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| MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH DESCRIPTION The M52758 is a semiconductor integrated circuit f or the RGBHV interf ace. The dev ice f eatures switching signals input f rom two ty pes of image and outputting them to CRT display etc. Sy nchronous signal meeting the f requency band of 10 kHz to 200 kHz are output at TTL. The f requency band of v ideo signals is 250MHz, acquiring high-resolution images,and are optimum as an interf ace IC with high-resolution CRT display and v arious new media. PIN CONFIGURATION(TOP VIEW) Vcc1(R) INPUT1(R) Vcc1(G) NC INPUT1(G) Vcc1(B) INPUT1(B) INPUT1(H) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 36 Vcc2(R) 35 OUTPUT(R) 34 GND 33 NC 32 NC 31 Vcc2(G) 30 OUTPUT(G) 29 GND 28 Vcc2(B) 27 OUTPUT(B) 26 GND 25 OUTPUT(for sync-onG) 24 Vcc 23 NC 22 OUTPUT(H) 21 OUTPUT(V) 20 GND 19 SWITCH FEATURES Frequency band : RGB 250MHz HV 10Hz to 200kHz Input lev el : RGB 0.7Vp-p (ty p.) HV TTL input 2.0Vo-p(both channel) Only t he G channel is prov ided with sy nc-on v ideo output. The TTL f ormat is adopted f or HV output. INPUT1(V) GND INPUT2(R) GND INPUT2(G) NC GND INPUT2(B) APPLICATION Display m onitor INPUT2(H) INPUT2(V) RECOMMENDED OPERATING CONDITION Supply v oltage range Rated supply v oltage 4.75 to 5.5V 5.0V Vcc1(R) INPUT1(R) Vcc1(G) INPUT1(G) Vcc1(B) INPUT1(B) INPUT1(H) INPUT1(V) GND INPUT2(R) GND INPUT2(G) GND INPUT2(B) INPUT2(H) INPUT2(V) Outline 36P2R-D 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 32 Vcc2(R) 31 OUTPUT(R) 30 GND 29 Vcc2(G) 28 OUTPUT(G) 27 GND 26 Vcc2(B) 25 OUTPUT(B) 24 GND 23 OUTPUT(for sync-onG) 22 NC 21 Vcc 20 OUTPUT(H) 19 OUTPUT(V) 18 GND 17 SWITCH Outline 32P4B NC : NO CONNECTION MITSUBISHI ELECTRIC 1 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH BLOCK DIAGRAM M52758FP OUTPUT(R) Vcc2(R) 36 35 GND 34 NC NC 33 32 Vcc2(G) GND OUTPUT OUTPUT(B) (for sync on G) Vcc2(B) 28 27 GND 26 25 Vcc 24 NC OUTPUT(V) SWITCH OUTPUT(G) 31 30 29 OUTPUT(H) 23 22 21 GND 20 19 1 2 INPUT1(R) 3 4 NC 5 6 Vcc1(B) 7 8 9 10 GND 11 12 GND 13 14 NC 15 16 17 18 INPUT2(V) INPUT1(H) INPUT2(B) GND Vcc1(R) Vcc1(G) INPUT1(G) INPUT1(B) INPUT1(V) INPUT2(R) INPUT2(G) INPUT2(H) BLOCK DIAGRAM M52758SP OUTPUT(R) Vcc2(R) 32 31 GND 30 Vcc2(G) GND OUTPUT OUTPUT(B) (for sync on G) Vcc2(B) 26 25 GND 24 23 NC 22 Vcc OUTPUT(V) GND 18 SWITCH OUTPUT(G) 29 28 27 OUTPUT(H) 21 20 19 17 1 2 INPUT1(R) 3 4 5 6 7 8 INPUT1(V) 9 10 11 12 13 14 15 16 INPUT2(V) INPUT1(G) INPUT1(B) Vcc1(B) INPUT2(R) INPUT2(G) INPUT2(B) Vcc1(R) Vcc1(G) INPUT1(H) GND GND GND INPUT2(H) MITSUBISHI ELECTRIC 2 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH ABSOLUTE MAXIMUM RATIINGS(Ta=25 oC ) Symbol Vcc Pd Topr Tstg Vopr Vopr' Surge Parameter Supply voltage Power dissipation Ambient temperature Storage temperature Recommended supply voltage Recommended supply voltage range Electrostatic discharge Ratings 7.0 1068(FP) 1603(SP) -20 to +85 -40 to +150 5.0 4.75 to 5.5 +200 o Unit V mW o o C C V V V ELECTRICAL CHARACTERISTICS Pin No is FP(Vcc=5V, Ta=25 