LINER LT1999-50

LT1999-10/LT1999-20/
LT1999-50
High Voltage, Bidirectional
Current Sense Amplifier
Features
Description
Buffered Output with 3 Gain Options:
10V/V, 20V/V, 50V/V
n Gain Accuracy: 0.5% Max
n Input Common Mode Voltage Range: –5V to 80V
n AC CMRR > 80dB at 100kHz
n Input Offset Voltage: 1.5mV Max
n –3dB Bandwidth: 2MHz
n Smooth, Continuous Operation Over Entire Common
Mode Range
n 4kV HBM Tolerant and 1kV CDM Tolerant
n Low Power Shutdown <10µA
n –55°C to 150°C Operating Temperature Range
n 8-Lead MSOP and 8-Lead SO (Narrow) Packages
The LT®1999 is a high speed precision current sense
amplifier, designed to monitor bidirectional currents over
a wide common mode range. The LT1999 is offered in
three gain options: 10V/V, 20V/V, and 50V/V.
n
The LT1999 senses current via an external resistive shunt
and generates an output voltage, indicating both magnitude
and direction of the sensed current. The output voltage is
referenced halfway between the supply voltage and ground,
or an external voltage can be used to set the reference
level. With a 2MHz bandwidth and a common mode input
range of –5V to 80V, the LT1999 is suitable for monitoring
currents in H-Bridge motor controls, switching power
supplies, solenoid currents, and battery charge currents
from full charge to depletion.
Applications
n
n
n
n
n
n
The LT1999 operates from an independent 5V supply and
draws 1.55mA. A shutdown mode is provided for minimizing power consumption.
High Side or Low Side Current Sensing
H-Bridge Motor Control
Solenoid Current Sense
High Voltage Data Acquisition
PWM Control Loops
Fuse/MOSFET Monitoring
The LT1999 is available in an 8-lead MSOP or SOP package.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Typical Application
V+
1
8
+
V
0.8k
V–IN
VOUT
VSHDN
2.5V
RG
–
+
7
VOUT
+
V
3
5V
4
4k
V+
0.8k
160k
6
160k
V+IN
VREF
0.1µF
5
V+IN (20V/DIV)
+
–
4k
V+IN 2
RS
2µA
SHDN
VOUT (2V/DIV)
5V
Full Bridge Armature Current Monitor
V+
LT1999
VS
TIME (10µs/DIV)
1999 TA01b
0.1µF
1999 TA01a
1999fb
1
LT1999-10/LT1999-20/
LT1999-50
Absolute Maximum Ratings
(Note 1)
Differential Input Voltage
+IN to –IN (Notes 1, 3).................................. ±60V, 10ms
+IN to GND, –IN to GND (Note 2).............. –5.25V to 88V
Total Supply Voltage (V+ to GND).................................6V
Input Voltage Pins 6 and 8 .................... V+ + 0.3V, –0.3V
Output Short-Circuit Duration (Note 4)............. Indefinite
Operating Ambient Temperature (Note 5)
LT1999C...............................................–40°C to 85°C
LT1999I.................................................–40°C to 85°C
LT1999H............................................. –40°C to 125°C
LT1999MP.......................................... –55°C to 150°C
Specified Temperature Range (Note 6)
LT1999C................................................... 0°C to 70°C
LT1999I.................................................–40°C to 85°C
LT1999H............................................. –40°C to 125°C
LT1999MP.......................................... –55°C to 150°C
Junction Temperature............................................ 150°C
Storage Temperature Range................... –65°C to 150°C
Pin Configuration
TOP VIEW
TOP VIEW
V+
+IN
–IN
V+
1
2
3
4
8
7
6
5
V+
SHDN
OUT
REF
GND
MS8 PACKAGE
8-LEAD PLASTIC MSOP
1
8
SHDN
+IN 2
7
OUT
–IN 3
6
REF
V+ 4
5
GND
S8 PACKAGE
8-LEAD PLASTIC SO
TJMAX = 150°C, ΘJA = 300°C/W
TJMAX = 150°C, ΘJA = 190°C/W
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LT1999CMS8-10#PBF
LT1999CMS8-10#TRPBF
LTFPB
8-Lead Plastic MSOP
0°C to 70°C
LT1999IMS8-10#PBF
LT1999IMS8-10#TRPBF
LTFPB
8-Lead Plastic MSOP
–40°C to 85°C
LT1999HMS8-10#PBF
LT1999HMS8-10#TRPBF
LTFPB
8-Lead Plastic MSOP
–40°C to 125°C
LT1999MPMS8-10#PBF
LT1999MPMS8-10#TRPBF
LTFQP
8-Lead Plastic MSOP
–55°C to 150°C
LT1999CS8-10#PBF
LT1999CS8-10#TRPBF
199910
8-Lead Plastic SO
0°C to 70°C
LT1999IS8-10#PBF
LT1999IS8-10#TRPBF
199910
8-Lead Plastic SO
–40°C to 85°C
LT1999HS8-10#PBF
LT1999HS8-10#TRPBF
199910
8-Lead Plastic SO
–40°C to 125°C
LT1999MPS8-10#PBF
LT1999MPS8-10#TRPBF
99MP10
8-Lead Plastic SO
–55°C to 150°C
LT1999CMS8-20#PBF
LT1999CMS8-20#TRPBF
LTFNZ
8-Lead Plastic MSOP
0°C to 70°C
LT1999IMS8-20#PBF
LT1999IMS8-20#TRPBF
LTFNZ
8-Lead Plastic MSOP
–40°C to 85°C
LT1999HMS8-20#PBF
LT1999HMS8-20#TRPBF
LTFNZ
8-Lead Plastic MSOP
–40°C to 125°C
LT1999MPMS8-20#PBF
LT1999MPMS8-20#TRPBF
LTFQQ
8-Lead Plastic MSOP
–55°C to 150°C
1999fb
2
LT1999-10/LT1999-20/
LT1999-50
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
SPECIFIED TEMPERATURE RANGE
LT1999CS8-20#PBF
LT1999CS8-20#TRPBF
199920
8-Lead Plastic SO
0°C to 70°C
LT1999IS8-20#PBF
LT1999IS8-20#TRPBF
199920
8-Lead Plastic SO
–40°C to 85°C
LT1999HS8-20#PBF
LT1999HS8-20#TRPBF
199920
8-Lead Plastic SO
–40°C to 125°C
LT1999MPS8-20#PBF
LT1999MPS8-20#TRPBF
99MP20
8-Lead Plastic SO
–55°C to 150°C
LT1999CMS8-50#PBF
LT1999CMS8-50#TRPBF
LTFPC
8-Lead Plastic MSOP
0°C to 70°C
LT1999IMS8-50#PBF
LT1999IMS8-50#TRPBF
LTFPC
8-Lead Plastic MSOP
–40°C to 85°C
LT1999HMS8-50#PBF
LT1999HMS8-50#TRPBF
LTFPC
8-Lead Plastic MSOP
–40°C to 125°C
LT1999MPMS8-50#PBF
LT1999MPMS8-50#TRPBF
LTFQR
8-Lead Plastic MSOP
–55°C to 150°C
LT1999CS8-50#PBF
LT1999CS8-50#TRPBF
199950
8-Lead Plastic SO
0°C to 70°C
LT1999IS8-50#PBF
LT1999IS8-50#TRPBF
199950
8-Lead Plastic SO
–40°C to 85°C
LT1999HS8-50#PBF
LT1999HS8-50#TRPBF
199950
8-Lead Plastic SO
–40°C to 125°C
LT1999MPS8-50#PBF
LT1999MPS8-50#TRPBF
99MP50
8-Lead Plastic SO
–55°C to 150°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, 0°C < TA < 70°C for C-grade parts, –40°C < TA < 85°C for I-grade parts, and –40°C < TA < 125°C for H-grade parts,
otherwise specifications are at TA = 25°C. V+ = 5V, GND = 0V, VCM = 12V, VREF = floating, VSHDN = floating, unless otherwise specified.
