Reverse Battery Protection

Application Note, 2.0, June 2009
Automotive MOSFETs
Reverse Battery Protection
by Marco Pürschel
Automotive Power
Application Note
Datasheet Explanation
Table of Contents
Page
1
Abstract .......................................................................................................................................... 3
2
Introduction ................................................................................................................................... 3
3
3.1
3.2
3.3
Possible Solutions ........................................................................................................................ 3
Reverse Battery Protection with Diode ........................................................................................... 3
Reverse Battery Protection with n-channel MOSFET ..................................................................... 4
Reverse Battery protection with p-channel MOSFET ..................................................................... 7
4
4.1
4.2
MOSFETs and ISO pulses ............................................................................................................ 8
Calculation example ...................................................................................................................... 10
Simulation example ....................................................................................................................... 11
5
Conclusion ................................................................................................................................... 13
Application Note
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Application Note
Datasheet Explanation
1 Abstract
This Application Note is intended to provide an overview of reverse battery
protection in automotive applications. The pros and cons of each solution will be
discussed.
2 Introduction
By changing the battery of a car or during maintenance work on the electronic
system of a car, the battery has to be reconnected. During this event, it is possible
that the polarity of the battery could be applied in reverse direction. Today’s battery
terminals are marked with colours and the terminal post itself are mechanically
different, nevertheless the possibility for reverse battery is still present, at least for
short connection duration.
With reverse applied voltage, a short circuit via diodes or transistors could occur,
leading to fatal errors of the electronics of the car. This means, that the ECUs
(Electronic Control Unit) have to be protected against reverse battery polarity.
3 Possible Solutions
In this chapter three most common reverse battery protection circuits will be
discussed. A solution with relay is not taken into account.
3.1 Reverse Battery Protection with Diode
The easiest way for reverse battery protection would be a series diode in the
positive supply line to the ECU accordingly the load. By applying the battery in the
wrong polarity the pn junction of the diode blocks the battery voltage and the
electronics are protected.
Diode
VF
VBat
Figure 1
Load
Solution with diode
From a correctly installed battery the supply current is flowing in forward direction
through the diode to the load.
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Application Note
Datasheet Explanation
Power losses of the diode can be calculated easily with its forward voltage drop
characteristic.
Efficiency @ diode
7
98.6%
6
98.4%
98.2%
Ploss [W]
5
98.0%
4
97.8%
3
97.6%
2
97.4%
1
97.2%
0
97.0%
250
0
50
100
150
200
Efficiency [%]
Ptot diode
Pload [W]
Figure 2
Ptot = f(Pload) for diode solution
Figure 1 shows an example of a solution using 45V rated Schottky diode(s). The
total power losses as a function of the power rating of the load with the assumption
of a battery voltage of 14V are shown. If the power losses at high output powers
can not be handled by one diode, several devices have to be connected in parallel.
Due to the diode threshold, which is a constant, switching the devices in parallel the
total power losses will stay more or less at the same level. They will be distributed
only according to the amount of used diodes.
3.2 Reverse Battery Protection with n-channel MOSFET
To lower the power losses of the reverse battery protection, a MOSFET can be
used. Inserting such a device in the right direction in the positive supply line can
protect the load against reversal battery as well. Note that a MOSFET has always
an intrinsic anti parallel body diode.
The MOSFET is fully turned on when applying the battery in the right direction. Due
to the fact that the Source is at high potential, the MOSFET is a high side switch not
referenced to ground. A charge pump circuit (or something equivalent) is needed to
boost the Gate-voltage over the Source-voltage to turn the MOSFET on.
During reverse polarity of the battery, the diode in the ground line of the charge
pump blocks the voltage. No voltage supplies the Gate and the MOSFET will be
switched off. The diode protects as well the charge pump against reverse battery.
Otherwise a short via the two transistors would occur.
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Application Note
Datasheet Explanation
30V n-Channel
MOSFET
S
D
G
Charge
Pump
Figure 3
Load
Oscillator
VBat
Solution with n-channel MOSFET
Figure 3 shows a typical solution for reverse battery protection with an n-channel
MOSFET.
