High Voltage 12 V - 400 V DC Current Sense

Simon Forstner
TI Designs: Verified Design
High Voltage 12 V – 400 V DC Current Sense Reference
Design
TI Designs
Circuit Description
TI Designs provide the foundation that you need
including methodology, testing and design files to
quickly evaluate and customize the system. TI
designs help you accelerate your time to market.
This Verified Design shows a low cost circuit to
measure currents with very high common mode of up
to 400V using an INA138. A DDZ12CSF-7 Zener
Diode and STR2550 Transistor were used to create a
simple floating power supply and biasing the INA138
directly from the high voltage source. The 400V in
this design is an example. With different components
even higher common mode voltages can be achieved.
Design Resources
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TINA-TI™
INA138
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All Design files
SPICE Simulator
Product Folder
VCM 400V
Rshunt 50mΩ
Vin+
Vin-
+
5kΩ
5kΩ
+
–
Load current
Z1
V+
hut
INA138
C2 0.1 mF
R1 200kΩ
GN5
Q1
Vout
R3 50kΩ
CAUTION: This equipment operates at high voltages and currents which can result in hazardous electrical
shock. Please make sure you understand and follow all necessary safety precautions prior to purchasing
and operating.
An IMPORTANT NOTICE at the end of this TI reference design addresses authorized use, intellectual property matters and
other important disclaimers and information.
TINA-TI is a trademark of Texas Instruments
WEBENCH is a registered trademark of Texas Instruments
TIDU833- March 2015
High Voltage 12 V - 400 V DC Current Sense Reference Design
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1
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1
Design Summary
The design requirements are as follows:
•
Common Mode Voltage: 12 V to 400 V
•
Input: 0.1 A – 6 A (50mΩ Shunt) or 1 A – 20 A (5mΩ Shunt)
•
Output: 50 mV – 3 V
The design goals and performance are summarized in Table 1 Comparison of Design Goals, Simulation,
and Measured Performance. Figure 1 depicts the measured relative output error of the design.
Table 1 Comparison of Design Goals, Simulation, and Measured Performance
Goal
Simulated
Error (%FSR)
Measured
0.3%
0.012%
0.17%
Relative Error
(Iload=200 mA)
10%
0.13%
5.03%
Output Error @200mA from 10 to 400V CMV
Output Error in mV
5.40 mV
5.20 mV
5.00 mV
4.80 mV
4.60 mV
4.40 mV
4.20 mV
4.00 mV
0V
40 V
80 V
120 V
160 V 200 V 240 V 280 V
Common Mode Voltage
320 V
360 V
400 V
360 V
400 V
Figure 1: Output Error over Common Mode Voltage
Input Error @200mA from 10 to 400V CMV
Output Error in uV
540 uV
520 uV
500 uV
480 uV
460 uV
440 uV
420 uV
400 uV
0V
40 V
80 V
120 V
160 V 200 V 240 V 280 V
Common Mode Voltage
320 V
Figure 2: Input Error over Common Mode Voltage
2
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2
Theory of Operation
VCM 400V
Load current
Rshunt 50mΩ
+
5kΩ
+
–
Vin5kΩ
Vin+
Z1
V+
hut
INA138
High
Voltage
C2 0.1 mF
GN5
Q1
Vout
R1 200kΩ
R3 50kΩ
Figure 3 - Schematic
The INA138 only works up to a common mode voltage of 36V. To be able to measure currents at higher
voltages we need the INA138 to “float” near the measurement voltage. This is achieved by using a 10V
zener diode (Z1) to create a “virtual ground” which is always ~10V below the common mode voltage.
Connecting the power supply and ground pins of the INA138 across the zener diode utilizes the zener as a
floating power supply. The rest of the voltage, in our case up to 390V, will drop over the series resistance
(R1) to ground. Power to the INA138 will be provided directly from the high voltage rail which eliminates
the need for an extra LDO or something similar for voltage regulation.