See Figure 2.
SYMBOL
PARAMETER
CONDITIONS
VSENSE
Full-Scale Input Sense Voltage (Note 7)
VSENSE = V+IN – V–IN
LT1999-10
LT1999-20
LT1999-50
VCM
CM Input Voltage Range
MIN
MAX
UNITS
–0.35
–0.2
–0.08
0.35
0.2
0.08
V
V
V
l
–5
80
V
l
l
l
TYP
RIN(DIFF)
Differential Input Impedance
ΔVINDIFF = ±2V/Gain
l
6.4
8
RINCM
CM Input Impedance
ΔVCM = 5.5V to 80V
ΔVCM = –5V to 4.5V
l
l
5
3.6
20
4.8
VOSI
Input Referred Voltage Offset
–750
–1500
±500
l
LT1999-10
LT1999-20
LT1999-50
l
l
l
9.95
19.9
48.75
10
20
50
ΔVOSI /ΔT
Input Referred Voltage Offset Drift
AV
Gain
9.6
kΩ
6
MΩ
kΩ
750
1500
μV
μV
5
μV/°C
10.05
20.1
50.25
V/V
V/V
V/V
AV Error
Gain Error
ΔVOUT = ±2V
l
–0.5
±0.2
0.5
%
IB
Input Bias Current
I(+IN) = I(–IN)
(Note 8)
VCM > 5.5V
VCM = –5V
VSHDN = 0.5V, 0V < VCM < 80V
l
l
l
100
–2.35
137.5
–1.95
0.001
175
–1.5
2.5
μA
mA
μA
IOS
Input Offset Current
IOS = I(+IN) – I(–IN)
(Note 8)
VCM > 5.5V
VCM = –5V
VSHDN = 0.5V, 0V < VCM < 80V
l
l
l
–1
–10
–2.5
1
10
2.5
μA
μA
μA
PSRR
Supply Rejection Ratio
V+ = 4.5V to 5.5V
l
68
77
dB
1999fb
3
LT1999-10/LT1999-20/
LT1999-50
Electrical
Characteristics
The
l denotes the specifications which apply over the full operating
temperature range, 0°C < TA < 70°C for C-grade parts, –40°C < TA < 85°C for I-grade parts, and –40°C < TA < 125°C for H-grade parts,
otherwise specifications are at TA = 25°C. V+ = 5V, GND = 0V, VCM = 12V, VREF = floating, VSHDN = floating, unless otherwise specified.
See Figure 2.
SYMBOL
PARAMETER
CONDITIONS
CMRR
Sense Input Common Mode Rejection
VCM = –5V to 80V
VCM = –5V to 5.5V
VCM = 12V, 7VP-P, f = 100kHz,
VCM = 0V, 7VP-P, f = 100kHz
en
Differential Input Referred Noise Voltage Density
f = 10kHz
f = 0.1Hz to 10Hz
REFRR
REF Pin Rejection, V+ = 5.5V
ΔVREF = 3.0V
ΔVREF = 3.25V
ΔVREF = 3.25V
l
l
l
l
MIN
TYP
MAX
UNITS
96
96
75
80
105
120
90
100
dB
dB
dB
dB
97
8
nV/√Hz
μVP-P
dB
dB
dB
LT1999-10
LT1999-20
LT1999-50
l
l
l
62
62
62
70
70
70
VSHDN = 0.5V
l
l
60
0.15
80
0.4
100
0.65
kΩ
MΩ
VSHDN = 0.5V
l
l
2.45
1
2.5
2.5
2.55
2.75
V
V
l
l
l
1.25
1.125
1.125
V+ – 1.25
V+ – 1.125
V+ – 1.125
V
V
V
RREF
REF Pin Input Impedance
VREF
Open Circuit Voltage
VREFR
REF Pin Input Range (Note 9)
LT1999-10
LT1999-20
LT1999-50
ISHDN
Pin Pull-Up Current
V+ = 5.5V, VSHDN = 0V
l
–6
V+ – 0.5
–2
μA
VIH
SHDN Pin Input High
l
VIL
SHDN Pin Input Low
l
f3dB
Small Signal Bandwidth
SR
Slew Rate
ts
Settling Time due to Input Step, ΔVOUT = ±2V
0.5% Settling
2.5
μs
tr
Common Mode Step Recovery Time
ΔVCM = ±50V, 20ns
(Note 10)
LT1999-10
LT1999-20
LT1999-50
0.8
1
1.3
μs
μs
μs
VS
Supply Voltage (Note 11)
IS
Supply Current
VCM > 5.5V
VCM = –5V
V+ = 5.5V, VSHDN = 0.5V, VCM > 0V
RO
Output Impedance
ΔIO = ±2mA
ISRC
Sourcing Output Current
RLOAD = 50Ω to GND
ISNK
Sinking Output Current
VOUT
LT1999-10
LT1999-20
LT1999-50
l
V
0.5
4.5
l
l
l
V
2
2
1.2
MHz
MHz
MHz
3
V/μs
5
5.5
V
1.55
5.8
3
1.9
7.1
10
mA
mA
μA
40
mA
0.15
31
Ω
l
6
RLOAD = 50Ω to V+
l
15
26
40
mA
Swing Output High (with Respect to V+)
RLOAD = 1kΩ to Mid-Supply
RLOAD = Open
l
l
125
5
250
125
mV
mV
Swing Output Low (with Respect to V–)
RLOAD = 1kΩ to Mid-Supply
RLOAD = Open
l
l
250
150
400
225
mV
mV
tON
Turn-On Time
VSHDN = 0V to 5V
1
μs
tOFF
Turn-Off Time
VSHDN = 5V to 0V
1
μs
1999fb
4
LT1999-10/LT1999-20/
LT1999-50
Electrical
Characteristics
The
l denotes the specifications which apply over the full operating
+
temperature range, –55°C < TA < 150°C for MP-grade parts, otherwise specifications are at TA = 25°C. V = 5V, GND = 0V, VCM = 12V,
VREF = floating, VSHDN = floating, unless otherwise specified. See Figure 2.
