Altium Designer Tutorial: Step by Step Guide.
Altium Circuit Maker Beginner Course. Free tutorial. Rating: out of 5 ( ratings) 5, students. 1hr 54min of on-demand video. Created by Sven Ingelfinger. English. 8 years experience in Hardware Design and 6 years of it in everyday working experience with Altium Designer. about 40 projects from schematic design, component. Altium designer 17 manual pdf. Step-by-Step tutorial. A PDF 3D file will be created in 3D format, regardless of the current PCB Editor view mode (2D or 3D). Our Microsoft licensing experts can determine if buying through one of these systems is best for altium designer 17 tutorial pdf your business. Altium Designer Guide Beginning & Intermediate Version Glenn Mercier mercierg@ Research Engineer, TBE-B University of Las Vegas, Nevada. Part 1: Beginning Guide This guide is a beginner’s guide to PCB design using Altium Designer and is geared towards the following individuals: Beginning Guide Before proceeding to the.
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Altium designer 17 tutorial for beginners free
The design you will be capturing and then designing a printed circuit board PCB for is a simple astable multivibrator. The circuit is shown below, it uses two general purpose NPN transistors configured as a self-running astable multivibrator. Circuit for the multivibrator.
You’re ready to begin capturing drawing the schematic. The first step is to create a PCB project. Main article: New Project. In Altium’s software, a PCB project is the set of design documents files required to specify and manufacture a printed circuit board. The project file, for example Multivibrator. PrjPCB , is an ASCII file that lists which documents are in the project, as well as other project-level settings, such as the required electrical rule checks, project preferences, and project outputs, such as print and CAM settings.
Create the new PCB project in the required location. Enabling the Add Project to Version Control option will result in the project’s source files being stored in an available SVN repository click Managed Repositories , and check out the working copies into the folder specified in the Location field. To learn more about version control support, refer to the Version Control and Design Repositories article.
If the Managed Project option is enabled, the source files are stored stored in an available SVN repository and the project outputs are stored in an available Altium Vault. Add a schematic sheet to the project, name and save the schematic, and save the project. When the blank schematic sheet opens you will notice that the workspace changes. The main toolbar includes a range of new buttons, new toolbars are visible, the menu bar includes new items, and the Sheet panel is displayed – you are now in the Schematic Editor.
The floating panel s can be closed using the icon at the top right of the panel, when needed they can be reopened via the buttons down the bottom right of the application. Main article: Document Options.
Before you start drawing your circuit, is is worth setting up the appropriate document options, including the Sheet Size, and the Snap and Visible grids. Document options are configured for each schematic sheet, set the sheet size as required. As well as the technique described in the collapsible section below, the Document Options dialog can be opened by double-clicking in the sheet border. Environment options, such as the cursor type, selection color and auto pan behavior are configured in the Preferences dialog File » System Preferences.
Related article: More about Components and Libraries. This section of the tutorial will explain the two different approaches to working with components from libraries, or from the Vault.
In the following section, you will locate and place the components you need, from the Vault. 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 Designer components can be:. Both of these panels can be accessed via the System menu, click the button down the bottom right of the application to display the menu. The menus provides quick access to the panels. Access components through either: the Libraries panel, or the Vaults panel.
Main article: Available Libraries. In Altium Designer, library-based components can be placed from Available Libraries. The libraries that are available include:. Libraries are installed in the Installed tab of the Available Libraries dialog. To open the dialog, click the Libraries button at the top of the Libraries panel. If the panel is not currently visible, click System » Libraries to display it. Install the required libraries to make their components available for designs.
To help you find the component you need, Altium Designer includes powerful library searching capabilities. Although there are components that are suitable for the multivibrator design available in the pre-installed libraries, it is useful to know how to use the search feature to find components.
The Libraries Search dialog is accessed by clicking the Search button on the Libraries panel. The upper half of the dialog is used to define what you are searching for, the lower half is used to define where to search. Search for the component using the Libraries Search dialog. You can search across installed libraries Available libraries , or libraries on the hard drive Libraries on path.
