SHARP 6N137 6N137 M Features 1. Super high speed response (tent, tern > TYP. 45ns at Rr=3500) 2. Isolation voltage between input and output Visa + 2 500Vims 3. Low input current drive (Imm : MAX. 5mA) 4, Instantaneous common mode rejection voltage CMu: TYP. 500V/ us 5. LSTTL and TTL compatible output 6. Recognized by UL , file No. E64380 Hl Applications 1. High speed interfaces for computer peripherals, microcomputer systems 2. High speed line receivers 3. Noise reduction 4. Interfaces for data transmission equipment Super High Speed Response OPIC Photocoupler Hi Outline Dimensions (Unit : mm) Internal connection 0.85408 12 diagram Long ene Q 6N137 9 SHARP 5 O * ODROUST Oo d 1.2204 | _ [ost . Primary side_mark (Sunken place) 7.62703 9.22405 O.5TYP +05 37208 35*0: | 6&0 to 13" | 0.2620" @ NC GND @ Anode Vo @ Cathode @ Ve @ NC Vec * OPIC" (Optical IC) is a trademark of the SHARP Corporation. An OPIC consists of a light-detecting element and signal- processing circuit integrated onto a single chip. @ Absolute Maximum Ratings (Ta=25C) Parameter Symbol Rating Unit "Forward current Ir 20 mA Input Peak forward current Ir 40 mA Reverse voltage Vr 5 Vv Supply voltage Vec 7 Vv Enable voltage CE 5.5 Vv Output High level output voltage Vou 7 Vv Low level output current Jot 50 mA Output collector Pe 85 mW power dissipation Isolation voltage Vise 2 500 Vims Operating temperature Topr 0 to +70 Cc Storage temperature Tag 55 to +125 Cc Soldering temperature Tsoi 260 Cc *] Ta=0 to 70C *2 Pulse width < Ims *3 For 1 minute MAX. #4 Not exceed 500mV or more than supply voltage (Vcc) *5 AC for 1 minute, 40 to 60% RH Apply the specific voltage between all the input electrode pins connected together and all the output electrode pins connected together. *6 2mm or more away from the lead base for 10 seconds 566 In the absence of confirmation by device specification sheets, SHARP takes no responsibility for any defects that occur in equipment using any of SHARPs devices, shown in catalogs, data books, etc. Contact SHARP in order fo obtain the latest version of the device specification sheets before using any SHARPs device.SHARP 6N137 @ Electro-optical Characteristics (Ta=0 to+70T unless otherwise specified) Parameter Symbol! Conditions MIN. | TYP. | MAX. {| Unit Logic (1) output current Ton | Vec=5.5V, Vo=5.5V, Ir=250 4A, Ve=2.0V = 2 250 BA Logic (0) output voltage Vor | Voc=55V, r=5mA, Ven=2.0V, Jor (Sinking)=)3mA = 0.4 0.6 Vv Logic (1) enable current Ten | Voc=5.5V, Ve=2.0V = 0.8 = mA Logic (0) enable current Ter | Vcc=5.5V, Ve=0.5V _ -1.2 ~2.0 mA Logic (1) supply current Tock | Voc=5.5V, Ir=0mA, Ve=0.5V - 7 15 mA Logic (0) supply current Iccu | Voc=5.5V, Ir=10mA, Ve=0.5V _ 13 18 mA Leak current Io | 45% RH, Ta=25C, t=5s, Vio=3 000Ve - 1.0 uA Isolation resistance (input-output) Rro | Vio=500V, Ta=25'C - 19! = a "Capacitance (input-output) Ciro | f=1MHz, Ta=25C _ 0.6 - pF Input forward voltage Ve |[Ir=l0mA, Ta=25T _ 1.6 1.75 Vv Input reverse voltage BVr |lr=10uvA, Ta=25C _ = V Input capacitance Cr | Ve=0, f=1MHz = 60 = pF Current transfer ratio CTR |Ir=5.0mA, Rr=1000 _ 700 = % Propagation delay time Output (0) tern |Ta=250, Voc=5V, Ri=3500, CL=15pF, Ir=75mA | 45 75 ns = - One Oe time ten | Ta=25C, Vor=5V, Ri=3600, C.=l5pF, e=75mA | | 45 | 75 | ns Output rise-fall time (10 to 90%) | tr, te |R1=3500, C.