I'm a newcomer to Arduino, and I'm trying to use Processing to control my Arduino Uno board relying on Firmata library. However after quick test, I can't seem to be able to light up my LED when using analog pins from A0 to A5, while it works without any problem for digital pins 0 - 13. Using Arduino directly works without any issue for all 19 pins.
void setup() {
arduino = new Arduino(this, "/dev/tty.usbmodem1411" );
for( int i = 0; i < 20; i++ ) // in Arduino A0 is pin 14, but to be sure I also tried in processing pin 16, just in case if A0 is 0xA0
arduino.pinMode( i, Arduino.OUTPUT );
}
void draw() {
for( int i = 0; i < 20; i++ ) { // quick and dirty mode to test all LEDs
arduino.digitalWrite( i, Arduino.HIGH );
arduino.analogWrite( i, 255 );
}
}
Currently I'm using SainSmart UNO board, and the reason I'm using processing because I need to access higher level libraries which are only available at processing for now.
Does anyone know how to code so that I can use Processing to access the analog pins on the Arduino board ?
It might be good idea to turn Analog Inputs as INPUTS in Firmata sketch inside Arduino.
void setup()
{
pinMode(A0, OUTPUT); // <- like this...
Firmata.setFirmwareVersion(0, 1); //... and then go on with standard firmata
Firmata.begin();
}
Related
Hey i got a bit problem with my Arduino and sensor
Here is what i tried ;
#define USE_ARDUINO_INTERRUPTS true // Set-up low-level interrupts for most acurate BPM math.
#include <PulseSensorPlayground.h> // Includes the PulseSensorPlayground Library.
#include <SoftwareSerial.h>
SoftwareSerial blue(0,1);
const int PulseWire = 0; // PulseSensor PURPLE WIRE connected to ANALOG PIN 0
const int LED13 = 13; // The on-board Arduino LED, close to PIN 13.
int Threshold = 550;
PulseSensorPlayground pulseSensor;
void setup() {
// put your setup code here, to run once:
Serial.begin(9600);
blue.begin(9600);
pulseSensor.analogInput(PulseWire);
pulseSensor.blinkOnPulse(LED13); //auto-magically blink Arduino's LED with heartbeat.
pulseSensor.setThreshold(Threshold);
pulseSensor.begin();
}
void loop() {
// put your main code here, to run repeatedly:
int myBPM = pulseSensor.getBeatsPerMinute();
if(myBPM>200){
myBPM-100;
}
if (pulseSensor.sawStartOfBeat()) {
Serial.println(myBPM);
blue.println(myBPM);
}
delay(10);
}
this code I got from the example library and modified it.
so i want to send data to my android using Bluetooth but this sensor kinda ticked me off because whenever i use it with my HC-06 Bluetooth module it suddenly got a hearth beat without i even touching it and it just sends so much data ignoring the delay I set.
I just need to slowly sending data just like a second but the data didn't show up
so anyone can help?
I read your code and I noticed this piece of code
if(myBPM > 200){ myBPM - 100; }
that is poorly written if (I understand correctly) you want to check the size of myBPM and if it is larger than 200 then it should be subtracted 100.
it should be:
myBPM = myBPM - 100; not myBPM - 100;
I hope my answer will help you. Have a nice day!
I made a nice code which generates fast PWM with 50% duty cycle and I can change the frequency with a potentiometer. It outputs straight and inverted channels with some dead time. I am using Arduino Micro aka ATmega32U4. The code is actually "Atmel" code. Code is working fine until I power Arduino Micro off and then on again.
I have programmed the code and registers so that the frequency is changeable from 10kHz to 100kHz. But after power on/off the frequency changes from 5kHz to 50kHz. After this has happened I have to program the board again using Arduino IDE, to make it work correctly. Again after power on/off it has changed. I am quite sure that one of the registers is overwritten by the "Arduino hardware abstraction layer" or however we should name it. I have not yet read out all the registers so I do not know which one is overwritten. I guess it's the prescaler.
How do I prevent this from happening? Should I write the register contents somewhere else? Or should I write it few times to be sure?
Why or how this is happening anyway?
