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| ac/dc to logic interface hermetically sealed optocouplers technical data applications ? military and space ? high reliability systems ? transportation, medical, and life critical systems ? limit switch sensing ? low voltage detector ? ac/dc voltage sensing ? relay contact monitor ? relay coil voltage monitor ? current sensing ? microprocessor interface ? telephone ring detection ? harsh industrial environments features ? dual marked with device part number and dscc standard microcircuit drawing ? manufactured and tested on a mil-prf-38534 certified line ? qml-38534, class h and k ? hermetically sealed 8-pin dual in-line packages ? performance guaranteed over -55 c to +125 c ? ac or dc input ? programmable sense voltage ? hysteresis ? hcpl-3700 operating compatibility ? logic compatible output ? 1500 vdc withstand test voltage ? thresholds guaranteed over temperature ? thresholds independent of led characteristics description these devices are single channel, hermetically sealed, voltage/ current threshold detection optocouplers. the products are capable of operation and storage over the full military temperature range and can be purchased as either standard product, or with full mil-prf-38534 class level h or k testing, or from the dscc standard microcircuit drawing (smd) 5962-89477. all devices are manufactured and tested on a mil-prf-38534 certified line and are included in the dscc qualified manufacturers list, qml-38534 for hybrid microcircuits. schematic 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. hcpl-576x* 5962-8947701 *see matrix for available extensions the connection of a 0.1 m f bypass capacitor between pins 8 and 5 is recommended. hcpl-5760/1/k
2 selection guideCpackage styles and lead configuration options agilent part # and options commercial hcpl-5760 mil-prf-38534 class h hcpl-5761 mil-prf-38534 class k hcpl-576k standard lead finish gold solder dipped option #200 butt joint/gold plate option #100 gull wing/soldered option #300 crew cut/gold plate option #600 class h smd part # prescript for all below 5962- either gold or soldered 8947701px gold plate 8947701pc solder dipped 8947701pa butt joint/gold plate 8947701yc butt joint/soldered 8947701ya gull wing/soldered 8947701xa crew cut/gold plate available crew cut/soldered available class k smd part # prescript for all below 5962- either gold or soldered 8947702kpx gold plate 8947702kpc solder dipped 8947702kpa butt joint/gold plate 8947702kyc butt joint/soldered 8947702kya gull wing/soldered 8947702kxa crew cut/gold plate available crew cut/soldered available each unit contains a light emit- ting diode (led), a threshold sensing input buffer ic, and a high gain photon detector to provide an optocoupler which permits adjustable external threshold levels. the input buffer circuit has a nominal turn on threshold of 2.5 ma (i th+ ) and 3.6 volts (v th+ ). the addition of one or more external attenuation resistors permits the use of this device over a wide range of input voltages and currents. threshold sensing prior to the led and detector elements minimizes effects of any variation in optical coupling. hysteresis is also provided in the buffer for extra noise immunity and switching stability. the buffer circuit is designed with internal clamping diodes to protect the circuitry and led from a wide range of over-voltage and over-current transients while the diode bridge enables easy use with ac voltage input. these units combine several unique functions in a single package, providing the user with an ideal component for computer input boards and other applica- tions where a predetermined input threshold optocoupler level is desirable. the high gain output stage features an open collector output providing both ttl compatible saturation voltages and cmos compatible breakdown voltages. this is an eight pin dip which may be purchased with a variety of lead bend and plating options. see selection guide table for details. standard microcircuit drawing (smd) parts are available for each lead style. 3 outline drawing 8 pin dip through hole device marking parameter symbol min. max. units power supply v cc 3.0 18 v operating frequency [1] f 0 10 khz recommended operating conditions absolute maximum ratings storage temperature range ....................................... -65 c to +150 c operating temperature .................................................. -55 c to 125 c lead solder temperature ............................................. 