuit Display control register Display RAM Display character ROM MITSUBISHI M52780-XXXSP 3 38 1999. 7.27 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR I2C-BUS PROTOCOL Slave address D7 VIDEO PRE-AMP OSD CONTROLLER D6 D5 D4 D3 D2 D1 R/W 1 0 0 1 0 1 0 1 1 1 0 1 0 0 0 0 =88H =7CH Data transmission format * Pre - Amp part 8bit 8bit 8bit S SLAVE ADDRESS A SUB ADDRESS A DATA BYTE A P Transmit all data by a timing of Vsync * OSD part 8bit 8bit 8bit S SLAVE ADDRESS A SUB ADDRESS 1 A SUB ADDRESS 2 A 8bit DATA 11 8bit A DATA 12 A S : Syart condotion A : Acknowledge P : Stop condition 8bit DATA 21 8bit A DATA 22 A 2 bytes after Slave Address set with sub address, and the address increases by 2 bytes. Therefore, I don't need to input an address from next data 8bit DATA n1 8bit A DATA n2 A P MITSUBISHI 4 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR OSD part data input (Sequence) (a) Sub addresses are consists of 16 bits. (b) Data is consists of 16 bits. (c) Sub addresses and data are communicated in 8-bit units. Input the lower 8 bits before the upper 8 bits. Make input from the MSB side. (d) After the start state has been attained and the control byte (7CH) received, the next 16 bits (2bytes) are for inputting the address. Addresses are increased in increments for every 16 bits (2 bytes) of data input thereafter. As a result, it is not necessary to input the address from the second data. S T A R T SLAVE ADDRESS (7CH) SUB ADDRESS1 (Lower 8 bits) M S B A* C K SUB ADDRESS2 DATA11 DATA12 DATAn1 (Upper 8 bits) (Lower 8 bits) (Upper 8 bits) (Lower 8 bits) LM SS BB A C K LM SS BB A C K LM SS BB A C K S T O P SDA S LM SS BB A C K L SP B A C K ACK*(Acknowledge) : Output the acknowledge signal whenevre one byte input after the start state. Output the acknowledge signal and receieve the data thereafter when mach the slave address(7CH). Data input sequence MITSUBISHI 5 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Timing requirement of I2C parameter Input voltage LOW Input voltage HIGH 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 rerevant for a repeated start condition) symbol MIN -0.5 3.0 0 4.7 4.0 4.7 4.0 4.7 0 250 MAX 1.5 5.5 100 units V V KHz s s s s s s ns ns ns s VIL VIH fSCL tBUF tHD:STA tLOW tHIGH tSU:STA tHD:DAT tSU:DAT tR tF tSU:STO 1000 300 Hold time for I2C devices Set-up time DATA Rise time of both SDA and SCL Fall time of both SDA and SCL Set-up time for stop condition 4.0 - tR, tF tBUF VIH SDA VIL tHD:STA VIH SCL tSU:DAT tHD:DAT tSU:STA tSU:STO VIL tLOW S tHIGH S P S MITSUBISHI 6 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Pre - Amp Block sub address byte and data byte format NO. function bit 8 8 8 8 8 4 4 8 8 8 8 8 sub Data Byte (top:byte format under:start condition) add. D7 D6 D5 D4 D3 D2 D1 D0 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H A07 0 2 Sub contrast R 3 Sub contrast G 4 Sub contrast B 5 Brightness cont. 6 OSD level 7 RE-BLK Adjust 8 D/A OUT1 9 D/A OUT2 10 D/A OUT3 11 D/A OUT4 12 D/A OUT5 1 1 1 1 0 0 1 1 1 A06 A05 A04 A03 A02 A01 A00 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 Main contrast A17 A16 A15 A14 A13 A12 A11 A10 A27 A26 A25 A24 A23 A22 A21 A20 A37 A36 A35 A34 A33 A32 A31 A30 A47 A46 A45 A44 A43 A42 A41 A40 A53 A52 A51 A50 A63 A62 A61 A60 A77 A76 A75 A74 A73 A72 A71 A70 A87 A86 A85 A84 A83 A82 A81 A80 A97 A96 A95 A94 A93 A92 A91 A90 0AH AA7 AA6 AA5 AA4 AA3 AA2 AA1 AA0 1 0 0 0 0 0 0 0 0BH AB7 AB6 AB5 AB4 AB3 AB2 AB1 AB0 1 0 0 0 0 0 0 0 MITSUBISHI 7 38 Electrical Characteristics (Vcc = 9V,5V; Ta = 25C unless otherwise specified) Input Control voltage BUS CTL ( H ) Standard MIN TYP MAX Unit Note1 brightness=4V 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH Main Sub cont cont 1 Sub cont 2 Sub Bright cont 3 No OSD BLK D/A D/A D/A D/A INT Adj Adj OUT1 OUT2 OUT3 OUT4 EXT parameter 23 12 13 18 147 5 Symbol Test Point(s) SOG Ret ABL RGB In In H In V In CP In BLK Remark 1 - 130 Circuit current1 Icc1 a a 5.0 IA a a a 110 mA b SG5 b SG5 a 5.0 - 55 mA 35 Note2 FFH FFH FFH FFH 7FH 00H 00H FFH FFH FFH FFH 00H 255 255 255 255 127 0 0 255 255 255 255 0 TENTATIVE 2 a a Circuit current2 Icc2 IB a a 3 a a a 5.0 5.5 - Output dynamic range Vomax OUT b SG2 a 7.0 b SG5 Vari able Vp-p Note3 Note4 4 a a a 5.0 1.5 - Maximum input Vimax IN OUT a - 64H 100 3FH 63 b SG2 b SG5 b SG5 a 5.0 FFH 255 Vp-p Variable brightness=1.5V 5 a a Maximum gain Gv OUT - - - - - - - b SG1 a 0.8 15.4 16.2 17.0 dB Note5 6 Relative maximum gain Gv - - 1.0 1.2 - Note6 7 a a a 5.0 Main contrast control characteristics 1 VC1 OUT - - - - - - - b SG1 a C8H 200 b SG5 13.0 14.0 15.0 dB 0.8 1.0 1.2 - Note7 I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI a a a a 5.0 b SG5 64H 100 8 Main contrast control relative characteristics 1 VC1 - - Note8 9 Main contrast control characteristics 2 VC2 OUT - - - - - - - b SG1 7.0 8.2 9.4 dB Note9 10 Main contrast control relative characteristics 2 VC2 - a a a a 5.0 - 0.8 1.0 1.2 - Note10 11 Main contrast control characteristics 3 VC3 OUT b SG1 14H 20 b SG5 - - - - 0.2 0.4 0.6 Vp-p Note11 12 - - Main contrast control relative characteristics3 VC3 - - - 0.8 1.0 1.2 - Note12 13 a a a 5.0 Sub contrast control characteristics 1 VSC1 OUT b SG1 a - - - - - - b SG5 FFH C8H C8H C8H 255 200 200 200 12.0 14.5 16.0 dB Note13 MITSUBISHI M52780-XXXSP 8 a a a b SG5 - - a - - - 14 Sub contrast control relative characteristics 1 VSC1 - - - - - - 0.8 1.0 1.2 - Note14 38 15 Sub contrast control characteristics 2 VSC2 OUT b SG1 5.0 FFH 64H 64H 64H 255 100 100 100 9.8 10.3 11.5 dB Note15 1999. 