Here's the code:
#define OSC1 5
#define OSC2 13
uint8_t read_reg1;
uint8_t read_reg2;
int pot, freq;
void setup() {
pinMode(OSC1, OUTPUT);
pinMode(OSC2, OUTPUT);
Serial.begin(9600);
cli(); // disable global interrupts
TCCR4A=0; // clear register
TCCR4B=0x06; // configure prescaler to 64 (CK = CLK / 64 = 1.5 MHz)
TCCR4C=0;
TCCR4D=0; // select Fast PWM operation (0 << WGM41)|(0 << WGM40)
PLLFRQ=(PLLFRQ&0xCF)|0x30; // select clock source and frequency
OCR4C=150; // select PWM frequency
OCR4A=150/2; // set duty cycle
DT4 = 0x55; // set dead times. DT = (1 / 48Mhz) * 0...15
// enable interrupt on timer4 overflow
TIMSK4|=(1 << TOIE4);
// This register write has to be after others. Otherwise the PWM generation will not work. I do not know why.
TCCR4A=0x42; // COM4A1..0 = 01, OC4A and !OC4A connected. PWM4A = 1 (activate channel A PWM output)
sei(); // enable global interrupts
}
void loop() {
//cli();
pot = analogRead(A0);
freq = map(pot, 0, 1023, 14, 166);
//sei();
/*
Serial.print("Pot value: ");
Serial.print(pot);
Serial.print("\tFreq value: ");
Serial.println(1500000/freq);
*/
}
ISR(TIMER4_OVF_vect){
OCR4C = freq;
OCR4A = freq / 2;
}
I am not sure exactly why you got different behavior right after programming, but the bootloader that the Arduino Micro uses (Caterina) does not perform a full reset after it runs, so changes that the bootloader made to the AVR's registers are often visible to the user's sketch.
I was able to fix the problem by removing the line that modifies PLLFRQ. Here is a simplified version of your code that always produces 3.31 kHz PWM:
void setup()
{
pinMode(5, OUTPUT);
pinMode(13, OUTPUT);
TCCR4A = 0;
TCCR4B = 0x06; // configure prescaler to 64 (CK = CLK / 64 = 1.5 MHz)
TCCR4C = 0;
TCCR4D = 0; // select Fast PWM operation (0 << WGM41)|(0 << WGM40)
OCR4C = 150; // select PWM frequency
OCR4A = 150 / 2; // set duty cycle
DT4 = 0x55; // set dead times. DT = (1 / 48Mhz) * 0...15
// This register write has to be after others.
// Otherwise the PWM generation will not work. I do not know why.
// COM4A1..0 = 01, OC4A and !OC4A connected.
// PWM4A = 1 (activate channel A PWM output)
TCCR4A = 0x42;
}
void loop()
{
}
It's not a great idea to mess with the PLL postscaler since it will probably affect every other Arduino library that uses timers, including the USB stack.
I've got an Arduino with a WS2812 hooked up to it, powered by the USB on my computer and I am trying to run the following code:
#include <FastLED.h>
#define NUM_LEDS 144
#define DATA_PIN 6
#define LED_TYPE WS2812B
#define COLOR_ORDER GRB
CRGB leds[NUM_LEDS];
void setup() {
FastLED.addLeds<LED_TYPE, DATA_PIN, COLOR_ORDER>(leds, NUM_LEDS);
FastLED.show();
}
void loop() {
for(int dot = 0; dot < NUM_LEDS; dot++) {
fill_solid(leds, NUM_LEDS, CRGB::Red);
leds[dot] = CRGB::Black;
leds[dot] = CRGB::Blue;
FastLED.show();
leds[dot] = CRGB::Red;
delay(30);
}
}
void setAll() {
FastLED.show();
}
What this does is sets all the LEDs to red, then goes through each one turning it off, then to blue and then back to red.
For some reason, it gets X number of LEDs along and then crashes. By crashes I mean the Arduino disconnects itself from the computer, but the Arduino stays on with the LED strip still powered up.
Any ideas? This is a genuine Uno.
Also. If I plug the LED into the 3.3v pin, the animations works just fine, but the LED flashes black and doesn't complete the Blue part.
I never used the NeoPixels, so I'm not really sure about this, but I'm pretty confident these will solve your problem.
