# Arduino calculating the frequency - what am I doing wrong here?

I'm a newbie when it comes to electronics and Arduino - so the best way is to just to play around with it, right?

I have started a small project that utilize and LDR (Light Density Resistor) and want to use it to calculate the frequency that a light beam is blocked or turned off.

For debugging purposes I setup a small LED that blinks at a defined frequency (5 Hz etc.) and use a LCD to display the output.

I have a problem with my top right corner... It seems as it performs wrongly. It was the intention that it should show the registered frequency, but while debugging I have set it to show the number of counts in an interval of 5 sec (5,000 msec). But it appears as 24 is the max no matter what frequency I set (When I get it to show the right number [5 sec x 5 Hz = 25] I will divide by the time interval and get the results in Hz). It also shows 24.0 for 9 Hz etc..

I also have this: YouTube video

...but some fumbling in the beginning caused the LED to move a bit so it counted wrong. But in the end it "works".. But the 24.0 keeps being constant

This is my code:

``````#include <LiquidCrystal.h>

LiquidCrystal lcd(7, 8, 9, 10, 11 , 12);
int booBlocked = 0;
int counter = 0;
int checkValue = counter + 1;

int ledPin = 3;                // LED connected to digital pin 3
int value = LOW;                // previous value of the LED
long previousMillis = 0;        // will store last time LED was updated
long freqency = 5; // Hz (1/sec)
long thousand = 1000;
long interval = thousand / freqency; // milliseconds
//long interval = 59;           // interval at which to blink (milliseconds)

int tValue = 0; // Threshold value used for counting (are calibrated in the beginning)
long pMillis = 0;
long inter = 5000;
int pCount = 0;
float freq = 0;  // Calculated blink frequency...

void setup() {
lcd.begin(16, 2);
lcd.setCursor(0,1);  lcd.print(interval);
lcd.setCursor(4,1);  lcd.print("ms");

pinMode(ledPin, OUTPUT);      // sets the digital pin as output

lcd.setCursor(0,0);  lcd.print(freqency);
lcd.setCursor(4,0);  lcd.print("Hz");
}

void loop() {
// Print LDR sensor value to the display
lcd.setCursor(7,1);
lcd.print(sensorValue);
delay(100);

if (millis() > 5000){
doCount(sensorValue);
updateFreq();
lcd.setCursor(7+5,0);
lcd.print(freq);
} else {
setThresholdValue(sensorValue);
lcd.setCursor(7+5,1);
lcd.print(tValue);
}

if (millis() - previousMillis > interval) {
previousMillis = millis();   // remember the last time we blinked the LED
// if the LED is off turn it on and vice-versa.
if (value == LOW)
value = HIGH;
else
value = LOW;
digitalWrite(ledPin, value);
}
}

void updateFreq(){
long now = millis();
long t = now - pMillis;
if (t >= 10000) {
freq = (float) (counter - pCount);
//freq = ((float) (counter - pCount)) / (float) 10.0;
pMillis = now;   // remember the last time we blinked the LED
pCount = counter;
}
}

void setThresholdValue(int sensorValue){
if (sensorValue > int(tValue/0.90)){
tValue = int (sensorValue*0.90);
}
}

void doCount(int sensorValue){
// Count stuff
if (sensorValue < tValue){
booBlocked = 1;
//lcd.setCursor(0,0);
//lcd.print("Blocked");
} else {
booBlocked = 0;
//lcd.setCursor(0,0);
//lcd.print("       ");
}

if (booBlocked == 1) {
if (counter != checkValue){
counter = counter + 1;
lcd.setCursor(7,0);
lcd.print(counter);
}
} else {
if (counter == checkValue){
checkValue = checkValue + 1;
}
}
}
``````

