Dublin City University

About: Dublin City University is a education organization based out in Dublin, Ireland. It is known for research contribution in the topics: Machine translation & Laser. The organization has 5904 authors who have published 17178 publications receiving 389376 citations. The organization is also known as: National Institute for Higher Education, Dublin & DCU.

In-situ sensing, process monitoring and machine control in Laser Powder Bed Fusion: A review

Abstract: Process monitoring and sensing is widely used across many industries for quality assurance, and for increasing machine uptime and reliability. Though still in the emergent stages, process monitoring is beginning to see strong adoption in the additive manufacturing community through the use of process sensors recording a wide range of optical, acoustic and thermal signals. The ability to acquire these signals in a holistic manner, coupled with intelligence-based machine control has the potential to make additive manufacturing a robust and competitive alternative to conventional fabrication techniques. This paper presents an overview of the state-of the art of in-situ process monitoring in laser powder bed fusion processes and highlights some current limitations and areas for advancement. Also presented is an overview of real-time process control requirements, which when combined with the emergent process monitoring tools, will eventually allow for in-depth process control of the powder bed fusion process, which is essential for wide-scale industrial credibility and adoption of this technology.

Thirty years of computational autopoiesis: a review.

Abstract: Computational autopoiesis—the realization of autopoietic entities in computational media—holds an important and distinctive role within the field of artificial life. Its earliest formulation by Francisco Varela, Humberto Maturana, and Ricardo Uribe was seminal in demonstrating the use of an artificial, computational medium to explore the most basic question of the abstract nature of living systems—over a decade in advance of the first Santa Fe Workshop on Artificial Life. The research program it originated has generated substantive demonstrations of progressively richer, lifelike phenomena. It has also sharply illuminated both conceptual and methodological problems in the field. This article provides an integrative overview of the sometimes disparate work in this area, and argues that computational autopoiesis continues to provide an effective framework for addressing key open problems in artificial life.

Stabilization of brain microvascular endothelial barrier function by shear stress involves VE‐cadherin signaling leading to modulation of pTyr‐occludin levels

Abstract: Blood-brain barrier (BBB) regulation involves the coordinated interaction of intercellular adherens and tight junctions in response to stimuli. One such stimulus, shear stress, has been shown to upregulate brain microvascular endothelial cell (BMvEC) barrier function, although our knowledge of the signaling mechanisms involved is limited. In this article, we examined the hypothesis that VE-cadherin can transmit shear signals to tight junction occludin with consequences for pTyr-occludin and barrier function. In initial studies, chronic shear enhanced membrane localization of ZO-1 and claudin-5, decreased pTyr-occludin (in part via a dephostatin-sensitive mechanism), and reduced BMvEC permeability, with flow reduction in pre-sheared BMvECs having converse effects. In further studies, VE-cadherin inhibition (VE-cad ΔEXD) blocked shear-induced Rac1 activation, pTyr-occludin reduction, and barrier upregulation, consistent with an upstream role for VE-cadherin in transmitting shear signals to tight junctions through Rac1. As VE-cadherin is known to mediate Rac1 activation via Tiam1 recruitment, we subsequently confirmed that Tiam1 inhibition (Tiam1-C580) could elicit effects similar to VE-cad ΔEXD. Finally, the observed attenuation of shear-induced changes in pTyr-occludin level and barrier phenotype following Rac1 inhibition (NSC23766, T17N) establishes a downstream role for Rac1 in this pathway. In summary, we describe for the first time in BMvECs a role for VE-cadherin in the transmission of physiological shear signals to tight junction occludin through engagement of Tiam1/Rac1 leading to barrier stabilization. A downstream role is also strongly indicated for a protein tyrosine phosphatase in pTyr-occludin modulation. Importantly, these findings suggest an important route of inter-junctional signaling cross-talk during BBB response to flow.

Real-time intrusion detection for ad hoc networks

Abstract: A mobile ad hoc network is a collection of nodes that are connected through a wireless medium and form rapidly changing topologies. The widely accepted existing routing protocols designed to accommodate the needs of such self-organised networks do not address possible threats aimed at the disruption of the protocol itself. The assumption of a trusted environment is not one that can be realistically expected; hence several efforts have been made towards the design of a secure routing protocol for ad hoc networks. The main problems with this approach are that it requires changes to the underlying routing protocol and that manual configuration of the initial security associations cannot be completely avoided. We propose RIDAN, a novel architecture that uses knowledge-based intrusion detection techniques to detect, in real-time, attacks that an adversary can perform against the routing fabric of a mobile ad hoc network. Our system is designed to take countermeasures minimising the effectiveness of an attack and maintaining the performance of the network within acceptable limits. RIDAN does not introduce any changes to the underlying routing protocol since it operates as an intermediate component between the network traffic and the utilised protocol with minimum processing overhead. We have developed a prototype that was evaluated in AODV-enabled networks using the ns-2 network simulator.