design features High Voltage Surge Stoppers Ease MIL-STD-1275D Compliance by Replacing Bulky Passive Components Dan Eddleman Electronics in a military vehicle face a unique set of challenges, chief among them operation from a perverse power supply. Recognizing the difficult power supply fluctuations that occur in the field, the US Department of Defense created MIL-STD-1275D to set down the requirements of electrical systems powered from a military vehicle’s 28V supply. Designing systems to withstand MIL-STD-1275D’s surge and related transients traditionally requires large and expensive passive components. Linear Technology’s surge stopper product line is well suited to protecting systems from this type of surge while reducing the cost and solution size. MIL-STD-1275D REQUIREMENTS MIL-STD-1275D defines a variety of conditions, most importantly those of steady state operation, starting disturbances, spikes, surges, and ripple. MIL-STD-1275D lays down requirements for each of these conditions in three separate “modes of operation”: starting mode, normal operating mode, and generator-only mode. Before describing the specifics of spikes, surges, ripple, and other requirements, let’s first look at the modes of operation. Not surprisingly, “starting mode” describes the conditions that occur when the engine is started; “normal mode” describes the conditions when the system is operating without any faults; and “generatoronly” mode describes a particularly vicious circumstance where the battery has been disconnected and the generator is directly powering the electronics. Generator-only mode is a challenging situation. Normally, a battery conceals the erratic nature of the generator by maintaining a relatively constant voltage despite the generator’s power fluctuations. Predictably, the limits set down for generator-only mode are worse than normal operating mode. For the most part, if the system operates through the generator-only mode conditions, it will have no difficulty with normal mode. (The one possible exception is that generatoronly mode’s 500mΩ source impedance during a surge can ease the burden when compared with the 20mΩ source impedance in the normal operating mode.) Steady-State As with any standard, MIL-STD-1275D spells out conditions and requirements in detail. The purpose of this article is to present these requirements, and a proposed solution, in a more digestible form. It is recommended to refer to MIL-STD-1275D for more precise definitions and requirements. MIL-STD-1275D defines steady-state as, “The condition in which circuit values remain essentially constant, occurring after all initial transients or fluctuating conditions have subsided. It is also definitive of the condition where, during normal system operation, only inherent or natural changes occur; (i.e., no malfunctions occur and no unanticipated changes are made to any part of the system).” More simply, in steady-state the input voltage remains relatively constant. As shown in Table 1, the steady-state input voltage range during normal operating mode ranges from 25V to 30V. During generator-only mode (the condition where the battery is disconnected), the steady-state voltage range is somewhat wider at 23V to 33V. Table 1. Selected MIL-STD-1275D specifications in normal operating mode and generator-only mode SPECIFICATION NORMAL OPERATING MODE GENERATOR-ONLY MODE Steady State 25V < V IN < 30V 23V < V IN < 33V Spikes 250V, Max Energy=15mJ Same as Normal Operating Mode Surges 40V Max, ~500ms, R IN = 20mΩ 100V Max, ~500ms, R IN = 500mΩ Ripple Magnitude ±2V Magnitude ±7V April 2014 : LT Journal of Analog Innovation | 15 Linear Technology’s surge stopper products provide a compelling solution to MIL-STD-1275D compliance. Alternative designs typically use shunt clamps at the input, which can result in damage or blown fuses during sustained overvoltage conditions. 