+++ title = "Position Sensors" author = ["Dehaeze Thomas"] draft = false category = "equipment" +++ Tags : [Inertial Sensors]({{< relref "inertial_sensors.md" >}}), [Force Sensors]({{< relref "force_sensors.md" >}}), [Sensor Fusion]({{< relref "sensor_fusion.md" >}}), [Signal Conditioner]({{< relref "signal_conditioner.md" >}}), [Signal to Noise Ratio]({{< relref "signal_to_noise_ratio.md" >}}) ## Types of Positioning sensors {#types-of-positioning-sensors} High precision positioning sensors include: - [Interferometers]({{< relref "interferometers.md" >}}) - [Capacitive Sensors]({{< relref "capacitive_sensors.md" >}}) - [LVDT]({{< relref "linear_variable_differential_transformers.md" >}}) - [Eddy Current Sensors]({{< relref "eddy_current_sensors.md" >}}) - [Encoders]({{< relref "encoders.md" >}}) - [Quadrant Photodiodes]({{< relref "quadrant_photodiodes.md" >}}) ## Reviews of Relative Position Sensors {#reviews-of-relative-position-sensors} - Fleming, A. J., A review of nanometer resolution position sensors: operation and performance (Fleming 2013) ([Notes]({{< relref "fleming13_review_nanom_resol_posit_sensor.md" >}})) - (Gao et al. 2015) Table [1](#table--tab:characteristics-relative-sensor) is taken from (Collette et al. 2011).

Table 1: Characteristics of relative measurement sensors

| Technology | Frequency | Resolution | Range | T Range | |----------------|------------|----------------|--------------|-------------| | LVDT | DC-200 Hz | 10 nm rms | 1-10 mm | -50,100 °C | | Eddy current | 5 kHz | 0.1-100 nm rms | 0.5-55 mm | -50,100 °C | | Capacitive | DC-100 kHz | 0.05-50 nm rms | 50 nm - 1 cm | -40,100 °C | | Interferometer | 300 kHz | 0.1 nm rms | 10 cm | -250,100 °C | | Encoder | DC-1 MHz | 1 nm rms | 7-27 mm | 0,40 °C | | Bragg Fibers | DC-150 Hz | 0.3 nm rms | 3.5 cm | -30,80 °C | Table [2](#table--tab:summary-position-sensors) it taken from (Fleming 2013).

Table 2: Summary of position sensor characteristics. The dynamic range (DNR) and resolution are approximations based on a full-scale range of 100um and a first order bandwidth of \(1 kHz\)

| Sensor Type | Range | DNR | Resolution | Max. BW | Accuracy | |----------------|--------------------------------|---------|------------|-------------|-----------| | Metal foil | \\(10-500 \mu m\\) | 230 ppm | 23 nm | 1-10 kHz | 1% FSR | | Piezoresistive | \\(1-500 \mu m\\) | 5 ppm | 0.5 nm | >100 kHz | 1% FSR | | Capacitive | \\(10 \mu m\\) to \\(10 mm\\) | 24 ppm | 2.4 nm | 100 kHz | 0.1% FSR | | Electrothermal | \\(10 \mu m\\) to \\(1 mm\\) | 100 ppm | 10 nm | 10 kHz | 1% FSR | | Eddy current | \\(100 \mu m\\) to \\(80 mm\\) | 10 ppm | 1 nm | 40 kHz | 0.1% FSR | | LVDT | \\(0.5-500 mm\\) | 10 ppm | 5 nm | 1 kHz | 0.25% FSR | | Interferometer | Meters | | 0.5 nm | >100kHz | 1 ppm FSR | | Encoder | Meters | | 6 nm | >100kHz | 5 ppm FSR | Capacitive Sensors and Eddy-Current sensors are compare [here](https://www.lionprecision.com/comparing-capacitive-and-eddy-current-sensors/). Figure [1](#figure--fig:position-sensors-thurner15) is taken from (Thurner et al. 2015). {{< figure src="/ox-hugo/position_sensors_thurner15.png" caption="Figure 1: Overview of range and precision of different position displacement sensors" >}} ## Bibliography {#bibliography}

Collette, C, K Artoos, M Guinchard, S Janssens, P Carmona Fernandez, and C Hauviller. 2011. “Review of Sensors for Low Frequency Seismic Vibration Measurement.” CERN.

Fleming, Andrew J. 2013. “A Review of Nanometer Resolution Position Sensors: Operation and Performance.” Sensors and Actuators a: Physical 190 (nil): 106–26. doi:10.1016/j.sna.2012.10.016.

Gao, W., S.W. Kim, H. Bosse, H. Haitjema, Y.L. Chen, X.D. Lu, W. Knapp, A. Weckenmann, W.T. Estler, and H. Kunzmann. 2015. “Measurement Technologies for Precision Positioning.” Cirp Annals 64 (2): 773–96. doi:10.1016/j.cirp.2015.05.009.

Thurner, Klaus, Francesca Paola Quacquarelli, Pierre-François Braun, Claudio Dal Savio, and Khaled Karrai. 2015. “Fiber-Based Distance Sensing Interferometry.” Applied Optics 54 (10). Optical Society of America: 3051–63.