QT160-DG Atmel, QT160-DG Datasheet - Page 4

QT160-DG

Manufacturer Part Number

QT160-DG

Description

IC SENSOR 6CH 5V 5MA SGL 28DIP

Manufacturer

Atmel

Series

QProx™, QTouch™r

Type

Capacitiver

Datasheet

1.QT161-ASG.pdf (12 pages)

Specifications of QT160-DG

Touch Panel Interface

6, 2-Wire

Number Of Inputs/keys

6 Key

Resolution (bits)

10, 14 b

Voltage Reference

Internal

Voltage - Supply

2.5 V ~ 5 V

Current - Supply

20µA

Operating Temperature

0°C ~ 70°C

Mounting Type

Through Hole

Package / Case

28-DIP (0.300", 7.62mm)

Output Type

Logic

Interface

2-Wire

Input Type

Logic

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

427-1100

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to circuit ground (Figure 1-6). For example, on flat surfaces,

the field can spread laterally and create a larger touch area

than desired. To stop field spreading, it is only necessary to

surround the touch electrode on all sides with a ring of metal

connected to circuit ground; the ring can be on the same or

opposite side from the electrode. The ring will kill field

spreading from that point outwards.

If one side of the panel to which the electrode is fixed has

moving traffic near it, these objects can cause inadvertent

detections. This is called ‘walk-by’ and is caused by the fact

that the fields radiate from either surface of the electrode

equally well. Again, shielding in the form of a metal sheet or

foil connected to circuit ground will prevent walk-by; putting a

small air gap between the grounded shield and the electrode

will keep the value of Cx lower and is encouraged. In the

case of the QT160/161, sensitivity can be high enough

(depending on Cx and Cs) that 'walk-by' signals are a

concern; if this is a problem, then some form of rear

shielding may be required.

1.3.6 S

Sensitivity can be altered to suit various applications and

situations on a channel-by-channel basis. The easiest and

most direct way to impact sensitivity is to alter the value of

Cs. More Cs yields higher sensitivity.

1.3.6.1 Alternative Ways to Increase Sensitivity

Sensitivity can also be increased by using bigger electrodes,

reducing panel thickness, or altering panel composition.

Increasing electrode size can have diminishing returns, as

high values of Cx counteract sensor gain. Also, increasing

the electrode's surface area will not substantially increase

touch sensitivity if its diameter is already much larger in

surface area than the object being detected. The panel or

other intervening material can be made thinner, but again

there are diminishing rewards for doing so. Panel material

can also be changed to one having a higher dielectric

constant, which will help propagate the field through to the

front. Locally adding some conductive material to the panel

(conductive materials essentially have an infinite dielectric

constant) will also help; for example, adding carbon or metal

fibers to a plastic panel will greatly increase frontal field

strength, even if the fiber density is too low to make the

plastic bulk-conductive.

SENSO R

X 1

ENSITIVITY

Figure 1-5 Kirchoff's Current Law

Su rro und ing e nv iro nm en t

Se nse E le ctro de

X 3

1.3.6.2 Decreasing Sensitivity

In some cases the QT160 may be too sensitive. In this case

gain can be lowered further by a number of strategies:

a) making the electrode smaller, b) making the electrode into

a sparse mesh using a high space-to-conductor ratio (Figure

1-3), or c) by decreasing the Cs capacitors.

2 - QT160/QT161 SPECIFICS

2.1 SIGNAL PROCESSING

The QT160 processes all signals using 16 bit math, using a

number of algorithms pioneered by Quantum. The algorithms

are specifically designed to provide for high survivability in

the face of adverse environmental changes.

2.1.1 D

Signal drift can occur because of changes in Cx, Cs, and

Vdd over time. If a low grade Cs capacitor is chosen, the

signal can drift greatly with temperature. If keys are subject

to extremes of temperature and humidity, the signal can also

shift. It is crucial that drift be compensated, else false

detections, non-detections, and sensitivity shifts will follow.

Drift compensation (Figure 2-1) is a method that makes the

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

no detection is in effect. The rate of reference adjustment

must be performed slowly else legitimate detections can also

be ignored. The IC drift compensates each channel

independently using a slew-rate limited change to the

reference level; the threshold and hysteresis values are

slaved to this reference.

Once an object is sensed, the drift compensation

mechanism ceases since the signal is legitimately high, and

therefore should not cause the reference level to change.

The signal drift compensation is 'asymmetric'; the reference

level drift-compensates in one direction faster than it does in

the other. Specifically, it compensates faster for decreasing

signals than for increasing signals. Increasing signals should

not be compensated for quickly, since an approaching finger

Sense

wire

Figure 1-6 Shielding Against Fringe Fields

RIFT

OMPENSATION

LGORITHM

Sense

QT160/161 1.07/0904

w ire

QT160-DG Atmel, QT160-DG Datasheet - Page 4

QT160-DG

Specifications of QT160-DG

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