QT310-D ETC, QT310-D Datasheet - Page 5

QT310-D

Manufacturer Part Number

QT310-D

Description

PROGRAMMABLE CAPACITANCE SENSOR IC

Manufacturer

ETC

Datasheet

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doing so. Panel material can also be changed to one having a

higher dielectric constant, which will help propagate the field.

Locally adding some conductive material to the panel

(conductive materials essentially have an infinite dielectric

constant) will also help; for example, adding carbon or metal

fibers to a plastic panel will greatly increase frontal field

strength, even if the fiber density is too low to make the

plastic electrically conductive.

1.4.2 D

In some cases the circuit may be too sensitive, even with high

signal threshold values. In this case gain can be lowered by

making the electrode smaller, using sparse mesh with a high

space-to-conductor ratio (Figure 1-3), and most importantly by

decreasing Cs. Adding Cx capacitance will also decrease

sensitivity.

It is also possible to reduce sensitivity by making a capacitive

divider with Cx by adding a low-value capacitor in series with

the electrode wire.

1.5 TIMING

Figure 1-7 and 1-8 shows the basic timing parameters of the

QT310. The basic QT310 timing parameters are:

1.5.1 B

The burst duration depends on the values of Cs and Cx, and

to a lesser extend, Vdd. The burst is normally composed of

hundreds of charge-transfer cycles (Figure 1-6) operating at

about 240kHz. This frequency varies by about ±7% during the

burst in a spread-spectrum modulation pattern. See Section

3.5.2 page 13 for more information on spread-spectrum.

(Observed using a 750K resistor in series with probe)

Tbd

Tbs

Tsc

Tmod

Tdet

URST

ECREASING

Figure 1-7 Burst when SC is set to 1

REQUENCY AND

Burst duration

Burst spacing

Sleep Cycle duration

Max On-Duration

Detection response time

ENSITIVITY

URATION

(1.5.1)

(1.5.2)

(1.5.3)

(1.5.4)

The number of pulses in a burst and hence its duration

increases with Cs and decreases with Cx.

1.5.2 B

Between acquisition bursts, the device can go into a low

power sleep mode. The duration of this is a multiple of Tsc,

the basic sleep cycle time. Tsc depends heavily on Vdd as

shown in Figure 5-4, page 16. The parameter SC calls out

how many of these cycles are used. More SC means lower

power but also slower response time.

Tbs is the spacing from the start of one burst to the start of

the next. This timing depends on the burst length Tbd and the

dead time between bursts, i.e. Tsc.

The resulting timing of Tbs is:

If SC = 0, the device never sleeps between bursts (example:

Figure 1-8). In this case the value of Tsc is fixed at about

2.25ms, but this time is not spent in Sleep mode and maximal

power is consumed.

if SC >> 0 (example: SC=15), the device will spend most of its

time in sleep mode and will consume very little power, but it

will be much slower to respond.

By selecting a supply voltage and a value for SC, it is possible

to fine-tune the circuit for the desired speed / power trade-off.

1.5.3 M

The Max On-Duration is the amount of time required for

sensor to recalibrate itself when continuously detecting. This

parameter is user-settable by changing MOD and SC (see

Section 2.6).

Tmod restarts if the sensor becomes inactive before the end

of the Max On Duration period.

Figure 1-8 Burst when SC is set to 0 (no sleep cycles)

(Observed using a 750K resistor in series with probe)

URST

Tbs = Tbd + (SC x Tsc)

-or-

Tbs = Tbd + 2.25ms

-D

PACING

URATION

: T

, T

MOD

QT310/R1.03 21.09.03

where SC = 0

where SC > 0

QT310-D ETC, QT310-D Datasheet - Page 5

QT310-D

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