Select Articles With An Identifiable Dateline No Earlier Tha ✓ Solved

Select Articles With An Identifiable Dateline No Earlier Than

Select articles with an identifiable dateline no earlier than October 2020. Use at most two articles from any one publication or web site. Avoid articles that lack enough substance to support Institute for Medical and Biological Engineering Society of Civil Engineers News-Recordenr.com IEEE Spectrum newsletter American Society of Mechanical Engineers Academy of Engineering – Current Issues American Technology Review magazinetechnologyreview.com/magazineMIT Newsnews.mit.eduEngineering 360 — New products, misc. tutorials, and vendor white papers answer the following for each news:

• # PUBLICATION TITLE or authoritative news source:
• # ARTICLE TITLE (and subtitle if any):
• # Clickable, persistent URL that links directly or very close to the article:
• # Brief but accurate and substantive SUMMARY of article, in your own words: If the article is wide-ranging, just summarize the aspect of the article you will be analyzing.
• Professional opportunities or challenges that this development may pose for ENGINEERS:
• Some foreseeable impacts on direct or indirect STAKEHOLDERS other than engineers:
• TECHNICAL engineering aspects of this development that you think merit a closer look?
• Are there “SOCIOTECHNICAL” aspects of this development that you think merit a closer look?
• Are there design, economic, or other TRADEOFFS in this development that merit analysis?
• Does this development look to you with respect to SUSTAINABILITY?
• Any of the above considerations pose ETHICAL concerns?
• This news article suggest any topic areas or specific topics you might like to address in the major course paper?

Paper For Above Instructions

Article 1

Publication Title: IEEE Spectrum

Article Title: "The Future of Engineering: Innovations Shaping Tomorrow’s Infrastructure"

Clickable URL: https://spectrum.ieee.org/future-of-engineering-innovations

Summary: This article discusses the latest innovations in engineering, particularly focusing on advancements in sustainable infrastructure. It highlights various projects that incorporate smart technology, renewable energy sources, and environmentally friendly materials. The analysis highlights how these innovations represent a shift towards more sustainable practices in engineering, indicating a growing trend to integrate technology with ecology.

Professional Opportunities or Challenges: The developments discussed in this article present both opportunities and challenges for engineers. The pressure to implement sustainable practices encourages engineers to innovate but also demands new skills and knowledge. The challenge lies in balancing the cost of new technological integration with traditional engineering practices while maintaining efficiency.

Impacts on Stakeholders: Beyond engineers, these developments impact local communities, policymakers, and the environment. The adoption of sustainable infrastructure can enhance community wellbeing but may require significant upfront investment and changes in policy. Stakeholders need to be involved in discussions to ensure that the benefits of such projects reach a wider audience.

Technical Aspects Meriting Closer Look: Specific technical aspects that merit further examination include the integration of smart grids and renewable energy sources. The challenges inherent in embedding technology into existing systems and the necessity for engineers to adapt to rapid technological advancements are crucial considerations for the future of civil engineering.

Sociotechnical Aspects: The shift towards sustainable engineering practices underlines the importance of sociotechnical systems. Engineers need to consider not just the technical feasibility of projects but also how these technologies will affect social structures and environmental contexts. The development of public acceptance and community involvement will ultimately shape the success of these innovations.

Tradeoffs in Development: Engineers often face tradeoffs between innovation and cost-effectiveness. The shift towards sustainability may require initial investments that could deter some stakeholders. Evaluating the long-term benefits against short-term costs is essential for successful project implementation.

Sustainability Perspective: This development looks promising with respect to sustainability. The emphasis on reducing carbon emissions and utilizing eco-friendly materials indicates a shift in engineering priorities. Nonetheless, continuous assessment is necessary to ensure that these innovations contribute genuinely to sustainable progress.

Ethical Considerations: The article raises ethical concerns regarding technology adoption and accessibility. Ensuring that lower-income communities also benefit from these engineering advances is critical. The ethical obligation lies in creating equitable solutions that do not leave behind disadvantaged populations.

