ADXL210JQC-1 - N/A - Datasheet.Directory

REV. B

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

which may result from its use. No license is granted by implication or

otherwise under any patent or patent rights of Analog Devices.

Low Cost ⴞ2

ⴞ10

Dual Axis

iMEMS

Accelerometers

with Digital Output

ADXL202/ADXL210

FEATURES

2-Axis Acceleration Sensor on a Single IC Chip

Measures Static Acceleration as Well as Dynamic

Acceleration

Duty Cycle Output with User Adjustable Period

Low Power <0.6 mA

Faster Response than Electrolytic, Mercury or Thermal

Tilt Sensors

Bandwidth Adjustment with a Single Capacitor Per Axis

5 m

Resolution at 60 Hz Bandwidth

+3 V to +5.25 V Single Supply Operation

1000

Shock Survival

APPLICATIONS

2-Axis Tilt Sensing

Computer Peripherals

Inertial Navigation

Seismic Monitoring

Vehicle Security Systems

Battery Powered Motion Sensing

2 =

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781/329-4700 World Wide Web Site: http://www.analog.com

Fax: 781/326-8703 © Analog Devices, Inc., 1999

FUNCTIONAL BLOCK DIAGRAM

DEMOD

RFILT

32kV

RFILT

32kV

OSCILLATOR

X SENSOR

Y SENSOR

ADXL202/

ADXL210

X OUT

Y OUT

SELF TEST

XFILT

VDD

+3.0V TO +5.25V

CDC

COM YFILT T2

CYRSET

) = (T1/T2 – 0.5)/12.5%

= 50% DUTY CYCLE

T2 = RSET/125MV

DEMOD

DUTY

CYCLE

MODULATOR

(DCM)

GENERAL DESCRIPTION

The ADXL202/ADXL210 are low cost, low power, complete

2-axis accelerometers with a measurement range of either

±2 g/±10 g. The ADXL202/ADXL210 can measure both dy-

namic acceleration (e.g., vibration) and static acceleration (e.g.,

gravity).

The outputs are digital signals whose duty cycles (ratio of pulse-

width to period) are proportional to the acceleration in each of

the 2 sensitive axes. These outputs may be measured directly

with a microprocessor counter, requiring no A/D converter or

glue logic. The output period is adjustable from 0.5 ms to 10 ms

via a single resistor (R

SET

). If a voltage output is desired, a

voltage output proportional to acceleration is available from the

FILT

and Y

FILT

pins, or may be reconstructed by filtering the

duty cycle outputs.

The bandwidth of the ADXL202/ADXL210 may be set from

0.01 Hz to 5 kHz via capacitors C

and C

. The typical noise

floor is 500 µg/√Hz allowing signals below 5 mg to be resolved

for bandwidths below 60 Hz.

The ADXL202/ADXL210 is available in a hermetic 14-lead

Surface Mount CERPAK, specified over the 0°C to +70°C

commercial or –40°C to +85°C industrial temperature range.

MEM

is a registered trademark of Analog Devices, Inc.

