ADXL202JE_技术文档

Low-Cost ꢀ2 g Dual-Axis Accelerometer

a

with Duty Cycle Output

ADXL202E*

FEATURES

FUNCTIONAL BLOCK DIAGRAM

2-Axis Acceleration Sensor on a Single IC Chip

5 mm ꢃ 5 mm ꢃ 2 mm Ultrasmall Chip Scale Package

2 mg Resolution at 60 Hz

3V TO 5.25V

C

X

V

X

FILT

SELF-TEST

DD

Low-Power < 0.6 mA

Direct Interface to Low-Cost Microcontrollers via

Duty Cycle Output

BW Adjustment with a Single Capacitor

3 V to 5.25 V Single Supply Operation

1000 g Shock Survival

R

32kꢂ

X SENSOR

FILT

X

OUT

C

O

U

N

T

E

R

DEMOD

ANALOG

TO

DUTY

CYCLE

(ADC)

C

DC

OSCILLATOR

ꢁP

ADXL202E

DEMOD

R

32kꢂ

Y

FILT

OUT

APPLICATIONS

Y SENSOR

COM

Y

T2

R

FILT

2-Axis Tilt Sensing with Faster Response than

Electrolytic, Mercury, or Thermal Sensors

Computer Peripherals

C

Y

SET

Information Appliances

Alarms and Motion Detectors

Disk Drives

T2

T1

A(g) = (T1/T2 – 0.5)/12.5%

0g = 50% DUTY CYCLE

Vehicle Security

T2 = R

/125Mꢂ

SET

GENERAL DESCRIPTION

The typical noise floor is 200 ␮g√Hz, allowing signals below

2 mg (at 60 Hz bandwidth) to be resolved.

The ADXL202E is a low-cost, low-power, complete 2-axis acceler-

ometer with a digital output, all on a single monolithic IC. It is an

improved version of the ADXL202AQC/JQC. The ADXL202E

will measure accelerations with a full-scale range of Ϯ2 g. The

ADXL202E can measure both dynamic acceleration (e.g., vibra-

tion) and static acceleration (e.g., gravity).

The bandwidth of the accelerometer is set with capacitors C_Xand

C_Yat the X_FILTand Y_FILTpins. An analog output can be recon-

structed by filtering the duty cycle output.

The ADXL202E is available in 5 mm ϫ 5 mm ϫ 2 mm 8-lead

hermetic LCC package.

The outputs are analog voltage or digital signals whose duty cycles

(ratio of pulsewidth to period) are proportional to acceleration.

The duty cycle outputs can be directly measured by a micro-

processor counter, without an A/D converter or glue logic. The

duty cycle period is adjustable from 0.5 ms to 10 ms via a single

resistor (R_SET).

*Patents Pending

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

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

otherwise under any patent or patent rights of Analog Devices.

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

Tel: 781/329-4700

Fax: 781/326-8703

World Wide Web Site: http://www.analog.com

(T_A= T_MINto T_MAX, T_A= 25ꢄC for J Grade only, V_DD= 5 V, R_SET= 125 kꢂ,

Acceleration = 0 g, unless otherwise noted.)

