Flying Sea Glider
most functionality to splashdwon, find neutral and start mission. short timeouts still in code for testing, will adjust to go directly to sit_idle after splashdown
Dependencies: mbed MODSERIAL FATFileSystem
main.cpp
- Committer:
- tnhnrl
- Date:
- 2018-07-30
- Revision:
- 73:f6f378311c8d
- Parent:
- 72:250b2665755c
- Child:
- 74:d281aaef9766
File content as of revision 73:f6f378311c8d:
#include "mbed.h"
#include "StaticDefs.hpp"
#ifndef lround
#define lround(var) (long)(var+0.5f)
#endif
////////////////////////////////////////////////////////////////// NEW TICKER
Ticker systemTicker;
bool setup_complete = false;
volatile unsigned int bTick = 0;
volatile unsigned int timer_counter = 0;
static unsigned int read_ticker(void) { //Basically this makes sure you're reading the data at one instance (not while it's changing)
unsigned int val = bTick;
if( val )
bTick = 0;
return( val );
}
////////////////////////////////////////////////////////////////// NEW TICKER
// loop rate used to determine how fast events trigger in the while loop
//Ticker main_loop_rate_ticker;
//Ticker log_loop_rate_ticker;
volatile bool fsm_loop = false; //used so the compiler does not optimize this variable (load from memory, do not assume state of variable)
volatile bool log_loop = false; //used so the compiler does not optimize this variable (load from memory, do not assume state of variable)
void loop_trigger() { fsm_loop = true;} // loop trigger (used in while loop)
void log_loop_trigger() { log_loop = true;} // log loop trigger (used in while loop)
static int current_state = 0;
static bool file_opened = false;
void FSM() { // FSM loop runs at 10 hz
if(fsm_loop) {
// led one removed
fsm_loop = false; // wait until the loop rate timer fires again
current_state = stateMachine().runStateMachine(); //running State Machine. Returns 0 if sitting idle or keyboard press (SIT_IDLE state).
}
}
void log_function() {
// log loop runs at 1 hz
if (log_loop) {
//when the state machine is not in SIT_IDLE state (or a random keyboard press)
//if (current_state == TRANSMIT_MBED_LOG or current_state == RECEIVE_SEQUENCE) {
// ; //pass
// }
if(current_state != 0) {
if (!file_opened) { //if the log file is not open, open it
mbedLogger().appendLogFile(current_state, 0); //open MBED file once
//sdLogger().appendLogFile(current_state, 0); //open SD file once
file_opened = true; //stops it from continuing to open it
pc().printf(">>>>>>>> Recording. Log file opened. <<<<<<<<\n\r");
}
//record to Mbed file system
mbedLogger().appendLogFile(current_state, 1); //writing data
//sdLogger().appendLogFile(current_state, 1); //writing data
}
//when the current FSM state is zero (SIT_IDLE), close the file
else {
//this can only happen once
if (file_opened) {
//WRITE ONCE
mbedLogger().appendLogFile(current_state, 1); //write the idle state, then close
mbedLogger().appendLogFile(current_state, 0); //close log file
//sdLogger().appendLogFile(current_state, 0); //close log file
file_opened = false;
pc().printf(">>>>>>>> Stopped recording. Log file closed. <<<<<<<<\n\r");
}
}
} //END OF LOG LOOP
log_loop = false; // wait until the loop rate timer fires again
}
//single system timer to run hardware/electronics timing
static void system_timer(void) {
bTick = 1;
timer_counter++;
//only start these updates when everything is properly setup (through setup function)
if (setup_complete) {
if ( (timer_counter % 1) == 0) { //this runs at 0.001 second intervals (1000 Hz)
adc().update(); //every iteration of this the A/D converter runs //now this runs at 0.01 second intervals 03/12/2018
}
if ( (timer_counter % 10) == 0) {
bce().update(); //update() inside LinearActuator class (running at 0.01 second intervals)
batt().update();
}
if ( (timer_counter % 20) == 0 ) { // 0.02 second intervals
//rudder().runServo();
}
if ( (timer_counter % 50) == 0 ) { // 0.05 second intervals
imu().runIMU();
}
if ( (timer_counter % 100) == 0) { // 100,000 microseconds = 0.1 second intervals
depthLoop().runOuterLoop();
pitchLoop().runOuterLoop();
headingLoop().runOuterLoop();
}
if ( (timer_counter % 1000) == 0) { // update at 1.0 second intervals
//gui().updateGUI();
}
}
}
void setup() {
pc().baud(57600);
pc().printf("\n\n\r FSG PCB Bench Test version 1.7C)\n\n\r");
// start up the system timer
//systemTimer().start();
// set up and start the adc. This runs on a fixed interval and is interrupt driven
adc().initialize();
//one central interrupt is updating the ADC (not using the start function)
// setup and run the rudder(servo) pwm signal (start the ticker)
//rudder().init();
pc().printf("Rudder servo initialized!\n\r");
// set up and start the imu. This polls in the background
imu().initialize();
//imu().start();
// construct the MBED local file system
local();
// construct the SD card file system
//sd_card();
// load config data from files
configFileIO().load_BCE_config(); // load the buoyancy engine parameters from the file "bce.txt"
configFileIO().load_BATT_config(); // load the battery mass mover parameters from the file "batt.txt"
configFileIO().load_DEPTH_config(); // load the depth control loop parameters from the file "depth.txt" (contains neutral position)
configFileIO().load_PITCH_config(); // load the depth control loop parameters from the file "pitch.txt" (contains neutral position)
configFileIO().load_RUDDER_config(); // load the rudder servo inner loop parameters from the file "SERVO.txt"
configFileIO().load_HEADING_config(); // load the rudder servo outer loop HEADING control parameters from the file "HEADING.txt" (contains neutral position)
// set up the linear actuators. adc has to be running first.
