CA packarD 200-V/160 Ohm, 1 Form A, Small-Signal Solid State Relay Technical Data Features * Compact Solid-State Bidirectional Signal Switch * Normally-Off Single-Pole Relay Function (1 Form A) * Very High Output Off- Impedance: 10,000 Gigaohms Typical at 25C * Very Low Output Offset Voltage: < 0.5 LV at Ip =1lmA * 200-Volt Output Withstand Voltage at 25C * High-Transient Immunity: > 2000 V/us * Monolithic High-Voltage IC Operating Range: -40C to +85C * Very Low Input Current (1 mA); CMOS Compatibility * High-Speed Switching: 50 Ls Typical 160-Ohm Maximum On- Resistance at 25C * Surface Mount Option 8-kV ESD Immunity: MIL- STD-883 Method 3015 * Input-to-Output Insulation Voltage: 2500 Vac, 1 Minute * UL 508 Recognized * CSA Approved Applications * Relay Scanners & Analog Input Modules of Data Acquisition Systems * Analog Input Modules of Programmable Logic Controllers " Relay Multiplexers of High- Performance Voltmeters * Telecommunication Test Instruments * Functional Tester of Board Test Equipment * Analog Signal Multiplexer * Flying Capacitor Multiplexer * Reed Relay Replacement Functional Diagram f fs te _ 7 = HSSR-8200 Description The HSSR-8200 consists of a high- voltage integrated circuit optically coupled with a light emitting diode. This device is a solid-state replacement for single-pole, normally-open electromechanical relays used for general purpose switching of analog signals. The light-emitting diode controls the ON/OFF function of the solid- State relay. The detector contains high voltage MOS transistors and a high speed photosensitive drive circuit. This relay has superior OFF impedance, very low output offset voltage and input drive current. EQUIVALENT RELAY DIAGRAM TRUTH TABLE (POSITIVE LOGIC) LEO | OUTPUT ON L OFF H 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. 1-454 5965-3574EThe electrical and switching characteristics of the HSSR-8200 are specified from -40C to +85C. The low Ip allows compatibility with TTL, LSTTL, and CMOS logic resulting in low power consumption compared to other solid state and mechanical relays. Selection Guide Maximum | Maximum | Maximum 6-Pin DIP 4-Pin DIP | Maximum ON Output Output Hermetic (300 Mil) (300 Mil) Speed | Resistance | Voltage Current Minimum 8-Pin Single Dual t(ON) RON) VO(off) Io(ON) Input Single Channel Channel msec Q Vv mA Current Channel Package Package 25C 25C 25C 25C mA Packages HSSR-8400!11 0.95 10 400 150 5 HSSR-8060111 1.4 0.7 60 750 5 HSSR-8200 1.5 200 200 40 1 6 1 90 800 5 HSSR-71101) Note: 1. Technical data are on separate HP publication. Ordering Information Specify part number followed by Option Number (if desired). HSSR-8200#XXX_ 300 = Gull Wing Surface Mount Lead Option 500 = Tape/Reel Package Option (1 K min) Option data sheets available. Contact your Hewlett-Packard sales representative or authorized distributor for information. Schematic 1 FL + ve SWITCH ORIVER 1-465 wi or iva a) oo ay oe) rn 1. OPTOPackage Outline Drawings 4-Pin DIP Package (HSSR-8200) TYPE boos 1. NUMBER 7 DATE CODE HP RXXKX eto ip. O yyww ~ 6.60 (o-2t0) earn ; a eo one LO MU at 1.19 (0.047) MAX. oe 4.70 (0.185) MAX. en ; yo r = -~-~0.61 (0.020) MIN. 2.92 (0.118) MIN. Y 978 (0.630) a >< - 0,65 (0,028) MAX. <___9.40 (0.370) 330-(0350) : (y ca 7.87 CE 4. 