LINER LTC6104IMS8 High voltage, high side, bi-directional current sense amplifi er Datasheet

LTC6104
High Voltage, High Side,
Bi-Directional Current
Sense Amplifier
DESCRIPTION
FEATURES
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Wide Supply Range: 4V to 60V with 70V Absolute
Maximum
Low Offset Voltage: ±450µV Maximum
Fast Response: 1µs Response Time
Gain Configurable with External Resistors; Each
Direction is Gain Configurable
Low Input Bias Current: 170nA Maximum
PSRR: 110dB Minimum
Output Current: ±1mA Maximum
Low Supply Current: 520µA, VS = 12V
Specified for –40°C to 125°C Temperature Range
Available in an 8-Lead MSOP Package
APPLICATIONS
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Current Shunt Measurement
Battery Monitoring
Remote Sensing
Power Management
The LTC®6104 is a versatile, high voltage, high side, bidirectional current sense amplifier. Design flexibility is
provided by the excellent device characteristics: ±450µV
maximum offset and only 520µA of current consumption
(typical at 12V). The LTC6104 operates on supplies from
4V to 60V.
The LTC6104 monitors bi-directional current via the voltage
across an external sense resistor (shunt resistor). This
sense voltage is then translated into a ground referenced
signal. Gain is set with three external resistors and can
be separately configured for both directions. Low DC
offset allows the use of a small shunt resistor and large
gain-setting resistors. As a result, power loss in the shunt
is minimal.
The wide operating supply range and high accuracy make
the LTC6104 ideal for a wide variety of automotive, industrial
and power management applications. A maximum input
sense voltage of 500mV allows a wide range of currents
to be monitored. The fast response makes the LTC6104
the perfect choice for load current warnings and shutoff
protection control. With very low supply current, the
LTC6104 is suitable for power sensitive applications.
, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
The LTC6104 is available in an 8-lead MSOP package.
TYPICAL APPLICATION
16-Bit Resolution Bi-Directional Output into LTC1286 ADC
ILOAD
–
TO
CHARGER/LOAD
VSENSE
+
Step Response
+
RSENSE
RIN
RIN
100Ω 100Ω
12V
VSENSE–
8
7
+INA
6
–INA
5
–INB
6V
+INB
+ –
– +
A
B
R1
2.3k
VS
VS
LTC6104
CURRENT
MIRROR
1
VREF
+IN
V–
VCC
–IN
LT®1004-2.5
1.5V
1V
CS
LTC1286
C2
0.1µF
5V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 1V
VOUT
4
ROUT
2.5k
+
C1
1µF
VREF
OUT
∆VSENSE = 100mV
CLK
DOUT
GND
TO µP
IOUT = 100µA
IOUT = 0µA
TIME (1µs/DIV)
6104 G15
6104 TA01a
6104f
1
LTC6104
ABSOLUTE MAXIMUM RATINGS
PACKAGE/ORDER INFORMATION
(Note 1)
Total Supply Voltage (+INB(VS) to V–) ......................70V
Maximum Applied Output Voltage (OUT) ....................9V
Input Current........................................................±10mA
Output Short-Circuit Duration (to V–)............... Indefinite
Operating Temperature Range
LTC6104C ............................................ –40°C to 85°C
LTC6104I ............................................. –40°C to 85°C
LTC6104H .......................................... –40°C to 125°C
Specified Temperature Range (Note 2)
LTC6104C ................................................ 0°C to 70°C
LTC6104I ............................................. –40°C to 85°C
LTC6104H .......................................... –40°C to 125°C
Storage Temperature Range................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec) .................. 300°C
TOP VIEW
OUT
NC
NC
V–
1
2
3
4
8
7
6
5
+INA
–INA
–INB
+INB/VS
MS8 PACKAGE
8-LEAD PLASTIC MSOP
TJMAX = 150°C, θJA = 300°C/W
ORDER PART NUMBER
MS8 PART MARKING*
LTC6104CMS8
LTC6104IMS8
LTC6104HMS8
LTCMP
LTCMP
LTCMP
Order Options Tape and Reel: Add #TR
Lead Free: Add #PBF Lead Free Tape and Reel: Add #TRPBF
Lead Free Part Marking: http://www.linear.com/leadfree/
Consult LTC Marketing for parts specified with wider operating temperature ranges.
