1.1 Motivation
Current linear and planar phased array radar technologies are limited to range-independent direc-
tivity. However, this limits the radar performance to mitigate non-desirable range-dependent signal
sources and thus its ability to discern targets of interests from background noise or interference. By
introducing frequency diversity at the element level, we can increase the degrees of freedom in the
domain space to achieve range dependent beam steering. This is realizable with the FDA concept.
Additionally, frequency diversity could be used to fulfill simultaneous mission requirements.
For example, a spatial linear frequency modulation (LFM), which is simply another way of thinking
about the FDA concept, could be used to image a scene while the composite signal response could
be assigned to tracking or acquisition or another radar function. This is a step towards maximizing
the information output by using domain diversity and again, FDA is aptly suited for this business.
This is one example, and given that FDA as a topic of interest is relatively new, it is likely that
possible applications are only beginning to present themselves.
1.2 Contribution
In this thesis, we extend the field of FDA research to develop efficient receiver architectures by in-
vestigating transmit and receive architectures for multiple configurations and comparing directivity
responses. To begin, we investigate the uniform linear array on transmit and receive with frequency
diversity at each element.
Secondly, we propose a planar array with frequency offsets along both axes such that a linear
increase is witnessed in both dimensions. We also propose a receiver architecture that allows beam-
forming on receive to include all frequencies from a planar geometry. This will allow the receiver to
maximize the signal-to-noise ratio for the available power and the signal structure herein is flexible
enough to include other frequency progressions or waveform types although not investigated in this
thesis.
Lastly, we present a technique designed for multi-mission, multi mode systems to use multiple
beams with frequency diversity by deploying coding as a method to separate range-dependent main
beam structures.
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