I'm a newby to robotics and electronics in general, so please don't assume I tried anything you might think is obvious.
I'm trying to create a cart which will basically run around by itself (simple AI routines to avoid obstacles, go from pt. A to pt. B around corners, follow lines, etc.). I'm putting together an Adafruit Arduino Uno R3 with the Adafruit Motor Shield v2 and an MPU-6050. I'm using the "breadboard" on the Motor Shield for the circuitry, soldering everything there.
I can get all the pieces working independently with their own scripts: the Motor Shield drives the 4 motors as expected using the Adafruit library; I'm using the "JRowberg" library for the MPU-6050, and started with the example MPU6050_DMP6.ino, which works fine as long as the cart motors are turned off. My only changes in the example script below are motor startup and some simple motor commands.
As long as I leave the switch which powers the motors off, everything seems fine: it outputs to the Serial window continuously with Euler data which, I assume, is correct. However, a few seconds after I turn on the power to the motors (and the wheels start turning), it just hangs/freezes: the output to the Serial window stops (sometimes in mid-line), and the wheels keep turning at the speed of their last change. Sometimes I see "FIFO overflow" errors, but not always. Sometimes I see "nan" for some of the floating point values before it hangs, but not always.
Some things I've tried, all of which changed noting:
* I've swapped out the MPU-6050 board for another from the same manufacturer.
* I've tried moving the MPU-6050 away from the motors using a ribbon cable.
* I've changed the I2C clock using JRowber's advice (a change in a .h file and changing the value of the TWBR variable), but I don't think I've tried all possible values.
* I've changed the speed of the MotorShield in the AFMS.begin() command, although, again, there are probably other values I haven't tried, and I'm not sure how in-sync this and the TWBR value need to be.
And some other things, all to no avail.
Below is an example script which fails for me:
#include "I2Cdev.h"
#include "MPU6050_6Axis_MotionApps20.h"
// is used in I2Cdev.h
#if I2CDEV_IMPLEMENTATION == I2CDEV_ARDUINO_WIRE
#include "Wire.h"
#endif
#include "Adafruit_MotorShield.h"
#include "utility/Adafruit_PWMServoDriver.h"
#define DEBUG 1
MPU6050 mpu;
#define OUTPUT_READABLE_EULER
#define LED_PIN 13
bool blinkState = false;
bool dmpReady = false; // set true if DMP init was successful
uint8_t mpuIntStatus; // holds actual interrupt status byte from MPU
uint8_t devStatus; // return status after each device operation (0 = success, !0 = error)
uint16_t packetSize; // expected DMP packet size (default is 42 bytes)
uint16_t fifoCount; // count of all bytes currently in FIFO
uint8_t fifoBuffer[64]; // FIFO storage buffer
Quaternion q; // [w, x, y, z] quaternion container
VectorInt16 aa; // [x, y, z] accel sensor measurements
VectorInt16 aaReal; // [x, y, z] gravity-free accel sensor measurements
VectorInt16 aaWorld; // [x, y, z] world-frame accel sensor measurements
VectorFloat gravity; // [x, y, z] gravity vector
float euler[3]; // [psi, theta, phi] Euler angle container
float ypr[3]; // [yaw, pitch, roll] yaw/pitch/roll container and gravity vector
uint8_t teapotPacket[14] = { '$', 0x02, 0,0, 0,0, 0,0, 0,0, 0x00, 0x00, '\r', '\n' };
Adafruit_MotorShield AFMS = Adafruit_MotorShield();
#define NUM_MOTORS 4
#define MOTOR_FL 0
#define MOTOR_FR 1
#define MOTOR_RR 2
#define MOTOR_RL 3
Adafruit_DCMotor *myMotors[NUM_MOTORS] = {
AFMS.getMotor(1),
AFMS.getMotor(2),
AFMS.getMotor(3),
AFMS.getMotor(4),
};
#define CHANGE_SPEED_TIME 500
long changeSpeedMillis = 0;
int curSpeed = 30;
volatile bool mpuInterrupt = false; // indicates whether MPU interrupt pin has gone high
void dmpDataReady() {
mpuInterrupt = true;
}
void setup() {
#if I2CDEV_IMPLEMENTATION == I2CDEV_ARDUINO_WIRE
Wire.begin();
TWBR = 24; // 400kHz I2C clock (200kHz if CPU is 8MHz)
#elif I2CDEV_IMPLEMENTATION == I2CDEV_BUILTIN_FASTWIRE
Fastwire::setup(400, true);
#endif
Serial.begin(115200);
while (!Serial); // wait for Leonardo enumeration, others continue immediately
// start the motor shield.
