CashComplete2.0
Test the speed of sensor module PID controlled speed. When note is passed the optical sensors data is collected and shared via SWO
Diff: main.cpp
- Revision:
- 0:fc81857d8067
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/main.cpp Fri Nov 30 10:22:36 2018 +0000
@@ -0,0 +1,456 @@
+#include "mbed.h"
+#include "SWO.h"
+#include "PID.h"
+
+#define RATE 5 //interval PID calculation performed every 5th milliseconds.
+
+
+
+DigitalOut LED_GREEN(PA_4);
+DigitalOut LED_RED(PA_5);
+DigitalOut LED_ENABLE(PB_5);
+
+//optical sensors
+DigitalIn SCANNER_INPUT(PC_10);
+DigitalIn SCANNER_OUTPUT(PC_1);
+DigitalIn SWITCH_INPUT(PC_2);
+DigitalIn REJECT_INPUT(PA_7);
+DigitalIn REJECT_OUTPUT(PA_6);
+DigitalIn STORAGE_INPUT(PC_3);
+
+int opticalSensors[6] = {0}; //list to store the values from optical sensors
+int lastValueOpticalSensors[6] = {0}; //list to store the previous values from optical sensors
+float sensorNoteRunningTimes[10] = {0}; //The times (in us) when note hit the sensors are stored in this array
+int pulseCountBetweenSensors[10] = {0}; //The counted number encoder pulses between sensors
+int noteInSystem = 0;
+long lastPulseTime = 0;
+long maxTimeBetweenPulses = 0;
+long minTimeBetweenPulses = 10000000;
+long timeBetweenPulses = 0;
+double currentSpeed = 0; //speed in mm/ms
+long lastControl = 0;
+
+PID controller(4.0, 0.0, 0.0, RATE);
+
+
+int AtoB_dist = 357; //distance from SCANNER_INPUT to SCANNER_OUTPUT counted pulses: 372
+int BtoC_dist = 81; //distance from SCANNER_OUTPUT to SWITCH_INPUT counted pulses: 82
+int CtoD_dist = 201; //distance from SWITCH_INPUT to REJECT_INPUT counted pulses: 203
+int DtoE_dist = 158; //distance from REJECT_INPUT to REJECT_OUTPUT counted pulses: 156
+int Tot_dist = 797; //distance from SCANNER_INPUT to REJECT_OUTPUT counted pulses: 813
+
+int TenEURnoteLength = 127;
+int FiftyEURnoteLength = 140;
+int TwentyEURnoteLength = 120;
+
+//encoders
+InterruptIn MAIN_ENC(PA_8);
+//InterruptIn STORAGE_ENC(PA_15);
+//InterruptIn SWITCH_ENC(PB_4);
+//InterruptIn ROUTER_ENC(PB_6);
+
+
+//Motors
+PwmOut MAIN_PWM(PC_7); //PWM to Main Drive
+DigitalOut MAIN_DIR(PC_0); //Direction of main drive
+
+PwmOut SWITCH_PWM(PB_14); //PWM to Switch
+DigitalOut SWITCH_DIR(PB_15); //Direction of Switch
+
+PwmOut ROUTER_PWM(PC_8); //PWM to Router
+DigitalOut ROUTER_DIR(PB_7); //Direction of Router
+
+PwmOut STORAGE_PWM(PC_6); //PWM to Storage
+DigitalOut STORAGE_DIR(PC_9); //Direction of Storage
+
+
+
+uint32_t blinkTime_ms = 0;
+uint32_t reportTimer = 0;
+uint32_t pulses = 0;
+
+
+Timer t;
+//PID controller(1, 0, 0, RATE); //Kc, Ti, Td, interval
+
+
+Serial pc(USBTX, USBRX);
+SWO_Channel swo("channel");
+
+void green_blink(void)
+{
+ if(t.read_ms() - blinkTime_ms > 200) {
+ LED_RED = 0;
+ LED_GREEN = !LED_GREEN;
+ blinkTime_ms = t.read_ms();
+ }
+}
+void red_blink(void)
