创建PCB封装

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Applies to NEXUS Client versions: 3.0, 3.1, 3.2 and 4

This documentation page references Altium NEXUS/NEXUS Client (part of the deployed NEXUS solution), which has been discontinued. All your PCB design, data management and collaboration needs can now be delivered by Altium Designer and a connected Altium 365 Workspace. Check out the FAQs page for more information.

Chinese - Translation is available for NEXUS Client 1.1: Go to the page
 
Altium NEXUS hosts a huge array of ready-made PCB Components both in servers as well as in several integrated and discrete libraries available through AltiumLive. However, even with this rich set of resources, it is likely that at some point in your career you will need to create a custom PCB Component. PCB Component Footprints are created in the PCB Library editor using the same set of primitive objects available in the PCB editor. In addition to footprints, company logos, fabrication definitions, and other objects required during board design can also be saved as PCB Components.
 

The real-world component that gets mounted on the board is represented as a schematic symbol during design capture, and as a PCB footprint for board design. Altium NEXUS components can be:

  • Created in and placed from local libraries or
  • Placed directly from a managed content server, which is a globally accessible component storage system that contains thousands of components, each with a symbol, footprint, component parameters, and links to suppliers.

Manually Creating a Footprint

2D and 3D views of a footprint for a joystick component. The 3D image shows the imported STEP model for the component. Note
that the pads and component overlay can be seen below the STEP model.

The typical sequence for manually creating a component footprint is:

  1. Footprints should be built around the workspace reference point at the center of the PCBLIB editor. Use the J, R shortcut keys to jump directly to the reference point. If you have forgotten to move to the reference point before beginning to build your footprint, you can bring the reference pad to your footprint using the Edit » Set Reference sub-menu commands.
  2. Place the pads (Place » Pad) according to the component requirements. After running the Place Pad command but prior to placing the first pad, press the Tab key to open the Properties panel to define all the pad properties, including the pad Designator, Size and Shape, Layer, and Hole Size (for a thru-hole pad). The Designator automatically increments for subsequent pad placements. For a surface mount pad, set the Layer to Top Layer. For a thru-hole pad, set the Layer to Multi-Layer.
Some care should be exercised when designating pads since it is this property that Altium NEXUS uses when mapping from pin numbers on the schematic symbol.
  1. To ensure accurate placement of the pads, consider setting up a grid specifically for the task. Use the Ctrl+G shortcut keys to open the Cartesian Grid Editor dialog and the Q key to toggle the grid from Imperial to Metric.
  2. To accurately place a pad while moving it with the mouse, use the keyboard arrow keys to move the cursor in current grid increments. Additionally, holding Shift will move in steps of 10 times the grid. The current X, Y location is displayed on the Status bar and also in the Heads Up display. The Heads Up display contains both the location and the delta from the last click location to the current cursor location. Use the Shift+H shortcut to toggle the Heads Up display on and off. Alternatively, double-click to edit a placed pad and enter the required X and Y locations in the Properties panel.
  3. To check a distance between two points in the workspace, use the Reports » Measure Distance (shortcut Ctrl+M). Follow the prompts on the Status bar.
  4. Pad-specific attributes, such as solder mask and paste mask, are automatically calculated based on the pad dimensions and applicable mask design rules. While mask settings can be defined manually for each pad, doing so makes it difficult to modify these settings later during the board design process. Typically this is done only when it is not possible to target the pads by design rules. Note that rules are defined in the PCB editor during board design.
  5. Use tracks, arcs and other primitive objects to define the component outline on the silkscreen layer.
  6. Place tracks and other primitive objects on a mechanical layer to define extra mechanical detail, such as a placement courtyard. Mechanical layers are general-purpose layers. You should allocate the function of these layers and use them consistently across their footprints.
  7. Place 3D Body objects to define the three-dimensional shape of the component that fits on the footprint. Multiple 3D Body objects can be placed to build up the shape, or a STEP format 3D component model can be imported into a 3D Body object.
  8. The Designator and Comment strings are automatically added to the footprint’s Overlay layer during placement into the main PCB workspace. Additional Designator and Comment strings can be included by placing the .Designator and .Comment special strings on a mechanical layer.
    When placing Designator and Comment strings, a Layer Pair needs to be defined in the PCB editor. This ensures that the strings will be tied to the side of the board on which the component is mounted and must flip to the other side of the board when the component is flipped. For more information, see the Handling Special Layer-specific Requirements section below.
  9. Rename the completed footprint by double-clicking on its name in the Footprints list in the PCB Library panel to open the PCB Library Footprint dialog. Enter the desired name; names can be up to 255 characters.
For a standardized pad / via definition across all footprints, the PAD/Via library (*.PvLiB) can be used for Pad/Via placement.  

