FSG
/
7_21_17_FSG
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Dependencies: BCEmotor Battery_Linear_Actuator Controller_ IMU_code_ LTC1298_7_14 MODSERIAL PosVelFilter_7_14 System mbed
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7_20_17_FSG_
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FSG
main.cpp
- Committer:
- tnhnrl
- Date:
- 2017-07-17
- Revision:
- 5:7421776f6b08
- Parent:
- 4:3c22d85a94a8
- Child:
- 6:ce2cf7f4d7d5
File content as of revision 5:7421776f6b08:
#include "mbed.h"
#include "MODSERIAL.h" //for IMU (and got rid of regular serial library) #include "IMU_code.h"
#include "StaticDefs.hpp"
#include "ltc1298.hpp"
#include <cstdlib>
#include <string>
using namespace std;
bool debug_mode = false;
#include "IMU_code.h" //IMU code
#include "Battery_Linear_Actuator.h" //Battery Linear Actuator code (TROY) (FIX INCLUSION ISSUES, ports)
Serial PC(USBTX,USBRX); //tx, rx
extern "C" void mbed_reset(); //utilized to reset the mbed through the serial terminal
char Key;
string IMU_STRING = "";
DigitalOut led1(LED1);
DigitalOut led2(LED2);
DigitalOut led3(LED3);
DigitalOut led4(LED4);
AnalogIn pressure_analog_in(A5); //Initialize pin20 (read is float value)
AnalogIn ain(p18);
/* ************ These tickers work independent of any while loops ********** */
Ticker IMU_ticker; //ticker for printing IMU //https://developer.mbed.org/handbook/Ticker
Ticker BE_position_ticker; //probably delete soon
Ticker PRESSURE_ticker;
Ticker BCE_ticker; //new 6/5/17
Ticker PID_ticker; //new 6/14/17
Ticker LA_ticker; //new 6/22/17
float positionCmd = 200.0; //250
/* ************************************************************************* */
float pi = 3.14159265359;
/* PID LOOP STUFF */
float la_setPoint = 0.00; //the IMU pitch angle we want (setpoint)
float la_P_gain = 1.0;
float la_I_gain = 0.00;
float la_D_gain = 0.00;
/* PID LOOP STUFF */
float IMU_pitch_angle = 0.00;
bool motor_retracting = false;
bool motor_extending = false;
// 7/10/17
string actual_position_string = "";
double double_actual_position = 0.00;
void IMU_ticking()
{
led1 = !led1; //flash the IMU LED
if (debug_mode)
PC.printf("%s\n", IMU_STRING.c_str()); //if there's something there, print it
}
void PRESSURE_ticking()
{
if (debug_mode)
PC.printf("ressure: %f psi \r", (0.00122*(adc().ch1_filt)*14.931)-0.0845); //read the analog pin
//this voltage has been checked and scaled properly (6/28/2017)
}
void BCE_ticking() //new 6/5/17
{
if (debug_mode)
PC.printf("Buoyancy_Engine_POS: %3.0f mm BE_vel: %2.2f mm/s Set Point %3.0f posCon.getOutput: % 1.3f \n", pvf().getPosition(), pvf().getVelocity(), positionCmd, posCon().getOutput());
//PC.printf("BE_pos: %3.0f mm BE_vel: %2.2f mm/s Set Point %3.0f controller output: % 1.3f \n", pvf().getPosition(), pvf().getVelocity(), positionCmd, posCon().getOutput());
}
int main()
{
PC.baud(9600); //mbed to PC serial connection speed
//PC.baud(230400);
//got screwy when i changed it
hBridge().stop();
PC.printf("* * * * * * * * * * * * * * * * *\n");
PC.printf("PV TEST PROGRAM STARTED 7/13/2017\n");
PC.printf("* * * * * * * * * * * * * * * * *\n");
systemTime().start(); //start the timer, needed for PID loop
/* **************** Linear Actuator MOTOR CONTROLLER **************** */
Battery_Linear_Actuator BLA_object; //create the IMU object from the imported class
PC.printf("%s\n", BLA_object.Keyboard_U().c_str()); //velocity = 0, motor disabled
PC.printf("%s\n", BLA_object.Keyboard_Q().c_str()); //turn off motor
wait(1);
PC.printf("%s\n", BLA_object.Keyboard_E().c_str()); //turn on motor
wait(1);
//setup and start the adc. This runs on a fixed interval and is interrupt driven
adc().initialize();
adc().start();
//Initialize the position velocity filter. This will consume a couple of seconds for
//the filter to converge
pvf().init();
////CHANGED TO GLOBAL VARIABLES
float motor_cmd = 0.0;
// float positionCmd = 250.0;
float P = 0.10;
float I = 0.00;
float D = 0.00;
float count = 0.0;
//char userInput; //from Trent's code?
