20% Time Initial Problem (Post 1)

Problem Solving

Students, you may have noticed from time to time as you go about your day that there are problems everywhere in need of solving. You may have seen problems that other people face as well as problems you may face. In order to stimulate some thought leading into our 20 percent projects, I want you to watch the video below for Clean Bottle, an invention that met the need of a cyclist as he was exercising. After you watch the video, I would like you to reflect on problems that you experience in your everyday lives and how you could possible solve those problems. Remember that these problems can come from any experiences you have, not just in school. Once you have come up with 3 problems that you experience, I would like for you to comment on this post with your three problems. Please make sure that you provide plenty of detail such as why it is a problem.

Below is an experience that I have every morning:

In the morning, my dogs always have to go use the bathroom. When they go outside, their paws get wet from the dew or from rain. They then track this water and dirt back into the house onto the floors and the carpets. I need to find a way of drying their paws before they enter the house when their paws are wet. 

This is just one example of the many problems we can face from day to day. I would like to see your comments reflect the detail and specificity in the example that I just provided. If you have questions, feel free to ask.

Below is the video you need to watch:

Welcome

The purpose behind this blog is to enhance classroom interaction with technology by encouraging reflection and engagement with robotics students. I would like to welcome you to the blog and please feel free to browse the various posts and comment. You can also follow me on Google+ or on Twitter by clicking on the links to the right.

Twiducate Post

A) The primary result of the study presented was to conclude that higher level reflection was impacted by two sources, High Level Prompts and High Level Observation. Interestingly, the quality of peer reviews did not impact levels of student reflection. In terms of what this means in relation to online learning, It seems that students tend to reflect and respond at higher levels when the questioning performed by the teacher is set up in such a way that the questions prompt students into higher levels of thought such as analysis and synthesis. By providing guidance to student thoughts, they then can understand where their thoughts should lead them and thus think on a higher level. Additionally, by seeing high level examples to reflect upon, students gain a better understanding of the breadth and depth of reflection expected in the activity. Finally, in asynchronous discussion it seems that not as much credit is given to student feedback, most likely because by its very nature asynchronous discussions do not create a rapid back and forth dialogue. Thus, individuals are not as concerned with the feedback from their peers. I believe this also happens because people are typically more concerned about the content of their primary or "Main" posts rather than responding to their peer's remarks. Additionally, peer remarks often tend to be vague or unsubstantial and thus do not merit a deeper level of thought. Coupled with the lack of a face to face environment and the intimacy such an environment creates, there is little respect for peer feedback.

B) One of the primary goals of robotics (and engineering as a whole) is to problem solve. Often problems and their solutions arise from experiences within our lives or that we may indirectly experience. For example, when my dogs go out in the morning to use the bathroom, their paws get wet from the dew. In order to keep them from tracking water into the house, I have to wipe their paws off every morning. When I am in a hurry to get ready, this becomes time consuming and irritating (not to mention I am lazy about this). To alleviate this problem, I could come up with a paw drying solution such as a mat to dry my dogs feet better. In order to get my students thinking about how to solve problems and have them develop their own solutions, I would ask them to take mental (or written) notes of things that bother them on a daily basis in their lives. Once they have reflected on these irritations, I would then ask them to choose one and develop a solution for this problem. They could then describe or explain their problem and solution as well as its pros and cons (requiring more reflection) and then could ask them to use the design principles they learned in class to create a model or prototype of their solution. If they are unable to prototype, I could have them find another creative way of pitching their idea to the class. In line with the observations made by Chen, Wei, Wu, and Uden, I could then provide examples for them of past classes that had high-level, successful solutions.