+{
+ if(t.read_ms() - blinkTime_ms > 200) {
+ LED_GREEN = 0;
+ LED_RED = !LED_RED;
+ blinkTime_ms = t.read_ms();
+ }
+}
+
+void reportNoteThroughSensorLengths()
+{
+
+ swo.printf("\n");
+
+ //Time for note to travel through first sensor
+ long time = (sensorNoteRunningTimes[1] - sensorNoteRunningTimes[0]); //us
+ swo.printf("Time for note to pass 1th sensor (us): %d\r", time);
+ //int length = TwentyEURnoteLength;
+ int countedPulses = pulseCountBetweenSensors[1] - pulseCountBetweenSensors[0];
+ swo.printf(" Counted pulses: %d\r\n", countedPulses);
+
+ //Time for note to travel through second sensor
+ time = (sensorNoteRunningTimes[3] - sensorNoteRunningTimes[2]); //us
+ swo.printf("Time for note to pass 2th sensor (us): %d\r\n", time);
+ countedPulses = pulseCountBetweenSensors[3] - pulseCountBetweenSensors[2];
+ swo.printf(" Counted pulses: %d\r\n", countedPulses);
+
+ //Time for note to travel through third sensor
+ time = (sensorNoteRunningTimes[5] - sensorNoteRunningTimes[4]); //us
+ swo.printf("Time for note to pass 3th sensor (us): %d\r\n", time);
+ countedPulses = pulseCountBetweenSensors[5] - pulseCountBetweenSensors[4];
+ swo.printf(" Counted pulses: %d\r\n", countedPulses);
+
+ //Time for note to travel through fourth sensor
+ time = (sensorNoteRunningTimes[7] - sensorNoteRunningTimes[6]); //us
+ swo.printf("Time for note to pass 4th sensor (us): %d\r\n", time);
+ countedPulses = pulseCountBetweenSensors[7] - pulseCountBetweenSensors[6];
+ swo.printf(" Counted pulses: %d\r\n", countedPulses);
+
+ //Time for note to travel through fifth sensor
+ time = (sensorNoteRunningTimes[9] - sensorNoteRunningTimes[8]); //us
+ swo.printf("Time for note to pass 5th sensor (us): %d\r\n", time);
+ countedPulses = pulseCountBetweenSensors[9] - pulseCountBetweenSensors[8];
+ swo.printf(" Counted pulses: %d\r\n", countedPulses);
+
+ swo.printf("\n");
+ swo.printf("\n");
+
+}
+
+void report(void)
+{
+ //uint32_t now = t.read_ms();
+
+ /*
+ swo.printf("Optical sensor status: ");
+ for(int j = 0; j <=5 ; j++) {
+ swo.printf("%d ", opticalSensors[j]);
+ }
+ swo.printf("\n");
+ */
+
+ long time = (sensorNoteRunningTimes[2] - sensorNoteRunningTimes[0]) / 1000; //ms
+
+ //swo.printf("Time between first two sensors (ms): ");
+ //swo.printf("%d ", time);
+ //swo.printf("\n");
+
+ //V = S / T
+ float V = 1000 * AtoB_dist / time; //(mm/s)
+
+ swo.printf("Speed between first two sensors (mm/s): ");
+ swo.printf("%f ", V);
+ swo.printf(" Counted encoder pulses: ");
+ uint32_t countedPulses = pulseCountBetweenSensors[2] - pulseCountBetweenSensors[0];
+ swo.printf("%d ", countedPulses);
+ swo.printf(" ->Encoder speed (mm/s): ");
+ float countedSpeed = 1000 * countedPulses / time;
+ swo.printf("%f ", countedSpeed);
+ swo.printf(" ->Speed difference (percentage): ");
+ double difference = (100 * V / countedSpeed) - 100;
