ASSR- High Current, Form A, Solid State Relay (MOSFET) (V/.A/W) Data Sheet Lead (Pb) Free RoHS fully compliant RoHS fully compliant options available; -xxxe denotes a lead-free product Description The ASSR- is specifically designed for high current applications, commonly found in the industrial equipments. The relay is a solid-state replacement for singlepole, normally-open, ( Form A) electromechanical relays. The ASSR- consists of an AlGaAs infrared lightemitting diode (LED) input stage optically coupled to a high-voltage output detector circuit. The detector consists of a high-speed photovoltaic diode array and driver circuitry to switch on/off two discrete high voltage MOSFETs. The relay turns on (contact closes) with a minimum input current of 3mA through the input LED. The relay turns off (contact opens) with an input voltage of.8v or less. The ASSR- connection A, as shown in the schematic, allows the relay to switch either ac or dc loads. The connection B, with its advantages of reduced on-resistance and higher output current, allows the relays to switch dc loads only. The electrical and switching characteristics are specified over the temperature range of - C to +8 C. Functional Diagram Opto-isolation Turn-off Circuit Truth Table LED Off On Output Open Close Features Compact Solid-State Bi-directional Signal Switch Single Channel Normally-off Single-Pole-Single-Throw (SPST) Relay V Output Withstand Voltage.A or.a Current Rating Low Input Current: CMOS Compatibility Low On-Resistance:.Ω Typical for DC-only, Ω Typical for AC/DC High Speed Switching:.7ms (Ton),.7ms (Toff) Typical @ I F = ma High Transient Immunity: >kv/μs High Input-to-Output Insulation Voltage (Safety and Regulatory Approvals Pending) - 37 V RMS for min per UL77 - CSA Component Acceptance - * V RMS / Minute rating is for Option X only (Please consult your regional Avago representatives) Applications Industrial Controls Factory Automation Data Acquisition Measuring Instrument Medical System Security System EMR / Reed Relay Replacement 3 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.
Ordering Table ASSR- is UL Recognized with 37 V RMS and V RMS (option x*) for minute per UL77 and is approved under CSA Components Acceptance Notice #, File CA 883 Part Number ASSR- Option RoHS Compliant Package Surface Mount Gullwing Tape & Reel UL VRMS/ Minute Rating Quantity -E 3mil -3E DIP- X X units per tube -E X X X units 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 : ASSR--E to order product of 3mil DIP- Gull Wing Surface Mount package in Tape and Reel packaging and RoHS Compliant. x* - Please consult your regional Avago representatives Schematic Connection A AC/DC Opto -isolation Opto -isolation Turn -off Circuit Vo Equivalent Relay Diagram 3 Connection B DC Only Opto -isolation + Opto -isolation Turn -off Circuit - Vo Equivalent Relay Diagram and 3
Package Outline Drawings ASSR- -Pin DIP Package 9. (.37) 9.9 (.39) 7.3 (.9) 7.88 (.3) LEAD FREE PIN ONE DOT.78 (.7) MAX. A XXXX YYWW U R 3 TYPE NUMBER DATE CODE UL RECOGNITION. (.). (.). (.8).33 (.3) TYP..7 (.8) MAX.. (.) MIN. (.) (.). (.8). (.). (.8). (.).8 (.9).8 (.) DIMENSIONS IN MILLIMETERS AND (INCHES). ASSR- -Pin DIP Package with Gull Wing Surface Mount Option 3 9. ±. (.38 ±.) LAND PATTERN RECOMMENDATION.3 ±. (. ±.).9 (.3).7 (.). (.8).9 MAX. (.).78 (.7) MAX..3 ±.3 (. ±.) 9. ±. (.38 ±.) 7. ±. (.3 ±.). (.8).3 (.3).9 (.9). (.) TYP..3 ±. (. ±.) NOM. NOTE: FLOATING LEAD PROTRUSION IS. mm ( mils) MAX. 3
