acpl-m50l, acpl-054l, acpl-w50l and acpl-k54l low power, 1mbd digital optocoupler data sheet caution: it is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation which may be induced by esd. description the acpl-m50l (single-channel in so-5 footprint), acpl-054l (dual-channel in so-8 footprint), acpl-w50l (single-channel in stretched so-6 footprint) and acpl- k54l (dual-channel in stretched so-8 footprint) are low power, low-input current, 1mbd digital optocouplers. this digital optocouplers use an insulating layer between the light emitting diode and an integrated photon detector to provide electrical insulation between input and output. separate connections for the photodiode bias and output transistor collector increase the speed up to a hundred times over that of a conventional photo-transistor coupler by reducing the base-collector capacitance. the acpl-m50l/054l/w50l/k54l have an increased com- mon mode transient immunity of 15kv/ ? s minimum at v cm = 1500v over a temperature range of -40 to 105c. the current transfer ratio (ctr) is 140% typical for acpl- m50l or 130% typical for acpl-054l/w50l/k54l at i f = 3ma. this digital optocoupler can be use in any ttl/ cmos, ttl/lsttl or wide bandwidth analog applications. functional diagram features ?? wide supply voltage vcc: 2.7v to 24v ?? low drive current: 3ma ?? open-collector output ?? ttl compatible ?? compact so-5, so-8, stretched so-6 and stretched so-8 package ?? 15 kv/ ? s high common-mode rejection at v cm = 1500 v ?? guaranteed performance from temperature range: -40c to +105c ?? low propagation delay: 1 ? s max at 5v ?? worldwide safety approval: (pending except acpl-m50l) C ul1577 recognized, 3750vrms/1min for acpl-m50l/054l, 5000vrms/1min for acpl-w50l/k54l, C csa approval C iec 60747-5-5, iec/en/din en 60747-5-2 applications ??? communications interface ??? digital signal isolation ??? micro-controller interface ??? feedback elements in switching power supplies ??? digital isolation for a/d, d/a conversion digital fi eld lead (pb) free rohs 6 fully compliant rohs 6 fully compliant options available; -xxxe denotes a lead-f r ee p r oduct the connection of a 0.1 ? f bypass capacitor between pins 4 and 6 for acpl-m50l/w50l and between pins 5 and 8 for acpl-054l/k54l is recommended. truth table led vo on low off high 7 1 2 3 4 5 6 8 acpl-054l/k54l 5 1 3 4 6 acpl-m50l acpl-w50l 1 2 3 6 5 4 v o anode cathode gnd v cc v o gnd v cc nc cathode anode v o1 gnd v o2 v cc cathode1 anode2 cathode2 anode1
2 ordering information acpl-m50l and acpl-054l are ul recognized with 3750 vrms for 1 minute per ul1577. acpl-w50l and acpl-k54l are ul recognized with 5000 vrms for 1 minute per ul1577 part number options package surface mount tape & reel iec 60747-5-5, iec/en/din en 60747-5-2 quantity rohs compliant acpl-m50l -000e so-5 x 100 per tube -060e x x 100 per tube -500e x x 1500 per reel -560e x x x 1500 per reel acpl-054l -000e so-8 x 100 per tube -060e x x 100 per tube -500e x x 1500 per reel -560e x x x 1500 per reel acpl-w50l -000e stretched so-6 x 100 per tube -060e x x 100 per tube -500e x x 1000 per reel -560e x x x 1000 per reel acpl-k54l -000e stretched so-8 x 80 per tube -060e x x 80 per tube -500e x x 1000 per reel -560e x x x 1000 per reel to order, choose a part number from the part number column and combine with the desired option from the option column to form an order entry. example 1: acpl-m50l-500e to order product of mini-fl at surface mount 5-pin package in tape and reel packaging with rohs compliant. option datasheets are available. contact your avago sales representative or authorized distributor for information.
