PD-94583A AHV28XX SERIES HYBRID-HIGH RELIABILITY DC/DC CONVERTER 28V Input, Single, Dual and Triple Output Description The AHV Series of DC/DC converters are designed to replace the AHE/ATO family of converters in applications requiring compliance to MIL-STD-704A through E, in particular the input surge requirement of 80V specified to withstand transient input voltage of 80V. No input voltage or output power derating is necessary over the full military temperature range. These converters are packaged in an extremely rugged, low profile package that meets all requirements of MILSTD-883 and MIL-PRF-38534. Parallel seam weld sealing and the use of ceramic pin feed thru seals assure long term hermeticity after exposure to extended temperature cycling. The basic circuit is a push-pull forward topology using power MOSFET switches. The nominal switching frequency is 500KHz. A unique current injection circuit assures current balancing in the power switches. All AHV series converters use a single stage LC input filter to attenuate input ripple current. A low power 11.5V series regulator provides power to an epitaxial CMOS custom pulse width modulator integrated circuit. This single integrated circuit provides all PWM primary circuit functions. Power is transferred from primary to secondary through a ferrite core power transformer. An error voltage signal is generated by comparing a highly stable reference voltage with the converter output voltage and drives the PWM through a unique wideband magnetic feedback circuit. This proprietary feedback circuit provides an extremely wide bandwidth, high gain control loop, with high phase margin. The feedback control loop gain is insensitive to temperature, radiation, aging, and variations in manufacturing. The transfer function of the feedback circuit is a function of the feedback transformer turns ratio which cannot change when subjected to environmental extremes. AHV Features n n n n n n n n n n n n n n 80V Transient Input (100 msec max.) 50V DC Input (Continous) 16V to 40V DC Input Range Single, Dual and Triple Outputs 15W Output Power (No Temperature Derating) Low Input / Output Noise Full Military Temperature Range Wideband PWM Control Loop Magnetic Feedback Low Profile Hermetic Package (0.405”) Short Circuit and Overload Protection Constant Switching Frequency (500KHz) True Hermetic Package (Parallel Seam Welded, Ceramic Pin Feedthru) Standard Microcircuit Drawings Available Manufactured in a facility fully qualified to MIL-PRF-38534, these converters are fabricated utilizing DSCC qualified processes. For available screening options, refer to device screening table in the data sheet. Variations in electrical, mechanical and screening can be accommodated. Contact IR Santa Clara for special requirements. www.irf.com 1 12/13/06 AHV28XX Series Specifications (Single Output Models) TCASE = -55°C to +125°C, VIN = +28V ± 5% unless otherwise specified Absolute Maximum Ratings Input voltage Power output Soldering temperature Operating case temperature Storage case temperature TEST STATIC CHARACTERISTICS OUTPUT Voltage Current Ripple Voltage1 Power REGULATION Line SYMBOL VOUT IOUT VRIP POUT VRLINE VRLOAD Load INPUT Current IIN Ripple Current EFFICIENCY IRIP EFF ISOLATION ISO Capacitive Load 2,3 CL Load Fault Power Dissipation PD FS -0.5V