AFMS.begin(); // create with the default frequency 1.6KHz
// AFMS.begin(4000); // OR with a different frequency, say 4KHz
// kill all the motors.
myMotors[MOTOR_FL]->run(BRAKE);
myMotors[MOTOR_FL]->setSpeed(0);
myMotors[MOTOR_FR]->run(BRAKE);
myMotors[MOTOR_FR]->setSpeed(0);
myMotors[MOTOR_RR]->run(BRAKE);
myMotors[MOTOR_RR]->setSpeed(0);
myMotors[MOTOR_RL]->run(BRAKE);
myMotors[MOTOR_RL]->setSpeed(0);
Serial.println("Motor Shield ready!");
Serial.println(F("Initializing I2C devices..."));
mpu.initialize();
// verify connection
Serial.println(F("Testing device connections..."));
Serial.println(mpu.testConnection() ? F("MPU6050 connection successful") : F("MPU6050 connection failed"));
// wait for ready
Serial.println(F("\nSend any character to begin DMP programming and demo: "));
while (Serial.available() && Serial.read()); // empty buffer
while (!Serial.available()); // wait for data
while (Serial.available() && Serial.read()); // empty buffer again
// load and configure the DMP
Serial.println(F("Initializing DMP..."));
devStatus = mpu.dmpInitialize();
// supply your own gyro offsets here, scaled for min sensitivity
mpu.setXGyroOffset(220);
mpu.setYGyroOffset(76);
mpu.setZGyroOffset(-85);
mpu.setZAccelOffset(1788); // 1688 factory default for my test chip
// make sure it worked (returns 0 if so)
if (devStatus == 0) {
// turn on the DMP, now that it's ready
Serial.println(F("Enabling DMP..."));
mpu.setDMPEnabled(true);
// enable Arduino interrupt detection
Serial.println(F("Enabling interrupt detection (Arduino external interrupt 0)..."));
attachInterrupt(0, dmpDataReady, RISING);
mpuIntStatus = mpu.getIntStatus();
// set our DMP Ready flag so the main loop() function knows it's okay to use it
Serial.println(F("DMP ready! Waiting for first interrupt..."));
dmpReady = true;
// get expected DMP packet size for later comparison
packetSize = mpu.dmpGetFIFOPacketSize();
} else {
// ERROR!
// 1 = initial memory load failed
// 2 = DMP configuration updates failed
// (if it's going to break, usually the code will be 1)
Serial.print(F("DMP Initialization failed (code "));
Serial.print(devStatus);
Serial.println(F(")"));
}
// configure LED for output
pinMode(LED_PIN, OUTPUT);
}
void loop() {
// if programming failed, don't try to do anything
if (!dmpReady) return;
// wait for MPU interrupt or extra packet(s) available
while (!mpuInterrupt && fifoCount < packetSize) {
// as per Vulpo's post.
