QT114 Datasheet, PDF(2/12 Page) Quantum Research Group

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QT114 Datasheet, PDF (2/12 Pages) Quantum Research Group – CHARGE-TRANSFER QLEVEL SENSOR IC

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The QT114 is a digital burst mode charge-transfer (QT)

sensor designed specifically for point level sensing; it

includes all hardware and signal processing functions

necessary to provide stable level sensing under a wide

variety of changing conditions. Only a single external

capacitor is required for operation.

Figure 1-1 shows a basic QT114 circuit using the device,

with conventional OUT drives and power supply connections.

The sensing electrode can be connected to a single-tier or

2-tier electrode as required.

Calibration is done by design, through adjustment of the

electrode sizes and the Cs capacitor. Only under rare

situations do QT114 circuits require calibration on an

individual basis, and the circuit can make provision for that.

OUT 1

OUT 2

FILTER

Vcc

2 OUT1 SNS2 7

3 OUT2 SNS1 6

4 FILT POL 5

To 10x Scope Probe

2Mâ¦ (optional)

To Electrode(s)

1Mâ¦ multi-turn

pot (optional)

8 Gnd

Vdd

POLARITY

Vdd

POL: 1 = Active High

FILT: 1 = Slosh Filter

1 - SIGNAL ACQUISITION

The QT114 employs a short, low duty cycle burst of

charge-transfer cycles to acquire its signal. Burst mode

permits power consumption in the low microamp range,

dramatically reduces RF emissions, lowers susceptibility to

EMI, and yet permits excellent response time. Internally the

signals are digitally processed to generate the required

output signals.

The QT switches and charge measurement hardware

functions are all internal to the QT114 (Figure 1-2). A 14-bit

single-slope switched capacitor ADC includes both the

required QT charge and transfer switches in a configuration

that provides direct ADC conversion. The burst length is

inversely proportional to the rate of charge buildup on Cs,

which in turn depends on the values of Cs, Cx, and Vcc. Vcc

is used as the charge reference voltage. Larger values of Cx

cause the charge transferred into Cs to accumulate more

rapidly. The trip points of the sensor can be changed by

altering Cs and Cx, the load capacitance. As a result, the

values of Cs, Cx, and Vcc should be fairly stable over the

expected operating temperature range.

Two fixed thresholds are used, one for low fluid level and the

other for high level; adjusting Cs and Cx to allow these to trip

at appropriate points is required by design, and if required

may be trimmed by an adjustment. Figure 1-1 shows the

optional potentiometer which can be used to fine-tune the

placement of these threshold points relative to the signal.

Figure 1-1 Standard mode options

It is not necessary to use both detection threshold points; if

only single point sensing is desired, only the lower threshold

and OUT1 can be used, while ignoring OUT2.

Two option pins allow the selection of output polarity and the

insertion of a 'slosh filter' before the OUT pins, as shown in

Figure 1-1.

1.1 ELECTRODE DRIVE

The internal ADC treats Cs as a floating transfer capacitor;

as a direct result, the sense electrode can be connected to

either SNS1 or SNS2 with no performance difference. The

polarity of the charge buildup across Cs during a burst is the

same in either case. Cs must be of within a certain range for

proper operation.

It is possible to connect separate Cx and Cxâ loads to SNS1

and SNS2 simultaneously, although the result is no different

than if the loads were connected together at SNS2 (or

SNS1). It is important to limit the amount of stray

capacitance on both terminals, especially if the load Cx is

already large, for example by minimizing trace lengths and

widths so as not to exceed the Cx load specification and to

allow for a larger sensing electrode size if so desired.

The PCB traces, wiring, and any components associated

with or in contact with SNS1 and SNS2 will become

proximity sensitive and should be treated with caution.

Result

S tart

Done

SNS2

SNS1

ELEC T RO DE

1.2 THRESHOLD POINTS

The QT114 employs twin threshold points set at both

250 (for T1) and 150 counts (for T2) of acquisition

signal. The signal travels in an inverse direction:

increasing amounts of Cx reduce the signal level; the

baseline ('dry') signal should lie at 300 counts or

more under most conditions. Calibration details are

discussed fully in Section 3.2.

2 ELECTRODE DESIGN

The QT114 is designed to operate with a 'plateau'

sensor, having a substantial surface area at each

desired trip point, to create a capacitive 'step'.

C ha rg e

Amp

Figure 1-2 Internal Switching & Timing

As Figure 2-1 shows, a vertical strip sensor on the

outside of a container (or a vertical, insulated rod in

the fluid) will generate a long sloping signal. The

desired trip point 'T' is subject to a great deal of

variation in location if the sensing signal drifts much,

-2-

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