• University of Surrey Featured PhD Programmes
  • University of Southampton Featured PhD Programmes
  • University College London Featured PhD Programmes
  • University of East Anglia Featured PhD Programmes
  • University of Glasgow Featured PhD Programmes
  • National University of Singapore Featured PhD Programmes
  • Northumbria University Featured PhD Programmes
  • University of Warwick Featured PhD Programmes
Brunel University London Featured PhD Programmes
University of Huddersfield Featured PhD Programmes
Cardiff University Featured PhD Programmes
University of Glasgow Featured PhD Programmes
Heriot-Watt University Featured PhD Programmes

A hybrid-systems approach to uncover complex networks behaviour

This project is no longer listed in the FindAPhD
database and may not be available.

Click here to search the FindAPhD database
for PhD studentship opportunities
  • Full or part time
    Dr E Navarro-Lopez
  • Application Deadline
    Applications accepted all year round
  • Competition Funded PhD Project (Students Worldwide)
    Competition Funded PhD Project (Students Worldwide)

Project Description

A synchronised school of fish swimming in the sea; a network of computer systems; the evolution of a flock of birds; the controlled motion of swarm satellites; the cooperation of several robotic systems to accomplish a common goal; social networks; water or electrical power distribution systems: these are examples of complex networks and collective behaviour. That is, a group of systems (normally, a big number of them) interconnected in a non-trivial and non-regular way. The key aspect of these networks is the complex nature of their interconnection topology, which defines the behaviour of the overall structure and entails the onset of complex dynamical phenomena not present in the individual systems.

Two key ideas are pivotal to propose a model for these systems: 1) individual elements following elementary behavioural rules can produce complex behavioural patterns, and 2) in many cases, individual elements achieve a global goal with minimal communication with other elements in the network, and without having a complete picture of the overall structure. This type of behaviour implies different discrete transitions and the interaction of different types of dynamics (discrete and continuous). Consequently, the hybrid-systems framework - characterised by the coupling of continuous-type and discrete-event dynamics - seems to be very adequate to improve the existing models of complex networks and to give answers to many questions concerning the stability of the network and its structure.The goal of this PhD project is to formulate the evolution and dynamical behaviour of complex networks within the hybrid-systems framework. The ultimate goal is to design robust and resilient systems, that is, systems capable of preserving stability and recovering from faults. The control or decision-making techniques to explore fall into distributed, cooperative and networked control techniques. This research covers multiple emerging applications from robotic systems to transportation and distribution networks, and from high-confidence healthcare to national security.

Funding Notes

Candidates who have been offered a place for PhD study in the School of Computer Science may be considered for funding by the School. Further details on School funding can be found at: http://www.cs.manchester.ac.uk/study/postgraduate-research/programmes/phd/funding/school-studentships/.


The minimum requirements to get a place in our PhD programme are available from:

How good is research at University of Manchester in Computer Science and Informatics?

FTE Category A staff submitted: 44.86

Research output data provided by the Research Excellence Framework (REF)

Click here to see the results for all UK universities

Cookie Policy    X