*The temperature grade is identified by a label on the shipping container.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. RIN = 100Ω, ROUT = 5k, 4V ≤ +INB(VS) ≤ 60V, V– = 0V, VREF = 2V for
VS ≥ 6V, VREF = 0.75V for VS = 4V, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
VS
Supply Range
VOS
Output Offset Voltage
VSENSE = ±5mV, LTC6104
VSENSE = ±5mV, LTC6104C, LTC6104I
VSENSE = ±5mV, LTC6104H
●
●
ΔVOS/ΔT
Input Offset Voltage Drift
VSENSE = ±5mV
●
IB
Input Bias Current
RIN = 1M for –INA and –INB
VSENSE(MAX)
(Note 3)
Input Sense Voltage Full Scale
6V ≤ VS ≤ 60V, RIN = 1k, ROUT = 2k, VREF = 2V
●
±500
mV
VS = 4V, RIN = 1k, ROUT = 1k, VREF = 0.5V when
VSENSE = 500mV, VREF = 1V when VSENSE = –500mV
●
±500
mV
PSRR
Power Supply Rejection Ratio
●
116
112
140
dB
dB
●
110
105
120
dB
dB
●
110
105
133
dB
dB
●
105
100
8
3
1
●
VS = 6V to 60V, VSENSE = 5mV
VS = 6V to 60V, VSENSE = –5mV
VS = 4V to 60V, VSENSE = 5mV
VS = 4V to 60V, VSENSE = –5mV
4
±85
Maximum Output Voltage
12V ≤ VS ≤ 60V, VSENSE = 90mV, VREF = 4V
VS = 6V, VSENSE = 75mV, VREF = 1.8V, ROUT = 2k
VS = 4V, VSENSE = 35mV, VREF = 0.75V, ROUT = 1k
●
●
●
VOUT(MIN)
Minimum Output Voltage
12V ≤ VS ≤ 60V, VSENSE = –80mV, VREF = 4V
VS = 6V, VSENSE = –90mV, VREF = 1.8V, ROUT = 2k
VS = 4V, VSENSE = –75mV, VREF = 0.75V, ROUT = 1k
●
●
●
MAX
100
UNITS
60
V
±450
±600
±700
µV
µV
µV
±1.5
●
VOUT(MAX)
TYP
µV/°C
170
245
nA
nA
dB
dB
115
V
V
V
0.3
0.3
0.25
V
V
V
6104f
2
LTC6104
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. RIN = 100Ω, ROUT = 5k, 4V ≤ +INB(VS) ≤ 60V, V– = 0V, VREF = 2V for
VS ≥ 6V, VREF = 0.75V for VS = 4V, unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
IOUT(MAX)
Maximum Output Current
6V ≤ VS ≤ 60V, VSENSE = ±110mV, VREF = 2V, ROUT = 1k
VS = 4V, VSENSE = ±27.5mV, VREF = 0.75V, ROUT = 1k
IOUT-GAINERR
Current Mirror Gain Error
VINB– > VINB+ and VINA– < VINA+ (Note 4)
±0.2
IOUT-OSERR
Current Mirror Offset Error
VINB– > VINB+ and VINA– < VINA+ (Note 4)
±0.2
µA
tr
Input Step Response (ΔVOUT = to
50% on a 5V Output Step)
8V ≤ VS ≤ 60V, VREF = 1V, VSENSE = 0mV to 100mV
Transient
1
µs
8V ≤ VS ≤ 60V, VREF = 6V, VSENSE = –100mV to 0mV
Transient
1
µs
8V ≤ VS ≤ 60V, VREF = 4V, VSENSE = –50mV to 50mV
Transient
3
µs
VS = 4V, ROUT = 500Ω, Gain = 5, VREF = 0.5V,
VSENSE = 0mV to 100mV Transient
1.2
µs
VS = 4V, ROUT = 500Ω, Gain = 5, VREF = 1V,
VSENSE = –100mV to 0mV Transient
1.2
µs
VS = 4V, ROUT = 500Ω, Gain = 5, VREF = 0.75V,
VSENSE = –50mV to 50mV Transient
3.2
µs
140
140
200
200
kHz
kHz
kHz
kHz
Input Step Response (ΔVOUT = to
50% on a 0.5V Output Step)
MIN
BW
Signal Bandwidth
IOUT = 200µA, ROUT = 5k
IOUT = –200µA, ROUT = 5k
IOUT = 1mA, ROUT = 5k
IOUT = –1mA, ROUT = 5k
IS
Supply Current
VS = 4V, IOUT = 0, RIN = 1M
VS = 6V, IOUT = 0, RIN = 1M
VS = 12V, IOUT = 0, RIN = 1M
VS = 60V, IOUT = 0, RIN = 1M
LTC6104I, LTC6104C
LTC6104H
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: The LTC6104C is guaranteed to meet specified performance from
0°C to 70°C. The LTC6104C is designed, characterized and expected to
meet specified performance from –40°C to 85°C but are not tested or QA
sampled at these temperatures. LTC6104I is guaranteed to meet specified
performance from –40°C to 85°C. The LTC6104H is guaranteed to meet
specified performance from –40°C to 125°C.
●
●
●
●
●
●
●
TYP
MAX
±1
±0.25
UNITS
mA
mA
±0.75
%
0.45
0.73
0.825
mA
mA
0.5
0.79
1
mA
mA
0.52
0.81
1
mA
mA
0.64
1.04
1.1
1.2
mA
mA
mA
Note 3: VSENSE(MAX) is tested by applying 550mV and verifying the gain
error is less than 1%. The 1% limit is set by the accuracy of high speed
test equipment. Gain error is typically dominated by external resistor
tolerance.
Note 4: When amplifier A is active and amplifier B is inactive, the gain
error is entirely due to the external resistors RIN and ROUT. When amplifier
A is inactive and amplifier B is active, there is an additional gain error from
the LTC6104 current mirror circuit. This error term is the gain error term,
IOUT-GAINERR plus the offset error term, IOUT-OSERR.
