AVAGO HCPL-7510

HCPL-7510
Isolated Linear Sensing IC
Data Sheet
Lead (Pb) Free
RoHS 6 fully
compliant
RoHS 6 fully compliant options available;
-xxxE denotes a lead-free product
Description
Features
The HCPL-7510 isolated linear current sensing IC family
is designed for current sensing in low-power electronic
motor drives. In a typical implementa­tion, motor current
flows through an external resistor and the resulting
analog voltage drop is sensed by the HCPL-7510. An
output voltage is created on the other side of the HCPL7510 optical isolation barrier. This single-ended output
voltage is proportional to the motor current. Since
common-mode voltage swings of several hundred volts
in tens of nanoseconds are common in modern switching
inverter motor drives, the HCPL-7510 was designed to
ignore very high common-mode transient slew rates (of
at least 10 kV/µs).
• 15 kV/µs common-mode rejection at Vcm = 1000 V
• Compact, auto-insertable 8-pin DIP package
• 60 ppm/°C gain drift vs. temperature
• –0.6 mV input offset voltage
• 8 µV/°C input offset voltage vs. temperature
• 100 kHz bandwidth
• 0.06% nonlinearity, single-ended amplifier output for
low power application.
• Worldwide safety approval:
UL 1577 (3750 Vrms/1 min.),
CSA and IEC/EN/DIN EN 60747-5-2
(Option 060 only)
• Advanced sigma-delta (S-D)
A/D converter technology
The high CMR capability of the HCPL-7510 isolation
amplifier provides the precision and stability needed to
accurately monitor motor current in high noise motor
control environ­ments, providing for smoother control
(less “torque ripple”) in various types of motor control
applications.
The product can also be used for general analog signal
isolation applications. For general applications, we
recommend the HCPL-7510 (gain tolerance of ±3%).
The HCPL-7510 utilizes sigma-delta (S-D) analog-todigital converter technology to delivery offset and gain
accuracy and stability over time and temper­a­ture. This
performance is delivered in a compact, auto-insert, 8pin DIP package that meets world­wide regulatory safety
standards. (A gull-wing surface mount option 300 is also
available).
Applications
• Low-power inverter current sensing
• Motor phase and rail current sensing
• Switched mode power supply signal isolation
• General purpose low-power current sensing and
monitoring
• General purpose analog signal isolation
Functional Diagram
IDD1
IDD2
VDD1
1
VIN+
2
+
VIN–
3
–
GND1
4
SHIELD
8
VDD2
+
7
VOUT
–
6
VREF
5
GND2
NOTE: A 0.1 µF bypass capacitor must be connected between pins 1 and 4 and between pins 5 and 8.
CAUTION: It is advised that normal static precautions be taken in handling and assembly
of this component to prevent damage and /or degradation which may be induced by ESD.
Ordering Information
HCPL-7510 is UL Recognized with 3750 Vrms for 1 minute per UL1577.
Option
Part number
HCPL-7510
RoHS
Compliant
Non-RoHS
Compliant
-000E
No option
-300E
-300
-500E
-500
-060E
-060
-360E
-360
X
X
-560E
-560
X
X
Package
Surface
Mount
Gull Wing
Tape& Reel
IEC/EN/DIN
EN 60747-5-2 Quantity
50 per tube
300 mil DIP-8
X
X
X
X
50 per tube
X
X
1000 per reel
X
50 per tube
X
50 per tube
X
1000 per reel
To order, choose a part number from the part number column and combine with the desired option from the option
column to form an order entry.
Example 1:
HCPL-7510-560E to order product of Gull Wing Surface Mount package in Tape and Reel packaging
with IEC/EN/DIN EN 60747-5-2 Safety Approval in RoHS compliant.
Example 2:
HCPL-7510 to order product of 300 mil DIP package in tube packaging and non-RoHS compliant.
Option datasheets are available. Contact your Avago sales representative or authorized distributor for information.
Package Outline Drawings
HCPL-7510 Standard DIP Package
9.80 ± 0.25
(0.386 ± 0.010)
8
7
6
5
DATE CODE
A 7510
YYWW
1
1.19 (0.047) MAX.
3.56 ± 0.13
(0.140 ± 0.005)
2
3
7.62 ± 0.25
(0.300 ± 0.010)
4
1.78 (0.070) MAX.
6.35 ± 0.25
(0.250 ± 0.010)
4.70 (0.185) MAX.
0.51 (0.020) MIN.
