Basic Mid-Level control for the rebuilt MorphGI control unit, using PWM to communicate with the low level controllers.
Dependencies: ros_lib_kinetic
main.cpp
- Committer:
- WD40andTape
- Date:
- 2019-02-06
- Revision:
- 28:8e0c502c1a50
- Parent:
- 27:6853ee8ffefd
- Child:
- 29:10a5cf37a875
File content as of revision 28:8e0c502c1a50:
// STANDARD IMPORTS
#include "math.h"
// MBED IMPORTS
#include "mbed.h"
#include "mbed_events.h"
// CUSTOM IMPORTS
#include "MLSettings.h"
#include "HLComms.h"
#include "LLComms.h"
// DEMAND VARIABLES
double dblDemandSpeed_mmps[N_CHANNELS] = { 0.0 }; // The linear path velocity (not sent to actuator)
double dblDemandPosition_mm[N_CHANNELS] = { 0.0 }; // The final target position for the actuator
Serial pc(USBTX, USBRX); // tx, rx for usb debugging
LLComms llcomms;
HLComms hlcomms(HL_COMMS_FREQ_HZ);
Thread threadLowLevelSPI(osPriorityRealtime);
Thread threadSetDemands(osPriorityNormal);
Thread threadReceiveAndReplan(osPriorityBelowNormal);
Thread threadSensorFeedback(osPriorityBelowNormal);
Mutex mutPathIn;
Semaphore semLLcomms(1);
Semaphore semSensorData(1);
Ticker setDemandsTicker;
Ticker SendSensorDataTicker;
void sendSensorData() {
while( true ) {
semSensorData.wait();
hlcomms.send_sensor_message(llcomms.positionSensor_mm,llcomms.pressureSensor_bar);
}
}
void signalSendSensorData() {
semSensorData.release();
}
// This function will be called when a new transmission is received from high level
void ReceiveAndReplan() {
SendSensorDataTicker.attach(&signalSendSensorData, 1/(float)SENSOR_FEEDBACK_HZ); // Set up planning thread to recur at fixed intervals
struct demands_struct input;
while( true ) {
hlcomms.newData.wait();
input = hlcomms.get_demands();
// PROCESS INPUT
double dblTarget_mm[N_CHANNELS]; // The currenly assigned final target position (actuator will reach this at end of path)
// Update rear segment
dblTarget_mm[3] = input.psi_mm[0]*1000;
dblTarget_mm[5] = -1.0;
dblTarget_mm[6] = -1.0;
// Update mid segment
dblTarget_mm[4] = input.psi_mm[3]*1000;
dblTarget_mm[7] = dblTarget_mm[4]; // Same because two pumps are used
// Update front segment
dblTarget_mm[0] = input.psi_mm[6]*1000;
dblTarget_mm[1] = input.psi_mm[7]*1000;
dblTarget_mm[2] = input.psi_mm[8]*1000;
/*input.psi_mm[5] = -1; // Disable additional mid actuator
input.psi_mm[7] = -1; // Disable additional rear actuator
input.psi_mm[8] = -1; // Disable additional rear actuator*/
// Lock mutex, preventing setDemandsForLL from running
mutPathIn.lock();
// Limit requested speed
double limitedSpeed_mmps = min( max( 0.0 , input.speed_mmps ) , (double)MAX_SPEED_MMPS );
// For each actuator, limit the input position, calculate the position change, and select the absolute max
double dblDisplacementToTarget_mm[N_CHANNELS];
double maxDistanceToTarget_mm = 0.0;
for(int i=0; i<N_CHANNELS; i++) {
double dblCurrentPosition_mm = llcomms.positionSensor_mm[i];
if(dblTarget_mm[i]<0 || dblCurrentPosition_mm<0) { // If requested position is negative or the sensor feedback is erroneous
// Set actuator position change to 0
dblDisplacementToTarget_mm[i] = 0.0;
} else { // Requested position is positive
// ? Limit requested chamber lengths
// ? Convert from chamber length to actuator space
// Limit actuator position
dblTarget_mm[i] = min( max( 0.0 , dblTarget_mm[i] ) , (double)MAX_ACTUATOR_LIMIT_MM );
// Calculate actuator position change
dblDisplacementToTarget_mm[i] = dblTarget_mm[i] - dblCurrentPosition_mm;
// Select the max absolute actuator position change
if(fabs(dblDisplacementToTarget_mm[i])>maxDistanceToTarget_mm) {
maxDistanceToTarget_mm = fabs(dblDisplacementToTarget_mm[i]);
}
}
}
// For max actuator position change, calculate the time to destination at the limited speed
double maxTimeToTarget_s = fabs(maxDistanceToTarget_mm) / limitedSpeed_mmps;
// For each actuator, replan target position and velocity as required
for(int i=0; i<N_CHANNELS; i++) {
// If requested actuator position change is already within tolerance, do NOT replan that actuator
//printf("%d\t%0.5f\t%0.5f\r\n",i,dblDisplacementToTarget_mm[i],FLT_PATH_TOLERANCE_MM);
//printf("%d\t%0.5f\t%0.5f\t%0.5f\r\n",i,dblTarget_mm[i],fabs(dblDisplacementToTarget_mm[i]),maxTimeToTarget_s);
if( fabs(dblDisplacementToTarget_mm[i]) < FLT_PATH_TOLERANCE_MM ) continue;
// Calculate velocity for each motor to synchronise movements to complete in max time
// Set dblDemandPosition_mm and dblDemandSpeed_mmps
//printf("%d\t%0.5f\t%0.5f\t%0.5f\r\n",i,dblTarget_mm[i],fabs(dblDisplacementToTarget_mm[i]),maxTimeToTarget_s);
dblDemandPosition_mm[i] = dblTarget_mm[i];
dblDemandSpeed_mmps[i] = fabs(dblDisplacementToTarget_mm[i]) / maxTimeToTarget_s;
}
// Unlock mutex, allowing setDemandsForLL to run again
mutPathIn.unlock();
// SEND MESSAGE
hlcomms.send_duration_message(maxTimeToTarget_s);
}
}
void startLLcomms() { // Send new demands to LL after receiving new target data
semLLcomms.release(); // Uses threadSetDemands which is normal priority
}
void setDemandsForLL() {
while(1) {
semLLcomms.wait();
mutPathIn.lock(); // Lock relevant mutex
for(short int i=0; i<N_CHANNELS; i++) { // For each LL
llcomms.mutChannel[i].lock(); // MUTEX LOCK
llcomms.demandPosition_mm[i] = dblDemandPosition_mm[i];
llcomms.demandSpeed_mmps[i] = dblDemandSpeed_mmps[i];
llcomms.mutChannel[i].unlock(); // MUTEX UNLOCK
llcomms.isDataReady[i] = 1; // Signal that data ready
} // end for
mutPathIn.unlock(); // Unlock relevant mutex
} // end while(1)
}
int main() {
pc.baud(BAUD_RATE);
printf("ML engage. Compiled at %s\r\n.",__TIME__);
wait(3);
threadLowLevelSPI.start(callback(&llcomms.queue, &EventQueue::dispatch_forever)); // Start the event queue
threadReceiveAndReplan.start(ReceiveAndReplan);// Start replanning thread
threadSetDemands.start(setDemandsForLL); // Start planning thread
threadSensorFeedback.start(sendSensorData); // Start sensor feedback thread
setDemandsTicker.attach(&startLLcomms, 1/(float)LL_DEMANDS_FREQ_HZ); // Set up LL comms thread to recur at fixed intervals
Thread::wait(1);
while(1) {
Thread::wait(osWaitForever);
}
}