A prototype is essentially an early sample of a product, built with the purpose of testing the design idea to see if it works. While most prototypes are made simply to test basic user functionality, PCB prototypes have the added need to be somewhat, if not entirely, functional. This is because PCB prototypes are made to test the total functionality of the design.
Different types of PCB prototypes are used to test different aspects of the design. Over the course of a project, a design team may use multiple PCBs at various stages of the design process. Some of these prototype types include:
·Visual models: Visual models are used to illustrate the physical aspects of the PCB design and show the overall shape and component structure. These are usually the first prototypes in the design process, and they are used to communicate and review the design in a way that is easy and affordable.
·Proof-of-concept prototype: Proof-of-concept prototypes are simple prototypes that focus on replicating the primary function of the board without carrying all of the capabilities of the final product. This kind of prototype is primarily meant to show that the design concept is viable.
·Working prototype: Working prototypes are functioning boards that contain all of the planned features and functions of the final product. These are usually tested to identify weaknesses or problems in the design and rarely represent what the finished product is going to look like.
·Functional prototype: Functional prototypes are meant to be as close to the final product as possible, providing the most accurate idea of what the design will look like and how it will work, with some basic material differences to keep prototyping costs low.
Engineers will usually work through this list from top to bottom throughout the design and testing process, starting with a visual model and ending with a functional prototype.
What are the benefits of PCB prototyping?
PCB designers use prototype PCBs throughout the design process, repeatedly testing the functionality of their solution with every new addition or change. But, why do designers choose to use PCB prototypes instead of going straight into standard production runs?
While it may seem like prototypes add several steps and costs to the process, prototypes serve important functions in the design process. Prototyping allows designers, their teams and clients to test at multiple stages of design and make adjustments as needed to tailor the solution before the full production run. This creates several advantages for the client and designers, which are detailed below.
1. Reduced Timeline
When developing a PCB design, engineers will go through several iterations before creating the final product. While this can create lengthy timelines, PCB prototypes can help speed up the design and manufacturing process as a whole through the following means:
Complete testing: PCB prototypes enable design teams to test designs and spot problems quickly and accurately, taking the guesswork out of the equation. Without this, spotting flaws would take significantly more time, potentially resulting in a longer time frame, lost revenue and unhappy customers.
Visual assistance: Clients often want to see the product at several points in the production process, and providing prototypes as visual aids can help communicate the design more easily. This helps minimize time spent on explanations and client-requested redesigns.
Minimized rework: Prototype testing allows you to see and test the board before a full production run. If a faulty product goes all the way to production, the required rework to fix the problem will take significantly longer and cost much more money.
These benefits are maximized when you work with a PCB supplier that specializes in quick PCB prototype turnaround. MCL’s in-house service creates high-quality prototypes, reducing the time frame for fabricating prototypes from weeks to minutes while also making sure you are independent of service suppliers.
2. Manufacturing Review and Assistance
When using a third party PCB prototyping service, companies can benefit from the assistance of a new set of eyes. Several things can go wrong in the design process that result in mistakes, including:
Excessive input: In the design process, customer and team changes can build up and overlap to the point where the design is unrecognizable compared to its first iteration. Eventually, the designers may simply lose track of design best practices in the rush to meet client demands.
Design blindspots: Designers are human, and humans have blind spots. While a designer may create fantastic PCBs of one specific type, they may have less experience in another area and subsequently create a small problem in the design.
Design-rule-check (DRC): While DRC tools are extremely helpful to catch glaring problems in a design, they have limitations. As an example, DRCs can verify that a return path to ground exists, but may not determine the best trace geometry, size and length to get the best results from that path.
These problems can result in inefficiencies, design flaws and other issues that designers miss in the review process. Third-party prototyping services are primed to catch these small problems. As a result, they can make design improvement suggestions before prototyping, making the prototype even more ready for the testing process.
This doesn’t mean that companies should work independently from their prototyping company — in fact, the opposite is true. Industry professionals recommend working closely with your prototype supplier to make the most of their expertise, adjust designs to their strengths and avoid technical issues like tool incompatibility.
3. Accurate, Reliable Prototype
Having an accurate, reliable PCB prototype makes it much easier to solve design issues throughout the development process. Quality PCB prototypes accurately represent the functionality of your final product, allowing designers to see and test the following aspects:
PCB design: Prototyping enables designers to catch flaws early in the development process, and the more accurate the design, the more accurate the identification of the flaw. This helps minimize design costs down the line, while also reducing the project timeline.
Functional testing: What works in theory doesn’t always work in practice. Accurate PCB boards will help assess the theoretical values of the board to see if they show up in the practical values. This allows any differences in value to be checked, updated and potentially reevaluated.
Conditional testing: The real world is a brutal environment for products, so it is essential that PCB products go through appropriate testing to ensure that they will survive environmental conditions. For example, prototypes typically undergo temperature variation testing, power variation testing, shock resistance testing and more.
Final product design: PCBs are usually incorporated into a final product, and prototypes help determine if the planned product or packaging need to be adjusted for the final PCB design.
For these purposes, having an accurate PCB prototype will help make other processes significantly easier, and will better prepare design teams for what to expect when they begin production runs.
4. Test Components Individually
Engineers frequently use prototype PCBs for testing, but the most beneficial testing occurs with simple PCBs that test singular components and functions. These prototype PCBs test single functions that are meant to be incorporated into a larger PCB, ensuring that they work as expected. This type of testing can be used for many purposes, including:
Testing design theories: Simple PCB prototypes are used in proof-of-concept runs, allowing engineers to see and test a design idea before it goes further into the design process. This allows engineers to see whether the design works and, if it doesn’t, figure out what went wrong.
Breaking down complex designs: Often, simple PCB prototypes break down the basic parts of a final PCB, ensuring that the design performs one basic function before moving on to the next. This piece-by-piece testing helps identify design issues in a compartmentalized manner, allowing for quicker, more accurate adjustments.
This individual testing method allows designers to test singular functions effectively and efficiently without ordering an entire PCB and breaking it down to figure out the problem when it doesn’t work.
5. Reduced Costs
Standard PCB production runs can get costly, and leaving things to chance can increase the bill. Prototypes are essential for reducing production costs because they help designers address and avoid the following issues:
Catching design flaws: The sooner the development team catches a design flaw, the sooner it can be fixed and the less costly the fix is. If a problem persists all the way to full-scale production, it’ll likely destroy the budget completely. With a high-quality PCB prototyping service, design teams can catch and fix problems quickly and accurately, reducing costs in the long run.
Pinpointing cost-saving adjustments: Depending on the specific design of a PCB, there may be several options available for materials and components. Prototyping allows design teams to test out different permutations of components, materials and assembly methods to find the one that best balances cost and functionality.
Determining product adjustments: In some cases, adjustments to the PCB will result in the PCB taking on a slightly different shape or material than originally planned, which may affect the specifications and manufacturing needs of the product as a whole. Prototyping can help determine whether product adjustments are needed early on, allowing for improved planning and reduced redesign costs for the product and any associated packaging.