UNDERVOLTAGE / OVERVOLTAGE LOCKOUT

APPLICATION NOTE
UNDERVOLTAGE / OVERVOLTAGE LOCKOUT
Table of Contents
Introduction .....................................................................1
Design Considerations ......................................................1
Undervoltage Lockout ......................................................3
Resistor Values for VI-200/VI-J00 Converters.....................3
Circuit Operation..............................................................4
Formulas for Customized UV Lockout
Voltages and Maxi, Mini, Micro Converters ...................4
Overvoltage Lockout.........................................................5
Resistor Values for VI-200/VI-J00 Converters.....................5
Circuit Operation..............................................................6
Formulas for Customized OV Lockout
Voltages and Maxi, Mini, Micro Converters ...................6
Undervoltage/Overvoltage Lockout ...................................7
Circuit Description/Operation............................................7
Resistor Values for VI-200/VI-J00 Converters.....................8
Formulas for Customized UV/OV Lockout
Voltages and Maxi, Mini, Micro Converters ...................9
VI-200/VI-J00 modules are capable of turning on at very
low input voltages, i.e., lower than the voltage at which
they can operate correctly. This necessitates the use of a
lockout circuit (Figure 1)
for applications where the input voltage may drop below
low line. Vicor’s Maxi, Mini, Micro modules have built-in
undervoltage and overvoltage protection. For these
converters the following circuits should be implemented if
lockout is required inside the preexisting range of the
converter.
+In
UV/OV Lockout
Circuit
Gate In/PC
DC-DC
Converter
-In
Introduction
For many applications it is necessary to disable a DC-DC
converter when its input voltage goes outside a specified
range. This note describes circuits that can be used to
disable a Vicor converter based on programmable
undervoltage or overvoltage set points. These circuits
operate as comparators that monitor the input voltage and
disable the converter via the Gate In or PC pin when the
comparator trips. Configurable hysteresis is included in
each circuit so that lockout will occur cleanly in the
presence of noise.
Design Considerations
To disable a Vicor DC-DC converter the Gate In / PC pin
should be pulled low. The modules require a switch capable
of sinking a minimum of 6 mA for the VI-200/VI-J00
converters and 4 mA for Maxi, Mini, Micro converters.
When Gate In / PC is allowed to go high in the absence of
a fault condition it will rise to about 6 V.
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Figure 1: Undervoltage / overvoltage
lockout block diagram
All input sources have some noise that could cause
glitching at the transition point if it was fed directly into a
comparator. Using positive feedback to add hysteresis to
the circuit cleans up the transitions. For example, Figure 2
shows how this hysteresis will affect lockout of the VI-JV0CY module. The diagram shows a circuit configured for 4%
hysteresis such that the converter cannot be enabled
outside its normal operating range. Inside the hysteresis
bands the status of Gate In / PC will depend on whether
the input voltage is going into or out of range.
The hysteresis voltage bands will ensure clean transitions if
they are greater than the maximum possible peak-to-peak
change in input voltage. Their widths should be chosen
based on the maximum anticipated noise and ripple.
Applications Engineering: 800 927.9474
Page 1
VI-JV0-CY
Normal Operating Range
Gate IN / PC
Undervoltage
Hysteresis
Band
10 V
Overvoltage
