IR2130/IR2132(J)(S) & (PbF)

Transcription

1 Data Sheet No. PD619 Rev.P Features Floating channel designed for bootstrap operation Fully operational to +6V Tolerant to negative transient voltage dv/dt immune Gate drive supply range from 1 to 2V Undervoltage lockout for all channels Over-current shutdown turns off all six drivers Independent half-bridge drivers Matched propagation delay for all channels 2.5V logic compatible Outputs out of phase with inputs Cross-conduction prevention logic Also available LEAD-FREE Description IR213/IR2132(J)(S) & (PbF) 3-PHASE BRIDGE DRIVER V OFFSET I O +/- V OUT t on/off (typ.) Deadtime (typ.) 6V max. 2 ma / 42 ma 1-2V 675 & 425 ns 2.5 µs (IR213).8 µs (IR2132) The IR213/IR2132(J)(S) is a high voltage, high speed power MOSFET and IGBT driver with three independent high and low side referenced output channels. Proprietary HVIC technology enables ruggedized 28-Lead SOIC monolithic construction. Logic inputs are compatible with CMOS or LSTTL outputs, down to 2.5V logic. A 28-Lead PDIP ground-referenced operational amplifier provides analog feedback of bridge current via an external current sense resistor. A current trip function which terminates all six outputs is also derived from this resistor. 44-Lead PLCC w/o 12 Leads An open drain FAULT signal indicates if an over-current or undervoltage shutdown has occurred. The output drivers feature a high pulse current buffer stage designed for minimum driver cross-conduction. Propagation delays are matched to simplify use at high frequencies. The floating channels can be used to drive N-channel power MOSFETs or IGBTs in the high side configuration which operate up to 6 volts. Typical Connection Product Summary Packages (Refer to Lead Assignments for correct pin configuration). This/These diagram(s) show electrical connections only. Please refer to our Application Notes and DesignTips for proper circuit board layout. 1

2 IR213/IR2132(J)(S) & (PbF) Absolute Maximum Ratings Absolute Maximum Ratings indicate sustained limits beyond which damage to the device may occur. All voltage parameters are absolute voltages referenced to V S. The Thermal Resistance and Power Dissipation ratings are measured under board mounted and still air conditions. Additional information is shown in Figures 5 through 53. Symbol Definition Units V B1,2,3 High Side Floating Supply Voltage V S1,2,3 High Side Floating Offset Voltage V B1,2,3-25 V B1,2,3 +.3 V HO1,2,3 High Side Floating Output Voltage V S1,2,3 -.3 V B1,2,3 +.3 V CC Low Side and Logic Fixed Supply Voltage V SS Logic Ground V CC - 25 V CC +.3 V LO1,2,3 Low Side Output Voltage -.3 V CC +.3 V IN Logic Input Voltage (HIN1,2,3, LIN1,2,3 & ITRIP) V SS -.3 (V SS + 15) or (V CC +.3) whichever is lower V V FLT FAULT Output Voltage V SS -.3 V CC +.3 V CAO Operational Amplifier Output Voltage V SS -.3 V CC +.3 V CA- Operational Amplifier Inverting Input Voltage V SS -.3 V CC +.3 dv S /dt Allowable Offset Supply Voltage Transient 5 V/ns P D Package Power TA +25 C (28 Lead DIP) 1.5 (28 Lead SOIC) 1.6 W (44 Lead PLCC) 2. Rth JA Thermal Resistance, Junction to Ambient (28 Lead DIP) 83 (28 Lead SOIC) 78 C/W (44 Lead PLCC) 63 T J Junction Temperature 15 T S Storage Temperature C T L Lead Temperature (Soldering, 1 seconds) 3 Recommended Operating Conditions The Input/Output logic timing diagram is shown in Figure 1. For proper operation the device should be used within the recommended conditions. All voltage parameters are absolute voltages referenced to V S. The V S offset rating is tested with all supplies biased at 15V differential. Typical ratings at other bias conditions are shown in Figure 54. Symbol Definition Units V B1,2,3 High Side Floating Supply Voltage V S1,2,3 + 1 V S1,2,3 + 2 V S1,2,3 High Side Floating Offset Voltage Note 1 6 V HO1,2,3 High Side Floating Output Voltage V S1,2,3 V B1,2,3 V CC Low Side and Logic Fixed Supply Voltage 1 2 V SS Logic Ground -5 5 V LO1,2,3 Low Side Output Voltage V CC V IN Logic Input Voltage (HIN1,2,3, LIN1,2,3 & ITRIP) V SS V SS + 5 V V FLT FAULT Output Voltage V SS V CC V CAO Operational Amplifier Output Voltage V SS V SS + 5 V CA- Operational Amplifier Inverting Input Voltage V SS V SS + 5 T A Ambient Temperature C Note 1: Logic operational for V S of (V S - 5V) to (V S + 6V). Logic state held for V S of (V S - 5V) to (V S - V BS ). (Please refer to the Design Tip DT97-3 for more details). Note 2: All input pins, CA- and CAO pins are internally clamped with a 5.2V zener diode. 2

