qt60161b Quantum Research Group, qt60161b Datasheet - Page 7

qt60161b

Manufacturer Part Number

qt60161b

Description

16 Key Qmatrix Keypanel Sensor Ic

Manufacturer

Quantum Research Group

Datasheet

1.QT60161B.pdf (36 pages)

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the suppression of multiple key presses based on relative

signal strengths. AKS assists in solving the problem of

surface water which can bridge a key touch to an adjacent

key, causing multiple key presses, causing multiple key

presses even though only one key was touched. This feature

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

fingertip can partially overlap 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 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.

AKS works to augment the natural moisture suppression

capabilities of the device (Section 3.10), creating a more

robust touch panel.

2.10 Full Recalibration

See also command ‘b’, page 24

The part fully recalibrates one or more keys after the ‘b’

command has been issued to it, depending on the current

scope of the ‘b’ command. The device recalibrates all keys on

powerup, after a hard reset via the RST pin or on power up,

or via a reset using the ‘r’ command. Since the circuit

tolerates a very wide dynamic signal range, it is capable of

adapting to a wide mix of key sizes and shapes having widely

varying Cx coupling capacitances.

If a false calibration occurs due to a key touch or foreign

object on the keys during powerup, the affected key will

recalibrate again when the object is removed depending on

the settings of Positive Threshold and Positive Recal Delay

(Sections 2.2 and 2.7).

Calibration requires 9 full burst cycles to complete, and so the

time it takes is dependent on the burst spacing parameter

(Section 3.8 also, ^G, page 22.

2.11 Device Status & Reporting

See also commands ‘7’, page 19; ‘e’, page 19; ‘E’, page 20;

The device can report on the general device status or specific

key states including touches and error conditions, depending

on the command used.

Usually it is most efficient to periodically request the general

device status using command ‘7’ first, as the response to this

command is a single byte which reports back on behalf of all

keys. ‘7’ indicates if there are any keys detecting, calibrating,

or in error.

If command ‘7’ reports a condition requiring further

investigation, the host device can then use commands ‘e’, ‘E’,

‘k’ or ‘K’ to provide further details of the event(s) in progress.

This hierarchical approach provides for a concise information

‘k’, page 20, ‘K’, page 20

©Quantum Research Group Ltd.

flow using minimal data transfers and low host software

overhead.

3 Circuit Operation

A QT60161B reference circuit is shown in Figure 2-1.

3.1 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 Y0X2 Y0X3 Y1X0 etc.

Each key is sampled from 1 to 64 times in a burst whose

length is determined by Setup ^F. A burst is completed

entirely before the next key is sampled; at the end of each

burst the resulting analog signal is converted to digital using a

single-slope conversion process. The length of the burst

directly impacts on the gain of the key; each key can have a

unique burst length in order to allow tailoring of key sensitivity

on a key by key basis.

3.2 Signal Path

Refer to Figures 1-5, 3-1, and 3-2.

X-Drives. The X drives are push-pull CMOS lines which drive

charge through the matrix keys on the positive and negative

edges of X. Only the positive edge of X is used for signal

purposes, however the negative edge must cause the charge

across the keys to neutralize prior to the next positive edge,

else the sampling mechanism will cease after one pulse. The

part accomplishes this by holding all Y lines to ground during

the falling edge of X.

Charge gate. Only one X row is pulsed during a burst.

Charge is coupled across a key's Cx capacitance from the X

row to all Y columns. A particular key is chosen by gating the

charge from a single Y column into a single one of four

possible sampler capacitors. The other three X and three Y

lines are clamped to ground during this process.

Dwell time. The dwell time is determined internally and is

the same as one oscillator period, i.e. 83.3ns with a 12MHz

resonator. The dwell time is set via internal switching action

S ta rt

R e su lt

Figure 3-1 QT60161B Circuit Model

Do ne

www.qprox.com QT60161B / R1.03

(1 of 4)

X d rive

CSA

CSB

SM P

ele ctrode

C s (1 of 4)

R s (1 of 4)

Y line (1 o f 4)

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qt60161b Quantum Research Group, qt60161b Datasheet - Page 7

qt60161b

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