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Open up just about any electronic product and inside will be a Printed Circuit Board (PCB). This board provides the mechanical mounting for the electronic components that make up the design, as well as the electrical connections between them. Having found common use in the electronics industry for over half a century, PCBs have evolved into complex items created by skilled designers and manufactured using precision processes.
While understanding the way a PCB is manufactured is not mandatory for designers, those who have a grasp of the processes involved are far better equipped to design lower cost PCBs that benefit from higher manufacturing yields.
The following sections take a look at various types of PCB - from single-sided, to rigid-flex - and the key elements that are a common factor in the fabrication of all.
The simplest PCB to manufacture is called a single-sided PCB, because it only has conductors on one side; usually the bottom side.
Single-sided PCBs begin their life in much the same way as all PCBs, and that is as an insulating substrate called the Core. The Core can be made from a multitude of materials depending on the desired properties of the final circuit, but the most common material is fiberglass.
The Core is coated completely on one side with a thin layer of copper. After drilling the holes that will later be used for mounting the components, unwanted copper is removed, using a chemical etching process, to leave the tracks and pads needed to electrically connect the circuit’s components together.
The top side of the board is called the Component Side because through-hole components are usually mounted on this side so that their leads protrude through the board to the bottom side, where they can be more easily soldered to the copper pads and tracks. Surface mount components are the exception to this rule since they need to be mounted directly to the copper pads and can only ever exist on the Solder Side.
Only slightly more complex than the single-sided PCB is a double-sided PCB, with copper traces on both the top and bottom sides of the core. This allows for more complex routing. By convention, through-hole components remain mounted on the Top Layer and surface mount components on the Bottom Layer, as per single-sided PCBs.
Double-sided boards typically rely on the leads of through-hole components to provide the electrical connection between top and bottom layers. However this is not always possible, since traces will sometimes need to traverse between the two layers at locations that don’t coincide with a component lead. Therefore, a common addition to double-sided PCBs is Plated Through Holes (PTH).
Hole plating is achieved using an electrolysis process to deposit copper inside the hole after it has been drilled. This creates a conduction path between copper on the top and bottom layers, without relying on the lead of a through-hole component.
Most PCB assemblies are soldered using either wave or reflow soldering processes. In either case, there is the potential for solder bridging to occur between adjacent traces unless a Solder Mask is applied. The solder mask, as its name implies, provides a repellant (or mask) that helps prevent solder from indiscriminately adhering to copper in areas of the board that would otherwise cause a malfunction. As a secondary benefit, solder masks also prevent the otherwise exposed copper on the PCB traces from corroding.
While just about any color is possible, solder masks have traditionally been colored green and are responsible for the characteristic green that most people recognize PCBs as having. The solder mask is painted onto the top and bottom layers of the PCB using a precision screen printing process.
When visible information such as company logos, part numbers, or instructions need to be applied to the board, silk screening is used to apply the text to the outer surface of the circuit board. Silk screen information is usually colored white so as to contrast with the chosen solder mask, however any color can be used. Where spacing allows, screened text can indicate component designators, switch setting requirements, and additional features to assist in the assembly process.
So far, only PCBs containing one or two copper layers have been described, however it is possible to create PCBs that contain many more layers. These PCBs are called multi-layered PCBs and they can offer much denser routing topologies, as well as better electrical noise characteristics. Each layer within a multi-layered PCB will either be a signal, or plane layer.
Multi-layered PCBs can be manufactured in a couple of different ways but the simplest involves laminating multiple thin, double-sided PCBs together, using a prepreg layer between each.
The ratio of double-sided PCBs to prepreg layers can be defined according to cost, weight and electro-mechanical considerations. The following scenarios illustrate variations of layer stack for an example 8-layered board.
In this layer stack, the copper on all four cores can be etched simultaneously and then sandwiched together (laminated) around layers of prepreg. This PCB would require the least complex manufacturing process.
In this layer stack, the three cores can be etched simultaneously but then the outer prepreg and copper layers must be added separate, as part of the laminating process. The PCB as a whole must then pass through the etching process one more time to remove unwanted copper from the recently added outer layers.
In this layer stack, a single PCB core is progressively built up using multiple layers of prepreg and copper. Each time a new prepreg and copper layer is added, the PCB must past through the etching process again to remove unwanted copper from the recently added outer layer. This will occur sequentially for each of the 6 different prepreg layers. Because of the number of times the board has to pass through the copper etching process, this PCB would require the most complex manufacturing process. This process is normally only used when microvias (µVias) are required.
Main article: Defining the Via Types
Vias are used to span, or connect between the copper layers. If the via passes from the top surface of the board to the bottom surface, it is called a through hole via, thruhole via, or thru via. This type of via will include a land area, or ring of copper on each layer, which may or may not be used to connect to routing on that layer. These types of vias are mechanically drilled, once all of the layers are laminated together to form the board.
It is also possible to create vias that span other layers, by creating the vias at specific points during the fabrication process. These types of vias fall into two groups: blind and buried vias, and microvias (µVias). Each type has their own pros and cons, which are discussed below.