7.37 (0.290 oa DIMENSIONS IN MILLIMETERS AND (INCHES). 4-Pin DIP Package with Gull Wing Surface Mount Option 300 9:65 20.25 (0.380 2 0.010) rm i oO PINT ~ 8.66 + 0.25 =4 y - (0.3002 0.010) _ 7.62:20.28 (0.300 + 0.010) | . oan) + t 6.35 2 0.25- MAX. (0.260 + 0.010) 4.19 (0.165)M4%- w J - 1.08020.920 5) 4 AL... 0.835 0.25 (0.043 = 0.013) (0.025 = 0.010) +-7.62 3 0.25 -= 0.50 = 0.130 (0.300 + 0.010) (0.020 + 0.005) DIMENSIONS IN MILLIMETERS (INCHES). 1-456 0.20 (0.008 0.33 (0.013) Y i em -12 NOM.Thermal Profile (Option #300) 260 240 220 200 180 160 140 120 100 80 60 40 20 TEMPERATURE - C 0 TIME - MINUTES Figure 1. Maximum Solder Reflow Thermal Profile. (Note: Use of non-chlorine activated fluxes is recommended.) Regulatory Information UL The HSSR-8200 has been approved by the following organizations: Recognized under UL 508, Component Recognition Program, Industrial Control CSA Approved under CAN/CSA-C22.2 No. 14-95, Industrial Control Equipment, File LR 87683. Switches, File E142465. Insulation and Safety Related Specifications Parameter Symbol | Value | Units Conditions Min. External Air Gap Ld01) 7.0 mm | Measured from input terminals to output (External Clearance) terminals, shortest distance through air Min. External Tracking Path Ld02) 7.5 mm | Measured from input terminals to output (External Creepage) terminals, shortest distance path along body Min. Internal Plastic Gap 0.5 mm | Through insulation distance, conductor to (Internal Clearance) conductor, usually the direct distance between the photoemitter and photodetector inside the optocoupler cavity Tracking Resistance CTI 200 | Volts | DIN IEC 112/VDE 0303 PART 1 (Comparative Tracking Index) Isolation Group Ila Material Group (DIN VDE 0110, 1/89, Table 1) Option 300 - surface mount classification is Class A in accordance with CECC 00802. 1-457Absolute Maximum Ratings Storage Temperature ......cccccssscssssssssesscssecesnereerereses -55C to+ 125C Operating Temperature -40C to +85C Lead Solder Temperature .... 260C for 10 s (1.6 mm below seating plane) Average Input Current - Ip.....cecccesecssesccteeessneesseceerecaserenssesvansersaes 10 mA Repetitive Peak Input Current - Ip... ccc eeees 20 mA; 50% Duty Cycle Transient Peak Input Current - Ip oi... ces seccseseseeteneetseseeeeseeteea 100 mA (s 1 us pulse width; 1 kHz Pulse Repetition Rate) Reverse Input Voltage 0... cecsccecescsessteestereeterscseeenseeesererseetieesereeees 5vV Average Output Current -1o .ccisscesssrrssecseeenseceteseersserteeeas 40 mA!) Input Output Insulation Voltage .... ... 2500 VACI61 Output Power Dissipation ..........0csccscssccsssecssssessesensevssseesses 320 mwi2l Output Voltage Vo v..ecccecscsstscesseresesstsescterstsersnseecsenes -200 V to 200 V Infrared and Vapor Phase Reflow Temperature (Option #300) oe ceccecsseesessteeesseensee see Fig. 1, Thermal Profile Recommended Operating Conditions Parameter Symbol Min. Max. Units Input Current (ON) Tron) 1 5 mA Input Voltage (OFF) VecorF) 0 0.6 Volt Operating Temperature Ty -40 +85 C Output Voltage Vocorr) -200 200 Volt Output Current Igrony -40 40 mA 1-458DC Electrical Specifications ~40C < Ty S$ +85C, 1 mA < Ip(ony S 5 MA, OV S Vevoryy 0.6 V, and all Typicals at T, = 25C unless otherwise specified. Parameter Sym. | Min.