XD33153

XD33153 DIP-8 XL33153 SOP-8 Single IGBT Gate Driver The XDXL33153 is specifically designed as an IGBT driver for high power applications that include ac induction motor control, brushless dc motor control and uninterruptable power supplies. Although designed for driving discrete and module IGBTs, this device offers a cost effective solution for driving power MOSFETs and Bipolar Transistors. Device protection features include the choice of desaturation or overcurrent sensing and undervoltage detection. These devices are available in dual−in−line and surface mount packages. PIN CONNECTIONS Current Sense Input 1 8 Fault Blanking/ Desaturation Input Kelvin GND 2 7 Fault Output VEE 3 6 VCC Input 4 5 Drive Output Features • • • • • • • • High Current Output Stage: 1.0 A Source/2.0 A Sink Protection Circuits for Both Conventional and Sense IGBTs Programmable Fault Blanking Time Protection against Overcurrent and Short Circuit Undervoltage Lockout Optimized for IGBT’s Negative Gate Drive Capability Cost Effectively Drives Power MOSFETs and Bipolar Transistors This is a Pb−Free and Halide−Free Device (Top View) VCC 6 VCC Short Circuit Comparator VCC Short Circuit Latch S Q R Fault Output 7 VEE VCC Overcurrent Comparator Overcurrent Latch S Q R Current Sense 1 Input 130 mV 65 mV VCC VEE VCC 2 Kelvin GND 270 mA Fault Blanking/ Desaturation Comparator 6.5 V VEE Fault 8 Blanking/ Desaturation Input VCC Output Stage VCC Input VCC 4 VEE Drive 5 Output Under Voltage Lockout 100 k VEE 12 V/ 11 V 3 VEE This device contains 133 active transistors. Figure 1. Representative Block Diagram 1 XD33153 DIP-8 XL33153 SOP-8 MAXIMUM RATINGS Rating Symbol Value Unit VCC − VEE KGND − VEE 20 V Vin VEE −0.3 to VCC V Current Sense Input VS −0.3 to VCC V Blanking/Desaturation Input VBD −0.3 to VCC V Power Supply Voltage VCC to VEE Kelvin Ground to VEE (Note 1) Logic Input Gate Drive Output Source Current Sink Current Diode Clamp Current IO Fault Output Source Current Sink Current IFO Power Dissipation and Thermal Characteristics D Suffix SO−8 Package, Case 751 Maximum Power Dissipation @ TA = 50°C Thermal Resistance, Junction−to−Air P Suffix DIP−8 Package, Case 626 Maximum Power Dissipation @ TA = 50°C Thermal Resistance, Junction−to−Air A 1.0 2.0 1.0 mA 25 10 PD RqJA 0.56 180 W °C/W PD RqJA 1.0 100 W °C/W Operating Junction Temperature TJ +150 °C Operating Ambient Temperature TA −40 to +105 °C Tstg −65 to +150 °C Storage Temperature Range Electrostatic Discharge Sensitivity (ESD) (Note 2) Human Body Model (HBM) Machine Model (MM) Charged Device Model (CDM) ESD V 2500 250 1500 NOTE: ESD data available upon request. Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability. 1. Kelvin Ground must always be between VEE and VCC. 2. ESD protection per JEDEC Standard JESD22−A114−F for HBM per JEDEC Standard JESD22−A115−A for MM per JEDEC Standard JESD22−C101D for CDM. ELECTRICAL CHARACTERISTICS (VCC = 15 V, VEE = 0 V, Kelvin GND connected to VEE. For typical values TA = 25°C, for min/max values TA is the operating ambient temperature range that applies (Note 3), unless otherwise noted.) Characteristic Symbol Min Typ Max Input Threshold Voltage High State (Logic 1) Low State (Logic 0) VIH VIL − 1.2 2.70 2.30 3.2 − Input Current High State (VIH = 3.0 V) Low State (VIL = 1.2 V) IIH IIL − − 130 50 500 100 Output Voltage Low State (ISink = 1.0 A) High State (ISource = 500 mA) VOL VOH − 12 2.0 13.9 2.5 − Output Pull−Down Resistor RPD − 100 200 VFL VFH − 12 0.2 13.3 1.0 − Unit LOGIC