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precision Mechatronics systems and algorithms. Ability to develop kinematic and/or dynamic analysis of Mechanical/Robotic systems. Ability to implement control and kinematics with hardware-in-the–loop
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modelling of the gut microbiome. This is a unique opportunity to work within a dynamic, multidisciplinary team of microbiologists, clinicians, and molecular scientists with a strong track record in
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. Experience with molecular dynamics software such as LAMMS is desirable. Experience with molecular simulation software is beneficial. To apply please contact Dr Siperstein - flor.siperstein@manchester.ac.uk
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tuition fees. This PhD project in the area of autonomy, navigation and artificial intelligence, aims to advance the development of intelligent and resilient navigation systems for autonomous transport
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. This project seeks to enhance the phase-field method, enabling more accurate predictions of fracture under dynamic conditions. State-of-the-art computational techniques combined with insights from advanced
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approach to understanding material performance. The outcomes of this research could guide the development of new refractory alloys and coating systems critical for future aerospace technologies, directly
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management and business model innovation in SMEs The aim of this project is to study how entrepreneurial firms engage with IP strategy in the context of dynamic technological disruption and their ecosystems. A
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dynamic and uncertain environments [1]. A key application of such systems is in the Internet of Things (IoT), where networked sensors and actuators enable real-time adaptation to environmental changes
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Imperial College London is proud to be part of "AUREUS", an international collaboration consisting of nine leading academic institutions and four prominent industry partners across Europe. Recently
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integrates dynamic “smart” materials into 3D-printed structures, opens new frontiers in both bioelectronics and solar energy harvesting. Our goal is to create adaptive electrode architectures. These advanced