Performance study of differential frequency hopping systems over a Rayleigh-faded channel in the presence of jamming
Differential frequency hopping (DFH) is a novel technique employed by the correlated hopping enhanced spread spectrum (CHESS) radio, developed by the Sanders Company. The core of the DFH technique is in its frequency transition function (FTF), which generates a sequence of correlated freque...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2013
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/53276 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Differential frequency hopping (DFH) is a novel technique employed by the
correlated hopping enhanced spread spectrum (CHESS) radio, developed by the
Sanders Company. The core of the DFH technique is in its frequency transition
function (FTF), which generates a sequence of correlated frequency hops
corresponding to the input information sequence. As a result, DFH systems are able
to reconstruct missed hops in the detection process.
This Final Year Project (FYP) report documents the investigations of the bit-error
performance of DFH systems in Rayleigh-fading channels in the presence of partialband
noise jamming (PBNJ). The bit-error performance of fast frequency-hopped
(FFH) systems employing binary frequency-shift keying (BFSK) corrupted by the
worst-case PBNJ, additive white Gaussian noise (AWGN) and Rayleigh-fading
channels is also investigated and acts as supplementary materials for the
investigation of DFH systems. Four different designs of FTF encoders for DFH
systems are investigated in this FYP.
Simulation results obtained show that DFH systems outperform conventional
FFH/BFSK systems when corrupted by the worst-case PBNJ and AWGN. The
improved performance is due to the error correcting characteristic of DFH systems.
When operating in Rayleigh-fading channels corrupted with the worst-case PBNJ,
DFH systems, depending on the type of FTF encoder employed, exhibits better
performance as compared to FFH/BFSK systems with a diversity level of one.
However, it is observed that the performance of DFH systems vary with the four
different encoder types. Therefore, it can be concluded that the design of the FTF
plays a key role in dictating the performance for DFH systems. |
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