260 c for 10 s [2] average input current, i in ........................................................ 15 ma [3] surge input current, i in,sg ................................................... 140 ma [3,4] peak transient input current, i in,pk ..................................... 500 ma [3,4] input power dissipation, p in ................................................. 195 mw [5] total package power dissipation, p d ......................................... 260 mw output power dissipation, p o ..................................................... 65 mw average output current, i o .......................................................... 40 ma supply voltage,v cc (pins 8-5) .............................. -0.5 min., 20 v max. output voltage, v o (pins 6-5) ................................ -0.5 min., 20 v max. esd classification (mil-std-883, method 3015) ........................................... ( dd ), class 2 �� �� �� �� 3.81 (0.150) min. 4.32 (0.170) max. 9.40 (0.370) 9.91 (0.390) 0.51 (0.020) max. 2.29 (0.090) 2.79 (0.110) 0.51 (0.020) min. 0.76 (0.030) 1.27 (0.050) 8.13 (0.320) max. 7.36 (0.290) 7.87 (0.310) 0.20 (0.008) 0.33 (0.013) 7.16 (0.282) 7.57 (0.298) note: dimensions in millimeters (inches). compliance indicator,* date code, suffix (if needed) a qyywwz xxxxxx xxxxxxx xxx xxx 50434 country of mfr. agilent cage code* agilent designator dscc smd* pin one/ esd ident agilent p/n dscc smd* * qualified parts only 4 option description hermetic optocoupler options 100 surface mountable hermetic optocoupler with leads trimmed for butt joint assembly. this option is available on commercial and hi-rel product. 200 lead finish is solder dipped rather than gold plated. this option is available on commercial and hi-rel product. dscc drawing part numbers contain provisions for lead finish. 300 surface mountable hermetic optocoupler with leads cut and bent for gull wing assembly. this option is available on commercial and hi-rel product. this option has solder dipped leads. 600 surface mountable hermetic optocoupler with leads trimmed for butt joint assembly. this option is available on commercial and hi-rel product. contact factory for the availability of this option on dscc part types. note: dimensions in millimeters (inches). �� �� � �� 1.14 (0.045) 1.40 (0.055) 4.32 (0.170) max. 0.51 (0.020) max. 2.29 (0.090) 2.79 (0.110) 0.51 (0.020) min. 7.36 (0.290) 7.87 (0.310) 0.20 (0.008) 0.33 (0.013) � �� � �� 0.51 (0.020) min. 4.57 (0.180) max. 0.51 (0.020) max. 2.29 (0.090) 2.79 (0.110) 1.40 (0.055) 1.65 (0.065) 9.65 (0.380) 9.91 (0.390) 5?max. 4.57 (0.180) max. 0.20 (0.008) 0.33 (0.013) � �� � �� 3.81 (0.150) max. 1.02 (0.040) typ. 2.29 (0.090) 2.79 (0.110) 0.51 (0.020) min. 7.36 (0.290) 7.87 (0.310) 0.20 (0.008) 0.33 (0.013) 5 group a parameter symbol conditions subgroup min. typ.* max. units fig. note i th+ v in = v th+ ; v cc = 4.5 v; 1, 2, 3 1.75 2.5 3.20 ma v o = 0.4 v; i o 3 2.6 ma input threshold current i th- v in = v th- ; v cc = 4.5 v; 1, 2, 3 0.93 1.3 1.62 ma v o = 2.4 v; i oh 250 m a v in = v 2 - v 3 ; pins 1 v th+ & 4 open 1, 2, 3 3.18 3.6 4.10 v 7 v cc = 4.5 v; v o = 0.4 v; dc i o 3 2.6 ma (pins 2, 3) v in = v 2 - v 3 ; pins 1 v th- & 4 open 1, 2, 3 1.90 2.5 3.00 v 1, 2 v cc = 4.5 v; v o = 2.4 v; input i o 250 m a threshold voltage v in = |v 1 - v 4 |; pins v th+ 2 & 3 open 1, 2, 3 3.79 5.0 5.62 v v cc = 4.5 v; v o = 0.4 v; ac i o 3 2.6 ma (pins 1, 4) 7, 8 v in = |v 1 - v 4 |; pins 2 v th- & 3 open 1, 2, 3 2.57 3.7 4.52 v v cc = 4.5 v; v o = 2.4 v; i o 250 m a v ihc1 = v 2 - v 3 ; v ihc1 v 3 = gnd; 1, 2, 3 5.3 5.9 6.7 v i in = 10 ma; pin 1 & 4 connected to pin 3 v ihc2 = |v 1 - v 4 |; input clamp voltage v ihc2 |i in | = 10 ma; 1, 2, 3 6.0 6.6 7.4 v 3 15 pins 2 & 3 open v ihc3 = v 2 - v 3 ; v 3 = gnd; 1, 2, 3 12.0 13.0 v v ihc3 i in = 15 ma; pins 1 & 4 open input current i in v in = v 2 - v 3 = 5.0 v; 1, 2, 3 3.0 3.9 4.5 ma 4 pins 1 & 4 open logic low v ol v cc = 4.5 v; 1, 2, 3 0.05 0.4 v 4 output voltage i ol = 2.6 ma logic high i oh v oh = v cc = 18 v 1, 2, 3 250 m a output current 7 logic low i ccl v 2 - v 3 = 5.0 v; 1, 2, 3 0.8 3.0 ma supply current v o = open; v cc = 18 v logic high i cch v cc = 18 v; v o = open 1, 2, 3 0.001 20 m a5 supply current 45% rh, t = 5 s; input-output i i-o v i-o = 1500 vdc; 1 1 m a 9, 10 insulation t a = 25 c electrical characteristics t a = -55 c to 125 c, unless otherwise specified. see note 16. 