C ,unless otherwise noted) Test conditions Symbol Parameter Vcc Test (V) point (s) Vcc A A T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.25 Input SW Min. 46 46 Limits Unit Typ. 66 66 Max. 86 86 mA mA SW2 SW5 SW7 SW8 SW9 SW11 SW13 SW16 SW17 SW18 SW19 Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2 Bin2 Hin2 Vin2 Switch Icc1 Icc2 (RGB SW) VDC1 VDC2 VDC3 VDC4 Vimax1 Vimax2 Gv1 Gv1 Gv2 Gv2 Gv3 Gv4 Fc1 Fc1 Fc2 Fc2 Fc3 Fc4 Circuit current1 (no signal) Circuit current2 (no signal) 5 5 b b b b b b b b b b b b b b b b b b b b b a Output DC voltage1 Output DC voltage2 Output DC voltage3 Output DC voltage4 Maximum allowable input1 Maximum allowable input2 Voltage gain1 Relative Voltage gain1 Voltage gain2 Relative Voltage gain2 Voltage gain3 Voltage gain4 Frequency characteristic1 (100MHz) Relative Frequency characteristic1(100MHz) Frequency characteristic2 (100MHz) Relative Frequency characteristic2(100MHz) Frequency characteristic3 (250MHz) Frequency characteristic4 (250MHz) 5 5 5 5 5 5 5 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b a b a b a b 1.85 1.85 0.75 0.75 2.0 2.0 0.3 -0.4 2.05 2.05 1.15 1.15 2.4 2.4 0.9 0 0.9 0 0.2 0.2 0 0 0 0 -1.5 -1.5 2.25 2.25 1.55 1.55 1.5 0.4 1.5 0.4 0.8 0.8 1.0 1.0 1.0 1.0 1.0 1.0 V V V V Vp-p Vp-p dB dB dB dB dB dB dB dB dB dB dB dB T.P.25 T.P.2 T.P.5 T.P.7 T.P.11 T.P.13 T.P.16 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 abb bab bba b SG1 SG1 SG1 b b b b abb bab bba SG1 SG1 SG1 abb bab bba b b b b b SG2 SG2 SG2 Relative to measured values above b abb bab bba SG2 SG2 SG2 Relative to measured values above a SG2 b b b b b b b b b b b b a SG2 b b b b b b b b 5 b b a 0.3 -0.4 T.P.25 5 5 5 b b b b b b b b b a b -0.4 -0.4 -1.0 -1.0 T.P.25 T.P.31 T.P.28 T.P.25 abb bab bba b SG4 SG4 SG4 Relative to measured values above T.P.35 T.P.30 T.P.27 5 b b b b b abb bab bba b SG4 SG4 SG4 b a -1.0 -1.0 Relative to measured values above T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 5 5 abb bab bba b SG5 SG5 SG5 b b b b b b b b b b b b b b a -3.0 -3.0 abb bab bba SG5 SG5 SG5 MITSUBISHI ELECTRIC 3 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH ELECTRICAL CHARACTERISTICS (cont.) Test conditions Symbol Parameter Vcc Test (V) point (s) Vcc T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 T.P.35 T.P.30 T.P.27 Input SW Min. -0.4 b a b a b a b a b a c c 4.5 4.5 1.4 1.4 0.5 0.5 Limits Unit Typ. -60 -60 -40 -40 -50 -50 -30 -30 1.6 1.6 1.6 1.6 0 0.5 0.5 0.2 0.2 1.8 1.8 100 100 50 50 1.5 1.5 Max. -50 -50 -35 -35 -40 -40 -25 -25 2.5 2.5 2.5 2.5 0.8 0.5 0.5 2.0 2.0 150 150 100 100 2.0 2.0 dB dB dB dB dB dB dB dB nsec nsec nsec nsec dB dB dB dB dB dB dB nsec nsec nsec nsec V V SW2 SW5 SW7 SW8 SW9 SW11 SW13 SW16 SW17 SW18 SW19 Rin1 Gin1 Bin1 Hin1 Vin1 Rin2 Gin2 Bin2 Hin2 Vin2 Switch C.T.I.1 C.T.I.2 C.T.I.3 C.T.I.4 C.T.C.1 C.T.C.2 C.T.C.3 C.T.C.4 Tr1 Crosstalk between two inputs1(10MHz) Crosstalk between two inputs2(10MHz) Crosstalk between two inputs3(100MHz) Crosstalk between two inputs4(100MHz) Crosstalk between channels1(10MHz) Crosstalk between