Product Data Sheet Spec No. :DS70-06-00 Effective Date: 0/8/08 Revision: A LITE-ON DCC RELEASE BNS-OD-FC00/A LITE-ON Technology Corp. / Optoelectronics No.90,Chien Road, Chung Ho, New Taipei City 8, Taiwan, R.O.C. Tel: 886---68 Fax: 886---98 / 886---0660 http://www.liteon.com/opto
.0 Amp Output Current IGBT Gate Drive Photocoupler with Rail-to-Rail Output Voltage in Stretched SO6. Description The Photocoupler is ideally suited for driving power IGBTs and MOSFETs used in motor control inverter applications and inverters in power supply system. It contains an AlGaAs LED optically coupled to an integrated circuit with a power output stage. The Photocoupler operational parameters are guaranteed over the temperature range from -0 o C ~ +0 o C.. Features.0 A maximum peak output current 0.8 A minimum peak output current Rail-to-rail output voltage Functional Diagram Pin No. and Internal connection diagram 6 00 ns maximum propagation delay 00 ns maximum propagation delay difference Under Voltage Lock-Out protection (UVLO) with hysteresis kv/us minimum Common Mode Rejection (CMR) at V CM = 00 V Wide operating range: to 0 Volts (V CC) Guaranteed performance over temperature -0 o C ~ +0 o C. SHIELD. Anode. Cathode. GND. Vo (Output) 6. Vcc MSL Level Safety approval: UL 77 recognized with 000 V RMS for minute for LTV-0P and LTV-0W VDE DIN EN 6077-- Approved V IORM = 89Vpeak for LTV-0P V IORM = 0Vpeak for LTV-0W. Applications IGBT/MOSFET gate drive Uninterruptible power supply (UPS) Truth Table LED VCC-GND (Turn-ON, +ve going) VCC-GND (Turn-OFF, -ve going) OFF 0-0 V 0-0 V Low ON 0 -.0 V 0-9. V Low ON.0 -. V 9. - V Transition ON. - 0 V - 0 V High Note: A 0.μF bypass capacitor must be connected between Pin and 6. VO Industrial Inverters AC/Brushless DC motor drives Switching power suppliers / Part No. :
. PACKAGE DIMENSIONS. LTV-0W. LTV-0P Notes :. Year date code.. -digit work week.. Factory identification mark (Y : Thailand).. or V for VDE option. * Dimensions are in Millimeters and (Inches). / Part No. :
. TAPING DIMENSIONS. LTV-0W-TA. LTV-0W-TA. LTV-0P-TA. LTV-0P-TA Description Symbol Dimension in mm (inch) For W type Dimension in mm (inch) For P type Tape wide W 6±0. (0.6) 6±0. (0.6) Pitch of sprocket holes P 0 ±0. (0.6) ±0. (0.6) Distance of compartment Distance of compartment to compartment F 7.±0. (0.) 7.±0. (0.) P ±0. (0.079) ±0. (0.079) P 6±0. (0.6) ±0. (0.7). Quantities Per Reel Package Type Quantities (pcs) 000 / Part No. :
. IEC/EN/DIN EN 6077-- Insulation Characteristics Description Symbol LTV-0P LTV-0W Unit Climatic Classification /00/ /00/ Pollution Degree (DIN VDE 00/.89) Maximum Working Insulation Voltage V IORM 89 0 V peak Input to Output Test Voltage, Method b* V IORM x.87 = V PR, 00% Production Test with t m = sec, Partial discharge < pc Input to Output Test Voltage, Method a* V IORM x.6 = V PR, Type and Sample Test, tm = 0 sec, Partial discharge < pc Highest Allowable Overvoltage (Transient Overvoltage t ini = 60 sec) V PR 67 7 V peak V PR 6 8 V peak V IOTM 6000 8000 V peak Safety-limiting values maximum values allowed in the event of a failure. Case Temperature T S 7 7 o C Input Current I S, INPUT 0 0 ma Output Power P S, OUTPUT 600 600 mw Insulation Resistance at TS, V IO = 00 V R S >0 9 >0 9 Ω * Refer to the optocoupler section of the Isolation and Control Components Designer s Catalog, under Product Safety Regulations section, (IEC/EN/DIN EN 6077--) for a detailed description of Method a and Method b partial discharge test profiles. Note: These optocouplers are suitable for safe electrical isolation only within the safety limit data. Maintenance of the safety data shall be ensured by means of protective circuits. Surface mount classification is Class A in accordance with CECC 0080.. Insulation and Safety Related Specification Parameter Symbol LTV-0P LTV-0W Unit Test Condition Minimum External Air Gap (External Clearance) Minimum External Tracking (External Clearance) Tracking Resistance (Comparative Tracking Index) L(0) 7.0 8.0 mm L(0) 8.0 8.0 mm CTI >7 >7 V Measured from input terminals to output terminals, shortest distance through air. Measured from input terminals to output terminals, shortest distance DIN EN 60 (VDE 00 Teil ) / Part No. :