3 package outline drawings acpl-m50l small outline so-5 package (jedec mo-155) m50l yww 7.0 0.2 (0.276 0.008) 2.5 0.1 (0.098 0.004) 0.102 0.102 (0.004 0.004) 4.4 0.1 (0.173 0.004) 1.27 (0.050) bsc 0.216 0.038 (0.0085 0.0015) 0.71 (0.028) min 0.4 0.05 (0.016 0.002) 3.6 0.1* (0.142 0.004) dimensions in millimeters (inches) * maximum mold ?ash on each side is 0.15 mm (0.006) note: floating lead protrusion is 0.15 mm (6 mils) max. 7 max. max. lead coplanarity = 0.102 (0.004) 6 5 4 3 1 v cc v out gnd cathode anode 8.27 ( 0.325 ) 1 .8 ( 0.072 ) 2.5 ( 0. 1 0 ) 1 .3 ( 0.05 ) 0.64 ( 0.025 ) 4.4 ( 0. 1 7 ) dimension in mi ll imeters (i nches) land pattern recommendation
4 acpl-054l (small outline s0-8 package) acpl-w50l stretched so-6 package 4.480 0.254 ( 0.0 1 80 0.0 1 0 ) 45 0.38 1 0. 1 27 ( 0.0 1 5 0.005 ) 1 .27 ( 0.050 ) bsg 0.20 0. 1 0 ( 0.008 0.004 ) 0.45 ( 0.0 1 8 ) 0.750 0.250 ( 0.0295 0.0 1 0 ) 11 .50 0.250 ( 0.453 0.0 1 0 ) 6.807 0.268 d imensions in m illimeters (inches) . lead coplanarity = 0. 1 mm ( 0.004 inches) . 7 1 2.65 ( 0.498 ) l and pa tte rn r e comm e nda ti on 3. 1 80 0. 1 27 ( 0. 1 25 0.005 ) 1 .590 0. 1 27 ( 0.063 0.005 ) 7 1 .9 1 ( 0.075 ) 3 2 1 4 5 6 0.76 ( 0.030 ) + 0. 1 27 0 + 0.005 - 0.000 ) ( w 50 l yww par t numb e r da te cod e ro h s - comp li anc e i nd i ca t or �x�� 54 lv yww 8765 4 3 2 1 5.994 0.203 ( 0.236 0.008 ) 3.937 0. 1 27 ( 0. 1 55 0.005 ) 0.406 0.076 ( 0.0 1 6 0.003 ) 1 .270 ( 0.050 ) bsc 5.080 0. 1 27 ( 0.200 0.005 ) 3. 1 75 0. 1 27 ( 0. 1 25 0.005 ) 1 .524 ( 0.060 ) 45 x 0.432 ( 0.0 1 7 ) 0.228 0.025 ( 0.009 0.00 1) ty p e numb e r (v for op ti on 060 ) da te cod e le ad f r ee 0.305 ( 0.0 1 2 ) m i n. 0.203 0. 1 02 ( 0.008 0.004 ) 7 p i n on e 0 ~ 7 * t ota l pac k age l ength ( inc lu si v e o f mo l d fl ash) 5. 2 0 7 0. 2 5 4 ( 0. 2 05 0.0 1 0) dimensions in mi ll imeters (i nches). l ead cop l anarit y = 0. 1 0 mm ( 0.00 4 inches) max. o ption n u m b er 500 not mar k ed. note: fl oating l ead protr u sion is 0. 1 5 mm (6 mi l s) max. * 7.49 ( 0.295 ) 1 .9 ( 0.075 ) 0.64 ( 0.025 ) l and pa tte rn r e comm e nda ti on
5 acpl-k54l stretched so-8 package solder refl ow profi le recommended refl ow condition as per jedec standard, j-std-020 (latest revision). non-halide flux should be used. regulatory information the acpl-m50l/054l/w50l/k54l will be approved by the following organizations: ul approval under ul 1577, component recognition program up to v iso = 3750 v rms for acpl-m50l/054l and v iso = 5000 v rms for acpl-w50l/k54l. csa approval under csa component acceptance notice #5. iec 60747-5-5, iec/en/din en 60747-5-2 (option 060e only) 4 0.38 1 0. 1 3 ( 0.0 1 5 0.005 ) 1 .270 ( 0.050 ) bsg 1 2.650 ( 0.5 ) 1 .905 ( 0. 