INPUT V mA DRIVE OUTPUT V kW FAULT OUTPUT Output Voltage Low State (ISink = 5.0 mA) High State (ISource = 20 mA) 3. Low duty cycle pulse techniques are used during test to maintain the junction temperature as close to ambient as possible. Tlow = −40°C for XDXL33153 Thigh = +105°C for XDXL33153 2 V XD33153 DIP-8 XL33153 SOP-8 ELECTRICAL CHARACTERISTICS (continued) (VCC = 15 V, VEE = 0 V, Kelvin GND connected to VEE. For typical values TA = 25°C, for min/max values TA is the operating ambient temperature range that applies (Note 4), unless otherwise noted.) Symbol Min Typ Max tPLH(in/out) tPHL (in/out) − − 80 120 300 300 Drive Output Rise Time (10% to 90%) CL = 1.0 nF tr − 17 55 ns Drive Output Fall Time (90% to 10%) CL = 1.0 nF tf − 17 55 ns tP(OC) tP(FLT) − 0.3 1.0 ms Startup Voltage VCC start 11.3 12 12.6 V Disable Voltage VCC dis 10.4 11 11.7 V Overcurrent Threshold Voltage (VPin8 > 7.0 V) VSOC 50 65 80 mV Short Circuit Threshold Voltage (VPin8 > 7.0 V) VSSC 100 130 160 mV Vth(FLT) 6.0 6.5 7.0 V ISI − −1.4 −10 mA Ichg −200 −270 −300 mA Idschg 1.0 2.5 − mA − − 7.2 7.9 14 20 Characteristic Unit SWITCHING CHARACTERISTICS Propagation Delay (50% Input to 50% Output CL = 1.0 nF) Logic Input to Drive Output Rise Logic Input to Drive Output Fall Propagation Delay Current Sense Input to Drive Output Fault Blanking/Desaturation Input to Drive Output ns UVLO COMPARATORS Fault Blanking/Desaturation Threshold (VPin1 > 100 mV) Current Sense Input Current (VSI = 0 V) FAULT BLANKING/DESATURATION INPUT Current Source (VPin8 = 0 V, VPin4 = 0 V) Discharge Current (VPin8 = 15 V, VPin4 = 5.0 V) TOTAL DEVICE Power Supply Current Standby (VPin 4 = VCC, Output Open) Operating (CL = 1.0 nF, f = 20 kHz) ICC mA 4. Low duty cycle pulse techniques are used during test to maintain the junction temperature as close to ambient as possible. Tlow = −40°C for XDXL33153 Thigh = +105°C for XDXL33153 1.5 16 VCC = 15 V TA = 25°C VO , OUTPUT VOLTAGE (V) I in , INPUT CURRENT (mA) 14 1.0 0.5 VCC = 15 V TA = 25°C 0 0 2.0 4.0 6.0 8.0 10 12 14 12 10 8.0 6.0 4.0 2.0 0 16 0 1.0 2.0 3.0 4.0 Vin, INPUT VOLTAGE (V) Vin, INPUT VOLTAGE (V) Figure 2. Input Current versus Input Voltage Figure 3. Output Voltage versus Input Voltage 3 5.0 VCC = 15 V 3.0 VIH 2.8 2.6 2.4 VIL 2.2 2.0 -60 -40 -20 0 20 40 60 80 100 120 140 2.6 2.5 2.4 VIL 2.3 2.2 12 13 14 15 16 17 18 19 Figure 4. Input Threshold Voltage versus Temperature Figure 5. Input Threshold Voltage versus Supply Voltage V OL, OUTPUT LOW STATE VOLTAGE (V) ISink = 1.0 A = 500 mA 1.5 = 250 mA 1.0 0.5 VCC = 15 V -20 0 20 40 60 80 100 120 1.6 1.2 0.8 0.4 TA = 25°C VCC = 15 V 0 0.2 0.4 0.6 0.8 TA, AMBIENT TEMPERATURE (°C) ISink, OUTPUT SINK CURRENT (A) Figure 6. Drive Output Low State Voltage versus Temperature Figure 7. Drive Output Low State Voltage versus Sink Current 13.9 13.8 13.7 VCC = 15 V ISource = 500 mA 13.6 -40 -20 0 20 40 60 80 100 120 140 1.0 15.0 VCC = 15 V TA = 25°C 14.6 14.2 13.8 13.4 13.0 0 0.1 0.2 0.3 0.4 TA, AMBIENT TEMPERATURE (°C) ISource, OUTPUT SOURCE CURRENT (A) Figure 8. Drive Output High State Voltage versus Temperature Figure 9. Drive Output High State Voltage versus Source Current 4 20 2.0 0 140 14.0 13.5 -60 TA = 25°C VIH 2.7 VCC, SUPPLY VOLTAGE (V) 2.0 -40 2.8 TA, AMBIENT TEMPERATURE (°C) 2.5 0 -60 VOH , DRIVE OUTPUT HIGH STATE VOLTAGE (V) V IH - V IL , INPUT THRESHOLD VOLTAGE (V) 3.2 VOH , DRIVE OUTPUT HIGH STATE VOLTAGE (V) V OL, OUTPUT LOW STATE VOLTAGE (V) V IH - V IL , INPUT THRESHOLD VOLTAGE (V) XD33153 DIP-8 XL33153 