AD AD22283-B

Single-Axis, High-g,
iMEMS® Accelerometers
ADXL193
FEATURES
GENERAL DESCRIPTION
Complete acceleration measurement system on a
single monolithic IC
Available in ±120 g or ±250 g output full-scale ranges
Full differential sensor and circuitry for high resistance
to EMI/RFI
Environmentally robust packaging
Complete mechanical and electrical self-test on
digital command
Output ratiometric to supply
Sensitive axes in the plane of the chip
High linearity (0.2% of full scale)
Frequency response down to dc
Low noise
Low power consumption (1.5 mA)
Tight sensitivity tolerance and 0 g offset capability
Largest available prefilter clipping headroom
400 Hz, 2-pole Bessel filter
Single-supply operation
Compatible with Sn/Pb and Pb-free solder processes
The ADXL193 is a low power, complete single-axis
accelerometer with signal conditioned voltage outputs that are
all on a single monolithic IC. This product measures
acceleration with a full-scale range of ±120 g or ±250 g
(minimum). It can also measure both dynamic acceleration
(vibration) and static acceleration (gravity).
The ADXL193 is a fourth-generation surface micromachined
iMEMS® accelerometer from ADI with enhanced performance
and lower cost. Designed for use in front and side impact airbag
applications, this product also provides a complete costeffective solution useful for a wide variety of other applications.
The ADXL193 is temperature stable and accurate over the
automotive temperature range, with a self-test feature that fully
exercises all the mechanical and electrical elements of the
sensor with a digital signal applied to a single pin.
The ADXL193 is available in a 5 mm × 5 mm × 2 mm,
8-terminal ceramic LCC package.
APPLICATIONS
Vibration monitoring and control
Vehicle collision sensing
Shock detection
FUNCTIONAL BLOCK DIAGRAM
VS
ADXL193
TIMING
GENERATOR
VDD
VDD2
DIFFERENTIAL
SENSOR
SELF-TEST
DEMOD
AMP
400Hz
BESSEL
FILTER
XOUT
05366-001
EXC
Figure 1.
Rev. A
Information furnished by Analog Devices is believed to be accurate and reliable.
However, no responsibility is assumed by Analog Devices for its use, nor for any
infringements of patents or other rights of third parties that may result from its use.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2005 Analog Devices, Inc. All rights reserved.
ADXL193
TABLE OF CONTENTS
Specifications..................................................................................... 3
Power Supply Decoupling ............................................................8
Absolute Maximum Ratings............................................................ 4
Self-Test ..........................................................................................8
ESD Caution.................................................................................. 4
Clock Frequency Supply Response .............................................8
Pin Configuration and Function Descriptions............................. 5
Signal Distortion ...........................................................................8
Theory of Operation ........................................................................ 7
Outline Dimensions ..........................................................................9
Applications....................................................................................... 8
Ordering Guide .............................................................................9
REVISION HISTORY
5/05—Rev. 0 to Rev. A
Rev. A | Page 2 of 12
ADXL193
SPECIFICATIONS 1
At TA = −40°C to +105°C, 5.0 V dc ± 5%, acceleration = 0 g; unless otherwise noted.
Table 1.