First of all, your program. I don't think it is doing what you think it should do. Try with this loop, instead:
void loop()
{
fill_solid(leds, NUM_LEDS, CRGB::Red);
FastLED.show();
delay(100);
for(int dot = 0; dot < NUM_LEDS; dot++)
{
leds[dot] = CRGB::Black;
FastLED.show();
delay(100);
leds[dot] = CRGB::Blue;
FastLED.show();
delay(100);
leds[dot] = CRGB::Red;
FastLED.show();
delay(100);
}
}
and remove the SetAll function, since it is useless.
Try this code with NUM_LEDS set to 5, and it should work.
Now the main problem: are you really using 144 leds powered by the USB? I suggest you to read this link about powering the neopixels. Particularly the part stating that at full brightness each neopixel draws 60mA. Doing the math, 144 neopixels draw at most 8.64A, so you need a 5V 10A power supply to power them all! a USB with 5V 0.5A will just shut itself down when you try to turn them on, thus giving you strange behaviors.
So lower the number of leds you are using (7 at most), or use an external power supply. And by external I do not mean use the barrel jack on the arduino, but connect a 5V 10A (or more amps) to the neopixel strip, then the ground and data wire to the arduino (not the +5v) and power the arduino through the usb port: it should work.
UPDATE:
According to the chat with the author, the problem was indeed the power supply
The datasheet from adafruit https://cdn-shop.adafruit.com/datasheets/WS2812.pdf says that you need a power supply between 6v and 7v but USB cannot provide more than 5v, I am guessing the arduino crashes because it cannot find enough power.
Can you try using an external power supply?
I have this RFID reader "Rosslare AY-X12", and it's working with Wiegand 26bit. I have an arduino mini Pro and connected together it's working fine but it only reads the card one time and then I have nothing.
When I put on the card arduino reads that card but only one time during the card is near by the reader and it again reads that card when I put off the card and then I put on. But I want to read that card continuously, I mean when the card is near by the Reader still reading the card, every 1ms reads that card.
Do you have any idea how to do that ? Is there any RFID arduino library which can do that? I had got the Mifare and its can do that. But this 125Khz reader which can communicate over Wiegand can't do that or I don't know how to do that.
I'm using this library : https://github.com/monkeyboard/Wiegand-Protocol-Library-for-Arduino
My previous answer was deleted. I am going to make another attempt to answer the questions.
Do you have any idea how to do that ?
This cannot be done by Arduino because Arduino in your case is just reading the D0 and D1 pulses from your RFID reader. Since your RFID reader Rosslare AY-X12 does not send out continuous output of wiegand protocol, there is no way Arduino can read more than what was not sent to it.
The common RFID readers will not send continuous data of the same card because in the common use case (entry/exit/attendance), normally one tap is to check-in and another tap is to check-out. If the RFID reader sends continuous data of the same card, the main system receiving the multiple wiegand data will be confused and will not be able to determine if the user actually wish to check-in or check-out.
Is there any RFID arduino library which can do that?
No. There is no such RFID Arduino library. If the RFID reader is not sending out continuous data, there is no way the receiver (Arduino) can receive them.
Is there a way to achieve this?
Yes, there are some readers that has the option to turn on the continuous output of data, for example 714-52 MifareĀ® ID Reader with selectable outputs. In its specification :
Continuous output with tag in field or single transmission
With this reader configured to continuous output, you can then use Arduino and the monkeyboard wiegand library to read the data.
I wrote my own wiegand code. Its not that difficult. I attached interrupts to the data pins and when they change I log the zero or one. You then build up the binary string and once timed out because no bits coming in. Then you convert the binary to decimal.
