B.10 uncoded operation (no fec) – Comtech EF Data CDM-625A User Manual

CDM-625A Advanced Satellite Modem

MN-CDM625A

Appendix B

Revision 3

B–20

B.10 Uncoded Operation (No FEC)

CAUTION – Comtech EF Data strongly cautions users when using uncoded operation.

If the acquisition sweep width exceeds one quarter of the symbol rate, there is a

very high probability that the demodulator will false lock.
Example: If selecting 64 kbps QPSK, uncoded, the symbol rate will be half of this

rate, or 32 ksymbols/second. One quarter of this equals 8 kHz. Therefore, the
absolute maximum acquisition sweep range that should be considered is ± 8 kHz. If

there is any frequency uncertainty on the incoming carrier, this should be subtracted

from the sweep width. The problem becomes progressively better with increasing

symbol rate.

Comtech EF Data cannot be held responsible for incorrect operation if you do not

adhere to these guidelines when using uncoded operation.

There are occasions where a user may wish to operate a satellite link with no forward error

correction of any kind. For this reason, the CDM-625A offers this uncoded mode for three

modulation types – BPSK, QPSK, and OQPSK. However, you should be aware of some of the

implications of using this approach.

PSK demodulators have two inherent undesirable features. The first, known as ‘phase

ambiguity’, is due to the fact the demodulator does not have any absolute phase reference and,

in the process of carrier recovery, the demodulator can lock up in any of K phase states where K

= 2 for BPSK, K = 4 for QPSK. Without the ability to resolve these ambiguous states, there would

be a 1-in-2 chance that the data at the output of the demodulator would be wrong in the case of

BPSK. For QPSK, the probability would be 3-in-4.

The problem is solved in the case of BPSK by differentially encoding the data prior to

transmission, then performing the inverse decoding process. This is a very simple process, but

has the disadvantage that it doubles the receive BER. For every bit error the demodulator

produces, the differential decoder produces two.

The problem for QPSK is more complex, as there are four possible lock states leading to four

ambiguities. When FEC is employed, the lock state of the FEC decoder can be used to resolve

two of the four ambiguities, and the remaining two can be resolved using serial differential

encoding/decoding. However, when no FEC is being used, an entirely different scheme must be

used. Therefore, in QPSK, a parallel differential encoding/decoding technique is used, but has

the disadvantage that it again doubles the receive BER.

OQPSK is a different situation again, where the ambiguities result not only from not having an

absolute phase reference, but also not knowing which of the two parallel paths in the demod, I

or Q, contains the half-symbol delay. Another type of differential encoding is used, but yet again

the error rate is doubled, compared to ideal.

Whenever uncoded operation is selected, the modem offers the choice between

enabling and disabling the differential encoder/decoder appropriate for the

modulation type.