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Title: Closed Loop Control of a DC Motor with ROS

Introduction

This Project was created with the aim of controlling the motor with ROS Code. The motor is controlled using a PID Controller implemented a ROS Node. Encoder Sensing and Motor movement was done using Arduino Mega 2560.

Components Used

  1. ROS Melodic along with rosserial library/package.
  2. Arduino Mega 2560
  3. DC Geared Motor with Encoder ( 12v, 300RPM at 10Kgcm RMCS-5033 )
    datasheet :- https://robokits.download/downloads/RMCS%205033.pdf
  4. Motor Shield : VNH3ASP30 DC Motor Driver 2x14A
    datasheet :- https://www.pololu.com/file/0J52/vnh2sp30.pdf
  5. Li-ion Battery

Programming Languages Used

  1. Python
  2. C++

Theoretical Description

There is a Arduino Sketch as shown in this repository where ros.h library is included to enable ros capabilities. Now we use the rosserial package which enables serial communication of Arduino with ROS Environment. Now there is a Node that has a PID Controller implementation. Basic overall structure is

Arduino Node :-

  • Publishes - encoderValue
  • Subscribes - PWM_Values

Node_motor.py :-

  • Publishes - PWM_Values
  • Subscribes - encoderValue, desiredPosition

Below is the rqt_graph of the program

rosgraph

Basic Flow of the program :-

  1. The encodervalue is published from Arduino node.
  2. node_motor subscribes to /encoderValue and /desiredPosition.
  3. Now we Publish the desired angle/position to /desiredPosition.
  4. These inputs are provided to the PID controller implemented in the node_motor.py where Setpoint is /desiredPosition and feedback is /encodervalue.
  5. The PID controller gives PWM_value as output to control the motor direction and speed at a given refresh rate.
  6. This PWM value is published to /PWM_value and Arduino node subscribes to the /PWM_value and accordingly give commands to the motor driver.

How does a encoder work?

Incremental encoders, in their basic form, detect light, magnetic or physical changes on a disc that rotates with the shaft. Here motor is equiped with a optical encoder which observes the transition of light on a receiver as shown in the picture

encoder

Now, if we use a single channel encoder as shown above there is a disadvantage that we cannot determine the direction of the movement of the motor (i.e. Clockwise or Anti-Clockwise)

To overcome this disadvantage we use quadrature encoder as shown below.

encoder_quad

Now we can calculate the phase difference between the output signals of the encoder and determine the direction as shown.

What is a PID Controller?

A PID controller (proportional–integral–derivative controller) is a closed loop control mechanism employing feedback that is widely used in industrial control systems and a variety of other applications requiring continuously modulated control. A PID controller continuously calculates an error value e(t) as the difference between a desired setpoint (SP) and a measured process variable (PV) and applies a correction based on proportional, integral, and derivative terms (denoted P, I, and D respectively).

In our case:-

pid

We need to tune the P,I,D parameters individually for a specific control system according to the requirement.

pid_tunning

Following are general types of system response depending upon the P,I,D values.

introduction-to-pid-damped-controller

Program Explaination

Arduino Code (serial node)

Code to rotate the motor.

Defining the Motor Pins for motor1 slot on the shield.

#define MOTOR_1 0
#define BRAKE 0
#define CW    1
#define CCW   2
#define MOTOR_A1_PIN 7
#define MOTOR_B1_PIN 8

#define PWM_MOTOR_1 5

const int encoderPinA = 19;
const int encoderPinB = 20;

Now, we define a function to move the motor according to the direction and PWM Signal

void motorGo(int16_t motor, int16_t direct, uint16_t pwm)
  if(motor == MOTOR_1)
  {
    if(direct == CW)
    {
      digitalWrite(MOTOR_A1_PIN, LOW); 
      digitalWrite(MOTOR_B1_PIN, HIGH);
    }
    else if(direct == CCW)
    {
      digitalWrite(MOTOR_A1_PIN, HIGH);
      digitalWrite(MOTOR_B1_PIN, LOW);      
    }
    else
    {
      digitalWrite(MOTOR_A1_PIN, LOW);
      digitalWrite(MOTOR_B1_PIN, LOW);            
    }
    
    analogWrite(PWM_MOTOR_1, pwm); 
  }

Now we want create a function to move the motor according to the sign of PWM value given to it. Also we write the subscriber for the topic /PWM_Values.

void pwm_input( const std_msgs::Int16& pwm_value){
  int pwm =0;
  pwm = pwm_value.data;
  
  if ( pwm > 0 )
  {
  motorGo(MOTOR_1,CCW,pwm);
  }
  else
  {
  motorGo(MOTOR_1,CW,abs(pwm));
  }
ros::Subscriber<std_msgs::Int16> pwm("PWM_Values", &pwm_input);

