PNC Online Blog: May 2023

Wednesday, May 24, 2023

Best Printed Circuit Board Routing Practices

Auto routing is an incredible tool for PCB design. It can save time and money, as well as reduce the risk of errors in the design. But, after completing the auto-routing process, you must remember that some manual routing is still necessary to ensure the best performance and reliability for your circuit board. In this article, we will explore the best practices for Printed Circuit Board routing after auto routing goes the distance. We will see what kind of manual routing is necessary, how to go about it, and why it’s important.

Assess the Quality of Your Auto-Router’s Work

Before you begin the process of editing or manually routing your design, you must assess the quality of the work completed by your auto-router. If your design has a lot of violations or errors, then it’s likely that manual routing is going to be necessary. To assess the quality of your auto-routed design, start by checking for errors. Make sure you properly connected all the tracks and that there are no shorts or open circuits.

Also, check the placement of the routes to ensure that they have the right width and direction. You must make sure that there are no sharp corners in the traces, as these can create stress points and reduce the reliability of your circuit. After completing this assessment, you’ll have a better idea of how much manual routing you need to complete your design.

Edit Your Design to Clean Up the Auto-Router’s Mistakes

When you auto-route your PC Board, it is important to review and clean up the results before sending it off for manufacturing. This is especially true if the auto-routing process got off center, leaving you with an excessively long or inefficient route. Before doing any manual routing, take some time to examine the auto-router’s work and make any necessary corrections.

First, check for violations of routing rules like clearance, width, and length rules. Make sure that the auto-router didn’t miss any components or create any neglected sections of traces. Then, look for any vias that you can replace with direct routing or traces that are easy to shorten to increase efficiency. You should also visually inspect the entire board layout to ensure everything looks reasonable and follows good design principles.

After editing your design to fix any errors, it is time to move on to the manual routing process. Be sure to take your time and double-check all your work before sending it off to a manufacturer. This extra effort can save you time and money down the road.

Manually Route Any Difficult or Important Signals

Manually routing signals is always the best way to ensure that you’re PCB will function correctly. Even though auto-routing can help complete most of the work, it’s important to manually route certain signals to achieve a high-quality design. This includes difficult or important signals such as the clock or power signals which require special attention.

When manually routing a signal, you must make sure that there is enough spacing between the tracks to ensure that the signals won’t be interfered with by any other nearby signals. Moreover, if you are routing high-frequency signals, you should ensure that the impedance of the track is correct for those frequencies.

Make sure that the routing of the signal is in the most direct manner possible. This minimizes the amount of noise picked up by the signal and helps reduce crosstalk between other traces on the board. Routing the high-speed signals manually also helps minimize trace inductance, which can cause ringing on the signals and increase noise levels.

By taking the time to manually route certain signals, you can ensure that your design will be reliable and high quality. Moreover, you can use techniques such as differential pairs and impedance matching to further enhance the performance of these sensory signals. You may want to consider setting aside some extra budget when designing your PCB with manual routing. As the process can be more costly than auto-routing.

Moreover, before going into production, you must double-check that all the signal routes are correct. Using software tools such as DRC (Design Rule Checking) can help identify any errors to fix them before the board goes into production. Doing this will help ensure that your final product is of the highest quality and able to meet your performance requirements.

Check Your Work For Errors Before Sending It To Fabrication

Making sure your design is free of errors before sending it to fabrication is essential for the success of your PCB. During the auto-routing process, small errors can occur and the manufacturer would reject your design. To avoid this, you should double-check your design for any errors before sending it to the manufacturer.

To check for errors, you should use a combination of inspection tools, such as visual inspections and electronic rule-checking (ERC) software. Visual inspections involve examining the traces and components on the board. Whereas the ERC software checks your design against a set of rules defined by the manufacturer.

Inspecting your board manually can help you identify issues with the routing that an auto-router could not detect. For example, if two traces cross without via, you should add one to prevent shorts and crosstalk. If you notice any errors, such as incorrect trace widths or spacing, make sure to adjust them accordingly before sending your design to the manufacturer.

