Hi folks, thanks a million to those who watched last week. This week we do something simple and fun: some low-poly trees that will look great added to any low-poly outdoor scene.
This technique uses extrusion and the skin modifier to build the trunk. The canopy is made of ico spheres that we’ve distorted.
Here’s the video link:
My blend file can be downloaded from here.
Hi Folks,
I thought it would be nice if we could finish out our animated tank, notwithstanding that we’re all self-isolating at the moment. To that end, I’ve recorded a litte video to show the last bit of the animated tank model, the bit that actually includes the animation!
I hope this video will be of some use to at least a few of you. If you watch it, please do let me know with a YouTube comment or a comment here so I can decide if I should make a few more like this. Happy to do it if someone’s watching!
Take care and mind yourselves and your families.
Here’s the link to the finished tank model.
Hi everyone!
Hope you are all keeping safe and well, getting lots of exercise and fresh air, doing your work that your teachers have given you and of course helping out around the house.
I’ve made a video of how to make a snakes & ladders game in scratch. It is tailored towards my Explorers Group here in Coderdojo, Athenry but of course it is available to anyone and feel free to share it.
I hope to do more if I can but you’ll get notified when a new video is up. I have created a YouTube channel so you can the video as it was too large for this website.
Here is the link: https://youtu.be/cjQ0qE6ALLI
Hope to see you all soon and don’t forget,
KEEP WASHING THOSE HANDS!
Martha
Hi All
As you all know Clarin College is closed until at least 29-Mar-2020, as a result we will not be able to run CoderDojo Athenry until the school reopens.
The CoderDojo Foundation have also announced that the Coolest Projects Showcase that was scheduled to take place on 06-Jun-2020 in the RDS has been cancelled.
We will keep you updated by email, on Facebook, Twitter and here if the situation changes.
Enjoy St.Patrick’s weekend.
Declan
This week we looked at the mechanical design for our Connect 4 robot. We need a way to hold the tokens and drop one into a slot when the game-playing AI decides what to play.
We started with two ideas for holding the tokens:
The photo below shows an illustration of the magazine idea.
The magazine would move across the board and drop a token into a slot by pulling out the lower pin. The upper pin would hold the rest of the tokens in place so that the wouldn’t drop into the board. Once the bottom token was dropped, the lower pin would be pushed back and the upper pin pulled out to allow the tokens to drop down one step.
The disc idea involved it rotating into place over the board and dropping a token into the board as needed.
We decided that both ideas were impractical on size grounds: the magazine and disc would be very high and hard to support.
We eventually settled on a modification of the magazine idea: 3 magazines with 7 tokens each. This would be smaller and more stable. It does require us to keep track of the number of tokens in each magazine. That’s something our code should be able to manage.
We decided to keep the position of the magazines fixed. A carrier (think cup) could move under the magazine, collect a token and drop it into the board. The magazine and carrier would both need a single pin at the bottom to hold the tokens in place. The carrier should be the height of a single token, so that only one can drop into it. The carrier would have an arm (like a handle) that sits on the magazine side and holds the other tokens in position.
We spent some time discussing how to move the pins in and out before one ninja had a great idea: the pin should be the arm of a servo motor. The servo can rotate the arm through 90° to allow a token to drop.
We then considered how to move the carrier back and forth. We settled on having a single stepper motor drive a gear on a rack that holds the carrier. Turning the gear moves the rack and the carrier into position. Keeping track of the carrier position might be difficult. The easiest way would be to measure the time it takes to reach a particular slot and then power the motor for that amount of time. The problem with that is that it depends on the motor always taking the same amount of time to reach a slot. The motor might slow down as the battery driving it runs down. Mentor Declan suggested using a beam sensor to locate the correct position. We could put a marker above each board position and stop the motor when the sensor reaches the marker. That marker could be something as simple as a small hole. If the beam shines through the hole instead of reflecting, the mark has been found.
Lastly, we considered how to hold everything in place. We think that a large piece of plywood should do the job. We can also attach a sheet of paper to the plywood behind the board to help the vision system see the empty slots. Mentor Kevin pointed out that anything in the background of the board with the same colour as the tokens could confuse the vision system.
