The output signal of the sensor circuit is a DC level, swinging from zero volts
to several volts, when a touch sensor circuit is activated. However, if the distance between the sensor circuit and the circuit used to detect an
activated switch is great, the unshielded wires will often collect a lot of unwanted AC power line noise signals. I highly recommend adding an
interface circuit to process the DC level swing from the sensor circuit, before sending the signal to a computer system or to a power switch circuit. To remove the AC noise components, a
passive RC filter is recommended at the front end of the interface circuit. The filter circuit not only filters unwanted AC line noise, but also does
a fine job of preventing damage to the interface circuit from electrostatic discharge. The output of the filter circuit can be routed to an N-channel FET or to Schmitt trigger circuit.
The Schmitt trigger circuit does a fine job of converting the slow voltage swing from the sensor to a fast clean logic voltage shift. The Schmitt
trigger action also requires a consistent minimum input voltage level, which helps to prevent false switch action.
The circuit shown in figure 1 shows both examples
of an FET and a Schmitt trigger circuit. I personally prefer the Schmitt trigger circuit but have also used the FET circuit when the distance between the touch switch and the
interface circuit are short..
The output of the interface circuit can be used to operate both solid state and
mechanical relays. It can also be fed to logic inputs of a computer system. I have also used the simple logic circuits to produce a sequence of
switch outputs. A touch sequence can also be used to turn on and off various loads according to the logic circuit. As an example, the first touch of a button might turn on one light. The second might turn on two lights, a third touch might turn on
three lights and a forth touch might turn off all lights.