Force Sensitive Resistor

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Overview

FSRs are sensors that allow you to detect physical pressure, squeezing and weight. They are simple to use and low cost. This is a photo of an FSR, specifically the Interlink 402 model. The 1/2" diameter round part is the sensitive bit.

FSR402 MED.jpg

402FSR large.jpg

The FSR is made of 2 layers seperated by a spacer. The more one presses, the more of those Active Element dots touch the semiconductor and that makes the resistance go down.


FSRimage.jpg


FSR's are basically a resistor that changes its resistive value (in ohms Ω) depending on how much its pressed. These sensors are fairly low cost, and easy to use but they're rarely accurate. They also vary some from sensor to sensor perhaps 10%. So basically when you use FSR's you should only expect to get ranges of response. While FSRs can detect weight, they're a bad choice for detecting exactly how many pounds of weight are on them.

However, for most touch-sensitive applications like "has this been squeezed or pushed and about how much" they're a good deal for the money!

Specification

  • Size: 1/2" (12.5mm) diameter active area by 0.02" thick
  • Resistance range: Infinite/open circuit (no pressure), 100KΩ (light pressure) to 200Ω (max. pressure)
  • Force range: 0 to 20 lb. (0 to 100 Newtons) applied evenly over the 0.125 sq in surface area
  • Power supply: Any! Uses less than 1mA of current (depends on any pullup/down resistors used and supply voltage)
  • Datasheet

How to measure force/pressure with an FSR

As we've said, the FSR's resistance changes as more pressure is applied. When there is no pressure, the sensor looks like an infinite resistor (open circuit), as the pressure increases, the resistance goes down. This graph indicates approximately the resistance of the sensor at different force measurements. (Note that force is not measured in grams and what they really mean is Newtons * 100!)

Resistanceforce.jpg

Its important to notice that the graph isn't really linear (its a log/log graph) and that at especially low force measurements it quickly goes from infinite to 100KΩ.


Testing an FSR

The easiest way to determine how your FSR works is to connect a multimeter in resistance-measurement mode to the two tabs on your sensor and see how the resistance changes. Because the resistance changes a lot, a auto-ranging meter works well here. Otherwise, just make sure you try different ranges, between 1 Mohm and 100 ohm before 'giving up'.

Fsrmetertesting.jpg


Connecting to an FSR

Because FSRs are basically resistors, they are non-polarized. That means you can connect them up 'either way'a and they'll work just fine!

We recommend to use a 2.54mm female header to connect to it.

Fsrhead.jpg


FSR Sample Project

Simple Code for Analog FSR Measurements

Fsrpulldowndia.png

Fsrpulldownsch.gif

Simpletestout.gif


<syntaxhighlight lang="c">

/* FSR simple testing sketch.

Connect one end of FSR to power, the other end to Analog 0. Then connect one end of a 10K resistor from Analog 0 to ground


int fsrPin = 0; // the FSR and 10K pulldown are connected to a0 int fsrReading; // the analog reading from the FSR resistor divider

void setup(void) {

 // We'll send debugging information via the Serial monitor
 Serial.begin(9600);   

}

void loop(void) {

 fsrReading = analogRead(fsrPin);  

 Serial.print("Analog reading = ");
 Serial.print(fsrReading);     // the raw analog reading

 // We'll have a few threshholds, qualitatively determined
 if (fsrReading < 10) {
   Serial.println(" - No pressure");
 } else if (fsrReading < 200) {
   Serial.println(" - Light touch");
 } else if (fsrReading < 500) {
   Serial.println(" - Light squeeze");
 } else if (fsrReading < 800) {
   Serial.println(" - Medium squeeze");
 } else {
   Serial.println(" - Big squeeze");
 }
 delay(1000);

}

</syntaxhighlight>