## UPDATE

``````#include <LiquidCrystal.h>
// Initiate the LCD display
LiquidCrystal lcd(7, 8, 9, 10, 11 , 12); // see setup at http://lassenorfeldt.weebly.com/1/post/2013/02/ardunio-lcd.html
long updateInterval = 150;                // ms
long updateTime = 0;

// Declare the pins
int ledPin = 3;                       // LED connected to digital pin 3

// LED setup
int value = LOW;                      // previous value of the LED
long previousMillis = 0;              // will store last time LED was updated
long freqency = 16;                   // Hz (1/sec)
long thousand = 1000;
long blinkInterval = thousand / freqency;  // milliseconds

//// LDR counter variables ////
// Counting vars
static int counter = 0;
int booBlocked = 0;
int checkValue = counter + 1;
// Calibration vars
long onBootCalibrationTime = 5000;     // time [time] to use for calibration when the system is booted
static int threshold = 0;              // Value used for counting (calibrated in the beginning)
float cutValue = 0.90;                 // Procent value used to allow jitting in the max signal without counting.

// Frequency vars
float freq = 0;                        // Calculated blink frequency...
long frequencyInterval = 5000;        // time [ms]
long pMillis = 0;
int pCount = 0;

void setup() {
// Setup the pins
pinMode(ledPin, OUTPUT);      // sets the digital pin as output

// display static values
lcd.begin(16, 2);
lcd.setCursor(0,0);  lcd.print(freqency);
lcd.setCursor(4,0);  lcd.print("Hz");
lcd.setCursor(4,1);  lcd.print("ms");

// Setup that allows loggin
Serial.begin(9600);  // Allows to get a readout from Putty (windows 7)
}

void loop() {
long time = millis();

// Calibrate or Count (AND calculate the frequency) via the LDR
if (time < onBootCalibrationTime){
setThresholdValue(sensorValue);
} else {
doCount(sensorValue);
updateFreq(time);
}

// Update the LCD
if (time > updateTime){
updateTime += updateInterval;  // set the next time to update the LCD

// Display the sensor value
lcd.setCursor(7,1);  lcd.print(sensorValue);
// Display the threshold value used to determined if blocked or not
lcd.setCursor(7+5,1);  lcd.print(threshold);
// Display the count
lcd.setCursor(7,0);
lcd.print(counter);
// Display the calculated frequency
lcd.setCursor(7+5,0);  lcd.print(freq);
}
}

if (t - previousMillis > blinkInterval) {
previousMillis = t;   // remember the last time we blinked the LED
// if the LED is off turn it on and vice-versa.
if (value == LOW)
value = HIGH;
else
value = LOW;
digitalWrite(ledPin, value);
}
}

void setThresholdValue(int sValue){
if (sValue > int(threshold/cutValue)){
threshold = int (sValue*cutValue);
}
}

void doCount(int sValue){
if (sValue < threshold){
booBlocked = 1;
} else {
booBlocked = 0;
}

if (booBlocked == 1) {
if (counter != checkValue){
counter = counter + 1;
}
} else {
if (counter == checkValue){
checkValue = checkValue + 1;
}
}
}

void updateFreq(long t){
long inter = t - pMillis;
if (inter >= frequencyInterval) {
freq = (counter - pCount) / (float) (inter/1000);
pMillis = t;           // remember the last time we blinked the LED
pCount = counter;
}
}
``````

This code does not fix my question, but is just more easy to read.

-
I haven't analyzed all your code, but you definitely should account for noise and jitter in your digitized analog values: Use some hysteresis or at least reasonable averaging of the ADC readout to avoid artificial oscillations. Note also that LDRs are rather slow-responding devices, which implies that the resistance changes gradually instead of instantaneous. So you should also allow for some settling of the sensor between the change of the LED state and the measuring of the LDR. (Some 100ms will usually be sufficient.) –  Hanno Binder Feb 13 at 14:10

The issue with your plan is that a light density resistor is going to pick up all the ambient light around and therefore be completely environment sensitive.

Have any other project hopes? This one seems like an engineering learning experience, not a coding one.

Have you thought of motor projects? Personally I'm more into home automation, but motor projects are almost instantly rewarding.

