2 Notes on PCB Reverse Engineering

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2 Notes on PCB Reverse Engineering

Computerized tomography

A computerized tomography is a powerful tool for reverse engineering PCBs. This technique uses x-rays to take images of the inside of a circuit board. The resulting image can be used to reconstruct the board’s structure. Computerized tomography has several limitations, however. Its field of view is small, which makes it less effective for PCBs with large areas of copper foil.

Computerized tomography is not a good choice for all reverse engineering projects. CT scans can result in inaccurate results. It’s best to use a non-destructive method, which gives you more margin of error. CT scans are commonly used in this process, but you can also use X-ray tomography to capture the inside of a substance. It can also extract geometrical information, which can be extremely helpful for re-engineering circuit boards without destroying the device.

The main drawbacks of CT are the fact that x-rays can distort the image and cause a lot of artifacts. Additionally, the powerful X-rays can damage IC chips. In addition, the board needs to be depopulated before the process can begin.

In contrast, reverse engineering PCBs use a deconstructing method to understand complex things. This method is not limited to hardware engineering; it’s used in software development and human DNA mapping. This process starts with the PCB and works backward from it to the schematics to analyze how it works.

Another advantage of PCB reverse engineering is the ability to produce high-resolution optical images of a board with up to six layers in a few hours. It also has a low cost. The results can be sent directly to a PCB manufacturer for replica PCBs.

Computerized tomography can also be used to analyze multilayer PCBs. The results can also be used to generate a bill of materials. It is recommended to supply a sample PCB when PCB reverse engineering is needed. The sample board should be at least 10 mm in width.

Another benefit of using computerized tomography is that it allows the user to visualize individual components. In addition, it can also determine GD&T controls. A PC-DMIS can export features to polylines and step files. This allows the user to visualize the connections made on the printed circuit board.

X-ray

X-ray for PCB reverse engineering is a relatively new technique for identifying components on a printed circuit board. Traditional methods rely on de-layering the PCB, which is a time-consuming, error-prone, and damaging process. X-ray for PCB reverse engineering, on the other hand, requires no physical damage to the PCB and takes much less time to evaluate. This method also allows the researcher to extract data from the circuit board.

X-ray for PCB reverse engineering is often used for reverse engineering, but the cost of purchasing such an inspection machine can be prohibitive for many people. One hardware hacker, John McMaster, decided to build his own X-ray to use in his own lab to save money.

Another important consideration is the resolution of the X-ray. Low resolution survey scans can reveal the main components of a board, but submicron resolution is needed to see traces and interconnects. Current micro-CT scanners and XRMs do not have the resolution necessary for this. Moreover, imaging a large PCB at coarse resolution can take hours. Furthermore, the X-ray beam can be harden and create streaks and bands.

PCB reverse engineering is a process of analyzing existing electronic products and recreating them with superior features and lower cost. During the process, documents are generated and sent to a PCB manufacturer for fabrication of a replica PCB. This method can also be used to reduce the time required for repairs and new circuit boards. In addition, it can reveal whether or not a given fabricator is a good match.

The process begins by cleaning the surface of a PCB. Afterward, the X-ray can reveal hidden information within the part. In addition, it can be used to solve quality and failure problems. It can also be used to create computer-aided design models of internal surfaces and trace connections.

Things to Know Before Ordering a PCB Project

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Things to Know Before Ordering a PCB Project

If you are going to order a PCB project, there are a few things that you should be aware of. For instance, you must double check your traces before ordering. In addition, you need to make sure that your BOM and drill file match. Moreover, you must choose the right material.

Double checking traces

When ordering PCBs from a PCB manufacturer, it is crucial to double-check the traces and spacing on your board. The thickness and width of the traces on your project will determine the amount of current that can flow through the circuit. You can use an online trace width calculator to find the ideal trace width. This will reduce the chances of connections breaking.

Checking your BOM

The first step in ordering PCB components is checking your BOM. It will help you avoid missing or incorrect component numbers. Using the BOM is also beneficial when it comes to sourcing parts. The description of the component will help the buyer and assembly house find a suitable replacement part. This will also help them confirm that the parts have the right MPN.

It is important to check your BOM before sending the PCB project to a manufacturer. This is because even a small mistake can cause problems during the PCB assembly process. You should also keep track of any changes made to the BOM and label them clearly. The most up-to-date version of the BOM is the one that you should use.

Once you have your BOM, you need to find out the cost of the component you’re ordering. It is important to know exactly what you’re going to be paying. The price of your components should match the BOM of your PCB project. If not, you may have to replace the components or even change the design.

