diff --git a/.vscode/launch.json b/.vscode/launch.json
new file mode 100644
index 0000000..3e0feaf
--- /dev/null
+++ b/.vscode/launch.json
@@ -0,0 +1,15 @@
+{
+    // Use IntelliSense to learn about possible attributes.
+    // Hover to view descriptions of existing attributes.
+    // For more information, visit: https://go.microsoft.com/fwlink/?linkid=830387
+    "version": "0.2.0",
+    "configurations": [
+        {
+            "type": "pwa-chrome",
+            "request": "launch",
+            "name": "Launch Chrome against localhost",
+            "url": "http://localhost:5660/",
+            "webRoot": "${workspaceFolder}"
+        }
+    ]
+}
\ No newline at end of file
diff --git a/NoisyPlanetScreenShot.png b/NoisyPlanetScreenShot.png
new file mode 100644
index 0000000..6830072
Binary files /dev/null and b/NoisyPlanetScreenShot.png differ
diff --git a/README.md b/README.md
index c636328..7cf7d2b 100644
--- a/README.md
+++ b/README.md
@@ -1,77 +1,18 @@
-# HW 0: Noisy Planet Part 1 (Intro to Javascript and WebGL)
+# Noisy Planet
 
-<p align="center">
-  <img width="360" height="360" src="https://user-images.githubusercontent.com/1758825/132532354-e3a45402-e484-499e-bfa7-2d73b9f2c946.png">
-</p>
-<p align="center">(source: Ken Perlin)</p>
+## Details
+- Created by Nathan Devlin, based on code by Adam Mally
+- Written in TypeScript
+- Renders a cube and an icosphere.
+- Allows the user to modify the base color of the objects and the number of subdivisions of the icosphere
+- Utilizes a fractal brownian motion fragment shader to give the objects an interesting coloring
+- Utilizes a time-based sinusoidal function to undulate the objects in an organic-looking way
 
-## Objective
-- Check that the tools and build configuration we will be using for the class works.
-- Start learning Typescript and WebGL2
-- Practice implementing noise
+## Live Demo
+View a live WebGL Demo here!:
+https://ndevlin.github.io/hw00-webgl-intro/
 
-## Forking the Code
-Rather than cloning the homework repository, please __fork__ the code into your own repository using the `Fork` button in the upper-right hand corner of the Github UI. This will enable you to have your own personal repository copy of the code, and let you make a live demo (described later in this document).
 
-## Running the Code
+## ScreenShot: 
+![](NoisyPlanetScreenShot.png)
 
