LM3814MX-7.0/NOPB [TI]
2-CHANNEL POWER SUPPLY SUPPORT CKT, PDSO8, 0.150 INCH, PLASTIC, SOP-8;![LM3814MX-7.0/NOPB](http://pdffile.icpdf.com/pdf2/p00312/img/icpdf/LM3814MX-1-0_1876080_icpdf.jpg)
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February 2005
LM3814/LM3815
Fast Current Gauge IC with Ultra Low Loss Sense
Element and PWM Output
n
3.5% accuracy at room temperature (includes
accuracy of the internal sense element) (LM3814-1.0,
LM3815-1.0)
General Description
The LM3814/LM3815 Current Gauges provide easy to use
precision current measurement with virtually zero insertion
loss (typically 0.004Ω). The LM3814 is used for high-side
sensing and the LM3815 is used for low-side sensing.
n Low quiescent current in shutdown mode (typically 2.5
µA)
n 6 msec sampling interval
A Delta Sigma analog to digital converter is incorporated to
precisely measure the current and to provide a current av-
eraging function. Current is averaged over 6 msec time
periods in order to provide immunity to current spikes. The
ICs have a pulse-width modulated (PWM) output which indi-
cates the current magnitude and direction. The shutdown pin
can be used to inhibit false triggering during start-up, or to
enter a low quiescent current mode.
Features
n No external sense element required
n PWM output indicates the current magnitude and
direction
n PWM output can be interfaced with microprocessors
n Precision ∆Σ current-sense technique
n Low temperature sensitivity
n Internal filtering rejects false trips
n Internal Power-On-Reset (POR)
The LM3814 and LM3815 are factory-set in two different
current options. The sense range is −1A to +1A or −7A to
+7A. The user specifies a particular part number to match
the current range for a given application. The sampling
interval for these parts is 6ms. If larger sampling interval is
desired for better accuracy, please refer to the data sheets
for the part numbers LM3812 and LM3813.
Applications
n Battery charge/discharge gauge
n Motion control diagnostics
n Power supply load monitoring and management
n Resettable smart fuse
Key Specifications
n Ultra low insertion loss (typically 0.004Ω)
n 2V to 5.25V supply range
Connection Diagrams
10101303
Top View
LM3815
10101301
Top View
LM3814
for Low-Side Sensing
for High-Side Sensing
© 2005 National Semiconductor Corporation
DS101013
www.national.com
Ordering Information
Order No.#
Sense
Range
Sampling
Interval*
Sensing
Method
NS
Package
Number‡
M08A
Package
Type
Supplied As:
LM3814M-1.0
LM3814MX-1.0
LM3814M-7.0
LM3814MX-7.0
LM3815M-1.0
LM3815MX-1.0
LM3815M-7.0
LM3815MX-7.0
1A
1A
7A
7A
1A
1A
7A
7A
6 ms
6 ms
6 ms
6 ms
6 ms
6 ms
6 ms
6 ms
High-side
High-side
High-side
High-side
Low-side
Low-side
Low-side
Low-side
SO-8
SO-8
SO-8
SO-8
SO-8
SO-8
SO-8
SO-8
95 units in Rails
M08A
2.5k units on Tape and Reel
95 units in Rails
M08A
M08A
2.5k units on Tape and Reel
95 units in Rails
M08A
M08A
2.5k units on Tape and Reel
95 units in Rails
M08A
M08A
2.5k units on Tape and Reel
‡
#
Suffix M indicates that the part is available in Surface
The Package code M08A is internal to National Semicon-
ductor and indicates an 8-lead surface mount package,
SO-8.
Mount package. Suffix X indicates that the part is available in
2.5k units on Tape and Reel.
* Current is sampled over a fixed interval. The average
current during this interval is indicated by the duty cycle of
the PWM output during next interval.
Pin Description (High-Side, LM3814)
Pin Description (High-Side, LM3814)
Pin
1
Name
SENSE+, VDD
Function
High side of internal current sense, also supply voltage.
Low side of internal current sense.
2
SENSE−
FLTR+
FLTR−
SD
3
Filter input — provides anti-aliasing for delta sigma modulator.
Filter input.
4
5
Shutdown pin. Connected to VDD through a pull up resistor for normal operation. When
low, the IC goes into a low current mode (typically 3 µA).
PWM output indicates the current magnitude and direction.