Parameter
SENSOR
Output Full-Scale Range
Nonlinearity
Package Alignment Error
Cross-Axis Sensitivity
Resonant Frequency
Sensitivity, Ratiometric
(Over Temperature)
OFFSET
Zero-g Output Voltage
(Over Temperature) 2
NOISE
Noise Density
Clock Noise
FREQUENCY RESPONSE
−3 dB Frequency
−3 dB Frequency Drift
SELF-TEST
Output Change
(Cube vs. VDD) 3
Logic Input High
Logic Input Low
Input Resistance
OUTPUT AMPLIFIER
Output Voltage Swing
Capacitive Load Drive
PREFILTER HEADROOM
CFSR @ 400 kHz
POWER SUPPLY (VDD)
Functional Range
Quiescent Supply Current
TEMPERATURE RANGE
1
2
3
Conditions
Model No. AD22282
Min
Typ
Max
Model No. AD22283
Min
Typ
Max
IOUT ≤ ±100 μA
120
250
0.2
1
−5
VDD = 5 V, 100 Hz
17.1
VOUT − VDD/2, VDD = 5 V
−125
10 Hz − 400 Hz, 5 V
2
+5
24
18
8.4
g
%
Degree
%
kHz
mV/g
+100
mV
5
5
15
mg/√Hz
mV p-p
0.2
1
−5
18.9
7.6
+125
−100
Unit
2
+5
24
8
3
5
10
360
400
2
440
360
400
2
440
Hz
Hz
VDD = 5 V
400
500
600
200
250
300
mV
VDD = 5 V
VDD = 5 V
Pull-down resistor to GND
3.5
1
V
V
kΩ
IOUT = ±400 μA
0.25
1000
Two-pole Bessel
25°C to TMIN or TMAX
3.5
1
30
50
30
VDD − 0.25
0.25
1000
800
2
4.75
3.5
VDD = 5 V
1.5
−40
VDD − 0.25
1400
1.5
5.25
6
2
+125
All minimum and maximum specifications are guaranteed. Typical specifications are not guaranteed.
Zero g output is ratiometric.
Self-test output at VDD = (Self-Test Output at 5 V) × (VDD/5 V)3.
Rev. A | Page 3 of 12
50
4.75
3.5
1.5
−40
5.25
6
2
+125
V
pF
g
V/V
V
V
mA
°C
ADXL193
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter
Acceleration (Any Axis, Unpowered)
Acceleration (Any Axis, Powered)
VS
All Other Pins
Output Short-Circuit Duration
(Any Pin to Common)
Operating Temperature Range
Storage Temperature
Rating
4,000 g
4,000 g
−0.3 V to +7.0 V
(COM − 0.3 V) to
(VS + 0.3 V)
Indefinite
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
−65°C to +150°C
−65°C to +150°C
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the
human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. A | Page 4 of 12
ADXL193
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
VDD2
8
NC 1
NC 2
ADXL193
TOP VIEW
(Not to Scale)
COM 3
7
VDD
6
XOUT
5
NC
05366-002
4
ST
NC = NO CONNECT
Figure 2. Pin Configuration
Table 3. Pin Function Descriptions
Pin No.
1
2
3
4
5
6
7
8
Mnemonic
NC
NC
COM
ST
NC
XOUT
VDD
VDD2
Description
Do Not Connect
Do Not Connect
Common
Self-Test
Do Not Connect
X Channel Output
3.5 V to 6 V
3.5 V to 6 V
Rev. A | Page 5 of 12
ADXL193
CRITICAL ZONE
TL TO TP
tP
TP
TEMPERATURE
RAMP-UP
TL
tL
TSMAX
TSMIN
tS
RAMP-DOWN
05366-003
PREHEAT
t25°C TO PEAK
TIME
Figure 3. Recommended Soldering Profile
Table 4. Recommended Soldering Profile
Profile Feature
AVERAGE RAMP RATE (TL TO TP)
PREHEAT
Minimum Temperature (TSMIN)
Maximum Temperature (TSMAX)
TIME (TSMIN TO TSMAX), tS
TSMAX TO TL
Ramp-Up Rate
TIME MAINTAINED ABOVE LIQUIDOUS (TL)
Liquidous Temperature (TL)
Time (tL)
PEAK TEMPERATURE (TP)
TIME WITHIN 5°C OF ACTUAL PEAK TEMPERATURE (tP)
RAMP-DOWN RATE
TIME 25°C TO PEAK TEMPERATURE
Sn63/Pb37
3°C/s max
Pb-Free
3°C/s max
100°C
150°C
60 s − 120 s
150°C
200°C
60 s − 150 s
3°C/s
3°C/s
183°C
60 s − 150 s
240°C + 0°C/−5°C
10 s − 30 s
6°C/s max
6 min max
217°C
60 s − 150 s
260°C + 0°C/−5°C
20 s − 40 s
6°C/s max
8 min max
PIN 8
XXXXX
XXXX
XOUT = 2.482V
22282
XXXXX
XXXX
22282
XOUT = 2.500V
22282
XXXXX
XXXX
XOUT = 2.518V
XOUT = 2.500V
EARTH'S SURFACE
Figure 4. Output Response vs. Orientation
Rev. A | Page 6 of 12
05366-004
XOUT = 2.500V
XXXXX
XXXX
22282
ADXL193
THEORY OF OPERATION
Complementary 400 kHz square waves drive the fixed plates.
