Embedded Sensor Specifications
Each of our enDAQ sensors has within it a primary accelerometer and then 7 additional embedded sensors. This article will provide specific details on these embedded sensors, many of which are common to every one of our products. The main accelerometer is the primary difference between each enDAQ sensor after the form factor.
In this Article
- Primary & Common: Digital Capacitive Accelerometer
- Primary: Piezoelectric Accelerometer
- Primary: Piezoresistive Accelerometer
- Common: Orientation Sensor (Gyroscope and IMU)
- Common: External Temperature, Pressure & Humidity Sensor
- Common: Ambient Visible and UV Light Sensor
- Common: Internal Temperature & Pressure Sensor
- Common on W: GPS Module
- Common on W: Microphone
Digital Capacitive Accelerometer
The triaxial capacitive MEMS accelerometer is great for general purpose testing and in some of our sensors, it is the primary accelerometer. In models that have the piezoelectric or piezoresistive accelerometer, this serves as a secondary accelerometer to extend the measurable range (provide a DC response or better lower amplitude information for shock sensors). See our blog on accelerometer selection for more detail on different accelerometer types.
| Triaxial Digital Capacitive Accelerometer Performance | |||||
| Products | Comes standard on all our sensors | ||||
| Sampling Rate Per Channel 1 | 4 Hz to 4.0 kHz | 12.5 Hz to 3.2 kHz | Selectable with Provided Software | ||
| Frequency Response Within ±5% Accuracy |
0 Hz to 300 Hz | 0 Hz to 500 Hz | See Frequency Response Plot | ||
| Transverse Sensitivity | <10 % | ||||
| Low-Pass Filter | 2nd Order (Filter Frequency is 1/4 Sample Frequency) | 2nd Order (Filter Frequency is 1/2 Sample Frequency) | |||
| enDAQ Designation | D8 | D40 | D16 | D200 | |
| Sensor Part Number | ADXL355 |
ADXL357 |
ADXL345 |
ADXL375 |
|
| Measurement Range | ±8 g | ±40 g | ±16 g | ±200 g | |
| Broadband Noise | < 0.002 g RMS | < 0.01 g RMS | < 0.01 g RMS | < 0.14 g RMS | Reduces with slower sample rates |
| Resolution | 0.00002 g | 0.00008 g | 0.004 g | 0.05 g | 20-bit for the D8 & D40, 13-bit for the D16 & D200 |
| Nonlinearity | ± 0.1% | ± 0.1% | ± 0.5% | ± 0.25% | Percentage of the full scale |
| Temperature Response | ± 0.01 %/°C | ± 0.01 %/°C | ± 0.01 %/°C | ± 0.02 %/°C | |
1The sample rate varies over temperature by -0.1% per degree C. The enDAQ sensor's clock accurately accounts for this drift, but just note that long recording files may not have perfectly equal spacing between points throughout the entire recording (important to note for FFTs). Also, the sample rate is typically -2.2% lower than specified by the user at room temperature (for example a 100 Hz sample rate configuration will result in a 97.8 Hz sample rate).
Note that the MEMS accelerometer has a DC response (can measure down to 0 hertz). The plot only goes to 1 Hz because it is on a logarithmic scale. The accelerometer data was generated with the sample rate at 3.2 kHz and 4.0 kHz with the unit bolted to the mounting fixture.
Piezoelectric Accelerometer
| Triaxial Piezoelectric Accelerometer Performance | |||||
| Products | Comes standard in enDAQ -E sensors | ||||
| Sampling Rate Per Channel: | User Selectable from 100 Hz to 20 kHz | Selectable with Provided Software | |||
| Frequency Response Within ±5% Accuracy (X, Y & Z Axis) |
Aluminum Enclosure: 5 Hz to 2,000 Hz Polycarbonate Enclosure: 5 Hz to 1,000 Hz |
See Frequency Response Plot | |||
| Transverse Sensitivity | <10 % | ||||
| Nonlinearity | ± 2% | ||||
| Temperature Sensitivity 1 | - 0.3 %/°C | ||||
| Low-Pass Filter | 5th Order Hardware Butterworth (Linear Phase & Software Tunable) | ||||
| Sensor Part Number | 832M1- 0025 | 832M1- 0100 | 832M1- 0500 | 834M1-2000 |
|
| Measurement Range | ±25 g | ±100 g | ±500 g | ±2,000 g | |
| Broadband Noise 2 | < 0.01 g RMS | < 0.04 g RMS | < 0.20 g RMS | < 0.80g RMS | |
| Resolution 3 | 0.0008 g | 0.003 g | 0.015 g | 0.06 g | 16-bit |
| Sensitivity (mV/g) | 50.0 | 12.5 | 2.5 | 0.62 | ±30%, @ 3.3 Vdc Excitation |
1Temperature compensated with software and internal temperature sensor. This linear compensation is only valid between -20C and 60C (non-linear at extremes).