-
If you look at the video you will see that I have shielded the LDR. I do believe that this is a code bug I just can't find it.. –  Norfeldt Feb 13 at 6:37
Yeah, I wrote this from work and chose not to look at videos :) but I'll look at it when I get home. –  Eric Fossum Feb 13 at 16:58
Did you come up with anything? –  Norfeldt Feb 19 at 8:24
Sorry, I've forgotten the last couple nights. I'll set myself a reminder. –  Eric Fossum Feb 20 at 17:54

I'd recommend to re-write your `doCount()` function along these lines to make things simpler and easier to grasp:

``````void doCount(int sensorValue){

static int previousState;
int currentState;

if ( previousState == 0 ) {
currentState = sensorValue > upperThreshold;
} else {
currentState = sensorValue > lowerThreshold;
}

if ( previousState != 0 ) {
if ( currentState == 0 ) {
counter++;
}
}

previousState = currentState;

}
``````

Let `lowerThreshold` and `upperThreshold` be, for example, 90% and 110%, respectively, of your former `tValue`, and you have a hysteresis to smoothen the reaction to noisy ADC read-outs.

-
Your code didn't help me.. couldn't implement it so it worked.. –  Norfeldt Feb 16 at 10:17

I think i found one of the bugs.. I was using a `delay()` which caused some trouble..

I cleaned up the code:

``````#include <LiquidCrystal.h>
// Initiate the LCD display
LiquidCrystal lcd(7, 8, 9, 10, 11 , 12); // see setup at http://lassenorfeldt.weebly.com/1/post/2013/02/ardunio-lcd.html
long updateInterval = 150;                // ms
long updateTime = 0;

// Declare the pins
int ledPin = 3;                       // LED connected to digital pin 3

// LED setup
int value = LOW;                      // previous value of the LED
long previousMillis = 0;              // will store last time LED was updated
long freqency = 16;                   // Hz (1/sec)
long thousand = 1000;
long blinkInterval = thousand / freqency;  // milliseconds

//// LDR counter variables ////
// Counting vars
static int counter = 0;
int booBlocked = 0;
int checkValue = counter + 1;
// Calibration vars
long onBootCalibrationTime = 5000;     // time [time] to use for calibration when the system is booted
static int threshold = 0;              // Value used for counting (calibrated in the beginning)
float cutValue = 0.90;                 // Procent value used to allow jitting in the max signal without counting.

// Frequency vars
float freq = 0;                        // Calculated blink frequency...
long frequencyInterval = 5000;        // time [ms]
long pMillis = 0;
int pCount = 0;

void setup() {
// Setup the pins
pinMode(ledPin, OUTPUT);      // sets the digital pin as output

// display static values
lcd.begin(16, 2);
lcd.setCursor(0,0);  lcd.print(freqency);
lcd.setCursor(4,0);  lcd.print("Hz");
lcd.setCursor(4,1);  lcd.print("ms");

// Setup that allows loggin
Serial.begin(9600);  // Allows to get a readout from Putty (windows 7)
}

void loop() {
long time = millis();

// Calibrate or Count (AND calculate the frequency) via the LDR
if (time < onBootCalibrationTime){
setThresholdValue(sensorValue);
} else {
doCount(sensorValue);
updateFreq(time);
}

// Update the LCD
if (time > updateTime){
updateTime += updateInterval;  // set the next time to update the LCD

// Display the sensor value
lcd.setCursor(7,1);  lcd.print(sensorValue);
// Display the threshold value used to determined if blocked or not
lcd.setCursor(7+5,1);  lcd.print(threshold);
// Display the count
lcd.setCursor(7,0);
lcd.print(counter);
// Display the calculated frequency
lcd.setCursor(7+5,0);  lcd.print(freq);
}
}

if (t - previousMillis > blinkInterval) {
previousMillis = t;   // remember the last time we blinked the LED
// if the LED is off turn it on and vice-versa.
if (value == LOW)
value = HIGH;
else
value = LOW;
digitalWrite(ledPin, value);
}
}

void setThresholdValue(int sValue){
if (sValue > int(threshold/cutValue)){
threshold = int (sValue*cutValue);
}
}

void doCount(int sValue){
if (sValue < threshold){
booBlocked = 1;
} else {
booBlocked = 0;
}

if (booBlocked == 1) {
if (counter != checkValue){
counter = counter + 1;
}
} else {
if (counter == checkValue){
checkValue = checkValue + 1;
}
}
}

void updateFreq(long t){
long inter = t - pMillis;
if (inter >= frequencyInterval) {
freq = (counter - pCount) / (float) (inter/1000);
pMillis = t;           // remember the last time we blinked the LED
pCount = counter;
}
}
``````