+ swo.printf("%f ", difference);
+
+ swo.printf("\n");
+
+ time = (sensorNoteRunningTimes[4] - sensorNoteRunningTimes[2]) / 1000; //ms
+ V = 1000 * BtoC_dist / time; //(mm/s)
+
+ swo.printf("Speed between second and third sensor (mm/s): ");
+ swo.printf("%f ", V);
+ swo.printf(" Counted encoder pulses: ");
+ countedPulses = pulseCountBetweenSensors[4] - pulseCountBetweenSensors[2];
+ swo.printf("%d ", countedPulses);
+ swo.printf(" ->Encoder speed (mm/s): ");
+ countedSpeed = 1000 * countedPulses / time;
+ swo.printf("%f ", countedSpeed);
+ swo.printf(" ->Speed difference (percentage): ");
+ difference = (100 * V / countedSpeed) - 100;
+ swo.printf("%f ", difference);
+
+ swo.printf("\n");
+
+ time = (sensorNoteRunningTimes[6] - sensorNoteRunningTimes[4]) / 1000; //ms
+ V = 1000 * CtoD_dist / time; //(mm/s)
+
+ swo.printf("Speed between third and fourth sensor (mm/s): ");
+ swo.printf("%f ", V);
+ swo.printf(" Counted encoder pulses: ");
+ countedPulses = pulseCountBetweenSensors[6] - pulseCountBetweenSensors[4];
+ swo.printf("%d ", countedPulses);
+ swo.printf(" ->Encoder speed (mm/s): ");
+ countedSpeed = 1000 * countedPulses / time;
+ swo.printf("%f ", countedSpeed);
+ swo.printf(" ->Speed difference (percentage): ");
+ difference = (100 * V / countedSpeed) - 100;
+ swo.printf("%f ", difference);
+
+ swo.printf("\n");
+
+ time = (sensorNoteRunningTimes[8] - sensorNoteRunningTimes[6]) / 1000; //ms
+ V = 1000 * DtoE_dist / time; //(mm/s)
+
+ swo.printf("Speed between fourth and fifth sensor (mm/s): ");
+ swo.printf("%f ", V);
+ swo.printf(" Counted encoder pulses: ");
+ countedPulses = pulseCountBetweenSensors[8] - pulseCountBetweenSensors[6];
+ swo.printf("%d ", countedPulses);
+ swo.printf(" ->Encoder speed (mm/s): ");
+ countedSpeed = 1000 * countedPulses / time;
+ swo.printf("%f ", countedSpeed);
+ swo.printf(" ->Speed difference (percentage): ");
+ difference = (100 * V / countedSpeed) - 100;
+ swo.printf("%f ", difference);
+
+ swo.printf("\n");
+ swo.printf("\n");
+
+ time = (sensorNoteRunningTimes[8] - sensorNoteRunningTimes[0]) / 1000; //ms
+ V = 1000 * Tot_dist / time; //(mm/s)
+
+ swo.printf("Total mean speed between first and last sensor (mm/s): ");
+ swo.printf("%f ", V);
+ swo.printf(" Total counted encoder pulses: ");
+ countedPulses = pulseCountBetweenSensors[8] - pulseCountBetweenSensors[0];
+ swo.printf("%d ", countedPulses);
+ swo.printf(" ->Encoder speed (mm/s): ");
+ countedSpeed = 1000 * countedPulses / time;
+ swo.printf("%f ", countedSpeed);
+ swo.printf(" ->Total speed difference (percentage): ");
+ difference = (100 * V / countedSpeed) - 100;
+ swo.printf("%f ", difference);
+
+ swo.printf("\n");
+ swo.printf("\n");
+
+ swo.printf("Maximum time between pulses (us): %d\r\n", maxTimeBetweenPulses);
+ swo.printf("Minimum time between pulses (us): %d\r\n", minTimeBetweenPulses);
