Category: Spring 2024 – Aaron (Section 001)

Week 3 – Flower Garden

My project is an interactive generative artwork featuring a digital garden where flowers bloom and fade over time while butterflies move toward them. The user can interact by clicking anywhere on the canvas to plant new flowers.

My inspiration came from teamLab Phenomena in Abu Dhabi I visited, where there was an immersive environment allowing people to draw butterflies, snakes, and other animals that then came to life in a shared space. That experience brought me back to childhood memories of imagination, and I wanted to capture a similar feeling through code. In future versions, I plan to expand this project by adding sound elements for the atmosphere to be richer and more immersive. I also hope to introduce more types of creatures and possibly explore touch or motion-based interaction.

Inside teamLab Phenomena Abu Dhabi | Condé Nast Traveller Middle East

Explore TeamLab Phenomena General Admission for Adults and Youths - Pt Tourism | Groupon

The program begins in the setup() function, which creates the canvas and spawns an initial set of flowers and butterflies in random positions across the screen. The draw() loop serves as the heartbeat of the sketch. It first draws a smooth vertical gradient sky using the lerpColor() function, transitioning from soft blue at the top to gentle green near the bottom. Then, it updates all active flowers, allowing each one to grow and eventually fade as time passes. Meanwhile, the butterflies search for nearby flowers, moving toward them. The sketch also displays basic information such as the number of flowers and user instructions on planting new ones.

// Arrays to store objects
let flowers = [];
let butterflies = [];

function setup() {
  createCanvas(700, 600);
  
  // start flowers
  for (let i = 0; i < 8; i++) {
    flowers.push(new Flower(random(width), random(height)));
  }
  
  // start butterflies
  for (let i = 0; i < 6; i++) {
    butterflies.push(new Butterfly(random(width), random(height)));
  }
}


function draw() {
  // Draw gradient sky background
  for (let y = 0; y < height; y++) {
    let c = lerpColor(color(135, 206, 235), color(180, 220, 160), y / height);
    stroke(c);
    line(0, y, width, y);
  }
  
  // Update and draw flowers
  for (let i = flowers.length - 1; i >= 0; i--) {
    flowers[i].grow();
    flowers[i].display();
    
    // Remove old flowers
    if (flowers[i].age > flowers[i].lifespan) {
      flowers.splice(i, 1);
    }
  }
  
  // Update and draw butterflies
  for (let butterfly of butterflies) {
    butterfly.moveTowardFlowers();
    butterfly.display();
  }
  
  // Instructions
  fill(255, 200);
  noStroke();
  fill(60);
  textSize(14);
  text("Click to plant flowers", 20, 30);
  text(`Flowers: ${flowers.length}`, 20, 45);
}

// mouse interaction

function mousePressed() {
  flowers.push(new Flower(mouseX, mouseY));
}

// flower class

class Flower {
  constructor(x, y) {
    // Position
    this.x = x;
    this.y = y;
    
    // Size (starts small, grows)
    this.size = 0;
    this.maxSize = random(30, 60);
    
    // colors (random pastels)
    this.petalColor = color(random(200, 255), random(100, 200), random(200, 255));
    this.centerColor = color(random(200, 255), random(180, 220), random(50, 100));
    
    // Life
    this.age = 0;
    this.lifespan = random(600, 1000);
    
    // Look
    this.petalCount = floor(random(5, 9));
    this.angle = random(TWO_PI);
  }
  
  // make flower grow each frame
  grow() {
    this.age++;
    if (this.size < this.maxSize) {
      this.size += 0.5;
    }
    this.angle += 0.005; // Slow rotation
  }
  
  // draw the flower
  display() {
    push();
    translate(this.x, this.y);
    rotate(this.angle);
    
    // Fade out when old
    let alpha = 255;
    if (this.age > this.lifespan * 0.7) {
      alpha = map(this.age, this.lifespan * 0.7, this.lifespan, 255, 0);
    }
    
