Abstract:
This article presents a novel cross-layer design strategy for tactical software-defined radio
(SDR) networks. The approach takes into consideration the stringent criteria regarding
latency, throughput, and dependability. An Adaptive Multi-Input-Output Medium
Access Control (AMIO-MAC) protocol, an intelligent channel allocation method, and a
hybrid physical layer that is multi-mode and multi-band powered by a cognitive engine
are the components that make up the system that has been presented. SDR is able
to function in a hybrid topology, thanks to the physical layer’s innovative usage of a
mixed combination of narrow-band and wide-band waveforms to satisfy differing range
needs. This makes the physical layer one of a kind. The AMIO-MAC design guarantees
a decrease in both the control phase and the data phase delay, while the MAC layer
assures that the most of the time and frequency spectrum is utilized. Bandwidth and
latency optimization are managed by the suggested trio consisting of the physical layer,
the MAC layer, and cognition to achieve the quality of service that is required. The results
of the simulation illustrate that the proposed design is superior to the conventional
method of tactical radio MAC. The overall objective of the cross-layer design strategy
that has been advocated for SDR networks is to achieve high throughput, improved
quality of service, and flexible range capabilities. A hybrid physical layer that is capable
of simultaneously supporting multiple bands has been proposed. A technique for the
MAC layer that enables the software-defined radio to transmit data to numerous users
who are operating on various bands within a single time slot by using the hybrid physical
layer’s capability to its greatest potential. In comparison to a conventional tactical radio
network, this will result in decreased latency as well as a shorter scheduling period.
