Uses of Flex Circuits
Designers shape flex circuits to fit where it’s impossible to use any other type of PCB. One can think of flex circuits as being a hybrid combination of the ordinary PCB and round wires, while exhibiting their individual benefits. With flex circuits, one can retain the precision, density, and repeatability of regular PCBs, and still achieve unlimited freedom for packaging geometry.
Flex circuits are commonly used to replace the wiring harness. This allows a single flex circuit to supplant several connectors, cables, and hardboards in one operation. The assembly proceeds much faster, because it eliminates the need to color-code wires and wrap them in bundles. Volume production levels go up, while installation costs come down, and there are lower chances of rejects during assembly and in-service failures.
Replacing wire harnesses with flex circuits increases the repeatability of wire routing. It eliminates errors during wire routing, thus reducing rejections, rework, and test times. The connections are more robust, because flat foil conductors can dissipate heat better and carry more current than round wires of the same cross-sectional area. As the designer decides on a more uniform conductor pattern in a flex circuit, the impedance, crosstalk, and noise will be better controlled.
Furthermore, use of flex circuitry can reduce the space and/or weight of conventional wiring by up to 75%. Compared to the use of wire harnesses, the recurring costs of flex circuits are lower. As flex circuits are more resistant to vibration and shock, costs for repair and replacement are far lower compared to those incurred for hard boards. Moreover, by placing bonded stiffeners at required areas, surface-mount components can be easily mounted on flex boards.
Advantages of Rigid-Flex Circuits
Flexible circuits provide advantages over rigid PCBs, but they also come with more design considerations.
When reviewing the entire installation for the total cost of ownership, use of a rigid-flex circuit is advantageous in the fact that it replaces the maximum number of components. Not only can surface-mount components be mounted on both sides of the board, rigid-flex circuits make it possible to integrate the best capabilities of the resilient flex areas with the resistant rigid areas, thereby offering the highest capability and maximum vibration resistance. Since it offers the smoothest transition between rigid and flex areas while preserving the benefits of each, this combination is the best option when mounting a component with a high mass.
One of the most important aspects in the initial design of a multilayer PCB is defining its appropriate stackup. This is essential for large, dense PCBs with multiple pin-count BGAs, especially when standard laminate stackups are inadequate in terms of cost and performance goals. HDI stackups are a viable alternative to large number of layers providing lower cost with higher performance if properly designed.
For boards with high pin-count BGAs, there can be three types of stackups—standard lamination with through-vias, sequential lamination with blind and buried vias, and buildups with micro-vias. Of these, HDI boards primarily use a buildup with micro-vias, because it offers several advantages:
1）The vias and traces have smaller feature sizes, leading to higher routing density and fewer layers.
2）Micro-via patterns can be more effectively used, which opens up more channels for routing and leads to potentially fewer layers
3）This is the only practical way for designing with multiple large BGAs with pitch less than 0.8 mm.
4）Offers the lowest cost for high-density boards.
5）Appropriate stackup definition leads to improved signal and power integrity.
6）Appropriate materials for processes that must meet RoHS standards.
7）Newer materials are available for higher performance at lower costs, but these new materials may not be suitable for other types of laminations.
Eminent PCB manufacturers have defined HDI PCB stackups with 16 layers, where the overall board thickness is only 66 ± 7 Mils. This requires sequential build-up (SUB) and has laser-drilled micro-vias.
The Impact of Cost
Although flexible circuits are more expensive than rigid PCBs, the costs generally rise with the layer count. Therefore, options may have to be considered to minimize the cost. For instance, two double-layer circuits could turn out to be less expensive compared to using one four-layer circuit.
Other factors may lower the overall cost in favor of flex circuits. For instance, the ability to fold a flexible circuit could save space and layers. Depending on the situation, time invested in project assessment has the potential to result in significant overall savings.
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Below you will find our rigid-flex manufacturing process. Including, material preparations, etch, drilling, plating, to