delay(10);
if (millis() > changeSpeedMillis) {
curSpeed += 20;
if (curSpeed > 256) {
curSpeed = 30;
}
Serial.print("changing speed to: ");
Serial.println(curSpeed);
myMotors[MOTOR_FL]->run(FORWARD);
myMotors[MOTOR_FL]->setSpeed(curSpeed);
myMotors[MOTOR_FR]->run(FORWARD);
myMotors[MOTOR_FR]->setSpeed(curSpeed);
myMotors[MOTOR_RR]->run(FORWARD);
myMotors[MOTOR_RR]->setSpeed(curSpeed);
myMotors[MOTOR_RL]->run(FORWARD);
myMotors[MOTOR_RL]->setSpeed(curSpeed);
changeSpeedMillis = millis() + CHANGE_SPEED_TIME;
}
}
// reset interrupt flag and get INT_STATUS byte
mpuInterrupt = false;
mpuIntStatus = mpu.getIntStatus();
// get current FIFO count
fifoCount = mpu.getFIFOCount();
// check for overflow (this should never happen unless our code is too inefficient)
if ((mpuIntStatus & 0x10) || fifoCount == 1024) {
// reset so we can continue cleanly
mpu.resetFIFO();
Serial.println(F("FIFO overflow!"));
// otherwise, check for DMP data ready interrupt (this should happen frequently)
} else if (mpuIntStatus & 0x02) {
// wait for correct available data length, should be a VERY short wait
while (fifoCount < packetSize) fifoCount = mpu.getFIFOCount();
// read a packet from FIFO
mpu.getFIFOBytes(fifoBuffer, packetSize);
// track FIFO count here in case there is > 1 packet available
// (this lets us immediately read more without waiting for an interrupt)
fifoCount -= packetSize;
#ifdef OUTPUT_READABLE_EULER
// display Euler angles in degrees
mpu.dmpGetQuaternion(&q, fifoBuffer);
mpu.dmpGetEuler(euler, &q);
Serial.print("euler\t");
Serial.print(euler[0] * 180/M_PI);
Serial.print("\t");
Serial.print(euler[1] * 180/M_PI);
Serial.print("\t");
Serial.println(euler[2] * 180/M_PI);
#endif
// blink LED to indicate activity
blinkState = !blinkState;
digitalWrite(LED_PIN, blinkState);
}
}
Have you considered that your troubles are caused by interference from the currents flowing into your motors?
If your motors are DC brush, then more interference may be radiated from the brushes back into your various wires.
As a first step, perhaps let only one motor work and see if hangups diminish in frequency (although, to be sure, you need a 'scope onto a few wires carrying logic signals.
Related
There are a lot of AC Fan dimmer codes are available in internet with zero cross detection and runs by Blynk app as well.
Problem is All those are only controllable by wifi (with internet) , rather have no manual control (without internet) at all.
I share a code below for AC fan dimmer which is runs by blynk app (Board NodeMCU) . It is only runs when wifi is available, i.e it has no manual contro. I am trying to improve/modify the same code by adding two physical push buttons to control Fan speed manually when internet is not available. In this case I am unable to modify the codes for these two push buttons which also capable to increase and decrease the fan speed along with the Blynk app slider button. Can anyone help/Guide me to develop this.
#define BLYNK_PRINT Serial
#include <ESP8266WiFi.h>
#include <BlynkSimpleEsp8266.h>
#define triacPulse 4 //D2
#define ZVC 12 //D6
int Slider_Value;
int dimming;
int x = 0;
char auth[] = "AUTH TOKEN"; // You should get Auth Token in the Blynk App.
char ssid[] = "SSID"; // Your WiFi credentials.
char pass[] = "PASS"; // Set password to "" for open networks.
