SG8080 2A Output Current IGBT Gate Drive Optocoupler Description Applications The SG8080 is an optically coupled 2A Output Current Gate Driver, designed to drive most 1200V / 100A IGBTs and MOSFETs. It is intended for driving high power IGBTs and MOSFETs used in motor control inverter applications. The circuit consists of an infrared input LED optically coupled to an integrated circuit which utilizes a high speed driver. The SG8080 comes standard in a miniature 8 pin DIP package. IGBT / MOSFET Gate Drives AC & Brushless DC Motor Drives Industrial Inverters Uninterruptable Power Supplies (UPS) Switch Mode Power Supplies Features Schematic Diagram High Common Mode Rejection: 10kV/S minimum @ VCM = 1500V 2A Maximum Peak Output Current Fast Switching Speeds o 200nS Maximum Propagation Delay ICC=5mA Maximum Supply Current Wide Supply Voltage Range (10V to 20V) Under Voltage Lockout Protection (UVLO) with Hysteresis Broad Temperature Performance Range (-40°C to 100°C) Low Power Dissipation (RON ≤ 1Ω) Rail-to-Rail Output Voltage High Input to Output Isolation (5kVRMS) RoHS / Pb-Free / REACH Compliant Agency Approvals SG8080 UL/C-UL approved to UL1577 VDE approved to EN60747-5-5 Truth Table (Positive Logic) LED OFF VCC-VEE (“Positive Going”) Turn On 0 – 30V VCC-VEE (“Negative Going”) Turn Off 0 – 30V Ordering Information VO LOW ON 0 – 11.5V 0 – 10V LOW ON 11.5 – 13.5V 10 – 12V TRANSITION ON 13.5 – 20V 12 – 20V HIGH ** A 0.1μF bypass Capacitor must be connected between pins 5 & 8 (GND & VCC) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Part Number SG8080 SG8080-H SG8080-S SG8080-STR Description 8 pin DIP, (50/Tube) 0.40” (10.16mm) Wide Lead Spacing (VDE0884) 8 pin SMD, (50/Tube) 8 pin SMD, Tape and Reel (1000/Reel) NOTE: Suffixes listed above are not included in marking on device for part number identification Page 1 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler Absolute Maximum Ratings, TA = 25°C (unless otherwise specified) The values indicated are absolute stress ratings. Functional operation of the device is not implied at these or any conditions in excess of those defined in electrical characteristics section of this document. Exposure to absolute Maximum Ratings may cause permanent damage to the device and may adversely affect reliability. Parameter Symbol Min. Typ. Max. Units Storage Temperature TST -55 - 125 °C Operating Temperature TA -40 - 100 °C VISO 5000 - - Supply Voltage VCC 0 - 25 V Solder Temperature – Wave (10 sec) TSOL - - 260 °C PT - - 295 mW IF(AVG) - - 25 mA VR - - 5 V Test Conditions Fig. Notes General Maximum Ratings Isolation Voltage Total Power Dissipation VRMS 8 Input Maximum Ratings Average Forward Input Current Reverse Input Voltage Peak Transient Input Current IF(TRAN) - - 1 A tr(IN) / tf(IN) - - 200 nS PI - - 45 mW 9 “High” Peak Output Current IOH(PEAK) - - 2 A 1 “Low” Peak Output Current IOL(PEAK) - - 2 A 1 Output Voltage VO - - VCC V Output Power Dissipation PO - - 250 mW Input Current (Rise / Fall Time) Input Power Dissipation <1S pulse width, 300pps Output Maximum Ratings 10 Recommended Operating Conditions The values indicated are recommended for steady, consistent operation with optimal performance across the operating temperature range. Parameter Symbol Min. Typ. Max. TA -40 - 100 Units Test Conditions Fig. Notes Recommended Specifications Operating Temperature Supply Voltage °C VCC 10 - 20 V Input Current (ON) IFL(ON) 10 - 16 mA Input Voltage (OFF) VF(OFF) -3.0 - 0.8 V © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 2 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler Electrical Characteristics, TA = 25°C, VEE = Ground and VCC = 30V (unless otherwise