Best Robot Simulation Software for Linux of 2025

RoboDK serves as an effective and affordable simulator tailored for industrial robots and their programming needs. With RoboDK's simulation software, users can maximize the capabilities of their robots without needing any prior programming expertise, thanks to its user-friendly interface. Programming any robot offline becomes a simple task that can be accomplished in just a few clicks. The software boasts a comprehensive library that includes over 500 different robot arms, catering to a wide range of applications. One significant benefit of utilizing RoboDK’s simulation and offline programming tools is the ability to develop robot programs away from the production floor, thereby minimizing the disruptions associated with on-site programming. This feature allows you to work directly from your computer, effectively preventing any production downtime. In addition, RoboDK enables you to operate your robot arm similarly to a 5-axis milling machine (CNC) or a 3D printer. It can simulate and convert NC programs into robot programs, including formats like G-code or APT-CLS files. Furthermore, RoboDK automatically optimizes the robot's path to prevent issues such as singularities, axis constraints, and collisions. Overall, the process of simulating and programming industrial robots with RoboDK has reached unparalleled ease and efficiency. Whether you're a novice or an expert, RoboDK's capabilities can significantly enhance your robotic programming experience.

Cyberbotics' Webots is a versatile, open-source desktop application that operates across multiple platforms, specifically designed for the modeling, programming, and simulation of robotic systems. This tool provides an extensive development environment, complete with a rich library of assets including robots, sensors, actuators, objects, and materials, which streamlines the prototyping process and enhances the efficiency of robotics project development. Additionally, users have the capability to import pre-existing CAD models from software such as Blender or URDF and can incorporate OpenStreetMap data to enrich their simulations with real-world mapping. Webots accommodates various programming languages, such as C, C++, Python, Java, MATLAB, and ROS, which allows developers the flexibility to choose the best fit for their specific needs. Its contemporary graphical user interface, in conjunction with a robust physics engine and OpenGL rendering, facilitates the realistic simulation of a wide range of robotic systems, including wheeled robots, industrial arms, legged robots, drones, and autonomous vehicles. The application sees widespread use in industries, educational institutions, and research environments for purposes such as robot prototyping, AI algorithm development, and testing innovative robotic concepts. Overall, Webots stands out as a powerful resource for anyone looking to advance their work in robotics and simulation technologies.

SCAPE CoCreator is an innovative no-code platform for robotic automation that allows users to design, simulate, and implement robotic workflows without requiring any programming skills. This platform provides a seamless blend of hardware and software within an easy-to-use interface, facilitating the development of robotic applications that leverage 3D vision and artificial intelligence. Users have the ability to test and refine their solutions in a digital twin setting as well as on actual hardware, which can lead to a remarkable decrease in development time and expenses, potentially by up to 95% in comparison to conventional approaches. The platform conveniently supports integration with 3D scanners that adhere to the GenICam standard, promoting efficient communication and functionality. Furthermore, CoCreator accommodates the use of Python and C++, enabling the crafting of bespoke solutions specifically designed for unique tasks. Its user-friendly design empowers individuals to construct robotic applications without any coding knowledge, making it accessible to users across a wide range of expertise. Ultimately, SCAPE CoCreator democratizes robotic automation, inviting more people to engage in the creation and deployment of advanced robotic solutions.

Gazebo serves as an open-source simulator for robotics, offering a high level of fidelity in physics, visual rendering, and sensor modeling, which is essential for the development and testing of robotic applications. It accommodates various physics engines, such as ODE, Bullet, and Simbody, which facilitate precise dynamics simulation. The platform boasts sophisticated 3D graphics capabilities through rendering engines like OGRE v2, producing immersive environments enriched with realistic lighting, shadows, and textures. Gazebo comes equipped with a diverse set of sensors, including laser range finders, 2D and 3D cameras, IMUs, and GPS, along with features to emulate sensor noise. Users have the opportunity to create custom plugins to enhance robot, sensor, and environmental control and can engage with the simulations through a plugin-based graphical interface powered by the Gazebo GUI. Additionally, Gazebo provides a library of various robot models, such as the PR2, Pioneer2 DX, iRobot Create, and TurtleBot, while also allowing users to design their own models utilizing the SDF format. This flexibility and range of features make Gazebo a vital tool for researchers and developers in the field of robotics.

CoppeliaSim, created by Coppelia Robotics, stands out as a dynamic and robust platform for robot simulation, effectively serving various purposes such as rapid algorithm development, factory automation modeling, quick prototyping, verification processes, educational applications in robotics, remote monitoring capabilities, safety checks, and the creation of digital twins. Its architecture supports distributed control, allowing for individual management of objects and models through embedded scripts in Python or Lua, plugins written in C/C++, and remote API clients that support multiple programming languages including Java, MATLAB, Octave, C, C++, and Rust, as well as tailored solutions. The simulator is compatible with five different physics engines—MuJoCo, Bullet Physics, ODE, Newton, and Vortex Dynamics—enabling swift and customizable dynamics calculations that facilitate highly realistic simulations of physical phenomena and interactions, such as collision responses, grasping mechanisms, and the behavior of soft bodies, strings, ropes, and fabrics. Additionally, CoppeliaSim offers both forward and inverse kinematics computations for a diverse range of mechanical systems, enhancing its utility in various robotics applications. This flexibility and capability make CoppeliaSim an essential tool for researchers and professionals in the field of robotics.

PyBullet is a versatile Python library designed for simulating physics, robotics, and deep reinforcement learning, and it is rooted in the Bullet Physics SDK. This module enables users to load articulated bodies from various formats such as URDF and SDF, while also offering capabilities like forward dynamics simulation, inverse dynamics computation, kinematics, collision detection, and ray intersection queries. In addition to its robust simulation features, PyBullet includes rendering options, such as a CPU renderer and OpenGL visualization, along with support for virtual reality headsets. It finds applications in numerous research initiatives, including Assistive Gym, which utilizes PyBullet to facilitate physical human-robot interactions and advance assistive robotics for collaborative and physically supportive tasks. Additionally, the Kubric project serves as an open-source Python framework that collaborates with PyBullet and Blender to create photorealistic scenes complete with detailed annotations, demonstrating its ability to scale to extensive projects that can be distributed across thousands of machines. This combination of functionalities makes PyBullet an essential tool for researchers and developers working in the fields of robotics and simulation.

MORAI presents an innovative digital twin simulation platform designed to expedite the development and evaluation of autonomous vehicles, urban air mobility solutions, and maritime autonomous surface vessels. This platform utilizes high-definition mapping and an advanced physics engine to seamlessly connect real-world applications with simulated testing environments, ensuring all critical components for validating autonomous systems are included, such as those for self-driving cars, drones, and unmanned marine vehicles. It features a comprehensive array of sensor models, which encompass cameras, LiDAR, GPS, radar, and Inertial Measurement Units (IMUs). Users have the capability to create intricate and varied testing scenarios derived from actual data, including those based on logs and edge cases. Furthermore, MORAI's cloud-based simulation framework enables safe, efficient, and scalable testing processes, allowing multiple simulations to operate simultaneously while assessing various scenarios in parallel. This robust infrastructure not only enhances the reliability of testing but also significantly reduces the time and costs associated with the development of autonomous technologies.