BLYNK_WRITE(V1) // function to assign value to variable Slider_Value whenever slider changes position
{
Slider_Value = param.asInt(); // assigning incoming value from pin V1 to a variable
}
void setup()
{
pinMode(ZVC, INPUT_PULLUP);
//digitalWrite(2, INPUT_PULLUP); // pull up
pinMode(triacPulse, OUTPUT);
Serial.begin(9600);
Blynk.begin(auth, ssid, pass);
attachInterrupt(digitalPinToInterrupt(ZVC), acon, FALLING); // attach Interrupt at PIN2
}
void loop()
{
Blynk.run();
// When the switch is closed
dimming = map(Slider_Value, 0, 100, 7200, 200);
}
void acon()
{
// Serial.println("REad");
delayMicroseconds(dimming); // read AD0
digitalWrite(triacPulse, HIGH);
delayMicroseconds(50); //delay 50 uSec on output pulse to turn on triac
digitalWrite(triacPulse, LOW);
// Serial.println(digitalRead(triacPulse));
}
I'm currently implementing a driver for the WINC1500 to be used with an ATMEGA32 MCU and it's getting stuck on this line of "while(!spi_is_tx_empty(WINC1500_SPI));". The code builds and runs but it won't clear what's inside in this function to proceed through my code and boot up the Wifi Module. I've been stuck on this problem for weeks now with no progress and don't know how to clear it.
static inline bool spi_is_tx_empty(volatile avr32_spi_t *spi)
{
// 1 = All Transmissions complete
// 0 = Transmissions not complete
return (spi->sr & AVR32_SPI_SR_TXEMPTY_MASK) != 0;
}
Here is my implementation of the SPI Tx/Rx function
void m2mStub_SpiTxRx(uint8_t *p_txBuf,
uint16_t txLen,
uint8_t *p_rxBuf,
uint16_t rxLen)
{
uint16_t byteCount;
uint16_t i;
uint16_t data;
// Calculate the number of clock cycles necessary, this implies a full-duplex SPI.
byteCount = (txLen >= rxLen) ? txLen : rxLen;
// Read / Transmit.
for (i = 0; i < byteCount; ++i)
{
// Wait for transmitter to be ready.
while(!spi_is_tx_ready(WINC1500_SPI));
// Transmit.
if (txLen > 0)
{
// Send data from the transmit buffer
spi_put(WINC1500_SPI, *p_txBuf++);
--txLen;
}
else
{
// No more Tx data to send, just send something to keep clock active.
// Here we clock out a don't care byte
spi_put(WINC1500_SPI, 0x00U);
// Not reading it back, not being cleared 16/1/2020
}
// Reference http://asf.atmel.com/docs/latest/avr32.components.memory.sdmmc.spi.example.evk1101/html/avr32_drivers_spi_quick_start.html
// Wait for transfer to finish, stuck on here
// Need to clear the buffer for it to be able to continue
while(!spi_is_tx_empty(WINC1500_SPI));
// Wait for transmitter to be ready again
while(!spi_is_tx_ready(WINC1500_SPI));
// Send dummy data to slave, so we can read something from it.
spi_put(WINC1500_SPI, 0x00U); // Change dummy data from 00U to 0xFF idea
// Wait for a complete transmission
while(!spi_is_tx_empty(WINC1500_SPI));
// Read or throw away data from the slave as required.
if (rxLen > 0)
{
*p_rxBuf++ = spi_get(WINC1500_SPI);
--rxLen;
}
else
{
spi_get(WINC1500_SPI);
}
}
Debug output log
Disable SPI
Init SPI module as master
Configure SPI and Clock settings
spi_enable(WINC1500_SPI)
InitStateMachine()
INIT_START_STATE
InitStateMachine()
INIT_WAIT_FOR_CHIP_RESET_STATE
m2mStub_PinSet_CE
m2mStub_PinSet_RESET
m2mStub_GetOneMsTimer();
SetChipHardwareResetState (CHIP_HARDWARE_RESET_FIRST_DELAY_1MS)
InitStateMachine()
INIT_WAIT_FOR_CHIP_RESET_STATE
if(m2m_get_elapsed_time(startTime) >= 2)
m2mStub_PinSet_CE(M2M_WIFI_PIN_HIGH)
startTime = m2mStub_GetOneMsTimer();
SetChipHardwareResetState(CHIP_HARDWARE_RESET_SECOND_DELAY_5_MS);
InitStateMachine()
INIT_WAIT_FOR_CHIP_RESET_STATE
m2m_get_elapsed_time(startTime) >= 6
m2mStub_PinSet_RESET(M2M_WIFI_PIN_HIGH)
startTime = m2mStub_GetOneMsTimer();
SetChipHardwareResetState(CHIP_HARDWARE_RESET_FINAL_DELAY);
InitStateMachine()
INIT_WAIT_FOR_CHIP_RESET_STATE
m2m_get_elapsed_time(startTime) >= 10
SetChipHardwareResetState(CHIP_HARDWARE_RESET_COMPLETE)
retVal = true // State machine has completed successfully
g_scanInProgress = false
nm_spi_init();
reg = spi_read_reg(NMI_SPI_PROTOCOL_CONFIG)
Wait for a complete transmission
Wait for transmitter to be ready
SPI_PUT(WINC1500_SPI, *p_txBuf++);
--txLen;
Wait for transfer to finish, stuck on here
Wait for transfer to finish, stuck on here
The ATmega32 is an 8-bit AVR but you seem to be using code for the AVR32, a family of 32-bit AVRs. You're probably just using the totally wrong code and you should consult the datasheet of the ATmega32, and search for SPI for the AVR ATmega family.