2Tested with a 20 kHz sampling rate and a 5 kHz filter frequency. Noise levels will be lower with slower sampling rates and/or lower filter frequency.
3The resolution depends on sampling rate: 16-bit < 8.5 kHz, 15-bit < 16 kHz, 14-bit > 16 kHz
The piezoelectric accelerometer was sampled at 20kHz with a 5 kHz filter. Adequate compression of the tape was achieved by first bolting the unit to allow the tape to set, then remove the bolts. The mounting torque of these bolts was 70 in-oz.
Piezoresistive Accelerometer
The piezoresistive accelerometer offers similar advantages as the piezoelectric in terms of data quality. But they have the added benefit of being capable of measuring static accelerations and low-frequency vibrations. They also have internal gas damping to widen the dynamic frequency range of the accelerometer. These accelerometers are increasingly becoming more popular for shock and vibration testing applications. See our blog on accelerometer selection for more detail on different accelerometer types.
| Triaxial Piezoresistive Accelerometer Performance | ||||
| Products | Comes standard in enDAQ -R sensors | |||
| Sampling Rate Per Channel: | User Selectable from 100 Hz to 20 kHz | Selectable with Provided Software | ||
| Frequency Response Within ±5% Accuracy (X, Y & Z Axis) |
Aluminum Enclosure: 0 Hz to 2,000 Hz | See Frequency Response Plot | ||
| Transverse Sensitivity | <10 % | |||
| Nonlinearity | ± 0.5% | |||
| Temperature Sensitivity | ± 0.02 %/°C | |||
| Low-Pass Filter | 5th Order Hardware Bessel (Linear Phase & Software Tunable) | |||
| Sensor Part Number | 3255A-100 |
3255A-500 | 3255A-2000 |
|
| Measurement Range | ±100 g | ±500 g | ±2,000 g | |
| Broadband Noise 1 | < 0.08 g RMS | < 0.40 g RMS | <1.60 g RMS | |
| Resolution 2 | 0.003 g | 0.015 g | 0.06 g | 16-bit |
| Sensitivity (mV/g) | 20.0 | 4.0 | 1.0 | ±10%, @ 5 Vdc Excitation |
| Damping Ratio | 0.7 | 0.5 | TBD | Typical |
1Tested with a 20 kHz sampling rate and a 5 kHz filter frequency. Noise levels will be lower with slower sampling rates and/or lower filter frequency.
2The resolution depends on sampling rate: 16-bit < 8.5 kHz, 15-bit < 16 kHz, 14-bit > 16 kHz
Orientation Sensor (Gyroscope & IMU)
As of November 2017, a selection of our enDAQ sensors now include an embedded "smart sensor hub" that has an integrated triaxial gyroscope, triaxial accelerometer, triaxial geomagnetic sensor, and a microcontroller for intelligently fusing raw data from the 9 sensors. The output of this sensor hub include the following:
- Rotation (gyroscope only)
- Relative orientation (output in quaternions relative to starting location)
- Absolute orientation (output in quaternions relative to earth's magnetic field - involves a startup time for the geomagnetic sensor to self-calibrate)
We published a blog that goes into more detail; but here is an excerpt that explains the difference between relative and absolute orientation mode.
There are two options for the orientation sensor: absolute and relative. The absolute measurement provides a rotation relative to magnetic north, and the relative measurement is the orientation relative to the orientation the sensor had when the acquisition started. Both sensors work by integrating the rotation and applying a correction factor from the accelerometer, including detection of the gravity vector. The absolute orientation sensor also uses the magnetometer to orient itself to the magnetic field.