+
+ swo.printf("\n");
+ swo.printf("Filtered speed value to PID (mm/s): ");
+ swo.printf("%f ", currentSpeed);
+
+
+ swo.printf("\n");
+ swo.printf("\n");
+
+
+ reportNoteThroughSensorLengths();
+
+ maxTimeBetweenPulses = 0;
+ minTimeBetweenPulses = 10000000;
+ pulses = 0;
+
+ reportTimer = t.read_ms();
+}
+
+
+
+void encTick(void)
+{
+ long now = t.read_us();
+ timeBetweenPulses = now - lastPulseTime;
+
+ if(noteInSystem) {
+ if(timeBetweenPulses > maxTimeBetweenPulses) maxTimeBetweenPulses = timeBetweenPulses; //storing maximum time between pulses
+ if(timeBetweenPulses < minTimeBetweenPulses) minTimeBetweenPulses = timeBetweenPulses; //storing minimum time between pulses
+ }
+
+ lastPulseTime = now;
+
+ pulses++;
+
+ //filtered 10%
+ currentSpeed = 0.05 * (1000000/timeBetweenPulses) + 0.95 * currentSpeed; //mm/s
+ //currentSpeed = 1000000/timeBetweenPulses; //mm/s
+}
+
+void checkOpticalSensors(void)
+{
+
+ for(int i=0; i<=5; i++) {
+ opticalSensors[i]=0;
+ }
+
+ if(SCANNER_INPUT) {
+ opticalSensors[0]=1;
+ if(lastValueOpticalSensors[0] == 0) {
+ sensorNoteRunningTimes[0] = t.read_us(); //leading edge of note detected on first optical sensor - storing time
+ noteInSystem = 1; //note entered the system
+ pulseCountBetweenSensors[0] = pulses;
+ }
+ } else {
+ if(lastValueOpticalSensors[0] == 1) {
+ sensorNoteRunningTimes[1] = t.read_us(); //leaving edge of note detected on first optical sensor - storing time
+ pulseCountBetweenSensors[1] = pulses;
+ }
+ }
+
+ if(SCANNER_OUTPUT) {
+ opticalSensors[1]=1;
+ if(lastValueOpticalSensors[1] == 0) {
+ sensorNoteRunningTimes[2] = t.read_us(); //note detected on second optical sensor - storing time
+ pulseCountBetweenSensors[2] = pulses;
+ }
+ } else {
+ if(lastValueOpticalSensors[1] == 1) {
+ sensorNoteRunningTimes[3] = t.read_us(); //leaving edge of note detected on first optical sensor - storing time
+ pulseCountBetweenSensors[3] = pulses;
+ }
+ }
+
+ if(SWITCH_INPUT) {
+ opticalSensors[2]=1;
+ if(lastValueOpticalSensors[2] == 0) {
+ sensorNoteRunningTimes[4] = t.read_us(); //note detected on second optical sensor - storing time
+ pulseCountBetweenSensors[4] = pulses;
+ }
+ } else {
+ if(lastValueOpticalSensors[2] == 1) {
+ sensorNoteRunningTimes[5] = t.read_us(); //leaving edge of note detected on first optical sensor - storing time
+ pulseCountBetweenSensors[5] = pulses;
+ }
+ }
+
+ if(REJECT_INPUT) {
+ opticalSensors[3]=1;
+ if(lastValueOpticalSensors[3] == 0) {
+ sensorNoteRunningTimes[6] = t.read_us(); //note detected on second optical sensor - storing time
+ pulseCountBetweenSensors[6] = pulses;
+ }
+ } else {
+ if(lastValueOpticalSensors[3] == 1) {
+ sensorNoteRunningTimes[7] = t.read_us(); //leaving edge of note detected on first optical sensor - storing time
+ pulseCountBetweenSensors[7] = pulses;
+ }
+ }
+
+ if(REJECT_OUTPUT) {
+ opticalSensors[4]=1;