300 VOLTAGE 110 250V, 70µs 250 VPEAK 200 90 100V, 1ms STEADY STATE VOLTAGE (23V–33V) 50 0 −50 MAXIMUM ENERGY CONTENT OF 15mJ −100 0V 80 100 VOLTAGE (V) VOLTAGE (V) 150 28V −250 tOSC Figure 1. MIL-STD-1275D spike Spikes Rather than quote the definition of a spike from MIL-STD-1275D, let’s instead look at the example in Figure 1. A spike is generally oscillatory (it rings) and decays to the steady-state voltage within 1ms. MIL-STD-1275D states that these spikes occur when reactive loads are switched, and may occur during events such as sounding the horn, operating the bilge pumps, starting and stopping the engine, or rotating the turret. Figure 4. Starting disturbances 50 40V, 500ms 40 10 −250V, 70µs 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 TIME (ms) 0 1 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 TIME (s) Figure 2. Envelope of spike in generator-only mode Figure 3. Generator-only mode surge envelope While that description is useful in understanding a spike, the actual requirements are defined by Figure 2 (for generator-only mode). Additionally, in subsection 5.3.2.3, “Voltage Spikes Imported into EDUT,” MIL-STD-1275D describes a recommended test setup as well as the required risetime and frequency of oscillation. An important fact to note is that the maximum energy is limited to 15mJ. The spike requirement for normal operating mode is similar to generator-only mode except that rather than a 100V limit at 1ms, the normal operating mode limit is 40V at 1ms. VOLTAGE IES CRANKING LEVEL STEADY STATE INITIAL ENGAGEMENT SURGE (IES) CRANKING LEVEL VOLTAGE 6V MIN 0V TIME 1s MAX 16 | April 2014 : LT Journal of Analog Innovation 60 20 −200 −300 70 30 −100V, 1ms −150 TIME 100V, 50ms 100 30s MAX 1 Surges Spikes are transients that last less than 1ms; surges are transients that last longer. Figure 3 shows the limitations for generator-only mode. Note that the recommended test in MIL-STD-1275D specifies that five 100V pulses of 50ms duration should be applied at the system input with a 1s repeat time. Interestingly, the envelope of the surge condition shown in Figure 3 is more difficult to satisfy, as it does not return to 40V for a full 500ms. The solution shown in this article satisfies both of these conditions. Once again, the requirements for normal operating mode are easier; the surge envelope looks similar, except that it has a 40V maximum instead of 100V. The reader should refer to the actual specification for details not covered here. design features Rather than shunt high energy levels to ground using bulky passive components, high voltage surge stoppers such as the LTC4366 and LT4363 limit the output voltage using series MOSFETs when faced with input voltage spikes and surges. Figure 5. 4A/28V MIL-STD-1275D solution provides uninterrupted power to 4A loads while limiting the output voltage to 44V during MIL-STD-1275D 100V/500ms surges and ±250V spikes; powers 2.8A loads during ±7V ripple. 0.1µF 500V 1210 237k 1206 15nF 10k 1206 1206 100Ω D4A C14 1µF 250V 2220 SOURCE1 M1 INPUT TVS OPT C13 1µF 250V 2220 100Ω HS1 20k D3A D3B D4B C15 1µF 250V 2220 HS2 D1 0.1µF 1210 20k 100Ω 1210 HS3 DRAIN2 M2 + C1–C12 22µF ×12 D2 RSENSE 10mΩ 1206 10Ω OUTPUT 68µF 50V 0.47µF VDD GATE SD OUT LTC4366-2 TIMER VSS BASE 2.2µF 25V 18.2k 1210 18.2k 1210 FB RFB1 12.1k D5 30.1Ω RFB2 649k 1206 RFB3 332k 0.047µF 18.2k 1210 1k R3 R1 301k 301k 301k C1–C12: TDK CKG57NX7S2A226M500JH C25: TDK C5750X7R2E105K230KA D1: VISHAY FEP30GP-E3/45 D2: DIODES INC. BAT54-7-F Q2A D3, D4: DIODES INC. MMBD3004S-7-F D5: DIODES INC. BAS21W-7-F Q1A Q1B M1: IXYS IXTQ88N30P R4 M2: IXYS IXTQ170N10P 1k R THERM RSENSE: IRC LRC-LRF-1206LF-01-R010 R2 AFFIXED RTHERM: EPCOS B59901D100A40 100k 1k TO HS3 Q1, Q2: DIODES INC. MMDT5551-7-F TVS (OPTIONAL): VISHAY P6SMB150CA-E3/5B HS1, HS2, HS3 (HEATSINKS): ASSMANN WSW COMPONENTS V8813X 332k 0.1µF VCC GATE SNS OPT OUT FB SHDN OV 10k UV RFB4 10k LT4363DE-2 GND TMR ENOUT ENOUT FLT 6.19k 1µF 16V FAULT 5.6M 10µF 16V UNLESS OTHERWISE NOTED, COMPONENT PACKAGE SIZES ARE 0805 