I am trying to read data from both the sensor and the gps (one by one is ok). The sensors work well individually but the Ultrasonic sensor does not give any output. I am new to arduino so i just mixed the codes from the two examples using NewPing Library and TinyGPS libraries. Here is the code. Please suggest what additions need to be made to the code to make both devices work together.
/*********************
*10 to GPS Module TX*
*09 to GPS Module RX*
*********************/
// 1.TESTED USING LED
// 2. added ultrasound libraries
#include <NewPing.h>
#define TRIGGER_PIN 5 // Arduino pin tied to trigger pin on the ultrasonic sensor.
#define ECHO_PIN 4 // Arduino pin tied to echo pin on the ultrasonic sensor.
#define MAX_DISTANCE 400 // Maximum distance we want to ping for (in centimeters). Maximum sensor distance is rated at 400-500cm.
NewPing sonar(TRIGGER_PIN, ECHO_PIN, MAX_DISTANCE); // NewPing setup of pins and maximum distance.
#include <SoftwareSerial.h>
#include <TinyGPS.h>
SoftwareSerial mySerial(10, 11);
TinyGPS gps;
float gpsdump(TinyGPS &gps);
void setup()
{
// Oploen serial communications and wait for port to open:
Serial.begin(9600);
// set the data rate for the SoftwareSerial port
mySerial.begin(9600);
delay(1000);
}
void loop() // run over and over
{
bool newdata = false;
unsigned long start = millis();
// Every 5 seconds we print an update
while (millis() - start < 5000)
{
if (mySerial.available())
{
char c = mySerial.read();
//Serial.print(c); // uncomment to see raw GPS data
if (gps.encode(c))
{
newdata = true;
break; // uncomment to print new data immediately!
}
}
}
if (newdata)
{
Serial.println("Acquired Data");
Serial.println("-------------");
gpsdump(gps);
Serial.println("-------------");
Serial.println();
}
}
float gpsdump(TinyGPS &gps)
{
// On Arduino, GPS characters may be lost during lengthy Serial.print()
// On Teensy, Serial prints to USB, which has large output buffering and
// runs very fast, so it's not necessary to worry about missing 4800
// baud GPS characters.
Serial.println("speed");
Serial.println(gps.f_speed_kmph()) ;
Serial.print(sonar.ping_cm());
;
}
The main problems:
You cannot wait 5 seconds without processing the characters. The Arduino receive buffer only has room for 64 characters. The GPS device could have sent 5000 characters during that time, so most of them will get dropped. This prevents the GPS library from ever parsing a complete sentence.
A ping will interfere with software serial ports. You will have to wait for the GPS quiet time to do the ping. Otherwise, the ping process will cause characters to be lost.
Other problems:
You are printing the speed value even though it may not be valid. If you are not moving, or you do not have good satellite reception, the GPS device may not provide a speed.
