Advancers -Boiling Water

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Introduction

This week we looked at what happens to water molecules when they are heated up.

We started with a little science experiment to demonstrate Brownian Motion, this was done with a glass of very hot water and a glass of very cold water and some ink.

When the ink is dropped in the two glasses it behaves very differently, in the cold water the ink stays suspended and visible as ink for a long time, but in the hot water the ink gets mixed into the water molecules very quickly, this is because the water molecules in the hot water are moving around much faster and bashing into the ink molecules and mixing them up.

BrownianMotion

Can you guess which glass has the cold water in?

The Plan

The plan was to build a scratch program that would  show the water molecules moving around faster or slower, depending on temperature. In order to do this we needed the following:

  • A Sprite for our water molecule
  • A slider to control the temperature
  • Some code to make them move around.

The Sprite

Water molecules are made up of 2 Hydrogen atoms and 1 Oxygen atom (H2O), the Oxygen atom is quite large compared to the Hydrogen atoms and the Hydrogen atoms stick to the Oxygen atom at about a 45 degree angle, they end up looking like Mickey Mouse, so our Sprite looked something like this:

Sprite            SpriteSettings

We changed the settings of the Clone so it didn’t rotate.

The Temperature Slider

In order top control the temperature we created a variable, making sure that it was set for “All Sprites” and that it was set to be a slider. We also set the minimum and maximum values:

TempSlider

The Code

As we needed lots of these Sprites we decided to use the Create Clone block (Control) to create 100 of them.

In order to move the Sprites around we needed to keep looping, picking a random direction and then moving a little bit. We also needed to change the amount we moved and also the direction as the temperature went up. The direction needed to be more upwards as the temperature got higher so the water molecules would start floating like steam if the temperature got high enough.

We used a Gravity variable to make sure the Sprites pointed upwards as the temperature got higher, because this needed to be different for all the Sprites so they moved in random directions, we created the Gravity variable “For this Sprite only”

The code ended up looking like this:

GreenFlagCode

 

Initialise the Temperature variable and then create 100 clones.

 

 

 

CloneCode

 

Initialise the Sprites Gravity variable

Pick a random spot along the bottom of the Stage

Make sure we are pointing more towards the top, depending on the temperature.

 

 

If the temperature is > -1 move around, otherwise we are frozen, so just go back to the bottom of the screen.

 

 

Notes:

The project that we built is available on the Scratch Web Site:

User Name : cdadvancers1819
Password : advancers

Project : Class-BoilingWater

Remember, you can put your own projects up there as well if you want.

 

 

 

 

Advancers – Gravity

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Introduction

This week we decided to create a Lunar Lander game that demonstrated the effects of Gravity.

The Plan

As always we started with a plan:

  1. A Spaceship Sprite with 4 Costumes
    1. No power
    2. Up Rocket firing
    3. Left Rocket firing
    4. Right Rocket firing
  2. Buttons to control the Space Ship
  3. Stage which should be a picture of the moon.
  4. A landing pad to land on – just draw on the Stage
  5. Code to control the Space Ship
    1. 3 Variables, to store Gravity, Power and LeftRight information.

Space Ship Sprite

This what mine looked like:

SpaceShipSprite

Space Ship Sprite

 

 

 

The Left and Right costumes can be confusing, to move left, the flame needs to come out of the right, and to move right the flame needs to come out of the left hand side.

 

 

 

 

 

 

Stage

My Stage looked like this:

Stage

 

One thing to remember is to have the landing pad in a different colour.

Buttons and Code

I’ll put these 2 parts of the plan together as it makes more sense.

We decided to use 3 different buttons to control the Space Ship

  1. Up Arrow – This would fire the rocket at the bottom of the Space Ship
  2. Left Arrow – This would fire the rocket on the right side of the Space Ship
  3. Right Arrow – This would fire the rocket on the left side of the Space Ship

And now the code.

We needed code for each of the buttons, code to move the Space Ship and code to know when we have landed. This meant we had lots of small pieces of code all running together in Green Flags with forever loops.

We also decided that we would need 3 variables to store information so we could work out how far to move the Space Ship.

  1. Gravity – This would change as the Space Ship got higher, just as real gravity does.
  2. Power – This would change when the Up arrow was pressed and also when nothing was happening
  3. LeftRight – This would change when the left or right arrows were pressed

And don’t forget if we have variables, we should set them to starting values when the Green Flag is clicked.

Initialise

 

This also has the code that puts the Space Ship in to a starting position. Note the Y value as this is used later in the code to see if we are on the ground or not.

 

For example, when the one of the left or right arrow keys was pressed we would change the Costume and change the LeftRight variable.

RightArrow

 

We did the same for the left arrow. Note that we just add (or subtract for the left arrow) a small amount from the LeftRight variable.

The delay is to make sure that the variable is not updated too fast if the arrow button is held down.