6104f
3
LTC6104
TYPICAL PERFORMANCE CHARACTERISTICS
Input VOS vs Temperature
50
TWO REPRESENTATIVE UNITS
60
30
40
20
0
RIN = 100Ω
ROUT = 5k
VIN = 5mV
VOS OF INTERNAL
AMPLIFIER A
VOS OF INTERNAL
AMPLIFIER B
–40
–60
–80
–100
–40 –20
0
20 40 60 80
TEMPERATURE (°C)
10
0
–10
–20
TA = 25°C
RIN = 100Ω
ROUT = 5k
VIN = 5mV
–30
–40
VOS OF INTERNAL
AMPLIFIER A
VOS OF INTERNAL
AMPLIFIER B
4
11
18
25
32 39
VS (V)
46
12
VS = 60V
10
4
VS = 4V
2
0
–40 –20
0
20 40 60 80
TEMPERATURE (°C)
100 120
MINIMUM OUTPUT (V)
MAXIMUM OUTPUT (V)
VS = 12V
VS = 6V
0.080
VS = 60V
0.075
VS = 4V, 6V, 12V
0.070
0.065
0.050
–40 –20
0
20 40 60 80
TEMPERATURE (°C)
IB (nA)
10k
100k
FREQUENCY (Hz)
6104 G08
0
20 40 60 80
TEMPERATURE (°C)
100 120
Supply Current vs Supply Voltage
900
140
800
80
VS = 4V
20
1M
VS = 4V
6104 G06
160
40
1k
VS = 6V
6104 G05
60
–5
–10
–40 –20
100 120
VS = 6V TO 100V
0
–40 –20
60
–4
–8
5
–10
VS = 60V VS = 12V
0.055
100
TA = 25°C
RIN = 100Ω
ROUT = 5k
50
–2
–6
IOUT = ±200µA
0
30
40
VS (V)
0
0.060
120
10
20
2
Input Bias Current vs Temperature
15
10
IOUT Maximum vs Temperature
4
IOUT = ±1mA
20
NO LIMITS FOR VSENSE IF
VSENSE < 0V AND VS ≥ 4V
6104 G03
0.085
Gain vs Frequency
25
4
0.090
40
30
RIN = 5k
ROUT = 2.5k
TA = 25°C
0
60
6
6104 G04
35
TA = 125°C
1.0
VOUT Minimum vs Temperature
VOUT Maximum vs Temperature
6
TA = 85°C
6104 G02
6104 G01
8
53
TA = 70°C
1.5
0.5
–50
100 120
TA = 0°C
2.0
SUPPLY CURRENT (µA)
–20
TA = –40°C
TA = 25°C
MAXIMUM IOUT (mA)
20
INPUT OFFSET (µV)
INPUT OFFSET (µV)
80
2.5
TWO REPRESENTATIVE UNITS
40
MAXIMUM VSENSE (V)
100
GAIN (dB)
Input Sense Range vs Supply
Voltage
Input VOS vs Supply Voltage
TA = 70°C
700
TA = 85°C
TA = 125°C
600
500
TA = 25°C
400
TA = 0°C
TA = –40°C
300
200
VIN = 0V
ROUT = 1M
100
0
0
20 40 60 80
TEMPERATURE (°C)
100 120
6104 G09
4
10
20
30
40
SUPPLY VOLTAGE (V)
50
60
6104 G10
6104f
4
LTC6104
TYPICAL PERFORMANCE CHARACTERISTICS
Step Response 0mV to 10mV
VS
Step Response 0mV to –10mV
VSENSE–
VS + 5mV
VS + 10mV
VS
VS –10mV
2.5V
VSENSE–
VS – 5mV
2.25V
2V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 2V
VOUT
1.5V
VOUT
1.75V
VOUT
TIME (10µs/DIV)
TIME (10µs/DIV)
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 2V
TIME (10µs/DIV)
6104 G12
6104 G11
Step Response –50mV to 50mV
6104 G13
Step Response Rising Edge
Step Response Rising Edge
VS + 50mV
VS – 50mV VSENSE
6.5V
VSENSE–
∆VSENSE = 100mV
∆VSENSE– = 100mV
VSENSE–
6V
IOUT = 0µA
6V
5.5V
CLOAD
1000pF
IOUT = –100µA
CLOAD
10pF
4V
1.5V
VSENSE–
2V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 2V
2V
Step Response –5mV to 5mV
VOUT
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 4V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 1V
VOUT
1.5V
1V
IOUT = 100µA
IOUT = 0µA
VOUT
TIME (1µs/DIV)
TIME (1µs/DIV)
TIME (10µs/DIV)
6104 G16
6104 G15
6104 G14
Step Response Rising Edge
VS + 50mV
VS – 50mV
7V
1V
0.5V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 6V
Step Response Falling Edge
VSENSE–
VSENSE–
∆VSENSE– = 100mV
6.5V
5V
VOUT
4.5V
2V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 4.5V
VOUT
TIME (1µs/DIV)
1.5V
1V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 1V
IOUT = 100µA
IOUT = 0µA
TIME (1µs/DIV)
6104 G17
6104 G18
6104f
5
LTC6104
TYPICAL PERFORMANCE CHARACTERISTICS
Step Response Falling Edge
VSENSE–
6V
5.5V
Step Response Falling Edge
VS + 50mV
VS – 50mV
7V
∆VSENSE– = 100mV
IOUT = 0µA
PSRR vs Frequency
160
VSENSE–
140
VOUT
120
PSRR (dB)
IOUT = –100µA
4.5V
1V
0.5V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 6V
VOUT
2V
TA = 25°C
VS = 12V
RIN = 100Ω
ROUT = 5k
VSENSE+ = VS
VREF = 4.5V
TIME (1µs/DIV)
TIME (1µs/DIV)
6104 G19
6104 G20
V+ = 4V
V+ = 12V
100
80
60 R = 100Ω
IN
ROUT = 5k
40 C
OUT = 5pF
GAIN = 50
20 I
OUTDC = 100µA
VINAC = 50mVP-P
0
0.1
1
10 100 1k
10k
FREQUENCY (Hz)
100k
1M
6104 G20
PIN FUNCTIONS
OUT (Pin 1): Current Output. OUT will source or sink a
current that is proportional to the sense voltage into an
external resistor. A voltage reference is required to provide
the proper positive offset voltage so that the output can
swing both positive and negative.