3 IR213/IR2132(J)(S) & (PbF) Dynamic Electrical Characteristics V BIAS (V CC, V BS1,2,3 ) = 15V, V S,1,2,3 = V SS, C L = pf and T A = 25 C unless otherwise specified. The dynamic electrical characteristics are defined in Figures 3 through 5. Symbol Definition Figure Units Test Conditions t on Turn-On Propagation Delay t off Turn-Off Propagation Delay V IN = & 5V t r Turn-On Rise Time V S1,2,3 = to 6V t f Turn-Off Fall Time t itrip ITRIP to Output Shutdown Prop. Delay V IN, V ITRIP = & 5V t bl ITRIP Blanking Time 4 ns V ITRIP = 1V t flt ITRIP to FAULT Indication Delay V IN, V ITRIP = & 5V t flt,in Input Filter Time (All Six Inputs) 31 V IN = & 5V t fltclr LIN1,2,3 to FAULT Clear Time V IN, V ITRIP = & 5V DT SR+ Deadtime Operational Amplifier Slew Rate (+) (IR213) SR- Operational Amplifier Slew Rate (-) (IR2132) µs V/µs V IN = & 5V NOTE: For high side PWM, HIN pulse width must be 1.5µsec Static Electrical Characteristics V BIAS (V CC, V BS1,2,3 ) = 15V, V S,1,2,3 = V SS and T A = 25 C unless otherwise specified. The V IN, V TH and I IN parameters are referenced to V SS and are applicable to all six logic input leads: HIN1,2,3 & LIN1,2,3. The V O and I O parameters are referenced to V S,1,2,3 and are applicable to the respective output leads: HO1,2,3 or LO1,2,3. Symbol Definition Figure Units Test Conditions V IH Logic Input Voltage (OUT = LO) V IL Logic 1 Input Voltage (OUT = HI) 22.8 V V IT,TH+ ITRIP Input Positive Going Threshold V OH High Level Output Voltage, V BIAS - VO 24 mv V IN = V, I O = A V OL Low Level Output Voltage, VO 25 V IN = 5V, I O = A I LK Offset Supply Leakage Current 26 5 V B = V S = 6V µa I QBS Quiescent V BS Supply Current V IN = V or 5V I QCC Quiescent V CC Supply Current ma V IN = V or 5V I IN+ Logic 1 Input Bias Current (OUT = HI) V IN = V I IN- Logic Input Bias Current (OUT = LO) µa V IN = 5V I ITRIP+ High ITRIP Bias Current ITRIP = 5V I ITRIP- Low ITRIP Bias Current 32 na ITRIP = V V BSUV+ V BS Supply Undervoltage Positive Going Threshold V BSUV- V BS Supply Undervoltage Negative Going Threshold V CCUV+ V CC Supply Undervoltage Positive Going V Threshold V CCUV- V CC Supply Undervoltage Negative Going Threshold R on,flt FAULT Low On-Resistance Ω 3

