Correlation Vs. Causation

As of two days ago when writing this, the latest PLP project just ended. I am writing today about that project, the correlation and causation project. in this project, I learned how to identify correlation and causation, and make surveys and show the results. So, without further ado, here is the post.

To kick off this project, I started the same way I usually do: with a mind map. This Mindmap graphs all the existing knowleadge I have and the question I have onto paper (or pixels).

This project was about correlation and causation. Correlation is a statistical term that evaluated the degree at which two or more things are related. Causation is when those things actually cause eachother.

The final product of this project is a presentation featuring survey results on graphs that show correlation and causation. For the next major milestone in this project, me and my partner had to make a plan for our survey. We had some ideas for what our survey could be, and in the end we made this:

After making this, we assembled and wrote the questions into a survey we made using google forms. We sent this form our via Basecamp, Snapchat, and iMessage. We received 40 responses in total, all of which are 13-18 years olds. We put our results onto graphs, and found no correlation with our original plan. But, we didn’t just ask four questions, we asked more so that we could look through the data to find correlations (almost) no matter what. And with that, we found these two correlations:

Correlation 1: Friend height VS. Your height
Correlation 2: Perceived height VS. Actual height

Finally, it was time to start working on our final presentation. We started out with an outline of what our presentation would look like

And after that, we made out final presentation, and nothing to notable happened with this.

And then we presented. The presentation went smoothly, though I think we could’ve improved upon it by making our data more clear.

And for the curricular competencies for this project:

Planning and conducting:Select and use appropriate equipment, including digital technologies, to systematically and accurately collect and record data


Two correlations are found using well crafted survey results. The survey results and correlations are are displayed and explained through presentation software. At least two graphs are analyzed to confirm correlation.

Our presentation clearly showed our survey results, correlations and featured two graphs

Communicating and Representing: Use mathematical vocabulary and language to contribute to mathematical discussions

Verbal and pictorial explanations help the audience to understand the circumstances where both correlation and causation are present, and also where a correlation is falsely associated with causation. A Logical explanation for causation is explored for one case.

We showed our exploration into one of the correlations to prove causation which follows a logical course. We also have verbal and pictorial explanations that help guide the audience to a conclusion.

Applying and Innovating: Contribute to care for self, others, community, and world through individual or collaborative approaches

Good ethics are followed when conducting surveys. All class time is used efficiently for learning without distractions.

I used my time wisely and only missed one deadline this whole project.

Well, thanks for reading my post, and I hope you enjoyed it. Stay tuned for the next one.

My partners Max’s blog

Epidemic Exponents!

Hello, and welcome. I am back to school, and starting this year in scimatics with exponents! In the first scimatics project this year, Game of Exponent Laws, I learned how to evaluate exponents, exponent laws, and more. So without further ado, here is the post.

To kick of the project, we did a quick activity were we made up games that used one and two dice. We got into groups of four, and started working. And here are the rules we came up with:

Rollie poll-E

Assemble all the players in a circle. Decide who will roll first, and have them roll the die. If their roll is a 4, 5, or 6, add the roll to their point tally. If their roll is a 1, or 3, subtract their roll from their point tally. Point tallies cannot drop below zero, and if they reach twenty, that person wins. If they roll a 2, they get to roll again and multiply that roll by two and add it to their point tally.

Rollie poll-E 2.0

To win, gain 5 points. You gain a point when you correctly answer a question faster than your opponent(s). Choose someone to roll each round, and have them roll the two dice. Once the dice have settled, every player starts solving the math problem. If the dice are both even, devide the greater roll by the smaller one. If the dice are both odd, multiply them. If the dice are odd and even, add them together. Once you figure out the answer, say it aloud, and if you are the first to solve the problem, you get a point. Decimal points are allowed for answers. If the roll has a 1 then subtract 1 from the other roll

(Special thanks to Jocelyn for thinking of the names)

So, as common with scimatics projects, we all were supposed to make a mind map that’s outlines what we already know and what questions we have.

Project Start Mindmap

Now, in this project, the milestones were not a linear process, but in a slightly erratic way, with the milestones not coming in numerical order. So, for the sake of this post, I will tell you about the events of this project in chronological order.

After these first assignments, me and my partner started brainstorming Ideas for our game. Our first milestone was milestone four (confusing). For this project, everybody was given a partner, and together you and your partner would make a game that uses exponents as a central mechanic. So, eventually, me and Aliciah decided to make a game about viruses. Our idea was quite similar to pandemic: contagion, which is a game were each player is a virus trying to exterminate humanity. Our first draft of our rules are here.

Throughout the next week, we updated our game rules and did some exponent practice, and eventually landed on this set of rules:

After making these final game rules, it was time to make our game board and pieces.

Final Game Board!

And, of course, there were curricular competencies for this project, which are listed below.

Applying and innovating: Contribute to care for self, others, community, and world through personal or collaborative approaches.

All class time is used efficiently for learning without distractions. All group members contribute equally.