ADXL202E–SPECIFICATIONS

TPC¹

Graph Min

ADXL202JE

Typ

ADXL202AE

Typ

Parameter

Conditions

Max

Min

Max

Unit

SENSOR INPUT

Measurement Range²

Nonlinearity

Each Axis

2

g

Best Fit Straight Line

X Sensor to Y Sensor

0.2

1

0.01

2

0.2

1

0.01

2

% of FS

Degrees

%

Alignment Error³

Alignment Error

Cross-Axis Sensitivity⁴

X

SENSITIVITY

Each Axis

Duty Cycle per g

Sensitivity X_FILT, Y_FILT

Temperature Drift⁵

T1/T2, V_DD= 5 V

T1/T2, V_DD= 3 V

V_DD= 5 V

V_DD= 3 V

Delta from 25ЊC

X

10.5

9.0

265

140

12.5

11

312

167

0.5

14.5

13.0

360

195

10

12.5

11

312

167

0.5

15

%/g

mV/g

%

8.5

250

140

13.5

375

200

ZERO g BIAS LEVEL

0 g Duty Cycle

0 g Voltage X_FILT, Y_FILT

0 g Duty Cycle vs. Supply

0 g Offset vs. Temperature⁵

Each Axis

T1/T2, V_DD= 5 V

T1/T2, V_DD= 3 V

V_DD= 5 V

X

34

31

2.1

1.2

50

2.5

1.5

1.0

2.0

66

69

2.9

1.8

4.0

30

31

2.0

1.2

50

2.5

1.5

1.0

2.0

70

69

3.0

1.8

4.0

%

V

%/V

mg/ЊC

V_DD= 3 V

Delta from 25ЊC

@ 25ЊC

NOISE PERFORMANCE

Noise Density

X

200

1000

µg√Hz rms

FREQUENCY RESPONSE

3 dB Bandwidth

Sensor Resonant Frequency

At Pins X_FILT, Y_FILT

6

10

6

10

kHz

FILTER

R_FILTTolerance

Minimum Capacitance

32 kΩ Nominal

15

10

15

10

%

pF

At Pins X_FILT, Y_FILT

1000

0.7

1000

0.7

SELF-TEST

Duty Cycle Change

Self-Test “0” to “1”

%

DUTY CYCLE OUTPUT STAGE

F_SET

Output High Voltage

Output Low Voltage

T2 Drift vs. Temperature

Rise/Fall Time

R_SET= 125 kΩ

I = 25 µA

1.3

kHz

V

mV

ppm/ЊC

ns

V_S– 200 mV

200

50

200

50

200

POWER SUPPLY

Operating Voltage Range

Quiescent Supply Current

Turn-On Time

3

5.25

1.0

3.0

5.25

1.0

V

mA

ms

0.6

C_FILTin µF

160 ϫ C_FILT+ 0.3

TEMPERATURE RANGE

Specified Performance AE

Operating Range

–40

+85

ЊC

0

70

NOTES

¹Typical Performance Characteristics.

²Guaranteed by measurement of initial offset and sensitivity.

³Alignment error is specified as the angle between the true and indicated axis of sensitivity (see TPC 15).

⁴Cross-axis sensitivity is the algebraic sum of the alignment and the inherent sensitivity errors.

⁵Defined as the output change from ambient to maximum temperature or ambient to minimum temperature.

Specifications subject to change without notice.

–2–

REV. A

ADXL202E

PIN CONFIGURATION

ABSOLUTE MAXIMUM RATINGS*

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

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

+V_S. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to +6.0 V

Output Short Circuit Duration, (Any Pin to Common)

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Indefinite

Operating Temperature . . . . . . . . . . . . . . . . –55ЊC to +125ЊC

Storage Temperature . . . . . . . . . . . . . . . . . . –65ЊC to +150ЊC

V

DD

8

1

2

3

7

6

5

ST

X

Y

FILT

T2

FILT

OUT

X

COM

4

Y

OUT

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

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

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

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

conditions for extended periods may affect device reliability.

BOTTOM VIEW

PIN FUNCTION DESCRIPTIONS

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.

No.

Mnemonic

Description

1

2

3

4

5

6

7

8

ST

T2

Self-Test

Connect R_SETto Set T2 Period

Common

Y-Channel Duty Cycle Output

X-Channel Duty Cycle Output

Y-Channel Filter Pin

X-Channel Filter Pin

3 V to 5.25 V

Package Characteristics

Package

COM

Y_OUT

X_OUT

Y_FILT

X_FILT

V_DD

Weight

ꢅ_JA

ꢅ_JC

Device

8-Lead LCC

120°C/W

tbd°C/W

<1.0 grams

ORDERING GUIDE

Specified Temperature

No.

of Axes

Package

Description

Package

Option

Model

Voltage

Range

ADXL202JE

ADXL202AE

2

3 V to 5 V

0 to 70ЊC

–40ЊC to +85ЊC

8-Lead LCC

E-8

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 ADXL202E 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.