7.27 16 Sub contrast control relative characteristics 2 VSC2 - - - - - - - 0.8 1.0 1.2 - Note16 Input Control voltage BUS CTL ( H ) Standard MIN TYP MAX Unit 0.8 1.1 1.4 Vp-p Note17 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH Main Sub Sub Sub Bright OSD BLK D/A D/A D/A D/A INT cont cont cont Adj Adj OUT1 OUT2 OUT3 OUT4 EXT cont 1 3 2 No a a a b SG5 a 5.0 FFH 14H 14H 14H 3FH 00H 00H FFH FFH FFH FFH 00H 0 255 255 255 255 0 255 20 20 20 63 0 parameter 23 12 13 18 147 5 Symbol Test Point(s) SOG Ret ABL RGB In In H In V In CP In BLK Remark 17 Sub contrast control characteristics 2 VSC3 OUT b SG1 - - - - - 0.8 1.0 1.2 - a 2.3 0.8 1.0 1.2 - Vp-p 4.8 2.9 3.5 Vp-p a a 5.0 a - - - - - Note18 TENTATIVE 18 Sub contrast control relative characteristics 2 VSC3 - - 19 Main/sub contrast control characteristics 2 VMSC OUT b SG1 C8H C8H C8H C8H 200 200 200 200 b SG5 - - - FFH FFH FFH FFH 255 255 255 255 Note19 20 - - - 3.2 4.0 - - Main/sub contrast control relative characteristics 2 VMSC - - - - Note20 21 a a ABL control characteristics 1 ABL1 a OUT b SG1 a 4.0 - - - - - - 0.8 1.0 b SG5 Note21 22 ABL control relative characteristics 1 ABL1 - - 1.2 - Note22 23 a ABL control characteristics 2 ABL2 a a 2.0 OUT b SG1 a - - - - - - b SG5 1.5 0.8 2.0 1.0 2.5 1.2 Vp-p - Note23 I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI a a 7FH 127 24 ABL control relative characteristics2 ABL2 - - Note24 25 Brightness control characteristics 1 VB1 OUT a a b SG5 a 5.0 - - - 3.3 3.7 4.1 V Note25 26 - - - Brightness control relative characteristics 1 VB1 - - -0.3 0 0.3 V 1.5 1.8 2.1 V Note26 27 a a a Brightness control characteristics 2 VB2 OUT a b SG5 a 5.0 - - - 3FH 63 Note27 28 - - - Brightness control relative characteristics 2 VB2 - - -0.3 0.7 0 0.9 0.3 1.1 V 1FH 31 Note28 29 a a a Brightness control characteristics 3 VB3 OUT a b SG5 a 5.0 - - - V Note29 MITSUBISHI M52780-XXXSP 9 - - - a a a a 5V - - a - - - 30 Brightness control relative characteristics 3 VB3 - - -0.3 0 0.3 V Note30 38 31 Frequency characteristics 1 (f=50MHz) FC1 OUT b SG3 5.0 Vari able Vari able -2.0 0 2.5 dB Note31 1999. 7.27 32 Frequency relative characteristics 1 (f=50MHz) FC1 - - - - -1.0 0 1.0 dB Note32 Input Control voltage BUS CTL ( H ) Standard MIN TYP MAX Unit -3.0 Note34 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH Bright OSD Sub Main cont cont 1 Sub cont 2 Sub cont 3 No Adj BLK D/A D/A D/A D/A INT Adj OUT1 OUT2 OUT3 OUT4 EXT 18 23 13 12 parameter Symbol Test 147 5 Point(s) Ret ABL SOG RGB In In H In V In CP In BLK Remark 33 Frequency characteristics 1 (f=150MHz) FC1' - - -1.0 Note35 OUT b SG3 a a 5.0 0 3.0 dB Note33 a a 5V a Vari FFH FFH FFH Vari 00H 00H FFH FFH FFH FFH 00H able 255 255 255 able 0 0 255 255 255 255 0 34 Frequency relative characteristics 1 (f=150MHz) FC1' a a a a 5.0 -3.0 3.0 5.0 dB - - 0 1.0 dB - - - TENTATIVE 35 Frequency characteristics 2 (f=150MHz) FC2 OUT b SG3 - - -1.0 5.0 - -25 -20 0 1.0 - - - dB dB a 5V 36 Frequency relative characteristics 2 (f=150MHz) FC2 a a a a 5V a FFH 255 - - Note36 37 Crosstalk 1 (f=50MHz) CT1 2 b SG3 OUT(29) 6 a OUT(32) 11a Note37 38 a a a a Crosstalk 1 (f=150MHz) CT1' 2 b SG3 OUT(29) 6 a OUT(32) 11a a 5V 5.0 - a 5V a 5.0 a 5V a 5.0 a 5V a 5.0 a 5V a 5.0 b SG5 a 5.0 Vari able -15 -10 dB Note38 39 a a a Crosstalk 2 (f=50MHz) CT2 2a OUT(29) 6 b SG3 OUT(35) 11a - -25 -20 dB Note39 40 Crosstalk 2 (f=150MHz) CT2' 2a OUT(29) 6 b SG3 OUT(35) 11a a a a - -15 -10 dB Note40 I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI a a a - a a a - - a a a a b SG5 a 5.0 Variable 41 Crosstalk 3 (f=50MHz) CT3 2a OUT(32) 6 a OUT(35) 11b SG3 -25 -20 dB Note41 42 Crosstalk 3 (f=150MHz) CT3' 2a OUT(32) 6 a OUT(35) 11b SG3 -15 1.7 -10 - dB Note42 43 Pulse characteristics 1 (4Vp-p) Tr OUT b SG1 a a b SG5 a 5.0 Vari able nS Note43 44 Pulse characteristics 2 (4Vp-p) Tf OUT b SG1 a a a FFH 255 - 3.0 - nS Note44 45 Clamp pulse threshold voltage VthCP a Variable OUT b SG1 a a a a b SG5 a 5.0 3FH 63 1.0 1.5 2.0 V Note45 MITSUBISHI M52780-XXXSP 10 a b SG6 b SG6 a b SG5 b SG5 a a 46 Clamp pulse minimum width WCP OUT b SG1 0.2 0.5 5.0 - 3.0 - S Note46 47 OSD pulse characteristics 1 OTr OUT a 6.0 nS Note47 38 1999. 7.27 48 OSD pulse characteristics 2 OTf OUT a 5.0 08H 8 - 3.0 6.0 nS Note48 Input Control voltage BUS CTL ( H ) Standard MIN TYP MAX Unit 5.4 1.0 - Note50 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH Main Sub Sub Sub Bright OSD BLK D/A D/A D/A D/A INT cont cont cont Adj Adj OUT1 OUT2 OUT3 OUT4 EXT cont 1 3 2 No a a 5.0 6.2 1.2 Vp-p - 0.8 b SG6 b SG5 a Note49 FFH FFH FFH FFH 3FH 0FH 00H FFH FFH FFH FFH 00H 255 255 255 255 63 15 0 255 255 255 255 0 4.6 parameter 12 13 18 23 147 5 Symbol Test Point(s) SOG Ret ABL RGB In In H In V In CP In BLK Remark 49 OSD adjust control characteristics 1 Oaj1 OUT a 50 - - - - - - OSD adjust control relative characteristics 1 Oaj1 - - TENTATIVE 51 a a 5.0 0.8 1.0 1.2 - 2.8 3.3 3.8 Vp-p a OSD adjust control characteristics 2 Oaj2 OUT a b SG6 b SG5 08H 8 Note51 52 - - - - - - - OSD adjust control relative characteristics 2 Oaj2 - - Note52 53 a a 5.0 0 -0.15 0 0.1 a OSD adjust control characteristics 3 Oaj3 OUT a b SG6 00H 0 b SG5 - - - - 0.3 0.15 Vp-p - Note53 54 - - - OSD adjust control relative characteristics 3 Oaj3 - - Note54 55 a a 5.0 a Retrace BLK characteristics 1 HBLK1 OUT a b b SG5 SG6 00H 0FH 0 15 1.7 2.0 2.3 V Note55 56 a a 5.0 a Retrace BLK characteristics 2 HBLK2 OUT a b b SG5 SG6 06H 6 0.7 1.0 1.3 V Note56 I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI a a a 5.0 b b SG5 SG6 00H 0 57 Retrace BLK characteristics 3 HBLK3 OUT a 0.1 0.4 0.7 V Note57 58 a a a Retrace BLK input threshold voltag VthRET OUT a b b SG6 SG5 Variable 5.0 a 5.0 a 08H 8 1.0 - 1.5 - 2.0 0.02 V Vp-p Note58 59 a a Variable SOG input maximum noize voltage SS - NV b G4 a 5.0 a a a Variable S on G IN Sync OUT a b G4 Note59 60 SOG minimum input voltage SS - SV a 5.0 5.0 5.0 a a a a S on G IN Sync OUT a 0.2 0.3 - Vp-p Note60 61 Sync Output Hi Level VSH Sync OUT a b SG4 b SG4 a a a a a a a b SG4 b SG4 a a a 4.5 0 0 4.9 0.3 60 5.0 0.6 90 V V nS Note61 MITSUBISHI M52780-XXXSP 11 a 62 Sync Output Lo Level VSL Sync OUT a Note62 63 Sync Output Delay Time1 TDS-F Sync OUT a Note63 38 1999. 