=15pF, Ir=7.5mA ~ 20, 30 _ ns 2 dctay tine Ge 0) tern | RL=3500, CL=15pP, Ip=7Z5mA, Vex=30V, Veu=05V) ~ 40 - ns ; ty ten | RL=350, Ce=15pF, fp=7.5mA, Ven=30V, Va=05v]) ~ 15 - ns ee Cee etage Ont (0) CMu | Vor=10V, Ri =3500, Vo (min. )=2V, [p=0mA ~ 500 - |V/us ww Instantaneous common mode |) cya, | You=10V, R:=3500, Vo (min, )=08V, [r=5mA ~ |-500} - | V/us rejection voltage Output (1) Note) Typical values are all at Vcc=5V, Ta=25C *1 Measured as 2-pin element. Connect pins 2 and 3, connect pins 5, 6, 7 and 8. *2 At Ir=10mA, Vp decreases at the rate of 1.6mV/'C if the temperature goes up. *3 DC current transfer ratio is defined as the ratio of output collector current to forward bias input current. *4, *5 Refer to the Fig. 1. *6, *7 Refer to the Fig. 2. #8 CMu represents a common mode voltage ignorable rise time ratio that can hold logic (1) state in output. CML represents a common mode voltage ignorable fall time ratio that can hold logic (0) state in output. Mi Recommmended Operating Conditions current level current level enable Low level enable *6.3 2.0 0 4.5 0 1. No necessary external pull-up resistor to hold enable input at high level 2. Connect a ceramic by-pass capacitor (0.01 to 0.1 #F) between Vcc and GND at the position within lcm from pin. 3. * 20% giard band, switching threshold for degradation of CTR are 5mA or less at initial value. Crcult Block Diagram 15 Vec 0.8 5.5 8 70 Tru Vex VeL Voc N Fanout Truth Table Voc Anode H H L L H H H L H Ve (Enable) Vo Cathode GND L:Logic (0) H:Logic (1) 567 | Protocoupters JSHARP 6N137 Fig.1 Teet Circult for Propagation Delay time +5V - 350mV(te=7.5mA) 175mV (p= 3.75mA) Pulse oscillator Zo=00 ta=5ns Pulse oscillator +5v Zo=500 i ta=5ns | Input de Ve tection e=7.5mA > re Fig.3 Test Circuit for Instantaneous Common Mode Rejection Voltage . -.. 104 +8V Vo Pulse oscillator Zo=500 (nr) re a Vom Fig. 4 Output Collector Power Dissipation vs. Fig. 5 Forward Current vs. Forward Voltage Forward current Ip (mA) Collector power dissipation Pc (mW) 0 25 70 75 100 1.0 1.2 14 16 18 2.0 2.2 Ambient temperature Ta (C) Forward voltage V (V) 5686N137 Fig. 6 High Level Output Current vs. Fig. 7 Low Level Output Voltage vs. Ambient Temperature Ambient Temperature 4 05 ip 25a Ip=5mA < cc=5.5 cs Fae 3 Vo=55VC E Voc=55V z Vp=2V 2 Ve=2V 3 3 2 04 _ uo 5 2 o=l6mA 5 3 12.8mA 3 2 s = 03 9.6mA O o o pS Z 21 B 02 a 3 es = 5 0 0.1 0 25 50 5 100 0 25 50 5 100 Ambient temperature T, (C) Ambient temperature T, (C) Fig. S-a Output Voltage vs. Forward Current Fig. 8-b Output Voltage vs. Forward Current (Ambient Temp. Characteristics ) 6 6 Vec=5V Voec=5V T,=25C 5 < 5 > | W 5 N 4 o 4 > R, =3500 > \ E , | L Ry = 3500 bE 3 tka E 3 T= to HC 6 tka 3 | 4 - - Ryp=1k g 2 mi g 2 Ty=0 to 0 1 \ WW 1 ! \ 0 0 0 1 2 3 4 5 6 0 1 2 3 4 5 6 Forward current Ip (mA) Forward current I (mA) Fig. 9 Propagation Delay Time vs. Fig.10 Propagation Delay Time vs. Forward Current Ambient Temperature 20 Vec=8V 0 Ip=7.5mA cc= = FY fom a 5 ae # Voc=5V = yo} tyLt | = a _ z 100 ao yo + al Z go ei = LT " a PLH - a 3900 = 99 | wh g | iyi g Ss 60 4 L_ 00 s S 6 | o y ns] a tp 5 40 5 | } PHL 8 3 Ss, Rp=3500 oe & 40 i A 20 1kQ sg 1ka & 4kQ 4kQ 0 20 { 5 10 15 20 0 25 50 5 100 Forward current Ip (mA) Ambient temperature T, (C) 569SHARP Fig.11 Rise Time, Fall Time vs. Rise time. fall time t,, t (4s) Ambient Temperature 320 Ip= 280 Voo=5V Ry? 4kQ 240 200 160 120 80 40 1kQ 25 50 75 100 Ambient temperature Ta () lM Precautions for Use @ Handle this product the same as with other integrated circuits against static electricity. @ Please refer to the chapter Precautions for Use . (Page 78 to 93) Fig.12 Enable Propagation Time vs. Enable propagation time tgHL, teLy (ns) 120 100 80 60 40 20 Ambient Temperature 6N137 [p=7.5mA Voc =5V va ume LL tELH Rw i Lee o, > ar R, =3500 teHL - / |. 1ka 4kQ 0 25 50 75 Ambient temperature T, (C} 100 570