Staying home during COVID means teachers and students have to get creative. Things that you would normally have at school you might not have at home and vice versa. A few days ago I decided to see if I could make a homemade “force plate” that could accurately measure impact forces. My smartphone has a high speed camera. I just needed something that was sensitive enough that it could measure tiny forces happening over very short periods of time.
My solution is shown above. To build it you will need:
Assemble your force plate as shown above. Adjust the height of the stick such that the laser beam hits the middle of it.
To measure static forces, press on the plate. As you press the laser beam will move across the stick. You can use a ruler and some known weights to calibrate your stick.
To measure impact, download a suitable video analysis app to your smartphone. For iPhones and iPads the “Technique” app by HUDL works well. I used Technique and a homemade force plate to create the latest Video Motion Analysis activity, “Measuring The Force Of Impact Over Time“. In the activity students learn how padding minimizes the force of impact.
Feel free to share and comment below!
We had a great evening of physics demos and discussions on Wednesday night. Thanks to Marty (CHS), Dave (CHS), Caleb (CHS), Josh (PMSA), Kunal (HPHS), Bryan ( GBN), Mark (PHS), Mike (SHS), and Sasha (Northwestern University) for sharing. The hosts were excited to give away 3D printed models of the “Accurate PVC Launcher”, “Moment of Inertia Spinner”, “Cheap Pulley”, and “Adjustable Frequency PVC Horn”. All of the designs were built using the free website www.tinkercad.com.
If you have access to your own 3D printer, you can print your own!
Click on the images below for the model files and instructions for printing the “Accurate PVC Launcher”, “Moment of Inertia Spinner”, “Adjustable Frequency PVC Horn”, and the “Cheap Pulley”:
We just finished uploading six (really five, because we were able to reuse one of the scenarios) new high-speed videos for Video Motion Analysis called “Horizontal Atwood Lab”. We also put together a very simple lab activity to go with it, suitable for an introductory high school physics classes. In the activity, students analyze sets of three videos to determine the relationships between acceleration and total mass, and acceleration and force. Students should be able to finish the activity in about 30 minutes.
Now that the analysis apps are built, shooting new videos and uploading them goes fairly quickly. Let us know if you have any videos that you would like to see for your class!
We are pleased to announce “Video Motion Analysis“, a new set of apps on www.simbucket.com. Each app features one video shot with a high-speed camera. Students can scroll through each frame and take careful measurements. Some of the apps contain more advanced plotting, graphing, and analysis tools so that students can collect, plot, and analyze the data directly within the app.
We tried the “Ball Launched At An Angle” videos today with our students. Using the graphing and slope calculation tools, they were quickly able to determine that horizontal acceleration is always zero, and vertical acceleration is always 9.8 m/s² downward, no matter which videos they selected for analysis.
We are continuing to shoot video, and hope to have many more videos available for analysis over the coming months. If you have a physics lab that you do with your students and would like us to shoot video, please let us know. We will do our best to recreate it for you and make it available on www.simbucket.com.
The new Video Motion Analysis section can be found on the www.simbucket.com homepage, or via the following direct link.
Simbucket.com is pleased to announce that the HTML5 version of the Chemthink “Atomic Structure” tutorial and problem set is now online. Because the new version is designed from the ground up for HTML5, it means that students with iPads, iPod Touches, or phones can now run the tutorial in a browser without needing an actual computer. In 1:1 classrooms, this means students won’t need to go to the computers to log in. It should take approximately five minutes less to get students up and running with the tutorial.
In creating the HTML5 version, I tried to stay as faithful as possible to the original Flash version, only adding or making changes where it made sense. For teachers, this means any worksheets or activities you created based on the original should still work with the HTML5 version.
When a student clicks to launch the app, they are presented with a choice between the tutorial and the problem set. In practice, I have found that it is easiest to tell my students to open up and run the tutorial in one browser tab while running the problem set in another. If a student misses a question, I tell them to find the answer in the tutorial before clicking the “continue” button.
Because there is no student login required, students are able to get started very quickly. This also means that students will need to show you when they are finished with the problem set. I have included a large gold star on the completion screen so that you can very quickly glance at a student’s screen to see that they are finished. For students completing the problem sets at home, I have asked that they take a “selfie” with their completion screen.
Because of the amount of class time I have saved by not requiring a log in, I am strongly considering permanently eliminating the need to log in. The drawback to not requiring students to log in is that teachers will have no ability to track student progress, other than physically observing their students’ screens. If you can’t live without the student tracking feature, please speak up!
From start to finish, the “Atomic Structure” HTML5 port took 12 days to complete. I am hoping that I can maintain this pace for the remaining 9 tutorial/problem sets, plus the “Chemical Reactions” lab simulation. At this rate I should finish everything in about 20 weeks, roughly around the beginning of September.
I’ve begun the process of rewriting Chemthink from scratch. At this point I’m looking at reusing all of the existing animations and texts, but we have an opportunity to make the suite of tutorials, question sets, and virtual labs even better. I can’t promise anything because I have only a finite amount of time to finish the project, but I would like to open things up for input from Chemthink users.
So far, the to-do list includes:
If you could change anything about Chemthink, what would you change?
If you could add any capabilities, what would you add?
A few weeks ago I posted 8 of the original Chemthink Flash tutorials. I am excited to announce that the Chemthink problem sets are now available for these tutorials! The question sets require students to answer a certain number correct before they miss a small number of questions. As a result they are fairly difficult. If students struggle on a problem set, they are encouraged to take a look at the tutorial again.
There is no server backend, so if you want to keep track of which problem sets or tutorials you or your students have completed you will need to take a screenshot of the completion screen.
Tutorials and their corresponding problem sets are now available for the following:
In addition, over the next few days I post two more problem sets without tutorials: “Chemical Reactions” and “Isotopes”. At the moment the tutorials for each of these are nonfunctional, but I will do my best to get both the tutorials and their question sets working as soon as I can.
This week in physical science we needed a basic simulation to show a particle model of the melting and boiling of ice. “Melting and Boiling” is designed to address very basic questions, such as “What is ice?”, “What is water?”, “What is steam?”, and “What happens to water molecules as temperature rises?”
Would you like to see more basic chemistry simulations? If so, comment below, and I will try to get to them when I can!