-1. [Install Node.js](https://nodejs.org/en/download/). Node.js is a JavaScript runtime. It basically allows you to run JavaScript when not in a browser. For our purposes, this is not necessary. The important part is that with it comes `npm`, the Node Package Manager. This allows us to easily declare and install external dependencies such as [dat.GUI](https://workshop.chromeexperiments.com/examples/gui/#1--Basic-Usage), and [glMatrix](http://glmatrix.net/).
-
-2. Using a command terminal, run `npm install` in the root directory of your project. This will download all of those dependencies.
-
-3. Do either of the following (but we highly recommend the first one for reasons we will explain later).
-
-    a. Run `npm start` and then go to `localhost:5660` in your web browser
-
-    b. Run `npm run build` and then go open `dist/index.html` in your web browser
-
-## Module Bundling
-One of the most important dependencies of our projects is [Webpack](https://webpack.js.org/concepts/). Webpack is a module bundler which allows us to write code in separate files and use `import`s and `export`s to load classes and functions for other files. It also allows us to preprocess code before compiling to a single file. We will be using [Typescript](https://www.typescriptlang.org/docs/home.html) for this course which is Javascript augmented with type annotations. Webpack will convert Typescript files to Javascript files on compilation and in doing so will also check for proper type-safety and usage. Read more about Javascript modules in the resources section below.
-
-## Developing Your Code
-All of the JavaScript code is living inside the `src` directory. The main file that gets executed when you load the page as you may have guessed is `main.ts`. Here, you can make any changes you want, import functions from other files, etc. The reason that we highly suggest you build your project with `npm start` is that doing so will start a process that watches for any changes you make to your code. If it detects anything, it'll automagically rebuild your project and then refresh your browser window for you. Wow. That's cool. If you do it the other way, you'll need to run `npm build` and then refresh your page every time you want to test something.
-
-We would suggest editing your project with Visual Studio Code https://code.visualstudio.com/. Microsoft develops it and Microsoft also develops Typescript so all of the features work nicely together. Sublime Text and installing the Typescript plugins should probably work as well.
-
-## Assignment Details
-1. Take some time to go through the existing codebase so you can get an understanding of syntax and how the code is architected. Much of the code is designed to mirror the class structures used in CIS 460's OpenGL assignments, so it should hopefully be somewhat familiar.
-2. Take a look at the resources linked in the section below. Definitely read about Javascript modules and Typescript. The other links provide documentation for classes used in the code.
-3. Add a `Cube` class that inherits from `Drawable` and at the very least implement a constructor and its `create` function. Then, add a `Cube` instance to the scene to be rendered.
-4. Read the documentation for dat.GUI below. Update the existing GUI in `main.ts` with a parameter to alter the color passed to `u_Color` in the Lambert shader.
-5. Write a custom fragment shader that implements FBM, Worley Noise, or Perlin Noise based on 3D inputs (as opposed to the 2D inputs in the slides). This noise must be used to modify your fragment color. If your custom shader is particularly interesting, you'll earn some bonus points.
-6. Write a custom vertex shader that uses a trigonometric function (e.g. `sin`, `tan`) to non-uniformly modify your cube's vertex positions over time. This will necessitate instantiating an incrementing variable in your Typescript code that you pass to your shader every tick. Refer to the base code's methods of passing variables to shaders if you are unsure how to do so.
-7. Feel free to update any of the files when writing your code. The implementation of the `OpenGLRenderer` is currently very simple.
-
-## Making a Live Demo
-When you push changes to the `master` branch of your repository on Github, a Github workflow will run automatically which builds your code and pushes the build to a new branch `gh-pages`. The configuration file which handles this is located at `.github/workflows/build-and-deploy.yml`. If you want to modify this, you can read more about workflows [here](https://docs.github.com/en/actions/reference/workflow-syntax-for-github-actions).
-
-Once your built code is pushed to `gh-pages`, Github can automatically publish a live site. Configure that by:
-
-  1. Open the Settings tab of your repository in Github.
-
-  2. Scroll down to the Pages tab of the Settings (in the table on the left) and choose which branch to make the source for the deployed project. This should be the `gh-pages` branch which is automatically created after the first successful build of the `master` branch.
-
-  3. Done! Now, any new commits on the `master` branch will be built and pushed to `gh-pages`. The project should be visible at http://username.github.io/repo-name.
- 
-
-To check if everything is on the right track:
-