1) 3 2 1 5 6 7 8 5.850 0.254 ( 0.230 0.0 1 0 ) l and pa tte rn r e comm e nda ti on d imensions in m illimeters (inches) . lead coplanarity = 0. 1 mm ( 0.004 inches) . 7 45 0.200 0. 1 00 ( 0.008 0.004 ) 0.450 ( 0.0 1 8 ) 0.750 0.250 ( 0.0295 0.0 1 0 ) 11 .5 0.250 ( 0.453 0.0 1 0 ) 6.807 0. 1 27 ( 0.268 0.005 ) 7 3. 1 80 0. 1 27 ( 0. 1 25 0.005 ) 1 .590 0. 1 27 ( 0.063 0.005 ) k 54 l yww par t numb e r da te cod e ro h s - comp li anc e i nd i ca t or
6 insulation and safety related specifi cations parameter symbol acpl-m50l acpl-054l acpl-w50l acpl-k54l units conditions minimum external air gap (clearance) l(101) 5 4.9 8 mm measured from input terminals to output terminals, shortest distance through air. minimum external tracking (creepage) l(102) 5 4.8 8 mm measured from input terminals to output terminals, shortest distance path along body. minimum internal plastic gap (internal clearance) 0.08 0.08 0.08 mm through insulation distance conductor to conductor, usually the straight line distance thickness between the emitter and detector. tracking resistance (comparative tracking index) cti 175 175 175 volts din iec 112/vde 0303 part 1 isolation group iiia iiia iiia material group (din vde 0110, 1/89, table 1) iec 60747-5-5, iec/en/din en 60747-5-2 insulation characteristics* (option 060e) description symbol characteristic unit acpl-m50l/ 054l acpl-w50l/ k54l installation classifi cation per din vde 0110/39, table 1 for rated mains voltage 150 v rms for rated mains voltage 300 v rms for rated mains voltage 600 v rms for rated mains voltage 1000 v rms i C iv i C iii i C ii i C iv i C iv i C iii i C iii climatic classifi cation 55/105/21 55/105/21 pollution degree (din vde 0110/39) 2 2 maximum working insulation voltage v iorm 560 1140 vpeak input to output test voltage, method b* v iorm x 1.875 = v pr , 100% production test with t m = 1 sec, partial discharge < 5 pc v pr 1050 2137 vpeak input to output test voltage, method a* v iorm x 1.6 = v pr , type and sample test, t m = 10 sec, partial discharge < 5 pc v pr 896 1824 vpeak highest allowable overvoltage (transient overvoltage t ini = 60 sec) v iotm 6000 8000 vpeak safety-limiting values C maximum values allowed in the event of a failure. case temperature input current** output power** t s i s, input p s, output 150 150 600 175 230 600 c ma mw insulation resistance at ts, v io = 500 v r s >10 9 >10 9 ? * refer to the optocoupler section of the isolation and control components designers catalog, under product safety regulations section, (iec 60747-5-5, iec/en/din en 60747-5-2) for a detailed description of method a and method b partial discharge test profi les. ** refer to the following fi gure for dependence of p s and i s on ambient temperature.