I used my class time well, and I think that is reflected in the quality of my work. My partner and I shared equal part in the workload for this project.

Reasoning and Analyzing: Use logic and patterns to solve puzzles and play games

A clear and simple points system and win conditions for the game are carefully designed.

Points system is clearly represented by physical game pieces, and finding out who wins a game is easy and concise.

Communicating and Representing: Represent mathematical ideas in concrete, pictorial, and symbolic forms

A set of clear, complete, interesting and personalized instructions are created for how each player takes their turn. Examples are included. The game design uses at least 4 different exponent laws and using these laws is integrated into each player’s turn.

Our game features game rules completely written from scratch, with our own ideas and examples of gameplay and game pieces. There are over four exponent laws included in our rules.

And that concludes my blog post for today! Thanks for reading this far, and if you want to check out my partner Alicah’s blog, click here.

See you in the next post, bye.

Don’t Eat Rat Feces!

Today, I am writing a summative post about my latest, and last project of the year. This project is called Comic Cells. I learned a ton from this project, from what subsequent endocytosis is to why you shouldn’t eat rat poo. So, without further ado, here is the post.

As with all scimatics projects, we started off the project with a mind map of existing knowledge, question, sources, and anything else about the topic. Here is mine:

Project Start Mind Map

For the second milestone of the project, I created a wanted poster for a disease containing the date of discovery, how it affects cells, it’s mortality rate, and more.

Typhoid Wanted Poster

Then I started working on a storyboard to guide the making of my comic. The storyboard was a very rough guide to the comic, and some parts were not even in the final comic.

Rough Storyboard

Then I started to research a TON of facts about the virus I chose. (Hantavirus) To read more about hantavirus, veiw the sources down below. I learned a ton about cellular processes, and then started drawing pictures for my comic. I am not the best at drawing, so this was a hard task for me. However, I a very proud of the final comic, which is the namesake for this post.

And, as with all projects, there were core competencies I worked towards throughout the project. They are:

1. Questioning and predicting: Demonstrate a sustained curiosity about a scientific topic or problem of personal interest.

All class time is used for learning and creating a comic book story about cellular processes and/or diseases. I think I used almost all of my class time efficiently, but even so I still think I could’ve worked slightly faster in class and had less homework after school. But it worked out in the end, which is good.

2. Scientific communication: communicate ideas, findings, and solutions to problems using scientific language, representations, and digital technologies

Correct vocabulary and accurate diagrams are used. At least 10 interesting science vocabulary words are included in the story. I used more than ten science words in my Story, and I think my diagrams are concise and accurate at what they represent.

Evaluating: Demonstrate an understanding and appreciation of evidence

Cell/bacteria/virus characters interact in a scientific way. Symptoms and logical outcomes of the chosen disease/cellular/ body process are integrated into the story. In my story, the reaction to the virus is realistic to real-life cases, and the outcomes are on the probable side.

Sources:

Source 1

Source 2

Source 3

Source 4

Source 5

Source 6

Source 7

Thanks for making it this far. If you liked this post, make sure to check my other ones here. See you in the next post! Bye.

Atoms

As you can probably tell from the title, this project was one about atoms (and molecules, Kenetic energy, etc…). We spent about three weeks learning, coding and thinking to answer the driving question for this project: how can the behaviour of matter be explained by the Kinetic Molecular theory and the Atomic theory? So, without further ado, here is the post.

We started this project with a mind map and an experiment/magic trick. We wrote the mind map about what we already knew about matter, and then all of our questions about it.

Project start mind map

For the demonstration of atomic and molecular theory, the teacher performed a trick using a sealed bottle filled with water and an eyedropper.

The trick works by utilizing pressure. When the bottle is not squeezed, it looks like this:

Eyedropper at the top

But when the bottle is squeezed, the pressure increases, forcing the eyedropper down, and if you are subtle, it looks as if you magically made the eyedropper go down.

Squeezed bottle with the eyedropper down

One really cool activity was called the gemstone identification challenge. The whole class partnered up to measure the volume, weight, and then calculate the density of a few stones. The class average density was 3.74 grams per millemeter, and the closest density to that was that of colourless topaz, so we confirmed that the stones were colourless topaz.

Gemstone ID sheet

For milestone 2, we created accurate models for our coded project. In order to make our simulations or games follow this competency: Several different atoms/molecules, different states of matter, and particle motion are represented in the finished product. A historical model of the atom is chosen and implemented, we created some sort of model and text.

In order to create realistic and functioning models of atoms, molecules, and in my case quarks, I worked on three slides of information and graphics. It took three other versions to create to the one shown below.

The next week was mostly spent learning more about matter and coding or refining our scratch projects. Then we did milestone four, which was a coding plan for the rest of the project. This was my milestone four coding plan:

Features:
Press space to show Bohr models
Press M to mute music
Press N to unmute music
Press Q to create more clones
Press 1-3 to change molecule type
Gravity that can be turned on and off
Click the reset button to reset the simulation
Use the temperature slider to change how fast the particles move.
Setting the temperature to zero will stop the particles from moving, other than gravity acting on them.
You can create different states of matter by adjusting the temperature and gravity.
you can adjust how much gravity there is.
You can move between subatomic particle models, Bohr models, and no models by pressing space bar twice This kinetic molecular theory is included in the simulation when the particles move. They follow the Kinetic molecular theory.

