MC33794EKR2 Freescale, MC33794EKR2 Datasheet - Page 13

MC33794EKR2

Manufacturer Part Number

MC33794EKR2

Description

Manufacturer

Freescale

Datasheet

1.MC33794EKR2.pdf (18 pages)

Specifications of MC33794EKR2

Lead Free Status / RoHS Status

Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

MC33794EKR2

Manufacturer:

ROHM

Quantity:

3 200

Company:

Meier Automation Equipment Co., Limited

Part Number:

MC33794EKR2

Manufacturer:

FREESCALE

Quantity:

20 000

Current page: 13 of 18
Download datasheet (392Kb)

and the object, each forming a “plate” that holds the electric

charge. Capacitance is directly proportional to the area of the

electrode plates. Doubling the area doubles the capacitance.

Capacitance is also directly proportional to the dielectric

constant of the material between the plates. Air typically has

a dielectric constant of 1 (unity) whereas water can have a

dielectic constant of 80 (which means the capacitance is

roughly 80 times larger). Plastics and glass that are

commonly used in touch panel applications have dielectric

constants greater than unity. A third consideration is that

capacitance is inversely proportional to the distance between

the plates. Doubling the distance between the two plates will

reduce capacitance by four. This property can be exploited in

cases where small distances need to be measured.

sensitivity is a function of the plate size, the dielectric

constant of the material between the plates, and the distance

between them.

the capacitance between the electrode being measured and

the surrounding electrodes and other objects in the electric

field surrounding the electrode. Increasing capacitance

results in decreasing voltage. The value of series resistance

(22 k

120 kHz over a range of 10 pF to 100 pF.

frequency, series resistance, driving voltage, the dielectric

constant of the capacitor, or detector sensitivity. These can

change with temperature and time. There are several ways to

compensate for these changes. One method uses the

REF_A and REF_B capacitors. Another method may use

long term averages to set a baseline value.

algorithm would start by measuring the voltage for two known

value capacitors (attached to REF_A and REF_B). The value

of these capacitors would be chosen to be near the minimum

and maximum values of capacitance expected to be seen at

the electrodes. These reference voltages and the known

capacitance values are then used with the electrode

Sensors

Freescale Semiconductor

A “capacitor” can be formed between the driving electrode

From the above, it can be seen that increased detection

The voltage measured at LEVEL is an inverse function of

The measured value may change with any change in

Using REF_A and REF_B, a typical measurement

Ω

) was chosen to provide a nearly linear relationship at

measurement voltage to determine the capacitance seen by

the electrode. This method can be used to detect short- and

long-term changes due to objects in the electric field and

significantly reduce the effect of temperature-and time-

induced changes.

electrode values. Long term, in this case, may mean several

seconds. These long term averages are then used as a set

point so that short term changes in the field intensity can be

reliably determined. This is typically the method used for

touch panel applications.

be used with an MCU that contains one. Offset and gain have

been added to the MC33794 to maximize the sensitivity over

the range of 0 pF to 100 pF. An 8-bit ADC can resolve around

0.4 pF of change and a 10-bit converter around 0.1 pF.

Higher resolution results in more distant detection of smaller

objects. Due to the relatively slow data access requirements

(approximately 2 ms per electrode), digital over-sampling

techniques can be used to extend the resolution of 8- or 10-

bit converters by 2 or 3 bits.

situation where this might occur is if moisture gets in direct

contact between electrodes, or between an electrode and

ground or shield drive. The signal is generated with a DC

offset that is more than half the peak-to-peak level. This

keeps the signal positive above ground at all times. The

detector uses this voltage level as the midpoint for detection.

All signals below this level are inverted and added to all

signals above this level. Loading of the DC level will cause

some of the positive half of the signal to be inverted and

added and will change the measurement.

have a high DC resistance to ground source, a series

capacitor of about 10 nF should be connected between the IC

electrode terminals and the electrodes. This capacitor will

block DC bias voltages to the detector. Note that it is also

advisable to add a DC blocking capacitor in series with the

Shield Driver output as well.

Another approach is to run long term averaging of the

The MC33794 does not contain an ADC. It is intended to

DC loading on the electrodes should be avoided. A typical

If it is not possible to assure that the electrodes will always

MC33794

MC33794EKR2 Freescale, MC33794EKR2 Datasheet - Page 13

MC33794EKR2

Specifications of MC33794EKR2

Available stocks

Related parts for MC33794EKR2