Ground
6
7
8
PWM
GND
GND
Ground
Pin Description (Low-Side, LM3815)
Pin Description (Low-Side, LM3815)
Pin
1
Name
SENSE+, GND
Function
High side of internal current sense, also ground.
Low side of internal current sense.
2
SENSE−
FLTR+
FLTR−
SD
3
Filter input – provides anti-aliasing for delta sigma modulator.
Filter input.
4
5
Shutdown pin. Connected to VDD through a pull up resistor for normal operation. When
low, the IC goes into a low current mode (typically 3 µA).
PWM output indicates the current magnitude and direction.
Ground
6
7
8
PWM
GND
VDD
VDD (supply)
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2
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Maximum Junction Temperature
Storage Temperature
150˚C
−65˚C to +150˚C
260˚C
Lead Temperature (Soldering, 10 sec)
Absolute Maximum Supply Voltage
Power Dissipation
5.5V
(Note 2)
1.5 kV
10A
Operating Ratings (Note 1)
Input Voltage
2.0V to 5.25V
7A
ESD Susceptibility (Note 3)
Sense Current (peak, for 200 msec) (Note 4)
Sink Current for PWM pin
Voltage on Pin 5
Sense Current (continuous) (Note 4)
Junction Temperature Range
−40˚C to +125˚C
1 mA
5.25V
Electrical Characteristics
LM3814-1.0, LM3815-1.0
VDD = 5.0V for the following specifications. Supply bypass capacitor is 1µF and filter capacitor is 0.1µF.
Typ
(Note 5)
0.9
Limit
(Note 6)
Symbol
IACC
Parameter
Conditions
at 0.9A current
Units
Average Current Accuracy
(Note 7)
A
0.868 / 0.850
0.932 / 0.950
A (min)
A (max)
mA
en
Effective Output Noise (rms)
12
LM3814-7.0, LM3815-7.0
VDD = 5.0V for the following specifications. Supply bypass capacitor is 1µF and filter capacitor is 0.1µF.
Typ
(Note 5)
2.5
Limit
(Note 6)
Symbol
IACC
Parameter
Conditions
Units
Average Current Accuracy
(Note 7)
at 2.5A current (Note 8)
A
2.350 / 2.288
2.650 / 2.712
A (min)
A (max)
mA
en
Effective Output Noise (rms)
120
Common Device Parameters
Unless otherwise specified, VDD = 5.0V for the following specifications. Supply bypass capacitor is 1µF and filter capacitor is
0.1µF.
Typ
(Note 5)
100
Limit
(Note 6)
Symbol
IQ1
Parameter
Quiescent Current
Conditions
Units
Normal Mode, SD = high
µA
µA (max)
µA
160
10
IQ2
Quiescent Current
Shutdown Mode, SD = low
2.5
µA (max)
%
DRES
tS
PWM Resolution
Sampling Time
0.8
6
ms
4
ms (min)
ms (max)
Hz
10
fP
Frequency of PWM Waveform
160
100
250
Hz (min)
Hz (max)
V
VTH
VTL
VOH
Threshold High Level for SD
Threshold Low Level for SD
Logic High Level for PWM
1.2
1.3
1.8
0.7
V (min)
V
V (max)
V
Load current = 1mA, 2V ≤ VDD
≤
VDD − 0.05
5.25V
VDD − 0.2
V (min)
3
www.national.com
Electrical Characteristics (Continued)
Common Device Parameters (Continued)
Unless otherwise specified, VDD = 5.0V for the following specifications. Supply bypass capacitor is 1µF and filter capacitor is
0.1µF.
Typ
(Note 5)
0.04
Limit
(Note 6)
Symbol
VOL
Parameter
Conditions
Units
Logic Low Level for PWM
Sink current = 1mA, 2V ≤ VDD
≤
V
V (max)
Ω
5.25V
0.2
PI
Insertion Loss
ISENSE = 1A (Note 9)
0.004
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see Electrical Characteristics. The
guaranteed specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed
test conditions.
Note 2: At elevated temperatures, devices must be derated based on package thermal resistance. The device in the surface-mount package must be derated at
θ
= 150˚C/W (typically), junction-to-ambient.
JA
Note 3: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
Note 4: The absolute maximum peak and continuous currents specified are not tested. These specifications are dependent on the θ , which is 150˚C/W for the
JA
S08 package.
