SIK Experiment Guide for the Arduino 101/Genuino 101 Board

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Experiment 5: Reading a Button Press

Introduction

Up until now, we’ve focused mostly on outputs. Now we’re going to go to the other end of spectrum and play around with inputs. In Experiment 2, we used an analog input to read the potentiometer. In this experiment, we’ll be reading one of the most common and simple inputs – a push button – by using a digital input. We will use it to cycle through different colors on the RGB.

Parts Needed

You will need the following parts:

  • 1x Breadboard
  • 1x Arduino 101 or Genuino 101 board
  • 1x RGB LED
  • 3x 100Ω Resistor
  • 8x Jumper Wires
  • 1x Push Button
  • 1x 10K Resistors

Didn't Get the SIK?

If you are conducting this experiment and didn't get the SIK, we suggest using these parts:

Breadboard - Self-Adhesive (White)

Breadboard - Self-Adhesive (White)

PRT-12002
$5.50
48
Jumper Wires - Connected 6" (M/M, 20 pack)

Jumper Wires - Connected 6" (M/M, 20 pack)

PRT-12795
$2.10
2
LED - RGB Clear Common Cathode

LED - RGB Clear Common Cathode

COM-00105
$2.25
3
Momentary Pushbutton Switch - 12mm Square

Momentary Pushbutton Switch - 12mm Square

COM-09190
$0.55
4
Resistor 10K Ohm 1/6th Watt PTH - 20 pack

Resistor 10K Ohm 1/6th Watt PTH - 20 pack

COM-11508
$0.95 $0.50

Resistor 100 Ohm 1/4th Watt PTH - 20 pack

COM-13761
Retired

You will also need either an Arduino 101 OR Genuino 101 board.

Arduino 101

DEV-13787
9 Retired

Genuino 101

DEV-13984
Retired

Suggested Reading

Before continuing with this tutorial, we recommend you be somewhat familiar with the concepts in these tutorials:

Introducing the Push Button

alt text

A momentary push button closes or completes the circuit only while it is being pressed. The button has four pins, which are broken out into two sets of two pins. When you press down on the button and get a nice "click," the button bridges the two sets of pins and allows current to flow through the circuit.

How do you know which pins are paired up? The buttons included in this kit will only fit across the breadboard ditch in one direction. Once you get the button pressed firmly into the breadboard (across the ditch), the pins are horizontally paired. The pins toward the top of the breadboard are connected, and the pins toward the button of the breadboard are connected.

Note: Not all buttons share this pin format. Please refer to the data sheet of your specific button to determine which pins are paired up.

Hardware Hookup

Ready to start hooking everything up? Check out the wiring diagram and hookup table below to see how everything is connected.

Pay special attention to the component’s markings indicating how to place it on the breadboard. Polarized components can only be connected to a circuit in one direction.

Wiring Diagram for the Experiment

alt text

Having a hard time seeing the circuit? Click on the wiring diagram for a closer look.

Digital Input

Previously we've used the analog pins for input; now we'll use the digital pins for input as well. Because digital pins only know about HIGH and LOW signals, they're perfect for interfacing to pushbuttons and switches that also only have "on" and "off" states.

We'll connect one side of the pushbutton to ground, and the other side to a digital pin. When we press down on the pushbutton, the pin will be connected to ground, and therefore will be read as "LOW" by the Arduino board.

But wait -- what happens when you're not pushing the button? In this state, the pin is disconnected from everything, which we call "floating." What will the pin read as then, HIGH or LOW? It's hard to say, because there's no solid connection to either 3.3V or ground. The pin could read as either one.

To deal with this issue, we'll connect a small (10K, or 10,000 Ohm) resistance between the signal pin and 3.3V. This "pullup" resistor will ensure that when you're NOT pushing the button, the pin will still have a weak connection to 3.3 volts, and therefore read as HIGH.

Advanced: When you get used to pullup resistors and know when they're required, you can activate internal pullup resistors on the ATmega processor in Arduino. See http://arduino.cc/en/Tutorial/DigitalPins for information.