Creating a Component Using the IPC Compliant Footprint Wizard

The IPC Compliant Footprint Wizard creates IPC-compliant component footprints. Rather than working directly from footprint dimensions, the Wizard uses dimensional information from the component itself, then calculates suitable pad and other footprint properties in accordance with the algorithms released by the IPC.

   One of the supported packages in the IPC Compliant Footprint Wizard is the DPAK (Transistor Outline).

  • Select Tools » IPC Compliant Footprint Wizard  from a PCB Library (*.PcbLib) document to run the IPC Compliant Footprint Wizard.
  • The wizard can create the following footprint type: BGA, BQFP, CAPAE, CFP, CHIP Array, DFN, CHIP, CQFP, DPAK, LCC, LGA, MELF, MOLDED, PLCC, PQFN, PQFP, PSON, QFN, QFN-2ROW, SODFL, SOIC, SOJ, SON, SOP/TSOP, SOT143/343, SOT223, SOT23, SOT89, SOTFL, and WIRE WOUND.
  • The IPC Compliant Footprint Wizard uses dimensional information from the component itself in accordance with the standards released by the IPC.

Some of the IPC Compliant Footprint Wizard features include:

  • Overall packaging dimensions, pin information, heel spacing, solder fillets, and tolerances can be entered and immediately viewed.
  • Mechanical dimensions, such as Courtyard, Assembly, and Component (3D) Body Information, can be entered.
  • The Wizard is re-entrant and allows reviewing and making adjustments easy. Previews of the footprint are shown at every stage.
  • The finish button can be pressed at any stage to generate the currently previewed footprint.
If you click Finish before completing the entire Wizard, the footprint will be created using the system defaults for the component type you selected.

Creating a Component Using the IPC Footprint Batch Generator

The IPC Footprint Batch Generator can be used to generate multiple footprints at multiple density levels. The generator reads the dimensional data of electronic components from an Excel spreadsheet or comma delimited file then applies the IPC equations to build IPC compliant footprints. Support for the IPC Footprints Batch Generator includes:

  • Package type blank template files are included in the \Templates folder in the Altium NEXUS installation.
  • Package input files can contain the information for one or more footprints of a single package type and can be either an Excel or comma-delimited (CSV) format file.


The IPC Footprints Batch Generator has options to either create all the footprints in the open PCB footprint
library or generate a single library based on either an input file or footprint name.

Creating a Component Using the Footprint Wizard

The PCB Library Editor includes a Footprint Wizard. This Wizard allows you to select from various package types and fill in appropriate information and it will then build the component footprint for you. Note that in the Footprint Wizard you enter the sizes required for the pads and component overlay.

To launch the Footprint Wizard, right-click in the Footprints section of the PCB Library panel then select Footprint Wizard or select Tools » Footprint Wizard from the main menus.

Including a 3D Model of the Component

A 3D representation of the component can be included in the footprint. The following 3D model formats can be used in Altium NEXUS:

  • Altium NEXUS 3D Body Objects - place these to build up the required component shape.
  • STEP models - *.Stp and *.Step.
  • SolidWorks parts - *.SldPrt.
  • Parasolid Models - *.x_t and *.x_b.

The shape can be created by placing a number of Altium NEXUS 3D Body objects to build up the shape by placing one 3D Body object and importing a 3D model into it or a combination of both. 