to +50VDC (Continous), 80V (100 msec) Internally limited, 17.5W typical 300°C for 10 seconds (1 pin at a time) -55°C to +125°C -65°C to +135°C Condition -55°C ≤ TC ≤ +125°C, VIN = 28 VDC ±5%, CL=0, unless otherwise specified Group A Subgroups AHV2805S Min Max 11.88 11.76 0.0 12.12 12.24 1.25 60 AHV2815S Min Max VIN = 16, 28, and 40 VDC IOUT = 0 VIN = 16, 28, and 40 VDC VIN = 16, 28, and 40 VDC BW = DC to 1 MHz VIN = 16, 28, and 40 VDC 1 2,3 1,2,3 1,2,3 4.95 4.90 0.0 1,2,3 15 VIN = 16, 28, and 40 VDC IOUT = 0, half load and full load VIN = 16, 28, and 40 VDC IOUT = 0, half load and full load 1 2,3 1,2,3 5.0 25 50 30 60 120 35 75 150 1,2,3 18 50 50 18 50 50 18 50 50 IOUT = 0, Inhibit (pin 2) = 0 IOUT = 0, Inhibit (pin 2) = Open IOUT = Full load IOUT = Full Load TC = +25°C Input to output or any pin to case (except pin 8) at 500 VDC TC = +25°C No effect on DC performance TC = +25°C 5.05 5.10 3.00 60 AHV2812S Min Max 15 14.85 14.70 0.0 15.15 15.30 1.00 60 15 Units V V A mVp-p W mV 1,2,3, 1 72 72 72 mA mA mAp-p % 1 100 100 100 MΩ 4 500 200 200 µF Overload, TC = +25°C Short Circuit, TC = +25°C 1 8.5 8.5 8,5 8.5 8.5 8.5 W IOUT = Full Load 4 450 550 450 550 450 550 KHz 50% Load 135 100% Load No Load 135 50% 50% Load 135 100% No Load 335 50% Load 50% Load 335 No lLoad 4 4 4 4 4 -300 -500 +300 +500 70 200 5.0 -300 -750 +300 +750 70 1500 5.0 -300 -750 +300 +750 70 1500 5.0 mVpk mVpk µs µs ms Input step 16 to 40 VDC 3,7 Input step 40 to 16 VDC 3,7 Input step 16 to 40 VDC 3,6,7 Input step 40 to 16 VDC 3,6,7 4 4 4 4 300 -1000 800 800 500 -1500 800 800 500 -1500 800 800 mVpk mVpk µs µs 4,5,6 4,5,6 4,5,6 550 10 10 750 10 10 750 10 10 mVpk ms ms 4 Switching Frequency DYNAMIC CHARACTERISTICS Step Load Changes Output Transient5 Recovery 5,6 Step Line Changes Output Transient Recovery TURN-ON Overshoot Delay Load Fault Recovery VOTLOAD TTLOAD VOTLINE TTLINE VTonos T on D TRLF IOUT = OA and Full Load IOUT = O and Full Load 8 VIN = 16 to 40 VDC Notes to Specifications (Single Output Models) 1. Bandwidth guaranteed by design. Tested for 20KHz to 2MHz. 2. Capacitive load may be any value from 0 to the maximum limit without affecting dc performance. A capacitive load in excess of the maximum limit will not disturb loop stability but will interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn-on. 3. Parameter shall be tested as part of design characterization and after design or process changes. Thereafter shall be guaranteed to the limits specified. 4. An overload is that condition with a load in excess of the rated load but less than necessary to trigger the short circuit protection and is the condition of maximum power dissipation. 5. Load step transition time between 2µs to 10µs. 6. Recovery time is measured from the initiation of the transient to where VOUT has returned to within ±1% of VOUT at 50% load. 7. Input step transition time between 2µs and 10µs. 8. Turn on delay time measurement is for either a step application of power at input or the removal of a ground signal from the inhinbit pin (pin 2) while power is applied to the input. Above 125°C case temperature, derate output power linearly to 0 at 135°C case. 2 www.irf.com AHV28XX Series Specifications (Dual Output Models) TCASE = -55°C to +125°C, VIN = +28V ± 5% unless otherwise specified Absolute Maximum Ratings Input voltage