7.27 64 Sync Output Delay Time2 TDS-R Sync OUT a 5.0 0 60 90 nS Note64 Input Control voltage BUS CTL ( H ) Standard MIN TYP MAX Unit Note65 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH Main Sub Sub Sub Bright OSD BLK D/A D/A D/A D/A INT cont cont cont cont Adj Adj OUT1 OUT2 OUT3 OUT4 EXT 2 3 1 No a a Note66 12 13 18 23 parameter Symbol Test 147 5 Point(s) SOG Ret ABL RGB In In H In V In CP In BLK Remark 65 a a -1.0 - 0.4 mA a 5.0 0 0.5 1.0 VDC a D/A H output voltage VOH a a D/A OUT a 5.0 5.0 5.5 VDC a FFH FFH FFH FFH 3FH 00H 00H FFH FFH FFH FFH 00H 4.5 255 255 255 255 63 0 0 255 255 255 255 0 TENTATIVE 66 a a a 5.0 -1.0 - 1.0 LSB a a D/A L output voltage VOL D/A OUT a 00H 00H 00H 00H 0 0 0 0 67 a a 5.0 -0.8 0 0.8 a 5.0 a Vari Varia Varia Vari able ble ble able D/A output current range IAO D/A OUT a a Vari Varia Varia Vari able ble ble able Note67 68 a D/A nonlinearity DNL D/A OUT a Note68 43a a a a a b SG5 b SG5 a 5.0 Vari able Vari able Relative Pulse characteristics 1 Tr OUT b SG1 a a a -0.8 0 FFH FFH FFH FFH 255 255 255 255 nS Note43a I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI 44a Relative Pulse characteristics 2 Tf OUT b SG1 0.8 nS Note44a MITSUBISHI M52780-XXXSP 12 38 1999. 7.27 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Note 1) Measuring conditions are as listed in supplementary Table.Mesured with a current meter at test point IA. Note 2) Measureing conditions are as listed in supplemtary Tabke.Measured with a current meter at test point IB. Note 3) Decrease V30 gradually ,and measure the voltage when the 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 5.0 Waveform output VOL 0.0 Note 4) 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. Note 5) Input SG1,and read the amplitude output at OUT(29,32,35).The amplitude is called VOUT(29,32,35).Maximum gain GV is calculated by the equation below: GV=20Log(VOUT/0.7) (dB) Note 6) Relative maximum gain GV is calculated by the equation bellow: GV=VOUT(29)/VOUT(32), VOUT(32)/VOUT(35), VOUT(35)/VOUT(29) Note 7) Measureing the amplitude output at OUT(29,32,35).The measuredvalue is called VOUT(29,32,35). Main contrast control characterics VC1 is calculated by the equation bellow: VC1=20Log(VOUT/0.7) (dB) Note 8) Relative characteristics VC1 is calculated by the equation bellow: VC1=VOUT(29)/VOUT(32), VOUT(32)/VOUT(35), VOUT(35)/VOUT(29) Note 9) Measuring condition and procedure are the same as described in Note7. Note 10) Measuring condition and procedure are the same as described in Note8. Note 11) Measuring condition and procedure are the same as described in Note7. Note 12) Measuring condition and procedure are the same as described in Note8. MITSUBISHI 13 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Note 13) Measur the amplitude output at OUT(29,32,35). The measured value is called VOUT(29,32,35). Sub contrast control characteristics VSC1 is calculated by the equation below: VSC1=20Log(VOUT/0.7) (dB) Note 14) Relative characteristics VSC1 is calculated by the equation below: VCS1=VOUT(29)/VOUT(32), VOUT(32)/VOUT(35), VOUT(35)/VOUT(29). Note 15) Measuring condition and procedure are the same as described in Note13. Note 16) Measuring condition and procedure are the same as described in Note14. Note 17) Measuring condition and procedure are the same as described in Note13. Note 18) Measuring condition and procedure are the same as described in Note14. Note 19) Measure the amplitude output at OUT(29,32,35). The measured value is called VOUT(29,32,35). Main/Sub contrast conrol characteristics VMSC is calculated by the equation below: VMSC=20log(VOUT/0.7) (dB) Note 20) Relative characteristics VMSC is calculated by the equation below: VMSC=VOUT(29)/VOUT(32) , VOUT(32)/VOUT(35) , VOUT(35/VOUT(29) Note 21) Measure the amplitude output at OUT(29,32,35). The measured value is called VOUT(29,32,35), and is ttreated as ABL1. Note 22) Relative characteristics ABL1 is calculated by the equation below: ABL1=VOUT(29)/VOUT(32) , VOUT(32)/VOUT(35) , VOUT(35)/VOUT(29) Note 23) Measuring condition and procedure are the same as described in Note21. Note 24) Measuring condition and procedure are the same as described in Note22. Note 25) Measure the DC voltage at OUT(29,32,35) with a voltmeter. The measured value is called VOUT(29,32,35), and is ttreated as VB1. Note 26) Relative characteristics VB1 is calculated by the difference in the output between the channels. VB1=VOUT(29)-VOUT(32) , VOUT(32)-VOUT(35) , VOUT(35)-VOUT(29) Note 27) Measuring condition and procedure are the same as described in Note25. Note 28) Measuring condition and procedure are the same as described in Note26. Note 29) Measuring condition and procedure are the same as described in Note25. MITSUBISHI 14 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Note 30) Measuring condition and procedure are the same as described in Note26. Note 31) First, SG3 to 1MHz is as input signal. Input a resister that is about 2K to offer the voltage at input pins(2,6,11) 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(29,32,35).Frequency characteristics FC1(29,32,35) is calculated by the equation below: FC1=20 log[VOUT(Vp-p)/output amplitude when inputed SG3(1MHz):4Vp-p](dB) Note 32) Relative characteristics FC1 is calculated by the difference in the output between the channels. Note 33) Measuring condition and procedure are the same as described in Note31,expect SG3 to 150MHz. Note 34) Relative characteristics FC1' is calculated by the difference in the output between the channels. Note 35) 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 to 150MHz is as input signal.The measured value is called VOUT(29,32,35).Frequency characteristics FC2(29,32,35) is calculated by the equation below: FC1=20log[VOUT(Vp-p)/output amplitude when inputed SG3(1MHz):4Vp-p](dB) Note 36) Relative characteristics FC2 is calculated by the difference in the output between the channels. Note 37) Input SG3 (50MHz) to pin2 only, and then measure the waveform amplitude output at OUT(29,32,35).The measured value is called VOUT(29,32,35).Crosstalk CT1 is calculated by the equation below: CT1=20 log [VOUT(29,32)/VOUT(35)] (dB) Note 38) Measuring condition and procedure are the same as described in Note37,expect SG3 to 150MHz. Note 39) Input SG3 (50MHz) to pin6 only, and then measure the waveform amplitude output at OUT(29,32,35).The measured value is called VOUT(29,32,35).Crosstalk CT2 is calculated by the equation below: CT2=20 log [VOUT(29,35)/VOUT(32)] (dB) Note 40) Measuring condition and procedure are the same as described in Note39,expect SG3 to 150MHz. Note 41) Input SG3 (50MHz) to pin11 only, and then measure the waveform amplitude output at OUT(29,32,35).The measured value is called VOUT(29,32,35).Crosstalk CT2 is calculated by the equation below: CT3=20 log [VOUT(32,35)/VOUT(29)] (dB) Note 42) Measuring condition and procedure are the same as described in Note41,expect SG3 to 150MHz. Note 43) Control the main contrast (00H) in order that the amplitude of output signal is 4.0Vp-p. Control the brightness (V30) 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 : Tr= [ (Tr2) 2 -(Tr1) 2 ] (nsec) MITSUBISHI 15 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Note 43a) Relative characteristics Tr is calculated by the difference in the output between the channels. Note 44) 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 : Tf= [ (Tf2)2 -(Tf1)2 ] (nsec) Note 44a) Relative characteristics Tf is calculated by the difference in the output between the channels. 100% 90% 10% 0% Tr1 or Tr2 Tf1 or Tf2 Note 45) 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. Note 46) Decrease the SG5 pulse width gradually from 0.5s, monitoring the output. Measure the SG5 pulse width (a point of 1.5V) when the output pedestal voltage turn decrease with unstable. Note 47) Measure the time needed for the output pulse to rise from 10% to 90% (OTr) with an active prove. Note 48) Measure the time needed for the output pulse to fall from 90% to 10% (OTf) with an active prove. Note 49) Measure the amplitude output at OUT(29,32,35). The measured value is called VOUT(29,32,35), and is treated as Oaj1. Note 50) Relative characteristics Oaj1 is calculated by the equation below: Oaj1=VOUT(29)/VOUT(32), VOUT(32)/VOUT(35), VOUT(35)/VOUT(29) Note 51) Measuring condition and procedure are the same as described in Note49. Note 52) Measuring condition and procedure are the same as described in Note50. Note 53) Measuring condition and procedure are the same as described in Note49. Note 54) Measuring condition and procedure are the same as described in Note50. Note 55) Measure the amplitude output is blanked by the SG6at OUT(29,32,35). The measured value is called VOUT(29,32,35), and is treated as HBLK1. Note 56) Measure the amplitude output is blanked by the SG6at OUT(29,32,35). The measured value is called VOUT(29,32,35), and is treated as HBLK2. MITSUBISHI 16 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Note 57) Measure the amplitude output is blanked by the SG6at OUT(29,32,35). The measured value is called VOUT(29,32,35), and is treated as HBLK3. Note 58) Confirm that output signal is being blanked by the SG6at 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 VthRET. Note 59) The sync's amplitude of SG4 be changed all white into all black, increase from 0Vp-p to 0.02Vp-p. No pulse output permitted. Note 60) 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. Note 61) Measure the high voltage at SyncOUT. The measured value is treated as VSH. Note 62) Measure the low voltage at SyncOUT. The measured value is treated as VSL. Note 63) SyncOUT becomes High with sync part of SG4. Measure the time needed for the rear edge of SG4 sync 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. Note 64) Measure the time needed for the rear edge of SG4 sync to rise from 50 % and for SyncOUT 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%) SyncOUT TDS-F TDS-R Note 65) Measure the DC voltage at D/AOUT. The measured value is ttreated as VOH. Note 66) Measure the DC voltage at D/AOUT. The measured value is ttreated as VOL. Note 67) Electric current flow from the output of D/AOUT must be less than 1.0 mA. Electric current flow in the output of D/AOUT must be less than 0.4 mA. Note 68) The difference of differential non- linearity of D/AOUT must be less than 1.0LSB. MITSUBISHI 17 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR SG No. SG1 Video signal (all white) SG2 Video signal (step wave) SG3 Sine wave (for freq. char.) INPUT SIGNAL 33s 8s Pulse with amplirude of 0.7Vpp ( f=30KHz). Video width of 25 s. (75%) 0.7VP-P 0.7VP-P (Amplitude is partially variable.) Sine wave amplitude of 0.7Vp-p. f=1MHz,50MHz,150MHz(variable) Video width of 25s. (75%) SG4 Videosignal (all white,all black) 3s 0.5s 0.7VP-P all white or all black variable. 0.3VPP Sync's amplitude is variable. SG5 Clamp pulse Pulse width and amplitude are variable. 5VTTL SG6 BLK pulse 5s 5VTTL Amplitude is partially variable. MITSUBISHI 18 38 V15 0~5V OUT(35) C/P IN 470 b a SW 18 SG5 OUT(32) OUT(29) D/A OUT5 D/A D/A b OUT2 OUT1 a TEST CIRCUIT 470 470 TENTATIVE SW 23 1 + 0.1 32 out abl gnd out out ACB blk dac dac dac dac dac c/p 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 cap gnd 9V R SonG gnd 9V G gnd B gnd CP OUT 5V sync V IN H IN sda scl gnd 1 + 2 47 3 4 5 6 7 8 9 10 11 12 13 14 15 16 100K I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MITSUBISHI IN(11) 1K 4700p 3.3 + + IN(2) SYNC OUT 1K 0.1 3.3 + IN(6) SONG IN 0.01 0.01 3.3 0.01 + 1 SW7 a b SW12 SW13 a ba b SDA SCL SW1 SW4 a ba b SW5 a b A 47 MITSUBISHI M52780-XXXSP 19 SG4 A IA SG6 SG7 9V SG1 SG2 SG3 38 1999. 