Current Sense Circuit Collection

Application Note 105
December 2005
Current Sense Circuit Collection
Making Sense of Current
Tim Regan, Jon Munson
Greg Zimmer, Michael Stokowski
INTRODUCTION
Sensing and/or controlling current flow is a fundamental requirement in many electronics systems, and the
techniques to do so are as diverse as the applications
themselves. This Application Note compiles solutions to
current sensing problems and organizes the solutions by
general application type. These circuits have been culled
from a variety of Linear Technology documents.
Circuits Organized by General Application
Each chapter collects together applications that tend to
solve a similar general problem, such as high side current
sensing, or negative supply sensing. The chapters are titled
accordingly. In this way, the reader has access to many
possible solutions to a particular problem in one place.
It is unlikely that any particular circuit shown will exactly
meet the requirements for a specific design, but the suggestion of many circuit techniques and devices should
prove useful. To avoid duplication, circuits relevant to
multiple chapters may appear in one location.
L, LT, LTC, LTM, Linear Technology, the Linear logo, Over-The-Top and TimerBlox are
registered trademarks and Hot Swap is a trademark of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
CIRCUIT COLLECTION INDEX
n
n
n
n
n
n
n
n
Current Sense Basics
High Side
Low Side
Negative Voltage
Unidirectional
Bidirectional
AC
DC
n
n
n
n
n
n
n
Level Shifting
High Voltage
Low Voltage
High Current (100mA to Amps)
Low Current (Picoamps to Milliamps)
Motors and Inductive Loads
Batteries
n
n
n
n
n
n
High Speed
Fault Sensing
Digitizing
Current Control
Precision
Wide Range
an105fa
AN105-1
Application Note 105
CURRENT SENSE BASICS
This chapter introduces the basic techniques used for
sensing current. It serves also as a definition of common
terms. Each technique has advantages and disadvantages
and these are described. The types of amplifiers used to
implement the circuits are provided.
LOW SIDE CURRENT SENSING (Figure 1)
Current sensed in the ground return path of the power
connection to the monitored load. Current generally flows
in just one direction (unidirectional). Any switching is
performed on the load-side of monitor.
DC VSUPPLY
ILOAD
VCC
LOAD
+
RSENSE
ISENSE
OUTPUT ≈ ILOAD
High Side Advantages
Load is grounded
Load not activated by accidental short at power connection
n High load current caused by short is detected
n
n
High Side Disadvantages
High input common mode voltages (often very high)
Output needs to be level shifted down to system
operating voltage levels
n
n
FULL-RANGE (HIGH AND LOW SIDE)
CURRENT SENSING (Figure 3)
Bidirectional current sensed in a bridge driven load, or unidirectional high side connection with a supply side switch.
DC VSUPPLY
–
VCC
Figure 1. Low Side Current Sensing
Low Side Advantages
LOAD
Low input common mode voltage
Ground referenced output voltage
n Easy single-supply design
n
RSENSE
ILOAD
+
ISENSE
OUTPUT ∝ ILOAD
–
n
Low Side Disadvantages
Load lifted from direct ground connection
Load activated by accidental short at ground end load
switch
n High load current caused by short is not detected
n
Figure 3. Full-Range (High And Low Side) Current Sensing
n
HIGH SIDE CURRENT SENSING (Figure 2)
Current sensed in the supply path of the power connection
to the monitored load. Current generally flows in just one
direction (unidirectional). Any switching is performed on
the load-side of monitor.
Full-Range Advantages
Only one current sense resistor needed for bidirectional sensing
n Convenient sensing of load current on/off profiles for
inductive loads
n
Full-Range Disadvantages
Wide input common mode voltage swings
Common mode rejection may limit high frequency
accuracy in PWM applications
n
DC VSUPPLY
n
+
RSENSE
ISENSE
OUTPUT ≈ ILOAD
–
ILOAD
LOAD
Figure 2. High Side Current Sensing
an105fa
AN105-2
Application Note 105
HIGH SIDE
This chapter discusses solutions for high side current
sensing. With these circuits the total current supplied
to a load is monitored in the positive power supply line.
LT6100 Load Current Monitor (Figure 4)
This is the basic LT6100 circuit configuration. The internal
circuitry, including an output buffer, typically operates from
a low voltage supply, such as the 3V shown. The monitored supply can range anywhere from VCC + 1.4V up to
48V. The A2 and A4 pins can be strapped various ways to
provide a wide range of internally fixed gains. The input
leads become very Hi-Z when VCC is powered down, so
as not to drain batteries for example. Access to an internal
signal node (Pin 3) provides an option to include a filtering
function with one added capacitor. Small-signal range is
limited by VOL in single-supply operation.
TO LOAD
3V
3
4
8
VS–
VS+
VCC
A2
FIL
VEE
C1
0.1µF
A4
–
2
C2
0.1µF
1
+
5V
7
+
+
RSENSE
6
OUT 5
5V
200Ω
+
0.2Ω
LT1637
200Ω
LOAD
–
Q1
2N3904
0V TO 4.3V
2k
ILOAD
VOUT = (2Ω)(ILOAD)
1637 TA02
Figure 5. “Classic” Positive Supply Rail Current Sense
Over-The-Top Current Sense (Figure 6)
This circuit is a variation on the “classic” high side circuit, but takes advantage of Over-the-Top input capability
to separately supply the IC from a low voltage rail. This
provides a measure of fault protection to downstream
circuitry by virtue of the limited output swing set by the low
voltage supply. The disadvantage is VOS in the Over-theTop mode is generally inferior to other modes, thus less
accurate. The finite current gain of the bipolar transistor
is a source of small gain error.
3V TO 44V
R1
200Ω
OUTPUT
LT6100
6100 F04
3V
RS
0.2Ω
+
LT1637
Figure 4. LT6100 Load Current Monitor
“Classic” Positive Supply Rail Current Sense
(Figure 5)
This circuit uses generic devices to assemble a function
similar to an LTC6101. A rail-to-rail input type op amp is
required since input voltages are right at the upper rail.
The circuit shown here is capable of monitoring up to 44V
applications. Besides the complication of extra parts, the
VOS performance of op amps at the supply is generally not
factory trimmed, thus less accurate than other solutions.
The finite current gain of the bipolar transistor is a small
source of gain error.
ILOAD
LOAD
–
ILOAD =
VOUT
(RS)(R2/R1)
Q1
2N3904
VOUT
(0V TO 2.7V)
R2
2k
1637 TA06
Figure 6. Over-The-Top Current Sense
Self-Powered High Side Current Sense (Figure 7)
This circuit takes advantage of the microampere supply
current and rail-to-rail input of the LT1494. The circuit is
simple because the supply draw is essentially equal to the
load current developed through RA. This supply current is
simply passed through RB to form an output voltage that
is appropriately amplified.
an105fa
AN105-3
Application Note 105
HIGH SIDE
Precision High Side Power Supply Current Sense
(Figure 9)
VS = 2.7V TO 36V
RA
1k
VO = IL
–
RSENSE
1Ω
LOAD
FOR RA = 1k, RB = 10k, RS = 1Ω
VO
= 10 V/A
IL
LT1494
+
+
RB
10k
IL
( RRBA )RS
VO
OUTPUT OFFSET ≈ IS • RB ≈ 10mV
OUTPUT CLIPS AT VS – 2.4V
_
1495 TA09
Figure 7. Self-Powered High Side Current Sense
High Side Current Sense and Fuse Monitor (Figure 8)
The LT6100 can be used as a combination current sensor and fuse monitor. This part includes on-chip output
buffering and was designed to operate with the low supply
voltage (≥2.7V), typical of vehicle data acquisition systems,
while the sense inputs monitor signals at the higher battery bus potential. The LT6100 inputs are tolerant of large
input differentials, thus allowing the blown-fuse operating
condition (this would be detected by an output full-scale
indication). The LT6100 can also be powered down while
maintaining high impedance sense inputs, drawing less
than 1µA max from the battery bus.
TO LOAD
C2
0.1µF
3
4
8
VS–
VS+
VCC
FIL
VEE
+
A4
–
2
1
BATTERY
BUS
7
+
ADC
POWER
≥2.7V
RSENSE
2mΩ FUSE
A2
6
OUT 5
LT6100
OUTPUT
2.5V = 25A
DN374 F02
Figure 8. High Side Current Sense and Fuse Monitor
This is a low voltage, ultrahigh precision monitor featuring
a zero-drift instrumentation amplifier (IA) that provides
rail-to-rail inputs and outputs. Voltage gain is set by the
feedback resistors. Accuracy of this circuit is set by the
quality of resistors selected by the user, small-signal range
is limited by VOL in single-supply operation. The voltage
rating of this part restricts this solution to applications of
<5.5V. This IA is sampled, so the output is discontinuous
with input changes, thus only suited to very low frequency
measurements.
VREGULATOR
1.5mΩ
2
3
–
8
7
LTC6800
+
4
5
6
10k
0.1µF
OUT
100mV/A
OF LOAD
CURRENT
ILOAD
LOAD
150Ω
6800 TA01
Figure 9. Precision High Side Power Supply Current Sense
Positive Supply Rail Current Sense (Figure 10)
This is a configuration similar to an LT6100 implemented
with generic components. A rail-to-rail or Over-the-Top
input op amp type is required (for the first section). The
first section is a variation on the classic high side where
the P-MOSFET provides an accurate output current into
R2 (compared to a BJT). The second section is a buffer
to allow driving ADC ports, etc., and could be configured
with gain if needed. As shown, this circuit can handle up
to 36V operation. Small-signal range is limited by VOL in
single-supply operation.
an105fa
AN105-4
Application Note 105
HIGH SIDE
VCC
Measuring Bias Current Into an Avalanche Photo
Diode (APD) Using an Instrumentation Amplifier
(Figures 12a and 12b)
R1
200Ω
Rs
0.2Ω
–
–
Q1
TP0610L
1/2 LT1366
+
1/2 LT1366
+
ILOAD
LOAD
( )
R2
R1
= ILOAD • 20Ω
VO = ILOAD • RS
R2
20k
1366 TA01
Figure 10. Positive Supply Rail Current Sense
Precision Current Sensing in Supply Rails (Figure 11)
This is the same sampling architecture as used in the
front end of the LTC2053 and LTC6800, but sans op amp
gain stage. This particular switch can handle up to 18V, so
the ultrahigh precision concept can be utilized at higher
voltages than the fully integrated ICs mentioned. This
circuit simply commutates charge from the flying sense
capacitor to the ground-referenced output capacitor so
that under DC input conditions the single-ended output
voltage is exactly the same as the differential across the
sense resistor. A high precision buffer amplifier would
typically follow this circuit (such as an LTC2054). The
commutation rate is user set by the capacitor connected
to Pin 14. For negative supply monitoring, Pin 15 would
be tied to the negative rail rather than ground.
The upper circuit (a) uses an instrumentation amplifier
(IA) powered by a separate rail (>1V above VIN) to measure across the 1kΩ current shunt. The lower figure (b)
is similar but derives its power supply from the APD bias
line. The limitation of these circuits is the 35V maximum
APD voltage, whereas some APDs may require 90V or
more. In the single-supply configuration shown, there is
also a dynamic range limitation due to VOL to consider.
The advantage of this approach is the high accuracy that
is available in an IA.
VIN
10V TO 33V
1k
1%
BIAS OUTPUT
TO APD
35V
–
CURRENT
MONITOR OUTPUT
0mA TO 1mA = 0V TO 1V
LT1789
+
A=1
AN92 F02a
Figure 12a
VIN
10V TO 35V
1N4684
3.3V
1k
1%
BIAS OUTPUT
TO APD
10M
–
CURRENT
MONITOR OUTPUT
0mA TO 1mA = 0V TO 1V
LT1789
POSITIVE OR
NEGATIVE RAIL
I
+
E
RSHUNT
A=1
AN92 F02b
Figure 12b
1/2 LTC6943
11
12
Figure 12. Measuring Bias Current Into an Avalanche Photo
Diode (APD) Using an Instrumentation Amplifier
10
1µF
E I=
1µF
E
RSHUNT
9
6
7
14
15
0.01µF
6943 • TA01b
Figure 11. Precision Current Sensing in Supply Rails
an105fa
AN105-5
Application Note 105
HIGH SIDE
Simple 500V Current Monitor (Figure 13)
Bidirectional Battery-Current Monitor (Figure 14)
Adding two external MOSFETs to hold off the voltage allows
the LTC6101 to connect to very high potentials and monitor
the current flow. The output current from the LTC6101,
which is proportional to the sensed input voltage, flows
through M1 to create a ground referenced output voltage.
This circuit provides the capability of monitoring current
in either direction through the sense resistor. To allow
negative outputs to represent charging current, VEE is
connected to a small negative supply. In single-supply
operation (VEE at ground), the output range may be offset
upwards by applying a positive reference level to VBIAS
(1.25V for example). C3 may be used to form a filter in
conjunction with the output resistance (ROUT) of the part.
This solution offers excellent precision (very low VOS) and
a fixed nominal gain of 8.
DANGER! Lethal Potentials Present — Use Caution
ISENSE
VSENSE
–
500V
+
RSENSE
4
L
O
A
D
RIN
100Ω
3
+ –
2
DANGER!!
HIGH VOLTAGE!!
5
1
LTC6101
62V
CMZ5944B
M1
VOUT
M2
ROUT
4.99k
M1 AND M2 ARE FQD3P50 TM
ROUT
VOUT =
• VSENSE = 49.9 VSENSE
RIN
2M
6101 TA09
Figure 13. Simple 500V Current Monitor
RSENSE
TO
CHARGER/
LOAD
1
FIL–
–
2 VS
3
4
C2
1µF
–5V
DNC
LT1787
15V
VS+ 7
VBIAS 6
ROUT
VEE
C1
1µF
8
FIL+
VOUT
5
OUTPUT
C3*
1000pF
1787 F02
*OPTIONAL
Figure 14. Bidirectional Battery-Current Monitor
AN105-6
an105fa
Application Note 105
HIGH SIDE
LTC6101 Supply Current Included as Load in
Measurement (Figure 15)
This is the basic LTC6101 high side sensing supply-monitor
configuration, where the supply current drawn by the IC is
included in the readout signal. This configuration is useful when the IC current may not be negligible in terms of
overall current draw, such as in low power battery-powered
applications. RSENSE should be selected to limit voltage
drop to <500mV for best linearity. If it is desirable not to
include the IC current in the readout, as in load monitoring, Pin 5 may be connected directly to V+ instead of the
load. Gain accuracy of this circuit is limited only by the
precision of the resistors selected by the user.
or an H-bridge. The circuit is programmable to produce up
to 1mA of full-scale output current into ROUT, yet draws a
mere 250µA supply current when the load is off.
BATTERY BUS
RSENSE
0.01Ω
RIN
100Ω
4
3
–
+
LOAD
2
5
1
LT6101
ROUT
4.99k
V+
VOUT = ILOAD(RSENSE • ROUT/RIN)
RSENSE
DN374 F01
RIN
4
Figure 16. Simple High Side Current Sense Using the LTC6101
3
+
LOAD
VOUT
4.99V = 10A
2
–
High Side Transimpedance Amplifier (Figure 17)
5
LTC6101
1
VOUT
ROUT
6101 F06
Current through a photodiode with a large reverse bias
potential is converted to a ground referenced output voltage directly through an LTC6101. The supply rail can be
as high as 70V. Gain of the I to V conversion, the transimpedance, is set by the selection of resistor RL.
VS
Figure 15. LTC6101 Supply Current Included as Load
in Measurement
Simple High Side Current Sense Using the LTC6101
(Figure 16)
This is a basic high side current monitor using the LTC6101.
The selection of RIN and ROUT establishes the desired gain
of this circuit, powered directly from the battery bus. The
current output of the LTC6101 allows it to be located remotely to ROUT. Thus, the amplifier can be placed directly
at the shunt, while ROUT is placed near the monitoring
electronics without ground drop errors. This circuit has
a fast 1µs response time that makes it ideal for providing
MOSFET load switch protection. The switch element may
be the high side type connected between the sense resistor
and the load, a low side type between the load and ground
CMPZ4697*
(10V)
LASER MONITOR
PHOTODIODE
4.75k
4.75k
4
2
iPD
10k
3
+ –
LTC6101
5
1
VO
RL
VO = IPD • RL
*VZ SETS PHOTODIODE BIAS
VZ + 4 ≤ VS ≤ VZ + 60
6101 TA04
Figure 17. High Side Transimpedance Amplifier
an105fa
AN105-7
Application Note 105
HIGH SIDE
Intelligent High Side Switch (Figure 18)
ISENSE
VSENSE
+
VS
The LT1910 is a dedicated high side MOSFET driver with
built in protection features. It provides the gate drive for a
power switch from standard logic voltage levels. It provides
shorted load protection by monitoring the current flow
to through the switch. Adding an LTC6101 to the same
circuit, sharing the same current sense resistor, provides
a linear voltage signal proportional to the load current for
additional intelligent control.
–
LOAD
RSENSE
RIN
3
4
– +
5
2
V–
LTC6101HV
VLOGIC
48V Supply Current Monitor with Isolated Output and
105V Survivability (Figure 19)
ROUT
VOUT
The HV version of the LTC6101 can operate with a total
supply voltage of 105V. Current flow in high supply voltage
rails can be monitored directly or in an isolated fashion
as shown in this circuit. The gain of the circuit and the
level of output current from the LTC6101 depends on the
particular opto-isolator used.
ANY OPTO-ISOLATOR
V–
N = OPTO-ISOLATOR CURRENT GAIN
R
VOUT = VLOGIC – ISENSE • SENSE • N • ROUT
RIN
6101 TA08
Figure 19. 48V Supply Current Monitor with Isolated Output and
105V Survivability
10µF
63V
VLOGIC
14V
47k
FAULT
OFF ON
3
4
8
5
3
RS
LT1910
1
LTC6101
6
2
1µF
100Ω
1%
4
100Ω
1
VO
4.99k
2
5
SUB85N06-5
L
O
A
D
VO = 49.9 • RS • IL
IL
FOR RS = 5mΩ,
VO = 2.5V AT IL = 10A (FULL-SCALE)
6101 TA07
Figure 18. Intelligent High Side Switch
an105fa
AN105-8
Application Note 105
HIGH SIDE
Precision, Wide Dynamic Range High Side Current
Sensing (Figure 20)
Sensed Current Includes Monitor Circuit Supply
Current (Figure 21)
The LTC6102 offers exceptionally high precision (VOS <
10µV) so that a low value sense resistor may be used.
This reduces dissipation in the circuit and allows wider
variations in current to be accurately measured. In this
circuit, the components are scaled for a 10A measuring
range, with the offset error corresponding to less than
10mA. This is effectively better than 10-bit dynamic range
with dissipation under 100mW.
To sense all current drawn from a battery power source
which is also powering the sensing circuitry requires the
proper connection of the supply pin. Connecting the supply
pin to the load side of the sense resistor adds the supply
current to the load current. The sense amplifier operates
properly with the inputs equal to the device V+ supply.
+
RIN
20Ω
VSENSE
1mΩ
–
+IN
–INS
+
+
5V TO
105V
L
O
A
D
–
–INF
V–
V+
0.1µF
VREG
VOUT
OUT
LTC6102
1µF
5V
LTC2433-1
ROUT
4.99k
TO µP
6102 TA01
VOUT =
ROUT
• VSENSE = 249.5VSENSE
RIN
*PROPER SHUNT SELECTION COULD ALLOW
MONITORING OF CURRENTS IN EXCESS OF 1000A
Figure 20. Precision, Wide Dynamic Range High Side Current Sensing
RSENSE
+IN
VBATT
L
O
A
D
ILOAD
–INS
+ –
V–
V+
0.1µF
OUT
R2
4.99k
VOUT = 49.9 • RSENSE (ILOAD + ISUPPLY)
ISUPPLY
–INF
VREG
LTC6102
R1
100
+
–
VOUT
6102 TA03
Figure 21. Sensed Current Includes Monitor Circuit Supply Current
an105fa
AN105-9
Application Note 105
HIGH SIDE
Wide Voltage Range Current Sensing (Figure 22)
The LT6105 has a supply voltage that is independent from
the potential at the current sense inputs. The input voltage
can extend below ground or exceed the sense amplifier
supply voltage. While the sensed current must flow in just
one direction, it can be sensed above the load, high side,
or below the load, low side. Gain is programmed through
resistor scaling and is set to 50 in the circuit shown.
SOURCE
–0.3V TO 44V
RIN2
VS+
100Ω
0.02Ω
RIN1
100Ω
Smooth Current Monitor Output Signal by Simple
Filtering (Figure 23)
The output impedance of the LT6105 amplifier is defined
by the value of the gain setting output resistor. Bypassing
this resistor with a single capacitor provides first order
filtering to smooth noisy current signals and spikes.
LT6105
+IN
+
–IN
VS–
VOUT
–
V+
ROUT
4.99k
V–
2.85V TO 36V
TO LOAD
VOUT = 1V/A
6105 TA01
VOUT = ( VS+ − VS – ) •
R OUT
R
; A V = OUT ; RIN1 = RIN2 = RIN
RIN
RIN
Figure 22. Wide Voltage Range Current Sensing
2.85V TO 36V
SOURCE
0V TO 44V
LT6105
249Ω
VS+
0.039Ω
+IN
–IN
VS–
249Ω
V+
+
VOUT
–
VOUT = 780mV/A
4.99k
0.22µF
V–
TO LOAD
6105 TA02
Figure 23. Smooth Current Monitor Output Signal by Simple Filtering
an105fa
AN105-10
Application Note 105
HIGH SIDE
Power on Reset Pulse Using a TimerBlox Device
(Figure 24)
up time delay interval, R7 and C1 create a falling edge to
trigger an LTC6993-3 one-shot programmed for 10µs.
This pulse unlatches the comparators. R8 and Q2 will
discharge C1 on loss of the supply to ensure that a full
delay interval occurs when power returns.
When power is first applied to a system the load current
may require some time to rise to the normal operating
level. This can trigger and latch the LT6109 comparator
monitoring undercurrent conditions. After a known start-
5V
9
V+
LT6109-1
RIN
100Ω 10
RSENSE
1
SENSEHI
–
SENSELO
+
ILOAD
R5
10k
V+
OUTA 8
V–
V+
3
R1
8.06k
INC2 7
+
OUTC2
–
R4
10k
5V
R8
30.1k
Q1
2N2222
OPTIONAL:
DISCHARGES C1
WHEN SUPPLY
IS DISCONNECTED
V–
CREATES A DELAYED
C1 10µs RESET PULSE
0.1µF ON START-UP
R7
1M
TRIG
OUT
LTC6993-3
GND
V+
SET
DIV
400mV
REFERENCE
V+
4
OUTC1
2
EN/RST
V+
V–
R2
1.5k
+
–
INC1 6
R3
499Ω
V–
5
610912 TA06
R6
487k
Figure 24. Power on Reset Pulse Using a TimerBlox Device
an105fa
AN105-11
Application Note 105
HIGH SIDE
Accurate Delayed Power on Reset Pulse Using
TimerBlox Devices (Figure 25)
When power is first applied to a system the load current
may require some time to rise to the normal operating
level. This can trigger and latch the LT6109 comparator
monitoring undercurrent conditions. In this circuit an
LTC6994-1 delay timer is used to set an interval longer
than the known time for the load current to settle (1 second in the example) then triggers an LTC6993-3 one-shot
programmed for 10µs. This pulse unlatches the comparators. The power-on delay time is resistor programmable
over a wide range.
5V
9
V+
LT6109-1
RIN
100Ω 10
RSENSE
1
SENSEHI
–
SENSELO
+
ILOAD
R5
10k
V+
OUTA
8
V–
V+
3
R1
8.06k
INC2
+
OUTC2
7
–
V–
R4
10k
R8
100k
C1
0.1µF
1 SECOND DELAY
ON START-UP
10µs RESET PULSE
GENERATOR
TRIG
OUT
LTC6994-1
V+
GND
TRIG
OUT
LTC6993-1
GND
V+
SET
R7
191k
DIV
R6
1M
R5
681k
SET
DIV
C2
0.1µF
400mV
REFERENCE
V+
4
OUTC1
2
EN/RST
V+
V–
R2
1.5k
+
–
INC1
6
R3
499Ω
V–
5
610912 TA07
R4
487k
Figure 25. Accurate Delayed Power on Reset Pulse Using TimerBlox Devices
an105fa
AN105-12
Application Note 105
HIGH SIDE
More High Side Circuits Are Shown in Other Chapters:
FIGURE
TITLE
40
Monitor Current in Positive or Negative Supply Lines
58
Bidirectional Precision Current Sensing
59
Differential Output Bidirectional 10A Current Sense
60
Absolute Value Output Bidirectional Current Sensing
93
High Voltage Current and Temperature Monitoring
104
Using Printed Circuit Sense Resistance
105
High Voltage, 5A High Side Current Sensing in Small Package
120
Bidirectional Current Sensing in H-Bridge Drivers
121
Single Output Provides 10A H-Bridge Current and Direction
123
Monitor Solenoid Current on the High Side
125
Large Input Voltage Range for Fused Solenoid Current Monitoring
126
Monitor both the ON Current and the Freewheeling Current Through a High Side Driven Solenoid
129
Simple DC Motor Torque Control
130
Small Motor Protection and Control
131
Large Motor Protection and Control
136
Coulomb Counting Battery Gas Gauge
142
Monitor Charge and Discharge Currents at One Output
143
Battery Stack Monitoring
145
High Voltage Battery Coulomb Counting
146
Low Voltage Battery Coulomb Counting
147
Single Cell Lithium-Ion Battery Coulomb Counter
148
Complete Single Cell Battery Protection
167
Monitor Current in an Isolated Supply Line
168
Monitoring a Fuse Protected Circuit
169
Circuit Fault Protection with Early Warning and Latching Load Disconnect
170
Use Comparator Output to Initialize Interrupt Routines
171
Current Sense with Over-current Latch and Power-On Reset with Loss of Supply
176
Directly Digitize Current with 16-Bit Resolution
177
Directly Digitizing Two Independent Currents
178
Digitize a Bidirectional Current Using a Single Sense Amplifier and ADC
179
Digitizing Charging and Loading Current in a Battery Monitor
180
Complete Digital Current Monitoring
181
Ampere-Hour Gauge
182
Power Sensing with Built In A-to-D Converter
183
Isolated Power Measurement
184
Fast Data Rate Isolated Power Measurement
185
Adding Temperature Measurement to Supply Power Measurement
186
Current, Voltage and Fuse Monitoring
187
Automotive Socket Power Monitoring
an105fa
AN105-13
Application Note 105
HIGH SIDE
More High Side Circuits Are Shown in Other Chapters:
FIGURE
TITLE
188
Power over Ethernet, PoE, Monitoring
189
Monitor Current, Voltage and Temperature
208
Remote Current Sensing with Minimal Wiring
209
Use Kelvin Connections to Maintain High Current Accuracy
210
Crystal/Reference Oven Controller
211
Power Intensive Circuit Board Monitoring
212
Crystal/Reference Oven Controller
215
0 to 10A Sensing Over Two Ranges
216
Dual Sense Amplifier Can Have Different Sense Resistors and Gain
an105fa
AN105-14
Application Note 105
LOW SIDE
This chapter discusses solutions for low side current
sensing. With these circuits the current flowing in the
ground return or negative power supply line is monitored.
“Classic” High Precision Low Side Current Sense
(Figure 26)
This configuration is basically a standard noninverting
amplifier. The op amp used must support common mode
operation at the lower rail and the use of a zero-drift type
(as shown) provides excellent precision. The output of
this circuit is referenced to the lower Kelvin contact, which
could be ground in a single-supply application. Small-signal
range is limited by VOL for single-supply designs. Scaling
accuracy is set by the quality of the user-selected resistors.
5V
3
4
+
5
–
2
10Ω
TO
MEASURED
CIRCUIT
1
LTC2050HV
10k
OUT
3V/AMP
LOAD CURRENT
IN MEASURED
CIRCUIT, REFERRED
TO –5V
Precision Current Sensing in Supply Rails (Figure 27)
This is the same sampling architecture as used in the
front end of the LTC2053 and LTC6800, but sans op amp
gain stage. This particular switch can handle up to 18V, so
the ultrahigh precision concept can be utilized at higher
voltages than the fully integrated ICs mentioned. This
circuit simply commutates charge from the flying sense
capacitor to the ground-referenced output capacitor so
that under DC input conditions the single-ended output
voltage is exactly the same as the differential across the
sense resistor. A high precision buffer amplifier would
typically follow this circuit (such as an LTC2054). The
commutation rate is user-set by the capacitor connected
to Pin 14. For negative supply monitoring, Pin 15 would
be tied to the negative rail rather than ground.