  • Allocate a mechanical layer for 3D Body objects then during placement, ensure that this layer is selected in the Properties panel.
The Properties panel can also be used to reference a 3D model stored in a server. 
  • Building a component shape from 3D Body objects is generally easier with the display in 2D mode. Available shapes for 3D Body objects include extruded, cylindrical or spherical.
  • To switch the PCB Library editor between 2D and 3D display modes, press the 2 and 3 hotkey shortcuts.
  • 3D component models can be downloaded from component manufacturer websites or shared resource sites such as www.3dContentCentral.com.
  • 3D models are easier to place with the display in 3D mode. To place a Generic 3D model, first place a 3D Body object, when the Properties panel opens, set the 3D Model Type to Generic, select the Embed Model option in the Source region. Click the Choose button to browse and locate the 3D model file.
  • When a 3D model is clicked and held to be moved, it will be held by the nearest vertex belonging to the 3D Body object the 3D model is embedded in or by a snap point defined on the 3D model. Snap Points can be defined in the Properties panel Snap Points region or by using the Tools » 3D Body Placement » Add Snap Points From Vertices command. This command is interactive; watch the Status bar for prompts. Note that the command has two modes. The default is to add a Snap Point at the vertex chosen by the user. The second mode is enabled by pressing the Spacebar after launching the command. In this mode the Status bar prompts you to click on two points. The software then calculates and positions the Snap Point at the mid-point of the two clicks.
  • Use the standard Windows shortcuts to zoom and pan when the PCB Library editor is in 3D display mode. As in 2D mode, click and hold the right-mouse button to pan or slide the document. To rotate the view, hold the Shift key then click and hold the right-mouse button. Alternatively, use a 3D mouse, such as the Space Navigator™.
  • The List panel is good for editing 3D Body object properties, such as dimension, rotation and color. These panels allow you to easily edit a value and immediately see the impact – ideal for tasks such as rotating a 3D model.
  • 3D model support is not limited to components. It also can be used to import other mechanical detail such as a bracket or the finished enclosure. Import the enclosure directly into the PCB editor. If it is linked rather than embedded, when a change is made to the linked 3D model, a warning dialog pops up in the PCB editor offering to reload the 3D model.

The same footprint: on the left, the physical component has been created from a set of 3D Body objects; on the right, a STEP model has been imported.
The same footprint: on the left, the physical component has been created from a set of 3D Body objects; on the right, a STEP model has been imported.

Note that Altium NEXUS’s 3D view mode requires a graphics card that supports Microsoft DirectX 9 (or better) with Shader Model 3 (or better).

Creating Footprints With Irregular Shapes

Some footprints require pads that have an irregular shape. This can be done using any of the design objects available in the PCB Library Editor, but when doing this, there is an important factor that must be kept in mind.


Create irregular shaped pads by placing multiple objects.

Altium NEXUS automatically adds solder and paste masks to pad objects based on their shape. Default expansion values are defined by design rules by default, although they can also be specified by the Pad settings contained on the PCB Editor - Defaults page of the Preferences dialog. These settings can be overridden during placement or after placement through the Properties panel.

For more information about using design rules to define default expansion values, see the Mask Rules pages under the Design Rules Reference section.

Creating a Custom Pad Shape

Main article: Working with Custom Pad Shapes

If only pad objects have been used to build up an irregular shape, the matching irregular mask shape will automatically be generated as an expansion of the pad shape. But if the irregular shape was built up using other objects, such as lines (tracks), fills, regions, pads, vias, or arcs, the solder and paste masks will need to be configured manually.

All object-kinds have a solder mask property, and fill and region objects also have a paste mask expansion property. If these objects have been placed on the top layer to create a pad shape, then the solder mask property of those objects can be enabled to either obey the applicable design rule, or use a manual expansion value. If fill and region objects have been used to build up a pad shape, then the paste mask can also be enabled as a property of the extra objects.

When the mask shape is not correctly created as an expansion (or contraction) of the set of objects used to create the custom pad shape, then manually defined solder and paste mask expansions can be also achieved by placing lines (tracks), fills, regions, or arc primitives directly on the corresponding solder or paste mask layer. The custom button footprint shown below is an example of this.

A pad object must be used within a custom pad shape so that the software knows where to attach the net.