channels2(10MHz) Crosstalk between channels3(100MHz) Crosstalk between channels4(100MHz) 5 5 5 5 5 5 5 5 5 5 5 5 5 abb bab bba SG3 SG3 SG3 b b b b b b b b b b b b b b b - b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b GND b b a a b b a a b b a b a b b a a abb bab bba SG3 SG3 SG3 b b b abb bab bba SG4 SG4 SG4 b b b abb bab bba SG4 SG4 SG4 b b b abb bab bba SG3 SG3 SG3 b b b abb bab bba SG3 SG3 SG3 b b b abb bab bba SG4 SG4 SG4 b b b abb bab bba SG4 SG4 SG4 b b b b b b Pulse characteristic1 Tf1 Tr2 Pulse characteristic2 T.P.35 Tf2 (HV SW) VOH1 VOH2 VOL1 VOL2 Vith1 Vith2 Trd1 Trd2 Tfd1 Tfd2 Vsth1 Vsth2 High level output voltage1 High level output voltage2 Low level output voltage1 Low level output voltage2 Input selectional voltage1 Input selectional voltage2 Rising delay time1 Rising delay time2 Falling delay time1 Falling delay time2 Switching selectional voltage1 Switching selectional voltage2 T.P.30 T.P.27 a a a SG6 SG6 SG6 a a a SG6 SG6 SG6 b b b b b b b b b b b b b b SG2 b b b b b b b b b b b b b b b b b b b b b b a a a SG6 SG6 SG6 a a a SG6 SG6 SG6 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b - T.P.21 T.P.22 T.P.21 T.P.22 T.P.21 T.P.22 T.P.21 T.P.22 T.P.8 T.P.9 T.P.17 T.P.18 T.P.21 T.P.22 T.P.21 T.P.22 T.P.21 T.P.22 T.P.21 T.P.22 T.P.19 5 5 5 5 5 5 5 5 5 5 5 5 c c 5.0V 5.0V b c 0V b c Variable b c 0V b c Variable c c 5.0V 5.0V b c 0V b c Variable b c 0V b c Variable b b a a SG7 SG7 b b b b a a SG7 SG7 b b a a SG7 SG7 b b a a SG7 SG7 b b a a a a a SG1 SG1 SG1 SG7 SG7 b b b b b T.P.19 a a a a a SG1 SG1 SG1 SG7 SG7 MITSUBISHI ELECTRIC 4 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH ELECTRICAL CHARACTERISTICS TEST METHOD (Pin No is FP) It omits the SW.No accorded with signal input pin because it is already written in Table . SW A,SW1,SW3,SW5 is in side a if there is not defined specially. Icc1,Icc2,Circuit current(no signal) The condition is shown as Table . Set SW19 to GND(or OPEN) and SW A to side b, measure the current by current meter A. The current is as Icc1(Icc2). VDC1,VDC2 Output DC voltage Set SW19 to GND (or OPEN), measure the DC voltage of T.P.35(T.P.30,T.P.27) when there is no signal input.The DC voltage is as VDC1(or VDC2). VDC3,VDC4 Output DC voltage Measure the DC voltage of T.P.25 same as Table, the DC voltage is as VDC3(or VDC4). Vimax1,Vimax2 Maximum allowable Input Set SW19 to GND, SG1 as the input signal of Pin 2.Rising up the amplitude of SG1 slowly, read the amplitude of input signal when the output waveform is distorted. The amplitude is as Vimax1. And measure Vimax1 when SG2 as the input signal of Pin 5,Pin 7 in same way. Next, set SW to OPEN, measure Vimax2 when SG2 as the input signal of Pin11, 13, 16. Gv1, Gv1,GV2, GV2 1. The condition is shown as Table . 2. Set SW19 to GND, SG2 as the input signal of Pin 2. At this time, read the amplitude output from T.P 35. The amplitude is as VOR1. 3. Voltage gain Gv1 is Fc3,Fc4 Frequency characteristic By the same way as Table measure the Fc3, Fc4 when SG5 of input signal. C.T.I.1,C.T.I.2 Crosstalk between two Input 1. The condition is shown as Table. This test is by active prove. 