Ignacio Vergara - Noise Makers

 

 

Noise Makers

Description

This week I built a simple MIDI instrument using three buttons and one potentiometer. The buttons trigger the notes, and the knob controls the pitch across two octaves.

Each button corresponds to a different note: C, D, and E. The potentiometer changes the MIDI note value over a 24-semitone range, which equals two octaves, since one octave consists of 12 consecutive semitones.

For each button, I mapped the knob to a specific MIDI range:

• Button 1 (C): The knob controls values from 48 to 72, which corresponds to C3 up to C5
• Button 2 (D): The knob controls values from 50 to 74, which corresponds to D3 up to D5.
• Button 3 (E): The knob controls values from 52 to 76, which corresponds to E3 up to E5. 

To play the notes I used a software called Reaper which is a DAW program that allows me to attach a synthesizer to my MIDI instrument and play piano notes.

 Video Demonstration

 

 Photos

 Sketch

 

 

Schematic

Code

 

/*

 * MIDIUSB_test.ino

 *

 * Created: 4/6/2015 10:47:08 AM

 * Author: gurbrinder grewal

 * Modified by Arduino LLC (2015)

 */

#include "MIDIUSB.h"

// First parameter is the event type (0x09 = note on, 0x08 = note off).

// Second parameter is note-on/note-off, combined with the channel.

// Channel can be anything between 0-15. Typically reported to the user as 1-16.

// Third parameter is the note number (48 = middle C).

// Fourth parameter is the velocity (64 = normal, 127 = fastest).

void noteOn(byte channel, byte pitch, byte velocity) {

  midiEventPacket_t noteOn = {0x09, 0x90 | channel, pitch, velocity};

  MidiUSB.sendMIDI(noteOn);

}

void noteOff(byte channel, byte pitch, byte velocity) {

  midiEventPacket_t noteOff = {0x08, 0x80 | channel, pitch, velocity};

  MidiUSB.sendMIDI(noteOff);

}

int btn1 = 9;

int btn2 = 10;

int btn3 = 11;

const int knobPin = A0;

void setup() {

  Serial.begin(115200);

  pinMode(btn1, INPUT_PULLUP);

  pinMode(btn2, INPUT_PULLUP);

  pinMode(btn3, INPUT_PULLUP);

}

// First parameter is the event type (0x0B = control change).

// Second parameter is the event type, combined with the channel.

// Third parameter is the control number number (0-119).

// Fourth parameter is the control value (0-127).

void controlChange(byte channel, byte control, byte value) {

  midiEventPacket_t event = {0x0B, 0xB0 | channel, control, value};

  MidiUSB.sendMIDI(event);

}

void loop() {

  int knob = analogRead(knobPin);

 

  int note1 = map(knob, 0, 1023, 48, 72); // 1 octave is 12 consecutive semitones so this will go from C3 which is 48 to 72 which is C5

  int note2 = map(knob, 0, 1023, 50, 74);

  int note3 = map(knob, 0, 1023, 52, 76);

  // note 1

  if(digitalRead(btn1) == LOW){

    noteOn(0, note1, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

    if(digitalRead(btn1) == HIGH){

    noteOff(0, note1, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

  MidiUSB.flush();

  // note 2

    if(digitalRead(btn2) == LOW){

    noteOn(0, note2, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

    if(digitalRead(btn2) == HIGH){

    noteOff(0, note2, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

  MidiUSB.flush();

  // note 3

    if(digitalRead(btn3) == LOW){

    noteOn(0, note3, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

    if(digitalRead(btn3) == HIGH){

    noteOff(0, note3, 64);   // Channel 0, middle C, normal velocity

    Serial.println("Sending note on");

  }

  MidiUSB.flush();

}

 

Cubano Tarot

This project takes a DC motor with a fan attachment and turns it into a fun little Fortune Teller game. The Cubano Tarot is based on a form of card-based fortune telling more commonly seen in members of the Afro-Latino Cuban community. Including my own family.

A button placed on the breadboard and when pressed by either the Fortune Teller or the person having their fortune read, the preprogrammed Arduino code allows the fan on the DC Motor to spin for about 10 to 15 seconds. Attached to the fan are three coins. The Crying Eye, which represents failure. The Rose which represents money. And lastly, the wine cup which represents happiness. There is also a circular based at the bottom with three leaf-designed. Each leaf has a Roman numeral from 1 to 3. The person having their fortune read has to assign a wish or a prediction to each leaf. Depending on what coin lands where determines their future. Or, if the coins don’t align with the three leaves, then the fortune is inconclusive or if the person likes, they can wait for the coins to spin again and land on a proper leaf.