7 absolute maximum ratings parameter symbol min. max. units storage temperature t s -55 125 c operating temperature t a -40 105 c lead soldering cycle temperature 260 c time 10 s average forward input current [1] i f(avg) 20 ma peak forward input current [2] (50% duty cycle, 1ms pulse width) i f(peak) 40 ma peak transient input current (1 ? s pulse width, 300ps) i f(trans) 1a reversed input voltage v r 5v input power dissipation [3] p in 36 mw output power dissipation [4] p o 45 mw average output current i o(avg) 8ma peak output current i o(peak) 16 ma supply voltage v cc -0.5 30 v output voltage v o -0.5 24 v solder refl ow temperature profi le see package outline drawings section notes: 1. derate linearly above 85c free-air temperature at a rate of 0.5 ma/c. 2. derate linearly above 85c free-air temperature at a rate of 1.0 ma/c. 3. derate linearly above 85c free-air temperature at a rate of 0.9 mw/c. 4. derate linearly above 85c free-air temperature at a rate of 1.2 mw/c. recommended operating conditions parameter symbol min. max. units supply voltage v cc 2.7 24 v input current, high level i fh 310ma operating temperature t a -40 105 c forward input voltage (off) v f(off) 0.8 v
8 electrical specifi cations (dc) over recommended operating t a = -40c to 105c, supply voltage (2.7v v cc 24v) and unless otherwise specifi ed. all typicals are at t a =25c parameter sym. part number min. typ. max. units conditions fig. current transfer ratio ctr [1] acpl-m50l 100 140 200 % t a = 25c v o =0.4v v cc =3.3v or 5v i f =3ma 2,3 80 % v o =0.5v acpl-054l acpl-w50l acpl-k54l 93 130 200 % t a = 25c v o =0.4v v cc =3.3v or 5v i f =3ma 2,3 53 % v o =0.5v logic low output voltage v ol 0.2 0.4 v t a = 25c i o =3ma v cc =3.3v or 5v i f =3ma 0.2 0.5 v i o =1.6ma logic high output current i oh 0.003 0.5 ? a t a = 25c v o =v cc =5.5v i f =0ma 4,5 0.01 1 v o =v cc =24v 80 v o =v cc =24v logic low supply current per channel i ccl 36 100 ? a i f =3ma, v o =open, v cc =24v logic high supply current per channel i cch 0.02 2 ? a i f =0ma, v o =open, v cc =24v input forward voltage v f 1.5 1.8 v t a =25c i f =3ma 1 1.5 1.95 v i f =3ma input reversed breakdown voltage bv r 5v i r =10 ? a temperature coeffi cient of forward voltage ? v f / ? t a -1.6 mv/c i f =3ma input capacitance c in 77 pf f = 1mhz, v f = 0 notes: 1. current transfer ratio in percent is defi ned as the ratio of output collector current, i o , to the forward led input current, i f , times 100%.
9 switching specifi cations (acpl-m50l) over recommended operating (t a = -40c to 105c), i f = 3ma, (2.7v v cc 24v), unless otherwise specifi ed. parameter symbol min typ max units test conditions fig. propagation delay time to logic low at output t phl 0.2 0.5 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =3.3 v, r l =1.2k ? , c l =15pf, v thhl =1.5v 14 0.2 1 ? s 6a, 14? 0.22 0.5 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =5.0 v, r l =1.9k ? , c l =15pf, v thhl =1.5v 14 0.22 1 ? s 7a, 14? 0.33 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =24v, r l =10k ? , c l =15pf, v thhl =1.5v 14 0.33 1.3 ? s 8a, 14? propagation delay time to logic high at output t plh 0.38 0.8 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =3.3 v, r l =1.2k ? , c l =15pf, v thhl =2.0v 14 0.38 1.2 ? s 6a, 14? 0.31 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =5.0 v, r l =1.9k ? , c l =15pf, v thhl =2.0v 14 0.31 1 ? s 7a, 14? 0.3 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =24v, r l =10k ? , c l =15pf, v thhl =2.0v 14 0.3 1 ? s 8a, 14? pulse width distortion [1] pwd 0.18 0.8 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =3.3 v, r l =1.2k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.18 1.2 ? s 14 0.1 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =5.0v, r l =1.9k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.1 1 ? s 14 0.1 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =24v, r l =10k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.1 1 ? s 14 propagation delay diff erence between any two parts [2] t psk 0.18 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =3.3 v , r l =1.2k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v ? 