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x x $ 4 $%*. =%> ? 4 78 :: 4 ? : 4 ? &5 ' ,5, ,5,0&5"' :5 0*9 ,5",0&5"' :5 " x '" 0 , & *3'1@3(1@311$66*' 0 : ) '9 *3'1 C' *3'1 , ! (C9 " ' *( 0 , & *3'1@3(1@311$66*' 0 ' ) '9 Fig.1 Forward Current vs. Ambient Temperature Fig.2 Collector Power Dissipation vs. Ambient Temperature Collector power dissipation Pc (mW) Forward current I (mA) 60 50 40 30 20 10 0 -30 0 25 50 75 100 125 200 150 100 50 0 -30 0 Ambient temperature Ta ( C) 3 2 1 Ta= 75 C 50 C o o 200 25 C 0C -25 C o 100 o 50 20 10 5 2 1 2.5 5.0 7.5 10.0 12.5 15.0 0 0.5 Fig.5 Current Transfer Ratio vs. Forward Current 140 15 20 25 30 Fig.6 Collector Current vs. Collector-emitter Voltage 50 V = 5V Ta= 25 C o Ta= 25 C o IF = 30mA Collector current Ic (mA) 120 10 Forward voltage VF (V) Forward current IF(mA) Current transfer ratio CTR (%) 125 o 0 0 100 80 60 40 40 20mA 30 Pc(MAX.) 10mA 20 5mA 10 20 1mA 0 0.1 0.2 0.5 1 0 2 5 10 20 50 100 Forward current I F (mA) 0 , & *3'1@3(1@311$66*' 100 500 O Ta= 25 C Forward current IF (mA) Collector-emitter saturation voltage V (sat) (V) 4 75 Fig.4 Forward Current vs. Forward Voltage 6 Ic= 0.5mA 1mA 3mA 5mA 7mA 50 Ambient temperature Ta ( C) Fig.3 Collector-emitter Saturation Voltage vs. Forward Current 5 25 o o 0 1 2 3 4 5 6 7 8 9 10 Collector-emitter voltage V (V) 0 '' ) '9 Relative current transfer ratio (%) 150 Fig.8 Collector-emitter Saturation Voltage vs. Ambient Temperature Collector-emitter saturation voltage V (sat) (V) Fig.7 Relative Current Transfer Ratio vs. Ambient Temperature I F= 1mA VCE= 5V 100 50 0 -30 0 25 50 75 0.10 I F= 20mA Ic= 1mA 0.08 0.06 0.04 0.02 0 -30 100 o -6 100 50 -7 10 60 80 100 VCE= 2V Ic= 2mA Ta= 25 C o Response time ( s) (A) 40 Fig.10 Response Time vs. Load Resistance 10 Collector Dark Current I 20 Ambient temperature Ta ( C) Fig.9 Collector Dark Current vs. vs. Ambient Temperature -8 10 -9 10 -10 10 -11 20 tr tf 10 5 td 2 ts 1 0.5 10 0.2 -12 10 -30 0.1 0 20 40 60 80 100 0.1 0.2 0.5 1 o Ambient Temperature Ta ( C) 2 5 10 Load resistance RL (k ) Fig.11 Frequency Response Voltage gain Av (dB) 0 o Ambient temperature Ta ( C) Test Circuit for Response Time V = 2V Ic= 2mA o Ta= 25 C 0 Vcc Input RD RL Input Output Output 10% 90% td R L= 10k 1k ts tr 100 -10 tf Test Circuit for Frequency Response Vcc RD -20 0.2 0.5 1 2 5 10 100 RL Output 1000 Frequency f (kHz) 0 , & *3'1@3(1@311$66*' 0 '( ) '9 0 , & *3'1@3(1@311$66*' 0 '9 ) '9