A keypad is one of the most commonly used input devices in microprocessor applications. In a standard keypad wired as an X-Y switch matrix, normally-open switches connect a row to a column when pressed. If a keypad has 12 keys, it is wired as 3 columns by 4 rows. A 16 key pad would have 4 columns by 4 rows. Some time ago, I bought a couple of 3×4 membrane keypads from eBay. As usual it’s packed with zero documentation, thus it took couple of hours to get to work. Anyway the keypad is a perfect blend of art and technology with a price tag far below rubies!
This little article is designed to help you get started with your new microcontroller + keypad project so let’s start. Following figure shows the internal structure and pin notation of the 3×4 keypad used for the experiment. The drawing is the result of an obscene amount of research work because I really wanted to make an error-free guide for the project we are working on.
(keypad: internal structure and pin notation)
Here is the same information in a textual way; keypad columns C1-C2-C3 are routed to pins 3,1,5 and rows R1-R2-R3-R4 are routed to pins 2,7,6,4 located at the end of the 7-pin flexible cable. Much more clear now?
(keypad: columns and rows switching)
So now you can see how the button presses can be translated into electrical data for use with a microcontroller. We can now start the real experiment with as Arduino Uno by wiring up the keypad to the Arduino in the following/like manner:
- Keypad pin 1 to Arduino digital 3 //C2
- Keypad pin 2 to Arduino digital 5 //R1
- Keypad pin 3 to Arduino digital 2 //C1
- Keypad pin 4 to Arduino digital 8 //R4
- Keypad pin 5 to Arduino digital 4 //C3
- Keypad pin 6 to Arduino digital 7 //R3
- Keypad pin 7 to Arduino digital 6 //R2
Since keypads are available from many retailers make sure you can get the data sheet as this will make the task easier when wiring them up. If your keypad is different, take note of the lines in the sketch from //keypad type definition, as you need to change the numbers in the arrays rowPins[ROWS] and colPins[COLS]. You should enter the digital pin numbers connected to the rows and columns of the keypad respectively. Example from Arduino playground:
- #include "Keypad.h"
- // keypad type definition
- const byte ROWS = 4; //four rows
- const byte COLS = 3; //three columns
- char keys[ROWS][COLS] = {
- {'1','2','3'},
- {'4','5','6'},
- {'7','8','9'},
- {'*','0','#'}
- };
- byte rowPins[ROWS] = {5, 6, 7, 8}; //connect to the row R1-R4 pinouts of the keypad
- byte colPins[COLS] = {2, 3, 4}; //connect to the column C1-C3 pinouts of the keypad
Next is a project example, where the Arduino is instructed to do something based on a correct key (secret number) being entered into the keypad, probably the most demanded application of the keypad. For this, just wire up the hardware (arduino+keypad) as described earlier.
Although the code is an entry-level one, it includes a secret key option that will need to be entered on the keypad. The Serial Monitor will tell whether the numerical-key inputted to the keypad is correct or not. To activate and deactivate the lock, the user must press * and then the secret key, followed by #. Okay, copy-paste, compile and upload this sketch (adaptation of a work by John Boxall) as usual:
- #include "Keypad.h"
- const byte ROWS = 4; // four rows
- const byte COLS = 3; // three columns
- char keys[ROWS][COLS] =
- {
- {'1','2','3' },
- {'4','5','6' },
- {'7','8','9' },
- {'*','0','#' }
- };
- byte rowPins[ROWS] = {5, 6, 7, 8};
- byte colPins[COLS] = {2, 3, 4};
- Keypad keypad = Keypad( makeKeymap(keys), rowPins, colPins, ROWS, COLS );
- char KEY[4] = {'1','2','3','4'}; // default secret key
- char attempt[4] = {0,0,0,0};
- int z=0;
- void setup()
- {
- Serial.begin(9600);
- }
- void correctKEY() // do this if the correct KEY is entered
- {
- Serial.println(" KEY ACCEPTED...");
- }
- void incorrectKEY() // do this if an incorrect KEY is entered
- {
- Serial.println("KEY REJECTED!");
- }
- void checkKEY()
- {
- int correct=0;
- int i;
- for ( i = 0; i < 4 ; i++ )
- {
- if (attempt[i]==KEY[i])
- {
- correct++;
- }
- }
- if (correct==4)
- {
- correctKEY();
- }
- else
- {
- incorrectKEY();
- }
- for (int zz=0; zz<4; zz++) // clear previous key input
- {
- attempt[zz]=0;
- }
- }
- void readKeypad()
- {
- char key = keypad.getKey();
- if (key != NO_KEY)
- {
- switch(key)
- {
- case '*':
- z=0;
- break;
- case '#':
- delay(100); // added debounce
- checkKEY();
- break;
- default:
- attempt[z]=key;
- z++;
- }
- }
- }
- void loop()
- {
- readKeypad();
- }
If your compiler raises an error “
keypad does not name a type”, probably you have not installed the required
Keypad Library correctly. If you still have the problem after downloading and installing the library, just drop me a line here in the comments.
Note that the good old 3×4 telephone keypad from your junk box can also be used for this project. Like most keypads, it is wired as an X-Y switch matrix, the normally-open switches connect a row (R) to a column (C) when pressed. Next figure shows the pin assignments of a generic 3×4 telephone keypad:
If you don’t know which pin represents which row or column, you have to fiddle the “rummy” keypad using your analog multimeter. It might take hours to get to work, be patient!
(from author’s workbench)
Note: At the middle of this experiment, I got another 3×4 keypad from an eBay seller with the “true” Arduino compatible pin-out (see figure shown below). If you are using this type, it would be better to change the arrays rowPins[ROWS] and colPins[COLS] in the sketch as indicated.