 

For the Up arrow we have to change a different variable

UpArrow

 

Note the wait is much shorter, this is to match the wait in the forever loop that moves the Sprite.

We also change the Power variable by a large amount as this helps with the calculations.

 

Once we had the buttons working we could move on to the Code that moved the Sprite.

The Left or Right movements were easy, that would just be the amount in the LeftRight variable.

The Up or Down movements were a little trickier as we had to account for Gravity as well. So we just used the Y position of the Sprite and added 180 (to make it a positive number). This meant that Gravity changed as the Sprite moved up or down, which is exactly how Gravity works in real life.

This is how the code ended up

MainForeverLoop

 

We move first and then check how high we are.

If we are above the ground, we know this by checking that we are above the starting position of the Sprite, then we adjust Gravity and adjust the Power down.

Note the wait is the same as the Up Arrow code.

Also, if we are on the ground, we set Gravity and Power to 0.

 

 

There was one final piece of code that we didn’t do but I have added here, this was to check if we had landed and if we had, display a message and end.

It was just another Green Flag with a Forever loop and we kept checking to see if we were touching the colour of the landing pad.

Landing

 

Not much here, but might be better if there was a wait as well.

 

 

 

Finally, if you want to see all the code in one go, here it is

AllCode

Notes:

The project that we built is available on the Scratch Web Site:

User Name : cdadvancers1819
Password : advancers

Project : Class-Gravity

Remember, you can put your own projects up there as well if you want.

Bodgers – Making Pictures With LEDs

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Hello again everyone.

We started of this week’s session by looking at the recent Soyuz rocket launch which was to send two people to the ISS. During the launch one of the booster rockets failed and the launch had to be aborted. Both crew members, astronaut Nick Hague and cosmonaut Aleksey Ovchinin, escaped without injuries.

Official astronaut portrait of Tyler (Nick) Hague – Blue Flight Suit Picture. Photo Date: January 13, 2014. Location: Building 8, Room 183 – Photo Studio. Photographer: Robert Markowitz

We then continued to work on our pictures and messages for the Mission Zero Challenge. I made a video of some of the work we did, but it’s very hard to film LEDs so the quality is very poor.

If you want to find out more about the Soyuz incident and have another look at how to make pictures and messages with the Sense-hat LEDs my notes are here day 4.

Next Saturday we’ll start looking at Pygame Zero. See you all then.

Declan, Dave and Alaidh

Creators – Pattern

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washer-machine-porous-mechanical-83852

This week we looked at two important concepts, loops and lists.

Loops

Start by imagining we wanted to draw four circles next to each other. We could write four calls the ellipse function, like this:

let size = 50;

ellipse(25, 25, size, size);
ellipse(75, 25, size, size);
ellipse(125, 25, size, size);
ellipse(175, 25, size, size);

Pretty easy. What if we had variables for the positions? We’d get this:

let size = 50;
let x = size / 2;
ley y = size / 2;

ellipse(x, y, size, size);
x = x + size;
ellipse(x, y, size, size);
x = x + size;
ellipse(x, y, size, size);
x = x + size;
ellipse(x, y, size, size);
x = x + size;

It’s longer than before, but notice how the same two lines now keep repeating. If we had a way to say “do these two lines four times” then this would get much shorter, and we do. We use the for statement:

let size = 50;
let x = size / 2;
ley y = size / 2;

for (let i = 0; i < 4; i++){
  ellipse(x, y, size, size);
  x = x + size;
}

The for statement is a bit complicated, so let’s break it down:

for (do first; check to see if we keep going; do every time 2) {
  do every time 1
}

Note the curly brackets (braces) containing the stuff we want repeated.

So in our case we:

  1. First create a new variable called i and give it the value 0
  2. Check to make sure that i is less than 4
  3. Draw our ellipse and make x bigger
  4. Increase i by 1
  5. Go back to step 2 and check if we can keep going, otherwise stop

This means that i will have the values 0, 1, 2 and 3 and our two lines will be run four times in total. Result! Our code can draw a row of circles. If we increase the value in the check, we can have as many as we like. We choose to have 8.

Nested Loops

Nesting a loop means putting one loop inside another. What’s the point of that? Well in our case we have a loop that can draw a single row of circles. If we put all of that inside another loop we could draw several rows. The row outside has a different variable j and also runs eight times. After we draw our row we do two things:

  1. We make y bigger move down the screen
  2. We move x back to the left to its starting position for the next row

The code now looks like this:

let size = 50;
let x = size / 2;
let y = size / 2;

for (let j = 0; j < 8; j++){
  for (let i = 0; i < 8; i++){
    ellipse(x, y, size, size);
    x = x + size;
  }
  y = y + size; // Move down and
  x = size / 2; // Back to the left
}

We now have 8 x 8 = 64 circles in a grid.

