invertedpendulum - Balancing an object or a robot mechanically in its unstable equilibrium position ie pendulum will be upside down

Project Information

Project feeds
Code license
GNU GPL v3
Labels
1D, pendulum, inverted, acclerometer, potentiometer, Microcontroller

Members

sushanti...@gmail.com

mudit.da...@gmail.com

rhythm2...@gmail.com

manavkat...@gmail.com

Featured

Downloads

Wiki pages

Links

External links
Modeling, Simulation and Control of Inverted Pendulum (CMU)
Action Plan (MindMap)
Groups
classical problem of inverted pendulum

Introduction

We propose to make an 1-Dimensional Inverted Pendulum which is a pendulum having its mass above its pivot point. An inverted pendulum is inherently unstable, and must be actively balanced by moving the pivot point horizontally as part of a feedback system.

Problem Statement

The problem involves a cart, able to move backwards and forwards, and a pendulum, hinged to the cart at the bottom of its length such that the pendulum can move in the same plane as the cart, shown below. That is, the pendulum mounted on the cart is free to fall along the cart's axis of motion. The system is to be controlled so that the pendulum remains balanced and upright, and is resistant to a step disturbance.

Proposed Solution

To mount the pendulum following can be used

cart (preferred), or
sliding platform,
rotating platform

To obtain data concerning the angle of rotation of the pendulum, potentiometer, accelerometer and gyroscopes are the possible options. As of now we will use potentiometers considering the convenience. Once we are successful with this mechanism we might use inertial sensors if required.

Control:

We will use the PID controller to stabilize the system. The controller design would be trail and error to start with and we aim to apply formal methods if are able to keep ourselves on track. Standard control equation of PID : The PID control we are planning to stablize our pendulum For processing we will use AVR Microcontrollers.

Timeline:

We are planning to do all the major reading stuff and collect necessary details about the problem during first two weeks of may when we are at home. And then seriously engage ourselves in project from may 20. We are expecting to ready our first model using potentiometers providing satisfactory results by 15th of june. Then we can make it better.

Real-Life Applications utilizing Principle of Inverted Pendulum

Missiles and rockets
Self balancing robots
Future Transport Vehicles like Segways, jetpacks etc

Demonstration:

We expect our final robot to be capable enough even to balance the pendulum even when delibrately disturbed. So, we can demostrate it by showing How the cart balances the pendulum. Else we can make this more fancy by making our robot compete against a volunteer ...who can balance stick for greater time.? who can balance the stick even when disturbed.?

Mentor - Manav Kataria