Also, ensure that your design meets the manufacturer’s requirements before sending it out for fabrication. The design should be compliant with their minimum trace widths, spacing, drill sizes, and more. If the design is not compatible with manufacturing parameters, it can result in costly delays and rejections, which could easily have been avoided.

How to find that PCB design is according to the manufacturer’s requirements

You can do it by checking the size of your design. Make sure that all components fit within the PCB dimensions and have the right placement. Then, make sure that any traces or vias are wide enough for your manufacturer’s specifications. In the case of auto-routing, you must check for any clearance issues between traces. This can help you spot any potential problems before sending your board off for fabrication.

You should also review the data sheets to make sure that no noise or interference could affect the operation of your board.

By taking the time to ensure your design is compliant with the manufacturer’s requirements, you can help ensure a successful Circuit board fabrication process and save yourself from potentially costly delays down the line.

After confirming compliance, consider running some simulations to test your board’s performance under various conditions. This will allow you to see if there are any areas with crosstalk or power integrity issues. Moreover, if your board has high-speed signals on it, you may want to simulate its performance at various temperatures or levels of humidity.

Some Other Rules To Follow

You have to follow certain rules while making PCB layout as it will bring good results. So, let’s explore it further.

The traces should have as much direct and short routing, as you can do without affecting the design.
Try to route similar signals together, as the routing of RF and RF signals should be together. Similarly, two digital signals should also have the same route.
Try to route vias as simply as possible, such as BGAs, ball grid arrays, or some other types of vias.
Make sure to work according to the DFM guidelines to have perfect manufacturing.
In the case of high-power signals, you consider impedance and choose high-quality material while routing traces or determining the length.
Design Principles

The design standards of printed circuit boards keep on changing due to changing technologies. But, you can’t compromise on safety and quality in this regard. The design of the PCB involves certain principles that you have to follow to have an effective product. Let’s look at those principles.

The grid spacing should be precise
The traces should be direct and shortest possible.
You should be careful about power distribution
Try not to have multiple grids
The placement of the components should be wise as it will make design and PCB inspection easy.
Make use of silkscreens in the best way to have more benefits.
Always try to follow the DRC (design rule check)
Try to avoid auto routers and go for manual work as much as possible if the budget allows you.

Wrap Up

When you auto-route the PCB, it is important to review and clean up the results before sending it off for manufacturing. This is especially true if the auto-routing process got off center, leaving you with an excessively long or inefficient route. Before doing any manual routing, take some time to examine the auto-router’s work and make any necessary corrections.

By taking the time to manually route certain signals, you can ensure that your PCB design will be reliable and high quality. Moreover, you can use techniques such as differential pairs and impedance matching to further enhance the performance of these signals.

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Thursday, May 18, 2023

Printed Circuit Board Backplane

Backplane PCBs are an essential component of many electrical systems, providing a convenient and efficient way to connect multiple printed circuit boards. We’ll explore the basics of backplane PCBs and discuss the process of fabricating them. Backplane PCBs vary in terms of types, construction materials, and the key steps in the fabrication process. After understanding all essentials, you can create a reliable, high-quality backplane Printed Circuit Board that meets your needs.

What is a Backplane PCB?

A backplane PCB, also known as a printed circuit board, is an interconnecting circuit board that helps support and provide electrical connections for multiple electronic components. The backplane PC Board provides a platform for connecting the individual PCBs that make up a larger electronic system. You can find the backplane PCBs in computers, servers, network switches, and routers.

The construction of backplane PCBs involves several layers of copper foil laminated together with an insulating material, such as glass-reinforced epoxy or polyimide. This combination of materials allows the backplane to be very durable and reliable. The copper traces that make up the interconnections are placed in specific patterns to create a flexible platform that can support various types of components.

The Various Types of Backplane PCBs

Backplane PCBs come in a variety of shapes and sizes to meet the requirements of any design. These include double-sided, multilayer, surface mount, and rigid-flex backplanes. Each of these types offers distinct advantages and disadvantages, depending on the application.

Double-sided Backplane: This type of backplane has two layers of PCB material being connected by an array of holes drilled through the board. The application of this type of board is popular for low-cost, high-volume products such as consumer electronics.

Multilayer Backplane: This type of backplane has multiple layers of printed circuit board material being connected by various types of wiring. You will see its application in complex designs where routing or high density is essential.