SYMBOL
PARAMETER
CONDITIONS
VSENSE
Full-Scale Input Sense Voltage (Note 7)
VSENSE = V+IN – V–IN
LT1999-10
LT1999-20
LT1999-50
VCM
CM Input Voltage Range
MAX
UNITS
l
l
l
–0.35
–0.2
–0.08
MIN
TYP
0.35
0.2
0.08
V
V
V
l
–5
80
V
RIN(DIFF)
Differential Input Impedance
ΔVINDIFF = ±2V/GAIN
l
6.4
8
RINCM
CM Input Impedance
ΔVCM = 5.5V to 80V
ΔVCM = –5V to 4.5V
l
l
5
3.6
20
4.8
VOSI
Input Referred Voltage Offset
±500
l
–750
–2000
9.6
kΩ
6
MΩ
kΩ
750
2000
μV
μV
ΔVOSI /ΔT
Input Referred Voltage Offset Drift
8
AV
Gain
LT1999-10
LT1999-20
LT1999-50
l
l
l
9.95
19.9
48.75
AV Error
Gain Error
ΔVOUT = ±2V
l
–0.5
±0.2
0.5
%
IB
Input Bias Current
I(+IN) = I(–IN)
(Note 8)
VCM > 5.5V
VCM = –5V
VSHDN = 0.5V, 0V < VCM < 80V
l
l
l
100
–2.35
137.5
–1.95
0.001
180
–1.5
10
μA
mA
μA
IOS
Input Offset Current
IOS = I(+IN) – I(–IN)
(Note 8)
VCM > 5.5V
VCM = –5V
VSHDN = 0.5V, 0V < VCM < 80V
l
l
l
–1
–10
–10
1
10
10
μA
μA
μA
PSRR
Supply Rejection Ratio
V+ = 4.5V to 5.5V
l
68
77
dB
CMRR
Sense Input Common Mode Rejection
VCM = –5V to 80V
VCM = –5V to 5.5V
VCM = 12V, 7VP-P, f = 100kHz,
VCM = 0V, 7VP-P, f = 100kHz
l
l
l
l
96
96
75
80
105
120
90
100
dB
dB
dB
dB
en
Differential Input Referred Noise Voltage Density
f= 10kHz
f = 0.1Hz to 10Hz
97
8
nV/√Hz
μVP-P
REFRR
REF Pin Rejection, V+ = 5.5V
ΔVREF = 2.75V
ΔVREF = 3.25V
ΔVREF = 3.25V
dB
dB
dB
10
20
50
μV/°C
10.05
20.1
50.25
V/V
V/V
V/V
LT1999-10
LT1999-20
LT1999-50
l
l
l
62
62
62
70
70
70
VSHDN = 0.5V
l
l
60
0.15
80
0.4
100
0.65
kΩ
MΩ
VSHDN = 0.5V
l
l
2.45
0.25
2.5
2.5
2.55
2.75
V
V
1.5
1.125
1.125
V+ – 1.25
V+ – 1.125
V+ – 1.125
V
V
V
RREF
REF Pin Input Impedance
VREF
Open Circuit Voltage
VREFR
REF Pin Input Range (Note 9)
LT1999-10
LT1999-20
LT1999-50
l
l
l
ISHDN
Pin Pull-Up Current
V+ = 5.5V, VSHDN = 0V
l
–6
V+ – 0.5
VIH
SHDN Pin Input High
l
VIL
SHDN Pin Input Low
l
f3dB
Small Signal Bandwidth
SR
Slew Rate
tS
Settling Time Due to Input Step, ΔVOUT = ±2V
–2
μA
V
0.5
V
LT1999-10
LT1999-20
LT1999-50
2
2
1.2
MHz
MHz
MHz
3
V/μs
0.5% Settling
2.5
μs
1999fb
5
LT1999-10/LT1999-20/
LT1999-50
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, –55°C < TA < 150°C for MP-grade parts, otherwise specifications are at TA = 25°C. V+ = 5V, GND = 0V, VCM = 12V,
VREF = floating, VSHDN = floating, unless otherwise specified. See Figure 2.
SYMBOL
PARAMETER
CONDITIONS
MIN
tr
Common Mode Step Recovery Time
ΔVCM = ±50V, 20ns
(Note 10)
LT1999-10
LT1999-20
LT1999-50
VS
Supply Voltage (Note 11)
IS
Supply Current
VCM > 5.5V
VCM = –5V
V+ = 5.5V, VSHDN = 0.5V, VCM > 0V
TYP
MAX
0.8
1
1.3
l
4.5
l
l
l
UNITS
μs
μs
μs
5
5.5
V
1.55
5.8
3
1.9
7.1
25
mA
mA
μA
40
mA
RO
Output Impedance
ΔIO = ±2mA
ISRC
Sourcing Output Current
RLOAD = 50Ω to GND
l
3
ISNK
Sinking Output Current
RLOAD = 50Ω to V+
l
10
26
40
mA
VOUT
Swing Output High (with Respect to V+)
RLOAD = 1kΩ to Mid-Supply
RLOAD = Open
l
l
125
5
250
125
mV
mV
Swing Output Low (with Respect to V –)
RLOAD = 1kΩ to Mid-Supply
RLOAD = Open
l
l
250
150
400
225
mV
mV
tON
Turn-On Time
VSHDN = 0V to 5V
1
μs
tOFF
Turn-Off Time
VSHDN = 5V to 0V
1
μs
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: Pin 2 (+IN) and Pin 3 (–IN) are protected by ESD voltage clamps
which have asymmetric bidirectional breakdown characteristics with respect
to the GND pin (Pin 5). These pins can safely support common mode
voltages which vary from –5.25V to 88V without triggering an ESD clamp.
Note 3: Exposure to differential sense voltages exceeding the normal
operating range for extended periods of time may degrade part
performance. A heat sink may be required to keep the junction temperature
below the Absolute Maximum Rating when the inputs are stressed
differentially. The amount of power dissipated in the LT1999 due to input
overdrive can be approximated by:
PDISS =
( V+IN − V−IN )2
8kΩ
Note 4: A heat sink may be required to keep the junction temperature
below the absolute maximum rating.
Note 5: The LT1999C/LT1999I are guaranteed functional over the operating
temperature range –40°C to 85°C. The LT1999H is guaranteed functional
over the operating temperature range –40°C to 125°C. The LT1999MP is
guaranteed functional over the operating temperature range –55°C to 150°C.
Junction temperatures greater than 125°C will promote accelerated aging.
The LT1999 has a demonstrated typical life beyond 1000 hours at 150°C.
Note 6: The LT1999C is guaranteed to meet specified performance from
0°C to 70°C. The LT1999C is designed, characterized, and expected to
meet specified performance from –40°C to 85°C but is not tested or
QA sampled at these temperatures. The LT1999I is guaranteed to meet
specified performance from –40°C to 85°C. The LT1999H is guaranteed
to meet specified performance from –40°C to 125°C. The LT1999MP is
guaranteed to meet specified performance from –55°C to 150°C.
0.15
31
Ω
Note 7: Full-scale sense (VSENSE) gives indication of the maximum
differential input that can be applied with better than 0.5% gain accuracy.
Gain accuracy is degraded when the output saturates against either power
supply rail. VSENSE is verified with V+ = 5.5V, VCM = 12V, with the REF pin
set to it’s voltage range limits. The maximum VSENSE is verified with the
REF pin set to it’s minimum specified limit, verifying the gain error is less
than 0.5% at the output. The minimum VSENSE is verified with the REF pin
set to its maximum specified limit, verifying the gain error at the output is
less than 0.5%. See Note 9 for more information.
Note 8: IB is defined as the average of the input bias currents to the +IN
and –IN pins (Pins 2 and 3). A positive current indicates current flowing
into the pin. IOS is defined as the difference of the input bias currents.
IOS = I(+IN) – I(–IN)
Note 9: The REF pin voltage range is the minimum and maximum limits
that ensures the input referred voltage offset does not exceed ±3mV over
the I, C, and H temperature ranges, and ±3.5mV over the MP temperature
range.
Note 10: Common mode recovery time is defined as the time it takes the
output of the LT1999 to recover from a 50V, 20ns input common mode
voltage transition, and settle to within the DC amplifier specifications.