POSITIVE OR
NEGATIVE RAIL
I
E
RSHUNT
1/2 LTC6943
11
12
3mΩ
10
0.1µF
LOAD CURRENT
– 5V
1µF
2050 TA08
1µF
E I=
E
RSHUNT
9
Figure 26. “Classic” High Precision Low Side Current Sense
6
7
14
15
0.01µF
6943 • TA01b
Figure 27. Precision Current Sensing in Supply Rails
an105fa
AN105-15
Application Note 105
LOW SIDE
op amp. The N-MOSFET drain delivers a metered current
into the virtual ground of the second stage, configured as
a transimpedance amplifier (TIA). The second op amp is
powered from a positive supply and furnishes a positive
output voltage for increasing load current. A dual op amp
cannot be used for this implementation due to the different
supply voltages for each stage. This circuit is exceptionally
precise due to the use of zero-drift op amps. The scaling
accuracy is established by the quality of the user-selected
resistors. Small-signal range is limited by VOL in singlesupply operation of the second stage.
–48V Hot Swap Controller (Figure 28)
This load protecting circuit employs low side current
sensing. The N-MOSFET is controlled to soft-start the
load (current ramping) or to disconnect the load in the
event of supply or load faults. An internal shunt regulator
establishes a local operating voltage.
–48V Low Side Precision Current Sense (Figure 29)
The first stage amplifier is basically a complementary form
of the “classic” high side current sense, designed to operate
with telecom negative supply voltage. The Zener forms an
inexpensive “floating” shunt-regulated supply for the first
GND
GND
(SHORT PIN)
CL
100µF
R3
5.1k
CIN
1µF
1
LOAD
VIN
R1
402k
1%
8
9
R2
32.4k
1%
10
CT
0.33µF
C1
10nF
–48V
+
RIN
3× 1.8k IN SERIES
1/4W EACH
3
EN
LTC4252-1
OV
PWRGD
UV
DRAIN
TIMER
SS
CSS
68nF
GATE
VEE SENSE
*
2
RD 1M
7
6
VOUT
Q1
IRF530S
4
RC
10Ω
CC
18nF
5
RS
0.02Ω
425212 TA01
* M0C207
Figure 28.–48V Hot Swap Controller
Q1
ZETEX
ZVN3320F
100Ω
1%
–
39k
0.01µF
LTC2054
+
100Ω
BZX84C5V1
VZ = 5.1
–48V SUPPLY
+
5V
–
LTC2054
VOUT = 100VSENSE
+
0.1µF
0.003Ω
1% 3W
–
10k
1%
0.1µF
20545 TA01
–48V LOAD
ISENSE, VSENSE
Figure 29.–48V Low Side Precision Current Sense
an105fa
AN105-16
Application Note 105
LOW SIDE
Fast Compact –48V Current Sense (Figure 30)
–48V Current Monitor (Figures 31a and 31b)
This amplifier configuration is essentially the complementary implementation to the classic high side configuration.
The op amp used must support common mode operation
at its lower rail. A “floating” shunt-regulated local supply
is provided by the Zener diode, and the transistor provides
metered current to an output load resistance (1kΩ in this
circuit). In this circuit, the output voltage is referenced to a
positive potential and moves downward when representing increasing –48V loading. Scaling accuracy is set by
the quality of resistors used and the performance of the
NPN transistor.
In this circuit an economical ADC is used to acquire the
sense resistor voltage drop directly. The converter is
powered from a “floating” high accuracy shunt-regulated
supply and is configured to perform continuous conversions. The ADC digital output drives an opto-isolator,
level-shifting the serial data stream to ground. For wider
supply voltage applications, the 13k biasing resistor may
be replaced with an active 4mA current source such as
shown in Figure 31b. For complete dielectric isolation and/
or higher efficiency operation, the ADC may be powered
from a small transformer circuit as shown in Figure 31b.
VOUT = 3V – 0.1Ω • ISENSE
ISENSE = 0A TO 30A
ACCURACY ≈ 3%
VOUT
30.1Ω
1%
–
3.3k
0805
×3
+
R1 REDUCES Q1 DISSIPATION
0.003Ω
1% 3W
–48V SUPPLY
(–42V TO –56V)
–
ISENSE
VS = 3V
LT1797
0.1µF
BZX84C6V8
VZ = 6.8V
1k
1%
R1
4.7k
Q1
FMMT493
+
1797 TA01
SETTLES TO 1% IN 2µs,
1V OUTPUT STEP
–48V LOAD
Figure 30. Fast Compact –48V Current Sense
BAT54S
2×
1µF
13k
5V
100kHz
DRIVE
SELECT R FOR 3mA AT MINIMUM SUPPLY
VOLTAGE, 10mA MAX CURRENT AT MAXIMUM
SUPPLY VOLTAGE
a
+
–
48V
0.010Ω
–48V
4.7µF
45.3k
1
VREF
108mV
1k
2
3
4
5
FULL-SCALE = 5.4A
–48V
10k
LTC2433
10
VCC
FO
VCC
9
REF+
SCK
8
SDO
REF–
7
GND
+
CS
IN
6
GND
IN–
1µF
b
MIDCOM
50480
b
5V
1.54k 2
6N139
3
Figure 31b
1.05k
VCC
MPSA92
8
7
6
4.7µF
DN341 F01
0.1µF LT1029
LOAD
a
LT1790-5
590Ω
a
DATA
(INVERTED)
5
–48V
4.7µF
b
V–
–7V TO –100V
Figure 31a
Figure 31. –48V Current Monitor
an105fa
AN105-17
Application Note 105
LOW SIDE
Simple Telecom Power Supply Fuse Monitor
(Figure 33)
–48V Hot Swap Controller (Figure 32)
This load protecting circuit employs low side current
sensing. The N-MOSFET is controlled to soft-start the
load (current ramping) or to disconnect the load in the
event of supply or load faults. An internal shunt regulator
establishes a local operating voltage.
The LTC1921 provides an all-in-one telecom fuse and
supply voltage monitoring function. Three opto-isolated
status flags are generated that indicate the condition of
the supplies and the fuses.
GND
GND
(SHORT PIN)
CL
100µF
R3
5.1k
CIN
1µF
1
LOAD
VIN
R1
402k
1%
8
9
R2
32.4k
1%
10
3
CT
0.33µF
C1
10nF
–48V
+
RIN
3× 1.8k IN SERIES
1/4W EACH
EN
LTC4252-1
OV
PWRGD
UV
DRAIN
TIMER
SS
GATE
VEE SENSE
CSS
68nF
*
2
7
RD 1M
6
Q1
IRF530S
4
RC
10Ω
CC
18nF
5
VOUT
RS
0.02Ω
425212 TA01
* M0C207
Figure 32.–48V Hot Swap Controller
47k
–48V
RETURN
R1
100k
R2
100k
1
8
2
7
MOC207
3
RTN
OUT F
VA
SUPPLY B
–48V
47k
4
5V
SUPPLY A
STATUS
VB
LTC1921
47k
FUSE B
OUT A
F1
D1
F2
D2
5
6
5V
SUPPLY B
STATUS
MOC207
R3
47k
1/4W
VA
VB
OK
OK
OK
UV OR OV
UV OR OV
OK
UV OR OV UV OR OV
SUPPLY A
STATUS
0
0
1
1
SUPPLY B
STATUS
0
1
0
1
OK: WITHIN SPECIFICATION
OV: OVERVOLTAGE
UV: UNDERVOLTAGE
MOC207
FUSE A
OUT B
SUPPLY A
–48V
5V
FUSE
STATUS
–48V OUT
= LOGIC COMMON
VFUSE A
= VA
= VA
≠ VA
≠ VA
VFUSE B
= VB
≠ VB
= VB
≠ VB
FUSE STATUS
0
1
1
1*
0: LED/PHOTODIODE ON
1: LED/PHOTODIODE OFF
*IF BOTH FUSES (F1 AND F2) ARE OPEN,
ALL STATUS OUTPUTS WILL BE HIGH
SINCE R3 WILL NOT BE POWERED
Figure 33. Simple Telecom Power Supply Fuse Monitor
an105fa
AN105-18
Application Note 105
LOW SIDE
More Low Side Circuits Are Shown in Other Chapters:
FIGURE
TITLE
22
Wide Voltage Range Current Sensing
23
Smooth Current Monitor Output Signal by Simple Filtering
40
Monitor Current in Positive or Negative Supply Lines
122
Monitor Solenoid Current on the Low Side
127
Monitor both the ON Current and the Freewheeling Current In a Low Side Driven Solenoid
168
Monitoring a Fuse Protected Circuit
an105fa
AN105-19
Application Note 105
NEGATIVE VOLTAGE
This chapter discusses solutions for negative voltage
current sensing.
–48V Hot Swap Controller (Figure 35)
This load protecting circuit employs low side current
sensing. The N-MOSFET is controlled to soft-start the
load (current ramping) or to disconnect the load in the
event of supply or load faults. An internal shunt regulator
establishes a local operating voltage.
Telecom Supply Current Monitor (Figure 34)
The LT1990 is a wide common mode range difference
amplifier used here to amplify the sense resistor drop by
ten. To provide the desired input range when using a single
5V supply, the reference potential is set to approximately
4V by the LT6650. The output signal moves downward
from the reference potential in this connection so that a
large output swing can be accommodated.
+
LOAD
IL
5V
48V
–
3
RS
G2
LT1990
2
–77V ≤ VCM ≤ 8V
VOUT = VREF – (10 • IL • RS)
7
+
–
4
G1
5 6
VOUT
8
1
REF
VREF = 4V
4
5
IN
OUT
LT6650
1
GND FB
2
1nF
174k
20k
1990 AI01
1µF
Figure 34. Telecom Supply Current Monitor
GND
GND
(SHORT PIN)
CL
100µF
R3
5.1k
CIN
1µF
1
LOAD
VIN
R1
402k
1%
8
9
R2
32.4k
1%
10
CT
0.33µF
C1
10nF
–48V
+
RIN
3× 1.8k IN SERIES
1/4W EACH
3
EN
LTC4252-1
OV
PWRGD
UV
DRAIN
TIMER
SS
CSS
68nF
GATE
VEE SENSE
*
2
7
RD 1M
6
Q1
IRF530S
4
5
VOUT
RC
10Ω
CC
18nF
RS
0.02Ω
425212 TA01
* M0C207
Figure 35.–48V Hot Swap Controller
an105fa
AN105-20
Application Note 105
NEGATIVE VOLTAGE
–48V Low Side Precision Current Sense (Figure 36)
Fast Compact –48V Current Sense (Figure 37)
The first stage amplifier is basically a complementary form
of the “classic” high side current sense, designed to operate
with telecom negative supply voltage. The Zener forms an
inexpensive “floating” shunt-regulated supply for the first
op amp. The N-MOSFET drain delivers a metered current
into the virtual ground of the second stage, configured as
a transimpedance amplifier (TIA). The second op amp is
powered from a positive supply and furnishes a positive
output voltage for increasing load current. A dual op amp
cannot be used for this implementation due to the different
supply voltages for each stage. This circuit is exceptionally
precise due to the use of zero-drift op amps. The scaling
accuracy is established by the quality of the user-selected
resistors. Small-signal range is limited by VOL in singlesupply operation of the second stage.
This amplifier configuration is essentially the complementary implementation to the classic high side configuration.
The op amp used must support common mode operation
at its lower rail. A “floating” shunt-regulated local supply
is provided by the Zener diode, and the transistor provides
metered current to an output load resistance (1kΩ in this
circuit). In this circuit, the output voltage is referenced to a
positive potential and moves downward when representing increasing –48V loading. Scaling accuracy is set by
the quality of resistors used and the performance of the
NPN transistor.
Q1
ZETEX
ZVN3320F
100Ω
1%
–
39k
0.1µF
100Ω
0.003Ω
1% 3W
–
VOUT = 100VSENSE
LTC2054
+
+
–48V SUPPLY
5V
–
0.01µF
LTC2054
BZX84C5V1
VZ = 5.1
10k
1%
0.1µF
+
20545 TA01
–48V LOAD
ISENSE, VSENSE
Figure 36.–48V Low Side Precision Current Sense
VOUT = 3V – 0.1Ω • ISENSE
ISENSE = 0A TO 30A
ACCURACY ≈ 3%
VOUT
Q1
FMMT493
30.1Ω
1%
–
3.3k
0805
×3
+
–48V SUPPLY
(–42V TO –56V)
ISENSE
+
VS = 3V
LT1797
0.003Ω
1% 3W
–
1k
1%
R1 REDUCES Q1 DISSIPATION
0.1µF
BZX84C6V8
VZ = 6.8V
R1
4.7k
1797 TA01
SETTLES TO 1% IN 2µs,
1V OUTPUT STEP
–48V LOAD
Figure 37. Fast Compact –48V Current Sense
an105fa
AN105-21
Application Note 105
NEGATIVE VOLTAGE
–48V Current Monitor (Figures 38a and 38b)
Simple Telecom Power Supply Fuse Monitor
(Figure 39)
In this circuit an economical ADC is used to acquire the
sense resistor voltage drop directly. The converter is
powered from a “floating” high accuracy shunt-regulated
supply and is configured to perform continuous conversions. The ADC digital output drives an opto-isolator,
level-shifting the serial data stream to ground. For wider
supply voltage applications, the 13k biasing resistor may
be replaced with an active 4mA current source such
as shown to the right. For complete dielectric isolation
and/or higher efficiency operation, the ADC may be powered
from a small transformer circuit as shown in Figure 38b.
The LTC1921 provides an all-in-one telecom fuse and
supply voltage monitoring function. Three opto-isolated
status flags are generated that indicate the condition of
the supplies and the fuses.
5V
100kHz
DRIVE
SELECT R FOR 3mA AT MINIMUM SUPPLY
VOLTAGE, 10mA MAX CURRENT AT MAXIMUM
SUPPLY VOLTAGE
a
13k
+
–
48V
45.3k
1
VREF
108mV
1k
2
0.010Ω
–48V
4.7µF
3
4
5
FULL-SCALE = 5.4A
1µF
MIDCOM
50480
Figure 38b
5V
6N139
1.54k 2
1.05k
VCC
MPSA92
8
7
6
3
4.7µF
b
b
–48V
10k
LTC2433
10
VCC
FO
VCC
9
REF+
SCK
8
SDO
REF–
7
GND
CS
IN+
6
GND
IN–
a
LT1790-5
DN341 F01
0.1µF LT1029
LOAD
BAT54S
2×
1µF
590Ω
a
DATA
(INVERTED)
5
4.7µF
b
V–
–7V TO –100V
–48V
Figure 38a
Figure 38. –48V Current Monitor
47k
–48V
RETURN
R1
100k
R2
100k
1
8
2
7
MOC207
3
RTN
OUT F
VA
SUPPLY B
–48V
47k
4
5V
SUPPLY A
STATUS
VB
LTC1921
47k
FUSE B
OUT A
F1
D1
F2
D2
5
6
5V
SUPPLY B
STATUS
MOC207
R3
47k
1/4W
VA
VB
OK
OK
OK
UV OR OV
UV OR OV
OK
UV OR OV UV OR OV
–48V OUT
= LOGIC COMMON
VFUSE A
= VA
= VA
≠ VA
≠ VA
VFUSE B
= VB
≠ VB
= VB
≠ VB
SUPPLY B
STATUS
0
1
0
1
FUSE STATUS
0
1
1
1*
0: LED/PHOTODIODE ON
1: LED/PHOTODIODE OFF
*IF BOTH FUSES (F1 AND F2) ARE OPEN,
ALL STATUS OUTPUTS WILL BE HIGH
SINCE R3 WILL NOT BE POWERED
Figure 39. Simple Telecom Power Supply Fuse Monitor
AN105-22
SUPPLY A
STATUS
0
0
1
1
OK: WITHIN SPECIFICATION
OV: OVERVOLTAGE
UV: UNDERVOLTAGE
MOC207
FUSE A
OUT B
SUPPLY A
–48V
5V
FUSE
STATUS
an105fa
Application Note 105
NEGATIVE VOLTAGE
Monitor Current in Positive or Negative Supply Lines
(Figure 40)
input connections. In both configurations the output is a
ground referred positive voltage. The negative supply to
the LT6105 must be at least as negative as the supply line
it is monitoring.
Using a negative supply voltage to power the LT6105 creates
a circuit that can be used to monitor the supply current
in a positive or negative supply line by only changing the
VOUT = 1V/A
VOUT
LT6105
4.99k
1%
+IN
100Ω
1%
+15V
POSITIVE
SUPPLY
V–
–15V
V+
5VDC
–IN
20mΩ
1%
+
100Ω
1%
–
TO +15V
LOAD
CURRENT FLOW
CURRENT FLOW
–IN
5VDC
V+
–15V
V–
–
100Ω
1%
20mΩ
1%
LT6105
+
–15V
NEGATIVE
SUPPLY
100Ω
1%
TO –15V
LOAD
+IN
VOUT
6105 F07
VOUT = 1V/A
4.99k
1%
Figure 40. Monitor Current in Positive or Negative Supply Lines
an105fa
AN105-23
Application Note 105
UNIDIRECTIONAL
Unidirectional current sensing monitors the current flowing
only in one direction through a sense resistor.
Unidirectional Current Sensing Mode
(Figures 42a and 42b)
Unidirectional Output into A/D with
Fixed Supply at VS+ (Figure 41)
This is just about the simplest connection in which the
LT1787 may be used. The VBIAS pin is connected to ground,
and the VOUT pin swings positive with increasing sense
current. The output can swing as low as 30mV. Accuracy is
sacrificed at small output levels, but this is not a limitation
in protection circuit applications or where sensed currents
do not vary greatly. Increased low level accuracy can be
obtained by level shifting VBIAS above ground. The level
shifting may be done with resistor dividers, voltage references or a simple diode. Accuracy is ensured if the output
signal is sensed differentially between VBIAS and VOUT.
Here the LT1787 is operating with the LTC1286 A/D converter. The –IN pin of the A/D converter is biased at 1V by
the resistor divider R1 and R2. This voltage increases as
sense current increases, with the amplified sense voltage
appearing between the A/D converters –IN and +IN terminals. The LTC1286 converter uses sequential sampling of
its –IN and +IN inputs. Accuracy is degraded if the inputs
move between sampling intervals. A filter capacitor from
FIL+ to FIL– as well as a filter capacitor from VBIAS to VOUT
may be necessary if the sensed current changes more than
1LSB within a conversion cycle.
RSENSE
TO
LOAD
2.5V TO
60V
C
0.1µF
RSENSE
5V
1
FIL–
LT1787
–
2 VS
3
4
DNC
VS+ 7
VBIAS 6 IOUT
ROUT
VEE
C1
1µF
8
FIL+
1
8
FIL+
LT1787HV
–
VS+ 7
2 VS
5V
R1
20k
5%
3
4
5
CS
LTC1286 CLK
–IN
D
VREF GND OUT
+IN
VOUT
R2
5k
5%
VCC
FIL–
DNC
VBIAS 6
ROUT
VEE
TO µP
5
VOUT
VOUT
1787 F08
Figure 42a
1787 F06
0.30
0.25
OUTPUT VOLTAGE (V)
Figure 41. Unidirectional Output into A/D
with Fixed Supply at VS+
0.20
0.15
0.10
0.05
0
IDEAL
0
0.005 0.010 0.015 0.020
VS+ – VS– (V)
0.025 0.030
1787 F09
Figure 42b
Figure 42. Unidirectional Current Sensing Mode
an105fa
AN105-24
Application Note 105
UNIDIRECTIONAL
16-Bit Resolution Unidirectional Output
into LTC2433 ADC (Figure 43)
Intelligent High Side Switch (Figure 44)
The LT1910 is a dedicated high side MOSFET driver with
built in protection features. It provides the gate drive for a
power switch from standard logic voltage levels. It provides
shorted load protection by monitoring the current flow
to through the switch. Adding an LTC6101 to the same
circuit, sharing the same current sense resistor, provides
a linear voltage signal proportional to the load current for
additional intelligent control.
The LTC2433-1 can accurately digitize signal with source
impedances up to 5kΩ. This LTC6101 current sense circuit
uses a 4.99kΩ output resistance to meet this requirement,
thus no additional buffering is necessary.
ILOAD
VSENSE
–
+
4
L
O
A
D
RIN
100Ω
3
+ –
2
4V TO 60V
5
1µF
5V
2
VOUT
1
LTC6101
4
IN+
1
REF+
VCC
LTC2433-1
ROUT
4.99k
5
IN–
REF– GND
3
ROUT
VOUT =
• VSENSE = 49.9VSENSE
RIN
SCK
SDD
CC
9
8
TO µP
7
FO
6
10
ADC FULL-SCALE = 2.5V
6101 TA06
Figure 43. 16-Bit Resolution Unidirectional Output into LTC2433 ADC
10µF
63V
VLOGIC
14V
47k
FAULT
OFF ON
3
4
RS
LT1910
5
3
4
6
2
1µF
100Ω
1%
8
1
LTC6101
100Ω
1
VO
4.99k
2
5
SUB85N06-5
L
O
A
D
VO = 49.9 • RS • IL
IL
FOR RS = 5mΩ,
VO = 2.5V AT IL = 10A (FULL-SCALE)
6101 TA07
Figure 44. Intelligent High Side Switch
an105fa
AN105-25
Application Note 105
UNIDIRECTIONAL
48V Supply Current Monitor with Isolated Output
and 105V Survivability (Figure 45)
12-Bit Resolution Unidirectional Output
into LTC1286 ADC (Figure 46)
The HV version of the LTC6101 can operate with a total
supply voltage of 105V. Current flow in high supply voltage
rails can be monitored directly or in an isolated fashion
as shown in this circuit. The gain of the circuit and the
level of output current from the LTC6101 depends on the
particular opto-isolator used.
While the LT1787 is able to provide a bidirectional output,
in this application the economical LTC1286 is used to
digitize a unidirectional measurement. The LT1787 has a
nominal gain of eight, providing a 1.25V full-scale output
at approximately 100A of load current.
ISENSE
VSENSE
+
VS
RIN
–
LOAD
RSENSE
4
3
– +
5
2
V–
LTC6101HV
VLOGIC
ROUT
VOUT
ANY OPTO-ISOLATOR
V–
N = OPTO-ISOLATOR CURRENT GAIN
R
VOUT = VLOGIC – ISENSE • SENSE • N • ROUT
RIN
6101 TA08
Figure 45. 48V Supply Current Monitor with Isolated Output and 105V Survivability
TO
LOAD
I = 100A
1
RSENSE
0.0016Ω
8
FIL+
LT1787HV
–
VS+ 7
2 VS
3
4
FIL–
DNC
VEE
VBIAS 6
ROUT
20k
5
VOUT
VOUT = VBIAS + (8 • ILOAD • RSENSE)
C2
0.1µF
2.5V TO 60V
R1
15k
C1
1µF
VREF VCC
CS
+IN
LTC1286 CLK
–IN
D
GND OUT
LT1634-1.25
5V
TO µP
1787 TA01
Figure 46. 12-Bit Resolution Unidirectional Output into LTC1286 ADC
an105fa
AN105-26
Application Note 105
UNIDIRECTIONAL
More Unidirectional Circuits Are Shown in Other Chapters:
FIGURE
TITLE
20
Precision, Wide Dynamic Range High-side Current Sensing
21
Sensed Current Includes Monitor Circuit Supply Current
22
Wide Voltage Range Current Sensing
23
Smooth Current Monitor Output Signal by Simple Filtering
24
Power on Reset Pulse Using a TimerBlox Device
25
Accurate Delayed Power on Reset Pulse Using TimerBlox Devices
40
Monitor Current in Positive or Negative Supply Lines
93
High Voltage Current and Temperature Monitoring
104
Using Printed Circuit Sense Resistance
105
High Voltage, 5A High Side Current Sensing in Small Package
121
Single Output Provides 10A H-Bridge Current and Direction
122
Monitor Solenoid Current on the Low Side
123
Monitor Solenoid Current on the High Side
125
Large Input Voltage Range for Fused Solenoid Current Monitoring
126
Monitor both the ON Current and the Freewheeling Current Through a High Side Driven Solenoid
127
Monitor both the ON Current and the Freewheeling Current In a Low Side Driven Solenoid
129
Simple DC Motor Torque Control
130
Small Motor Protection and Control
131
Large Motor Protection and Control
143
Battery Stack Monitoring
148
Complete Single Cell Battery Protection
167
Monitor Current in an Isolated Supply Line
168
Monitoring a Fuse Protected Circuit
169
Circuit Fault Protection with Early Warning and Latching Load Disconnect
170
Use Comparator Output to Initialize Interrupt Routines
171
Current Sense with Over-current Latch and Power-On Reset with Loss of Supply
176
Directly Digitize Current with 16-Bit Resolution
177
Directly Digitizing Two Independent Currents
180
Complete Digital Current Monitoring
182
Power Sensing with Built In A to D Converter
183
Isolated Power Measurement
184
Fast Data Rate Isolated Power Measurement
185
Adding Temperature Measurement to Supply Power Measurement
186
Current, Voltage and Fuse Monitoring
187
Automotive Socket Power Monitoring
188
Power over Ethernet, PoE, Monitoring
189
Monitor Current, Voltage and Temperature
208
Remote Current Sensing with Minimal Wiring
an105fa
AN105-27
Application Note 105
UNIDIRECTIONAL
More Unidirectional Circuits Are Shown in Other Chapters:
FIGURE
TITLE
210
Crystal/Reference Oven Controller
211
Power Intensive Circuit Board Monitoring
212
Crystal/Reference Oven Controller
215
0A to 10A Sensing Over Two Ranges
an105fa
AN105-28
Application Note 105
BIDIRECTIONAL
Bidirectional current sensing monitors current flow in both
directions through a sense resistor.
Bidirectional Current Sensing with
Single-Ended Output (Figure 47)
Two LTC6101’s are used to monitor the current in a load
in either direction. Using a separate rail-to-rail op amp to
combine the two outputs provides a single ended output.
With zero current flowing the output sits at the reference
potential, one-half the supply voltage for maximum output swing or 2.5V as shown. With power supplied to the
load through connection A the output will move positive
between 2.5V and VCC. With connection B the output
moves down between 2.5V and 0V.
VS
B
A
LOAD
This circuit implements a differential load measurement
for an ADC using twin unidirectional sense measurements.
Each LTC6101 performs high side sensing that rapidly
responds to fault conditions, including load shorts and
MOSFET failures. Hardware local to the switch module
(not shown in the diagram) can provide the protection
logic and furnish a status flag to the control system.
The two LTC6101 outputs taken differentially produce
a bidirectional load measurement for the control servo.
The ground-referenced signals are compatible with most
∆ΣADCs. The ∆ΣADC circuit also provides a “free” integration function that removes PWM content from the
measurement. This scheme also eliminates the need for
analog-to-digital conversions at the rate needed to support switch protection, thus reducing cost and complexity.
–
BATTERY BUS
DIFF
OUTPUT
TO ADC
100Ω
100Ω
I
100Ω
3
A
RS
0.1
100Ω
4
B
Practical H-Bridge Current Monitor Offers Fault
Detection and Bidirectional Load Information
(Figure 48)
ROUT
5
5
–
3
4
LTC6101
RIN
RIN
RS
RS
+
LTC6101
+
FOR IM RANGE = ±100A,
DIFF OUT =±2.5V
–
LTC6101
RS = 1mΩ
RIN = 200Ω
ROUT = 4.99k
LTC6101
+
+
2
1
2.5V
REF
2.5k
1
IM
2
5V
+
DN374 F04
LT1490
2.5V TO 5V (CONNECTION A)
2.5V TO 0V (CONNECTION B)
0A TO 1A IN EITHER DIRECTION
ROUT
VOUT
Figure 48. Practical H-Bridge Current Monitor Offers Fault
Detection and Bidirectional Load Information
–
2.5k
Figure 47. Bidirectional Current Sensing with
Single-Ended Output
an105fa
AN105-29
Application Note 105
BIDIRECTIONAL
Conventional H-Bridge Current Monitor (Figure 49)
Many of the newer electric drive functions, such as steering assist, are bidirectional in nature. These functions are
generally driven by H-bridge MOSFET arrays using pulsewidth modulation (PWM) methods to vary the commanded
torque. In these systems, there are two main purposes for
current monitoring. One is to monitor the current in the
load, to track its performance against the desired command (i.e., closed-loop servo law), and another is for fault
detection and protection features.
A common monitoring approach in these systems is to
amplify the voltage on a “flying” sense resistor, as shown.
Unfortunately, several potentially hazardous fault scenarios
go undetected, such as a simple short to ground at a motor
terminal. Another complication is the noise introduced by
the PWM activity. While the PWM noise may be filtered for
purposes of the servo law, information useful for protection
becomes obscured. The best solution is to simply provide
two circuits that individually protect each half-bridge and
report the bidirectional load current. In some cases, a
smart MOSFET bridge driver may already include sense
resistors and offer the protection features needed. In these
situations, the best solution is the one that derives the load
information with the least additional circuitry.