The Arduino millis() clock will not be synchronized with the GPS clock. You could use the GPS updates as an exact 1-second clock. Simply count 5 fixes as they arrive, and this will mean that 5 seconds have elapsed.
You should use a different serial port and/or library.
This answer describes the various choices: HardwareSerial (i.e. Serial on pins 0 & 1), AltSoftSerial (8 & 9 on an UNO) or NeoSWSerial (any two pins).
Here is a NeoGPS version of your sketch that addresses these issues:
/*********************
*10 to GPS Module TX*
*09 to GPS Module RX*
*********************/
// 1.TESTED USING LED
// 2. added ultrasound libraries
#include <NewPing.h>
#define TRIGGER_PIN 5 // Arduino pin tied to trigger pin on the ultrasonic sensor.
#define ECHO_PIN 4 // Arduino pin tied to echo pin on the ultrasonic sensor.
#define MAX_DISTANCE 400 // Maximum distance we want to ping for (in centimeters). Maximum sensor distance is rated at 400-500cm.
NewPing sonar(TRIGGER_PIN, ECHO_PIN, MAX_DISTANCE); // NewPing setup of pins and maximum distance.
#include <NeoSWSerial.h>
#include <NMEAGPS.h>
NeoSWSerial gpsPort(10, 11);
NMEAGPS gps; // the parser
gps_fix fix; // all the parsed values from GPS
uint8_t fixCount = 0; // a one-second "clock"
float gpsdump();
void setup()
{
// Open serial communications and wait for port to open:
Serial.begin(9600);
// set the data rate for the SoftwareSerial port
gpsPort.begin(9600);
delay(1000);
}
void loop() // run over and over
{
// Check for available GPS characters and parse them
if (gps.available( gpsPort ))
{
// Once per second, a complete fix structure is ready.
fix = gps.read();
fixCount++;
// The GPS device is going to be quiet for a while,
// *now* is a good time to do a ping.
Serial.print( "ping " );
Serial.println( sonar.ping_cm() );
// Every 5 seconds we print an update
if (fixCount >= 5)
{
fixCount = 0; // reset counter
Serial.println("Acquired Data");
Serial.println("-------------");
gpsdump();
Serial.println("-------------");
Serial.println();
}
}
}
float gpsdump()
{
// On Arduino, GPS characters may be lost during lengthy Serial.print()
// On Teensy, Serial prints to USB, which has large output buffering and
// runs very fast, so it's not necessary to worry about missing 4800
// baud GPS characters.
Serial.println("speed ");
if (fix.valid.speed)
Serial.println( fix.speed_kph() );
}
If you want to try it, NeoGPS, AltSoftSerial and NeoSWSerial are available from the IDE Library Manager, under the menu Sketch -> Include Library -> Manage Libraries. NeoGPS is smaller, faster, more reliable and more accurate than all other libraries.
Even if you don't use it, there are many suggestions on the Installation and Troubleshooting pages.
I would like to use an arduino to read 433 MHz transmission from multiple Soil Moisture Sensors. Since I can never be sure all transmissions reach the receiver I'd like to set a countdown from the moment the first transmission is received. If another transmission is received, the countdown starts again.
After a defined amount of time (e.g. 10 Minutes) without any more signals or if all signals have been received (e.g 4 Sensors) the receiving unit should stop and come to decision based on the data it got to the point.
For transmitting and receiving I am using the <RCSwitch.h>library.
The loop of the receiving unit and one Sensor looks like this:
#include <RCSwitch.h>
RCSwitch mySwitch = RCSwitch();
void Setup(){
Serial.begin(9600);
mySwitch.enableReceive(4);
}
void loop() {
if (mySwitch.available()) {
int value = mySwitch.getReceivedValue();
if (value == 0) {
lcd.clear();
Serial.print("Unknown encoding");
}
else {
Serial.print(mySwitch.getReceivedValue());
Serial.print("%");
}
The full code includes some differentiation mechanism for all sensors but I figured that might not be relevant for my question.