INA138 is used in this design because of its ability to output a current as illustrated in Figure 3 Schematic. The voltage drop over the shunt resistor generates a higher voltage on the plus input of the
internal Opamp than on the minus input. The Opamp will then start to rise its output voltage and with that
the base voltage of the internal NPN Transistor. Now the transistor will let some current flow through
emitter and collector. This current has to come from the Vin+ input and therefore generates a voltage drop
over the internal 5kΩ resistor. It will then regulate the output current to generate a voltage drop equal to
the shunt resistor drop over the internal 5kΩ resistor at the Vin+ input. Now we have reached steady state
and the INA138 generates an output current which is directly related to the voltage drop over the shunt
resistor. The output current is calculated as:
I out =
I Load ⋅ RShunt
5kΩ
(1)
With a load current equal to 200mA and a 50mΩ shunt the output current is calculated like as:
I out =
I Load ⋅ RShunt VShunt 10mV
=
=
= 2mA
5kΩ
5kΩ
5kΩ
(2)
The output current of the INA138 will flow through the PNP Transistor (Q1) used to cascode the INA138
and create a voltage drop over resistor R3. The voltage over R3 is now referenced to the system ground
and can be easily measured with an ADC or µController. The output voltage is calculated as illustrated
below:
Vout =
TIDU833- March 2015
I Load ⋅ RShunt ⋅ R3 VShunt ⋅ R3 10mV ⋅ 50kΩ
=
=
= 100mV
5kΩ
5kΩ
5kΩ
High Voltage 12 V - 400 V DC Current Sense Reference Design
Copyright © 2015, Texas Instruments Incorporated
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3
3.1
Component Selection
Current Shunt Monitor
The INA138 was chosen because of its ability to output a current. This made it easy to get an output
voltage referenced to ground with the use of a PNP transistor. For faster transient response devices with a
wider gain bandwidth such as INA139 can be selected.
3.2
Zener Diode and Series Resistance
The input voltage of the INA138 can range from 2.7V to 36V. The Zener Diode voltage should be chosen
somewhere in that range. Conveniently a 12V diode lies in the middle between those two voltages. Not
only will the Zener diode regulate the maximum voltage applied across the INA138 and protect it from
transient events it will also allow for a suitable margin to still reach the 2.7V needed to start up the device.
Since datasheet parameters such as offset are defined for 12V Vin+ to GND using a 12V Zener diode
makes it easy to predict the maximum output errors. Substituting a 10V Zener diode will have little impact
on accuracy and is used throughout the following simulations and testing verification.
The series resistance (R1) has the most influence over the power consumption. The main voltage drop (up
to 390V in this case) drops over this resistor. As calculated in equation (4) 0.76W is dissipated by the
resistor.
2
2
(
VCM − VDiode )
(
400V − 10V )
=
P( R1) =
R1
200kW
= 0.76 W
(4)
When selecting the value for resistor R1 it is important to consider several system requirements. Most
important is maintaining enough current flow through the Zener diode at the lowest value of the common
mode voltage required for system operation. For use at lower voltages a smaller resistor lets the Zener
Diode run more safely further above its needed minimum current to maintain the voltage regulation but will
also have an impact on the power dissipation at the higher common mode voltages.
3.3
PNP Transistor
The PNP transistor is used to stand off the high voltage while passing the current from the INA138 through
to a ground referenced resistor. The most important requirement for the transistor is to be able to
withstand the maximum voltage coming from the input. For the output accuracy it is also important to use a
transistor with a high βF (sometimes called hFE, DC current Gain, current Gain) as this transistor parameter
has an influence on the gain accuracy of the design.
AM2 2.0094uA
Q1
AM4 19.5007nA
AM3 1.9899uA
Figure 4 – Current through the PNP Transistor
4
High Voltage 12 V - 400 V DC Current Sense Reference Design
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TIDU833- March 2015
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Figure 4 – Current through the PNP Transistor shows the current running through a transistor with a βF of
roughly 100. A βF of 100 means that approximately 1% of the current flowing through the emitter will not
flow out the collector but instead will flow out of the base. This reduction in collector current due to the βF
adds a gain error of 1% to our whole system for a βF equal to 100.