BATTERY BUS
+
The LT1787’s output is buffered by an LT1495 rail-to-rail
op amp configured as an I/V converter. This configuration
is ideal for monitoring very low voltage supplies. The
LT1787’s VOUT pin is held equal to the reference voltage
appearing at the op amp’s noninverting input. This allows one to monitor supply voltages as low as 2.5V. The
op amp’s output may swing from ground to its positive
supply voltage. The low impedance output of the op amp
may drive following circuitry more effectively than the
high output impedance of the LT1787. The I/V converter
configuration also works well with split supply voltages.
ISENSE
RSENSE
TO
CHARGER/
LOAD
1
FIL–
–
2 VS
3
4
DNC
8
FIL+
LT1787
C1
1µF
2.5V + VSENSE(MAX)
VS+ 7
2.5V
VBIAS 6
ROUT
VEE
5
VOUT
2.5V
1M
5%
C3
1000pF
–
+
VOUT A
A1
LT1495
LT1389-1.25
1787 F07
RS
IM
Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
(Figure 50)
Figure 50. Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
+
–
DIFF
AMP
DN374 F03
Figure 49. Conventional H-Bridge Current Monitor
an105fa
AN105-30
Application Note 105
BIDIRECTIONAL
Battery Current Monitor (Figure 51)
Fast Current Sense with Alarm (Figure 52)
One LT1495 dual op amp package can be used to establish
separate charge and discharge current monitoring outputs.
The LT1495 features Over-the-Top operation allowing
the battery potential to be as high as 36V with only a 5V
amplifier supply voltage.
The LT1995 is shown as a simple unity gain difference
amplifier. When biased with split supplies the input current
can flow in either direction providing an output voltage of
100mV per Amp from the voltage across the 100mΩ sense
resistor. With 32MHz of bandwidth and 1000V/µs slew
rate the response of this sense amplifier is fast. Adding a
simple comparator with a built in reference voltage circuit
such as the LT6700-3 can be used to generate an overcurrent flag. With the 400mV reference the flag occurs at 4A.
IL
CHARGE
RSENSE
0.1Ω
DISCHARGE
–
A2
1/2 LT1495
RA
RA
RA
2N3904
DISCHARGE
OUT
RB
12V
5V
RA
A1
1/2 LT1495
+
2N3904
CHARGE
OUT
VO = IL
RB
15V
15V TO –15V
–
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
I
P1
0.1Ω LT1995
G=1
M1
–15V
LT6700-3
10k
REF
SENSE
OUTPUT
100mV/A
10k
+
–
FLAG
OUTPUT
4A LIMIT
400mV
1995 TA05
Figure 51. Battery Current Monitor
Figure 52. Fast Current Sense with Alarm
an105fa
AN105-31
+
Application Note 105
BIDIRECTIONAL
Bidirectional Current Sense with Separate
Charge/Discharge Output (Figure 53)
Bidirectional Absolute Value Current Sense
(Figure 54)
In this circuit the outputs are enabled by the direction of
current flow. The battery current when either charging
or discharging enables only one of the outputs. For example when charging, the VOUT D signal goes low since
the output MOSFET of that LTC6101 turns completely off
while the other LT6101, VOUT C, ramps from low to high
in proportion to the charging current. The active output
reverses when the charger is removed and the battery
discharges into the load.
The high impedance current source outputs of two
LTC6101’s can be directly tied together. In this circuit
the voltage at VOUT continuously represents the absolute
value of the magnitude of the current into or out of the
battery. The direction or polarity of the current flow is not
discriminated.
IDISCHARGE
ICHARGE
RSENSE
CHARGER
RIN C
100
RIN D
100
4
+ –
2
L
O
A
D
RIN C
100
RIN D
100
3
3
5
5
1
LTC6101
+
ROUT D
4.99k
DISCHARGING: VOUT D = IDISCHARGE • RSENSE
CHARGING: VOUT C = ICHARGE • RSENSE
(
(
+
VOUT D VOUT C
–
–
4
– +
1
VBATT
2
LTC6101
ROUT C
4.99k
6101 TA02
)
ROUT D
WHEN IDISCHARGE ≥ 0
RIN D
)
ROUT C
WHEN ICHARGE ≥ 0
RIN C
Figure 53. Bidirectional Current Sense with Separate Charge/Discharge Output
IDISCHARGE
ICHARGE
RSENSE
CHARGER
RIN C
RIN D
RIN D
4
L
O
A
D
+ –
2
3
3
5
5
1
LTC6101
RIN C
–
DISCHARGING: VOUT = IDISCHARGE • RSENSE
(
(
1
+
VOUT
– +
4
VBATT
2
LTC6101
ROUT
)
6101 TA05
ROUT
WHEN IDISCHARGE ≥ 0
RIN D
)
ROUT
CHARGING: VOUT = ICHARGE • RSENSE
WHEN ICHARGE ≥ 0
RIN C
Figure 54. Bidirectional Absolute Value Current Sense
an105fa
AN105-32
Application Note 105
BIDIRECTIONAL
Full-Bridge Load Current Monitor (Figure 55)
Low Power, Bidirectional 60V Precision High Side
Current Sense (Figure 56)
The LT1990 is a difference amplifier that features a very
wide common mode input voltage range that can far
exceed its own supply voltage. This is an advantage to
reject transient voltages when used to monitor the current
in a full-bridge driven inductive load such as a motor. The
LT6650 provides a voltage reference of 1.5V to bias up the
output away from ground. The output will move above or
below 1.5V as a function of which direction the current
in the load is flowing. As shown, the amplifier provides
a gain of 10 to the voltage developed across resistor RS.
+VSOURCE
Using a very precise zero-drift amplifier as a pre-amp
allows for the use of a very small sense resistor in a high
voltage supply line. A floating power supply regulates the
voltage across the pre-amplifier on any voltage rail up to
the 60V limit of the LT1787HV circuit. Overall gain of this
circuit is 1000. A 1mA change in current in either direction
through the 10mΩ sense resistor will produce a 10mV
change in the output voltage.
5V
LT1990
900k
10k
8
7
– +
2
1M
3
1M
RS
VREF = 1.5V
IL
IN
OUT
LT6650
GND FB
6
+
4
10k
1nF
54.9k
100k
–
40k
900k
40k
VOUT
5
100k
20k
–12V ≤ VCM ≤ 73V
VOUT = VREF ± (10 • IL • RS)
1
1990 TA01
1µF
Figure 55. Full-Bridge Load Current Monitor
POSITIVE SENSE
10mΩ
5
3
1
BAT54
+
–
VSENSE
LTC1754-5
1N4686
3.9VZ
2
10µF
4
100Ω
6
1µF
0.1µF
10µF
100Ω
3
4
5
+
LTC2054
–
2
PRECISION
BIDIRECTIONAL
GAIN OF 125
1
0.1µF
12.4k
33Ω
2
1
2N5401
ON 5V
OFF 0V
MPSA42
35.7k
POWER SUPPLY
(NOTE: POSITIVE
CURRENT SENSE
INCLUDES CIRCUIT
SUPPLY CURRENT)
PRECISION
BIDIRECTIONAL
HIGH VOLTAGE
LEVEL SHIFT
AND GAIN OF 8
VS–
7
VS+
LT1787HV
8
5
6
VOUT = 2.5V
+1000* VSENSE
4.7µF
2.5V REF
4
20545 TA06
Figure 56. Low Power, Bidirectional 60V Precision High Side Current Sense
an105fa
AN105-33
Application Note 105
BIDIRECTIONAL
Split or Single Supply Operation, Bidirectional Output
into A/D (Figure 57)
Bidirectional Precision Current Sensing (Figure 58)
This circuit uses two LTC6102 devices, one for each direction of current flow through a single sense resistance.
While each output only provides a result in one particular
direction of current, taking the two output signals differentially provides a bipolar signal to other circuitry such
as an ADC. Since each circuit has its own gain resistors,
bilinear scaling is possible (different scaling depending
on direction).
In this circuit, split supply operation is used on both the
LT1787 and LT1404 to provide a symmetric bidirectional
measurement. In the single-supply case, where the LT1787
Pin 6 is driven by VREF, the bidirectional measurement
range is slightly asymmetric due to VREF being somewhat
greater than midspan of the ADC input range.
1Ω
1%
IS = ±125mA
1
VSRCE
≈4.75V
FIL–
–
2 VS
3
VCC
5V
8
FIL+
LT1787
10µF
16V
VS+ 7
VBIAS 6
DNC
20k
VEE 4
VEE
–5V
1
VOUT (±1V)
5
VOUT
CONV
2
7
6
AIN LTC1404 CLK
VREF
5
DOUT
GND
10µF
16V
4
8
3
OPTIONAL SINGLE
SUPPLY OPERATION:
DISCONNECT VBIAS
FROM GROUND
AND CONNECT IT TO VREF.
REPLACE –5V SUPPLY
WITH GROUND.
OUTPUT CODE FOR ZERO
CURRENT WILL BE ~2430
CLOCKING
CIRCUITRY
10µF
16V
DOUT
VEE
–5V
1787 TA02
Figure 57. Split or Single Supply Operation, Bidirectional Output into A/D
ICHARGE
IDISCHARGE
RSENSE
CHARGER
RIN C
100Ω
+IN
VBATT
V–
RIN C
100Ω
–INS
+ –
–INF
–INS
–INF
V+
V+
VREG
LTC6102
RIN D
100Ω
RIN D
100Ω
0.1µF
OUT
0.1µF
+
ROUT C
4.99k
+
VOUT C VOUT D
–
–
+IN
– +
VREG
OUT
V–
L
O
A
D
LTC6102
ROUT D
4.99k
6102 TA02
DISCHARGING: VOUT D = IDISCHARGE • RSENSE
CHARGING: VOUT C = ICHARGE • RSENSE
(
(
)
ROUT D
WHEN IDISCHARGE ≥ 0
RIN D
)
ROUT C
WHEN ICHARGE ≥ 0
RIN C
Figure 58. Bidirectional Precision Current Sensing
AN105-34
an105fa
Application Note 105
BIDIRECTIONAL
Differential Output Bidirectional 10A Current Sense
(Figure 59)
Absolute Value Output Bidirectional Current Sensing
(Figure 60)
The LTC6103 has dual sense amplifiers and each measures
current in one direction through a single sense resistance.
The outputs can be taken together as a differential output
to subsequent circuitry such as an ADC. Values shown
are for 10A maximum measurement.
Connecting an LTC6103 so that the outputs each represent
opposite current flow through a shared sense resistance,
but with the outputs driving a common load, results in a
positive only output function while sensing bidirectionally.
10mΩ
VBATT
+
200Ω
200Ω
LOAD
CHARGER
4V < VBATT < 60V
8
7
6
–INA
+INA
5
–INB
+ –
+INB
– +
VSA
VSB
V–
OUTA
LTC6103
1
4
OUTB
2
+
–
4.99k
DIFFERENTIAL OUTPUT*
±2.5V FS (+ IS CHARGE CURRENT)
4.99k
+OUTPUT MAY BE TAKEN SINGLE ENDED
AS CHARGE CURRENT MONITOR
* –OUTPUT MAY BE TAKEN SINGLE ENDED
AS DISCHARGE CURRENT MONITOR
6103 TA02
OUTPUT SWING MAY BE LIMITED FOR
VBATT BELOW 6V
Figure 59. Differential Output Bidirectional 10A Current Sense
20mΩ
VBATT
+
200Ω
8
7
200Ω
6
–INA
+INA
+ –
CHARGER
5
–INB
+INB
– +
VSA
LTC6103
LOAD
VSB
V–
OUTA
1
4
4.99k
OUTB
2
VOUT
2.5V FS
6103 TA03
Figure 60. Absolute Value Output Bidirectional Current Sensing
an105fa
AN105-35
Application Note 105
BIDIRECTIONAL
More Bidirectional Circuits Are Shown in Other Chapters:
FIGURE
TITLE
104
Using Printed Circuit Sense Resistance
120
Bidirectional Current Sensing in H-Bridge Drivers
124
Monitor H-Bridge Motor Current Directly
128
Fixed Gain DC Motor Current Monitor
136
Coulomb Counting Battery Gas Gauge
142
Monitor Charge and Discharge Currents at One Output
145
High Voltage Battery Coulomb Counting
146
Low Voltage Battery Coulomb Counting
147
Single Cell Lithium-Ion Battery Coulomb Counter
178
Digitize a Bidirectional Current Using a Single Sense Amplifier and ADC
179
Digitizing Charging and Loading Current in a Battery Monitor
181
Ampere-Hour Gauge
209
Use Kelvin Connections to Maintain High Current Accuracy
216
Dual Sense Amplifier Can Have Different Sense Resistors and Gain
an105fa
AN105-36
Application Note 105
AC
Sensing current in AC power lines is quite tricky in the
sense that both the current and voltage are continuously
changing polarity. Transformer coupling of signals to drive
ground referenced circuitry is often a good approach.
Single-Supply RMS Current Measurement (Figure 61)
The LT1966 is a true RMS-to-DC converter that takes a
single-ended or differential input signal with rail-to-rail
range. The output of a PCB mounted current sense trans-
former can be connected directly to the converter. Up to
75A of AC current is measurable without breaking the signal
path from a power source to a load. The accurate operating
range of the circuit is determined by the selection of the
transformer termination resistor. All of the math is built
in to the LTC1966 to provide a DC output voltage that is
proportional to the true RMS value of the current. This is
valuable in determining the power/energy consumption
of AC-powered appliances.
V+
AC CURRENT
75A MAX
50Hz TO 400Hz
LTC1966
IN1
T1
VOUT
10Ω
IN2 OUT RTN
CAVE
1µF
VOUT = 4mVDC/ARMS
100k VSS GND EN
0.1µF
100k
1966 TA08
T1: CR MAGNETICS CR8348-2500-N
www.crmagnetics.com
Figure 61. Single-Supply RMS Current Measurement
More AC Circuits Are Shown in Other Chapters:
FIGURE
TITLE
120
Bidirectional Current Sensing in H-Bridge Drivers
124
Monitor H-Bridge Motor Current Directly
128
Fixed Gain DC Motor Current Monitor
an105fa
AN105-37
Application Note 105
DC
DC current sensing is for measuring current flow that is
changing at a very slow rate.
Micro-Hotplate Voltage and Current Monitor
(Figure 62)
Materials science research examines the properties and
interactions of materials at various temperatures. Some
of the more interesting properties can be excited with
localized nano-technology heaters and detected using the
presence of interactive thin films.
While the exact methods of detection are highly complex
and relatively proprietary, the method of creating localized
heat is as old as the light bulb. Shown is the schematic
of the heater elements of a Micro-hotplate from Boston
Microsystems (www.bostonmicrosystems.com). The
physical dimensions of the elements are tens of microns.
They are micromachined out of SiC and heated with simple
DC electrical power, being able to reach 1000°C without
damage.
The power introduced to the elements, and thereby their
temperature, is ascertained from the voltage-current
product with the LT6100 measuring the current and the
LT1991 measuring the voltage. The LT6100 senses the
current by measuring the voltage across the 10Ω resistor,
applies a gain of 50, and provides a ground referenced
output. The I to V gain is therefore 500mV/mA, which
makes sense given the 10mA full-scale heater current and
the 5V output swing of the LT6100. The LT1991’s task is
the opposite, applying precision attenuation instead of
gain. The full-scale voltage of the heater is a total of 40V
(±20), beyond which the life of the heater may be reduced
in some atmospheres. The LT1991 is set up for an attenuation factor of 10, so that the 40V full-scale differential drive
becomes 4V ground referenced at the LT1991 output. In
both cases, the voltages are easily read by 0V–5V PC I/O
cards and the system readily software controlled.
Battery Current Monitor (Figure 63)
One LT1495 dual op amp package can be used to establish separate charge and discharge current monitoring
outputs. The LT1495 features Over-the-Top operation
allowing the battery potential to be as high as 36V with
only a 5V amplifier supply voltage.
IL
CHARGE
RSENSE
0.1Ω
+
VDR
DISCHARGE
VS–
IHOTPLATE
VS+
A2
1/2 LT1495
+ –
VCC
LT6100
VEE A2 A4
MICRO-HOTPLATE
BOSTON
MICROSYSTEMS
MHP100S-005
+
5V
CURRENT
MONITOR
VOUT = 500mV/mA
RA
RA
RA
2N3904
DISCHARGE
OUT
–
A1
1/2 LT1495
+
2N3904
CHARGE
OUT
V O = IL
RB
5V
M9
M3
M1
LT1991
P1
P3
P9
VOLTAGE
MONITOR
V + – VDR–
VOUT = DR
10
12V
5V
RA
RB
5V
VDR–
–
10Ω
1%
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
Figure 63. Battery Current Monitor
6100 TA06
www.bostonmicrosystems.com
Figure 62. Micro-Hotplate Voltage and Current Monitor
an105fa
AN105-38
Application Note 105
DC
This circuit provides the capability of monitoring current
in either direction through the sense resistor. To allow
negative outputs to represent charging current, VEE is
connected to a small negative supply. In single-supply
operation (VEE at ground), the output range may be offset
upwards by applying a positive reference level to VBIAS
(1.25V for example). C3 may be used to form a filter in
conjunction with the output resistance (ROUT) of the part.
This solution offers excellent precision (very low VOS) and
a fixed nominal gain of 8.
RSENSE
TO
CHARGER/
LOAD
1
FIL–
–
2 VS
3
4
LT1787
C1
1µF
8
15V
VS+ 7
VBIAS 6
DNC
ROUT
VEE
5
VOUT
C2
1µF
–5V
FIL+
VOS performance of op amps at the supply is generally not
factory trimmed, thus less accurate than other solutions.
The finite current gain of the bipolar transistor is a small
source of gain error.
High Side Current Sense and Fuse Monitor (Figure 66)
The LT6100 can be used as a combination current sensor and fuse monitor. This part includes on-chip output
buffering and was designed to operate with the low supply
voltage (≥2.7V), typical of vehicle data acquisition systems,
while the sense inputs monitor signals at the higher battery bus potential. The LT6100 inputs are tolerant of large
input differentials, thus allowing the blown-fuse operating
condition (this would be detected by an output full-scale
indication). The LT6100 can also be powered down while
maintaining high impedance sense inputs, drawing less
than 1µA max from the battery bus.
OUTPUT
TO LOAD
C3*
1000pF
RSENSE
2mΩ FUSE
1
1787 F02
Figure 64. Bidirectional Battery-Current Monitor
“Classic” Positive Supply Rail Current Sense
(Figure 65)
This circuit uses generic devices to assemble a function
similar to an LTC6101. A rail-to-rail input type op amp is
required since input voltages are right at the upper rail.
The circuit shown here is capable of monitoring up to 44V
applications. Besides the complication of extra parts, the
ADC
POWER
≥2.7V
VS+
VS
2
C2
0.1µF
3
4
VCC
FIL
VEE
7
A4
–
*OPTIONAL
+
8
–
BATTERY
BUS
+
Bidirectional Battery-Current Monitor (Figure 64)
6
A2
OUT 5
LT6100
OUTPUT
2.5V = 25A
DN374 F02
Figure 66. High Side Current Sense and Fuse Monitor
5V
200Ω
+
0.2Ω
200Ω
LOAD
LT1637
–
Q1
2N3904
0V TO 4.3V
2k
ILOAD
VOUT = (2Ω)(ILOAD)
1637 TA02
Figure 65. “Classic” Positive Supply Rail Current Sense
an105fa
AN105-39
Application Note 105
DC
Gain of 50 Current Sense (Figure 67)
Dual LTC6101’s Allow High-Low Current Ranging
(Figure 68)
The LT6100 is configured for a gain of 50 by grounding
both A2 and A4. This is one of the simplest current sensing
amplifier circuits where only a sense resistor is required.
ISENSE
VSUPPLY
6.4V TO 48V
RSENSE
+
LT6100 VS
VS–
LOAD
–
+
5V
Using two current sense amplifiers with two values of
sense resistors is an easy method of sensing current over
a wide range. In this circuit the sensitivity and resolution of
measurement is 10 times greater with low currents, less
than 1.2A, than with higher currents. A comparator detects
higher current flow, up to 10A, and switches sensing over
to the high current circuitry.
VCC
FIL
VEE
A2
VOUT
50 • RSENSE • ISENSE
A4
6100 TA04
Figure 67. Gain of 50 Current Sense
VLOGIC
(3.3V TO 5V)
CMPZ4697
7
10k
3
M1
Si4465
VIN
RSENSE HI
10m
ILOAD
VOUT
301
RSENSE LO
100m
301
301
4
+
–
301
2
+ –
LTC6101
3
4
5
2
VIN
1
3
+ –
4.7k
2
5
LTC1540
1
619k
1
LTC6101
7.5k
Q1
CMPT5551
40.2k 6
1.74M
4
8
5
HIGH
RANGE
INDICATOR
(ILOAD > 1.2A)
HIGH CURRENT RANGE OUT
250mV/A
VLOGIC
BAT54C
R5
7.5k
(VLOGIC +5V) ≤ VIN ≤ 60V
LOW CURRENT RANGE OUT
2.5V/A
0 ≤ ILOAD ≤ 10A
6101 F03b
Figure 68. Dual LTC6101’s Allow High-Low Current Ranging
an105fa
AN105-40
Application Note 105
DC
Two Terminal Current Regulator (Figure 69)
The LT1635 combines an op amp with a 200mV reference.
Scaling this reference voltage to a potential across resistor
R3 forces a controlled amount of current to flow from the
+terminal to the –terminal. Power is taken from the loop.
+
2
3
–
IOUT =
+
R1
10M
R4
10k
6
–
–
+
8
R1
R2
R3
–
1.5V
1/2
LT1495
INPUT
CURRENT
4
1
100pF
(R2 + R3)VREF
(R1)(R3)
7
LT1635
power to the circuit with batteries, any voltage potential
at the inputs are handled. The LT1495 is a micropower op
amp so the quiescent current drain from the batteries is
very low and thus no on/off switch is required.
1635 TA05
µA
Figure 69. Two Terminal Current Regulator
The low offset error of the LTC6800 allows for unusually
low sense resistance while retaining accuracy.
1.5mΩ
2
3
–
8
7
LTC6800
+
4
5
6
10k
0.1µF
OUT
100mV/A
OF LOAD
CURRENT
ILOAD
+
R2
9k
1.5V
R3
2k
FULL-SCALE
ADJUST
IS = 3µA WHEN IIN = 0
NO ON/OFF SWITCH
REQUIRED
0µA TO
200µA
1495 TA06
High Side Power Supply Current Sense (Figure 70)
VREGULATOR
1/2
LT1495
LOAD
150Ω
6800 TA01
Figure 70. High Side Power Supply Current Sense
Figure 71. 0nA to 200nA Current Meter
Over-The-Top Current Sense (Figure 72)
This circuit is a variation on the “classic” high side circuit, but takes advantage of Over-the-Top input capability
to separately supply the IC from a low voltage rail. This
provides a measure of fault protection to downstream
circuitry by virtue of the limited output swing set by the low
voltage supply. The disadvantage is VOS in the Over-theTop mode is generally inferior to other modes, thus less
accurate. The finite current gain of the bipolar transistor
is a source of small gain error.
3V TO 44V
R1
200Ω
3V
RS
0.2Ω
LT1637
0nA to 200nA Current Meter (Figure 71)
A floating amplifier circuit converts a full-scale 200nA
flowing in the direction indicated at the inputs to 2V at
the output of the LT1495. This voltage is converted to a
current to drive a 200µA meter movement. By floating the
+
ILOAD
LOAD
–
ILOAD =
VOUT
(RS)(R2/R1)
Q1
2N3904
VOUT
(0V TO 2.7V)
R2
2k
1637 TA06
Figure 72. Over-The-Top Current Sense
an105fa
AN105-41
Application Note 105
DC
Conventional H-Bridge Current Monitor (Figure 73)
Many of the newer electric drive functions, such as steering assist, are bidirectional in nature. These functions are
generally driven by H-bridge MOSFET arrays using pulsewidth modulation (PWM) methods to vary the commanded
torque. In these systems, there are two main purposes for
current monitoring. One is to monitor the current in the
load, to track its performance against the desired command (i.e., closed-loop servo law), and another is for fault
detection and protection features.
A common monitoring approach in these systems is to
amplify the voltage on a “flying” sense resistor, as shown.
Unfortunately, several potentially hazardous fault scenarios
go undetected, such as a simple short to ground at a motor
terminal. Another complication is the noise introduced by
the PWM activity. While the PWM noise may be filtered for
purposes of the servo law, information useful for protection
becomes obscured. The best solution is to simply provide
two circuits that individually protect each half-bridge and
report the bidirectional load current. In some cases, a
smart MOSFET bridge driver may already include sense
resistors and offer the protection features needed. In these
situations, the best solution is the one that derives the load
information with the least additional circuitry.
BATTERY BUS
Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
(Figure 74)
The LT1787’s output is buffered by an LT1495 rail-to-rail
op amp configured as an I/V converter. This configuration
is ideal for monitoring very low voltage supplies. The
LT1787’s VOUT pin is held equal to the reference voltage
appearing at the op amp’s non-inverting input. This allows one to monitor supply voltages as low as 2.5V. The
op amp’s output may swing from ground to its positive
supply voltage. The low impedance output of the op amp
may drive following circuitry more effectively than the
high output impedance of the LT1787. The I/V converter
configuration also works well with split supply voltages.
ISENSE
RSENSE
TO
CHARGER/
LOAD
1
FIL–
–
2 VS
3
4
DNC
8
FIL+
LT1787
C1
1µF
2.5V + VSENSE(MAX)
VS+ 7
2.5V
VBIAS 6
ROUT
VEE
5
VOUT
2.5V
1M
5%
C3
1000pF
–
+
VOUT A
A1
LT1495
LT1389-1.25
1787 F07
+
Figure 74. Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
RS
IM
+
–
DIFF
AMP
DN374 F03
Figure 73. Conventional H-Bridge Current Monitor
an105fa
AN105-42
Application Note 105
DC
Battery Current Monitor (Figure 75)
IL
CHARGE
One LT1495 dual op amp package can be used to establish
separate charge and discharge current monitoring outputs.
The LT1495 features Over-the-Top operation allowing
the battery potential to be as high as 36V with only a 5V
amplifier supply voltage.
DISCHARGE
–
A2
1/2 LT1495
+
Fast Current Sense with Alarm (Figure 76)
The LT1995 is shown as a simple unity-gain difference
amplifier. When biased with split supplies the input
current can flow in either direction providing an output
voltage of 100mV per Amp from the voltage across the
100mΩ sense resistor. With 32MHz of bandwidth and
1000V/µs slew rate the response of this sense amplifier
is fast. Adding a simple comparator with a built in reference voltage circuit such as the LT6700-3 can be used to
generate an over current flag. With the 400mV reference
the flag occurs at 4A.
12V
5V
RA
RA
RA
RA
2N3904
–
A1
1/2 LT1495
+
2N3904
DISCHARGE
OUT
CHARGE
OUT
V O = IL
RB
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
RB
Figure 75. Battery Current Monitor
15V
15V TO –15V
I
P1
0.1Ω LT1995
G=1
M1
Positive Supply Rail Current Sense (Figure 77)
This is a configuration similar to an LT6100 implemented
with generic components. A rail-to-rail or Over-the-Top
input op amp type is required (for the first section). The
first section is a variation on the classic high side where
the P-MOSFET provides an accurate output current into
R2 (compared to a BJT). The second section is a buffer
to allow driving ADC ports, etc., and could be configured
with gain if needed. As shown, this circuit can handle up
to 36V operation. Small-signal range is limited by VOL in
single-supply operation.
RSENSE
0.1Ω
–15V
LT6700-3
10k
REF
SENSE
OUTPUT
100mV/A
10k
+
–
FLAG
OUTPUT
4A LIMIT
400mV
1995 TA05
Figure 76. Fast Current Sense with Alarm
VCC
R1
200Ω
Rs
0.2Ω
–
–
Q1
TP0610L
1/2 LT1366
+
ILOAD
LOAD
R2
20k
1/2 LT1366
+
( )
R2
R1
= ILOAD • 20Ω
VO = ILOAD • RS
1366 TA01
Figure 77. Positive Supply Rail Current Sense
an105fa
AN105-43
Application Note 105
DC
LT6100 Load Current Monitor (Figure 78)
2
8
VS–
VS+
3
A4
A2
FIL
4
OUTPUT
6100 F04
Figure 78. LT6100 Load Current Monitor
V+
V+
VIN
RL
IOUT
+
100Ω
1/2
LT1492
–
Si9410DY
N-CHANNEL
100pF
1k
LTC6101 Supply Current Included as Load in
Measurement (Figure 80)
This is the basic LTC6101 high side sensing supply-monitor
configuration, where the supply current drawn by the IC is
included in the readout signal. This configuration is useful when the IC current may not be negligible in terms of
overall current draw, such as in low power battery-powered
applications. RSENSE should be selected to limit voltage
drop to <500mV for best linearity. If it is desirable not to
include the IC current in the readout, as in load monitoring, Pin 5 may be connected directly to V+ instead of the
load. Gain accuracy of this circuit is limited only by the
precision of the resistors selected by the user.