SOP-8 0.5 XD33153 DIP-8 XL33153 SOP-8 12 10 8.0 6.0 4.0 2.0 55 60 65 70 75 10 8.0 6.0 4.0 2.0 110 120 130 140 150 VPin 1, CURRENT SENSE INPUT VOLTAGE (mV) VPin 1, CURRENT SENSE INPUT VOLTAGE (mV) Figure 10. Drive Output Voltage versus Current Sense Input Voltage Figure 11. Fault Output Voltage versus Current Sense Input Voltage 70 VCC = 15 V 68 66 64 62 60 -60 -40 -20 0 20 40 60 80 100 120 140 TA = 25°C 68 66 64 62 60 12 14 16 18 VCC, SUPPLY VOLTAGE (V) Figure 12. Overcurrent Protection Threshold Voltage versus Temperature Figure 13. Overcurrent Protection Threshold Voltage versus Supply Voltage VCC = 15 V 130 -40 -20 0 20 40 60 80 100 120 140 160 70 TA, AMBIENT TEMPERATURE (°C) 135 125 -60 VCC = 15 V VPin 4 = 0 V VPin 8 > 7.0 V TA = 25°C 12 0 100 80 V SOC , OVERCURRENT THRESHOLD VOLTAGE (mV) V SOC , OVERCURRENT THRESHOLD VOLTAGE (mV) 0 50 VSSC, SHORT CIRCUIT THRESHOLD VOLTAGE (mV) V Pin 7, FAULT OUTPUT VOLTAGE (V) 14 VCC = 15 V VPin 4 = 0 V VPin 8 > 7.0 V TA = 25°C 14 VSSC, SHORT CIRCUIT THRESHOLD VOLTAGE (mV) VO , DRIVE OUTPUT VOLTAGE (V) 16 20 135 TA = 25°C 130 125 12 14 16 18 20 TA, AMBIENT TEMPERATURE (°C) VCC, SUPPLY VOLTAGE (V) Figure 14. Short Circuit Comparator Threshold Voltage versus Temperature Figure 15. Short Circuit Comparator Threshold Voltage versus Supply Voltage 5 16 VO , DRIVE OUTPUT VOLTAGE (V) 0 VCC = 15 V TA = 25°C -0.5 -1.0 -1.5 0 2.0 4.0 6.0 8.0 10 12 14 VCC = 15 V VPin 4 = 0 V VPin 1 > 100 mV TA = 25°C 12 10 8.0 6.0 4.0 2.0 6.4 6.6 6.8 VPin 8, FAULT BLANKING/DESATURATION INPUT VOLTAGE (V) Figure 16. Current Sense Input Current versus Voltage Figure 17. Drive Output Voltage versus Fault Blanking/Desaturation Input Voltage VCC = 15 V VPin 4 = 0 V VPin 1 > 100 mV 6.5 -40 -20 0 20 40 60 80 100 120 140 7.0 6.6 VPin 4 = 0 V VPin 1 > 100 mV TA = 25°C 6.5 6.4 12 TA, AMBIENT TEMPERATURE (°C) 14 16 18 20 VCC, SUPPLY VOLTAGE (V) Figure 18. Fault Blanking/Desaturation Comparator Threshold Voltage versus Temperature Figure 19. Fault Blanking/Desaturation Comparator Threshold Voltage versus Supply Voltage -200 -200 VCC = 15 V VPin 8 = 0 V -220 Ichg, CURRENT SOURCE ( μ A) Ichg, CURRENT SOURCE ( μ A) 6.2 VPin 1, CURRENT SENSE INPUT VOLTAGE (V) 6.6 6.4 -60 14 0 6.0 16 V BDT , FAULT BLANKING/DESATURATION THRESHOLD VOLTAGE (V) V BDT , FAULT BLANKING/DESATURATION THRESHOLD VOLTAGE (V) ISI , CURRENT SENSE INPUT CURRENT (μ A) XD33153 DIP-8 XL33153 SOP-8 -240 -260 -280 -300 -60 -40 -20 0 20 40 60 80 100 120 140 VPin 4 = 0 V VPin 8 = 0 V TA = 25°C -220 -240 -260 -280 -300 5.0 10 15 20 TA, AMBIENT TEMPERATURE (°C) VCC, SUPPLY VOLTAGE (V) Figure 20. Fault Blanking/Desaturation Current Source versus Temperature Figure 21. Fault Blanking/Desaturation Current Source versus Supply Voltage 6 XD33153 DIP-8 XL33153 SOP-8 2.5 I dscg, DISCHARGE CURRENT (mA) I chg, CURRENT SOURCE ( μ A) -200 VCC = 15 V VPin 4 = 0 V TA = 25°C -220 -240 -260 -280 -300 0 2.0 4.0 6.0 8.0 10 12 14 0.5 VCC = 15 V VPin 4 = 5.0 V TA = 25°C 0 0 4.0 8.0 12 16 VPin 8, FAULT BLANKING/DESATURATION INPUT VOLTAGE (V) Figure 22. Fault Blanking/Desaturation Current Source versus Input Voltage Figure 23. Fault Blanking/Desaturation Discharge Current versus Input Voltage 14.0 VPin 7 , FAULT OUTPUT VOLTAGE (V) VPin 7 , FAULT OUTPUT VOLTAGE (V) 1.0 VPin 8, FAULT BLANKING/DESATURATION INPUT VOLTAGE (V) VCC = 15 V VPin 4 = 5.0 V TA = 25°C 0.8 0.6 0.4 0.2 0 2.0 4.0 6.0 8.0 VCC = 15 V VPin 4 = 0 V VPin 1 = 1.0 V Pin 8 = Open TA = 25°C 13.8 13.6 13.4 13.2 13.0 10 0 2.0 4.0 10 12 14 16 18 Figure 