AND CAPACITOR RATINGS ARE 100V Ripple Starting Mode Other Requirements Ripple is the term used to refer to variations of the input voltage about the steady state DC voltage. It may be composed of frequencies from 50Hz to 200kHz. In generator-only mode, the ripple is as large as ±7V about the DC steady state voltage. In normal mode, it is somewhat lower, ±2V around the steady state DC voltage. The MIL-STD-1275D specification provides explicit test conditions and recommends a set of frequencies for testing. In addition to normal mode and generator-only mode, MIL-STD-1275D defines starting mode, which describes the voltage variations caused by the engine starter and cranking. Figure 4 appears in the MIL-STD-1275D specification. It begins at the steady-state DC voltage and then drops as low as 6V during the “Initial Engagement Surge.” Within one second it rises to the “Cranking Level” which has a 16V minimum voltage. It returns again to the steady state DC voltage within 30 seconds. MIL-STD-1275D stipulates that the system withstand polarity reversal without harm. Such a condition can occur during a jump start, if the jumper cables are connected backwards. MIL-STD-1275D in turn refers to another standard, MIL-STD-461—regarding electromagnetic compatibility requirements— which is beyond the scope of this article. April 2014 : LT Journal of Analog Innovation | 17 During normal operation, the MOSFET is fully enhanced to minimize the power dissipated in the MOSFET. When the input voltage rises during a surge or spike, a surge stopper regulates the output voltage to provide safe, uninterrupted power to the load. Current limit and timer features protect the external MOSFETs from more severe conditions. SURGE STOPPER SOLUTION FOR MIL-STD-1275D COMPLIANCE Linear Technology’s surge stopper products provide a compelling solution to MIL-STD-1275D compliance. Alternative designs typically use shunt clamps at the input, which can result in damage or blown fuses during sustained overvoltage conditions. Rather than shunt high energy levels to ground using bulky passive components, high voltage surge stoppers such as the LTC4366 and LT4363 limit the output voltage using series MOSFETs when faced with input voltage spikes and surges. During normal operation, the MOSFET is fully enhanced to minimize the power dissipated in the MOSFET. When the input voltage rises during a surge or spike, a surge stopper regulates the output voltage to provide safe, uninterrupted power to the load. Current limit and timer features protect the external MOSFETs from more severe conditions. Surge In MIL-STD-1275D, the worst-case MOSFET power dissipation condition occurs during the 100V input surge. The circuit shown in Figure 5 regulates the output voltage to 44V. As a result, the circuit must drop 56V from the 100V input to the 44V output. In this MIL-STD-1275D solution, to increase power available at the output, two series MOSFETs are used. The first MOSFET’s source is regulated to 66V by the LTC4366, while the second MOSFET’s source is regulated to 44V by the LT4363. This reduces the power that must be dissipated in either MOSFET. 18 | April 2014 : LT Journal of Analog Innovation 100V 100V VIN 28V 43V 20V/DIV VIN 28V 20V/DIV VOUT 27V 4.3A 20V/DIV IOUT 2A/DIV 2.7A 27V VOUT 27V 20V/DIV IOUT 2A/DIV 2.7A 43V 4.3A RLOAD = 10Ω 100ms/DIV Figure 6. MIL-STD-1275D 100V/500ms surge test Figures 6 and 7 show the results measured during surge testing. The oscilloscope waveform in Figure 6 shows this circuit operating through the full 100V/500ms MIL-STD-1275D surge requirement described earlier. Figure 7 shows this circuit operating through the less stringent 100V/50ms pulses described in MIL-STD-1275D’s recommended tests. Spike The +250V spike condition is handled by MOSFET M1, which is rated to withstand over 300V from drain to source. MIL-STD-1275D specifies that the input energy is limited to 15mJ, well within the capabilities of this