WARNING!

ESD SENSITIVE DEVICE

–3–

REV. A

ADXL202E–Typical Performance Characteristics*

V_DD= 3 V

V_DD= 5 V

16

14

12

10

8

18

16

14

12

10

8

6

4

2

0

1.28 1.32 1.36 1.41 1.45 1.49 1.53 1.58 1.62 1.66

VOLTS

2.05 2.14 2.23 2.31 2.40 2.48 2.57 2.65 2.74 2.82

VOLTS

TPC 1. X-Axis Zero g Bias Distribution at X_FILT, V_DD= 3 V

TPC 4. X-Axis Zero g Bias Distribution at X_FILT, V_DD= 5 V

25

20

15

10

5

16

14

12

10

8

6

4

2

0

2.05 2.14 2.23 2.31 2.40 2.48 2.57 2.65 2.74 2.82

1.25

1.31

1.36

1.42

1.48

1.53

1.59

1.65

VOLTS

TPC 2. Y-Axis Zero g Bias Distribution at Y_FILT, V_DD= 3 V

TPC 5. Y-Axis Zero g Bias Distribution at Y_FILT, V_DD= 5 V

25

20

15

10

5

25

20

15

10

5

0

0.148 0.155 0.162 0.169 0.176 0.182 0.189

0.26

0.28

0.29

0.30

0.32

0.33

0.34

0.142

V/g

TPC 6. X-Axis Sensitivity Distribution at X_FILT, V_DD= 5 V

TPC 3. X-Axis Sensitivity Distribution at X_FILT, V_DD= 3 V

*Data taken from 4500 parts over 3 lots minimum.