Displaying Solder / Paste Masks

To check that solder and/or paste masks have been correctly defined in the PCB Library Editor, open the View Configuration panel and enable the show option ( ) option for each mask layer.

The image in the Footprints with Multiple Pads Connected to the Same Pin section below shows a PCB footprint with a purple (color of the Top Solder Mask layer) border that appears around the edge of each pad. This represents the edge of the solder mask shape protruding by the expansion amount from under the pad.

To quickly walk through layers, use the Single Layer Mode (Shift+S) in combination with Ctrl+Shift+Wheel roll

Handling Special Solder Mask Requirements

The footprint shown below is the contact set for a push button switch implemented directly in the copper on the surface layer of the PCB.


Printed push button footprint designed by placing pads, lines and arcs.

A rubber switchpad overlay is placed on the PCB, with a small captive carbon button that contacts both sets of fingers in the footprint when the button is pressed to create the electrical connectivity. For this to happen, both sets of fingers must not be covered by the solder mask.

The circular solder mask opening has been achieved by placing an arc whose width is equal to or greater than the arc radius, resulting in the solid purple circle shown behind the two sets of fingers. Each set of copper fingers has been defined by an arc, horizontal lines, and a pad (selected in the image to make them visible). The pads are required to define the points of connectivity. Manually placed top solder mask definitions are automatically be transferred to the bottom side solder mask layer if the component is placed on the bottom side of the board.

Creating a Free-Form Solder Paste Stencil

As described above, a common approach to defining custom shapes on the mask layers is to build up the shape on the Solder Mask or Paste Mask layer from standard objects.

These objects can include pads, which designers sometimes choose to achieve a rounded rectangle shape they require on the solder paste layer. However, if the designer is intending to perform Pin/Part Swapping this will not function correctly, because a component with these additional pads in the solder paste layer will not synchronize correctly to the component pins on the schematic.

In this situation, the required shape can be created from a Region object. Rather than drawing the region object, it can sometimes be simpler to define the outline of the shape from line and arc objects, and then convert that shape to a region object, as demonstrated below.

The required rounded rectangle shape is create by tracing a pad with lines and arcs, and then converting the shape formed by the lines and arcs, to a region object.

Managing Components With Routing Primitives

When a design is transferred, the footprint specified in each component is extracted from the available libraries and placed on the board. Then each pad in the footprint has its net property set to the name of the net connected to that component pin in the schematic. All objects touching a pad connect to the same net as the pad.

The PCB Editor includes a comprehensive net management tool. To launch it select Design » Netlist » Configure Physical Nets from the main menus to open the Configure Physical Nets dialog. Click the Menu button for a menu of options. Click the New Net Name header drop-down to select the net to assign to the unassigned primitives.

Footprints With Multiple Pads Connected to the Same Pin

The footprint shown below, a SOT223 transistor, has multiple pads that are connected to the same logical schematic component pin - Pin 2. To make this connection, two pads have been added with the same designator - '2'. When the Design » Update PCB command is used in the Schematic Editor to transfer design information to the PCB, the resulting synchronization will show the connection lines going to both pads in the PCB Editor.


SOT223 footprint showing two pads with a designator of 2.

Parameter Support

Parameters applied to objects in Altium NEXUS provide a powerful and flexible means of adding additional information to a PCB design. Applied as properties of the parent object, parameters can be applied at a range of levels, including projects, documents, templates, and individual objects within a design document.

See the Parameter object for more information.

Parameters that become available in the PCB space can be used to filter Queries, Design Rules, Scripts, and Variants, and can be applied in PCB component libraries for invoking custom strings in placed Footprints.

Parameters via an Engineering Change Order

The PCB parameter capabilities are based on functionality included in the ECO mechanism and PCB document, which allow user-defined component parameters to be transferred to and retained in the PCB space. This is a one-way transfer and the passed parameters are read-only in the PCB domain.

The parameter transfer is done by creating an ECO from the schematic to PCB with the Design » Update PCB Document menu command.

When the ECO is executed (by using the Execute Changes button), any new user-defined schematic component parameters will be transferred to the corresponding footprint reference in the PCB design. 