Note 11: Operating the LT1999 with V+ < 4.5V is possible, although the
LT1999 is not tested or specified in this condition. See the Applications
Information section.
1999fb
6
LT1999-10/LT1999-20/
LT1999-50
Typical Performance Characteristics
Supply Current
vs Input Common Mode
7
Supply Current vs Temperature
1.8
V+ = 5V
6
VSHDN = OPEN
VINDIFF = 0V
VCM = 12V
150°C
130°C
90°C
25°C
–45°C
–55°C
3.5
1.7
5
3.0
3
2
IS (mA)
2.5
4
IS (mA)
IS (mA)
Supply Current vs Supply Voltage
4.0
1.6
V+ = 5.5V
1.5
VCM = 12V
2.0
1.5
V+ = 4.5V
1.0
1
0.5
0
–5
5
15
25
35 45
VCM (V)
55
65
1.4
–55 –30
75 80
20 45 70 95
TEMPERATURE (°C)
0
120 145
0
2
3
SUPPLY VOLTAGE (V)
1
10
V+ = 5V
VCM = 12V
8
1
Shutdown Input Bias Current
vs Input Common Mode
1000
VSHDN = 0V
VINDIFF = 0V
VCM = 12V
V+ = 5V
VSHDN = 0V
VSENSE = 0V
TA = 150°C
TA =130°C
6
V+ = 5.5V
4
TA =110°C
IB (nA)
IS (µA)
IS (mA)
100
TA = 150°C
TA = 90°C
10
0.01
0.001
TA = 25°C
0
1
TA = 70°C
TA = –55°C
3
2
VSHDN (V)
4
0
–55 –30
5
–5
20 45 70 95
TEMPERATURE (°C)
1999 G04
146
V+ = 5V
IMPEDANCE (kΩ)
IB (µA)
IB (mA)
VCM = 80V
140
138
VCM = 5.5V
136
–1.5
5
15
25
35 45
VCM (V)
55
65
75 80
1999 G07
132
–55 –30
–5
100
80
1999 G06
1000
100
DIFFERENTIAL INPUT IMPEDANCE
10
134
–5
60
40
VCM (V)
COMMON MODE INPUT
IMPEDANCE
10000
142
–1.0
20
100000
VSHDN = OPEN
VINDIFF = 0V
144 V+ = 5V
–0.5
0
Input Impedance
vs Input Common Mode Voltage
Input Bias Current vs Temperature
0
–2.0
1
120 145
1999 G05
Input Bias Current
vs Input Common Mode
0.5
V+ = 4.5V
2
5
1999 G03
Shutdown Supply Current
vs Temperature
0.1
4
1999 G02
1999 G01
Supply Current
vs SHDN Pin Voltage
10
–5
20 45 70 95
TEMPERATURE (°C)
120 145
1999 G08
1
–5
5
15
25
35 45
VCM (V)
55
65
75
1999 G09
1999fb
7
LT1999-10/LT1999-20/
LT1999-50
Typical Performance Characteristics
Input Referred Voltage Offset
vs Temperature and Gain Option
1500
Input Referred Voltage Offset
vs Input Common Mode Voltage
1500
VCM = 12V
12 UNITS PLOTTED
1000
1000
500
VOSI (µV)
500
VOSI (µV)
V+ = 5V
TA = 25°C
12 UNITS PLOTTED
0
0
–500
–500
–1000
–1500
–55 –30
–5
LT1999-10
LT1999-20
LT1999-50
–1000
LT1999-10
LT1999-20
LT1999-50
20 45 70 95
TEMPERATURE (°C)
–1500
120 145
–5
5
15
25
1999 G10
25
GAIN
GAIN (dB)
135
30
90
25
45
20
0
VOUT = 0.5VP-P AT 1kHz
10
100
1000
FREQUENCY (kHz)
135
GAIN
90
45
PHASE
15
0
–90
5
–90
–135
0
0
–5
180
–45
–45
1
1999 G11
10
5
–10
–5
–180
10000
–135
VOUT = 0.5VP-P AT 1kHz
1
10
LT1999-50 Small Signal
Frequency Response
1999 G13
135
90
45
PHASE
20
0
15
–45
10
–90
5
GAIN ERROR (%)
25
VOUT = 0.5VP-P AT 1kHz
10
100
1000
FREQUENCY (kHz)
–180
10000
1999 G14
0
–0.25
–0.25
–0.50
–55 –30
V+ = 5V
TA = 25°C
12 UNITS PLOTTED
0.25
0
–135
1
0.50
VCM = 12V
12 UNITS PLOTTED
0.25
PHASE (DEG)
GAIN (dB)
30
0
0.50
GAIN ERROR (%)
GAIN
35
Gain Error
vs Input Common Mode Voltage
Gain Error vs Temperature
180
–180
10000
100
1000
FREQUENCY (kHz)
1999 G12
40
75
PHASE (DEG)
PHASE
35
PHASE (DEG)
15
180
GAIN (dB)
30
10
65
55
LT1999-20 Small Signal
Frequency Response
LT1999-10 Small Signal
Frequency Response
20
35 45
VCM (V)
LT1999-10
LT1999-20
LT1999-50
–5
20 45 70 95
TEMPERATURE (°C)
120 145
1999 G15
–0.50
LT1999-10
LT1999-20
LT1999-50
–5
5
15
25
35 45
VCM (V)
55
65
75
1999 G16
1999fb
8
LT1999-10/LT1999-20/
LT1999-50
Typical Performance Characteristics
VSENSE
VSENSE
VSENSE
4.5
VOUT
0.100
4.5
0.075
4.0
2.5
0
2.0
1.5
–0.025
OUTPUT ERROR
1.0
0.5
1999 G20
TIME (1µs/DIV)
VOUT (V)
0.025
0.15
VOUT
0.10
3.0
0.05
2.5
0
–0.05
2.0
–0.050
1.5
–0.075
1.0
–0.100
0.5
OUTPUT ERROR
OUTPUT ERROR (V)
3.0
0.20
3.5
0.050
OUTPUT ERROR (V)
VOUT (V)
3.5
1999 G19
TIME (2µs/DIV)
LT1999-20 2V Step Response
Settling Time
LT1999-10 2V Step Response
Settling Time
4.0
VOUT
1999 G18
TIME (2µs/DIV)
VOUT (1V/DIV)
VOUT
1999 G17
TIME (2µs/DIV)
VOUT (1V/DIV)
VOUT (1V/DIV)
VOUT
VSENSE (0.1V/DIV)
LT1999-50 Pulse Response
VSENSE (0.2V/DIV)
LT1999-20 Pulse Response
VSENSE (0.5V/DIV)
LT1999-10 Pulse Response
–0.01
–0.15
–1 0
1
2
3 4 5 6
TIME (1µs/DIV)
7
8
9 10
–0.20
1999 G21
LT1999-50 2V Step Response
Settling Time
0.500
4.0
0.375
VOUT
0
2.0
–0.125
OUTPUT ERROR
–0.250
–0.375
1.0
TIME (1µs/DIV)
LT1999-10
LT1999-20
LT1999-50
LT1999-10
LT1999-20
LT1999-50
100
1999 G22
–0.500
80
80
CMRR (dB)
2.5
OUTPUT ERROR (V)
0.125
0.5
100
CMRR vs Frequency
120
0.250
3.0
1.5
120
CMRR (dB)
3.5
VOUT (V)
CMRR vs Frequency
4.5
60
40
40
VCM = 12V
20 V+ = 5V
TA = 25°C
6 UNITS PLOTTED
0
1000
1
10
100
FREQUENCY (kHz)
60
VCM = 0V
V+ = 5V
TA = 25°C
6 UNITS PLOTTED
20
10000
1999 G23
0
1
10
100
1000
FREQUENCY (kHz)
10000
1999 G24
1999fb
9
LT1999-10/LT1999-20/
LT1999-50
Typical Performance Characteristics
LT1999-10 Common Mode Rising
Edge Step Response
