What is the range of a PCB board?

Introduction to PCB Range

The range of a printed circuit board (PCB) refers to the various types, sizes, materials, layer counts, and other specifications that are available when designing and manufacturing PCBs. PCBs are used in virtually all modern electronic devices to mechanically support and electrically connect electronic components using conductive pathways, tracks or signal traces etched from copper sheets laminated onto a non-conductive substrate.

Understanding the range of options and trade-offs when it comes to PCB specifications is critical for electronics designers and engineers to optimize their designs for functionality, reliability, manufacturability and cost-effectiveness. Key aspects that define the range of a PCB include:

• Board size and shape
• Number of layers
• Material selection
• Copper weight and trace width/spacing
• Surface finish
• Special requirements (impedance control, thermal management, etc.)

Let’s dive into each of these factors to explore the full range of PCB possibilities.

PCB Size and Shape

One of the first considerations when designing a PCB is determining the size and shape required to fit the enclosure and mount all necessary components. PCBs can be manufactured in a wide range of sizes from very small (less than 1 cm2) up to very large (1 meter2 or more).

Common PCB shapes include:

• Rectangular – most common
• Square
• Circular
• Irregular/custom

The size and shape is often constrained by the product packaging, but multilayer designs or high density interconnect (HDI) techniques can help shrink the PCB footprint. Smaller PCBs are generally cheaper to produce but more challenging to assemble.

Standard PCB Sizes

While custom sizes are possible, most PCB fabricators offer a range of standard panel sizes for automated production which helps reduce cost, such as:

Dimension	Inches	Millimeters
5″ x 7″	12.7 x 17.8	322 x 452
8″ x 10″	20.3 x 25.4	516 x 645
11″ x 14″	27.9 x 35.6	709 x 903
18″ x 24″	45.7 x 61.0	1162 x 1548

Designers must work with their PCB manufacturer to determine the maximum usable area within the standard panel to allow for tooling and panelization.

Number of PCB Layers

The layer count is one of the main drivers of PCB cost and complexity. Most PCBs are composed of multiple layers of copper foil laminated with insulating material in between and sandwiched by solder mask on the outer layers.

Typical PCB layer counts include:

• Single sided (1 layer)
• Double sided (2 layers)
• 4 layers
• 6 layers
• 8 layers
• 10+ layers (up to 40 or more in some high density applications)

More layers allow for higher connection density but increase cost and manufacturing challenges. Inner layers are used for power planes, ground planes, and signal routing.

Advantages of Multilayer PCBs

Compared to single or double layer boards, multilayer PCBs offer several benefits:

• Increased circuit density and functionality in smaller footprint
• Better signal integrity and EMI performance
• Power and ground planes for lower impedance
• Shielding and crosstalk reduction
• Stiffness and mechanical strength

The tradeoff is higher cost, longer lead time, and more difficulty troubleshooting and reworking. Multilayer boards require careful stackup design and signal integrity analysis.

PCB Material Selection

The choice of laminate material is another important factor in PCB range and performance. The base material provides electrical insulation and mechanical support for the copper traces.

Standard PCB Materials include:

• FR-4 – glass-reinforced epoxy laminate, most common
• FR-2 – phenolic paper, low cost but lower grade
• CEM-1 – composite epoxy material, lower cost than FR-4
• Polyimide – high temp and flex applications
• Teflon – high frequency and controlled dielectric
• Aluminum – metal core for heatsinking
• Flex materials – polyimide or polyester for flexible circuits

Material selection depends on the electrical, thermal, mechanical and environmental requirements as well as cost targets. Dielectric constant (Dk) and dissipation factor (Df) are key electrical properties.

FR-4 Material Grades

Even within the FR-4 category there are many different grades and formulations with varying glass-to-resin ratios and performance specs. Higher glass content generally provides the following:

• Better thermal performance (higher Tg)
• Lower CTE for improved reliability
• Better controlled Dk for impedance
• More laser drilling cycles (for HDI)

However, this comes at a higher price point, so designers must weigh the cost and benefits. Some common FR-4 grades include:

Grade	Tg (°C)	Resin Content	Dk @ 1 GHz
Standard FR-4	130	Medium	4.4
FR408	180	Low	3.8
Isola 370HR	180	Low	4.0
MEGTRON 6	210	Very Low	3.6

Work with your laminate supplier and PCB fabricator to select the appropriate material grade for your application and budget.

Copper Weight and Trace Geometries

The copper foil thickness and trace width/spacing are also key variables in PCB range. Thicker copper allows higher current carrying capacity but is more expensive. Finer pitch allows higher density but is more challenging to manufacture.

Standard copper weights include:
– 0.5 oz (17 um)
– 1.0 oz (35 um)
– 2.0 oz (70 um)
– 3.0 oz (105 um)
– 4.0 oz (140 um)

Most PCBs use 1 oz copper on outer layers and 0.5 oz on inner layers, but thicker copper may be needed for high current applications like power electronics. Copper weight also affects impedance.