| Typ. | Max. | Units | Test Conditions | Fig. | Notes Output Withstand [VororF)|} 200 245 Vv Ip =1pA Voltage 70 125 160 Ta = 25C, Ip = 1 MA Output On-Resistance Rron) 40 125 250 Q Ip = 1 MA 3, 4, 5 30 100 200 Ip = 40 mA Output On-Current Hocon| 40 mA | Vos 8V, 1 Rating Ta s 40C Output Off-Resistance Riorr) 50 | 10,000 GQ | Vo = 200V 6 6 Output Off-Leakage To.oFF) 0.02 4.0 nA ig = 200 V 6 Current Output Crorr) 4.5 pF | Vo =OV, 7 Off-Capacitance f = 1 MHz -0.2 Ip = OA: Tp = 1 mA Output Offset Voros) | Note Note uv 8, 17, 3 Voltage 3 -1.3 3 Ip =OA Tp =5mA] 18 Input Reverse Ve 3 10 v Ip = 10 pA Breakdown Voltage Input Diode dVe/dT -1.75 mV/ | Ip=1mA Temperature Coefficient C Input Forward Ve 1.5 2.0 v Ip =5 mA 9 Voltage Input Capacitance Cin 21 pF Vr = OV; f = | MHz Switching Specifications ~40C < Ty $ +85C, 1 MAS Ian, S 5 MA. OV S Vevorp) S 0.6 V, and all Typicals at Ty = 25C unless otherwise specified. Parameter Symbol | Min. | Typ. | Max. | Units Test Conditions Fig. | Notes 50 200 Ip=5mA Turn On Time ton ps Vo = 50 V / 10, 11, 300 | 1500 Ip = 1 mA 12,13 45 250 Ip=5mA Turn Off Time torr ys Vo = 50 V 1/10, 11, 75 350 Ir = 1 mA 12,13 > 7000 AVo = 200 V Output Transient dV, /dt V/us Ta = 25C 14 Rejection 2000 AVo = 50 V Input-Output > 7000 AV.o = 300 V Transient dVi_o/dt V/us Ty = 25C 15 Rejection 2000 AV.o = 50V 1-459 OPTOCOUPLERSPackage Characteristics For -40C < T, < +85C, unless otherwise specified. All Typicals at Ty = 25C. Parameter Symbol | Min. Typ. | Max.| Units Test Conditions Fig. | Notes Input-Output Viso 2500 Vrms | RH = 45%, t = 1 min, 4,5 Momentary With- Ta = 25C stand Voltage* Resistance Rio 100 | 100,000 GQ. | Vio = 500 VDC, t = 1 min, 4 Input-Output RH = 45% Capacitance Cro 0.6 1.0 pF Vio = OV, f = 1 MHz, 4 Input-Output Ta = 25C *The Input-Output Momentary Withstand Voltage is a dielectric voltage rating that should not be interpreted as an input-output continuous voltage rating. For the continuous voltage rating refer to the VDE 0884 Insulation Characteristics Table (if applicable), your equipment Jevel safety specification, or HP Application Note 1074, Optocoupler Input-Output Endurance Voltage. Notes: 1. Derate linearly above 40C at a rate of 0.3 mA/rC. 2. Derate linearly above 60C at a rate of 5 mW/C. 3. Voqosy is @ function of Ippon, and is defined between pins 8 and 5 with pin 5 oe Vcc {+5 V) Figure 2. Recommended Input Circuit. Io1on, OUTPUT CURRENT mA Voom. QUTPUT VOLTAGE V Figure 3. Typical On State I-V Characteristics. 1-460 as reference. Vas, must be measured ina stable ambient. See Figure 8 for variation of Vyas) around the typical value. 5. This is a momentary withstand proof test. These parts are 100% tested in production at 3000 Vrms. one second. 6. Ruarry is defined as Vo, orryloworr)- . Device considered a two terminal device: pins 1 and 4 shorted together, and pins 5 and 8 shorted together. s4 a | Ail - REQUIRED CURRENT-LIMITING RESISTOR ' FOR le jon) = | MA 5 R2 - PULL-UP RESISTOR FOR Ve (opp) < 600 mY; 1 IF (Veg Ving) < 600 mv, OMIT A2 --i A3, C - OPTIONAL PEAKING CIRCUIT FOR Ie (pxy = 5 MA, toy 200 us Aion OUTPUT RESISTANCE OHMS le om INPUT CURRENT mA Figure 4, Typical Output Resistance vs. Input Current.NORMALIZED TO 1s fron o2sic F(ON) = 9 40 mA os NORMALIZED OUTPUT RESISTANCE Rios, OUTPUT RESISTANCE OHMS 0.10 -40 = -20 o 20 4 60 30 5 Ts TEMPERATURE C Figure 5. Typical Output Resistance vs. Temperature. 