airsun-Scope

For this project, I was new to Java, so I first spent a while trying to learn the syntax. After finding out the syntax shared many similarities with Javascript, I started by experimenting with different ideas and see how it will turn out visually. The idea of the scope is to demonstrate four fingers of a hand, facing downwards, and scratching a surface. The index is the moving and looping object and it will always leave a scratch mark.

Preparatory hand-drawn sketches of my design:

The PNG file:

The loop gif:

// Template for KidzLabs/4M/Toysmith Animation Praxinoscope
// https://www.amazon.com/4M-3474-Animation-Praxinoscope/dp/B000P02HYC
// https://www.walmart.com/ip/Animation-Praxinoscope-Science-Kits-by-Toysmith-3474/45681503
// Developed for Processing 3.3.6 * http://processing.org
// 23 January 2018 * Golan Levin 
 
// See information about Processing PDF export at: 
// https://processing.org/reference/libraries/pdf/index.html
// PDF generated by Processing can be opened in Adobe Illustrator.
import processing.pdf.*;
boolean bRecordingPDF = false;
 
float inch = 72; 
float diamArtInner = inch * 1.50; 
float diamArtOuter = inch * 4.80; 
float diamCutInner = inch * 1.41; 
float diamCutOuter = inch * 4.875; 
float holeDy = inch * 0.23;
float holeDx = inch * 0.20;
float holeD = inch * 0.1;
 
final int nFrames = 10; 
int myFrameCount = 0;
int exportFrameCount = 0; 
boolean bAnimate = true; 
boolean bExportFrameImages = false;
 
//-------------------------------------------------------
void setup() {
  size(792, 612); // 11x8.5" at 72DPI
  frameRate(15);
  smooth();
} 
 
//-------------------------------------------------------
void draw() {
  background(240); 
  if (bRecordingPDF) {
    beginRecord(PDF, "praxinoscope-output.pdf");
  }
 
  // Do all the drawing. 
  pushMatrix(); 
  translate(width/2, height/2);
  drawCutLines(); 
  drawGuides(); 
  drawAllFrames();
  popMatrix();
 
  if (bExportFrameImages) {
    // If activated, export .PNG frames 
    if (exportFrameCount < nFrames) { String filename = "frame_" + nf((exportFrameCount%nFrames), 3) + ".png"; saveFrame("frames/" + filename); println("Saved: " + filename); exportFrameCount++; if (exportFrameCount >= nFrames) {
        bExportFrameImages = false;
        exportFrameCount = 0;
      }
    }
  }
 
  if (bRecordingPDF) {
    endRecord();
    bRecordingPDF = false;
  }
}
 
 
//-------------------------------------------------------
void keyPressed() {
  switch (key) {
  case ' ': 
    // Press spacebar to pause/unpause the animation. 
    bAnimate = !bAnimate;
    break;
 
  case 'p': 
  case 'P':
    // Press 'p' to export a PDF for the Praxinoscope.
    bRecordingPDF = true; 
    break;
 
  case 'f': 
  case 'F': 
    // Press 'f' to export .png Frames (to make an animated .GIF)
    myFrameCount = 0; 
    exportFrameCount = 0; 
    bExportFrameImages = true;
    bAnimate = true; 
    break;
  }
}
 
//-------------------------------------------------------
void drawCutLines() {
  fill(0); 
  textAlign(CENTER, BOTTOM); 
  text("Praxinoscope Template", 0, 0-diamCutOuter/2-6); 
 
  stroke(0); 
  strokeWeight(1.0);
 
  noFill(); 
  if (!bRecordingPDF) {
    fill(255); 
  }
  ellipse(0, 0, diamCutOuter, diamCutOuter);
 
  noFill(); 
  if (!bRecordingPDF) {
    fill(240); 
  }
  ellipse(0, 0, diamCutInner, diamCutInner);
 
  noFill(); 
  ellipse(diamCutOuter/2 - holeDx, 0-holeDy, holeD, holeD); 
 
  line (diamCutInner/2, 0, diamCutOuter/2, 0);
}
 
//-------------------------------------------------------
void drawGuides() {
  // This function draws the guidelines. 
  // Don't draw these when we're exporting the PDF. 
  if (!bRecordingPDF) {
 
    noFill(); 
    stroke(128); 
    strokeWeight(0.2); 
    ellipse(0, 0, diamArtInner, diamArtInner); 
    ellipse(0, 0, diamArtOuter, diamArtOuter);
 
    for (int i=0; i<nFrames; i++) {
      float angle = map(i, 0, nFrames, 0, TWO_PI); 
      float pxi = diamArtInner/2 * cos(angle);
      float pyi = diamArtInner/2 * sin(angle);
      float pxo = diamArtOuter/2 * cos(angle);
      float pyo = diamArtOuter/2 * sin(angle);
      stroke(128); 
      strokeWeight(0.2);
      line (pxi, pyi, pxo, pyo);
    }
 