#include <LiquidCrystal.h>
int data0 = 2; //set wiegand data 0 pin
int data1 = 3; //set wiegand data 1 pin
unsigned long bit_holder; //unsigned long (positive 32 bit number)
unsigned long oldbit = 0;
volatile int bit_count = 0;
LiquidCrystal lcd(8, 9, 10, 11, 12, 13);
unsigned long badge;
unsigned int timeout;
unsigned int t = 800;
void setup() {
Serial.begin(9600);
lcd.begin(16, 2);
lcd.print("Present Badge");
delay(2);
Serial.println("Present Badge");
pinMode(data0, INPUT);
digitalWrite(data0, HIGH);
pinMode(data1, INPUT);
digitalWrite(data1, HIGH);
attachInterrupt(0, zero, FALLING); //attach interrupts and assign functions
attachInterrupt(1, one, FALLING);
}
void zero(){
bit_count ++;
bit_holder = (bit_holder << 1) + 0; //shift left one and add a 0
timeout = t;
}
void one(){
bit_count ++;
bit_holder = (bit_holder << 1) + 1; //shift left one and add a 1
timeout = t;
}
void loop() {
timeout --;
if (timeout == 0 && bit_count > 0){
lcd.clear();
lcd.print("Dec:");
lcd.print(bit_holder);
lcd.setCursor(0,1);
lcd.print("Hex:");
lcd.print(String(bit_holder,HEX));
Serial.print("bit count= ");
Serial.println(bit_count);
Serial.print("bits= ");
Serial.println(bit_holder,BIN);
oldbit = bit_holder; //store previous this value as previous
bit_count = 0; //reset bit count
bit_holder = 0; //reset badge number
}
}
You may need to find a reader that offer a continuously reading, as I know almost of Wiegand Reader in the market can't perform a continuously reading because they have a "onboard" control that controls this...
Maybe you can try with Arduino Serial RFID Reader...
try a this timer libary Timer1 and mayby try this code it worked for me, my tags and cards now reads continuously.
Greetings from Denmark
Gregor
#include <Timer1.h>
//******************************************************************
// ATmega168, ATmega328:
// - Using Timer 1 disables PWM (analogWrite) on pins 9 and 10
// ATmega2560:
// - Using Timer 1 disables PWM (analogWrite) on pins 11 and 12
// - Using Timer 3 disables PWM (analogWrite) on pins 2, 3 and 5
// - Using Timer 4 disables PWM (analogWrite) on pins 6, 7 and 8
// - Using Timer 5 disables PWM (analogWrite) on pins 44, 45 and 46
//******************************************************************
unsigned int lastTime;
#include <SoftwareSerial.h>
SoftwareSerial RFID = SoftwareSerial(2,4);
char character;
String our_id;
void setup()
{
// Disable Arduino's default millisecond counter (from now on, millis(), micros(),
// delay() and delayMicroseconds() will not work)
disableMillis();
// Prepare Timer1 to count
// On 16 MHz Arduino boards, this function has a resolution of 4us
// On 8 MHz Arduino boards, this function has a resolution of 8us
startCountingTimer1();
lastTime = readTimer1();
Serial.begin(9600);
RFID.begin(9600);
}
void loop()
{
unsigned int now = readTimer1();
while (RFID.available()>0)
{
character = RFID.read();
our_id += character;
lastTime = now;
}
if (our_id.length() > 10) {
our_id = our_id.substring(1,13);
Serial.println(our_id);
our_id = "";
}
delay(1000);
}
So my problem is as title says: Arduino UNO analogRead always returns 1023.
But when I burn the same sketch in Arduino Mega 2650 everything works like a charm.
I have tried to change Atmel chips on the UNO, have tried like 3 of them (ATMEGA328P-PU) and nothing changes.
I'm trying to count signals from a hall effect sensor and display the count on a 7 segment display.
Here is the code:
#include "SevSeg.h"
SevSeg sevseg;
volatile int rpmcount;
void setup() {
Serial.begin(9600);
pinMode(2,INPUT_PULLUP);
rpmcount = 0;
sevseg.Begin(1,3,4,5,6,7,8,9,10,11,12,13);
}
int border=15;
void loop() {
int tmp=0;
tmp = analogRead(0);
if(!digitalRead(2))rpmcount=0;
Serial.println(tmp,DEC);
if(tmp<=border && res >border){
rpmcount++;
if(rpmcount>9999)rpmcount=0;
}
res=tmp;
sevseg.NewNum(rpmcount,(byte) 0);
sevseg.PrintOutput();
}
Any help would be much appreciated
This sounds to me as if you had the internal pullup resistor on the ADC pin enabled.
generic checklist:
ACD bit in ACSR is 0 (comparator enable)
MUX bits in ADMUX set properly
correct AREF selected
ADC pin set as input
internal pull up resistors are deselected