-1. Make sure the `gh-pages` branch of your repo has a files called `index.html`, `bundle.js`, and `bundle.js.map`
-
-2. In the settings tab of the repo, under Pages, make sure it says your site is published at some url.
-
-## Submission
-1. Create a pull request to this repository with your completed code.
-2. Update README.md to contain a solid description of your project with a screenshot of some visuals, and a link to your live demo.
-3. Submit the link to your pull request on Canvas, and add a comment to your submission with a hyperlink to your live demo.
-4. Include a link to your live site.
-
-## Resources
-- Javascript modules https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Statements/import
-- Typescript https://www.typescriptlang.org/docs/home.html
-- dat.gui https://workshop.chromeexperiments.com/examples/gui/
-- glMatrix http://glmatrix.net/docs/
-- WebGL
-  - Interfaces https://developer.mozilla.org/en-US/docs/Web/API/WebGL_API
-  - Types https://developer.mozilla.org/en-US/docs/Web/API/WebGL_API/Types
-  - Constants https://developer.mozilla.org/en-US/docs/Web/API/WebGL_API/Constants
diff --git a/src/geometry/Cube.ts b/src/geometry/Cube.ts
new file mode 100644
index 0000000..81395a6
--- /dev/null
+++ b/src/geometry/Cube.ts
@@ -0,0 +1,142 @@
+
+// Written by Nathan Devlin, using reference by Adam Mally
+
+import {vec3, vec4} from 'gl-matrix';
+import Drawable from '../rendering/gl/Drawable';
+import {gl} from '../globals';
+
+class Cube extends Drawable {
+  indices: Uint32Array;
+  positions: Float32Array;
+  normals: Float32Array;
+  center: vec4;
+
+  constructor(center: vec3) 
+  {
+    super(); // Call the constructor of the super class. This is required.
+    // Set the origin of the cube to center
+    this.center = vec4.fromValues(center[0], center[1], center[2], 1);
+  }
+
+  create() 
+  {
+      // Positions array
+    this.positions = new Float32Array([
+      // First Face
+      -1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+      -1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+
+      // Second Face
+      -1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+      1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1,
+      -1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1,
+
+      // Third Face
+      1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+
+      // Fourth Face
+      -1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      -1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+      -1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1,
+      -1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+
+      // Fifth Face
+      -1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], -1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+      -1 + this.center[0], -1 + this.center[1], -1 + this.center[2], 1,
+
+      // Sixth Face
+      -1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], 1 + this.center[2], 1,
+      1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1,
+      -1 + this.center[0], 1 + this.center[1], -1 + this.center[2], 1
+    ]);
+
+    // Normals array
+    this.normals = new Float32Array([
+      // First Face
+      0, 0, 1, 0,
+      0, 0, 1, 0,
+      0, 0, 1, 0,
+      0, 0, 1, 0,
+
+      // Second Face
+      0, 0, -1, 0,
+      0, 0, -1, 0,
+      0, 0, -1, 0,
+      0, 0, -1, 0,
+
+      // Third Face
+      1, 0, 0, 0,
+      1, 0, 0, 0,
+      1, 0, 0, 0,
+      1, 0, 0, 0,
+
+      // Fourth Face
+      -1, 0, 0, 0,
+      -1, 0, 0, 0,
+      -1, 0, 0, 0,
+      -1, 0, 0, 0,
+
+      // Fifth Face
+      0, -1, 0, 0,
+      0, -1, 0, 0,
+      0, -1, 0, 0,
+      0, -1, 0, 0,
+
+      // Sixth Face
+      0, 1, 0, 0,
+      0, 1, 0, 0,
+      0, 1, 0, 0,
+      0, 1, 0, 0
+    ]);
+
+    // Indices array
+    this.indices = new Uint32Array([
+      // First Face
+      0, 1, 2, 0, 2, 3, 
+
+      // Second Face
+      4, 5, 6, 4, 6, 7,
+
+      // Third Face
+      8, 9, 10, 8, 10, 11, 
+
+      // Fourth Face
+      12, 13, 14, 12, 14, 15,
+
+      // Fifth Face
+      16, 17, 18, 16, 18, 19, 
+
+      // Sixth Face
+      20, 21, 22, 20, 22, 23
+    ]);
+
+
+    this.generateIdx();
+    this.generatePos();
+    this.generateNor();
+
+    this.count = this.indices.length;
+    gl.bindBuffer(gl.ELEMENT_ARRAY_BUFFER, this.bufIdx);
+    gl.bufferData(gl.ELEMENT_ARRAY_BUFFER, this.indices, gl.STATIC_DRAW);
+
+    gl.bindBuffer(gl.ARRAY_BUFFER, this.bufNor);
+    gl.bufferData(gl.ARRAY_BUFFER, this.normals, gl.STATIC_DRAW);
+
+    gl.bindBuffer(gl.ARRAY_BUFFER, this.bufPos);
+    gl.bufferData(gl.ARRAY_BUFFER, this.positions, gl.STATIC_DRAW);
+
+    console.log(`Created cube`);
+  }
+};
+
+export default Cube;
+
diff --git a/src/main.ts b/src/main.ts
index 65a9461..8bc7463 100644
--- a/src/main.ts
+++ b/src/main.ts
@@ -1,4 +1,7 @@
-import {vec3} from 'gl-matrix';
+
+// Original code by Adam Mally, additions by Nathan Devlin
+
+import {vec3, vec4} from 'gl-matrix';
 const Stats = require('stats-js');
 import * as DAT from 'dat.gui';
 import Icosphere from './geometry/Icosphere';
@@ -7,26 +10,47 @@ import OpenGLRenderer from './rendering/gl/OpenGLRenderer';
 import Camera from './Camera';
 import {setGL} from './globals';
 import ShaderProgram, {Shader} from './rendering/gl/ShaderProgram';
+import Cube from './geometry/Cube';
 
