Shuto Naruse
Eurobot2012_Primary
Dependencies: mbed Eurobot_2012_Primary
Diff: Kalman/Kalman.cpp
- Revision:
- 0:f3bf6c7e2283
- Child:
- 1:bbabbd997d21
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/Kalman/Kalman.cpp Fri Apr 20 20:39:35 2012 +0000
@@ -0,0 +1,243 @@
+//***************************************************************************************
+//Kalman Filter implementation
+//***************************************************************************************
+#include "Kalman.h"
+#include "rtos.h"
+#include "RFSRF05.h"
+//#include "MatrixMath.h"
+//#include "Matrix.h"
+#include "math.h"
+#include "globals.h"
+#include "motors.h"
+#include "system.h"
+
+#include <tvmet/Matrix.h>
+#include <tvmet/Vector.h>
+using namespace tvmet;
+DigitalOut led1(LED1);
+DigitalOut led2(LED2);
+DigitalOut led3(LED3);
+DigitalOut led4(LED4);
+
+
+Kalman::Kalman(Motors &motorsin) :
+ sonararray(p23,p14,p14,p14,p15,p15,p15,p5,p6,p7,p8,p11),
+ motors(motorsin),
+ predictthread(predictloopwrapper, this, osPriorityNormal, 512),
+ predictticker( SIGTICKARGS(predictthread, 0x1) ),
+// sonarthread(sonarloopwrapper, this, osPriorityNormal, 256),
+// sonarticker( SIGTICKARGS(sonarthread, 0x1) ),
+ updatethread(updateloopwrapper, this, osPriorityNormal, 512) {
+
+ //Initilising matrices
+
+ // X = x, y, theta;
+ X = 0.5, 0, 0;
+
+ P = 1, 0, 0,
+ 0, 1, 0,
+ 0, 0, 0.04;
+
+ Q = 0.002, 0, 0, //temporary matrix, Use dt!
+ 0, 0.002, 0,
+ 0, 0, 0.002;
+
+ //measurment variance R is provided by each sensor when calling runupdate
+
+ //attach callback
+ sonararray.callbackobj = (DummyCT*)this;
+ sonararray.mcallbackfunc = (void (DummyCT::*)(int beaconnum, float distance, float variance)) &Kalman::runupdate;
+
+
+// predictticker.start(20);
+// sonarticker.start(50);
+
+
+}
+
+
+void Kalman::predictloop() {
+ Matrix<float, 3, 3> F;
+ int lastleft = motors.getEncoder1();
+ int lastright = motors.getEncoder2();
+ int leftenc;
+ int rightenc;
+ float dleft,dright;
+ float dxp, dyp;
+ float thetap,d,r;
+
+ while (1) {
+// Thread::signal_wait(0x1);
+ led1 = !led1;
+
+ leftenc = motors.getEncoder1();
+ rightenc = motors.getEncoder2();
+
+ dleft = motors.encoderToDistance(leftenc-lastleft)/1000.0f;
+ dright = motors.encoderToDistance(rightenc-lastright)/1000.0f;
+
+ lastleft = leftenc;
+ lastright = rightenc;
+
+
+ //The below calculation are in body frame (where +x is forward)
+ thetap = (dright - dleft)*PI / (float(robotCircumference)/1000.0f);
+ if (abs(thetap) < 0.02) { //if the rotation through the integration step is small, approximate with a straight line to avoid numerical error
+ d = (dright + dleft)/2.0f;
+ dxp = d*cos(thetap/2.0f);
+ dyp = d*sin(thetap/2.0f);
+
+ } else { //calculate circle arc
+ //float r = (right + left) / (4.0f * PI * thetap);
+ r = (dright + dleft) / (2.0f*thetap);
+ dxp = abs(r)*sin(thetap);
+ dyp = r - r*cos(thetap);
+ }
+
+ statelock.lock();
+
+ //rotating to cartesian frame and updating state