ADXL202/ADXL210–SPECIFICATIONS

ADXL202/JQC/AQC ADXL210/JQC/AQC

Parameter Conditions Min Typ Max Min Typ Max Units

SENSOR INPUT Each Axis

Measurement Range

±1.5 ±2±8±10 g

Nonlinearity Best Fit Straight Line 0.2 0.2 % of FS

Alignment Error

±1±1 Degrees

Alignment Error X Sensor to Y Sensor ±0.01 ±0.01 Degrees

Transverse Sensitivity

±2±2%

SENSITIVITY Each Axis

Duty Cycle per g T1/T2 @ +25°C 10 12.5 15 3.2 4.0 4.8 %/g

Sensitivity, Analog Output At Pins X

FILT

, Y

FILT

312 100 mV/g

Temperature Drift

∆ from +25°C±0.5 ±0.5 % Rdg

ZERO g BIAS LEVEL Each Axis

0 g Duty Cycle T1/T2 25 50 75 42 50 58 %

Initial Offset ±2±2g

0 g Duty Cycle vs. Supply 1.0 4.0 1.0 4.0 %/V

0 g Offset vs. Temperature

∆ from +25°C 2.0 2.0 mg/°C

NOISE PERFORMANCE

Noise Density

@ +25°C 500 1000 500 1000 µg/√Hz

FREQUENCY RESPONSE

3 dB Bandwidth Duty Cycle Output 500 500 Hz

3 dB Bandwidth At Pins X

FILT

, Y

FILT

55kHz

Sensor Resonant Frequency 10 14 kHz

FILTER

FILT

Tolerance 32 kΩ Nominal ±15 ±15 %

Minimum Capacitance At X

FILT

, Y

FILT

1000 1000 pF

SELF TEST

Duty Cycle Change Self-Test “0” to “1” 10 10 %

DUTY CYCLE OUTPUT STAGE

SET

125 MΩ/R

SET

125 MΩ/R

SET

Tolerance R

SET

= 125 kΩ0.7 1.3 0.7 1.3 kHz

Output High Voltage I = 25 µAV

– 200 mV V

– 200 mV mV

Output Low Voltage I = 25 µA 200 200 mV

T2 Drift vs. Temperature 35 35 ppm/°C

Rise/Fall Time 200 200 ns

POWER SUPPLY

Operating Voltage Range 3.0 5.25 2.7 5.25 V

Specified Performance 4.75 5.25 4.75 5.25 V

Quiescent Supply Current 0.6 1.0 0.6 1.0 mA

Turn-On Time

To 99% 160 C

FILT

+ 0.3 160 C

FILT

+ 0.3 ms

TEMPERATURE RANGE

Operating Range JQC 0 +70 0 +70 °C

Specified Performance AQC –40 +85 –40 +85 °C

NOTES

For all combinations of offset and sensitivity variation.

Alignment error is specified as the angle between the true and indicated axis of sensitivity.

Transverse sensitivity is the algebraic sum of the alignment and the inherent sensitivity errors.

Specification refers to the maximum change in parameter from its initial at +25 °C to its worst case value at T

MIN

to T

MAX

Noise density (µg/√Hz) is the average noise at any frequency in the bandwidth of the part.

FILT

in µF. Addition of filter capacitor will increase turn on time. Please see the Application section on power cycling.

All min and max specifications are guaranteed. Typical specifications are not tested or guaranteed.

Specifications subject to change without notice.

= T

MIN

to T

MAX

, T

= +25ⴗC for J Grade only, V

= +5 V,

SET

= 125 k⍀, Acceleration = 0

, unless otherwise noted)

REV. B

–2–

ADXL202/ADXL210

–3–REV. B

PIN FUNCTION DESCRIPTIONS

Pin Name Description

1 NC No Connect

Test Point, Do Not Connect

3 ST Self Test

4 COM Common

5 T2 Connect R

SET

to Set T2 Period

6 NC No Connect

7 COM Common

8 NC No Connect

OUT

Y Axis Duty Cycle Output

10 X

OUT

X Axis Duty Cycle Output

11 Y

FILT

Connect Capacitor for Y Filter

12 X

FILT

Connect Capacitor for X Filter

13 V

+3 V to +5.25 V, Connect to 14

14 V

+3 V to +5.25 V, Connect to 13

PACKAGE CHARACTERISTICS

Package ␪

␪

Device Weight

14-Lead CERPAK 110°C/W 30°C/W 5 Grams

ABSOLUTE MAXIMUM RATINGS*

Acceleration (Any Axis, Unpowered for 0.5 ms) . . . . . . 1000 g

Acceleration (Any Axis, Powered for 0.5 ms) . . . . . . . . . 500 g

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +7.0 V

Output Short Circuit Duration

(Any Pin to Common) . . . . . . . . . . . . . . . . . . . . . . Indefinite

Operating Temperature . . . . . . . . . . . . . . . . . –55°C to +125°C

Storage Temperature . . . . . . . . . . . . . . . . . . . –65°C to +150°C

*Stresses above those listed under Absolute Maximum Ratings may cause perma-

nent damage to the device. This is a stress rating only; the functional operation of

the device at these or any other conditions above those indicated in the operational

sections of this specification is not implied. Exposure to absolute maximum rating

conditions for extended periods may affect device reliability.

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 the ADXL202/ADXL210 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.

Drops onto hard surfaces can cause shocks of greater than 1000 g

and exceed the absolute maximum rating of the device. Care

should be exercised in handling to avoid damage.

PIN CONFIGURATION

TOP VIEW

(Not to Scale)

NC = NO CONNECT

YFILT

XFILT

VDD

VTP

COM

YOUT

XOUT

COM

ADXL202/

ADXL210

Figure 1 shows the response of the ADXL202 to the Earth’s

gravitational field. The output values shown are nominal. They

are presented to show the user what type of response to expect

from each of the output pins due to changes in orientation with

respect to the Earth. The ADXL210 reacts similarly with out-

put changes appropriate to its scale.

