Optocoupler, Phototransistor Output, AC Input (Dual, Quad Channel) Features Identical Channel to Channel Footprint ILD620 Crosses to TLP620-2 ILQ620 Crosses to TLP620-4 High Collector-Emitter Voltage, BV CEO = 70 V Dual and Quad Packages Feature: - Reduced Board Space - Lower Pin and Parts Count - Better Channel to Channel CTR Match - Improved Common Mode Rejection Isolation Test Voltage 5300 V RMS Dual Channel 1 2 3 4 8 7 6 5 C E C E Agency Approvals UL File #E52744 System Code H or J CSA 93751 DIN EN 60747-5-2(VDE0884) DIN EN 60747-5-5 pending Available with Option 1 BSI IEC60950 IEC60965 Quad Channel 1 2 3 4 5 6 7 16 C 15 E 14 C 13 E 12 C 11 E 10 C Description The ILD620/ ILQ620 and ILD620GB/ ILQ620GB are multi-channel input phototransistor optocouplers that use inverse parallel GaAs IRLED emitter and high i179053 8 9 E gain NPN silicon phototransistors per channel. These devices are constructed using over/under leadframe optical coupling and double molded insulation resulting in a withstand test voltage of 5300 V RMS. The LED parameters and the linear CTR characteristics make these devices well suited for AC voltage detection. the ILD/Q620GB with its low I F quaranteed CTR CEsat minimizes power dissipation of the AC voltage detection network that is placed in series with the LEDs. Eliminating the phototransistor base connection provides added electrical noise immunity from the transients found in many industrial control environments. Order Information Part Remarks ILD620 CTR > 50 %, DIP-8 ILD620GB CTR > %, DIP-8 ILQ620 CTR > 50 %, DIP-16 ILQ620GB CTR > %, DIP-16 ILD620-X007 CTR > 50 %, SMD-8 (option 7) ILD620-X009 CTR > 50 %, SMD-8 (option 9) ILD620GB-X009 CTR > %, SMD-8 (option 9) ILQ620-X009 CTR > 50 %, SMD-16 (option 9) ILQ620GB-X009 CTR > %, SMD-16 (option 9) For additional information on the available options refer to Option Information. 1
VISHAY Absolute Maximum Ratings T amb = 25 C, unless otherwise specified Stresses in excess of the absolute Maximum Ratings can cause permanent damage to the device. Functional operation of the device is not implied at these or any other conditions in excess of those given in the operational sections of this document. Exposure to absolute Maximum Rating for extended periods of the time can adversely affect reliability. Input Parameter Test condition Symbol Value Unit Forward current I F ± 60 ma Surge current I FSM ± 1.5 A Power dissipation P diss mw Derate linearly from 25 C 1.3 mw/ C Output Parameter Test condition Symbol Value Unit Collector-emitter breakdown BV CEO 70 V voltage Collector current I C 50 ma t < 1.0 sec: I C ma Power dissipation P diss 150 mw Derate from 25 C 2.0 mw/ C Coupler Parameter Test condition Part Symbol Value Unit Isolation test voltage t = 1.0 sec. V ISO 5300 V RMS Package dissipation ILD620 400 mw ILD620GB 400 mw Derate from 25 C 5.33 mw/ C Package dissipation ILQ620 500 mw ILQ620GB 500 mw Derate from 25 C 6.67 mw/ C Creepage 7.0 mm Clearance 7.0 mm Isolation resistance V IO = 500 V, T amb = 25 C R IO 10 12 Ω V IO = 500 V, T amb = C R IO 10 11 Ω Storage temperature T stg - 55 to + 150 C Operating temperature T amb - 55 to + C Junction temperature T j C Soldering temperature 2.0 mm from case bottom T sld 260 C 2
Electrical Characteristics T amb = 25 C, unless otherwise specified Minimum and maximum values are testing requirements. Typical values are characteristics of the device and are the result of engineering evaluation. Typical values are for information only and are not part of the testing requirements. Input Parameter Test condition Symbol Min Typ. Max Unit Forward voltage I F = ± 10 ma V F 1.0 1.15 1.3 V Forward current V R = ± 0.7 V I F 2.5 20 µa Capacitance V F = 0 V, f = 1.0 MHz C O 25 pf Thermal resistance, junction to lead R THJL 750 K/W Output Parameter Test condition Symbol Min Typ. Max Unit Collector-emitter