QT110-DG Atmel, QT110-DG Datasheet - Page 6

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QT110-DG

Manufacturer Part Number

QT110-DG

Description

IC SENSOR TOUCH/PROX 1CHAN 8DIP

Manufacturer

Atmel

Series

QTouch™r

Type

Capacitiver

Datasheet

1.QT110-DG.pdf (12 pages)

Specifications of QT110-DG

Touch Panel Interface

1, 2-Wire

Number Of Inputs/keys

1 Key

Resolution (bits)

14 b

Data Interface

Serial

Voltage Reference

Internal

Voltage - Supply

2.5V, 3.3V, 5V

Current - Supply

26µA

Operating Temperature

0°C ~ 70°C

Mounting Type

Through Hole

Package / Case

8-DIP

Output Type

Logic

Interface

2-Wire

Input Type

Logic

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

427-1091

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Bonase Electronics (HK) Co., Limited

Part Number:

QT110-DG

Manufacturer:

MAXIM

Quantity:

201

Current page: 6 of 12
Download datasheet (388Kb)

the load is turned off, the supply rises and the object is

reacquired, ad infinitum. To prevent this occurrence, the output

should only be lightly loaded if the device is operated from an

unregulated supply, e.g. batteries. Detection ‘stiction’, the

opposite effect, can occur if a load is shed when Out is active.

The output of the QT110 can directly drive a resistively limited

LED. The LED should be connected with its cathode to the

output and its anode towards Vcc, so that it lights when the

sensor is active-low. If desired the LED can be connected from

Out to ground, and driven on when the sensor is inactive, but

only with less drive current (1mA).

3 - CIRCUIT GUIDELINES

3.1 SAMPLE CAPACITOR

When used for most applications, the charge sampler Cs can

be virtually any plastic film or good quality ceramic capacitor.

The type should be relatively stable in the anticipated

temperature range. If fast temperature swings are expected,

especially at higher sensitivity, a more stable capacitor might

be required for example PPS film.

In most moderate applications a low-cost X7R type will work

fine.

3.2 ELECTRODE WIRING

See also Section 3.4.

The wiring of the electrode and its connecting trace is important

to achieving high signal levels and low noise. Certain design

rules should be adhered to for best results:

LQ

1. Use a ground plane under the IC itself and Cs and Rs but

NOT under Re, or under or closely around the electrode or

its connecting trace. Keep ground away from these things

H eartBeat™ P ulses

Getting HB pulses with a pull-down resistor

C M O S

M IC RO INP U T

Figure 2-6 Eliminating HB Pulses

G AT E OR

Ro

100p F

2

3

4

Figure 2-4

C

O UT

O PT 1

O PT 2

o

+2 .5 to 5

1

8

Vdd

Vss

2

3

4

S NS 2

GAIN

S NS 1

O UT

O PT1

O PT2

7

5

6

SN S 2

GA IN

SN S 1

7

5

6

M icro processo r

6

3.3 POWER SUPPLY, PCB LAYOUT

See also Section 3.4.

The power supply can range from 2.5 to 5.0 volts. At 2.5 volts

current drain averages less than 10µA with Cs = 10nF,

provided a 470K Rs resistor is used (Figure 2-6). Idd curves

are shown in Figure 4-4.

Higher values of Cs will raise current drain. Higher Cx values

can actually decrease power drain. Operation can be from

batteries, but be cautious about loads causing supply droop

(see Output Drive, Section 2.2.6) if the batteries are

unregulated.

As battery voltage sags with use or fluctuates slowly with

temperature, the IC will track and compensate for these

changes automatically with only minor changes in sensitivity.

If the power supply is shared with another electronic system,

care should be taken to assure that the supply is free of digital

spikes, sags, and surges which can adversely affect the

device. The IC will track slow changes in Vdd, but it can be

affected by rapid voltage steps.

if desired, the supply can be regulated using a conventional

low current regulator, for example CMOS LDO regulators that

have nanoamp quiescent currents. Care should be taken that

the regulator does not have a minimum load specification,

which almost certainly will be violated by the QT110's low

current requirement. Furthermore, some LDO regulators are

unable to provide adequate transient regulation between the

quiescent and acquire states, creating Vdd disturbances that

will interfere with the acquisition process. This can usually be

solved by adding a small extra load from Vdd to ground, such

as 10K ohms, to provide a minimum load on the regulator.

Conventional non-LDO type regulators are usually more stable

than slow, low power CMOS LDO types. Consult the regulator

manufacturer for recommendations.

For proper operation a 100nF (0.1uF) ceramic bypass

capacitor must be used between Vdd and Vss; the bypass cap

2. Keep Cs, Rs, and Re very close to the IC.

3. Make Re as large as possible. As a test, check to be sure

4. Do not route the sense wire near other ‘live’ traces

Using a micro to obtain HB pulses in either output state

to reduce stray loading (which will dramatically reduce

sensitivity).

that an increase of Re by 50% does not appreciably

decrease sensitivity; if it does, reduce Re until the 50%

test increase has a negligible effect on sensitivity.

containing repetitive switching signals; the sense trace will

pick up noise from them.

P O RT _ M .x

P O RT _ M .y

R

Figure 2-5

o

2

3

4

OU T

OP T 1

OP T 2

QT110 R1.04/0405

SN S 2

GA IN

SN S 1

7

5

6

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