IXDD414PI / 414YI / 414CI / 414SI 14 Amp Low-Side Ultrafast MOSFET Driver Features General Description • Built using the advantages and compatibility of CMOS and IXYS HDMOSTM processes. • Latch-Up Protected • High Peak Output Current: 14A Peak • Wide Operating Range: 4.5V to 35V • -55 oC to 125 oC Extended Operating Temperature Standard • Ability to Disable Output under Faults • High Capacitive Load Drive Capability: 15nF in <30ns • Matched Rise And Fall Times • Low Propagation Delay Time • Low Output Impedance • Low Supply Current The IXDD414 is a high speed high current gate driver specifically designed to drive the largest MOSFETs and IGBTs to their minimum switching time and maximum practical frequency limits. The IXDD414 can source and sink 14A of peak current while producing voltage rise and fall times of less than 30ns. The input of the driver is compatible with TTL or CMOS and is fully immune to latch up over the entire operating range. Designed with small internal delays, cross conduction/current shootthrough is virtually eliminated in the IXDD414. Its features and wide safety margin in operating voltage and power make the IXDD414 unmatched in performance and value. The IXDD414 incorporates a unique ability to disable the output under fault conditions. When a logical low is forced into the Enable input, both final output stage MOSFETs (NMOS and PMOS) are turned off. As a result, the output of the IXDD414 enters a tristate mode and achieves a Soft Turn-Off of the MOSFET/IGBT when a short circuit is detected. This helps prevent damage that could occur to the MOSFET/IGBT if it were to be switched off abruptly due to a dv/dt over-voltage transient. Applications • • • • • • • • • • Driving MOSFETs and IGBTs Limiting di/dt under Short Circuit Motor Controls Line Drivers Pulse Generators Local Power ON/OFF Switch Switch Mode Power Supplies (SMPS) DC to DC Converters Pulse Transformer Driver Class D Switching Amplifiers The IXDD414 is available in the standard 8-pin P-DIP (PI), 14-pin SOIC (SI), 5-pin TO-220 (CI) and in the TO-263 (YI) surface-mount package. Figure 1 - Functional Diagram 200 k Copyright © IXYS CORPORATION 2004 Patent Pending DS99061E(8/10) First Release IXDD414PI/414YI/414CI/414SI Absolute Maximum Ratings (Note 1) Operating Ratings Parameter Value Supply Voltage 40 V All Other Pins (unless -0.3 V to VCC + 0.3 V specified otherwise) Power Dissipation, TAMBIENT = 25 oC 8 Pin PDIP (PI) 833 mW 14-Pin SOIC (SI) 1000 mW TO-220 (CI), TO-263 (YI) 12.5 W Storage Temperature -55 oC to 150 oC Lead Temperature (10 s) 300 oC Parameter Value Maximum Junction Temperature 150 oC Operating Temperature Range -55 oC to 125 oC Thermal Resistance (Junction-to- Case) TO-220, TO-263 (YI) 10 K/W 14-Pin SOIC (SI) 10 K/W Thermal Resistance (Junction to Ambient) 8-Pin PDIP (PI) 150 K/W 14-Pin SOIC TO-220 (CI), TO-263 (YI) 120 K/W 62.5 K/W Electrical Characteristics Unless otherwise noted, TA = 25 oC, 4.5V ≤ VCC ≤ 35V . All voltage measurements with respect to GND. IXDD414 configured as described in Test Conditions. Symbol Parameter Test Conditions Min VIH, VENH High input & EN voltage 4.5V ≤ VCC ≤ 18V 3.5 VIL, VENL Low input & EN voltage 4.5V ≤ VCC ≤ 18V VIN Input voltage range VEN Enable voltage range IIN Input current VOH High output voltage VOL Low output voltage ROH Output resistance @ Output high Output resistance @ Output Low Peak output current IOUT = 10mA, VCC = 18V tR Continuous output current Rise time 8 Pin Dip (PI) (Limited by pkg power dissipation) TO220 (CI), TO263 (YI) CL=15nF Vcc=18V 23 tF Fall time CL=15nF Vcc=18V tONDLY VCC On-time propagation delay Off-time propagation delay Enable to output high delay time Disable to output low disable delay time Power supply voltage ICC Power supply current REN Enable Pull-up Resistor ROL IPEAK