The art has been drawn by me in Adobe Illustrator. Then, laser cut into their specific shapes and glued together. A fan has had each coin, (that has been glued to a stick) taped to its individual wing. Then, the DC Motor is placed through a hole in the bottom base—the base being propped up by a Cuban coffee cup—and the fan attached. Allowing it to spin above the base.

Sketch

Schematic

Pictures

 

 

Video Demonstration 

Code

//www.elegoo.com
//2016.12.12

/************************
Exercise the motor using
the L293D chip
************************/

#define ENABLE 5
#define DIRA 3
#define DIRB 4

int i;
 
void setup() {
  //---set pin direction
  pinMode(ENABLE,OUTPUT);
  pinMode(DIRA,OUTPUT);
  pinMode(DIRB,OUTPUT);
  Serial.begin(9600);
}

void loop() {

  // RUN MOTOR for 10 SECONDS TOTAL
  digitalWrite(ENABLE, HIGH);

  digitalWrite(DIRA, HIGH);
  digitalWrite(DIRB, LOW);
  delay(5000);   // run 5 seconds

  digitalWrite(DIRA, LOW);
  digitalWrite(DIRB, HIGH);
  delay(5000);   // run 5 seconds

  // TOP MOTOR FOR 15 SECONDS
  digitalWrite(ENABLE, LOW);   // stop motor
  Serial.println("Motor stopped");
  delay(15000);                // stay stopped 15 seconds
}
   

Cat Paw

SVG File

 This work is called Cat Paw. The main intention of this was to create a cute motorized cat that moves its paw up and down. Referencing the beckoning cat, this project uses a motor along with a joystick to control the paw. Along with the cat is a fish that can easily get knocked down. The story is of a playful cat messing aggressively with a fish. 

//cat code

#define ENABLE 5

#define DIRA 3

#define DIRB 4

int joyStickPin = A0;

int drift = 20;

int i;

 

void setup() {

  //---set pin direction

  pinMode(ENABLE,OUTPUT);

  pinMode(DIRA,OUTPUT);

  pinMode(DIRB,OUTPUT);

  pinMode (joyStickPin, INPUT_PULLUP);

  Serial.begin(9600);

}

void loop() {

  //first get the up or down of the joy stick  between 1023 and 0 and then remap it to ... -255 to 255 for the motor if it's 0 - 255 it's down paw, if it's -255 through 0 it's up paw

  int inputY = MapValues(); //get a return value that will determine if up or down and how fast up or down

  Serial.println(inputY);

  if(inputY > drift){

    analogWrite(ENABLE,abs(inputY)); // enable amount

    digitalWrite(DIRA,HIGH); //down paw

    digitalWrite(DIRB,LOW);

     //delay(50);

  }

  else if(inputY <= drift && inputY >= -drift ){

    digitalWrite(ENABLE, LOW); //paw off, might need some fall off

    // delay(50);

 

  }

  else if (inputY < -drift ){

    analogWrite(ENABLE,abs(inputY)); // enable amount

    digitalWrite(DIRA,LOW);  //up paw

    digitalWrite(DIRB,HIGH);

     //delay(50);

  }

   

  }

  int MapValues(){

Serial.println(analogRead(joyStickPin));

  int mapStick = map(analogRead(joyStickPin), 0, 1023, -200, 200);

      Serial.println("Mapped Input: ");

  return mapStick;

}

Ignacio Vergara - Expressive Motion

 

Expressive Motion

Concept Description

For this assignment, I created a project called Perseverance. The concept represents a young man training to become a samurai. His posture is firm and focused, and his only objective is the training post in front of him. Through continuous practice and repetition, he aims to master his skill. The deeper idea behind the project is that perseverance through discipline not only builds strength but also cultivates inner peace.

In the starting state, everything is static. The warrior stands still, symbolizing preparation and mental focus. When the button is pressed once, the servo moves the arm and produces a single swing of the blade. This represents the beginning of effort. If the button remains pressed, the warrior continues swinging repeatedly, expressing long-term dedication and consistent practice. When the button is released, the motion stops and the system resets.