0.1 0.6 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =5.0v, r l =1.9k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v ? 0.1 0.6 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f = 3ma, v cc =24v, r l =10k ? , c l =15pf, v thhl =2.0v ? common mode transient immunity at logic high output [3] |cm h |1525? kv/ ? s ?v cm =1500v, i f =0ma, t a =25c, r l =1.2k ? or 1.9k ? , v cc =3.3 v or 5v 15 common mode transient immunity at logic low output [4] |cm l |1520? kv/ ? s ?v cm =1500v, i f =3ma, t a =25c, r l =1.2k ? , v cc =5v 15 10 15 ? kv/ ? s ?v cm =1500v, i f =3ma, t a =25c, r l =1.2k ? , v cc =3.3 v 15
10 switching specifi cations (acpl-054l/w50l/k54l) over recommended operating (t a = -40c to 105c), i f = 3ma, (2.7v v cc 24v), unless otherwise specifi ed. parameter symbol min typ max units test conditions fig. propagation delay time to logic low at output t phl 0.2 0.5 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =3.3 v, r l = 1.8k ? , c l =15pf, v thhl =1.5v 14 0.2 1 ? s 6b, 14? 0.22 0.5 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =5.0 v, rl= 2.9k ? , c l =15pf, v thhl =1.5v 14 0.22 1 ? s 7b, 14? 0.33 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =24v, r l =14.8k ? , c l =15pf, v thhl =1.5v 14 0.33 1.3 ? s 8b, 14? propagation delay time to logic high at output t plh 0.38 0.8 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =3.3 v, r l =1.8k ? , c l =15pf, v thhl =2.0v 14 0.38 1.4 ? s 6b, 14? 0.31 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =5.0 v, r l =2.9k ? , c l =15pf, v thhl =2.0v 14 0.31 1 ? s 7b, 14? 0.3 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =24v, r l =14.8k ? , c l =15pf, v thhl =2.0v 14 0.3 1 ? s 8b, 14? pulse width distortion [1] pwd 0.18 0.8 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =3.3 v, r l =1.8k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.18 1.4 ? s 14 0.1 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =5.0v, rl = 2.9k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.1 1 ? s 14 0.1 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =24v, r l =14.8k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v 14 0.1 1 ? s 14 propagation delay diff erence between any two parts [2] t psk 0.18 0.7 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =3.3 v, r l =1.8k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v ? 0.1 0.6 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =5.0v, r l =2.9k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v ? 0.1 0.6 ? s t a =25c pulse: f=10khz, duty cycle=50%, i f =3ma, v cc =24v, r l =14.8k ? , c l =15pf, v thhl =1.5v, v thlh =2.0v ? common mode transient immunity at logic high output [3] |cm h |1525? kv/ ? s ?v cm =1500v, i f =0ma, t a =25c, r l =1.8k ? or 2.9k ? , v cc =3.3 v or 5v 15 common mode transient immunity at logic low output [4] |cm l |1520? kv/ ? s ?v cm =1500v, i f =4ma, t a =25c, r l =2.9k ? , v cc =5v 15 15 20 ? kv/ ? s ?v cm =1500v, i f =3ma, t a =25c, r l =1.8k ? , v cc =3.3 v 15 notes: 1. pulse width distortion (pwd) is defi ned as |t phl - t plh | for any given device. 2. the diff erence between t plh and t phl between any two parts under the same test condition. (see ipm dead time and propagation delay specifi cations section.) 3. common transient immunity in a logic high level is the maximum tolerable (positive) dv cm /dt on the rising edge of the common mode pulse, v cm , to assure that the output will remain in a logic high state (i.e., v o > 2.0 v). 4. common mode transient immunity in a logic low level is the maximum tolerable (negative) dv cm /dt on the falling edge of the common mode pulse signal, v cm to assure that the output will remain in a logic low state (i.e., v o < 0.8 v).