2.92 (0.115) MIN.
1.080 ± 0.320
(0.043 ± 0.013)
0.65 (0.025) MAX.
2.54 ± 0.25
(0.100 ± 0.010)
5 TYP.
0.20 (0.008)
0.33 (0.013)
DIMENSIONS IN MILLIMETERS AND (INCHES).
NOTE: FLOATING LEAD PROTUSION IS 0.5 mm (20 mils) MAX.
HCPL-7510 Gull Wing Surface Mount Option 300 Outline Drawing
Land Pattern Recommendation
9.80 ± 0.25
(0.386 ± 0.010)
8
6
7
1.016 (0.040)
5
A 7510
6.350 ± 0.25
(0.250 ± 0.010)
YYWW
1
2
3
10.9 (0.430)
4
2.0 (0.080)
1.27 (0.050)
9.65 ± 0.25
(0.380 ± 0.010)
1.780
(0.070)
MAX.
1.19
(0.047)
MAX.
7.62 ± 0.25
(0.300 ± 0.010)
0.20 (0.008)
0.33 (0.013)
3.56 ± 0.13
(0.140 ± 0.005)
1.080 ± 0.320
(0.043 ± 0.013)
2.54
(0.100)
BSC
0.635 ± 0.130
(0.025 ± 0.005)
DIMENSIONS IN MILLIMETERS (INCHES).
TOLERANCES (UNLESS OTHERWISE SPECIFIED): xx.xx = 0.01
xx.xxx = 0.005
NOTE: FLOATING LEAD PROTUSION IS 0.5 mm (20 mils) MAX.
0.635 ± 0.25
(0.025 ± 0.010)
12 NOM.
LEAD COPLANARITY
MAXIMUM: 0.102 (0.004)
Solder Reflow Temperature Profile
300
PREHEATING RATE 3˚C + 1˚C/–0.5˚C/SEC.
REFLOW HEATING RATE 2.5˚C ± 0.5˚C/SEC.
TEMPERATURE (˚C)
200
PEAK
TEMP.
245˚C
PEAK
TEMP.
240˚C
2.5˚C ± 0.5˚C/SEC.
30
SEC.
160˚C
150˚C
140˚C
PEAK
TEMP.
230˚C
SOLDERING
TIME
200˚C
30
SEC.
3˚C + 1˚C/–0.5˚C
100
PREHEATING TIME
150˚C, 90 + 30 SEC.
50 SEC.
TIGHT
TYPICAL
LOOSE
0
0
50
ROOM TEMPERATURE
100
150
TIME (SECONDS)
Note: Use of non-chlorine-activated fluxes is highly recommended.
Recommended Pb-Free IR Profile
TEMPERATURE (˚C)
tp
Tp
217 ˚C
TL
Tsmax
Tsmin
260 +0/-5 ˚C
TIME WITHIN 5 ˚C of ACTUAL
PEAK TEMPERATURE
20-40 SEC.
RAMP-UP
3 ˚C/SEC. MAX.
150 - 200 ˚C
ts
PREHEAT
60 to 180 SEC.
RAMP-DOWN
6 ˚C/SEC. MAX.
tL
60 to 150 SEC.
25
t 25 ˚C to PEAK
TIME (SECONDS)
NOTES:
THE TIME FROM 25 ˚C to PEAK TEMPERATURE = 8 MINUTES MAX.
Tsmax = 200 ˚C, Tsmin = 150 ˚C
Note: Use of non-chlorine-activated fluxes is highly recommended.
200
250
Regulatory Information
The HCPL-7510 has been approved by the following organizations:
IEC/EN/DIN EN 60747-5-2
Approved under:
IEC 60747-5-2:1997 + A1:2002
EN 60747-5-2:2001 + A1:2002
DIN EN 60747-5-2 (VDE 0884 Teil 2):2003-01.
UL
Approved under UL 1577, component recognition
program up to VISO = 3750 VRMS. File E55361.
CSA
Approved under CSA Component Acceptance Notice #5,
File CA 88324.
