Operation and application of the CSA-1V old 529 DownloadLink 5314

Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Operation and application of the
Sentron CSA-1V-SO surface mount
Current Sensor
Contents
Topic
Page
Introduction
Basic Operation
Basic Electrical Connections
Current-Voltage transfer functions
Accuracy considerations
Saturation Limits
Accommodating various current limits
High output, improved accuracy midrange current measurements
Stray magnetic field interference
Shielding
Multiple current circuits
9
Response time
Interface circuits
Test PCB’s
Conversion Table for common magnetic terms
14
2
2
2
3
5
5
5
7
8
9
11
11
12
1
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Introduction
B = 4π ⋅10−7
The CSA-1V is an integrated circuit combining Hall
devices and Sentron’s patented IMC* Hall
technology. The Hall-sensor is fabricated using a
conventional CMOS technology with an additional
ferromagnetic layer. The ferromagnetic layer is used
as a magnetic flux concentrator providing a magnetic
gain of about 10, to increase the output signal without
increasing the inherent sensor electrical noise. The
CSA-1V is a SOIC-8 packaged device suitable for
surface mount PCB construction and miniaturization.
The CSA-1V is a very simple device to use and
provides an analog output voltage proportional to the
magnetic field generated by the current flowing
through a conductor near the IC. The IC can sense
DC currents as well as AC currents up to 100
kHz.
It is particularly appropriate for on-board DC
current measurement with ohmic isolation, fast
response, small package size and low assembly
cost.
Vs
20A
⋅
= 2. 0 mT
Am 2π ⋅ 0.002 m
The CSA-1V can be used to measure current in an
adjacent wire as shown in Figure 1 or in PCB trace
conductors mounted below the IC as shown in Figure
2. The output vs. direction of current will be reversed
for these two illustrations because the direction of the
magnetic field is dependant on whether the IC is
above the wire or below it, see figure 5.
Figure 1- Sensing current in a conductor
Basic operation.
The CSA-1V senses current by converting the
magnetic field generated by current flowing through
a conductor to a voltage which is proportional to that
field.
The magnetic field at distance r from an ideally thin,
straight and infinitely long current conductor carrying
a current I is given by
H (r ) =
Basic electrical connections
I
2πr
In a vacuum (or air) the magnetic induction (or flux
density) B can be calculated from H by multiplication
with the permeability
B = µ0 H
withµ0 = 4π ⋅ 10−7
Figure 2 – Sensing current in a PCB trace
Vs
Am
The connection diagram is shown in figure 3. The
CSA-1V has two output configurations; Single ended
output (Vout) which provides a 0 to 5V analog output
with respect to ground and a differential output (Vout
diff) which provides a 0 +/- 2.5 volts with respect to an
internal reference voltage (CO_OUT).
See section on Current to Voltage transfer functions for
direct relationship between current and the CSA-1V
* IMC = Integrated Magnetic Concentrator
Example: Flux density at a distance r = 2 mm from a
current conductor carrying 20 Amperes:
2
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Differential output (pins 1 & 8)
3
V ou t d iff
2
1
0
-1
-2
-3
-10
Figure 3- Basic electrical connection diagram
V out
5.5
5
4.5
4
3.5
3
2.5
2
1.5
1
0.5
0
-0.5
-5
-2.5
0
2.5
-2.5
0
2.5
5
7.5
10
Figure 3b- Differential output configuration – output
swing is 0 +/- 2.5 volts
In both, cases the maximum output should be scaled
to +/- 2.0 volts in order to provide a margin of 0.5
volts from the 0 and 5 volt rails and to prevent
electrical saturation.
The IC is a 5 V device but will operate within
specifications over a +/- 10% variation from the
nominal 5 volt supply. The analog output
characteristics are ratio-metric to supply voltage
which should be considered in the circuit design.
There are many cases where ratio-metric outputs are
desired, however if the output needs to be absolute,
the 5 volt supply voltage should be a regulated and
stable source.
