qt60325 Quantum Research Group, qt60325 Datasheet - Page 4

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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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 8 square

centimeters of PCB area.

QMatrix devices include charge cancellation methods which

allow for a wide range of key sizes and shapes to be mixed

together in a single touch panel. These features permit the

construction of entirely new classes of keypads never before

contemplated, such as touch-sliders, back-illuminated keys,

and complex warped panel shapes, all at very low cost.

The devices use an SPI interface running at up to 1.5MHz 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 IC as

well as read back key status and

signal levels in real time.

QMatrix parts employ transverse

charge-transfer ('QT') sensing, a

new technology that senses

changes in the charge forced

across an electrode by a digital

edge.

The parts are electrically

identical with the exception of the

number of keys which may be

sensed.

1.1 Field Flows

Figure 1-1 shows how charge is

transferred across an electrode

set to permeate the overlying

panel material; this charge flow

exhibits a high dQ/dt during the

Figure 1-1 Field flow between X and Y elements

elem e nt

Figure 1-4 Fields With a Conductive Film

overly ing panel

Figure 1-3 Field Flows When Touched

elem ent

elem e nt

edge transitions of the X drive pulse. The charge emitted by

the X electrode is partly received onto the corresponding Y

electrode which is then processed. The parts use 8 'X'

edge-driven rows and 8 'Y' sense columns to permit up to 64

keys. Keys are typically formed from interleaved conductive

traces on a substrate like a flex circuit or PCB (Figure 1-2).

The charge flows are absorbed by the touch of a human

finger (Figure 1-3) resulting in a decrease in coupling from X

to Y. Thus, received signals decrease or go negative with

respect to the reference level during a touch.

Water films cause the coupled fields to increase slightly,

making water films easy to distinguish from touch.

1.2 Circuit Model

An electrical circuit model is shown in Figure 1-5. The

coupling capacitance between X and Y electrodes is

represented by Cx. While the reset switch is open, a sample

switch is gated so that it transfers charge flows only from the

rising edge of X into a charge integrator. On the falling edge

of X, the switch connects the Y line to ground to allow the

charge across Cx to neutralize to zero. The voltage change

on the output of the charge integrator after each X edge is

quite small, on the order of a few tens of millivolts. Changes

due to touch are typically under 0.1% of total integrator

PARALLEL LINES

ov e rly in g pan el

Figure 1-2 Sample Electrode Geometries

elem ent

www.qprox.com

SERPENTINE

voltage. The X pulse can be

repeated in a burst of up to 64

pulses to increase the change in

integrator output voltage due to

touch during an acquire (Section

3.6) to increase gain.

The charge detector is an opamp

configured as an integrator with a

reset switch; this creates a virtual

ground input, making the Y lines

appear low impedance when the

sample switch is closed. This

configuration effectively

eliminates cross-coupling among

Y lines while greatly lowering

susceptibility to EMI. The circuit

is also highly immune to

capacitive loading on the Y lines,

since stray C from Y to ground

appears merely as a small

parallel capacitance across a

virtual ground.

The circuit uses an 8-bit ADC,

with a subranging structure to

effectively deliver a 14-bit total

conversion 'space' (see Figure

1-6 and Section 3.3). In this way

the circuit can tolerate very large

QT60xx5 / R1.05

SPIRAL

qt60325 Quantum Research Group, qt60325 Datasheet - Page 4

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