Technical Description

The movement is achieved using a servo motor connected at the arm joint. The laser-cut components consist of three separate pieces: the body of the warrior, the arm with the sword, and the training post. The Arduino reads the button input and controls the servo to create the swinging motion.

 Video Demonstration

 

 Photos

 Sketch

  

 

Schematic

Code

 

#include <Servo.h>

Servo myservo;  

int pos = 80;  

const int btnPin=2;

void setup() {

  myservo.attach(9);  

  pinMode(btnPin,INPUT_PULLUP);

  Serial.begin(9600);

}

void loop() {

  if(digitalRead(btnPin)== LOW){

    train();

  } ;

  Serial.println(digitalRead(btnPin));

}

void train() {

  for (pos = 30; pos <= 150; pos += 2) {  

 

    myservo.write(pos);  

    delay(15);          

  }

  for (pos = 150; pos >= 30; pos -= 2) {  

    myservo.write(pos);                  

    delay(15);                            

  }

}

 

 

The LED game

 

This is meant to be a game where you use the potentiometer along with an analog joystick to control the values of an LED. You try to match these values to the first LED, which is randomly assigned at the start of the game. When you finish and get close enough to the color, the LEDs flash and restart, allowing the first LED to change color. If you get it wrong, a buzzer will sound, letting you know you haven't gotten it yet. 
The analog inputs include two from the Joystick: vrX and VrY. The Joystick also uses the press-down digital input represented by the white wire. This allows the user to check whether they are close to the LED color. The jumper cable wires represent what color they are: red, green, or blue. For the Joystick, the red value is the power, while black is the ground, and white is the button input. For the potentiometer, the jumper wires are primarily red to both show power and the input for the red LED. The only exception to this is an orange wire used with the buzzer. 
Finally, there are paper UI showing the red knob, the Green and blue, and a label that says press to check on the joystick. 

int ledUpRed = 6; 

int ledUpGreen = 5; 

int ledUpBlue = 3; 

int ledDownRed = 11; 

int ledDownGreen = 10; 

int ledDownBlue = 9 ; 

int buzzer = 7; 

int vrXGreen = A1; 

int vrYBlue = A2; 

int knobRed = A0; 

int confirmButton = 2; 

int randomRed; 

int randomGreen; 

int randomBlue; 

int mapValRed; 

int mapValGreen; 

int mapValBlue; 

int close = 5; 

 

void setup() {

  pinMode(ledUpRed, OUTPUT);

  pinMode(ledUpGreen, OUTPUT);

  pinMode(ledUpBlue, OUTPUT);

  pinMode(ledDownRed, OUTPUT);

  pinMode(ledDownGreen, OUTPUT);

  pinMode(ledDownBlue, OUTPUT);

  pinMode(buzzer, OUTPUT);

  pinMode (vrXGreen, INPUT);

  pinMode (vrYBlue, INPUT);

  pinMode (knobRed, INPUT);

  pinMode(confirmButton, INPUT_PULLUP);

  //set up the first random number for the upper one

  Random(); 

  // put your setup code here, to run once:

    Serial.begin(9600);

 

}

void Random(){//also going to be the reset function for the end of the 'game' 

  //get random numbers 

  randomRed = random(0, 255);

  randomGreen = random (0, 255);

  randomBlue = random ( 0, 255);

  //set these values to the upper pin .. probably in loop. 

}

void AssignRandom(){

  analogWrite(ledUpRed, randomRed);

  analogWrite(ledUpGreen, randomGreen);

  analogWrite(ledUpBlue, randomBlue);

  delay(10); //this is to make sure its not too quick

}

void loop() {

   digitalWrite(buzzer, LOW);

  

  AssignRandom(); 

  // scale the values of the inputs map and set them 

  MapValues(); 

    

  //check the values to see if they are close to one another when pressing confirm 

  if(!digitalRead(confirmButton)){ 

      if(CheckValues()){ //check values is kinda wrong 

        // do the lalalalala

        // make both the LEDs fade to white then off then slowly restart the 'game' 

        CoolEnd(); 

      } 

      else{ 

        //fail sound play buzzer

        digitalWrite(buzzer, HIGH);

        

        Serial.println("you failed!");

