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What is the order of the 4 layer PCB?

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Liang

May. 13, 2024
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How do You Stack 4 Layer PCB? - LinkedIn

Introduction

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A 4 layer PCB (printed circuit board) refers to a PCB with 4 copper layers that are used to route signals and distribute power. Stacking a 4 layer PCB properly is important to ensure good signal integrity, reduce noise and crosstalk, and effectively manage power distribution.

In a 4 layer board, layers are typically stacked in the following order from top to bottom:


Top Layer

This is the topmost layer used for routing signals, components, and connectors. It is sometimes referred to as the component layer.

Layer 2

The second layer down is commonly used as a ground plane, providing a low impedance return path for signals routing on the top layer. A solid ground plane helps reduce noise.

Layer 3

The third layer is often used as a power plane for distributing power to different sections of the board. Splitting power planes allows for better power distribution and decoupling.

Bottom Layer

The bottom layer mirrors the top layer and is used for additional signal routing, routing of traces exiting the board, and for components and connectors.

4 Layer Stackup Configurations

There are several common 4 layer PCB stackup configurations that can be used depending on the needs of the design:

Signal-Ground-Power-Signal

This is a very common stackup used for mixed-signal or digital boards:

Layer Use Top Signals Layer 2 Ground Plane Layer 3 Power Plane Bottom Signals

The ground plane provides shielding between the top and bottom signal layers, and the power plane delivers power efficiently.

Signal-Power-Ground-Signal

Another option is to swap the power and ground planes:

Layer Use Top Signals Layer 2 Power Plane Layer 3 Ground Plane Bottom Signals

This provides good power distribution while maintaining a ground plane in the middle for shielding.

Ground-Power-Ground-Signal

For boards with high speed or RF signals, a stackup with ground planes sandwiching the power plane may be used:

Layer Use Top Ground Plane Layer 2 Power Plane Layer 3 Ground Plane Bottom Signals

The double ground planes prevent noise coupling and improve signal integrity at high frequencies.

Signal-Ground-Signal-Power


Another high frequency stackup option is:

Layer Use Top Signals Layer 2 Ground Plane Layer 3 Signals Bottom Power Plane

The ground plane provides shielding between the two signal layers.

Layer Stackup Design Considerations

Here are some key factors to consider when designing the layer stackup in a 4 layer PCB:

  • Signal integrity - Ensure adequate isolation and shielding between critical or high-speed signals to prevent crosstalk or EMI problems. Use ground planes between signal layers.
  • Power integrity - The power plane layer should distribute power evenly to different sections of the board. Use multiple power planes or splits if needed. Decouple power planes with bypass capacitors.
  • Heat dissipation - The layer stackup impacts heat spreading and cooling. Place low power layers next to high power layers to help dissipate heat.
  • EMI - Adding ground planes helps block EMI emissions and prevent external EMI from disrupting sensitive circuits. Minimize slots or openings in ground planes.
  • Component placement - Consider component placement and routing needs when deciding layer usage. Critical traces may need to be routed on inner layers.
  • Manufacturability - Simpler layer configs are easier to manufacture. Also consider fabrication shop capabilities.
  • Future expandability - If designing an evolutionary product, consider future layer stackup needs and high-speed signals.
  • Cost - More layers increase cost. Balance performance needs with budget.

4 Layer PCB Routing Tips


Here are some useful routing practices for a 4 layer board:

  • Route critical signals on inner layers adjacent to a ground plane whenever possible. This provides shielding and isolation.
  • Route traces orthogonally between layers to avoid overlapping traces and crosstalk.
  • Flood unused areas on signal layers with ground to provide additional shielding and EMI reduction.
  • Use vias to transition signals between layers. Minimize the number of vias used.
  • Avoid routing signals through cutouts or splits in the ground/power planes. This can cause noise coupling.
  • Use thicker traces for high current power nets, especially near connectors.
  • Include stitching vias around the edges of the board to connect ground and power planes. This improves bypassing.
  • Route traces perpendicular to slots or openings in planes. Avoid routing signals parallel to slots.
  • Use blind and buried vias when possible to optimize routing between inner layers.
  • Assess RF designs for transmission line effects. Control impedance with trace width/spacing.

Following good layout practices for a 4 layer PCB will help ensure the board meets all of its signal and power integrity requirements.

Example 4 Layer PCB Stackups


Here are a few examples of typical 4 layer PCB designs and their layer stackup configurations:

Digital Electronics Board

This board has both digital and analog circuits and needs to manage moderate speed signals and power requirements. A signal-ground-power-signal stackup is used:

Layer Use Top Digital and Analog Signals Layer 2 Ground Plane Layer 3 3.3V and 5V Power Bottom Mixed Signal Routing

The ground plane isolates the top and bottom layers. The power plane distributes multiple voltages.

RF Transceiver Board

To maintain signal integrity at high RF frequencies, this wireless board uses a ground-power-ground-signal stackup:

Layer Use Top Ground Plane Layer 2 3.3V Power Distribution Layer 3 Ground Plane Bottom RF Circuits and Traces

The double ground plane configuration shields the RF components and traces from EMI and crosstalk.