4 IR213/IR2132(J)(S) & (PbF) Static Electrical Characteristics -- Continued V BIAS (V CC, V BS1,2,3 ) = 15V, V S,1,2,3 = V SS and T A = 25 C unless otherwise specified. The V IN, V TH and I IN parameters are referenced to V SS and are applicable to all six logic input leads: HIN1,2,3 & LIN1,2,3. The V O and I O parameters are referenced to V S,1,2,3 and are applicable to the respective output leads: HO1,2,3 or LO1,2,3. Symbol Definition Figure Units Test Conditions I O+ Output High Short Circuit Pulsed Current V O = V, V IN = V PW 1 µs I O- Output Low Short Circuit Pulsed Current ma V O = 15V, V IN = 5V PW 1 µs V OS Operational Amplifer Input Offset Voltage 4 3 mv V S = V CA- =.2V I CA- CA- Input Bais Current na V CA- = 2.5V CMRR Op. Amp. Common Mode Rejection Ratio V S =V CA- =.1V & 5V PSRR Op. Amp. Power Supply Rejection Ratio db V S = V CA- =.2V V CC = 1V & 2V V OH,AMP Op. Amp. High Level Output Voltage V V CA- = V, V S = 1V V OL,AMP Op. Amp. Low Level Output Voltage 45 2 mv V CA- = 1V, V S = V I SRC,AMP Op. Amp. Output Source Current V CA- = V, V S = 1V V CAO = 4V I SRC,AMP Op. Amp. Output Sink Current ma V CA- = 1V, V S = V V CAO = 2V I O+,AMP Operational Amplifier Output High Short V CA- = V, V S = 5V Circuit Current V CAO = V I O-,AMP Operational Amplifier Output Low Short V CA- = 5V, V S = V Circuit Current V CAO = 5V Lead Assignments 28 Lead PDIP 44 Lead PLCC w/o 12 Leads 28 Lead SOIC (Wide Body) IR213 / IR2132 IR213J / IR2132J IR213S / IR2132S Part Number 4

5 IR213/IR2132(J)(S) & (PbF) Functional Block Diagram Lead Definitions Symbol Description HIN1,2,3 Logic inputs for high side gate driver outputs (HO1,2,3), out of phase LIN1,2,3 Logic inputs for low side gate driver output (LO1,2,3), out of phase FAULT Indicates over-current or undervoltage lockout (low side) has occurred, negative logic V CC Low side and logic fixed supply ITRIP Input for over-current shutdown CAO Output of current amplifier CA- Negative input of current amplifier V SS Logic ground V B1,2,3 High side floating supplies HO1,2,3 High side gate drive outputs V S1,2,3 High side floating supply returns LO1,2,3 Low side gate drive outputs V S Low side return and positive input of current amplifier 5

6 IR213/IR2132(J)(S) & (PbF) HIN1,2,3 LIN1,2,3 ITRIP FAULT <5 V/ns HO1,2,3 LO1,2,3 Figure 1. Input/Output Timing Diagram Figure 2. Floating Supply Voltage Transient Test Circuit HIN1,2,3 5% 5% HIN1,2,3 LIN1,2,3 5% 5% LIN1,2,3 LO1,2,3 5% 5% t on t r t off t f 9% 9% HO1,2,3 DT DT HO1,2,3 LO1,2,3 1% 1% Figure 3. Deadtime Waveform Definitions Figure 4. Input/Output Switching Time Waveform Definitions 6

7 IR213/IR2132(J)(S) & (PbF) LIN1,2,3 5% ITRIP 5% FAULT 5% 5% LO1,2,3 5% t flt t fltclr t itrip Figure 5. Overcurrent Shutdown Switching Time Waveform Definitions t in,fil t in,fil U HIN/LIN on off on off on off HO/LO high low Figure 5.5 Input Filter Function V CC V S CA- + - CAO V SS V SS Figure 6. Diagnostic Feedback Operational Amplifier Circuit 7

8 IR213/IR2132(J)(S) & (PbF) V 3V V S V V CC V SS CAO 5 pf V S CA- CA V V CC CAO V SS + 2k 3V T1 9% T2.2V 1k V V SR+ = 1% V T1 SR- = V T2 V OS = V CAO V Figure 7. Operational Amplifier Slew Rate Measurement Figure 8. Operational Amplifier Input Offset Voltage Measurement V CC V S V V CC V SS CAO + V S CA- + CA- - 2k V SS CAO.2V 1k Measure V CAO1 at V S =.1V V CAO2 at V S = 5V (V CAO1 -.1V) - (V CAO2-5V) CMRR = -2 * LOG 4.9V (db) Measure V CAO1 at V CC = 1V V CAO2 at V CC = 2V PSRR = -2 * LOG V CAO1 - V CAO2 (1V) (21) Figure 9. Operational Amplifier Common Mode Rejection Ratio Measurements Figure 1. Operational Amplifier Power Supply Rejection Ratio Measurements 8