–4–

REV. A

ADXL202E

V_DD= 3 V

V_DD= 5 V

25

20

15

10

5

25

20

15

10

5

0

0.26

0.27

0.29

0.30

0.31

V/g

0.33

0.34

0.35

0.142 0.148 0.155 0.162 0.169 0.176 0.182 0.189

V/g

TPC 10. Y-Axis Sensitivity Distribution at Y_FILT, V_DD= 5 V

TPC 7. Y-Axis Sensitivity Distribution at Y_FILT, V_DD= 3 V

25

20

15

10

5

30

25

20

15

10

5

0

10.3

10.8

11.3

11.8

12.3

12.8

13.3

13.8

9.50

9.90

10.4

10.8

11.3

11.8

12.2

12.7

PERCENT DUTY CYCLE/g

TPC 8. X-Axis Sensitivity at X_OUT, V_DD= 3 V

TPC 11. X-Axis Sensitivity at X_OUT, V_DD= 5 V

20

18

16

14

12

10

8

25

20

15

10

5

6

4

2

0

9.50

9.90

10.4

10.8

11.3

11.8

12.2

12.7

10.6

11.0

11.6

12.0

12.6

13.0

13.6

14.0

PERCENT DUTY CYCLE/g

TPC 12. Y-Axis Sensitivity at Y_OUT, V_DD= 5 V

TPC 9. Y-Axis Sensitivity at Y_OUT, V_DD= 3 V

–5–

REV. A

ADXL202E

35

30

25

20

15

10

5

25

20

15

10

5

0

230 250 270 290 310 330 350 370 390 410

150

170

190

210

230

250

270

290

310

NOISE DENSITY – ꢁg Hz rms

TPC 13. Noise Density Distribution, V_DD= 3 V

TPC 16. Noise Density Distribution, V_DD= 5 V

0.7

0.6

40

35

30

25

20

15

10

5

V

= 5 VDC

S

0.5

0.4

0.3

0.2

0.1

0

= 3.5 VDC

S

0

–40

–20

0

20

40

60

80

100

–3

–2

–1

0

1

2

3

TEMPERATURE – ꢄC

PERCENT – %

TPC 14. Typical Supply Current vs. Temperature

TPC 17. Cross-Axis Sensitivity Distribution

20

18

16

14

12

10

8

V

DD

3

2

1

0

C

= 0.01ꢁF

X

FILT

OUT

6

4

2

0

0.4

0.8

1.2

1.4

TIME – ms

DEGREES OF MISALIGNMENT

TPC 15. Rotational Die Alignment

TPC 18. Typical Turn-On Time

–6–

REV. A

ADXL202E

25

20

15

10

5

40

35

30

25

20

15

10

5

0

–0.73

–0.12

0.50

1.11

1.73

2.35

–2.08

–1.44

–0.80

–0.17

0.47

1.11

mg/ꢄC

TPC 19. X-Axis Zero g Drift Due to Temperature

TPC 22. Y-Axis Zero g Drift Due to Temperature

Distribution, –40°C to +85°C

20

18

16

14

12

10

8

40

30

20

10

0

6

4

2

0

–0.046 –0.038 –0.029 –0.021 –0.013 –0.004

PERCENT/

0.004

–0.046 –0.038 –0.029 –0.021 –0.013 –0.004

PERCENT/

0.004

ꢄ

C

ꢄ

C

TPC 20. X-Axis Sensitivity Drift at X_FILTDue to

TPC 23. Y-Axis Sensitivity Drift at Y_FILTDue to

Temperature Distribution, –40°C to +85°C

400

300

200

100

0

400

300

200

100

0

–100

–200

–300

–400

–100

–200

–300

–50

–25

0

25

50

75

100

–50

–25

0

25

50

75

100

TEMPERATURE – ꢄC

TPC 21. Typical X-Axis Zero g vs. Output for 16 Parts

TPC 24. Typical Y-Axis Zero g vs. Output for 16 Parts

–7–

REV. A

ADXL202E

1.06

1.04

1.02

1.00

0.98

0.96

0.94

–45

–30

–15

0

15

30

45

60

75

90

TEMPERATURE – ꢄC

TPC 25. Normalized DCM Period (T2) vs. Temperature

DEFINITIONS

nominally 50% duty cycle. The acceleration signal can be deter-

T1

T2

Length of the “on” portion of the cycle.

Length of the total cycle.

mined by measuring the length of the T1 and T2 pulses with

a counter/timer or with a polling loop using a low cost micro-

controller.

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

cycle (T2). Defined as T1/T2 for the ADXL202E/

ADXL210.

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

the ADXL202E/ADXL210.

An analog output voltage can be obtained either by buffering the

signal from the X_FILTand Y_FILTpin, or by passing the duty cycle

signal through an RC filter to reconstruct the dc value.

The ADXL202E will operate with supply voltages as low as 3.0 V

or as high as 5.25 V.

THEORY OF OPERATION

T2

The ADXL202E is a complete, dual-axis acceleration measurement

system on a single monolithic IC. It contains a polysilicon surface-

micromachined sensor and signal conditioning circuitry to imple-

ment an open loop acceleration measurement 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 microprocessor. The ADXL202E is

capable of measuring both positive and negative accelerations to

at least 2 g. The accelerometer can measure static acceleration

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

T1

A(g) = (T1/T2 – 0.5)/12.5%

0g = 50% DUTY CYCLE

T2(s) = R

SET

(ꢂ)/125Mꢂ

Figure 1. Typical Output Duty Cycle

APPLICATIONS

POWER SUPPLY DECOUPLING

For most applications a single 0.1 µF capacitor, C_DC, will

adequately 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, digital noise on the supply may cause interference on

the ADXL202E output. This may be observed as a slowly

undulating fluctuation of voltage at X_FILTand Y_FILT. If additional

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

beads, may be inserted in the supply line of the ADXL202E.

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 measured

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 accelera-

tion will deflect the beam and unbalance the differential capacitor,

resulting in an output square wave whose amplitude is propor-

tional to acceleration. Phase sensitive demodulation techniques are

then used to rectify the signal and determine the direction of

the acceleration.