Single ended output (pins 1& 5)
-7.5
-5
Magnetic field
The single ended output is provided between pins 1
and 5. With zero current, the output is nominally at ½
VDD (approximately 2.5 Volts) and will go toward
GND (0 volts) when the current is negative. The
output will go toward VDD (+5 Volts) when the
current is positive. The actual levels will depend on
the mechanical relationship between the sensor and
the current carrying conductor.
-10
-7.5
5
7.5
10
Magnetic field
Figure 3a - Single ended output configuration - output
swing is 0 to 5 volt
The differential output voltage (Vout diff) is provided
between pins 1 and 8. With zero current, the
differential output voltage will be zero and go toward
– 2.5 volts with negative current. The output will go
toward + 2.5 volts when the current is positive.
There are three pins (pins 4, 6 & 7) used for factory
programming and they should be terminated as
shown in the schematic diagram. Pins 4 & 7 should
be terminated to VDD (pin 2) and pin 6, should be
terminated to GND (pin 5).
It is recommended that a 0.01 to 0.1 uF ceramic
capacitor be placed across the supply and ground as
close as possible to the IC.
Current -Voltage transfer functions
As shown above, the current to voltage transfer
function is dependant on the distance between the
center of the conductor and the location of the
sensing element in the CSA-1V. It is also affected by
the shape of the conductor.
The sensing area of the IC is located approximately
0.3 mm below the top surface of the IC package, see
3
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
figure 4. The output will produce a positive output
when the magnetic field vector, B, is in the direction
shown.
surface of the IC is 1.0 mm, then the
differential output voltage will be:
0.065
[1.66]
8
7
6
Vout diff ≈
0.060* 25
≅ 1.15 volts
(1 + 0.3)
5
Sensitivity 300V/T
B
2500
2
3
4
0.012
[0.30]
Figure 4- Direction of sensitivity and location of
sensing element
Figure 5 illustrates the magnetic flux lines from two
different examples of conductor shapes. The upper
conductor is a circular wire and the lower is a wide
trace on a PCB. Notice that the direction of the
magnetic flux is reversed for the two conductors
assuming the current is flowing out of the page.
B
d
2000
Sensor output voltage [mV]
1
1A
2A
1500
5A
10A
25A
1000
50A
100A
500
0
0.1
1
10
distance chip surface to conductor center [m m ]
Fig. 6- CSA-1V sensor output voltage is dependent on
the applied current in the current conductor (wire on
the top of the sensor) and the distance between chip
surface and center of the current conductor.
Flat Conductor on PCB under the IC.
PCB conductor
Figure 5 – Shape and direction of magnetic field from
two different conductor shapes.
The CSA-1V output for the flat conductor directly
below the IC can be approximated with the following
equation:
Vout diff ≈ 40
mV
*I
amp
Circular conductor on top of IC.
I = Current in conductor
The CSA-1V differential output voltage for a circular
conductor (wire) located on top of the IC can be
approximated with the following equation:
Vout diff ≈
0.060 * I
(d + 0.3 mm)
d = distance (mm) from chip surface to center of
wire as shown in figure 5 in mm
I = Current in conductor
Example for a wire on top of IC:
If the current in the conductor is 25 amps
and the distance of the wire from the
Example for flat conductor located directly under the
CSA-1V:
If the current, I, is +15 amps (positive current
in this illustration will be current flowing out of
the page), the output will be:
Vout diff ≈ 40
mV
* ( +15 amps ) ≅ 0.60 volts
amp
If the current, I, is -15 amps the differential
output voltage will be:
4
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Vout diff ≈ 40
mV
* ( −15 amps ) ≅ − 0.60 volts
amp
The sensitivity to a flat conductor is greater when
located under the IC than when it’s located on the top
of the IC. This is due to the internal construction of
the IC and the location of the Hall elements with
respect to the integrated magnetic concentrator.
Accuracy considerations
The absolute accuracy of the current measurement is
dependant on several factors. One factor is the
variation in magnetic sensitivity of the CSA-1V
which is +/- 3%. Another factor is the offset voltage
which is specified to 10mV max. Generally speaking,
the higher the current and closeness of the conductor
to the IC, the more accurate the reading will be.