V– (Pin 4): Negative Supply (or Ground for Single-Supply
Operation).
+INB/VS (Pin 5): The positive input of the internal sense
amplifier B. It also works as the positive supply input.
Supply current is drawn through this pin.
A resistor (RIN) tied from one end of RSENSE to –INB sets
the output current IOUT = VSENSE/RIN. VSENSE is the voltage
developed across the external RSENSE (Figure 1).
–INA (Pin 7): The negative input of the internal sense
amplifier A. The internal sense amplifier will drive –INA
to the same potential as +INA when VSENSE is positive. A
resistor (RIN) tied from one end of RSENSE to –INA sets
the output current IOUT = VSENSE/RIN.
+INA (Pin 8): The positive input of the internal sense
amplifier A.
–INB (Pin 6): The negative input of the internal sense
amplifier B. The internal sense amplifier will drive –INB
to the same potential as +INB when VSENSE is negative.
6104f
6
LTC6104
BLOCK DIAGRAM
–
VSENSE
ILOAD
+
RSENSE
RINB
8
RINA
7
+INA
6
VS
–INA
10V
5k
5k
–
5k
+
–
V+
A
+INB
10V
5k
+
V–
5
–INB
V+
B
V–
10V
V–
OUT
1
4
6104 F01
VOUT
R
VOUT = VSENSE • OUT + VREF
RIN
ROUT
+
–
VREF
Figure 1. LTC6104 Block Diagram
THEORY OF OPERATION
When VSENSE is positive, an internal sense amplifier loop
forces –INA to have the same potential as +INA. Connecting an external resistor, RINA, in series with –INA causes
a current, VSENSE/RINA, to flow through RINA. The high
impedance inputs of the sense amplifier will not conduct
this input current, so the current will flow through an
internal MOSFET to the OUT pin.
The output current can be transformed into a voltage by
adding a resistor from OUT to a reference voltage (VREF). The
output voltage is then VOUT = (VSENSE/RINA) • ROUT + VREF.
When operating on a dual supply, ROUT can be tied to ground.
The output voltage is then VOUT = (VSENSE/RINA) • ROUT.
Only one amplifier is active at a time in the LTC6104. If the
load current direction (VSENSE is negative) activates the
“B” amplifier, the “A” amplifier will be inactive. The signal
current goes into the –INB pin, through the MOSFET, and
into the current mirror. The mirror reverses the polarity of
the signal so that current flows into the “OUT” pin, causing
the output voltage to change polarity. The magnitude of the
output is then VSENSE • ROUT/RINB + VREF . Keep in mind
that the OUT voltage cannot swing below V–, even though
it’s sinking current. A proper VREF and ROUT need to be
chosen so that the designed OUT voltage swing does not
go beyond the specified voltage range of the output.
Supply current is drawn from +INB pin. The user may
choose to include this current in the monitored current
through RSENSE by careful choice of connection polarity.
6104f
7
LTC6104
APPLICATIONS INFORMATION
Selection of External Current Sense Resistor
The external sense resistor, RSENSE, has a significant effect
on the function of a current sensing system and must be
chosen with care.
First, the power dissipation in the resistor should be
considered. The system load current will cause both heat
and voltage loss in RSENSE. As a result, the sense resistor should be as small as possible while still providing
the input dynamic range required by the measurement.
Note that input dynamic range is the difference between
the maximum input signal and the minimum accurately
reproduced signal, and is limited primarily by input DC
offset of the internal amplifier of the LTC6104. In addition,
RSENSE must be small enough that VSENSE does not exceed
the maximum input voltage specified by the LTC6104, even
under peak load conditions.
As an example, an application may require that the
maximum sense voltage be ±100mV. If this application
is expected to draw ±2A at peak load, RSENSE should be
no more than 50mΩ.
RSENSE =
VSENSE 100mV
=
= 50mΩ
IPEAK
2A
The low offset and corresponding large dynamic range of
the LTC6104 make it more flexible than other solutions
in this respect. The ±85µV typical offset gives 60dB of
dynamic range for a sense voltage that is limited to ±85mV
max, and over 75dB of dynamic range if the rated input
maximum of ±500mV is allowed.
Sense Resistor Connection
Kelvin connection of the –INA/–INB and +INA/+INB 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. One 10mm × 10mm square trace of
one-ounce copper is approximately 0.5mΩ. A 1mV error
can be caused by as little as 2A flowing through this small
interconnect. This will cause a 1% error in a 100mV signal.
A 10A load current in the same interconnect will cause
a 5% error for the same 100mV signal. 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.
Figure 2 illustrates the recommended method.