. RATING AND CHARACTERISTICS. Absolute Maximum Ratings Photocoupler Parameter Symbol Min Max Unit Note Storage Temperature T stg - + o C Operating Temperature T opr -0 +0 o C Output IC Junction Temperature T J o C Total Output Supply Voltage (V CC V EE) 0 V Average Forward Input Current I F ma Reverse Input Voltage V R V Peak Transient Input Current I F(TRAN).0 A High Peak Output Current I OH(PEAK).0 A Low Peak Output Current I OL(PEAK).0 A Input Current (Rise/Fall Time) t r(in) /t f(in) 00 ns Output Voltage V O(PEAK) V CC V Power Dissipation P I mw Output IC Power Dissipation P O 0 mw Total Power Dissipation P T 9 mw Lead Solder Temperature T sol 60 o C Note: Ambient temperature = o C, unless otherwise specified. Stresses exceeding the absolute maximum ratings can cause permanent damage to the device. Exposure to absolute maximum ratings for long periods of time can adversely affect reliability. Note: Note: A ceramic capacitor (0. μf) should be connected between pin 6 and pin to stabilize the operation of a high gain linear amplifier. Otherwise, this Photocoupler may not switch properly. The bypass capacitor should be placed within cm of each pin. Note : Pulse width (PW) μs, 00 pps Note : Exponential waveform. Pulse width 0. μs, f khz Note : The rise and fall times of the input on-current should be less than 00 ns. Recommended Operating Conditions Parameter Symbol Min Max Unit Operating Temperature T A -0 0 o C Supply Voltage V CC 0 V Input Current (ON) I FL(ON) 7 6 ma Input Voltage (OFF) V F(OFF) -.0 0.8 V / Part No. :
. ELECTRICAL OPTICAL CHARACTERISTICS Parameter Symbol Min. Typ. Max. Unit Test Condition Figure Note Input Forward Voltage V F..7.8 V I F = 0mA Input Forward Voltage Temperature Coefficient ΔV F/ ΔT -.7 mv/ O C I F = 0mA Input Reverse Voltage BV R V I R = 0μA Input Input Threshold Current (Low to High) I FLH.9 ma V CC = 0 V, V O > V 6, 7,8 Input Threshold Voltage (High to Low) V FHL 0.8 V V CC = 0 V, V O < V Input Capacitance C IN pf f = MHz, V F = 0 V High Level Supply Current Low Level Supply Current I CCH.9.0 ma I CCL.0.0 ma I F = 0 ma, V CC = 0V, V O = Open I F = 0 ma, V CC = 0V, V O = Open, High level output current I OH -0. V O = (V CC. V) A 6-0.8 V O = (V CC V) Output Low level output current I OL 0. V O = (V EE +. V) A 7 0.8 V O = (V EE + V) High level output voltage V OH V CC - 0.6 V CC - 0. V I F = 0mA, I O = -00mA,, Low level output voltage V OL V EE + 0. V EE + 0. V I F = 0mA, I O = 00mA, UVLO Threshold V UVLO+.0.7. V V O > V, I F = 0 ma V UVLO- 9...0 V V O < V, I F = 0 ma 9 UVLO Hysteresis UVLO HYS. V All Typical values at T A = C and V CC V EE = to 0 V, unless otherwise specified; all minimum and maximum specifications are at recommended operating condition. (Refer to.) Note : Maximum pulse width = 0 μs. Note : Maximum pulse width = 0 μs. 6/ Part No. :