IDC tOFFDLY tENOH tDOLD 0V ≤ VIN ≤ VCC Typ Max Units V 0.8 V -5 VCC + 0.3 V - 0.3 Vcc + 0.3 V -10 10 µA VCC - 0.025 V 0.025 V 600 1000 mΩ IOUT = 10mA, VCC = 18V 600 1000 mΩ VCC is 18V 14 A 25 3 4 29 A A ns 21 22 26 ns CL=15nF Vcc=18V 29 30 33 ns CL=15nF Vcc=18V 29 31 34 ns Vcc=18V 40 ns Vcc=18V 30 ns 18 35 V 1 0 3 10 10 mA µA µA kΩ 4.5 VIN = 3.5V VIN = 0V VIN = + VCC 200 Specifications Subject To Change Without Notice 2 IXDD414PI/414YI/414CI/414SI Pin Configurations GND GND I X D D 4 1 4 P I 1 VCC 2 IN 3 EN 4 GND 8-Pin DIP (PI) GND GND VCC 8 OUT 7 1 2 OUT 6 3 4 GND 5 5 Vcc OUT GND IN EN IXDD414YI IXDD414C I I X D D 4 1 4 S I TO-220 (CI) TO-263 (YI) 14-Pin SOIC (SI) Pin Description SYMBOL FUNCTION VCC Supply Voltage IN Input EN Enable OUT Output GND Ground DESCRIPTION Positive power-supply voltage input. This pin provides power to the 3 is from 4.5V to 25V. entire chip. The range for this voltage Input signal-TTL or CMOS compatible. The system enable pin. This pin, when driven low, disables the chip, forcing high impedance state to the output. Driver Output. For application purposes, this pin is connected, through a resistor, to Gate of a MOSFET/IGBT. The system ground pin. Internally connected to all circuitry, this pin provides ground reference for the entire chip. This pin should be connected to a low noise analog ground plane for optimum performance. Note 1: Operating the device beyond parameters with listed “absolute maximum ratings” may cause permanent damage to the device. Typical values indicate conditions for which the device is intended to be functional, but do not guarantee specific performance limits. The guaranteed specifications apply only for the test conditions listed. Exposure to absolute maximum rated conditions for extended periods may affect device reliability. CAUTION: These devices are sensitive to electrostatic discharge; follow proper ESD procedures when handling and assembling this component. Figure 2 - Characteristics Test Diagram VIN 3 IXDD414PI/414YI/414CI/414SI Typical Performance Characteristics Fig. 3 Rise Time vs. Supply Voltage Fig. 4 30 30 Fall Time vs. Supply Voltage Fall Time (ns) 40 Rise Time (ns) 40 CL=15,000 pF CL=15,000 pF 20 20 7,500 pF 10 3,600 pF 10 7,500 pF 3,600 pF 0 0 8 10 12 14 16 8 18 10 12 Fig. 5 40 14 16 18 Supply Voltage (V) Supply Voltage (V) Rise And Fall Times vs. Case Temperature CL = 15 nF, Vcc = 18V Rise Time vs. Load Capacitance Fig. 6 50 35 8V 40 10V tR 12V Rise Time (ns) Time (ns) 30 25 tF 20 15 30 18V 14V 16V 20 10 10 5 0 -40 -20 0 20 40 60 80 100 0 0k 120 10k 15k 20k Load Capacitance (pF) Temperature (°C) Fig. 7 5k Fig. 8 Fall Time vs. Load Capacitance Max / Min Input vs. Case Temperature VCC=18V CL=15nF 3.2 40 3.0 Fall Time (ns) 30 8V 10V Max / Min Input (V) 14V 12V 16V18V 20 MinimumInput High 2.8 2.6 2.4 2.2 MaximumInput Low 2.0 10 1.8 0 0k 1.6 -60 5k 10k 15k 20k -40 -20 0 20 40 o Temperature ( C) Load Capacitance (pF) 4 60 80 100 IXDD414PI/414YI/414CI/414SI Fig. 9 Supply Current vs. Load Capacitance Vcc=18V Supply Current vs. Frequency Vcc=18V Fig. 10 1000 CL= 30 nF Supply Current (mA) Supply Current (mA) 1000 100 2 MHz 1 MHz 500 kHz 10 100 kHz 15 nF 100 5000 pF 10 2000 pF 1 50 kHz 1 1k 0.1 10k 10 100k Fig. 11 Supply Current vs. Load Capacitance Vcc=12V 1000 10000 Supply Current vs. Frequency Vcc=12V Fig. 12 1000 1000 CL = 30 nF Supply Current (mA) Supply Current (mA) 100 Frequency (kHz) Load Capacitance (pF) 100 2 MHz 1 MHz 500 kHz 10 100 15 nF 5000 pF 10 2000 pF 1 100 kHz 50 kHz 1 1k 0.1 10k 10 100k Fig. 13 Supply Current vs. Load Capacitance Vcc=8V 1000 10000 Supply Current vs. Frequency Vcc=8V Fig. 14 1000 Supply Current (mA) 1000 Supply Current (mA) 100 Frequency (kHz) Load Capacitance (pF) 100 2 MHz 1 MHz 10 500 kHz CL= 30 nF 100 15 nF 10 5000 pF 2000 pF 1 100 kHz 1 