IEC/EN/DIN EN 60747-5-2 Insulation Characteristics[1]
Description
Symbol
Characteristic Unit
Installation classification per DIN EN 0110-1/1997-04, Table 1
for rated mains voltage ≤ 150 Vrms
for rated mains voltage ≤ 300 Vrms
for rated mains voltage ≤ 600 Vrms
I – IV
I – III
I – II
Climatic Classification
55/100/21
Pollution Degree (DIN EN 0110-1/1997-04)
2
Maximum Working Insulation Voltage
VIORM
891
Vpeak
VPR
1670 Vpeak
VIORM x 1.5 = VPR, type and sample test, tm = 60 sec, partial discharge <5 pC
VPR
1336 Vpeak
Highest Allowable Overvoltage (transient overvoltage tini = 10 sec)
VIOTM
6000 Vpeak
Safety-limiting values – maximum values allowed in the event of a failure.
Case Temperature
Input Current[3]
Output Power[3]
TS
175 IS, INPUT 400 PS, OUTPUT 600 Insulation Resistance at TS, VIO = 500 V
RS
Input to Output Test Voltage, Method b[2]
VIORM x 1.875 = VPR, 100% production test with tm = 1 sec, partial discharge <5 pC
Input to Output Test Voltage, Method a[2]
Ω
800
OUTPUT POWER – PS, INPUT CURRENT – IS
Notes:
1. Insulation characteristics are guaranteed only within the safety maximum ratings which
must be ensured by protective circuits within the application. Surface Mount Classifications
is Class A in accordance with CECC00802.
2. Refer to the optocoupler section of the Isolation and Control Components Designer’s Catalog, under Product Safety Regulations section,
(IEC/EN/DIN EN 60747-5-2) for a detailed description of Method a and Method b partial discharge test profiles.
3. Refer to the following figure for dependence of PS and IS on ambient temperature.
>109 °C
mA
mW
PS (mW)
IS (mA)
700
600
500
400
300
200
100
0
0
25
50
75
100 125 150 175 200
TS – CASE TEMPERATURE – °C
Insulation and Safety Related Specifications
Parameter
Symbol Value Unit
Conditions
Minimum External Air Gap
L(101)
7.4
mm
(clearance)
Measured from input terminals to output terminals,
shortest distance through air.
Minimum External Tracking
L(102)
8.0
mm
(creepage)
Measured from input terminals to output terminals,
shortest distance path along body.
Minimum Internal Plastic Gap
0.5
mm
(internal clearance)
Through insulation distance conductor to conductor,
usually the straight line distance thickness between
the emitter and detector.
Tracking Resistance
(comparative tracking index)
CTI
Isolation Group
>175
V
DIN IEC 112 Part 1
IIIa
Material Group (DIN EN 0110-1/1997-04)
Option 300 - surface mount classification is Class A in accordance with CECC 00802.
Absolute Maximum Ratings
Parameter
Symbol
Min.
Max.
Units
Note
Storage Temperature
TS
–55
125
°C
Operating Temperature
TA
–40
100
°C
Supply Voltage
VDD1, VDD2
0
6
V
Steady-State Input Voltage VIN+, VIN-
–2.0
VDD1 + 0.5
V
Two Second Transient Input Voltage
VIN+, VIN-
–6.0
VDD1 + 0.5
V
Output Voltage
VOUT
–0.5
VDD2 + 0.5
V
Reference Input Voltage
VREF
0.0
VDD2 + 0.5
V
Reference Input Current
IREF
20
mA
Lead Solder Temperature
260°C for 10 sec., 1.6 mm below seating plane
Solder Reflow Temperature Profile
See Package Outline Drawings section
Recommended Operating Conditions
Parameter
Symbol
Min.
Max.
Units
Operating Temperature
TA
–40
85
°C
Supply Voltage
VDD1, VDD2
4.5
5.5
V
Input Voltage (accurate and linear)
VIN+, VIN-
–200
200
mV
Input Voltage (functional)
VIN+, VIN-
–2.0
2.0
V
Reference Input Voltage
VREF
4.0
VDD2
V
Note
Electrical Specifications (DC)
Unless otherwise noted, all typicals and figures are at the nominal operation conditions of VIN+ = 0 V, VIN- = 0 V,
VREF = 4.0 V, VDD1 = VDD2 = 5.0 V and TA = 25°C; all Minimum/Maximum specifications are within the Recommended
Operating Conditions.
Test
Parameter
Symbol
Min.
Typ.
Max.