6
LT6100
1A Voltage-Controlled Current Sink (Figure 79)
This is a simple controlled current sink, where the op amp
drives the N-MOSFET gate to develop a match between
the 1Ω sense resistor drop and the VIN current command.
Since the common mode voltage seen by the op amp is
near ground potential, a “single-supply” or rail-to-rail type
is required in this application.
5V
7
OUT 5
VEE
+
C1
0.1µF
VCC
C2
0.1µF
3V
1
–
+
RSENSE
+
This is the basic LT6100 circuit configuration. The internal
circuitry, including an output buffer, typically operates from
a low voltage supply, such as the 3V shown. The monitored supply can range anywhere from VCC + 1.4V up to
48V. The A2 and A4 pins can be strapped various ways to
provide a wide range of internally fixed gains. The input
leads become very Hi-Z when VCC is powered down, so
as not to drain batteries for example. Access to an internal
signal node (Pin 3) provides an option to include a filtering
function with one added capacitor. Small-signal range is
limited by VOL in single-supply operation.
TO LOAD
V
IOUT = IN
1Ω
tr < 1µs
1Ω
1492/93 TA06
Figure 79. 1A Voltage-Controlled Current Sink
V+
RSENSE
RIN
4
3
+
LOAD
2
–
5
LTC6101
1
VOUT
ROUT
6101 F06
Figure 80. LTC6101 Supply Current Included as Load
in Measurement
an105fa
AN105-44
Application Note 105
DC
V+ Powered Separately from Load Supply (Figure 81)
The inputs of the LTC6101 can function from 1.4V above
the device positive supply to 48V DC. In this circuit the
current flow in the high voltage rail is directly translated
to a 0V to 3V range.
Simple High Side Current Sense Using the LTC6101
(Figure 82)
This is a basic high side current monitor using the LTC6101.
The selection of RIN and ROUT establishes the desired gain
of this circuit, powered directly from the battery bus. The
current output of the LTC6101 allows it to be located remotely to ROUT. Thus, the amplifier can be placed directly
at the shunt, while ROUT is placed near the monitoring
electronics without ground drop errors. This circuit has
a fast 1µs response time that makes it ideal for providing
MOSFET load switch protection. The switch element may
be the high side type connected between the sense resistor
and the load, a low side type between the load and ground
or an H-bridge. The circuit is programmable to produce up
to 1mA of full-scale output current into ROUT, yet draws a
mere 250µA supply current when the load is off.
4.4V TO 48V
SUPPLY
3V
2
LT6100
7
6
A4
A2
+
8 VS
VOUT 5
RSENSE
3mΩ
–
1 VS
LOAD
VEE
FIL
4
3
VOUT = 2.5V
ISENSE = 33A
6100 TA01a
220pF
CONFIGURED FOR GAIN = 25V/V
Figure 81. V+ Powered Separately from Load Supply
BATTERY BUS
RIN
100Ω
4
RSENSE
0.01Ω
3
–
+
LOAD
2
5
1
LT6101
“Classic” High Precision Low Side Current Sense
(Figure 83)
This configuration is basically a standard noninverting
amplifier. The op amp used must support common mode
operation at the lower rail and the use of a zero-drift type
(as shown) provides excellent precision. The output of
this circuit is referenced to the lower Kelvin contact, which
could be ground in a single-supply application. Small-signal
range is limited by VOL for single-supply designs. Scaling
accuracy is set by the quality of the user-selected resistors.
VCC
ROUT
4.99k
VOUT = ILOAD(RSENSE • ROUT/RIN)
VOUT
4.99V = 10A
DN374 F01
Figure 82. Simple High Side Current Sense Using the LTC6101
5V
3
4
+
5
–
2
10Ω
TO
MEASURED
CIRCUIT
1
LTC2050HV
10k
OUT
3V/AMP
LOAD CURRENT
IN MEASURED
CIRCUIT, REFERRED
TO –5V
3mΩ
0.1µF
LOAD CURRENT
–5V
2050 TA08
Figure 83. “Classic” High Precision Low Side Current Sense
an105fa
AN105-45
Application Note 105
DC
More DC Circuits Are Shown in Other Chapters:
FIGURE
TITLE
20
Precision, Wide Dynamic Range High-side Current Sensing
22
Wide Voltage Range Current Sensing
58
Bidirectional Precision Current Sensing
59
Differential Output Bidirectional 10A Current Sense
60
Absolute Value Output Bidirectional Current Sensing
142
Monitor Charge and Discharge Currents at One Output
178
Digitize a Bi-Directional Current Using a Single Sense Amplifier and ADC
208
Remote Current Sensing with Minimal Wiring
209
Use Kelvin Connections to Maintain High Current Accuracy
216
Dual Sense Amplifier Can Have Different Sense Resistors and Gain
an105fa
AN105-46
Application Note 105
LEVEL SHIFTING
V+ Powered Separately from Load Supply (Figure 85)
Quite often it is required to sense current flow in a supply rail that is a much higher voltage potential than the
supply voltage for the system electronics. Current sense
circuits with high voltage capability are useful to translate
information to lower voltage signals for processing.
The inputs of the LTC6101 can function from 1.4V above
the device positive supply to 48V DC. In this circuit the
current flow in the high voltage rail is directly translated
to a 0V to 3V range.
Over-The-Top Current Sense (Figure 84)
Voltage Translator (Figure 86)
This circuit is a variation on the “classic” high side circuit, but takes advantage of Over-the-Top input capability
to separately supply the IC from a low voltage rail. This
provides a measure of fault protection to downstream
circuitry by virtue of the limited output swing set by the low
voltage supply. The disadvantage is VOS in the Over-theTop mode is generally inferior to other modes, thus less
accurate. The finite current gain of the bipolar transistor
is a source of small gain error.
This is a convenient usage of the LTC6101 current sense
amplifier as a high voltage level translator. Differential
voltage signals riding on top of a high common mode
voltage (up to 105V with the LTC6101HV) get converted to
a current, through RIN, and then scaled down to a ground
referenced voltage across ROUT.
+
VIN
RIN
–
3V TO 44V
R1
200Ω
4
+
3V
RS
0.2Ω
2
+
Q1
2N3904
VOUT
(0V TO 2.7V)
R2
2k
LT1637
ILOAD
LOAD
3
–
ILOAD =
VOUT
(RS)(R2/R1)
VTRANSLATE
–
5
+
–
LTC6101
1
VOUT
ROUT
1637 TA06
Figure 84. Over-The-Top Current Sense
4.4V TO 48V
SUPPLY
Figure 86. Voltage Translator
3V
2
LT6100
VCC
7
6
A4
A2
+
8 VS
VOUT 5
RSENSE
3mΩ
–
1 VS
LOAD
CONFIGURED FOR GAIN = 25V/V
VEE
FIL
4
3
VOUT = 2.5V
ISENSE = 33A
6100 TA01a
220pF
Figure 85. V+ Powered Separately from Load Supply
an105fa
AN105-47
Application Note 105
LEVEL SHIFTING
Low Power, Bidirectional 60V Precision High Side
Current Sense (Figure 87)
Using a very precise zero-drift amplifier as a pre-amp
allows for the use of a very small sense resistor in a high
voltage supply line. A floating power supply regulates the
voltage across the pre-amplifier on any voltage rail up to
the 60V limit of the LT1787HV circuit. Overall gain of this
circuit is 1000. A 1mA change in current in either direction
through the 10mΩ sense resistor will produce a 10mV
change in the output voltage.
POSITIVE SENSE
10mΩ
5
3
1
BAT54
+
–
VSENSE
LTC1754-5
1N4686
3.9VZ
2
10µF
4
100Ω
6
1µF
0.1µF
10µF
100Ω
3
4
PRECISION
BIDIRECTIONAL
5 GAIN OF 125
+
LTC2054
–
2
1
0.1µF
12.4k
33Ω
2
1
2N5401
ON 5V
OFF 0V
MPSA42
35.7k
POWER SUPPLY
(NOTE: POSITIVE
CURRENT SENSE
INCLUDES CIRCUIT
SUPPLY CURRENT)
PRECISION
BIDIRECTIONAL
HIGH VOLTAGE
LEVEL SHIFT
AND GAIN OF 8
VS–
7
VS+
LT1787HV
8
5
6
VOUT = 2.5V
+1000* VSENSE
4.7µF
2.5V REF
4
20545 TA06
Figure 87. Low Power, Bidirectional 60V Precision High Side Current Sense
More Level Shifting Circuits Are Shown in Other Chapters:
FIGURE
40
TITLE
Monitor Current in Positive or Negative Supply Lines
an105fa
AN105-48
Application Note 105
HIGH VOLTAGE
Monitoring current flow in a high voltage line often requires floating the supply of the measuring circuits up
near the high voltage potentials. Level shifting and isolation components are then often used to develop a lower
output voltage indication.
Over-The-Top Current Sense (Figure 88)
This circuit is a variation on the “classic” high side circuit, but takes advantage of Over-the-Top input capability
to separately supply the IC from a low voltage rail. This
provides a measure of fault protection to downstream
circuitry by virtue of the limited output swing set by the low
voltage supply. The disadvantage is VOS in the Over-theTop mode is generally inferior to other modes, thus less
accurate. The finite current gain of the bipolar transistor
is a source of small gain error.
Measuring Bias Current Into an Avalanche Photo
Diode (APD) Using an Instrumentation Amplifier
(Figures 89a and 89b)
The upper circuit (a) uses an instrumentation amplifier
(IA) powered by a separate rail (>1V above VIN) to measure across the 1kΩ current shunt. The lower figure (b)
is similar but derives its power supply from the APD bias
line. The limitation of these circuits is the 35V maximum
APD voltage, whereas some APDs may require 90V or
more. In the single-supply configuration shown, there is
also a dynamic range limitation due to VOL to consider.
The advantage of this approach is the high accuracy that
is available in an IA.
1k
1%
VIN
10V TO 33V
3V TO 44V
R1
200Ω
–
+
LT1637
ILOAD
LOAD
CURRENT
MONITOR OUTPUT
0mA TO 1mA = 0V TO 1V
LT1789
+
3V
RS
0.2Ω
BIAS OUTPUT
TO APD
35V
–
ILOAD =
VOUT
(RS)(R2/R1)
AN92 F02b
Q1
2N3904
VOUT
(0V TO 2.7V)
R2
2k
1637 TA06
Figure 89a
VIN
10V TO 35V
1N4684
3.3V
1k
1%
BIAS OUTPUT
TO APD
10M
Figure 88. Over-The-Top Current Sense
–
CURRENT
MONITOR OUTPUT
0mA TO 1mA = 0V TO 1V
LT1789
+
A=1
AN92 F02b
Figure 89b
Figure 89. Measuring Bias Current Into an Avalanche Photo
Diode (APD) Using an Instrumentation Amplifier
an105fa
AN105-49
Application Note 105
HIGH VOLTAGE
Simple 500V Current Monitor (Figure 90)
Adding two external MOSFETs to hold off the voltage allows
the LTC6101 to connect to very high potentials and monitor
the current flow. The output current from the LTC6101,
which is proportional to the sensed input voltage, flows
through M1 to create a ground referenced output voltage.
48V Supply Current Monitor with Isolated Output and
105V Survivability (Figure 91)
The HV version of the LTC6101 can operate with a total
supply voltage of 105V. Current flow in high supply voltage
rails can be monitored directly or in an isolated fashion
as shown in this circuit. The gain of the circuit and the
level of output current from the LTC6101 depends on the
particular opto-isolator used.
DANGER! Lethal Potentials Present — Use Caution
ISENSE
VSENSE
–
500V
+
RIN
RSENSE
4
3
RIN
100Ω
+ –
2
–
LOAD
RSENSE
3
4
– +
5
L
O
A
D
ISENSE
VSENSE
+
VS
2
DANGER!!
HIGH VOLTAGE!!
5
V–
LTC6101HV
1
LTC6101
62V
CMZ59448
VLOGIC
ROUT
M1
VOUT
VOUT
M1 AND M2 ARE FQD3P50 TM
ROUT
VOUT =
• VSENSE = 49.9 VSENSE
RIN
M2
ANY OPTO-ISOLATOR
ROUT
4.99k
2M
6101 TA09
Figure 90. Simple 500V Current Monitor
V–
N = OPTO-ISOLATOR CURRENT GAIN
R
VOUT = VLOGIC – ISENSE • SENSE • N • ROUT
RIN
6101 TA08
Figure 91. 48V Supply Current Monitor with
Isolated Output and 105V Survivability
an105fa
AN105-50
Application Note 105
HIGH VOLTAGE
Low Power, Bidirectional 60V Precision High Side
Current Sense (Figure 92)
Using a very precise zero-drift amplifier as a pre-amp allows for the use of a very small sense resistor in a high
voltage supply line. A floating power supply regulates the
voltage across the pre-amplifier on any voltage rail up to
the 60V limit of the LT1787HV circuit. Overall gain of this
circuit is 1000. A 1mA change in current in either direction
through the 10mΩ sense resistor will produce a 10mV
change in the output voltage.
POSITIVE SENSE
10mΩ
5
3
1
BAT54
+
–
VSENSE
LTC1754-5
1N4686
3.9VZ
2
10µF
4
100Ω
6
1µF
0.1µF
10µF
100Ω
3
4
PRECISION
BIDIRECTIONAL
5 GAIN OF 125
+
LTC2054
–
2
1
0.1µF
12.4k
33Ω
2
1
2N5401
ON 5V
OFF 0V
MPSA42
35.7k
POWER SUPPLY
(NOTE: POSITIVE
CURRENT SENSE
INCLUDES CIRCUIT
SUPPLY CURRENT)
PRECISION
BIDIRECTIONAL
HIGH VOLTAGE
LEVEL SHIFT
AND GAIN OF 8
VS–
7
VS+
LT1787HV
8
5
6
VOUT = 2.5V
+1000* VSENSE
4.7µF
2.5V REF
4
20545 TA06
Figure 92. Low Power, Bidirectional 60V Precision High Side Current Sense
an105fa
AN105-51
Application Note 105
HIGH VOLTAGE
High Voltage Current and Temperature Monitoring
(Figure 93)
referenced voltage proportional to the load current and is
measured as a single ended input by the ADC. A divided
down representation of the supply voltage is a second
input. An external NPN transistor serves as a remote
temperature sensor.
Combining an LTC2990 ADC converter with a high voltage
LTC6102HV current sense amplifier allows the measurement of very high voltage rails, up to 104V, and very high
current loads. The current sense amplifier outputs a ground
RSENSE
1mΩ
1%
ILOAD
0A TO 10A
VIN
5V TO 105V
RIN
20Ω
1%
+IN
0.1µF
–INS
–
+
–INF
V+
VREG
V–
OUT
LTC6102HV
200k
1%
4.75k
1%
5V
2-WIRE
I2C
INTERFACE
ROUT
4.99k
1%
0.1µF
0.1µF
0.1µF
VCC
V1
V2
SDA
SCL LTC2990
ADR0
ADR1
GND
MMBT3904
V3
470pF
V4
2990 TA02
ALL CAPACITORS ±20%
VOLTAGE, CURRENT AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x58
REG 4, 5
0.0625°C/LSB
TAMB
REG 6, 7
13.2mVLSB
VLOAD
REG 8, 9
1.223mA/LSB
V2(ILOAD)
REG A, B
0.0625°C/LSB
TREMOTE
REG E, F
2.5V + 305.18µV/LSB
VCC
Figure 93. High Voltage Current and Temperature Monitoring
an105fa
AN105-52
Application Note 105
HIGH VOLTAGE
More High Voltage Circuits Are Shown In Other Chapters:
FIGURE
TITLE
22
Wide Voltage Range Current Sensing
23
Smooth Current Monitor Output Signal by Simple Filtering
105
High Voltage, 5A High Side Current Sensing in Small Package
124
Monitor H-Bridge Motor Current Directly
128
Fixed Gain DC Motor Current Monitor
167
Monitor Current in an Isolated Supply Line
168
Monitoring a Fuse Protected Circuit
179
Digitizing Charging and Loading Current in a Battery Monitor
182
Power Sensing with Built In A to D Converter
183
Isolated Power Measurement
184
Fast Data Rate Isolated Power Measurement
185
Adding Temperature Measurement to Supply Power Measurement
186
Current, Voltage and Fuse Monitoring
187
Automotive Socket Power Monitoring
188
Power over Ethernet, PoE, Monitoring
an105fa
AN105-53
Application Note 105
LOW VOLTAGE
Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
(Figure 94)
1.25V Electronic Circuit Breaker (Figure 95)
The LT1787’s output is buffered by an LT1495 rail-to-rail
op amp configured as an I/V converter. This configuration
is ideal for monitoring very low voltage supplies. The
LT1787’s VOUT pin is held equal to the reference voltage
appearing at the op amp’s noninverting input. This allows one to monitor supply voltages as low as 2.5V. The
op amp’s output may swing from ground to its positive
supply voltage. The low impedance output of the op amp
may drive following circuitry more effectively than the
high output impedance of the LT1787. The I/V converter
configuration also works well with split supply voltages.
The LTC4213 provides protection and automatic circuit
breaker action by sensing drain-to-source voltage drop
across the N-MOSFET. The sense inputs have a rail-to-rail
common mode range, so the circuit breaker can protect
bus voltages from 0V up to 6V. Logic signals flag a trip
condition (with the READY output signal) and reinitialize
the breaker (using the ON input). The ON input may also
be used as a command in a “smart switch” application.
SI4864DY
VIN
1.25V
VBIAS
2.3V TO 6V
VCC
VOUT
1.25V
3.5A
SENSEP GATE SENSEN
LTC4213
TO
CHARGER/
LOAD
1
2
3
4
FIL–
VS–
DNC
10k
ISENSE
RSENSE
OFF ON
FIL+
LT1787
8
C1
1µF
ROUT
VEE
5
VOUT
2.5V
1M
5%
GND
ISEL
READY
2.5V + VSENSE(MAX)
4213 TA01
VS+ 7
Figure 95. 1.25V Electronic Circuit Breaker
2.5V
VBIAS 6
ON
VBIAS
C3
1000pF
–
+
VOUT A
A1
LT1495
LT1389-1.25
1787 F07
Figure 94. Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
an105fa
AN105-54
Application Note 105
HIGH CURRENT (100mA to Amps)
Sensing high currents accurately requires excellent control
of the sensing resistance, which is typically a very small
value to minimize losses, and the dynamic range of the
measurement circuitry
Kelvin Input Connection Preserves Accuracy Despite
Large Load Currents (Figure 96)
Kelvin connection of the –IN and +IN inputs to the sense
resistor should be used in all but the lowest power applications. Solder connections and PC board interconnections that carry high current can cause significant error
in measurement due to their relatively large resistances.
By isolating the sense traces from the high current paths,
this error can be reduced by orders of magnitude. A sense
resistor with integrated Kelvin sense terminals will give
the best results.
than the max current spec allowed unless the max current
is limited in another way, such as with a Schottky diode
across RSENSE. This will reduce the high current measurement accuracy by limiting the result, while increasing the
low current measurement resolution. This approach can
be helpful in cases where an occasional large burst of
current may be ignored.
V+
DSENSE
RSENSE
6101 F03a
LOAD
Figure 97. Shunt Diode Limits Maximum Input Voltage to Allow
Better Low Input Resolution Without Over-Ranging
the LTC6101
V+
Kelvin Sensing (Figure 98)
RSENSE
In any high current, >1A, application, Kelvin contacts to
the sense resistor are important to maintain accuracy.
This simple illustration from a battery charger application
shows two voltage-sensing traces added to the pads of the
current sense resistor. If the voltage is sensed with high
impedance amplifier inputs, no IxR voltage drop errors
are developed.
RIN
4
3
+
–
LOAD
2
5
LTC6101
1
VOUT
ROUT
DIRECTION OF CHARGING CURRENT
6101 F02
Figure 96. Kelvin Input Connection Preserves Accuracy Despite
Large Load Currents
Shunt Diode Limits Maximum Input Voltage to Allow
Better Low Input Resolution Without Over-Ranging
the LTC6101 (Figure 97)
If low sense currents must be resolved accurately in a
system that has very wide dynamic range, more gain can
be taken in the sense amplifier by using a smaller value for
resistor RIN. This can result in an operating current greater
RSENSE
4008 F12
CSP
BAT
Figure 98. Kelvin Sensing
an105fa
AN105-55
Application Note 105
HIGH CURRENT (100mA to Amps)
0A to 33A High Side Current Monitor with Filtering
(Figure 99)
Single Supply RMS Current Measurement
(Figure 100)
High current sensing on a high voltage supply rail is easily accomplished with the LT6100. The sense amplifier is
biased from a low 3V supply and pin strapped to a gain
of 25V/V to output a 2.5V full-scale reading of the current
flow. A capacitor at the FIL pin to ground will filter out
noise of the system (220pF produces a 12kHz lowpass
corner frequency).
The LT1966 is a true RMS-to-DC converter that takes a
single-ended or differential input signal with rail-to-rail
range. The output of a PCB mounted current sense transformer can be connected directly to the converter. Up to
75A of AC current is measurable without breaking the signal
path from a power source to a load. The accurate operating
range of the circuit is determined by the selection of the
transformer termination resistor. All of the math is built
in to the LTC1966 to provide a DC output voltage that is
proportional to the true RMS value of the current. This is
valuable in determining the power/energy consumption
of AC-powered appliances.
4.4V TO 48V
SUPPLY
3V
2
LT6100 VCC
7
6
A4
A2
+
8 VS
VOUT 5
RSENSE
3mΩ
–
1 VS
LOAD
VEE
FIL
4
3
VOUT = 2.5V
ISENSE = 33A
6100 TA01a
220pF
CONFIGURED FOR GAIN = 25V/V
Figure 99. 0A to 33A High Side Current Monitor with Filtering
V+
AC CURRENT
75A MAX
50Hz TO 400Hz
LTC1966
IN1
T1
VOUT
10Ω
IN2 OUT RTN
CAVE
1µF
VOUT = 4mVDC/ARMS
100k VSS GND EN
0.1µF
100k
1966 TA08
T1: CR MAGNETICS CR8348-2500-N
www.crmagnetics.com
Figure 100. Single Supply RMS Current Measurement
an105fa
AN105-56
Application Note 105
HIGH CURRENT (100mA to Amps)
Dual LTC6101’s Allow High-Low Current Ranging
(Figure 101)
measurement is 10 times greater with low currents, less
than 1.2A, than with higher currents. A comparator detects
higher current flow, up to 10A, and switches sensing over
to the high current circuitry.
Using two current sense amplifiers with two values of
sense resistors is an easy method of sensing current over
a wide range. In this circuit the sensitivity and resolution of
VLOGIC
(3.3V TO 5V)
CMPZ4697
7
10k
3
M1
Si4465
VIN
RSENSE HI
10m
ILOAD
VOUT
301
RSENSE LO
100m
301
301
4
+
–
301
2
+ –
LTC6101
3
4
5
2
VIN
1
3
+ –
4.7k
2
5
LTC1540
1
619k
1
LTC6101
7.5k
Q1
CMPT5551
40.2k 6
1.74M
4
8
5
HIGH
RANGE
INDICATOR
(ILOAD > 1.2A)
HIGH CURRENT RANGE OUT
250mV/A
VLOGIC
BAT54C
R5
7.5k
(VLOGIC +5V) ≤ VIN ≤ 60V
LOW CURRENT RANGE OUT
2.5V/A
0 ≤ ILOAD ≤ 10A
6101 F03b
Figure 101. Dual LTC6101’s Allow High-Low Current Ranging
an105fa
AN105-57
Application Note 105
HIGH CURRENT (100mA to Amps)
LDO Load Balancing (Figure 102)
As system design enhancements are made there is often
the need to supply more current to a load than originally
expected. A simple way to modify power amplifiers or
voltage regulators, as shown here, is to parallel devices.
When paralleling devices it is desired that each device
shares the total load current equally. In this circuit two
adjustable “slave” regulator output voltages are sensed
VIN
1.8V TO 20V
+
IN
10µF
and servo’ed to match the master regulator output voltage. The precise low offset voltage of the LTC6078 dual op
amp (10µV) balances the load current provided by each
regulator to within 1mA. This is achieved using a very
small 10mΩ current sense resistor in series with each
output. This sense resistor can be implemented with PCB
copper traces or thin gauge wire.
BALLAST RESISTANCE:
IDENTICAL LENGTH
THERMALLY MATED
WIRE OR PCB TRACE
OUT
LT1763
0.01µF
10µF
SHDN BYP
FB
R2
2k
IN
R1
2k
( )
VOUT = 1.22V 1 +
OUT
LT1763
0.01µF
10µF
SHDN BYP
100Ω
ILOAD
FB
2k
R1
R2
LOAD
2k
1k
0.1µF
–
A
10k
IN
+
OUT
LT1763
0.01µF
10µF
SHDN BYP
100Ω
FB
0 ≤ ILOAD ≤ 1.5A
1.22V ≤ VOUT ≤ VDD
LDO LOADS MATCH TO WITHIN
1mA WITH 10mΩ OF BALLAST
RESISTANCE (2 INCHES OF AWG
28 GAUGE STRANDED WIRE)
A, B: LTC6078
2k
2k
0.1µF
1k
VDD
–
B
10k
+
60789 TA09
Figure 102. LDO Load Balancing
an105fa
AN105-58
Application Note 105
HIGH CURRENT (100mA to Amps)
Sensing Output Current (Figure 103)
The LT1970 is a 500mA power amplifier with voltage
programmable output current limit. Separate DC voltage
inputs and an output current sensing resistor control the
maximum sourcing and sinking current values. These
control voltages could be provided by a D-to-A converter
in a microprocessor controlled system. For closed loop
control of the current to a load an LT1787 can monitor the
output current. The LT1880 op amp provides scaling and
level shifting of the voltage applied to an A-to-D converter
for a 5mV/mA feedback signal.
VCC
0V TO 1V
12V
VCSRC
VCSNK
+IN
–IN
COMMON
EN
VCC
V+
ISRC
ISNK
RS
0.2Ω
TSD
OUT
LT1970
SENSE+
–
SENSE
FILTER
–
V
VEE
RLOAD
R4
255k
LT1787
RG
RF
VS–
–12V
+
VS
20k
VEE
–12V
BIAS
–12V
R1
60.4k
R2
10k
–
+
R3
20k
12V
VOUT
2.5V
±5mV/mA
LT1880
1kHz FULL CURRENT
BANDWIDTH
–12V
0V TO 5V
A/D
1970 F10
OPTIONAL DIGITAL FEEDBACK
Figure 103. Sensing Output Current
an105fa
AN105-59
Application Note 105
HIGH CURRENT (100mA to Amps)
Using Printed Circuit Sense Resistance (Figure 104)
The outstanding LTC6102 precision allows the use of
sense resistances fabricated with conventional printed
circuit techniques. For “one ounce” copperclad, the trace
resistance is approximately (L/W)·0.0005Ω and can carry
about 4A per mm of trace width. The example below shows
a practical 5A monitoring solution with both L and W set
to 2.5mm. The resistance is subject to about +0.4%/ºC
temperature change and the geometric tolerances of the
fabrication process, so this will not generally be for high
accuracy work, but can be useful in various low cost
protection and status monitoring functions.
High Voltage, 5A High Side Current Sensing in Small
Package (Figure 105)
The LT6106 is packaged in a small SOT-23 package but
still operates over a wide supply range of 3V to 44V. Just
two resistors set the gain (10 in circuit shown) and the
output is a voltage referred to ground.
3V TO 36V
0.02Ω
+IN
L
RSENSE*
RIN–
–IN
+
LOAD
CURRENT CARRYING TRACE
FROM
SUPPLY
100Ω
V–
–
V+
TO LOAD
10A MAX
W
RIN+
LT6106
OUT
1k
VOUT
200mV/A
6106 TA01a
CREG
V–
OUTPUT
ROUT
V–
LTC6102
* 2.5mm × 2.5mm
1oz COPPER
500µΩ
Figure 105. High Voltage, 5A High Side Current Sensing
in Small Package
DN423 F02
Figure 104. Using Printed Circuit Sense Resistance
More High Current Circuits Are Shown in Other Chapters:
FIGURE
TITLE
59
Differential Output Bidirectional 10A Current Sense
93
High Voltage Current and Temperature Monitoring
121
Single Output Provides 10A H-Bridge Current and Direction
179
Digitizing Charging and Loading Current in a Battery Monitor
209
Use Kelvin Connections to Maintain High Current Accuracy
215
0 to 10A Sensing Over Two Ranges
an105fa
AN105-60
Application Note 105
LOW CURRENT
(Picoamps to Milliamps)
ISENSE
VSUPPLY
6.4V TO 48V
RSENSE
+
LT6100 VS
+
5V
VS–
LOAD
–
For low current applications the easiest way to sense current is to use a large sense resistor. This however causes
larger voltage drops in the line being sensed which may
not be acceptable. Using a smaller sense resistor and
taking gain in the sense amplifier stage is often a better
approach. Low current implies high source impedance
measurements which are subject approach. Low current
implies high source impedance measurements which
are subject to noise pickup and often require filtering of
some sort.