50 kHz 1k 0.1 10k 10 100k 100 Frequency (kHz) Load Capacitance (pF) 5 1000 10000 IXDD414PI/414YI/414CI/414SI Fig. 15 50 tOFFDLY 40 Propagation Delay vs. Input Voltage CL=15nF VCC=15V 50 Propagation Delay (ns) Propagation Delay (ns) Fig. 16 Propagation Delay vs. Supply Voltage CL=15nF VIN=5V@1kHz tONDLY 30 20 10 40 tONDLY 30 tOFFDLY 20 10 0 0 8 10 12 14 16 2 18 4 Propagation Delay vs. Case Temperature CL = 2500pF, VCC = 18V Fig. 17 Fig. 18 0.60 Quiescent Supply Current (mA) 50 45 tONDLY Time (ns) 40 35 tOFFDLY 30 25 20 15 8 10 12 Quiescent Supply Current vs. Case Temperature VCC=18V VIN=5V@1kHz 0.58 0.56 0.54 0.52 0.50 10 -40 -20 0 20 40 60 80 100 -40 120 -20 Fig. 19 0 20 40 60 80 Temperature (oC) Temperature (°C) P Channel Output Current vs. Case Temperature VCC=18V CL=.1uF Fig. 20 N Channel Output Current vs. Case Temperature VCC=18V CL=.1uF 16 17 N Channel Output Current (A) P Channel Output Current (A) 6 Input Voltage (V) Supply Voltage (V) 15 14 13 16 15 14 12 -40 -20 0 20 40 60 80 -40 100 -20 0 20 40 Temperature (oC) Temperature (oC) 6 60 80 100 IXDD414PI/414YI/414CI/414SI Fig. 22 14 High State Output Resistance (Ohm) 1.0 12 Enable Threshold (V) High State Output Resistance vs. Supply Voltage Enable Threshold vs. Supply Voltage Fig. 21 10 8 6 4 2 0.8 0.6 0.4 0.2 0.0 0 8 10 12 14 16 18 20 22 24 10 8 26 Supply Voltage (V) Fig. 23 15 20 25 Supply Voltage (V) Low-State Output Resistance vs. Supply Voltage VCC vs. P Channel Output Current CL=.1uF VIN=0-5V@1kHz Fig. 24 1.0 Low-State Output Resistance (Ohms) 0 P Channel Output Current (A) -2 0.8 0.6 -4 -6 -8 -10 -12 -14 0.4 -16 -18 0.2 -20 -22 -24 0.0 8 10 15 20 25 8 Supply Voltage (V) Fig. 25 N Channel Output Current (A) 22 20 18 16 14 12 10 8 6 4 2 0 15 20 Figure 26 - Typical Application Short Circuit di/dt Limit 24 10 15 Vcc Vcc vs. N Channel Output Current CL=.1uF VIN=0-5V@1kHz 8 10 20 25 Vcc 7 25 IXDD414PI/414YI/414CI/414SI APPLICATIONS INFORMATION Short Circuit di/dt Limit ground. (Those glitches might cause false triggering of the comparator). A short circuit in a high-power MOSFET module such as the VM0580-02F, (580A, 200V), as shown in Figure 26, can cause the current through the module to flow in excess of 1500A for 10µs or more prior to self-destruction due to thermal runaway. For this reason, some protection circuitry is needed to turn off the MOSFET module. However, if the module is switched off too fast, there is a danger of voltage transients occuring on the drain due to Ldi/dt, (where L represents total inductance in series with drain). If these voltage transients exceed the MOSFET's voltage rating, this can cause an avalanche breakdown. The comparator's output should be connected to a SRFF(Set Reset Flip Flop). The flip-flop controls both the Enable signal, and the low power MOSFET gate. Please note that CMOS 4000series devices operate with a VCC range from 3 to 15 VDC, (with 18 VDC being the maximum allowable limit). A low power MOSFET, such as the 2N7000, in series with a resistor, will enable the VMO580-02F gate voltage to drop gradually. The resistor should be chosen so that the RC time constant will be 100us, where "C" is the Miller capacitance of the VMO580-02F. The IXDD414 has the unique capability to softly switch off the high-power MOSFET module, significantly reducing these Ldi/dt transients. For resuming normal operation, a Reset signal is needed at the SRFF's input to enable the IXDD414 again. This Reset can be generated by connecting a One Shot circuit between the IXDD414 Input signal and the SRFF restart input. The One Shot will create a pulse on the rise of the IXDD414 input, and this pulse will reset the SRFF outputs to normal operation. Thus, the IXDD414 helps to prevent device destruction from both dangers; over-current, and avalanche breakdown due to di/dt