The PNP transistor can be exchanged by a P-Channel MOSFET. Replacing the bipolar transistor with a
FET device will eliminate the gain error term due to the base current effects in the bipolar device. One
downside is that Vth of high voltage FETs can be as high as 5V. This will require the output of INA138 to be
5V higher than the GND of the INA138. This can be a problem for lower common mode voltages and for
Zener Diodes with low voltages.
TIDU833- March 2015
High Voltage 12 V - 400 V DC Current Sense Reference Design
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4
4.1
Simulation
Steady State
Figure 5 - DC Circuit Simulation
In Figure 5 - DC Circuit Simulation a steady state simulation of the circuit at 400V DC is illustrated. Note
that with the component values illustrated the INA138 is biased from a floating 10V power supply created
by the Zener diode. Approximately 2mA of current flows in R1. This current will vary according to the
common mode voltage. The load current is set to 200mA and creates a voltage drop of 10mV across the
shunt resistor. This input voltage is multiplied by the gain of the circuit, resulting in an output voltage of
approximately 100mV.
6
High Voltage 12 V - 400 V DC Current Sense Reference Design
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TIDU833- March 2015
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4.2
Performance with different Common Mode Voltages
Table 2 - Vout over different Common Mode Voltages shows the common mode voltage (VCM), the voltage
drop over the diode (V+ to INA-GND) which is also the INA138 supply voltage and the output voltage
measured at R2 (Vout). In all simulations the load was set to 0.2A which generated a 10mV drop over the
shunt resistor.
Table 2 - Vout over different Common Mode Voltages
VCM
V+ to INA_GND
VOut
Relative
Output Error
6.00 V
1.50 V
125.110 mV
25.11%
7.00 V
2.65 V
100.37 mV
0.37%
8.00 V
3.85 V
100.37 mV
0.37%
10.00 V
6.25 V
100.37 mV
0.37%
15.00 V
11.12 V
100.37 mV
0.37%
25.00 V
11.35 V
100.37 mV
0.37%
50.00 V
11.46 V
100.37 mV
0.37%
100.00 V
11.54 V
100.37 mV
0.37%
200.00 V
11.62 V
100.37 mV
0.37%
400.00 V
11.69 V
100.37 mV
0.37%
The simulation shows that for common mode voltages below 7V the supply voltage for the INA138 is too
low. Since the INA138 model is not defined outside the datasheet specs the output shows strange
behavior. But for all voltages above 7V the output behaves as it should and gives us 100.37mV. Because
the common mode for the INA138 does not change significantly after 15V VCM the common mode
rejection ratio of the whole system is very good and we get the same results over the full voltage range.
TIDU833- March 2015
High Voltage 12 V - 400 V DC Current Sense Reference Design
Copyright © 2015, Texas Instruments Incorporated
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5
PCB Design
The PCB schematic and bill of materials can be found in the Appendix.
5.1
PCB Layout
The PCB used in this design is 3” by 2”. Most of the space is used by the isolated banana jacks. The
actual parts, excluding the shunt resistor, could be placed in a 0.5” by 0.5” area. The test pins are placed
between the banana jacks so they are hard to touch by accident but still easy to reach with probes.
1
2
1
2
2
1
1
1
2
5
4
2
1
2
1
3
2
1
1
1
1
3
2
2
1
2
1
1
1
1
2
2
1
0
Figure 6 - PCB Layout
Also very important is to put a bypass cap (C2) close to the INA138. This makes the design a lot more
stable and reduces the influence of noise which makes the results more accurate.
The layout for shunt voltage measurement is also important. The voltage sense lines should be connected
to the inside of the shunt resistor pads as shown here. For shunt resistor values below 10mΩ a 4-wire
force/sense pad layout is suggested. For more information refer to the Texas Instruments Application Note
http://www.ti.com/lit/pdf/sboa137.
