qt60325 Quantum Research Group, qt60325 Datasheet - Page 6

qt60325

Manufacturer Part Number

qt60325

Description

32, 48, 64 Key Qmatrix Keypanel Sensor Ics

Manufacturer

Quantum Research Group

Datasheet

1.QT60325.pdf (42 pages)

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the detection integrator (Section 2.6). Larger absolute values

of threshold desensitize keys since the signal must travel

farther in order to cross the threshold level. Conversely, lower

thresholds make keys more sensitive.

As Cx and Cs drift, the reference point drift-compensates for

these changes at a user-settable rate (Section 2.4); the

threshold level is recomputed whenever the reference point

moves, and thus it also is drift compensated.

The negative threshold is programmed on a per-key basis

using the setup process described in Section 5.

2.2 Positive Threshold

See also commands ^H, ^I, page 26

Signals can drift because of changes in Cx and Cs over time

and temperature. It is crucial that such drift be compensated,

else false detections and sensitivity shifts can occur. The

QT60xx5 compensates for drift using setups, ^H and ^I.

Drift compensation (Figure 2-1) is performed by making the

reference level track the raw signal at a slow rate, but only

while there is no detection in effect. The rate of adjustment

must be performed slowly, otherwise legitimate

detections could be ignored. The devices drift

compensate using a slew-rate limited change to

the reference level; the threshold and hysteresis

values are slaved to this reference.

When a finger is sensed, the signal falls since the

human body acts to absorb charge from the

cross-coupling between X and Y lines. An isolated,

untouched foreign object (a coin, or a water film)

will cause the signal to rise very slightly due to an

enhancement of coupling. This is contrary to the

way most capacitive sensors operate.

Once a finger is sensed, the drift compensation

mechanism ceases since the signal is legitimately

detecting an object. Drift compensation only works

Threshold

Hysteresis

Output

Figure 2-1 Thresholds and Drift Compensation

when the signal in question has not crossed the negative

threshold level (Section 2.1).

The drift compensation mechanism can be made asymmetric

if desired; the drift-compensation can be made to occur in

one direction faster than it does in the other simply by setting

^H and ^I to different settings.

Specifically, drift compensation should be set to compensate

faster for increasing signals than for decreasing signals.

Decreasing signals should not be compensated quickly, since

an approaching finger could be compensated for partially or

entirely before even touching the touch pad. However, an

obstruction over the sense pad, for which the sensor has

already made full allowance for, could suddenly be removed

leaving the sensor with an artificially suppressed reference

level and thus become insensitive to touch. In this latter case,

the sensor should compensate for the object's removal by

raising the reference level relatively quickly.

The drift compensation rate can be set for each key

individually, and can also be disabled completely if desired on

a per-key basis.

Drift compensation and the detection time-outs (Section 2.5)

work together to provide for robust, adaptive sensing. The

time-outs provide abrupt changes in reference calibration

depending on the duration of the signal 'event'.

Drift compensation can result in reference levels that are at

the boundaries of the 8-bit signal window. When this occurs,

saturation is reached and the drift compensation process

stops. One of two error flags is set when the signal

approaches either end of the signal window; it is up to the

host to read these flags and induce a full recalibration via a

recalibration command at that time (Section 2.10 and

command ‘b’, page 28) for the key in question.

2.5 Detection Recalibration Delay

qt60325 Quantum Research Group, qt60325 Datasheet - Page 6

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