24. Fault Output Low State Voltage versus Sink Current Figure 25. Fault Output High State Voltage versus Source Current 20 12.5 Vth(UVLO), UNDERVOLTAGE LOCKOUT THRESHOLD (V) 12 10 Turn-Off Threshold 6.0 4.0 Startup Threshold 2.0 0 10 8.0 ISource, OUTPUT SOURCE CURRENT (mA) Startup Threshold VCC Increasing 14 8.0 6.0 ISink, OUTPUT SINK CURRENT (mA) 16 VO , DRIVE OUTPUT VOLTAGE (V) 1.5 -0.5 16 1.0 0 2.0 11 12 13 VPin 4 = 0 V TA = 25°C 14 12.0 11.5 11.0 10.5 -60 15 Turn-Off Threshold VCC Decreasing -40 -20 0 20 40 60 80 100 VCC, SUPPLY VOLTAGE (V) TA, AMBIENT TEMPERATURE (°C) Figure 26. Drive Output Voltage versus Supply Voltage Figure 27. UVLO Thresholds versus Temperature 7 120 140 XD33153 DIP-8 XL33153 SOP-8 10 Output High 8.0 ICC, SUPPLY CURRENT (mA) ICC, SUPPLY CURRENT (mA) 10 Output Low 6.0 4.0 TA = 25°C 2.0 0 5.0 10 15 8.0 6.0 4.0 VCC = 15 V VPin 4 = VCC Drive Output Open 2.0 0 -60 20 -40 -20 0 20 40 60 80 100 120 140 VCC, SUPPLY VOLTAGE (V) TA, AMBIENT TEMPERATURE (°C) Figure 28. Supply Current versus Supply Voltage Figure 29. Supply Current versus Temperature ICC, SUPPLY CURRENT (mA) 80 CL = 10 nF VCC = 15 V TA = 25°C = 5.0 nF 60 40 = 2.0 nF 20 = 1.0 nF 0 1.0 10 100 1000 f, INPUT FREQUENCY (kHz) Figure 30. Supply Current versus Input Frequency OPERATING DESCRIPTION GATE DRIVE Controlling Switching Times The most important design aspect of an IGBT gate drive is optimization of the switching characteristics. The switching characteristics are especially important in motor control applications in which PWM transistors are used in a bridge configuration. In these applications, the gate drive circuit components should be selected to optimize turn−on, turn−off and off−state impedance. A single resistor may be used to control both turn−on and turn−off as shown in Figure 31. However, the resistor value selected must be a compromise in turn−on abruptness and turn−off losses. Using a single resistor is normally suitable only for very low frequency PWM. An optimized gate drive output stage is shown in Figure 32. This circuit allows turn−on and turn−off to be optimized separately. The turn−on resistor, Ron, provides control over the IGBT turn−on speed. In motor control circuits, the resistor sets the turn−on di/dt that controls how fast the free−wheel diode is cleared. The interaction of the IGBT and free−wheeling diode determines the turn−on dv/dt. Excessive turn−on dv/dt is a common problem in half−bridge circuits. The turn−off resistor, Roff, controls the turn−off speed and ensures that the IGBT remains off under commutation stresses. Turn−off is critical to obtain low switching losses. While IGBTs exhibit a fixed minimum loss due to minority carrier recombination, a slow gate drive will dominate the turn−off losses. This is particularly true for fast IGBTs. It is also possible to turn−off an IGBT too fast. Excessive turn−off speed will result in large overshoot voltages. Normally, the turn−off resistor is a small fraction of the turn−on resistor. The XDXL33153 contains a bipolar totem pole output stage that is capable of sourcing 1.0 amp and sinking 2.0 amps peak. This output also contains a pull down resistor to ensure that the IGBT is off whenever there is insufficient VCC to the XDXL33153. In a PWM inverter, IGBTs are used in a half−bridge configuration. Thus, at least one device is always off. While 8 XD33153 DIP-8 XL33153 SOP-8 the IGBT is in the off−state, it will be subjected to changes in voltage caused by the other devices. This is particularly