Hysteresis
Band
10.4 V
34.56 V
36 V
Module Enabled
Module Disabled
Module Disabled
VIN
VUV(off) VUV(on)
VOV(on)
VOV(off)
Figure 2: Hysteresis diagram
Figures 3 and 4 show startup and shutdown waveforms for
a converter configured for the lockout voltages in Figure 2.
Gate In / PC shows clean transitions in spite of the slowly
changing input.
Figure 3: VI-JV0-CY with input rising from undervoltage
lockout to overvoltage lockout
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For high-input-voltage modules care should be taken not to
exceed either maximum power or maximum voltage ratings
of the resistors. One way to achieve this is to replace a
single resistor with a series of smaller resistors that share
power and voltage.
Figure 4: VI-JV0-CY with input falling from overvoltage
lockout to undervoltage lockout
Applications Engineering: 800 927.9474
Page 2
Undervoltage Lockout
Figure 5 shows the undervoltege lockout circuit schematic.
R3
R1
+In
Z1
4.7 V
U1
TLV431
R4
10 kΩ
C1
0.68 nF
Gate In /
PC
Q1
2N2222
Gate Out/
PR
–In
R2
10 kΩ
R5
D1
1N4148
UV hystersis
Figure 5: Undervoltage lockout circuit schematic
Resistor Values for VI-200/VI-J00 Converters
Table 1 lists standard lockout voltages for VI-200/
VI-J00 family modules and resistor values. Use the formulas
that follow for applications not listed.
Input Des.
VUV(off) (V)
VUV(on) (V)
Max. VIN (V)
R1 (kΩ)
R3 (kΩ)
R5 (kΩ)
R1 Rating (W)
R3 Rating (W)
0, V
10
10.4
40
3.65
73.2
806
1.00
0.25
W, 1*, 2*
18
18.72
60
3.65
140.0
845
1.50
0.25
1, 2
21
21.84
60
6.98
165.0
866
1.00
0.25
N, 3*
36
37.44
84
23.70
294.0
887
0.50
0.25
3
42
43.68
72
30.10
340.0
887
0.25
0.25
4*
45
46.8
110
34.00
365.0
887
0.50
0.25
4
55
57.2
110
45.30
453.0
887
0.50
0.25
T
66
68.64
176
57.60
549.0
887
1.00
0.25
5*
85
88.4
215
78.70
698.0
909
1.00
0.25
5, 7
100
104
413
95.30
825.0
909
3.00
0.50
6*
170
176.8
425
174.00
1430.0
909
1.50
0.25
6
200
208
425
205.00
1650.0
909
1.50
0.25
7*
90
93.6
413
84.50
750.0
909
3.00
0.50
Table 1: Resistor values for common undervoltage thresholds.
Notes:
1. * Voltage ranges that allow the converter to support 75% load (brown out).
2. Hysteresis is set at 4%.
3. All resistors are 0.25 W unless otherwise specified.
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Applications Engineering: 800 927.9474
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Circuit Operation
As the input voltage ramps up R1 feeds the base of Q1
through zener Z1. This turns Q1 on, which pulls the Gate In
/ PC pin low and disables the module.
Q1 remains on until the input voltage scaled by R3 and R4
reaches 1.24 V, the reference voltage of U1 (TLV431).
When this occurs U1 shunts current from the cathode of Z1
and pulls this point down to about 1 V. This in turn pulls
the base of Q1 low forcing it into cutoff and enabling the
module. R2 prevents Z1 leakage from pulling Q1 out of
cutoff.
When the Gate In / PC pin goes high the feedback resistor
(R5) pulls up the reference of U1 thereby adding hysteresis
to the circuit. D1 disables the feedback when Gate In / PC is
low.
Where:
VHL is the maximum operating voltage of the module.
IR1(HL) should not exceed the 15 mA limit of U1. Power
dissipation is governed by the following formula:
PR1 =
Solving For R1
R1 should be selected so that the base of Q1 is fed enough
current to saturate it but not more than U1 is capable of
sinking. Assuming R2 is large enough to be neglected and
the worst case Beta of Q1 is 20, then R1 should provide at
least 0.3 mA to sink 6 mA from Gate In / PC. This leads to
the following formula for R1:
2
R1
Solving For R3
A good starting value for R4 is 10 kΩ. With the value of R4
known, R3 can be calculated as follows:
 VUV ( on )