6 group a parameter symbol conditions subgroup min. typ.* max. units fig. note propagation delay time to logic low t phl r l =1.8 k w , c l = 15 pf 9, 10, 11 4 20 m s 6, 11 output level 6, 7 propagation delay time to logic high t plh r l =1.8 k w , c l = 15 pf 9, 10, 11 8 40 m s 6, 12 output level logic high common v cm = 50 v t a = 25 c 9 1000 3 10,000 mode transient |cm h |i in = 0 ma v/ m s immunity v cm = 450 v 3 10,000 13, 8 14, logic low common v cm = 50 v t a = 25 c 9 1000 3 5,000 17 mode transient |cm l |i in = 4 ma v/ m s immunity v cm = 250 v 3 5,000 *all typical values are at t a = 25 c, v cc = 5 v unless otherwise noted. electrical characteristics t a = -55 c to 125 c, v cc = 5.0 v, unless otherwise specified (continued). figure 1. typical transfer characteristics. figure 2. typical dc threshold levels vs. temperature. 7 parameter symbol typ. units conditions fig. note i hys 1.2 ma i hys = i th+ - i th- hysteresis 1 v hys 1.1 v v hys = v th+ - v th- input clamp voltage v ilc -0.76 v v ilc = v 2 - v 3 ; v 3 = gnd; i in = -10 ma bridge diode v d1,2 0.62 i in = 3 ma (see schematic) forward voltage v d3,4 0.73 input-output resistance r i-o 10 12 w v i-o = 500 vdc 9 input-output capacitance c i-o 2.0 pf f = 1 mhz, v i-o = 0 vdc input capacitance c in 50 pf f = 1 mhz; v in = 0 v, pins 2 & 3, pins 1 & 4 open output rise time t r 10 m s7 (10-90%) output fall time t f 0.5 m s7 (90-10%) typical characteristics all typical values are at t a = 25 c, v cc = 5 v, unless otherwise specified. notes: 1. maximum operating frequency is defined when output waveform (pin 6) attains only 90% of v cc with r l = 1.8 k w , c l = 15 pf using a 5 v square wave input signal. 2. measured at a point 1.6 mm below seating plane. 3. current into/out of any single lead. 4. surge input current duration is 3 ms at 120 hz pulse repetition rate. transient input current duration is 10 m s at 120 hz pulse repetition rate. note that maximum input power, p in , must be observed. 5. derate linearly above 100 c free-air temperature at a rate of 4.26 mw/ c. maximum input power dissipation of 195 mw allows an input ic junction temperature of 150 c at an ambient temperature of t a = 125 c with a typical thermal resistance from junction to ambient of q ja i = 235 c/w. the typical thermal resistance from junction to case is equal to 170 c/w. excessive p in and t j may result in device degradation. 6. the 1.8 k w load represents 1 ttl unit load of 1.6 ma and the 4.7 k w pull-up resistor. 7. logic low output level at pin 6 occurs under the conditions of v in 3 v th+ as well as the range of v in > v th C once v in has exceeded v th+ . logic high output level at pin 6 occurs under the conditions of v in v th- as well as the range of v in < v th+ once v in has decreased below v th- . 8. the ac voltage is instantaneous voltage. 9. device considered a two terminal device: pins 1, 2, 3, 4 connected together, pins 5, 6, 7 8 connected together. 10. this is a momentary withstand test, not an operating condition. 11. the t phl propagation delay is measured from the 2.5 v level of the leading edge of a 5.0 v input pulse (1 m s rise time) to the 1.5 v level on the leading edge of the output pulse (see figure 7). 12. the t plh propagation delay is measured from the 2.5 v level of the trailing edge of a 5.0 v input pulse (1 m s fall time) to the 1.5 v level on the trailing edge of the output pulse (see figure 7). 13. common mode transient immunity in logic high level is the maximum tolerable dv cm/dt of the common mode voltage, v cm , to ensure that the output will remain in a logic high state (i.e., v o > 2.0 v). common mode transient immunity in logic low level is the maximum tolerable dv cm/dt of the common mode voltage, v cm , to ensure that the output will remain in a logic low state (i.e., v o < 0.8 v). see figure 8. 14. in applications where dv cm/dt may exceed 50,000 v/ m s (such as static discharge), a series resistor, r cc , should be included to protect the detector ic from destructively high surge currents. the recommended value for r cc is 240 w per volt of allowable drop in v cc (between pin 8 and v cc ) with a minimum value of 240 w . 15. d 1 and d 2 are schottky diodes; d 3 and d 4 are zener diodes. 