✨ Overview

This discussion is a **comprehensive collection of complete PCB designs**, ranging from initial **Proteus circuit designs** to **fabricated PCBs**. Each project includes **simulation screenshots**, **production-ready Gerber files**, and where possible, **images from real-life production**. Whether you're looking to study PCB layouts or simulate circuits in **Proteus**, this repository has everything you need to get started with PCB design and prototyping.

🏭 Simulations

Each project includes fully designed PCBs ready for production. View and simulate circuits using Proteus before converting to PCB.

🏭 PCB

Where applicable, you’ll find images of the **fabricated PCB** to compare the final product.

Recent Updates

Recent:

Portfolio of Photos:

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πŸ–ΌοΈ Features:

Proteus Simulation Example
  • Complete PCB Designs: Each project includes fully designed PCBs ready for production.
  • Proteus Simulations: View and simulate circuits using Proteus before converting to PCB.
  • Test Screenshots: Every PCB design is accompanied by **test-time screenshots**, proving real-world functionality.
  • Real Production Images: Where applicable, you’ll find images of the **fabricated PCB** to compare the final product.
  • Gerber Files Included: Exportable **Gerber files** are provided for each PCB design, ready for manufacturing.
  • Detailed Bill of Materials (BOM): Comprehensive BOMs ensure all required components are listed for easy production.
  • 3D PCB Visualization: View your PCB in 3D to understand the component placement and overall structure.

πŸ“„ Included Files

πŸ”§ **Proteus Simulation Files**: `.pdsprj` files for every circuit design, allowing you to simulate the project in **Proteus**. πŸ–₯️ **PCB Layouts**: `.pcb` files for complete **PCB designs**, ready for export to Gerber. πŸ“¦ **Gerber Files**: Exportable **Gerber files** (`.gbr`) for direct use in PCB fabrication. πŸ“Έ **Test-Time Screenshots**: Real-time simulation screenshots in `.png` format showing functionality during testing. πŸ–ΌοΈ **Production Images**: Photos of the fabricated PCB, where available, to showcase the end product.

βš™οΈ Using ISIS for Circuit Simulation

Step 1: Create a New Project

File > New Project: Create a new project and give it a meaningful name.

Choose a location to save your project files.

Step 2: Add Components

Component Mode (P): Click on the component icon or press 'P'.

Use the search bar to find specific components (e.g., resistors, capacitors, ICs).

Select the component and place it on the workspace.

Step 3: Connect Components

Wire Tool (W): Click on the wire tool icon or press 'W' to draw connections between component pins.

Click on a pin to start the wire and then click again on another pin to connect.

Step 4: Configure Component Properties

Double-click on a component to open its properties dialog.

Adjust parameters as needed (e.g., resistance values for resistors).

Step 5: Run the Simulation

Click the Play button (β–Ά) to start the simulation.

Utilize virtual instruments like oscilloscopes and multimeters to observe circuit behavior.

Modify your circuit if necessary and re-simulate to see changes.

Step 6: Save Your Work

File > Save: Regularly save your project to avoid losing changes.

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Recent Updates

Recent:

Portfolio of Photos:

πŸ‘₯ Tips for Effective Use of Proteus

🎯 Explore Tutorials**: Look for [video tutorials](https://www.youtube.com/results?search_query=proteus+tutorial) and documentation on the Labcenter website or YouTube to see **Proteus** in action.

Highlights:

  • Experiment with Components**: Don’t hesitate to experiment with different components to deepen your understanding.
  • Use Libraries**: Proteus has a vast library of components. Utilize these to streamline your designs.
  • Simulation Features**: Make the most of various simulation tools, like [logic analyzers](https://www.labcenter.com/logic-analyzer/) and virtual instruments, to accurately analyze circuit performance.
H-Bridge Circuit Diagram



About App Inventor

H-Bridge Circuit Diagram

MIT App Inventor is a web-based application that allows users to create Android apps using a blocks-based programming language. It's an excellent tool for educators and learners to understand programming and app development fundamentals.

Key Features:

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H-Bridge Circuit Diagram

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H-Bridge Circuit Diagram

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