LT1999-10 Common Mode Falling
Edge Step Response
VCM , tRISE ≈ 20ns
VOUT (0.5V/DIV)
VOUT
TIME (0.5µs/DIV)
VCM (25V/DIV)
VCM (25V/DIV)
VOUT (0.5V/DIV)
VCM , tFALL ≈ 20ns
VOUT
1999 G25
1999 G26
TIME (0.5µs/DIV)
LT1999-20 Common Mode Rising
Edge Step Response
LT1999-20 Common Mode Falling
Edge Step Response
VOUT (0.5V/DIV)
VOUT
TIME (0.5µs/DIV)
VCM , tFALL ≈ 20ns
VCM (25V/DIV)
VCM (25V/DIV)
VOUT (0.5V/DIV)
VCM , tRISE ≈ 20ns
VOUT
1999 G27
1999 G28
TIME (0.5µs/DIV)
LT1999-50 Comm
Step Response
LT1999-50 Common Mode Falling
Edge Step Response
VCM
tRISE20ns
VOUT (0.5V/DIV)
VCM , tFALL ≈ 20ns
VCM (25V/DIV)
VCM (25V/DIV)
VOUT (0.5V/DIV)
VCM , tRISE ≈ 20ns
VOUT
VOUT (0.5 V / div)
LT1999-50 Common Mode Rising
Edge Step Response
TIM
VOUT
TIME (0.5µs/DIV)
1999 G29
TIME (0.5µs/DIV)
1999 G30
1999fb
10
LT1999-10/LT1999-20/
LT1999-50
Typical Performance Characteristics
LT1999 Input Referred Noise
Density vs Frequency
Short-Circuit Current
vs Temperature
1000
3.0
40
30
SINKING
REF PIN VOLTAGE (V)
ISC (mA)
100
10
0
–10
–20
SOURCING
0.1
1
10
FREQUENCY (kHz)
1000 10000
–5
20 45 70 95
TEMPERATURE (°C)
1999 G31
0
1.5
1.0
V+ = 5V
0
–55 –30 –5
120 145
20 45 70 95
TEMPERATURE (°C)
Turn-On/Turn-Off Time
vs SHDN Voltage
V+ = 5V
VCM = 12V
VCM = 12V
IS (1mA/DIV)
TA = 150°C
TA = 25°C
TA = –55°C
SHDN PIN VOLTAGE (5V/DIV)
IS
–1
–2
SHUTDOWN
–3
VSHDN
–4
6
0
1
2
3
VSHDN (V)
4
5
1999 G35
TIME (1µs/DIV)
1999 G34
VOUT vs VSENSE Over the Sense
ABSMAX Range
VOUT vs VSENSE
6
VREF = 2.5V
5
4
4
3
3
VOUT (V)
5
2
1
VOUT PHASE REVERSAL FOR VSENSE < –25V
2
1
LT1999-10
LT1999-20
LT1999-50
0
–1
–0.25
120 145
1999 G33
1999 G32
SHDN Pin Current vs SHDN Pin
Voltage and Temperature
ISHDN (µA)
0.01
–40
–55 –30
SHDN MODE
2.0
0.5
–30
10
0.001
ACTIVE MODE
2.5
20
VOUT (V)
NOISE DENSITY (nV/√Hz)
REF Open Circuit Voltage
vs Temperature
–0.15
0.05
–0.05
VSENSE (V)
0.15
0.25
1999 G36
LT1999-10
LT1999-20
LT1999-50
0
VREF = 2.5V
–1
–60
–30
0
VSENSE (V)
30
60
1999 G37
1999fb
11
LT1999-10/LT1999-20/
LT1999-50
Pin Functions
V+ (Pins 1, 4): Power Supply Voltage. Pins 1 and 4 are
tied internally together. The specified range of operation
is 4.5V to 5.5V, but lower supply voltages (down to approximately 4V) is possible although the LT1999 is not
tested or characterized below 4.5V. See the Applications
Information section.
OUT (Pin 7): Voltage Output. VOUT = AV •(VSENSE ± VOSI),
where AV is the gain, and VOSI is the input referred offset voltage. The output amplifier has a low impedance
output and is designed to drive up to 200pF capacitive
loads directly. Capacitive loads exceeding 200pF should
be decoupled with an external resistor of at least 100Ω.
+IN (Pin 2): Positive Sense Input Pin.
SHDN (Pin 8): Shutdown Pin. When pulled to within 0.5V
of GND (Pin 5), will place the LT1999 into low power
shutdown. If the pin is left floating, an internal 2µA pullup current source will place the LT1999 into the active
(amplifying) state.
–IN (Pin 3): Negative Sense Input Pin.
GND (Pin 5): Ground Pin.
REF (Pin 6): Reference Pin Input. The REF pin sets the
output common mode level and is set halfway between V+
and GND using a divider made of two 160k resistors. The
default open circuit potential of the REF pin is mid-supply.
It can be overdriven by an external voltage source cable
of driving 80k to a mid-supply potential (see the Electrical
Characteristics table for its specified input voltage range).
1999fb
12
LT1999-10/LT1999-20/
LT1999-50
Block Diagram
V+
2µA
V+
4.5k
V(G+IN)
R +IN
2
2k
2k
+IN
CF
4pF
3
8
SHDN
1
2k
–IN
2k
+
GIN
–
V(G–IN)
0.8k
R +S
RG
–
+ AO
V+
D1
OUT
7
V+
0.8k
R –S
300Ω
160k
REF
6
160k
R –IN
V+
GND
4
5
1999 BD
Figure 1. Simplified Block Diagram
Test Circuit
V+
LT1999
V+
5V
2µA
1
VCM
+
–
+
–
V
+
+
–
4k
2
+
–
8 V
SHDN
SHDN
+
0.8k
RG
–
+
V+
VIN(DIFF)
–
4k
3
0.8k
160k
6
V+
5V
7 V
OUT
160k
4
VREF
0.1µF
5
0.1µF
1999 F02
Figure 2. Test Circuit
1999fb
13
LT1999-10/LT1999-20/
LT1999-50
Applications Information
The LT1999 current sense amplifier provides accurate
bidirectional monitoring of current through a user-selected
sense resistor. The voltage generated by the current flowing
in the sense resistor is amplified by a fixed gain of 10V/V,
20V/V or 50V/V (LT1999-10, LT1999-20, or LT1999-50
respectively) and is level shifted to the OUT pin. The voltage difference and polarity of the OUT pin with respect
to REF (Pin 6) indicates magnitude and direction of the
current in the sense resistor.
Theory of Operation
Refer to the Block Diagram (Figure 1).
Case 1: V+ < VCM < 80V
For input common mode voltages exceeding the power
supply, one can assume D1 of Figure 1 is completely off.
