10 Questions You Should to Know about multilayer pcb design tips

Author: Minnie

Sep. 09, 2024

The 10 most common mistakes to avoid in PCB design

The printed circuit board, or PCB, represents the heart and soul of any electronic circuit. Being responsible for the electrical connection between the components and the interfacing of the device with the outside world, it is evident that even the smallest design error can cause additional delays or costs during manufacturing, or even lead to the malfunction or complete failure of the circuit. The latest and most innovative design tools allow PCB manufacturers to significantly reduce, compared to the past, production costs. On some occasions, however, manufacturing costs can increase due to mistakes made in the PCB design phase. That said, it should be pointed out that errors are not unlikely even for the most experienced PCB designers ; our advice is to follow some simple rules to avoid repeating the ten most common design mistakes, which we will now describe.

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1 &#; Wrong trace geometry

PCB traces are responsible for transmitting electrical signals between the various components of the circuit, respecting precise constraints related to speed, current intensity and frequency of the signal. In this context, the geometry of each trace plays an essential role; in particular, it is necessary to appropriately size the width and thickness of each trace. When the current flowing through a trace exceeds the indicative value of 0.5 A, we can speak of a power transmission line, or a high current line. In this case, it is no longer possible to use the standard width used in low power circuits, but it shall be suitably sized using, for example, calculators based on the IPC- standard or later for internal (stripline) and external (microstrip) traces. It should also be noted that the traces placed on the external layers of the PCB can carry, at the same thickness, a higher current, as they can take advantage of a higher air flow and heat dissipation. The trace width depends on the amount of copper used for that layer. In addition to the width, the thickness of each trace must also be appropriately sized. Most PCB manufacturers allow you to choose from various copper thickness, from 0.5 oz/ft2 to 2.5 oz/ft2 and beyond. Many designers often choose the standard thickness value, corresponding to one ounce of copper (1 oz, corresponding to 35 µm). However, this value may not be sufficient for high power tracks, where a thickness of 2 or 3 ounces is typically used. The advantage of a greater thickness is to present a lower resistance to the passage of current, with a consequent improvement in thermal dissipation. The disadvantages are related to greater weight and the need for higher trace isolation.

2 &#; Inadequate layout

As the demand for ever-smaller printed circuit boards continues to grow, designers are forced to use components with smaller footprints and reduce the distance between components. If an inefficient layout is used, there is a risk of encountering connection or non-compliance issues. This is especially true when using components with smaller pitch and higher pin count. To ensure the desired functionality, it is very important to select a layout technique that suits the needs of the particular circuit. A very useful expedient is to put enough space on the PCB for additional components (or alternatives to the current ones), which may be needed in the immediate future. In case these additional components are not used, it is always possible to remove them before manufacturing.

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3 &#; Wrong position of the decoupling capacitors

Decoupling capacitors are required on the PCB power supply lines to ensure a stable power supply free from transients or oscillations to all board components. It is absolutely necessary that these capacitors are always connected in parallel with the power supply and placed as close as possible to the pins of the components that require power. The power line coming from the power source must be properly routed on the PCB, in order to get to the decoupling capacitor before going to the pin that needs a stable voltage. Note that, otherwise, the decoupling function cannot work properly; in fact, all voltage regulators use a feedback circuit which can oscillate if not adequately stabilized.

4 &#; Landing pattern errors

Although the terms landing pattern and footprint are often used interchangeably, there is a subtle difference between them. More precisely, the landing patterns refer to the size of the pads and, for each component, they should always have an area slightly larger than that of the corresponding footprint. Even a half-millimeter error in measuring pad-to-pad spacing can prove fatal in soldering during the manufacturing process, causing misalignments between components and PCB. The best PCB CAD software tools come with a large collection of libraries that include both the schematic symbol and the landing pattern for each component. If a component not included in these libraries is used, it is necessary to add by hand both the electrical symbol and the landing pattern for the PCB. At this stage, the possibility of making some mistakes is not uncommon; for example, if the distance between two pads is less than one millimeter, the pins will not align properly, making soldering impossible. Figure 1 shows the dimensions relating to the landing pattern for a component with PG-TQFP-64-19 package, obtained directly from the datasheet. Normally, electronic component manufacturers follow the requirements contained in the IPC-B standard (&#;Generic Requirements for Surface Mount Design and Land Pattern Standards&#;).