    // draw petals
    fill(red(this.petalColor), green(this.petalColor), blue(this.petalColor), alpha);
    noStroke();
    for (let i = 0; i < this.petalCount; i++) {
      let angle = (TWO_PI / this.petalCount) * i;
      let px = cos(angle) * this.size * 0.4;
      let py = sin(angle) * this.size * 0.4;
      push();
      translate(px, py);
      rotate(angle);
      ellipse(0, 0, this.size * 0.6, this.size * 0.3);
      pop();
    }
    
    // draw center
    fill(red(this.centerColor), green(this.centerColor), blue(this.centerColor), alpha);
    ellipse(0, 0, this.size * 0.4);
    pop();
  }
}

// butterfly class

class Butterfly {
  constructor(x, y) {
    // Position
    this.x = x;
    this.y = y;
    
    // movement
    this.vx = random(-1, 1);
    this.vy = random(-1, 1);
    this.speed = 1.5;
    
    // wings
    this.wingAngle = 0;
    this.wingSize = random(15, 25);
    
    // colors (random)
    this.wingColor = color(random(150, 255), random(100, 200), random(150, 255));
  }
  
  // move toward nearest flower
  moveTowardFlowers() {
    // Find closest flower
    let closestFlower = null;
    let closestDist = 999999;
    
    for (let flower of flowers) {
      let d = dist(this.x, this.y, flower.x, flower.y);
      if (d < closestDist && flower.size > 20) {
        closestDist = d;
        closestFlower = flower;
      }
    }
    
    // move toward it if close enough
    if (closestFlower && closestDist < 200) {
      let dx = closestFlower.x - this.x;
      let dy = closestFlower.y - this.y;
      this.vx += dx * 0.0002;
      this.vy += dy * 0.0002;
    }
    
    // randomness
    this.vx += random(-0.1, 0.1);
    this.vy += random(-0.1, 0.1);
    
    // limit speed
    let currentSpeed = sqrt(this.vx * this.vx + this.vy * this.vy);
    if (currentSpeed > this.speed) {
      this.vx = (this.vx / currentSpeed) * this.speed;
      this.vy = (this.vy / currentSpeed) * this.speed;
    }
    
    // update position
    this.x += this.vx;
    this.y += this.vy;
    
    // wrap around edges
    if (this.x < 0) this.x = width;
    if (this.x > width) this.x = 0;
    if (this.y < 0) this.y = height;
    if (this.y > height) this.y = 0;
    
    // flap wings
    this.wingAngle += 0.2;
  }
  
  // draw the butterfly
  display() {
    push();
    translate(this.x, this.y);
    
    // point in direction of movement
    let angle = atan2(this.vy, this.vx);
    rotate(angle);
    
    // wing flapping (0 to 1)
    let flap = sin(this.wingAngle) * 0.5 + 0.5;
    let wingHeight = this.wingSize * (0.5 + flap * 0.5);
    
    // wings
    fill(this.wingColor);
    noStroke();
    ellipse(-5, -wingHeight, 12, wingHeight * 1.5);
    ellipse(-5, wingHeight, 12, wingHeight * 1.5);
    
    // body
    fill(40);
    ellipse(0, 0, 8, 15);
    
    pop();
  }
}

 

Every flower is represented by an instance of the Flower class. Each flower starts small and increases in size frame by frame until it reaches its maximum. Colors are chosen randomly from pastel ranges to keep the palette gentle. Each flower contains several petals arranged uniformly in a circle and slowly rotates over time. The petals fade as the flower ages. The Butterfly class handles behavior for each butterfly’s movement, which combines randomness with directed motion toward flowers.

One of the challenges I encountered was controlling butterfly motion. At first, they moved too chaotically. By adjusting acceleration toward flowers and capping their speed, I achieved a more graceful flying style. I also experimented with the fading  for flowers to make the transition from bright color to transparency appear gradual and organic.