TYPICAL OUTPUT AT PIN:

9 = 50% DUTY CYCLE

10 = 62.5% DUTY CYCLE

11 = 2.5V

12 = 2.188V

TYPICAL OUTPUT AT PIN:

9 = 62.5% DUTY CYCLE

10 = 50% DUTY CYCLE

11 = 2.188V

12 = 2.5V

TYPICAL OUTPUT AT PIN:

9 = 37.5% DUTY CYCLE

10 = 50% DUTY CYCLE

11 = 2.812V

12 = 2.5V

TYPICAL OUTPUT AT PIN:

9 = 50% DUTY CYCLE

10 = 37.5% DUTY CYCLE

11 = 2.5V

12 = 2.812V EARTH'S SURFACE

Figure 1. ADXL202/ADXL210 Nominal Response Due to

Gravity

WARNING!

ESD SENSITIVE DEVICE

ORDERING GUIDE

gTemperature Package Package

Model Range Range Description Option

ADXL202JQC ±20°C to +70°C 14-Lead CERPAK QC-14

ADXL202AQC ±2 –40°C to +85°C 14-Lead CERPAK QC-14

ADXL210JQC ±10 0°C to +70°C 14-Lead CERPAK QC-14

ADXL210AQC ±10 –40°C to +85°C 14-Lead CERPAK QC-14

ADXL202/ADXL210

REV. B

–4–

TEMPERATURE – 8C

1.06

0.94

–45 90–30

PERIOD NORMALIZED TO 1 AT 25 8C

–150 1530456075

1.04

1.02

1.00

0.98

0.96

Figure 2. Normalized DCM Period (T2) vs. Temperature

TEMPERATURE – 8C

0.8

–0.2

–0.8

–40 90–30

ZERO

OFFSET SHIFT IN

–20–100 1020304050 607080

0.6

–0.4

–0.6

0.4

0.2

Figure 3. Typical Zero g Offset vs. Temperature

TEMPERATURE – 8C

0.7

–40 100–20

SUPPLY CURRENT – mA

020406080

0.6

0.4

0.3

0.2

0.1

0.5

VS = 5 VDC

VS = 3.5 VDC

Figure 4. Typical Supply Current vs. Temperature

(@ +25ⴗC RSET = 125 k⍀, VDD = +5 V, unless otherwise noted)

TYPICAL CHARACTERISTICS

TEMPERATURE – 8C

–4%

–40 8525

–1%

–2%

–3%

CHANGE IN SENSITIVITY

Figure 5. Typical X Axis Sensitivity Drift Due to

Temperature

0 0.4 0.8 1.2 1.4

FREQUENCY – ms

VOLTS

CFILT = 0.01mF

Figure 6. Typical Turn-On Time

/DUTY CYCLE OUTPUT

0–0.87g

PERCENTAGE OF SAMPLES

–0.64g –0.41g –0.17g 0.06g 0.29g 0.52g 0.75g

Figure 7. Typical Zero g Distribution at +25

ADXL202/ADXL210

–5–REV. B

DUTY CYCLE OUTPUT – % per

11.3 11.5 11.7 11.9 12.2 12.4 12.6 12.8 13.1 13.3 13.5 13.7

PERCENTAGE OF SAMPLES

Figure 8. Typical Sensitivity per g at +25

CX, CY

BANDWIDTH

0.01mF

500Hz 0.47mF

10Hz

0.047mF

100Hz

TOTAL RMS NOISE – m

0.1mF

50Hz

Figure 9. Typical Noise at X

FILT

Output

NUMBER OF AVERAGE SAMPLES

01644

TOTAL RMS NOISE – m

10 CFILT = 0.047mF

BW = 100Hz

CFILT = 0.1mF

BW = 50Hz

CFILT = 0.47mF

BW = 10Hz

CFILT = 0.01mF

BW = 500Hz T2 = 1ms

Figure 10. Typical Noise at Digital Outputs

DEGREES OF MISALIGNMENT

–1.375

0.375

% OF PARTS

–1.125

–0.875

–0.625

–0.375

–0.0125

0.625

0.875

1.125

1.375

0.0125

Figure 11. Rotational Die Alignment

ADXL202/ADXL210

REV. B

–6–

DEFINITIONS

T1 Length of the “on” portion of the cycle.

T2 Length of the total cycle.

Duty Cycle Ratio of the “on” time (T1) of the cycle to the total

cycle (T2). Defined as T1/T2 for the ADXL202/

ADXL210.

