Click to enlarge
Previous product
QLabs Controls
Back to products
Next product
Quanser Mechatronic Sensors Board
Quanser

QLabs Robotics

QLabs Robotics is a collection of virtual laboratory activities that supplement traditional or online robotics courses. The virtual hardware labs are based on Quanser QArm robotic manipulator and QBot 2e mobile ground robot. The virtual twins of these robots are fully instrumented and dynamically accurate, allowing users to measure simulated sensors, including video and depth data, interact with virtual environments, and work with the same code created for the “real” robots. With QLabs Robotics, you can combine physical and virtual plants to enrich your lectures and in-lab activities and increases engagement and students’ learning outcomes in class-based or online courses.

Brand

Quanser
Compare
Add to wishlist
Description

QLabs Robotics is a scalable platform capable of delivering credible, academically appropriate, and high-fidelity lab experiences through interactions with virtual hardware. QLabs Robotics offers fully instrumented and dynamically accurate digital twins of the Quanser QBot 2e mobile robot and QArm robotic manipulator that behave and can be measured and controlled using MATLAB®/Simulink® and other platforms exactly as the real systems would.

QLabs Robotics is accompanied by a comprehensive curriculum covering topics such as kinematics, dynamics, control, and a survey of modern mobile robotics from actuation and localization to mapping and path planning. The platform also comes with instructor resources and tools to manage student access and monitor their progress.

QLabs Robotics is available as a 12-month subscription. To access and manage your QLabs Robotics subscription, log in to your Quanser Academic Portal account.

Categories: ,

Related products

Compare
Close

Linear Flexible Inverted Pendulum

The linear flexible inverted pendulum challenges students to gain advanced modeling and control experience by controlling both the damping of a flexible link, and an unstable inverted pendulum.
Add to wishlist
Read more
Quick view
Compare
Close

Magnetic Levitation

The force between electromagnet and ball is highly nonlinear. Further, the electromagnet itself has its own dynamics that must be compensated for. The challenging dynamics of the system make it perfect for teaching modeling, linearization, current control, position control, and using multiple loops (i.e. cascade control). It could also be used to test and implement more advanced control strategies, such as multi-variable, gain scheduling, and nonlinear control.
Add to wishlist
Read more
Quick view
New
Compare
Close

QLabs Virtual Coupled Tanks

Same as the physical Coupled Tanks, the virtual system features a single pump and two tanks. Each tank is instrumented with a pressure sensor to measure the liquid level. The different outflow valves configurations allow to direct the flow of the liquid, while the flow rate can be changed by using outflow orifices of different diameters.
Add to wishlist
Read more
Quick view
New
Compare
Close

QLabs Virtual Rotary Servo

Same as the physical Rotary Servo Base Unit, the virtual system features a DC motor that drives a smaller pinion gear. This gear is fixed to a larger middle gear that rotates on the load shaft. The position of the load shaft is measured using a high-resolution optical encoder or a potentiometer.
Add to wishlist
Read more
Quick view
Compare
Close

QLabs Virtual QBot 2e

Same as the physical QBot 2e, the virtual system is an autonomous ground robot featuring built-in sensors and vision system.
Add to wishlist
Read more
Quick view
Compare
Close

QLabs Virtual QUBE-Servo 2

Same as the physical QUBE-Servo 2, the virtual system features a DC motor with the inertia disk and inverted pendulum modules. Rotary encoders measure the angular position of the DC motor and pendulum. The motor angular velocity is measured through a software-based tachometer.
Add to wishlist
Read more
Quick view
Compare
Close

Linear Flexible Joint

The Linear Flexible Joint experiment will help your students learn how to model and control real-world dynamic systems such as flexible couplings and gearboxes.
Add to wishlist
Read more
Quick view
Compare
Close

Quanser AERO myRIO

The experiment is reconfigurable for various aerospace systems, from 1 DOF and 2 DOF helicopter to half-quadrotor. Integrating Quanser-developed QFLEX 2 computing interface technology, the Quanser AERO also offers flexibility in lab configurations, using a PC, or microcontrollers, such as NI myRIO, Arduino and Raspberry Pi. With the comprehensive course materials included, you can build a state-of-the-art teaching lab for your mechatronics or control courses, engage students in various design and capstone projects, and validate your research concepts on a high-quality, robust, and precise platform.
Add to wishlist
Read more
Quick view