Solder Reflow Temperature Profile Recommended reflow condition as per JEDEC Standard, J-STD- (latest revision). Non-Halide Flux should be used. Regulatory Information The ASSR- is approved by the following organizations: UL Approved under UL 77, component recognition program up to V ISO = 37 V RMS and V RMS (option x). Approved under CSA Component Acceptance Notice #. Insulation and Safety Related Specifications Parameter Symbol ASSR- Units Conditions Minimum External Air Gap (Clearance) Minimum External Tracking (Creepage) Minimum Internal Plastic Gap (Internal Clearance) Tracking Resistance (Comparative Tracking Index) L() 7. mm Measured from input terminals to output terminals, shortest distance through air. L() 7. mm Measured from input terminals to output terminals, shortest distance path along body..8 mm Through insulation distance conductor to conductor, usually the straight line distance thickness between the emitter and detector. CTI 7 V DIN IEC /VDE 33 Part Isolation Group (DIN VDE9) IIIa Material Group (DIN VDE 9)
Absolute Maximum Ratings Parameter Symbol Min. Max. Units Note Storage Temperature T S - C Operating Temperature T A - 8 C Junction Temperature T J C Lead Soldering Cycle Temperature C Time sec Input Current Average I F ma Surge ma Transient ma Reversed Input Voltage V R V Input Power Dissipation P IN mw Output Power Dissipation Average Output Current (T A = C, T C C) Output Voltage (T A = C) ESD Human Body Model: MIL-STD-883 Method 3.7 Solder Reflow Temperature Profile Connection A P O mw Connection B mw Connection A I O. A Connection B. A Connection A V O - V Connection B V See Lead Free IR Profile kv Recommended Operating Conditions Parameter Symbol Min. Max. Units Note Input Current (ON) I F(ON) 3 ma Input Voltage (OFF) V F(OFF).8 V Operating Temperature T A - +8 C Package Characteristics Unless otherwise specified, operating temperature T A = C. Parameter Symbol Min. Typ. Max. Units Conditions Note Input-Output Momentary Withstand Voltage V ISO 37 V RMS RH %, t = min, T A = C RH %, t = min, T A = C, option x Input-Output Resistance R I-O W V I-O = Vdc 3 Input-Output Capacitance C I-O.8 pf V I-O = Vdc, f = MHz 3 3,
Electrical Specifications (DC) Over recommended operating T A = - C to 8 C, I F = ma to ma, unless otherwise specified. Parameter Sym. Min. Typ. Max. Units Conditions Fig. Note Output Withstand Voltage V O(OFF) V V F =.8V, I O =ma, T A = C Output On-Resistance V V F =.8V, I O =ma Connection A R (ON) W I F =ma, I O =.A, Pulse 3ms, T A = C Connection B R (ON). W I F =ma, I O =.A, Pulse 3ms, T A = C 3 - Output Leakage Current I O(OFF).. ma V F =.8V, V O =V, T A = C - ma V F =.8V, V O =V - Output Off-Capacitance C (OFF) pf V F =.8V, V O =V, f=mhz - Output Offset Voltage V (OS) mv I F =ma, I O =ma Input Reverse Breakdown Voltage V R V I R =ma Input Forward Voltage V F..3.7 V I F =ma 7,8 - Switching Specifications (AC) Over recommended operating T A = - C to 8 C, I F = ma to ma, unless otherwise specified. Parameter Sym. Min. Typ. Max. Units Conditions Fig. Note Turn On Time T ON.7. ms I F =ma, I O =.A, T A = C,. ms I F =ma, I O =.A 3,.. ms I F =ma, I O =.A, T A = C, 3. ms I F =ma, I O =.A 3, Turn Off Time T OFF.7. ms I F =ma, I O =.A, T A = C, ms I F =ma, I O =.A,.. ms I F =ma, I O =.A, T A = C,. ms I F =ma, I O =.A, Output Transient Rejection dv O /dt 7 kv/ms V O =V, R M MΩ, C M =pf, T A = C Input-Output Transient Rejection dv I-O /dt kv/ms V DD =V, V I-O =V, R L =kω, C L =pf, T A = C 7 8 Notes:. For derating, refer to Figure and.. The voltage across the output terminal of the relay should not exceed this rated withstand voltage. Over-voltage protection circuits should be added in some applications to protect against over-voltage transients. 3. Device is considered as a two terminal device: pins,, and 3 shorted together and pins,, and 7 shorted together.. 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 IEC/EN/DIN EN 77-- Insulation Characteristics Table (if applicable), your equipment level safety specification, or Avago Application Note 7, Optocoupler Input-Output Endurance Voltage.. During the pulsed R (ON) measurement ( I O duration 3ms), ambient (T A ) and case temperature (T C ) are equal.. For the transient rejection measurements, refer to Avago whitepaper, AV-EN, Solid State Relay Transient Immunity.