High Speed Data Acquisition Board


With multi-gigabit data channels, a signal-ground-signal-power configuration is used:

Layer Use Top Analog Signals Layer 2 Ground Plane Layer 3 Digital Signals Bottom 5V and 3.3V Power

This provides isolation between the analog and digital signals, minimizing interference.

Summary

  • A 4 layer PCB is stacked starting with signals on the top, followed by ground, power, and bottom signal layers.
  • Key stackups are signal-ground-power-signal, signal-power-ground-signal, ground-power-ground-signal, and signal-ground-signal-power.
  • Carefully consider signal integrity, power delivery, thermal design, EMI, component placement, manufacturability, and cost when selecting the layer configuration.
  • Use good routing practices on 4 layer boards like orthogonal traces, minimizing vias, flooding with ground, and proper via transitions.
  • Choose a 4 layer stackup that is optimized for the design requirements like RF performance, high-speed signals, power levels, etc.

FAQ

What is the most common 4 layer stackup?

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The most common stackup is signal-ground-power-signal. This provides a good balance of shielding, signal routing, and power distribution for many mixed signal PCB designs.

How do you decide on 4 layer stackup?

Consider factors like signal types (digital, RF, analog), speed and isolation requirements, power levels, thermal design, EMI, manufacturability, and cost constraints. Choose a stackup that optimizes for the critical design parameters.

Is 4 layer better than 2 layer?

4 layer PCBs provide better performance than 2 layer for many designs. The additional ground and power planes improve shielding, power delivery, and heat conduction. 4 layers can support more complex, higher speed designs. However, 4 layers are also more expensive.

What is the best material for a 4 layer PCB?

FR-4 glass epoxy is the most common and cost effective material for 4 layer PCBs. For boards with very high speeds (> 5Gbps), RF signals, or special thermal/mechanical needs, materials like polyimide, ceramic filled epoxy, or Rogers laminates may be preferable.

How do you design a 4 layer board?

Start by planning the layer stackup and usage. Use CAD best practices for trace routing, plane design, via transitions, and component placement. Run signal and power integrity simulations. Accurately specify characteristics like trace widths, dielectric materials, finishes, and board thickness for fabrication. Review with your PCB manufacturer.

4 Layer PCB - Stackup & Prototype

4 Layer PCB - Stackup & Prototype

What is a 4 layer PCB

4 layer PCB means there are 4 layers to rout electrical signals: Top Layer, Inner Layer 1, Inner Layer 2 and Bottom Layer. TOP and bottom layers are the outer layers where we are placing components and routing. Inner layer 1 and inner layer 2 are in the core, and normally used as power planes or used for signal routing. Therefore, 4 layer PCB = 3 Signal layer + GND layer or 4 layer PCB = 2 signal layers + a VCC layer + a GND layer.


4 Layer PCB Stackup

For a 4 layer PCB, why are the power and ground planes usually inner layers, while traces are on the outer layers?

Solid power and ground planes are good to reduce EMI emissions and can enhance the quality of the signal on the traces. Moreover, connecting components to the planes is much simpler than to route the power and ground trees with traces. The stackup with grounds on outer layers is said to be best from EMC perspective.

Connections between components tend to be clustered locally, and those local connections will have a fairly good chance of being routable on just one layer. If you put all the traces on the inner layers, you will require a via for all the signals to go from the component to the signal layers.

For example, when using SMD components, the connections are on the same layer as the component, so that there is not need for a via or through-hole pad. In space-constrained designs, you are able to put more circuitry on the other side of the board.

4 Layer PCB Board

SMT circuity is always on the surface, if your power and GND were outside, you have to continuously break it up for the parts being placed. Besides, it is really difficult to debug, if you put the power and GND planes on the outside of a board. For RF layout, the rules are different for a trace on the outer layer of a board than on the inner layers of a board. It is possible to use fewer layers if you're doing microstrip routing.


2 Types of 4 Layer PCB Stackup

The standard 4 layer pcb stackup is as following and GND and VCC can be switched depending on the layer with more signals.

Signals

GND

VCC

Singals

If you don’t want to connect all ground pins through vias, there is a different stack-up and the power is being routed with wide traces on the signal planes.

GND

Signals

Signals

GND

This may be a better stack-up with a four layer PCB, for the following reasons:

1. Signal layers are adjacent to ground planes. A signal running over a reference plane, whose voltage happens to be at VCC will still return over that reference plane.

2. Signal layers are tightly coupled to their adjacent planes.

3. The ground planes can act as shields for the inner signal layers. You'll get better results keeping your trace to plane height as low as possible.

4. Multiple ground planes lower the ground (reference plane) impedance of the board and reduce the common-mode radiation.

When a high speed signal changes reference plane, there ought to be a nearby path for it's return current to move between the two reference planes. With two ground planes you can do that with a single via connecting the two planes directly. With ground and power planes the connection has

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