Pulsewidth Time period of the “on” pulse. Defined as T1 for

the ADXL202/ADXL210.

THEORY OF OPERATION

The ADXL202/ADXL210 are complete dual axis acceleration

measurement systems on a single monolithic IC. They contain a

polysilicon surface-micromachined sensor and signal condition-

ing circuitry to implement an open loop acceleration measure-

ment architecture. For each axis, an output circuit converts the

analog signal to a duty cycle modulated (DCM) digital signal

that can be decoded with a counter/timer port on a micropro-

cessor. The ADXL202/ADXL210 are capable of measuring

both positive and negative accelerations to a maximum level of

±2 g or ±10 g. The accelerometer measures static acceleration

forces such as gravity, allowing it to be used as a tilt sensor.

The sensor is a surface micromachined polysilicon structure

built on top of the silicon wafer. Polysilicon springs suspend the

structure over the surface of the wafer and provide a resistance

against acceleration forces. Deflection of the structure is mea-

sured using a differential capacitor that consists of independent

fixed plates and central plates attached to the moving mass. The

fixed plates are driven by 180° out of phase square waves. An

acceleration will deflect the beam and unbalance the differential

capacitor, resulting in an output square wave whose amplitude

is proportional to acceleration. Phase sensitive demodulation

techniques are then used to rectify the signal and determine the

direction of the acceleration.

The output of the demodulator drives a duty cycle modulator

(DCM) stage through a 32 kΩ resistor. At this point a pin is

available on each channel to allow the user to set the signal

bandwidth of the device by adding a capacitor. This filtering

improves measurement resolution and helps prevent aliasing.

After being low-pass filtered, the analog signal is converted to a

duty cycle modulated signal by the DCM stage. A single resistor

sets the period for a complete cycle (T2), which can be set be-

tween 0.5 ms and 10 ms (see Figure 12). A 0 g acceleration

produces a nominally 50% duty cycle. The acceleration signal

can be determined by measuring the length of the T1 and T2

pulses with a counter/timer or with a polling loop using a low

cost microcontroller.

An analog output voltage can be obtained either by buffering the

signal from the X

FILT

and Y

FILT

pin, or by passing the duty cycle

signal through an RC filter to reconstruct the dc value.

The ADXL202/ADXL210 will operate with supply voltages as

low as 3.0 V or as high as 5.25 V.

) = (T1/T2 – 0.5)/12.5%

= 50% DUTY CYCLE

T2(s) = RSET(V)/125MV

Figure 12. Typical Output Duty Cycle

APPLICATIONS

POWER SUPPLY DECOUPLING

For most applications a single 0.1 µF capacitor, C

, will ad-

equately decouple the accelerometer from signal and noise on

the power supply. However, in some cases, especially where digital

devices such as microcontrollers share the same power supply, digi-

tal noise on the supply may cause interference on the ADXL202/

ADXL210 output. This is often observed as a slowly undulating

fluctuation of voltage at X

FILT

and Y

FILT

. If additional decou-

pling is needed, a 100 Ω (or smaller) resistor or ferrite beads,

may be inserted in the ADXL202/ADXL210’s supply line.

DESIGN PROCEDURE FOR THE ADXL202/ADXL210

The design procedure for using the ADXL202/ADXL210 with a

duty cycle output involves selecting a duty cycle period and a

filter capacitor. A proper design will take into account the appli-

cation requirements for bandwidth, signal resolution and acqui-

sition time, as discussed in the following sections.

The ADXL202/ADXL210 have two power supply (V

) Pins:

13 and 14. These two pins should be connected directly together.

COM

The ADXL202/ADXL210 have two commons, Pins 4 and 7.

These two pins should be connected directly together and Pin 7

grounded.

This pin is to be left open; make no connections of any kind to

this pin.

Decoupling Capacitor C

A 0.1 µF capacitor is recommended from V

to COM for

power supply decoupling.

The ST pin controls the self-test feature. When this pin is set to

, an electrostatic force is exerted on the beam of the acceler-

ometer. The resulting movement of the beam allows the user to

test if the accelerometer is functional. The typical change in

output will be 10% at the duty cycle outputs (corresponding to

800 mg). This pin may be left open circuit or connected to

common in normal use.