a problem when the opposite transistor turns on. When the lower device is turned on, clearing the upper diode, the turn−on dv/dt of the lower device appears across the collector emitter of the upper device. To eliminate shoot−through currents, it is necessary to provide a low sink impedance to the device that is in the off−state. In most applications the turn−off resistor can be made small enough to hold off the device that is under commutation without causing excessively fast turn−off speeds. VCC that the opto’s dv/dt capability is not exceeded. Like most optoisolators, the HCPL4053 has an active low open−collector output. Thus, when the LED is on, the output will be low. The XDXL33153 has an inverting input pin to interface directly with an optoisolator using a pullup resistor. The input may also be interfaced directly to 5.0 V CMOS logic or a microcontroller. Optoisolator Output Fault The XDXL33153 has an active high fault output. The fault output may be easily interfaced to an optoisolator. While it is important that all faults are properly reported, it is equally important that no false signals are propagated. Again, a high dv/dt optoisolator should be used. The LED drive provides a resistor programmable current of 10 to 20 mA when on, and provides a low impedance path when off. An active high output, resistor, and small signal diode provide an excellent LED driver. This circuit is shown in Figure 33. IGBT Output Rg 5 VEE VEE 3 Short Circuit Latch Output VEE VCC Figure 31. Using a Single Gate Resistor Q 7 VCC IGBT Ron Output 5 Doff VEE Roff Figure 33. Output Fault Optoisolator VEE VEE VEE UNDERVOLTAGE LOCKOUT 3 VEE Figure 32. Using Separate Resistors for Turn−On and Turn−Off A negative bias voltage can be used to drive the IGBT into the off−state. This is a practice carried over from bipolar Darlington drives and is generally not required for IGBTs. However, a negative bias will reduce the possibility of shoot−through. The XDXL33153 has separate pins for VEE and Kelvin Ground. This permits operation using a +15/−5.0 V supply. It is desirable to protect an IGBT from insufficient gate voltage. IGBTs require 15 V on the gate to achieve the rated on−voltage. At gate voltages below 13 V, the on−voltage increases dramatically, especially at higher currents. At very low gate voltages, below 10 V, the IGBT may operate in the linear region and quickly overheat. Many PWM motor drives use a bootstrap supply for the upper gate drive. The UVLO provides protection for the IGBT in case the bootstrap capacitor discharges. The XDXL33153 will typically start up at about 12 V. The UVLO circuit has about 1.0 V of hysteresis and will disable the output if the supply voltage falls below about 11 V. PROTECTION CIRCUITRY INTERFACING WITH OPTOISOLATORS Desaturation Protection Isolated Input Bipolar Power circuits have commonly used what is known as “Desaturation Detection”. This involves monitoring the collector voltage and turning off the device if this voltage rises above a certain limit. A bipolar transistor will only conduct a certain amount of current for a given base drive. When the base is overdriven, the device is in The XDXL33153 may be used with an optically isolated input. The optoisolator can be used to provide level shifting, and if desired, isolation from ac line voltages. An optoisolator with a very high dv/dt capability should be used, such as the Hewlett Packard HCPL4053. The IGBT gate turn−on resistor should be set large enough to ensure 9 XD33153 