Trace Width and Spacing

The minimum trace width and spacing depends on the PCB manufacturer’s capabilities. Standard specs include:

Copper Weight	Minimum Width/Spacing
0.5 oz	3-4 mil (75-100 um)
1.0 oz	4-5 mil (100-125 um)
2.0 oz	8-10 mil (200-250 um)

Finer geometries down to 2 mil (50 um) or less are possible with advanced processes but come at a higher cost. Designers must also consider current carrying capacity and impedance control when selecting trace geometries.

PCB Surface Finish

The final surface finish on exposed copper pads is important for solderability, durability and signal integrity. Standard surface finishes include:

• HASL (Hot Air Solder Leveling) – tin-lead or lead-free
• ENIG (Electroless Nickel Immersion Gold)
• ENEPIG (Electroless Nickel Electroless Palladium Immersion Gold)
• Immersion Silver
• Immersion Tin
• OSP (Organic Solderability Preservative)

Each finish has pros and cons in terms of cost, flat surface, shelf life, and suitability for different components and assembly processes. HASL is the cheapest but not as flat. ENIG and ENEPIG offer good planarity and shelf life but cost more.

Comparison of Surface Finishes

Here is a quick comparison of the common PCB surface finishes:

Finish	Cost	Flatness	Shelf Life	Leaded/Lead-free	Fine Pitch
HASL	$	Poor	12+ months	Both	Not ideal
ENIG	$$$	Great	12+ months	Lead-free only	Excellent
ENEPIG	$$$$	Great	12+ months	Both	Excellent
ImAg	$$	Good	6-12 months	Both	Very Good
ImSn	$$	Good	6-12 months	Lead-free only	Very Good
OSP	$	Good	3-6 months	Lead-free only	Good

Work with your CM to select the best finish for your design requirements and budget.

Special PCB Requirements

Aside from the standard specifications, some PCB designs may have special performance requirements that impact the material selection and manufacturing process:

• Controlled impedance – for high speed signals
• Thermal management – for high power dissipation
• Flexible or rigid-flex – for wearables or tight packaging
• High frequency – low loss materials up to mmWave
• Extreme environments – hi-temp, hi-rel aerospace/military

These speciality PCBs often require advanced materials, tighter process controls, and more extensive testing and qualification which increases cost and lead time. Designers must weigh the performance and reliability requirements against development and unit cost.

Controlled Impedance

Signal integrity is critical in high speed digital designs. The characteristic impedance of PCB transmission lines must be tightly controlled to minimize reflections and maintain signal quality. The target impedance is typically 50 ohms for single-ended and 100 ohms for differential pairs.

Controlled impedance requires precise control of the laminate Dk as well as the trace geometries:

• Microstrip – trace above ground plane
• Stripline – trace between ground planes
• Coplanar waveguide – trace with ground trace on same layer
• Edge-coupled differential pair – two coupled traces
• Broadside-coupled differential pair – two traces on adjacent layers

The PCB stackup and trace geometries must be carefully designed and simulated to achieve the target impedance. This requires close collaboration between the designer and fabricator.

Frequently Asked Questions (FAQ)

What is the most common PCB size?

The most common size varies by industry and product, but many designs fall in the 50-150 cm2 range which fits a variety of enclosures. Typical dimensions might be 100×100 mm, 120×80 mm, 160×100 mm, etc.

How many layers do most PCBs have?

The majority of PCB designs are 2 or 4 layers, but more complex boards can range up to 8, 10 or 12 layers. Smartphones and other advanced consumer electronics may use 8-16 layers. 40+ layer PCBs are used in some supercomputer and telecom applications but are very rare and expensive.

What is FR in FR-4?

FR stands for “Flame Retardant”. FR-4 is a NEMA grade designation for glass-reinforced epoxy laminate that is flame retardant. It is the most common PCB material.

What copper weight should I use?

For most general purpose PCBs, 1 oz copper (35 um) is standard on outer layers and 0.5 oz (18 um) on inner layers. Boards with higher current carrying requirements may use 2 oz (70 um) or more on power/ground planes. High frequency PCBs may use 0.5 oz or less on controlled impedance traces.

What is the best surface finish?

The choice of surface finish depends on many factors including cost, availability, shelf life requirements, assembly process, etc. HASL is the most economical and common but ENIG and Immersion Silver are growing in popularity for lead-free and fine pitch applications. ENEPIG is a high-end finish for demanding applications.

Conclusion

In summary, the range of PCB Types, sizes, materials, and features is extremely broad and continues to expand with new technologies and applications. Designers and engineers must carefully consider all of the electrical, mechanical, thermal, and manufacturability requirements to select the optimal combination of specifications to balance performance, reliability, and cost.

Some key considerations in defining the range of a particular PCB include:

• Board size and shape to fit enclosure and mount components
• Number of copper layers for routing density and signal integrity
• Material selection for electrical and thermal performance
• Copper weight and trace geometries for current capacity and impedance
• Surface finish for solderability and durability
• Any special requirements like impedance control or thermal management

By understanding the full range of PCB possibilities and trade-offs, designers can optimize their board stack-up and layout for manufacturability and product reliability. Close collaboration between the design team and the fabrication and assembly partners is essential to ensure a successful product development cycle.

Keeping up with the latest advancements in PCB materials, processes, and design tools is an ongoing challenge but also an opportunity for innovation. The range of PCB options will continue to evolve and expand to enable the next generation of electronic products and technologies.