Duty Cycle Decoding

The ADXL202/ADXL210’s digital output is a duty cycle modu-

lator. Acceleration is proportional to the ratio T1/T2. The

nominal output of the ADXL202 is:

0 g = 50% Duty Cycle

Scale factor is 12.5% Duty Cycle Change per g

The nominal output of the ADXL210 is:

0 g = 50% Duty Cycle

Scale factor is 4% Duty Cycle Change per g

These nominal values are affected by the initial tolerance of the

device including zero g offset error and sensitivity error.

T2 does not have to be measured for every measurement cycle.

It need only be updated to account for changes due to tempera-

ture, (a relatively slow process). Since the T2 time period is

shared by both X and Y channels, it is necessary only to mea-

sure it on one channel of the ADXL202/ADXL210. Decoding

algorithms for various microcontrollers have been developed.

Consult the appropriate Application Note.

ADXL202/ADXL210

–7–REV. B

Setting the Bandwidth Using C

and C

The ADXL202/ADXL210 have provisions for bandlimiting the

FILT

and Y

FILT

pins. Capacitors must be added at these pins to

implement low-pass filtering for antialiasing and noise reduc-

tion. The equation for the 3 dB bandwidth is:

–3 dB

(32 kΩ)×C(x,y)

()

or, more simply,

F–3 dB =5µF

C(X,Y)

The tolerance of the internal resistor (R

FILT

), can vary as much

as ±25% of its nominal value of 32 kΩ; so the bandwidth will

vary accordingly. A minimum capacitance of 1000 pF for C

(X, Y)

is required in all cases.

Table I. Filter Capacitor Selection, C

and C

Capacitor

Bandwidth Value

10 Hz 0.47 µF

50 Hz 0.10 µF

100 Hz 0.05 µF

200 Hz 0.027 µF

500 Hz 0.01 µF

5 kHz 0.001 µF

Setting the DCM Period with R

SET

The period of the DCM output is set for both channels by a

single resistor from R

SET

to ground. The equation for the period

is:

T2=RSET (Ω)

125 MΩ

A 125 kΩ resistor will set the duty cycle repetition rate to ap-

proximately 1 kHz, or 1 ms. The device is designed to operate at

duty cycle periods between 0.5 ms and 10 ms.

Table II. Resistor Values to Set T2

T2 R

SET

1 ms 125 kΩ

2 ms 250 kΩ

5 ms 625 kΩ

10 ms 1.25 MΩ

Note that the R

SET

should always be included, even if only an

analog output is desired. Use an R

SET

value between 500 kΩ

and 2 MΩ when taking the output from X

FILT

or Y

FILT

. The

SET

resistor should be place close to the T2 Pin to minimize

parasitic capacitance at this node.

Selecting the Right Accelerometer

For most tilt sensing applications the ADXL202 is the most

appropriate accelerometer. Its higher sensitivity (12.5%/g allows

the user to use a lower speed counter for PWM decoding while

maintaining high resolution. The ADXL210 should be used in

applications where accelerations of greater than ±2 g are expected.

MICROCOMPUTER INTERFACES

The ADXL202/ADXL210 were specifically designed to work

with low cost microcontrollers. Specific code sets, reference

designs, and application notes are available from the factory.

This section will outline a general design procedure and discuss

the various trade-offs that need to be considered.

The designer should have some idea of the required perfor-

mance of the system in terms of:

Resolution: the smallest signal change that needs to be detected.

Bandwidth: the highest frequency that needs to be detected.

Acquisition Time: the time that will be available to acquire the

signal on each axis.

These requirements will help to determine the accelerometer

bandwidth, the speed of the microcontroller clock and the

length of the T2 period.

When selecting a microcontroller it is helpful to have a counter

timer port available. The microcontroller should have provisions

for software calibration. While the ADXL202/ADXL210 are

highly accurate accelerometers, they have a wide tolerance for

DEMOD

RFILT

32kV

RFILT

32kV

OSCILLATOR

X SENSOR

Y SENSOR

X OUT

Y OUT

SELF TEST

XFILT

VDD

+3.0V TO +5.25V

CDC

COM YFILT T2

CYRSET

) = (T1/T2 – 0.5)/12.5%

= 50% DUTY CYCLE

T2 = RSET/125MV

DEMOD

DUTY

CYCLE

MODULATOR

(DCM)

ADXL202/

ADXL210

Figure 13. Block Diagram

ADXL202/ADXL210

REV. B

–8–

Table IV gives typical noise output of the ADXL202/ADXL210

for various C

and C

values.