16. standard parts receive 100% testing at 25 c (subgroups 1 and 9). smd, class h and class k parts receive 100% testing at 25, 125, and -55 c (subgroups 1 and 9, 2 and 10 ,3 and 11, respectively.) 17. parameters shall be tested as part of device initial characterization and after process changes. parameters shall be guaranteed to the limits specified for all lots not specifically tested. 8 figure 7. switching test circuit. figure 8. test circuit for common mode transient immunity and typical waveforms. figure 3. typical input characteristics, i in vs. v in . (ac voltage is instantaneous value.) figure 4. typical input current, i in , and low level output voltage, v ol , vs. temperature. figure 5. typical high level supply current, i cch vs. temperature. figure 6. typical propagation delay vs. temperature. hcpl-5760/1/k hcpl-5760/1/k 9 electrical considerations the hcpl-5760, hcpl-5761, hcpl-576k or 5962-89477 optocoupler has internal temperature compensated, predictable voltage and current threshold points which allow selection of an external resistor, r x , to determine larger external threshold voltage levels. for a desired external threshold voltage, v , a corresponding typical value of r x can be obtained from figure 10. specific calculation of r x can be obtained from equation (1) of figure 11. specification of both v + and v - voltage threshold levels simulta- neously can be obtained by the use of r x and r p as shown in figure 11 and determined by equations (2) and (3). r x can provide over-current transient protection by limiting input current during a transient condition. for monitoring contacts with a relay or switch, the hcpl-5760/1/k, or 5962-89477 combination with r x and r p can be used to allow a specific current to be conducted through the contacts for cleaning purposes (wetting current). the choice of which input voltage clamp level to choose depends upon the application of this device (see figure 3). it is recommended that the low clamp condition be used when possible to lower the input power dissipation as well as the led current, which minimizes led degradation over time. in applications where dv cm/dt may be extremely large (such as static discharge), a series resistor, r cc , should be connected in series with v cc and pin 8 to protect the figure 10. typical external threshold characteristic, v vs. r x . detector ic from destructively high surge currents. see note 14 for determination of r cc . in addition, it is recommended that a ceramic disc bypass capacitor of 0.01 m f to 0.1 m f be placed between pins 8 and 5 to reduce the effect of power supply noise. for interfacing ac signals to ttl systems, output low pass filtering can be performed with a pullup resistor of 1.5 k w and 20 m f capacitor. this application requires a schmitt trigger gate to avoid slow rise time chatter problems. for ac input applica- tions, a filter capacitor can be placed across the dc input terminals for either signal or transient filtering. either ac (pins 1, 4) or dc (pins 2, 3) input can be used to determine external threshold levels. for one specifically selected external threshold voltage level v + or v - , r x can be determined without use of r p via v + - v th+ (-) (-) r x = CCCCCCCCC (1) i th+ (-) see application note 1004 for more information. for two specifically selected external threshold voltage levels, v + and v - , the use of r x and r p will permit this selection via equations (2), (3) provided the following conditions are met: r p = v th- (v + ) - v th+ (v - ) CCCCCCCCCCCCCCCCCCCCCCCCCCC (3) i th+ (v - - v th- ) + i th- (v th+ - v + ) v th- (v + ) - v th+ (v - ) r x = CCCCCCCCCCCCCCCCCCCC (2) i th+ (v th- ) - i th- (v th+ ) v + v th+ v + - v th+ i th+ CCC 3 CCC and CCCCCCCC < CCCC v - v th- v - - v th- i th- figure 9. operating circuit for burn-in and steady state life tests. mil-prf-38534 class h, class k, and dscc smd test program agilent technologies hi-rel optocouplers are in compliance with mil-prf-38534 class h and k. class h and class k devices are also in compliance with dscc drawing 5962-89477. testing consists of 100% screen- ing and quality conformance inspection to mil-prf-38534. figure 11. external threshold voltage level selection. hcpl-5760/1/k 10 www.semiconductor.agilent.com data subject to change. copyright ? 2000 agilent technologies obsoletes 5968-0406e 5968-9404e (4/00) |
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