Units
Conditions Fig. Note
Input Offset Voltage
VOS
Magnitude of Input Offset Change vs. Temperature
∆Vos/∆T
–6
–0.6
6
mV
VIN+ = 0 V
6
8
20
µV/°C
VIN+ = 0 V
7
Gain
G
VREF/0.512 VREF/ VREF/0.512 V/V
– 3%
0.512 + 3%
-0.2 V < VIN+ 8, 9
< 0.2 V
TA = 25°C
1
2
Magnitude of Gain Change ∆G/∆T
60
300
ppm/°C -0.2 V < VIN+ 9
vs. Temperature
< 0.2 V
VOUT 200 mV Nonlinearity
NL200
0.06
0.55
%
-0.2 V < VIN+ 10,
< 0.2 V
11
Magnitude of VOUT 200 mV |dNL200/dT| 0.0004 %/°C
Nonlinearity Change
vs. Temperature
-0.2 V < VIN+ 11
< 0.2 V
VOUT 100 mV Nonlinearity
NL100
0.04
0.4
%
-0.1 V < VIN+ 10,
< 0.1 V
11
Input Supply Current
IDD1
11.7
16
mA
1,2,3
Output Supply Current
IDD2
9.9
16
mA
1,2,3
Reference Voltage Input
Current
IREF
0.26
1
mA
Input Current
IIN+
–0.6
5
µA
Magnitude of Input Bias
Current vs. Termperature
Coefficient
|dIIN/dT|
0.45
nA/°C
Maximum Input Voltage
before VOUT Clipping
|VIN+|MAX
256
700
kΩ
Equivalent Input Impedance RIN
VIN+ = 0 V
mV
3,5
4
5
VOUT Output Impedance
ROUT
15
Ω
Input DC Common-Mode
Rejection Ratio
CMRRIN
63
dB
3,4
7
Switching Specifications (AC)
Over recommended operating conditions unless otherwise specified.
Parameter
Symbol Min. Typ. Max. Units
Test Conditions
VIN to VOUT Signal Delay (50 – 10%) tPD10
2.2
4
µs
VIN+ = 0 mV to 200 mV step 13
VIN to VOUT Signal Delay (50 – 50%) tPD50
3.4
5
µs
VIN to VOUT Signal Delay (50 – 90%) tPD90
5.2
9.9
µs
VOUT Rise Time (10 – 90%)
tR
3.0
7
µs
VOUT Fall Time (10 – 90%)
tF
3.2
7
µs
VOUT Bandwidth (-3 dB)
BW
100
kHz
VOUT Noise
NOUT
31.5
mVrms VIN+ = 0 V
Common Mode Transient
Immunity
CMTI
15
kV/µs
50
10
Fig. Note
VIN+ = 200 mVpk-pk
14
TA = 25°C, VCM = 1000 V
15
Package Characteristics
Parameter
Symbol
Min.
Typ.
Max.
Units
Test Conditions
Input-Output Momentary
Withstand Voltage
VISO
3750
Input-Output Resistance
RI-O
Input-Output Capacitance
CI-O
Fig. Note
Vrms
TA = 25°C, RH < 50%
>109
Ω
VI-O = 500 V
1.4
pF
Freq = 1 MHz
6
Notes:
General Note: Typical values were taken from a sample of nominal units operating at nominal conditions (VDD1 = VDD2 = 5 V, VREF = 4.0 V, Temperature = 25°C) unless otherwise stated. Nominal plots shown from Figure 1 to 11 represented the drift of these nominal units from their nominal
operating conditions.
1. Input Offset Voltage is defined as the DC Input Voltage required to obtain an output voltage of VREF/2.
2. Gain is defined as the slope of the best-fit line of the output voltage vs. the differential input voltage (VIN+ - VIN-) over the specified input range.
Gain is derived from VREF/512 mV; e.g. VREF = 5.0, gain will be 9.77 V/V.
3. Nonlinearity is defined as half of the peak-to-peak output deviation from the best-fit gain line, expressed as a percentage of the full-scale output
voltage range.
4. NL200 is the nonlinearity specified over an input voltage range of ±200 mV.
5. NL100 is the nonlinearity specified over an input voltage range of ±100 mV.
6. In accordance with UL1577, each optocoupler is proof tested by applying an insulation test voltage ≥ 4500 Vrms for 1 second (leakage
detection current limit, II-O ≤ 5 µA). This test is performed before the 100% production test for the partial discharge (method b) shown in
IEC/EN/DIN EN 60747-5-2 Insulation Characteristic Table, if applicable.
7. CMRR is defined as the ratio of the differential signal gain (signal applied differentially between pins 2 and 3) to the common-mode gain (input
pins tied together and the signal applied to both inputs at the same time), expressed in dB.