Checking your drill file

You can easily check your drill file before ordering your PCB project from a PCB manufacturing company. However, there are some important things you must remember before placing an order. The first step is to make sure that the file is in the correct format. You can use a gerber file viewer to double check your file.

A drill file is a secondary file that explains where holes should be drilled on the PCB. This file must be sent along with the Gerber files. If your Drill file does not specify the locations or sizes of holes, your PCB order will fail the audit.

The drill file should also contain a tool list. It lists which tools are needed for each component hole. The tool list should be either embedded in the drill file or be sent as a separate text file. Failure to provide this tool list on the fabrication drawing will eliminate automated verifications and result in more errors when it comes to data entry.

Choosing the right materials

Choosing the right materials for your PCB project is essential. The physical properties of PCB materials can significantly affect the performance of the board. For example, a lower dielectric constant will mean thinner dielectrics and lower board thickness, while a higher dielectric constant will lead to higher losses. This information will help you narrow down your selection of PCB materials and find those that deliver the required performance.

Next, you should determine the number of routing layers on your PCB. For a simple PCB design, there may be only one or two layers, while a moderately complex design may need four to six layers. More complicated designs may require eight layers or more. The number of layers will directly affect the cost of your PCB project.

How to Know the Surface Finish From PCB Color

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How to Know the Surface Finish From PCB Color

If you’re wondering how to know the surface finish of a PCB, you’re not alone. The color of a PCB can reveal its surface finish. You may also see a color designation called ENIG or Hard gold, Silver, or Light red. Regardless of what you see, you’ll want to make sure the PCB is plated to protect the surface.

ENIG

ENIG surface finish is one of the most popular finishes for PCBs. It is made by combining gold and nickel. The gold helps protect the nickel layer from oxidation, and nickel acts as a diffusion barrier. The gold layer has a low contact resistance and is usually a thin layer. The thickness of the gold layer should be consistent with the requirements of the circuit board. This surface finish helps extend the life of the circuit board. It also has excellent electrical performance and enhances electrical conduction between the PCB’s components.

ENIG surface finish has a higher cost but a high success rate. It is resistant to multiple thermal cycles and displays good solderability and wire bonding. It is composed of two metallic layers: a layer of nickel protects the base copper layer from corrosion, and a layer of gold acts as an anti-corrosion layer for the nickel. ENIG is suitable for devices that require high levels of solderability and tight tolerances. ENIG is also lead-free.

Hard gold

Hard gold is a costly PCB surface finish. It is a high-quality, durable finish that is often reserved for components that see a high level of wear and tear. Hard gold is usually applied to edge connectors. Its main use is to provide a durable surface for components that undergo frequent actuation, such as battery contacts or keyboard contacts.

Hard electrolytic gold is a gold plated layer over a nickel barrier coat. It is the most durable of the two and is typically applied to areas that are susceptible to wear and tear. However, this surface finish is very expensive and has a low solderability factor.

Silver

Depending on the PCB’s composition, it can be produced with different colors and finishes. The three most common colors for PCB surfaces are silver, gold, and light red. PCBs with a gold surface finish are usually the most expensive, while those with a silver finish are cheaper. The circuit on the PCB is primarily made of pure copper. Because copper oxidizes easily when exposed to air, it is very important to protect the outer layer of the PCB with a protective coating.

Silver surface finishes can be applied using two different techniques. The first technique is immersion, in which the board is immersed in a solution containing gold ions. The gold ions on the board react with the nickel and form a film that covers the surface. The thickness of the gold layer must be controlled so that the copper and nickel can remain solderable, and the copper is protected from oxygen molecules.

Light red

The surface finish of a PCB can be glossy, non-glossy, or light red. A non-glossy finish tends to have a more porous look, and a glossy finish tends to be reflective and hard shell-like. Green is the most popular PCB color, and it’s also one of the least expensive. It’s important to clean PCBs before using them to avoid oxidation.

Although solder mask color isn’t a direct reflection of PCB performance, some manufacturers use it as a design tool. The color is ideal for PCBs that require brilliant visibility and sharp contrasts. Red PCBs are also attractive when combined with silkscreens.

Electroless palladium

Using the electroless palladium surface finish on your PCBs prevents the formation of black pads on the board, and has many benefits, including excellent solderability and aluminum and silver wire bonding. This type of finish also has an extremely long shelf life. However, it is also more expensive than other finishes and requires a longer lead time.

The ENEPIG PCB surface finish process involves several steps, each of which requires careful monitoring. In the first step, copper is activated, followed by the deposition of electroless nickel and palladium. After that, the circuit board goes through a cleaning procedure, to remove oxidation residues and dust from the surface.