VCC
FIL
VEE
A2
A4
VOUT
50 • RSENSE • ISENSE
6100 TA04
Filtered Gain of 20 Current Sense (Figure 106)
The LT6100 has pin strap connections to establish a variety
of accurate gain settings without using external components. For this circuit grounding A2 and leaving A4 open
set a gain of 20. Adding one external capacitor to the FIL
pin creates a lowpass filter in the signal path. A capacitor of
1000pF as shown sets a filter corner frequency of 2.6KHz.
ISENSE
VSUPPLY
4.4V TO 48V
RSENSE
+
LT6100 VS
LOAD
–
+
3V
VS–
Figure 107. Gain of 50 Current Sense
0nA to 200nA Current Meter (Figure 108)
A floating amplifier circuit converts a full-scale 200nA
flowing in the direction indicated at the inputs to 2V at
the output of the LT1495. This voltage is converted to a
current to drive a 200µA meter movement. By floating the
power to the circuit with batteries, any voltage potential
at the inputs are handled. The LT1495 is a micropower op
amp so the quiescent current drain from the batteries is
very low and thus no on/off switch is required.
VCC
100pF
FIL
1000pF
VEE
A2
A4
VOUT
20 • RSENSE • ISENSE
6100 TA03
–3dB AT 2.6kHz
Figure 106. Filtered Gain of 20 Current Sense
R1
10M
R4
10k
INPUT
CURRENT
–
–
1.5V
1/2
LT1495
+
Gain of 50 Current Sense (Figure 107)
The LT6100 is configured for a gain of 50 by grounding
both A2 and A4. This is one of the simplest current sensing
amplifier circuits where only a sense resistor is required.
µA
1/2
LT1495
+
R2
9k
1.5V
R3
2k
FULL-SCALE
ADJUST
IS = 3µA WHEN IIN = 0
NO ON/OFF SWITCH
REQUIRED
0µA TO
200µA
1495 TA06
Figure 108. 0nA to 200nA Current Meter
an105fa
AN105-61
Application Note 105
LOW CURRENT
(Picoamps to Milliamps)
Lock-In Amplifier Technique Permits 1% Accurate
APD Current Measurement Over 100nA to 1mA Range
(Figure 109)
shunt, modulating it into a differential square wave signal
which feeds A1 through 0.2µF AC coupling capacitors.
A1’s single-ended output biases demodulator S2, which
presents a DC output to buffer amplifier A2. A2’s output
is the circuit output.
Avalanche Photodiodes, APDs, require a small amount of
current from a high voltage supply. The current into the
diode is an indication of optical signal strength and must
be monitored very accurately. It is desirable to power all
of the support circuitry from a single 5V supply.
Switch S3 clocks a negative output charge pump which
supplies the amplifier’s V– pins, permitting output swing to
(and below) zero volts. The 100k resistors at Q1 minimize
its on-resistance error contribution and prevent destructive potentials from reaching A1 (and the 5V rail) if either
0.2µF capacitor fails. A2’s gain of 1.1 corrects for the slight
attenuation introduced by A1’s input resistors. In practice,
it may be desirable to derive the APD bias voltage regulator’s feedback signal from the indicated point, eliminating
the 1kΩ shunt resistor’s voltage drop. Verifying accuracy
involves loading the APD bias line with 100nA to 1mA and
noting output agreement.
This circuit utilizes AC carrier modulation techniques to
meet APD current monitor requirements. It features 0.4%
accuracy over the sensed current range, runs from a 5V
supply and has the high noise rejection characteristics of
carrier based “lock in” measurements.
The LTC1043 switch array is clocked by its internal
oscillator. Oscillator frequency, set by the capacitor at
Pin 16, is about 150Hz. S1 clocking biases Q1 via level
shifter Q2. Q1 chops the DC voltage across the 1k current
APD
HIGH VOLTAGE
BIAS INPUT
FOR OPTIONAL “ZERO CURRENT” FEEDBACK TO
APD BIAS REGULATOR, SEE APPENDIX A
1k*
1%
1µF
100V
1µF
100V
100k*
100k*
Q1
1N4690
5.6V
1M*
0.2µF
VOUT = 20V TO 90V
TO APD
5V
–
10k
A1
LT1789
30k
+
Q2
MPSA42
20k
0.2µF
5V
1µF
20k
6
2
+
S2
5
1µF
–
1M* –3.5V
20k*
–3.5V
200k*
12
13
OUTPUT
0V TO 1V =
0mA TO 1mA
A2
LT1006
14
S1
5V
5V
18
15
+
* = 0.1% METAL FILM RESISTOR
1µF 100V = TECATE CMC100105MX1825
# CIRCLED NUMBERS = LTC1043 PIN NUMBER
3
+
S3
–3.5V TO
AMPLIFIERS
22µF
22µF
= 1N4148
= TP0610L
16
17
4
0.056µF
5V
AN92 F04
Figure 109. Lock-In Amplifier Technique Permits 1% Accurate APD Current Measurement Over 100nA to 1mA Range
an105fa
AN105-62
Application Note 105
LOW CURRENT
(Picoamps to Milliamps)
DC-Coupled APD Current Monitor (Figure 110)
drop across the ground referred 1kΩ resistor identical to
the drop across the 1kΩ current shunt and, hence, APD
current. This relationship holds across the 20V to 90V APD
bias voltage range. The 5.6V zener assures A1’s inputs
are always within their common mode operating range
and the 10MΩ resistor maintains adequate Zener current
when APD current is at very low levels.
Avalanche Photodiodes, APDs, require a small amount of
current from a high voltage supply. The current into the
diode is an indication of optical signal strength and must
be monitored very accurately. It is desirable to power all
of the support circuitry from a single 5V supply.
This circuit’s DC-coupled current monitor eliminates the
previous circuit’s trim but pulls more current from the
APD bias supply. A1 floats, powered by the APD bias rail.
The 15V Zener diode and current source Q2 ensure A1
never is exposed to destructive voltages. The 1kΩ current
shunt’s voltage drop sets A1’s positive input potential. A1
balances its inputs by feedback controlling its negative input
via Q1. As such, Q1’s source voltage equals A1’s positive
input voltage and its drain current sets the voltage across
its source resistor. Q1’s drain current produces a voltage
APD
HIGH VOLTAGE
BIAS INPUT
1N4690
5.6V
FOR OPTIONAL “ZERO CURRENT” FEEDBACK TO
APD BIAS REGULATOR, SEE APPENDIX A
1k*
CURRENT SHUNT
10M
Two output options are shown. A2, a chopper stabilized
amplifier, provides an analog output. Its output is able to
swing to (and below) zero because its V– pin is supplied
with a negative voltage. This potential is generated by using A2’s internal clock to activate a charge pump which,
in turn, biases A2’s V– Pin 3. A second output option
substitutes an A-to-D converter, providing a serial format
digital output. No V– supply is required, as the LTC2400
A-to-D will convert inputs to (and slightly below) zero volts.
VOUT = 20V TO 90V
TO APD
51K
1k*
+
+
A1
LT1077
51k
1µF
1N4702
15V
–
Q1
ZVP0545A
100k
Q2
MPSA42
10k
Hi-Z OUTPUT
0V TO 1V = 0mA TO 1mA
5V
5V
1k*
LT1460
2.5V
1k*
VIN
+
1k
A2
LTC1150
= BAT85
–
CLK OUT
V–
≈ –3.5V HERE
39k
10µF
Q2
2N3904
100k
OPTIONAL BUFFERED OUTPUT
FO
LTC2400 SCK
A-TO-D
SDO
CS
5V
+
* = 0.1% METAL FILM RESISTOR
BUFFERED OUTPUT
0mA TO 1mA = 0V TO 1V
+
5V
VREF
10µF
DIGITAL
INTERFACE
OPTIONAL
DIGITAL OUTPUT
AN92 F05
Figure 110. DC-Coupled APD Current Monitor
an105fa
AN105-63
Application Note 105
LOW CURRENT
(Picoamps to Milliamps)
current sensing. In this circuit a six decade range of current
pulled from the circuit input terminal is converted to an
output voltage in logarithmic fashion increasing 150mV
for every decade of current change.
Six Decade (10nA to 10mA) Current Log Amplifier
(Figure 111)
Using precision quad amplifiers like the LTC6079, (10µV
offset and <1pA bias current) allow for very wide range
–
C
+
100Ω
–
B
100Ω
+
33µF
Q2
Q1
100k
133k
VDD
–
1000pF
–
A
+
+
IIN
LT6650
VCC
IN
1µF
1.58k
D
OUT
GND
1µF
VOUT
PRECISION
RESISTOR PT146
1k
+3500ppm/°C
10nA ≤ IIN ≤ 10mA
Q1, Q2: DIODES INC. DMMT3906W
A TO D: LTC6079
VOUT ≈ 150mV • log (IIN) + 1.23V, IIN IN AMPS
60789 TA07
Figure 111. Six Decade (10nA to 10mA) Current Log Amplifier
an105fa
AN105-64
Application Note 105
MOTORS AND INDUCTIVE LOADS
The largest challenge in measuring current through inductive circuits is the transients of voltage that often occur.
Current flow can remain continuous in one direction while
the voltage across the sense terminals reverses in polarity.
Electronic Circuit Breaker (Figure 112)
The LTC1153 is an electronic circuit breaker. Sensed current to a load opens the breaker when 100mV is developed
between the supply input, VS, and the drain sense pin, DS.
To avoid transient, or nuisance trips of the break components RD and CD delay the action for 1ms. A thermistor
can also be used to bias the shutdown input to monitor
heat generated in the load and remove power should the
temperature exceed 70°C in this example. A feature of
the LTC1153 is timed automatic reset which will try to
reconnect the load after 200ms using the 0.22μF timer
capacitor shown.
ON/OFF
IN
CT
0.22µF
VS
DS
CT
Z5U
BATTERY BUS
+
*RSEN
0.1Ω
STATUS
51k
GND
IRLR024
G
SHUTDOWN
**70°C
PTC
+
RS
LTC1153
TO µP
5V
CD
RD
0.01µF 100k
A common monitoring approach in these systems is to
amplify the voltage on a “flying” sense resistor, as shown.
Unfortunately, several potentially hazardous fault scenarios
go undetected, such as a simple short to ground at a motor
terminal. Another complication is the noise introduced by
the PWM activity. While the PWM noise may be filtered for
purposes of the servo law, information useful for protection
becomes obscured. The best solution is to simply provide
two circuits that individually protect each half-bridge and
report the bidirectional load current. In some cases, a
smart MOSFET bridge driver may already include sense
resistors and offer the protection features needed. In these
situations, the best solution is the one that derives the load
information with the least additional circuitry.
–
IM
51k
DIFF
AMP
SENSITIVE
5V LOAD
ALL COMPONENTS SHOWN ARE SURFACE MOUNT.
* IMS026 INTERNATIONAL MANUFACTURING SERVICE, INC. (401) 683-9700
** RL2006-100-70-30-PT1 KEYSTONE CARBON COMPANY (814) 781-1591
LTC1153 • TA01
Figure 112. Electronic Circuit Breaker
Conventional H-Bridge Current Monitor (Figure 113)
Many of the newer electric drive functions, such as steering assist, are bidirectional in nature. These functions are
generally driven by H-bridge MOSFET arrays using pulsewidth modulation (PWM) methods to vary the commanded
torque. In these systems, there are two main purposes for
current monitoring. One is to monitor the current in the
load, to track its performance against the desired command (i.e., closed-loop servo law), and another is for fault
detection and protection features.
DN374 F03
Figure 113. Conventional H-Bridge Current Monitor
Motor Speed Control (Figure 114)
This uses an LT1970 power amplifier as a linear driver
of a DC motor with speed control. The ability to source
and sink the same amount of output current provides
for bidirectional rotation of the motor. Speed control is
managed by sensing the output of a tachometer built on
to the motor. A typical feedback signal of 3V/1000rpm is
compared with the desired speed-set input voltage. Because the LT1970 is unity-gain stable, it can be configured
as an integrator to force whatever voltage across the motor as necessary to match the feedback speed signal with
the set input signal. Additionally, the current limit of the
amplifier can be adjusted to control the torque and stall
current of the motor.
an105fa
AN105-65
Application Note 105
MOTORS AND INDUCTIVE LOADS
OV TO 5V
TORQUE/STALL
CURRENT CONTROL
15V
VCSRC
VCSNK
+IN
–IN
COMMON
EN
VCC
V+
ISRC
ISNK
TSD
OUT
LT1970
SENSE+
SENSE–
FILTER
V–
VEE
RS
1Ω
12V DC
MOTOR
GND
15V
R1
1.2k
R2
10k
–15V
REVERSE
R4
49.9k
C1
1µF
TACH
FEEDBACK
3V/1000rpm
R5
49.9k
1970 F13
FORWARD
R3
1.2k
–15V
Figure 114. Motor Speed Control
Practical H-Bridge Current Monitor Offers Fault
Detection and Bidirectional Load Information
(Figure 115)
This circuit implements a differential load measurement
for an ADC using twin unidirectional sense measurements.
Each LTC6101 performs high side sensing that rapidly
responds to fault conditions, including load shorts and
MOSFET failures. Hardware local to the switch module
(not shown in the diagram) can provide the protection
logic and furnish a status flag to the control system.
The two LTC6101 outputs taken differentially produce
a bidirectional load measurement for the control servo.
The ground-referenced signals are compatible with most
ΔΣADCs. The ΔΣADC circuit also provides a “free” integration function that removes PWM content from the
measurement. This scheme also eliminates the need for
analog-to-digital conversions at the rate needed to support switch protection, thus reducing cost and complexity.
–
BATTERY BUS
ROUT
LTC6101
DIFF
OUTPUT
TO ADC
RIN
RIN
RS
RS
+
LTC6101
ROUT
+
FOR IM RANGE = ±100A,
DIFF OUT = ±2.5V
RS = 1mΩ
RIN = 200Ω
ROUT = 4.99k
IM
DN374 F04
Figure 115. Practical H-Bridge Current Monitor Offers Fault
Detection and Bidirectional Load Information
an105fa
AN105-66
Application Note 105
MOTORS AND INDUCTIVE LOADS
Lamp Driver (Figure 116)
Intelligent High Side Switch (Figure 117)
The inrush current created by a lamp during turn-on can
be 10 to 20 times greater than the rated operating current. This circuit shifts the trip threshold of an LTC1153
electronic circuit breaker up by a factor of 11:1 (to 30A) for
100ms while the bulb is turned on. The trip threshold then
drops down to 2.7A after the inrush current has subsided.
The LT1910 is a dedicated high side MOSFET driver with
built in protection features. It provides the gate drive for a
power switch from standard logic voltage levels. It provides
shorted load protection by monitoring the current flow
to through the switch. Adding an LTC6101 to the same
circuit, sharing the same current sense resistor, provides
a linear voltage signal proportional to the load current for
additional intelligent control.
12V
IN
5V
0.33µF
+
10k
VS
470µF
0.02Ω
100k
DS
CT
VN2222LL
LTC1153
STATUS
G
0.1µF
1M
GND
SD
IRFZ34
12V
12V/2A
BULB
LTC1153 • TA07
Figure 116. Lamp Driver
10µF
63V
VLOGIC
14V
47k
FAULT
OFF ON
3
4
8
RS
LT1910
5
3
4
6
2
1µF
100Ω
1%
1
LTC6101
100Ω
1
VO
4.99k
2
5
SUB85N06-5
L
O
A
D
VO = 49.9 • RS • IL
IL
FOR RS = 5mΩ,
VO = 2.5V AT IL = 10A (FULL-SCALE)
6101 TA07
Figure 117. Intelligent High Side Switch
an105fa
AN105-67
Application Note 105
MOTORS AND INDUCTIVE LOADS
Relay Driver (Figure 118)
Full-Bridge Load Current Monitor (Figure 119)
This circuit provides reliable control of a relay by using an
electronic circuit breaker circuit with two-level over-current
protection. Current flow is sensed through two separate
resistors, one for the current into the relay coil and the
other for the current through the relay contacts. When
100mV is developed between the VS supply pin and the
drain sense pin, DS, the N-channel MOSFET is turned off
opening the contacts. As shown, the relay coil current is
limited to 350mA and the contact current to 5A.
The LT1990 is a difference amplifier that features a very
wide common mode input voltage range that can far
exceed its own supply voltage. This is an advantage to
reject transient voltages when used to monitor the current
in a full-bridge driven inductive load such as a motor. The
LT6650 provides a voltage reference of 1.5V to bias up the
output away from ground. The output will move above or
below 1.5V as a function of which direction the current
in the load is flowing. As shown, the amplifier provides
a gain of 10 to the voltage developed across resistor RS.
12V
+
100µF
2Ω
IN
VS
CT
DS
0.01µF
5V
1µF
1N4148
MTD3055E
LTC1153
STATUS
G
TO 12V
LOAD
15V
GND
0.02Ω
10k
SD
1N4001
COIL CURRENT LIMITED TO 350mA
CONTACT CURRENT LIMITED TO 5A
LTC1153 • TA08
Figure 118. Relay Driver
+VSOURCE
5V
LT1990
900k
10k
8
7
– +
2
1M
3
1M
RS
VREF = 1.5V
IL
IN
–12V ≤ VCM ≤ 73V
VOUT = VREF ± (10 • IL • RS)
OUT
LT6650
GND FB
1nF
54.9k
100k
–
6
+
4
10k
40k
40k
900k
VOUT
5
100k
20k
1
1990 TA01
1µF
Figure 119. Full-Bridge Load Current Monitor
an105fa
AN105-68
Application Note 105
MOTORS AND INDUCTIVE LOADS
Bidirectional Current Sensing in H-Bridge Drivers
(Figure 120)
two outputs form a bidirectional measurement for subsequent circuitry, such as an ADC. In this configuration, any
load fault to ground will also be detected so that bridge
protection can be implemented. This arrangement avoids
the high frequency common mode rejection problem that
can cause problems in “flying” sense resistor circuits.
Each channel of an LTC6103 provides measurement of the
supply current into a half-bridge driver section. Since only
one of the half-bridge sections will be conducting current
in the measurable direction at any given time, only one
output at a time will have a signal. Taken differentially, the
V+
4V TO 60V
10mΩ
10mΩ
200Ω
8
200Ω
7
6
–INA
+INA
5
–INB
+ –
– +
VSA
LTC6103
+INB
VSB
V–
OUTA
1
4
OUTB
2
+
4.99k
–
DIFFERENTIAL
OUTPUT
±2.5V FS (MAY BE LIMITED IF V+ < 6V)
±10A FS
4.99k
–
+
PWM*
PWM*
6103 TA04
*USE “SIGN-MAGNITUDE” PWM FOR ACCURATE
LOAD CURRENT CONTROL AND MEASUREMENT
Figure 120. Bidirectional Current Sensing in H-Bridge Drivers
an105fa
AN105-69
Application Note 105
MOTORS AND INDUCTIVE LOADS
Single Output Provides 10A H-Bridge Current and
Direction (Figure 121)
24VDC
VBATTERY
(8V TO 60V)
0.1µF
7
6
8
5
LTC6104
10m
1
+IN
2N7000
V+
1µF
2
6
V–
VOUT = 25mV/mA
VOUT
4.99k
4.99k
1%
6105 F04
VO
2
VO = 2.5V ±2V (±10A FS)
4
Figure 122. Monitor Solenoid Current on the Low Side
24VDC
PWM*
PWM*
IM
1Ω
1%
*USE “SIGN-MAGNITUDE” PWM FOR ACCURATE
LOAD CURRENT CONTROL AND MEASUREMENT
Figure 121. Single Output Provides 10A H-Bridge Current
and Direction
200Ω
1%
Monitor Solenoid Current on the High Side
(Figure 123)
Driving an inductive load such as a solenoid creates large
transients of common mode voltage at the inputs to a
current sense amplifier. When de-energized the voltage
24V/OFF
2k
1%
–IN
5VDC
TP0610L
200Ω
1%
1N914
24V, 3W
SOLENOID
Monitor Solenoid Current on the Low Side
(Figure 122)
Driving an inductive load such as a solenoid creates large
transients of common mode voltage at the inputs to a
current sense amplifier. When de-energized the voltage
across the solenoid reverses (also called the freewheel
state) and tries to go above its power supply voltage but
is clamped by the freewheel diode. The LT6105 senses the
solenoid current continuously over an input voltage range
of 0V to one diode drop above the 24V supply.
–
6104 TA02
19V/ON
+
10m
249Ω
0V/OFF
5V/ON
200Ω
1%
LT6105
–IN
5VDC
4
LT1790-2.5
249Ω
200Ω
1%
24V, 3W
SOLENOID
1Ω
1%
–
3V TO 18V
1N5818
+
The output voltage of the LTC6104 will be above or below
the external 2.5V reference potential depending on which
side of the H-bridge is conducting current. Monitoring the
current in the bridge supply lines eliminates fast voltage
changes at the inputs to the sense amplifiers.
2k
1%
LT6105
1N5818
+IN
V+
V–
VOUT
6105 F06
VOUT = 25mV/mA
4.99k
1%
Figure 123. Monitor Solenoid Current on the High Side
across the solenoid reverses (also called the freewheel
state) and tries to go below ground but is clamped by the
freewheel diode. The LT6105 senses the solenoid current
continuously with pull-up resistors keeping the inputs
within the most accurate input voltage range.
an105fa
AN105-70
Application Note 105
MOTORS AND INDUCTIVE LOADS
Monitor H-Bridge Motor Current Directly
(Figures 124a and 124b)
Large Input Voltage Range for Fused Solenoid Current
Monitoring (Figure 125)
The LT1999 is a differential input amplifier with a very wide,
–5V to 80V, input common mode voltage range. With an
AC CMRR greater than 80dB at 100kHz allows the direct
measurement of the bidirectional current in an H-bridge
driven load. The large and fast common mode input voltage swings are rejected at the output. The amplifier gain is
fixed at 10, 20 or 50 requiring only a current sense resistor
and supply bypass capacitors external to the amplifier.
The LT1999 has series resistors at each input. This allows
the input to be overdriven in voltage without damaging the
amplifier. The amplifier will monitor the current through the
positive and negative voltage swings of a solenoid driver.
The large differential input with a blown protective fuse
will force the output high and not damage the LT1999.
V+
LT1999
VS
5V
1
V+
8
+
–
4k
V+IN 2
RS
2µA
SHDN
V+
VOUT
–
+
0.8k
7
2.5V
VOUT
3
5V
4
0.8k
4k
160k
6
V+
VOUT (2V/DIV)
V+
VREF
160k
V+IN (20V/DIV)
V–IN
VSHDN
RG
V+IN
0.1µF
5
0.1µF
1999 TA01a
TIME (10µs/DIV)
Figure 124a
1999 TA01b
Figure 124b
Figure 124. Monitor H-Bridge Motor Current Directly
VS
5V
ON OFF
2µA
1
VSHDN
+
–
4k
V+IN 2
VOUT
VREF
STEERING
DIODE
V+
FUSE
8
SHDN
ILOAD
LOAD
V+
LT1999
V+
0.8k
VSHDN
RG
–
+
7
VOUT
V+
RSENSE
V–IN 3
4k
V+
5V
0.8k
160k
6
160k
4
VREF
0.1µF
5
0.1µF
1999 F05
Figure 125. Large Input Voltage Range for Fused Solenoid Current Monitoring
an105fa
AN105-71
Application Note 105
MOTORS AND INDUCTIVE LOADS
Monitor Both the ON Current and the Freewheeling
Current In a Low Side Driven Solenoid (Figure 127)
Monitor Both the ON Current and the Freewheeling
Current Through a High Side Driven Solenoid
(Figure 126)
Placing the current sense resistor inside the loop created
by a grounded solenoid and the freewheeling clamp diode
allows for continuous monitoring of the solenoid current
while being energized or switched OFF. The LT1999 operates accurately with an input common mode voltage up
to 80V. In this circuit the input is clamped at one diode
above the solenoid supply voltage.
Placing the current sense resistor inside the loop created
by a grounded solenoid and the freewheeling clamp diode
allows for continuous monitoring of the solenoid current
while being energized or switched OFF. The LT1999 operates accurately with an input common mode voltage down
to –5V below ground.
VS
V+
LT1999
OFF
V+
5V
ON
2µA
1
V+IN
8
SHDN
+
–
4k
2
+
V
VSHDN
RG
–
+
0.8k
7
VOUT
V+
RSENSE
V–IN
5V
SOLENOID
0.8k
4k
3
160k
VREF
6
V+
0.1µF
160k
4
5
0.1µF
1999 F07a
Figure 126. Monitor Both the ON Current and the Freewheeling Current Through a High Side Driven Solenoid
V+
LT1999
VS
5V
1
2µA
V+
SOLENOID
V+IN
+
–
4k
2
V
+
0.8k
V–IN
ON
VSHDN
RG
–
+
7
VOUT
V+
RSENSE
3
5V
OFF
8
SHDN
4
4k
V+
0.8k
160k
6 VREF
160k
0.1µF
5
0.1µF
1999 F08a
Figure 127. Monitor Both the ON Current and the Freewheeling Current In a Low Side Driven Solenoid
an105fa
AN105-72
Application Note 105
MOTORS AND INDUCTIVE LOADS
Fixed Gain DC Motor Current Monitor (Figure 128)
With no critical external components the LT1999 can be
connected directly across a sense resistor in series with
an H-bridge driven motor. The amplifier output voltage is
referenced to one-half supply so the direction of motor
rotation is indicated by the output being above or below
the DC output voltage when stopped.
5V
V+
10µF
V+
LT1999-20
1
2µA
SHDN
+
–
24V
4k
2
V+IN
C4
1000µF
0.8k
80k
V–IN
3
0.1µF
–
+
7
4k
0.8k
160k
6
160k
5V
V+
5V
OUTA
DIRECTION
OUTB
VOUT
RSENSE
0.025Ω
VREF
0.1µF
5
4
PWM INPUT
VSHDN
V+
VBRIDGE
H-BRIDGE
PWM IN
V+
8
1999 F09
24V MOTOR
BRAKE INPUT
GND
Figure 128. Fixed Gain DC Motor Current Monitor
an105fa
AN105-73
Application Note 105
MOTORS AND INDUCTIVE LOADS
Simple DC Motor Torque Control (Figure 129)
The torque of a spinning motor is directly proportional to
the current through it. In this circuit the motor current is
monitored and compared to a DC set point voltage. The
motor current is sensed by an LT6108-1 and forced to
match the set point current value through an amplifier
and a PWM motor drive circuit. The LTC6992-1 produces
a PWM signal from 0% to 100% duty cycle for a 0V to 1V
change at the MOD input pin.
VMOTOR
100µF
1k
8
7
SENSEHI SENSELO
V+
OUTA
6
LT6108-1
RESET
2
3
EN/RST
INC
5
CURRENT SET POINT (0V TO 5V)
VOUT
0.47µF
100k
9k
1k
OUTC
V–
4
0.1Ω
1
1µF
5V
2
3
–
+
4
7
6
1
LTC6246
78.7k
BRUSHED
DC MOTOR
(0A TO 5A)
MABUCHI
RS-540SH
5
V+
6
MOD OUT
LTC6992-1
3
1N5818
SET DIV
GND
2
4
IRF640
100k
1M
280k
5V
610812 TA04
Figure 129. Simple DC Motor Torque Control
an105fa
AN105-74
Application Note 105
MOTORS AND INDUCTIVE LOADS
Small Motor Protection and Control (Figure 130)
Large Motor Protection and Control (Figure 131)
DC motor operating current and temperature can be digitized and sent to a controller which can then adjust the
applied control voltage. Stalled rotor or excessive loading
on the motor can be sensed.
For high voltage/current motors, simple resistor dividers can scale the signals applied to an LTC2990 14-bit
converter. Proportional DC motor operating current and
temperature can be digitized and sent to a controller which
can then adjust the applied control voltage. Stalled rotor
or excessive loading on the motor can be sensed.
