QT60161B-A QUANTUM [Quantum Research Group], QT60161B-A Datasheet - Page 9

QT60161B-A

Manufacturer Part Number

QT60161B-A

Description

16 KEY QMATRIX KEYPANEL SENSOR IC

Manufacturer

QUANTUM [Quantum Research Group]

Datasheet

1.QT60161B-A.pdf (36 pages)

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Cx. Therefore it is vital that the circuit be checked with an

oscilloscope to make sure that burst spacings are unaffected

during normal operation.

3.7 Intra-Burst Spacing

See also Command ^G, page 22

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.

Shorter spacings result in faster response time, but due to

increasing timing restrictions at shorter spacings burst

lengths or the conversion resolution may be restricted,

limiting the amount of gain that can be obtained; see Sections

3.6 and 5.7. Conversely longer spacings permit higher burst

lengths but slow down response time.

Three settings of burst spacing are possible: 500µs, 1ms, and

2ms.

3.9 Sample Capacitors

Charge sampler capacitors Cs should be either ceramic NPO,

X7R 5%, or PPS film for stability reasons.

The values of capacitance should not be altered from that

shown in the schematic of Figure 3-2 without good reason.

Changes in Cs have only a limited effect on signal gain.

3.10 Water Film Suppression

Water films on the user surface can cause problems with

false detection under certain conditions. Water films on their

own will not normally cause false detections. The most

common problem occurs when surface water bridges over 2

or more keys, and a user touches one of the keys and the

water film causing an adjacent key to also trigger. Essentially,

the water film transports the touch contact to adjacent keys.

The circuit suppresses water coupling by having a short dwell

time, equal to one oscillator period or 83ns. A short dwell time

reduces the amount of charge collected via resistive water

films, i.e. it suppresses charge from areas adjacent to the

scanned key. This effect has nothing to do with the frequency

of the burst itself.

Very short dwell times can cause excess suppression of

human touch as well. If series resistors are used in line with

the X and Y matrix lines for noise and ESD suppression

©Quantum Research Group Ltd.

(Section 3.18), a short dwell time can seriously affect signal

gain.

Mechanical measures can also be used to suppress key

cross-coupling, for example one can use raised plastic

barriers between keys, or placing keys in shallow wells to

lengthen the electrical path from key to key.

3.11 Reset Input

The RST’ pin can be used to reset the device to simulate a

power down cycle, in order to bring the part up into a known

state should communications with the part be lost. The pin is

active low, and a low pulse lasting at least 10µs must be

applied to this pin to cause a reset.

To provide for proper operation during power transitions the

devices have an internal brown-out detector set to 4 volts.

A reset command, ‘r’, is also provided which generates an

equivalent hardware reset (page 25).

3.12 Oscillator

The oscillator can use either a quartz crystal or a ceramic

resonator. In either case, the XTI and XTO must both be

loaded with 22pF capacitors to ground. 3-terminal resonators

having onboard ceramic capacitors are commonly available

and are recommended. An external TTL-compatible

frequency source can also be connected to XTI; XTO should

be left unconnected.

The frequency of oscillation should be 12MHz +/-2%.

3.13 Startup / Calibration Times

The QT60161B requires initialization times as follows:

Keys that cannot calibrate for some reason require 5

calibration cycles before they report as errors. However, the

device can report back during this interval that the key(s)

affected are still in calibration via status function bits.

3.14 Sleep_Wake / Noise Sync Pin (WS)

The Sleep_wake and Noise sync features use input pin WS.

The Sleep and Sync features can be used simultaneously;

the part can be put into Sleep mode, but awakened by a

noise sync signal which is gated in at the time desired.

Sleep mode: See also command ‘Z’, page 25. The device

can be put into an ultra low-power sleep mode using the ‘Z’

command. When this command is received, the WS pin must

be placed immediately thereafter into a logic-high state. The

part will complete an ongoing burst before entering Sleep.

The part can be awakened by a low transition on the WS pin

lasting at least 5µs. One convenient way to wake the part is

to connect WS to MOSI, and have the host send a null

1. From very first powerup to ability to communicate:

2. Normal cold start to ability to communicate:

3. Calibration time per key vs. burst spacings:

2,000ms (One time event to initialize all of eeprom)

70ms (Normal initialization from any reset)

spacing = 500µs:

spacing = 1ms:

spacing = 2ms:

To the above, add 2,000ms or 70ms from (1) or (2) for

the total elapsed time from reset to ability to report key

detections.

www.qprox.com QT60161B / R1.03

100ms

150ms

300ms

QT60161B-A QUANTUM [Quantum Research Group], QT60161B-A Datasheet - Page 9

QT60161B-A

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