qt113 Quantum Research Group, qt113 Datasheet - Page 3

qt113

Manufacturer Part Number

qt113

Description

Charge-transfer Touch Sensor

Manufacturer

Quantum Research Group

Datasheet

1.QT113.pdf (12 pages)

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solid plane. Sensitivity may even remain the same, as the

sensor will be operating in a lower region of the gain curves.

1.3.2 K

Like all capacitance sensors, the QT113 relies on Kirchoff’s

Current Law (Figure 1-3) to detect the change in capacitance

of the electrode. This law as applied to capacitive sensing

requires that the sensor’s field current must complete a loop,

returning back to its source in order for capacitance to be

sensed. Although most designers relate to Kirchoff’s law with

regard to hardwired circuits, it applies equally to capacitive

field flows. By implication it requires that the signal ground

and the target object must both be coupled together in some

manner for a capacitive sensor to operate properly. Note that

there is no need to provide actual hardwired ground

connections; capacitive coupling to ground (Cx1) is always

sufficient, even if the coupling might seem very tenuous. For

example, powering the sensor via an isolated transformer will

provide ample ground coupling, since there is capacitance

between the windings and/or the transformer core, and from

the power wiring itself directly to 'local earth'. Even when

battery powered, just the physical size of the PCB and the

object into which the electronics is embedded will generally

be enough to couple a few picofarads back to local earth.

1.3.3 V

When detecting human contact (e.g. a fingertip), grounding

of the person is never required. The human body naturally

has several hundred picofarads of ‘free space’ capacitance to

the local environment (Cx3 in Figure 1-3), which is more than

two orders of magnitude greater than that required to create

a return path to the QT113 via earth. The QT113's PCB

however can be physically quite small, so there may be little

‘free space’ coupling (Cx1 in Figure 1-3) between it and the

environment to complete the return path. If the QT113 circuit

ground cannot be earth grounded by wire, for example via

the supply connections, then a ‘virtual capacitive ground’ may

be required to increase return coupling.

A ‘virtual capacitive ground’ can be created by connecting the

QT113’s own circuit ground to:

Free-floating ground planes such as metal foils should

maximize exposed surface area in a flat plane if possible. A

square of metal foil will have little effect if it is rolled up or

crumpled into a ball. Virtual ground planes are more effective

and can be made smaller if they are physically bonded to

other surfaces, for example a wall or floor.

1.3.4 F

The electrode can be prevented from sensing in undesired

directions with the assistance of metal shielding connected to

circuit ground (Figure 1-4). For example, on flat surfaces, the

field can spread laterally and create a larger touch area than

desired. To stop field spreading, it is only necessary to

surround the touch electrode on all sides with a ring of metal

connected to circuit ground; the ring can be on the same or

opposite side from the electrode. The ring will kill field

spreading from that point outwards.

If one side of the panel to which the electrode is fixed has

moving traffic near it, these objects can cause inadvertent

detections. This is called ‘walk-by’ and is caused by the fact

that the fields radiate from either surface of the electrode

- A nearby piece of metal or metallized housing;

- A floating conductive ground plane;

- Another electronic device (to which its output might be

connected anyway).

IELD

IRCHOFF

IRTUAL

HAPING

’

APACITIVE

URRENT

ROUNDS

equally well. Shielding in the form of a metal sheet or foil

connected to circuit ground will prevent walk-by; putting a

small air gap between the grounded shield and the electrode

will keep the value of Cx lower to reduce loading and keep

gain high.

1.3.5 S

The QT113 can be set for one of 2 gain levels using option

pin 5 (Table 1-1). This sensitivity change is made by altering

the internal numerical threshold level required for a detection.

Note that sensitivity is also a function of other things: like the

value of Cs, electrode size and capacitance, electrode shape

and orientation, the composition and aspect of the object to

be sensed, the thickness and composition of any overlaying

panel material, and the degree of ground coupling of both

sensor and object.

1.3.5.1 Increasing Sensitivity

In some cases it may be desirable to increase sensitivity

further, for example when using the sensor with very thick

panels having a low dielectric constant.

Sensitivity can often be increased by using a bigger

electrode, reducing panel thickness, or altering panel

composition. Increasing electrode size can have diminishing

returns, as high values of Cx will reduce sensor gain (Figures

4-1 to 4-3). The value of Cs also has a dramatic effect on

sensitivity, and this can be increased in value with the

tradeoff of reduced response time. Increasing the electrode's

surface area will not substantially increase touch sensitivity if

its diameter is already much larger in surface area than the

object being detected. Panel material can also be changed to

one having a higher dielectric constant, which will help

propagate the field. Metal areas near the electrode will

reduce the field strength and increase Cx loading.

Ground planes around and under the electrode and its SNS

trace will cause high Cx loading and destroy gain. The

possible signal-to-noise ratio benefits of ground area are

more than negated by the decreased gain from the circuit,

and so ground areas around electrodes are discouraged.

Keep ground away from the electrodes and traces.

1.3.5.2 Decreasing Sensitivity

In some cases the QT113 may be too sensitive, even on low

gain. In this case gain can be lowered further by decreasing

Cs.

S EN SO R

X 1

ENSITIVITY

Figure 1-3 Kirchoff's Current Law

Su rro und in g e nv iro nm en t

S e nse E le ctro de

R1.05/0405

X 3

qt113 Quantum Research Group, qt113 Datasheet - Page 3

qt113

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