02. Robot Class

Robot Class

Robot Class

Go through the Robot class and the functions in the C++ quiz section and try to understand the role of each one of them. After reviewing the robot class, print “I am ready for coding the MCL!” in the main function.

While scrolling through the C++ code, you'll notice some statements and functions commented out. These statements and functions are part of the matplotlib python library and are later used to graph and visualize the results. After you finish coding the MCL algorithm, you'll be asked to interface with this function on the Workspace and generate images to visualize the process of the MCL algorithm.

Start Quiz: 

//#include "src/matplotlibcpp.h"//Graph Library
#include <iostream>
#include <string>
#include <math.h>
#include <vector>
#include <stdexcept> // throw errors
#include <random> //C++ 11 Random Numbers

//namespace plt = matplotlibcpp;
using namespace std;

// Landmarks
double landmarks[8][2] = { { 20.0, 20.0 }, { 20.0, 80.0 }, { 20.0, 50.0 },
    { 50.0, 20.0 }, { 50.0, 80.0 }, { 80.0, 80.0 },
    { 80.0, 20.0 }, { 80.0, 50.0 } };

// Map size in meters
double world_size = 100.0;

// Random Generators
random_device rd;
mt19937 gen(rd());

// Global Functions
double mod(double first_term, double second_term);
double gen_real_random();

class Robot {
public:
    Robot()
    {
        // Constructor
        x = gen_real_random() * world_size; // robot's x coordinate
        y = gen_real_random() * world_size; // robot's y coordinate
        orient = gen_real_random() * 2.0 * M_PI; // robot's orientation

        forward_noise = 0.0; //noise of the forward movement
        turn_noise = 0.0; //noise of the turn
        sense_noise = 0.0; //noise of the sensing
    }

    void set(double new_x, double new_y, double new_orient)
    {
        // Set robot new position and orientation
        if (new_x < 0 || new_x >= world_size)
            throw std::invalid_argument("X coordinate out of bound");
        if (new_y < 0 || new_y >= world_size)
            throw std::invalid_argument("Y coordinate out of bound");
        if (new_orient < 0 || new_orient >= 2 * M_PI)
            throw std::invalid_argument("Orientation must be in [0..2pi]");

        x = new_x;
        y = new_y;
        orient = new_orient;
    }

    void set_noise(double new_forward_noise, double new_turn_noise, double new_sense_noise)
    {
        // Simulate noise, often useful in particle filters
        forward_noise = new_forward_noise;
        turn_noise = new_turn_noise;
        sense_noise = new_sense_noise;
    }

    vector<double> sense()
    {
        // Measure the distances from the robot toward the landmarks
        vector<double> z(sizeof(landmarks) / sizeof(landmarks[0]));
        double dist;

        for (int i = 0; i < sizeof(landmarks) / sizeof(landmarks[0]); i++) {
            dist = sqrt(pow((x - landmarks[i][0]), 2) + pow((y - landmarks[i][1]), 2));
            dist += gen_gauss_random(0.0, sense_noise);
            z[i] = dist;
        }
        return z;
    }

    Robot move(double turn, double forward)
    {
        if (forward < 0)
            throw std::invalid_argument("Robot cannot move backward");

        // turn, and add randomness to the turning command
        orient = orient + turn + gen_gauss_random(0.0, turn_noise);
        orient = mod(orient, 2 * M_PI);

        // move, and add randomness to the motion command
        double dist = forward + gen_gauss_random(0.0, forward_noise);
        x = x + (cos(orient) * dist);
        y = y + (sin(orient) * dist);

        // cyclic truncate
        x = mod(x, world_size);
        y = mod(y, world_size);

        // set particle
        Robot res;
        res.set(x, y, orient);
        res.set_noise(forward_noise, turn_noise, sense_noise);

        return res;
    }

    string show_pose()
    {
        // Returns the robot current position and orientation in a string format
        return "[x=" + to_string(x) + " y=" + to_string(y) + " orient=" + to_string(orient) + "]";
    }

    string read_sensors()
    {
        // Returns all the distances from the robot toward the landmarks
        vector<double> z = sense();
        string readings = "[";
        for (int i = 0; i < z.size(); i++) {
            readings += to_string(z[i]) + " ";
        }
        readings[readings.size() - 1] = ']';

        return readings;
    }

    double measurement_prob(vector<double> measurement)
    {
        // Calculates how likely a measurement should be
        double prob = 1.0;
        double dist;

        for (int i = 0; i < sizeof(landmarks) / sizeof(landmarks[0]); i++) {
            dist = sqrt(pow((x - landmarks[i][0]), 2) + pow((y - landmarks[i][1]), 2));
            prob *= gaussian(dist, sense_noise, measurement[i]);
        }

        return prob;
    }

    double x, y, orient; //robot poses
    double forward_noise, turn_noise, sense_noise; //robot noises

private:
    double gen_gauss_random(double mean, double variance)
    {
        // Gaussian random
        normal_distribution<double> gauss_dist(mean, variance);
        return gauss_dist(gen);
    }

    double gaussian(double mu, double sigma, double x)
    {
        // Probability of x for 1-dim Gaussian with mean mu and var. sigma
        return exp(-(pow((mu - x), 2)) / (pow(sigma, 2)) / 2.0) / sqrt(2.0 * M_PI * (pow(sigma, 2)));
    }
};

// Functions
double gen_real_random()
{
    // Generate real random between 0 and 1
    uniform_real_distribution<double> real_dist(0.0, 1.0); //Real
    return real_dist(gen);
}

double mod(double first_term, double second_term)
{
    // Compute the modulus
    return first_term - (second_term)*floor(first_term / (second_term));
}

double evaluation(Robot r, Robot p[], int n)
{
    //Calculate the mean error of the system
    double sum = 0.0;
    for (int i = 0; i < n; i++) {
        //the second part is because of world's cyclicity
        double dx = mod((p[i].x - r.x + (world_size / 2.0)), world_size) - (world_size / 2.0);
        double dy = mod((p[i].y - r.y + (world_size / 2.0)), world_size) - (world_size / 2.0);
        double err = sqrt(pow(dx, 2) + pow(dy, 2));
        sum += err;
    }
    return sum / n;
}
double max(double arr[], int n)
{
    // Identify the max element in an array
    double max = 0;
    for (int i = 0; i < n; i++) {
        if (arr[i] > max)
            max = arr[i];
    }
    return max;
}
/*
void visualization(int n, Robot robot, int step, Robot p[], Robot pr[])
{
	//Draw the robot, landmarks, particles and resampled particles on a graph
	
    //Graph Format
    plt::title("MCL, step " + to_string(step));
    plt::xlim(0, 100);
    plt::ylim(0, 100);

    //Draw particles in green
    for (int i = 0; i < n; i++) {
        plt::plot({ p[i].x }, { p[i].y }, "go");
    }

    //Draw resampled particles in yellow
    for (int i = 0; i < n; i++) {
        plt::plot({ pr[i].x }, { pr[i].y }, "yo");
    }

    //Draw landmarks in red
    for (int i = 0; i < sizeof(landmarks) / sizeof(landmarks[0]); i++) {
        plt::plot({ landmarks[i][0] }, { landmarks[i][1] }, "ro");
    }
    
    //Draw robot position in blue
    plt::plot({ robot.x }, { robot.y }, "bo");

	//Save the image and close the plot
    plt::save("./Images/Step" + to_string(step) + ".png");
    plt::clf();
}
*/

//####   DON'T MODIFY ANYTHING ABOVE HERE! ENTER CODE BELOW ####
int main()
{
    // TODO: Print "I am ready for coding the MCL!"

    return 0;
}

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