Code for reading the encoder values

Setting up the encoder pins as interrupt pins

volatile int64_t currentPosition = 0;

void setup()
{
  nh.initNode();
  nh.advertise(encoderValue);
  nh.subscribe(pwm);
  
  pinMode (encoderPinA, INPUT_PULLUP);
  pinMode (encoderPinB, INPUT_PULLUP);
  attachInterrupt (digitalPinToInterrupt (encoderPinA), readEncoderA, CHANGE);
  attachInterrupt (digitalPinToInterrupt (encoderPinB), readEncoderB, CHANGE);

  TCCR1B = TCCR1B & 0b11111000 | 1;
}

Now we code the Interrupt service routine program to update the encoder value upon the movement of the shaft

void readEncoderA()
{
  if (digitalRead(encoderPinA) != digitalRead(encoderPinB))
  {
    currentPosition++;
  }
  else
  {
    currentPosition--;
  }
}

void readEncoderB()
{
  if (digitalRead(encoderPinA) == digitalRead(encoderPinB))
  {
    currentPosition++;
  }
  else
  {
    currentPosition--;
  }
}

Now we integrate the ros.h library to enable ROS compatiblity Header files for including ros and std_msgs package which is to define the data type of that topic.

#include <ros.h>
#include <std_msgs/Float32.h>
#include <std_msgs/Int64.h>
#include <std_msgs/Int16.h>

ros::NodeHandle  nh;

std_msgs::Int64 encoder; 

ros::Publisher encoderValue("encoderValue", &encoder);

Now we write the publisher inside loop to continuosly publish the updated encodervalues to the given topic.

void loop()
{
    
  nh.loginfo("Encoder Value");
  
  encoder.data = currentPosition;
  encoderValue.publish( &encoder );
  
  nh.spinOnce();
  delay(100);
  
}

Circuit Diagram

Circuit diagram for interfacing encoder motor with Arduino Mega and VNH2P30 Motor Shield.

circuit_diagram


Python Node (node_motor.py)

This code is written for the angular control of the motor, but it can be modified for the distance/position control according to the wheel diameter.

importing rospy and std_msgs packages. Defining global variables and motor specifications.

#!/usr/bin/env python
import rospy
from simple_pid import PID

from std_msgs.msg import Int64
from std_msgs.msg import Float64
from std_msgs.msg import Int16

PWM_Output = 0
PPR = 41
gearRatio = 60
decodeNumber = 4

encoderValue = 0
started = False
started1 = False
desired_Position = 0.0

Defining Callback functions for subscribers and a general function with timer for subscribing to two topics /encoderValue and /desiredPosition.

pub = rospy.Publisher('/PWM_Values',Int16,queue_size=100)
pub1 = rospy.Publisher('/Current_angle',Int16,queue_size=100)

def sub_encoderValue():
    rospy.init_node('node_motor', anonymous=True)
    rospy.Subscriber('encoderValue',Int64,callback)
    rospy.Subscriber('desiredPosition',Float64,callback1)
    timer = rospy.Timer(rospy.Duration(0.01),timer_callback)
    rospy.spin()
    timer.shutdown()

def callback(data):
    global started,encoderValue
    print "EncoderValue Received",encoderValue
    encoderValue = data.data
    if (not started):
        started = True

def callback1(data):
    global started1,desired_Position
    desired_Position = data.data
    if (not started1):
        started1 = True

Defining a callback function to calculate the PID output according to the updated /encoderValue and /desiredPosition. After that the we run the sub_encoder() function with runs whole program.

def timer_callback(event):
    global started,started1,pub,encoderValue,PWM_Output,desired_Position,current_wheel_distance,current_angle
    
    if(started1):
        if (started):

            previous_angle=current_angle
            pid = PID(0.022,0.01,2,setpoint=desired_Position)
            pid.output_limits = (-255, 255)
            pid.sample_time = 0.001
            PWM_Output = pid(previous_angle)

            if( 0 < PWM_Output <= 13):
                PWM_Output = PWM_Output + 11.5
            elif (-13 <= PWM_Output < 0):
                PWM_Output = PWM_Output - 11.5
            
            current_angle = encoderValue/24
            
            pub.publish(PWM_Output)
            
            print "Publishing PWM Values",PWM_Output
            print "Current angle",current_angle
            print "Desired Position",desired_Position

if __name__ == '__main__':
    print "Running"
    sub_encoderValue()

Output Video

Steps to run the code

roscore

check your port number in Arduino IDE.Running the serial node after uploading the code to arduino

rosrun rosserial_arduino serial_node.py /dev/tty/ACM0

running the motor control node.

rosrun pkg_name node_motor.py

Now we publish the required output angle to /desiredPosition topic using terminal.

rostopic pub /desiredPosition std_msgs/Float64 "data: 0.0"

You will output similar to this YouTube Video Link:- https://youtu.be/7hB2t6oS2qI

Appendix and FAQ

Find this document incomplete? Leave a comment! Suggestions are always welcome.

Tags: Closed Loop Control Documentation DC Motor with encoder ROS Arduino Tutorial python VNH3ASP30 Motor shield

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This Repository Contains all the programs of my mini-project closed loop control of motor with ROS

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