Surface Mount Backplane: This type of backplane consists of one or more printed circuit boards with direct mounting onto the outside of another board. This type of board is suitable for high-speed applications, such as communication systems or computer networks.

Rigid-Flex Backplane: This type of backplane consists of two different printed circuit board materials. One layer is rigid and the other is flexible, allowing for greater flexibility in design. The board is ideal for applications with a large number of connections or tight spaces.

By understanding the different types of backplane PCBs, designers can choose the right type for their application and ensure that their product has the best performance possible.

Backplane PCB Fabrication
The fabrication of backplane PCBs involves a subtractive process, such as the removal of unwanted material from a starting substrate to create the desired traces and connections on the board. The most common method of fabrication is a chemical etching process, where manufacturers bond the copper foil onto the substrate, exposing it to a photoresist to create a pattern. The resist protects the copper during an acid etching step that removes the unwanted copper, leaving only the desired traces and connections. You can do it either manually or with an automated machine.

The complexity of the design and the number of layers will determine the board layout. The design is usually laid out in multiple layers, with each layer representing a different circuit or electrical signal. All the layers are then bonded together, creating the complete backplane PCB. The bonding of the layers involves either a chemical or thermal process, depending on the application.

After bonding the layers together, you may need to attach additional components to the board. This can include mounting holes for screws, heat sinks for components, and connectors for external devices. Then comes the typical process of components soldering onto the board, while keeping some in place with other methods such as rivets or adhesives.

In the end, you have to test it to make sure it works correctly. This includes electrical tests such as continuity tests and power tests to ensure that all the connections are working correctly. After thorough testing, the board is ready to use in its intended application.

The Advantages of Using a Backplane PCB

Backplane PCBs offer many advantages over traditional printed circuit boards They provide greater flexibility in terms of design and layout, as well as the ability to support larger numbers of components. This makes them ideal for high-density applications such as telecommunications, medical, industrial automation, and computing.

Using backplane PCBs also offers several other benefits. You can use them to reduce wiring complexity and cost since they allow for fewer wires in an interconnected system. Moreover, they make it easier to route signals and power within a device, allowing for more efficient communication between components. Besides, they help have the simultaneous operation of multiple cards or modules, which is beneficial in applications that require multiple functions.

Moreover, backplane PCB can also help reduce the size and weight of the final product. This is especially beneficial in applications that require a small form factor, such as portable electronics or embedded systems. Moreover, you can improve the overall reliability of the system due to the added strength of the backplane substrate.

The Disadvantages of Using a Backplane PCB

The main disadvantage of using a backplane PCB is its limited flexibility. Since all of the components are directly connected to the backplane, it can be difficult to modify or add new components to the board. This makes them less suitable for applications that require frequent changes or upgrades. Besides, they are more complex and costly to manufacture than other types of PCBs.

Another downside is that they take up a lot of space. Since they involve multiple layers, they require more physical area than simpler boards. This makes them less suitable for applications where size is an important factor. Besides, the wiring and component placement on a backplane PCB is quite challenging, since there are several connections to consider.

Moreover, backplane PCBs can also suffer from signal interference. This occurs when the signals from one component interfere with those from another component, leading to system errors or data corruption. This is especially true in the case of adjacent components with poor shielding.

Development Trend of Backplane

As technology advances, the need for higher performance and better reliability of backplane PCBs is on the rise. As a result, manufacturers are continuously developing new designs, materials, and components for backplane PCBs to ensure that they can keep up with the changing needs of the industry. The main trends in the development of backplane PCBs include miniaturization, increased functionality, improved signal integrity, and increased thermal efficiency.

Miniaturization: One of the main trends in the development of backplane PCBs is miniaturization. As more and more electronics are packed into smaller and smaller spaces, backplane PCBs should keep up with the trend. By reducing the size of the components used in the backplane, engineers can reduce the board area, allowing more components to fit into a smaller space.

Increased Functionality: As devices become increasingly complex, backplane PCBs must also provide more functionalities. By increasing the number of pins and features, engineers can provide more features in a single device. This helps engineers to design and develop more sophisticated products that can meet the needs of the market.