11
10
IDD1
9
IDD2
8
4.5
4.7
4.9
5.1
5.3
11.0
12.0
10.5
11.0
10.0
9.5
9.0
8.5
IDD1
8.0
IDD2
7.5
7.0
-40
5.5
-20
0
VDD – SUPPLY VOLTAGE – V
60
80
8.0
7.0
4.0
-0.3
100
3.5
2.0
-0.4
-0.6
-0.8
-1.0
∆VOS – INPUT OFFSET CHANGE – µV
0
-0.2
3.0
2.5
2.0
1.5
1.0
0.5
-0.1
0
0.1
0.2
0
-0.3
0.3
VIN – INPUT VOLTAGE – V
-0.1
0
0.1
0.2
0.5
0
-0.5
-1.0
-1.5
0.2
0.3
VDD1
VDD2
0.5
0
-0.5
-1.0
-1.5
4.7
4.9
5.1
5.3
5.5
Figure 6. Input offset change vs. supply voltage.
0.7
0.015
VDD1
0.6
VDD2
0.5
∆GAIN – GAIN CHANGE – %
∆GAIN – GAIN CHANGE – %
1.0
0.1
VDD – SUPPLY VOLTAGE – V
0.020
TYPICAL
MAXIMUM
0
1.0
-2.0
4.5
0.3
Figure 5. Output voltage vs. input voltage.
2.0
-2.0
-40
-0.2
-0.1
1.5
VIN – INPUT VOLTAGE – V
Figure 4. Input current vs. input voltage.
1.5
-0.2
VIN – INPUT VOLTAGE – V
2.5
-0.2
IDD2
Figure 3. Supply current vs. input voltage.
4.0
-1.4
-0.3
IDD1
6.0
0.2
VO – OUTPUT VOLTAGE – V
IIN – INPUT CURRENT – µA
40
9.0
5.0
Figure 2. Supply current vs. temperature.
-1.2
∆VOS – INPUT OFFSET CHANGE – mV
20
10.0
TA – TEMPERATURE – °C
Figure 1. Supply current vs. supply voltage.
0.010
0.005
0
-0.005
0.4
0.3
0.2
0.1
0
-0.1
-0.2
-20
0
20
40
60
80
100
TA – TEMPERATURE – °C
Figure 7. Input offset change vs. temperature.
IDD – SUPPLY CURRENT – mA
12
IDD – SUPPLY CURRENT – mA
IDD – SUPPLY CURRENT – mA
13
-0.010
4.5
4.7
4.9
5.1
5.3
VDD – SUPPLY VOLTAGE – V
Figure 8. Gain change vs. supply voltage.
5.5
-0.3
-40
-20
0
20
40
60
TA – TEMPERATURE – °C
Figure 9. Gain change vs. temperature.
80
100
0.09
0.048
NL – NONLINEARITY – %
NL – NONLINEARITY – %
0.050
0.046
0.044
VDD1
0.042
0.040
4.5
0.08
0.07
0.06
VDD2
4.7
4.9
5.1
5.3
0.05
-40
5.5
-20
Figure 10. Nonlinearity vs. supply voltage.
VDD2
40
60
80
100
6
8
0.1 µF
0.1 µF
2
7
VOUT
HCPL-7510
6
3
4
5
VREF
TPD – PROPAGATION DELAY – µs
1
0.1 µF
20
Figure 11. Nonlinearity vs. temperature.
VDD1
VIN
0
TA – TEMPERATURE – °C
VDD – SUPPLY VOLTAGE – V
5
4
3
2
Tp5010
Tp5050
Tp5090
Trise
1
0
-40
-20
0
20
40
60
80
100
TA – TEMPERATURE – °C
GND2
GND1
Figure 12. Propagation delay test circuit.
Figure 13. Propagation delay vs. temperature.
VDD2
78L05
IN OUT
1
0.1
µF
0.1
µF
1
8
0.1 µF
NORMALIZED GAIN - dB
0
2
3
6
4
5
-3
-4
-6
0.1
PULSE GEN.
1.0
10.0
100.0
1000.0
Figure 14. Bandwidth.
–
+
VCM
FREQUENCY – kHz
Figure 15. CMTI test circuit.
VOUT
HCPL-7510
9V
-2
-5
10
7
-1
VREF
Application Information
Power Supplies and Bypassing
The recommended supply connections are shown in
Figure 16. A floating power supply (which in many applications could be the same supply that is used to drive
the high-side power transistor) is regulated to 5 V using
a simple zener diode (D1); the value of resistor R4 should
be chosen to supply sufficient current from the existing
floating supply. The voltage from the current sensing
resistor (Rsense) is applied to the input of the HCPL-7510
through an RC anti-aliasing filter (R2 and C2). Although
the application circuit is relatively simple, a few recommendations should be followed to ensure optimal performance.