ILOAD
Once the maximum RSENSE value is determined, the minimum sense resistor value will be set by the resolution or
dynamic range required. The minimum signal that can be
accurately represented by this sense amp is limited by the
input offset. As an example, the LTC6104 has a typical
input offset of ±85µV. If the minimum current is ±20mA, a
sense resistor of 4.25mΩ will set VSENSE to ±85µV. This is
the same value as the input offset. A larger sense resistor
will reduce the error due to offset by increasing the sense
voltage for a given load current.
Choosing a 50mΩ RSENSE will maximize the dynamic range
and provide a system that has ±100mV across the sense
resistor at peak load (±2A), while input offset causes an
error equivalent to only ±1.7mA of load current. Peak dissipation in the sense resistor is 200mW in this example.
If instead a 5mΩ sense resistor is employed, then the effective current error is ±17mA, while the peak sense voltage
is reduced to ±10mV at ±2A, dissipating only 20mW.
–
TO
CHARGER/LOAD
VSENSE
+
+
RSENSE
RIN
8
7
+INA
RIN
6
–INA
5
–INB
+INB
+ –
– +
A
B
VS
LTC6104
VS
CURRENT
MIRROR
OUT
1
V–
4
6104 F02
+
ROUT
VOUT
+
–
VREF
–
Figure 2. Kelvin Input Connections Preserve Accuracy
Despite Large Load Currents
6104f
8
LTC6104
APPLICATIONS INFORMATION
Selection of External Input Resistor, RIN
The external input resistor, RIN, controls the transconductance of the current sense circuit.
Since IOUT =
VSENSE
1
, transconductance gm =
RIN
RIN
For example, if RIN = 100Ω, then IOUT =
VSENSE
or
100Ω
IOUT = ±1mA for VSENSE = ±100mV.
RIN should be chosen to allow the required resolution
while limiting the output current. At low supply voltage,
IOUT may be as much as ±1mA. By setting RIN such that
the largest expected sense voltage gives IOUT = ±1mA,
then the maximum output dynamic range is available.
Output dynamic range is limited by both the maximum
allowed output current and the maximum allowed output
voltage, as well as the minimum practical output signal. If
less dynamic range is required, then RIN can be increased
accordingly, reducing the maximum output current and
power dissipation. If low sense currents must be resolved
accurately in a system that has very wide dynamic range,
a smaller RIN than the maximum current specification
allows may be used if the maximum current is limited in
another way, such as with a Schottky diode across RSENSE
(Figure 3). 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 occasional large burst currents
may be ignored.
Care should be taken when designing the printed circuit
board layout to minimize input trace resistance (to Pins
5, 6, 7 and 8). Trace and interconnect impedances to the
–IN terminals will increase the effective RIN value, causing
a gain error, especially for small RIN values. In addition,
internal device resistance will add approximately 0.3Ω
to RIN.
Trace and interconnect impedances to the +INB terminal will
have an effect on offset error. These errors are described
in more detail later in this data sheet.
Selection of External Output Resistor, ROUT
The output resistor, ROUT, determines how the output current is converted to voltage. VOUT is simply IOUT • ROUT +
VREF. In choosing an output resistor, the maximum output
voltage range must first be considered. If the circuit that
is driven by the output does not limit the output voltage
range, then ROUT must be chosen such that the maximum
output voltage range does not exceed the LTC6104 maximum output voltage range (see Electrical Characteristics).
If the following circuit is a buffer or ADC with limited input
range, then ROUT must be chosen so that VOUT is in the
allowed maximum input range of this circuit.
In addition, the output impedance is determined by ROUT.
If the circuit to be driven has high enough input impedance, then almost any useful output impedance will be
acceptable. However, if the driven circuit has relatively low
input impedance, or draws spikes of current, such as an
ADC might do, then a lower ROUT value may be required
in order to preserve the accuracy of the output. As an
example, if the input impedance of the driven circuit is
100 times ROUT, then the accuracy of VOUT will be reduced
by 1% since:
VOUT – VREF = IOUT •
ROUT • RIN(DRIVEN)
ROUT + RIN(DRIVEN)
= IOUT • ROUT •
RSENSE
LOAD
100
= 0.99 • IOUT • ROUT
101
BATTERY
Selection of External Voltage Reference, VREF
DSENSE
6104 F03
Figure 3. Shunt Diodes Limit Maximum Input Voltage to Allow
Better Low Input Resolution Without Overranging
Selection of external reference voltage should be considered together with selection of ROUT.
Example:
Given the conditions: IOUT = –1mA to 1mA, VS = 12V.
6104f
9
LTC6104
APPLICATIONS INFORMATION
From the Electrical Characteristics of the LTC6104, the
output voltage range is 0.3V to 8V.
If the circuit that is driven by the output limits the maximum output voltage to ≈5V, to achieve maximum dynamic
range, VOUT should be 0.3V for –1mA IOUT and 5V for
1mA IOUT.
ROUT =
5V – 0.3V
= 2.35k,
2mA
VREF = 0.3 +
5 – 0.3
= 2.65V
2
A standard 2.5V reference could be used in this example.
With IOUT = ±1mA and ROUT = 2.2k, the output voltage
range would equal 0.3V to 4.7V
VREF Considerations
VREF as shown in Figure 1, provides a positive offset so
that the output can swing above and below this point. It is
recommended that this is an accurate voltage reference.
Most voltage references will work in this application as
long as they are able to sink and source current. Make sure
that the device maintains the required voltage accuracy as
the current varies through its entire range.