+ X(0) += dxp * cos(X(2)) - dyp * sin(X(2));
+ X(1) += dxp * sin(X(2)) + dyp * cos(X(2));
+ X(2) = rectifyAng(X(2) + thetap);
+
+ //Linearising F around X
+ F = 1, 0, (dxp * -sin(X(2)) - dyp * cos(X(2))),
+ 0, 1, (dxp * cos(X(2)) - dyp * sin(X(2))),
+ 0, 0, 1;
+
+
+ P = F * P * trans(F) + Q;
+
+ statelock.unlock();
+ Thread::wait(20);
+
+ //cout << "predict" << X << endl;
+ //cout << P << endl;
+ }
+}
+
+//void Kalman::sonarloop() {
+// while (1) {
+// Thread::signal_wait(0x1);
+// sonararray.startRange();
+// }
+//}
+
+
+void Kalman::runupdate(measurement_t type, float value, float variance) {
+ //printf("beacon %d dist %f\r\n", sonarid, dist);
+ //led2 = !led2;
+
+ measurmentdata* measured = (measurmentdata*)measureMQ.alloc();
+ if (measured) {
+ measured->mtype = type;
+ measured->value = value;
+ measured->variance = variance;
+
+ osStatus putret = measureMQ.put(measured);
+ if (putret)
+ led4 = 1;
+ // printf("putting in MQ error code %#x\r\n", putret);
+ } else {
+ led4 = 1;
+ //printf("MQalloc returned NULL ptr\r\n");
+ }
+
+}
+
+void Kalman::updateloop() {
+ measurement_t type;
+ float value,variance,rbx,rby,expecdist,Y;
+ float dhdx,dhdy;
+ bool aborton2stddev = false;
+
+ Matrix<float, 1, 3> H;
+
+ float S;
+ Matrix<float, 3, 3> I3( identity< Matrix<float, 3, 3> >() );
+
+
+ while (1) {
+ led2 = !led2;
+
+ osEvent evt = measureMQ.get();
+
+ if (evt.status == osEventMail) {
+
+ measurmentdata &measured = *(measurmentdata*)evt.value.p;
+ type = measured.mtype; //Note, may support more measurment types than sonar in the future!
+ value = measured.value;
+ variance = measured.variance;
+
+ // don't forget to free the memory
+ measureMQ.free(&measured);
+
+ if (type <= maxmeasure) {
+
+ if (type <= SONAR3) {
+
+ float dist = value / 1000.0f; //converting to m from mm
+ int sonarid = type;
+ aborton2stddev = true;
+
+ statelock.lock();
+ SonarMeasures[sonarid] = dist; //update the current sonar readings
+
+ rbx = X(0) - beaconpos[sonarid].x/1000.0f;
+ rby = X(1) - beaconpos[sonarid].y/1000.0f;
+
+ expecdist = sqrt(rbx*rbx + rby*rby);
+ Y = dist - expecdist;
+
+ dhdx = rbx / expecdist;
+ dhdy = rby / expecdist;
+
+ H = dhdx, dhdy, 0;
+
+ } else if (type <= IR3) {
+
+ int IRidx = type-3;
+
+ statelock.lock();
+ IRMeasures[IRidx] = value;
+
+ rbx = X(0) - beaconpos[IRidx].x/1000.0f;
+ rby = X(1) - beaconpos[IRidx].y/1000.0f;
+
+ float expecang = atan2(-rbx, -rby) - X(2);
+ Y = rectifyAng(value - expecang);
+
+ float dstsq = rbx*rbx + rby*rby;
+ H = -rby/dstsq, rbx/dstsq, -1;
+
+ }
+
+ Matrix<float, 3, 1> PH (P * trans(H));
+ S = (H * PH)(0,0) + variance;
+
+ if (aborton2stddev && Y*Y > 4 * S) {
+ statelock.unlock();
+ continue;
+ }
+
+ Matrix<float, 3, 1> K (PH * (1/S));
+
+ //Updating state
+ X += col(K, 0) * Y;
+ X(2) = rectifyAng(X(2));
+
+ P = (I3 - K * H) * P;
+
+ statelock.unlock();
+
+ }
+
+ } else {
+ led4 = 1;
+ //printf("ERROR: in updateloop, code %#x", evt);
+ }
+
+ }
+
+}
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