Table IV. Filter Capacitor Selection, C

and C

Peak-to-Peak Noise

Estimate 95%

Bandwidth C

, C

rms Noise Probability (rms ⴛ 4)

10 Hz 0.47 µF 1.9 mg7.6 mg

50 Hz 0.10 µF 4.3 mg17.2 mg

100 Hz 0.05 µF 6.1 mg24.4 mg

200 Hz 0.027 µF 8.7 mg35.8 mg

500 Hz 0.01 µF 13.7 mg54.8 mg

CHOOSING T2 AND COUNTER FREQUENCY: DESIGN

TRADE-OFFS

The noise level is one determinant of accelerometer resolution.

The second relates to the measurement resolution of the

counter when decoding the duty cycle output.

The ADXL202/ADXL210’s duty cycle converter has a resolu-

tion of approximately 14 bits; better resolution than the acceler-

ometer itself. The actual resolution of the acceleration signal is,

however, limited by the time resolution of the counting devices

used to decode the duty cycle. The faster the counter clock, the

higher the resolution of the duty cycle and the shorter the T2

period can be for a given resolution. The following table shows

some of the trade-offs. It is important to note that this is the

resolution due to the microprocessors’s counter. It is probable

that the accelerometer’s noise floor may set the lower limit on

the resolution, as discussed in the previous section.

Table V. Trade-Offs Between Microcontroller Counter Rate,

T2 Period and Resolution of Duty Cycle Modulator

ADXL202/ Counter-

ADXL210 Clock Counts

SET

Sample Rate per T2 Counts Resolution

T2 (ms) (k⍀) Rate (MHz) Cycle per g(mg)

1.0 124 1000 2.0 2000 250 4.0

1.0 124 1000 1.0 1000 125 8.0

1.0 124 1000 0.5 500 62.5 16.0

5.0 625 200 2.0 10000 1250 0.8

5.0 625 200 1.0 5000 625 1.6

5.0 625 200 0.5 2500 312.5 3.2

10.0 1250 100 2.0 20000 2500 0.4

10.0 1250 100 1.0 10000 1250 0.8

10.0 1250 100 0.5 5000 625 1.6

initial offset. The easiest way to null this offset is with a calibra-

tion factor saved on the microcontroller or by a user calibration

for zero g. In the case where the offset is calibrated during manu-

facture, there are several options, including external EEPROM

and microcontrollers with “one-time programmable” features.

DESIGN TRADE-OFFS FOR SELECTING FILTER

CHARACTERISTICS: THE NOISE/BW TRADE-OFF

The accelerometer bandwidth selected will determine the mea-

surement resolution (smallest detectable acceleration). Filtering

can be used to lower the noise floor and improve the resolution

of the accelerometer. Resolution is dependent on both the ana-

log filter bandwidth at X

FILT

and Y

FILT

and on the speed of the

microcontroller counter.

The analog output of the ADXL202/ADXL210 has a typical

bandwidth of 5 kHz, much higher than the duty cycle stage is

capable of converting. The user must filter the signal at this

point to limit aliasing errors. To minimize DCM errors the

analog bandwidth should be less than 1/10 the DCM frequency.

Analog bandwidth may be increased to up to 1/2 the DCM

frequency in many applications. This will result in greater dy-

namic error generated at the DCM.

The analog bandwidth may be further decreased to reduce noise

and improve resolution. The ADXL202/ADXL210 noise has

the characteristics of white Gaussian noise that contributes

equally at all frequencies and is described in terms of µg per root

Hz; i.e., the noise is proportional to the square root of the band-

width of the accelerometer. It is recommended that the user limit

bandwidth to the lowest frequency needed by the application, to

maximize the resolution and dynamic range of the accelerometer.

With the single pole roll-off characteristic, the typical noise of

the ADXL202/ADXL210 is determined by the following equation:

Noise rms

()

=500 µg/Hz





×BW ×1. 5







At 100 Hz the noise will be:

Noise rms

()

=500 µg/Hz





×100 ×(1. 5 )





=6.12 mg

Often the peak value of the noise is desired. Peak-to-peak noise

can only be estimated by statistical methods. Table III is useful

for estimating the probabilities of exceeding various peak values,

given the rms value.

Table III. Estimation of Peak-to-Peak Noise

% of Time that Noise

Nominal Peak-to-Peak Will Exceed Nominal

Value Peak-to-Peak Value

2.0 × rms 32%

4.0 × rms 4.6%

6.0 × rms 0.27%

8.0 × rms 0.006%

The peak-to-peak noise value will give the best estimate of the

uncertainty in a single measurement.