Open the Sketch

Open the Arduino IDE software on your computer. Coding in the Arduino language will control your circuit. Open the code for Circuit 5 by accessing the “101 SIK Guide Code” you downloaded and placed into your “Examples” folder earlier.

To open the code go to: File > Examples > 101 SIK Guide Code > Circuit_05

You can also copy and paste the following code into the Arduino IDE. Hit upload, and see what happens!

language:cpp
/*
SparkFun Inventor's Kit 
Example sketch 05

PUSH BUTTONS

  Use pushbuttons for digital input

This sketch was written by SparkFun Electronics,
with lots of help from the Arduino community.
This code is completely free for any use.
Visit http://learn.sparkfun.com/products/2 for SIK information.
Visit http://www.arduino.cc to learn about the Arduino.

*/


// First we'll set up constants for the pin numbers.
// This will make it easier to follow the code below.

 // pushbutton pin
 const int buttonPin = 3;

 //RGB LED pins
 const int redPin = 11;    
 const int greenPin = 10;
 const int bluePin = 9;


//create a variable to store a counter and set it to 0
int counter = 0;
void setup()
{
  // Set up the pushbutton pins to be an input:
  pinMode(buttonPin, INPUT);

  // Set up the RGB pins to be an outputs:
  pinMode(redPin, OUTPUT);  
  pinMode(greenPin,OUTPUT);
  pinMode(bluePin,OUTPUT);
}


void loop()
{
 // local variable to hold the pushbutton states
  int buttonState;  

  //read the digital state of buttonPin with digitalRead() function and store the           //value in buttonState variable
  buttonState = digitalRead(buttonPin);

  //if the button is pressed increment counter and wait a tiny bit to give us some          //time to release the button
  if (buttonState == LOW) // light the LED
  {
    counter++;
    delay(150);
  }

  //use the if satement to check the value of counter. If counter is equal to 0 all         //pins are off
  if(counter == 0)
  {
   digitalWrite(redPin,LOW);
   digitalWrite(greenPin,LOW);
   digitalWrite(bluePin,LOW);
  }

  //else if counter is equal to 1, redPin is HIGH
  else if(counter == 1)
  {
   digitalWrite(redPin,HIGH);
   digitalWrite(greenPin,LOW);
   digitalWrite(bluePin,LOW);
  }

  //else if counter is equal to 2 greenPin is HIGH
  else if(counter ==2)
  {
   digitalWrite(redPin,LOW);
   digitalWrite(greenPin,HIGH);
   digitalWrite(bluePin,LOW);
  }

  //else if counter is equal to 3 bluePin is HIGH
  else if(counter ==3)
  {
   digitalWrite(redPin,LOW);
   digitalWrite(greenPin,LOW);
   digitalWrite(bluePin,HIGH);
  }

  //else reset the counter to 0 (which turns all pins off)
  else
  {
   counter =0;
  }
}

Code to Note

pinMode(buttonPin, INPUT);

The digital pins can be used as inputs as well as outputs. Before you do either, you need to tell the Arduino which direction you're going.

buttonState = digitalRead(buttonPin);

To read a digital input, you use the digitalRead() function. It will return HIGH if there's 3.3V present at the pin, or LOW if there's 0V present at the pin.

if (button1State == LOW)

Because we've connected the button to GND, it will read LOW when it's being pressed. Here we're using the "equivalence" operator ("==") to see if the button is being pressed.

What You Should See

You should see the RGB LED light up a different color (red, green, blue) every time you press down on the button. The button will turn off the LED on the fourth button press. (See the code to find out why!) If it isn't working, make sure you have assembled the circuit correctly and verified and uploaded the code to your board or see the troubleshooting section.

alt text

Troubleshooting

Light Not Turning On

The pushbutton is square, and because of this it is easy to put it in the wrong way. Give it a 90 degree twist and see if it starts working.

Underwhelmed

No worries; these circuits are all super stripped-down to make playing with the components easy, but once you throw them together the sky is the limit.