Nonlinear waves at free surfaces of viscous liquids and within stratified interfaces

Monday January 13th at 14:00 

Wolfson Building of Mechanical Engineering, Room 206

Abstract:

Modelling mass and energy exchange between fluids often involves solving free boundary problems, where the computational domain is unknown a priori, and the fluid interface must be determined during the solution process. These interfaces can exhibit instability, leading to the formation of propagating or standing waves. This lecture will explore two problems demonstrating different wave patterns in dispersive and non-dispersive systems with viscous liquids.

The first problem focuses on the modelling of a circular hydraulic jump, which occurs when a liquid jet hits a plane and spreads symmetrically as a thin, fast-flowing film. This phenomenon is relevant for numerous applications involving heat and mass exchange, coating technologies being important examples. Circular hydraulic jump also serves as a laboratory model for astrophysical phenomena where the governing equations resemble those used in shallow-water theory. Several approaches to describe and control this flow will be discussed, including the effect of external body forces on the evolution of the jump.

The second problem examines resonant standing waves at the interface between two deep fluid layers (the liquid-gas boundary and the mixed layer between two liquids with slightly different densities are considered). The waves are generated by a small vertically oscillating body, with the forcing frequency being slightly different from the system's natural eigenfrequencies. A model that simplifies the system to a finite number of degrees of freedom will be presented, predicting how detuning from the dispersion relation leads to a superposition of multiple spatial modes. The effects of stratification within the mixed layer will also be explored, with the identification of localized internal waves.

Bio:

Evgeny Mogilevskiy earned his M.Sc. in Mechanics (with honors) in 2005 and a PhD in Fluid Mechanics in 2009 from the Lomonosov Moscow State University. After a postdoctoral fellowship at the University of Leuven in Belgium in 2014 he returned to the Moscow University as a faculty member at the Faculty of Mechanics and Mathematics. There, he led a research group focused on the investigation of free-surface viscous flows, their stability, and wavy flow regimes. In 2022, he repatriated to Israel, where, after a three-month appointment as a visiting scientist at the Weizmann Institute of Science, he joined the School of Mechanical Engineering at Tel Aviv University as a researcher. The lecture presents an overview of research carried out at both Moscow and Tel Aviv Universities.

Propeller Design – Novel Methods for Ancient Apparatus

Monday December 30th at 14:00 

Wolfson Building of Mechanical Engineering, Room 206

Abstract:

The primal propulsion apparatus, the propeller, has gained renewed popularity in recent years due to the flourishing of unmanned air vehicles, urban air mobility, and electric propulsion systems. The seminar will present the basic requirements of a propeller as an aerial propulsion apparatus. Propeller design should consider several fields, such as aerodynamics, structure, acoustics, engine matching, vehicle interaction, and performance. While analysis methods for most of these disciplines remained unchanged during the last decades, the design method improved substantially by harnessing the capabilities of multidisciplinary design optimization tools. This is accomplished by harnessing fundamentals and accurate methods from various fields into a unified framework. Then, advanced optimization algorithms search for a suitable solution.

The seminar will review some of the challenges and solutions of such design processes and demonstrate their efficiency and accuracy for this complex multi-objective, multi-constraint design problem.

From time to time, exotic and odd configurations are suggested by ignoring basic engineering principles and neglecting the proper engineering design procedure. The talk will demonstrate this for several quasi-attractive, unorthodox propeller designs.

Bio:

Ohad earned his BSc MSc and PhD from the Technion—IIT, Faculty of Aerospace Engineering.

For the past 15 years, Ohad has been an aeronautical engineer in IAI, Isreal Aerospace Industries.

Previously, he worked in the Israeli Air Force, BVR Systems, and Virginia Tech University.

Recently, his book Propeller Design was published under the AIAA Educational Series. This book summarizes three decades of mastering propeller design.

Towards Smarter Swarms: Optimizing Search Patterns and

Exploration with AI-Driven Frameworks

Monday December 16th at 14:00 

Wolfson Building of Mechanical Engineering, Room 206 

Abstract:

This research investigates the performance and efficiency of multi-agents in multi-target tracking scenarios using the Adaptive Particle Swarm Optimization with k-Nearest Neighbors (APSO-kNN) algorithm. The study explores various search patterns-Random Walk, Spiral, Lawnmower, and Cluster Search to assess their effectiveness in dynamic environments. Through extensive simulations, we evaluate the impact of different search strategies, varying the number of targets and agent’s sensing capabilities, and integrating a Pursuit-Evasion model to test adaptability. Our findings demonstrate that systematic search patterns like Spiral and Lawnmower provide superior coverage and tracking accuracy, making them ideal for thorough area exploration. In contrast, the Random Walk pattern, while highly adaptable, shows lower accuracy due to its non-deterministic nature, and Cluster Search maintains group cohesion but is heavily dependent on target distribution. The mixed strategy, combining multiple patterns, offers robust performance across varied scenarios, while APSO-kNN effectively balances exploration and exploitation, making it a promising approach for real-world applications such as surveillance, search and rescue, and environmental monitoring. This study provides valuable insights into optimizing search strategies and sensing configurations for swarms, ultimately enhancing their operational efficiency and success in complex environments.

