DCU Researchers Win Top International Paper Prize

DCU laser micromachining researchers have won the top application prize for their published paper on laser micromachining at the NI Days Worldwide Virtual Instrumentation Conference in London.

Over the last five years Dr. Dermot Brabazon, Dr. Ahmed Issa and Prof. Saleem Hashmi of the School of Mechanical and Manufacturing Engineering and the Materials Processing Research Centre (MPRC) have developed two laser micromachining processes which allow for the production of channels and voxels with highly repeatable micrometer level resolution. Devices fabricated with this developed technology can be used for applications such as microfluidic lab on a chip, strain measurement, sub-micrometer cooling systems and various photonic guiding systems.

The paper was entitled, Laser System Automation using LabVIEW and PCI E-Series Board for 3D Internal Micromachining. This work illustrated the sophisticated automated 3D Nd:YVO4 and CO2 laser micro fabrication facilities that were developed. In order to achieve the precise control, CAD processing, laser firing, 3D sample movement and thermal field modelling software were developed. In addition, in order to characterise the high efficiency achieved from these processes, an in house built automated channel and voxel profiler was used.

NI Days, which has been running for the past decade, gives engineers and scientists from across the UK & Ireland an opportunity to learn how the latest developments in computer-based measurement and automation increase productivity and lower cost through graphical system design and virtual instrumentation

The prize includes flight and accommodation to NI Week in Austin, TX, next year, a plaque and LEGO Mindstorms NXT.

Congratulations to Puspita Deo

Congratulations to Puspita Deo who successfully defended her thesis and will be awarded the degree of PhD.

The title of Puspita's thesis is "Heterogeneous Motorised Traffic Flow Modelling using Cellular Automata".

She completed her PhD in the Modelling & Scientific Computing Group, School of Computing, DCU under the supervision of Professor Heather Ruskin.

Brief description of Project:

Traffic congestion is a major problem in most major cities around the world with few signs that this is diminishing, despite management efforts. In planning traffic management and control strategies at urban and inter urban level, understanding the factors involved in vehicular progression is vital. Most work to date has, however, been restricted to single vehicle-type traffic. Study of heterogeneous traffic movements for urban single and multi-lane roads has been limited, even for developed countries and motorised traffic mix, (with a broader spectrum of vehicle type applicable for cities in the developing world). The aim of the research, was thus to propose and develop a model for heterogeneous motorised traffic, applicable to situations, involving common urban and interurban road features in the western or developed world. A further aim of the work was to provide a basis for comparison with current models for homogeneous vehicle type.

A two-component cellular automata (2-CA) methodology is used to examine traffic patterns for single-lane, multi-lane controlled and uncontrolled intersections and roundabouts. In this heterogeneous model (binary mix), space mapping rules are used for each vehicle type, namely long (double-unit length) and short (single-unit length) vehicles. Vehicle type is randomly categorised as long (LV) or short (SV) with different fractions considered. Update rules are defined based on given and neighbouring cell states at each time step, on manoeuvre complexity and on acceptable space criteria for different vehicle types. Inclusion of heterogeneous traffic units increases the algorithm complexity as different criteria apply to different cellular elements, but mixed traffic is clearly more reflective of the real-world situation.

The impact of vehicle mix on the overall performance of an intersection and roundabout (one-lane one-way, one-lane two-way and two-lane two-way) has been examined. Investigation of performance metrics for heterogeneous traffic (short and long vehicles), can be shown to reproduce main aspects of real-world configuration performance. This has been validated, using local Dublin traffic data.

The developed model has potential to extend its use to linked transport network elements and can also incorporate further motorised and non-motorised vehicle diversity for various road configurations.

This project was funded by the School of Computing, DCU.