Visually, the project is calm and immersive as I wanted it to be. The background gradient,  flower and butterflies all work together to create an environment that feels alive yet peaceful.

Week 3 Reading Reflection – Megan

After reading this chapter I realized that a strongly interactive system is really like having a good conversation. Both sides have to listen think and speak well for it to feel alive. If one side fails it just becomes boring or frustrating. So for a system to be truly interactive it has to respond to the user in a way that feels meaningful not just random or automatic. I liked how Crawford explains that interaction is not the same as reaction like with a fridge or a movie you can only watch but you don’t actually talk to it. That made me think about my p5 sketches because sometimes I make things move or change when the mouse touches them but it feels kind of one-sided. I realized that to make them more interactive I could have the objects respond in different ways depending on how you interact with them like changing speed direction color or even start a little animation that is unique for each action. I also liked thinking about giving each object its own “voice” like the dice in my project could react differently to the same input so it feels more alive and less predictable. I want to experiment more with letting the user affect not just the movement but the behavior and appearance over time so it feels like the sketch is listening and thinking a little bit before it reacts. Overall reading this made me want to make my sketches feel more like a real conversation between me and the code rather than just me controlling it.

Week 3 – Kamila Dautkhan

Concept 

Overall, I wanted to create something that’s between technical and visual. I was inspired by simple motion studies and minimalist generative art, where small variations in movement and size can create an interesting composition. I didn’t really want the artwork to feel chaotic or overly complex. Instead, I wanted to focus on clarity, repetition and subtle variation. My main idea was to treat each block as its own “entity.” When you look at it you can see that all the blocks follow the same basic rules but they move slightly differently since I wanted to create something chaotic rather than static.

Highlight of the Code

I’m especially proud of this part because it is how the blocks are created and stored using a class and an array:

blocks.push(new Block(random(width), random(height)));

I am proud of it because it represents the core idea of the project. It basically generates multiple objects from the same structure while still allowing each one to behave differently.

Reflection

This project helped me better understand how code structure directly affects the visual outcome. I learned that even very simple rules can produce very interesting results if they are applied consistently. I also became more confident using classes and arrays because it felt quite confusing at first but using them actually made the code much easier to manage.

If I were to continue developing this sketch, I would like to experiment with interaction like having the blocks respond to the mouse or to each other. I’m also very interested in exploring color systems more and maybe using gradients in my future works!



Week 3 – Reading Reflection

Reading Chris Crawford’s chapter made me realize that I never really thought deeply about what “interactivity” actually means. I always assumed anything on a screen was interactive, but Crawford explains that real interactivity is like a conversation where both sides listen, think, and respond. When I compare that to the apps and games I use the most, like TikTok, Tetris, and Block Blast, I can see how they fit his definition. These apps react to what I do, and I react back, so it becomes a cycle. Crawford also talks about how the word “interactive” gets thrown around too much, and I agree because I’ve seen products or websites call themselves interactive even when they don’t respond to the user at all. Sometimes a site has so many buttons, menus, or pop‑ups that it feels more overwhelming than interactive. His point about needing two “actors” made sense to me because a system that only shows information without responding to the user isn’t really interacting. It made me think about how much I value visuals, animations, and feedback because those things make a system feel alive and responsive, not just decorative.

The reading also made me reflect on my own p5 sketches and how they fit into Crawford’s idea of interactivity. So far, I’ve made things like my panda portrait and class exercises with bouncing balls and patterns. These sketches react in small ways, but they don’t fully “listen, think, and speak” back to the user yet. Crawford’s definition made me realize that I want my sketches to respond more directly to what the user does. I want to add animation, movement, and user‑controlled elements so the sketch feels like it is reacting to the person using it. I also want to make something that feels more like a small game or a mini‑movie, where characters move and interact with each other. The reading helped me understand that interactivity is not just about visuals but about creating a back‑and‑forth experience. By the end of the semester, I hope my sketches feel more alive and fun, and I want users to enjoy interacting with them. I’m inspired by old pixel games from the 2000s because they feel nostalgic, simple, and playful, and I want to bring that feeling into my work while also making sure the interaction follows the cycle Crawford describes.