11 package characteristics all typical at t a = 25c. parameter symbol part number min. typ. max. units test conditions input-output momentary withstand voltage [1,2] v iso acpl-m50l/054l 3750 v rms rh 50%, t = 1 min., t a = 25c acpl-w50l/k54l 5000 input-output resistance [1] r i-o 10 14 ? v i-o = 500 vdc input-output capacitance [1] c i-o 0.6 pf f = 1 mhz, t a = 25c input-input insulation leakage current [3] i i-i 0.005 ? a rh 45%, t = 5 s v i-i = 500vdc input-input resistance [3] r i-i 10 11 ? input-input capacitance [3] c i-i 0.25 pf f = 1 mhz notes: 1. device considered a two terminal device: pins 1 and 3 shorted together and pins 4, 5 and 6 shorted together for acpl-m50l, p ins 1, 2, 3 and 4 shorted together and pins 5, 6, 7 and 8 shorted together for acpl-054l/k54l, pins 1, 2 and 3 shorted together and pins 4, 5 and 6 shorted together for acpl-w50l. 2. in accordance with ul 1577, each optocoupler is proof tested by applying an insulation test voltage 4500 v rms for 1 second for acpl-m50l/054l and 6000 v rms for 1 second for acpl-w50l/k54l (leakage detection current limit, i i-o 5 ? a). 3. measured between pins 1 and 2 shorted together and pins 3 and 4 shorted together for acpl-054l/k54l.
12 figure 1. input current vs. forward voltage figure 2. typical current transfer ratio vs. temperature figure 3. typical current transfer ratio vs. temperature f igure 4. typical logic high output current vs. temperature figure 5. typical logic high output current vs. temperature v f - forward voltage - v i f - forward current - m a 0.6 0.7 0.8 0.9 1 1.1 -50 -25 0 25 50 75 100 125 t a - temperature - c normalized current transfer ratio normalized i f = 3 m a v o = 0.4 v v cc = 3.3 v 0.6 0.7 0.8 0.9 1 1.1 -50 -25 0 25 50 75 100 125 normalized current transfer ratio 0.01 0.1 1 10 100 1000 -60 -40 -20 0 20 40 60 80 100 120 i oh - logic high output current - na 0.01 0.1 1 10 100 1000 -60 -40 -20 0 20 40 60 80 100 120 normalized i f = 3 m a v o = 0.4 v v cc = 5 v t a - temperature - c t a - temperature - c i f = 0 m a v o = v cc = 3.3 v i f = 0 m a v o = v cc = 5 v i oh - logic high output current - na t a - temperature - c 0.0001 0.001 0.01 0.1 1 10 100 1.1 1.2 1.3 1.4 1.5 1.6 1.7 i f v f t a = 25c
13 t p - propagation delay - n s t a - temperature - c t a - temperature - c t p - propagation delay - n s t a - temperature - c t a - temperature - c 0 100 200 300 400 500 600 700 800 -60 -40 -20 0 20 40 60 80 100 120 t plh t phl 0 100 200 300 400 500 600 -60 -40 -20 0 20 40 60 80 100 120 t plh t phl 0 100 200 300 400 500 600 700 800 -60 -40 -20 0 20 40 60 80 100 120 t p - propagation delay - n s t plh t phl i f = 3 m a, v cc = 3.3 v r l = 1.9 k r l = 1.2 k i f = 3 m a, v cc = 5 v r l = 4.1 k r l = 1.9 k i f = 3 m a, v cc = 24 v r l = 20 k r l = 10 k 0 100 200 300 400 500 600 700 800 -60 -40 -20 0 20 40 60 80 100 120 t p - propagation delay - n s t p - propagation delay - n s t p - propagation delay - n s 0 100 200 300 400 500 600 700 800 -60 -40 -20 0 20 40 60 80 100 120 0 100 200 300 400 500 600 -60 -40 -20 0 20 40 60 80 100 120 t plh t phl i f = 3 m a, v cc = 3.3 v r l = 1.8 k i f = 3 m a, v cc = 24 v r l = 14.8 k i f = 3 m a, v cc = 5 v r l = 2.9 k t a - temperature - c t a - temperature - c t plh t phl t plh t phl figure 6a. typical propagation delay vs. temperature (acpl -m50l) figure 6b. typical propagation delay vs. temperature (acpl-054l/w50l/k54l) figure 7a. typical propagation delay vs. temperature (acpl -m50l) figure 7b. typical propagation delay vs. temperature (acpl-054l/w50l/k54l) figure 8a. typical propagation delay vs. temperature (acpl -m50l) figure 8b. typical propagation delay vs. temperature (acpl-054l/w50l/k54l)
