QT60168-ASG Atmel, QT60168-ASG Datasheet - Page 20

QT60168-ASG

Manufacturer Part Number

QT60168-ASG

Description

IC SENSOR QMATRIX 16CHAN 32TQFP

Manufacturer

Atmel

Series

QMatrix™, QProx™r

Type

Capacitiver

Datasheet

1.QT60168-ASG.pdf (28 pages)

Specifications of QT60168-ASG

Number Of Inputs/keys

16 Key

Resolution (bits)

9, 11 b

Data Interface

Serial, SPI™

Voltage - Supply

3 V ~ 5 V

Current - Supply

25mA

Operating Temperature

-40°C ~ 105°C

Mounting Type

Surface Mount

Package / Case

32-TQFP, 32-VQFP

Output Type

Logic

Interface

SPI

Input Type

Logic

Operating Supply Voltage

3 V to 5 V

Maximum Operating Temperature

+ 105 C

Minimum Operating Temperature

- 40 C

Mounting Style

SMD/SMT

For Use With

427-1087 - BOARD EVAL QT60248-AS QMATRIX

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

427-1107

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After the PRD interval has expired and the auto- recalibration

has taken place, the affected key will once again function

normally. PRD is fixed at 1 second for all keys, and cannot

be altered.

5.7 Burst Length - BL

The signal gain for each key is controlled by circuit

parameters as well as the burst length.

The burst length is simply the number of times the

charge-transfer (‘QT’) process is performed on a given key.

Each QT process is simply the pulsing of an X line once, with

a corresponding Y line enabled to capture the resulting

charge passed through the key’s capacitance Cx.

QT60xx8 devices use a fixed number of QT cycles which are

executed in burst mode. There can be up to 64 QT cycles in

a burst, in accordance with the list of permitted values shown

in Table 5.3.

Increasing burst length directly affects key sensitivity. This

occurs because the accumulation of charge in the charge

integrator is directly linked to the burst length. The burst

length of each key can be set individually, allowing for direct

digital control over the signal gains of each key individually.

Apparent touch sensitivity is also controlled by the Negative

Threshold level (NTHR). Burst length and NTHR interact;

normally burst lengths should be kept as short as possible to

limit RF emissions, but NTHR should be kept above 6 to

reduce false detections due to external noise. The detection

integrator mechanism also helps to prevent false detections.

BL Typical values:

BL Default value:

BL possible values:

5.8 Adjacent Key Suppression - AKS

These devices incorporate adjacent key suppression (‘AKS’ -

patent pending) that can be selected on a per-key basis.

AKS permits the suppression of multiple key presses based

on relative signal strength. This feature assists in solving the

problem of surface moisture which can bridge a key touch to

an adjacent key, causing multiple key presses. This feature

is also useful for panels with tightly spaced keys, where a

fingertip might inadvertently activate an adjacent key.

AKS works for keys that are AKS-enabled anywhere in the

matrix and is not restricted to physically adjacent keys; the

device has no knowledge of which keys are actually

physically adjacent. When enabled for a key, adjacent key

suppression causes detections on that key to be suppressed

if any other AKS-enabled key in the panel has a more

negative signal deviation from its reference.

This feature does not account for varying key gains (burst

length) but ignores the actual negative detection threshold

setting for the key. If AKS-enabled keys in a panel have

different sizes, it may be necessary to reduce the gains of

larger keys relative to smaller ones to equalize the effects of

AKS. The signal threshold of the larger keys can be altered

to compensate for this without causing problems with key

suppression.

Adjacent key suppression works to augment the natural

moisture suppression of narrow gated transfer switches

creating a more robust sensing method.

AKS Default value:

2, 3 (48, 64 pulses / burst)

2 (48 pulses / burst)

16, 32, 48, 64

0 (Off)

5.9 Oscilloscope Sync - SSYNC

Pin 11 (S_Sync) can output a positive pulse oscilloscope

sync that brackets the burst of a selected key. More than one

burst can output a sync pulse as determined by the Setups

parameter SSYNC for each key.

The SSYNC function does not become effective until the part

has been reset, or the desired key(s) are recalibrated.

This feature is invaluable for diagnostics; without it,

observing signals clearly on an oscilloscope for a particular

burst is very difficult.

This function is supported in Quantum’s QmBtn PC software.

SSYNC Default value:

5.10 Mains Sync - MSYNC

The MSync feature uses the SYNC pin.

External fields can cause interference leading to false

detections or sensitivity shifts. Most fields come from AC

power sources. RFI noise sources are heavily suppressed

by the low impedance nature of the QT circuitry itself.

Noise such as from 50Hz or 60Hz fields becomes a problem

if it is uncorrelated with acquisition signal sampling;

uncorrelated noise can cause aliasing effects in the key

signals. To suppress this problem the SYNC input allows

bursts to synchronize to the noise source.

The noise sync operating mode is set by parameter MSYNC

in Setups.

The sync occurs only at the burst for the lowest numbered

enabled key in the matrix; the device waits for the sync

signal for up to 100ms after the end of a preceding full matrix

scan, then when a negative sync edge is received, the matrix

is scanned in its entirety again.

The sync signal drive should be a buffered logic signal, but

never a raw AC signal from the mains; slow or erratic edges

on MSYNC can cause the device to sync on the wrong edge,

or both edges. The device should only sync to the falling

edge.

Since Noise sync is highly effective and inexpensive to

implement, it is strongly advised to take advantage of it

anywhere there is a possibility of encountering low frequency

(i.e. 50/60Hz) electric fields. Quantum’s QmBtn software can

show such noise effects on signals, and will hence assist in

determining the need to make use of this feature.

If the sync feature is enabled but no sync signal exists, the

sensor will continue to operate but with a delay of 100ms

from the end of one scan to the start of the next, and hence

will have a slow response time. A failed Sync signal (one

exceeding a 100ms period) will cause an error flag (see

commands 0x05, 0x06).

MSYNC Default value:

MSYNC Possible range:

5.11 Burst Spacing - BS

The interval of time from the start of one burst to the start of

the next is known as the burst spacing. This is an alterable

parameter which affects all keys. The burst spacing can be

viewed as a scheduled timeslot in which a burst occurs. This

approach results in an orderly and predictable sequencing of

key scanning with predictable response times.

QT60248-AS R4.02/0405

0 (Off)

0 (Off )

0, 1 (Off, On)

QT60168-ASG Atmel, QT60168-ASG Datasheet - Page 20

QT60168-ASG

Specifications of QT60168-ASG

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