Improved Signal Integrity: To ensure reliable signal transmission, engineers must ensure that their backplane PCBs have good signal integrity. This involves optimizing the board layout, as well as using proper signal routing techniques. By improving signal integrity, engineers can reduce noise and the risk of data loss or interference from other signals.

Increased Thermal Efficiency: Heat management is essential for any electronic device, especially those containing multiple components. To ensure that the system is not facing high heat, backplane PCBs should be designed with thermal management in mind. By optimizing board layout and component placement, engineers can ensure a quick and effective dissipation of heat.

These are just some of the trends that are impacting backplane PCB design and development today. By incorporating these trends into their designs, engineers can create products to meet the ever-changing needs of the industry.

Final Thoughts

A backplane PCB, also known as a printed circuit board, is an interconnecting circuit board that helps support and provide electrical connections for multiple electronic components. The backplane PCB provides a platform for connecting the individual PCBs that make up a larger electronic system. You can find the backplane PCBs in computers, servers, network switches, and routers.

Engineers use a backplane PCB to mount other types of PCBs, such as memory boards, processor boards, graphics cards, and storage devices. It also serves as a high-speed data bus between these components, providing faster communication and data transmission. Certain development trends can help engineers create products to meet the ever-changing needs of the industry.

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Monday, May 1, 2023

Bill Of Materials Management In PCB Design Process

Managing the Bill of Materials in the PCB design process can be a complex and time-consuming endeavor. Luckily, there are ways to make this process easier and more efficient. So, we will explore how to streamline BOM management in design so that you can save time and money. You will learn the best practices for maintaining an accurate BOM, methods for keeping track of changes, and tips for improving the overall design process. With these strategies, you can produce high-quality products faster and more effectively.

The Different Types of BOM

The BOM (Bill of Materials) is a document that lists all the parts, components, and materials that a product’s manufacturing requires. This includes all the parts used in assembling a product, such as the PCBs, capacitors, resistors, integrated circuits, etc. every industry needs the BOM, from automotive and aerospace to electronics and medical devices.

There are different types of BOMs, and the most common type is the pcb assembly BOM, which is used for producing products on an assembly line. This type of BOM contains detailed specifications and component information, such as the component type, quantity, and vendor information.

Another type of BOM is the engineering BOM, which is essential for design purposes and contains details about each component, such as electrical ratings, tolerances, and sizes.

The third type is the service BOM, which is necessary to keep track of spare parts or to identify which components need repair or replacement.

No matter what type of BOM you use, you should have an accurate and up-to-date list of all the parts used in the design and production process. Without an accurate list, you could end up with incorrect parts involving extra work while repairing or replacing them. Having a thorough understanding of the different types of BOMs will ensure that you can properly manage your products and design processes.

The BOM Management Process

Managing your BOMs correctly can help ensure that your designs are accurate and complete. Besides, it will minimize any potential errors or problems that could arise during the fabrication and assembly process.

The BOM management process typically begins with designing the PCB. This includes determining the parts that you will need for the design it also helps determine the components and their connections. Once the design is complete, you can create a BOM that outlines all the essential components and connections. The BOM should also include certain information, such as part numbers, descriptions, quantities, and other relevant details.

After creating the BOM, you have to send it to the manufacturer for review and approval. This step ensures that the manufacturer can accurately produce the board with all of the required components. After the review is complete and the BOM has been approved, you can send it to the supplier for ordering.

Throughout the entire process, it’s important to stay organized and maintain accurate records. This includes tracking changes to the BOM, ensuring that the parts are available and compatible with the design, and regularly updating the BOM as you require.

With a well-managed BOM system in place, it’s much easier to keep track of all of the components and connections in your design and ensure that everything is correct and up to date.

Having this level of detail and organization allows you to quickly troubleshoot any issues that may arise throughout the manufacturing process. Besides, having accurate BOM data makes it easier to identify discrepancies between what you ordered and what you received from the suppliers.

The most effective way to manage your BOMs is to use software specifically designed for this purpose. There are many different options available on the market today, so you should do some research to determine which one best fits your needs. These tools allow you to create detailed and organized BOMs quickly and easily, as well as keep track of changes over time. Moreover, some of these programs come with features like automated bill creation and interactive reports, making it even easier to manage your projects.