The sensed voltage (VSENSE) is applied across Pin 2 (+IN)
and Pin 3 (–IN) to matched resistors R+IN and R– IN (nominally 4k each). The opposite ends of R+IN and R– IN are
forced to equal potentials by transconductor GIN, which
convert the differentially sensed voltage into a sensed
current. The sensed current in R+IN and R– IN is combined,
level-shifted, and converted back into a voltage by transresistance amplifier AO and resistor RG. Amplifier AO provides high open loop gain to accurately convert the sensed
current back into a voltage and to drive external loads. The
theoretical output voltage is determined by the sensed
voltage (VSENSE), and the ratio of two on-chip resistors:
VOUT − VREF = VSENSE •
RG
RIN
Case 2: –5V < VCM < V+
For common mode inputs which transition or are set below
the supply voltage, diode D1 will turn on and will provide a
source of current through R+S and R –S to bias the inputs
of transconductance amplifier GIN at least 2.25V above
GND. The transition is smooth and continuous; there are
negligible changes to either gain or amplifier voltage offset. The only difference in amplifier operation is the bias
currents provided by D1 through R+S and R– S are steered
through the input pins, otherwise amplifier operation is
identical. The inputs to transconductance amplifier GIN are
still forced to equal potentials forcing any differential voltages appearing at the +IN and –IN pins into a differential
current. This differential current is combined, level-shifted,
and converted back into a voltage by trans-resistance
amplifier AO and Resistor RG. Resistors R+S and R– S are
trimmed to match R+IN and R– IN respectively, to prevent
common mode to differential conversion from occurring
(to the extent of the matched trim) when the input common mode transitions below V+.
As described in case 1, the output is determined by the
sense voltage and the ratio of two on-chip resistors:
VOUT − VREF = VSENSE •
RG
RIN
where
where
RIN =
The voltage difference between the OUT pin and the REF
pin represent both polarity and magnitude of the sensed
voltage. The noninverting input of amplifier AO is biased
by a resistive 160k to 160k divider tied between V+ and
GND to set the default REF pin bias to mid-supply.
R +IN + R −IN
nominally 4k
2
RIN =
R +IN + R −IN
2
For the LT1999-10, RG is nominally 40k. For the LT1999-20,
RG is nominally 80k, and for the LT1999-50, RG is nominally 200k.
1999fb
14
LT1999-10/LT1999-20/
LT1999-50
Applications Information
Input Common Mode Range
–2.0
With the V+ supply configured within the specified and
tested range (4.5V < V+ < 5.5V), the LT1999’s common
mode range extends from –5V to 80V. Pushing +IN and
–IN beyond the limits specified in the Absolute Maximum
table can turn on the voltage clamps designed to protect
the +IN and –IN pins during ESD events.
It is possible to operate the LT1999 on power supplies
as low as 4V (although it is not tested or specified below
4.5V). Operating the LT1999 on supplies below 4V will
produce erratic behavior. When operating the LT1999
with supplies as low as 4V, the common mode range for
inputs which extend below GND is reduced. Refer to the
Block Diagram (Figure 1). For inputs driven below V+,
diode D1 conducts. For proper operation, the input to the
transconductor V(G+IN) must be biased at approximately
2.25V above the GND pin. V(G+IN) sits on the centertap
of a voltage divider comprised of R+S and R+IN V(G –IN)
likewise sits in the middle of the voltage divider comprised
of R – S , and R–IN). The voltage on V(G+IN) input is given
by the following equation:
R +S
R +IN
V(G ) = V •
+ V + −VD1 •
+IN
+IN
R +S + R +IN
R +S + R +IN
(
)
Setting V(G+IN) = 2.25V, the ratio (R+IN /R+S) to 5, and VD1
equal to 0.8V (cold temperatures), a plot of the lower input
common mode range plotted against supply is shown in
Figure 3.
–2.5
VCM(LOWER LIMIT) (V)
The LT1999 was optimized for high common mode rejection. Its input stage is balanced and fully differential,
designed to amplify differential signals and reject common
mode signals. There is negligible crossover distortion due
to sense voltage reversals. The amplifier is most linear in
the zero-sense region.
BELOW GROUND INPUT
COMMON MODE RANGE
LIMITED BY V+
SUPPLY VOLTAGE
–3.0
–3.5
–4.0
BELOW GROUND INPUT
COMMON MODE RANGE
LIMITED BY ESD CLAMPS
–4.5
–5.0
–5.5
–6.0
TYPICAL ESD CLAMP VOLTAGE
4
4.25
4.5
5
4.75
SUPPLY VOLTAGE (V)
5.25
5.5
1999 F03
Figure 3. Lower Input Common Mode vs Supply Voltage
Output Common Mode Range
The LT1999’s output common mode level is set by the
voltage on the REF pin. The REF pin sits in the middle of
a 160k to 160k voltage divider connected between V+ and
GND which sets the default open circuit potential of the
REF pin to mid-supply. It can be overdriven by an external
voltage source capable of driving 80k tied to a mid-supply
potential. See the Electrical Characteristics table for the
REF pin’s specified input voltage range.
Differential sampling of the OUT pin with respect the REF
pin provides the best noise immunity. Measurements of
the output voltage made differentially with respect to the
REF pin will provide the highest power supply and common mode rejection. Otherwise, power supply or GND pin
disturbances are divided by the REF pin’s voltage divider
and appear directly at the noninverting input of the transresistance amplifier AO and are not rejected.
If not driven by a low impedance (<100Ω), the REF pin
should be filtered with at least 1nF of capacitance to a
low impedance, low noise ground plane. This external
capacitance will also provide a charge reservoir during
high frequency sampling of the REF pin by ADC inputs
attached to this pin.
1999fb
15
LT1999-10/LT1999-20/
LT1999-50
Applications Information
Shutdown Capability
If SHDN (Pin 8) is driven to within 0.5V of GND, the LT1999
is placed into a low power shutdown state in which the
part will draw about 3μA from the V+ supply. The input
pins (+IN and –IN) will draw approximately 1nA if biased
within the range of 0V to 80V (with no differential voltage
applied). If the input pins are pulled below the GND pin,
each input appears as a diode tied to GND in series with
approximately 4k of resistance. The REF pin appears as
approximately 0.4MΩ tied to a mid-supply potential. The
output appears as reverse biased diodes tied between the
output to either V+ or GND pins.
EMI Filtering and Layout Practices
An internal 1st order differential lowpass noise/EMI suppression filter with a –3dB bandwidth of 10MHz (approximately 5× the LT1999’s –3dB bandwidth) is included to
help improve the LT1999’s EMI susceptibility and to assist
with the rejection of high frequency signals beyond the
bandwidth of the LT1999 that may introduce errors. The
pole is set by the following equation:
ffilt = 1/(π•(R+IN + R–IN)•CF) ≈ 10MHz
Both the resistors and capacitors have a ±15% variation
so the pole can vary by approximately ±30% over manufacturing process and temperature variations.
The layout for lowest EMI/noise susceptibility is achieved
by keeping short direct connections and minimizing loop
areas (see Figure 4). If the user-supplied sense resistor
cannot be placed in close proximity to the LT1999, the
surface area of the loop comprising connections of +IN
to RSENSE and back to –IN should be minimized. This
requires routing PCB traces connecting +IN to RSENSE
and –IN to RSENSE adjacent with one another with minimal
separation. The metal traces connecting +IN to the sense
resistor and –IN to the sense resistor should match and
use the same trace width.