However the limits of electrical and magnetic
saturation need to be respected. At small currents
where the output voltage is low, the 10 mV offset
could contribute to significant error in the
measurement. For example: if the maximum output
voltage is 200 mV, the 10 mV offset could introduce
a 5% error in the measurement. With 3% sensitivity
variation and 5% offset error, the maximum error for
a low current measurement could be as high as 8%.
If the circuit is configured to provide an output of 2.0
volts full scale, then the maximum error would be +/3.5%.
The position of the wire or conductor over the sensor
will have an impact on the accuracy. Any change in
distance from the IC face will change the output and
any side to side movement will also change the
output, thereby contributing to the potential error. A
single wire will be more sensitive to side to side
movement than the flat bus wire. The installation
should assure there is no movement in the physical
location of the conductor and that the conductor
position is the same for each part in a production run.
Increased accuracy can be acquired by using two ICs
as shown in figures 7, 10 & 11 to cancel out the
potential affect of stray fields and then adjusting out
the net DC offset from the two CSA-1Vs. The total
error from this configuration is equal to the error of
the CSA-1V’s sensitivities which is 2%, even at low
current levels.
Saturation Limits
The CSA-1V has excellent linearity from zero to
magnetic fields of 5 mT (50 Gauss) and will reach
electrical saturation at 8.3 mT (83 Gauss). The device
will not be damaged or upset by magnetic fields up to
1T (10,000 Gauss). Therefore high current surges
will not upset or damage the device and recovery
from these conditions occurs in microseconds.
Accommodating various current
ranges.
Low current – 1-2 Amps
To increase the signal level for low current sensing
circuits, a coil like circuit land pattern can be laid out
on the PCB to produce a number of loops as shown in
figure 7. With 4 loops, the magnetic field is increased
by a factor of 4. If two devices are used as shown
below, the outputs can be added together with a
summing circuit illustrated in Fig 7a, thereby
doubling the signal level for a given current. See
figure 7a.
The offset voltage and stray field effect can have a
major impact on the linearity and or linearity for low
current measurements. Therefore it is important to
eliminate or minimize both the DC offset voltage and
any stray field effect that may be present. The
advantage of the two device configuration is common
mode stray fields will be cancelled out and any DC
offset can be adjusted out with the post circuit shown
in figure 7a.
Figure 7 – Increasing signal level with multiple loops
5
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Top Layer
+5V (VDD)
2
4
1
(A-OUT1)
100 K
100 K
U1
C1
GND
7
0.1uF
+Supply
(CSA-1)
5
8
6
100 K
-
Vout
Current trace
+
2
4
7
I
Output =
-[ (A-OUT1) + (A-OUT2)]
1
(A-OUT2)
U2
Figure 8 – Medium range current sensing on PCB
(CSA-1)
5
6
Bottom Layer
8
100 K
2K
100 K
+Supply
Offset null adjustment
Figure 7a- Summing circuit for dual CSA-1V’s in an
output voltage doubling and noise cancellation
configuration
The differential output voltage for a single channel
configuration can be approximated with the following
equation:
Vout diff
mV
≈ 40
* n loops * I amps
amps
Where: n = number of loops
I = current in conductors
The differential output voltage for this configuration
can be approximated by the following equation:
Vout diff ≈ 40
mV
* I amps
amps
Increased output level for medium current
The sensitivity (mV/Amp) can be increased by a factor
of approximately 3 by configuring the PCB layout per
figure 8a. This configuration increases the magnetic
field for a given current by placing the IC within a
loop. This loop is created by using traces on both sides
of a PCB and a jumper wire mounted over the IC.
Example:
If n = 4 and I = +/- 2 amps
Vout diff ≈ 40
mV
* 4 * + / − 2 amps ≅ + / − 0.32 volts
amps
Figure 8a – PCB layout with jumper to increase
sensitivity.
Medium Current – 10 to 20 amps
With a single conductor located on the PCB, currents
in the range of 10 to 20 amps can be measured. The
sizing of the PCB trace needs to take in account the
current handling capability and the total power
dissipated. The PCB trace needs to be thick enough
and wide enough to handle 20 amps.