HV+
The power supply for the HCPL-7510 is most often
obtained from the same supply used to power the
power transistor gate drive circuit. If a dedicated supply
is required, in many cases it is possible to add an additional winding on an existing transformer. Otherwise,
some sort of simple isolated supply can be used, such as
a line powered transformer or a high-frequency DC-DC
converter.
An inexpensive 78L05 three-terminal regulator can also
be used to reduce the floating supply voltage to 5 V. To
help attenuate high- frequency power supply noise or
ripple, a resistor or inductor can be used in series with the
input of the regulator to form a low-pass filter with the
regulator’s input bypass capacitor.
+
FLOATING
POSITIVE
SUPPLY
GATE DRIVE
CIRCUIT
R4
R2
MOTOR
D1
5.1 V
39 Ω
+ R1 -
C2
0.01 µF
1 VDD1
2 VIN+
3 VIN4 GND1
RSENSE
HVFigure 16. Recommended supply and sense resistor connections.
11
C1
0.1 µF
HCPL-7510
As shown in Figure 17, 0.1 µF bypass capacitors (C1, C2)
should be located as close as possible to the pins of the
HCPL-7510. The bypass capacitors are required because
of the high-speed digital nature of the signals inside the
HCPL-7510. A 0.01 µF bypass capacitor (C2) is also recommended at the input due to the switched-capacitor
nature of the input circuit. The input bypass capacitor
also forms part of the anti-aliasing filter, which is recommended to prevent high frequency noise from aliasing
down to lower frequencies and interfering with the input
signal. The input filter also performs an important reliability function—it reduces transient spikes from ESD events
flowing through the current sensing resistor.
PC Board Layout
The design of the printed circuit board (PCB) should
follow good layout practices, such as keeping bypass
capacitors close to the supply pins, keeping output
signals away from input signals, the use of ground and
power planes, etc. In addition, the layout of the PCB can
also affect the isolation transient immunity (CMTI) of the
HCPL-7510, due primarily to stray capacitive coupling
between the input and the output circuits. To obtain
optimal CMTI performance, the layout of the PC board
should minimize any stray coupling by maintaining the
maximum possible distance between the input and
output sides of the circuit and ensuring that any ground
or power plane on the PC board does not pass directly
below or extend much wider than the body of the HCPL7510.
FLOATING
POSITIVE
SUPPLY
HV+
GATE DRIVE
CIRCUIT
U1
78L05
IN
C1
0.1 µF
MOTOR
OUT
C2
0.1 µF
R5
68 Ω
+ R1 -
1 VDD1
VDD2 8
2 VIN+
VOUT 7
3 VIN4 GND1
RSENSE
VREF 6
GND2 5
HCPL-7510
HV-
Figure 17. Recommended HCPL-7510 application circuit.
12
C3
0.01 µF
µC
+5 V
A/D
C4
C5
C6 = 150 pF
C4 = C5 = 0.1 µF
C6
VREF
GND
Current Sensing Resistors
The current sensing resistor should have low resistance
(to minimize power dissipation), low inductance (to
minimize di/dt induced voltage spikes which could
adversely affect operation), and reasonable tolerance (to
maintain overall circuit accuracy). Choosing a particular
value for the resistor is usually a compromise between
minimizing power dissipation and maximizing accuracy.
Smaller sense resistance decreases power dissipation,
while larger sense resistance can improve circuit accuracy
by utilizing the full input range of the HCPL-7510.
The first step in selecting a sense resistor is determining
how much current the resistor will be sensing. The graph
in Figure 18 shows the RMS current in each phase of a
three-phase induction motor as a function of average
motor output power (in horsepower, hp) and motor
drive supply voltage. The maximum value of the sense
resistor is determined by the current being measured
and the maximum recommended input voltage of the
isolation amplifier. The maximum sense resistance can
be calculated by taking the maximum recommended
input voltage and dividing by the peak current that the
sense resistor should see during normal operation. For
example, if a motor will have a maximum RMS current
of 10 A and can experience up to 50% overloads during
normal operation, then the peak current is 21.1 A (=10
x 1.414 x 1.5). Assuming a maximum input voltage of
200 mV, the maximum value of sense resistance in this
case would be about 10 mΩ. The maximum average
power dissipation in the sense resistor can also be easily
calculated by multiplying the sense resistance times the
square of the maximum RMS current, which is about 1 W
in the previous example. If the power dissipation in the
sense resistor is too high, the resistance can be decreased
below the maximum value to decrease power dissipation.