DIP-8 XL33153 SOP-8 saturation. When the collector current rises above the knee, the device pulls out of saturation. The maximum current the device will conduct in the linear region is a function of the base current and the dc current gain (hFE) of the transistor. The output characteristics of an IGBT are similar to a Bipolar device. However, the output current is a function of gate voltage instead of current. The maximum current depends on the gate voltage and the device type. IGBTs tend to have a very high transconductance and a much higher current density under a short circuit than a bipolar device. Motor control IGBTs are designed for a lower current density under shorted conditions and a longer short circuit survival time. The best method for detecting desaturation is the use of a high voltage clamp diode and a comparator. The XDXL33153 has a Fault Blanking/Desaturation Comparator whichsenses the collector voltage and provides an outputindicating when the device is not fully saturated. Diode D1is an external high voltage diode with a rated voltagecomparable to the power device. When the IGBT is “on” andsaturated, D1 will pull down the voltage on the FaultBlanking/Desaturation Input. When the IGBT pulls out of saturation or is “off”, the current source will pull up the inputand trip the comparator. The comparator threshold is 6.5 V,allowing a maximum on−voltage of about 5.8 V. A fault exists when the gate input is high and VCE is greater than the maximum allowable VCE(sat). The output of the Desaturation Comparator is ANDed with the gate input signal and fed into the Short Circuit and Overcurrent Latches. The Overcurrent Latch will turn−off the IGBT for the remainder of the cycle when a fault is detected. When input goes high, both latches are reset. The reference voltage is tied to the Kelvin Ground instead of the VEE to make the threshold independent of negative gate bias. Note that for proper operation of the Desaturation Comparator and the Fault Output, the Current Sense Input must be biased above the Overcurrent and Short Circuit Comparator thresholds. This can be accomplished by connecting Pin 1 to VCC. Desaturation Comparator VCC been cleared, the voltage will come down quickly to the VCE(sat) of the device. Following turn−on, there is normally considerable ringing on the collector due to the COSS capacitance of the IGBTs and the parasitic wiring inductance. The fault signal from the Desaturation Comparator must be blanked sufficiently to allow the diode to be cleared and the ringing to settle out. The blanking function uses an NPN transistor to clamp the comparator input when the gate input is low. When the input is switched high, the clamp transistor will turn “off”, allowing the internal current source to charge the blanking capacitor. The time required for the blanking capacitor to charge up from the on−voltage of the internal NPN transistor to the trip voltage of the comparator is the blanking time. If a short circuit occurs after the IGBT is turned on and saturated, the delay time will be the time required for the current source to charge up the blanking capacitor from the VCE(sat) level of the IGBT to the trip voltage of the comparator. Fault blanking can be disabled by leaving Pin 8 unconnected. Sense IGBT Protection Another approach to protecting the IGBTs is to sense the emitter current using a current shunt or Sense IGBTs. This method has the advantage of being able to use high gain IGBTs which do not have any inherent short