− 1
R3 = R 4 
 1.24 V 
Where:
VUV(on) is the voltage at which the module is enabled as the
input voltage transitions low to high (See Figure 2).
The power dissipated in R3 can be calculated using the
formula below:
 VIN (max)
PR = 
 R3 + R 4
3
2

 R 3

Solving For R5
R5 should be set to add the proper amount of hysteresis to
the circuit based on input noise. It can be calculated using
this formula:
V
− 4.9 V
R1 = IN(min)
0.3 mA
Where:
VIN(min) is the minimum voltage at which the converter
should be disabled, typically 6 V or one third the
converter’s minimum input voltage whichever is greater.
At high line the current though R1 is then:
I R1 ( HL ) =
− 1 V)
IN (max)
Where:
VIN(max) is the maximum input voltage the circuit can
withstand.
C1 acts as a low-pass filter with a 20 kHz bandwidth that
decouples high-frequency noise from the reference of U1.
Formulas for Customized UV Lockout
Voltages and Maxi, Mini, Micro Converters
(V
R5 =
(4.36 V ) R3 R 4
1.24 V ( R3 + R 4 ) − VUV ( off ) R 4
Where:
VUV(off) is the voltage at which the module is disabled as the
input voltage transitions high to low (See Figure 2).
VHL − 1 V
R1
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Applications Engineering: 800 927.9474
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Overvoltage Lockout
Figure 6 shows the overvoltege lockout circuit schematic.
Reference designations are continued from the
undervoltage lockout schematic of Figure 5 so that the
circuits can be cascaded without confusion.
R6
R13
R11
3 kΩ
Q3
2N2907
R12
4 kΩ
R7
10 kΩ
R9
6 kΩ
U2
TLV431
C2
0.68 nF
R8
+In
Z2
5.6 V
Gate In /
PC
Gate Out/
PR
Q2
–In
2N2222
R10
10 kΩ
D2
1N4148
UV hystersis
Figure 6: Overvoltage lockout circuit schematic
Resistor Values for VI-200/VI-J00 Converters
Table 2 lists common lockout voltages for VI-200/
VI-J00 family modules and resistor values. Use the
formulas that follow for applications not listed.
Input Des.
0
VOV(off) (V)
VOV(on) (V)
Max. VIN (V)
R6 (kΩ)
R8 (kΩ)
R13 (kΩ)
R13 Rating (W)
20
19.2
22
150
715
2.87
0.25
1
32
30.72
36
249
732
5.23
0.25
V, W
36
34.56
40
280
732
6.04
0.25
2
56
53.76
60
442
750
10.00
0.50
3
60
57.6
72
475
750
11.00
1.00
N
76
72.96
84
604
750
14.00
1.00
4
100
96
110
787
750
18.70
1.00
T
160
153.6
167
1270
750
30.90
1.50
5
200
192
215
1620
750
39.20
1.50
7
375
360
413
3010
750
73.20
3.00
6
400
384
425
3240
750
78.70
3.00
Table 2: Resistor values for common overvoltage thresholds.
Notes:
1. Hysteresis is set at 4%.
2. All resistors are 0.25 W unless otherwise specified.
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Applications Engineering: 800 927.9474
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Circuit Operation
Solving For R8
When the input voltage transitions high, a 5.6 V source is
established by Z2 at the emitter of Q3. For voltages less than
lockout, Q3 is in cutoff since U2 conducts minimal cathode
current. Thus, Q3 passes negligible current to the base of
Q2 cutting Q2 off and allowing Gate In / PC to go high.
The feedback resistor R8 can be calculated using the
formula below:
When the input voltage as scaled by R6 and R7 increases
above the reference of U2, U2 will pull the base of Q3 low
through R12. As Q3 turns on, current flows into the base of
Q2 through R6 causing it to conduct and pull Gate In / PC
low, thereby disabling the module.
Where:
VOV(on) is the voltage at which the module is enabled as the
input voltage transitions high to low (See Figure 2).
R8 adds positive feedback by coupling Q3’s collector to the
reference of U2. D2 disables the feedback when Gate In /
PC is high.
C2 acts as a low-pass filter with a 20 kHz bandwidth that
decouples high-frequency noise from the reference of U2.
R8 =
(3.76 V ) R 6 R 7
1.24 V (R 6 + R 7 ) − VOV (on ) R 7
Solving For R13
The value of R13 should be chosen so that the current
through Z2 is about 5 mA at the overvoltage lockout point.
It can be set using this formula:
R13 =
VOV ( off ) − 5.6 V
5 mA
Power dissipation can be calculated as given below:
Formulas for Customized OV Lockout
Voltages and Maxi, Mini, Micro Converters
Solving For R6
PR13 =
(VIN (max) − 5.6 V ) 2
R13
A good starting value for R7 is 10 kΩ. With the value of R7
known R6 can be calculated as follows:
 VOV ( off )

R 6 = R 7 
− 1
 1.24 V 
Where:
VOV(off) is the voltage at which the module is disabled as the
input voltage transitions low to high (See Figure 2).
Dissipation in R6 can be calculated using the
formula below:
 VIN (max)
PR 6 = 
 R6 + R7
2