The detection and migration of parameters to the PCB is determined by the project's options settings (Project » Project Options). In the Project Options dialog, set the difference detection and modification behavior in the Differences Associated with Parameters section of the Comparator tab and the Modifications Associated with Parameters section of the ECO Generation tab.

To view the transferred parameters in the PCB editor, double-click a component to open the Properties panel then choose the Parameters tab. The tab will list the current user parameters that have been assigned to the selected component footprint. Parameters for a selected component footprint also are available in the Components panel.

The PCB domain automatically accepts the predefined ComponentLink parameters from the schematic. These are defined as parameter pairs (Description and link URL) that normally establish data reference links to specific files or internet locations – typically a manufacturer web site or datasheet URL.

See the Schematic Document Reference Link command and PCB Component Link command for information on Reference Link parameters.

In both the schematic and PCB design space, the links are accessed from the right-click context menu when hovering over a component (under the References sub-menu options). The specialized parameters are added in the Properties panel, and when transferred to the PCB space, they appear as a component footprint parameter. 

Parameters in Source Footprints

Parameters passed to the PCB can be used for providing additional board production or functional information via component footprints. By adding special parameter strings to footprints at the source library level, the custom strings will be interpreted on the target mechanical layer or overlay.

A special string representing a user-defined parameter can be added to the source component footprint using the special strings button and drop-down ( ) in the Properties panel.

In the below library footprint, the special string .Designator has been placed on the Mechanical 2 layer.

A special string representing a user parameter can be added to the component footprint.

A special string representing a user parameter can be added to the component footprint.

When that custom parameter has also been applied to schematic components and the parameter data has been transferred to the PCB, the interpreted footprint strings will appear on both the board view and generated output files. In this case the special parameter string contains a custom component part identifier to aid assembly.

The application of the user parameters to component footprints as special strings can serve a range of other custom PCB requirements, including function labels for switches and connectors, where a 'function' parameter string might be placed on the Top Overlay in footprints for those component types.

To see the interpreted value of special strings on the board layout, enable Special Strings option under the Additional Options region of the View Options tab in the View Configuration panel. Special strings are always converted in generated output files.
In the schematic editor, if desired, enable the Display Names of Special Strings that have No Value Defined option on the Schematic – Graphical Editing page of the Preferences dialog.

Parameter Queries

Parameter strings in the PCB domain are also accessible through the Altium NEXUS query language, and therefore, are available for object filtering functions, including the Find Similar Objects feature.

To perform a similar objects selection, right-click on a component then select Find Similar Objects from the context menu to open the Find Similar Objects dialog.

The Find Similar Objects dialog includes a Parameters section where the filtering options can be selected as required.

The PCB Filter panel can apply parameter-specific query words as filter criteria, and can be used for creating Design Rules based on PCB parameters.

Several query words are available for working with PCB footprint parameters, including specific function words for converting string values to numbers (such as StrToNumber). The string Value conversions are unit-aware (V, mA, mV, kOhm etc.,) and allow the query result to be determined by the numerical processing of a parameter value string.

The supported Unit Types that can be nominated in the queries are:

  • % – Percent
  • A – Current
  • C – Temperature
  • dB – Decibels
  • F – Capacitance
  • G – Conductance
  • H – Inductance
  • Hz – Frequency
  • Kg – Mass
  • m – Length
  • Ohm – Resistance
  • Q – Charge
  • s – Time
  • V – Voltage
  • W – Power
  • Z – Impedance

Several Parameter query words are available for working with PCB component footprint parameters.

Several Parameter query words are available for working with PCB component footprint parameters.

The example shown in the Query Helper dialog above processes the Voltage Rating parameter for each component (using the string-to-number conversion – StrToNumber(Unit Value, Unit Type))  to determine if its value is greater than 50V. When applied in the PCB Filter panel, the example board layout exposes a single high-voltage component, C1 (which has a Voltage Rating value of 3kV).