Power output Soldering temperature Operating case temperature Storage case temperature SYMBOL TEST -0.5V to +50VDC (Continous), 80V (100 msec) Internally limited, 17.5W typical 300°C for 10 seconds (1 pin at a time) -55°C to +125°C -65°C to +135°C Condition -55°C ≤ TC ≤ +125°C, VIN = 28 VDC ±5%, CL=0, unless otherwise specified STATIC CHARACTERISTICS OUTPUT Voltage 1 VOUT IOUT = 0 Current 1,2 Ripple Voltage 1,3 IOUT VRIP VIN = 16, 28, and 40 VDC VIN = 16, 28, and 40 VDC BW = DC to 2 MHz VIN = 16, 28, and 40 VDC Power 1,2,4 REGULATION Line 1,5 POUT Load 1 VRLINE IOUT VRLOAD INPUT Current IIN Ripple Current 3 IRIP EFFICIENCY EFF ISOLATION ISO Capacitive Load 6,7 Load Fault Power Dissipation CL Group A Subgroups AHV2805D AHV2812 AHV281D Min Max Min Max Min Max Units 1 2,3 1,2,3 1,2,3 ±4.95 ±4.90 0.0 ±5.05 ±5.10 ±1500 60 ±11.88 ±11.76 0.0 ±12.12 ±12.24 ±625 60 ±14.85 ±14.70 0.0 ±15.15 ±15.30 ±500 60 V V mA mVp-p 1,2,3 15 15 15 W VIN = 16, 28, and 40 VDC IOUT = 0, half load and full load VIN = 16, 28, and 40 VDC IOUT = 0, half load and full load 1 2,3 1,2,3 30 60 120 30 60 120 35 75 150 mV IOUT = 0, Inhibit (pin 2) Tied to input return (pin 10) IOUT = 0, Inhibit (pin 2) = Open IOUT = Full load BW = DC to 2MHz IOUT = Full Load TC = +25°C Input to output or any pin to case (except pin 8) at 500 VDC, TC = +25°C No effect on DC performance TC = +25°C 1,2,3 18 18 18 mA 1,2,3, 65 50 65 50 65 50 mA mAp-p 1 72 72 72 % 1 100 100 100 MΩ 4 200 200 200 µF 8,5 8.5 8,5 8.5 8.5 8.5 W PD Overload, TC = +25°C 8 Short Circuit, TC = +25°C 1 FS IOUT = Full Load 4 450 550 450 550 450 550 KHz 50% Load 135 100% Load No Load 135 50% 50% Load 135 100% No Load 335 50% Load 50% Load 335 No lLoad 4 4 4 4 4 -300 -500 +300 +500 70 200 5.0 -300 -500 +300 +500 70 1500 5.0 -300 -500 +300 +500 70 1500 5.0 mVpk mVpk µs µs ms Input step 16 to Input step 40 to Input step 16 to Input step 40 to 4 4 4 4 300 1000 4800 4800 1200 -1500 4.0 4.0 1500 -1500 4.0 4.0 mVpk mVpk µs µs 4,5,6 4,5,6 4,5,6 550 10 10 600 10 10 600 10 10 mVpk ms ms Switching Frequency DYNAMIC CHARACTERISTICS Step Load Changes Output Transient 9 Recovery 9,10 Step Line Changes Output Transient 7,11 Recovery 7,10, 11 TURN-ON Overshoot 1 Delay 1,12 Load Fault Recovery 7 VOTLOAD TTLOAD VOT LINE TTLINE VTonOS T on D TRLF 40 VDC 16 VDC 40 VDC 16 VDC IOUT = O and Full Load IOUT = O and Full Load For Notes to Specifications, refer to page 5 www.irf.com 3 AHV28XX Series Specifications (Triple Output Models) TCASE = -55°C to +125°C, VIN = +28V ± 5% unless otherwise specified Absolute Maximum Ratings Input voltage Power output Soldering temperature Operating case temperature Storage case temperature TEST SYMBOL STATIC CHARACTERISTICS OUTPUT Voltage 1 VOUT -0.5V to +50VDC (Continous), 80V (100 msec) Internally limited, 17.5W typical 300°C for 10 seconds (1 pin at a time) -55°C to +125°C -65°C to +135°C Condition -55°C ≤ TC ≤ +125°C, V IN = 28 VDC ±5%, CL=0, unless otherwise specified IOUT = 0 (main) IOUT = 0 (dual) Current 1,2,3 Ripple Voltage IOUT 1,4 Power 1,2,3 REGULATION Line 1,3 Load 1,3 VRIP POUT VRLINE VRLOAD INPUT Current IIN Ripple Current 4 IRIP EFFICIENCY EFF ISOLATION ISO Capacitive Load 6,7 Load Fault Power Dissipation 3 CL 1 VIN = 16, 28, and 40 VDC (main) VIN = 16, 28, and 40 VDC (dual)1 VIN = 16, 28, and 40 VDC BW = DC to 2 MHz (main) VIN = 16, 28, and 40 VDC BW = DC to 2 MHz (main) VIN = 16, 28, and 40 VDC (main) (+dual) (-dual) (total) VIN = 16, 28, and 40 VDC IOUT = 0, 50%, and 100% load (main) IOUT = 0, 50%, and 100% load (dual) VIN = 16, 28, and 40 VDC IOUT = 0, 50%, and 100% load (main) IOUT = 0, 50%, and 100% load (dual) IOUT = 0, Inhibit (pin 8) Tied to input return (pin 10) IOUT = 0 Inhibit (pin 2) = open IOUT = 2000 mA (main) IOUT = ±208mA (±12V) IOUT = ±167mA (±15V) BW = DC to 2MHz IOUT = 2000mA (main) IOUT = ±208mA (±12V) IOUT = ±167mA (±15V) Input to output or any pin to case (except pin 7) at 500 VDC, TC = +25°C No effect on DC performance TC = +25°C (main) (dual) Group A Subgroups 1 2,3 1 2,3 1,2,3 1,2,3 1,2,3 1,2,3 1,2,3 1,2,3 1,2,3 AHV2815T Max Min Max Units 4.95 4.90 ±11.88 ±11.76 0.0 0.0 5.05 5.10 ±12.12 ±12.24 2000 ±208 80 4.95 4.90 ±14.85 ±14.70 0.0 0.0 5.05 5.10 ±15.15 ±15.30 2000 ±167 80 V V V V mA mA mVp-p 1,2,3 40 10 2.5 2.5 15 1,2,3 40 10 2.5 2.5 15 MVp-p W W W W 25 ±60 25 ±75 50 ±60 50 ±75 1,2,3 15 15 1,2,3 50 50 mA 1,2,3 50 50 mAp-p mV mA 1 72 72 % 1 100 100 MΩ 4 500 200 500 200 µF 8.5 8.5 8.5 8.5 W 550 KHz PD Overload, TC = +25°C5 Short Circuit, TC = +25°C 1 1 FS IOUT = 2000mA (main) IOUT = ±208mA (±12V) IOUT = ±167mA (±15V) 4 Switching Frequency 1 AHV2812T Min 450 550 450 For Notes to Specifications, refer to page 5 4 www.irf.com AHV28XX Series Specifications (Triple Output Models) - continued TEST DYNAMIC CHARACTERISTICS Step Load Changes 9 Output Transient Recovery 9,10 Step Line Changes Output Transient Recovery 7,10, 11 TURN-ON Overshoot 1 1,12 Delay 7 Load Fault Recovery SYMBOL VOTLOAD TTLOAD VOTLINE TTLINE VTonOS T on D TRLF Condition -55°C ≤ TC ≤ +125°C, VIN = 28 VDC ±5%, CL=0, unless otherwise specified Group A Subgroups AHV2812T AHV2815T Min Max Min Max Units -300 -400 +300 +400 100 2000 5.0 -300 -400 +300 +400 100 2000 5.0 mVpk mVpk µs µs ms 50% Load 135 100% Load No Load 135 50% 50% Load 135 100% No Load 335 50% Load 50% Load 335 No lLoad 4 4 4 4 4 Input step 16 to 40 VDC Input step 40 to 16 VDC Input step 16 to 40 VDC Input step 40 to 16 VDC 4 4 4 4 1200 -1500 4.0 4.0 1200 -1500 4.0 4.0 mVpk mVpk µs µs IOUT = o and ±625mA IOUT = o and ±625mA 4 4 4 750 15 15 750 15 15 mVpk ms ms Notes to Specifications (Triple Output Models) 1. 2. 3. 4. 5. Tested at each output. Parameter guaranteed by line and load regulation tests. At least 25% of the total power should be taken from the (+5V) main output. Bandwidth guaranteed by design. Tested for 20KHz to 2MHz. An overload is that condition with a load in excess of the rated load but less than that necessary to trigger the short circuit protection and is the condition of maximum power dissipation. 6. Capacitive load may be any value from 0 to the maximum limit without affecting dc performance. A capacitive load in excess of the maximum limit will not disturb loop stability but may interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn-on. 7. Parameter shall be tested as part of design characterization and after design or process changes. Thereafter parameters shall be guaranteed to the limits specified. 