Bypassing the V+ pin to the GND pin with a 0.1µF capacitor
with short wiring connection is recommended.
†
1 V+
FROM DC SOURCE
RSENSE *
TO LOAD
SHDN 8
2 +IN
OUT 7
3 –IN
REF 6
4 V+
GND 5
DIFFERENTIAL
ANALOG OUT
**
SUPPLY BYPASS
CAPACITOR
1999 F03
* KEEP LOOP AREA COMPRISING RSENSE, +IN AND –IN PINS
AS SMALL AS POSSIBLE.
** REF BYPASS TIED TO A LOW NOISE, LOW IMPEDANCE
SIGNAL GROUND PLANE.
† OPTIONAL 10pF CAPACITOR TO PREVENT dV/dt EDGES
ON INPUT COUPLING TO FLOATING SHDN PIN.
Figure 4. Recommended Layout
1999fb
16
LT1999-10/LT1999-20/
LT1999-50
Applications Information
The REF pin should be either driven by a low source impedance (<100Ω) or should be bypassed with at least 1nF
to a low impedance, low noise, signal ground plane (see
Figure 4). Larger bypass capacitors on both V+ pins, and
the REF pin, will extend enhanced AC CMRR, and PSRR
performance to lower frequencies. Bypassing the REF pin
to a quiet ground plane filters the V+ pin or GND pin noise
that is sensed by the REF pin voltage divider and applied
to the noninverting input of output amplifier AO. Any common I•R drops generated by pulsating ground currents in
common with the REF pin filter capacitor can compromise
the filtering performance and should be avoided.
If the SHDN pin is not driven and is left floating, routing
a PCB trace connecting Pins 1 and 8 under the part will
act as a shield, and will help limit edge coupling from the
inputs (Pins 2 and 3) to the SHDN pin. Periodic pulses on
the inputs with fast edges may glitch the high impedance
SHDN pin, periodically putting the part into low power
shutdown. Additional precaution against this may be taken
by adding an optional small (~10pF) capacitor may be tied
between V+ (Pin 1) and Pin 8.
Finally, when connecting the LT1999 inputs to the sense
resistor, it is important to use good Kelvin sensing practices
(sensing the resistor in a way that excludes PCB trace
I•R voltage drops). For sense resistors less than 1Ω, one
might consider using a 4-wire sense resistor to sense the
resistive element accurately.
Selection of the Current Sense Resistor
The external sense resistor selection presents a delicate
trade-off between power dissipation in the resistor and
current measurement accuracy.
In high current applications, the user may want to minimize the power dissipated in the sense resistor. The sense
resistor current will create heat and voltage loss, degrading
efficiency. As a result, the sense resistor should be as small
as possible while still providing adequate dynamic range
required by the measurement. The dynamic range is the
ratio between the maximum accurately produced signal
generated by the voltage across the sense resistor, and
the minimum accurately reproduced signal. The minimum
accurately reproduced signal is primarily dictated by the
voltage offset of the LT1999. The maximum accurately
reproduced signal is dictated by the output swing of the
LT1999.
Thus the dynamic range for the LT1999 can be thought of
the maximum sense voltage divided by the input referred
voltage offset or:
Dynamic Range =
∆VOUT(MAX)
GAIN • VOSI
The above equation tells us that the dynamic range is
inversely proportional to the gain of the LT1999. Thus,
if accuracy is of greater importance than efficiency or
power loss, the LT1999-10 used with the highest valued
sense resistor possible is recommended. If efficiency,
heat generated, and power loss in the resistive shunt is
the primary concern, the LT1999-50 and the lowest value
sense resistor possible is recommended. The LT1999-20
is available for applications somewhere in between these
two extremes.
1999fb
17
LT1999-10/LT1999-20/
LT1999-50
Applications Information
Fuse Monitor
The inputs can be overdriven without fear of damaging
the LT1999. This makes the LT1999 ideal for monitoring
fuses if either +IN or –IN are shorted to ground while the
other is at the full common mode supply voltage (see
Figure 5). If the fuse in Figure 5 opens with the +IN tied
to the positive supply, the load will pull –IN to GND. The
output will be forced to the positive V+ supply rail. If it is
desired that the output be near ground if the fuse opens,
it is a simple matter of swapping the inputs. Precautions
should be followed: First, when the inputs are stressed
differentially due to the fuse blowing open, a large voltage
drop will be placed across the +IN to –IN pins, dissipating
VS
V+
LT1999
2µA
1
VSHDN
+
–
4k
V+IN 2
VOUT
VREF
STEERING
DIODE
V+
FUSE
8
SHDN
ILOAD
LOAD
Finally, the user should be aware that in fuse monitoring
applications with the sense voltage (VSENSE = V+IN – V–IN)
being driven in excess of –25V, the output of the LT1999
will undergo phase reversal (see Figure 6).
V+
5V
ON OFF
power in the precision on-chip input resistors. Precaution
should be taken to prevent junction temperatures from
exceeding the Absolute Maximum ratings (see Note 3 in the
Electrical Characteristics section). Secondly, if the load is
inductive, and the fuse blows open without a clamp diode,
energy stored in the inductive load will be dissipated in
the LT1999, which could cause damage. A simple steering
diode as shown in Figure 5 will prevent this from happening, and will protect the LT1999 from damage.
VSHDN
RG
–
+
0.8k
7
VOUT
V+
RSENSE
V–IN 3
4k
0.8k
160k
6
V+
5V
160k
4
VREF
0.1µF
5
0.1µF
1999 F05
Figure 5. Using the LT1999 to Monitor a Fuse
VOUT (1V/DIV)
VOUT PHASE REVERSAL FOR VSENSE < –25V
VREF = 2.5V
–60 –45 –30 –15 0
15
VSENSE (V)
30
45
60
1999 F06
Figure 6. A Plot of the LT1999’s Output Voltage vs VSENSE (VSENSE = V+IN – V– IN).
In Applications Where the Sense Voltage Is Driven in Excess of –25V, the Output
of the LT1999 Will Undergo Phase Reversal
1999fb
18
LT1999-10/LT1999-20/
LT1999-50
Typical Applications
Solenoid Current Monitor
Bidirectional PWM Motor Monitor
The solenoid of Figure 7 consists of a coil of wire in an
iron case with permeable plunger that acts as a movable
element. When the MOSFET turns on, the diode is reversed
biased off, and current flows through RSENSE to actuate
the solenoid. If the MOSFET is turned off, the current
in the MOSFET is interrupted, but the energy stored in
the solenoid causes the diode to turn on and current to
freewheel in the loop consisting of the diode, RSENSE and
the solenoid.
Pulse width modulation is commonly used to efficiently
vary the average voltage applied across a DC motor. The
H-bridge topology of Figure 9 allows full 4-quadrant control:
clockwise control, counter-clockwise control, clockwise
regeneration, and counter-clockwise regeneration. The
LT1999 in conjunction with a non-inductive current shunt
is used to monitor currents in the rotor. The LT1999 can
be used to detect stuck rotors, provide detection of overcurrent conditions in general, or provide current mode
feedback control.
Figure 7 shows the LT1999 monitoring currents in a
ground referenced solenoid used when the coil is hard
tied to the case, and is tied to ground. Figure 8 shows a
supply referenced solenoid whose coil is insulated from
the case. The LT1999 will interface equally well to either
of these two configurations.
