qt60326 Quantum Research Group, qt60326 Datasheet - Page 4

qt60326

Manufacturer Part Number

qt60326

Description

32 & 48 Key Qmatrix Ics

Manufacturer

Quantum Research Group

Datasheet

1.QT60326.pdf (32 pages)

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2.3 Response Time

The response time of the device depends on the scan rate of

the keys (Section 5.13), the number of keys enabled (Section

5.4), the detect integrator settings (Section 5.4), and the serial

polling rate by the host microcontroller (or the use of the LED

pin as an interrupt to the host; Sections 5.16, and Table 5.2 on

page 25). An example timing:

The worst case response time is computed as:

The use of the LED pin to trigger host sampling can reduce this

to ~75ms by saving the majority of the host polling time; see

Section 5.16.

2.4 Oscillator

The oscillator can use either a quartz crystal or a ceramic

resonator. In either case, the XT1 and XT2 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 XT1 in which case, XT2 should be left

unconnected.

The frequency of oscillation should be 16MHz +/-1% for

accurate UART transmission timing.

2.5 Sample Capacitors; Saturation Effects

The charge sampler capacitors on the Y pins should be the

values shown. They should be X7R or NP0 ceramics or PPS

film. The value of these capacitors is not critical but 4.7nF is

recommended for most cases.

Cs voltage saturation is shown in Figure 2-1. This nonlinearity

is caused by excessively negative voltage on Cs inducing

conduction in the pin protection diodes. This badly saturated

signal destroys key gain and introduces a strong thermal

coefficient which can cause 'phantom' detection. The cause of

this is usually from the burst length being too long, the Cs value

being too small, or the X-Y coupling being too large. Solutions

include loosening up the interdigitation of key structures,

separating X and Y lines on the PCB more, increasing Cs, and

decreasing the burst length.

Increasing Cs will make the part slower; decreasing burst

length will make it less sensitive. A better PCB layout and a

looser key structure (up to a point) have no negative effects.

Cs voltages should be observed on an oscilloscope with the

matrix layer bonded to the panel material; if the Rs side of any

Cs ramps more negative than -0.25 volts during any burst (not

counting overshoot spikes which are probe artifacts), there is a

potential saturation problem.

Figure 2-2 shows a defective waveform similar to that of 2-1,

but in this case the distortion is caused by excessive stray

capacitance coupling from the Y line to AC ground, for example

from running too near and too far alongside a ground trace,

ground plane, or other traces. The excess coupling causes the

charge-transfer effect to dissipate a significant portion of the

received charge from a key into the stray capacitance. This

phenomenon is more subtle; it can be best detected by

)

Keys enabled (KE) = 20

Burst spacing (BS) = 1ms

NDIL = 3

FDIL = 5

Host polling rate (PR) = 10ms

((KE + FDIL) x NDIL x BS) + PR = Worst case response

((20 + 5) x 3 x 1ms) + 10ms = 85ms

increasing BL to a high count and watching what the waveform

does as it descends towards and below -0.25V. The waveform

will appear deceptively straight, but it will start to flatten even

before the -0.25V level is reached.

A correct waveform is shown in Figure 2-3. Note that the

bottom edge of the bottom trace is substantially straight

(ignoring the downward spikes).

Unlike other QT circuits, the Cs capacitor values on QT60xx6

devices have no effect on conversion gain. However they do

affect conversion time.

Unused Y lines should be left open.

2.6 Sample Resistors

There are 6 sample resistors (Rs) used to perform single-slope

ADC conversion of the acquired charge on each Cs capacitor.

These resistors directly control acquisition gain: larger values of

Rs will proportionately increase signal gain. Values of Rs can

range from 220K to 1M . 220K is a reasonable value for

most purposes.

Larger values for Rs will also increase conversion time and may

reduce the fastest possible key sampling rate, which can impact

response time especially with larger numbers of enabled keys.

Unused Y lines do not require an Rs resistor.

(Burst too long, or Cs too small, or X-Y capacitance too large)

Figure 2-2 VCs - Poor Gain, Non-Linear During Burst

Figure 2-1 VCs - Non-Linear During Burst

(Excess capacitance from Y line to Gnd)

Figure 2-3 Vcs - Correct

QT60486-AS R8.01/0105

qt60326 Quantum Research Group, qt60326 Datasheet - Page 4

qt60326

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