float la_step = 1.0;
float la_setPoint_temp = 0.0;
//Start off in manual mode for testing.
bool BCE_auto = false;
bool LA_auto = false;
float bce_auto_step_raw = 1.0;
float bce_auto_step_l;
//float convert = 10000;
float convert = 1;
float bce_auto_step_ml = bce_auto_step_raw * convert;
int bce_manual_step = 10;
//float volume_bce = 90.0*convert; //Troy: Not sure I get the conversion
float volume_bce = 0;
float positionCmd_temp;
//float ml_to_l= 0.000000001; //Is this a milliliter? TROY: 7/10/17
float ml_to_l= 0.001; //milliliter???? TROY: 7/10/17
hBridge().run(motor_cmd);
//set the intial gains for the position controller
posCon().setPgain(P);
posCon().setIgain(I);
posCon().setDgain(D);
posCon().writeSetPoint(positionCmd); //7/13/17 initialize the position of the motor to 200
PC.printf("BCE Test Program Started!\n");
wait(1);
/* *************************** LED *************************** */
led1 = 1; //initial values
led2 = 1;
led3 = 0;
led4 = 1;
/* *************************** LED *************************** */
int la_cases = 0;
int count_while = 0;
//hBridge().reset();
PC.printf("\n```````````Linear Actuator in IMU controlled mode````````````\n\n");
//PC.printf("Hit shift + \"H\" to home the battery Linear Actuator\n");
/* ************************** Pressure Sensor ************************** */
PRESSURE_ticker.attach(&PRESSURE_ticking, 3.0);
/* ************************** Pressure Sensor ************************** */
/* *************************** MOTOR CONTROLLER *************************** */
//Battery_Linear_Actuator BLA_object; //create the IMU object from the imported class
/* *************************** MOTOR CONTROLLER *************************** */
/* *************************** IMU *************************** */
IMU_code IMU_object; //create the IMU object from the imported class
IMU_ticker.attach(&IMU_ticking, 3.0);
/* *************************** IMU *************************** */
/* *************************** BCE *************************** */
//float previous_positionCmd = -1;
//BCE_ticker.attach(&BCE_ticking, 3.0);
/* *************************** BCE *************************** */
while(1)
{
//PC.printf("DEBUG: POT position: %f velocity: %f adc_count: %d VS conv_distance: %f adc_ch0_filter: %f\n ", pvf().getPosition(), pvf().getVelocity(), adc().ch0_filt, pvf().getVelocity(), adc().get_ch0_filt); //DEBUG TROY
if (debug_mode)
{
PC.printf("DEBUG: POT position: %6.3f velocity: %6.3f adc_count: %d VS conv_distance: %6.3f adc_ch0_filter: %6.3f\n", pvf().getPosition(), pvf().getVelocity(), adc().ch0_filt, pvf().get_conv_distance(), adc().get_ch0_filt()); //DEBUG TROY
PC.printf("DEBUG: dt: %f current_time: %f last_time: %f\n", pvf().getDt(), pvf().get_curr_time(), pvf().get_last_time()); //DEBUG TROY
PC.printf("DEBUG: x1: %f x2: %f x1_dot: %f x2_dot: %f\n", pvf().get_x1(), pvf().get_x2(), pvf().get_x1_dot(), pvf().get_x2_dot()); //DEBUG TROY
}
/* *************************** IMU *************************** */
IMU_STRING = IMU_object.IMU_run(); //grab the IMU string each iteration through the loop
IMU_pitch_angle = 1.0 * IMU_object.IMU_pitch(); //get the pitch update constantly?