Figure 1: Example of specification for a landing pattern (Source: NXP).

5 &#; Over-reliance on automatic routing

For PCBs that are not too complex, some designers tend to rely on the automatic routing functionality, today offered by most PCB design tools. However, automatic routing tends to occupy a greater than desirable area of the PCB and to create via holes larger than what can be achieved with manual routing. It is a fact that the number of PCB tracks, along with the number of via holes, directly affects the PCB manufacturing cost.

6 &#; Blind or buried vias

Via holes are very convenient, as they allow to solve many complex routing situations and improve the PCB heat exchange; however, they must be used with caution and judgment. Blind vias (type &#;1&#; in Figure 2) must be used to connect an external layer with an internal one, while buried vias (type &#;2&#; in Figure 2) to connect two internal layers together. The through hole vias (type "3" in Figure 2) must instead be used only to connect the two external layers of the PCB and, possibly, some internal layer. To create a via hole, it is necessary to specify the overall size, hole size, tolerances, and other attributes. They can be created from templates, can be defined on the fly. It should also be noted that blind and buried vias involve a higher production cost, so it is advisable to plan their use in advance in order to respect the budget allocated to the PCB.

Figure 2: Types of via holes (Source: Altium).

7 &#; Excessive trace length

Traces carrying high speed signals should be as short and straight as possible. If the length is exceeded, there is a chance to encounter serious problems such as signal reflection (with direct consequences on the integrity of the signal), greater sensitivity to electromagnetic interference (EMI) and, obviously, higher costs. If the length of a trace exceeds a tenth of the wavelength of the signal that crosses it, we can speak of a transmission line. In this case, in addition to the length, it becomes essential to perform an impedance calculation (using one of the many dedicated tools, also available online) in order to ensure impedance coupling and avoid loss of signal power.

8 &#; Electromagnetic interference (EMI)

Electromagnetic interference is often caused by improper PCB design. To reduce EMI on a PCB, it is recommended to group elements according to their functionality, such as analog and digital blocks, power sections, low speed circuits, high speed circuits, and so on. In addition, it is necessary to reduce, or rather eliminate, the right angles on the traces, and use metal containers and shielded cables to absorb interference.

9 &#; Incorrect antenna layout

In case the PCB includes antennas for wireless communication, designers shall be very careful not to make layout mistakes. In order to maximize the power transfer, it is first of all necessary to adapt the impedance between the transceiver and the antenna. Normally, the transmission line connecting the transceiver with the antenna should have an impedance of 50 Ω. For accurate impedance adjustment, a Pi (LC) tuner filter, or any other matching circuit, should be placed between the antenna and the transceiver.

10 &#; Insufficient revision of the project

Often underestimated, design review is actually one of the most important elements in the PCB development process. The periodic reviews of the project allow to verify the conformity with the high- level requirements of the project, the functions assigned to the PCB and the interconnections between the various circuits. This allows designers to avoid, or detect in advance, the most common design errors; a peer review performed by other members of the development team is often able to spot mistakes the designer had not previously noticed.

10 Questions You Should to Know about multilayer pcb ...

Whether you are moving at a high speed or you're designing a high-speed printed circuit board, good board design practices help ensure your design will work as intended and can be manufactured at volume. In this guide, we've compiled some of the essential PCB board design and layout guidelines that apply to most modern circuit boards. Specialty designs may need to follow additional board layout guidelines, but the PCB layout guidelines shown here are a good place to start for most board designs.