By streamlining your BOM management process through software solutions, you’ll save time and money in the long run.

Best Practices for BOM Management

BOM management is an important part of any PCB design process. To ensure accuracy and consistency, there are some best practices to follow when managing BOMs.

Start Early: Starting the BOM early in the design process allows for errors to be identified and corrected quickly. It also gives the design team time to make any necessary changes before the board goes into production.
Update Frequently: It’s important to keep the BOM updated as the design changes. Make sure the BOM reflects the changes like replacement or removal of any component.
Use Automation: Automating the BOM management process can help reduce errors and save time. You can use the automation tools such as software or scripts to generate, update, and manage the BOM.
Keep Records: Keeping records of all BOMs throughout the design process allows for quick reference and helps identify any inconsistencies.
Maintain Accuracy: The accuracy of the BOM is essential for the success of a PCB design. Check for any errors or typos in the BOM before sending it out for production.

Following these best practices for BOM management will ensure accuracy and efficiency in your design process. By implementing these practices early on in the design process. You can avoid costly mistakes and delays that can arise from using outdated or inaccurate BOMs.

Having accurate BOMs helps during testing and post-production analysis since they provide an accurate inventory of components used during manufacture. With proper BOM management processes in place, you’ll be able to complete projects faster while still producing high-quality products.

During the development stage, designers should always check the BOM against their schematic diagram to verify accuracy and compliance with industry standards. This verification process should take place after every step of the design process. Moreover, you should conduct it according to industry regulations.

When assembling the Printed Circuit Board, you should double-check the components against the BOM to ensure that nothing is missing. The testing should also involve verifying that all parts meet the specifications listed on the BOM.

After completing the design and assembly process, you should have one final review against the original BOM to make sure everything matches. Implementing these practices into your workflow will help streamline your bill of materials management. Eventually, it will result in a successful PCB project.

What Else To Consider

In addition to knowing the different types of BOMs, there are some other things to follow when managing them.

For example, always check the validity of any part numbers provided on the BOM. It is also wise to provide clear descriptions for any custom parts or non-standard items included in the list.

Furthermore, make sure any drawings or schematics referenced on the BOM are current and accurately reflect any changes made throughout the design process.

Also, carefully review any cross-references provided between components, especially if any of those components become obsolete or unavailable during the product life cycle.

By following these best practices, you will be able to streamline your bill of materials management in design. Doing so will make sure that any components specified are valid and accurately reflect any changes made during the design process, ultimately saving time and resources.

Frequently Asked Questions

What is BOM?

BOM means the bill of materials, and it is a document that lists all the parts, components, and materials that a product’s manufacturing requires.

What Is There In BOM Of A PCB?

A BOM includes all the parts used in assembling a PCB, such as capacitors, resistors, integrated circuits, etc.

What is a PC Board?

A printed circuit board or PCB is a way to provide signals to help an electronic device to function. It gives mechanical support to various parts of electronics.

What Is Schematic Drawing In PCB?

A PCB schematic is a diagram with symbols that define different components. It also shows the electrical connection of components.

What Are The Benefits Of BOM Management?

Maintaining accurate BOMs throughout the entire design cycle can help improve product quality. Moreover, if a project has multiple designers working on it, having well-maintained BOMs with each revision ensures everyone is up-to-date with the latest version.

Wrap Up

When it comes to design, Bill of Materials (BOM) management is an essential part of the process. There are different types of BOMs, and the most common type is the manufacturing BOM, which is used for producing products on an assembly line. This type of BOM contains detailed specifications and component information, such as the component type, quantity, and vendor information.

Using automation tools for BOM management can also speed up processes by making it easier to track components and changes. After creating the BOM, you have to send it to the manufacturer for review and approval. This step ensures that the manufacturer can accurately produce the board with all of the required components.

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PNC Online Blog

Wednesday, May 24, 2023

Best Printed Circuit Board Routing Practices

Wrap Up

Thursday, May 18, 2023

Printed Circuit Board Backplane

Monday, May 1, 2023

Bill Of Materials Management In PCB Design Process

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