Additions to the book "Systems Design and Engineering" by Bonnema et.al. Subjects were chosen based on the Systems Engineering needs for Small and Medium Enterprises, as researched in the SESAME project. The
MULTIFILE
At present, COVID-19 has caused a possible paradigm shift in education, especially in education delivery for higher educational and learning institutions. To align with the national government and relevant national/international authorities’ policies and to avoid the spread of the virus, educational institutions in many nations have decided to temporarily suspend the traditional classroom-based education and replace it with online-based education. This studyaims at exploring the impact of COVID-19 pandemic and obligatory remote working on work-life balance, mental health and productivity of faculty members working in higher education institutions (HEI). The study is exploratory and uses a qualitative approach using an online survey strategy to include voices of faculty members from different countries. While the results of this study indicate both positive and negative effects of obligatory remote working on faculty members’ work-life balance, well-being and productivity at the same time our findings indicate that university administration must pay heed to address concerns presented in the results.
MULTIFILE
De sterke groei van b2b, b2c en c2c e-commerce zorgt echter voor nieuwe problemen op logistiek vlak. De straten worden drukker door rondrijdende bestelauto’s, er is meer vervuiling, verkeersonveiligheid en geluidsoverlast. E-commerce zorgt voor meer leveringen in steden, en dat onder grote tijdsdruk. Welke innovaties zijn nodig om de situatie te verbeteren? Wat zijn de tien belangrijkste trends in last mile bezorging?
Drones have been verified as the camera of 2024 due to the enormous exponential growth in terms of the relevant technologies and applications such as smart agriculture, transportation, inspection, logistics, surveillance and interaction. Therefore, the commercial solutions to deploy drones in different working places have become a crucial demand for companies. Warehouses are one of the most promising industrial domains to utilize drones to automate different operations such as inventory scanning, goods transportation to the delivery lines, area monitoring on demand and so on. On the other hands, deploying drones (or even mobile robots) in such challenging environment needs to enable accurate state estimation in terms of position and orientation to allow autonomous navigation. This is because GPS signals are not available in warehouses due to the obstruction by the closed-sky areas and the signal deflection by structures. Vision-based positioning systems are the most promising techniques to achieve reliable position estimation in indoor environments. This is because of using low-cost sensors (cameras), the utilization of dense environmental features and the possibilities to operate in indoor/outdoor areas. Therefore, this proposal aims to address a crucial question for industrial applications with our industrial partners to explore limitations and develop solutions towards robust state estimation of drones in challenging environments such as warehouses and greenhouses. The results of this project will be used as the baseline to develop other navigation technologies towards full autonomous deployment of drones such as mapping, localization, docking and maneuvering to safely deploy drones in GPS-denied areas.
In de automotive sector vindt veel onderzoek en ontwikkeling plaats op het gebied van autonome voertuigtechnologie. Dit resulteert in rijke open source software oplossingen voor besturing van robotvoertuigen. HAN heeft met haar Streetdrone voertuig reeds goede praktijkervaring met dergelijke software. Deze oplossingen richten zich op een Operational Design Domain dat uitgaat van de publieke verkeersinfrastructuur met daarbij de weggebruikers rondom het robotvoertuig. In de sectoren agrifood en smart industry is een groeiende behoefte aan automatisering van mobiele machinerie, versterkt door de actuele coronacrisis. Veel functionaliteit van bovengenoemde automotive software is inzetbaar voor mobiele robotica in deze sectoren. De toepassingen zijn enerzijds minder veeleisend - denk aan de meer gestructureerde omgeving, lagere snelheden en minder of geen ‘overige weggebruikers’ – en anderzijds heel specifiek als het gaat over routeplanning en (indoor) lokalisatie. Vanwege dit specifiek karakter is de bestaande software niet direct inzetbaar in deze sectoren. Het MKB in deze sectoren ervaart daarom een grote uitdaging om dergelijke complexe autonome functionaliteit beschikbaar te maken, zonder dat men kan voorbouwen een open, sectorspecifieke softwareoplossing. In Automotion willen de aangesloten partners vanuit bestaande kennis en ervaring tot een eerste integratie en demonstratie komen van een beschikbare automotive open source softwarebibliotheek, aangepast en specifiek ingezet op rijdende robots voor agrifood en smart industry, met focus ‘pickup and delivery’ scenario’s. Hierbij worden de aanpassingen - nieuwe en herschreven ‘boeken’ in de ‘bibliotheek’ - weer in open source gepubliceerd ter versterking van het MKB en het onderwijs. Parallel hieraan willen de partners ontdekken welke praktijkvragen uit dit proces voortvloeien en welke onderliggende kennislacunes in de toekomst moeten worden ingevuld. Via open workshops met uitnodigingen in diverse netwerken worden vele partijen uitgenodigd om gezamenlijk aan de hand van de opgedane ervaringen van gedachten te wisselen over actuele kennisvragen en mogelijke gezamenlijke toekomstige beantwoording daarvan.
With the help of sensors that made data collection and processing possible, many products around us have become “smarter”. The situation that our car, refrigerator, or umbrella communicating with us and each other is no longer a future scenario; it is increasingly a shared reality. There are good examples of such connectedness such as lifestyle monitoring of elderly persons or waste management in a smart city. Yet, many other smart products are designed just for the sake of embedding a chip in something without thinking through what kind of value they add everyday life. In other words, the design of these systems have mainly been driven by technology until now and little studies have been carried out on how the design of such systems helps citizens to improve or maintain the quality of their individual and collective lives. The CREATE-IT research center creates new solutions and methodologies in “digital design” that contribute to the quality of life of citizens. Correspondingly, this proposal focuses on one type of digital design—smart products—and investigate the concept of empowerment in relation to the design of smart products. In particular, the proposal aims to develop a model with its supplementary tools and methods for designing such products better. By following a research-through-design methodology, the proposal intends to offer a critical understanding on designing smart products. Along with its theoretical contribution, the proposal will also aid the students of ICT and design, and professionals such as designers and engineers to create smart products that will empower people and the industry to develop products grounded in a clear user experience and business model.