FERRITE BEAD

100ꢂ

V

X

OUT

DD

C

DC

ADXL202E

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 band-

width of the device by adding a capacitor. This filtering improves

measurement resolution and helps prevent aliasing.

COM

ST

Y

X

Y

OUT

FILT

X

FILT

T2

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 between

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

R

SET

Y

FILT

Figure 2.

–8–

REV. A

ADXL202E

DESIGN PROCEDURE FOR THE ADXL202E

Setting the Bandwidth Using C_Xand C_Y

The ADXL202E has provisions for bandlimiting the X_FILTand

_FILTpins. Capacitors must be added at these pins to implement

low-pass filtering for antialiasing and noise reduction. The equa-

tion for the 3 dB bandwidth is:

The design procedure for using the ADXL202E with a duty cycle

output involves selecting a duty cycle period and a filter capacitor.

A proper design will take into account the application requirements

for bandwidth, signal resolution and acquisition time, as discussed

in the following sections.

Y

1

F_{–3 dB}

=

Decoupling Capacitor C_DC

A 0.1 µF capacitor is recommended from V_DDto COM for power

supply decoupling.

2 π (32 kΩ)× C(x, y)

(

)

5µF

F_–3dB

=

ST

or, more simply,

C_{(X,Y )}

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

V_DD, an electrostatic force is exerted on the beam of the accelerom-

eter. 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.

The tolerance of the internal resistor (R_FILT), can vary typically as

much as 15% 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_Xand C_Y

Capacitor

Duty Cycle Decoding

The ADXL202E’s digital output is a duty cycle modulator.

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

output of the ADXL202E is:

Bandwidth

Value

10 Hz

50 Hz

100 Hz

200 Hz

500 Hz

5 kHz

0.47 µF

0.10 µF

0.05 µF

0.027 µF

0.01 µF

0.001 µF

0 g = 50% Duty Cycle

Scale factor is 12.5% 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 measure it on

one channel of the ADXL202E. Decoding algorithms for various

microcontrollers have been developed. Consult the appropriate

Application Note.

Setting the DCM Period with R_SET

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

resistor from R_SETto ground. The equation for the period is:

R

_SET(Ω)

T2 =

125 MΩ

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

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

cycle periods between 0.5 ms and 10 ms.

3V TO 5.25V

C

X

V

X

FILT

SELF-TEST

X

DD

Table II. Resistor Values to Set T2

R

32kꢂ

X SENSOR

FILT

OUT

C

O

U

N

T

E

R

DEMOD

ANALOG

T2

R_SET

TO

C

DC

OSCILLATOR

ꢁP

DUTY

CYCLE

(ADC)

ADXL202E

1 ms

2 ms

5 ms

10 ms

125 kΩ

250 kΩ

625 kΩ

1.25 MΩ

DEMOD

R

Y

FILT

OUT

Y SENSOR

COM

32kꢂ

Y

T2

R

FILT

C

Y

SET

Note that the R_SETshould always be included, even if only an

analog output is desired. Use an R_SETvalue between 500 kΩ

and 2 MΩ when taking the output from X_FILTor Y_FILT. The R_SET

resistor should be place close to the T2 Pin to minimize parasitic

capacitance at this node.

T2

T1

A(g) = (T1/T2 – 0.5)/12.5%

0g = 50% DUTY CYCLE

Selecting the Right Accelerometer

T2 = R

/125Mꢂ

SET

For most tilt sensing applications the ADXL202E 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.

Figure 3. Block Diagram

–9–

REV. A

ADXL202E

MICROCOMPUTER INTERFACES

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

the ADXL202E is determined by the following equation:

The ADXL202E is specifically designed to work with low-cost

microcontrollers. Specific code sets, reference designs, and applica-

tion 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.

Noise rms = 200 µg/ Hz × BW ×1.6

(

)

(

)

(

)

At 100 Hz the noise will be:

The designer should have some idea of the required performance

of the system in terms of:







Noise rms = 200 µg/ Hz

×

100 × 1.6 = 2.53 mg

(

)

(

)

(

)



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

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.

on each axis.