9 IR213/IR2132(J)(S) & (PbF) Turn-On Delay Time (µs).9.6 Turn-On Delay Time (µs) Figure 11A. Turn-On Time vs. Temperature VBIAS Supply Voltage (V) Figure 11B. Turn-On Time vs. Supply Voltage Turn-On Time (µs) Max Turn-Off Delay Time (µs) Input Voltage (V) Figure 11C. Turn-On Time vs. Voltage Figure 12A. Turn-Off Time vs. Temperature Turn-Off Delay Time (µs) Turn-Off Time (µs) Max Typ VBIAS Supply Voltage (V) Figure 12B. Turn-Off Time vs. Supply Voltage Input Voltage (V) Figure 12C. Turn-Off Time vs. Input Voltage 9

10 IR213/IR2132(J)(S) & (PbF) Turn-On Rise Time (ns) 15 Turn-On Rise Time (ns) Figure 13A. Turn-On Rise Time vs. Temperature VBIAS Supply Voltage (V) Figure 13B. Turn-On Rise Time vs. Voltage Turn-Off Fall Time (ns) 75 5 Turn-Off Fall Time (ns) Figure 14A. Turn-Off Fall Time vs. Temperature VBIAS Supply Voltage (V) Figure 14B. Turn-Off Fall Time vs. Voltage ITRIP to Output Shutdown Delay Time (µs) ITRIP to Output Shutdown Delay Time (µs) Figure 15A. ITRIP to Output Shutdown Time vs. Temperature VBIAS Supply Voltage (V) Figure 15B. ITRIP to Output Shutdown Time vs. Voltage 1

11 IR213/IR2132(J)(S) & (PbF) ITRIP to FAULT Indication Delay Time (µs) ITRIP to FAULT Indication Delay Time (µs) Figure 16A. ITRIP to FAULT Indication Time vs. Temperature 25. Figure 16B. ITRIP to FAULT Indication Time vs. Voltage 25. LIN1,2,3 to FAULT Clear Time (µs) LIN1,2,3 to FAULT Clear Time (µs) Figure 17A. LIN1,2,3 to FAULT Clear Time vs. Temperature 7.5. Figure 17B. LIN1,2,3 to FAULT Clear Time vs. Voltage Deadtime (µs) Deadtime (µs) Figure 18A. Deadtime vs. Temperature (IR213) VBIAS Supply Voltage (V) Figure 18B. Deadtime vs. Voltage (IR213) 11

12 IR213/IR2132(J)(S) & (PbF) Deadtime (µs) Deadtime (µs) Figure 18C. Deadtime vs. Temperature (IR2132) VBIAS Supply Voltage (V) Figure 18D. Deadtime vs. Voltage (IR2132) Amplifier Slew Rate + (V/µs) Amplifier Slew Rate + (V/µs) Figure 19A. Amplifier Slew Rate (+) vs. Temperature. Figure 19B. Amplifier Slew Rate (+) vs. Voltage Amplifier Slew Rate - (V/µs) Amplifier Slew Rate - (V/µs) Figure 2A. Amplifier Slew Rate (-) vs. Temperature Figure 2B. Amplifier Slew Rate (-) vs. Voltage 12

13 IR213/IR2132(J)(S) & (PbF) Logic "" Input Threshold (V) Logic "" Input Threshold (V) Figure 21A. Logic Input Threshold vs. Temperature Figure 2B. Logic Input Threshold vs. Voltage Logic "1" Input Threshold (V) Logic "1" Input Threshold (V) Figure 22A. Logic 1 Input Threshold vs. Temperature Figure 22B. Logic 1 Input Threshold vs. Voltage ITRIP Input Positive Going Threshold (mv) ITRIP Input Positive Going Threshold (mv) Figure 23A. ITRIP Input Positive Going Threshold vs. Temperature Figure 23B. ITRIP Input Positive Going Threshold vs. Voltage 13