VS
V+
LT1999
V+
5V
2µA
1
V+IN
+
–
4k
2
V
+
0.8k
VSHDN
RG
–
+
7
VOUT
V–IN
4k
3
5V
V+
0.8k
160k
6
0.1µF
160k
4
VREF
2.5V
VOUT
V+IN (10V/DIV)
V+
RSENSE
SOLENOID
8
SHDN
VOUT (0.5V/DIV)
OFF
ON
Figure 10 shows a plot of the output voltage of the LT1999.
SOLENOID RELEASES
SOLENOID PLUNGER PULLS IN
V+IN
5
0.1µF
1999 F07a
TIME (50ms/DIV)
1999 F07b
Figure 7. Solenoid Current Monitor for Ground Tied Solenoid. The Common Mode
Inputs to the LT1999 Switch Between VS and One Diode Drop Below Ground
1999fb
19
LT1999-10/LT1999-20/
LT1999-50
Typical Applications
V+
LT1999
VS
1
2µA
V+
SOLENOID
V+IN
+
–
4k
2
+
V
0.8k
–
+
7
VOUT
3
5V
4
4k
V+
0.8k
160k
6 VREF
160k
0.1µF
2.5V
VOUT
V+IN (10V/DIV)
V–IN
ON
VSHDN
RG
V+
RSENSE
OFF
8
SHDN
VOUT (0.5V/DIV)
5V
SOLENOID RELEASES
SOLENOID PLUNGER PULLS IN
V+IN
5
0.1µF
1999 F08a
TIME (50ms/DIV)
1999 F08b
Figure 8. Solenoid Current Monitor for Non-Grounded Solenoids. This Circuit Performs the
Same Function as Figure 7 Except One End of the Solenoid Is Tied to VS. The Common Mode
Voltage of Inputs of the LT1999 Switch Between Ground and One Diode Drop Above VS
1999fb
20
LT1999-10/LT1999-20/
LT1999-50
Typical Applications
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
VOUT
VREF
0.1µF
5
4
PWM INPUT
VSHDN
V+
VBRIDGE
H-BRIDGE
RSENSE
0.025Ω
1999 F09
24V MOTOR
OUTB
BRAKE INPUT
GND
Figure 9. Armature Current Monitor for DC Motor Applications
VOUT
2.5V
V+IN (20V/DIV)
VOUT (2V/DIV)
PWM IN
V+
8
V+IN
TIME (20µs/DIV)
1999 F10
Figure 10. LT1999 Output Waveforms for the Circuit of Figure 9
1999fb
21
LT1999-10/LT1999-20/
LT1999-50
Package Description
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
MS8 Package
8-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1660 Rev F)
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.889 ± 0.127
(.035 ± .005)
0.254
(.010)
8
7 6 5
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0.52
(.0205)
REF
0° – 6° TYP
GAUGE PLANE
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
1
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
4
0.86
(.034)
REF
0.18
(.007)
0.65
(.0256)
BSC
0.42 ± 0.038
(.0165 ± .0015)
TYP
2 3
1.10
(.043)
MAX
SEATING
PLANE
RECOMMENDED SOLDER PAD LAYOUT
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
0.22 – 0.38
(.009 – .015)
TYP
0.1016 ± 0.0508
(.004 ± .002)
0.65
(.0256)
BSC
MSOP (MS8) 0307 REV F
S8 Package
8-Lead Plastic Small Outline (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1610)
.050 BSC
.189 – .197
(4.801 – 5.004)
NOTE 3
.045 ±.005
8
.245
MIN
.160 ±.005
.010 – .020
× 45°
(0.254 – 0.508)
NOTE:
1. DIMENSIONS IN
5
.150 – .157
(3.810 – 3.988)
NOTE 3
1
RECOMMENDED SOLDER PAD LAYOUT
.053 – .069
(1.346 – 1.752)
0°– 8° TYP
.016 – .050
(0.406 – 1.270)
6
.228 – .244
(5.791 – 6.197)
.030 ±.005
TYP
.008 – .010
(0.203 – 0.254)
7
.014 – .019
(0.355 – 0.483)
TYP
INCHES
(MILLIMETERS)
2. DRAWING NOT TO SCALE
3. THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS.
MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED .006" (0.15mm)
2
3
4
.004 – .010
(0.101 – 0.254)
.050
(1.270)
BSC
SO8 0303
1999fb
22
LT1999-10/LT1999-20/
LT1999-50
Revision History
REV
DATE
DESCRIPTION
PAGE NUMBER
A
5/11
Revised +IN and –IN pin descriptions in Pin Functions section
12
B
3/12
Revised Voltage Output Swing Low specification (VOUT) under a loaded condition of 1kΩ to mid-supply.
4, 6
Updated Figure 4 to multicolor.
16
1999fb
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.
23
LT1999-10/LT1999-20/
LT1999-50
Typical Application
Battery Charge Current and Load Current Monitor
VOUT = 0.25V/A, Maximum Measured Current ±9.5A
0.025Ω
CHARGER
BAT
42V
V+
5V
2µA
1
V+IN
SHDN
+
–
4k
2
+
V
0.8k
8
VSHDN
7
VOUT
4k
3
0.8k
V+
5V
0.1µF
0.1µF
10µF
40k
–
+
V+
V–IN
5V
V+
LT1999-10
LOAD
160k
+
+IN
VOUT
6
160k
VREF
–
VCC
VREF
LTC2433-1
–IN
CS
SCK
SDO
0.1µF
5
4
0.1µF
1999 TA02
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LT1787/
LT1787HV
Precision, Bidirectional High Side Current Sense Amplifier
2.7V to 60V Operation, 75μV Offset, 60μA Current Draw
LT6100
Gain-Selectable High Side Current Sense Amplifier
4.1V to 48V Operation, Pin-Selectable Gain:
10V/V, 12.5V/V, 20V/V, 25V/V, 40V/V, 50V/V
LTC6101/
LTC6101HV
High Voltage High Side Current Sense Amplifier
4V to 60V/5V to 100V Operation, External Resistor Set Gain, SOT23
LTC6102/
LTC6102HV
Zero Drift High Side Current Sense Amplifier
4V to 60V/5V to 100V Operation, ±10μV Offset, 1μs Step Response,
MSOP8/DFN Packages
LTC6103
Dual High Side Precision Current Sense Amplifier
4V to 60V, Gain Configurable, 8-Pin MSOP Package
LTC6104
Bidirectional, High Side Current Sense
4V to 60V, Gain Configurable, 8-Pin MSOP Package
LT6106
Low Cost, High Side Precision Current Sense Amplifier
2.7V to 36V, Gain Configurable, SOT23 Package
LT6105
Precision, Extended Input Range Current Sense Amplifier
–0.3 to 44V, Gain Configurable, 8-Pin MSOP Package
LTC4150
Coulomb Counter/Battery Gas Gauge
Indicates Charge Quantity and Polarity
LT1990
Precision, 100μA Gain Selectable Amplifier
2.7V to 36V Operation, CMRR > 70dB, Input Voltage = ±250V
LT1991
±250V Input Range Difference Amplifier
2.7V to 36V Operation, 50μV Offset, CMRR > 75B, Input Voltage = ±60V
LT1637/LT1638
1.1/1.2MHz, 0.4V/μs Over-The-Top, Rail-to-Rail Input and
Output Amplifier
0.4V/μs Slew Rate, 230μA per Amplifier
1999fb
24 Linear Technology Corporation
LT 0312 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 l FAX: (408) 434-0507
l
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2010