capacitance V CE = 5.0 V, f = 1.0 MHz C CE 6.8 pf Collector-emitter leakage V CE = 24 V I CEO 10 na current T A = 85 C, V CE = 24 V I CEO 2.0 50 µa Thermal resistance, junction to lead R THJL 500 K/W Coupler Parameter Test condition Part Symbol Min Typ. Max Unit Off-state collector current V F = ± 0.7 V, V CE = 24 V I CE(OFF) 1.0 10 µa Collector-emitter saturation I F = ± 8.0 ma, I CE = 2.4 ma ILD620 V CEsat 0.4 V voltage ILQ620 V CEsat 0.4 V I F = ± 1.0 ma, I CE = 0.2 ma ILD620GB V CEsat 0.4 V ILQ620GB V CEsat 0.4 V Parameter Test condition Part Symbol Min Typ. Max Unit Channel/Channel CTR match I F = ± 5.0 ma, V CE = 5.0 V CTRX/CTRY 1 to 1 3 to 1 CTR symmetry I CE (I F = - 5.0 ma)/ I CE (I F = + 5.0 ma) I CE(RATIO) 0.5 2.0 (collector-emitter saturated) (collector-emitter) (collector-emitter saturated) (collector-emitter) I F = ± 1.0 ma, V CE = 0.4 V ILD620 CTR CEsat 60 % ILQ620 CTR CEsat 60 % I F = ± 5.0 ma, V CE = 5.0 V ILD620 CTR CE 50 80 600 % ILQ620 CTR CE 50 80 600 % I F = ± 1.0 ma, V CE = 0.4 V ILD620GB CTR CEsat 30 % ILQ620GB CTR CEsat 30 % I F = ± 5.0 ma, V CE = 5.0 V ILD620GB CTR CE 200 600 % ILQ620GB CTR CE 200 600 % 3
VISHAY Switching Characteristics Non-saturated Parameter Test condition Symbol Min Typ. Max Unit On time I F = ± 10 ma, V CC = 5.0 V, t on 3.0 µs Rise time I F = ± 10 ma, V CC = 5.0 V, t r 20 µs Off time I F = ± 10 ma, V CC = 5.0 V, t off 2.3 µs Fall time I F = ± 10 ma, V CC = 5.0 V, t f 2.0 µs Propagation H-L I F = ± 10 ma, V CC = 5.0 V, t PHL 1.1 µs Propagation L-H I F = ± 10 ma, V CC = 5.0 V, t PLH 2.5 µs Saturated Parameter Test condition Symbol Min Typ. Max Unit On time I F = ± 10 ma, V CC = 5.0 V, t on 4.3 µs Rise time I F = ± 10 ma, V CC = 5.0 V, Off time I F = ± 10 ma, V CC = 5.0 V, Fall time I F = ± 10 ma, V CC = 5.0 V, Propagation H-L I F = ± 10 ma, V CC = 5.0 V, Propagation L-H I F = ± 10 ma, V CC = 5.0 V, t r 2.8 µs t off 2.5 µs t f 11 µs t PHL 2.6 µs t PLH 7.2 µs Typical Characteristics (T amb = 25 C unless otherwise specified) IF =10mA VCC =5V F = 10 KHz, DF = 50% VCC =5V RL =1kΩ F = 10 KHz, DF = 50% VO RL = 75 Ω IF =10mA VO iild620_01 iild620_02 Fig. 1 Non-saturated Switching Timing Fig. 2 Saturated Switching Timing 4
I F 10 5 V O t PLH t D t R t PLH t S t F 50% ICEO - Collector-Emitter - na 10 4 10 3 10 2 10 1 10 0 10-1 10-2 -20 Vce=10V Typical 0 20 40 60 80 T A - Ambient Temperature - C iild620_03 t on t off iild620_06 Fig. 3 Non-saturated Switching Timing Fig. 6 Collector-Emitter Leakage vs. Temperature 120 iild620 _04 I F V O t D t R t PHL t PLH t S V TH = 1.5 V t F IF - Maximum LED Current - ma iild620_07 80 60 TJ (MAX) = C 40 20 0-60 -40-20 0 20 40 60 80 Ta - Ambient Temperature - C Fig. 4 Saturated Switching Timing Fig. 7 Maximum LED Current vs. Ambient Temperature 60 200 I F - LED Forward Current - ma iild620_05 40 85 C 20 25 C 0 55 C -20-40 -60-1.5-1.0-0.5 0.0 0.5 1.0 1.5 V F - LED Forward Voltage - V PLED - LED Power - mw iild620_08 150 50 0-60 -40-20 0 20 40 60 80 Ta - Ambient Temperature - C Fig. 5 LED Forward Current vs.forward Voltage Fig. 8 Maximum LED Power Dissipation 5
VISHAY I C - Normalized Collector Current 50 10 5.0 2.5 1.0 0.5 Normalized to I F =10mA V CE =5V ILD/Q620GB ILD/Q620 0.1 1 5 10 20 Forward Current - I F ma CTRNF - Normalized CTR Factor 2.0 1.5 1.0 Normalized to: V CE =10V,I F = 5 ma, CTRce(sat) V CE = 0.4 V NCTRce 0.5 NCTRce(sat) TA = C 0.0.1 1 10 IF - LED Current - ma iild620_09 iild620_12 Fig. 9 Collector Current vs. Diode Forward Current Fig. 12 Normalization Factor for Non-saturated and Saturated CTR vs. I F CTRNF - Normalized CTR Factor iild620_10 2.0 1.5 1.0 0.5 Normalized to: V CE =10V,I F = 5 ma, CTRce(sat) V CE = 0.4 V NCTRce NCTRce(sat) T A =50 C 0.0.1 1 10 I F - LED Current - ma If(pk) - Peak LED Current - ma iild620_13 00 0 Duty Factor.005.01.02.05.1.2.5 10 10-6 10-5 10-4 10-3 10-2 10-1 10 0 10 1 t - LED Pulse Duration - s τ ˇ t τ DF = /t Fig. 10 Normalization Factor for Non-saturated and Saturated CTR vs. I F Fig. 13 Peak LED Current vs. Pulse Duration, Tau CTRNF - Normalized CTR Factor iild620_11 2.0 1.5 1.0 Normalized to: V CE =10V,I F = 5 ma, CTRce(sat) V CE = 0.4 V NCTRce NCTRce(sat) 0.5 T A =70 C 0.0.1 1 10 I F - LED Current - ma PDET - Detector Power - mw iild620_14 200 150 50 0-60 -40-20 0 20 40 60 80 Ta - Ambient Temperature - C Fig. 11 Normalization Factor for Non-saturated and Saturated CTR vs. I F Fig. 14 Maximum Detector Power Dissipation 6