if (debug_mode)
PC.printf("pitch angle... %f set pitch angle: %f\n", IMU_pitch_angle, la_setPoint);
/* *************************** IMU *************************** */
/* Buoyancy Engine */
// update the position velocity filter
pvf().update();
//update the controller with the current numbers in the position guesser
posCon().update(pvf().getPosition(), pvf().getVelocity(), pvf().getDt()) ;
hBridge().run(posCon().getOutput());
/* Buoyancy Engine */
//FOR DEBUGGING
//PC.printf("BE_pos: %3.0f mm BE_vel: %2.2f mm/s Set Point %3.0f controller output: % 1.3f P: %1.3f I: %1.4f D: %1.4f\r", pvf().getPosition(), pvf().getVelocity(), positionCmd, posCon().getOutput(), P, I, D);
if (PC.readable())
{
led4 = !led4; //read indicator changes
Key=PC.getc();
//Universal MBED Controls
if(Key == '!') //RESET THE MBED
{
PC.printf("MBED RESET KEY (!) PRESSED\n");
PC.printf("Linear Actuator Motor disabled!\n");
//disable the motor
BLA_object.Keyboard_Q(); //DISABLE THE MOTOR
wait(0.5); //500 milliseconds
mbed_reset(); //reset the mbed!
}
else if(Key == '~') // (shift + '`')
{
debug_mode = !debug_mode; //shift it back and forth
PC.printf(" # # # # # # DEBUG MODE: %d # # # # # # \n", debug_mode);
}
else if(Key == 'H') //homing sequence
{
PC.printf("### homing the device ###");
BLA_object.Keyboard_H();
wait(5); //for debugging
////TEST THIS
//PC.printf("BE_pos: 0\n");
//PC.printf("### position is %d ###\n", BLA_object.get_pos().c_str()); //flip this back and forth
//TROY: TEST THIS 7/11/2017
const char *char_actual_position = BLA_object.get_pos().c_str();
//actual_position_string = BLA_object.get_pos().c_str();
sscanf(char_actual_position, "%lf", &double_actual_position);
// 7/10/17
PC.printf("### position is\nBEP: %lf ###\n", double_actual_position);
wait(1); //for debugging
}
else if(Key == 'p' or Key == 'P')
{
// 7/10/17
//actual_position_string = BLA_object.get_pos();
//actual_position_string = BLA_object.get_pos().c_str();
//const char *char_actual_position = string_actual_position.c_str();
const char *char_actual_position = BLA_object.get_pos().c_str();
//actual_position_string = BLA_object.get_pos().c_str();
sscanf(char_actual_position, "%lf", &double_actual_position);
// 7/10/17
PC.printf("### position is\nBEP: %lf ###\n", double_actual_position); //flip this back and forth
wait(1); //for debugging
// "-999999" means it is not working
}
//Buoyancy Engine Controls
else if (Key == ',' or Key == '<')
{
if (BCE_auto == false)
{
PC.printf("BCE: Now in Automatic Mode\n");
BCE_auto = true;
}
else
{
PC.printf("BCE: Still in Automatic Mode\n");
}
}
else if (Key == '.' or Key == '>')
{
if (BCE_auto == true)
{
PC.printf("BCE: Now in Manual Mode\n");
BCE_auto = false;
}
else
{
PC.printf("BCE: Still in Manual Mode\n");
}
}
//BCE Automatic Controls
else if (Key == 's' or Key == 'S')
{
if (BCE_auto == true)
{
//PC.printf("BCE Automatic Step Size Change\n");
if (bce_auto_step_raw == 1.0)
{
bce_auto_step_raw = 5.0;
}
else if (bce_auto_step_raw == 5.0)
{
bce_auto_step_raw = 10.0;
}
else if (bce_auto_step_raw == 10.0)
{
bce_auto_step_raw = 50.0;
}
else if (bce_auto_step_raw == 50.0)
{
bce_auto_step_raw = 100.0;
}
else if (bce_auto_step_raw == 100.0)
{
bce_auto_step_raw = 1.0;
}
bce_auto_step_ml = bce_auto_step_raw * convert;
PC.printf("BCE Auto Step Size Now\n BE_ST_ML: %7.0f milliliters\n", bce_auto_step_ml);
}
else
{