Question:
What's the best way to do this without a real time clock module. As far as I know I can't wait by using delay(...)since then I won't receive any data while the processor waiting.
You can use millis() as a clock. It returns the number of milliseconds since the arduino started.
#define MINUTES(x) ((x) * 60000UL)
unsigned long countStart = 0;
void loop()
{
if (/*read from module ok*/)
{
countStart = millis();
// sanity check, since millis() eventually rolls over
if (countStart == 0)
countStart = 1;
}
if (countStart && ((millis() - countStart) > MINUTES(10)))
{
countStart = 0;
// trigger event
}
}
Arduino's internal timers can also be used in this situation. If a long time period is needed, it's better to use 16bit counter (usually timer1) at 1024 prescaler (largest available). If the largest time interval of timer is greater than time required, then a counter have to be added in order to keep track of 1 minute interval.
For example, for 1-minute interval, initialize registers as:
TCCR1A = 0; //Initially setting every register as 0x0000
TCCR1B = 0;
TCNT1 = 0;
OCR1A = 468750; // compare match register 16MHz/1024/2/frequency(hz)
TCCR1B |= (1 << WGM12); // Timer compare mode
TCCR1B |= (1 << CS10) | (1 << CS10); // 1024 prescaler
TIMSK1 |= (1 << OCIE1A); // enable timer compare interrupt
These configuration of timer will give interrupt time of 1 minute. And upon timer completion ISR TIMER1_COMPA_vect will be run. You can play around with value of OCR1A for different interrupt periods.
Main advantage of using interrupts is that they don't block any task and can will be executed instantaneously (if interrupts are not disabled explicitly).
I am using the Time.h and TimeAlarms.h libraries in Arduino. I try to call a function on specific times of the day (every day). The function is called on the first day, but then on the next day it seems like the alarm ceases to work, although it should repeat every day. Any ideas what's wrong with my sketch?
#include <Time.h>
#include <TimeAlarms.h>
#define TIME_MSG_LEN 11 // time sync to PC is HEADER followed by Unix time_t as ten ASCII digits
#define TIME_HEADER 'T' // Header tag for serial time sync message
#define TIME_REQUEST 7 // ASCII bell character requests a time sync message
// The constant variables used in the code:
const unsigned long shock_delay = 10; // shock stimulus duration (s)
// Edit below only if you make changes to the hardware configuration:
const int tonePin = 13; // the number of the LED pin
const int shockPin = 12; // the number of the shocker pin
const int buzzerOut = 8; // the number of the tone producer
const int trialButton=2; // the number of the trial button
const int controlButton=3; // the number of the control button
// Define the variables that will change in the code
unsigned int Interval1; // the interval between the beginning of the hour and the first footshock
unsigned int Interval2; // the interval between the first and the second footshock
void setup()
{
Serial.begin(9600); // opens serial port, sets data rate to 9600 bps
setTime(23,59,50,10,4,15); // The current time (HH,MM,SS,DD,MM,YY)
// Define the position of the different digital pins
pinMode(tonePin, OUTPUT); // The tone LED (red)
pinMode(shockPin, OUTPUT); // The shock output, which will coincide with green LED
pinMode(trialButton, INPUT); // The trial input button
pinMode(controlButton, INPUT); // The control input button
Alarm.alarmRepeat(20,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(21,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(22,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(23,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(0,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(1,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(2,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(3,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(4,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(5,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(6,00,0,RandomShock); // Initiate the user defined RandomShock function
