Solution for congested networks

The Network Traffic Oscillator (NTO) is a concept that combines network switching and routing seamlessly together. These two concepts have fundamentally different operations. The former refers to packet transmission control using network addresses such as Internet Protocol (IP) to send data from source to destination. On the other hand, the latter refers to external factors concerning the steering of data transmission via the best route on a network. Thus, network switching focuses on the delivery of traffic whilst network routing focuses on managing network capacity.

Custom applications that use multi-purposed packet protocols such as User Datagram Protocol (UDP), IP, and Ethernet, have no network troubleshooting tools or responses to network faults. The only defence against missing data is left to the transport or the application layer, which are ineffective when the missing data are lost as a result of networking issues.

We are currently in the process of safety critical networking progressing from small network to large ones with hundreds of routes and nodes. In this scenario, greater delays are introduced from switching, routing and applications rather than from the physical constraints of the communication medium. In the air traffic context, the introduction of SWIM has leads to many modern communication problems, particular in network switching, routing and application load traffic management.

While tools such as EIGRP have addressed these issues with traffic management by configuring an active routing plan (via the K-values and resultant vector metric) to stave off transmission disasters, these tools are poorly utilised given the modern plethora of application traffic types. Our algorithm shows how to increase data throughput by considering additional parameters such as the application bandwidth usage, and the synchronisation between receiver and transmitter response time.

In comparison with EIGRP, this system offers a reduction of tens of percent in the delay time coupled with a narrow spread in this response. Moreover, as a result only 1% of packets experience problematic transmission delays compared to 10% using EIGRP. This is a great improvement QoS via the improved response time and removal of unnecessary bandwidth wastage from delays and retransmission.