specified) Parameter Symbol Min. Typ. Max. Units Test Conditions VF 1.2 1.4 1.8 ΔVF / ΔT - -1.24 LED Reverse Voltage BVR 5 Input Threshold Current (Low to High) IFLH Input Threshold Voltage (High to Low) Input Capacitance Fig. Notes V IF = 10mA - mV/°C IF = 10mA - - V IR = 10A - 2.9 5 mA VO > 5V, IO = 0A VFHL 0.8 - - V VO < 5V, IO = 0A CIN - 33 - pF f = 1MHz, VF = 0V High Level Supply Current ICCH - 1 5 mA Open VO, IF = 10 to 16mA 7,8 Low Level Supply Current ICCL - 1 5 mA Open VO, VF = -3 to +0.8V 7,8 High Level Output Current IOH -2 - - A VO = (VCC – 6V) 2,13,19 1 Low Level Output Current IOL 2 - - A VO = (VCC + 6V) 5,6,20 1 High Level Output Voltage VOH VCC0.4 VCC-0.2 - V IF = 10mA, IO = -100mA 1,3,17 Low Level Output Voltage VOL - VEE+0.2 VEE+0.4 V IF = 0mA, IO = 100mA 4,16,18 VUVLO+ - 8.3 - V VO > 5V, IF = 10mA 22 VUVLO- - 7.7 - V VO < 5V, IF = 10mA 22 UVLOHYS - 0.6 - V Withstand Insulation Test VISO 5000 - - V RH ≤ 40-60%, t = 1 min Input-Output Resistance RI-O - 10 - Ω VI-O = 500VDC 2 Input-Output Capacitance CI-O - 0.9 - pF f =1MHz 2 Input Specifications LED Forward Voltage LED Forward Voltage Temperature Coefficient 15 9,16,21 Output Specifications Under Voltage Lockout Threshold Under Voltage Lockout Hysteresis 22 Isolation Specifications © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 12 Page 3 of 15 2,3 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler Electrical Characteristics, continued… TA = 25°C, VEE = Ground and VCC = 30V (unless otherwise specified) Parameter Symbol Min. Typ. Max. Units Test Conditions Fig. Notes Switching Specifications Propagation Delay Time to High Output Level tPLH 100 150 200 Propagation Delay Time to Low Output Level tPHL 100 150 200 Pulse Width Distortion PWD - - 65 Propagation Delay Difference Between Any Two Parts PDD - - 90 Output Rise Time (10 to 90%) tr - 25 - nS IF = 7 to 16mA VCC = 15 to 30V VEE = Ground Rg = 10Ω Cg = 10nF f = 10kHz Duty Cycle = 50% 10 11 12 13 14 23 7 4 23 Output Fall Time (90 – 10%) tf - 25 - UVLO Turn On Delay tUVLO ON - 2 - S IF = 10mA, VO > 5V UVLO Turn Off Delay tUVLO OFF - 0.3 - S IF = 10mA, VO < 5V Common Mode Transient Immunity at HIGH Level Output Common Mode Transient Immunity at LOW Level Output | CMH | | CML | 10 - 10 - - - kV/S kV/S IF = 7 to 16mA VCM = 1500V TA = 25°C VCC = 30V VF = 0V VCM = 1500V TA = 25°C VCC = 30V 5 24 6 Notes 1. Maximum pulse width = 10S, maximum duty cycle = 0.2% 2. Device is considered a two-terminal device: pins 1, 2, 3, and 4 shorted together, and pins 5, 6, 7, and 8 shorted together 3. In accordance with UL 1577, each optocoupler is proof tested by applying an insulation test voltage ≥6000 VRMS for one second (leakage current less than 5 A) 4. The difference between TPHL and TPLH between any two SG8080 devices under the same test conditions 5. Common mode transient immunity in HIGH stage is the maximum tolerable negative dVCM/dt on the trailing edge of the common mode impulse signal, VCM, to assure that the output will remain HIGH 6. Common mode transient immunity in LOW stage is the maximum tolerable positive dVCM/dt on the leading edge of the common mode impulse signal, VCM, to assure that the output will remain LOW 7. Pulse Width Distortion is defined as |TPHL – TPLH| for any given device 8. 