Electrical feedback adjusts the amplitudes of the square waves
such that the ac signal on the moving plates is 0. The feedback
signal is linearly proportional to the applied acceleration. This
unique feedback technique ensures that there is no net
electrostatic force applied to the sensor. The differential
feedback control signal is also applied to the input of the filter,
where it is filtered and converted to a single-ended signal.
Rev. A | Page 7 of 12
MOVABLE
FRAME
PLATE
CAPACITORS
UNIT
SENSING
CELL
FIXED
PLATES
UNIT
FORCING
CELL
MOVING
PLATE
ANCHOR
Figure 5. Simplified View of Sensor Under Acceleration
05366-005
Figure 5 is a simplified view of one of the differential sensor
elements. Each sensor includes several differential capacitor
unit cells. Each cell is composed of fixed plates attached
to the substrate and movable plates attached to the frame.
Displacement of the frame changes the differential capacitance,
which is measured by the on-chip circuitry.
ANCHOR
ACCELERATION
The ADXL193 provides a fully differential sensor structure and
circuit path, resulting in the industry’s highest resistance to
EMI/RFI effects. This latest generation uses electrical feedback
with zero-force feedback for improved accuracy and stability.
The sensor resonant frequency is significantly higher than the
signal bandwidth set by the on-chip filter, avoiding the signal
analysis problems caused by resonant peaks near the signal
bandwidth.
ADXL193
APPLICATIONS
POWER SUPPLY DECOUPLING
For most applications, a single 0.1 μF capacitor, CDC, adequately
decouples the accelerometer from noise on the power supply.
However, in some cases, particularly where noise is present at
the 400 kHz internal clock frequency (or any harmonic
thereof), noise on the supply can cause interference on the
ADXL193’s output. If additional decoupling is needed, a 50 Ω
(or smaller) resistor or ferrite bead can be inserted in the supply
line. Additionally, a larger bulk bypass capacitor (in the 1 μF to
4.7 μF range) can be added in parallel to CDC.
SELF-TEST
The fixed fingers in the forcing cells are normally kept at the
same potential as that of the movable frame. When the self-test
digital input is activated, the voltage on the fixed fingers on one
side of the moving plate in the forcing cells is changed. This
creates an attractive electrostatic force, which causes the frame
to move toward those fixed fingers. The entire signal channel is
active; therefore, the sensor displacement causes a change in
VOUT. The ADXL193’s self-test function is a comprehensive
method of verifying the operation of the accelerometer.
Because electrostatic force is independent of the polarity of the
voltage across capacitor plates, a positive voltage is applied in
half of the forcing cells, and its complement in the other half of
the forcing cells. Activating self-test causes a step function force
to be applied to the sensor, while the capacitive coupling term is
canceled. The ADXL193 has improved self-test functionality,
including excellent transient response and high speed switching
capability. Arbitrary force waveforms can be applied to the
sensor by modulating the self-test input, such as test signals to
measure the system frequency response, or even crash signals to
verify algorithms within the limits of the self-test swing.
The ST pin should never be exposed to voltages greater than
VS + 0.3 V. If this cannot be guaranteed due to the system
design (for instance, if there are multiple supply voltages), then
a low VF clamping diode between ST and VS is recommended.
CLOCK FREQUENCY SUPPLY RESPONSE
In any clocked system, power supply noise near the clock
frequency may have consequences at other frequencies. An
internal clock typically controls the sensor excitation and the
signal demodulator for micromachined accelerometers.