8. Above 125°C case temperature, derate output power linearly to 0 at 135°C case. 9. Load step transition time between 2 µs and 10µs. 10. Recovery time is measured from the initiation of the transient to where V OUT has returned to within ±1% of VOUT at 50% load. 11. Input step transition time between 2µs and 10 µs. 12. Turn on delay time measurement is for either a step application of power at input or the removal of a ground signal from the inhibit pin (pin 8) while power is applied to the input. Notes to Specifications (Dual Output Models) 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. Tested at each output. Parameter guaranteed by line and load regulation tests. Bandwidth guaranteed by design. Tested for 20KHz to 2MHz. Total power at both outputs. When operating with unbalanced loads, at least 25% of the load must be on the positive output to maintain regulation. Capacitive load may be any value from 0 to the maximum limit without affecting dc performance. A capacitive load in excess of the maximum limit will not disturb loop stability but may interfere with the operation of the load fault detection circuitry, appearing as a short circuit during turn-on. Parameter shall be tested as part of design characterization and after design or process changes. Thereafter parameters shall be guaranteed to the limits specified. An overload is that condition with a load in excess of the rated load but less than that necessary to trigger the short circuit protection and is the condition of maximum power dissipation. Load step transition time between 2µs and 10 µs. Recovery time is measured from the initiation of the transient to where V OUT has returned to within ±1% of VOUT at 50% load. Input step transition time between 2 µs and 10 µs. Turn on delay time measurement is for either a step application of power at input or the removal of a ground signal from the inhibit pin (pin 2) while power is applied to the input. Above 125°C case temperature, derate output power linearly to 0 at 135°C. www.irf.com 5 AHV28XX Series Application Information Inhibit Function EMI Filter Connecting the inhibit pin (Pin 2 of single and dual models, pin 8 of triple models) to the input return (pin 10) will cause the converter to shutdown and operate in a low power standby mode. Power consumption in this mode is calculated by multiplying Vin times the input current inhibited, typically 225mW at Vin equal to 28V. The input current inhibited is relatively constant with changes in Vin. The open circuit inhibit pin voltage is typically 11.5V and can be conveniently driven by an open collector driver. An internal pull-up resistor enables the user to leave this pin floating if the inhibit function is not used in their particular application. All models use identical inhibit internal circuits. Forcing inhibit pin to any voltage between 0V and 6V will assure the converter is inhibited. The input current to this pin is 500µA maximum at Vpin2 = to 0V. The converter can be turned on by opening Pin 2 or forcing a voltage from 10V to 50V. Inhibit pin current from 10V to 50V is less than ± 50µA. An optional EMI filter ( AFC461) will reduce the input ripple current to levels below the limits imposed by MIL-STD461 CEO3. The output voltage of the AHV28XXS can be adjusted upward by connecting a resistor between the Output Adjust (Pin 3) and the Output Common (Pin 4) as shown in Table 1. Table 1: Output Adjustment Resistor Values * Resistance (Ohms) Pin 3 to 4 None 390 K 145 K 63 K 22 K 0 Output Voltage Increase (%) 5V 