Since the absolute orientation sensor uses a magnetometer, it can be better at detecting slow turns, which result in a low rate of degrees per second applied over a number of seconds. Similarly, it should be less likely to drift over long periods. But, since the absolute measurement uses a magnetometer, it increases the power draw (3 mA vs 1.5 mA; but this equates to roughly a 10% increase on the overall power consumption depending on configuration). The absolute sensor also requires some movement before the sensors all lock-on for high accuracy data. How to get high-accuracy data is detailed here.
| Orientation Sensor Performance | |||||||||||
| Products | Comes standard on all of our enDAQ sensors | Not available on S3-D16 | |||||||||
| Sampling Rate Per Channel | User Selectable from 0 Hz (off) to 200 Hz |
User Selectable from 0 Hz (off) to 3,200 Hz |
Selectable with Provided Software | ||||||||
| Sensor Part Number | BHI160 |
BMG-250 | BMM150 |
||||||||
| Measurement Range | 2000 °/s | 2000 °/s | ± 1300 µT | ||||||||
| Resolution | 0.06 °/s | 0.06 °/s | 0.3 µT | |
|||||||
| Transverse Sensitivity | ± 2% | ± 2% | Not Specified | ||||||||
| Nonlinearity | ± 0.1% |
± 0.1% | ± 1% | |
Percentage of full scale | ||||||
External Temperature, Pressure & Humidity Sensor
As of February 2017, all of our enDAQ sensors now include temperature, pressure, and humidity sensors in the external "control pad" (has LEDs and button). This addition was largely due to a request from the Navy. They were using a Slam Stick (now re-branded as enDAQ) to record cabin pressure on every F-18 flight because of the cabin pressure issues they've been having in F/A-18s, but they wanted better pressure data. This new sensor has improved accuracy and response on its own; but with its external location, the data will be a better representation of ambient conditions. This sensor also has an integrated humidity sensor that was enabled as of firmware revision 20.
| External Temperature, Pressure, and Humidity Sensor Performance | ||||
| Products | Comes standard on all of our enDAQ sensors | |||
| Sampling Rate Per Channel | User Selectable from 0 Hz (off) to 10 Hz | Selectable with Provided Software | ||
| Sensor Part Number | MS8607 |
|
||
| Sensor | Temperature |
Pressure |
Humidity |
|
| Measurement Range | -40 to 85 °C | 1 to 200 kPa | 0 to 100 %RH | |
| Accuracy | ± 1 °C | ± 0.2 kPa | ± 3% RH | -25°C to 80°C |
| Resolution | 0.01 °C | 1.6 Pa | 0.04% RH | 24-bit |
Internal Temperature & Pressure Sensor
This sensor is still used to compensate for the change in sensitivity of the piezoelectric accelerometer over temperature which is why it is still enabled.
| Internal Temperature and Pressure Sensor Performance | |||
| Products | Standard prior to HW 2.0.0 | Standard on HW 2.0.0+ | |
| Sampling Rate Per Channel | Always on at 1 Hz | User Selectable from 0 Hz (off) to 10 Hz | |
| Sensor Part Number | MPL3115A2 |
MS8607 |
|
External Visible and UV Light Sensor
As of Firmware version 20, the light sensor on the control pad is enabled. This sensor is capable of capturing the intensity of visible and ultraviolet light at a rate of 4 Hz. This sensor is not calibrated and is intended for rough, relative measurements only. We wrote a blog on light sensors in general too that can help provide some background on how this sensor can be utilized. The sensor is placed as shown below:
| External Light Sensor Performance | |||
| Products | Comes standard on all of our enDAQ sensors | ||
| Sampling Rate Per Channel | About 4 Hz |
|
|
| Sensor Part Number | Si1133 |
|
|
GPS Module
All W-Series units have a GPS module capable of measuring
- Latitude and Longitude
- Speed in m/s
- Epoch time (number of seconds since 1/1/1970)
This module is the ublox CAM-M8. This is a link to the full receiver description protocol that lists the many different metrics we can add to the device from GPS with firmware updates.
Microphone
The microphone records at the same rate as the other analog channels (up to 20 kHz) and was added for W-Series devices. The specific sensor used is the ICS-40619.