| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Seeed |
GROVE BEGINNER KIT FOR ARDUINO E |
99 |
|
 |
Seeed |
GROVE SMART AGRICULTURE KIT WITH |
0 |
|
 |
Seeed |
GROVE STARTER KIT FOR ARDUINO |
1 |
|
 |
Seeed |
TETRIS MICROCARD |
16 |
|
 |
Seeed |
MICROSOFT IOT GROVE KIT |
91 |
|
 |
Seeed |
GROVE KIT WIN10 IOT CORE & AZURE |
1 |
|
 |
Seeed |
ARDUBOY GAME KIT ARDUINO |
5 |
|
 |
Seeed |
GROVE STARTER KIT FOR LINKIT ONE |
1 |
|
 |
Seeed |
MOTOR PACK FOR ARDUINO |
0 |
|
|
Seeed |
GROVE STARTER KIT FOR AZURE SPHE |
0 |
|
|
Seeed |
GROVE ZERO_EXPLORER KIT |
0 |
|
|
Seeed |
KITTENBOT MEOWBIT CARDSIZED GRAP |
0 |
|
|
Seeed |
PIXHAWK4 DIGITAL AIR SPEED SENSO |
0 |
|
|
Seeed |
PIXHAWK 4 |
0 |
|
|
Seeed |
SEEEDSTUDIO DEEP LEARNING STARTE |
0 |
|
|
Seeed |
PIXHAWK4 MINI FLIGHT CONTROL |
0 |
|
|
Seeed |
GROVE STARTER KIT FOR WIO LTE |
0 |
|
 |
Seeed |
BASIC ELECTRONICS KIT FOR FABLAB |
0 |
|
 |
Seeed |
PIPER COMPUTER KIT |
0 |
|
|
Seeed |
NCC S1+ ROC-RK3399-PC AI PACKAG |
0 |
|
Educational Kits refer to modular learning systems combining hardware and software components for STEM (Science, Technology, Engineering, Mathematics) education. These kits enable hands-on experimentation and prototyping, fostering technical literacy and innovation skills. Their importance in modern education stems from bridging theoretical knowledge with practical implementation, aligning with Industry 4.0 requirements for digital literacy and system integration.
| Type | Functional Features | Application Examples |
|---|---|---|
| Electronic Prototyping Kits | Microcontrollers, sensors, breadboards, and circuit modules | Arduino Starter Kits for robotics projects |
| Mechanical Engineering Kits | Gears, linkages, motor drivers, and structural components | VEX Robotics Competition systems |
| Programming & AI Kits | Single-board computers, ML accelerators, vision modules | Raspberry Pi AI Vision Kits |
| STEM Foundation Kits | Basic electronics, simple machines, and measurement tools | LEGO Education Simple & Powered Machines |
Typical educational kits contain: - Core Controller: Microcontroller (Arduino Uno, ESP32) or SBC (Raspberry Pi) - Peripheral Modules: Sensors (temperature, light, motion), actuators (motors, servos), and display units - Structural Elements: Laser-cut acrylic panels or 3D-printable components - Power System: Battery packs and voltage regulation circuits - Software Suite: IDEs (Arduino IDE, Scratch), firmware libraries, and simulation tools
| Parameter | Description | Importance |
|---|---|---|
| Component Compatibility | Standardized interfaces (I2C, SPI, GPIO) | Enables system expansion and third-party integration |
| Processing Power | Clock speed (16MHz-1.5GHz), RAM (256KB-4GB) | Determines complexity of programmable tasks |
| Sensor Resolution | Analog/digital precision (8-16bit) | Affects measurement accuracy and control granularity |
| Power Requirements | Operating voltage (3.3V-12V) | Dictates safety classification and peripheral selection |
| Educational Standards | NGSS (Next Gen Science Standards) alignment | Ensures curriculum relevance and pedagogical effectiveness |
Primary sectors include: - K-12 Education: Classroom STEM labs with LEGO Mindstorms or Codey Rocky - Higher Education: Engineering prototyping using NI myRIO devices - Maker Spaces: Community workshops with open-source hardware platforms - Corporate Training: Industrial automation simulation with Festo Didactic systems
| Manufacturer | Flagship Product | Key Features |
|---|---|---|
| Arduino | Arduino Education Starter Kit | Modular electronics with Tinkercad integration |
| Raspberry Pi Foundation | Raspberry Pi 400 Kit | Keyboard computer with Python programming environment |
| Makeblock | Makeblock Ultimate 2.0 | 10-in-1 robotics platform with mechanical/electronic components |
| Parallax | Parallax ActivityBot | Propeller multicore processor with robotics curriculum |
Key considerations: - Educational Objectives: Match complexity to learning outcomes (basic electronics vs. AI) - User Proficiency: Choose age-appropriate abstraction levels (Scratch vs. C++) - Budget Constraints: Balance performance with cost (entry-level vs. professional kits) - Scalability: Verify expansion options through available shields/accessory modules - Support Ecosystem: Evaluate documentation quality and community resources
Case Study: A university engineering department adopted the Texas Instruments MSP432 LaunchPad for embedded systems courses due to its industry-grade ARM Cortex-M4F processor and integration with MATLAB/Simulink for control system modeling.
Emerging developments: - AI Integration: Embedded machine learning modules (Google Coral TPU integration) - Web-Based Platforms: Browser-accessible IDEs with real-time collaboration - Cross-Disciplinary Focus: Biotechnology kits merging electronics with living systems - Sustainability Emphasis: Recyclable components and energy efficiency monitoring - Cloud Connectivity: IoT-enabled kits with AWS/GCP integration for remote data analysis