The power losses of an n-channel MOSFET for a reverse battery protection are
determined by the RDS(on) of the device and the load current. Switching losses can
be neglected because the device will be switched on once when the battery is
applied and stays in on state during normal operation. The power losses and ratio
of power losses versus output power are shown in Figure 4 with an example of a
30V, 3.3mOhm MOSFET (SPP100N03S2-03).
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Application Note
Datasheet Explanation
Ptot @ 2 MOSFETs
Efficiency @ 2 MOSFETs
1.8
100.1%
1.6
100.0%
1.4
99.9%
1.2
99.8%
1
99.7%
0.8
99.6%
0.6
99.5%
0.4
99.4%
0.2
99.3%
0
99.2%
250
0
50
100
150
200
Ptot / Pload [%]
Ploss [W]
Ptot @ 1 MOSFET
Efficiency @ 1 MOSFET
Pload [W]
Figure 4
Ptot = f(Pload) for n-channel MOSFET (1 and 2 in parallel) solution
The power losses of the MOSFET are increasing by the power of two over the
output power and decreasing linear by the size of the MOSFET. Meaning by
switching two MOSFETs in parallel the power losses will be reduced by a factor of
two. This means by switching n MOSFETs in parallel, the total power losses will be
reduced by a factor of n and the power losses which has to be handled by each
MOSFET will be reduced by n2.
Such a solution would be feasible for high output power requirements.
The drawback of this solution is the additional circuit effort which has to be spent to
drive the n-channel MOSFET during normal operation. A charge pump circuit is
needed to create the required offset on the Gate pin over the battery line.
EMI is an issue because the oscillator of the charge pump circuit is switching the
two MOSFETs. But the power which will be handled by the charge pump is not
significant because the power MOSFET is switched on only once. This means that
the EMI is not as high as it is normally by dealing with such circuits.
It is not always possible in automotive applications to insert the MOSFET in the
ground line to eliminate the need for the high side driver. The voltage drop over
such a MOSFET connected to a ground line would result in a shift of the ground
level. For sensitive loads this can lead to malfunction.
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Application Note
Datasheet Explanation
3.3 Reverse Battery protection with p-channel MOSFET
The third solution to achieve reverse battery protection would be to connect a pchannel MOSFET in the positive supply line of the load. It is again important to
insert the transistor in the right direction, because the p-channel MOSFET has as
well an intrinsic anti parallel body diode. Note: For a p-channel MOSFET the diode
is in forward direction from Drain to Source.
30V p-channel MOSFET
D
S
G
VBat
Figure 5
Load
Solution with p-channel MOSFET
The huge benefit by using a p-channel MOSFET belongs to the fact, that no
additional high side driver circuit is needed. Compared to an n-channel MOSFET
the device will be turned on by applying a negative Gate Source voltage. By
referring the Gate signal to the ground line, the device is fully turned on when the
battery is applied in the right polarity. For the first start up, the intrinsic body diode
of the MOSFET will conduct, until the channel is switched on in parallel. The Zener
diode will clamp the Gate of the MOSFET to its Zener voltage and protecting it
against over voltage.
By reverse polarity, the MOSFET will be switched off, because the Gate Source
voltage for this case will be positive (voltage drop over the Zener diode).
The main difference in terms of technology between an n-channel MOSFET and a
p-channel MOSFET is the inverse doping profile over the whole device as it can be
seen in Figure 6.
n-channel MOSFET
p-channel MOSFET
Source
Source
Gate
Gate
n+
p+
p+
n+
nepi
Drain
Figure 6
pepi
n+
Drain
p+
Cross section of a planar n-channel and p-channel MOSFET
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Application Note
Datasheet Explanation
To switch on a p-channel MOSFET a negative Gate Source voltage has to be
applied. The electrical field will push the electrons in the channel region back and
will attract the holes, the “p-channel” is created and a load current can flow through
the device. But this current is a hole current and not an electron current as for an nchannel MOSFET. Holes do not have the same mobility of electrons. It is much
harder to push them through the device, resulting in a higher area specific on state
resistance. In the past this was a blocking point for the use of a p-channel MOSFET
because you have to replace an n-channel MOSFET with a two to three times
larger p-channel. With today’s technologies it is possible to shrink the p-FET and
the price is going down accordingly.