+ if(lastValueOpticalSensors[4] == 0) {
+ sensorNoteRunningTimes[8] = t.read_us(); //note detected on second optical sensor - storing time
+ pulseCountBetweenSensors[8] = pulses;
+ }
+ } else {
+ if(lastValueOpticalSensors[4] == 1) {
+ sensorNoteRunningTimes[9] = t.read_us(); //leaving edge of note detected on first optical sensor - storing time
+ pulseCountBetweenSensors[9] = pulses;
+ noteInSystem = 0; //note left the system
+ report();
+ }
+ }
+
+ if(STORAGE_INPUT) opticalSensors[5]=1;
+
+ //storing sensor state in previous value array
+ for(int i=0; i<=5; i++) {
+ lastValueOpticalSensors[i] = opticalSensors[i];
+ }
+
+}
+
+void tunePID()
+{
+
+ swo.printf("setting 60percent output %\n");
+ MAIN_PWM.write(0.6f);
+ swo.printf("waiting for speedup... %\n");
+ wait(2); //waiting 2 sec
+ swo.printf("Current speed (mm/s): %f\n", currentSpeed);
+ double beforeSpeed = currentSpeed;
+ swo.printf("setting 70percent output %\n");
+ MAIN_PWM.write(0.7f); //10% more output
+ swo.printf("waiting for speedup... %\n");
+ wait(2); //waiting 2 sec
+ swo.printf("Current speed (mm/s): %f\n", currentSpeed);
+ double deltaSpeed = currentSpeed - beforeSpeed;
+ swo.printf("delta Speed (mm/s): %f\n", deltaSpeed);
+ double K = deltaSpeed / 10;
+ swo.printf("PID K-factor (deltaSpeed/10): %f\n", K);
+
+ controller.setTunings(K/2, 0, 0); //K/2?
+
+ controller.setInputLimits(0.0, 600);
+
+ //Pwm output from 0.0 to 1.0
+ controller.setOutputLimits(0.0, 1.0);
+
+ controller.setMode(AUTO_MODE);
+
+ controller.setSetPoint(600);
+
+ swo.printf("\n");
+ swo.printf("\n");
+ swo.printf("\n");
+
+}
+
+
+int main()
+{
+ LED_ENABLE = 1; //turning leds on
+ LED_GREEN = 0;
+ LED_RED = 0;
+
+ //Setting motors off
+ MAIN_PWM.write(0.00f);
+ SWITCH_PWM.write(0.00f);
+ ROUTER_PWM.write(0.00f);
+ STORAGE_PWM.write(0.00f);
+ MAIN_PWM.period(0.00005); //Set motor PWM periods to 20KHz.
+ SWITCH_PWM.period(0.00005); //Set motor PWM periods to 20KHz.
+ ROUTER_PWM.period(0.00005); //Set motor PWM periods to 20KHz.
+ STORAGE_PWM.period(0.00005); //Set motor PWM periods to 20KHz.
+
+
+ swo.printf("STARTED %\n");
+ swo.printf("CPU SystemCoreClock is %d Hz\r\n", SystemCoreClock); //SYTEM CLOCK 72MHz
+ MAIN_ENC.rise(&encTick); // attach the address of the encTick function to the rising edge
+
+ t.start();
+
+ //MAIN_PWM.write(0.7f); //40% works 0.4f
+
+ tunePID();
+
+
+ while(1) {
+
+
+ checkOpticalSensors(); //updating opticalSensors array
+
+ //if(t.read_ms() - reportTimer > 1000 && noteInSystem == 0) report(); //reporting every second
+
+ if(t.read_ms() - lastControl > RATE) {
+ //Update the process variable.
+ controller.setProcessValue(currentSpeed);
+ //Set the new output.
+ double output = controller.compute();
+ MAIN_PWM.write(output);
+ //swo.printf("sent to controller: %f\n", output);
+ lastControl = t.read_ms();
+ }
+
+ }
+
+
+}
+
+