Abstract
Spread Spectrum systems are found in many flavours, used in many applications and have
existed since the early days of radio communications. The properties of spread spectrum do
however place restrictions on the design, and often make the implementation expensive and
complex. When using spread spectrum to provide a basic communications infrastructure,
many factors need to be considered. These indude supplying the appropriate technology
at the right cost. To achieve this a trade-off against performance is often required.
One of the more difficult aspects of Spread Spectrum design is the synchronisation of the
spreading waveform. The primary characteristic of pseudonoise sequence synchronisation is
the need for two levels of synchronisation namely acquisition {course synchronisation) and
tracking (fine synchronisation). In these networks (the term network is used to describe
a circuit or system throughout the thesis.) a decision is required to switch between the
two synchronisation modes. The two layer structure of the typical pseudonoise sequence
5,Ynchronisation network can increase the overall cost of spread spectrum systems. The
objective of the research was therefore to find solutions to reduce the overall cost and
complexity of the synchronisation network. The synchronisation structure should perform
acquisition and tracking in a single structure, and thereby be low cost.
To achieve the primary objective of this dissertation a. mi.xture of theory, simulations and
practical implementation was used. The basis of the investigation was a time-variant spectral
evaluation of pseud~noise sequences. It is shown that by multiplying a differentiated
pseudonoise sequence with another pseudonoise sequence, useful information is obtained
that can form the basis of a synchronisation network.
Using the conclusions drawn from this investigation, a low cost synchronisation network
wa.S proposed. The network was simple in design and through simulation was shown to
achieve the accurate synchronisation in one structure. The network was also implemented
and was shown to work. However, the network was parameter sensitive and not robust .
. -. second structure based on the same principles was proposed. This network was shown.
through simulation and practical results, to be effective, low cost and achieved the primary
objective.
The low-cost synchronisation network is highly non-linear and therefore the use of linear
techniques to analyse the network is not possible. The non-linear equation for the synchronisation
network was derived and phase-plane techniques were applied. The chaotic
nature of the network was clearly illustrated. Using phase-plane plots the effect of various
parameters on the synchronisation of spreading sequences was illustrated
One important result of this analysis was how the network evaluates the, code-phase -
frequency grid. This grid is a representation of the tracking space for spread spectrum
synchronisation networks. The traditional methods used to perform course acquisition
evaluate the grid uniformally and deterministically. The novel low cost synchronisation
network evaluates this grid in a random fashion.
The low cost spread spectrum synchronisation network was compared to the methods discussed
in the literature. Based on a number of assumptions, locking times were compared
and it was shown that the novel synchronisation network's locking times were of the same
order.
One of the short-comings of the basic network is that it is sensitive to data modulation. This
is a common problem with networks not using energy detectors. The problem was solved
using a mixture of correlation and digital circuitry. The detection circuitry altered the loop
conditions and with that improved the noise performance of the low cost synchronisation
network. The effect of noise and carrier tracking on the novel low cost synchronisation
network was also investigated. The network was evaluated down to an input signal-to-noise
ratio of -18 dB, where it still achieved lock. It is important to realize that due to the
structure of the synchronisation network it is more suited to low-noise spread spectrum
applications.
While implementing the network;·a novel low cost square-wave differentiator was designed.
This signed edge detector has a number of advantages over standard differentiators. It
is wide-band, with the only limiting factors being the speed of the logic gates and the
bandwidth of the multiplier. It is also shown to perform better at lower signal-to-noise ratios.
Other practical aspects that were investigated in the search for a low cost synchronisation
network, was the synchronous oscillator (a form of an injection-locked oscillator with a
constant output amplitude).
The novel low cost spread spectrum synchronisation network achieved its objective of offering
a single solution to acquisition and tracking without the need for an intermediate
decision stage. The network was shown to operate at an input signal-to-noise ratio of -18
dB (in half the simulation bandwidth) and was shown to deal effectively with data modulation.
The network is also low cost and easy to implement. It is important to realize that due
to the structure of the synchronisation network, it is more suited to higher signal-to-noise
ratio applications.
van, . (2021). Novel Low Cost Synchronisation Network For Spread Spectrulyi Systelvis. Afribary. Retrieved from https://tracking.afribary.com/works/novel-low-cost-synchronisation-network-for-spread-spectrulyi-systelvis
Van, .Joannes "Novel Low Cost Synchronisation Network For Spread Spectrulyi Systelvis" Afribary. Afribary, 15 May. 2021, https://tracking.afribary.com/works/novel-low-cost-synchronisation-network-for-spread-spectrulyi-systelvis. Accessed 24 Nov. 2024.
Van, .Joannes . "Novel Low Cost Synchronisation Network For Spread Spectrulyi Systelvis". Afribary, Afribary, 15 May. 2021. Web. 24 Nov. 2024. < https://tracking.afribary.com/works/novel-low-cost-synchronisation-network-for-spread-spectrulyi-systelvis >.
Van, .Joannes . "Novel Low Cost Synchronisation Network For Spread Spectrulyi Systelvis" Afribary (2021). Accessed November 24, 2024. https://tracking.afribary.com/works/novel-low-cost-synchronisation-network-for-spread-spectrulyi-systelvis