Due to the presence of high voltages, the spacing between high voltage pads and low voltage pads must
to be considered. The PCB trace spacings used in this design meet the requirements specified in table 6-1
of the IPC-2221 standard for external conductors with conformal coating over assembly. The IPC-2221
“Generic Standard on Printed Board Design” specifies spacing requirements for various types of PCB
construction, coating and applications.
8
High Voltage 12 V - 400 V DC Current Sense Reference Design
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TIDU833- March 2015
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6
6.1
Verification & Measured Performance
Performance with different Common Mode Voltages
Table 3 - Vout over different Common Mode Voltages shows the common mode voltage (VCM), the
voltage drop over the diode (V+ to INA-GND) which is also the INA138 supply voltage and the output
voltage measured at R2 (Vout). In all measurements the load was set to 0.2A which generated a 10mV
drop over the shunt resistor.
Table 3 - Vout over different Common Mode Voltages
Relative
Output Error
VCM
V+ to INA_GND
VOut
6.00 V
1.45 V
0 mV
7.00 V
1.75 V
96.29 mV
3.7%
8.00 V
2.35 V
95.79 mV
4.2%
10.00 V
4.58 V
94.97 mV
5.04%
15.00 V
10.62 V
95.07 mV
4.93%
25.00 V
11.95 V
95.08 mV
4.92%
50.00 V
11.95 V
95.23 mV
4.77%
100.00 V
11.99 V
95.59 mV
4.41%
200.00 V
12.00 V
95.50 mV
4.50%
400.00 V
12.01 V
95.55 mV
4.45%
The measurement shows that this particular device operates down to a common mode voltage of 7V
resulting in a supply voltage for the INA138 of 1.75V. Since the INA138 is only specified down to a supply
voltage of 2.7V it is not recommended to operate below a common mode voltage of 10V based on these
results. The error of 5mV is mainly based on the input offset of maximum 1mV together with the
amplification of 10V/V. From 10V to 400V the output only changes by 580µV indicating the superior
common mode rejection ratio of this design over the full scale operating voltage range.
 ∆V
CMRR =
20 ⋅ log  CMV
 ∆VInput

TIDU833- March 2015

 390V 
20 ⋅ log 
136dB
 =
=
V
58
µ



High Voltage 12 V - 400 V DC Current Sense Reference Design
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6.2
Maximum Relative Output Error
There are several main influences on the maximum output error
6.2.1
•
The offset voltage of the INA138
•
The initial CMRR of the INA138 and the system CMRR calculated in 6.1 with 58µV input related
error
•
The initial PSRR of the INA138
•
The gain error due to βF from the PNP transistor
•
The shunt resistor accuracy
•
The output resistor accuracy
Dominant Errors at Small Values of Load Current
When the load current is small there is a corresponding small input voltage to the INA138. Errors will be
dominated primarily by the input offset related errors such as:
•
The Input Offset Voltage (VOS)of the INA138
•
The initial Common Mode Rejection (CMR) of the INA138
•
The initial Power Supply Rejection (PSR) of the INA138
Because these errors are uncorrelated to one another they can be combined with a square root of the sum
of the squares approach.
EMax =
(VOS ) + (VCMR ) + (VPSR )
2
2
2
(6)
Determining the errors associated with each of the three parameters is straightforward and described
below.
Initial Offset Voltage Error
The maximum error due to input offset voltage can be taken directly from the INA138 device specification.
The maximum input offset voltage is given as 1mV at 25˚C.