14 IR213/IR2132(J)(S) & (PbF) High Level Output Voltage (V).6.4 High Level Output Voltage (V) Figure 24A. High Level Output vs. Temperature 1. VBIAS Supply Voltage (V) 1. Figure 24B. High Level Output vs. Voltage.8.8 Low Level Output Voltage (V).6.4 Low Level Output Voltage (V) Figure 25A. Low Level Output vs. Temperature VBIAS Supply Voltage (V) Figure 25B. Low Level Output vs. Voltage 5 5 Offset Supply Leakage Current (µa) Figure 26A. Offset Supply Leakage Current vs. Temperature Offset Supply Leakage Current (µa) VB Boost Voltage (V) Figure 26B. Offset Supply Leakage Current vs. Voltage 14

15 IR213/IR2132(J)(S) & (PbF) 8 8 VBS Supply Current (µa) VBS Supply Current (µa) Figure 27A. V BS Supply Current vs. Temperature VBS Floating Supply Voltage (V) Figure 27B. V BS Supply Current vs. Voltage VCC Supply Current (ma) VCC Supply Current (ma) Figure 28A. V CC Supply Current vs. Temperature. Figure 28B. V CC Supply Current vs. Voltage Logic "1" Input Bias Current (ma) Logic "1" Input Bias Current (ma) Figure 29A. Logic 1 Input Current vs. Temperature Figure 29A. Logic 1 Input Current vs. Voltage 15

16 IR213/IR2132(J)(S) & (PbF) Logic "" Input Bias Current (ma) Logic "" Input Bias Current (ma) Figure 3A. Logic Input Current vs. Temperature Figure 3B. Logic Input Current vs. Voltage "High" ITRIP Bias Current (µa) 3 2 "High" ITRIP Bias Current (µa) 3 2 Figure 31A. High ITRIP Current vs. Temperature Figure 31B. High ITRIP Current vs. Voltage "Low" ITRIP Bias Current (na) 15 5 "Low" ITRIP Bias Current (µa) 3 2 Figure 32A. Low ITRIP Current vs. Temperature Figure 32B. Low ITRIP Current vs. Voltage 16

17 IR213/IR2132(J)(S) & (PbF) VBS Undervoltage Lockout + (V) VBS Undervoltage Lockout - (V) Figure 33. V BS Undervoltage (+) vs. Temperature 6. Figure 34. V BS Undervoltage (-) vs. Temperature VCC Undervoltage Lockout + (V) VCC Undervoltage Lockout - (V) Figure 35. V CC Undervoltage (+) vs. Temperature 6. Figure 36. V CC Undervoltage (-) vs. Temperature FAULT- Low On Resistance (ohms) FAULT- Low On Resistance (ohms) Figure 37A. FAULT Low On Resistance vs. Temperature Figure 37B. FAULT Low On Resistance vs. Voltage 17

18 IR213/IR2132(J)(S) & (PbF) Output Source Current (ma) 3 2 Output Source Current (ma) 3 2 Figure 38A. Output Source Current vs. Temperature VBIAS Supply Voltage (V) Figure 38B. Output Source Current vs. Voltage Output Sink Current (ma) Output Sink Current (ma) Figure 39A. Output Sink Current vs. Temperature VBIAS Supply Voltage (V) Figure 39B. Output Sink Current vs. Voltage Amplifier Input Offset Voltage (mv) Amplifier Input Offset Voltage (mv) Figure 4A. Amplifier Input Offset vs. Temperature Figure 4B. Amplifier Input Offset vs. Voltage 18

19 IR213/IR2132(J)(S) & (PbF) CA- Input Bias Current (na) CA- Input Bias Current (na) Figure 41A. CA- Input Current vs. Temperature. Figure 41B. CA- Input Current vs. Voltage 8 8 Amplifier CMRR (db) 6 4 Amplifier CMRR (db) Figure 42A. Amplifier CMRR vs. Temperature Figure 42B. Amplifier CMRR vs. Voltage 8 8 Amplifier PSRR (db) 6 4 Amplifier PSRR (db) Figure 43A. Amplifier PSRR vs. Temperature Figure 43B. Amplifier PSRR vs. Voltage 19

20 IR213/IR2132(J)(S) & (PbF) Amplifier High Level Output Voltage (V) Amplifier High Level Output Voltage (V) Figure 44A. Amplifier High Level Output vs. Temperature 4.5 Figure 44B. Amplifier High Level Output vs. Voltage Amplifier Low Level Output Voltage (mv) Amplifier Low Level Output Voltage (mv) Figure 45A. Amplifier Low Level Output vs. Temperature Figure 45B. Amplifier Low Level Output vs. Voltage 1. Amplifier Output Source Current (ma) Amplifier Output Source Current (ma) Figure 46A. Amplifier Output Source Current vs. Temperature. Figure 46B. Amplifier Output Source Current vs. Voltage 2