induced over-voltage transients. The IXDD414 is designed to not only provide ±14A under normal conditions, but also to allow it's output to go into a high impedance state. This permits the IXDD414 output to control a separate weak pull-down circuit during detected overcurrent shutdown conditions to limit and separately control dVGS/dt gate turnoff. This circuit is shown in Figure 27. When a short circuit occurs, the voltage drop across the lowvalue, current-sensing resistor, (Rs=0.005 Ohm), connected between the MOSFET Source and ground, increases. This triggers the comparator at a preset level. The SRFF drives a low input into the Enable pin disabling the IXDD408 output. The SRFF also turns on the low power MOSFET, (2N7000). Referring to Figure 27, the protection circuitry should include a comparator, whose positive input is connected to the source of the VM0580-02. A low pass filter should be added to the input of the comparator to eliminate any glitches in voltage caused by the inductance of the wire connecting the source resistor to In this way, the high-power MOSFET module is softly turned off by the IXDD414, preventing its destruction. Figure 27 - Application Test Diagram + Ld 10uH - VB Rd IXDD414 0.1ohm VCC VCCA Rg OUT IN EN + - VCC + - VIN High_Power VMO580-02F 1ohm Rsh 1600ohm GND GND Rs Low_Power 2N7002/PLP Ls R+ 10kohm 20nH One Shot Circuit Rcomp 5kohm NAND CD4011A NOT1 CD4049A NOT2 CD4049A Ccomp 1pF Ros 0 Comp LM339 + V+ V- C+ 100pF + R 1Mohm REF Cos 1pF Q NOT3 CD4049A NOR1 CD4001A EN NOR2 CD4001A SR Flip-Flop 8 S - IXDD414PI/414YI/414CI/414SI Supply Bypassing and Grounding Practices, Output Lead inductance TTL to High Voltage CMOS Level Translation When designing a circuit to drive a high speed MOSFET utilizing the IXDD414, it is very important to keep certain design criteria in mind, in order to optimize performance of the driver. Particular attention needs to be paid to Supply Bypassing, Grounding, and minimizing the Output Lead Inductance. The enable (EN) input to the IXDD414 is a high voltage CMOS logic level input where the EN input threshold is ½ VCC, and may not be compatible with 5V CMOS or TTL input levels. The IXDD414 EN input was intentionally designed for enhanced noise immunity with the high voltage CMOS logic levels. In a typical gate driver application, VCC =15V and the EN input threshold at 7.5V, a 5V CMOS logical high input applied to this typical IXDD414 application’s EN input will be misinterpreted as a logical low, and may cause undesirable or unexpected results. The note below is for optional adaptation of TTL or 5V CMOS levels. Say, for example, we are using the IXDD414 to charge a 5000pF capacitive load from 0 to 25 volts in 25ns. Using the formula: I= ∆V C / ∆t, where ∆V=25V C=5000pF & ∆t=25ns we can determine that to charge 5000pF to 25 volts in 25ns will take a constant current of 5A. (In reality, the charging current won’t be constant, and will peak somewhere around 8A). SUPPLY BYPASSING In order for our design to turn the load on properly, the IXDD414 must be able to draw this 5A of current from the power supply in the 25ns. This means that there must be very low impedance between the driver and the power supply. The most common method of achieving this low impedance is to bypass the power supply at the driver with a capacitance value that is a magnitude larger than the load capacitance. Usually, this would be achieved by placing two different types of bypassing capacitors, with complementary impedance curves, very close to the driver itself. (These capacitors should be carefully selected, low inductance, low resistance, high-pulse currentservice capacitors). Lead lengths may radiate at high frequency due to inductance, so care should be taken to keep the lengths of the leads between these bypass