•
VOS = 1mV
Initial CMR Error
The maximum input offset error due to the common mode rejection of the INA138 (VCMR) is calculated by
determining the actual common mode voltage as applied to the INA138 with reference to the ground pin of
the INA138. In this design this value is equal to the value of the zener voltage of approximately 10V. From
the INA138 device specification the common mode rejection ratio minimum is given as 100dB (10µV/V),
and since the test condition for the V+ input of the INA138 input offset voltage is with a 12V common mode
voltage (CMV), the resulting common mode error is determined as:
VCMR
=
( CMVtestcondition − CMVactual ) × CMRR
VCMR = (12V − 10V ) ×10 µµ
V / V = 20 V
10
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This error term is described as “initial” as it is determined at a particular system common mode voltage
that would result in a zener voltage equal to 10V. Any changes to the system common mode voltage will
result in a very slight change in zener diode voltage, which in turn changes (albeit slightly) the common
mode voltage applied to the INA138. In this case the results from section 5 can be used to estimate the
common mode error if the common mode voltage is changing in the application.
Initial PSR Error
Similar to the initial common mode error, the initial error due to the power supply rejection of the INA138
can easily be determined. From the INA138 device specification the specified power supply voltage for the
input offset voltage specification is given as 5V. Any deviation from 5V applied between the INA138 V+ pin
and ground pin will result in an additional error, VPSR. This error is determined as:
VPSR
=
( PSVtestcondition − PSVactual ) × PSRR
(9)
Where PSV is the power supply voltage applied between the V+ pin and ground pin of the INA138.
VPSR = ( 5V − 10V ) ×10 µµ
V / V =50 V
(10)
The total error at small load currents (input voltages) is calculated from equation (6) as:
EMAX = 1mV 2 + 20 mV 2 + 50 mV 2 = 1.001mV
6.2.2
(11)
Dominant Errors at Large Values of Load Current
At large load currents the input voltage developed across the shunt resistor will be at its maximum. This
minimizes the percentage contribution of the errors from the initial error sources described above. The
dominant errors sources for large inputs are:
•
Gain error from the INA138
•
Shunt resistor accuracy
•
Output resistor accuracy
In this design it is assumed that the maximum INA138 gain error and resistor accuracy is 1%. Again
because these error sources are uncorrelated to one another they can be combined with a square root of
the sum of the squares approach.
EMAX =
INA138 _ GAIN ERROR 2 + SHUNT _ RESISTORERROR 2 + OUTPUT _ RESISTOR ERROR 2
(12)
INA138 Gain Error
To determine the error due to the gain error of the INA138 we first determine the ideal maximum output
voltage, VOUTMAX. In this example it is assumed that the maximum load current is 6A resulting in a
maximum output voltage of 3V. From the INA138 device specification the transconductance (gain) error is
given as 1%. This in turn will result in an output referred error voltage of 30mV. Referring this output error
back to the input it is required to divide by the gain of the circuit (10V/V). This results in an input referred
gain error of 3mV.
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High Voltage 12 V - 400 V DC Current Sense Reference Design
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Shunt Resistor Error
Similarly to the INA138 gain error the error contribution from the shunt resistor is determined in a similar
fashion. In this example it is assumed that the maximum load current is 6A resulting in a maximum output
voltage of 3V. It is also assumed that the shunt resistor tolerance is given as 1%. This in turn will result in
an output referred error voltage of 30mV. Referring this output error back to the input it is required to divide
by the gain of the circuit (10V/V). This results in an input referred error due to the tolerance of the shunt
resistor of 3mV.
Output Resistor Error
Similarly to the INA138 gain error and the error due to the shunt resistor initial tolerance the error
contribution from the output resistor is determined in a similar fashion. In this example it is assumed that
the maximum load current is 6A resulting in a maximum output voltage of 3V. It is also assumed that the
output resistor tolerance is given as 1%. This in turn will result in an output referred error voltage of 30mV.
Referring this output error back to the input it is required to divide by the gain of the circuit (10V/V). This
results in an input referred error due to the tolerance of the output resistor of 3mV.