After creating a plan, I continued coding my scratch project until it was completely done and polished. If you want to check out my simulator, click here. After all was said and done, I created a summative mind map of the project, which helped round of the end of the project.

As with all projects, there were curricular competencies which you can see below:

Questioning and Predicting: Demonstrate a sustained curiosity about a scientific topic or problem of personal interest.

All class time is used efficiently for learning without distractions. I used all my class time efficiently, and I am very proud of my final product.

Scientific Communication: communicate ideas, findings, and solutions to problems using scientific language, representations, and digital technologies.

Several different atoms/ molecules, different states of matter, and particle motion are represented in the finished product. A historical model of the atom is chosen and implemented. I have three different molecule designs: H2O (water), carbon dioxide (CO2), and ozone (O3). I also have three Bohr models of the elements: carbon, hydrogen, and oxygen, And finally two subatomic models of protons and neutrons.

Reasoning and Analyzing: Use logic and patterns (including coding) to solve puzzles and play games.

An interactive Scratch coded matter simulator or game is created with logical conditions and functional user controls. I created a simulator with four variables that the player/user can change, and extra aesthetic changes as well. The user can change limits all the variables, and the layout is logical and easy to use.

Thanks for reading my post! I had a great time doing this project, and i am sure to do more, so stay tuned .Even though I have featured it already, just in case, here is the link to my scratch matter simulator. Thanks to my friend Noah for all the coding help and feedback. If you want to check out his blog, click here. See you in the next post!

Exploring European Exploration

Welcome to another summative post. Today, I am going to talk about our latest project on European Exploration. This was a three weeks long, and consists of five milestones. So, without further ado, here is the post.

The driving question for this project was: What Did European Settlement Mean For Everyone Involved? To answer this question, there are two thing you need to know first: what is European settlement, and who was involved, and this post is documenting how I found the answer to this.

We kicked off this project with our first milestone: a stream-of-consciousness writing about European Settlement. This was the first assignment of this project.

We did some other activities to build our knowledge, and then did milestone two, a sheet were we used evidence to rank events by significance on a chart. This is what it looked like:

Continuity and Change sheet

Throughout this project, me and my partner have been writing almost everything in one shared document. We have written scripts, notes, photos, content, and sources.

After we finished researching and creating our facts and graphics, we handed the rough infographic in as milestone three.

Milestone 3

Over time, me and Cale refined our infographic, and created six different version before the final product was created.

We then created a script, description, title, QR code, and Keynote magic move for our YouTube video.

Video Script
YouTube Information
QR Code To Video

Using all of this, we created the video which the QR code on the infographic leads to. You can find this video here.

And finally, we worked on putting all 26 infographics up around the school. We decided on were to put the infographics and which ones should go together, then put them up!

And that brings us to now, where I can answer the driving question: What Did European Settlement Mean For Everyone Involved? Well, the answer is complicated, because of how broad of an event it was. In my infographic, I focus on one aspect of it: alliance and trade. European settlement affected the First Nations, British, and French. Even today, and I’m sure for long afterward, trading will remain a constant. But what resources that are being traded, how they are traded, and the people trading them will always be changing. Alliances are crucial to humanity, and we are able to accomplish much more when we ally together. European Settlement gave new resources, trading routes, and opportunities for alliance to everyone involved, and that completely changed history for long after.

Thanks for reading my post! If you want to check out my partner’s experience with “The More Things Change” project, click here. Anyways, thanks for reading my blog and see you in the next post.

Music!

Hello! This post is day 6 of the 2020 Student Blogging Challenge, and today we are doing a post on music! I love to listen to music, and I can play guitar decently. And without further ado, here is the post.

Record Guitars

all hail the biggest of them all! In January, 2001, the largest playable acoustic guitar was created: measuring 16.75m long, 7.57m wide and 2.67m deep, and weighs four tons. The instrument was built in Porto, Portugal. This record still stands today. source here.

Running down the scale of size works too, clearly, or else why make a guitar smaller than as human hair? Yes, you heard me right, this tiny guitar measures ten micrometres long – 1/20 the thickness of human hair! It can only be played by using lasers to move the strings, and makes sounds at frequencies human can’t even hear.

source.

Minuscule or massive, we must pay respect to our elders. And the oldest and first guitar ever, owned by an artist known as Har-Mose, in ancient Egypt is no exeption. The guitar had three strings and was made of two pieces of wood, with no ability to tune it.

Survey

On that topic, I also made a survey about music Here.

Guess that instrument

Now, here is a guess that instrument quiz.

You have finished the post! Congrats! But, if you look at the start of each paragraph, they are in perfect harmony.