 // Define an object with application parameters and button callbacks
 // This will be referred to by dat.GUI's functions that add GUI elements.
 const controls = {
-  tesselations: 5,
+  tesselations: 4,
   'Load Scene': loadScene, // A function pointer, essentially
 };
 
+// Controller that allows user color input
+const colorObject = 
+{
+  actualColor: [ 255, 0, 0 ], // RGB array
+};
+
 let icosphere: Icosphere;
+
 let square: Square;
+
+let cube: Cube;
+
 let prevTesselations: number = 5;
 
+// Used as a clock
+let currTick: number = 0.0;
+
 function loadScene() {
   icosphere = new Icosphere(vec3.fromValues(0, 0, 0), 1, controls.tesselations);
   icosphere.create();
+
   square = new Square(vec3.fromValues(0, 0, 0));
   square.create();
+
+  // Cube constructor takes in object origin
+  cube = new Cube(vec3.fromValues(1, 1, 1));
+  cube.create();
 }
 
-function main() {
+
+function main() 
+{
   // Initial display for framerate
   const stats = Stats();
   stats.setMode(0);
@@ -40,6 +64,10 @@ function main() {
   gui.add(controls, 'tesselations', 0, 8).step(1);
   gui.add(controls, 'Load Scene');
 
+  // Color control; RGB input
+  gui.addColor(colorObject, 'actualColor');
+
+
   // get canvas and webgl context
   const canvas = <HTMLCanvasElement> document.getElementById('canvas');
   const gl = <WebGL2RenderingContext> canvas.getContext('webgl2');
@@ -56,16 +84,29 @@ function main() {
   const camera = new Camera(vec3.fromValues(0, 0, 5), vec3.fromValues(0, 0, 0));
 
   const renderer = new OpenGLRenderer(canvas);
+
   renderer.setClearColor(0.2, 0.2, 0.2, 1);
+
   gl.enable(gl.DEPTH_TEST);
 
+  // Standard lambert shader
   const lambert = new ShaderProgram([
     new Shader(gl.VERTEX_SHADER, require('./shaders/lambert-vert.glsl')),
     new Shader(gl.FRAGMENT_SHADER, require('./shaders/lambert-frag.glsl')),
   ]);
 
