QT60486-AS Atmel, QT60486-AS Datasheet - Page 2

QT60486-AS

Manufacturer Part Number

QT60486-AS

Description

SENSOR IC MTRX TOUCH48KEY 44TQFP

Manufacturer

Atmel

Series

QMatrix™, QProx™r

Type

Capacitiver

Datasheet

1.QT60326-AS.pdf (23 pages)

Specifications of QT60486-AS

Rohs Status

RoHS non-compliant

Number Of Inputs/keys

48 Key

Resolution (bits)

9, 11 b

Data Interface

Serial, SPI™, UART

Voltage - Supply

4.75 V ~ 5.25 V

Current - Supply

25mA

Operating Temperature

-40°C ~ 105°C

Mounting Type

Surface Mount

Package / Case

44-TQFP, 44-VQFP

Output Type

Interface

Input Type

For Use With

427-1088 - BOARD EVAL QT60486-AS QMATRIX

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Manufacturer

Quantity

Price

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Bonase Electronics (HK) Co., Limited

Part Number:

QT60486-ASG

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1 Overview

QMatrix devices are digital burst mode charge-transfer (QT)

sensors designed specifically for matrix geometry touch

controls; they include all signal processing functions

necessary to provide stable sensing under a wide variety of

changing conditions. Only a few external parts are required

for operation. The entire circuit can be built within 5 square

centimeters of single-sided PCB area.

QMatrix parts employ transverse charge-transfer ('QT')

sensing, a technology that senses changes in electrical

charge forced across an electrode by a digital edge (Figure

1-1).

QMatrix devices allow for a wide range of key sizes and

shapes to be mixed together in a single touch panel.

The devices use both UART and SPI interfaces to allow key

data to be extracted and to permit individual key parameter

setup. The interface protocol uses simple single byte

commands and responds with single byte responses in most

cases. The command structure is designed to minimize the

amount of data traffic while maximizing the amount of

information conveyed.

In addition to normal operating and setup functions the device

can also report back actual signal strengths and error codes.

QmBtn software for the PC can be used to program the

operation of the IC as well as read back key status and signal

levels in real time.

The parts are electrically identical with the exception of the

number of keys which may be sensed.

1.1 Part differences

Versions of the device are capable of a maximum of 16, 24,

32, and 48 keys.

The QT60xx6 devices are identical to one another in all

respects, except that each device is capable of only the

number of keys specified for each device. These keys can be

located anywhere within the electrical grid of 8 X and 6 Y

scan lines. Unused keys are always pared from the burst

sequence in order to optimize timing performance.

Even with a given part type, such as QT60486, a lesser

number of enabled keys will cause any unused acquisition

burst timeslots to be pared. Thus, if only 40 keys are actually

enabled, only 40 timeslots are used for scanning.

Advanced information; subject to change

Figure 1-1 Field flow between X and Y elements

elem e nt

overly ing panel

elem ent

2 Hardware

2.1 Matrix Scan Sequence

The circuit operates by scanning each key sequentially, key

by key. Key scanning begins with location X=0 / Y=0. X axis

keys are known as rows while Y axis keys are referred to as

columns. Keys are scanned sequentially by row, for example

the sequence Y0X0 Y0X1 .... Y0X3, Y1X0 Y1X1... etc.

Each key is sampled up to 64 times in a burst whose length is

determined by the Setups parameter BL, which can be set on

a per-key basis. A burst is completed entirely before the next

key is sampled; at the end of each burst the resulting signal is

converted to digital form and processed. The burst length

directly impacts key gain; each key can have a unique burst

length in order to allow tailoring of key sensitivity on a key by

key basis.

2.2 Oscillator

The oscillator can use either a quartz crystal or a ceramic

resonator. In either case, the XT1 and XT2 must both be

loaded with 22pF capacitors to ground. 3-terminal resonators

having onboard ceramic capacitors are commonly available

and are recommended. An external TTL-compatible

frequency source can also be connected to XT1 in which

case, XT2 should be left unconnected.

The frequency of oscillation should be 16MHz +/-1% for

accurate UART transmission timing.

2.3 Sample Capacitors

The charge sampler capacitors on the Y pins should be the

values shown. They can be X7R ceramic type. The value of

these capacitors is non-critical and can vary from 3.3nF to

10nF; 4.7nF is acceptable in most cases. Heavy Cx load

capacitances may necessitate the use of larger Cs

capacitors.

The Cs capacitor values have no effect on conversion gain.

Unused Y lines should have a 1nF dummy capacitor

connected as shown.

2.4 Sample Resistors

There are 6 sample resistors (Rs) used to perform

single-slope ADC conversion of the acquired charge on each

Cs capacitor. These resistors are directly linked with

acquisition gain. Larger values of Rs will proportionately

increase signal gain. Values of Rs can range from 220K✡ to

1M✡. 220K✡ is a reasonable typical value for most

purposes.

Larger values for Rs will also increase conversion time and

may reduce the fastest possible key sampling rate, which can

impact response time especially with larger numbers of

enabled keys.

2.5 Signal Levels

Using Quantum’s QmBtn™ software it is easy to observe the

absolute level of signal received by the sensor on each key.

The signal values should normally be in the range from 250 to

750 counts with properly designed key shapes (see

appropriate Quantum app note on matrix key design).

QmBtn software is available free of charge on Quantum’s

website.

QT60486-AS 0.07/1103

QT60486-AS Atmel, QT60486-AS Datasheet - Page 2

QT60486-AS

Specifications of QT60486-AS

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