    // Draw the red wedge outline, highlighting the main view.
    int redWedge = 7; // assuming nFrames = 10
    for (int i=redWedge; i<=(redWedge+1); i++) {
      float angle = map(i, 0, nFrames, 0, TWO_PI); 
      float pxi = diamArtInner/2 * cos(angle);
      float pyi = diamArtInner/2 * sin(angle);
      float pxo = diamArtOuter/2 * cos(angle);
      float pyo = diamArtOuter/2 * sin(angle);
      stroke(255, 0, 0); 
      strokeWeight(2.0);
      line (pxi, pyi, pxo, pyo);
    }
    noFill(); 
    stroke(255, 0, 0); 
    strokeWeight(2.0);
    float startAngle = redWedge*TWO_PI/nFrames;
    float endAngle = (redWedge+1)*TWO_PI/nFrames;
    arc(0, 0, diamArtInner, diamArtInner, startAngle, endAngle); 
    arc(0, 0, diamArtOuter, diamArtOuter, startAngle, endAngle); 
 
 
    for (int i=0; i<nFrames; i++) {
      float angle = map(i, 0, nFrames, 0, TWO_PI); 
 
      pushMatrix();
      rotate(angle); 
      float originY = ((diamArtOuter + diamArtInner)/2)/2;
      translate(0, 0-originY); 
 
      noFill(); 
      stroke(128); 
      strokeWeight(0.2);
      line (-inch/2, 0, inch/2, 0); 
      line (0, -inch/2, 0, inch/2); 
 
      popMatrix();
    }
  }
}
 
//-------------------------------------------------------
void drawAllFrames() {
  for (int i=0; i<nFrames; i++) {
    float angle = map(i, 0, nFrames, 0, TWO_PI); 
    float originY = ((diamArtOuter + diamArtInner)/2)/2;
 
    pushMatrix();
    rotate(angle); 
    translate(0, 0-originY); 
    scale(0.8, 0.8); // feel free to ditch this 
 
    int whichFrame = i; 
    if (bAnimate) {
      whichFrame = (i+myFrameCount)%nFrames;
    }
    drawArtFrame (whichFrame); 
    // drawArtFrameAlternate (whichFrame); 
 
    popMatrix();
  }
  myFrameCount++;
}
 
 
//-------------------------------------------------------
void drawArtFrame (int whichFrame) { 
  // Draw the artwork for a generic frame of the Praxinoscope, 
  // given the framenumber (whichFrame) out of nFrames.
  // NOTE #1: The "origin" for the frame is in the center of the wedge.
  // NOTE #2: Remember that everything will appear upside-down!
 
  // Draw the frame number
  fill(0); 
  noStroke(); 
  textAlign(CENTER, CENTER); 
 
  // Draw some expanding boxes, centered on the local origin
  int nBoxes = 32;
 
  float ry=0;
  float rx=14;
  float rs=11;
  float W1 = whichFrame%nBoxes;
  float Yoffset = 15;
  stroke(0);
  strokeWeight(2.5);
  line(-45,ry, 45,ry);
 
  fill(0);
  strokeWeight(1);
  line(0-rx-2, ry, 0-rx-2, ry+40);
  ellipse(0-rx-2, ry+(W1), rs, rs*5);
  ellipse(0, ry, rs, rs*5);
  ellipse(rx, ry, rs, rs*5);
  ellipse(rx*2, ry, rs, rs*5);
  pushMatrix();
  rotate((7*PI)/4);
  ellipse(18, -3, 10, 35);
  ellipse(28, 8, 10, 35);
  popMatrix();
  pushMatrix();
  rotate((13*PI)/7);
  ellipse(36, 5, 10, 30);
  popMatrix();
 
  fill(255);
  noStroke();
  rect(0-rx-5, ry+(W1)+Yoffset,6.7,8,15,15,45,45);
  fill(200,200,200);
  stroke(255);
  strokeWeight(1);
  line(0-rx-2-rs/4, ry+(W1)+Yoffset-4, 0-rx-2+rs/4, ry+(W1)+Yoffset-4);
  line(0-rx-2-rs/4, ry+(W1)+Yoffset-6, 0-rx-2+rs/4, ry+(W1)+Yoffset-6);
 
  for (int i=0; i<3; i++){
    fill(255);
    rect(-3+14*i, ry+Yoffset,6.7,8,15,15,45,45);
    line(3+14*i, ry+Yoffset-4, 0-rs/4+14*i, ry+Yoffset-4);
    line(3+14*i, ry+Yoffset-6, 0-rs/4+14*i, ry+Yoffset-6);
  }
 
 
}
 
//-------------------------------------------------------
void drawArtFrameAlternate(int whichFrame) { 
  // An alternate drawing test. 
  // Draw a falling object. 
 
 
  // Draw a little splat on the frame when it hits the ground. 
  if (whichFrame == (nFrames-1)) {
    stroke(0, 0, 0); 
    strokeWeight(0.5); 
    int nL = 10;
    for (int i=0; i<nL; i++) {
      float a = HALF_PI + map(i, 0, nL-1, 0, TWO_PI);
      float cx = 12 * cos(a);
      float cy = 10 * sin(a); 
      float dx = 16 * cos(a);
      float dy = 13 * sin(a); 
      line (cx, 45+cy, dx, 45+dy);
    }
  }
 
  // Draw a little box frame
  fill(255); 
  stroke(0, 0, 0);
  strokeWeight(1); 
  rect(-5, -50, 10, 100); 
 
  // Make the puck accelerate downward
  float t = map(whichFrame, 0, nFrames-1, 0, 1); 
  float t2 = pow(t, 2.0); 
  float rh = 8 + whichFrame * 0.5; // wee stretch
  float ry = map(t2, 0, 1, 0, 100-rh) - 50; 
 
  noStroke(); 
  fill(0, 0, 0);
  rect(-5, ry, 10, rh);
}