There are 6 repositories under lqr-controller topic.
The Control Toolbox - An Open-Source C++ Library for Robotics, Optimal and Model Predictive Control
A Control Systems Toolbox for Julia
Motion planning and Navigation of AGV/AMR:ROS planner plugin implementation of A*, Theta*, JPS, D*, LPA*, D* Lite, RRT, RRT*, RRT-Connect, Informed RRT*, ACO, Voronoi, PID, LQR, MPC, APF, DWA, Bezier, B-spline, Dubins, Reeds-Shepp etc.
An inverted pendulum that jumps and balances. It's a simplified version of the Cubli that you can build yourself.
Master's Thesis Project: Design, Development, Modelling and Simulating of a Y6 Multi-Rotor UAV, Imlementing Control Schemes such as Proportional Integral Derivative Control, Linear Quadratic Gaussian Control and Model Predictive Control on a BeagleBone Blue
LQR-RRT* method is used for random motion planning of a simple pendulum in it's phase plot
本项目是全国大学生智能车竞赛GDUT 2022年极速越野组的项目文件。采用了LQR控制器和多速率卡尔曼融合算法,并在单片机上实现。This project is the project document for the GDUT 2022 Extreme Off-Road Category of the National Student Intelligent Vehicle Competition.
反馈跟踪控制器,控制算法工具包,ADRC自抗扰控制,PID控制,抗积分饱和PID控制,增量式PID控制,模糊FuzzyPID控制,LQR线性二次型调节器控制,启发算法控制,强化学习控制,无人机轨迹跟踪控制
This repository contains different aspects of autonomous mobile robots including motion, control, and estimation. PID, LQR, and MPC controllers for differential drive robot are developed with ROS2. In addition, some filters are covered such as particle filter and ekf for localization.
Control an inverted pendulum (Segway robot) with an Arduino & RaspberryPi
Modelling and control of a railway vehicle active suspension system to improve the reduction in vibrations in the vehicle.
This project aims to design a LQR controller to control a car following a trajectory as accurate and fast as possible
Self-balancing robot analysis and LQG optimal controller design with MATLAB Simulink and Simscape Multibody
Addressing the combined problem of trajectory planning and tracking control for under-actuated autonomous underwater vehicle (AUV).
Simulink implementations of sliding mode and LQR controller for rotary inverted pendulum
Contains simple MPC implementation with neural network learned dynamics.
25 path-tracking algorithms are (goint to be) implemented with python.
Research Project for controller development of Autonomous Navigation of a self Balancing Segway Robot.
Autonomous drone simulation with LQR controller, trajectory planning, obstacle avoidance features in ROS2 and Python
Design of a Linear Quadratic Regulator balance controller for the Inverted Pendulum. After manually initializing the pendulum in the upright vertical position, the balance controller moves the rotary arm to keep the pendulum in this upright position. Moreover it is capable of balancing itself, even if minor external disturbances are given.
An example of active vibration attenuation by linear quadratic control entirely implemented in ANSYS APDL.
LQR and LQG control for gantry crane with 2 connected masses
Building self-balancing robot using LQR controller
Simple example of a finite-horizon LQR in continuous time
Fossen's Marine Systems Simulator
Active suspension system, quarter-car dynamic model, LQR controller & PID controller
Multivariable Control - Output feedback optimal controller
A two-wheeled remote control self-balancing robot based on the ATmega2560 microcontroller.
The goal of this project is to control a quadrotor to perform acrobatic moves.
Linear Quadratic Regulator and Linear Quadratic Gaussian Controller Design for a crane system.
A two-wheel self-balancing robot based on the Arduino micro-controller using LQR System
Implemented pole placement and linear quadratic regulator on several real-world systems.
Repository for AUV Control Optimisation using LQR Project with ECA Group