The photo below shows a sketch of the final design.
So, where will the parts from our design come from?
We have an old flatbed scanner that we can scavenge parts from. It has a gear and rack system to move the scan head. It should be long enough to meet our needs. We haven’t looked at the motor that drives the gear yet. We will have to figure out if we can power it and control it. If not, we have motors from previous projects that we can use. The gear probably won’t fit one of the old motors, so we will have to modify it. Or, we can 3D-print a part that will allow us to fit the gear to the motor. That worked well for us last year when we made axles to allow us fit wheels to the motors we had for our hide and seek robots.
We will have to 3D-print the carrier. It will probably take a few iterations to get something that works. It will need to be the right size to hold only one token, and be shaped to stop tokens from dropping lightly and getting wedged. Some experimentation will be needed. We can 3D-print the magazines as well, or maybe make something from plywood strips and cardboard.
We will also need to make a camera mount for our vision system. The mount will need to sit in front of the board, out of the way of the human player. It will need to be in a fixed position so that it covers the whole board and allows us to reliably identify token positions. This will probably be a mix of a 3D-printed part and plywood.
We will tackle these tasks at our next session.
For the last two weeks (with a break for a Red Weather Warning!) we worked on a Pacman type game. We tried to put in all the code we have learned over this year and all the games were brilliant and all so different.
We designed our own sprites rather than take them from the library.
Here are the notes in PDF CDA-S9-Week_05_Pacman.pdf
Here is a link to the game if you want to check it out. https://scratch.mit.edu/projects/375094277
See you two weeks time, keep yourselves safe and healthy.
Martha
Julie, Ruaidhrí, Iseult and Eoin
We continued with our tank. In this session we:
Which was a lot!
Here are the video notes:
The updated tank model can be found here.
As we plan our AI robot to play Connect-4, we have decided that Python would be a good programming language for the job, as it is widely used for many of the tasks we will need to do:
Therefore, we spent time this week brushing up on Python. Following the same approach that we had used previously to move from Scratch to C, we looked at how we would move from programming in Scratch to Python.
Here is the full set of notes (PDF): CoderDojo-Hackers-IntroToPython
Kevin then spent time explaining how to write a basic Python program to read an image from a webcam. Here is the code:
# We are using OpenCV
import cv2
# Capture webcam image
camera=cv2.VideoCapture(0)
val, img = camera.read()
# Display the image
cv2.imshow("Window display", img)
# Stop using the camera
camera.release
This week we continued with our tank model.
We created a set of wheels from a cylinder which we then scaled, duplicated and used inset and extrude to provide a little detail on each wheel.
We then created a bezier curve to define the shape of the track across then wheels. Bezier curves are an easy way to defined a smooth shape. They have a number of points through which the curve passes. Each point has a pair of handles. The rotation of these handles defines the angle at which the curve passes through the point. The distance between the handles defines how tightly the curve bends as it approaches the point.
Here are the video instructions for this week:
The updated tank model can be found here.
Hi everyone,
You all did great work on Saturday, there was some quite complex thinking to be done to figure it out but you did great!
Can you improve our game??! Can you figure out how to subtract or multiply instead of add? Can you get the computer to add three numbers together or give the user 3 level options like: easy, medium or hard? The notes for the Maths Game are here: CDA-S9-Week_4_20-MathsGame.pdf
and here is a link to the game
https://scratch.mit.edu/projects/367754778/embed
See you all in two weeks, enjoy the mid term break!
Martha
Julie, Ruaidhrí, Eoin and Iseult
Hi everyone,
We completed our Mario game this week. We coded Mario so that he always floated down on to the wall. We added a fraction of a second of a wait so that it appears that he floats as he comes down. This also allows time for you to navigate left or right as needed.
We also introduced a more advanced concept, the Parallax effect, whereby objects further away appear to move slower than objects nearer. We coded mountains and a Sun to demonstrate this.
You will a full version of the my notes in pdf form here. CDA-S4-Challenge09-Scrolling.pdf
Have a great Easter!
Martha