Week 2 – Creative Reading Megan

Casey Reas Eyeo talk on chance operations

How are you planning to incorporate random elements into your work? Where do you feel is the optimum balance between total randomness and complete control?

Before answering this questions, I wanted to implement by myself the concepts the video was talking about. Randomness. One quote by Casey Reas really stayed with me: “change it by a little so that movement creates chaos in an ordered way.” And I think that perfectly represents what I was trying to do in my work. The things I changed to create this element of randomness were data, small pieces of data that might seem insignificant at first, but machines are built based on that, so even the smallest thousandth can make a difference.

This brings me to another quote from the video, about Dadaism: “Dada wished to replace the logical nonsense of the men of today with an illogical nonsense.” To what point is something considered logical? Computers are supposed to be based on pure logic. And yet, artists find ways to turn that logic into illogical sense. And yet, it still has meaning. It’s like deconstructing the logic embedded in the machine with the purpose of illogically creating something that has meaning behind it. Or the other way around, creating something without meaning by using the logic of the computer. Either way, I feel this can be applied to the artworks shown in the video.

A quote by Gerhard Richter captures this idea very well: “Above all, it’s never a blind chance; it’s a chance that is always planned but also always surprising.” These artists construct from chance as a base. It’s about bringing in disorder that has been curated with intention, in a way that even surprises the artist themselves. I think that finding this balance between total randomness and complete control is about using logic and repetition, patterns and algorithms that allow you to repeat a process, while the outcome is completely different, but the essence of it remains present.

Something that really caught my attention in the video was the idea of the million random digitized values and the 1,000 normal deviates. It honestly amazed me to think about the power, the expectation, and the importance that randomness has in our lives when we understand that art imitates or simulates the real world, and the real world is chaotic and not curated by anyone, but rather filled with randomness. Without a doubt, this video and this work opened my eyes and helped me understand even better the importance of chaos within order, and order within chaos.

Week 2: Loop

Concept:

My concept is to create a simple “inside the hive” scene where order and randomness happen at the same time. The honeycomb background is built from repeated hexagons in a grid, which represents the hive’s structure—tight, organized, and predictable. In contrast, the bee moves with a random flying motion that changes slightly every frame, so it feels alive and spontaneous rather than mechanical. I also made the bee bounce within the canvas so it stays inside the hive space, like it is exploring but still contained by its environment. Also, during the class time when I was thinking about what to draw in the project, I felt really hungry and I want to eat honey cake.


The code that I am proud of:
  // --- Bee motion (random flying) ---
  beeVX += random(-0.3, 0.3);
  beeVY += random(-0.3, 0.3);
  beeVX = constrain(beeVX, -2.5, 2.5);
  beeVY = constrain(beeVY, -2.5, 2.5);

  beeX += beeVX;
  beeY += beeVY;

  // Keep bee inside canvas (bounce)
  let margin = 30;
  if (beeX < margin || beeX > width - margin) beeVX *= -1;
  if (beeY < margin || beeY > height - margin) beeVY *= -1;

  // Draw bee on top
  drawBee(beeX, beeY, 0.35);
}

At the beginning, I wasn’t sure how to create this project, so I watched several YouTube tutorials to learn how to animate an object with “random” speed and changing positions. I borrowed the basic motion idea from those videos, but when I copied it into my own sketch, it didn’t fit well at first because most examples were things like spaceships or tanks, not a bee flying inside a hive. I wanted the bee to feel a little “drunk” and overworked—like it’s been collecting too much honey—so I tried lowering the speed. After that, I ran into another issue: the bee sometimes flew past the canvas boundaries instead of bouncing back. I returned to YouTube to look for a solution, but I couldn’t find an explanation that matched my situation. I then asked ChatGPT, but the first version of the code was too complicated for me to fully understand. In the end, I asked a friend on campus for help, and the final motion code in my project was revised with my friend’s support so it works properly and still matches the bee-in-a-hive idea.