PC.printf("ERROR: In BCE Manual Mode, this is a auto command\n");
}
}
else if(Key == 'd' or Key == 'D') //0 mm = 0 mL, 350 mm = 1816 mL
{
PC.printf("(d) volume_bce: %f\n", volume_bce);
if (BCE_auto == true)
{
PC.printf("(d) BCE_auto: %d\n", BCE_auto);
if (volume_bce >= 1) //350 mm retracted from end = 1816 mL in buyoancy engine tube
{
volume_bce -= bce_auto_step_ml;
float calc_height = (volume_bce * 1000) / (pi*40.64*40.64);
PC.printf("Buoyancy Engine Volume VBE: %1.5f milliliters (Distance: %f mm)\n", volume_bce, calc_height); //to read in MATLAB
}
else if (volume_bce < 1)
{
PC.printf("Volume reset to 1 mL!\n"); //keep the volume at zero mL
volume_bce = 1;
}
}
else
{
PC.printf("ERROR: In BCE Manual Mode, this is a auto command\n");
}
}
else if(Key == 'f' or Key == 'F')
{
PC.printf("(f) volume_bce: %f\n", volume_bce);
if (BCE_auto == true)
{
PC.printf("(f) BCE_auto: %d\n", BCE_auto);
if (volume_bce <= 1816) //350 mm retracted from end = 1816 mL in buyoancy engine tube
{
volume_bce += bce_auto_step_ml;
float calc_height = (volume_bce * 1000) / (pi*40.64*40.64);
PC.printf("Buoyancy Engine Volume VBE: %1.5f milliliters (Distance: %f mm)\n", volume_bce, calc_height); //to read in MATLAB
}
else if (volume_bce > 1816)
{
PC.printf("Volume reset to 1816 mL (max volume)!\n"); //keep the volume at 1816 mL (max)
volume_bce = 1816;
}
}
else
{
PC.printf("ERROR: In BCE Manual Mode, this is a auto command\n");
}
}
else if(Key == 'r' or Key == 'R')
{
if (BCE_auto == true)
{
PC.printf("\nR received!\n");
//Troy equation (volume 1 mL = 1000 mm^3)
positionCmd = (volume_bce * 1000) / (pi*40.64*40.64); //volume / (pi * r^2)
PC.printf("\nBCE volume sent was %d mL (distance: %f mm)\n", volume_bce, positionCmd);
PC.printf("(BCE Distance) VBE_SENT: %3.0f\n", positionCmd);
posCon().writeSetPoint(positionCmd); //write the setPoint (target)
hBridge().run(posCon().getOutput()); //run the h-bridge until it reaches the target
hBridge().reset(); //reset to start this process of moving the h-bridge
count = 0; //not sure...
}
else
{
PC.printf("ERROR: In BCE Manual Mode, this is a auto command\n");
}
}
//BCE Manual Controls
else if (Key == '2' or Key == '@')
{
if (BCE_auto == false)
{
PC.printf("BCE Manual Step Size Change\n");
if (bce_manual_step == 1)
{
bce_manual_step = 10;
}
else if (bce_manual_step == 10)
{
bce_manual_step = 25;
}
else if (bce_manual_step == 25)
{
bce_manual_step = 50;
}
else if (bce_manual_step == 50)
{
bce_manual_step = 1;
}
PC.printf("BCE Manual Step Size Now\nBEM_ST: %d\n", bce_manual_step);
}
else
{
PC.printf("ERROR: BCE in Auto Mode, this is a manual command\n");
}
}
else if (Key == 'z' or Key == 'Z')
{
if (BCE_auto == false)
{
positionCmd -= bce_manual_step;
//PC.printf(">>> BEM_P: %3.0f\n", positionCmd); //to read in MATLAB (DEBUG)
//decrement the duty cycle
if (positionCmd >= 50 && positionCmd <=350) //limit buoyancy engine position 25 to 375
{
PC.printf("Commanded BCE position is BEM_P: %3.0f\n", positionCmd); //to read in MATLAB
}
else if (positionCmd < 50)
{
PC.printf("BCE past limits! Reset to 50\n"); //to read in MATLAB
positionCmd = 50;
}
}
else
{
PC.printf("ERROR: BCE in Auto Mode, this is a manual command\n");
}
}
else if (Key == 'l' or Key == 'L')
PC.printf("DEBUG: String position? %f velocity? %f (BCE active: %d)\n", pvf().getPosition(), pvf().getVelocity(),posCon().getOutput()); //DEBUG TROY
else if (Key == 'x' or Key == 'X')
{