0 ICE - Collector Current - ma 10 1 Rth = 500 C/W 25 C 50 C 75 C 90 C.1.1 1 10 VCE - Collector-Emitter Voltage - V iild620_15 Fig. 15 Maximum Collector Current vs. Collector Voltage Package Dimensions in Inches (mm) pin one ID.255 (6.48).268 (6.81) 4 3 2 1 5 6 7 8 ISO Method A i178006.030 (0.76).045 (1.14) 4 typ..379 (9.63).390 (9.91).031 (0.79).130 (3.30).150 (3.81).300 (7.62) typ..050 (1.27).018 (.46).020 (.51 ).035 (.89 ) 10 3 9.022 (.56). (2.54) typ..008 (.20).012 (.30).230(5.84).110 (2.79).250(6.35).130 (3.30) 7
VISHAY Package Dimensions in Inches (mm) 8 7 6 5 4 3 2 1 9 10 11 12 13 14 15 16.779 (19.77 ).790 (20.07) pin one ID.255 (6.48).265 (6.81) ISO Method A.030 (.76).045 (1.14).031(.79).300 (7.62) typ. 4.018 (.46).022 (.56). (2.54)typ..130 (3.30).150 (3.81).020(.51).035 (.89).050 (1.27) 10 typ. 3 9.008 (.20).012 (.30).110 (2.79).130 (3.30).230 (5.84).250 (6.35) i178007 Option 7 Option 9.300 (7.62) TYP..375 (9.53).395 (10.03).028 (0.7) MIN..315 (8.0) MIN..331 (8.4) MIN..406 (10.3) MAX..180 (4.6).160 (4.1).0040 (.102).0098 (.249).300 (7.62) ref..020 (.51).040 (1.02).315 (8.00) min..012 (.30) typ. 15 max. 18494 8
Ozone Depleting Substances Policy Statement It is the policy of Vishay Semiconductor GmbH to 1. Meet all present and future national and international statutory requirements. 2. Regularly and continuously improve the performance of our products, processes, distribution and operatingsystems with respect to their impact on the health and safety of our employees and the public, as well as their impact on the environment. It is particular concern to control or eliminate releases of those substances into the atmosphere which are known as ozone depleting substances (ODSs). The Montreal Protocol (1987) and its London Amendments (1990) intend to severely restrict the use of ODSs and forbid their use within the next ten years. Various national and international initiatives are pressing for an earlier ban on these substances. Vishay Semiconductor GmbH has been able to use its policy of continuous improvements to eliminate the use of ODSs listed in the following documents. 1. Annex A, B and list of transitional substances of the Montreal Protocol and the London Amendments respectively 2. Class I and II ozone depleting substances in the Clean Air Act Amendments of 1990 by the Environmental Protection Agency (EPA) in the USA 3. Council Decision 88/540/EEC and 91/690/EEC Annex A, B and C (transitional substances) respectively. Vishay Semiconductor GmbH can certify that our semiconductors are not manufactured with ozone depleting substances and do not contain such substances. We reserve the right to make changes to improve technical design and may do so without further notice. Parameters can vary in different applications. All operating parameters must be validated for each customer application by the customer. Should the buyer use products for any unintended or unauthorized application, the buyer shall indemnify against all claims, costs, damages, and expenses, arising out of, directly or indirectly, any claim of personal damage, injury or death associated with such unintended or unauthorized use. Vishay Semiconductor GmbH, P.O.B. 3535, D-74025 Heilbronn, Germany Telephone: 49 (0)7131 67 2831, Fax number: 49 (0)7131 67 2423 9