ADXL202/ADXL210

–9–REV. B

A DUAL AXIS TILT SENSOR: CONVERTING

ACCELERATION TO TILT

When the accelerometer is oriented so both its X and Y axes are

parallel to the earth’s surface it can be used as a two axis tilt

sensor with a roll and a pitch axis. Once the output signal from

the accelerometer has been converted to an acceleration that

varies between –1 g and +1 g, the output tilt in degrees is calcu-

lated as follows:

Pitch = ASIN (Ax/1 g)

Roll = ASIN (Ay/1 g)

Be sure to account for overranges. It is possible for the acceler-

ometers to output a signal greater than ±1 g due to vibration,

shock or other accelerations.

MEASURING 360ⴗ OF TILT

It is possible to measure a full 360° of orientation through grav-

ity by using two accelerometers oriented perpendicular to one

another (see Figure 15). When one sensor is reading a maxi-

mum change in output per degree, the other is at its minimum.

3608 OF TILT 1

Figure 15. Using a Two-Axis Accelerometer to Measure

360

of Tilt

STRATEGIES FOR USING THE DUTY CYCLE OUTPUT

WITH MICROCONTROLLERS

Application notes outlining various strategies for using the duty

cycle output with low cost microcontrollers are available from

the factory.

USING THE ADXL202/ADXL210 AS A DUAL AXIS TILT

SENSOR

One of the most popular applications of the ADXL202/ADXL210

is tilt measurement. An accelerometer uses the force of gravity

as an input vector to determine orientation of an object in space.

An accelerometer is most sensitive to tilt when its sensitive axis

is perpendicular to the force of gravity, i.e., parallel to the

earth’s surface. At this orientation its sensitivity to changes in

tilt is highest. When the accelerometer is oriented on axis to

gravity, i.e., near its +1 g or –1 g reading, the change in output

acceleration per degree of tilt is negligible. When the accelerom-

eter is perpendicular to gravity, its output will change nearly

17.5 mg per degree of tilt, but at 45° degrees it is changing only

at 12.2 mg per degree and resolution declines. The following

table illustrates the changes in the X and Y axes as the device is

tilted ±90° through gravity.

+908

–908

X OUTPUT Y OUTPUT (

)

X AXIS ⌬ PER ⌬ PER

ORIENTATION DEGREE OF DEGREE OF

TO HORIZON (ⴗ) X OUTPUT (

) TILT (m

) Y OUTPUT (

) TILT (m

)

–90 –1.000 –0.2 0.000 17.5

–75 –0.966 4.4 0.259 16.9

–60 –0.866 8.6 0.500 15.2

–45 –0.707 12.2 0.707 12.4

–30 –0.500 15.0 0.866 8.9

–15 –0.259 16.8 0.966 4.7

–0 0.000 17.5 1.000 0.2

–15 0.259 16.9 0.966 –4.4

–30 0.500 15.2 0.866 –8.6

–45 0.707 12.4 0.707 –12.2

–60 0.866 8.9 0.500 –15.0

–75 0.966 4.7 0.259 –16.8

–90 1.000 0.2 0.000 –17.5

Figure 14. How the X and Y Axes Respond to Changes in

Tilt

ADXL202/ADXL210

REV. B

–10–

USING THE ANALOG OUTPUT

The ADXL202/ADXL210 was specifically designed for use with

its digital outputs, but has provisions to provide analog outputs

as well.

Duty Cycle Filtering

An analog output can be reconstructed by filtering the duty

cycle output. This technique requires only passive components.

The duty cycle period (T2) should be set to 1 ms. An RC filter

with a 3 dB point at least a factor of 10 less than the duty cycle

frequency is connected to the duty cycle output. The filter resis-

tor should be no less than 100 kΩ to prevent loading of the

output stage. The analog output signal will be ratiometric to the

supply voltage. The advantage of this method is an output scale

factor of approximately double the analog output. Its disadvan-

tage is that the frequency response will be lower than when

using the X

FILT

, Y

FILT

output.

FILT

, Y

FILT

Output

The second method is to use the analog output present at the

FILT

and Y

FILT

pin. Unfortunately, these pins have a 32 kΩ

output impedance and are not designed to drive a load directly.