The power losses of a p-channel MOSFET versus the output power and the
efficiency are shown in Figure 7. By switching several MOSFETs in parallel the
same effect is valid as for n-channel MOSFETs. The power losses of each device
are decreasing with a dependency of n2.
Ptot @ 1 MOSFET
Efficiency @ 1 MOSFET
Ptot @ 2 MOSFETs
Efficiency @ 2 MOSFETs
2.5
100.0%
Ploss [W]
99.6%
1.5
99.4%
1
99.2%
0.5
99.0%
0
98.8%
250
0
50
100
150
200
Efficiency [%]
99.8%
2
Pload [W]
Figure 7
Ptot = f(Pload) for p-channel MOSFET solution
4 MOSFETs and ISO pulses
One common point of uncertainty for the development of the application using
MOSFETs as reverse polarity protection is related to the ISO pulses.
Basis for most OEM or TIER 1 is the ISO 7637-1 plus some tailored add-on tests.
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Application Note
Datasheet Explanation
Table 1
ISO pulses VW standard puls 1 – 3 and 6 (12V and 42V)
Typical IC products are commonly protected against the high voltage transients with
special protection circuits. The MOSFET however is not protected against these
transients as a stand alone component. How should these transients be considered
during the selection of the right reverse polarity protection concept?
First: The only critical pulses for the MOSFETs used as reverse polarity protection
are the negative transients. The positive ISO pulses will pass the MOSFET via its
intrinsic body diode or the parallel connection of the MOS-channel and the diode.
Second: the first point is valid as well for n-channel MOSFET as for p-channel
MOSFETs (and finally as well for a diode solution).
VISO
VISO
Positive ISO pulse will pass the
MOSFET via the body diode
Negative ISO pulse will stress the
breakdown voltage of the MOSFET
Load
D
MOSFET will avalanche!
S
D
G
G
VBat
Figure 8
Load
S
VBat
Reverse polarity MOSFET pass the positive and block or avalanche the negative ISO
pulse
If the negative pulses (e.g. Impulse 1 or 3a or 6 out of Table 1) will reach the
MOSFET, the device will go to avalanche mode if the breakdown voltage of the
MOSFET is significantly exceeded (as a rule of thumb: avalanche occurs at 1.4
times the rated min breakdown voltage of a low voltage MOSFET up to 100V).
As the pulses are all repetitive (up to 72,000 pulses for 3a and 3b) and repetitive
avanche is not specified in today’s data sheets, the device will operate in a grey
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Application Note
Datasheet Explanation
area. However for a single pulse the avanche energy could be calculated and the
according increase of the junction temperature of the MOSFET defined.
4.1
Calculation example
MOSFET:
ISO pulse to asses:
IPD80P03P4L-07
OptiMOS P2 technology
Min breakdown voltage = 30V
Typ avalanche voltage = 1.4 x 30V = 42V
Impulse 1 with -150V peak
tr = 1µs
td = 200µs
t1 = 0.5s … 5s
t2 = 200µs
- please note that the attached conditions might vary from OEM to OEM
To simplify the calculation lets assume a triangular voltage shape with a peak
voltage of -150V and a time duration of the pulse of 200µs.
For the given MOSFET the typical avalanche voltage is 42V. The time duration in
avalanche is according to the voltage wafe form:
Vavalanche ⋅ t d
)
150V
42V ⋅ 200µs
)
= 200µs − (
150V
= 144µs
t avalanch = t´d − (
t avalanch
t avalanch
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Application Note
Datasheet Explanation
During that time the MOSFET will clamp the Drain Source voltage to 42V. The
current flowing through the device can be determined using internal resistance of
the load dump generator (4Ohm for 12V bord net) and the rest of the voltage pulse
(150V – 42V with a triangular shape).