EOUT( VOS) = VOS •
ROUT
RIN
The DC offset voltage of the amplifier adds directly to the
value of the sense voltage, VSENSE. This is the dominant
error of the system and it limits the available dynamic
range. The section, Selection of External Current Sense
Resistor, provides details.
Output Error, EOUT, Due to the Bias Currents, IB+ and
IB–
The bias current IB+ flows into the positive input of the
internal op amp. IB– flows into the negative input.
⎛
⎞
R
EOUT(IBIAS) = ROUT ⎜IB + • SENSE – IB – ⎟
RIN
⎝
⎠
Since IB+ ≈ IB– = IBIAS, if RSENSE << RIN then:
EOUT(IBIAS) ≈ –ROUT • IBIAS
For instance if IBIAS is 100nA and ROUT is 1k, the output
error is 0.1mV.
Output Error, EOUT, Due to the Finite DC Open-Loop
Gain, AOL, of the LTC6104 Amplifier
Error Sources
The current sense system uses an amplifier and resistors
to apply gain and level shift the result. The output is then
dependent on the characteristics of the amplifier, such as
gain and input offset, as well as resistor matching. Ideally,
the circuit output is:
VOUT – VREF = IOUT • ROUT = VSENSE •
Output Error, EOUT, Due to the Amplifier DC Offset
Voltage, VOS
ROUT
,
RIN
VSENSE = RSENSE • ISENSE
In this case, the only error is due to resistor mismatch,
which provides an error in gain only. However, offset
voltage, bias current and finite gain in the amplifier cause
additional errors.
This error is inconsequential as the AOL of the LTC6104
is very large.
Example:
If an ISENSE range = (±1mA to ±1A) and
VOUT
ISENSE
=
3V
1A
Then, from the Electrical Characteristics of the
LTC6104:
RSENSE ≈
Gain =
VSENSE(MAX )
ISENSE(MAX )
=
500mV
= 500mΩ
1A
VOUT(MAX )
ROUT
3V
=
=
=6
RIN
VSENSE(MAX ) 500mV
6104f
10
LTC6104
APPLICATIONS INFORMATION
If the maximum output current, IOUT, is limited to 1mA,
ROUT equals 3V/1mA = 3k and RIN = 3k/6 – 0.3Ω (internal
device resistance) = 499.7Ω.
The output error due to DC offset is ±510µV (typ) and
the error due to offset current, IOS, is 3k • 100nA =
300µV(typ).
The maximum output error can therefore reach ±810µV
or 0.027% (–71dB) of the output full scale. Considering
the system input 60dB dynamic range (ISENSE = ±1mA to
±1A), the 71dB performance of the LTC6104 makes this
application feasible.
Output Error, EOUT, Due to the Current Mirror Errors,
IOUT-GAINERR and IOUT-OSERR
When VSENSE is negative, amplifier B would be on and
amplifier A off. The output of amplifier B drives an internal
current mirror which is connected to the OUT pin. This
current mirror has some error associated with it, and this
error can be calculated as follows:
IOUT-GAINERR = ±0.2% • IOUT, with IOUT = ±1mA,
IOUT-GAINERR(MAX) = ±2μA
Output Error, EOUT, Due to Trace Resistance
The LTC6104 uses the +INB pin for both the positive “B”
amplifier input and the positive supply input for both
amplifiers. If trace resistance (RT) become significant
(Figure 5), this supply current can cause an input offset
error, which can be calculated as follows:
ROUT
RIN
EOUT(OFFSET) = R T • IS •
Trace resistances to the –IN terminals will increase the
effective RIN value, causing a gain error (Figure 5). In addition, internal device resistance will add approximately
0.3Ω to RIN.
Gain error equals:
A V(ERROR) =
ROUT
R
– OUT
RIN + R T + 0.3Ω RIN
Minimizing resistance in the input traces is important and
care should be taken in the PCB layout. Make the trace
short and wide. Kelvin connection to the shunt resistor
pad should be used. Avoid tapping into this signal along
IOUT-OSERR = ±0.2μA
IOUT-ERR(MAX) = IOUT-GAINERR + IOUT-OSERR = ±2μA +
±0.2μA = ±2.2μA
ILOAD
–
TO
CHARGER/LOAD
VSENSE
The combined effect of amplifier offset and current mirror
errors is shown graphically in Figure 4.
RT
8
100
OUTPUT ERROR (%)
RIN
RIN
RT
RT
7
+INA
RT
6
–INA
5
–INB
+INB
+ –
IS
– +
A
10
1
+
RSENSE
EOUT-ERR(MAX) = IOUT-ERR(MAX) • ROUT
RIN = 100Ω
ROUT = 5k
+
B
VS
VS
MAXIMUM
LTC6104
0.1
CURRENT
MIRROR
OUT
TYPICAL
1
VOUT
–300
–100
100
VSENSE (mV)
300
500
6104 F04
Figure 4. Output Error vs Input Voltage
–
6104 F05
IOUT
+
0.01
–500
V–
4
ROUT
+
–
VREF
Figure 5. Errors from PCB Traces and Other Parasitic Resistances
6104f
11
LTC6104
APPLICATIONS INFORMATION
the high current path, as this will increase the voltage drop
and escalate this error.