if (BCE_auto == false)
{
positionCmd += bce_manual_step;
//PC.printf(">>> BEM_P: %3.0f\n", positionCmd); //to read in MATLAB (DEBUG)
//decrement the duty cycle
if (positionCmd >= 50 && positionCmd <=350) //limit buoyancy engine position 25 to 375
{
PC.printf("Commanded BCE position is BEM_P: %3.0f\n", positionCmd); //to read in MATLAB
}
else if (positionCmd >350)
{
PC.printf("BCE past limits! Reset to 350\n"); //to read in MATLAB
positionCmd = 350;
}
}
else
{
PC.printf("ERROR: In BCE Auto Mode, this is a manual command\n");
}
}
else if(Key == 'w' or Key == 'W')
{
if (BCE_auto == false)
{
PC.printf("\nW received!\n");
PC.printf("BEM_SND: %3.0f\n", positionCmd);
posCon().writeSetPoint(positionCmd); //writing once doesn't work sometimes
//posCon().setPgain(P);
//posCon().setIgain(I);
//posCon().setDgain(D);
hBridge().run(posCon().getOutput());
hBridge().reset();
count = 0;
}
else
{
PC.printf("ERROR: In BCE Auto Mode, this is a manual command\n");
}
}
//Linear Actuator Controls
else if(Key == 'c' or Key == 'C')
{
if (LA_auto == true)
{
PC.printf("ERROR: LA already in auto mode\n");
}
else
{
LA_auto = true;
PC.printf("```````````LA now in IMU (Auto) Controlled Mode```````````````\n");
la_cases = 0;
count_while = 0;
}
}
else if (Key == 'v' or Key == 'V')
{
if (LA_auto == true)
{
LA_auto = false;
//Change cases: go from imu controlled to manual
PC.printf("```````````LA now in Manual Mode````````````````````\n");
la_cases = 1;
count_while = 0;
}
else
{
PC.printf("ERROR: LA already in manual mode\n");
PC.printf("LA_auto ==> %d\n", LA_auto); //should show "0" (false)
}
}
else if (Key == '0' or Key == ')')
{
if (LA_auto == true)
{
PC.printf(") recieved\n");
if (la_step == 0.5)
{
la_step = 1.0;
}
else if (la_step == 1.0)
{
la_step = 5.0;
}
else if (la_step == 5.0)
{
la_step = 10.0;
}
else if (la_step == 10.0)
{
la_step = 15.0;
}
else if (la_step == 15.0)
{
la_step = 0.5;
}
PC.printf("LA Step Size Now\nLA_ST_SZ: %f\n", la_step);
}
else
{
PC.printf("ERROR: LA in manual mode!\n");
}
}
else if (Key == '-' or Key == '_')
{
if (LA_auto == true)
{
la_setPoint_temp -= la_step; //IMU_pitch_angle -= 1.0;
PC.printf("- recieved\n");
PC.printf("LA auto step size: %f\n", la_step);
PC.printf("LA angle changed to\nLA_ANG: %f\n", la_setPoint_temp);
}
else
{
PC.printf("ERROR: LA in manual mode!\n");
}
}
else if (Key == '=' or Key == '+')
{
if (LA_auto == true)
{
la_setPoint_temp += la_step; //IMU_pitch_angle += 1.0;
PC.printf("+ recieved\n");
PC.printf("LA auto step size: %f\n", la_step);
PC.printf("LA angle changed to\nLA_ANG: %f\n", la_setPoint_temp);
}
else
{
PC.printf("ERROR: LA in manual mode!\n");
}
}
else if (Key == 'A' or Key == 'a')
{
if (LA_auto == true)
{
PC.printf("A recieved\n");
la_setPoint=la_setPoint_temp;
PC.printf("LA angle now set to\nLA_A_SND: %f\n", la_setPoint);
}
else
{
PC.printf("ERROR: LA in manual mode!\n");
}
}
else if (Key == '[' or Key == '{')
{
la_P_gain -= 0.1;
PC.printf("[ key pressed\n");
PC.printf("P gain is now %f\n", la_P_gain);
}
else if (Key == ']' or Key == '}')
{
la_P_gain += 0.1;
PC.printf("] key pressed\n");
PC.printf("P gain is now %f\n", la_P_gain);
}
else if (Key == ';')
{
la_I_gain -= 0.1;
PC.printf("; key pressed\n");
PC.printf("I gain is now %f\n", la_I_gain);
}
else if (Key == '\'')
{
la_I_gain += 0.1;
PC.printf("\\ key pressed\n");
PC.printf("I gain is now %f\n", la_I_gain);
}
else if (Key == '.')