Possible Topics for Major Paper: This article supports potential topics related to sustainable infrastructure development, the role of technology in engineering, and the ethical considerations of engineering advancements.

Article 2

Publication Title: MIT News

Article Title: "Engineers Design AI Systems to Improve Urban Mobility"

Clickable URL: https://news.mit.edu/2021/engineers-design-ai-urban-mobility-1013

Summary: This article delves into how engineers are using artificial intelligence (AI) to improve urban mobility systems. It discusses advanced algorithms that optimize traffic management and enhance public transportation efficiency. The focus is on the collaboration between human engineers and AI, highlighting the technological advancements that are reshaping city infrastructure.

Professional Opportunities or Challenges: The integration of AI in urban planning represents a significant opportunity for engineers to enhance mobility solutions. However, it also requires them to adapt to new technologies, presenting a challenge in terms of skill acquisition and operational adaptation.

Impacts on Stakeholders: The primary stakeholders affected include urban planners, commuters, and local government authorities. Improved urban mobility has the potential to reduce congestion and pollution, thus benefiting public health and welfare, but it necessitates careful collaboration among all parties involved.

Technical Aspects Meriting Closer Look: The technical aspects of algorithm development and the implementation of real-time data systems warrant deeper examination. Understanding the intricacies of AI decision-making in urban environments is essential for effective application and evaluation.

Sociotechnical Aspects: The sociotechnical implications of AI in mobility entail considering public acceptance of AI decision-making in transportation. Engineers must ensure that these systems consider bias and accessibility, requiring a multidisciplinary approach during design.

Tradeoffs in Development: A key tradeoff involves the dependence on technology versus human oversight. While AI can enhance efficiency, the potential for errors necessitates a balanced approach, ensuring human operators remain central to decision-making processes.

Sustainability Perspective: The development shows promise in promoting sustainability by optimizing transport routes and reducing emissions. This strategic use of AI signifies a forward-thinking approach to urban planning and resource management.

Ethical Considerations: Ethical questions arise regarding data privacy and algorithmic bias, particularly in how AI systems might inadvertently perpetuate or exacerbate inequalities within urban mobility systems.

Possible Topics for Major Paper: This article could lead to discussions on the ethical implications of AI in engineering, the intersection of technology and social equity, and sustainable urban infrastructure development.

References

• IEEE Spectrum. (2021). The Future of Engineering: Innovations Shaping Tomorrow’s Infrastructure. Retrieved from https://spectrum.ieee.org/future-of-engineering-innovations
• MIT News. (2021). Engineers Design AI Systems to Improve Urban Mobility. Retrieved from https://news.mit.edu/2021/engineers-design-ai-urban-mobility-1013
• National Academy of Engineering. (2020). The Role of Engineering in Sustainable Development. Retrieved from https://nae.edu/94072/The-Role-of-Engineering-in-Sustainable-Development
• American Society of Civil Engineers. (2021). Infrastructure and Sustainability. Retrieved from https://www.asce.org/infrastructure-sustainability
• Journal of Urban Technology. (2020). AI and Urban Mobility: A New Era of Transportation. Retrieved from https://www.tandfonline.com/journals/turb20
• Engineering Ethics: Concepts and Cases. (2020). Ethical Practices in Engineering. Retrieved from https://www.routledge.com/engineering-ethics-concepts-and-cases/
• International Journal of Sustainable Transportation. (2019). Integrating AI in Transportation: Opportunities and Challenges. Retrieved from https://www.tandfonline.com/toc/ujst20/current
• Smart Cities: A New Approach to Urban Mobility. (2021). Springer Publications. Retrieved from https://link.springer.com/book/10.1007/978-3-030-08686-6
• Sustainable Cities: The Role of Civil Engineering. (2020). Wiley Online Library. Retrieved from https://onlinelibrary.wiley.com/journal/20421338
• Ethics of Artificial Intelligence and Robotics. (2020). Stanford Encyclopedia of Philosophy. Retrieved from https://plato.stanford.edu/entries/ethics-ai/