Note 5: Typical numbers are at 25˚C and represent the most likely parametric norm. Specifications in standard type face are for T = 25˚C and those with boldface
J
type apply over full operating temperature ranges.
Note 6: Limits are 100% production tested at 25˚C. Limits over the operating temperature range are guaranteed through correlation using Statistical Quality Control
(SQC) methods. The limits are used to calculate National’s Averaging Outgoing Quality Level (AOQL).
Note 7: There is a variation in accuracy over time due to thermal effects. Please refer to the PWM Output and Current Accuracy section for more information.
Note 8: The PWM accuracy for LM3814-7.0 and LM3815-7.0 depends on the amount of copper area under pins 1 and 2, and the layout. Please refer to the "PWM
Output and Current Accuracy" section for more information.
Note 9: The tolerance of the internal lead frame resistor is corrected internally. The temperature coefficient of this resistor is 2600 ppm/˚C.
Typical Performance Characteristics
Supply bypass capacitor is 0.1µF and filter capacitor is
0.1µF.
Measured Current vs Actual Current
(LM3814-1.0 and LM3815-1.0)
Measured Current vs Actual Current
(LM3814-7.0 and LM3815-7.0)
10101315
10101324
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4
Typical Performance Characteristics Supply bypass capacitor is 0.1µF and filter capacitor is
0.1µF. (Continued)
PWM Frequency vs Supply Voltage
PWM Frequency vs Temperature
10101317
10101314
Operating Current vs Supply Voltage
Shutdown Current vs Supply Voltage
10101318
10101319
Operating Current vs Temperature
Shutdown Current vs Temperature
10101320
10101321
5
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Typical Performance Characteristics Supply bypass capacitor is 0.1µF and filter capacitor is
0.1µF. (Continued)
Current vs Duty Cycle
Accuracy vs Supply Voltage
10101322
10101328
Accuracy vs Temperature (LM3814-1.0 and LM3815-1.0)
Accuracy vs Temperature (LM3814-7.0 and LM3815-7.0)
10101329
10101330
Error vs Current (LM3814-1.0 and LM3815-1.0)
(Note 10)
Error vs Current (LM3814-7.0 and LM3815-7.0)
(Note 10)
10101327
10101331
Note 10: These curves represent a statistical average such that the noise is
insignificant.
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6
Typical Application Circuits
In the application circuits, the 0.1µF ceramic capacitor
between pins 1 and 8 is used for bypassing, and the 0.1µF
ceramic capacitor between pins 3 and 4 is used for filter-
ing. Shutdown (SD) is tied to VDD through a 10kΩ resistor.
10101305
FIGURE 1. High Side Sense
10101306
FIGURE 2. Low Side Sense
7
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Typical Application Circuits In the application circuits, the 0.1µF ceramic capacitor between pins 1 and 8
is used for bypassing, and the 0.1µF ceramic capacitor between pins 3 and 4 is used for filtering. Shutdown (SD) is tied to
VDD through a 10kΩ resistor. (Continued)
10101307
FIGURE 3. Paralleling LM3814 for Higher Load Current
ITOTAL = 2.2(D1−0.5)IMAX + 2.2(D2−0.5)IMAX
where D1 is the duty cycle of PWM1 and D2 is the duty cycle of PWM2.
Please refer to the Product Operation section for more information.
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8
Typical Application Circuits In the application circuits, the 0.1µF ceramic capacitor between pins 1 and 8
is used for bypassing, and the 0.1µF ceramic capacitor between pins 3 and 4 is used for filtering. Shutdown (SD) is tied to
VDD through a 10kΩ resistor. (Continued)
10101308
FIGURE 4. High Voltage Operation — VIN Greater Than 5.25V (High Side Sense)
(PWM output is referred to Pin 7)
10101309
FIGURE 5. High Voltage Operation — VIN Greater Than 5.25V (Low Side Sense)
9
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The user should note that, while the LM3814-7.0/
LM3815-7.0 will read 10A full scale, it is rated for 10A
operation for a duration of no more than 200 msec, and
7A operation continuously.
Product Operation
The current is sampled by the delta-sigma modulator, as
illustrated in Figure 6. The pulse density output of the delta-
sigma modulator is digitally filtered. The digital output is then
compared to the output of a digital ramp generator. This
produces a PWM output. The duty cycle of the PWM output
is proportional to the amount of current flowing. A duty cycle
of 50% indicates zero current flow. If the current is flowing in
positive direction, the duty cycle will be greater than 50%.