{
la_D_gain -= 0.1;
PC.printf(". key pressed\n");
PC.printf("D gain is now %f\n", la_D_gain);
}
else if (Key == '/')
{
la_D_gain += 0.1;
PC.printf("/ key pressed\n");
PC.printf("D gain is now %f\n", la_D_gain);
}
else if(Key == 'n' or Key == 'N')
{
if (LA_auto == false)
{
PC.printf("N key pressed. \n");
PC.printf("%s\n", BLA_object.Keyboard_DASH_KEY());
}
else
{
PC.printf("ERROR: In LA in Auto Mode, this is a manual command\n");
}
}
else if(Key == 'm' or Key == 'M')
{
if (LA_auto == false)
{
PC.printf("M key pressed. \n");
PC.printf("%s\n", BLA_object.Keyboard_EQUAL_KEY());
}
else
{
PC.printf("ERROR: In LA in Auto Mode, this is a manual command\n");
}
}
else if(Key == 'j' or Key == 'J')
{
if (LA_auto == false)
{
PC.printf("J key pressed. \n");
PC.printf("%s\n", BLA_object.Keyboard_A());
}
else
{
PC.printf("ERROR: In LA in Auto Mode, this is a manual command\n");
}
}
else if(Key == 'k' or Key == 'K')
{
if (LA_auto == false)
{
PC.printf("K key pressed. \n");
PC.printf("%s\n", BLA_object.Keyboard_D());
}
else
{
PC.printf("ERROR: In LA in Auto Mode, this is a manual command\n");
}
}
else if (Key == 't')
{
PC.printf("VELOCITY?\n%s\n",BLA_object.get_vel());
}
else
{
PC.printf("\n%c received!\n", Key);
PC.printf("\nDoing nothing.\n");
}
wait_us(100); //for PC readable
//PC.printf("%s\n", BLA_object.PID_velocity_control(la_setPoint, IMU_pitch_angle, la_P_gain, la_I_gain, la_D_gain).c_str()); //get output string
//BLA_object.PID_velocity_control(la_setPoint, IMU_pitch_angle, la_P_gain, la_I_gain, la_D_gain).c_str();
}
//MC readable
string MC_readable_string = "";
MC_readable_string = BLA_object.MC_readable_redux();
//PC.printf("CHECK_MC_readable:\n%s\n", MC_readable_string);
if (LA_auto == false)
{
if (!MC_readable_string.empty()) //if this string is empty
{
PC.printf("%s\n", MC_readable_string); //get responses from the linear actuator motor controller
}
else
{
;
//PC.printf("NOTHING?\n");
}
}
//change between automatic and manual mode of linear actuator? Troy: 7/11/2017
if (la_cases==0)
{
if (debug_mode) //debug mode true
PC.printf("%s\n", BLA_object.PID_velocity_control(la_setPoint, IMU_pitch_angle, la_P_gain, la_I_gain, la_D_gain).c_str()); //get output string
else //debug mode false
BLA_object.PID_velocity_control(la_setPoint, IMU_pitch_angle, la_P_gain, la_I_gain, la_D_gain).c_str();
}
else if (la_cases==1)
{
while (count_while==0)
{
PC.printf("%s\n", BLA_object.Keyboard_U().c_str()); //velocity = 0, motor disabled
PC.printf("%s\n", BLA_object.Keyboard_Q().c_str()); //turn off motor
wait(1);
PC.printf("%s\n", BLA_object.Keyboard_E().c_str()); //turn on motor
wait(1);
PC.printf("\n```````````Linear Actuator in Manual controlled mode````````````\n\n");
count_while++;
}
}
if ((abs(pvf().getVelocity())<0.1) && (posCon().getOutput()>0.0))
{
count ++;
//pc().printf("We have a small issue\n");
//PC.printf("posCon().getOutput() %f\n", posCon().getOutput()); //what is this again?
//always 1?
if(count==10)
{
//PC.printf("> > > Bad pot issue?\n");
//hBridge().stop();
count = 0; //reset counter
}
}
else if ((5.0*ain.read())<1.0)
{
PC.printf("Hit the limit switch??\n");
hBridge().stop();
}
/* buoyancy engine potentiometer string snaps */
else if (pvf().getVelocity() > 100)
{
PC.printf("DEBUG: String position? %f velocity? %f\n", pvf().getPosition(), pvf().getVelocity()); //DEBUG TROY
//hBridge().stop();
//PC.printf("PosVelFilter B.E. Velocity: %f\n", pvf().getVelocity());
PC.printf("********** String broke? *********\n");
}
if (debug_mode)
PC.printf("+");
//PC.printf("DEBUG: End of while loop?\n");
} //end of while loop
}