circuit capability. Current sense IGBTs work as well as current sense MOSFETs in most circumstances. However, the basic problem of working with very low sense voltages still exists. Sense IGBTs sense current through the channel and are therefore linear with respect to the collector current. Because IGBTs have a very low incremental on−resistance, sense IGBTs behave much like low−on resistance current sense MOSFETs. The output voltage of a properly terminated sense IGBT is very low, normally less than 100 mV. The sense IGBT approach requires fault blanking to prevent false tripping during turn−on. The sense IGBT also requires that the sense signal is ignored while the gate is low. This is because the mirror output normally produces large transient voltages during both turn−on and turn−off due to the collector to mirror capacitance. With non−sensing types of IGBTs, a low resistance current shunt (5.0 to 50 mW) can be used to sense the emitter current. When the output is an actual short circuit, the inductance will be very low. Since the blanking circuit provides a fixed minimum on−time, the peak current under a short circuit can be very high. A short circuit discern function is implemented by the second comparator which has a higher trip voltage. The short circuit signal is latched and appears at the Fault Output. When a short circuit is detected, the IGBT should be turned−off for several milliseconds allowing it to cool down before it is turned back on. The sense circuit is very similar to the desaturation circuit. It is possible to build a combination circuit that provides protection for both Short Circuit capable IGBTs and Sense IGBTs. VCC 270 mA D1 8 Kelvin GND Vref 6.5 V VEE Figure 34. Desaturation Detection The XDXL33153 also features a programmable faultblanking time. During turn−on, the IGBT must clear theopposing free−wheeling diode. The collector voltage willremain high until the diode is cleared. Once the diode has 10 XD33153 DIP-8 XL33153 SOP-8 APPLICATION INFORMATION Figure 35 shows a basic IGBT driver application. When driven from an optoisolator, an input pull up resistor is required. This resistor value should be set to bias the output transistor at the desired current. A decoupling capacitor should be placed close to the IC to minimize switching noise. A bootstrap diode may be used for a floating supply. If the protection features are not required, then both the Fault Blanking/Desaturation and Current Sense Inputs should both be connected to the Kelvin Ground (Pin 2). When used with a single supply, the Kelvin Ground and VEE pins should be connected together. Separate gate resistors are recommended to optimize the turn−on and turn−off drive. blanking capacitor should be connected from the Desaturation pin to the VEE pin. If a dual supply is used, the blanking capacitor should be connected to the Kelvin Ground. The Current Sense Input should be tied high because the two comparator outputs are ANDed together. Although the reverse voltage on collector of the IGBT is clamped to the emitter by the free−wheeling diode, there is normally considerable inductance within the package itself. A small resistor in series with the diode can be used to protect the IC from reverse voltage transients. 