These requirements will help to determine the accelerometer band-

width, the speed of the microcontroller clock and the length of

the T2 period.

Table III. Estimation of Peak-to-Peak Noise

% of Time that Noise

When selecting a microcontroller it is helpful to have a counter

timer port available. The microcontroller should have provisions

for software calibration. While the ADXL202E is a highly accurate

accelerometer, it has a wide tolerance for initial offset. The easi-

est way to null this offset is with a calibration factor saved on the

microcontroller or by a user calibration for zero g. In the case

where the offset is calibrated during manufacture, there are several

options, including external EEPROM and microcontrollers with

“one-time programmable” features.

Nominal Peak-to-Peak Will Exceed Nominal

Value

Peak-to-Peak Value

2.0 × rms

4.0 × rms

6.0 × rms

8.0 × rms

32%

4.6%

0.27%

0.006%

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

uncertainty in a single measurement.

Table IV gives typical noise output of the ADXL202E for various

DESIGN TRADE-OFFS FOR SELECTING FILTER

CHARACTERISTICS: THE NOISE/BW TRADE-OFF

The accelerometer bandwidth selected will determine the measure-

ment 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 analog filter

bandwidth at X_FILTand Y_FILTand on the speed of the micro-

controller counter.

C

_Xand C_Yvalues.

Table IV. Filter Capacitor Selection, C_Xand C_Y

Peak-to-Peak Noise

Estimate 95%

rms Noise Probability (rms ꢃ 4)

Bandwidth C_X, C_Y

The analog output of the ADXL202E has a typical bandwidth

of 5 kHz, while the duty cycle modulators’ bandwidth is 500 Hz.

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 dynamic error generated at the DCM.

10 Hz

50 Hz

100 Hz

200 Hz

500 Hz

0.47 µF

0.10 µF

0.05 µF

0.8 mg

1.8 mg

2.5 mg

3.2 mg

7.2 mg

10.1 mg

14.3 mg

22.6 mg

0.027 µF 3.6 mg

0.01 µF 5.7 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 analog bandwidth may be further decreased to reduce noise

and improve resolution. The ADXL202E noise has the character-

istics 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 bandwidth 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.

The ADXL202E’s duty cycle converter has a resolution of

approximately 14 bits; better resolution than the accelerometer

itself. The actual resolution of the acceleration signal is, how-

ever, 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’ counter. It is probable that the

accelerometer’s noise floor may set the lower limit on the resolu-

tion, as discussed in the previous section.

–10–

REV. A

ADXL202E

Table V. Trade-Offs Between Microcontroller Counter Rate,

T2 Period, and Resolution of Duty Cycle Modulator

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 calculated as

follows:

Counter-

ADXL202E Clock

Counts

per T2 Counts Resolution

Cycle

R_SETSample

T2 (ms) (kꢂ) Rate

Rate

(MHz)

per g

(mg)

1.0

124 1000

625 200

1250 100

2.0

1.0

0.5

2.0

1.0

0.5

2.0

1.0

0.5

2000

1000

500

10000

5000

2500

20000

10000

5000

250

125

4.0

8.0

16.0

0.8

1.6

3.2

0.4

0.8

1.6

1.0

Pitch = ASIN (Ax/1 g)

Roll = ASIN (Ay/1 g)

62.5

1250

625

312.5

2500

1250

625

5.0

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.

10.0

MEASURING 360ꢄ OF TILT

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

by using two accelerometers oriented perpendicular to one another

(see Figure 5). When one sensor is reading a maximum change

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

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.

X

USING THE ADXL202E AS A DUAL-AXIS TILT SENSOR

One of the most popular applications of the ADXL202E is tilt

measurement. An accelerometer uses the force of gravity as an

input vector to determine orientation of an object in space.

360ꢄ OF TILT

1g

Y

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 high-

est. 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 accelerometer is perpen-

dicular 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.