Changing the Colour of Some Circles Based on a Check

We then added code just before our call to ellipse() to change the colour based on some check:

if( /* some check here */ ){
  fill("red");
}
else {
  fill("white");
}

We experimented with some different checks to see what might happen. This check turns the upper-left of the grid red:

if (i + j < 8 ){ 
  :  :  :

This check, using the modulus operator, turns every third circle of the grid red:

if ((i + j) % 3 == 0){ 
  :  :  :

This check paints a red cross through the centre of the grid:

if (i == 3 || i == 4 || j == 3 || j == 4){ 
  :  :  :

Lists

We then jumped quickly into lists. Also called arrays, lists are like a variable that can store several values. We create them simply like this:

let a = []; // An empty list
let b = [1, 2, 4, 7]; // A list created with four entries

To get at the entries in a list you just use the list variable’s name and square brackets containing the number of the entry in the list you want to get out, noting that the first one is zero:

b[0] = 10; // Set the first entry in the list to ten
b[4] = 301; // Set the fifth entry in the list to three hundred and one

A list isn’t just for holding numbers though, it can hold anything. It can hold strings for example, or even other lists!

It’s this idea of holding lists that we use to define our pattern.

Defining our Pattern

We make a list with eight entries, each of which is a list also containing eight entries, all zero. We write it so it forms a neat block like this:

let pattern = [
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0]
];

Then down in our code, where we’re deciding what colour to make our circles, we change the check to read:

if (pattern[j][i] == 1){  
  : : :

What does this mean? Well, j is a counter that goes from 0 -> 7 as we go down our eight rows. Given that, pattern[j] means get entry from our list for that row. Since pattern[j] is a list too, we need to say which entry we want in. The variable i goes from 0 -> 7 as we go across each row. So, pattern[j][i] gets the list for the row and then picks out the number for that column.

Once it’s set up, we can then change zeros to one in our pattern and have our circles turn red to match (red in the text below to make them stand out):

let pattern = [
  [0, 0, 0, 0, 0, 0, 0, 0],
  [0, 0, 1, 0, 0, 1, 0, 0],
  [0, 0, 1, 0, 1, 0, 0, 0],
  [0, 0, 1, 1, 0, 0, 0, 0],
  [0, 0, 1, 1, 0, 0, 0, 0],
  [0, 0, 1, 0, 1, 0, 0, 0],
  [0, 0, 1, 0, 0, 1, 0, 0],
  [0, 0, 0, 0, 0, 0, 0, 0]
];

Screenshot 2018-10-15 at 18.14.34

We have essentially built something that works like an image file! Our pattern is the image data and our program is the code that draws it.

As several smart people already noticed, you’re not limited to one and zero. By using more numbers, and expanding the if statement, you can have as many colours as you like.

Download

The files for this week are on our GitHub, as always.

Explorers Week 5 – Help Bo Peep find her sheep

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Hi everyone,

Thanks for coming Saturday even though the weather was dreadful.

This week, I helped Bo Peep found her sheep! Some of you did the same and some used ideas like Minecraft Steve finding Iron Ore and Diamonds, Knights finding dragons or a Princess finding flowers.

Before we even started our game this week we talked a little bit about File Management and about the importance of keeping your files somewhere you can access them quickly and giving them a meaningful name.

So to this end, we all created a folder where we will be keeping our files in the future and within that we had a sub folder for this weeks files.

We started our game by drawing our background on our stage:

Unfortunately, due to internet problems we could not search the internet for images for our Sprites, but we could still use the sprites from the Scratch Library.

This week, we decided to move our main sprite using the arrow keys. For this we had to learn a small bit about the X and Y axis and I gave you a little tip on how to remember which is which!

Hope you all enjoyed this week, aee you next week when we will be starting a new game!

Here are the notes for this weeks session in PDF CDA-S7-Week_05-BoBeep.pdf

Martha

Julie, Ruaidhrí and Eoin

 

Hackers – Temperature Control, Part 2

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Today we continued towards building a temperature controller.

Last week, we used an LM35 temperature sensor to read the temperature in the room and report it on the Arduino serial console.
We were able to get a reading for the temperature of the air in the room, and the temperature of a cup of coffee touching the sensor.  We couldn’t be sure, however, that the readings were correct.  So, we decided to test with a potentiometer and a voltmeter.

We supplied 5 V to the potentiometer and fed the output to the Arduino.  We used a voltmeter to measure the output from the pot and compared it to the reading from
the Arduino.  Once we got the code working, we got good agreement on voltage readings between the meter and the Arduino.

The sensor presents a voltage on its output pin that represents the temperature its measuring.  In its basic mode, the sensor reads temperatures between 0.2 and 150 degrees Celsius.  Every degree is 10 mV, so the output voltage ranges from 2 mV to 1500 mV.  Converting our voltage reading to a temperature is simple then:  divide the voltage reading in millivolts by 10.