Output Current Limitations Due to Power Dissipation
The LTC6104 can deliver up to ±1mA continuous current
to the output pin. This current flows through RIN and
enters the current sense amp via the –IN pin. The power
dissipated in the LTC6104 due to the output signal is:
POUT ≈ VS • |IOUT|
There is also power dissipated due to the quiescent supply current:
PQ = IS • VS
The total power dissipated is the output dissipation plus
the quiescent dissipation:
PTOTAL = POUT + PQ
At maximum supply and maximum output current, the
total power dissipation can exceed 100mW. This will cause
significant heating of the LTC6104 die. In order to prevent
damage to the LTC6104, the maximum expected dissipation in each application should be calculated. This number
can be multiplied by the θJA value to find the maximum
expected die temperature. This must not be allowed to
exceed 150°C, or performance may be degraded.
As an example, if an LTC6104 in the MS8 package is to be
run at 55V ±5V supply with 1mA output current at 80°C:
PQ(MAX) = IS(MAX) • V+(MAX) = 1.2mA • 60V = 72mW
POUT(MAX) = IOUT • V+(MAX) = 1mA • 60V = 60mW
θJA = 300C˚/W
TRISE = θJA • PTOTAL(MAX) = 300C°/W • (72mW + 60mW)
= 39.6°C
TMAX = TAMBIENT + TRISE = 80˚C + 39.6˚C = 119.6˚C
If this same circuit must run at 125°C, the maximum die
temperature will exceed 150°C. (Note that supply current,
and therefore PQ, is proportional to temperature. Refer to
Typical Performance Characteristics.) In this condition,
the maximum output current should be reduced to avoid
device damage. It is important to note that the LTC6104
has been designed to provide at least ±1mA to the output
when required, and can deliver more depending on the
conditions. Care must be taken to limit the maximum
output current by proper choice of sense resistor and, if
input fault conditions exist, external clamps.
Output Filtering
The output voltage, VOUT, is simply IOUT • ZOUT. This
makes filtering straightforward. Any circuit may be used
which generates the required ZOUT to get the desired filter
response. For example, a capacitor in parallel with ROUT
will give a lowpass response. This will reduce unwanted
noise from the output, and may also be useful as a charge
reservoir to keep the output steady while driving a switching circuit such as a MUX or ADC. This output capacitor
in parallel with an output resistor will create a pole in the
output response at:
f–3dB =
1
2 • π • ROUT • COUT
Useful Equations
Input Voltage: VSENSE = ISENSE • RSENSE
Voltage Gain:
Current Gain:
VOUT
R
= OUT
VSENSE
RIN
IOUT
ISENSE
PTOTAL(MAX) ≈ 132mW and the max die temp will be
119.6°C
Transconductance:
TMAX must be <150°C
Transimpedance:
=
RSENSE
RIN
IOUT
1
=
VSENSE RIN
VOUT
ISENSE
= RSENSE •
ROUT
RIN
6104f
12
LTC6104
APPLICATIONS INFORMATION
Reverse Supply Protection
Some applications may be tested with reverse-polarity
supplies due to an expectation of this type of fault during
operation. The LTC6104 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– (Figure 6). This will limit the
reverse current through the LTC6104. Note that this diode
will limit the low voltage performance of the LTC6104 by
effectively reducing the supply voltage to the part by VD.
Keep this in mind when choosing an output resistor and
voltage reference.
In addition, if the output of the LTC6104 is wired to a
device that will effectively short it to high voltage (such as
through an ESD protection clamp) during a reverse supply condition, the LTC6104’s output should be connected
through a resistor or Schottky diode (Figure 7).
Response Time
The LTC6104 is designed to exhibit fast response to inputs
for the purpose of circuit protection or signal transmission.
This response time will be affected by the external circuit
in two ways: delay and speed.
ILOAD
–
TO
CHARGER/LOAD
VSENSE
7
ILOAD
6
–INA
5
–INB
CURRENT
MIRROR
1
LTC6104
–
R1
6104 F06
+
VOUT
6
–INA
5
–INB
+INB
– +
B
VS
VS
V–
4
7
A
VS
OUT
+
RIN
+ –
B
VS
+
RIN
+INA
IS
– +
VSENSE
RSENSE
8
+INB
A
–
TO
CHARGER/LOAD
RIN
+ –
LTC6104
Speed is also affected by the external circuit. In this case,
if the input changes very quickly, the internal amplifier
and the internal output FET (Figure 1) will attempt to
maintain the internal loop, but may be slew rate limited.
This results in current flowing through RIN and the internal
FET. This current slew rate will be determined by the amplifier and FET characteristics as well as the input resistor,
RIN. Using a smaller RIN will allow the output current to
increase more quickly, decreasing the response time at
the output. This will also have the effect of increasing
the maximum output current. Using a larger ROUT will
+
RIN
+INA
For bidirectional applications, there is a delay when output
current changes polarity. The delay time can be found
in the step response curves in the Typical Performance
Characteristics section of this data sheet.
+
RSENSE
8
For unidirectional applications, if the output current is
very low and an input transient occurs, there may be an
increased delay before the output voltage starts to change.
This can be improved by increasing the minimum output
current, either by increasing RSENSE or by decreasing RIN.
The effect of increased output current is illustrated in the
step response curves in the Typical Performance Characteristics section of this datasheet. Note that the curves are
labeled with respect to the initial output currents.