Its not as precise as I wished.. but I believe that this is might due to the way I blink the LED.

I also discovered that `float cutValue = 0.90;` has an influence... lowering the bar to 0.85 decrease the calculated frequency.. ??

-

I changed the code completely after Albert was so kind to help me out using his awesome FreqPeriodCounter library

I also added a potentiometer to control the frequency

Here is my code:

``````#include <FreqPeriodCounter.h>
#include <LiquidCrystal.h>

// FrequencyCounter vars
const byte counterPin = 3;  // Pin connected to the LDR
const byte counterInterrupt = 1; // = pin 3
FreqPeriodCounter counter(counterPin, micros, 0);

// LCD vars
LiquidCrystal lcd(7, 8, 9, 10, 11 , 12); // see setup at http://lassenorfeldt.weebly.com/1/post/2013/02/ardunio-lcd.html
long updateInterval = 200;                // ms
long updateTime = 0;

// LED vars
int ledPin = 5;                       // LED connected to digital pin 3
int value = LOW;                      // previous value of the LED
float previousMillis = 0;              // will store last time LED was updated
static float freqency;                   // Hz (1/sec)
static float pfreqency;

boolean logging = true;              // Logging by sending to serial

// Use potentiometer to control LED frequency
int potPin = 5;    // select the input pin for the potentiometer
int val = 0;       // variable to store the value coming from the sensor

void setup(void){
// Setup the pins
pinMode(ledPin, OUTPUT);      // sets the digital pin as output

freqency = map(val, 0, 1023, 0, 25);                   // Hz (1/sec)
pfreqency = freqency;
blinkInterval = 1000 / (freqency*2);                  // milliseconds

// LCD display static values
lcd.begin(16, 2);
lcd.setCursor(0,0);  lcd.print(freqency);
lcd.setCursor(4,0);  lcd.print("Hz");
lcd.setCursor(14,0);  lcd.print("Hz");
lcd.setCursor(4,1);  lcd.print("ms");

//
attachInterrupt(counterInterrupt, counterISR, CHANGE);

// Logging
if (logging) {Serial.begin(9600);}
}

void loop(void){
// Loop vars
float time = (float) millis();
float freq = (float) counter.hertz(10)/10.0;

if (logging) {
}

// Update the LCD
if (time > updateTime){
updateTime += updateInterval;  // set the next time to update the LCD
lcdNicePrint(7+3, 0, freq); lcd.setCursor(14,0);  lcd.print("Hz");
freqency = map(val, 0, 1023, 1, 30);

if (freqency != pfreqency){
pfreqency = freqency;
blinkInterval = 1000 / (freqency*2);                  // milliseconds

lcdNicePrint(0,0, freqency);  lcd.setCursor(4,0);  lcd.print("Hz");
lcd.setCursor(4,1);  lcd.print("ms");
}
}
}

void lcdNicePrint(int column, int row, float value){
lcd.setCursor(column, row);  lcd.print("00");
if (value < 10) {lcd.setCursor(column+1, row);  lcd.print(value);}
else {lcd.setCursor(column, row);  lcd.print(value);}
}

if (t - previousMillis > blinkInterval) {
previousMillis = t;   // remember the last time we blinked the LED
// if the LED is off turn it on and vice-versa.
if (value == LOW)
value = HIGH;
else
value = LOW;
digitalWrite(ledPin, value);
}
}

void counterISR()
{ counter.poll();
}
``````
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