Figure 5. Using a Two-Axis Accelerometer to Measure

360° of Tilt

USING THE ANALOG OUTPUT

The ADXL202E 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 fre-

quency is connected to the duty cycle output. The filter resistor

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 disadvantage is that

X

+90

ꢄ

0

ꢄ

1g

Y

–90

ꢄ

BOTTOM VIEW

X Output

ꢆ per

Y Output (g)

the frequency response will be lower than when using the X_FILT

Y_FILToutput.

,

X Axis

ꢆ per

Orientation

to Horizon (

Degree of

Tilt (mg)

Degree of

Tilt (mg)

ꢄ)

X Output (g)

Y Output (g)

X_FILT, Y_FILTOutput

–90

–75

–60

–45

–30

–15

0

15

30

45

60

–1.000

–0.966

–0.866

–0.707

–0.500

–0.259

0.000

0.259

0.500

0.707

0.866

–0.2

4.4

8.6

0.000

0.259

0.500

0.707

0.866

0.966

1.000

0.966

0.866

0.707

0.500

0.259

0.000

17.5

16.9

15.2

12.4

8.9

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

X_FILTand Y_FILTpin. 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 voltage.

The offset and sensitivity are nominally:

12.2

15.0

16.8

17.5

16.9

15.2

12.4

8.9

4.7

0.2

–4.4

–8.6

–12.2

–15.0

–16.8

–17.5

75

90

0.966

1.000

4.7

0.2

Figure 4. How the X and Y Axes Respond to Changes

in Tilt

0 g Offset = V_DD/2

ADXL202E Sensitivity = (60 mV × V_S)/g

–11–

REV. A

ADXL202E

USING THE ADXL202E IN VERY LOW POWER

APPLICATIONS

An application note outlining low power strategies for the

ADXL202E is available. Some key points are presented here.

It is possible to reduce the ADXL202E’s average current from

0.6 mA to less than 20 µA by using the following techniques:

CALIBRATING THE ADXL202E/ADXL210

The initial value of the offset and scale factor for the ADXL202E

will require calibration for applications such as tilt measurement.

The ADXL202E architecture has been designed so that these

calibrations take place in the software of the microcontroller used

to decode the duty cycle signal. Calibration factors can be stored in

EEPROM or determined at turn-on and saved in dynamic

memory.

1. Power Cycle the accelerometer.

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

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 par-

allel to the earth’s surface and then reading the output.

Power Cycling with an External A/D

Depending on the value of the X_FILTcapacitor, the ADXL202E

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 ADXL202E 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 average 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.

A more accurate calibration method is to make 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:

The A/D should read the analog output of the ADXL202E at

the X_FILTand Y_FILTpins. 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.

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

Power Cycling When Using the Digital Output

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

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

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 ADXL202E 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 acquire a reading as quickly as pos-

sible and then shut down the ADXL202E and the microcontroller

until the next sample is needed.

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.

In either of the above approaches, the ADXL202E can be turned

on and off directly using a digital port pin on the microcontroller to

power the accelerometer without additional components.

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

8-Terminal Ceramic Leadless Chip Carrier

(E-8)

0.050 (1.27)

7

0.070 (1.78)

0.197 (5.00)

SQ

ꢇ

0.015 (0.38)

1

0.075

0.099

(2.50)

(1.91)

0.177

(4.50)

SQ

0.050 (1.27)

TOP VIEW

0.050 (1.27)

0.025

0.099

(2.50)

(0.64)

3

5

R0.008

(0.20)

ꢇ

0.015 (0.38)

R0.028 (0.70)

0.008

(0.20)

BOTTOM VIEW

CONTROLLING DIMENSIONS ARE IN MILLIMETERS

–12–

REV. A


型号：	ADXL202JE
厂家：	ADI
描述：	Low-Cost +-2 g Dual-Axis Accelerometer with Duty Cycle Output 低成本+ -2克双轴加速度计与占空比输出
文件：	总12页 (文件大小：153K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ADXL202JE [ADI]

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