6. SWITCHING SPECIFICATION Parameter Symbol Min. Typ. Max. Unit Test Condition Figure Note Propagation Delay Time to High Output Level t PLH 0 0 00 Propagation Delay Time to t PHL 0 0 00 Low Output Level R g = 7Ω, 8, 9, 0, C g = nf,,, Pulse Width Distortion PWD 70 f = 0 khz, 0 Propagation delay difference ns Duty Cycle = 0% between any two parts or channels PDD -00 00 I F = 7 to 6 ma, V CC = to 0V Output Rise Time (0 to 90%) Tr V EE = ground Output Fall Time (90 to 0%) Tf 0 T A = C, Common mode transient immunity at high level output CM H 0 kv/μs I F = 0 to 6 ma, V CM = 00 V, V CC = 0 V T A = C, Common mode transient immunity at low level output CM L 0 kv/μs V F = 0 V, V CM = 00 V, V CC = 0 V All Typical values at T A = C and V CC V EE = to 0 V, unless otherwise specified; all minimum and maximum specifications are at recommended operating condition. (Refer to.) Note : CM H is the maximum rate of rise of the common mode voltage that can be sustained with the output voltage in the logic high state (V O > V). Note : CM L is the maximum rate of fall of the common mode voltage that can be sustained with the output voltage in the logic low state (V O < V). Note : The difference between t PHL and t PLH between any two parts series parts under same test conditions. 7/ Part No. :
7. ISOLATION CHARACTERISTIC Parameter Symbo Device Min. Typ. Max. Unit Test Condition Note Withstand Insulation Test Voltage V ISO LTV-0W LTV-0P 000 V RH 0%-60%, t = min, T A = o C, Input-Output Resistance R I-O 0 Ω V I-O = 00V DC Input-Output Capacitance C I-O 0.9 pf f = MHz, T A = o C All Typical values at T A = C unless otherwise specified. All minimum and maximum specifications are at recommended operating condition. (Refer to.) Note : Device is considered a two terminal device: pins, and are shorted together and pins, and 6 are shorted together. Note : According to UL77, each photocoupler is tested by applying an insulation test voltage 6000V RMS for one second (leakage current less than 0uA). This test is performed before the 00% production test for partial discharge 8/ Part No. :
8. TYPICAL PERFORMANCE CURVES & TEST CIRCUITS Photocoupler V OH -High Output Rail Voltage -V 9.7 9.70 9.6 9.60 9. 9.0 I F = 0 ma I OUT = -00mA V CC = 0 V V EE = 0 V 9. -0-0 -0-0 0 0 0 0 0 0 60 70 80 90 00 0 TA -Temperature - o C V OH -High Output Voltage Drop -V 0.00-0.0-0.0-0. -0.0-0. -0.0-0. -0.0-0. -0.0-0. I F = 0 ma I OUT = -00mA V CC = 0 V V EE = 0 V -0.60-0 -0-0 -0 0 0 0 0 0 0 60 70 80 90 00 0 TA -Temperature - o C Figure : High output rail voltage vs. Temperature Figure : VOH vs. Temperature 0. 0.0. V OL -Output Low Voltage -V 0. 0.0 0. 0.0 V F (OFF) = 0 V I out = 00 ma 0.0 V CC = 0 V V EE = 0 V 0.00-0 -0-0 -0 0 0 0 0 0 0 60 70 80 90 00 0 T A -Temperature - o C I CC -Supply Current -ma. I F = 0 ma for I CCH 0. V F = 0V for I CCL V CC = 0 V I CCH V EE = 0 V I CCL 0-0 -0-0 -0 0 0 0 0 0 0 60 70 80 90 00 0 T A -Tamperature - o C Figure : VOL vs. Temperature Figure : ICC vs. Temperature I CC -Supply Current -ma.. I F = 0 ma for I CCH 0. V F = 0V for I CCL T A = o C I CCH V EE = 0 V I CCL 0 0 0 V CC -Supply Voltage -V V O -Output Voltage -V 0 0 0 0 T A = o C V CC = 0 V V EE = 0V I FLH ON I FLH OFF 0 0.... I FLH -Low to High Current Threshold -ma Figure : ICC vs. VCC Figure 6: IFLH Hysteresis 9/ Part No. :
L FLH -Low To High Threshold -ma.... I FLH ON 0. V CC = 0 to 0 V V EE = 0 V I FLH OFF 0-0 -0-0 -0 0 0 0 0 0 0 60 70 80 90 00 0 T A -Temperature - o C T P -Propagation Delay -ns 0 0 0 00 9 90 8 I F = 8 ma, T A = o C R g = 7Ω, C g = nf Duty Cycle = 0% f = 0kHz 80 0 0 V CC -Supply Voltage -V T PLH T PHL Figure 7: IFLH vs. Temperature Figure 8: Propagation Delays vs. VCC T P -Propagation Delay -ns 00 80 60 0 0 00 80 60 0 0 0 V CC = 0V, V EE = 0V T A = o C R g = 7Ω, C g = nf Duty Cycle = 0% f = 0kHz 6 8 0 6 I F -Forward LED Cureent -ma T PLH T PHL T P -Propagation Delay -ns 00 80 60 0 0 00 80 I 60 F = 8mA V CC = 0V, V EE = 0V 0 R g = 7Ω, C g = nf Duty Cycle = 0% T PLH 0 f = 0kHz T PHL 0-0 -0-0 -0 0 0 0 0 0 0 60 70 80 90 00 0 T A -Temperature - o C Figure 9: Propagation Delays vs. IF Figure 0: Propagation Delays vs. Temperature T P -Propagation Delay -ns 60 0 0 0 0 0 00 90 I F = 8 ma, T A = o C V CC = 0 V, V EE = 0 V 80 C g = nf T Duty Cycle = 0% PLH 70 f = 0kHz T PHL 60 0 0 0 0 0 R g -Series Load Resistance -Ω T P -Propagation Delay -ns 0 0 0 00 90 80 I F = 8 ma, T A = o C 70 V CC = 0 V, V EE = 0 V 60 R g = 7 Ω T Duty Cycle = 0% PLH f = 0kHz T PHL 0 0 0 0 0 0 C g -Series Load Capacitance -nf Figure : Propagation Delays vs. Rg Figure : Propagation Delays vs. Cg 0/ Part No. :
