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Table of Contents
Best Engineering practices when using ADXL accelerometers
Introduction
This document intention is to provide some tips and basic considerations when using ADI ADXL accelerometers. We thank you for choosing ADI and want to let you know that our main focus is to offer High Performance Inertial Sensors for the most demanding applications.
The first and most important advise we would like to offer when using our ADXL portfolio is to carefully read the product datasheet, this can save you precious time.
Terminology
Full-Scale Range (FSR)
The FSR is the guaranteed dynamic range at the output of the signal chain. FSR is specified as a minimum value and is guaranteed across all conditions. Acceleration measurement may be possible beyond this minimum value. However, performance characteristics are not guaranteed.
Nonlinearity
Device nonlinearity is the maximum deviation of any sensor data point from the least squares linear fit of the acceleration data set at an equivalent input acceleration level. The acceleration data set can encompass any range of applied acceleration, up to the complete FSR. Nonlinearity is defined mathematically as
where: ACCMEAS is the measured acceleration at a defined gn. ACCFIT is the predicted acceleration at a defined gn. gn is the input acceleration level.
Cross Axis Sensitivity
Cross axis sensitivity is the measured output of the device in response to input stimuli orthogonal to the intended sense axis. It is measured as a percentage of the applied acceleration, as follows:
where: ACCMEAS(gx) is the measured x-axis acceleration. gy is the applied y-axis acceleration. gz is the applied z-axis acceleration.
The cross axis sensitivity specification accounts for device level cross axis components only. These components include variations in sensor fabrication and the alignment of the sensor to the orthogonal axes of the package (also known as package alignment error). The cross axis specification does not account for system level sources of misalignment (for example, on the PCB or module).
Resonant Frequency (fo)
fo is the natural frequency at which the MEMS element has a higher gain when subjected to acceleration events. Input acceleration at this resonant frequency causes the sensor to displace by an amount equal to the applied acceleration multiplied by the quality factor (Q). Some parts, for example the ADXL317, use different sensor types for the horizontal (x- and y-axes) and the vertical (z-axis) sensing axes. Therefore, the resonant frequency responses of these sensors are not the same.
Quality Factor
The quality factor is a scalar factor that governs the increase or decrease in amplitude of an acceleration signal applied at the resonant frequency of a MEMS element.
Power supply considerations
It is important to respect the power supply limits and considerations described in the datasheet.
As a general rule, it is highly recommended to always be started up the accelerometer from ground level (0 V).
Recommended VS and VDDIO power sequencing
Some products, e.g. ADXL313, specifies that VS and VDDIO can be applied in any sequence without damaging the part, whereas the the ADXL355 specifies that, VS cannot be powered before VDDIO.
Power supply decoupling specifications
Generally it is recommend to use a 0.1uF ceramic capacitor and a 1-to-10uF tantalum capacitor between VS/VDDIO. Following this recommendation is very important to meet the datasheet specifications, for example in terms of noise level.
Power Cycling
It is common in ULP applications to power cycle the accelerometer to reduce power consumption. When using this technique, please remember that it is highly recommend to always start up the accelerometer from ground level (0 V) to ensure proper operation. If this is not possible, care must be taken regarding the following specifications:
- VS supply start-up threshold: During start-up or power cycling, the VS and VDDIO supplies must always be started up from below 100 mV. When the device is in operation, any time power is removed or falls below the accelerometer power supply lower range voltage, VS and VDDIO supplies must be discharged below 100 mV. This specification is mandatory.
- Hold time: VS and VDDIO supplies must be held below 100 mV for at least 200 ms before re-powering the part.
- Rise time: For the worst case scenario (100mV Vs starts up and 200ms hold time) VS and VDDIO supplies rise time must be linear and within 250 μs to reach the supply lower range voltage. For example, for the ADXL372, the power supply lower range voltage is 1.6V, thus the voltage supply should raise from 0V to 1.6V within 250μs.
Fully discharging the power supply to the ground level allows a much more relaxed rise time, ≤600 µs, from 0 V to supply lower range voltage, for a 200 ms hold time.
To enable supply discharge, it is recommended to power the device from a microcontroller general-purpose input/output (GPIO), connect a shutdown discharge switch to the supply, or use a voltage regulator with a shutdown discharge feature.
resources/technical-guides/best_engineering_practices_when_using_adxl_accelerometers.1617032557.txt.gz · Last modified: 29 Mar 2021 17:42 by Pablo del Corro