The current flow through the circuit is shown in
figure 8b. The current flows from left wire through a
trace on the bottom side of the PCB and directly
under the CSA-1V and then up and over the IC
through the jumper wire and back under the CSA-1V
through the top layer trace and out through the right
wire.
6
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Current Flow
Jumper
equal but opposite outputs for stray fields that can be
cancelled out in a post summing circuit. The outputs
from the two CSA-1V’s can be added together to
produce an output sensitivity level of approximately
0.24 V/Amp. A +/- 10 amp current will produce a 2.5
V +/- 2.4 V output. Using the circuit shown in figure
7a , a very accurate high level current measurement
can be made with this configuration.
Figure 8b – Current flow under and around the CSA1V increases magnetic flux density in the chip.
Each conductor creates a magnetic flux that is sensed
by the IC as shown in figure 8c. The three add
together and increase the output signal by a factor of
approximately three. The actual gain depends on the
thickness of the PCB. A 0.03125 thick PCB will
create a 120 mV/ Amp sensitivity level. A 0.0625
thick PCB will have a slightly lower level because the
bottom conductor will be further away and it’s
contribution to the total flux density at the chip will
be less.
Figure 9 - Dual CSA-1V’s with the loop technique to
improve the output level and minimize stray field
effect.
High Current – 20 to 100 amps
High currents can be measured by placing a formed
copper bus bar over the IC as shown in Figure 10.
The distance and size will depend on the full scale
output desired. An approximation of differential
output voltage can be obtained with the following
equation:
Figure 8c- Magnetic flux generated by the jumper,
upper trace and lower trace add together at the
sensitive area of the chip.
Vout diff ≈ 120
mV
* I amps
amps
Vout diff ≈
40
mV
* I amps
Amm
(d + 0.3)
Where d =distance (mm) between conductor center and
CSA-1V surface and I = current in conductor
d
High output, improved accuracy midrange current measurement.
A technique to increase the output and minimize the
stray field effect is shown in figure 9. This technique
incorporates two CSA-1Vs using the scheme shown
in figure 8a. By placing two of these layouts parallel
to each other, but opposite orientation will create
7
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
minimize the interference. By using two devices as
shown in figure 7, 9, 11 & 12, common mode
magnetic fields are cancelled out with the added
advantage of a two fold increase in signal.
Figure 10- High current application using a formed
buss bar over IC.
Example:
If I = +/- 80 amps and d = 1 mm
Placing adjacent wires or PCB traces at right angles
to the IC’s direction of sensitivity can also minimize
the interference, see figure 16. Because the magnetic
field drops off dramatically as a function of distance,
locating the sensor as far away from the source is also
a way of reducing the interference noise.
then
Vout diff ≈
40 * (± 80 )
≈ ±2.46volts
1.3
Another method of measuring high currents on PCB’s
is to use a large thick gauge copper trace capable of
carrying the current on the opposite side of the PCB.
The CSA-1V should be located near the center of the
trace, however because the trace is wide, the output is
less sensitive to location on the PCB.
CSA-1V
Stray fields
Figure 11- Stray fields generate equal and opposite
voltages in the two CSA-1V’s and are cancelled out by
summing the differential outputs from the two devices.
Stray fields
Wide and
thick copper
trace
Figure 10a- High current application using a wide
heavy conductor on the opposite of PCB.
Stray magnetic field interference.
The CSA-1V is an open loop magnetic sensor and
will respond to any magnetic field that is in the
direction of sensitivity (across the chip). Stray fields
from other sources, such as transformers, adjacent
current carrying conductors and magnetic circuitry
can cause noise problems if they are too close to the
sensor. There are several things that can be done to
Figure 12 - This configuration provides excellent stray
field cancellation and significant improvement in the
signal level by making 4 loops per layer for a total of
16 loops.
Implementing stray field cancellation techniques and
signal amplification via multiple loops should be
considered when using the CSA-1V sensor to
measure low currents in the range 1-5 amps. Signal to
noise ratio will be greatly improved with the
incorporation of these techniques.
