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Jump To: Why PCB Testing Is Necessary? | What Is Being Tested? | Types of Testing Methods | In-Circuit Test (ICT) | Fixtureless In-Circuit Test | Functional Circuit Test | Boundary Scan Testing | Design for Manufacturing (DFM) | Design for Assembly (DFA) | Design for Test (DFT) | Design for Supply Chain (DSC) | Choose Millenium Circuits

PCB Testing Methods Guide

The last thing any designer wants is to discover last-minute that their product is faulty. Electronics of all types, even if they’re properly designed and meticulously built, are prone to problems. Many electronics come out of the prototype stage with plenty of bugs and issues for their designers to troubleshoot. However, when something is left unnoticed until the product is out in the field, it can mean huge problems for the company. It’s for this reason that testing electronics is so important, especially for PCBs.

Why PCB Testing Is Necessary

Man testing PCB

Testing is a crucial part of the development cycle for PCBs. Conducted throughout the production cycle, PCB testing can help save money and prevent issues when it comes to the final production run.

Some design analysis techniques can be used during the early stages to help minimize major issues during the manufacturing process, but there’s also a wide range of PCB testing methods that can be used on physical boards. These tests, run on prototypes or small-scale assemblies, look most closely at potential shorts, solder joint issues and functionality, ensuring that each tested PCB will function as intended.

This type of testing offers several benefits in the PCB design process, including the following:

  • Bug identification: The primary benefit of PCB testing is that it helps identify problems in PCBs. Whether the issue lies in functionality, manufacturability or elsewhere, PCB testing identifies issues in a PCB design so that designers can adjust accordingly.
  • Time savings: PCB testing in the early stages can help save time in the long run, allowing designers to identify major issues during the prototyping stage. Thorough testing enables designers to determine the root cause of each problem posed quickly and easily, making adjustments so that they can move on with production at a faster rate and reduce product lead-time.
  • Cost reduction: PCB testing prevents wasteful production of faulty products by using prototypes and small-scale assemblies to test the products. By completing thorough testing early in the design process, designers can prevent wasteful full-scale assemblies of faulty PCBs, ensuring that the design is as flawless as possible before it goes into production. This step helps to significantly reduce production costs.

While thorough testing isn’t necessary for all types of PCBs, especially matured products well into their product lifecycle, the majority of new PCB designs need robust and frequent testing of the design process. By establishing an appropriate PCB testing procedure for your organization’s needs, you can experience the benefits of PCB testing.

What Is Being Tested?

During the testing process, several components of PCBs are analyzed in detail, including:

  • Lamination: Lamination quality is essential to the lifespan of a PCB — peeling laminate can cause issues in the final functionality of a board. Generally, tests on lamination will look at the laminate’s resistance to peeling by force or application of heat.
  • Copper plating: The copper foil on a PCB is laminated to the board to provide conductivity, but the quality of the copper is often tested, with tensile strength and elongation analyzed in detail.
  • Solderability: Testing the solderability of a material is essential for a functioning PCB since it ensures that components can be attached firmly to the board. The most commonly analyzed factor is wetting, or how well a surface accepts liquid solder.
  • Hole wall quality: Hole wall quality is another essential part of a PCB, ensuring that the hole walls will not crack or delaminate when the PCB goes into the field. Hole walls are generally analyzed in environments with cycling and quickly changing temperatures to see how well they react to thermal stress.
  • Electrical: Electrical conductivity is essential for any PCB, so the ability of a PCB to pass electric currents with minimal leakage is a common test.
  • Environment: Many PCBs operate in humid environments, so a common test for PCBs is for water absorption. In these types of tests, the PCB is weighed before and after being put in a humid environment, and any significant weight change results in a failing grade.
  • Cleanliness: Cleanliness for PCBs is the ability to resist environmental factors like corrosion and humidity. Generally, these tests include analyzing PCBs before and after they’re put through varying environmental conditions.

Most of these factors are analyzed in early materials testing and environmental tests. However, factors like electrical conductivity and general functionality are analyzed with various methods and equipment, which are discussed in more detail below.

Types of Testing Methods

Several PCB testing methods are available, and no single one will catch every problem or meet the requirements of every designer. Each testing method should be considered closely to determine if it meets the specific needs of your manufacturing environment. Some factors to consider include the type of product you’re testing, the problems you’re testing for and the reliability of the test method. To give you an overview of the testing methods available, we’ve summarized the main qualities of several popular PCB testing methods below.

In-Circuit Test (ICT)

In-circuit testing is a popular PCB testing method that many PCB manufacturers prefer to employ, and it’s capable of finding 98 percent of faults. This testing method uses special equipment, including:

  • In-circuit tester: The tester system contains a matrix of hundreds or thousands of drivers and sensors, which perform the measurements for the test.
  • Fixture: A fixture connects to the in-circuit tester and is the part that interacts directly with the board being tested. This fixture looks like a bed of nails and is designed specifically for the board in question. Each “nail,” or sensor point, connects to relevant points on the test board, feeding information back to the tester. Fixtures are generally the most expensive part of this system.
  • Software: Software for the tester instructs the system on what tests to perform for each type of board being tested and dictates the parameters for a pass or fail.

Using the ICT method, a manufacturer can test individual components and measure their performance, regardless of the other components attached to them. Generally, this type of testing is best for analog circuits since it’s best at measuring resistance, capacitance and other analog measures. Additionally, the cost of the equipment means that this testing method is best suited for the final testing of stable, high-volume products, not for low-volume productions or early testing stages where the design may change multiple times.