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The guidelines shown here are focused on a few key areas that will help you with routing, manufacturability, basic signal integrity, and assembly:

When starting a new printed circuit board design, it&#;s sometimes easy to forget about the important design rules that will govern your project. There are some simple clearances that, if determined early in the design, will eliminate a lot of component shifting and re-routing later. So where can you get this information?

The first place to start is to talk to your PCB design rules fabrication house. A good fabricator will usually post their capabilities online or will supply this information in a document. If it's not in an obvious location on their website, send them an and ask for their capabilities. It's best to do this first before you start placing components. While you're at it, make sure to submit your proposed stack-up for review, or look for their standard stack-up data and use that.

Once you've found their list of capabilities, you should compare these to whatever industry reliability standard you'll work with (Class 2 vs. Class 3, or a specialty standard). Once these points are determined, you should select the more conservative design layout limits needed to ensure manufacturability and reliability, and you can encode these into your board design rules.

As you proceed through the layout process, your board design rules will help you eliminate most design errors that will lead to fabrication and assembly problems. After setting the board design rules, you can start the placement process.

The component placement stage of your PCB layout design process is both an art and a science, requiring a strategic consideration of the prime real estate available on your board. The goal in component placement is to create a board that can easily be routed, ideally with as few-layer transitions as possible. In addition, the design has to comply with the design rules and satisfy must-have component placements. These points can be difficult to balance, but a simple process can help a board designer place components that meet these requirements:

  1. Place must-have components first. There are often components that must be placed in specific locations, sometimes due to mechanical enclosure constraints or due to their size. It's best to place these components first and lock in their position before proceeding to the rest of the layout.
  2. Place large processors and ICs. Components like high pin count ICs or processors generally need to make connections to multiple components in the design. Locating these components centrally makes trace routing easier in the PCB layout.
  3. Try to avoid crossing nets. When components are placed in the PCB layout, the unrouted nets are normally visible. It's best to try and minimize the number of crossing nets. Each net intersection will require a layer transition through vias. If you can eliminate net crossings with creative component placement, it will be easier to implement the best routing guidelines for a PCB layout.
  4. SMD PCB board design rules. It&#;s recommended to place all surface mount device (SMD) components on the same side of the board. The main reason for this arises during assembly; each side of the board will require its own pass down the SMD soldering line, so placing all SMDs on one side will help you avoid some extra assembly costs. 
  5. Experiment with orientation. It's okay to rotate components to try and eliminate net intersections. Try to orient connected pads so that they face each other as this can help simplify routing.

If you follow points #1 and #2, it's much easier to lay out the rest of your board without too much crossover between routes. In addition, your board will have that modern look and feel to the layout, where a central processor supplies data to all the other components around the perimeter of a board.

The main processor in this PCB layout design is centrally located with traces routed out from the edges. This is the ideal placement of larger ICs and peripherals.

The main processor in this PCB layout design is centrally located with traces routed out from the edges. This is the ideal placement of larger ICs and peripherals.

With components placed, it&#;s now time to route power, ground, and signal traces to ensure signals have a clean and trouble-free path of travel. Here are some guidelines to keep in mind for this stage of your layout process:

It&#;s generally the case that power and ground are placed on two internal layers. For a 2-layer board, this might not be so easy, so you would want to place a large ground plane on one layer, and then route signals and power traces on the other layer. With 4-layer circuit board stack-ups and higher layer counts, you should use ground planes instead of trying to route ground traces. For components that need direct power connections, it&#;s recommended to use common rails for each supply if a power plane is not used; ensure you have wide enough traces (100 mils is fine for 5 to 10 A) and don't daisy chain power lines from part to part.

Some recommendations state that plane layer placement must be symmetrical, but this is not strictly required for manufacturing. In large boards, this might be needed to reduce the chances of warping, but this is not a concern in smaller boards. Focus on access to power and ground, as well as ensuring all traces have strong return path coupling to the nearest ground plane first, then worry about perfect symmetry in the PCB design stack-up.