We can use one of the analog I/O pins on the Arduino to read the voltage.  The analogRead() function returns a value between 0 and 1023 for voltages between 0 and 5 V.

We digressed into how to use a multimeter correctly.  The first thing to do is make sure that our meter is set up correctly.
We tried measuring a 9 V DC battery with the DC voltage setting and got 9.2 V.  We then tried measuring the same battery with the AC voltage setting.  This time we got 19.6 V.
There’s a lot of potential (sorry) to get confused, then.  Worse again, if we try measuring 220 VAC with the meter set to DC, we get a reading close to zero.  In other words, a live AC supply looks safe if we set our meter wrong.

Next, we start with the highest reading range and step down.  For a 1.5 V battery, we start with the 200 V reading, then step down to 20 V.  This is to protect the meter:  if the voltage is higher than we expected, we might damage the meter.

Voltage readings are taken in parallel with the circuit, and while it is live.

Resistance and continuity readings, on the other hand, are taken with the component disconnected from the circuit.
We worked out why with a simple circuit:

circuit1

F is a fuse.  W is a wire between the two ends.  We’re not sure if the fuse is blown.  We try testing for continuity across the fuse by putting our meter leads on A and B.
Even if the fuse is blown, we will get continuity because W provides a circuit.  We need to cut the wire to get a true reading.

Our first attempt at Arduino code for the voltage reading gave us a surprise.  Our meter displayed 2.5 V.  The Arduino displayed 2 V.  We used this formula to calculate the voltage:
v = 5 * analogRead_reading / 1023.
V was declared as float variable.  analogRead_reading was declared as an int.  The Arduino code multiplied two ints and divided the result by another int, truncated the result and stored the int as a float.  When we made the 5 and 1023 floating point numbers (5.0 and 1023.0), we got the right answer.

Once we were happy with the Arduino code, we replaced the potentiometer with an LM35.  Unfortunately, we didn’t notice the “bottom view” label on the datasheet drawing.  We connected the 5 V supply to the wrong side of the sensor.  It’s amazing how hot a temperature sensor can get!  It was too hot to touch.  And we couldn’t measure the temperature because…
After we disconnected the LM35, we made another discovery:  we continued to get random voltage readings displayed on the Arduino even though there was no voltage to read.  The analogRead() function happily outputs values from random noise.

Next week, we’ll use an LM35 connected the right way around, and try controlling a relay to switch power on and off to an external device.  We’ll build a temperature controlled soldering station carefully – we want to solder with the tip of the iron, not the temperature sensor.

Bodgers – Making With Trinket.io

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Hello again everyone.

In the Bodgers group,  we’ve been working on code for the International Space Station. To do this we are using on online Sense Hat emulator, the Sense Hat is a special piece of hardware designed to be deployed with a Raspberry Pi on the ISS.

Capture15

The online emulator is available at https://trinket.io/sense-hat and there’s a good tutorial on the Raspberr Pi website here https://projects.raspberrypi.org/en/projects/astro-pi-mission-zero.

Here is our Trinket https://trinket.io/python/04b90b70cf.

You can play around with these and we will probably finish up with the Mission Zero Challenge for while after Saturday. My slides from last Saturday are here day 3.

See you all on Saturday.

Declan, Dave and Alaidh

Creators: Creative Coding with p5.js

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What is P5?

This week we looked at p5.js – a library to make creative coding in javascript MUCH easier!  We first downloaded and copied p5.js onto our computers, and copied it into a new project folder.  We included p5.js in a html file, just like we included our own javascript file last week.

In fact, we looked at the file and realised that p5 is just another javascript file, just like the one we wrote – the code is long and looked a bit complicated, but it was basically the same kind of thing.

 

But really, what is P5?

p5 is a set of functions that make it easy to write programs for the most interesting parts of javascript!  Mainly, for drawing and animating things on a webpage, but also for sound, and other stuff.  If has lots of functions for:

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Explorers – Week 4 – 2018, Improving Our Game!

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Hi everyone,

Thank you do everyone you came along on such a lovely day on Saturday, hope you all got to go outside when you went home and enjoyed the weather.

This week, we improved on our game from last week.

Most games reward us for achievements (Gaining:Scores/Money/Health) and penalise us for making mistakes (Losing:Lives, Health, Money)

To this we had to create a Variable. Remember my box with the blocks. A variable holds information for you that you can use again. Remember to always give it a name that is meaningful….

Everything we have learned so far we will be using in ,most of our games we will make in future sessions. Don’t worry if you didn’t understand everything, we will be going over it again and again.

Have fun with the code you have done. Maybe try making another game!

Here are the notes from last week in PDF CDA-S7-Week_04-FirstGame-Part2.pdf

See you all next week

Martha & Julie, Ruaidhrí and Eoin