LOADPWR = I • V
0.1Ω
1%
MOTOR CONTROL VOLTAGE
0VDC TO 5VDC
0A TO ±2.2A
5V
0.1µF
2-WIRE
I2C
INTERFACE
VCC
V1
V2
SDA
SCL LTC2990
ADR0
ADR1
GND
MMBT3904
V3
470pF
V4
2990 TA04
TINTERNAL
CURRENT AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x59
REG 4, 5
0.0625°C/LSB
TAMB
REG 6, 7
194µA/LSB
IMOTOR
REG A, B
0.0625°C/LSB
TMOTOR
REG E, F
2.5V + 305.18µV/LSB
VCC
MOTOR
TMOTOR
VOLTAGE AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x58
REG 4, 5
0.0625°C/LSB
TAMB
REG 8, 9
305.18µVLSB
VMOTOR
REG A, B
0.0625°C/LSB
TMOTOR
REG E, F
2.5V + 305.18µV/LSB
VCC
Figure 130. Small Motor Protection and Control
LOADPWR = I • V
0.01Ω
1W, 1%
MOTOR CONTROL VOLTAGE
0V TO 40V
0A TO 10A
5V
2-WIRE
I2C
INTERFACE
71.5k
1%
71.5k
1%
10.2k
1%
10.2k
1%
0.1µF
VCC
V1 V2
SDA
SCL LTC2990
ADR0
ADR1
GND
MMBT3904
V3
470pF
V4
TMOTOR
TINTERNAL
VOLTAGE AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x58
REG 4, 5
0.0625°C/LSB
TAMB
REG 8, 9
2.44mVLSB
VMOTOR
REG A, B
0.0625°C/LSB
TMOTOR
REG E, F
2.5V + 305.18µV/LSB
VCC
MOTOR
2990 TA05
CURRENT AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x59
REG 4, 5
0.0625°C/LSB
TAMB
REG 6, 7
15.54mA/LSB
IMOTOR
REG A, B
0.0625°C/LSB
TMOTOR
REG E, F
2.5V + 305.18µV/LSB
VCC
Figure 131. Large Motor Protection and Control
an105fa
AN105-75
Application Note 105
BATTERIES
The science of battery chemistries and the charging and
discharging characteristics is a book of its own. This chapter is intended to provide a few examples of monitoring
current flow into and out of batteries of any chemistry.
RSENSE
TO
CHARGER/
LOAD
1
2
Input Remains Hi-Z when LT6100 is Powered Down
(Figure 132)
This is the typical configuration for an LT6100, monitoring
the load current of a battery. The circuit is powered from
a low voltage supply rail rather than the battery being
monitored. A unique benefit of this configuration is that
when the LT6100 is powered down, its battery sense inputs
remain high impedance, drawing less than 1µA of current.
This is due to an implementation of Linear Technology’s
Over-The-Top input technique at its front end.
ISENSE
RSENSE
TO LOAD
–
LT6100 VS
+
BATTERY
4.1V TO 48V
4
–
VEE
A4
6100 F08
Here the LT1787 is used in a single-supply mode with the
VBIAS pin shifted positive using an external LT1634 voltage
reference. The VOUT output signal can swing above and
below VBIAS to allow monitoring of positive or negative
currents through the sense resistor. The choice of reference voltage is not critical except for the precaution that
adequate headroom must be provided for VOUT to swing
without saturating the internal circuitry. The component
values shown allow operation with VS supplies as low
as 3.1V.
20k
5%
VBIAS 6
VOUT
C2
1µF
5
LT1634-1.25
C3*
1000pF
OUTPUT
1787 F04
RSENSE
0.1Ω
DISCHARGE
+
Charge/Discharge Current Monitor on Single Supply
with Shifted VBIAS (Figure 133)
3.3V
One LT1495 dual op amp package can be used to establish
separate charge and discharge current monitoring outputs.
The LT1495 features Over-the-Top operation allowing
the battery potential to be as high as 36V with only a 5V
amplifier supply voltage.
A2
1/2 LT1495
Figure 132. Input Remains Hi-Z when LT6100 is Powered Down
8
VS+ 7
Battery Current Monitor (Figure 134)
–
VOUT
FIL+
ROUT
IL
CHARGE
FIL
A2
DNC
LT1787HV
Figure 133. Charge/Discharge Current Monitor on Single Supply
with Shifted VBIAS
VCC
VEE
VS–
*OPTIONAL
+
POWER
DOWN OK
VCC
3V
0V
INPUTS
REMAIN
Hi-Z
VS+
3
FIL–
3.3V
TO
60V
C1
1µF
RA
RA
RA
2N3904
DISCHARGE
OUT
RB
12V
5V
RA
–
A1
1/2 LT1495
+
2N3904
CHARGE
OUT
VO = IL
RB
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
Figure 134. Battery Current Monitor
an105fa
AN105-76
Application Note 105
BATTERIES
Input Current Sensing Application (Figure 135)
Coulomb Counter (Figure 136)
The LT1620 is coupled with an LT1513 SEPIC battery charger IC to create an input over current protected charger
circuit. The programming voltage (VCC – VPROG) is set to
1.0V through a resistor divider (RP1 and RP2) from the
5V input supply to ground. In this configuration, if the
input current drawn by the battery charger combined
with the system load requirements exceeds a current
limit threshold of 3A, the battery charger current will be
reduced by the LT1620 such that the total input supply
current is limited to 3A.
The LTC4150 is a micropower high side sense circuit that
includes a V/F function. Voltage across the sense resistor
is cyclically integrated and reset to provide digital transitions that represent charge flow to or from the battery. A
polarity bit indicates the direction of the current. Supply
potential for the LTC4150 is 2.7V to 8.5V. In the free-running
mode (as shown, with CLR and INT connected together)
the pulses are approximately 1μs wide and around 1Hz
full-scale.
5V
22µF
+
+
C1
1µF
1
2
SENSE
AVG
RP1
3k
1%
8
7
PROG
LT1620MS8
6
3
VCC
GND
4
IOUT
+
7
22µF
VSW
VIN
L1B
10µH
5
4.7µF
LT1513
RUN
6
4
4.7µF
RL
RP2
12k
1%
R1
0.033Ω
S/S
VFB
GND
GND
TAB
IFB
4.7µF
8
VC
0.1µF
X7R
CF–
LTC4150
CLR
CHG
DISCHG
POL
µP
SHDN
TO
SYSTEM LOAD
4150 TA01a
Figure 136. Coulomb Counter
MBRS340
L1A
10µH
24Ω
VBATT = 12.3V
57k
+
22µF
×2
6.4k
0.22µF
1
RL
SENSE – SENSE + VDD
CF+
INT
GND
2
3
LOAD
C2
1µF
5
IN+
IN–
CHARGER
RSENSE
RSENSE
0.1Ω
1620/21 • F04
Figure 135. Input Current Sensing Application
Li-ION
Li-Ion Gas Gauge (Figure 137)
This is the same as the Coulomb Counter circuit, except that
the microprocessor clears the integration cycle complete
condition with software, so that a relatively slow polling
routine may be used.
NiMH Charger (Figure 138)
The LTC4008 is a complete NiMH battery pack controller.
It provides automatic switchover to battery power when
the external DC power source is removed. When power
is connected the battery pack is always kept charged and
ready for duty.
an105fa
AN105-77
Application Note 105
BATTERIES
POWER-DOWN
SWITCH
2.5V
1
RSENSE
0.1Ω
2-CELL
Li-Ion
6V ~ 8.4V
SENSE +
INT
LTC4150 CLR
2
3
+
CF
4.7µF
4
5
SENSE –
VDD
CF+
GND
CF–
SHDN
POL
RL
3k
RL
3k
10
LOAD
CL
47µF
9
8
C2
4.7µF
7
µP
6
SHUTDOWN
Figure 137. Li-Ion Gas Gauge
Q3
INPUT SWITCH
DCIN
0V TO 20V
VLOGIC
ICL
R8
147k
0.25%
R11
100k
R12
100k
ACP
C1
0.1µF
BATMON
DCIN
VFB
INFET
ICL
LTC4008 CLP
ACP/SHDN
FAULT
FLAG
R10 32.4k 1%
TGATE
FLAG
BGATE
NTC
PGND
ITH
R9
C7
13.3k
0.47µF 0.25%
THERMISTOR
10k
NTC
RT
150k
R7
6.04k
1%
C6
0.12µF
GND
RCL
0.02Ω
1%
SYSTEM
LOAD
C2
20µF
CLN
FAULT
RT
C4
0.1µF
R1 5.1k 1%
L1
10µH
Q1
Q2
D1
CSP
BAT
RSENSE
0.025Ω
1%
C3
20µF
NiMH
BATTERY
PACK
R4 3.01k 1%
R5 3.01k 1%
PROG
C5
0.0047µF
R6
26.7k
1%
CHARGING
CURRENT
MONITOR
D1: MBRS130T3
Q1: Si4431ADY
Q2: FDC645N
4008 TA02
Figure 138. NiMH Charger
an105fa
AN105-78
Application Note 105
BATTERIES
Single Cell Li-Ion Charger (Figure 139)
VIN
5V TO 22V
Controlling the current flow in lithium-ion battery chargers
is essential for safety and extending useful battery life.
Intelligent battery charger ICs can be used in fairly simple
circuits to monitor and control current, voltage and even
battery pack temperature for fast and safe charging.
0.1µF
BAT
GATE
2k
LTC4002ES8-4.2
CHARGE
STATUS
Li-Ion Charger (Figure 140)
6.8µH
CHRG
Just a few external components are required for this single
Li-Ion cell charger. Power for the charger can come from
a wall adapter or a computer’s USB port.
SENSE
68mΩ
0.47µF
2.2k
Battery Monitor (Figure 141)
Op amp sections A and B form classical high side sense
circuits in conjunction with Q1 and Q2 respectively. Each
section handles a different polarity of battery current flow
and delivers metered current to load resistor RG. Section C operates as a comparator to provide a logic signal
indicating whether the current is a charge or discharge
flow. S1 sets the section D buffer op-amp gain to +1 or
+10. Rail-to-rail op amps are required in this circuit, such
as the LT1491 quad in the example.
10µF
VCC
BAT
GND
COMP
NTC
22µF
10k
NTC
T
+
Li-Ion
BATTERY
4002 TA01
NTC: DALE NTHS-1206N02
Figure 139. Single Cell Li-Ion Charger
800mA (WALL)
500mA (USB)
LTC4076
WALL
ADAPTER
DCIN
USB
PORT
1µF
HPWR
+
IUSB
2k
IDC
1% 1.24k
1%
1µF
BAT
USBIN
ITERM
GND
4.2V
SINGLE CELL
Li-Ion BATTERY
1k
1%
4076 TA01
Figure 140. Li-Ion Charger
CHARGER
VOLTAGE
RS
0.2Ω
RA
2k
IBATT
RA'
2k
+
A
1/4 LT1491
Q1
2N3904
–
C
1/4 LT1491
–
LOGIC
+
RB
2k
+
B
1/4 LT1491
RB'
2k
LOAD
Q2
2N3904
–
+
+
RG
10k
VBATT = 12V
S1
IBATT =
LOGIC HIGH (5V) = CHARGING
LOGIC LOW (0V) = DISCHARGING
VOUT
V
= OUT AMPS
(RS)(RG /RA)(GAIN) GAIN
D
1/4 LT1491
VOUT
–
10k
90.9k
S1 = OPEN, GAIN = 1
S1 = CLOSED, GAIN = 10
RA = RB
VS = 5V, 0V
1490/91 TA01
Figure 141. Battery Monitor
an105fa
AN105-79
Application Note 105
BATTERIES
Battery Stack Monitoring (Figure 143)
Monitor Charge and Discharge Currents at One Output
(Figure 142)
The comparators used in the LT6109 can be used separately. In this battery stack monitoring circuit a low on
either comparator output will disconnect the load from
the battery. One comparator watches for an overcurrent
condition (800mA) and the other for a low voltage condition (30V). These threshold values are fully programmable
using resistor divider networks.
Current from a battery to a load or from a charger to the
battery can be monitored using a single sense resistor
and the LTC6104. Discharging load current will source
a current at the output pin in proportion to the voltage
across the sense resistor. Charging current into the battery
will sink a current at the output pin. The output voltage
above or below the voltage VREF will indicate charging or
discharging of the battery.
ICHARGE
–
CHARGER
+
RSENSE
IDISCHARGE
RIN
RIN
8
7
6
–INA
+INA
ILOAD
VSENSE
5
–INB
+INB
+ –
LOAD
LTC6104
– +
B
A
VS
CURRENT
MIRROR
OUT
1
+
VS
V–
4
+
ROUT
VOUT
+
–
–
VREF
6104 TA03
Figure 142. Monitor Charge and Discharge Currents at One Output
12 LITHIUM
40V CELL STACK
SENSE
LOW
0.1Ω
+
10µF
+
+
1M
0.1µF
100k
R10
100Ω
INC2
10
13.3k
9
5V
+
10k
SENSEHI SENSELO
V+
OUTA
LT6109-1
RESET
2
4
3
IRF9640
EN/RST
INC1
OUTC1
OUTC2
V–
5
INC2
TO
LOAD
6.2V
1
8
0.8A
OVERCURRENT
6 DETECTION
7
VOUT
9.53k
100k
475Ω
2N7000
30V
UNDERVOLTAGE
DETECTION
6109 TA02
Figure 143. Battery Stack Monitoring
an105fa
AN105-80
Application Note 105
BATTERIES
Coulomb Counting Battery Gas Gauge (Figure 144)
High Voltage Battery Coulomb Counting (Figure 145)
The LTC4150 converts the voltage across a sense resistor to a microprocessor interrupt pulse train. The time
between each interrupt pulse is directly proportional to the
current flowing through the sense resistor and therefore
the number of coulombs travelling to or from the battery
power source. A polarity output indicates the direction of
current flow. By counting interrupt pulses with the polarity
adding or subtracting from the running total, an indication
of the total change in charge on a battery is determined.
This acts as a battery gas gauge to indicate where the
battery charge is between full or empty.
When coulomb counting, after each interrupt interval
the internal counter needs to be cleared for the next
time interval. This can be accomplished by the µP or the
LTC4150 can clear itself. In this circuit the IC is powered
from a battery supply which is at a higher voltage than
the interrupt counting µP supply.
CHARGER
RSENSE
+
LOAD
4.7µF
SENSE– SENSE+
4.7µF
CF+
RL
RL
VDD
INT
LTC4150
CF–
CLR
CHG
GND
µP
DISCHG
POL
SHDN
4150 TA01a
Figure 144. Coulomb Counting Battery Gas Gauge
POWER-DOWN
SWITCH
PROCESSOR
VCC
1
SENSE+
2
2.7V TO 8.5V
BATTERY
INT
LTC4150 CLR
RSENSE
+
3
CF
4.7µF
4
5
SENSE–
VDD
CF+
GND
CF–
SHDN
POL
10
RL
CL
47µF
LOAD
RL
9
8
7
C2
4.7µF
µP
6
4150 F05
Figure 145. High Voltage Battery Coulomb Counting
an105fa
AN105-81
Application Note 105
BATTERIES
Low Voltage Battery Coulomb Counting (Figure 146)
When coulomb counting, after each interrupt interval the
internal counter needs to be cleared for the next time interval. This can be accomplished by the µP or the LTC4150
can clear itself. In this circuit the IC is powered from a
battery supply which is at a lower voltage than the interrupt
counting µP supply. The CLR signal must be attenuated
because the INT pin is pulled to a higher voltage.
Single Cell Lithium-Ion Battery Coulomb Counter
(Figure 147)
This is a circuit which will keep track of the total change
in charge of a single cell Li-Ion battery power source. The
maximum battery current is assumed to be 500mA due
to the 50mV full-scale sense voltage requirement of the
LTC4150. The µP supply is greater than the battery supply.
POWER-DOWN
SWITCH
CL
47µF
PROCESSOR
VCC
1
SENSE+
LTC4150 CLR
RSENSE
2
BATTERY
VBATTERY < VCC
INT
+
3
CF
4.7µF
4
5
SENSE–
VDD
CF+
GND
CF–
SHDN
POL
RL
10
9
LOAD
RL
R2
8
C2
4.7µF
7
R1
µP
6
SHUTDOWN
R4
4150 F06
R3
Figure 146. Low Voltage Battery Coulomb Counting
POWER-DOWN
SWITCH
5.0V
1
RSENSE
0.1Ω
SINGLE-CELL
Li-Ion
3.0V ~ 4.2V
SENSE+
INT
LTC4150 CLR
2
3
+
CF
4.7µF
4
5
SENSE–
CF+
VDD
GND
CF–
SHDN
POL
RL
3k
10
9
CL
47µF
LOAD
RL
3k
R2
76.8k
8
C2
4.7µF
7
R1
75k
µP
6
SHUTDOWN
R4
76.8k
R3
75k
4150 F08
Figure 147. Single Cell Lithium-Ion Battery Coulomb Counter
an105fa
AN105-82
Application Note 105
BATTERIES
Complete Single Cell Battery Protection (Figure 148)
and signal the termination or initiation of cell charging.
The ADC can be continually reconfigured for single-ended
or differential measurements to produce the required
information.
Voltage, current and battery temperature can all be monitored by a single LTC2990 ADC to 14-bit resolution. Each
of these parameters can detect an excessive condition
CHARGING
CURRENT
5V
2-WIRE
I2C
INTERFACE
BATTERY I AND V MONITOR
15mΩ*
0.1µF
VCC
V1
V2
SDA
SCL LTC2990
ADR0
ADR1
GND
MMBT3904
V3
•••
470pF
V4
TINTERNAL
+
NiMH
BATTERY
TBATT
T(t)
V(t)
100%
100%
I(t)
100%
2990 TA07
*IRC LRF3W01R015F
VOLTAGE AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x58
REG 4, 5
0.0625°C/LSB
TAMB
REG 8, 9
305.18µVLSB
VBAT
REG A, B
0.0625°C/LSB
TBAT
REG E, F
2.5V + 305.18µV/LSB
VCC
CURRENT AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x59
REG 4, 5
0.0625°C/LSB
TAMB
REG 6, 7
1.295mA/LSB
IBAT
REG A, B
0.0625°C/LSB
TBAT
REG E, F
2.5V + 305.18µV/LSB
VCC
Figure 148. Complete Single Cell Battery Protection
More Battery Circuits Are Shown in Other Chapters:
FIGURE
TITLE
21
Sensed Current Includes Monitor Circuit Supply Current
58
Bidirectional Precision Current Sensing
179
Digitizing Charging and Loading Current in a Battery Monitor
181
Ampere-Hour Gauge
209
Use Kelvin Connections to Maintain High Current Accuracy
216
Dual Sense Amplifier Can Have Different Sense Resistors and Gain
an105fa
AN105-83
Application Note 105
HIGH SPEED
Current monitoring is not normally a particularly high speed
requirement unless excessive current flow is caused by a
fault of some sort. The use of fast amplifiers in conventional
current sense circuits is usually sufficient to obtain the
response time desired.
Fast Compact –48V Current Sense (Figure 149)
This amplifier configuration is essentially the complementary implementation to the classic high side configuration.
The op amp used must support common mode operation
at its lower rail. A “floating” shunt-regulated local supply
is provided by the Zener diode, and the transistor provides
metered current to an output load resistance (1kΩ in this
circuit). In this circuit, the output voltage is referenced to a
positive potential and moves downward when representing increasing –48V loading. Scaling accuracy is set by
the quality of resistors used and the performance of the
NPN transistor.
A common monitoring approach in these systems is to
amplify the voltage on a “flying” sense resistor, as shown.
Unfortunately, several potentially hazardous fault scenarios
go undetected, such as a simple short to ground at a motor
terminal. Another complication is the noise introduced by
the PWM activity. While the PWM noise may be filtered for
purposes of the servo law, information useful for protection
becomes obscured. The best solution is to simply provide
two circuits that individually protect each half-bridge and
report the bidirectional load current. In some cases, a
smart MOSFET bridge driver may already include sense
resistors and offer the protection features needed. In these
situations, the best solution is the one that derives the load
information with the least additional circuitry.
BATTERY BUS
+
Conventional H-Bridge Current Monitor (Figure 150)
+
RS
Many of the newer electric drive functions, such as steering assist, are bidirectional in nature. These functions are
generally driven by H-bridge MOSFET arrays using pulsewidth modulation (PWM) methods to vary the commanded
torque. In these systems, there are two main purposes for
current monitoring. One is to monitor the current in the
load, to track its performance against the desired command (i.e., closed-loop servo law), and another is for fault
detection and protection features.
–
IM
DIFF
AMP
DN374 F03
Figure 150. Conventional H-Bridge Current Monitor
VOUT = 3V – 0.1Ω • ISENSE
ISENSE = 0A TO 30A
ACCURACY ≈ 3%
VOUT
Q1
FMMT493
30.1Ω
1%
–
3.3k
0805
×3
+
–48V SUPPLY
(–42V TO –56V)
ISENSE
+
VS = 3V
R1 REDUCES Q1 DISSIPATION
0.003Ω
1% 3W
–
1k
1%
LT1797
0.1µF
BZX84C6V8
VZ = 6.8V
R1
4.7k
1797 TA01
SETTLES TO 1% IN 2s,
1V OUTPUT STEP
–48V LOAD
Figure 149. Fast Compact –48V Current Sense
an105fa
AN105-84
Application Note 105
HIGH SPEED
Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
(Figure 151)
may drive following circuitry more effectively than the
high output impedance of the LT1787. The I/V converter
configuration also works well with split supply voltages.
The LT1787’s output is buffered by an LT1495 rail-to-rail
op amp configured as an I/V converter. This configuration
is ideal for monitoring very low voltage supplies. The
LT1787’s VOUT pin is held equal to the reference voltage
appearing at the op amp’s non-inverting input. This allows one to monitor supply voltages as low as 2.5V. The
op amp’s output may swing from ground to its positive
supply voltage. The low impedance output of the op amp
Battery Current Monitor (Figure 152)
One LT1495 dual op amp package can be used to establish
separate charge and discharge current monitoring outputs.
The LT1495 features Over-the-Top operation allowing
the battery potential to be as high as 36V with only a 5V
amplifier supply voltage.
ISENSE
RSENSE
TO
CHARGER/
LOAD
1
FIL–
–
2 VS
3
4
DNC
C1
1µF
8
FIL+
LT1787
2.5V + VSENSE(MAX)
VS+ 7
2.5V
VBIAS 6
ROUT
VEE
C3
1000pF
5
VOUT
2.5V
–
+
1M
5%
VOUT A
A1
LT1495
LT1389-1.25
1787 F07
Figure 151. Single-Supply 2.5V Bidirectional Operation with External Voltage Reference and I/V Converter
IL
CHARGE
RSENSE
0.1Ω
DISCHARGE
–
A2
1/2 LT1495
RA
RA
RA
2N3904
DISCHARGE
OUT
RB
12V
5V
RA
–
A1
1/2 LT1495
+
2N3904
CHARGE
OUT
VO = IL
RB
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
Figure 152. Battery Current Monitor
an105fa
AN105-85
+
Application Note 105
HIGH SPEED
Fast Current Sense with Alarm (Figure 153)
Fast Differential Current Source (Figure 154)
The LT1995 is shown as a simple unity gain difference
amplifier. When biased with split supplies the input current
can flow in either direction providing an output voltage of
100mV/A from the voltage across the 100mΩ sense resistor. With 32MHz of bandwidth and 1000V/µs slew rate the
response of this sense amplifier is fast. Adding a simple
comparator with a built in reference voltage circuit such
as the LT6700-3 can be used to generate an overcurrent
flag. With the 400mV reference the flag occurs at 4A.
This is a variation on the Howland configuration, where
load current actually passes through a feedback resistor
as an implicit sense resistance. Since the effective sense
resistance is relatively large, this topology is appropriate
for producing small controlled currents.
15V
15V TO –15V
VIN1
I
P1
0.1Ω LT1995
G=1
M1
–15V
LT6700-3
10k
REF
SENSE
OUTPUT
100mV/A
10k
+
–
VIN2
R*
R*
15V
2
3
LT1022
+
4
–15V
FLAG
OUTPUT
4A LIMIT
400mV
1995 TA05
10pF
7
–
R*
IOUT =
6
VIN2 – VIN1
R
R*
IOUT
RL
*MATCH TO 0.01%
FULL-SCALE POWER BANDWIDTH
= 1MHz FOR IOUTR = 8VP-P
= 400kHz FOR IOUTR = 20VP-P
MAXIMUM IOUT = 10mAP-P
IOUTP-P • RL
COMMON MODE VOLTAGE AT LT1022 INPUT =
2
LT1022 • TA07
Figure 153. Fast Current Sense with Alarm
Figure 154. Fast Differential Current Source
More High Speed Circuits Are Shown in Other Chapters:
FIGURE
TITLE
22
Wide Voltage Range Current Sensing
124
Monitor H-Bridge Motor Current Directly
128
Fixed Gain DC Motor Current Monitor
143
Battery Stack Monitoring
168
Monitoring a Fuse Protected Circuit
169
Circuit Fault Protection with Early Warning and Latching Load Disconnect
170
Use Comparator Output to Initialize Interrupt Routines
an105fa
AN105-86
Application Note 105
FAULT SENSING
The lack of current flow or the dramatic increase of current
flow very often indicates a system fault. In these circuits
it is important to not only detect the condition, but also
ensure the safe operation of the detection circuitry itself.
System faults can be destructive in many unpredictable
ways.
RSENSE
R1
100
4
L
O
A
D
D1
3
4
VS+
VCC
FIL
VEE
+
A4
–
2
C2
0.1µF
8
VS–
BATTERY
BUS
Figure 156. Schottky Prevents Damage During Supply Reversal
Additional Resistor R3 Protects Output During Supply
Reversal (Figure 157)
If the output of the LTC6101 is wired to an independently
powered device that will effectively short the output to
another rail or ground (such as through an ESD protection
clamp) during a reverse supply condition, the LTC6101’s
output should be connected through a resistor or Schottky
diode to prevent excessive fault current.
RSENSE
7
R1
100
4
A2
6
OUT 5
LT6100
R2
4.99k
6101 F07
+
ADC
POWER
≥2.7V
1
1
LTC6101
The LT6100 can be used as a combination current sensor and fuse monitor. This part includes on-chip output
buffering and was designed to operate with the low supply
voltage (≥2.7V), typical of vehicle data acquisition systems,
while the sense inputs monitor signals at the higher battery bus potential. The LT6100 inputs are tolerant of large
input differentials, thus allowing the blown-fuse operating
condition (this would be detected by an output full-scale
indication). The LT6100 can also be powered down while
maintaining high impedance sense inputs, drawing less
than 1µA max from the battery bus.
RSENSE
2mΩ FUSE
5
VBATT
High Side Current Sense and Fuse Monitor
(Figure 155)
TO LOAD
3
+ –
2
L
O
A
D
OUTPUT
2.5V = 25A
DN374 F02
+ –
2
LTC6101
D1
VBATT
3
5
1
R3
1k
ADC
R2
4.99k
6101 F08
Figure 155. High Side Current Sense and Fuse Monitor
Schottky Prevents Damage During Supply Reversal
(Figure 156)
The LTC6101 is not protected internally from external
reversal of supply polarity. To prevent damage that may
occur during this condition, a Schottky diode should be
added in series with V–. This will limit the reverse current
through the LTC6101. Note that this diode will limit the
low voltage performance of the LTC6101 by effectively
reducing the supply voltage to the part by VD.
Figure 157. Additional Resistor R3 Protects Output During
Supply Reversal
Electronic Circuit Breaker (Figure 158)
The LT1620l current sense amplifier is used to detect an
overcurrent condition and shut off a P-MOSFET load switch.
A fault flag is produced in the overcurrent condition and
a self-reset sequence is initiated.
an105fa
AN105-87
Application Note 105
FAULT SENSING
Si9434DY
0.033Ω
5V
0.1µF
5V AT 1A
PROTECTED
1k
FAULT
CDELAY
100Ω
33k
2N3904
1
2
SENSE
AVG
7
PROG
LT1620MS8
3
6
VCC
GND
4
1N4148
8
100k
IOUT
–IN
+IN
TYPICAL DC TRIP AT 1.6A
3A FAULT TRIPS
IN 2ms WITH CDELAY = 1.0µF
4.7k
33k
5
2N3904
LT1620/21 • TA03
Figure 158. Electronic Circuit Breaker
Electronic Circuit Breaker (Figure 159)
The LTC1153 is an electronic circuit breaker. Sensed current to a load opens the breaker when 100mV is developed
between the supply input, VS, and the drain sense pin, DS.
To avoid transient, or nuisance trips of the break components RD and CD delay the action for 1ms. A thermistor
can also be used to bias the shutdown input to monitor
heat generated in the load and remove power should the
temperature exceed 70°C in this example. A feature of
the LTC1153 is timed automatic reset which will try to
reconnect the load after 200ms using the 0.22μF timer
capacitor shown.
1.25V Electronic Circuit Breaker (Figure 160)
The LTC4213 provides protection and automatic circuit
breaker action by sensing drain-to-source voltage drop
across the N-MOSFET. The sense inputs have a rail-to-rail
common mode range, so the circuit breaker can protect
bus voltages from 0V up to 6V. Logic signals flag a trip
condition (with the READY output signal) and reinitialize
the breaker (using the ON input). The ON input may also
be used as a command in a “smart switch” application.
