将您的设计理念转化为原理图

您正在阅读的是 17.0. 版本。关于最新版本,请前往 将您的设计理念转化为原理图 阅读 25 版本

Schematic capture is the process of creating a logical representation of an electronic circuit. When you capture a schematic you are connecting a collection of symbols (components) together in a unique way, creating your unique electronic product. When you perform your schematic capture electronically, you can create more than a a high quality printed representation of the design, you can also perform related design tasks, such as a circuit simulation, and can transfer the design to a PCB layout tool.

The process sounds simple enough, right, place some components and wire them up - however the challenge is in the detail. On one hand there's the detail around the idea - will that complex concept actually work? On the other hand, there's the detail that comes with drafting a circuit that can have tens to hundreds of components, connected by hundreds to thousands of nets - is it wired correctly?

For both of these reasons, an electronics design tends to evolve. The circuit will typically be created in sections, here's the processor and memory, here's the analog to digital processing of inputs, here's the display interface, here's the power supply, and so on. Altium Designer has a number of features to help you design in this way. You can capture the sections on separate schematic sheets, then build up the overall design as you are ready. You can transfer a section of the design to the PCB editor, then transfer additional sections when they are ready. You can even easily re-use an existing circuit, either using a simple copy/paste/reannotate process; or as a device sheet, where the source schematic is not edited.

Before you create your first schematic, create the project. The project brings together all of the files in the design, and stores the setup and error checking settings.


Finding and Placing the Components

The heart of any electronics design is the components. While there are 100,000s of components that can be sourced from the Altium Content Vault and available libraries, you will also need to create your own.

The component that you ultimately solder onto the board needs to be represented, or modeled, in each design domain - as a symbol on the schematic, as a SPICE model in the simulator, as a footprint on the board, and as a 3D STEP model in the file you hand off to the mechanical designer.

Read more about Understanding Models, Components and Libraries.

A popular approach to working with the components is through the Libraries panel. You can access available libraries through the panel, and can also map preferred Vault folders into the panel, as a library. Alternatively, Vault components can be searched for and placed from the Vaults panel.

Read more about Finding and Placing Components.


Connecting the Components

Components are connected by wiring the pins together, or by placing net identifiers to connect the pins in that net.

Read more about Creating Connectivity.

If the design includes high pin-count components, then it is simply not practical to create all of the connectivity using individual wires. Multiple nets can be bundled into a Bus if they are members of a numerically incrementing set, such as Data0, Data1, and so on. Alternatively, any combination of nets and buses can be bundled into a Signal Harness, which offer a visually and logically neat way of transferring multiple nets throughout your design.

Read more about Bundling multiple nets.


Spreading the Design Over Multiple Sheets

Small format printers are the norm today, so anything other than the simplest design will be spread over multiple schematic sheets. There are 2 approaches to organizing a design over multiple sheets, either flat or hierarchical.

In a flat design, you can think of the design as a large, single sheet, that has been cut into smaller sheets.

Alternatively, you can arrange the design in a tree-like, or hierarchical structure, using a symbol to represent each lower-level sheet.

Both approaches are valid, each has its own strengths and weaknesses. A flat design will be quicker to create, but harder for others to follow signals and interpret the functionality, especially from a printed copy. An hierarchical design will take longer to draw as there are more steps to create the connectivity, with the reward being a design where others can more easily interpret its functionality, and follow the signals across the sheets. Hierarchical design is also important for design reuse, and an essential part of a multi-channel design.


Compiling and Verifying the Design

The schematic editor is actually an intelligent drawing tool, rather than a wiring tool. The connectivity defined by the wiring you place is established when you compile the project, not as you place the wires.  This approach of separating the capture process from the design analysis and verification process, means you can place and wire quickly and efficiently. Then when you are ready, compile the design and verify that it fulfills the electrical requirements.

Compiling the design builds the Unified Data Model - this single data model resolves many of the problems that come with the silo'd approach of separate design editors used by other design environments. In Altium Designer, the compiled view of the design is available to all of the editors, providing that editor with a complete view of the design.

Now that capture is complete, is the design correct, are there electrical or drafting errors? There's no point designing a PCB from an incorrect circuit,  compiling and verifying the design is an essential part of the process.

Place a compile mask to hide sections of the design that are not ready for error checking or transfer to the PCB editor. When you are ready, click the control to collapse the mask, exposing the circuit to be included in the compilation process and design transfer.

Compile masks belongs to a class of objects called design directives, use these to add design-level instructions (directions) to the schematic, such as: membership of a net class; or, identifying a location where the compiler is to ignore a specific violation; or, identifying a group of nets that are differential pairs, and so on.

Hover over the image for a demonstration of a compile mask.

Adding Detail to the Design

The output from the capture stage is an electrically complete and accurate schematic, and a detailed and functional set of print-ready schematic pages.

When you are designing in the schematic editor, use templates to create consistent-looking schematics, enhance their functionality and readability with notes and images, and generate PDF output, complete with bookmarks and additional component data.


Where to Next?

Like all of Altium's design technologies, the Schematic editor is designed to be quick to learn and easy to work in. Context sensitive right-click menus are used extensively, and context-sensitive help (F1) and in-command shortcut lists (Shift+F1) are available everywhere.

If you're new to Altium's design software, you might like to start with the concept to completion tutorial - based around a simple nine component circuit, you'll start with a blank schematic sheet and end up with the PCB, along with the files needed to fabricate the board.

Otherwise, you might like to check out the following articles:

 

 

If you find an issue, select the text/image and pressCtrl + Enterto send us your feedback.

软件的功能取决于您购买的Altium产品级别。您可以比较Altium Designer软件订阅的各个级别中包含的功能,以及通过Altium 365平台提供的应用程序所能实现的功能。

如果您在软件中找不到某个讨论过的功能,请联系Altium销售团队以获取更多信息。