The peak avalanche current is therefore:
150V − 42V
4Ohm
= 27 A
I avalanch _ peak =
I avalanch _ peak
The according avalanche energy can be calculated:
E avalanche = 0.5 ⋅ V avalanche ⋅ I avalanche ⋅ t avalanche
E avalanche = 0.5 ⋅ 42V ⋅ 27 A ⋅ 144 µs
E avalanche = 82 mJ
According to the data sheet the single pulse avalanche ruggedness is defined as
135mJ at Drain current of -40A and and case temperature of 25°C. The
dependency of the avalanche energy to the drain current is indirectly proporsional;
½ Drain current would result in double avalanche energy.
At 27A the device can sustain single pulse avalanche energy of:
(40A/27A) x 135mJ = 200mJ.
This value is well above the required 82mJ due to the ISO pulse.
For that example the device should withstand the ISO pulse without degradation or
destruction, but there might be effects reducing the life time of the device due to
repetitive avalanche events which are not considered in that application note.
4.2
Simulation example
To assess the junction temperature of the MOSFET for the calculated example and
to prove the result out of the calculation, a PSPice simulation has been performed.
Asumption was again a triangular voltage pulse (based on ISO pulse 1),
accordingly a triangular current shape in case of avalanche.
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Application Note
Datasheet Explanation
V1
25Vdc
R3
20
Tj
Tcase
X1
0
IPD80P03P4L-07
R1
V
50m
V
V1 = 0
V2 = -150
TD = 1u
TR = 1u
TF = 200u
PW = 1u
PER = 2m
D1
VD02CZ10
V+
V2
R2
I
4
R4
1k
0
Figure 9
38
Schematic of ISO pulse simulation
In Figure 9 the schematic for the simulation is shown. With a level three model of
the PFET (coupling between electrical and thermal properties of the device), the
junction temperature can be observed.
150
100
50
0
0.00E+00
1.00E-04
2.00E-04
3.00E-04
t [s]
-50
Load dump current [A]
Load dump voltage [V]
-100
Junction temperature [°C]
Drain Source voltage [V]
-150
Figure 10
Simulation results
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Application Note
Datasheet Explanation
The result of the simulation is showing the Drain to Source voltage, the Drain
current, the Junction temperature and the ISO pulse voltage. As soon as the load
dump voltage reaches the avalanche voltage of the MOSFET, the device starts to
conduct and a current is flowing till the load dump voltage goes below the
avalanche voltage.
The current flow through the device in combination with the Drain to Source voltage
leads to power losses, accordingly a rise in the junction temperature. For the
selected MOSFET and ISO pulse 1, the Junction temperature reaches 110°C.
5 Conclusion
This application note points out the three most common ways to achieve reverse
battery protection which are:
-
solution with a diode
solution with an n-channel MOSFET
solution with a p-channel MOSFET
Each solution has its advantages and drawbacks.
diode
Parts
EMI
Power
losses
Efficiency
High
power
+
+
----
npchannel channel
MOSFET MOSFET
0
+
++
+
++
++
+
+
The table is summarizing the pros and cons of the three described solutions. For
high power applications the diode is not feasible for reverse battery protection,
since power losses are much too high.
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Application Note
Datasheet Explanation
7
Diode
n-channel MOSFET
p-channel MOSFET
6
Ploss [W]
5
4
3
2
1
0
0
50
100
150
200
250
Pload [W]
Figure 11
Comparison of power losses for the three solutions
For such applications, the n-channel MOSFET solution offers the highest efficiency
with the drawback of additional circuit requirements such as a charge pump circuit
and EMI filter.
A very simple solution still with an excellent efficiency would be the p-channel
approach. Nearly no additional circuit effort compared to the diode and only a
slightly worse efficiency in comparison to the n-channel MOSFET makes this
solution very attractive.
With the introduction of p-channel MOSFETs in a trench technology the
performance of the device increased dramatically and compensates the
disadvantage of the hole mobility significantly.
Diode
n-channel MOSFET
p-channel MOSFET
1
Efficiency [%]
0.995
0.99
0.985
0.98
0.975
0.97
0
50
100
150
200
250
Pload [W]
Figure 12
Comparison of efficiency for the three solutions
The best solution for reverse battery will be determined by the requirements of the
application. The designer will have to find the trade off between power losses and
the effort to spend on the reverse battery protection schematic itself.
Application Note
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Edition 2009-01-14
Published by
Infineon Technologies AG
81726 Munich, Germany
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