Conversely, the duty cycle will be less than 50% for currents
flowing in the negative direction. A duty cycle of 95.5%
(4.5%) indicates the current is at IMAX (−IMAX). The IC can
sense currents from −IMAX to +IMAX. Options for IMAX are 1A
or 10A. The sense current is given by:
In this IC, the current is averaged over 6 msec time slots.
Hence, momentary current surges of less than 6 msec are
tolerated.
This is a sampled data system which requires an anti-
aliasing filter, provided by the filter capacitor.
The delta-sigma modulator converts the sensed current to
the digital domain. This allows digital filtering, and provides
immunity to current and noise spikes. This type of filtering
would be difficult or impossible to accomplish on an IC with
analog components.
ISENSE = 2.2 (D−0.5)(IMAX
)
When ordering, the user has to specify whether the part is
being used for low-side or high-side sense. The user also
needs to specify the full scale value. See the Ordering
Information table for details.
where D is the duty cycle of the PWM waveform, and IMAX is
the full scale current (1A or 10A). Similarly, the duty cycle is
given by:
D = [ISENSE/(2.2 IMAX)] + 0.5
For quick reference, see the Conversion Tables in Table 1
and Table 2.
10101310
FIGURE 6. Functional block diagram of LM3814 and LM3815
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10
PWM Output and Current Accuracy
OFFSET
tually the temperature difference reaches steady state,
which accounts for the under-damped exponential response.
The PWM output is quantized to 128 levels. Therefore, the
duty cycle can change only in increments of 1/128.
There is a one-half (0.5) quantization cycle delay in the
output of the PWM circuitry. That is to say that instead of a
duty cycle of N/128, the duty cycle actually is (N+1⁄
)/128.
2
The quantization error can be corrected for if a more precise
result is desired. To correct for this error, simply subtract
1/256 from the measured duty cycle.
1
The extra half cycle delay will show up as a DC offset of
⁄
2
bit if it is not corrected for. An offset of 1⁄
bit is 8 times larger
2
than for precision mode parts, and results in approximately
8.8 mA for a 1 Amp part is 88 mA for a 7 Amp part.
JITTER
In addition to quantization, the duty cycle will contain some
jitter. The jitter is quite small (for example, the standard
deviation of jitter is only 0.1% for the LM3814/15-1.0). Sta-
tistically the jitter can cause an error in a current sample.
Because the jitter is a random variable, the mean and stan-
dard deviation are used. The mean, or average value, of the
jitter is zero. The standard deviation (0.1%) can be used to
define the peak error caused from jitter.
10101323
FIGURE 7. Transient Response to 7 Amp Step Current
ACCURACY VERSUS NOISE
The graph shown in Figure 8 illustrates the typical response
of 1 Ampere current gauges. In this graph, the horizontal
axis indicates time, and the vertical axis indicates measured
current (the PWM duty cycle has been converted to current).
The graph was generated for an actual current of 500 mA.
The "crest factor" has often been used to define the maxi-
mum error caused by jitter. The crest factor defines a limit
within which 99.7% of the samples fall. The crest factor is
defined as 0.3% error in the duty cycle.
Since the jitter is a random variable, averaging multiple
outputs will reduce the effective jitter. Obeying statistical
laws, the jitter is reduced by the square root of the number of
readings that are averaged. For example, if four readings of
the duty cycle are averaged, the resulting jitter (and crest
factor) are reduced by a factor of two.
The difference between successive readings manifests itself
as jitter in the PWM output or noise in the current measure-
ment (when duty cycle of the PWM output is converted to
current).
The accuracy of the measurement depends on the noise in
the current waveform. The accuracy can be improved by
averaging several outputs. Although there is variation in
successive readings, a very accurate measurement can be
obtained by averaging the readings. For example, on aver-
aging the readings shown in this example, the average
current measurement is 497.5 mA (Figure 8). This value is
very close to the actual value of 500 mA. Moreover, the
accuracy depends on the number of readings that are aver-
aged.
JITTER AND NOISE
Jitter in the PWM output appears as noise in the current
measurement. The Electrical Characteristics show noise
measured in current RMS (root mean square). Arbitrarily one
could specify PWM jitter, as opposed to noise. In either case
the effect results in a random error in an individual current
measurement.