The minimum value of the sense resistor is limited by
precision and accuracy requirements of the design. As
the resistance value is reduced, the output voltage across
the resistor is also reduced, which means that the offset
and noise, which are fixed, become a larger percentage
of the signal amplitude. The selected value of the sense
resistor will fall somewhere between the minimum and
maximum values, depending on the particular requirements of a specific design.
13
When sensing currents large enough to cause significant
heating of the sense resistor, the temperature coefficient
(tempco) of the resistor can introduce nonlinearity due
to the signal dependent temperature rise of the resistor.
The effect increases as the resistor-to-ambient thermal
resistance increases. This effect can be minimized by
reducing the thermal resistance of the current sensing
resistor or by using a resistor with a lower tempco.
Lowering the thermal resistance can be accomplished
by repositioning the current sensing resistor on the PC
board, by using larger PC board traces to carry away more
heat, or by using a heat sink. For a two-terminal current
sensing resistor, as the value of resistance decreases, the
resistance of the leads become a significant percentage
of the total resistance. This has two primary effects on
resistor accuracy. First, the effective resistance of the
sense resistor can become dependent on factors such
as how long the leads are, how they are bent, how far
they are inserted into the board, and how far solder
wicks up the leads during assembly (these issues will be
discussed in more detail shortly). Second, the leads are
typically made from a material, such as copper, which
has a much higher tempco than the material from which
the resistive element itself is made, resulting in a higher
tempco overall. Both of these effects are eliminated
when a four-terminal current sensing resistor is used.
A four-terminal resistor has two additional terminals
that are Kelvin-connected directly across the resistive
element itself; these two terminals are used to monitor
the voltage across the resistive element while the other
two terminals are used to carry the load current. Because
of the Kelvin connection, any voltage drops across the
leads carrying the load current should have no impact
on the measured voltage.
Sense Resistor Connections
MOTOR OUTPUT POWER – HORSEPOWER
40
440
380
220
120
35
30
25
20
15
10
5
0
0
5
10
15
20
25
30
35
MOTOR PHASE CURRENT – A (rms)
Figure 18. Motor output horsepower vs. motor phase current and supply
voltage.
When laying out a PC board for the current sensing
resistors, a couple of points should be kept in mind. The
Kelvin connections to the resistor should be brought
together under the body of the resistor and then run very
close to each other to the input of the HCPL-7510; this
minimizes the loop area of the connection and reduces
the possibility of stray magnetic fields from interfering
with the measured signal. If the sense resistor is not
located on the same PC board as the HCPL-7510 circuit,
a tightly twisted pair of wires can accomplish the same
thing. Also, multiple layers of the PC board can be used
to increase current carrying capacity. Numerous platedthrough vias should surround each non-Kelvin terminal of
the sense resistor to help distribute the current between
the layers of the PC board. The PC board should use 2 or
4 oz. copper for the layers, resulting in a current carrying
capacity in excess of 20 A. Making the current carrying
traces on the PC board fairly large can also improve the
sense resistor’s power dissipation capability by acting as a
heat sink. Liberal use of vias where the load current enters
and exits the PC board is also recommended.
14
The recommended method for connecting the HCPL7510 to the current sensing resistor is shown in Figure
17. VIN+ (pin 2 of the HPCL-7510) is connected to the
positive terminal of the sense resistor, while VIN- (pin
3) is shorted to GND1 (pin 4), with the powersupply
return path functioning as the sense line to the negative
terminal of the current sense resistor. This allows a single
pair of wires or PC board traces to connect the HCPL7510 circuit to the sense resistor. By referencing the input
circuit to the negative side of the sense resistor, any load
current induced noise transients on the resistor are seen
as a common- mode signal and will not interfere with the
current-sense signal. This is important because the large
load currents flowing through the motor drive, along with
the parasitic inductances inherent in the wiring of the
circuit, can generate both noise spikes and offsets that are
relatively large compared to the small voltages that are
being measured across the current sensing resistor. If the
same power supply is used both for the gate drive circuit
and for the current sensing circuit, it is very important
that the connection from GND1 of the HCPL-7510 to the
sense resistor be the only return path for supply current
to the gate drive power supply in order to eliminate
potential ground loop problems. The only direct connection between the HCPL-7510 circuit and the gate drive
circuit should be the positive power supply line.