On the second part of this talk, we address the challenge of exploring unknown indoor environments using autonomous aerial robots with Size Weight and Power (SWaP) constraints. The SWaP constraints induce limits on mission time requiring efficiency in exploration. We present a novel exploration framework that uses Deep Learning (DL) to predict the most likely indoor map given the previous observations, and Deep Reinforcement Learning (DRL) for exploration, designed to run on modern SWaP constraints neural processors. The DL-based map predictor provides a prediction of the occupancy of the unseen environment while the DRL-based planner determines the best navigation goals that can be safely reached to provide the most information. The two modules are tightly coupled and run onboard allowing the vehicle to safely map an unknown environment. Extensive experimental and simulation results show that our approach surpasses state-of-the-art methods by 50-60% in efficiency, which we measure by the fraction of the explored space as a function of the trajectory length.

Bio:

Oren received my B.Sc. in Aerospace Engineering, M.Sc. degree in Mechanical Engineering and a Ph.D. in Geo-information Engineering, all from the Technion – Israel Institute of Technology. Oren is currently an Assistant Professor, heading the Swarm and AI (SAIL) Lab, at the Hatter Department of Marine Technologies. Prior to joining the University of Haifa, Oren was the founder and CTO of Autonomy & Data Science R&D in the Israeli Navy (CDR Ret.) and DDR&D for twenty years, working with research partners around the world and leading research groups (DARPA, ARL, NRL, ONR etc). In the last ten years, he is working on joint research with CSAIL & LIDS MIT labs and with Marine Robotics Lab at MIT, UPenn, all on swarms and machine learning algorithms.

Oren’s research focus on swarms and AI across scales. The adaptability and scalability of swarms make them particularly suited to tasks that require distributed sensing, acting, and processing, presenting numerous possibilities for addressing complex and large-scale challenges facing humanity. From nanorobots for cancer treatment, to environmental monitoring and conservation in the ocean, or disaster response and recovery, traffic management and logistics etc. - swarms, particularly swarm intelligence of AUVs, USVs and drones.

In our cutting-edge research lab, Oren’s research delve into the complex and rapidly evolving field of swarms and autonomy, leveraging the latest advancements in Artificial Intelligence (AI) to push the boundaries of autonomous systems across scales.

Spontaneous Directional Liquid Flow in Bio-Inspired Topological Structures

Monday November 18th at 14:00 

Wolfson Building of Mechanical Engineering, Room 206

abstract:

In nature, several organisms possess the extraordinary ability to guide liquids to specific places spontaneously. Trees, cactus spines, spider silk, desert lizard scales, and fleas are just some fascinating examples. Surfaces geometries combined with surface chemistries that promote directional liquid flow gained the term “liquid diodes”. Applications of such liquid diodes range from microfluidics and electronics to biomedicine and sensing. However, an in-depth understanding of how liquids spread and flow in complex networks of such liquid diodes still lacks.

In this work, the functionality, performance, and applications of liquid diodes inspired by the spermatheca organ found in female fleas were studied. High resolution 3D printing was used to design complex geometries and elucidate how liquid propagates in 2D networks made of liquid diodes. This includes flexible liquid diodes in which liquid flow can be mechanically actuated.

Finally, additional work on spontaneous unidirectional flow in asymmetric hollow structures and 3D meshes is presented. Drawbacks and future steps are discussed.

This research work highlights the emerging potential of liquid diodes as versatile tools for manipulating and modelling liquid flow in both technical and biological systems. Furthermore, it offers new opportunities in applications such as lab-on-a-chip devices, sensing, wearable electronics, and space aviation where fine control over fluid dynamics is crucial.

bio:

Camilla, originally from Milan, Italy, graduated in Physics in 2017 from Università degli Studi di Milano and moved to Israel the following year for her Master's degree in Materials Science and Engineering. During her MSc, she worked on metal laser-assisted 3D printing under the supervision of Prof. Noam Eliaz and in collaboration with Orbotech (now part of KLA). After graduating in 2021, she started her Ph.D in Dr. Bat-El Pinchasik's group, Biomimetic Mechanical Systems and Interfaces. She works on spontaneous directional liquid transport on bioinspired topological surfaces.