Because the cores used in creating multi-layered PCBs can be etched, drilled and plated individually, before being laminated together into a complete stack, it is possible to create vias that are only connected to internal layers and which do not surface on one or even both sides of the final board. This means that the land area that otherwise would have been occupied by the via on the outer layers of the PCB can now be used for routing. Thes types of via are:
Although the use of blind and buried vias is becoming increasingly common in advanced PCB designs, careful consideration needs to be given to the layer stackup of the PCB to ensure that the board is, in fact, able to be manufactured. Consider the layer stackup in the following image, that consists of 3 double-sided cores sandwiched around 2 prepreg layers. Consider also the via arrangement called for by an unwitting designer.
The via arrangement is impossible because it is not possible to drill (and plate) a hole that only passes through a prepreg layer. So in the image above, the 3rd and 5th vias (counting from the left) cannot be drilled. Using a standard multi-layer board fabrication process, the following via-layer pair combinations, would be possible.
To overcome this and be able to span other layer combinations other you would need a different approach, which is where µVias can come into play.
µVias are used as the interconnects between layers in high density interconnect (HDI) designs, to accommodate the high input/output (I/O) density of advanced component packages and board designs. Sequential build-up (SBU) technology is used to fabricate HDI boards. The HDI layers are usually built up onto a traditionally manufactured double-sided core board or a multilayer PCB, as shown by the darker core section of the board in the image above (which also includes a blind via). As each HDI layer is built on to each side of the traditional PCB, µVias can be formed using: laser drilling, via formation, via metallization, and via filling. Because the hole is laser drilled, it has a cone shape.
If a connection required a path through multiple layers, the original approach was to stagger a series of µVias using a step-like pattern. Improvements in technology and processes now allow µVias to be stacked directly on top of each other.
Buried µVias are required to be filled, while blind µVias on the external layers do not require filling. Stacked µVias are usually filled with electroplated copper to make electrical interconnections between the multiple HDI layers and provide structural support for the outer level(s) of the µVia.
► Learn more about µVias
Main article: Rigid-Flex Design
Rigid-flex is the name given to a printed circuit that is a combination of both flexible circuit(s) and rigid circuit(s). This combination is ideal for exploiting the benefits of both flexible and rigid circuits - the rigid circuits can carry all or the bulk of the components, with the flexible sections acting as interconnections between the rigid sections.
Flex circuits are created from a stackup of flexible substrate material and copper, laminated together with adhesive, heat and pressure. The following image illustrates a simplified view of a flex circuit, with the constituent elements summarized thereafter:
There are a number of standard stackups available for flex and rigid-flex circuits, referred to as Types. These are summarized below.
Functional Summary |
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One conductive layer, either laminated between two insulating layers or uncovered on one side. |
Access holes to conductors can be on either one or both sides. |
No plating in component holes. |
Components, stiffeners, pins and connectors can be used. |
Suitable for static and dynamic flex applications. |
Functional Summary |
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Two conductive layers with an insulating layer between; outer layers can have covers or exposed pads. |
Plated through-holes provide connection between layers. |
Access holes or exposed pads without covers can be on either or both sides; vias can be covered on both sides. |
Components, stiffeners, pins and connectors can be used. |
Suitable for static and dynamic flex applications. |
Functional Summary |
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Three or more flexible conductive layers with flexible insulating layers between each one; outer layers can have covers or exposed pads. |
Plated through-holes provide connection between layers. |
Access holes or exposed pads without covers can be on either or both sides. |
Vias can be blind or buried. |
Components, stiffeners, pins and connectors can be used. |
Typically used for static flex applications. |
Functional Summary |
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Three or more conductive layers with either flexible or rigid insulation material as insulators between each one; outer layers can have covers or exposed pads. |
Plated through-holes extend through both rigid and flexible layers (apart from blind and buried vias). |
Access holes or exposed pads without covers can be on either or both sides. |
Vias or interconnects can be fully covered for maximum insulation. |
Components, stiffeners, pins, connectors, heat sinks, and mounting brackets can be used. |
The process of manufacturing a PCB is reasonably straightforward, and while it may vary slightly from manufacturer to manufacturer, understanding how this process operates will help you create PCBs that are less likely to suffer from manufacturing issues. A detailed step-by-step flow of the process used to manufacture standard multi-layer PCBs is given as a guide below.
The following sections provide a more graphical look at the process involved in fabricating the bare-board, for PCBs of differing layer counts.
Main article: Defining the Layer Stack
No matter what type of PCB you are wanting to manufacture - be it rigid, or rigid-flex - the first thing to do is to define the layer stackup as required. Within Altium NEXUS's PCB Editor, all layer stacks are defined in the Layer Stack Manager (Design » Layer Stack Manager). For a new board, its single default stack comprises: a dielectric core, 2 copper (signal) layers, as well as the top and bottom solder mask/coverlay layers, as shown in the image below.
For more information on defining the layer stack for your board in Altium NEXUS, see Defining the Layer Stack.
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