Noise, just like jitter, can be reduced by averaging many
readings. The RMS value of the noise corresponds to one
standard deviation. The "crest factor" can be calculated in
terms of current, and is equal to 3 sigma (RMS value of the
noise).
Noise will also be reduced by averaging multiple readings,
and follows the statistical laws of a random variable.
ACCURACY OF 7A VERSIONS
The graph of Figure 7 shows two possible responses to a 7A
current step. The flat response shows basically a 7A level
with some noise. This is what is possible with a good thick
trace and a good thermal connection to the IC on the sense
pins.
The second trace that asymptotically approaches a higher
value shows what can happen under extremely poor thermal
conditions. Here a very small wire connects the IC to the
current source. The very small wire does not allow heat in
the sense resistor to dissipate. Hence, as the sense resistor
heats up, a temperature difference between the sense ele-
ment and the die gets larger, and an error develops. Even-
10101325
FIGURE 8. Typical Response of LM3814-1.0/LM3815-1.0
11
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1
quantization error of
⁄2 bit is not shown in these tables.
Look-Up Tables
The following tables show how to convert the duty cycle of
the PWM output to a current value, and vice versa. The
Please see the "PWM Output and Current Accuracy" section
for more details.
TABLE 1. CURRENT TO DUTY CYCLE CONVERSION TABLE
Duty Cycle Sense Current
(%) (Amps)*
Sense Current
(Amps)*
1.00
Duty Cycle
(%)
95.5
93.2
90.9
88.6
86.4
84.1
81.8
79.5
77.3
75.0
72.7
70.5
68.2
65.9
63.6
61.4
59.1
56.8
54.5
52.3
50.0
-1.00
-0.95
-0.90
-0.85
-0.80
-0.75
-0.70
-0.65
-0.60
-0.55
-0.50
-0.45
-0.40
-0.35
-0.30
-0.25
-0.20
-0.15
-0.10
-0.05
-0.00
4.5
0.95
6.8
0.90
9.1
0.85
11.4
13.6
15.9
18.2
20.5
22.7
25.0
27.3
29.5
31.8
34.1
36.4
38.6
40.9
43.2
45.5
47.7
50.0
0.80
0.75
0.70
0.65
0.60
0.55
0.50
0.45
0.40
0.35
0.30
0.25
0.20
0.15
0.10
0.05
0.00
*Maximum Sense Current = 1.0 Amps for LM3814-1.0 and LM3815-1.0
The sense current should be multiplied by 10 for LM3814-7.0 and LM3815-7.0.
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12
TABLE 2. DUTY CYCLE TO CURRENT CONVERSION TABLE
Duty Cycle
(%)
Sense Current
(Amps)
0.990
Duty Cycle
(%)
Sense Current
(Amps)
-0.000
-0.055
-0.110
95.5
92.5
90.0
87.5
85.0
82.5
80.0
77.5
75.0
72.5
70.0
67.5
65.0
62.5
60.0
57.5
55.0
52.5
50.0
50.0
47.5
45.0
42.5
40.0
37.5
35.0
32.5
30.0
27.5
25.0
22.5
20.0
17.5
15.0
12.5
10.0
7.5
0.935
0.880
0.825
-0.165
-0.220
-0.275
-0.330
-0.385
-0.440
-0.495
-0.550
-0.605
-0.660
-0.715
-0.770
-0.825
-0.880
-0.935
-0.990
0.770
0.715
0.660
0.605
0.550
0.495
0.440
0.385
0.330
0.275
0.220
0.165
0.110
0.055
0.000
5.0
*Maximum Sense Current = 1.0 Amps for LM3814-1.0 and LM3815-1.0.
The sense current should be multiplied by 10 for LM3814-7.0 and LM3815-7.0.
Timing Diagram
10101311
Duty cycle of the PWM waveform during any sampling interval indicates the current magnitude (average) and direction during the previous sampling interval.
FIGURE 9. Typical Timing Diagram for Mostly Positive Current
13
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Physical Dimensions inches (millimeters) unless otherwise noted
8-lead (0.150" Wide) Molded Small Outline Package
See Ordering Information table for Order Numbers
NS Package Number M08A
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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properly used in accordance with instructions for use
provided in the labeling, can be reasonably expected to result
in a significant injury to the user.
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device or system whose failure to perform can be reasonably
expected to cause the failure of the life support device or
system, or to affect its safety or effectiveness.
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