TEACHING IN THE CLOUD MICROELECTRONICS UBIQUITOUS LAB (MULAB)

CAD laboratory students activity is mandatory for microelectronics teaching. This, applied in the deep-submicron era, creates new challenges to couple software management simplicity to user friendliness inside lab sessions, which requires the use of complex tools and concepts. In this paper, a new approach to microelectronics CAD deployment is presented, based on virtualization capabilities of new servers hardware and software technology. A test case, realized at Politecnico di Torino, degree of Electronic Engineering, is presented, with real world results on resource consumption and user satisfactio

A New Laboratory for Hands-on Teaching of Electrical Engineering

© 2018 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works. This paper describes an innovative laboratory for students in Electrical Engineering courses, which is recently established at the Energy Department of Politecnico di Torino, Italy. The main peculiarities of the lab are the high ICT content of each test rig, the multidisciplinary experiences, and the hands-on teaching methodology, allowing the student to have access in overall safety to many complex electrical/electromechanical systems. Currently, eight courses of Bachelor and Master of Science degrees in electrical engineering carry out in-class exercises and hands-on experiments in the new lab, serving over 200 students in total per year. The innovative lab also allows for external collaborations with companies and institutions for specific (and in some cases permanent) training offers, like a one-day per month LabVIEW course for faculty and staff members of Politecnico di Torino

Plastic pollution in the ocean

Plastic pollution in the ocean was first reported by scientists in the 1970s, yet in recent years it has drawn tremendous attention from the media, the public, and an increasing number of scientists spanning diverse fields, including polymer science, environmental engineering, ecology, toxicology, marine biology, and oceanography. In the oceans, the threat to marine life comes in various forms, such as overexploitation and harvesting, dumping of waste, pollution, alien species, land reclamation, dredging and global climate change. The extremely visible nature of much of this contamination is easy to convey in shocking images of piles of trash on coastlines, marine mammals entangled in fishing nets, or seabird bellies filled with bottle caps, cigarette lighters, and colourful shards of plastic. Even without these images, anyone who has visited a beach has certainly encountered discarded cigarette butts, broken beach toys left behind, or pieces of fishing gear or buoys that have washed ashore

TFT and ULSI technologies: The parallel evolution of the research and the higher education in France

This paper deals with the evolution since the early eighties of the microelectronics applied to integrated circuits and to large area electronics. The evolution in France was linked to a very strong effort of the French government (Microelectronics national plan) to improve the Higher Education in this field and to form with the knowledge and the know-how the future engineers, masters and doctors to the research and development and to the production. A way to help the growth of microelectronics companies mainly in France, but also for the world in the frame of multinational companies. More recently, a new national plan was engaged in the frame of the French Large Investment Commissariat with the goal to improve the large area technology and the integrated technologies and to be adapted to the digital society coming. Connecting objects and Internet of Things are mainly mixing the different components of the electronics and microelectronics domains [1]. After a synthetic presentation of the evolution of the two main technologies developed in research and development centers and in academic laboratories, the paper highlights the strategy developed by the French community based on the innovation [2]. The interesting point is that, if at the beginning the two domains appear independent, the evolution of the process and the fabulous evolution of the CAD tools is making closer and closer the design and fabrication approaches by combining the two technologies. For example the FDSOI (Fully Depleted Silicon on Insulator) concept was in practice existing since many years in thin film transistor technology deposited at a relatively low temperature

A Multi-hop Topology Control Based on Inter-node Range Measurement for Wireless Sensor Networks Node Localization

In centralized range-based localization techniques, sufficiency of inter-node range information received by the base station strongly affects node position estimation results. Successful data aggregation is influenced by link stability of each connection of routes, especially in a multi-hop topology model. In general, measuring the inter-node range is only performed for position determination purposes. This research introduces the use of inter-node range measurement information for link selection in a multi-hop route composition in order to increase the rate of data aggregation. Due to irregularity problems of wireless media, two areas of node communication have been considered. The regular communication area is the area in which other nodes are able to perform symmetrical communication to the node without failure. The irregular area is the area in which other nodes are seldom able to communicate. Due to its instability, some existing methods tried to avoid the irregular area completely. The proposed method, named Virtual Boundaries (VBs) prioritizes these areas. The regular communication area’s nodes have high priority to be selected as link vertices; however, when there is no link candidate inside this area, nodes within the irregular area will be selected with respect to their range to the parent node. This technique resulted in a more robust multi-hop topology that can reduce isolated node numbers and increase the percentage of data collected by the base station accordingly

A Unique Opportunity for Michigan's Future: An Investment in Engineering Excellence Rationale and Plan

http://deepblue.lib.umich.edu/bitstream/2027.42/79529/1/1984_A_Unique_Opportunity_for_Michigans_Future_An_Investment_in_Engineering_Excellence_Rationale_and_Plan.pd

Issues Faced in a Remote Instrumentation Laboratory

An Online Lab is a multi-university shared laboratory environment, where students can exercise their knowledge as they would do in a physical lab. The idea is to have maximum resource utilization and collaboration between universities by sharing of ideas. This kind of remote laboratory negates the economic issues to set up a laboratory and allows every student to have an experience of real laboratory. As part of Ministry of Human Resource Development (MHRD) Robotics Lab project a study on state of art of remote labs was conducted. This paper discusses some key issues in the design and operation of such remote labs. The lab should be remotely usable by a large student body, with varied levels of sophistication, all the way from elementary learners, to PhD students doing research. In addition, the high design load implies that the architecture should be highly parallel, and structurally reliable