An op amp follower may be required to buffer this pin. The

advantage of this method is that the full 5 kHz bandwidth of the

accelerometer is available to the user. A capacitor still must be

added at this point for filtering. The duty cycle converter should

be kept running by using R

SET

<10 MΩ. Note that the acceler-

ometer offset and sensitivity are ratiometric to the supply volt-

age. The offset and sensitivity are nominally:

0 g Offset = V

/2 2.5 V at +5 V

ADXL202 Sensitivity = (60 mV × V

)/g300 mV/g at +5 V, V

ADXL210 Sensitivity = (20 mV × V

)/g100 mV/g at +5 V, V

USING THE ADXL202/ADXL210 IN VERY LOW POWER

APPLICATIONS

An application note outlining low power strategies for the

ADXL202/ADXL210 is available. Some key points are pre-

sented here. It is possible to reduce the ADXL202/ADXL210’s

average current from 0.6 mA to less than 20 µA by using the

following techniques:

1. Power Cycle the accelerometer.

2. Run the accelerometer at a Lower Voltage, (Down to 3 V).

Power Cycling with an External A/D

Depending on the value of the X

FILT

capacitor, the ADXL202/

ADXL210 is capable of turning on and giving a good reading in

1.6 ms. Most microcontroller based A/Ds can acquire a reading

in another 25 µs. Thus it is possible to turn on the ADXL202/

ADXL210 and take a reading in <2 ms. If we assume that a

20 Hz sample rate is sufficient, the total current required to

take 20 samples is 2 ms × 20 samples/s × 0.6 mA = 24 µA aver-

age current. Running the part at 3 V will reduce the supply

current from 0.6 mA to 0.4 mA, bringing the average current

down to 16 µA.

The A/D should read the analog output of the ADXL202/

ADXL210 at the X

FILT

and Y

FILT

pins. A buffer amplifier is

recommended, and may be required in any case to amplify the

analog output to give enough resolution with an 8-bit to 10-bit

converter.

Power Cycling When Using the Digital Output

An alternative is to run the microcontroller at a higher clock

rate and put it into shutdown between readings, allowing the

use of the digital output. In this approach the ADXL202/

ADXL210 should be set at its fastest sample rate (T2 = 0.5 ms),

with a 500 Hz filter at X

FILT

and Y

FILT

. The concept is to ac-

quire a reading as quickly as possible and then shut down the

ADXL202/ADXL210 and the microcontroller until the next

sample is needed.

In either of the above approaches, the ADXL202/ADXL210

can be turned on and off directly using a digital port pin on the

microcontroller to power the accelerometer without additional

components. The port should be used to switch the common

pin of the accelerometer so the port pin is “pulling down.”

CALIBRATING THE ADXL202/ADXL210

The initial value of the offset and scale factor for the ADXL202/

ADXL210 will require calibration for applications such as tilt

measurement. The ADXL202/ADXL210 architecture has been

designed so that these calibrations take place in the software of

the microcontroller used to decode the duty cycle signal. Cali-

bration factors can be stored in EEPROM or determined at

turn-on and saved in dynamic memory.

For low g applications, the force of gravity is the most stable,

accurate and convenient acceleration reference available. A

reading of the 0 g point can be determined by orientating the

device parallel to the earth’s surface and then reading the output.

A more accurate calibration method is to make a measurements

at +1 g and –1 g. The sensitivity can be determined by the two

measurements.

To calibrate, the accelerometer’s measurement axis is pointed

directly at the earth. The 1 g reading is saved and the sensor is

turned 180° to measure –1 g. Using the two readings, the sensi-

tivity is:

Let A = Accelerometer output with axis oriented to +1 g

Let B = Accelerometer output with axis oriented to –1 g then:

Sensitivity = [A – B]/2 g

For example, if the +1 g reading (A) is 55% duty cycle and the

–1 g reading (B) is 32% duty cycle, then:

Sensitivity = [55% – 32%]/2 g = 11.5%/g

These equations apply whether the output is analog, or duty

cycle.

Application notes outlining algorithms for calculating accelera-

tion from duty cycle and automated calibration routines are

available from the factory.

ADXL202/ADXL210

–11–REV. B

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

14-Lead CERPAK

(QC-14)

0.291 (7.391)

0.285 (7.239)

0.390 (9.906)

MAX

PIN 1

0.419 (10.643)

0.394 (10.008)

14 8

0.300 (7.62)

0.345 (8.763)

0.290 (7.366)

0.0125 (0.318)

0.009 (0.229) 0.050 (1.270)

0.016 (0.406)

8°

0°

SEATING

PLANE

0.020 (0.508)

0.004 (0.102)

0.020 (0.508)

0.013 (0.330)

0.050

(1.27)

BSC

0.195 (4.953)

0.115 (2.921)

0.215 (5.461)

0.119 (3.023)

C3037b–2–4/99

PRINTED IN U.S.A.