Robotics Lab Setup
Autonomous Robotics — Build, Program, Deploy
Full robotics laboratory for 20 20 students covering mobile robots, robotic arms, computer vision, and ROS. From basic motor control to autonomous navigation and manipulation.
Choose Your Package
All packages designed for 20 students — scalable on request
Starter
Build and program 4WD robots from scratch
- Arduino Mega 2560 × 20
- 4WD robot chassis kit × 10 (per pair)
- DC gear motors + L298N drivers × 20 sets
- Ultrasonic + IR sensor packs × 20
- Servo motors SG90/MG995 × 20 sets
- Bluetooth HC-05 modules × 20
- LiPo battery 3S 2200mAh × 15
Standard
Vision-enabled robots with ROS and camera integration
- Everything in Starter
- Raspberry Pi 4 4GB × 10 (per pair)
- Pi Camera Module v3 × 10
- 6-DOF Robotic Arm Kit × 4 (group use)
- RPLIDAR A1 2D LIDAR × 2
- ROS-compatible differential drive × 4
- 3D Printer (FDM, 220×220mm) × 1
- 2-ch Oscilloscopes × 3
Professional
Industry-grade with SLAM, manipulators & simulation
- Everything in Standard
- ROS2 navigation-ready wheeled base × 2
- NVIDIA Jetson AGX Orin × 2 (AI perception)
- Depth camera Intel RealSense D435i × 4
- Electric linear actuators + gripper × 4
- IMU (BNO055) + GPS module per robot
- Industrial robot trainer (6-axis) × 1
- Gazebo + ROS2 simulation workstations × 5
Equipment List
Complete equipment for 20 students — varies by selected package
| Equipment | Qty | Specification |
|---|---|---|
| Arduino Mega 2560 | 20 units | ATmega2560 16MHz, 54 digital I/O, 16 analog, 4 UART |
| 4WD Robot Chassis Kit | 10 sets | Aluminium frame, 4× TT gear motors 200RPM, 65mm wheels |
| L298N Dual Motor Driver | 20 units | 2A per channel, 5–35V, PWM speed control |
| Servo Motor Pack | 20 packs | SG90 × 4 (5g micro) + MG995 × 2 (55g standard) |
| Sensor Pack (Robotics) | 20 packs | HC-SR04 ultrasonic × 3, IR line × 4, Bump switch × 2 |
| LiPo Battery 3S 2200mAh | 20 units | 11.1V 2200mAh 25C, with XT60 connector |
| Raspberry Pi 4 4GB | 10 units | Cortex-A72 1.5GHz, 4GB LPDDR4, 40-pin GPIO |
Software & Tools
Included software stack — licensed for each student workstation
ROS 2 Humble / Iron
Open-SourceRobot Operating System — navigation, control, simulation
Gazebo Simulator
Open-Source3D robot simulation with physics engine
Arduino IDE + MegunoLink
FreeLow-level motor control and sensor code
OpenCV + Python
Open-SourceComputer vision, object detection, line following
MATLAB + Simulink
StudentControl systems, kinematics, path planning (student)
Fusion 360 / FreeCAD
FreeMechanical design for 3D-printed robot parts
Curriculum Modules
6 modules from Beginner to Advanced — typically covered in one academic semester
Duration: 2 weeks
- DC motors, PWM speed control
- L298N driver wiring
- Servo control (PWM timing)
- LiPo battery safety
What Makes This Lab Complete
10 complete 4WD robot platforms (per-pair)
4 articulated robotic arm kits for manipulation training
2D LIDAR + depth cameras for SLAM and navigation
ROS 2 simulation environment with Gazebo
3D printer for rapid custom part fabrication
Progression: motor control → autonomy → manipulation
Infrastructure Requirements
What your institution needs to provide before installation
Room Size
Minimum 800 sq ft — open floor space needed for robot testing (4×4m clear area)
Power Supply
20 workstation outlets + 8× 12V/5A adapters for robot charging
Flooring
Smooth hard floor (tile/vinyl) — avoid carpet, needed for wheeled robot testing
Internet
100 Mbps broadband + WiFi, ROS nodes communicate over local LAN
Safety Area
Designated robot run area with soft boundary markers; arm caging if industrial robot present
Setup Process
Consultation
Our team reviews your space, budget and learning objectives to recommend the right package.
Procurement
We source all equipment, verify quality and arrange delivery to your institution.
Installation
Our engineers set up all hardware, networking, software and test every workstation.
Training
Faculty training session included — start teaching from day one with our curriculum guide.
Get a Custom Quote
For Robotics Lab Setup — 20 students