7.27 : MEASURE POINT * Condenser:0.01F(unless otherwise specified.) TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Typical Characteristics Main Contrast Control Characteristics 6 Output Amplitude (Vp-p) Output Amplitude (Vp-p) 6 Sub Contrast Control Characteristics 4 4 2 2 Sub Contrast : Max 0 00H 3 Main Contrast Control Data FFH 0 00H 6 Main Contrast : Max Sub Contrast Control Data FFH Brightness Control Characteristics ABL Characteristics Output DC Voltage (VDC) Output Amplitude (Vp-p) 2 4 1 2 Main Contrast:Max Sub Contrast :Max 0 00H Brightness Control Data 7FH 0 0 ABL Control Voltage (VDC) 5 6 OSD Adjust Control Characteristics Duty of sync width (%) 12 Sync separate input min. sync width (Video Duty=75%) Output Amplitude (Vp-p) 4 8 Sync separate normal operating range 2 1 4 7 100K 0 0H OSDAdjust Control Data FH IN 0 Input amplitude (Vp-p) 0.5 MITSUBISHI 20 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR MEMORY CONSTITUTION Address 0000 H to 011F H are assigned to the display RAM, address 0120 H to 0128 H are assigned to the display control registers. The internal circuit is reset and all display control registers (address 0120 H to 0128 H) are set to "0" and display RAM (address 0000 H to 011F H) are set to "00FF H" when the AC pin level is "L". Memory constitution is shown in Figure 1. Upper 8 bits (DATA n2) Sub address SCREEN CONSTITUTION The screen lines and rows are determined from each address of the display RAM. The screen constitution is shown in Figure 2. Lower 8 bits (DATA n1) DA9 G DA8 R DA7 C7 DA6 C6 DA5 C5 DA4 C4 DA3 C3 DA2 C2 DA1 C1 DA0 C0 DAF 0 DAE BB DAD BG DAC BR DAB BLINK DAA B 0000H Background coloring 011FH 0120H 0121H 0122H 0123H 0124H 0125 H 0126 H 0127H 0128H 0 0 0 0 0 0 0 0 0 0 BB 0 0 0 0 0 0 0 0 0 BG DIVS2 PTD7 BR DIVS1 PTD6 BLINK DIVS0 PTD5 Character color Character code B DIV10 PTD4 G DIV9 PTD3 HP9 VP9 DSP9 R DIV8 PTD2 HP8 VP8 DSP8 V1SZ0 C7 DIV7 PTD1 HP7 VP7 DSP7 LIN9 C6 DIV6 PTD0 HP6 VP6 DSP6 LIN8 LIN16 VR BLK1 C5 DIV5 PTC5 HP5 VP5 DSP5 LIN7 LIN15 FB BLK0 C4 DIV4 PTC4 HP4 VP4 DSP4 LIN6 LIN14 FG POLH C3 DIV3 PTC3 HP3 VP3 DSP3 LIN5 LIN13 FR POLV C2 DIV2 PTC2 HP2 VP2 DSP2 LIN4 LIN12 RB VMASK C1 DIV1 PTC1 HP1 VP1 DSP1 LIN3 LIN11 RG B/F C0 DIV0 PTC0 HP0 VP0 DSP0 LIN2 LIN10 RR BCOL SPACE2 SPACE1 SPACE0 MOVON TEST3 PTC67 TEST2 MOVE TEST1 DSP11 TEST0 DSP10 VSZ1H1 VSZ1H0 VSZ1L1 VSZ1L0 V1SZ1 VSZ2H1 VSZ2H0 VSZ2L1 VSZ2L0 V18SZ1 V18SZ0 LIN17 HSZ21 HSZ20 HSZ11 HSZ10 BETA14 VB VG BLINK2 BLINK1 BLINK0 DSPON STOP RAMERS SYAD Memory constitution Column Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 H 21 22 H 23 24 1 2 3 4 5 6 7 8 9 10 11 12 0000 H 0001 H 0002 H 0003 H 0004 H 0005 H 0006 H 0007 H 0008 H 0009 H 000A H 000B H 000C H 000DH 000E H 000F H 0010 H 0011 H 0012 H 0013 0014 H 0015 0016 H 0017 H 0018 H 0019 H 001A H 001B H 001C H 001DH 001E H 001F H 0020 H 0021 H 0022 H 0023 H 0024 H 0025 H 0026 H 0270 H 0280 H 0029 H 002A H 002B H 002C H 002D H 002E H 002F H 0030 H 0031 H 0032 H 0033 H 0034 H 0035 H 0036 H 0037 H 0038 H 0039 H 003A H 003B H 003C H 003DH 003E H 003F H 0040 H 0041 H 0042 H 0043 H 0044 H 0045 H 0046 H 0047 H 0048 H 0049 H 004A H 004B H 004C H 004DH 004E H 004F H 0050 H 0510 H 0052 H 0053 H 0054 H 0055 H 0056 H 0057 H 0058 H 0059 H 005A H 005B H 005C H 005D H 005E H 005FH 0060 H 0061 H 0062 H 0063 H 0064 H 0065 H 0066 H 0067 H 0680 H 0069 H 006A H 006B H 006C H 006DH 006E H 006F H 0070 H 0071 H 0072 H 0073 H 0074 H 0075 H 0076 H 0077 H 0078 H 0079 H 007A H 007B H 007C H 007DH 007E H 007F H 0080 H 0081 H 0820 H 0083 H 0084 H 0085 H 0086 H 0087 H 0088 H 0089 H 008A H 008B H 008C H 008D H 008E H 008FH 0090 H 0091 H 0092 H 0093 H 0094 H 0095 H 0096 H 0097 H 0098 H 0099 H 009A H 009B H 009C H 009DH 009E H 009F H 00A0 H 00A1 H 00A2 H 00A3 H 00A4 H 00A5 H 00A6 H 00A7 H 00A8 H 00A9 H 00AAH 00AB H 00ACH 00ADH 00AEH 00AFH 00B0 H 00B1 H 00B2 H 00B3 H 00B4 H 00B5 H 00B6 H 00B7 H 00B8 H 00B9 H 00BAH 00BB H 00BCH 00BD H 00BE H 00BF H 00C0 H 00C1 H 00C2 H 00C3 H 00C4 H 00C5H 00C6 H 00C7H 00C8 H 00C9H 0CA0 H 00CB H 00CCH 00CDH 00CEH 00CFH 00D0 H 00D1H 00D2 H 00D3 H 00D4 H 00D5 H 00D6 H 00D7H 00D8 H 00D9 H 00DAH 00DBH 00DCH 00DDH 00DEH 00DFH 00E0 H 00E1 H 00E2 H 00E3 H 00E4 H 00E5 H 00E6 H 00E7 H 00E8 H 00E9 H 00EAH 00EB H 00ECH 00ED H 00EE H 00EFH 00F0 H 00F1 H 00F2 H 00F3 H 00F4 H 00F5 H 00F6 H 00F7 H 00F8 H 00F9 H 00FA H 00FBH 00FCH 00FDH 00FE H 00FF H 0100 H 0101 H 0102 H 0103 H 0104 H 0105 H 0106 H 0107 H 0108 H 0109 H 010A H 010B H 010C H 010DH 010E H 010F H 0110 H 0111 H 0112 H 0113 H 0114 H 0115 H 0116 H 0117 H 0118 H 0119 H 011A H 011B H 011C H 011D H 011E H 011F H The hexadecimalnumbers in the boxes show the display RAM address. Screen constitution MITSUBISHI 21 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR REGISTERS DESCRIPTION (1) Address 0120 H Contents DA Register Starus 0 Function Set multiply value (frequency value) of horizontal synchronous frequency. Remarks Display frequency is computed as show below. FOSC = fH X N1 FOSC [MHz] : Display frequency : Horizontal synchronous fH [KHz] signal frequency to HOR pin. : Shown left N1 Set display frequency FOSC to within 30MHz to 80MHz range. When display frequency FOSC, set frequency value N2 in association with DIVS0 and DIVS1. 0 DIV0 1 0 1 DIV1 1 10 0 N1 = 2 DIV2 1 0 n=0 (DIV n X 2 n ) N1:frequency value 3 DIV3 1 0 4 DIV4 1 0 5 DIV5 1 0 6 DIV6 1 0 7 DIV7 1 0 8 DIV8 1 0 9 DIV9 1 0 A DIVS0 1 0 Set frequency value N2 DIVS 1 0 0 1 1 0 0 1 0 1 Frequency value N2 Division into 2 Division into 3 Division into 4 Do not set Set frequency value N2 in association with display frequency range. Display frequency Frequency value N2 B DIVS1 1 0 C DIVS2 1 0 55 ~ 80 40 ~ 55 30 ~ 40 Division into 2 Division into 3 Division into 4 Normally set to "0". Do not set D DIVS3 1 Note 1 : The mark around the status value means the reset status by the "L" level is input to AC pin. MITSUBISHI 22 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (2) Address 0121 H Contents DA Register Starus 0 Function P0 output (port P0). Port data is set by PTD0. BLNK0 output. Polarity is set by PTD0. P1 output (port P1). Port data is set by PTD1. R signal output. Polarity is set by PTD1. P2 output (port P2). Port data is set by PTD2. Do not set. P3 output (port P3). Port data is set by PTD3. G signal output. Polarity is set by PTD3. P4 output (port P4). Port data is set by PTD4. Do not set. P5 output (port P5). Port data is set by PTD5. B signal output. Polarity is set by PTD5. "L" output (P0 output) or negative polarity output (BLNK0 output). "H" output (P0 output) or positive polarity output (BLNK0 output). "L" output (P1 output) or negative polarity output (R signal output). "H" output (P1 output) or positive polarity output (R signal output). "L" output (P2 output). Remarks 0 PTC0 1 0 BLNK0 outputs blanking signal. Blanking status is determined by BLK0, BLK1, and DSP0 to DSP11 setting. 1 PTC1 1 0 2 PTC2 1 0 3 PTC3 1 0 4 PTC4 1 0 5 PTC5 1 0 P0 pin deta control. 6 PTD0 1 0 P1 pin deta control. 