Next up, connect your signal traces to match the nets in your schematic. PCB layout best practices recommend that you always place short, direct traces between components when possible, although this may not always be practical on larger boards. If your component placement forces horizontal trace routing on one side of the board, then always route traces vertically on the opposite side. This is one of many important 2-layer PCB board design rules.

Printed circuit board design rules and PCB layout guidelines become more complex as the number of layers in your stack-up increases. Your routing strategy will require alternating horizontal and vertical traces in alternating layers unless you separate each signal layer with a reference plane. In very complex boards for specialized applications, many of the commonly-touted PCB best practices may no longer apply, and you'll need to follow PCB board design guidelines that are particular to your application.

PCB layout designs use traces to connect components, but how wide should these traces be? The required trace width for different nets depends on three possible factors:

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  1. Manufacturability. Traces cannot be too thin, otherwise, they can't be reliably manufactured. In the majority of cases, you'll be working with trace widths that are much larger than the minimum value your fabricator can produce.
  2. Current. The current carried in a trace will determine the minimum required width to prevent the trace from overheating. When the current is higher, the trace will need to be wider.
  3. Impedance. High-speed digital signals or RF signals will need to have a specific trace width to hit a required impedance value. This doesn't apply to all signals or nets, so you don't need to enforce impedance control on every net in your board design rules.

For traces that don't need specific impedance or high current, a 10 mil trace width is fine for the vast majority of low-current analog and digital signals. Printed circuit board traces that carry more than 0.3 A may need to be wider. To check this, you can use the IPC- nomograph to determine your PCB design trace width for a required current capacity and temperature rise limit.

Preferred routing (arrows indicate component shifting direction)

 

Non-preferred routing (arrows indicate component shifting direction)

The ground plane can act as a large heat sink that then transports heat evenly throughout the board. Therefore, if a particular via is connected to a ground plane, omitting the thermal relief pads on that via will allow heat to conduct to the ground plane. This is preferable to keeping heat trapped near the surface. However, this can create a problem if through-hole components are assembled on the board using wave soldering as you need to keep heat trapped near the surface.

Thermal reliefs are one PCB layout design feature that might be needed to ensure a board will be manufacturable in a wave soldering process, or in other words, for through-hole components connected directly to planes. Because it can be difficult to maintain process temperatures when a through-hole is a solder point directly to a plane, it&#;s recommended thermal reliefs be used to ensure the soldering temperature can be maintained. The idea behind thermal relief is simple: it slows the rate at which heat is dissipated into the plane during soldering, which will help prevent cold joints.

 

The typical thermal relief pattern

Some designers will tell you to use a thermal relief pattern for any via or hole that is connected to an internal ground or power plane, even if it is just a small polygon. This advice is often overgeneralized. The need for a thermal via on any through-hole component will depend on the size of the copper plane or polygon that will make a connection on the internal layer, and it is something you should request your fabricator review before you place your board into production.

Through-hole pads on copper pour could require the same thermal pad application as planes. When the pour is very large, it starts to look a lot like a plane, and so a thermal pad should naturally be applied if a through-hole pin will be soldered into that connection.

For SMD parts, this is not always the case. Whether the thermal gets applied to the pour region depends on how the PCB will be assembled. A reflow soldering process will heat up the board uniformly as the device passes through the reflow oven, so the potential form tombstoning is much lower for those SMD pads, regardless of the presence of a thermal connection.

If the design will be assembled by hand, such as with solder paste and a heat gun, then the PCB layout might need thermals to trap enough heat near the pad and prevent tombstoning. When soldering by hand, it can be difficult to maintain consistent heating across the component leads, and a thermal connection can help prevent a tombstoning defect.

Thermal connection on a polygon in Altium Designer.

