U4222B Datasheet, PDF(4/9 Page) TEMIC Semiconductors

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U4222B Datasheet, PDF (4/9 Pages) TEMIC Semiconductors – Radio Controlled Clock Receiver

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U4222B

TELEFUNKEN Semiconductors

There is some consideration concerning the calculation of

Rres:

in order to achieve high signal voltage:

Rres should be high

in order to achieve low antenna noise voltage:

Rres should be low

W Rres < 200 k :

the input noise voltage of A 1 dominates

W Rres > 300 k :

the antenna noise voltage dominates

That means the resonant resistance should be between

W 200 k and 300 kW.

Q of antenna must be high for attenuation of interfering

signals. But the temperature must not influence the

resonance frequency.

Design Hints for the Ferrite Antenna

The bar antenna is the most critical device of the complete

clock receiver. But by observing some basic rf design

knowledge, no problem should arise with this part. The IC

requires a resonance resistance of 200 kW to 300 kW. This

can be achieved by a variation of the L/C-relation in the

antenna circuit. But it is not easy to measure such high

resistances in the RF region. It is much more convenient

to distinguish the bandwidth of the antenna circuit and

afterwards to calculate the resonance resistance.

Thus the first step in designing the antenna circuit is to

measure the bandwidth. Figure 4. shows an example for

the test circuit. The RF signal is coupled into the bar

antenna by inductive means, e.g. a wire loop. It can be

measured by a simple oscilloscope using the 10:1 probe.

The input capacitance of the probe, typically about 10 pF,

should be taken into consideration. By varying the

frequency of the signal generator, the resonance

frequency can be determined.

RF - Signal

generator

40 kHz

Scope

wire loop

Cres

Probe

10 : 1

94 8049 e

Figure 4.

Afterwards, the two frequencies where the voltage of the

RF signal at the probe drops 3 dB down can be measured.

The difference between these two frequencies is called

the bandwidth BWA of the antenna circuit. As the value

of the capacitor Cres in the antenna circuit is well known,

it is easy to compute the resonance resistance according

to the following formula:

+ @ @ @ Rres

p BWA Cres

whereas

Rres is the resonance resistance,

BWA is the measured bandwidth (in Hz)

Cres is the value of the capacitor in the antenna circuit

(in Farad)

If high inductance values and low capacitor values are

used, the additional parasitic capacitances of the coil

must be considered. It may reach up to about 20 pF. The

Q-value of the capacitor should be no problem if a high

Q-type is used. The Q-value of the coil is more or less

distinguished by the simple DC-resistance of the wire.

Skin effects can be observed but do not dominate.

Therefore it should be no problem to achieve the

recommended values of resonance resistance. The use of

thicker wire increases Q and accordingly reduces

bandwidth. This is advantageous in order to improve

reception in noisy areas. On the other hand, temperature

compensation of the resonance frequency might become

a problem if the bandwidth of the antenna circuit is low

compared to the temperature variation of the resonance

frequency. Of course, Q can also be reduced by a parallel

resistor.

Temperature compensation of the resonance frequency is

a must if the clock is used at different temperatures.

Please ask your dealer of bar antenna material and of

capacitors for specified values of temperature coefficient.

Furthermore some critical parasitics have to be

considered. These are shortened loops (e.g. in the ground

line of the PCB board) close to the antenna and undesired

loops in the antenna circuit. Shortened loops decrease Q

of the circuit. They have the same effect like conducting

plates close to the antenna. To avoid undesired loops in

the antenna circuit it is recommended to mount the

capacitor Cres as close as possible to the antenna coil or

to use a twisted wire for the antenna coil connection. This

twisted line is also necessary to reduce feedback of noise

from the microprocessor to the IC input. Long connection

lines must be shielded.

For the adjustment of the resonance frequency the

capacitance of the probe and the input capacitance of the

IC are to be taken into account. The alignment should be

done in the final environment. The bandwidth is so low

that metal parts close to the antenna influence the

resonance frequency. The adjustment can be done by

pushing the coil along the bar antenna.

4 (9)

Preliminary Information

Rev. A1: 07.08.1995

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