ON/OFF
IN
CT
0.22µF
VS
CT
Z5U
DS
CD
RD
0.01µF 100k
*RSEN
0.1Ω
LTC1153
TO µP
STATUS
51k
5V
GND
IRLR024
G
51k
SHUTDOWN
SENSITIVE
5V LOAD
**70°C
PTC
ALL COMPONENTS SHOWN ARE SURFACE MOUNT.
* IMS026 INTERNATIONAL MANUFACTURING SERVICE, INC. (401) 683-9700
** RL2006-100-70-30-PT1 KEYSTONE CARBON COMPANY (814) 781-1591
LTC1153 • TA01
Figure 159. Electronic Circuit Breaker
SI4864DY
VIN
1.25V
VBIAS
2.3V TO 6V
VCC
VOUT
1.25V
3.5A
SENSEP GATE SENSEN
LTC4213
OFF ON
ON
GND
ISEL
VBIAS
10k
READY
4213 TA01
Figure 160. 1.25V Electronic Circuit Breaker
an105fa
AN105-88
Application Note 105
FAULT SENSING
Lamp Outage Detector (Figure 161)
In this circuit, the lamp is monitored in both the on and off
condition for continuity. In the off condition, the filament
pull-down action creates a small test current in the 5kΩ that
is detected to indicate a good lamp. If the lamp is open, the
100kΩ pull-up, or the relay contact, provides the op amp
bias current through the 5kΩ, that is opposite in polarity.
When the lamp is powered and filament current is flowing,
the drop in the 0.05Ω sense resistor will exceed that of the
5kΩ and a lamp-good detection will still occur. This circuit
requires particular Over-the-Top input characteristics for
5V TO 44V
LAMP
ON/OFF
1M
100k
5k
0.5Ω
3V
Simple Telecom Power Supply Fuse Monitor
(Figure 162)
The LTC1921 provides an all-in-one telecom fuse and
supply-voltage monitoring function. Three opto-isolated
status flags are generated that indicate the condition of
the supplies and the fuses.
Conventional H-Bridge Current Monitor (Figure 163)
Many of the newer electric drive functions, such as steering assist, are bidirectional in nature. These functions are
generally driven by H-bridge MOSFET arrays using pulsewidth modulation (PWM) methods to vary the commanded
torque. In these systems, there are two main purposes for
current monitoring. One is to monitor the current in the
load, to track its performance against the desired command (i.e., closed-loop servo law), and another is for fault
detection and protection features.
–
OUT
LT1637
the op amp, so part substitutions are discouraged (however, this same circuit also works properly with an LT1716
comparator, also an Over-the-Top part).
+
OUT = 0V FOR GOOD BULB
3V FOR OPEN BULB
1637 TA05
Figure 161. Lamp Outage Detector
47k
–48V
RETURN
R1
100k
R2
100k
1
8
2
7
MOC207
3
RTN
OUT F
VA
SUPPLY B
–48V
47k
4
5V
SUPPLY A
STATUS
VB
LTC1921
47k
FUSE B
OUT A
F1
D1
F2
D2
5
6
5V
SUPPLY B
STATUS
MOC207
R3
47k
1/4W
VA
VB
OK
OK
OK
UV OR OV
UV OR OV
OK
UV OR OV UV OR OV
SUPPLY A
STATUS
0
0
1
1
SUPPLY B
STATUS
0
1
0
1
OK: WITHIN SPECIFICATION
OV: OVERVOLTAGE
UV: UNDERVOLTAGE
MOC207
FUSE A
OUT B
SUPPLY A
–48V
5V
FUSE
STATUS
–48V OUT
= LOGIC COMMON
VFUSE A
= VA
= VA
≠ VA
≠ VA
VFUSE B
= VB
≠ VB
= VB
≠ VB
FUSE STATUS
0
1
1
1*
0: LED/PHOTODIODE ON
1: LED/PHOTODIODE OFF
*IF BOTH FUSES (F1 AND F2) ARE OPEN,
ALL STATUS OUTPUTS WILL BE HIGH
SINCE R3 WILL NOT BE POWERED
Figure 162. Simple Telecom Power Supply Fuse Monitor
an105fa
AN105-89
Application Note 105
FAULT SENSING
A common monitoring approach in these systems is to
amplify the voltage on a “flying” sense resistor, as shown.
Unfortunately, several potentially hazardous fault scenarios
go undetected, such as a simple short to ground at a motor
terminal. Another complication is the noise introduced by
the PWM activity. While the PWM noise may be filtered for
purposes of the servo law, information useful for protection
becomes obscured. The best solution is to simply provide
two circuits that individually protect each half-bridge and
report the bidirectional load current. In some cases, a
smart MOSFET bridge driver may already include sense
resistors and offer the protection features needed. In these
situations, the best solution is the one that derives the load
information with the least additional circuitry.
ISENSE
RSENSE
TO
CHARGER/
LOAD
1
FIL–
LT1787
–
2 VS
3
4
C1
1µF
8
FIL+
2.5V + VSENSE(MAX)
VS+ 7
2.5V
VBIAS 6
DNC
ROUT
VEE
C3
1000pF
5
VOUT
2.5V
–
+
1M
5%
VOUT A
A1
LT1495
LT1389-1.25
1787 F07
Figure 164. Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
BATTERY BUS
+
Battery Current Monitor (Figure 165)
RS
IM
+
–
DIFF
AMP
One LT1495 dual op amp package can be used to establish
separate charge and discharge current monitoring outputs.
The LT1495 features Over-the-Top operation allowing
the battery potential to be as high as 36V with only a 5V
amplifier supply voltage.
IL
CHARGE
Single-Supply 2.5V Bidirectional Operation with
External Voltage Reference and I/V Converter
(Figure 164)
The LT1787’s output is buffered by an LT1495 rail-to-rail
op amp configured as an I/V converter. This configuration
is ideal for monitoring very low voltage supplies. The
LT1787’s VOUT pin is held equal to the reference voltage
appearing at the op amp’s non-inverting input. This allows one to monitor supply voltages as low as 2.5V. The
op amp’s output may swing from ground to its positive
supply voltage. The low impedance output of the op amp
may drive following circuitry more effectively than the
high output impedance of the LT1787. The I/V converter
configuration also works well with split supply voltages.
AN105-90
A2
1/2 LT1495
+
Figure 163. Conventional H-Bridge Current Monitor
DISCHARGE
–
DN374 F03
RSENSE
0.1Ω
RA
RA
RA
2N3904
DISCHARGE
OUT
RB
12V
5V
RA
–
A1
1/2 LT1495
+
2N3904
CHARGE
OUT
V O = IL
RB
()
RB
RSENSE
RA
FOR RA = 1k, RB = 10k
VO
= 1V/A
IL
1495 TA05
Figure 165. Battery Current Monitor
an105fa
Application Note 105
FAULT SENSING
Fast Current Sense with Alarm (Figure 166)
The LT1995 is shown as a simple unity gain difference
amplifier. When biased with split supplies the input current
can flow in either direction providing an output voltage of
100mV/A from the voltage across the 100mΩ sense resistor. With 32MHz of bandwidth and 1000V/µs slew rate the
response of this sense amplifier is fast. Adding a simple
comparator with a built in reference voltage circuit such
as the LT6700-3 can be used to generate an overcurrent
flag. With the 400mV reference the flag occurs at 4A.
LOAD
RSENSE
RIN
–IN
+IN
– +
V–
V+
1/2
LTC6103
OUT
VLOGIC
ROUT
15V
15V TO –15V
ISENSE
+ VSENSE –
VS
VOUT
I
P1
0.1Ω LT1995
G=1
M1
–15V
LT6700-3
10k
REF
SENSE
OUTPUT
100mV/A
10k
+
–
ANY OPTO-ISOLATOR
V–
6103 TA07
N = OPTO-ISOLATOR CURRENT GAIN
FLAG
OUTPUT
4A LIMIT
R
VOUT = VLOGIC – ISENSE • SENSE • N • ROUT
RIN
400mV
Figure 167. Monitor Current in an Isolated Supply Line
1995 TA05
Figure 166. Fast Current Sense with Alarm
TO LOAD
C1
0.1µF
DC SOURCE
(≤ 44V)
+IN
V+
5V
C2
0.1µF
–
Current sensing a supply line that has a fuse for overcurrent
protection requires a current sense amplifier with a wide
differential input voltage rating. Should the fuse blow open
the full load supply voltage appears across the inputs to the
sense amplifier. The LT6105 can work with input voltage
differentials up to 44V. The LT6105 output slews at 2V/µs
so can respond quickly to fast current changes. When the
fuse opens the LT6105 output goes high and stays there.
RIN2
–IN
+
VS+
+
Monitoring a Fuse Protected Circuit (Figure 168)
FUSE
RIN1
Monitor Current in an Isolated Supply Line
(Figure 167)
Using the current sense amplifier output current to directly
modulate the current in a photo diode is a simple method
to monitor an isolated 48V industrial/telecom power supply.
Current faults can be signaled to nonisolated monitoring
circuitry.
RSENSE
VS–
V–
OUT
LT6105
6105 F03
OUTPUT
ROUT
Figure 168. Monitoring a Fuse Protected Circuit
an105fa
AN105-91
Application Note 105
FAULT SENSING
Circuit Fault Protection with Early Warning and
Latching Load Disconnect (Figure 169)
Use Comparator Output to Initialize Interrupt Routines
(Figure 170)
With a precision current sense amplifier driving two built
in comparators, LT6109-2 can provide current overload
protection to a load circuit. The internal comparators have
a fixed 400mV reference. The current sense output is
resistor divided down so that one comparator will trip at
an early warning level and the second at a danger level of
current to the load (100mA and 250mA in this example).
The comparator outputs latch when tripped so they can
be used as a circuit breaker to disconnect and protect the
load until a reset pulse is provided.
The comparator outputs can connect directly to I/O or
interrupt inputs to any microcontroller. A low level at
OUTC2 can indicate an undercurrent condition while a low
level at OUTC1 indicates an overcurrent condition. These
interrupts force service routines in the microcontroller.
0.1Ω
12V
6.2V
1k
IRF9640
TO LOAD
10µF
100Ω
3.3V
SENSEHI SENSELO
10k
1.62k
V+
100k
EN/RST
RESET
100mA WARNING
OUTC2
250mA DISCONNECT
OUTC1
1k
2N2700
VOUT
OUTA
LT6109-2
6.04k
INC2
2.37k
INC1
V–
1.6k
610912 TA01a
Figure 169. Circuit Fault Protection with Early Warning and Latching Load Disconnect
0.1Ω
V+
TO LOAD
EXAMPLE
5V
OUTC2 GOES LOW
100Ω
10
9
AtMega1280
5
PB0
6
PB1
7
PCINT2
2
PCINT3
3
ADC2
1
PB5
5V
V+
OUTA
1
8
LT6109-1
10k
RESET 2
3
4
5V
VOUT/ADC IN
SENSEHI SENSELO
10k
EN/RST
INC2
OUTC2
OUTC1
V–
5
INC1
7
6
VOUT
ADC IN
MCU INTERUPT
2k
6.65k
1.33k
UNDERCURRENT ROUTINE
RESET COMPARATORS
6109 TA03
Figure 170. Use Comparator Output to Initialize Interrupt Routines
an105fa
AN105-92
Application Note 105
FAULT SENSING
Current Sense with Overcurrent Latch and Power-On
Reset with Loss of Supply (Figure 171)
arrangement can create a latching output when an overcurrent condition is sensed. The same logic gate can also
generate an active low power-on reset signal.
The LT6801-2 has a normal nonlatching comparator built
in. An external logic gate configured in a positive feedback
5V
7
V+
LT6108-2
RIN
100Ω 8
R3
10k
RSENSE
1
SENSEHI
–
SENSELO
+
ILOAD
V+
OUTA 6
V–
V+
3
INC 5
–
OUTC
+
R1
24.9k VTH
R7
9.53k
R8
499Ω
400mV
REFERENCE
V–
R9*
30k
Q1*
2N2222
C1
0.1µF
VDD
R4*
3.4k
R5*
100k
R2
200k
4
610812 TA06
R6
1M
*OPTIONAL COMPONENT
Figure 171. Current Sense with Overcurrent Latch and Power-On Reset with Loss of Supply
an105fa
AN105-93
Application Note 105
FAULT SENSING
More Fault Sensing Circuits Are Shown in Other Chapters:
FIGURE
TITLE
120
Bidirectional Current Sensing in H-Bridge Drivers
125
Large Input Voltage Range for Fused Solenoid Current Monitoring
136
Coulomb Counting Battery Gas Gauge
143
Battery Stack Monitoring
145
High Voltage Battery Coulomb Counting
146
Low Voltage Battery Coulomb Counting
147
Single Cell Lithium-Ion Battery Coulomb Counter
211
Power Intensive Circuit Board Monitoring
an105fa
AN105-94
Application Note 105
DIGITIZING
In many systems the analog voltage quantity indicating
current flow must be input to a system controller. In this
chapter several examples of the direct interface of a current sense amplifier to an A to D converter are shown.
Sensing Output Current (Figure 172)
The LT1970 is a 500mA power amplifier with voltage
programmable output current limit. Separate DC voltage
inputs and an output current sensing resistor control the
maximum sourcing and sinking current values. These
control voltages could be provided by a D-to-A converter
in a microprocessor controlled system. For closed loop
control of the current to a load an LT1787 can monitor the
output current. The LT1880 op amp provides scaling and
level shifting of the voltage applied to an A-to-D converter
for a 5mV/mA feedback signal.
VCC
0V TO 1V
12V
VCSRC
VCSNK
+IN
–IN
COMMON
EN
VCC
V+
ISRC
ISNK
RS
0.2Ω
TSD
OUT
LT1970
SENSE+
–
SENSE
FILTER
–
V
VEE
RLOAD
R4
255k
LT1787
RG
RF
VS–
–12V
VS+
20k
VEE
–12V
BIAS
–12V
R1
60.4k
R2
10k
–
+
R3
20k
12V
VOUT
2.5V
±5mV/mA
LT1880
1kHz FULL CURRENT
BANDWIDTH
–12V
0V TO 5V
A/D
1970 F10
OPTIONAL DIGITAL FEEDBACK
Figure 172. Sensing Output Current
an105fa
AN105-95
Application Note 105
DIGITIZING
Split or Single-Supply Operation, Bidirectional Output
into A/D (Figure 173)
16-Bit Resolution Unidirectional Output into LTC2433
ADC (Figure 174)
In this circuit, split supply operation is used on both the
LT1787 and LT1404 to provide a symmetric bidirectional
measurement. In the single-supply case, where the LT1787
Pin 6 is driven by VREF, the bidirectional measurement
range is slightly asymmetric due to VREF being somewhat
greater than midspan of the ADC input range.
The LTC2433-1 can accurately digitize signal with source
impedances up to 5kΩ. This LTC6101 current sense circuit
uses a 4.99kΩ output resistance to meet this requirement,
thus no additional buffering is necessary.
1Ω
1%
IS = ±125mA
1
VSRCE
≈4.75V
FIL–
–
2 VS
3
LT1787
VCC
5V
8
FIL+
10µF
16V
VS+ 7
VBIAS 6
DNC
20k
VEE 4
VEE
–5V
1
VOUT (±1V)
5
VOUT
CONV
2
7
6
AIN LTC1404 CLK
VREF
5
DOUT
GND
10µF
16V
4
8
3
OPTIONAL SINGLE
SUPPLY OPERATION:
DISCONNECT VBIAS
FROM GROUND
AND CONNECT IT TO VREF.
REPLACE –5V SUPPLY
WITH GROUND.
OUTPUT CODE FOR ZERO
CURRENT WILL BE ~2430
10µF
16V
VEE
–5V
CLOCKING
CIRCUITRY
DOUT
1787 TA02
Figure 173. Split or Single-Supply Operation, Bidirectional Output into A/D
ILOAD
VSENSE
–
4
L
O
A
D
2
+
3
+ –
RIN
100Ω
4V TO 60V
5
1µF
5V
2
LTC6101
1
VOUT
ROUT
4.99k
4
IN+
REF+
LTC2433-1
5
IN–
REF– GND
3
ROUT
VOUT =
• VSENSE = 49.9VSENSE
RIN
1
VCC
6
SCK
SDD
CC
FO
9
8
7
TO µP
10
ADC FULL-SCALE = 2.5V
6101 TA06
Figure 174. 16-Bit Resolution Unidirectional Output into LTC2433 ADC
an105fa
AN105-96
Application Note 105
DIGITIZING
12-Bit Resolution Unidirectional Output
into LTC1286 ADC (Figure 175)
Directly Digitize Current with 16-Bit Resolution
(Figure 176)
While the LT1787 is able to provide a bidirectional output,
in this application the economical LTC1286 is used to
digitize a unidirectional measurement. The LT1787 has a
nominal gain of eight, providing a 1.25V full-scale output
at approximately 100A of load current.
The low offset precision of the LTC6102 permits direct
digitization of a high side sensed current. The LTC2433
is a 16-bit delta sigma converter with a 2.5V full-scale
range. A resolution of 16 bits has an LSB value of only
40µV. In this circuit the sense voltage is amplified by a
factor of 50. This translates to a sensed voltage resolution
of only 0.8µV per count. The LTC6102 DC offset typically
contributes only four LSB’s of uncertainty.
I = 100A
TO
LOAD
1
RSENSE
0.0016Ω
8
FIL+
LT1787HV
–
VS+ 7
2 VS
3
4
FIL–
DNC
VEE
2.5V TO 60V
R1
15k
VBIAS 6
ROUT
20k
C1
1µF
VREF VCC
CS
+IN
LTC1286 CLK
–IN
D
GND OUT
5
VOUT
VOUT = VBIAS + (8 • ILOAD • RSENSE)
5V
C2
0.1µF
TO µP
1787 TA01
LT1634-1.25
Figure 175. 12-Bit Resolution Unidirectional Output into LTC1286 ADC
+
4V TO 60V
VSENSE
+IN
–
ILOAD
POWER ENABLE
L
O
A
D
V–
RIN
100Ω
–INS
+ –
–INF
V+
VREG
0.1µF
5V
2
EN
LTC6102-1
OUT VOUT
ROUT
4.99k
4
IN+
REF+
5
REF– GND
3
ROUT
VOUT =
• VSENSE = 49.9VSENSE
RIN
VCC
LTC2433-1
IN–
1µF
1
SCK
SDD
CC
9
8
7
TO µP
FO
6
10
ADC FULL-SCALE = 2.5V
6102 TA05
Figure 176. Directly Digitize Current with 16-Bit Resolution
an105fa
AN105-97
Application Note 105
DIGITIZING
Directly Digitizing Two Independent Currents
(Figure 177)
Digitize a Bidirectional Current Using a Single-Sense
Amplifier and ADC (Figure 178)
With two independent current sense amplifiers in the
LTC6103, two currents from different sources can be
simultaneously digitized by a 2-channel 16-bit ADC such
as the LTC2436-1. While shown to have the same gain on
each channel, it is not necessary to do so. Two different
current ranges can be gain scaled to match the same fullscale range for each ADC channel.
The dual LTC6104 can be connected in a fashion to source
or sink current at its output depending on the direction
of current flow through the sense resistor. Biasing the
amplifier output resistor and the VREF input of the ADC to
an external 2.5V LT1004 voltage reference allows a 2.5V
full-scale input voltage to the ADC for current flowing in
either direction.
VA+
VSENSE
ILOAD
–
VB+
VSENSE
+
LOAD
+
RIN
100Ω
8
LOAD
RIN
100Ω
7
6
–INA
+INA
ILOAD
–
5
–INB
+ –
5V 1µF
+INB
– +
VSA
VSB
LTC6103
V–
OUTA
1
6
7
OUTB
4
2
CH1
13
5
11
TO µP
CH0
ROUT
4.99k
ROUT
4.99k
12
LTC2436-1
4
2
1
3,8,9,10,14,15,16
6103 TA01a
Figure 177. Directly Digitizing Two Independent Currents
ILOAD
–
TO
CHARGER/LOAD
VSENSE
+
+
RSENSE
RIN
RIN
100Ω 100Ω
8
7
+INA
6
–INA
5
–INB
+INB
+ –
VS
12V
– +
B
A
VS
VREF
LTC6104
CURRENT
MIRROR
OUT
1
R1
2.3k
VREF
+IN
V–
VCC
LTC1286
4
ROUT
2.5k
C2
0.1µF
–IN
LT1004-2.5
+
C1
1µF
GND
5V
CS
CLK
TO µP
DOUT
6104 TA01a
Figure 178. Digitize a Bidirectional Current Using a Single-Sense Amplifier and ADC
an105fa
AN105-98
Application Note 105
DIGITIZING
Digitizing Charging and Loading Current in a Battery
Monitor (Figure 179)
Complete Digital Current Monitoring (Figure 180)
An LTC2470 16-bit delta sigma A-to-D converter can
directly digitize the output of the LT6109 representing
a circuit load current. At the same time the comparator
outputs connect to MCU interrupt inputs to immediately
signal programmable threshold over and undercurrent
conditions.
A 16-bit digital output battery current monitor can be
implemented with just a single sense resistor, an LT1999
and an LTC2344 delta sigma ADC. With a fixed gain of
ten and DC biased output the digital code indicates the
instantaneous loading or charging current (up to 10A) of
a system battery power source.
0.025Ω
CHARGER
BAT
42V
V+
LT1999-10
LOAD
V+
5V
2µA
1
V+IN
SHDN
+
–
4k
2
V
+
8
VSHDN
7
VOUT
0.1µF
0.1µF
–
+
0.8k
4k
3
0.8k
160k
+
+IN
VOUT
6
–
VREF
160k
V+
5V
10µF
40k
V+
V–IN
5V
VCC
VREF
CS
LTC2433-1
SCK
–IN
SDO
0.1µF
5
4
0.1µF
1999 TA02
Figure 179. Digitizing Charging and Loading Current in a Battery Monitor
IN
SENSE
HIGH
SENSE
LOW
0.1Ω
0.1µF
OUT
VCC
VREF
100Ω
10
9
VCC
VCC
10k
10k
SENSEHI SENSELO
V+
OUTA
8
LT6109-1
RESET 2
3
4
EN/RST
INC2
OUTC2
OUTC1
V–
5
INC1
COMP
1
7
6
IN+
2k
LTC2470
TO
MCU
0.1µF
6.65k
1.33k
OVERCURRENT
6109 TA05
UNDERCURRENT
Figure 180. Complete Digital Current Monitoring
an105fa
AN105-99
Application Note 105
DIGITIZING
Ampere-Hour Gauge (Figure 181)
With specific scaling of the current sense resistor, the
LTC4150 can be set to output exactly 10,000 interrupt
pulses for one Amp-hr of charge drawn from a battery
source. With such a base-10 round number of pulses a
series of decade counters can be used to create a visual
5-digit display. This schematic is just the concept. The
polarity output can be used to direct the interrupt pulses
to either the count-up or count-down clock input to display
total net charge.
CHARGER
The LTC4151 contains a dedicated current sense input
channel to a 3-channel 12-bit delta-sigma ADC. The ADC
directly and sequentially measures the supply voltage
(102V full-scale), supply current (82mV full-scale) and a
separate analog input channel (2V full-scale). The 12-bit
resolution data for each measurement is output through
an I2C link.
LOAD
SENSE+
1.2Ω
Power Sensing with Built-In A-to-D Converter
(Figure 182)
1.1Ω
CD40110B
INT
LTC4150 CLR
100mΩ
SENSE–
+
CD40110B
CD40110B
SENSE RESISTANCE = 0.0852Ω
IMAX = 588mA
10,000 PULSES = 1Ah
CD40110B
CD40110B
4150 F09
Figure 181. Ampere-Hour Gauge
3.3V
0.02Ω
VIN
7V to 80V
VOUT
SENSE+ SENSE–
VIN
2k
µCONTROLLER
SHDN
LTC4151
ADR1
ADR0
SCL
SCL
SDA
SDA
ADIN
GND
VDD
2k
MEASURED
VOLTAGE
4151 TA01
Figure 182. Power Sensing with Built-In A-to-D Converter
an105fa
AN105-100
Application Note 105
DIGITIZING
Isolated Power Measurement (Figure 183)
With separate data input and output pins, it is a simple
matter to fully isolate the LTC4151-1/LTC4151-2 from a
controller system. The supply voltage and operating current
of the isolated system is digitized and conveyed through
three opto-isolators.
Fast Data Rate Isolated Power Measurement
(Figure 184)
With separate data input and output pins, it is a simple
matter to fully isolate the LTC4151-1/LTC4151-2 from a
controller system. The supply voltage and operating current
of the isolated system is digitized and conveyed through
three high speed opto-isolators.
RS
0.02Ω
VIN
48V
SENSE+
3.3V
SENSE–
SCL
R1
20k
R2
20k
R3
5.1k
8
VIN
LTC4151-1
SDAI
ADR1
SDA0
ADR0
ADIN
VADIN
1
7
6
2
3
5
4
1
GND
MOCD207M
MOCD207M
R5
0.51k
R4
0.51k
R6
10k
R7
10k
SCL
VDD
µ-CONTROLLER
8
SDA
4151 F09
2
3
7
6
4
5
Figure 183. Isolated Power Measurement
R1
0.02Ω
VIN
7V to 80V
VIN
VOUT
SENSE+ SENSE–
VIN
ADIN
LTC4151-2
ADIN
SDAO
ADR1
SDAI
ADR0
SCL
GND
1
IN
OUT
LT3010-5
C7
1µF 5 SHDN SENSE 2
100V
GND
4
ISO1
PS9817-2
8
C6
1µF
R8
1k
R3
10k
R4
10k
VCC
1
7
2
8
7
8
GND 5
VCC
6
5 GND
1
5V
C4
0.1µF R12
1k
R11
1k
R14
10k
R13
10k
2
ISO_SDA
3
ISO_SCL
4
4151 F11
ISO2
PS9817-2
Figure 184. Fast Data Rate Isolated Power Measurement
an105fa
AN105-101
Application Note 105
DIGITIZING
Current, Voltage and Fuse Monitoring (Figure 186)
Adding Temperature Measurement to Supply Power
Measurement (Figure 185)
Systems with redundant back-up power often have fuse
protection on the supply output. The LTC4151, with some
diodes and resistors can measure the total load current,
supply voltage and detect the integrity of the supply fuses.
The voltage on the spare analog input channel determines
the state of the fuses.
One use for the spare analog input of the LTC4151 could
be to measure temperature. This can be done by using a
thermistor to create a DC voltage proportional to temperature. The DC bias potential for the temperature network is
the system power supply which is also measured, Temperature is derived from both measurements. In addition
the system load current is also measured.
0.2Ω
VIN
48V
VISHAY
2381 615 4.104
100k AT 25°C
1%
SENSE+ SENSE –
250mA
LOAD
VIN
SCL
I2C
40.2k
1%
SDA
LTC4151
ADIN
ADR1
1.5k
1%
GND
ADR0
4151 TA02
T(°C) = 58.82 • (NADIN/NVIN – 0.1066), 20°C < T < 60°C.
NADIN AND NVIN ARE DIGITAL CODES MEASURED BY THE
ADC AT THE ADIN AND VIN PINS, RESPECTIVELY
Figure 185. Adding Temperature Measurement to Supply Power Measurement
VIN1
48V
F1
D1
F2
D2
RS
0.02Ω
VIN2
48V
D3
D4
R1
150k
R2
301k
SENSE+
SENSE–
VIN
SCL
LTC4151
SDA
LOAD
ADR1
ADIN
R3
3.4k
V+
I2C
V–
ADR0
GND
GND
4151 TA03
CONDITION
RESULT
Normal Operation
NADIN ≥ 1.375 • NVIN
0.835 • NVIN ≤ NADIN < 1.375 • NVIN F2 is Open
0.285 • NVIN ≤ NADIN < 0.835 • NVIN F1 is Open
(Not Responding)
Both F1 and F2 are Open
VIN1 AND VIN2 ARE WITHIN 20% APART. NADIN AND NVIN ARE DIGITAL
CODES MEASURED BY THE ADC AT THE ADIN AND VIN PINS,
RESPECTIVELY.
Figure 186. Current, Voltage and Fuse Monitoring
AN105-102
an105fa
Application Note 105
DIGITIZING
Automotive Socket Power Monitoring (Figure 187)
Power over Ethernet, PoE, Monitoring (Figure 188)
The wide operating voltage range is adequate to permit
the transients seen in automotive applications. The power
consumption of anything plugged into an auto power
socket can be directly digitized.
The power drawn by devices connected to an isolated telecom power supply can be continually monitored to ensure
that they comply with their power class rating. A voltage
proportional to the powered device rating is digitized by
the spare analog input of the LTC4151-1.
