TDA5240 Datasheet, PDF(28/284 Page) Infineon Technologies AG – Enhanced Sensitivity Multi-Channel Quad-Configuration Receiver

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

TDA5240 Datasheet, PDF (28/284 Pages) Infineon Technologies AG – Enhanced Sensitivity Multi-Channel Quad-Configuration Receiver

◁

TDA5240

Functional Description

2.4.6.2 FSK Demodulator

The limiter output signal, which has a constant amplitude over a wide range of the input

signal, feeds the FSK demodulator. There is a configurable lowpass filter in front of the

FSK demodulation to suppress the down conversion image and noise/limiter harmonics

(FSK Pre-Demodulation Filter, PDF). This is realized as a 3rd order digital filter. The

sampling rate after FSK demodulation is fixed and independent from the target data rate.

2.4.6.3 Automatic Frequency Control Unit (AFC)

In front of the image suppression filter a second FSK demodulator is used to derive the

control signal for the Automatic Frequency Control Unit, which is actually the DC

value of the FSK demodulated signal. This makes the AFC loop independent from signal

path filtering and allow so a wider frequency capture range of the AFC. The derivation of

the AFC control signal is preferably done during the DC free preamble and is then frozen

for the rest of the datagram.

Since the digital FSK demodulator determines the exact frequency offset between the

received input frequency and the programmed input center frequency of the receiver,

this offset can be corrected through the sigma delta control of the PLL. As shown in

Figure 10, for AFC purposes a parallel demodulation path is implemented. This path

does not contain the digital low pass filter (PDF, Pre-Demodulation Filter). The entire IF

bandwidth, filtered by the analog bandpass filter only, is processed by the AFC

demodulator.

There are two options for the active time of the AFC loop:

â¢ 1. always on

â¢ 2. active for a programmable time relative to a signal identification event (several

options can be programmed in SFR).

In the latter case the AFC can either be started or frozen relative to the signal

identification. After the active time the offset for the sigma-delta PLL (SD PLL) is frozen.

The programming of the active time is especially necessary in case the expected frame

structure contains a gap (noise) between wake-up and payload in order to avoid the AFC

from drifting.

AFC works both for FSK and ASK. In the latter case the AFC loop only regulates during

ASK data = high.

The maximum frequency offset generated by the AFC can be limited by means of the

x_AFCLIMIT register. This limit can be used to avoid the AFC from drifting in the

presence of interferers or when no RF input signal is available (AFC wander). A

maximum AFC limit of 42 kHz is recommended. AFC wandering needs to be kept in mind

especially when using Run Mode Slave.

Data Sheet

28

V4.0, 2010-02-19

▷