My Reflection for Critical Thinking and Communications

Throughout my Critical Thinking module with Professor Brad Blackstone, I engaged in various tasks that honed my communication skills, analytical abilities, and teamwork. From writing structured responses to delivering oral presentations, each activity provided unique learning opportunities that contributed to my growth. Reflecting on my progress, I have made significant strides in these areas, though there are still aspects I need to refine, particularly my confidence in public speaking.

A key area of development was my writing skills, especially in structuring arguments and presenting ideas coherently. Writing the Reader’s Response was initially challenging as I struggled with organizing my thoughts. However, through feedback and revisions, I refined my arguments, integrated evidence effectively, and maintained clarity. This iterative process highlighted the importance of revision in producing high-quality work. Writing technical reports in both small and large groups reinforced the need for precise, well-structured writing, especially in technical contexts. Working with teammates required coordination to ensure consistency in style and content. Through this, I learned to organize reports logically, apply proper citation techniques, and avoid plagiarism. Additionally, I leveraged AI tools to enhance clarity and make my arguments more concise and professional.

Critical thinking was another essential skill I developed. I learned to analyze arguments by identifying premises, conclusions, and logical connections, which helped me assess information credibility. I also unlearned the tendency to accept information at face value and instead focused on evaluating evidence critically. Moving forward, I aim to apply these skills in real-world engineering contexts, particularly in ethical decision-making and risk assessment.

While I have improved in both written and verbal communication, my biggest challenge remains public speaking. I’ve always had a fear of speaking in front of an audience, often feeling nervous and losing my train of thought. However, through this module, I’ve taken steps to improve. Presenting in front of my classmates forced me out of my comfort zone. Though anxious, I learned to manage my nerves better by preparing thoroughly and practicing. I also became more conscious of my tone, pace, and body language, which helped me deliver my message clearly. Despite this progress, I know I need to work on projecting confidence and handling impromptu speaking situations more effectively.

One of the most transformative aspects of this module was working on a group research project. Writing the research report required balancing individual contributions while maintaining a unified voice. Initially, coordinating ideas was challenging, but I learned that setting deadlines, maintaining open communication, and regularly reviewing work improved efficiency. Trusting teammates and valuing different perspectives strengthened our final report.

The presentation component was especially challenging due to my fear of public speaking. However, thorough preparation and practice made a significant difference. Receiving feedback from peers helped me identify areas for improvement, such as maintaining eye contact and using visual aids effectively. This experience reinforced that public speaking is a skill that can be developed over time, and I am determined to continue working on it.

Looking back, I recognize significant progress in my ability to communicate effectively, both in writing and speech. While there are still areas for improvement, such as refining my presentation delivery, this module has laid a strong foundation. The Critical Thinking module was a challenging yet rewarding experience that significantly improved my writing, analytical, and presentation skills. Most importantly, it helped me confront my fear of public speaking and take the first steps toward improvement. Moving forward, I plan to continue refining these skills, actively seeking opportunities to practice public speaking and apply what I’ve learned in academic and professional settings.

Reader's Response: Final Draft (Amended Version)

 The Apple Vision Pro is a mixed-reality headset that combines augmented and virtual reality, offering a groundbreaking spatial computing experience (Apple, 2023). According to the same website, it is powered by M2 and R1 chips, delivering high performance and ultra-low latency. The dual micro-OLED displays offer great visual clarity. Vision Pro’s intuitive control system includes advanced eye tracking, gesture recognition, and voice commands, allowing users to interact naturally with digital content (Apple, 2023).

Running on VisionOS, the headset enables applications to float in 3D space, blending seamlessly into the physical environment (Apple, 2023). Users can multitask across apps like Safari, FaceTime, and Photos, making it a versatile device for productivity, entertainment, and creative workflows, while spatial audio creates a personalized sound environment that enhances the immersion of these experiences (Apple, 2023).

The Apple Vision Pro’s augmented reality capabilities have the potential to revolutionize civil engineering workflows by enhancing project visualization, precision, and collaboration (Imaginit, 2024; XYZ Reality, 2024). Engineers could overlay 3D models of structures onto real-world environments for site analysis, perform virtual inspections, and collaborate remotely using immersive visualizations (Xu & Moreu, 2021). AR tools like the Vision Pro improve accuracy in field measurements, enhance project planning, and optimize communication between teams (Imaginit, 2024). According to XYZ Reality (2024), this could lead to more efficient project execution and reduced errors in construction processes.