+  // Noise-based vertex and fragment shaders
+  const custom = new ShaderProgram([
+    new Shader(gl.VERTEX_SHADER, require('./shaders/custom-vert.glsl')),
+    new Shader(gl.FRAGMENT_SHADER, require('./shaders/custom-frag.glsl')),
+  ]);
+
   // This function will be called every frame
-  function tick() {
+  function tick() 
+  {
+    // Increment the clock
+    currTick += 1.0;
+
     camera.update();
     stats.begin();
     gl.viewport(0, 0, window.innerWidth, window.innerHeight);
@@ -76,10 +117,26 @@ function main() {
       icosphere = new Icosphere(vec3.fromValues(0, 0, 0), 1, prevTesselations);
       icosphere.create();
     }
+
+    // Render with lambert shader
+    /*
     renderer.render(camera, lambert, [
       icosphere,
-      // square,
-    ]);
+      cube,
+    ],
+    // Divide by 256 to convert from web RGB to shader 0-1 values
+    vec4.fromValues(colorObject.actualColor[0] / 256.0, colorObject.actualColor[1] / 256.0, colorObject.actualColor[2] / 256.0, 1),
+    currTick
+    );
+    */
+
+    // Render with custom noise-based shader
+    renderer.render(camera, custom, [icosphere, cube],
+    // Divide by 256 to convert from web RGB to shader 0-1 values
+    vec4.fromValues(colorObject.actualColor[0] / 256.0, colorObject.actualColor[1] / 256.0, colorObject.actualColor[2] / 256.0, 1),
+    currTick
+    );
+    
     stats.end();
 
     // Tell the browser to call `tick` again whenever it renders a new frame
@@ -101,3 +158,4 @@ function main() {
 }
 
 main();
+
diff --git a/src/rendering/gl/OpenGLRenderer.ts b/src/rendering/gl/OpenGLRenderer.ts
index 7e527c2..1352edb 100644
--- a/src/rendering/gl/OpenGLRenderer.ts
+++ b/src/rendering/gl/OpenGLRenderer.ts
@@ -1,3 +1,6 @@
+
+// Original code by Adam Mally, additions by Nathan Devlin
+
 import {mat4, vec4} from 'gl-matrix';
 import Drawable from './Drawable';
 import Camera from '../../Camera';
@@ -5,7 +8,8 @@ import {gl} from '../../globals';
 import ShaderProgram from './ShaderProgram';
 
 // In this file, `gl` is accessible because it is imported above
-class OpenGLRenderer {
+class OpenGLRenderer 
+{
   constructor(public canvas: HTMLCanvasElement) {
   }
 
@@ -22,10 +26,11 @@ class OpenGLRenderer {
     gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);
   }
 
-  render(camera: Camera, prog: ShaderProgram, drawables: Array<Drawable>) {
+  render(camera: Camera, prog: ShaderProgram, drawables: Array<Drawable>, colorIn: vec4, currTick: number) 
+  {
     let model = mat4.create();
     let viewProj = mat4.create();
-    let color = vec4.fromValues(1, 0, 0, 1);
+    let color = colorIn;
 
     mat4.identity(model);
     mat4.multiply(viewProj, camera.projectionMatrix, camera.viewMatrix);
@@ -33,6 +38,8 @@ class OpenGLRenderer {
     prog.setViewProjMatrix(viewProj);
     prog.setGeometryColor(color);
 
+    prog.setCurrTick(currTick);
+
     for (let drawable of drawables) {
       prog.draw(drawable);
     }
@@ -40,3 +47,4 @@ class OpenGLRenderer {
 };
 
 export default OpenGLRenderer;
+
diff --git a/src/rendering/gl/ShaderProgram.ts b/src/rendering/gl/ShaderProgram.ts
index 67fef40..c4a31c2 100644
--- a/src/rendering/gl/ShaderProgram.ts
+++ b/src/rendering/gl/ShaderProgram.ts
@@ -1,3 +1,6 @@
+
+// Original code by Adam Mally, additions by Nathan Devlin
+
 import {vec4, mat4} from 'gl-matrix';
 import Drawable from './Drawable';
 import {gl} from '../../globals';
@@ -30,6 +33,8 @@ class ShaderProgram {
   unifViewProj: WebGLUniformLocation;
   unifColor: WebGLUniformLocation;
 
+  unifCurrTick: WebGLUniformLocation;
+
   constructor(shaders: Array<Shader>) {
     this.prog = gl.createProgram();
 