2. Set SW19 to GND, SG3 as the input signal of Pin 2. Measure the amplitude output from T.P.35.The amplitude is as VOR3. 3. Set SW19 to OPEN, measure the amplitude output from T.P.35. The amplitude is as VOR3'. 4. The crosstalk between two inputs C.T.I.1 is C.T.I.1 = 20 LOG VO R 3' [Vp-p] VO R 3 [Vp-p] [dB] 5. By the same way, measure the crosstalk between two inputs when SG3 as the input signal of Pin5, Pin 7. 6. Next, set SW19 to OPEN, SG3 as the input signal of Pin 11, measure the amplitude output from T.P.35. The amplitude is as VOR4. 7. Set SW19 to GND, measure the amplitude output from T.P.35. The amplitude is as VOR4'. 8. The crosstalk between two inputs C.T.I.2 is C.T.I.2 = 20 LOG VO R 4'[Vp-p] VO R 4[Vp-p] [dB] 9. By the same way, measure the crosstalk between channels when SG3 as the input signal of Pin 13,16. C.T.I.3,C.T.I.4 Crosstalk between two input Set SG4 as the input signal, and then the same method as Table, measure C.T.I.3, C.T.I.4. C.T.C.1,C.T.C.2 Crosstalk between channel 1. The condition is as Table .This test is by active prove. 2. Set SW19 to GND, SG3 as the input signal of Pin 2. Measure the amplitude output from T.P.35. The amplitude is as VOR5. 3. Next, measure T.P.30, T.P.27 in the same state, and the amplitude is as VOG 5, VOB 5. 4. The crosstalk between channels C.T.C.1 is GV1= 20 LOG VO R 1 [Vp-p] [dB] 0.7 [Vp-p] 4. The method as same as 2 and 3, measure the voltage gain Gv1 when SG2 as the input signal of Pin 5, 7. 5. The difference of each channel relative voltage gain is as Gv1. 6. Set SW19 to OPEN, measure Gv2, Gv12 in the same way. Gv3,Gv4,Voltage gain 1. The condition is shown as Table . This test is by active probe. 2. Measure the amplitude output from T.P.25. 3. Measure the GV3,GV4 by the same way as Gv1, Gv1,Gv2, Gv2. Fc1, Fc1,Fc2, Fc2 1. The condition is shown as Table . This test is by active probe. 2. Set SW19 to GND, SG2 as the input signal of Pin 2. Measure the amplitude output from T.P.35.The amplitude is as VOR1.By the same way, measure the output when SG4 is as input signal of Pin 2, the output is as VOR2. 3. The frequency characteristic Fc1 is C.T.C1= 20 LOG VO G 5 or VO B 5 [dB] VO R 5 FC1 = 20 LOG VO R 2 [Vp-p] VO R 1 [Vp-p] [dB] 4. The method as same as 2 and 3, measure the frequency Fc1 when input signal to Pin 5, 7. 5. The difference between of each channel frequency characteristic is as Fc1. 6. Set SW19 to OPEN, measure Fc2, Fc2. MITSUBISHI ELECTRIC 5 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH 5. Measure the crosstalk between channels when SG3 is as the input signal of Pin 5, Pin 7 . 6. Next, set SW19 to OPEN, SG3 as the input signal of Pin11, measure the amplitude output from T.P.35. The amplitude is as VOR6. 7.Next, measure the amplitude output from T.P.30, T.P.27 in the same state. The amplitude is as VOG6, VOB6. 