8
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Shielding
Shield on top
of bus bar
A level of shielding, as shown in fig. 13, can be
obtained by placing a small (approximately 1cm2)
ferromagnetic metal plate on the opposite side of the
conductor from the CSA-1V. Mu-metal is an
excellent choice because of its high permeability at
low field strengths. The plate will have the affect of
concentrating the flux from the field generated by the
current in the trace and provide shielding by
deflecting stray fields from the sensor. An additional
advantage with this shielding technique is an
increased level of signal by a factor of 30% to 50%
for a given current.
CSA-1V
Figure 13a – Adding shielding to the top bus bar
configuration increases signal level significantly and
minimizes the stray field interference.
Multiple current circuits
Field from PCB
CSA-
Current carrying
Stray
PCB
Magnetic shield
Figure 13 – Shielding the CSA-1V from stray fields.
In the configuration using a bus bar, Shielding and
increased signal level can be obtained by placing the shield
on top of the bus bar as shown in Fig 13a.
Often it will be desirable to monitor several currents
on one PCB assembly or there are other current carry
traces near by. Because these devices measure the
magnetic fields generated by the traces or wires
located in close proximity to the sensors, they will
also sense magnetic fields from adjacent conductors
if the fields generated by these conductors are large
enough. It is always good practice to maintain as
much spacing as possible between sensors and
adjacent wires. Alternatively, running traces at right
angles will minimize any pickup from adjacent traces.
The amount of potential interference can be estimated
from the graphs in the following figures.
Figure 14 shows the affect of other current
conductors which are parallel and placed on the same
side of the PCB. The affect is minimal, <5% at
distance of 6 mm (≈1/4”). Figure 15 shows the affect
of current conductors which are parallel but on the
opposite side of the PCB. The worst condition is
when the conductor is placed directly under the IC (d
= 0.0).
9
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Sensitivity to adjacent traces
Sensitivity to conductors on opposite
side of PCB
30
Interference voltage sensitivity
mV/amp
Interferance voltage sensitivity mV/Amp
6
5
4
3
2
1
0
3
5
7
9
11
13
15
17
19
Distance between centerline of traces
(mm)
25
1/32” PCB
20
15
1/16” PCB
10
5
0
0
2
4
6
8
10
12
14
16
18
20
Distance between conductor centerlines
mm
Measured current- I1
Measured current – I1
Adjacent current – I2
Adjacent current- I2
Board
Thickness
Adjacent
conductor
Distance
(mm)
Measured
conductor
Distance between
Conductors- (mm)
Adjacent
Conductor
Figure 14 – Affect of placing current carry conductors
close to each other.
Measured
Conductor
Figure 15– Affect of conductors on opposite side of
PCB. Maximum interference occurs at d = 0.0 mm
10
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
I1
Interface Circuits
I2
The following are some examples of interface circuits
that can be used with the CSA-1V’s to provide level
shifting, differential to single ended and
amplification. The output voltage is ratiometric to the
supply voltage and with VDD = 5.0VDC, it can
swing between 0 and 5 volts (minus 50 mV). It is
recommended that the output level be no more than
2.5 +/- 2.0 volts to prevent electrical saturation and
non-linearity
.
Full Scale output =
0 +/- 2.5 Volts
Figure 16 – Placing traces at right angles will
significantly reduce any cross talk between sensors.
+5V (VDD)
2
Response time
GND
The CSA-1V has a wide bandwidth of 100 KHz and a
response time of 6 microseconds. The response time
of the sensor consists of two components. One is the
Hall elements scan rate which takes up to 3
microseconds and the output driver rise time which is
3 microseconds. See figure 17.
Input current
4
7
C1
U1
0.1uF
(CSA-1V)
5
A-OUT
1
V out = A_OUT - CO_
CO-COM
8
6
Fig 18 – Direct Differential Output
Full Scale output =
2.5 +/- 2.5 Volts
pulse
CSA-1V Output voltage
+5V (VDD)
2
4
7
C1
U1
0.1uF
(CSA-1V)
5
A-OUT
1
V out = A_OUT
8
6
GND
GND
peak value = 80 A
Fig 19 – Direct Single ended Output
Full Scale output =
0 +/- 5.0 Volts
response time
3 µs
rise time
3 µs
200K
+Supply
+5V (VDD)
GND
Figure 17 – CSA-1V response to a current pulse.