Summing these errors results in:
EMAX =
3mV 2 + 3mV 2 + 3mV 2 = 5.2mV
(13)
The total error at the large load currents will also include the initial errors due to Vos, CMR and PSR
resulting in a total error of:
TotalErrorRTI = 5.2mV 2 + 1.001mV 2 =5.3mV
(14)
Total Error expressed as a percentage of the input voltage is given by:
TotalError=
% 100 ×
InputErrorVoltage
InputVoltage
(15)
In general all errors can be combined statistically with the sum of the square roots.
EMax =
12
(VOS )2 + (VCMRR )2 + (VPSRR )2 + (VShunt ⋅ GError )2 + (VShunt ⋅ GShunt −Error )2 + (VShunt ⋅ GRe s−Error )2
High Voltage 12 V - 400 V DC Current Sense Reference Design
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The maximum error over the shunt resistor drop voltage (blue curve) is plotted in Figure 7 – Maximum
Relative Output Error The red curve shows the measured values which are a lot lower than the maximum
possible values in our case.
Maximum Relatice Output Error
Maximum Relative Output Error over CMV Range
20.0%
18.0%
16.0%
14.0%
12.0%
10.0%
8.0%
6.0%
4.0%
2.0%
0.0%
0 mV
50 mV
100 mV
150 mV
200 mV
250 mV
300 mV
350 mV
Input Shunt Voltage Drop in mV
Max Error over CMV
Measured Error
Figure 7 – Maximum Relative Output Error
7
About the Author
Simon Forstner is a field applications engineer at Texas Instruments. Simon graduated from the University
of Applied Science in Munich where he earned a Bachelor of Electrical Engineering and a Master of
Systems Engineering.
TIDU833- March 2015
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www.ti.com
Appendix A.
A.1 Electrical Schematic
Figure A-1: Electrical Schematic
A.2 Bill of Materials
Item # Quantity
Value
Designator
Description
Manufacturer
Manufacturer
Part Number
Alternative
Part Number
1
2
10pF
C1, C2
CAP, CERM, 10pF, 50V,
+/-5%, C0G/NP0, 0603
Kemet
2
1
12V
D1
Diode, Zener, 12V,
500mW, SOD-323
Diodes Inc.
DDZ12CSF-7
3
5
SMT
GND, GND_1, TP3 Out,
TP1 400V, TP2 390V
Test Point, Compact,
SMT
Keystone
5016
4
2
10A
J1 Vin, J3 Vout
Standard Banana Jack,
insulated, 10A, red
DEM
Manufacturing
571-0500
5
2
10A
J2 GND, J4 GND
Standard Banana Jack,
insulated, 10A, black
DEM
Manufacturing
571-0100
6
1
500V
Q2
Transistor, PNP, 500V,
0.5A, SOT-23
ST
STR2550
7
1
200k
R1
RES, 200kohm, 1%, 1W,
2010
Vishay-Dale
8
1
0.05
R2
Stackpole
CSRN2512FK PF2512FKF7W
RES, 0.05 ohm, 1%, 2W,
Electronics Inc
50L0
0R05L
2512
9
1
49.9k
R3
10
1
INA138
U3
RES, 49.9k ohm, 1%,
0.1W, 0603
IC, High-Side
Measurement Current
Shunt Monitor
C0603C100J5 CL10C100JB8
GACTU
NCNC
MM3Z12VST1
G
PBHV9050T,21
5
CRCW20101R CRM2010-FX00JNEFHP
2003ELF
Rohm
MCR03ERTF4 RC1608F4992
Semiconductor
992
CS
TI
Figure A-2: Bill of Materials
14
High Voltage 12 V - 400 V DC Current Sense Reference Design
Copyright © 2015, Texas Instruments Incorporated
TIDU833- March 2015
www.ti.com
Cautions and Warnings
WARNING:
Voltages of 400V can be possibly deadly. So please proceed with maximum caution and
never handle the device alone.
TIDU833- March 2015
High Voltage 12 V - 400 V DC Current Sense Reference Design
Copyright © 2015, Texas Instruments Incorporated
15
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