QT60240-ISG QUANTUM ATMEL, QT60240-ISG Datasheet - Page 5

QT60240-ISG

Manufacturer Part Number

QT60240-ISG

Description

QPROX SENSOR 24 KEYS, SMD, MLF-32

Manufacturer

QUANTUM ATMEL

Datasheet

1.QT60160-ISG.pdf (26 pages)

Specifications of QT60240-ISG

Supply Voltage Range

1.8V To 5.5V

Operating Temperature Range

-40Â°C To +85Â°C

Digital Ic Case Style

MLF

No. Of Pins

Operating Temperature Max

85Â°C

Operating Temperature Min

-40Â°C

Package /

RoHS Compliant

Ic Function

16, 24 KEY QMATRIX Touch Sensor

Rohs Compliant

Yes

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QmBtn software is available free of charge on Quantum’s

website www.qprox.com.

The signal swing from the smallest finger touch should

preferably exceed 8 counts, with 12 being a reasonable

target. The signal threshold setting (NTHR) should be set to a

value guaranteed to be less than the signal swing caused by

the smallest touch.

Increasing the burst length (BL) parameter will increase the

signal strengths as will increasing the sampling resistor (Rs)

values.

2.7 Matrix Series Resistors

The X and Y matrix scan lines can use series resistors

(referred to as Rx and Ry respectively) for improved EMC

performance (Figure 2.7, page 9).

X drive lines require Rx in most cases to reduce edge rates

and thus reduce RF emissions. Typical values range from

Y lines need Ry to reduce EMC susceptibility problems and in

some extreme cases, ESD. Typical Y values are about 1K

Y resistors act to reduce noise susceptibility problems by

forming a natural low-pass filter with the Cs capacitors.

It is essential that the Rx and Ry resistors and Cs capacitors

be placed very close to the chip. Placing these parts more

than a few millimeters away opens the circuit up to high

frequency interference problems (above 20MHz) as the trace

lengths between the components and the chip start to act as

RF antennae.

✡

to 20K

✡

Figure 2.5 Probing X-Drive

Waveforms With a Coin

✡

The upper limits of Rx and Ry are reached when the signal

level and hence key sensitivity are clearly reduced. The limits

of Rx and Ry will depend on key geometry and stray

capacitance, and thus an oscilloscope is required to

determine optimum values of both.

Dwell time is the duration in which charge coupled from X to

Y is captured (Figure 2.4, page 4). Increasing Rx values will

cause the leading edge of the X pulses to increasingly roll off,

causing the loss of captured charge (and hence loss of signal

strength) from the keys.

The dwell time of these parts is fixed at 500ns. If the X pulses

have not settled within 500ns, key gain will be reduced; if this

happens, either the stray capacitance on the X line(s) should

be reduced (by a layout change, for example by reducing X

line exposure to nearby ground planes or traces), or, the Rx

resistor needs to be reduced in value (or a combination of

both approaches).

‘T’ should ideally be similar to the complete thickness the fields

need to penetrate to the touch surface. Smaller dimensions will also

work but will give less signal strength. If in doubt, make the pattern

coarser. The lower figure shows a simpler structure used for

compact key layouts, for example for mobile phones. A layout with a

common X drive and three receive electrodes is depicted.

Figure 2.6 Recommended Key Structure

QT60240-ISG R8.06/0906

QT60240-ISG QUANTUM ATMEL, QT60240-ISG Datasheet - Page 5

QT60240-ISG

Specifications of QT60240-ISG

Available stocks

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