 R6

Where:
VIN(max) is the maximum input voltage the circuit can
withstand.
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Applications Engineering: 800 927.9474
Page 6
Undervoltage/Overvoltage Lockout
Circuit Description/Operation
when it is off so that D3 can isolate it from the
undervoltage circuit’s divider. Z2 acts as a clamp to prevent
damage to U2. For detailed circuit operation please refer to
the individual circuit descriptions.
The circuit in Figure 7 combines the undervoltage and
overvoltage circuits. When an overvoltage event occurs the
second regulator (U2) shunts the reference of U1 forcing it
to disable the module. R9 is added to provide current to the
cathode of U2
OV Lockout
UV Lockout
UV hystersis
R5
R9
R6
U2
TLV431
R7
10 kΩ
R8
C2
0.68 nF
R1
R3
D3
1N4148
R10
8.06 kΩ
C1
0.68 nF
Z2
5.6 V
R4
10 kΩ
D1 1N4148
U1
Z1
4.7 V
TLV431
+In
Q1
2N2222
R2
10 kΩ
Gate In/
PC
Gate Out /
PR
–In
D2
1N4148
OV hystersis
Figure 7: Undervoltage/overvoltage lockout circuit schematic
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Applications Engineering: 800 927.9474
Page 7
Resistor Values for VI-200/VI-J00 Converters
Table 3 lists common lockout voltages for VI-200/
VI-J00 family modules and resistor values. Use the
formulas that follow for applications not listed.
Input
Des.
VUV(off)
(V)
VUV(on)
(V)
VOV(on)
(V)
VOV(off)
(V)
Max. VIN
(V)
R1
(kΩ)
R3
(kΩ)
R5
(kΩ)
R6
(kΩ)
R8
(kΩ)
R9
(kΩ)
R1
Rating
(W)
R3
Rating
(W)
0
10
10.4
19.2
20
22
3.65
66.5
806
150
715
44.2
0.25
0.25
V
10
10.4
34.56
36
40
3.65
66.5
806
280
732
44.2
0.50
0.25
1
21
21.84
30.72
32
36
6.98
158.0
866
249
732
154.0
0.25
0.25
1*
18
18.72
30.72
32
36
3.65
133.0
845
249
732
124.0
0.50
0.25
W
18
18.72
34.56
36
40
3.65
133.0
845
280
732
124.0
0.50
0.25
2
21
21.84
53.76
56
60
6.98
158.0
866
442
750
154.0
1.00
0.25
2*
18
18.72
53.76
56
60
3.65
133.0
845
442
750
124.0
1.50
0.25
3
42
43.68
57.6
60
72
30.10
332.0
887
475
750
365.0
0.25
0.25
3*
36
37.44
57.6
60
72
23.70
287.0
887
475
750
301.0
0.25
0.25
N
36
37.44
72.96
76
84
23.70
287.0
887
604
750
301.0
0.50
0.25
4
55
57.2
96
100
110
45.30
442.0
887
787
750
499.0
0.50
0.25
4*
45
46.8
96
100
110
34.00
357.0
887
787
750
392.0
0.50
0.25
T
66
68.64
153.6
160
176
57.60
536.0
887
1270
750
604.0
1.00
0.25
5
100
104
192
200
215
95.30
825.0
909
1620
750
953.0
1.00
0.25
5*
85
88.4
192
200
215
78.70
698.0
909
1620
750
787.0
1.00
0.25
6
200
208
384
400
425
205.00
1650.0
909
3240
750
1960.0
1.50
0.25
6*
170
176.8
384
400
425
174.00
1400.0
909
3240
750
1650.0
1.50
0.25
7
100
104
360
375
413
95.3
825.0
909
3010
750
953.0
3.00
0.50
7*
90
93.6
360
375
413
84.50
732.0
909
3010
750
845.0
3.00
0.50
Table 3: Resistor values for common undervoltageovervoltage thresholds.
Notes:
1. * Voltage ranges that allow the converter to support 75% load (brown out).
2. Hysteresis is set at 4% of the respective lockout voltages.
3. All resistors are 0.25 W unless otherwise specified.
vicorpower.com
Applications Engineering: 800 927.9474
Page 8
Formulas for Customized UV/OV Lockout
Voltages and Maxi, Mini, Micro Converters
For this circuit, the zener voltages have been selected such
that most of the resistor values need not be recalculated.
With the exception of R9 and R3, resistor values can be
found by using the equivalent resistors calculated for the
stand-alone undervoltage and overvoltage circuits.
Solving For R3
The formula below gives the value of R3:
⎛ VUV ( on ) ⎞
− 1⎟⎟ − 8.06 k Ω
R3 = R 4 ⎜⎜
⎝ 1.24 V ⎠
The power dissipated in R3 can be calculated using the
formula below:
PR 3 =
(VIN (max) − 1.7 V )2
R3
Solving For R9
The value of R9 can be calculated as follows:
R9 =
VUV (off ) − 5.6 V
100 uA
For more information, please contact Vicor’s Applications Engineers at 1-800-927-9474 or
vicorpower.com/support/ for worldwide assistance.
10/2013
vicorpower.com
Applications Engineering: 800 927.9474
Rev 1.6
Page 9