Lead-free HASL

If you’re looking for a new PCB, you may wonder how to tell lead-free HASL surface finishes from lead-based PCBs. While HASL has an attractive look, it’s not ideal for surface-mount components. This kind of finish is not flat, and larger components, like resistors, can’t align properly. Lead-free HASL, on the other hand, is flat, and does not use lead-based solder. Instead, it uses a copper-based solder that is RoHS compliant.

HASL offers high-quality solderability, and it can withstand multiple thermal cycles. It was once the industry standard, but the introduction of RoHS standards pushed it out of compliance. Nowadays, lead-free HASL is more acceptable in terms of environmental impact, as well as safety, and is a more efficient choice for electronic components. It also aligns more closely with the RoHS directive.

Tips to know about Semi-Flexible FR4 Printed Circuit Boards

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Tips to know about Semi-Flexible FR4 Printed Circuit Boards

FR4 is a flame-retardant material

Printed circuit boards made from FR4 are extremely durable. However, the cost of these boards is higher than the ones made from other materials. In addition, these boards tend to delaminate easily, and they emit a bad odor when soldered. This makes them unsuitable for high-end consumer electronics.

FR4 is a composite material that has excellent mechanical, electrical, and flame retardant properties. It is a yellow to light green material that withstands high temperatures. It is made of a fiberglass layer that gives the material its structural stability. The material also features an epoxy resin layer that provides it with its fire retardant properties.

FR4 PCBs can be produced with a varying thickness. The thickness of the material affects the weight of the board and its component compatibility. A thin FR4 material can help make a board lighter, which makes it more appealing to consumers. This material is also easy to ship and has excellent temperature resistance. However, it is not advisable for use in high-temperature environments, such as aerospace.

It has excellent thermal, mechanical, and electrical properties

FR-4 is a common printed circuit board substrate made from glass cloth impregnated with epoxy or hybrid resin. It is widely used in computers and servers and is well known for its excellent thermal, mechanical, and electrical properties. It can withstand high temperatures, which makes it an ideal choice for sensitive electronics.

However, FR4 semi-flex PCBs present some challenges when it comes to depth-controlling milling. In order to achieve good results with this type of material, the board’s remaining thickness must be uniform. The amount of resin and prepreg used must also be considered. The milling tolerance should be set appropriately.

Besides the excellent thermal, mechanical, and electrical properties, FR4 is lightweight and inexpensive. Its thinness is a major advantage over FR1 printed circuit boards. However, it should be noted that this material has a lower glass transition temperature than FR1 or XPC. FR4 PCBs are made from eight layers of glass fiber material. These boards can withstand temperatures between 120 degrees C and 130 degrees C.

It has a high signal loss compared to a high-frequency laminate

While the low cost and relative mechanical and electrical stability of FR4 makes it an attractive choice for many electronic applications, it is not appropriate for all applications. In cases where high-frequency signals are required, a high-frequency laminate is the better choice.

The dielectric constant of the laminate material plays a critical role in determining the best PCB. The higher the dielectric constant, the less signal loss the board will experience. This dielectric constant is a measure of the board’s ability to store electrical energy.

When comparing the signal loss of a printed circuit board with a high-frequency laminate, you can see that the former has a higher dielectric constant. In other words, the Semi-Flex FR4 material has a higher dielectric constant than the latter. A high dielectric constant is desirable for high-speed applications because it prevents signal loss.

FR-4 was not the first PCB material to be used for electronics. It was preceded by the FR-2 board, which was made from pressed phenolic-cotton paper. This material served as a bridge between discrete-wired hand-soldered circuits and FR-4. Some Magnavox advertisements advertised that the televisions were “hand-soldered”. FR-2 boards were often one-sided, but designers could solve the problem by using top-side jumpers and zero-ohm resistors.

It can be manufactured at a low cost

Semi-flex PCBs are flexible, and are ideal for applications where space is a consideration. While these PCBs are more expensive than conventional FR4 boards, the flexibility that they provide makes them ideal for many medical applications. Also, the flexibility that they provide is better suited to handling dynamic stress resulting from bent circuit boards.

Semi-flex PCBs are made with materials that are typically manufactured in rolls. These materials are then cut according to the final size of the product. For example, a roll of copper foil is cut to the desired shape, which then requires mechanical drilling to make the through-holes. Different hole diameters are used, which vary according to the needs of the customer.

However, the bending properties of this material can cause problems. For instance, FR4 is not suitable for bending at very high temperatures, as it tends to warp. To prevent such problems, it is necessary to ensure that the materials are made of a flexible material before they are etched or molded.