7 PTD1 1 0 8 PTD2 1 0 "H" output (P2 output). "L" output (P3 output) or negative polarity output (G signal output). "H" output (P3 output) or positive polarity output (G signal output). "L" output (P4 output). Set P2 output level. P3 pin deta control. 9 PTD3 1 0 A PTD4 1 0 "H" output (P4 output). "L" output (P5 output) or negative polarity output (B signal output). "H" output (P5 output) or positive polarity output (B signal output). "L" output (P6 output). Set P4 output level. P5 pin deta control. B PTD5 1 0 C PTD6 1 0 "H" output (P6 output). "L" output (P7 output). Set P6 output level. D PTD7 1 "H" output (P7 output). Set P7 output level. MITSUBISHI 23 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (3) Address 0122 H Contents DA Register Starus HP0 (LSB) 0 9 Function If HS is the horizontal display start location, HS = T X ( 2 n HPn + N ) n=0 T: The cycle of display frequency Remarks 0 1 0 Horizontal display atart location is specified using the 10 bits from HP9 to HP0. Note:HP9 to HP0 = (0000000000 2) and 1 HP1 1 0 2 HP2 1 0 HSZ11 HSZ21 0 0 1 1 HSZ10 HSZ20 0 1 0 1 Frequency value N2 Division into 2 Division into 3 Division into 4 Do not set (0000010111 2) setting is forbidden 1000 settings are possible 3 HP3 1 0 4 HP4 1 0 5 HP5 1 0 6 HP6 1 0 7 HP7 1 0 8 HP8 1 HP9 (MSB) 0 9 1 0 Normally set to "0". Test mode SPACE 1 0 0 1 1 0 0 1 1 Number of Lines and Space ( S represents space) A TEST9 1 0 B SPACE0 1 0 C SPACE1 1 0 D SPACE2 1 S 2 0 0 0 0 1 1 1 1 0 0 1 0 1 0 1 0 1 1 2 3 4 5 6 S S S S S 12 10 8 6 4 2 S S S S S S S S 1 2 3 4 5 6 Leave one line worth of space in the vertical direction. For example, 6 6 indicates two sets of 6 lines with a line of spaces between lines 6 and 7. A lone is 18 X N horizontal scan lines. N is determined by the character size in the vertical direction as follows: X1 X3 6 6 N=1 N=3 X2 X3 N=2 N=3 represents one line worth of spaces. MITSUBISHI 24 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (4) Address 0123 H Contents DA Register Starus VP0 (LSB) 0 9 Function If VS is the horizontal display start location, VS = H X ( n=02 n VPn ) H: Cycle with the horizontal synchronizing pulse 1023 setting are possible. Remarks 0 1 0 The vertical start location is specified using the 10 bits from VP9 to VP0. VP9 to VP0 = (0000000000 2) setting is forbidden. Note 1: In case of B/F register is "0". 1 VP1 1 0 HIN 2 VP2 1 0 VIN HP Character displaying area VP 3 VP3 1 0 4 VP4 1 0 5 VP5 1 0 6 VP6 1 0 7 VP7 1 0 8 VP8 1 VP9 (MSB) 0 9 1 0 Normally set to "0". Test mode Normally set to "0". Test mode Normally set to "0". Test mode Normally set to "0". Test mode A TEST0 1 0 B TEST1 1 0 C TEST2 1 0 D TEST3 1 MITSUBISHI 25 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (5) Address 0124 H Contents DA Register Starus 0 Function Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. (Note) Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. Blanking is in the display mode specified by except BLK0 and BLK1. Blanking is in the display mode specified by BLK0 and BLK1. Blanking is in the display mode specified by except BLK0 and BLK1. NOrmally set to "0". Test mode NOrmally set to "0". Test mode Remarks Sets the display mode of line 1. 0 DSP0 1 0 Sets the display mode of line 2. 1 DSP1 1 0 Sets the display mode of line 3. 2 DSP2 1 0 Sets the display mode of line 4. 3 DSP3 1 0 Sets the display mode of line 5. 4 DSP4 1 0 Sets the display mode of line 6. 5 DSP5 1 0 Sets the display mode of line 7. 6 DSP6 1 0 Sets the display mode of line 8. 7 DSP7 1 0 Sets the display mode of line 9. 8 DSP8 1 0 Sets the display mode of line 10. 9 DSP9 1 0 Sets the display mode of line 11. A DSP10 1 0 Sets the display mode of line 12. B DSP11 1 0 C TEST4 1 0 D TEST5 1 Note 2 : Refer to DISPLAY FORM 1. MITSUBISHI 26 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (6) Address 0125 H Contents DA Register Starus 0 Function The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. H: Cycle with the horizontal synchronizing pulse V1SZ1 V1SZ0 Vertical direction sive Remarks Character size setting in the vertical direction for the 2nd line. 0 LIN2 1 0 1 LIN3 1 0 Character size setting in the vertical direction for the 3rd line. 2 KIN4 1 0 Character size setting in the vertical direction for the 4th line. 3 LIN5 1 0 Character size setting in the vertical direction for the 5th line. 4 LIN6 1 0 Character size setting in the vertical direction for the 6th line. 5 LIN7 1 0 Character size setting in the vertical direction for the 7th line. 6 LIN8 1 0 Character size setting in the vertical direction for the 8th line. 7 LIN9 1 0 Character size setting in the vertical direction for the 9th line. 8 V1SZ0 1 0 9 V1SZ1 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction for the 1st line. ( display monitor 1 ~ 12 line ) H: Cycle with the horizontal synchronizing pulse VSZ1L1 VSZ1L0 Vertical direction sive A VSZ1L0 1 0 B VSZ1L1 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction (display monitor 1 line) at "0" state in register LIN2 ~ LIN17. H: Cycle with the horizontal synchronizing pulse VSZ1H1 VSZ1H0 Vertical direction sive C VSZ1H0 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction (display monitor 1 line) at "1" state in register LIN2 ~ LIN17. D VSZ1H1 1 MITSUBISHI 27 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (7) Address 0126 H Contents DA Register Starus 0 Function The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. The first line is set by VSZ1L0 and VSZ1L1. The second to 12th lines are set by VSZ2L0 and VSZ2L1. The first line is set by VSZ1H0 and VSZ1H1. The second to 12th lines are set by VSZ2H0 and VSZ2H1. H: Cycle with the horizontal synchronizing pulse V18SZ1 V18SZ0 Vertical direction sive Remarks Character size setting in the vertical direction for the 10th line. 0 LIN10 1 0 1 LIN11 1 0 Character size setting in the vertical direction for the 11th line. 2 KIN12 1 0 Character size setting in the vertical direction for the 12th line. 3 LIN13 1 0 Character size setting in the vertical direction for the 13th line. 4 LIN14 1 0 Character