How this was made:

In the beginning, I was frustrated with drawing the honeycomb. My first draft didn’t tile correctly—the shapes overlapped and collapsed into each other, so it didn’t look like a real hive at all. I made many adjustments and learned a lot from YouTube tutorials, especially about changing the way I structured the code so the hexagons could repeat cleanly in a grid. For the color choices, I also struggled because it would take too many trials to find the exact shade I wanted, so I asked ChatGPT for suggestions and used that as a starting point. After the hive finally worked, the next challenge was the bee’s movement, which I mentioned earlier. Once the motion was fixed, I focused on drawing the bee with more detail. The wings and stripes were honestly the hardest parts because small changes in position and size could make the bee look “off.” I spent a lot of time adjusting these details until the proportions felt right and the bee matched the hive scene more naturally.

Conclusion and reflection:

I learned a lot throughout the process of making this project. Compared to the beginning, I felt much more comfortable writing the code to draw the bee, mainly because the self-portrait assignment helped me get used to building shapes step by step and adjusting details. Next time, I think I can improve by creating a more surprising or interesting background and adding more animation—so the scene feels more dynamic rather than just a moving bee on a static hive.

Week 2 – Zere – Creative Reading Response

  Casey Reas’s talk made me look at the concept of randomness differently. In my prior opinion, randomness was something that took away the “magic” of art, as it took away the artist’s control over what their piece will look like. Yet, Reas’s speech gave a new perspective of randomness, as in, that it can be used with intentionality, utilizing logical rules given and created by the artist, therefore giving them a sense of control over their work. Generative art is exactly that in my opinion. I think that the “magic” of art in this case is the artist designing the structure, giving the rules, setting the limits on variations etc. Artists in this case, I think, showcase that code can be used as an art medium much like chalk, acrylic paint, colored pencils and various other types of mediums. If looked from the perspective that computers and generative tools were created by humans for humans, the same as paint and canvas, generative art is art. An artist can control the limits of the “random” decision made by the computer, and it can be exciting. Art is meant to be exciting, at least in my perspective of it. I am not saying it is meant to reach a deep part of your soul every time, but one of the reasons many people create art is for that sense of excitement it brings you. 

       Generative art is unique because of its randomness. One of the things that kept appearing in my head is chance operations in dance. I have taken Intro to Modern Dance last semester, and our professor introduced us to Merce Cunnigham’s work. His idea was to have a set of moves, number each of them, then randomly select the numbers and therefore build a unique dance each time. I feel like this is one of the examples of how I would like to utilize random elements in my work – having a set of elements that I adhere particular meaning to, then randomizing their order to see how many new and unique combinations I can get. In my opinion this is also an example of balancing randomness and control – you give an algorithm/ a machine a set of elements/variables that matter to you as an artist, but leave the combinational part up to the machine.

Week 2 – Reading Reflection – Kamila Dautkhan

This video really put into words something I’ve been figuring out with my own work. It’s not “randomness” itself that I find interesting, but what happens when you give a system a little bit of freedom to play with the code itself. I really like when my work starts with something simple and then escalates into something complex and interesting ! Also, I really liked the idea of the artist as a gardener, not a painter.

At the same time, the video’s question about “true randomness” and convergence really caught my attention. If you let systems run long enough, they tend to eventually form some sort of patterns. And it is exactly the kind of thing I enjoy the most: you start very broadly and then some kind of order appears.  And that is exactly what I want to see in my own generative pieces. I don’t want pure static, and I don’t want something completely predictable. I want that middle ground where you can still recognize my own aesthetic in the codes I wrote. This video helped me realize that I’m not just making art with controlled chaos, I’m actually designing a system’s tendencies and then letting the computer show me just how far they can be pushed.

