Top 12 Considerations to Know Before PCB Layout

High quality of PCB design or layout will take much convenience to PCB fabrication & manufacturing process, and improve the ratability of the SMT assembly process

The guidelines shown here are focused in a few key points that will help you with routing, manufacturability, basic signal integrity, and PCB assembly.

1. The spacing size between SMD components

Enough spacing between SMD components is the first important thing that PCB layout engineer need to take care. Too small spacing would raise up the difficulty of solder pasting and take soldering joints between soldering PAD. Below is some proposed spacing for designer’s reference.

Spacing L

Spacing for SMD components:

Homogeneous SMD components: ≥0.3mm
Heterogeneous SMD components: ≥0.13*H+0.3mm(H for maximum height difference of neighboring components)

Spacing for hand-soldering components: ≥1.5mm

Above spacing is reference to PCB designer for layout work from WELLER, different PCB assembler have different SMT capabilities.

2. The spacing size between SMD and Through hole components

SMD-through hole

Refer above picture illustration; enough spacing should be layouted between DIP and SMT components, proposed spacing is 1-3mm. Today, less and less though-hole components applied into electronic devices design due to it’s complicated soldering process and expensive cost.

3. The placement of IC’s decoupling capacitors

A decoupling capacitor (also called bypass capacitor) is a capacitor used to filter high-frequency noise in power supply signals.

Decoupling capacitors

Proposal: Decoupling capacitor placed as close as possible to an integrated circuit (IC) on a PCB layout. Each power supply port need to match one decoupling capacitor if multi power supply ports exists to IC

Decoupling capacitorsp PCB layout

4. The importance of orientation and spacing of the components close to boarder

Commonly, PCB panelization is preferred both by PCB fabrication house and PCB assembler. As PCB manufactured by panel can optimize the material utilization to reduce the manufacturing cost; also, to it can improve Contract Manufacturer (CM) efficiency at the SMT assembly process.
Two basic premises in layout must be met for PCB panel:
4-1. The components neighboring to the PCB boarder must be parallel with board outline( this will lead components to afford uniform mechanical stress from de-panelizing; for example, the components at the left aside in above picture could be dropped off it’s soldered PAD from the process of de-panelizing due to withstanding the Non-Uniform mechanical stress.
4-2. Do not place the component at the zone close to the PCB boarder(avoid damaging components when de-panelizing working panel).

The components to PCB boarder

5. Optimizing the continuous connecting PAD

If some serial SMD PADs need to be connected each other, design them by Serpentine Routing instead of direct bridge connection. And the width of the track need to be cared.

Optimizing PAD

6. Heat (thermal) Dissipation to the PAD on the certain regions must be cared

Obviously, better heat (thermal) dissipation, better working performance of the electronic devices. So, the designer must take high care to how to design and layout PCBs to prevent heat from accumulating in certain regions, which over time lead to serious failures, perhaps even causing could catch fire. Even if nobody is hurt, that boring heat can affect performance and damage the components. Therefore, it is very necessary to take care Heat (thermal) Dissipation to the thermal PAD when do PCB design or layout.


If the PADs locate in the common region, the right solution at above picture is the better option, chose 1 track or 4 tracks pending on the currency volume. If using the left solution at above picture, it could cause some difficulty in repairing or disassemble the components, as the temperature of dis-soldering could be dissipated by the large copper ground and lead to the hardness of dis-soldering.

7. PCB Teardrops in Your Layout

A teardrops are extra copper with some certain shapes used in a PCB layout is to provide extra strength so that the vias can be enough strong to withstand thermal and mechanical stress. Especially the regions at the junction of a pad or via and a trace line, or when a trace routing between wide and narrow. For example, if part of your trace line width is changing from 10 mils to 4 mils, then the teardrop is necessarily to be added at the transition point to reduce any potential stress or hairline cracks.

The advantages of teardrops
7-1. Avoid the reflected signals from sudden narrowed transition trace line, keep the smooth and steady between junction connecting between trace and PAD.
7-2. Avoid the hairlines and cracks from impact stress between PAD and trace.
7-3. Facilitate in etch process in PCB manufacturing.

8. Consistent trace width between soldering PAD

Consistent trace

The each trace connected to the PAD should have the same width of size.

9. Leave unused PAD and connect them to electrical ground

Un-used PAD

The un-used PAD should be kept at there, and correctly connect them to Electrical Ground.
For example, two pins of the IC chips on above picture are non-functional pad, but they are existing on the IC chips. It could cause signals interference if no connection to electrical ground.

10. Avoid the via holes on the solder PAD.

Via in PAd

If it is no choice, it is better not to put your via holes on the soldering PAD, this will cause soldering problem due the leaking solder from the hole; or else, PCB manufacturer have to use VIA IN PAD technology to avoid this problem but manufacturing cost raise up and lead time would be longer.

11. Enough spacing between trace or components and PCB boarder

Track to PCB boarder

Keep the spacing as large as possible between the track or components to the PCB boarder. Especially for single layer PCB which most large paper base material, the components or track closely placed to the boarder would be impacted from mechanical stress.

12. Electrolytic capacitor placed as far as possible to some possible heat source

Electrolytic capacitor