8. The crosstalk between channels C.T.C.2 is Trd1,Trd2 Rising delay time Tfd1,Tfd2 Falling delay time The condition is as Table . Set SW19 to GND (OPEN), SG7 is as the input signal of input terminal, measure the waveform of output. Rising delay time is as Trd1 (Trd2). Falling delay time is as Tfd1(Tfd2). Reference to the Fig. as shown below. C.T.C2= 20 LOG VO G 6 or VO B 6 [dB] VO R 6 50% SG7 Trd Tfd 50% Output waveform 9. By the same way, measure the crosstalk between channels when input signal to Pin13, 16. C.T.C.3,C.T.C.4 Crosstalk between channel Set SG4 as the input signal, and the same method as Table, measure C.T.C.3, C.T.C.4. Tr1,Tf1,Tr2,Tf2 Pulse characteristic 1. The condition is as Table 1. Set SW19 to GND (or OPEN). 2. The rising of 10 % to 90 % for input pulse is Tri, the falling of 10 % to 90 % for input pulse is Tfi. 3. Next, the rising of 10 % to 90 % for output pulse is Tro, the falling of 10 % to 90 % for output pulse is Tfo. 4. The pulse characteristic Tr1, Tf1 ( Tr2, Tf2 ) is 100% 90% 10% 0% Tr Tf Tr1(Tr2) = Tf 1(Tf 2) = (Tro) 2 - (Tri) 2 (nsec) (nsec) (Tf o) 2 - (Tf i) 2 Vsth1,Vsth2 Switching selectional voltage 1. The condition is as Table . SG1 is as the input signal of Pin2, Pin5, Pin7, and SG7 is as the input signal of Pin8, Pin9. There is no input at another pins. 2. Input 0V at Pin19, confirm that there are signals output from T.P.21, T.P.22, T.P.25, T.P.27,T.P.30,T.P.35. 3. Increase gradually the voltage of terminal Pin19. Read the voltage when there is no signal output from the terminals listed as above. The voltage is as Vsth1. 4. SG1 as the input signal of Pin11, Pin13, Pin16, and SG7 as the input signal of Pin17, Pin18.There is no input at another pins. 5. Inputs 5V at Pin19, confirm that there is no signal output from T.P.21, T.P.22, T.P.25, T.P.27,T.P.30,T.P.35. 6. Decreasing gradually the voltage of terminal Pin 19. Read the voltage when there are signals output from the terminals listed as above. The voltage is as Vsth2. VOH1,VOH2 High level output voltage The condition is as Table . Set SW19 to GND (OPEN), input 5V at input terminal. Measure the output voltage, the voltage is as VOH1 (VOH2). VOL1,VOL2 Low level output voltage The condition is as Table . Set SW19 to GND (OPEN), input 0V at input terminal. Measure the output voltage, the voltage is as VOL1 (VOL2). Vith1,Vith2 Input selectional voltage The condition is as Table . Set SW19 to GND (OPEN), increasing gradually the voltage of input terminal from 0V, measure the voltage of input terminal when output terminal is 4.5V. The input voltage is as Vith1(Vith 2). MITSUBISHI ELECTRIC 6 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH INPUT SIGNAL SG No. Input Signal Sine wave ( f = 60 kHz, 0.7Vp-p, amplitude variable ) SG1 0.7Vp-p(amplitude variable) SG2 SG3 SG4 SG5 Sine wave ( f = 1 MHz, amplitude 0.7Vp-p ) Sine wave ( f = 10 MHz, amplitude 0.7Vp-p ) Sine wave ( f = 100 MHz, amplitude 0.7Vp-p ) Sine wave ( f = 250 MHz, amplitude 0.7Vp-p ) Pulse with amplitude 0.7Vp-p ( f = 60 kHz, duty 80% ) SG6 0.7Vp-p Square wave ( Amplitude 5.0 Vo-p TTL, f = 60 KHz, duty 50% ) 5V SG7 0V Note how to use this IC (Pin No is FP) 1. R, G, B input signal is 0.7Vp-p of standard video signal. 