size setting in the vertical direction for the 14th line. 5 LIN15 1 0 Character size setting in the vertical direction for the 15th line. 6 LIN16 1 0 Character size setting in the vertical direction for the 16th line. 7 LIN17 1 0 Character size setting in the vertical direction for the 17th line. 8 V18SZ0 1 0 9 V18SZ1 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction for the 18th line. ( display monitor 1 ~ 12 line ) H: Cycle with the horizontal synchronizing pulse VSZ2L1 VSZ2L0 Vertical direction sive A VSZ2L0 1 0 B VSZ2L1 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction (display monitor 2 ~ 12 line) at "0"state in register LIN2 ~ LIN17. H: Cycle with the horizontal synchronizing pulse VSZ2H1 VSZ2H0 Vertical direction sive C VSZ2H0 1 0 D VSZ2H1 1 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction (display monitor 2 ~ 12 line) at "1"state in register LIN2 ~ LIN17. MITSUBISHI 28 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (8) Address 0127 H Contents DA Register Starus 0 RB 0 0 0 0 1 1 1 1 RG 0 0 1 1 0 0 1 1 RR 0 1 0 1 0 1 0 1 Function Color Black Red Green Yellow Blue Magenta Cyan White Remarks Sets the color of all blanking. 0 RR 1 0 1 RG 1 0 2 RB 1 0 BB 0 0 0 0 1 1 1 1 BG 0 0 1 1 0 0 1 1 BR 0 1 0 1 0 1 0 1 Color Black Red Green Yellow Blue Magenta Cyan White Sets the blanking color of the Border size, or the shadow size. 3 FR 1 0 4 FG 1 0 5 FB 1 0 Normally set to "0". Test mode Normally set to "0". Test mode Normally set to "0". Test mode Matrix-outline display (12 X 18 dot) Matrix-outline display (14 X 18 dot) T: Display frequency cycle HSZ11 HSZ10 Vertical direction sive 6 TEST6 1 0 7 TEST7 1 0 8 TEST8 1 0 9 BETA14 1 0 Set this register to the character font set by display RAM BR, BG and BB. A HSZ10 1 0 Character size setting in the vertical direction for the first line. B HSZ11 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot T: Display frequency cycle VSZ21 VSZ20 Vertical direction sive C HSZ20 1 0 0 0 1 1 0 1 0 1 1H/dot 2H/dot 3H/dot 4H/dot Character size setting in the vertical direction for the 2nd line to 12th line. D HSZ21 1 MITSUBISHI 29 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR (9) Address 0128 H Contents DA Register Starus 0 Blanking of BLK0, BLK1 All raster blanking Synchronize with the leading edge of horizontal synchronization. Synchronize with the trailing edge of horizontal synchronization. Do not mask by VERT input signal Mask by VERT input signal VERT pin polarity is negative electrode VERT pin polarity is positive electrode HOR pin polarity is negative electrode HOR pin polarity is positive electrode BLK 1 0 0 1 1 0 0 1 0 1 Set blanking mode. (Note 3) An example of blanking mode at BCOL = "0",DSPn = "0"(n = 0 ~ 11) shown left. Set HOR pin polarity Set VERT pin polarity Synchronize with the front porch or back porch of the horizontal synchronazation signal. This register has or do not have mask at phase comparison operating. Function Remarks Sets all raster blanking 0 BCOL 1 0 1 B/F 1 0 2 VMASK 1 0 3 POLV 1 0 4 POLH 1 0 5 BLK0 1 0 Blanking mode Matrix-outline size Character size Border size Matrix-outline size 6 BLK1 1 0 Border display of character Shadow display of character RAM not erased RAM erased Oscillation of clock for display Stop the oscillation of clock for display Display OFF Display ON BLK 1 0 0 1 1 (Note 4) 7 SYAD 1 0 8 RAMERS 1 0 There is no need to reset because there is no register for this bit. 9 STOP 1 0 R, G, B, and BLNK0 output can be altered. Display can be altered. A DSPON 1 0 Blinking duty ratio can be altered. 0 0 1 0 1 Duty Blinking OFF 25% 50% 75% B BLINK0 1 0 C BLINK1 1 0 Divided into 64 of vertical synchronous signal Divided into 32 of vertical synchronous signal Blinking frequency can be altered. D BLINK2 1 Note 3: Refer to DISPLAY FORM 1 4: Refer to DISPLAY FORM 3 MITSUBISHI 30 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR DISPLAY FORM 1 Table 1 shows display form of blanking. Table 1. Display mode Standard blanking BCOL BLK1 BLK0 When the all of registers DSPn (Note 2) are set to "0" Matrix-outline and border display. color set: FR,FG,FB or display RAM (Note 4) When some of registers DSPi are set to "1" BLNK0 output DSPn = 0 Matrix-outline and border display. color set: FR,FG,FB or display RAM (Note 4) DSPn = 1 Matrix-outline display color set: display RAM (Note 3) Border display color set: display RAM (Note 3) Matrix-outline display color set: display RAM (Note 3) DSPn = "0"line Matrix-outline size DSPn = "0"line DSPn = "0"line DSPn = "0"line Character size Border size 0 0 0 0 1 1 Character Character 0 Border display color set: display RAM (Note 3) Matrix-outline display color set: display RAM (Note 3) Matrix-outline and border display. color set: FR,FG,FB or display RAM (Note 4) Border display color set: display RAM (Note 3) Matrix-outline display color set: display RAM (Note 3) Matrix-outline and border display. color set: FR,FG,FB or display RAM (Note 4) DSPn = "0"line DSPn = "0"line DSPn = "0"line DSPn = "0"line Border size Matrix-outline size Matrix-outline size Character size 1 1 Character 0 0 Matrix-outline display color set: display RAM (Note 3) Border display color set: display RAM (Note 3) All blanking size Matrix-outline display color set: display RAM (Note 3) 0 1 (Note 1) 1 Character Character 1 0 Border display color set: display RAM (Note 3) Matrix-outline display color set: display RAM (Note 3) Border display color set: display RAM (Note 3) Matrix-outline display color set: display RAM (Note 3) 1 1 Character Note 1: Color setting of raster area is set by register RR, RG, and RB. 2: DSPn (n = 0 ~ 11) 3: Set by BR, BG, and BB of display RAM. 4: Set border by register FR, FG, and FB. Set matrix-outline by BR, BG, and BB of display RAM. MITSUBISHI 31 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR DISPLAY FORM 2 M52780SP has the following four display forms. (1) Character size : Blanking same as the character size. (2) Border size : Blanking the background as a size from character. (3) Marrix-outline size : Blanking the background 12 