5.0 1. a er) w o z = S 30 Bs < o 5 2 20 & > 5 = 10 2 oO a 0 85 10 18 20 25 30 3% 4 45 50 Vo .orr, OUTPUT VOLTAGE VOLTS Figure 7. Typical Output Capacitance ys. Output Voltage. 190-8 lr,on, INPUT FORWARD CURRENT & 19-8 05 06 0.7 08 09 1041.11213 1415 1617 Vevon. INPUT FORWARD VOLTAGE - Vv Figure 9. Typical Input Forward Current vs. Forward Voltage. Yq (OFF) = 200 Ve corp) 20.6 OPTOCOUPLERS 10$ wo? 190-11 torr) OUTPUT LEAKAGE CURRENT A 10-12 40-30-20-10 0 10 20 30 40 50 60 76 90 90 Ta - TEMPERATURE C Figure 6. Typical Output Leakage vs. Temperature. Votosi= - 0.2 uv a= O0.14uV | tp = 1 mA Ta = 25 C | | 2 + { Voias) = -1.3 o 70.4. Ip - 5 mA Ta = BC RELATIVE FREQUENCY / R x ~ ~ a 0 Late > 25 -2.0 -15 -1.0 -05 o O5 Vo.os; OUTPUT OFFSET VOLTAGE LV Figure 8. Output Offset Voltage Distribution. 1-461PULSE GENERATOR = son t, =t, =5ns Vec 3450 V + = 10ms 50% DUTY CYCLE Ry = SK! Vo MONITOR D C. = 25 pF 50V 90% v 10% (C, INCLUDES PROBE AND R (MONITOR) FIXTURE CAPACITANCE) 200 Ohms * ton torr = GNo GND Figure 10. Switching Test Circuit for t,,,, tp,.- 2.0 NORMALIZED TO toy AT Voiorr) = 50 yep Ta=25C ae D teon) = 5 ma 3 Ig= 40 mA ~ 16 . 9 a a [ z 14 . o t & 8 Q z uot Z 2 10 S =z 08 06 5 10 15 Q 20 40 60 80 100 120 140 160 180 200 lgion: CONTROL CUARENT mA Votorre) CONTACT VOLTAGE ~ V Figure 11. Typical t,,, and t,,., vs. Input Current. Figure 12. t,, and t,,,. vs. Output Voltage. INPUT OPEN : 1.77 NORMALIZED TO tox AT 25C Cw 1.6F beam 5 mA 15h A SKit 4 I 1.4F Voiorn=50V = & 13 4d 4 3 to 144 4 a ; = Veeax [--~ PULSE GENERATOR 2 os PEAK Vecax =50V 5 08 = { | te tt, =25ns < 07 = I. 1 & 0.8 | 1 z ae 7 [ol to . 1 ol I ot 0.3 4 14 O2- Vouore) -L ie ae mF V/ \ i [MAX. Voiorri= 0.226 40 -20 0 20 40 60 80 100 1, TEMPERATURE C Cw INCLUDES PROBE AND FIXTURE CAPACITANCE Figure 13. Normalized t,,, and t,,, vs. Temperature. Figure 14. Output Transient Rejection Test Circuit. 1-462OPTOCOUPLERS Voc 5V < > SRt st ke VeeAK pom me me we oe oe 50V _ B I tH Vy ! LEO { | = = C. = 25 pF a { (CL INCLUDES { 1 PROBE PLUS Voiorr) , 6V f- MIN. Vojarr)=4V 1 FIXTURE > Yn = 4 1 CAPACITANCE.) ip = OmA F I I I siata | tv ' L--.----J } 1 PEAK Vo tom) (n= I * veaesove le = 5 mal 92V MAX. Voion: 1.5V I PULSEGENERATOR = Ete = 258 STATS te SIR bAI tr = 25n8 r t Figure 15. Input-Output Transient Rejection. vi Va INPUT SIGNALS As HSSR-8200 + is} cr SO ee er me ! 4 ! + 1 I SIGNAL 1 bus ' a ee ee ee ee ts tg < Is, max Vs = Vo. max - sR Va, MAX EITHER-POLARITY INPUTS: Dg OUAL-POLARITY BREAKDOWN DEVICE, Vg < 0.5 Vowrr) SINGLE-POLARITY INPUTS: Ds UNI-POLAR BREAKDOWN DEVICE, Vs < Voiore) Figure 16. Over-Voltage Protection in Multiplexer Applications. 1-463V tos) + 8 5 r eee | I HSSR 8200 | 1 NN ee SOURCE , LOAD L_ | ANALOG v -4 y, SIGNAL a t PROCESSOR (eg. ADC) Va tos) Vi > Yn +S Vous) eee ee Figure 17. Differential Output Connections to Minimize Offset Voltage Effects. ISOTHERMAL CHAMBER OIGITAL NANOVOLT- METER Figure 18. Voltage Offset Test Setup. 1-464