Overall concept  

Floral Frenzy is an original design experience which seeks to tap on the emotional responses of the users. Unlike other video games, there is no “winning” or “losing”. Instead, this project relies on the exploration and curiosity of the individual, as well as offering a visually pleasing experience.

The initial ideas consisted of creating a background with multiple static elements, such as mountains, trees, and bushes, and only a few interactive objects that would contain multiple functions. However, after some trial and error, this plan shifted and I decided to add more objects with interactivity in order to balance the weight of static vs interactive.

How does the project work 

From the spaceships, floating stones, and blue trees to the massive fantasy-like structure, this project consists of a mystical, otherworldly plane, drawing the user’s attention from one point to another. Nonetheless, the roses are meant to be the main focus of interactivity, as each of these contain a different reaction, such as releasing a symphony, displaying text, or displaying an unexpected result. Nonetheless, in order to produce the illusion of failure and success, two of the roses are programmed to either poison or compliment the user.

Overall the end result is a game-like set of visuals in which the user is given the instructions to interact with the object, these being the roses, and press a single key in order to delve into the real experience filled with animations in the background, vibrant colors, elements of a variety of sizes, and the interactive objects. Two of these objects provide different outcomes which then take the user back to the homepage.

Fullscreen Mode Sketch 

Link to sketch: https://editor.p5js.org/imh9299/full/HPfU68QCi

Embedded sketch:

Favorite code snippets

Although it appears to be a simple, clear function and codes at first glance, it took me many hours to decipher how to make the music, text, change of color, and other reactions to activate whenever the user clicked on them. Nevertheless, once it proved to be operational, I was filled with joy and I was proud to have completed it successfully, especially since this is the main interactive attraction of the project.

function mousePressed() {
  // helpful debug print
  print('mousePressed at', mouseX, mouseY, 'gameState:', gameState);

  // Only win/lose while the game is playing
  if (gameState === "playing") {
    if (winningRose.contains(mouseX, mouseY)) {
      print("clicked winningRose");
      wonGame = true;
      gameState = "end";
      return; // stop further handling this click
    }

    if (losingRose.contains(mouseX, mouseY)) {
      print("clicked losingRose");
      wonGame = false;
      gameState = "end";
      return;
    }
  }

  // Other clickable objects (always checked)
  if (flower.contains(mouseX, mouseY)) {
    print("clicked flower");
    song.play();
  }

  if (messageRose.contains(mouseX, mouseY)) {
    print("clicked messageRose");
    displayText = !displayText;
  }
}

Another code I am very proud of is the one that allows my cut image of a rock float in the background. At the start, I had to introduce all the variables such as the image, the preload function, fixing the size, speed at which it moved, tracking the time, among other things. While this wasn’t the most difficult codes to understand, it took me a while to find a way to transfer them from a clean, almost empty sketch to one filled with more than one hundred codes. Not to mention, once I managed to implement this code, I found myself struggling to make the music in one of my objects play again. Nevertheless, it was worth the effort as I like how this simple animation adds a new layer of life, along the moving spaceship and fantastical creature,  compared to the rest of the composition.

let rockX, rockY; // Position of background rock
let amplitude = 20; // How far up and down the rock moves
let speed = 0.04; // How fast the rock bobs
let time = 0; // A variable to track time for the sine wave
let rockImage; // Image of the rock

// --- ROCK ANIMATION (only in game) ---
let yOffset = sin(time) * amplitude;
let currentY = rockY + yOffset;
image(rockImage, rockX, currentY, 160, 160);
time += speed;

Areas for improvement and obstacles along the way

Some of the major obstacles I ran into was the integration of interactivity to the sketch. While I managed to build the necessary functions, classes, and parameters to apply interactivity for the sounds, text, and other responses, embedding these into my designed objects proved to be far more challenging than I expected. Not only did these responses have to activate as a result of the interaction of the user, but they also had to be contained within the “game-like” structure of the sketch. Furthermore, fixing the position of these objects, along the non-responsive ones, also forced me to explore multiple x and y positions so that the objects, images, and all additional elements could adapt to the windowWidth and windowHeight. Finally, after solving the issue of merging interactivity with the objects, finding a way to assemble Game states and the transitions between start, playing, and end states turned out to be a difficult challenge. Given that my project was specifically designed to be explored and simply be “visually pleasing”, integrating a game-like structure meant finding an end result that would match my project’s story and tone, and remain original. Despite all the struggling, after many hours of exploring and researching the p5 references, libraries, and works done by students in the past, I managed to overcome all these obstacles and offer this final product which I am genuinely happy about.