60 I F -Forward Current -ma 0 0 0 0 0.....6 V F -Forward Voltage -V Figure : Input Current vs. Forward Voltage 6 6 00mA I F =7to6mA 0.μF V OH V CC = to 0V 0.μF VOL V CC = to 0V 00mA Figure : VOH Test Circuit Figure : VOL Test Circuit 6 V Pulsed 6 I F =7to6mA 0.μF I OH V CC = to 0V 0.μF IOL V CC = to 0V.V Pulse Figure 6 : IOH Test Circuit Figure 7 : IOL Test Circuit 6 6 IF 0.μF VO>V V CC = to 0V IF I F =7to6mA 0.μF VO>V V CC Figure 8 : IFLH Test Circuit Figure 9 : UVLO Test Circuit / Part No. :
6 IF tr tf I F = 7 to 6mA 0kHZ 0% Duty Cycle uf 0.μF V o>v 7Ω nf VCC=0 = to to 0V + - VO tp LH tp HL VOH 90% 0% 0% VOL Figure 0 : tr, tf, tplh and tphl Test Circuit and Waveforms SW A IF B 6 0.uF VO VCC VC M 0V VO SW A: IF=0mA Δt δv δt = VC M Δt VO H VCM Ω + - VO SW B: IF=0mA VO L Figure : CMR Test Circuit and Waveforms / Part No. :
9. TEMPERATURE PROFILE OF SOLDERING 9. IR Reflow soldering (JEDEC-STD-00C compliant) Photocoupler One time soldering reflow is recommended within the condition of temperature and time profile shown below. Do not solder more than three times. Profile item Conditions Preheat - Temperature Min (T Smin) - Temperature Max (T Smax) - Time (min to max) (ts) 0 C 00 C 90±0 sec Soldering zone - Temperature (T L) - Time (t L) Peak Temperature (T P) Ramp-up rate Ramp-down rate 7 C 60 ~ 00 sec 60 C C / sec max. ~6 C / sec Ramp-up 0 sec TP 60 C Temperature ( C) Tsmin 0 C TL 7 C Tsmax 00 C 60-00 sec tl (Soldering) Ramp-down C 60 ~ 0 sec ts (Preheat) Time (sec) / Part No. :
9. Wave soldering (JEDECA compliant) Photocoupler One time soldering is recommended within the condition of temperature. Temperature: 60+0/- C Time: 0 sec. Preheat temperature: to 0 C Preheat time: 0 to 80 sec. 9. Hand soldering by soldering iron Allow single lead soldering in every single process. One time soldering is recommended. Temperature: 80+0/- C Time: sec max. / Part No. :
0. NAMING RULE Photocoupler Part Number Options LTV-0P-TA LTV-0P-TA LTV-0W-TA LTV-0W-TA LTV0PTA-V LTV0PTA-V LTV0WTA-V LTV0WTA-V Definition of Suffix Remark "0" LiteOn model name "P" "W" "TA" "TA" "V" clearance distance 7mm typical clearance distance 8mm typical Pin location at lower right of the tape Pin location at upper left of the tape VDE approved option. Notes LiteOn is continually improving the quality, reliability, function or design and LiteOn reserves the right to make changes without further notices. The products shown in this publication are designed for the general use in electronic applications such as office automation equipment, communications devices, audio/visual equipment, electrical application and instrumentation. For equipment/devices where high reliability or safety is required, such as space applications, nuclear power control equipment, medical equipment, etc, please contact our sales representatives. When requiring a device for any specific application, please contact our sales in advice. If there are any questions about the contents of this publication, please contact us at your convenience. The contents described herein are subject to change without prior notice. Immerge unit s body in solder paste is not recommended. / Part No. :