Step 1 – Design Preparation
The first stage of PCB design is preparation. Our engineers review the schematic provided by the client to confirm whether it is ready for layout. We check the completeness of component information and verify important PCB requirements such as board size, number of layers, and design constraints.
If the client only provides a PDF or image schematic, we will redraw it in professional EDA software.
If the source schematic file is available, we directly generate the netlist and move on to the layout stage.
This step ensures a strong foundation for a smooth PCB layout process.
Step 2 – Component Placement
The second step of PCB layout is component placement, which plays a critical role in ensuring both performance and manufacturability of the circuit board. In this stage, all components—such as ICs, resistors, capacitors, and connectors—are positioned logically on the PCB.
Fixed-position components (e.g., connectors, mounting holes) are placed first since their location is usually determined by mechanical design.
Core devices (such as CPUs, FPGAs, or microcontrollers) are placed next, with supporting circuits arranged around them for optimal performance.
During placement, we carefully consider signal flow, thermal management, and electromagnetic interference (EMI) to reduce noise and improve stability.
Step 3 – Routing
PCB routing (also called trace routing) is the process of connecting all components with copper traces according to the schematic. This stage requires precision and is often the most time-consuming step in PCB design.
Power and ground planes are routed first to ensure system stability.
Critical signal lines (such as high-speed differential pairs, and buses) are routed with impedance control and length matching.
General signal lines are routed afterward, following design rules for trace width, clearance, and via usage.
Proper routing ensures high-speed performance, reduced signal interference, and compliance with manufacturing standards.
Step 4 – Post-Processing and Verification
After routing is complete, we refine and verify the layout through post-processing steps:
Copper pour (ground/power planes): for better grounding, shielding, and thermal performance.
Silkscreen optimization: to make reference designators clear for assembly.
DRC (Design Rule Check): to ensure there are no spacing violations or layout errors.
This stage guarantees that the PCB layout meets both electrical and mechanical requirements.
Step 5– Gerber Output
We will send the layout file to client to reivew. Once the design is approved, we generate Gerber files, which are the standard output format for PCB manufacturing. These files include:
Gerber layers (copper, solder mask, silkscreen, etc.)
Drill files for vias and holes
Bill of Materials (BOM) and pick-and-place files
By delivering Gerber files along with BOM and drill data, we ensure the PCB can be fabricated by any professional manufacturer.
Step 6 – Production
The final step is PCB manufacturing. With Gerber files, drill data, and BOM, the PCB manufacturer fabricates the physical board. A high-quality PCB layout file ensures smooth production, minimizes risks, and helps achieve faster time-to-market.
PCB layout design is much more than just drawing traces. It requires systematic planning, professional knowledge, and strict verification to guarantee that the final PCB is manufacturable, reliable, and high-performing.