260°C for 10 seconds. Refer to the lead free solder reflow profile for more information 9. Derate linearly above 70°C free air temperature at a rate of 0.47mW / °C 10. Derate linearly above 70°C free air temperature at a rate of 4.8mW / °C © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 4 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Performance & Characteristics Plots, TA = 25°C (unless otherwise specified) Figure 2: Output High Current vs. Temperature (°C) (VOH – VCC) – Output High Voltage Drop (V) IOH – Output High Current (A) Figure 1: Output High Voltage Drop vs. Temperature (°C) Ambient Temperature – TA (°C) Ambient Temperature – TA (°C) Figure 4: Output Low Voltage vs. Temperature (°C) (VOH – VCC) – Output High Voltage Drop (V) VOL – Output Low Voltage Drop (V) Figure 3: Output High Voltage Drop vs. High Current IOH – Output High Current (A) Ambient Temperature – TA (°C) Figure 6: Output Low Voltage Drop vs. Low Current IOL – Output Low Current (A) VOL – Output Low Voltage Drop (V) Figure 5: Output Low Current vs. Temperature (°C) IOL – Output Low Current (A) Ambient Temperature – TA (°C) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 5 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Performance & Characteristics Plots, continued… TA = 25°C (unless otherwise specified) Figure 8: Supply Current (ICC) vs. Supply Voltage (VCC) ICC – Supply Current (mA) ICC – Supply Current (mA) Figure 7: Supply Current (ICC) vs. Temperature (°C) Ambient Temperature – TA (°C) VCC – Supply Voltage (V) Figure 10: Propagation Delay (tP) vs. Supply Voltage (VCC) Figure 9: Low to High Input Current Threshold (IFLH) vs. IFLH – Low to High Input Current Threshold (mA) tP – Propagation Delay (nS) Temperature (°C) VCC – Supply Voltage (V) Ambient Temperature – TA (°C) Figure 12: Propagation Delay (tP) vs. Temperature (°C) tP – Propagation Delay (nS) tP – Propagation Delay (nS) Figure 11: Propagation Delay (tP) vs. Forward Current (IF) Ambient Temperature – TA (°C) IF – Forward Current (mA) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 6 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Performance & Characteristics Plots, continued… TA = 25°C (unless otherwise specified) Figure 13: Propagation Delay (tP) vs. Series Load Figure 14: Propagation Delay (tP) vs. Load Capacitance (Cg) tP – Propagation Delay (nS) tP – Propagation Delay (nS) Resistance (Rg) Rg – Load Resistance (Ω) Cg – Load Capacitance (nF) Figure 16: Transfer Characteristics VO – Output Voltage (V) IF – Forward Current (mA) Figure 15: Forward Current (IF) vs. Forward Voltage (VF) IF – Forward Current (mA) VF – Forward Voltage (V) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 7 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Electrical Test Circuits Figure 17: High Level Output Voltage (VOH) Test Circuit Figure 18: Low Level Output Voltage (VOL) Test Circuit Figure 19: High Level Output Current (IOH) Test Circuit Figure 20: Low Level Output Current (IOL) Test Circuit IF = 7mA to 16mA PW = 10S Period = 5mS IF = 7mA to 16mA PW = 4.99mS Period = 5mS Figure 21: Input Threshold Current (IFLH) Test Circuit IF = 10mA © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Figure 22: UVLO Test Circuit IF = 10mA Page 8 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Electrical Test Circuits, continued… Figure 23: Rise Time (tr), Fall Time (tf), and Propagation Delay Times (tPLH and tPHL) Test Circuit & Waveforms Figure 24: CMR Test Circuit & Waveforms © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 9 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Solder Reflow Temperature Profile Recommendations (1) Infrared Reflow: Refer to the following figure as an example of an optimal temperature profile for single occurrence infrared reflow. Soldering process should not exceed temperature or time limits expressed herein. Surface temperature of device package should not exceed 250ºC: G F D E H B A C Process Step A B C D E F G H Description Preheat Start Temperature (ºC) Preheat Finish Temperature (ºC) Preheat Time (s) Melting Temperature (ºC) Time above Melting Temperature (s) Peak Temperature, at Terminal (ºC) Dwell Time at Peak Temperature (s) Cool-down (ºC/s) Parameter 150ºC 180ºC 90 - 120s 230ºC 30s 260ºC 10s <6ºC/s (2) Wave Solder: Maximum Temperature: Maximum Time: Pre-heating: Single Occurrence 260ºC (at terminal) 10s 100 - 150ºC (30 - 90s) (3) Hand Solder: Maximum Temperature: Maximum Time: Single Occurrence © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 350ºC 3s (at tip of soldering iron) Page 10 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Package Dimensions 8 PIN DIP Package © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Note: All dimensions in millimeters [mm] with inches in parenthesis () Page 11 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Package Dimensions 8 PIN WIDE Lead Space Package (-H) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Note: All dimensions in millimeters [mm] with inches in parenthesis () Page 12 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Package Dimensions 8 PIN SMD Surface Mount Package (-S) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Note: All dimensions in millimeters [mm] with inches in parenthesis () Page 13 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Packaging Specifications Tape & Reel Specifications (T&R) Specification Note: All dimensions in millimeters [mm] with inches in parenthesis () Symbol Dimensions, mm ( inches ) Tape Width W 16 0.3 ( 0.63 ) Sprocket Hole Pitch P0 4 0.1 ( 0.15 ) Compartment Location F P2 7.5 0.1 ( 0.295 ) 2 0.1 ( 0.079 ) Compartment Pitch P1 12 0.1 ( 0.472 ) © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 14 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352 SG8080 2A Output Current IGBT Gate Drive Optocoupler SG8080 Packaging Marking SG8080 Package Weights Single Unit Full Tube (50pcs) Full Pouch (10 tubes) Full Reel (1000pcs) SG8080 0.54 48 490 - SG8080-S 0.53 46 470 - SG8080-H 0.55 49 500 - SG8080-STR 0.53 - - 480 Device Note: All weights above are in GRAMS, and include packaging materials where applicable DISCLAIMER Solid State Optronics (SSO) makes no warranties or representations with regards to the completeness and accuracy of this document. SSO reserves the right to make changes to product description, specifications at any time without further notices. SSO shall not assume any liability arising out of the application or use of any product or circuit described herein. Neither circuit patent licenses nor indemnity are expressed or implied. Except as specified in SSO’s Standard Terms & Conditions, SSO disclaims liability for consequential or other damage, and we make no other warranty, expressed or implied, including merchantability and fitness for particular use. LIFE SUPPORT POLICY SSO does not authorize use of its devices in life support applications wherein failure or malfunction of a device may lead to personal injury or death. Users of SSO devices in life support applications assume all risks of such use and agree to indemnify SSO against any and all damages resulting from such use. Life support devices are defined as devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and (c) whose failure to perform when used properly in accordance with instructions for use can be reasonably expected to result in significant injury to the user, or (d) a critical component of a life support device or system whose failure can be reasonably expected to cause failure of the life support device or system, or to affect its safety or effectiveness. © 2015 Solid State Optronics • San José, CA www.ssousa.com • +1.408.293.4600 Page 15 of 15 SG8080 /H/S/TR Rev03 (02/02/2015) 002352