FREQUENTLY ASKED QUESTIONS ABOUT THE HCPL-7510
1. THE BASICS
1.1: Why should I use the HCPL-7510 for sensing
current when Hall-effect sensors are available which
don’t need an isolated supply voltage?
Available in an auto-insertable, 8-pin DIP package, the
HCPL-7510 is smaller than and has better linearity, offset
vs. temperature and Common Mode Rejection (CMR)
performance than most Hall-effect sensors. Additionally, often the required input-side power supply can be
derived from the same supply that powers the gate-drive
optocoupler.
2. SENSE RESISTOR AND INPUT FILTER
2.1: Where do I get 10 mΩ resistors? I have never seen
one that low.
Although less common than values above 10 Ω, there
are quite a few manufacturers of resistors suitable for
measuring currents up to 50 A when combined with the
HCPL-7510. Example product information may be found
at Dale’s web site (http://www.vishay.com/vishay/dale)
and Isotek’s web site (http://www.isotekcorp.com) and
Iwaki Musen Kenkyusho’s website (http://www.iwakimusen.co.jp) and Micron Electric’s website (http://www.
micron-e.co.jp).
2.2: Should I connect both inputs across the sense
resistor instead of grounding VIN- directly to pin 4?
2. The input bandwidth is changed as a result of this
different R-C filter configuration. In fact this is one of
the main reasons for changing the input-filter R-C time
constant.
3. (Filter capacitance:) The input capacitance of the HCPL7510 is approximately 1.5 pF. For proper o p e r a t i o n
the switching input-side sampling capacitors must
be charged from a relatively fixed (low impedance)
voltage source. Therefore, if a filter capacitor is used
it is best for this capacitor to be a few orders of
magnitude greater than the CINPUT (A value of at least
100 pF works well.)
2.4: How do I ensure that the HCPL-7510 is not
destroyed as a result of short circuit conditions which
cause voltage drops across the sense resistor that
exceed the ratings of the HCPL-7510’s inputs?
Select the sense resistor so that it will have less than 5 V
drop when short circuits occur. The only other requirement is to shut down the drive before the sense resistor
is damaged or its solder joints melt. This ensures that the
input of the HCPL-7510 can not be damaged by sense
resistors going open-circuit.
3. ISOLATION AND INSULATION
3.1: How many volts will the HCPL-7510 withstand?
This is not necessary, but it will work. If you do, be sure to
use an RC filter on both pin 2 (VIN+) and pin 3 (VIN-) to
limit the input voltage at both pads.
The momentary (1 minute) withstand voltage is 3750 V
rms per UL 1577 and CSA Component Acceptance Notice
#5.
2.3: Do I really need an RC filter on the input? What is
it for? Are other values of R and C okay?
4. ACCURACY
The input anti-aliasing filter (R=39 Ω, C=0.01 µF) shown in
the typical application circuit is recommended for filtering
fast switching voltage transients from the input signal.
(This helps to attenuate higher signal frequencies which
could otherwise alias with the input sampling rate and
cause higher input offset voltage.)
No. The LED is used only to transmit a digital pattern.
Avago Technologies has accounted for LED degradation
in the design of the product to ensure long life.
Some issues to keep in mind using different filter resistors
or capacitors are:
1. (Filter resistor:) The equivalent input resistance for
HCPL-7510 is around 700 kΩ. It is therefore best to
ensure that the filter resistance is not a significant
percentage of this value; otherwise the offset voltage
will be increased through the resistor divider effect.
[As an example, if Rfilt = 5.5 kΩ, then VOS = (Vin * 1%)
= 2 mV for a maximum 200 mV input and VOS will vary
with respect to Vin.]
4.1: Does the gain change if the internal LED light
output degrades with time?
5. MISCELLANEOUS
5.1: How does the HCPL-7510 measure negative
signals with only a +5 V supply?
The inputs have a series resistor for protection against
large negative inputs. Normal signals are no more than
200 mV in amplitude. Such signals do not forward bias
any junctions sufficiently to interfere with accurate
For product information and a complete list of distributors, please go to our web site: www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Limited in the United States and other countries.
Data subject to change. Copyright © 2006 Avago Technologies Limited. All rights reserved. Obsoletes 5989-2162EN
AV02-0951EN - January 3, 2008