Alarm.alarmRepeat(7,00,0,RandomShock); // Initiate the user defined RandomShock function
}
void loop(){
// Create a message that gives the current time and date on the monitor
if(Serial.available() )
{
processSyncMessage();
}
if(timeStatus() == timeNotSet)
Serial.println("waiting for sync message");
else
digitalClockDisplay(); // The function that calls on the time display
Alarm.delay(1000); // Delay of 1 minute between time display
}
void digitalClockDisplay(){
// digital clock display of the time
Serial.print(hour());
printDigits(minute());
printDigits(second());
Serial.print(" ");
Serial.print(day());
Serial.print(" ");
Serial.print(month());
Serial.print(" ");
Serial.print(year());
Serial.println();
}
void printDigits(int digits){
// utility function for digital clock display: prints preceding colon and leading 0
Serial.print(":");
if(digits < 10)
Serial.print('0');
Serial.print(digits);
}
void processSyncMessage() {
// if time sync available from serial port, update time and return true
while(Serial.available() >= TIME_MSG_LEN ){ // time message consists of header & 10 ASCII digits
char c = Serial.read() ;
Serial.print(c);
if( c == TIME_HEADER ) {
time_t pctime = 0;
for(int i=0; i < TIME_MSG_LEN -1; i++){
c = Serial.read();
if( c >= '0' && c <= '9'){
pctime = (10 * pctime) + (c - '0') ; // convert digits to a number
}
}
setTime(pctime); // Sync Arduino clock to the time received on the serial port
}
}
}
void RandomShock () {
Interval1 = random(0,60); // Random value between 0 and 59 [min]
digitalWrite(tonePin,HIGH); // Indicate the shock program is ON by the red LED
Alarm.delay(Interval1*60000); // Wait for the duration of the first interval
digitalWrite(tonePin,LOW); // Turn the red LED OFF
digitalWrite(shockPin, HIGH); // Apply the first shock (green LED will turn ON)
Serial.println("Applying an electeric shock at:"); // Write a message indicating a shock is applied
digitalClockDisplay(); // Display the time during which the shock was applied
Alarm.delay(shock_delay*1000); // The duration of the shock [10 seconds]
digitalWrite(shockPin, LOW); // Terminate the first shock (green LED will turn OFF)
Interval2 = random(0,(61-Interval1)); // Randomly asign a value to the second interval [min]
digitalWrite(tonePin,HIGH); // Indicate the shock program is ON by the red LED
Alarm.delay(Interval2*60000-20000); // Wait for the duration of the second interval
digitalWrite(tonePin,LOW); // Turn the red LED OFF
digitalWrite(shockPin,HIGH); // Apply the second shock (green LED will turn ON)
Serial.println("Applying an electeric shock at:"); // Write a message indicating a shock is applied
digitalClockDisplay(); // Display the time during which the shock was applied
Alarm.delay(shock_delay*1000); // The duration of the shock [10 seconds]
digitalWrite(shockPin,LOW); // Terminate the second shock
digitalWrite(tonePin,HIGH); // Indicate the shock program is ON by the red LED
Alarm.delay((60-Interval1-Interval2)*60000); // Wait until the hour is completed
digitalWrite(tonePin,LOW); // Turn the red LED OFF
}
There are two problems with the sketch that I wrote:
Alarm.alarmRepeat function does not seem to be able to call my
function exactly at midnight (00:00:00), however, if I schedule it
to any other time (e.g., 00:00:01) it works just fine.
There is a limit to the number of alarms you can schedule: the
maximum number of alarms is 6. The solution is either to change this threshold, or to reduce the number of alarms.
After correcting for these two issues the sketch work smoothly.
Seems that TimeAlarm library is unable to set an alarm to midnight
https://github.com/PaulStoffregen/TimeAlarms/issues/3
Try this pull request https://github.com/PaulStoffregen/TimeAlarms/pull/4
If you need more than 6 alarms just look for that at TimeAlarms.h on the library:
#if defined(__AVR__)
#define dtNBR_ALARMS 6 // max is 255
#else
#define dtNBR_ALARMS 12 // assume non-AVR has more memory
#endif
and change it to your need (example:24)
#if defined(__AVR__)
#define dtNBR_ALARMS 24 // max is 255
#else
#define dtNBR_ALARMS 12 // assume non-AVR has more memory
#endif