18 V 18 V Bootstrap 6 VCC 7 B+ 7 Output Input VEE GND Sense 4 XDXL33153 Sense Desat/ 8 Blank XDXL33153 Desat/ 8 Blank 5 Output Fault 4 Fault 6 VCC Input 1 VEE GND CBlank 5 1 2 3 2 3 Figure 37. Desaturation Application Figure 35. Basic Application When using sense IGBTs or a sense resistor, the sense voltage is applied to the Current Sense Input. The sense trip voltages are referenced to the Kelvin Ground pin. The sense voltage is very small, typically about 65 mV, and sensitive to noise. Therefore, the sense and ground return conductors should be routed as a differential pair. An RC filter is useful in filtering any high frequency noise. A blanking capacitor is connected from the blanking pin to VEE. The stray capacitance on the blanking pin provides a very small level of blanking if left open. The blanking pin should not be grounded when using current sensing, that would disable the sense. The blanking pin should never be tied high, that would short out the clamp transistor. 15 V 6 VCC 7 Fault Desat/ 8 Blank 5 Output XDXL33153 4 Sense Input VEE GND 1 2 3 18 V -5.0 V 7 Figure 36. Dual Supply Application Fault 6 VCC Desat/ 8 Blank 5 Output XDXL33153 When used in a dual supply application as in Figure 36, the Kelvin Ground should be connected to the emitter of the IGBT. If the protection features are not used, then both the Fault Blanking/Desaturation and the Current Sense Inputs should be connected to Ground. The input optoisolator should always be referenced to VEE. If desaturation protection is desired, a high voltage diode is connected to the Fault Blanking/Desaturation pin. The Sense 4 Input VEE GND 1 2 3 Figure 38. Sense IGBT Application 11 XD33153 DIP-8 XL33153 SOP-8 PACKAGE DIMENSIONS DIP−8 D A E H 8 5 1 4 E1 NOTE 8 b2 c B END VIEW TOP VIEW WITH LEADS CONSTRAINED NOTE 5 A2 A e/2 NOTE 3 L SEATING PLANE A1 C D1 M e 8X SIDE VIEW b 0.010 eB END VIEW M C A M B M NOTE 6 12 NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: INCHES. 3. DIMENSIONS A, A1 AND L ARE MEASURED WITH THE PACKAGE SEATED IN JEDEC SEATING PLANE GAUGE GS−3. 4. DIMENSIONS D, D1 AND E1 DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS. MOLD FLASH OR PROTRUSIONS ARE NOT TO EXCEED 0.10 INCH. 5. DIMENSION E IS MEASURED AT A POINT 0.015 BELOW DATUM PLANE H WITH THE LEADS CONSTRAINED PERPENDICULAR TO DATUM C. 6. DIMENSION E3 IS MEASURED AT THE LEAD TIPS WITH THE LEADS UNCONSTRAINED. 7. DATUM PLANE H IS COINCIDENT WITH THE BOTTOM OF THE LEADS, WHERE THE LEADS EXIT THE BODY. 8. PACKAGE CONTOUR IS OPTIONAL (ROUNDED OR SQUARE CORNERS). DIM A A1 A2 b b2 C D D1 E E1 e eB L M INCHES MIN MAX −−−− 0.210 0.015 −−−− 0.115 0.195 0.014 0.022 0.060 TYP 0.008 0.014 0.355 0.400 0.005 −−−− 0.300 0.325 0.240 0.280 0.100 BSC −−−− 0.430 0.115 0.150 −−−− 10 ° MILLIMETERS MIN MAX −−− 5.33 0.38 −−− 2.92 4.95 0.35 0.56 1.52 TYP 0.20 0.36 9.02 10.16 0.13 −−− 7.62 8.26 6.10 7.11 2.54 BSC −−− 10.92 2.92 3.81 −−− 10 ° XD33153 DIP-8 XL33153 SOP-8 PACKAGE DIMENSIONS SOP−8 −X− NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: MILLIMETER. 3. DIMENSION A AND B DO NOT INCLUDE MOLD PROTRUSION. 4. MAXIMUM MOLD PROTRUSION 0.15 (0.006) PER SIDE. 5. DIMENSION D DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.127 (0.005) TOTAL IN EXCESS OF THE D DIMENSION AT MAXIMUM MATERIAL CONDITION. 6. 751−01 THRU 751−06 ARE OBSOLETE. NEW STANDARD IS 751−07. A 8 5 S B 0.25 (0.010) M Y M 1 4 −Y− K G C N X 45 _ SEATING PLANE −Z− 0.10 (0.004) H D 0.25 (0.010) M Z Y S X M J S 13 DIM A B C D G H J K M N S MILLIMETERS MIN MAX 4.80 5.00 3.80 4.00 1.35 1.75 0.33 0.51 1.27 BSC 0.10 0.25 0.19 0.25 0.40 1.27 0_ 8_ 0.25 0.50 5.80 6.20 INCHES MIN MAX 0.189 0.197 0.150 0.157 0.053 0.069 0.013 0.020 0.050 BSC 0.004 0.010 0.007 0.010 0.016 0.050 0 _ 8 _ 0.010 0.020 0.228 0.244