24
C1
0.1uF
7
1
U1
(CSA-1V)
5
8
6
A_OUT
100K
100K
+
CO_COM
Vout=
-2*[ (A_OUT) - (CO_OUT)]
200K
Note: DC flow should be
configured to create a negative
going A_OUT
Fig 20 – Differential to single ended, 0-5 V swing for
DC currents
11
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
AN_103 - Single or Dual CSA-1V’s. Medium
Full Scale output =
2.5 +/- 2.5 Volts
2
GND
100K
100K
+5V (VDD)
4
C1
0.1uF
7
(A_OUT1)
1
U1
(CSA-1V)
5
current range ( 5 - 20 Amps). Stray Field cancellation
and double sensitivity with Dual configuration.
+Supply
1K
(CO_OUT1)
8
6
-
Vout
Current trace
100K
2
4
7
1
1K
100K
Note: A_OUT1 and
A_OUT2 are
configured to have
opposite polarities for
the same current
(CO_OUT2)
8
6
Vout =
- [ (A-OUT1) - (A-OUT2)]
+(CO_OUT1 + C_OUT2)/2
(A_OUT2)
U2
(CSA-1V)
5
+
Fig 21 – Differential to single ended, 2-5 V +/- 2.5 swing
for AC currents
Full Scale output =
2.5 +/- 2.5 Volts
+5V (VDD)
GND
24
C1
0.1uF
7
(A-OUT1)
U1
CSA-1V
C1 .1uF
Top View of PCB
U2
CSA-1
100K
100K
1
U1
(CSA-1V)
5
8
6
+Supply
100K
Current trace
Vout=
-[ (A-OUT1) - (A-OUT2)]
+ 1/2 VDD +/- Adj
+
24
5
7
1
U2
(CSA-1V)
8
6
(A-OUT2)
100 K
200
Note: A_OUT1 and A_OUT2
are configured to have
opposite polarities for the
100K
same current
+5V
Offset null adjustment
Fig 22 – Differential to single ended, 2-5 V +/- 2.5 swing
for AC currents with DC offset adjustment.
Botttom view of PCB
AN_106 - Single or Dual CSA-1V’s. Lower current
ranges (0.5 - 5 Amps). Stray field cancellation and
double sensitivity with Dual configuration.
Test PCB’s
The following test PCB’s and application notes are
available for evaluating the CSA-1V in various
current sensing applications and configurations.
Top View of PCB
12
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Typical Assembly
Bottom View of PCB
AN_107 – High current Sensing (Up to 50 Amps)..
AN_108 – Medium current range sensing with loop
to increase sensitivity by a factor of three
(approximately 120 mV/Amp). Typical 2 to 20 Amps
Top View of PCB
Top View of PCB
Bottom View of PCB
Bottom View of PCB
13
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]
Current Sensing with the CSA-1V Hall IC
AN_102
Aug 17, 2004
Jumper Wire
Conversion table for common magnetic units
mT
(Tesla)
=1.0000
1 mT
=0.1000
1G
Assembly view
G
(Gauss)
kA/m
Oe
(Oersted)
=10.000
=0.7960*
=10.000*
=1.000
=0.0796*
=1.000*
1
kA/m
=1.2560*
=12.560*
=1.0000
=12.560
1 Oe
=0.1000*
=1.0000*
=0.0796
=1.000
* in free air
AN_109 – Medium to High current range sensing of
currents in wires. Typical >10 Amps
Top view of PCB
Typical assembly with Wire
14
SENTRON AG, Baarerstrasse 73, CH-6300, Zug, SWITZERLAND Tel: +41 41 7112170 Fax: +41 41 7112188. Email: [email protected]
GMW P.O. Box 2578, Redwood City, CA 94064, USA. Tel+1 (650) 802-8292. Fax: +1 (650) 802-8298. Email: [email protected]