21 IR213/IR2132(J)(S) & (PbF) Amplifier Output Sink Current (ma) Amplifier Output Sink Current (ma) Figure 47A. Amplifier Output Sink Current vs. Temperature 15. Figure 47B. Amplifier Output Sink Current vs. Voltage 15. Output High Short Circuit Current (ma) Output High Short Circuit Current (ma) Figure 48A. Amplifier Output High Short Circuit Current vs. Temperature 15.. Figure 48B. Amplifier Output High Short Circuit Current vs. Voltage 15. Output Low Short Circuit Current (ma) Output Low Short Circuit Current (ma) Figure 49A. Amplifier Output Low Short Circuit Current vs. Temperature. Figure 49B. Amplifier Output Low Short Circuit Current vs. Voltage 21

22 IR213/IR2132(J)(S) & (PbF). -3. VS Offset Supply Voltage (V) VBS Floating Supply Voltage (V) Figure 5. Maximum VS Negative Offset vs. V BS Supply Voltage V 45 48V Junction V 16V V Junction V 16V V E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 51. IR213/IR2132 T J vs. Frequency (IRF82) R GATE = 33Ω, V CC = 15V 2 1E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 52. IR213/IR2132 T J vs. Frequency (IRF83) R GATE = 2Ω, V CC = 15V 14 48V V Junction V 32V 16V V Junction V V 2 1E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 53. IR213/IR2132 T J vs. Frequency (IRF84) R GATE = 15Ω, V CC = 15V 2 1E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 54. IR213/IR2132 T J vs. Frequency (IRF45) R GATE = 1Ω, V CC = 15V 22

23 IR213/IR2132(J)(S) & (PbF) Jun ction Tem perature ( C) E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 55. IR213J/IR2132J T J vs. Frequency (IRGPC2KD2) R GATE = 33Ω, V CC = 15V 48V 32V 16V V Junction Tem perature ( C) E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 56. IR213J/IR2132J T J vs. Frequency (IRGPC3KD2) R GATE = 2Ω, V CC = 15V 48V 32V 16 V Ju nc tion Tem perature ( C) E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 57. IR213J/IR2132J T J vs. Frequency (IRGPC4KD2) R GATE = 15Ω, V CC = 15V 48V 32V 16V V Ju nction Tem p erature ( C ) E+2 1E+3 1E+4 1E+5 Frequency (Hz) Figure 58. IR213J/IR2132J T J vs. Frequency (IRGPC5KD2) R GATE = 1Ω, V CC = 15V 48V 32V 16V V 23

24 IR213/IR2132(J)(S) & (PbF) Case outlines 28-Lead PDIP (wide body) (MS-11AB) 28-Lead SOIC (wide body) (MS-13AE) 24

25 IR213/IR2132(J)(S) & (PbF) Case outline NOTES 44-Lead PLCC w/o 12 leads (mod.) (MS-18AC) 25

26 IR213/IR2132(J)(S) & (PbF) LEADFREE PART MARKING INFORMATION Part number IRxxxxxx Date code YWW? IR logo Pin 1 Identifier? MARKING CODE P Lead Free Released Non-Lead Free Released?XXXX Lot Code (Prod mode - 4 digit SPN code) Assembly site code Per SCOP 2-2 ORDER INFORMATION Basic Part (Non-Lead Free) 28-Lead PDIP IR213 order IR Lead SOIC IR213S order IR213S 28-Lead PDIP IR2132 order IR Lead SOIC IR2132S order IR2132S 44-Lead PLCC IR213J order IR213J 44-Lead PLCC IR2132J order IR2132J Leadfree Part 28-Lead PDIP IR213 order IR213PbF 28-Lead SOIC IR213S order IR213SPbF 28-Lead PDIP IR2132 order IR2132PbF 28-Lead SOIC IR2132S order IR2132SPbF 44-Lead PLCC IR213J order IR213JPbF 44-Lead PLCC IR2132J order IR2132JPbF IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 9245 Tel: (31) This product has been qualified per industrial level Data and specifications subject to change without notice. 4/2/