2. H, V input is 2.0V(minimum) TTL type. 3. Input signal with sufficient low impedance to input terminal. 4. The terminal of H, V output pin are shown as Fig.1. It is possible to reduce rise time by insert the resister between Vcc line and H, V output Pin, but set the value of resister in order that the current is under 7.5 mA. Setting the value of R is more than 2K as shown in Fig.1 . 5V 1k 5V R 19 I<7.5mA Fig.1 Fig.3 6. Switch (Pin 19) can be changed when this terminal is GND or OPEN When GND : Signal output from input 1 When OPEN : Signal output from input 2 When the switch is being used as Fig.5 0 to 0.5V : Signal output from input 1 2 to 5V : Signal output from input 2 It is not allowable to set voltage higher than Vcc. 5. The terminal of R,G,B output pin (Pin 27, 30, 35). It is possible to add a pull-up resister according as drive ability. but set the value of resister in order that the current is under 10mA. Setting the value of R is more than 500 as shown in Fig.2 . 5V I<10mA 50 Notice of making printed circuit board. Please notice following as shown below. It will maybe cause something oscillation because of the P.C.B. layout of the wide band analog switch. The distance between resister and output pin is as short as possible when insert a output pull-down resister. The capacitance of output terminal as small as possible. Set the capacitance between Vcc and GND near the pins if possible. Using stable power-source(if possible the separated power-source will be better). It will reduce the oscillation when add a resister that is tens of ohms between output pin and next stage. Assign an area as large as possible for grounding. 430 Fig.2 R MITSUBISHI ELECTRIC 7 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH TEST CIRCUIT (FP) MITSUBISHI ELECTRIC 8 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH TYPICAL CHARACTERISTICS THERMAL DERETING (MAXIMUM RATING) 1750 1603 1500 1250 SP 1068 1000 FP 750 500 250 -20 0 25 50 75 85 100 125 150 AMBIENT TEMERATURE Ta ( oC ) DESCRIPTION PIN Pin No.(FP) 1 3 6 Name Vcc1(R) Vcc1(G) Vcc1(B) DC voltage (V) 5.0 Peripheral circuit of pins Rmarks - 800 2 5 7 Input1(R) Input1(G) Input1(B) 1.5 Input signal with low impedance. 2.59mA 2.2V 620 Input pulse between 2V and 5V. 8 9 Input1(H) Input1(V) 0.2mA 2 to 5V 0 to 0.8V 10,12,15,20,26, 29,34 GND GND - MITSUBISHI ELECTRIC 9 MITSUBISHI ICs (Monitor) M52758SP/FP WIDE BAND ANALOG SWITCH DESCRIPTION PIN (cont.) Pin No.(FP) Name DC voltage (V) Peripheral circuit of pins Rmarks 800 11 13 16 Input2(R) Input2(G) Input2(B) 1.5 2.59mA 2.2V 620 Input signal with low impedance. Input pulse between 2V and 5V. 17 18 Input2(H) Input2(V) 0.2mA 2 to 5V 0 to 0.8V 10K 12K 19 Switch 2.6 7.3K Switch by OPEN and GND. 13K 2.3V 1K 21 22 Output(V) Output(H) - Output impedance is built-in. 24 4,14,23,32,33 Vcc (H,V,Switch) NC 5 - - 25 27 30 35 Output (sync on G) Output(B) Output(G) Output(R) 1.15 50 2.05 50 25 27,30,35 500 Output impedance is built-in. 430 28 31 36 Vcc2(R) Vcc2(G) Vcc2(B) 5 - MITSUBISHI ELECTRIC 10 |
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