User manual

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FSR

Integration Guide

2.0 Theory of Operation

The most basic FSR consists of two membranes separated by a thin air gap. The air gap

is maintained by a spacer around the edges and by the rigidity of the two membranes.

One of the membranes has two sets of interdigitated fingers that are electrically distinct,

with each set connecting to one trace on a tail. The other membrane is coated with FSR

ink. When pressed, the FSR ink shorts the two traces together with a resistance that

depends on applied force.

Figure 1: Basic FSR Construction

2.1 Basic Construction

Around the perimeter of the sensor is a spacer adhesive that serves both to separate the

two substrates and hold the sensor together. This spacer typically has a thickness

between 0.03mm and 0.15mm. This spacer may be screen printed of a pressure

sensitive adhesive, may be cut from a film pressure sensitive adhesive, or may be built

up using any combination of materials that can both separate and adhere to the two

substrates.

Both membranes are typically formed on flexible polymer sheets such as PET, polyimide,

or any othe

r film material. In custom force sensors, the top substrate could be made with

a slightly less flexible material, such as polycarbonate, thin metal or very thin circuit board

material, as long as it is sufficiently deformable to allow a reasonable force to push the

top substrate against the bottom substrate to activate the sensor.

The inside surface of one substrate is coated with FSR®

carbon-based ink. Figure 2

shows FSR ink under a microscope. When the two substrates are pressed together, the

microscopic protrusions on the FSR ink surface short across the interdigitated fingers of

the facing surface. At low forces only the tallest protrusions make contact. At higher

forces more and more points make contact

. The result is that the resistance between the

conducting fingers is inversely proportional to the applied force.