@@ -48,6 +53,9 @@ class ShaderProgram {
     this.unifModelInvTr = gl.getUniformLocation(this.prog, "u_ModelInvTr");
     this.unifViewProj   = gl.getUniformLocation(this.prog, "u_ViewProj");
     this.unifColor      = gl.getUniformLocation(this.prog, "u_Color");
+    
+    // currTick is referred to as u_Time in the shaders
+    this.unifCurrTick = gl.getUniformLocation(this.prog, "u_Time");
   }
 
   use() {
@@ -85,6 +93,17 @@ class ShaderProgram {
     }
   }
 
+
+  setCurrTick(currTick: number)
+  {
+    this.use();
+    if(this.unifCurrTick !== -1)
+    {
+      gl.uniform1f(this.unifCurrTick, currTick);
+    }
+  }
+
+
   draw(d: Drawable) {
     this.use();
 
@@ -107,3 +126,4 @@ class ShaderProgram {
 };
 
 export default ShaderProgram;
+
diff --git a/src/shaders/custom-frag.glsl b/src/shaders/custom-frag.glsl
new file mode 100644
index 0000000..34fe1dc
--- /dev/null
+++ b/src/shaders/custom-frag.glsl
@@ -0,0 +1,111 @@
+#version 300 es
+
+// Written by Nathan Devlin, based on reference by Adam Mally
+
+// 3D Fractal Brownian Motion Fragment Shader
+
+precision highp float;
+
+uniform vec4 u_Color; // User input color
+
+// Interpolated values out of the rasterizer
+in vec4 fs_Pos;
+
+in vec4 fs_Nor;
+in vec4 fs_LightVec;
+in vec4 fs_Col;
+
+out vec4 out_Col; 
+
+// Takes in a vec3, returns a vec3, to be used below as a color
+vec3 noise3D( vec3 p ) 
+{
+    float val1 = fract(sin((dot(p, vec3(127.1, 311.7, 191.999)))) * 43758.5453);
+
+    float val2 = fract(sin((dot(p, vec3(191.999, 127.1, 311.7)))) * 3758.5453);
+
+    float val3 = fract(sin((dot(p, vec3(311.7, 191.999, 127.1)))) * 758.5453);
+
+    return vec3(val1, val2, val3);
+}
+
+
+// Interpolate in 3 dimensions
+vec3 interpNoise3D(float x, float y, float z) 
+{
+    int intX = int(floor(x));
+    float fractX = fract(x);
+    int intY = int(floor(y));
+    float fractY = fract(y);
+    int intZ = int(floor(z));
+    float fractZ = fract(z);
+
+    vec3 v1 = noise3D(vec3(intX, intY, intZ));
+    vec3 v2 = noise3D(vec3(intX + 1, intY, intZ));
+    vec3 v3 = noise3D(vec3(intX, intY + 1, intZ));
+    vec3 v4 = noise3D(vec3(intX + 1, intY + 1, intZ));
+
+    vec3 v5 = noise3D(vec3(intX, intY, intZ + 1));
+    vec3 v6 = noise3D(vec3(intX + 1, intY, intZ + 1));
+    vec3 v7 = noise3D(vec3(intX, intY + 1, intZ + 1));
+    vec3 v8 = noise3D(vec3(intX + 1, intY + 1, intZ + 1));
+
+    vec3 i1 = mix(v1, v2, fractX);
+    vec3 i2 = mix(v3, v4, fractX);
+
+    vec3 i3 = mix(i1, i2, fractY);
+
+    vec3 i4 = mix(v5, v6, fractX);
+    vec3 i5 = mix(v7, v8, fractX);
+
+    vec3 i6 = mix(i4, i5, fractY);
+
+    vec3 i7 = mix(i3, i6, fractZ);
+
+    return i7;
+}
+
+
+// 3D Fractal Brownian Motion
+vec3 fbm(float x, float y, float z) 
+{
+    vec3 total = vec3(0.f, 0.f, 0.f);
+
+    float persistence = 0.5f;
+    int octaves = 8;
+
+    for(int i = 1; i <= octaves; i++) 
+    {
+        float freq = pow(2.f, float(i));
+        float amp = pow(persistence, float(i));
+
+        total += interpNoise3D(x * freq, y * freq, z * freq) * amp;
+    }
+    
+    return total;
+}
+
+
+void main()
+{