Scientific E notation is also supported, so, for example, a query to filter capacitor values over 1nF would be similar to:
StrToNumber(ParameterValue('CapacitanceValue'), F) > 1e-9
Alternatively, the number conversion function could be used for both the returned ParameterValue and the comparison value:
StrToNumber(ParameterValue('CapacitanceValue'), F) > StrToNumber('1nF', F)

Rules and Scripts

PCB parameter queries can also be applied to Altium NEXUS Scripts and Design Rules. The latter might perform layout validation checks, such as detecting footprint parameters in order to assess component placement or layer assignment. Note that the functions listed in the Query Helper dialog above are available to the Scripting language.

The below example shows the capacitor voltage rating query (see the filter query above) applied to a component placement rule, which, when run, checks for specific clearance values for components detected as high voltage (>50V) devices.

Design rules defined by specific footprint parameters, as transferred from the schematic space, can be used for detecting custom layout conditions.

Design rules defined by specific footprint parameters, as transferred from the schematic space, can be used for detecting custom layout conditions.

Similarly, custom PCB parameters can be used to check component layer compatibility, for example, where a component does not support wave soldering and therefore placement of the Bottom Layer. Here, an object matching query that processes a custom ‘WaveSoldering’ parameter (Yes/No) might be applied to the Permitted Layers Rule.

The (batch) Rule will subsequently check the value of that component parameter and create a violation if a component is not compatible with placement on the Bottom Layer.

Variants

Parameters transferred to the PCB that are included in variations of the design (Design Variants) are processed with Variant selection.

In practice, a varied component parameter in the PCB space will be dynamically detected by a query string, or, for example, displayed on a board layer through a special string. 

Designator and Comment Strings

Default Designator and Comment Strings

When a footprint is placed on a board, it is given a Designator and Comment based on information extracted from the schematic view of the design. Placeholders for the Designator and Comment strings do not need to be manually defined since they are added automatically when the footprint is placed on a board. The locations of these strings is determined by the Designator and Comment string Autoposition option in the Properties panel. The default position and size of Designator and Comment strings is configured in the respective Primitive on the PCB Editor - Defaults page of the Preferences dialog.

Additional Designator and Comment Strings

There may be situations where additional copies of the Designator or Comment strings are required. For example. the assembly house might want a detailed assembly drawing with the designator shown within each component outline, while in-house company requirements stipulate the designator to be located just above the component on the component overlay on the final PCB. This requirement for an additional designator can be achieved by including the .Designator special string in the footprint. A .Comment special string also is available for stipulating the location of the comment string on alternate layers or locations.

To cater for the assembly house's requirements, the .Designator string would be placed on a mechanical layer in the library editor and print outs that included this layer could then be generated as part of the design assembly instructions.

Handling Special Layer-specific Requirements

There are a number of special requirements a PCB component can have, such as needing a glue dot or a peel-able solder mask definition. Many of these special requirements will be tied to the side of the board on which the component is mounted and must flip to the other side of the board when the component is flipped.

Rather than including a large number of special purpose layers that may rarely be used, Altium NEXUS's PCB editor supports this requirement through a feature called layer pairs. A layer pair is two mechanical layers that have been defined as a pair. Whenever a component is flipped from one side of the board to the other, any objects on a paired mechanical layer are flipped to the other mechanical layer in that pair.

Layer Pairing needs to be defined before the component gets flipped. If the pairing is defined after the component has moved to the bottom side, the mechanical contents will flip but stay on their original layer. If you forget to create layer pairs before flipping, you can update from the library to refresh the instance of the component placed on the board.

The Names of Mechanical Layers can be edited directly from the View Configurations panel by right-clicking then selecting Edit Layer.

A common approach to managing mechanical layer usage is to assign a dedicated layer number for each required mechanical layer function. This approach requires all designers to adhere to the same layer assignment and numbering scheme. It can also create difficulties when components are obtained from other sources that do not follow the same assignment and numbering scheme. If a different scheme has been used, the design objects must be moved from their current mechanical layer to the mechanical layer assigned for that function.

This issue is resolved with the introduction of the Layer Type property. When a component is placed from a library into the PCB editor, or copied from one library to another, or created by the IPC Footprint Wizard, existing Layer Type assignments are automatically matched, regardless of the mechanical layer number(s) assigned to those Layer Types. The objects are relocated on the correct layer(s) according to their Layer Type. If the software is unable to match by Layer Type, it will fall back to matching by Layer Number.