Some areas of improvement I would like to work on my next project would be the use of interactivity. Although I did include interactive objects, these are not as impressive as I initially thought. I would like to challenge myself to create a more interactive and engaging element such as the games designed by my peers, not only for my assignments but to also implement in my future non-academic works. Furthermore, I would like to learn how to make my codes look “cleaner” and make functions and classes in a way that reduces my stress when I need to find a specific code.

References:

Images: Rocks, Spaceship, and Fantasy structure were downloaded from Pinterest. The fantasy creature is an original design

Mouse press: https://drive.google.com/drive/u/0/folders/1Qx5kltRZwxzt7Z6l-G-mabzWDUs7nLgj

Elements: https://p5js.org/reference/p5/p5.Element/

Ai overview displaying text through an object: how to display text when clicking an object p5

Window width height example by professor Aya: https://editor.p5js.org/mangtronix/sketches/t4G0erH1B

Text Font: https://p5js.org/reference/p5/textFont/

Mirror image: https://editor.p5js.org/icm4.0/sketches/ETcm93Ua1

Float: https://p5js.org/reference/p5/float/

Used ChatGTP to clean my codes, (also to store and recover them since I suffered from constant glitches that deleted my information), and to find errors in my work whenever a specific element was not showing or it wasn’t processing its intended objective.

Concept

Color Gate Challenge is a fast and colorful reaction game where the player controls a glowing ball that changes colors to pass through matching gates. The idea came from color-matching and reflex games I used to play, but I wanted to create something that feels more modern and bright, with glowing effects and smooth motion.

The goal of the game is to move the ball through falling gates without hitting the walls. Each gate has a color, and the player must change their ball to the same color to pass safely. If you pass the wrong color or crash into the barrier, the game ends.

My Final Game:

Code Snippet and Parts I Am Proud Of:

One of the parts I am most proud of is how I  control the player, the gates, and the full game system.
Each part of the game (player, gate, and main game) is built as a class, which made it easier to add new features later.

The player’s color can change, and the game checks if it matches the gate’s color before letting the player pass. This made the logic clear and fun.

if (this.player.checkCollision(gate)) {
this.gameOver();
return;
}

This simple check controls the whole challenge of the game.
If the player touches the wrong color or hits the gate walls, the game ends immediately.

I also added a color preview system that shows the next few gate colors, so the player can plan ahead.
It uses small color dots on the screen to help the player see which color to switch to next.

this.upcomingGates.forEach((gate, index) => {
const dot = document.createElement('div');
dot.className = 'color-dot';
dot.style.background = this.getColorString(this.player.colors[gate.color]);
colorPreview.appendChild(dot);
});

Another part I am proud of is how the speed control works. The player can press keys to make the gates fall faster or slower, and there is a live bar that shows the speed level. This made the game more interactive and customizable.

Problems and Future Improvements

At first, the game was too easy because the gates were falling too slowly, and it didn’t feel challenging. I changed the gate speed and added random colors to make it more unpredictable and exciting.

Another problem was keeping everything in the right position when resizing the window. I had to fix the player’s size and position every time the screen changed, using the windowResized() function.

In the future, I want to:

• Add special gates that move sideways

• Add sound effects for color switches and collisions

• Add power-ups that give the player a shield or slow motion

• Create a moving space background for more depth

• Add more visual effects like explosions and particle trails

Concept:

I think it’s safe to say that a lot of events on campus have photobooths, and even stores in malls. I wanted to do something similar, but fully digital. While my current sketch isn’t very aesthetic yet, I plan to model it after the Urban Outfitters photobooth, adding playful visuals and frames to make the experience interactive and fun, like a real-life booth.

The user interacts with the photobooth through a series of pages. They start at the main booth screen, where they can click a button to enter their name on the Start Page. After submitting their name, they move to the Filter Page to see a live video feed and choose a filter by pressing the arrow keys. Once they select a filter and click “OK,” they reach the Frame Screen, where they can take a photo. Finally, the Thank You Screen appears with an option to restart, which loops them back to the booth, letting them take another photo. Each page guides the user step by step, making the experience clear and interactive.