By default, Altium Designer will maintain thermal connections onto polygons when you create a new project. This is configured using the Polygon Connect rule in the PCB design rules editor. You can change this setting to apply based on specific footprints, layers, component classes, nets/net classes, or any other conditions using the query language in Altium Designer.

There are some routing guidelines for PCB design rules about how to group and separate components and traces so that you ensure easy routing while preventing electrical interference. These grouping guidelines can also help with thermal management as you might need to separate high-power components.

Some components are best placed in the PCB layout design by grouping them in one area. The reason is that they might be part of a circuit and they may only connect to each other, so there would be no need to place the components on different sides or areas of the board. PCB layout then becomes an exercise in designing and laying out individual groups of circuitry so that they can be easily connected together with traces.

In many layouts, you'll have some analog and some digital components, and you should prevent the digital components from interfering with the analog components. The way this was done decades ago was to split up ground and power planes into different regions, but this is not a valid design choice in modern board designs. Unfortunately, this is still communicated in many board layout guidelines and it leads to many bad routing practices that create EMI.

Instead, use a complete ground plane below your components, and do not physically break the ground plane up into sections. Keep the analog components with other analog components operating at the same frequency. Also, keep the digital components with other digital components. You can visualize this as having each type of component occupying a different region above the ground plane in the PCB layout design, but the ground plane should stay uniform in the majority of board designs.

Example of digital & analog sections in a PCB.

It is also appropriate to separate components that will dissipate a lot of heat on the board into different areas. The idea behind separating these high-power components is to equalize the temperature around the PCB layout, rather than to create large hotspots in the layout where high-temperature components are grouped. This can be accomplished by first finding the &#;thermal resistance&#; ratings in your component&#;s datasheet and calculating the temperature rise from the estimated heat dissipation. Heatsinks and cooling fans can be added to keep component temperatures down. You may have to carefully balance the placement of these components against keeping trace lengths short as you devise a routing strategy, which can be challenging.

It&#;s easy to get overwhelmed toward the end of your design project as you scramble to fit your remaining pieces together for manufacturing. Double and triple-checking your work for any errors at this stage can mean the difference between a manufacturing success or failure.

To help with this quality control process, it&#;s always recommended to start with your Electrical Rules Check (ERC) and Design Rules Check (DRC) to verify you&#;ve met all of your established constraints. With these two systems, you can easily define gap widths, trace widths, common manufacturing requirements, high-speed electrical requirements, and other physical requirements for your particular application. This automates PCB design layout review guidelines for validating your layout.

Note that many design processes state that you should run design rule checks at the end of the board design phase while preparing for manufacturing. If you use the right design software, you can run checks throughout the design process, which allows you to identify design potential problems early and correct them quickly. When your final ERC and DRC have produced error-free results, it&#;s then recommended to check the routing of every signal and confirm that you haven&#;t missed anything by running through your schematic one wire at a time.

There you have it - our top PCB layout guidelines that apply to most circuit board designs! Although the list of recommendations is short, this guideline can help you get well on your way toward designing a functional, manufacturable board in no time. These PCB board design guidelines only scratch the surface, but they form a foundation for building upon and solidifying a practice of continual improvement in all your design practices.

If you want to get started with the best PCB board design software with a built-in rules-driven design engine that helps you stay accurate, use the advanced design tools in Altium Designer®. When a design is finished and ready to be released to manufacturing, the Altium 365&#; platform makes it easy to collaborate and share your projects.

We have only scratched the surface of what&#;s possible with Altium Designer on Altium 365. Start your free trial of Altium Designer + Altium 365 today.

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Modern Interface Experience

&#;I had not been exposed to much 3D PCB design capability in the past. As a relatively new ALTIUM user I have to say that designing flexible and rigid PCBs in 3D using Altium is a lot easier than I thought it would be. Trading 3D PCB layout design files with my mechanical cohorts for review has never been easier!&#;

Kelly Dack, CID+ CIT
PCB Designer / IPC Instructor

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