0.005Ω
2W
12V
AUTO SOCKET
SENSE+
SENSE–
VIN
GPS
3.3V
ADIN
SHDN
2k
LTC4151
2k
VDD
µCONTROLLER
ADR1
SCL
SCL
ADR0
SDA
SDA
GND
DN452 F01
Figure 187. Automotive Socket Power Monitoring
RS
0.1Ω
VIN
ISOLATED 48V
(44V TO 57V)
1
2
3
4
–
SENSE
VIN
ADIN
LTC4151-1
ADR1
ADR0
R1
20k
10
SENSE+
SCL
SDAI
GND
SDAO
R2
20k
0.1µF
VPWRMGT
5
6
7
0.1µF
100V
1µF
8
fSCL**
3.33kHz
PD CLASS VPWRMGT
CLASS 1
CLASS 2
CLASS 3
R3*
8.25k
0.237V
0.417V
0.918V
*R3 = 4 • 33k, 1/8W IN PARALLEL
**FASTER OPTOCOUPLERS PERMIT
100kHz OR 400kHz BUS OPERATIONS
0.1µF
100V
LTC4263
RPM
12.7k
1%
MOCD207M
8
1
7
2
6
3
5
4
VDD5
LED
PWRMGT ENFCLS
SD
MIDSPAN
VDD48
LEGACY
OUT
VSS
VSS
OUT
OSC
ACOUT
R4
510Ω
R5
510Ω
R6
20k
SMAJ58A
TO PORT
MAGNETS
3.3V
R7
20k
VDD
SCL
µCONTROLLER
1/2 MOCD207M
1
8
2
7
SDA
DN452 F02
Figure 188. Power over Ethernet, PoE, Monitoring
an105fa
AN105-103
Application Note 105
DIGITIZING
Monitor Current, Voltage and Temperature
(Figure 189)
RSENSE
2.5V
ILOAD
5V
The LTC2990 is a 4-channel, 14-bit ADC fully configurable
through an I2C interface to measure single-ended, differential voltages and determine temperature from internal
or external diode sensors. For high side current measurements two of the inputs are configured for differential
input to measure the voltage across a sense resistor. The
maximum differential input voltage is limited to ±300mV.
Other channels can measure voltage and temperature for
a complete system power monitor.
VCC
SDA
SCL
ADR0
ADR1
V1
V2
V3
LTC2990
TREMOTE
V4
2990 TA01a
GND
TINTERNAL
MEASURES: TWO SUPPLY VOLTAGES,
SUPPLY CURRENT, INTERNAL AND
REMOTE TEMPERATURES
Figure 189. Monitor Current, Voltage and Temperature
More Digitizing Circuits Are Shown in Other Chapters:
FIGURE
TITLE
20
Precision, Wide Dynamic Range High-side Current Sensing
93
High Voltage Current and Temperature Monitoring
130
Small Motor Protection and Control
131
Large Motor Protection and Control
148
Complete Single Cell Battery Protection
208
Remote Current Sensing with Minimal Wiring
210
Crystal/Reference Oven Controller
211
Power Intensive Circuit Board Monitoring
212
Crystal/Reference Oven Controller
an105fa
AN105-104
Application Note 105
CURRENT CONTROL
Bidirectional Current Source (Figure 191)
This chapter collects a variety of techniques useful in
generating controlled levels of current in circuits.
The LT1990 is a differential amplifier with integrated precision resistors. The circuit shown is the classic Howland
current source, implemented by simply adding a sense
resistor.
800mA/1A White LED Current Regulator (Figure 190)
The LT6100 is configured for a gain of either 40V/V or
50V/V depending on whether the switch between A2 and
VEE is closed or not. When the switch is open (LT6100 gain
of 40V/V), 1A is delivered to the LED. When the switch is
closed (LT6100 gain of 50V/V), 800mA is delivered. The
LT3436 is a boost switching regulator which governs the
voltage/current supplied to the LED. The switch “LED ON”
connected to the SHDN pin allows for external control of
the ON/OFF state of the LED.
+V
VCTL
3
7
+
6
LT1990
2
–
REF
4
1
RSENSE
–V
ILOAD
ILOAD = VCTL/RSENSE ≤ 5mA
EXAMPLE: FOR RSENSE =100Ω,
OUTPUT IS 1mA PER 100mV INPUT
1990 AI03
Figure 191. Bidirectional Current Source
D2
LED
L1
3µH
VIN
3.3V TO 4.2V
SINGLE Li-Ion
VIN
D1
B130
SHDN
GND
FB
124k
VC
MMBT2222
8.2k
0.030Ω
VS+
LT6100
VSW
LT3436
LED
ON
4.7µF
6.3V
CER
LED
CURRENT
WARNING! VERY BRIGHT
DO NOT OBSERVE DIRECTLY
0.1µF
22µF
16V
CER
1210
+ –
VS–
VCC
VOUT
VEE
A4
A2
OPEN: 1A
CLOSED: 800mA
4.99k
D1: DIODES INC.
D2: LUMILEDS LXML-PW09 WHITE EMITTER
L1: SUMIDA CDRH6D28-3R0
6100 TA02
Figure 190. 800mA/1A White LED Current Regulator
an105fa
AN105-105
Application Note 105
CURRENT CONTROL
2-Terminal Current Regulator (Figure 192)
The LT1635 combines an op amp with a 200mV reference.
Scaling this reference voltage to a potential across resistor
R3 forces a controlled amount of current to flow from the
+terminal to the –terminal. Power is taken from the loop.
+
2
–
3
+
IOUT =
(R2 + R3)VREF
(R1)(R3)
Precision Voltage Controlled Current Source with
Ground Referred Input and Output (Figure 194)
The LTC6943 is used to accurately sample the voltage
across the 1kΩ sense resistor and translate it to a ground
reference by charge balancing in the 1µF capacitors. The
LTC2050 integrates the difference between the sense voltage and the input command voltage to drive the proper
current into load.
7
6
LT1635
R1
1
5V
3
INPUT
0V TO 3.7V
4
1
LTC2050
8
R2
5
+
4
R3
–
–
2
0.68µF
1635 TA05
5V
Figure 192. 2-Terminal Current Regulator
1k
Variable Current Source (Figure 193)
3
7
A basic high side current source is implemented at the
output, while an input translation amplifier section provides
for flexible input scaling. A rail-to-rail input capability is
required to have both amplifiers in one package, since
the input stage has common mode near ground and the
second section operates near VCC.
VCC
1/2 LTC6943
6
9
1µF
1k
1µF
10
12
15
11
0.001µF
IOUT =
VIN
1000Ω
14
OPERATES FROM A
SINGLE 5V SUPPLY
6943 • TA01a
R2
10k
VIN
0V TO 2.5V
R3
5.1Ω
+
Figure 194. Precision Voltage Controlled Current Source
with Ground Referred Input and Output
+
1/2 LT1466L
VN2222
10k 1/2 LT1466L
–
TP0610
–
R1
100k
( )( )
( )
IO = VIN
=
R2
R1
IO
1
R3
VIN
51
1466L/67L TA01
Figure 193. Variable Current Source
an105fa
AN105-106
Application Note 105
CURRENT CONTROL
Precision Voltage Controlled Current Source
(Figure 195)
Boosted Bidirectional Controlled Current Source
(Figure 197)
The ultra-precise LTC2053 instrumentation amplifier is
configured to servo the voltage drop on sense resistor R
to match the command VC. The LTC2053 output capability
limits this basic configuration to low current applications.
This is a classical Howland bidirectional current source
implemented with an LT1990 integrated difference amplifier.
The op amp circuit servos to match the RSENSE voltage
drop to the input command VCTL. When the load current
exceeds about 0.7mA in either direction, one of the boost
transistors will start conducting to provide the additional
commanded current.
5V
2
–
8
LTC2053 RG 7
REF 6 0.1µF
3 +
5
EN
4
1
R
VOUT
i
+V
1k
2.7k
LOAD
VC
VC
i = — , i ≤ 5mA
R
10k
3
VCTL
0 < VOUT < (5V – VC)
2
0.1µF
7
+
LT1990
–
4V TO 44V
+
R*
0A to 2A Current Source (Figure 198)
The LT1995 amplifies the sense resistor drop by 5V/V
and subtracts that from VIN, providing an error signal
to an LT1880 integrator. The integrated error drives the
P‑MOSFET as required to deliver the commanded current.
15V
TP0610
IOUT
SHDN
1990 AI04
Figure 197. Boosted Bidirectional Controlled Current Source
R
–
CZT651
–V
+
LT1637
RSENSE
ILOAD = VCTL/RSENSE 100mA
EXAMPLE: FOR RSENSE =10Ω,
OUTPUT IS 1mA PER 10mV INPUT
LT1004-1.2
2k
10µF
ILOAD
1k
Switchable Precision Current Source (Figure 196)
4.7µF
+
1
Figure 195. Precision Voltage Controlled Current Source
This is a simple current-source configuration where the
op amp servos to establish a match between the drop on
the sense resistor and that of the 1.2V reference. This
particular op amp includes a shutdown feature so the
current source function can be switched off with a logic
command. The 2kΩ pull-up resistor assures the output
MOSFET is off when the op amp is in shutdown mode.
6
4
REF
2053 TA02
CZT751
RS
0.2Ω
IOUT = 1.2
R
e.g., 10mA = 120Ω
*OPTIONAL FOR LOW OUTPUT CURRENTS,
R* = R
1637 TA01
Figure 196. Switchable Precision Current Source
M4
M1
P1
P4
15V
LT1995
G=5
1k
REF
+
–15V
10nF
–
VIN
LT1880
100Ω
–15V
IRF9530
IOUT
10nF
IOUT =
VIN
5 • RS
1995 TA04
Figure 198. 0A to 2A Current Source
an105fa
AN105-107
Application Note 105
CURRENT CONTROL
Fast Differential Current Source (Figure 199)
Voltage Controlled Current Source (Figure 201)
This is a variation on the Howland configuration, where
load current actually passes through a feedback resistor
as an implicit sense resistance. Since the effective sense
resistance is relatively large, this topology is appropriate
for producing small controlled currents.
Adding a current sense amplifier in the feedback loop
of an adjustable low dropout voltage regulator creates
a simple voltage controlled current source. The range of
output current sourced by the circuit is set only by the
current capability of the voltage regulator. The current
sense amplifier senses the output current and feeds back
a current to the summing junction of the regulator’s error
amplifier. The regulator will then source whatever current
is necessary to maintain the internal reference voltage at
the summing junction. For the circuit shown a 0V to 5V
control input produces 500mA to 0mA of output current.
VIN1
VIN2
R*
R*
15V
2
3
LT1022
+
R*
10pF
7
–
IOUT =
6
4
VIN2 – VIN1
R
R*
IOUT
–15V
RL
*MATCH TO 0.01%
FULL-SCALE POWER BANDWIDTH
= 1MHz FOR IOUTR = 8VP-P
= 400kHz FOR IOUTR = 20VP-P
MAXIMUM IOUT = 10mAP-P
IOUTP-P • RL
COMMON MODE VOLTAGE AT LT1022 INPUT =
2
V+
5V
2.5k
LT1022 • TA07
Figure 199. Fast Differential Current Source
1A Voltage-Controlled Current Sink (Figure 200)
This is a simple controlled current sink, where the op amp
drives the N-MOSFET gate to develop a match between
the 1Ω sense resistor drop and the VIN current command.
Since the common mode voltage seen by the op amp is
near ground potential, a “single supply” or rail-to-rail type
is required in this application.
RS
1Ω
+IN
–
+
LTC6101
FOR VIN = 0V TO 5V,
IOUT = 500mA TO 0mA
IOUT = 100mA/V
–
V+
LT3021
V+
VIN
10µF
+
0.2V
REF
RLOAD
24k
1k
VIN
RL
IOUT
+
1/2
LT1492
–
100Ω
Si9410DY
N-CHANNEL
Figure 201. Voltage Controlled Current Source
100pF
1k
V
IOUT = IN
1Ω
tr < 1µs
1Ω
1492/93 TA06
Figure 200. 1A Voltage-Controlled Current Sink
an105fa
AN105-108
Application Note 105
CURRENT CONTROL
Adjustable High Side Current Source (Figure 202)
Programmable Constant Current Source (Figure 203)
The wide-compliance current source shown takes advantage of the LT1366’s ability to measure small signals near
the positive supply rail. The LT1366 adjusts Q1’s gate voltage to force the voltage across the sense resistor (RSENSE)
to equal the voltage between VDC and the potentiometer’s
wiper. A rail-to-rail op amp is needed because the voltage
across the sense resistor is nearly the same as VDC. Q2
acts as a constant current sink to minimize error in the
reference voltage when the supply voltage varies. At low
input voltage, circuit operation is limited by the Q1 gate
drive requirement. At high input voltage, circuit operation
is limited by the LT1366’s absolute maximum ratings.
The current output can be controlled by a variable resistor
(RPROG) connected from the PROG pin to ground on the
LT1620. The LT1121 is a low dropout regulator that keeps
the voltage constant for the LT1620. Applying a shutdown
command to the LT1121 powers down the LT1620 and
eliminates the base drive to the current regulation pass
transistor, thereby turning off IOUT.
VCC
RSENSE
0.2Ω
1k
1/2 LT1366
RP
10k
The LT1970 provides current detection and limiting features
built-in. In this circuit, the logic flags that are produced in
a current limiting event are connected in a feedback arrangement that in turn reduces the current limit command
to a lower level. When the load condition permits the current to drop below the limiting level, then the flags clear
and full current drive capability is restored automatically.
0.0033µF
–
LT1004-1.2
Snap Back Current Limiting (Figure 204)
100Ω
+
Q1
MTP23P06
ILOAD
40k
5V < VCC < 30V
0A < ILOAD < 1A AT VCC = 5V
0mA < ILOAD < 160mA AT VCC = 30V
Q2
2N4340
LT1366 F07
Figure 202. Adjustable High Side Current Source
an105fa
AN105-109
Application Note 105
CURRENT CONTROL
D45VH10
6V
TO 28V
8
0.1µF
1
OUT
SHDN
5
IOUT
0A TO 1A
0.1µF
470Ω
LT1121CS8-5
IN
0.1Ω
GND
3
+
0.1µF
1µF
18k
SHUTDOWN
1
2
SENSE
AVG
0.1µF
8
7
PROG
LT1620MS8
3
6
VCC
GND
VN2222LM
2N3904
22Ω
4
10k
1%
IOUT
+IN
–IN
IPROG
5
RPROG
IOUT = (IPROG)(10,000)
RPROG = 40k FOR 1A OUTPUT
LT1620/21 • TA01
Figure 203. Programmable Constant Current Source
12V
R2
39.2k
R1
54.9k
VCSRC
VCSNK
+IN
VIN
EN
VCC
R3
2.55k
500mA
V+
ISRC
ISNK
–IN
COMMON
RG
10k
TSD
OUT
LT1970
SENSE+
–
SENSE
FILTER
V–
VEE
–12V
RS
1Ω
IOUT
RL
IMAX
50mA
0
ILOW
–500mA
IMAX
VCC • R2
(R1 + R2) • 10 • RS
ILOW
VCC • (R2||R3)
[R1 + (R2||R3)] • 10 • RS
RF
10k
1970 F04
Figure 204. Snap Back Current Limiting
More Current Control Circuits Are Shown in Other Chapters:
FIGURE
TITLE
120
Bidirectional Current Sensing in H-Bridge Drivers
129
Simple DC Motor Torque Control
170
Use Comparator Output to Initialize Interrupt Routines
an105fa
AN105-110
Application Note 105
PRECISION
Offset voltage and bias current are the primary sources of
error in current sensing applications. To maintain precision
operation the use of zero drift amplifier virtually eliminates
the offset error terms.
1.5mΩ
VREGULATOR
2
3
Precision High Side Power Supply Current Sense
(Figure 205)
8
+
5
3
–
8
7
LTC6800
+
4
5
6
10k
0.1µF
OUT
100mV/A
OF LOAD
CURRENT
ILOAD
10k
ILOAD
6800 TA01
Figure 206. High Side Power Supply Current Sense
V+
RIN–
RSENSE
RIN+
+IN
–IN
–
V–
V+
LTC6101
OUT
RIN+ = RIN– – RSENSE
6800 TA01
VOUT
ROUT
LOAD
150Ω
LOAD
150Ω
LOAD
2
6
0.1µF
+
1.5mΩ
OUT
100mV/A
OF LOAD
CURRENT
7
LTC6800
4
This is a low voltage, ultra high precision monitor featuring
a zero drift instrumentation amplifier (IA) that provides
rail-to-rail inputs and outputs. Voltage gain is set by the
feedback resistors. Accuracy of this circuit is set by the
quality of resistors selected by the user, small-signal range
is limited by VOL in single-supply operation. The voltage
rating of this part restricts this solution to applications of
<5.5V. This IA is sampled, so the output is discontinuous
with input changes, thus only suited to very low frequency
measurements.
VREGULATOR
–
6101 F04
Figure 207. Second Input R Minimizes Error Due to
Input Bias Current
Figure 205. Precision High Side Power Supply Current Sense
High Side Power Supply Current Sense (Figure 206)
The low offset error of the LTC6800 allows for unusually
low sense resistance while retaining accuracy.
Second Input R Minimizes Error Due to Input Bias
Current (Figure 207)
The second input resistor decreases input error due caused
by the input bias current. For smaller values of RIN this
may not be a significant consideration.
an105fa
AN105-111
Application Note 105
PRECISION
Remote Current Sensing with Minimal Wiring
(Figure 208)
ILOAD
TO
CHARGER/LOAD
Since the LTC6102 (and others) has a current output that
is ordinarily converted back to a voltage with a local load
resistance, additional wire resistance and ground offsets
don’t directly affect the part behavior. Consequently, if
the load resistance is placed at the far end of a wire, the
voltage developed at the destination will be correct with
respect to the destination ground potential.
7
+
RIN
6
–INA
+INA
5
–INB
+INB
+ –
– +
B
A
VS
LTC6104
CURRENT
MIRROR
OUT
1
VOUT
–
V–
4
+
VS
6104 F02
ROUT
+
–
VREF
Figure 209. Use Kelvin Connections to Maintain
High Current Accuracy
TIE AS CLOSE TO RIN AS POSSIBLE
RIN–
+IN
–INS
+
LOAD
+
RSENSE
8
Significant errors are caused by high currents flowing
through PCB traces in series with the connections to the
sense amplifier. Using a sense resistor with integrated VIN
sense terminals provides the sense amplifier with only
the voltage across the sense resistor. Using the LTC6104
maintains precision for currents flowing in both directions,
ideal for battery charging applications.
RSENSE
VSENSE
RIN
Use Kelvin Connections to Maintain High Current
Accuracy (Figure 209)
V+
–
–
fC =
1
2 • π • ROUT • COUT
–INF
V–
V+
VREG
OUT
LTC6102
6102 TA09
0.1µF
LONG WIRE
ADC
ROUT
COUT
REMOTE ADC
Figure 208. Remote Current Sensing with Minimal Wiring
an105fa
AN105-112
Application Note 105
PRECISION
Crystal/Reference Oven Controller (Figure 210)
5V
High precision instrumentation often use small ovens to
establish constant operation temperature for critical oscillators and reference voltages. Monitoring the power (current
and voltage) to the heater as well as the temperature is
required in a closed-loop control system.
3.3V
2.5V
2.5V I/O
RSENSE
1.2V
VCC V1
Power Intensive Circuit Board Monitoring (Figure 211)
Many systems contain densely populated circuit boards
using high power dissipation devices such as FPGAs.
8-channel, 14-bit ADC LTC2991 can be used to monitor device power consumption with voltage and current
measurements as well as temperatures at several points
on the board and even inside devices which provide die
temp monitoring. A PWM circuit is also built-in to provide
closed-loop control of PCB operating temperature.
3.3V I/O
1.2V CORE
V2
V3
V5
SDA
2-WIRE
I2C INTERFACE
SCL
ADR0
FPGA
V4
LTC2991
V6
FPGA
TEMPERATURE
ADR1
ADR2
V7
TAMBIENT
BOARD
TEMPERATURE
V8
PWM
GND
TO FAN
2991 TA01a
Figure 211. Power Intensive Circuit Board Monitoring
HEATER
VOLTAGE
5V
2-WIRE
I2C
INTERFACE
HEATERPWR = I •V
0.1Ω
STYROFOAM
INSULATION
0.1µF
VCC
V1
SDA
SCL LTC2990
ADR0
ADR1
GND
V2
MMBT3904
V3
20°C
AMBIENT
HEATER
470pF
V4
TINTERNAL
TOVEN
70°C
OVEN
2990 TA10
HEATER CONSTRUCTION:
HEATER POWER = α • (TSET – TAMB) + β • ∫(TOVEN – TSET) dt
5FT COIL OF #34 ENAMEL WIRE
FEED
FEED
~1.6Ω AT 70°C
FORWARD
BACK
PHEATER = ~0.4W WITH TA = 20°C
α = 0.004W, β = 0.00005W/DEG-s
VOLTAGE AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x58
REG 4, 5
0.0625°C/LSB
TAMB
V1, V2
REG 8, 9
305.18µVLSB
REG A, B
0.0625°C/LSB
TOVEN
REG E, F
2.5V + 305.18µV/LSB
VCC
CURRENT AND TEMPERATURE CONFIGURATION:
CONTROL REGISTER: 0x59
REG 4, 5
0.0625°C/LSB
TAMB
REG 6, 7
269µVLSB
IHEATER
REG A, B
0.0625°C/LSB
THEATER
REG E, F
2.5V + 305.18µV/LSB
VCC
Figure 210. Crystal/Reference Oven Controller
an105fa
AN105-113
Application Note 105
PRECISION
Crystal/Reference Oven Controller (Figure 212)
High precision instrumentation often use small ovens to
establish constant operation temperature for critical oscillators and reference voltages. Monitoring the power (current
and voltage) to the heater as well as the temperature is
required in a closed-loop control system. The LTC2991
includes a PWM output which can provide closed-loop
control of the heater.
VOLTAGE AND CURRENT (POWER) MONITOR
5V
VCC
V1
V2
SDA
I
SCL
2-WIRE
ADR0
2C INTERFACE
OTHER APPLICATIONS
V3
LTC2991
ADR1
V4
VCC
V5
V6
ADR2
OVEN
TSET 70°C
V7
TAMBIENT
V8
GND
PWM
HEATER
TEMPERATURE
SENSOR
VCC
5V
100k
+
VOLTAGE, CURRENT, TEMPERATURE AND PWM CONFIGURATION:
CONTROL REGISTER
0x06: 0x01
0x07: 0xA0
PWM, TINTERNAL, VCC REG: 0x08: 0x50
PWM REGISTER
0x09: 0x1B
TAMBIENT
VHEATER
IHEATER
TOVEN
VCC
REG 1A, 1B
REG 0A, 0B
REG 0C, 0D
REG 16, 17
REG 1C, 1D
0.0625°C/LSB
305µV/LSB
19.4µV/RHEATERA/LSB
0.0625°C/LSB
2.5V + 305.18µV/LSB
100k
–
1M
LT6240
1µF
2991 TA11
Figure 212. Crystal/Reference Oven Controller
an105fa
AN105-114
Application Note 105
PRECISION
More Precision Circuits Are Shown in Other Chapters:
FIGURE
TITLE
20
Precision, Wide Dynamic Range High-side Current Sensing
21
Sensed Current Includes Monitor Circuit Supply Current
58
Bidirectional Precision Current Sensing
93
High Voltage Current and Temperature Monitoring
124
Monitor H-Bridge Motor Current Directly
128
Fixed Gain DC Motor Current Monitor
136
Coulomb Counting Battery Gas Gauge
145
High Voltage Battery Coulomb Counting
146
Low Voltage Battery Coulomb Counting
147
Single Cell Lithium-Ion Battery Coulomb Counter
176
Directly Digitize Current with 16-Bit Resolution
179
Digitizing Charging and Loading Current in a Battery Monitor
182
Power Sensing with Built In A to D Converter
183
Isolated Power Measurement
184
Fast Data Rate Isolated Power Measurement
185
Adding Temperature Measurement to Supply Power Measurement
186
Current, Voltage and Fuse Monitoring
189
Monitor Current, Voltage and Temperature
an105fa
AN105-115
Application Note 105
WIDE RANGE
To measure current over a wide range of values requires
gain changing in the current sense amplifier. This allows
the use of a single value of sense resistor. The alternative
approach is to switch values of sense resistor. Both approaches are viable for wide range current sensing.
terminals (A2, A4) and ground to provide selection of
gain = 10 or gain = 50, depending on the state of the gate
drive. This provides a wider current measurement range
than otherwise possible with just a single sense resistor.
Dual LTC6101’s Allow High-Low Current Ranging
(Figure 213)
–
VCC
FIL
VOUT
VEE
A2
A4
2N7002
6100 TA05
5V
(GAIN = 50)
0V
(GAIN = 10)
Figure 214. Adjust Gain Dynamically for Enhanced Range
VLOGIC
(3.3V TO 5V)
CMPZ4697
7
10k
3
M1
Si4465
VIN
RSENSE HI
10m
ILOAD
RSENSE LO
100m
301
301
4
+
–
+ –
LTC6101
3
4
5
2
VIN
1
8
5
301
3
+ –
4.7k
2
5
LTC1540
1
619k
1
LTC6101
7.5k
Q1
CMPT5551
40.2k 6
1.74M
2
+
5V
Instead of having fixed gains of 10, 12.5, 20, 25, 40, and 50,
this circuit allows selecting between two gain settings. An
N-MOSFET switch is placed between the two gain-setting
4
VS+
LT6100 VS
Adjust Gain Dynamically for Enhanced Range
(Figure 214)
301
FROM SOURCE
–
Using two current sense amplifiers with two values of
sense resistors is an easy method of sensing current over
a wide range. In this circuit the sensitivity and resolution of
measurement is 10 times greater with low currents, less
than 1.2A, than with higher currents. A comparator detects
higher current flow, up to 10A, and switches sensing over
to the high current circuitry.
VOUT
ISENSE
RSENSE
TO LOAD
HIGH
RANGE
INDICATOR
(ILOAD > 1.2A)
HIGH CURRENT RANGE OUT
250mV/A
VLOGIC
BAT54C
R5
7.5k
(VLOGIC +5V) ≤ VIN ≤ 60V
LOW CURRENT RANGE OUT
2.5V/A
0 ≤ ILOAD ≤ 10A
6101 F03b
Figure 213. Dual LTC6101’s Allow High-Low Current Ranging
an105fa
AN105-116
Application Note 105
WIDE RANGE
0 to 10A Sensing Over Two Ranges (Figure 215)
Using two sense amplifiers a wide current range can be
broken up into a high and low range for better accuracy
at lower currents. Two different value sense resistors can
be used in series with each monitored by one side of the
LTC6103. The low current range, less than 1.2A in this
example, uses a larger sense resistor value to develop
a larger sense voltage. Current exceeding this range will
create a large sense voltage, which may exceed the input
differential voltage rating of a single sense amplifier. A
comparator senses the high current range and shorts out
the larger sense resistor. Now only the high range sense
amplifier outputs a voltage.
current ranges, yet be scaled through gain settings to
provide the same range of output current in each direction. This is ideal for battery charging application where
the charging current has a much smaller range than the
battery load current.
CHARGER
RINB
LOAD
RSHUNTA
RSHUNTB
BATTERY
RINA
A
B
VS
VOUT
Dual Sense Amplifier Can Have Different Sense
Resistors and Gain (Figure 216)
ROUT
The LTC6104 has a single output which both sources and
sinks current from the two independent sense amplifiers.
Different shunt sense resistors can monitor different
VREF
CURRENT
MIRROR
LTC6104
6104 F08
Figure 216. Dual Sense Amplifier Can Have Different Sense
Resistors and Gain
CMPZ4697
10k
VLOGIC
(3.3V TO 5V)
M1
Si4465
ILOAD
VOUT
7
RSENSE(LO)
100mΩ
RSENSE(HI)
10mΩ
3
4
VIN
5
40.2k
301Ω
8
LTC1540
+
–
8
6
4.7k
301Ω
7
6
1.74M
5
2
LTC6103
1
2
1
619k
HIGH
RANGE
INDICATOR
(ILOAD > 1.2A)
HIGH CURRENT
RANGE OUT
250mV/A
4
7.5k
Q1
CMPT5551
BAT54C
VLOGIC
R5
7.5k
(VLOGIC + 5V) ≤ VIN ≤ 60V
0A ≤ ILOAD ≤ 10A
6103 F03b
LOW CURRENT
RANGE OUT
250mV/A
Figure 215. 0 to 10A Sensing Over Two Ranges
an105f
AN105-117
Application Note 105
WIDE RANGE
More Wide Range Circuits Are Shown in Other Chapters:
FIGURE
TITLE
20
Precision, Wide Dynamic Range High-side Current Sensing
58
Bidirectional Precision Current Sensing
208
Remote Current Sensing with Minimal Wiring
an105fa
AN105-118
Linear Technology Corporation
LT 0614 REV A • PRINTED IN USA
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