 

there are no perfect circles in nature

This assignment was non less than an endeavor in its own. All I had in mind was circles when I started. I thought of them as colliding an getting bigger or something like that. The hardest part was to come up with something which uses loops. Not from the coding end but from the creative one. The it suddenly hit me; draw in itself if a big while TRUE loop. Honestly I still didn’t know what to do about it, but at least I had starting point.
I wanted to add an interactive side to it as well, so the first thing I did was created pointer for the pointer, so that it has visible interactions. I borrowed the monitor frame from my self portrait to add somewhat character to the framing.

The moment I had two circles bouncing off each other. I noticed the the repeating motion. To observe it in detail I wanted to add the trail into it. I had some what trouble doing that because of the monitor underneath, the trail was hidden under it. I asked chatgpt about it. It made me realize that I don;t want my monitor to be draw again and again. So I just put it up in the setup. no I could see their movement.

The most interesting part about it was they never collided if left undisturbed. Because of the movement variables I set. But if it is disturbed by the mouse the kinda stuck in the loop. This discovery is what I am most proud of, I am not sure which part of the code represents it. It randomly reminded me of how it is necessary to go off road to meet people or places that quite possible create the biggest impact in our lives.
I used the https://p5js.org/reference/p5/text/ to write the text. It represents a vague idea I conclude from above about living

lastly the part of code I think is highlight is as follows

x += 1
  if (x % 220 == 0){
  c1 = random(0,255)
  c2 = random(0,255)
  c3 = random(0,255)
  fill(c1,c2,c3)
  
}

I like this because this where I manipulated the draw loop code to change the circle colors

The Sketch

What I can add to this is. I feel like this is very sketchy. To represent the, I would want to make more calm and smooth

Assignment 1: Self Portrait

Concept:

For the very first assignment in Intro to Interactive media, I was able to make a 2D portrait of my own face which also included parts of my identity such as lifted eyebrows, bigger eyes and writing some parts about my identity such as being a polyglot from Thailand for the very first time using coding as I previously don’t have any previous experience in coding.

Below is my finished portrait:

Screenshot

http://<iframe src=”https://editor.p5js.org/po2127/full/E8eNn1n2a”></iframe>

How it’s made:

This portrait was made using p5.js functions using 2D shapes and different functions such as Fill, Elipse, Stroke, Strokeweight, noStroke, Circle, Arc and line, these basic functions help me have a good foundation of what I need to make a realistic face and to explore and add different more specific features such as eyebrows etc.

When I started it was pretty difficult as it took me quite a while to watch the 3 videos available on YouTube and the link provided to get a good basic grasp of the functions of this platform because I haven’t coded much before and which code I need to do to make the shape of each facial features compatible with the body.

Screenshot

I designed my face to be more of starting with face frame using fill and elipse with no stroke, then eye using ellipse, and the eyehole using fill and circle, then eyebrow using arc, and nose lines and more specifically far apart because my nose is more big, lip, hair and ear using arc and neck using lines and shirt using text and stroke.

Later on adjusting more specific details such as arc of lips and eyebrows to make it fit well with how I look and my body proportions or look like me was also another hard step.

As highlighted code I’m proud of:

The part I am proud of is I was trying to add different parts of my identity to my shirt such as giving purple theme and writing some things that really resonate with me and are part of my identity on the shirt and to be able to write design of NYU shirt on the portrait.

Screenshot

Reflection:

I enjoyed creating my  self portrait, alsthought hroguhout the journey I had some difficulties especially at positioning the shapes and getting used to how the gird works, I was able to get through and I think the main thing I struggled was when to apply the noStroke function and finding the right strokeWeight for specific places such as lips etc.

I think in the future what could have been better is after I get better and more used to program I can add some side effects such as animations, and different gimics into the portrait.  But overall, I think as the first work it was already pretty fun and I feel proud to create my first very own portrait.