1. What is a PCB Trace Width Calculator?

Definition: This calculator determines the minimum width of a printed circuit board (PCB) trace needed to carry a specified current without exceeding a given temperature rise.

Purpose: It helps electronics designers ensure proper current carrying capacity and prevent overheating in PCB traces.

2. How Does the Calculator Work?

The calculator uses the IPC-2221 formula:

Where:

• \( \text{Width} \) — Trace width (mils)
• \( I \) — Current (amps)
• \( \Delta T \) — Temperature rise (°C)
• \( \text{thickness} \) — Copper thickness (oz/ft²)
• \( k \) — Constant (0.048 for external, 0.024 for internal traces)

Explanation: The formula calculates width based on current, acceptable temperature rise, copper thickness, and trace location (internal/external).

3. Importance of Trace Width Calculation

Details: Proper trace width ensures reliable PCB operation, prevents overheating, and maintains signal integrity in electronic circuits.

4. Using the Calculator

Tips: Enter the current in amps, desired temperature rise (default 10°C), copper thickness (default 1 oz/ft²), and select trace location.

5. Frequently Asked Questions (FAQ)

Q1: What's the difference between internal and external traces?
A: External traces can dissipate heat better, hence the different k values. Internal traces require more width for the same current.

Q2: What's a typical temperature rise value?
A: 10°C is common, but higher values (20-30°C) may be acceptable for some applications.

Q3: How does copper thickness affect trace width?
A: Thicker copper allows narrower traces for the same current, as shown by the thickness exponent in the formula.

Q4: What are mils in PCB measurements?
A: 1 mil = 0.001 inch. Most PCB manufacturers specify trace widths in mils.

Q5: Does this account for high-frequency effects?
A: No, this is for DC/low-frequency current. High-frequency designs may need additional considerations.