bce().setPIDHighLimit(bce().getTravelLimit()); //travel limit of this linear actuator
bce().init();
//bce().start(); //removed start, it's handled by the interrupt
bce().runLinearActuator();
bce().pause(); // start by not moving
batt().setPIDHighLimit(batt().getTravelLimit()); //travel limit of this linear actuator
batt().init();
batt().runLinearActuator(); // _init = true;
//batt().start();//removed start, it's handled by the interrupt
batt().pause(); // start by not moving
// set up the depth, pitch, and rudder outer loop controllers
depthLoop().init();
//removed start, it's handled by the interrupt
depthLoop().setCommand(stateMachine().getDepthCommand());
pitchLoop().init();
//removed start, it's handled by the interrupt
pitchLoop().setCommand(stateMachine().getPitchCommand());
headingLoop().init();
//removed start, it's handled by the interrupt
//headingLoop().setCommand(stateMachine().getHeadingCommand()); // FIX LATER
//heading flag that adjust the PID error is set in the constructor
//systemTicker.attach_us(&system_timer, 10000); // Interrupt timer running at 0.01 seconds (slower than original ADC time interval)
// show that the PID gains are loading from the file
pc().printf("bce P:%6.2f, I:%6.2f, D:%6.2f, zero %3i, limit %6.1f mm, slope %0.5f \r\n", bce().getControllerP(), bce().getControllerI(), bce().getControllerD(), bce().getZeroCounts(), bce().getTravelLimit(), bce().getPotSlope());
pc().printf("batt P:%6.2f, I:%6.2f, D:%6.2f, zero %3i, limit %6.1f mm, slope %0.5f \r\n", batt().getControllerP(), batt().getControllerI(), batt().getControllerD(), batt().getZeroCounts(), batt().getTravelLimit(), batt().getPotSlope());
pc().printf("rudder min pwm: %6.2f, max pwm: %6.2f, center pwm: %6.2f, min deg: %6.2f, max deg: %6.2f\r\n", rudder().getMinPWM(), rudder().getMaxPWM(), rudder().getCenterPWM(), rudder().getMinDeg(), rudder().getMaxDeg());
pc().printf("depth P:%6.2f, I:%6.2f, D:%6.2f, offset:%6.1f mm \r\n", depthLoop().getControllerP(), depthLoop().getControllerI(), depthLoop().getControllerD(), depthLoop().getOutputOffset());
pc().printf("pitch P:%6.2f, I:%6.2f, D:%6.2f, offset:%6.1f mm \r\n", pitchLoop().getControllerP(), pitchLoop().getControllerI(), pitchLoop().getControllerD(), pitchLoop().getOutputOffset());
pc().printf("heading P: %3.2f, I: %3.2f, D %3.2f, offset: %3.1f deg (deadband: %0.1f)\r\n", headingLoop().getControllerP(), headingLoop().getControllerI(), headingLoop().getControllerD(), headingLoop().getOutputOffset(), headingLoop().getDeadband());
pc().printf("\n\r");
//load sequence from file
sequenceController().loadSequence();
//set time of logger (to current or close-to-current time)
mbedLogger().setLogTime();
//sdLogger().setLogTime();
//create log files if not present on file system
mbedLogger().initializeLogFile();
//sdLogger().initializeLogFile();
setup_complete = true;
}
/*************************** v1.8 **************************/
int main() {
setup(); //setup electronics/hardware
systemTicker.attach_us(&system_timer, 1000); // Interrupt timer running at 0.001 seconds (slower than original ADC time interval)
unsigned int tNow = 0;
//pc().baud(57600);
pc().printf("\n\n\r FSG PCB v1.8 (XBee) 07/12/2018 \n\n\r");
systemTicker.attach_us(&system_timer, 1000); // Interrupt timer running at 0.001 seconds (slower than original ADC time interval)
while (1) {
if( read_ticker() ) // read_ticker runs at the speed of 10 kHz (adc timing)
{
++tNow;
//run finite state machine fast when transmitting data
if (current_state == TX_MBED_LOG or current_state == RECEIVE_SEQUENCE) {
if ( (tNow % 100) == 0 ) { // 0.01 second intervals (100 Hz)
fsm_loop = true;
FSM();
}
}
//NOT TRANSMITTING DATA, NORMAL OPERATIONS
else {
//FSM
if ( (tNow % 100) == 0 ) { // 0.1 second intervals
fsm_loop = true;
FSM();
//get commands and update GUI
gui().getCommandFSM();
}
//LOGGING
if ( (tNow % 1000) == 0 ) { // 1.0 second intervals
log_loop = true;
log_function();
}
}
}
}
}