Fixtureless In-Circuit Test (FICT)/Flying Probe Test

The fixtureless in-circuit test (FICT), also known as the flying probe test, is a type of ICT that operates without the custom fixtures, reducing the overall cost of the test. First introduced in 1986, FICT uses a simple fixture to hold the board while test pins move around and test relevant points on it using a software-controlled program. Since its introduction, FICT has gained widespread use throughout the electronics manufacturing industry for its versatility.

FICT testing is used for the same things as traditional ICT, but because of the way it goes about testing, it offers different advantages and disadvantages. While FICT is able to adapt to new boards quickly, easily and cost-effectively, with a simple programming change, it tends to be slower than the traditional ICT. This quality makes it an ideal testing method for small-production tests and prototype testing, but less effective for large-scale production.

Functional Circuit Test

A functional circuit test is exactly what it sounds like — it tests the function of the circuit. This type of testing always comes at the end of the manufacturing plan, testing whether a finished PCB functions to specifications.

Functional testers come in several types but generally share the same function — they simulate the final environment in which the PCB is supposed to function. Functional testers usually do so by interfacing with the PCB via its test-probe points or edge connectors and testing to certify that the PCB functions according to design specifications.

In some ways, functional circuit tests are similar to ICTs in that they use connectors to attach to the board. In the case of functional circuit testers, they use pogo pin devices to connect to the PCB and generally need fewer pins than an ICT fixture. The test equipment then runs programs to test the PCB, ensuring that the equipment functions exactly as intended.

As previously stated, functional circuit tests are the last type of test to complete in a PCB manufacturing plan, ensuring that the product going out functions according to specifications. It’s not an ideal testing method for early prototypes since it doesn’t identify details on what’s wrong with the product — generally, functional circuit tests just look at the product’s functionality as a whole and grade it on a pass or fail basis.

Boundary Scan Testing

The boundary scan test looks at the wire lines on PCBs and is widely used as a way to test integrated circuits when it isn’t possible to reach all the nodes of the circuit. In this type of test, cells are placed in the leads from the silicon to the external pins, testing the functionality of the board.

The big differentiating quality of this type of test is its ability to assess a board without reaching all of its nodes. This quality is an important one for evaluating integrated circuits with multiple layers and high density since these types of PCBs have been becoming more common in recent years. In fact, this testing method is quite versatile and able to be used for several applications, including system level tests, memory testing, flash programming and CPU emulation among other functions. It’s commonly used in field service to detect problems in functioning systems.

Design for Manufacturing (DFM)

DFM, or Design for Manufacturing, is the process of arranging a PCB topology with the manufacturing process in mind. With this design mentality, the PCB layout topology is intended to mitigate problems that typically occur during the fabrication and assembly processes, including:

  • Slivers and islands: Pieces of free-floating copper on a PCB layer can cause issues in a PCB design, which tends to happen when a design includes several areas with small islands of copper between traces. These pieces can break away and cause interference on other parts of the board and islands, trace impedance, trace inaccuracies, impedance and other issues.
  • Solder bridges: When traces and pins are placed too close together and a solder mask isn’t used in a design, solder can create bridges between pins, causing shorts and corrosion along with other issues.
  • Copper to edge: Sometimes, the copper on a PCB is too close to the edge of the board, causing shorts to occur during the etching process when electrical current is applied.

DFM tests should be implemented early in a project timeline to reduce overall costs and development time. There are plenty of software programs available that help identify issues like those listed above.

Design for Assembly (DFA)

For any PCB assembly, it’s essential to attach components securely to the circuit board. Unfortunately, doing so can be difficult when the design is hard to assemble, which is why DFA, or Design for Assembly, is essential. With DFA, the goal is to determine how to design the PCB so that the assembler can complete their job quickly and effectively. This process includes minimizing material inputs, choosing components that are easily available, giving components enough space between each other, applying general standards of PCB design and making markings for components accurate and clear.

Like DFM, DFA tests should be implemented early on in a project design process in order to minimize production costs and product development time. Software programs are available to help ensure that PCB designs meet DFA standards.

Design for Test (DFT)

“DFT” is a general term that means “design for test,” and it applies to a type of design that helps make testing more thorough and less costly. Essentially, PCBs designed with DFT in mind are designed to make it easy to detect and locate failures. This way, it’s easier to run tests quickly and accurately, reducing the amount of time needed for testing. For this to work, designers have to know exactly what type of testing methods they’ll be using at each stage of production and design the PCB to work optimally with them.

DFT can require a great deal of additional design and engineering effort in the PCB design process, easily making up for the amount of time saved during testing. The amount of time spent, however, is easily made up for with an overall decrease in manufacturing costs. With faults more easy to find, it’s less likely for PCBs with hidden faults to be sent out, reducing the cost of customer dissatisfaction and potential recalls.

Design for Supply Chain (DSC)

One thing that many designers don’t consider is the life cycle of a product or component. Often, certain components become obsolete during the product life cycle of a PCB, and it becomes more difficult to source that component in a cost-effective way. It’s essential to consider component life cycles when designing new products.

Staying aware of life cycles includes talking to an experienced electronics contract manufacturer to determine stock availability and alternate sourcing for the components of a PCB early in the design process. In the long run, this strategy will help save money by ensuring a long lifespan for a PCB design.

Choose Millenium Circuits

Regardless of the method you use, PCB testing is an essential step in the design process, helping to save your business a great deal of time and money by preventing bugs before they affect your production. However, to successfully run tests on your PCBs, you need a supplier you can trust to ensure that your prototypes are made to order every time. Millennium Circuits Limited can help.

We provide several prototype and small-scale production services that can help speed up your testing process. With incredible reliability and no hidden fees, we make sure you can trust us to provide you with high-quality prototypes for your next round of PCB testing. Get a quote today!