capacitors and the IXDD414 to an absolute minimum. GROUNDING In order for the design to turn the load off properly, the IXDD414 must be able to drain this 5A of current into an adequate grounding system. There are three paths for returning current that need to be considered: Path #1 is between the IXDD414 and it’s load. Path #2 is between the IXDD414 and it’s power supply. Path #3 is between the IXDD414 and whatever logic is driving it. All three of these paths should be as low in resistance and inductance as possible, and thus as short as practical. In addition, every effort should be made to keep these three ground paths distinctly separate. Otherwise, (for instance), the returning ground current from the load may develop a voltage that would have a detrimental effect on the logic line driving the IXDD414. OUTPUT LEAD INDUCTANCE Of equal importance to Supply Bypassing and Grounding are issues related to the Output Lead Inductance. Every effort should be made to keep the leads between the driver and it’s load as short and wide as possible. If the driver must be placed farther than 2” from the load, then the output leads should be treated as transmission lines. In this case, a twisted-pair should be considered, and the return line of each twisted pair should be placed as close as possible to the ground pin of the driver, and connect directly to the ground terminal of the load. The circuit in Figure 28 alleviates this potential logic level misinterpretation by translating a TTL or 5V CMOS logic input to high voltage CMOS logic levels needed by the IXDD414 EN input. From the figure, VCC is the gate driver power supply, typically set between 8V to 20V, and VDD is the logic power supply, typically between 3.3V to 5.5V. Resistors R1 and R2 form a voltage divider network so that the Q1 base is positioned at the midpoint of the expected TTL logic transition levels. A TTL or 5V CMOS logic low, VTTLLOW=~<0.8V, input applied to the Q1 emitter will drive it on. This causes the level translator output, the Q1 collector output to settle to VCESATQ1 + VTTLLOW=<~2V, which is sufficiently low to be correctly interpreted as a high voltage CMOS logic low (<1/3VCC=5V for VCC =15V given in the IXDD414 data sheet.) A TTL high, VTTLHIGH=>~2.4V, or a 5V CMOS high, V5VCMOSHIGH=~>3.5V, applied to the EN input of the circuit in Figure 28 will cause Q1 to be biased off. This results in Q1 collector being pulled up by R3 to VCC=15V, and provides a high voltage CMOS logic high output. The high voltage CMOS logical EN output applied to the IXDD414 EN input will enable it, allowing the gate driver to fully function as an 8 Amp output driver. The total component cost of the circuit in Figure 28 is less than $0.10 if purchased in quantities >1K pieces. It is recommended that the physical placement of the level translator circuit be placed close to the source of the TTL or CMOS logic circuits to maximize noise rejection. Figure 28 - TTL to High Voltage CMOS Level Translator CC (From Gate Driver Power Supply) VDD (From Logic Power Supply) 10K 3.3K R3 High Voltage CMOS EN Output R1 Q1 2N3904 3.3K or TTLInput) 9 R2 (To IXDD414 EN Input) IXDD414PI/414YI/414CI/414SI TO-263 (YI) Outline 8-Pin DIP (PI) Outline 14-Pin SOIC (SI) Outline TO-220 (CI) Outline NOTE: Mounting or solder tabs on all packages are connected to ground Ordering Information Part Number Package Type IXDD414PI 8-Pin PDIP IXDD414YI 5-Pin TO-263 IXDD414CI 5-Pin TO-220 IXDD414SI 14-Pin SOIC IXYS Corporation 3540 Bassett St; Santa Clara, CA 95054 Tel: 408-982-0700; Fax: 408-496-0670 e-mail: [email protected] Temp. Range -55°C to +125°C -55°C to +125°C -55°C to +125°C -55°C to +125°C IXYS Semiconductor GmbH Edisonstrasse15 ; D-68623; Lampertheim Tel: +49-6206-503-0; Fax: +49-6206-503627 e-mail: [email protected] 10