+        // Material base color (before shading)
+        vec4 diffuseColor = u_Color;
+
+        // Calculate the diffuse term for Lambert shading
+        float diffuseTerm = dot(normalize(fs_Nor), normalize(fs_LightVec));
+
+        float ambientTerm = 0.3;
+
+        float lightIntensity = diffuseTerm + ambientTerm;   
+
+        // Lambert shading
+        out_Col = vec4(diffuseColor.rgb * lightIntensity, diffuseColor.a);
+
+        // Add fbm noise
+        vec3 val = fbm(fs_Pos[0], fs_Pos[1], fs_Pos[2]);
+
+        out_Col += vec4(val, 1.0);
+
+        out_Col /= (val[0] + val[1] + val[2]);
+}
+
diff --git a/src/shaders/custom-vert.glsl b/src/shaders/custom-vert.glsl
new file mode 100644
index 0000000..454ee9c
--- /dev/null
+++ b/src/shaders/custom-vert.glsl
@@ -0,0 +1,53 @@
+#version 300 es
+
+// Written by Nathan Devlin, based on reference by Adam Mally
+
+// Vertex Shader to create an organic undulating effect
+
+uniform mat4 u_Model;       // Model matrix
+
+uniform mat4 u_ModelInvTr;  // The inverse transpose of the model matrix.
+
+uniform mat4 u_ViewProj;    // The matrix that defines the camera's transformation.
+
+uniform float u_Time;
+
+in vec4 vs_Pos;             // The array of vertex positions passed to the shader
+
+in vec4 vs_Nor;             // The array of vertex normals passed to the shader
+
+in vec4 vs_Col;             // The array of vertex colors passed to the shader.
+
+out vec4 fs_Nor;            // The array of normals that has been transformed by u_ModelInvTr
+out vec4 fs_LightVec;       // The direction in which our virtual light lies, relative to each vertex. 
+out vec4 fs_Col;            // The color of each vertex. 
+
+out vec4 fs_Pos;
+
+const vec4 lightPos = vec4(5, 5, 3, 1); //The position of our virtual light
+
+void main()
+{
+    fs_Col = vs_Col;                         // Pass the vertex colors to the fragment shader for interpolation
+
+    mat3 invTranspose = mat3(u_ModelInvTr);
+    fs_Nor = vec4(invTranspose * vec3(vs_Nor), 0);          // Pass the vertex normals to the fragment shader for interpolation.
+                                                            // Transform the geometry's normals by the inverse transpose of the
+                                                            // model matrix. 
+
+    vec4 modelposition = u_Model * vs_Pos;   // Temporarily store the transformed vertex positions for use below
+
+    fs_LightVec = lightPos - modelposition;  // Compute the direction in which the light source lies
+
+
+    gl_Position = u_ViewProj * modelposition;   // Final positions of the geometry's vertices
+
+    fs_Pos = vs_Pos;
+
+    gl_Position = u_ViewProj * modelposition;
+
+    float toAdd = float(u_Time) / 20.0;
+
+    gl_Position += sin(gl_Position + toAdd) / 20.0;
+}
+
diff --git a/src/shaders/lambert-frag.glsl b/src/shaders/lambert-frag.glsl
index 2b8e11b..6984efe 100644
--- a/src/shaders/lambert-frag.glsl
+++ b/src/shaders/lambert-frag.glsl
@@ -41,3 +41,4 @@ void main()
         // Compute final shaded color
         out_Col = vec4(diffuseColor.rgb * lightIntensity, diffuseColor.a);
 }
+