14 t p - propaga ti on d el a y - ns t p - propaga ti on d el a y - ns t p - propaga ti on d el a y - ns t p - propaga ti on d el a y - ns 0 200 400 600 800 1 000 1 200 1 400 1 600 11 0 r l - l oad r e s i s t anc e - k r l - l oad r e s i s t anc e - k t p lh t p hl 0 1 00 200 300 400 500 600 700 800 900 1 000 11 0 t p lh t p hl 0 200 400 600 800 1 000 1 200 1 400 1 600 1 800 2000 2200 2400 2600 0 1 00 200 300 400 500 c l - l oad capac it anc e - pf c l - l oad capac it anc e - pf t p lh t p hl i f = 3 ma, v cc = 5 v i f = 1 0 ma i f = 3 ma i f = 3 ma, v cc = 3.3 v i f = 1 0 ma i f = 3 ma i f = 3 ma, v cc = 24 v r l = 1 0 k , t a = 25c 0 200 400 600 800 1 000 1 200 1 400 1 600 1 800 2000 2200 2400 2600 0 1 00 200 300 400 500 t p lh t p hl i f = 3 ma, v cc = 24 v r l = 1 4.8 k , t a = 25c figure 9. typical propagation delay vs. load resistance figure 10. typical propagation delay vs. load resistance figure 11a. typical propagation delay vs. load capacitance (acpl -m50l) figure 11b. typical propagation delay vs. load capacitanc e (acpl-054l/w50l/k54l) figure 12a. typical propagation delay vs. supply voltage (acpl-m50l) figure 12b. typical propagation delay vs. supply voltage (acpl-054l/w50l/k54l) 0 500 1 000 1 500 2000 2500 8 t p lh t p hl tp - propaga ti on d el a y - ns 0 500 1 000 1 500 2000 2500 8 1 0 1 420 v cc - supp ly v o lt ag e - v tp - propaga ti on d el a y - ns v cc - supp ly v o lt ag e - v t p lh t p hl 24 24 1 2 1 622 1 8 1 0 1 420 1 2 1 622 1 8 i f = 3 ma r l = 1 0 k t a = 25c i f = 3 ma r l = 1 4.8 k t a = 25c
15 v o pulse gen. z o = 50 t r = 5 n s i f monitor i f 0.1f r l c l r m 0 t phl t plh v o i f v ol v thhl v thlh v cc 1 3 6 5 4 v cc v o 0.1f r l a b pulse gen. v cm + v ff c l v cc C 1 3 6 5 4 v o v ol v o 0 v 10% 90% 90% 10% switch at a: i = 0 m a f switch at b: i = 3 m a f v cm t r t f v cc 10 v i f figure 13a. typical propagation delay vs. supply current (acpl -m50l) figure 13b. typical propagation delay vs. supply current (acpl-054l/w50l/k54l) figure 14. switching test circuits figure 15. test circuit for transient immunity and typical waveforms t p - propagation delay - n s 0 100 200 300 400 500 600 0 5 10 15 20 i f - forward led current - m a t p - propagation delay - n s i f - forward led current - m a t plh t phl v cc = 24 v r l = 10 k t a = 25c 0 100 200 300 400 500 600 0 5 10 15 20 t plh t phl v cc = 24 v r l = 14.8 k t a = 25c
for product infor m ation and a co m plete list of distributors, please go to our web site: www.avagotech.com avago, avago technologies, and the a logo are trade m arks of avago technologies in the united states and other countries. data subject to change. cop y right ? 2005-2011 avago technologies. all rights reserved. av02-2223en - october 25, 2011 figure 16. current transfer ratio versus input current figure 17. dc pulse transfer characteristic 0 50 1 00 1 50 200 250 05 1 0 1 52025 i f - f or w ard curr e n t - ma c t r - curr e n t t rans fe r ra ti o - % - 1 0 20 30 40 04 8 1 2 1 62024 v o - ou t pu t v o lt ag e - v i o - ou t pu t curr e n t - ma t a = 25 o c v cc = 5 v v o = 0.4 v v cc = 5 v i f = 20 ma i f = 1 5 ma i f = 1 0 ma i f = 5 ma
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