12V 15V 0 +1.0% +2.0% +3.1% +4.1% +5.0% 0 +1.6% +3.2% +4.9% +6.5% +7.9% 0 +1.7% +3.4% +5.1% +6.8% +8.3% * Output Adjust (Single Output Models Only) Standard Microcircuit Drawing Equivalence Table Standard Microcircuit Drawing Number 5962-91773 5962-92112 5962-92113 5962-92114 5962-92115 5962-92116 6 Vendor Cage Code 52467 52467 52467 52467 52467 52467 IR Standard Part Number AHV2805S AHV2812S AHV2815S AHV2812D AHV2812T AHV2815T www.irf.com AHV28XX Series Figure 1. (Single Output) Block Diagram 5 +Vout 1 +Input EMI Filter 8 Case 4 Output Return Drive 1 Pulse Width Modulator FB 2 Enable Input Error Amp & Ref Drive 2 3 VADJ Input Return 10 Figure 2. (Dual Output) Block Diagram 3 +Vout 1 +Input EMI Filter 4 Regulator 2 Enable Input Output Return 5 -Vout Drive 1 Pulse Width Modulator FB 8 Drive 2 Error Amp & Reference Case Input Return 10 Figure 3. (Triple Output) Block Diagram 5 +Vout Regulator +Input 1 Enable Input 8 7 Case 4 -Vout EMI Filter 2 +5 Vout 3 Drive 1 Pulse Width Drive 2 Modulator FB Output Return Error Amp & Reference Input Return 10 www.irf.com 7 AHV28XX Series Mechnical Outlines Single and Dual Output Model 0.050 Typical 0.800 10 9 8 7 5 Ø 0.162 2 Holes Typical 0.405 Max 1.110 4 4 X 0.400 =1.600 3 2.110 Max 2 2.560 1 2.880 Max 6 0.040 D X 0.26 L Pins Triple Output Model 10 8 3 7 2 4 6 1 9 1.000 5 1.95 2.700 Max 2.360 0.410 Max 1.345 Pin Designation Pin # Single Output Dual Output Triple Output 1 + Input + Input + Input 2 Enable Input Enable Input + 5VDC Output 3 Output Adjust * + Output Output Return 4 Output Return Output Return - Dual Output (12/15VDC) 5 + Output - Output + Dual Output (12/15VDC) 6 NC NC NC 7 NC NC Case Ground 8 Case Ground Case Ground Enable Input 9 NC NC NC 10 Input Return Input Return Input Return * Output Adjust (Single Output Models Only) 8 www.irf.com AHV28XX Series Device Screening Requirement MIL-STD-883 Method Temperature Range Element Evaluation No Suffix ES d -20°C to +85°C -55°C to +125°C HB e -55°C to +125°C CH -55°C to +125°C MIL-PRF-38534 N/A N/A N/A Class H 2023 N/A N/A N/A N/A Internal Visual 2017 c Yes Yes Yes Temperature Cycle 1010 N/A Cond B Cond C Cond C Constant Acceleration 2001, Y1 Axis N/A 500 Gs 3000 Gs 3000 Gs PIND 2020 N/A N/A N/A N/A 48 hrs@hi temp Non-Destructive Bond Pull Burn-In 1015 N/A Final Electrical MIL-PRF-38534 25°C ( Group A ) & Specification 25°C d 160 hrs@125°C 160 hrs@125°C -55°C, +25°C, -55°C, +25°C, +125°C +125°C PDA MIL-PRF-38534 N/A N/A N/A 10% Seal, Fine and Gross 1014 Cond A Cond A, C Cond A, C Cond A, C Radiographic 2012 N/A External Visual 2009 c N/A N/A N/A Yes Yes Yes Notes: Best commercial practice Sample tests at low and high temperatures -55°C to +105°C for AHE, ATO, ATW Part Numbering AHV 28 15 T F /CH Model Input Voltage Nominal 28 = 28V Screening Level (Please refer to Screening Table) No Suffix, ES, HB, CH Package Style F = Flange Output Voltage Output Single – 05 = 5V, 12 =12V, 15 =15V Dual – 05 = ±5V,12 = ±12V, 15 = ±15V Triple – 12 = 5V, ±12V 15 = 5V, ±15V S = Single D = Dual T = Triple WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, Tel: (310) 252-7105 IR SANTA CLARA: 2270 Martin Av., Santa Clara, California 95050, Tel: (408) 727-0500 Visit us at www.irf.com for sales contact information. Data and specifications subject to change without notice.12/2006 www.irf.com 9