If the power supply contains high frequency spikes, they may be
demodulated and interpreted as an acceleration signal. A signal
appears as the difference between the noise frequency and the
demodulator frequency. If the power supply spikes are 100 Hz
away from the demodulator clock, there is an output term at
100 Hz. If the power supply clock is at exactly the same frequency
as the accelerometer clock, the term appears as an offset.
If the difference frequency is outside of the signal bandwidth,
the filter attenuates it. However, both the power supply clock
and the accelerometer clock may vary with time or temperature,
which can cause the interference signal to appear in the output
filter bandwidth.
The ADXL193 addresses this issue in two ways. First, the high
clock frequency eases the task of choosing a power supply clock
frequency such that the difference between it and the accelerometer clock remains well outside of the filter bandwidth.
Second, the ADXL193 is the only micromachined accelerometer
to have a fully differential signal path, including differential
sensors. The differential sensors eliminate most of the power
supply noise before it reaches the demodulator. Good high
frequency supply bypassing, such as a ceramic capacitor close to
the supply pins, also minimizes the amount of interference.
The clock frequency supply response (CFSR) is the ratio of the
response at VOUT to the noise on the power supply near the
accelerometer clock frequency. A CFSR of 3 means that the
signal at VOUT is 3× the amplitude of an excitation signal at VDD
near the accelerometer internal clock frequency. This is
analogous to the power supply response, except that the
stimulus and the response are at different frequencies. The
ADXL193’s CFSR is 10× better than a typical single-ended
accelerometer system.
SIGNAL DISTORTION
Signals from crashes and other events may contain high
amplitude, high frequency components. These components
contain very little useful information and are reduced by the
2-pole Bessel filter at the output of the accelerometer. However,
if the signal saturates at any point, the accelerometer output
does not look like a filtered version of the acceleration signal.
The signal may saturate anywhere before the filter. For example, if
the resonant frequency of the sensor is low, the displacement per
unit acceleration is high. The sensor may reach the mechanical
limit of travel if the applied acceleration is high enough. This can
be remedied by locating the accelerometer where it does not see
high values of acceleration and by using a higher resonant
frequency sensor, such as the ADXL193.
Also, the electronics may saturate in an overload condition
between the sensor output and the filter input. Ensuring that
internal circuit nodes operate linearly to at least several times
the full-scale acceleration value can minimize electrical
saturation. The ADXL193 circuit is linear to approximately 8×
full scale.
Rev. A | Page 8 of 12
ADXL193
OUTLINE DIMENSIONS
5.00
SQ
1.27
1.78
1.27
4.50
SQ
7
0.50 DIAMETER
1
1.90
2.50
TOP VIEW
1.27
R 0.38
0.20
5
3
0.64 2.50
0.38 DIAMETER
R 0.20
BOTTOM VIEW
Figure 6. 8-Terminal Ceramic Leadless Chip Carrier [LCC]
(E-8)
Dimensions shown in millimeters
ADXL193 ORDERING GUIDE
Model 1
AD22282-A-R2
AD22282-A
AD22283-B-R2
AD22283-B
1
Parts
per Reel
250
3000
250
3000
Measurement
Range
±120 g
±120 g
±250 g
±250 g
Specified
Voltage (V)
5
5
5
5
Temperature
Range
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
−40°C to +125°C
All models are on tape and reel and are Pb-free parts.
Rev. A | Page 9 of 12
Package Description
8-Terminal Ceramic Leadless Chip Carrier
8-Terminal Ceramic Leadless Chip Carrier
8-Terminal Ceramic Leadless Chip Carrier
8-Terminal Ceramic Leadless Chip Carrier
Package
Option
E-8
E-8
E-8
E-8
ADXL193
NOTES
Rev. A | Page 10 of 12
ADXL193
NOTES
Rev. A | Page 11 of 12
ADXL193
NOTES
©2005 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D05366–0–5/05(A)
Rev. A | Page 12 of 12