MOSFET. Figure 8 shows that a +250V spike at the input is blocked from the output. Similarly, the –250V spike test result is shown in Figure 9. In this condition, diode D1 is reverse biased during the –250V spike, blocking the spike from M2 and the output. D1 also provides reverse polarity protection, preventing negative RLOAD = 10Ω 500ms/DIV Figure 7. MIL-STD-1275D 100V/50ms surge repeated five times input voltages from appearing at the output. (The LTC4366 surge stopper in front of D1 is capable of withstanding reverse voltages and the –250V spike without additional protection.) An optional bidirectional transient voltage suppressor (TVS) is present at the input to provide extra protection. Its 150V breakdown voltage does not affect circuit operation below 100V. For applications where a TVS is not desirable at the input, this optional component can be removed. Note that in Figures 8 and 9, the output voltage trace (VOUT) during the MIL-STD-1275D spike shows high frequency ringing, which is a measurement artifact of the large currents that flow in supply and ground traces when a 0.1µ F test capacitor is discharged directly at the circuit input with all resistances and inductances minimized. design features Even when the maximum transient power dissipation (such as during a high voltage surge) exceeds the capability of a single MOSFET, multiple series MOSFETs can be used to support higher power levels. RLOAD = 10Ω 250V SPIKE IOUT 2.7A 5A/DIV VOUT 27V 50V/DIV 28V V 35V VIN 5V/DIV IN 28V 50V/DIV 21V 34V VIN 28V 50V/DIV −250V SPIKE VOUT 27V 50V/DIV IOUT 2.7A 5A/DIV VOUT 5V/DIV 27.15V 20.3V IOUT 1A/DIV 2.715A 1µs/DIV Figure 8. Positive input spike 1µs/DIV Figure 9. Negative input spike RLOAD = 10Ω 10ms/DIV Figure 10. 14VP–P input ripple condition Ripple Thermal CONCLUSION Satisfying the ripple specification of MIL-STD-1275D requires a few more components. Diode D1 in combination with capacitors C1–C12 form an AC rectifier. This rectified signal appears at the DRAIN2 node. Finally, thermal protection is implemented by components Q1, Q2, R1–R4 and thermistor RTHERM . If the temperature at M2’s heat sink (HS3) exceeds 105°C, the LT4363’s UV pin is pulled down by Q2A to force off MOSFET M2 and limit its maximum temperature. Linear Technology’s surge stopper products simplify MIL-STD-1275D compliance by using MOSFETs to block high voltage input surges and spikes while providing uninterrupted power to downstream circuitry. Blocking the voltage with series components avoids the blown fuses and damage that can occur when circuits attempt to shunt high energy to ground with bulky passive components. Additionally, this article has shown that even when the maximum transient power dissipation (such as during a high voltage surge) exceeds the capability of a single MOSFET, multiple series MOSFETs can be used to support higher power levels. n The LT4363 in combination with sense resistor RSENSE limits the maximum current to 5A (typical). If the rising edge of the input ripple waveform attempts to pull up the output capacitor with more than 5A, the LT4363 momentarily limits the current by pulling down on M2’s gate. To quickly restore the gate voltage, the small charge pump formed by components D3–D4, C13–C15 supplements the LT4363’s internal charge pump to quickly pull up MOSFET M2’s gate. Even so, the available load current must be reduced to 2.8A during this ripple condition. Figure 10 shows that the output remains powered during ripple testing. It should be noted that with the specified components, this circuit is only guaranteed to work down to a minimum of 8V during the starting mode initial engagement surge rather than the minimum 6V specified in MIL-STD-1275D. Typically, an EMI filter is placed at the input of MIL-STD-1275D compliant systems—while surge stoppers do not eliminate the need for filtering, their linear mode operation introduces no additional noise. April 2014 : LT Journal of Analog Innovation | 19