      }

  }

}

void CoolEnd(){

  analogWrite(ledUpRed, 255);

  analogWrite(ledUpGreen, 255);

  analogWrite(ledUpBlue, 255);

  analogWrite(ledDownRed, 255);

  analogWrite(ledDownGreen, 255);

  analogWrite(ledDownBlue, 255);

  delay(200);

  analogWrite(ledUpRed, 0);

  analogWrite(ledUpGreen, 0);

  analogWrite(ledUpBlue, 0);

  analogWrite(ledDownRed, 0);

  analogWrite(ledDownGreen, 0);

  analogWrite(ledDownBlue, 0);

    delay(200);

  Random(); 

  

}

bool CheckValues(){

  // check the values.. if they are 30 ish close enough return true, if not return false 

  bool redCorrect = false; 

  bool blueCorrect = false; 

  bool greenCorrect = false; 

  if((analogRead(ledDownRed) - analogRead(ledUpRed))< close &&  (analogRead(ledDownRed) - analogRead(ledUpRed)) >-close )

  redCorrect = true; 

  if((analogRead(ledDownGreen) - analogRead(ledUpGreen))< close &&  (analogRead(ledDownGreen) - analogRead(ledUpGreen)) >-close )

  greenCorrect = true; 

  if((analogRead(ledDownBlue) - analogRead(ledUpBlue))< close &&  (analogRead(ledDownBlue) - analogRead(ledUpBlue)) >-close )

  blueCorrect = true; 

Serial.println("these are the true or false");

Serial.println(blueCorrect);

Serial.println(redCorrect);

  if(redCorrect && blueCorrect && greenCorrect){

    return true; 

  }

  else{

    return false; 

  }

}

void MapValues(){

  

  int mapValRed = map(analogRead(knobRed),0, 1023, 0, 255);

  int mapValBlue = map(analogRead(vrYBlue), 0, 1023, 0, 255);

  int mapValGreen = map(analogRead(vrXGreen), 0, 1023, 0, 255); 

 

  //then write 

  analogWrite(ledDownRed, mapValRed);

  analogWrite(ledDownGreen, mapValGreen);

  analogWrite(ledDownBlue, mapValBlue);

 

  //delay for nonsense 

  delay(10);

}

Marie's Mapping

 

Mapping

This project demonstrates an RGB LED controlled through a switch-based input system, where user interaction directly affects the color output of the light. The strength of which is determined by how far the user slides the potentiometer on the breadboard. The potentiometer functions as the primary and only way to provide user input. It sends signals that allows the light of the LED to appear blue when activated and increase it's brightness overall. The RGB LED switch emphasizes the relationship between hardware inputs, some minor software logic and visual output. Internally, the microcontroller reads the switch’s state and maps it to strength of the blue color in the LED. demonstrating basic input mapping and conditional logic. Displaying how user interaction can dynamically shape an electronic system’s behavior. This project serves as a practical example of physical computing design at a small scale.

Sketch

Schematic

Pictures

Video Demonstration 

Code

const int bluePin = 9;
const int greenPin = 10;
const int redPin = 11;
const int thePin = A1;

int maxVal = 0;
int minVal = 1023;

void setup() {
  // put your setup code here, to run once:
  pinMode (bluePin, OUTPUT);
  pinMode (greenPin, OUTPUT);
  pinMode (redPin, OUTPUT);
  pinMode (thePin, OUTPUT);
  Serial.begin(9600);
}

void loop() {
  // put your main code here, to run repeatedly:
  Serial.println(analogRead(thePin));
  int knobval = analogRead(thePin);
  if (knobval > maxVal) maxVal = knobval;
  if (knobval < minVal) minVal = knobval;
  int mapval = map(knobval, minVal, maxVal, 0, 255);
  analogWrite(redPin, mapval);
  delay(10);
  Serial.print(knobval);
  Serial.print("\t");
  Serial.print(minVal);
  Serial.print("\t");
  Serial.println(maxVal);

  //for(int i=0; i<255 analogwrite="" bluepin="" code="" delay="" greenpin="" i="" redpin="">

Unconventional Switch - Electronic Group 11

 

For our unconventional switch, we decided to make a can that when a lid closes it, an LED would light. We used a 3.3v power source, a 2v LED, and a 100-ohm resistor. One clip is connected to the lid, and the other clip is connected to the bottom of the can. The LED lights when the lid is on, signifying whatever is in the can can't be taken out, until the light turns off. The light kind of signifies the spark in a kid's brain whenever they see a closed wafer/cookie jar, and the light stays on until they figure out how to get the lid off.