Embedding Components, Part 4: Passive Component Selection and Land Pattern Development

This column will focus on land pattern development criteria, and methodology for accommodating low and moderately high-profile passive components within a multilayer circuit board.

As noted in Part 3 of this series, a broad range of discrete passive component elements are candidates for embedding, but the decision to embed these component elements within the multilayer circuit structure must be made early in the design process. While many of these components are easy candidates for integrating into the substrate, others may not be suitable, or they are difficult to rationalize because they involve more complex process methodology.

Substrate Development

Basic material sets selected for this embedded component application defines a 200-μm FR-4 epoxy-glass core base with 18-μm copper foil bonded to both sides. In this example, the buildup material includes pre-impregnated layers of glass cloth with an uncured epoxy resin furnished pre-dried, but not hardened, and layers of 18-μm copper foil. There are more than a dozen thickness options available for prepreg materials, but for this process description, a 200-μm material will be referenced. The prepreg layer and copper foils are sequentially bonded together using a combination of pressure and heat. The process begins with imaging and chemically etching the circuit pattern on the copper foil. The lamination, imaging, and etching processes continue until the layer structure is complete.

When embedding components in the multilayer structure, several factors must be considered:

  • Circuit layer selected for attachment
  • Component size (length, width, and height)
  • Terminal area and metalization
  • Location and orientation
  • Method for termination

While thin passive components may not require any preparation before lamination, taller components will likely need developing a cavity-like pocket in the dielectric layer to ensure that the overall flatness of the finished multilayer PCB can be maintained. Regarding the attachment method for components, tin-alloy plated terminals will be most compatible with a tin-based solder alloy or a conductive polymer material that is either deposited or stencil printed onto the mounting site.

To read this entire column, which appeared in the October 2018 issue of Design007 Magazine, click here.

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2018

Embedding Components, Part 4: Passive Component Selection and Land Pattern Development

11-29-2018

As noted in Part 3 of this series, a broad range of discrete passive component elements are candidates for embedding, but the decision to embed these component elements within the multilayer circuit structure must be made early in the design process. While many of these components are easy candidates for integrating into the substrate, others may not be suitable, or they are difficult to rationalize because they involve more complex process methodology.

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Embedding Components, Part 3: Implementing Discrete Passive Devices

11-15-2018

Most of the passive components used in electronics are discrete surface mount components configured to mount onto land patterns furnished on the surface of a PC board. Designers have several choices for providing passive functions in a system design, such as discrete surface-mounted passives, array passives or passive networks, integrated (Rs and Cs) passive devices, and embedded discrete passive components.

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Designers Notebook: Strategies for High-Density PCBs

01-01-2018

As hand-held and portable electronic products and their circuit boards continue to shrink in size, the designer is faced with solving the physical differences between traditional printed board fabrication and what’s commonly referred to as HDI processing. The primary driver for HDI is the increased complexity of the more advanced semiconductor package technology. These differences can be greater than one order of magnitude in interconnection density.

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2017

Strategies for High-Density PCBs

11-27-2017

As hand-held and portable electronic products and their circuit boards continue to shrink in size, the designer is faced with solving the physical differences between traditional printed board fabrication and what’s commonly referred to as high-density interconnect (HDI) processing.

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Embedding Components, Part 2

07-30-2017

Technology and processes for embedding capacitor and inductor elements rely on several unique methodologies. Regarding providing capacitor functions, IPC-4821 defines two methodologies for forming capacitor elements within the PCB structure: laminate-based (copper-dielectric-copper) or planar process and non-laminate process using deposited dielectric materials.

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Embedding Components, Part 1

06-30-2017

The printed circuit has traditionally served as the platform for mounting and interconnecting active and passive components on the outer surfaces. Companies attempting to improve functionality and minimize space are now considering embedding a broad range of these components within the circuit structure. Both uncased active and passive component elements are candidates for embedding but the decision to embed components within the multilayer circuit structure must be made early in the design process.

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2016

Specifying Lead-Free Compatible Surface Finish and Coating for Solderability and Surface Protection

07-06-2016

A majority of the components furnished for electronic assembly are designed for solder attachment to metalized land patterns specifically designed for each device type. Providing a solder process-compatible surface finish on these land patterns is vital...

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Flexible and Rigid-Flex Circuit Design Principles, Part 6

05-26-2016

The designer is generally under pressure to release the documentation and get the flexible circuit into production. There is, however, a great deal at risk. Setting up for medium-to-high volume manufacturing requires significant physical and monetary resources. To avoid potential heat from management, the designer must insist on prototyping the product and a thorough design review prior to release.

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Flexible and Rigid-Flex Circuit Design Principles, Part 5

04-27-2016

The outline profile of the flexible circuit is seldom uniform. One of the primary advantages of the flexible design is that the outline can be sculpted to fit into very oblique shapes. In this column, Vern Solberg focuses on outline planning, physical reinforcement, and accommodating bends and folds in flexible and rigid-flex circuits.

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Flexible and Rigid-Flex Circuit Design Principles, Part 4

03-30-2016

All of the design rules for the glass reinforced-portion of the board (land pattern geometry for mounting surface mount devices, solder mask and the like) are now well-established. One unique facet of fabricating the rigid-flex product is how the flexible portion of the circuit is incorporated with the rigid portion of the circuit. As a general rule for multilayer PCB design, furnish a balanced structure by building up the circuit layers in pairs (4, 6, 8 and so on).

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Flexible and Rigid-Flex Circuit Design Principles, Part 3

03-02-2016

This column focuses on methods for specifying base materials, and also address copper foil variations and fabrication documentation. It is important to research the various products in order to choose the one that best meets the design requirements.

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Flex and Rigid-Flex Circuit Design Principles, Part 2

02-19-2016

Flexible circuits are commonly developed to replace ordinary printed circuit board assemblies that rely on connectors and hardwire for interconnect.

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Flex and Rigid-Flex Circuit Design Principles, Part 1

01-27-2016

Flexible circuits represent an advanced approach to total electronics packaging, typically occupying a niche that replaces ordinary printed circuit board assemblies and the hard-wire interface needed to join assemblies.

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2005

PCB Designers Notebook: Flexible Circuit Design

01-03-2005

The flexible circuit was originally used as a conductive element for interfacing signals from one electronics assembly to another.

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