The Apple Vision Pro enhances civil engineering by using augmented reality to improve project visualization, precision, and collaboration, enabling faster decision-making and more efficient execution.

Visualization is a key application of the Vision Pro in civil engineering, enabling the overlay of precise digital models onto real-world environments. According to Apple (2023), integrating AR with Building Information Modelling (BIM) allows engineers to view designs in three dimensions before construction begins. This capability helps professionals identify structural conflicts, detect flaws, and improve spatial planning, which improves project efficiency. This is particularly beneficial for large-scale projects, where engineers can evaluate site conditions and assess structural integrity before physical work begins. By providing more detailed and interactive representations of construction plans, the Vision Pro enhances decision-making (Imaginit, 2024).

While visualization significantly enhances project planning and decision-making, another critical aspect of civil engineering that benefits from the Vision Pro is precision in measurements (Imaginit, 2024). Precision in measurements is crucial in civil engineering, as even small errors can compromise structural integrity. The Vision Pro’s AR capabilities allow engineers to make precise measurements through real-time overlays and digital annotations, reducing reliance on manual tools and minimizing human error (Imaginit,2024). Additionally, the Vision Pro integrates with laser scanning and geospatial data, improving measurement precision even further (Imaginit,2024). These features allow engineers to verify construction tolerances, monitor structural deformations, and cross-check field measurements against digital plans, ensuring that quality control and safety are maintained (Xu & Moreu, 2021).

Collaboration is another area where the Vision Pro revolutionizes civil engineering. Traditional project coordination often involves reviewing blueprints, sending emails, and holding on-site meetings. However, AR technology enables engineers to collaborate remotely in real-time using immersive 3D visualizations (Apple, 2023). According to XYZ Reality (2024), this reduces project delays by streamlining decision-making and minimizing miscommunication. Engineers can share live updates, conduct virtual site visits, and hold synchronized discussions via the Vision Pro (XYZ Reality, 2024). Furthermore, its features support safety training and on-site guidance, helping new engineers learn tasks more quickly while improving overall operational efficiency. This is particularly valuable in projects with strict engineering standards and safety protocols (Apple, 2023).

Despite the many advantages of AR in civil engineering, according to XYZ Reality (2024) some professionals argue that traditional tools, such as CAD software, physical blueprints, and on-site inspections, are sufficient for project execution. These methods have been refined over many years and remain the standard for planning and design. Moreover, implementing AR with devices like the Vision Pro presents challenges, such as excessive costs, adaptability to construction environments, and the need for training (XYZ Reality, 2024). One significant concern is the Vision Pro’s incompatibility with personal protective equipment (PPE), such as hard hats and safety goggles, which reduces its practicality on construction sites (XYZ Reality, 2024). Durability is another issue, as the device may not withstand harsh conditions such as dust, extreme temperatures, and vibrations. Furthermore, the Vision Pro’s premium price makes it difficult for smaller firms to justify the investment, and engineers accustomed to traditional methods may require substantial training to adopt AR-based workflows (XYZ Reality, 2024).

In conclusion, the Apple Vision Pro offers transformative possibilities for civil engineering by enhancing project visualization, improving measurement accuracy, and enabling real-time collaboration. Its integration with BIM, AR-assisted measurements, and seamless communication significantly enhances decision-making and project execution (Imaginit, 2024). However, challenges such as excessive costs, construction environment compatibility, and resistance to modern technologies must be addressed before widespread adoption (XYZ Reality, 2024). While traditional methods remain reliable, AR technology represents the future of civil engineering, offering unprecedented efficiency and accuracy in project execution. As technology evolves, future iterations of AR devices like the Vision Pro may become more durable, affordable, and construction-friendly, making them indispensable to the industry (Apple, 2023).

References

Apple. (2023). Apple Vision Pro: A new era of spatial computing. https://www.apple.com/apple-vision-pro/

Imaginit. (2024). Enhancing the construction industry with the highly anticipated Apple Vision Pro. https://resources.imaginit.com/building-solutions-blog/enhancing-the-construction-industry-with-the-highly-anticipated-apple-vision-pro

Xu, J., & Moreu, F. (2021). A review of augmented reality applications in civil infrastructure during the 4th Industrial Revolution. Frontiers in Built Environment, 7. https://doi.org/10.3389/fbuil.2021.640732

XYZ Reality. (2024). Exploring the use of Apple Vision Pro for construction. https://www.xyzreality.com/resources/exploring-the-use-of-apple-vision-pro-for-construction