For both individual mechanical layers and Component Layer Pairs, you can select a Layer Type from a pre-defined list of types. You may access the dialogs shown below by right-clicking on an individual layer, then selecting the Edit Layer or Add Component Layer command from the menu.

For detailed information about component-related mechanical layer types, refer to the Working with Mechanical Layers page.

Adding Height to a PCB Footprint

At the simplest level of 3D representation, height information can be added to a PCB Component. To do this, double-click on a footprint in the Footprints list in the PCB Library panel to open the PCB Library Footprint dialog. Enter the recommended height for the component in the Height field.

Height design rules can be defined during board design (click Design » Rules in the PCB Editor), typically testing for maximum component height in a class of components or within a room definition.

A better option for defining height information would be to attach 3D Bodies and/or a STEP model to the PCB Component. Details of this will be discussed in another module.

Adding Footprints from Other Sources

PCB Components can be copied from other PCB Libraries and then renamed and modified within the destination library to match the specifications required. There are a number of ways to execute this function.

  • Select placed footprint(s) in a PCB document then copy (Edit » Copy) and paste them into an open PCB library using Edit » Paste Component.
  • Select Edit » Copy Component when the footprint to be copied is active in the PCB Library Editor, change to the open PCB destination library then select Edit » Paste Component.
  • Select one or more footprints in the list in the panel using the standard Shift+Click or Ctrl+Click, right-click then choose Copy. Switch to the target library, right-click in the list of footprint names then choose Paste.

Validating Component Footprints

There are a series of reports that you can run to check that footprints have been created correctly as well as identifying which components are in the current PCB library.

The Component Rule Check report (Reports » Component Rule Check) is useful for validating all components in the current PCB library by testing for duplicate primitives, missing pad designators, floating copper, and inappropriate component references.

Validating PCB Libraries Within an Integrated Library

Including PCB Libraries as part of a Integrated Library Package provides an additional layer of validation because it allows the Design Compiler to examine the Schematic and PCB models together. This, of course, requires that a Schematic Library that matches the PCB Library exists however assuming this is the case, a range of additional checks are possible using the Error Reporting tab of the Project Options dialog.

Updating a PCB Footprint

Updating a PCB Footprint can be done in two ways: "Pushing" the PCB from the PCB Library, or by "Pulling: from the PCB Editor. Pushing a PCB Footprint update takes a selected footprint(s) from the PCB Library and uses it to update all open PCB documents containing that footprint. This first method is the best option when a complete replacement is desired. The second option allows you to review all the differences between the existing footprint and the footprint in the library before the update is performed. You can also select which objects are to be updated from the library. This second method is the best option when you need to figure out exactly what has changed between the footprint on the board and the footprint in the library.

Pushing Footprint Updates from the PCB Library

From the PCBLIB Editor, use the Tools » Update PCB with Current Footprint or Tools » Update PCB With All Footprints command. From the PCB Library panel, right-click in the Components region of the PCB Library panel then select Update PCB with [Component] or Update PCB with All. Running these commands opens the Component(s) Update Options dialog from which you can select the primitives/attributes to be updated.

The selected updates will be pushed to correlating footprints in all open PCB documents.

Pulling Footprint Updates from the PCB Editor

From the PCB editor, use the Tools » Update From PCB Libraries command, which, in turn, opens the Update From PCB Libraries - Options. Click OK to open the Update From PCB Libraries dialog.

Releasing Completed PCB Footprints to a Server

A PCB 2D/3D component model can be edited and released into the initial revision of a newly-created Footprint Item through the server's support for direct editing through the Explorer panel or by using the Component Editor in Single Component Editor mode. Through direct editing, you can edit a supported Item type using a temporary editor loaded with the latest source direct from the server itself. After editing is complete, the entity is released (or re-released) into a subsequent planned revision of its parent Item and the temporary editor is closed. 

For detailed information about managed footprints, refer to the Managed PCB Footprint Models page.
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