Code design :

All the pages are in their own class.

• • PhotoBooth: The main screen where users start. Displays the booth and a button to enter the next step.
  • StartPage: Handles the user’s name input and the “Start” button to move to the filter selection.
  • FilterPage: Shows a live video feed and lets users choose a filter using arrow keys, with an “OK” button to proceed.
  • FrameScreen: Applies the selected filter to the video and allows the user to take a photo with a camera button.
  • ThankYouScreen: Confirms the photo has been taken and offers a button to restart the booth.
  • Flow control: currentScreen determines which class is displayed, and button/key interactions manage transitions between screens.

Difficulties:

I think that throughout implementing this, the filter page class was the most troubling. I had to use the translate function to mirror my video feed because I wanted a mirrored picture as the result, and I needed it to only apply this to the video, and not the text and button. 

//mirror the video (so it feels like a mirror)

    push();

    translate(width, 0);

    scale(-1, 1);

    image(this.video, 0, 0, width, height);

    pop();

Another key part of the project is the filters and how the selection works. Each filter is applied as an overlay on the live video feed, and the user can browse through them using the left and right arrow keys. I also made sure the selection loops continuously, so moving past the last filter brings you back to the first one.

 //sepia filter overlay

    if (this.filters[this.currentFilter] === "sepia") {

      fill(112, 66, 20, 60);

      noStroke();

      rect(0, 0, width, height);




      //black & white filter using canvas filter

    } else if (this.filters[this.currentFilter] === "bw") {

      push();

      tint(255, 255);

      drawingContext.filter = "grayscale(100%)";

      translate(width, 0);

      scale(-1, 1);

      image(this.video, 0, 0, width, height);

      drawingContext.filter = "none";

      pop();

    }

nextFilter() {

    //go to next filter (wraps around)

    this.currentFilter = (this.currentFilter + 1) % this.filters.length;

  }




  prevFilter() {

    //go to previous filter (wraps around)

    this.currentFilter =

      (this.currentFilter - 1 + this.filters.length) % this.filters.length;

  }

To deal with, or let’s say minimize the risks with these two implementations, I first tested them out in a separate sketch on p5.js, and when I made sure they worked how I wanted them to, I added them to my project flow. I also added console logs to help me debug and then removed them once everything was working as expected.

Lastly, this project really tested my understanding of how order matters. I had to use .hide() a lot to make sure buttons and features weren’t carried on between screens. 

Reflection:

Now that the structure is solid, I can focus on making it look appealing. I’m open to any suggestions and even suggestions for my current flow!

Here’s my Sketch:

Concept:

For this assignment, I wanted to create a data visualization that conveys information through motion and color. Initially, I tried using real-world GDP data I downloaded from Kaggle, but I ran into errors because some columns were missing values, and I wasn’t sure how to handle those gaps. So, I decided to create my own fictional CSV file with made-up GDP numbers for a larger set of countries. Each country is represented as a bouncing circle whose size reflects its GDP and whose color adds a visual layer of distinction. The animation gives the data energy and makes patterns easier to notice. I also utilized arrays and a custom class to organize the circles, dynamically managing their movement, size, and color.

Code Highlight:

One part of my code I’m proud of is how the circles move and react to the edges of the canvas. Each circle has its own speed and direction, creating a sense of individuality while still forming a cohesive scene. I also added a feature that displays the country’s name when you hover over a circle, allowing you to read the data without cluttering the visualization.

if (dist(mouseX, mouseY, this.x, this.y) < this.size / 2) {
    fill(255);
    textAlign(CENTER, CENTER);
    textSize(18);
    text(this.name, this.x, this.y - this.size / 2 - 10);
}

Embedded Sketch:

Reflections & Future Improvements:

This project taught me how to combine datasets with visual techniques to make information more intuitive. I realized that adding motion and color can turn raw numbers into an engaging experience. Hover interactions enhanced the usability, making the visualization informative without overwhelming the viewer.

For future improvements, I would like to make the visualization more interactive, perhaps allowing users to filter by region or toggle between GDP and population. I also want to experiment with color gradients or circle trails that respond to velocity, so the data becomes even more expressive. Overall, this project helped me understand how programming, animation, and data can intersect to communicate ideas creatively.