QTAN0015 Datasheet, PDF(1/4 Page) ATMEL Corporation – Power Supply Considerations for QT ICs

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QTAN0015 Datasheet, PDF (1/4 Pages) ATMEL Corporation – Power Supply Considerations for QT ICs

Power Supply Considerations for AtmelÂ®

Capacitive-touch ICs

1. Introduction

This application note discusses the dedicated power supply arrangement for Atmel

capacitive touch-sensitive integrated circuits (QTâ¢ ICs).

2. Why Do I Need a Special Power Supply?

QT ICs derive their internal reference from the Vdd power supply. It is therefore

important to ensure that Vdd is stable and free of electrical noise. The proprietary drift

compensation algorithms of the QT IC are designed to overcome long-term drift.

Nevertheless, transient spikes of Â±10 mV can cause erratic behaviour such as false

key activations, stuck keys, and loss of touch detection.

A simple and inexpensive regulator circuit eliminates these potential problems.

3. General Recommendations

Do:

â¢ Use a dedicated regulator to power the QT IC.

â¢ Place the regulator as close as possible to the QT IC.

â¢ Use a GROUND plane under the regulator and under the Vss pins of the QT IC.

â¢ For PCBs with a GROUND plane layer, extend the plane under communications

circuits, any oscillator or crystal, and also decoupling capacitors.

â¢ Place a 0.1 ÂµF decoupling capacitor in close physical proximity to each Vdd pin.

Donât:

â¢ Share Vdd with other logic circuitry or light-emitting diodes (LED).

â¢ Use long power and GROUND traces between the regulator and the QT IC.

â¢ Extend the GROUND plane beneath the sense pins of the QT IC, Cs capacitors,

Rs resistors, or any sense line traces.

Power Supply

Considerations

for QT ICs

Application Note

QTAN0015

4. Low Drop-out (LDO) Regulator

QT ICs are optimized for low power operation. To conserve power, the device mostly

operates in an ultra-low-power sleep mode in which minimal current (ÂµA) is drawn.

Periodically, the QT IC wakes up to perform sampling and communication routines

that consume mA of current.

The poor load step response of some LDO regulators is well-known, often resulting in

significant output transients when the load increases from ÂµA to mA, causing erratic

sensor operation. Care must be taken in the selection and use of LDO regulators.

Figure 4-1 shows the circuit for a Seiko S-817 series LDO regulator.

10703AâAT42â10/08

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