CURRENT
MIRROR
OUT
1
V–
4
6104 F07
ADC
ROUT
+
–
ROUT
D1
VREF
Figure 6. Schottky Prevents Damage During Supply Reversal
+
–
D1
VREF
Figure 7. Additional Resistor R1 Protects Output
During Supply Reversal
6104f
13
LTC6104
APPLICATIONS INFORMATION
decrease the response time, since VOUT = IOUT • ROUT.
Reducing RIN and increasing ROUT will both have the
effect of increasing the voltage gain of the circuit.
sense amplifiers is furnished via the +INB pin, the input
protection for both sections is referenced to this one pin.
Normal operation of section A is maintained for +INA
and –INA voltages within the range of 0.5V above +INB
to 1.5V below +INB. As long as both sense resistors are
connected to a common potential and voltage drops are
small (like <500mV, for example), as in Figure 8 or the
H-bridge application, this condition will be met.
Use of Dual Sense Resistors
The dual amplifier topology offers significant advantages
for controlling gain, dynamic range and shunt current.
As an example, separate shunt resistors can be advantageous for an H-bridge current monitor (see H-Bridge Load
Current Monitor application). It can also be a significant
advantage for battery-operated systems, where battery
discharge and charge current can be significantly different. With different current range requirements, a “charge
shunt resistor” can be connected from the charger to the
battery and a separate “discharge shunt resistor” can be
connected from the battery to the load. Other applications
can benefit from similar topologies where different shunt
resistors enable the user to trade off accuracy and shunt
power consumption. Finally, since each amplifier has an
independent input resistor, gain for each channel can be
set to suit the application. The only limitation to observe
in this type of application is that since the power for both
CHARGER
RINB
RSHUNTB
LOAD
BATTERY
RSHUNTA
RINA
A
B
VS
VOUT
ROUT
CURRENT
MIRROR
VREF
LTC6104
6104 F08
Figure 8
TYPICAL APPLICATION
H-Bridge Load Current Monitor
3V TO 18V
VBATTERY
(8V TO 60V)
0.1µF
4
1µF
LT1790-2.5
10m
249Ω
7
6
8
249Ω
10m
1
2
6
4.99k
5
LTC6104
VO
2
VO = 2.5V ±2V (±10A FS)
4
PWM*
PWM*
IM
6104 TA02
*USE “SIGN-MAGNITUDE” PWM FOR ACCURATE
LOAD CURRENT CONTROL AND MEASUREMENT
6104f
14
LTC6104
PACKAGE DESCRIPTION
MS8 Package
8-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1660)
0.889 ± 0.127
(.035 ± .005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
0.42 ± 0.038
(.0165 ± .0015)
TYP
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.65
(.0256)
BSC
8
7 6 5
0.52
(.0205)
REF
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0° – 6° TYP
GAUGE PLANE
1
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
2 3
4
1.10
(.043)
MAX
0.86
(.034)
REF
0.18
(.007)
SEATING
PLANE
0.22 – 0.38
(.009 – .015)
TYP
0.65
(.0256)
BSC
0.127 ± 0.076
(.005 ± .003)
MSOP (MS8) 0204
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
6104f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
15
LTC6104
TYPICAL APPLICATION
LTC6104 Bi-Directional Current Sense Circuit with Combined Charge/Discharge Output
ICHARGE
–
CHARGER
VSENSE
+
RSENSE
IDISCHARGE
RIN
RIN
8
7
+INA
ILOAD
6
–INA
5
–INB
+INB
+ –
– +
A
B
VS
VS
LOAD
LTC6104
CURRENT
MIRROR
OUT
1
+
V–
4
+
ROUT
VOUT
–
+
–
VREF
6104 TA03
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LT1636
Rail-to-Rail Input/Output, Micropower Op Amp
VCM Extends 44V Above VEE, 55µA Supply Current,
Shutdown Function
LT1637/LT1638
LT1639
Single/Dual/Quad, Rail-to-Rail, Micropower Op Amp
VCM Extends 44V Above VEE, 0.4V/µs Slew Rate, >1MHz Bandwidth,
<250µA Supply Current per Amplifier
LT1787/LT1787HV
Precision, Bidirectional, High Side Current Sense Amplifier 2.7V to 60V Operation, 75µV Offset, 60µA Current Draw
LTC1921
Dual –48V Supply and Fuse Monitor
LT1990
High Voltage, Gain Selectable Difference Amplifier
±250V Common Mode, Micropower, Pin Selectable Gain = 1, 10
LT1991
Precision, Gain Selectable Difference Amplifier
2.7V to ±18V, Micropower, Pin Selectable Gain = –13 to 14
LTC2050/LTC2051
LTC2052
Single/Dual/Quad Zero-Drift Op Amp
3µV Offset, 30nV/°C Drift, Input Extends Down to V–
LTC4150
Coulomb Counter/Battery Gas Gauge
Indicates Charge Quantity and Polarity
LT6100
Gain-Selectable High Side Current Sense Amplifier
4.1V to 48V Operation, Pin-Selectable Gain: 10, 12.5, 20, 25, 40,
50V/V
±200V Transient Protection, Drives Three Optoisolators for Status
LTC6101/LTC6101HV High Voltage, High Side Current Sense Amplifier
High Voltage 5V to 100V Operation, SOT23
LTC6103
4V to 60V Operation, Gain Configurable with External Resistors
High Side Bidirectional Current Sense Amplifier
6104f
16 Linear Technology Corporation
LT 0107 • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900
●
FAX: (408) 434-0507 ● www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2007
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