I O - OUTPUT CURRENT - A..... Safe Operating Area I F = ma, -Layer I O - OUTPUT CURRENT - A...3.. Safe Operating Area I F = ma, -Layer - - 8 - - 8 T A - TEMPERATURE - C T A - TEMPERATURE - C Figure. Maximum Output Current Rating vs Ambient Temperature (AC/DC Connection) Figure. Maximum Output Current Rating vs Ambient Temperature (DC Connection) NORMALIZED OUTPUT WITHSTAND VOLTAGE...9.9 - - 8 T A - TEMPERATURE - C Figure 3. Normalized Typical Outupt Withstand Voltage vs Temperature I O(OFF) - OUTPUT LEAKAGE CURENT - A.E-7.E-8.E-9.E-.E-.E- - - 3 8 T A - TEMPERATURE - C Figure. Typical Output Leakage Current vs Ambient Temperature I O(OFF) - OUTPUT LEAKAGE CURRENT - µa.e-.e-.e-.e-.e-.e+ 3 Vo - OUTPUT VOLTAGE - V Figure. Typical Output Leakage Current vs Output Voltage C OUT - OUTPUT CAPACITANCE - pf 8 8 V O(OFF) - OUTPUT VOLTAGE - V Figure. Typical Output Off-State Capacitance vs Output Voltage 7
V F - FORWARD VOLTAGE - V.7.. I F = ma..3 I F = ma.. - - 8 T A - TEMPERATURE - C Figure 7. Typical Forward Voltage vs Ambient Temperature I F - FORWARD CURRRENT - ma 8 8 T A =- C T A = C T A = C T A = 8 C.8....8 V F - FORWARD VOLTAGE - V Figure 8. Typical Forward Current vs Forward Voltage I O - OUTPUT CURRENT - A..... -. -. -. -. T A = - C T A = C T A = 8 C -3 - - 3 V O - OUTPUT VOLTAGE - V Figure 9. Typical Output Current vs Output Voltage R ON(AC) - ON-RESISTANCE - Ω I F = ma I F = ma - - 7 T A - TEMPERATURE - C Figure. Typical On Resistance (AC/DC Connection) vs Temperature R ON(DC) - ON-RESISTANCE - Ω 8 I F = ma I F = ma - - 7 T A -TEMPERATURE - C TON - TURN ON TIME - µs 9 3 I F - CONTROL CURRENT - ma Figure. Typical On Resistance (DC Connection) vs Temperature Figure. Typical Turn On Time vs Input Current 8
T ON - TURN ON TIME - µs 8 I F = ma I F = ma TOFF - TURN OFF TIME - µs 8 - - 8 T A - TEMPERATURE - C Figure 3. Typical Turn On Time vs Temperature I F - CONTROL CURRENT - ma Figure. Typical Turn Off Time vs Input Current T OFF - TURN OFF TIME - µ-s 8 I F = ma I F = ma - - 8 T A -TEMPERATURE- o C Figure. Typical Turn Off Time vs Temperature PULSE GEN. Zo = Ω tf=tr=ns IF INPUT MONITORING NODE R ohm ASSR- 3 V DD RL C L* OUTPUT Vo MONITORING NODE (*CLIS APPROXIMATELY pf WHICH INCLUDES PROBE AND STRAY WIRING CAPACITANCE) OUTPUT IF OUTPU T Vo % t ON % P.W. = ms % 9% t OFF Figure Switching Circuit for TON, TOFF 9
INPUT OPEN ASSR- OUTPUT Vo MONITORING NODE 3 + V PEAK PULSE GEN Zo = C M =nf R M =Mohm C M INCLUDES PROBE AND FIXTURE CAPACITANCE R M INCLUDES PROBE AND FIXTURE RESISTANCE 9% 9% V PEAK % % t R t F V O(MAX) <.V dv (.8 ) V PEAK (. 8 ) V PEAK = OR dt t R t F OVER SHOOT ON V PEAK IS TO BE % Figure 7 Test Circuit for Output Transient Immunity
V DD = V + IF B A ASSR- 3 RL = koh m OUTPUT Vo MONITORING CL* NODE (*CLIS APPROXIMATELY pf WHICH INCLUDES PROBE AND STRAY WIRING CAPACITANCE) VFF V I-O + PULSE GEN. Zo = Ω 9% 9% V I-O(PEAK) % % t R t F V O(OFF) SWITCH AT POSITION A : IF = ma V O(OFF) (min)> V V O(ON) SWITCH AT POSITION B : IF = ma Figure 8. Test Circuit for Input-Output Transient Immunity V O(ON) (min)>.8v For product information and a complete list of distributors, please go to our web site: www.avagotech.com Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries. Data subject to change. Copyright -8 Avago Technologies. All rights reserved. AV-EN - June, 8