X 18 dot. When set register BETA14 to "1", setting of blanking the background 14 X 18 dot is possible. (4) All blanking size : When set register BCOL to "1", all raster area is blanking. < Register BCOL = "0" > 12dots 12dots 12dots 12dots Scanning Set character color by display 1 RAM * (address 0 to 011F H ) Set border color by display RAM *1 Set matrix-outline color by display RAM * 3 Set border color by register FR, FG and FB R, G or B output Set matrix-outline color by RAM for display * 3 BLNK0 output (1) Character display (character size)* 2 (2) Border display (border size) (3) Matrix-outline display (border size) (4) Matrix-outline and border display (border size) < Register BCOL = "1" > 12dots 12dots 12dots 12dots Scanning Set character color by display 1 RAM * (address 0 to 011F H ) Set raster area color by register RR, RG and RB Set matrix-outline color by display RAM * 3 Set border color by register FR, FG and FB R, G or B output Set border color by 1 display RAM * "H" level BLNK0 output GND level (1) Character display (all blanking size) (2) Border display (all blanking size) (3) Matrix-outline display (all blanking size) (4) Matrix-outline and border display (all blanking size) Set matrix-outline color by RAM for display * 3 *1 Red, Blue, Yellow, Green, Magenta, Cyan, White and Black are set possible. *2 ( ) is blanking moded. *3 All matrix-outline horizontal direction size is able to set to 14 dots by register BETA14 (BLNK0 output by 14 dots). Display form MITSUBISHI 32 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR DISPLAY FORM 3 When border display mode, if set SYAD = "0" to "1", it change to shadow display mode. Border and shadow display are shown below. Border display Shadow display Border and shadow display Set shadow display color by display RAM or register FR, FG and FB. MITSUBISHI 33 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR DATA INPUT EXAMPLE Data of display RAM and display control registers can be set by the I2C input function. Example of data setting is shown in Figure 5. Example of data setting by the serial input function (M52780SP) Upper 8 bits (ADDRESS2 or DATA n2) DAF DAE DAD DAC DAB DAA DA9 DA8 DA7 Lower 8 bits (ADDRESS1 or DATA n1) DA6 DA5 DA4 DA3 DA2 DA1 DA0 Addition System set-up 200 msec hold 1 address 0120H 2 deta 3 deta 4 deta 5 deta 6 deta 7 deta 8 deta 9 deta 10 deta 0120H 0121H 0122H 0123H 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 1 0 0 0 0 0 Address set Setting frequency dividing value (Note 1) DIVS1 DIVS0 DIV10 DIV9 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 HP9 VP9 0 0 0 0 0 DIV8 DIV7 DIV6 DIV5 DIV4 DIV3 DIV2 DIV1 DIV0 0 HP8 VP8 0 0 0 0 1 1 HP7 VP7 0 0 0 0 0 1 HP6 VP6 0 0 0 0 1 1 HP5 VP5 0 0 0 0 1 0 HP4 VP4 0 0 0 0 1 HP3 VP3 0 0 0 0 0 HP2 VP2 0 0 0 0 0 1 HP1 VP1 0 0 0 0 0 1 HP0 VP0 0 0 0 0 0 Output setting Horizontal display location setting Vertical display location setting Display form setting Character size setting Character size setting Color, character size setting Display OFF, display form (Note 2) 0124H 0125H 0126H 0127H 0128H POLH POLV 20 msec hold 11 deta 12 0000H 0 BB BG BR BLINK B G R C7 C6 C5 C4 C3 C2 C1 C0 297 298 deta 011FH Character background color 0 0 0 BB 0 0 BG 0 0 BR 0 0 BLINK 0 0 B 0 1 Character color G 0 0 R 1 0 C7 0 0 C6 0 1 C5 1 1 Character code Character setting C4 0 C3 1 C2 0 0 C1 0 0 C0 0 0 Address setting Display ON, display form (Note 2) 299 address 0128H 300 deta 0128H POLH POLV Note 1: Input horizontal synchronous signal to HOR pin. 2: Matrix-outline display in this data. Example of data setting by the I2C input function MITSUBISHI 34 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR CHARACTER FONT Images are composed on a 12 X 18 dot matrix, and characters can be linked vertically and horizontally with other characters to allow the display the continuous symbols. 12 dots 18 dots When the character extends to the top line of the matrix, no border is left at the top. When the character extends to the bottom (18th) line of the matrix, no border is left at the bottom. Note : Hatching represets border. Example for displaying a continuous pattern after combining characters in the horizontal or vertical direction Character code FFH is fixed as a blank without background. Therefore, you cannot register a character font in this code. MITSUBISHI 35 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR PIN DESCRIPTION Pin Number Symbol CPOUT Pin name Input/ Output Output Function Connect loop filter to this pin. 9 Phase difference 1pin 1k *1 4700pF *2 CPOUT 0.1 uF *2 *1 Use at 1 % precision *2 Use at 10% precision 12 13 17 VIN HIN AC Vertical synchronization signal input Horizontal synchronization signal input Auto-clear input Input Input Input This pin inputs the vertical synchrinization signal. Hysteresis input. This pin inputs the horizontal synchrinization signal. Hysteresis input. When "L", this pin resets the internal IC circuit.Hysteresis input. Includes built-in pull-up resistor. MITSUBISHI 36 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR Application Method CLAMP PULSE INPUT Clamp pulse width is recommended above 15 KHz, 1.0 sec above 30 KHz, 0.5 sec above 64 KHz, 0.3 sec . 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. 18 ~ Notice of application * Make the nearest distance between output pin and pull down resister. * Recommended pedestal voltage of IC output signal is 2V. MITSUBISHI 37 38 TENTATIVE 1999. 7.27 MITSUBISHI M52780-XXXSP I2C BUS CONTROLLED 3CH VIDEO PRE-AMP WITH OSD CONTROLLER FOR HIGH RESOLUTION COLOR DISPLAY MONITOR APPLICATION EXAMPLE 110V CRT Cut Off Adj DAC OUTX5 5VTTL BLK IN (for retrace) 0.01 47 + 1K 1K 0~5V 1K 0.1 0.01 0.01 0.01 0.01 0.01 0.01 ClampPulse IN + 1 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 M52780-XXXSP 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 1 3.3 0.01 + 100K 3.3 0.01 + 3.3 + 0.01 75 75 + 1K 75 0.1 4700pF SCL SDA 0.01 + 47 0.01 + 47 9V 5V INPUT (R) INPUT SonG (G) INPUT INPUT (B) Sync Sep OUT V IN H IN MITSUBISHI 38 38 |
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