If you are working from libraries, the first step is to search for a suitable general-purpose NPN transistor, such as a 2N The tutorial components are going to be placed from the Vault, which is discussed shortly. Library searching is actually performed using queries.
In the Libraries Search dialog, switch to the Advanced mode to examine the query. Libraries that are already installed are listed in the drop down at the top of the panel, click to select a library and display the components stored in it. Select the Miscellaneous Devices library from the list, then use the component Filter in the panel to locate the required 2N component within the library as shown in the image below.
Since the Miscellaneous Devices library is already installed, this component is ready to place. Do not place it though, instead you will use a transistor from the Altium Content Vault.
Filtering the library for components with the string somewhere in their name. Main article: Data Management – Vaults. To access the components in the Content Vault, you must first connect to it. Once you have connected to the Altium Content Vault, you can place components from the Vault into your design. Related article: Vaults panel. Once you have connected to the Altium Content Vault, you can explore or search for a component.
The panel includes a powerful search feature, enter the search string into the search field at the top-right of the panel, as shown in the image below. Click to examine a component of interest. The Vaults panel includes a number of sections, which can be resized as required. Take some time to explore the features and behavior of the panel, right-click for context-specific commands. Use the Preview mode to examine the models and parameters included with the selected component.
Components are placed from the Libraries or Vaults panel onto the current schematic sheet. This can be done by:. Main article: Libraries Panel. Main article: Vaults Panel. The next step is to search the Content Vault for the following componentsto use in the Multivibrator circuit.
You can proceed to find and place the components. Note that the collapsible sections below include tips on editing during placement, which is more efficient.
If you choose to leave the editing until after the components are placed, double-click on a component to edit it. All the components have been placed, ready for wiring. Set the Designator to Q1, and the Comment to be Visible. You have now placed all the components. Note that the components shown in the image above are spaced so that there is plenty of room to wire to each component pin.
This is important because you can not place a wire across the bottom of a pin to get to a pin beyond it. If you do, both pins will connect to the wire. If you need to move a component, click-and-hold on the body of the component, then drag the mouse to reposition it. Wiring is the process of creating connectivity between the various components of your circuit.
To wire up your schematic, refer to the sketch of the circuit and the animation shown below. Use the Wiring tool to wire up your circuit, towards the end of the animation you can see how wires can be dragged. Each set of component pins that you have connected to each other now form what is referred to as a net. For example, one net includes the base of Q1, one pin of R1 and one pin of C1. Each net is automatically assigned a system-generated name, which is based on one of the component pins in that net.
To make it easy to identify important nets in the design, you can add Net Labels to assign names. For the multivibrator circuit, you will label the 12V and GND nets in the circuit, as shown below. The net label in free space left image and positioned over a wire right image , note the red cross.
You have just completed your first schematic capture. Before you turn the schematic into a circuit board you need to configure the project options, and check the design for errors. The project options include the error checking parameters, a connectivity matrix, Class Generator, the Comparator setup, ECO generation, output paths and connectivity options, Multi-Channel naming formats, Default Print setups, Search Paths, and project-level Parameters.
These settings are used when you compile the project. Project outputs, such as assembly, fabrication outputs and reports can be set up from the File and Reports menus. These settings are also stored in the Project file so they are always available for this project.
An alternate approach is to use an OutputJob file to configure the outputs, with the advantage that an OutputJob can be copied from one project to the next. See More About Outputs to learn more configuring the outputs. After you complete the schematic in Altium Designer, you compile it. This generates an internal connectivity map of the design, detailing all of the components and nets.
When the project is compiled, comprehensive design and electrical rules are also applied to verify the design. When all errors are resolved, the compiled schematic design is ready to be transferred to the target PCB document by generating a series of Engineering Change Orders ECOs. Underlying this process is a comparator engine that identifies every difference between the schematic design and the PCB, and generates an ECO to resolve each difference.
This approach of using a comparator engine to identify differences means you not only work directly between the schematic and PCB there is no intermediate netlist file used , it also means the same approach can be used to synchronize the schematic and PCB at any stage during the design process.
The comparator engine also allows you to find differences between source and target files and update synchronize in both directions. Schematic diagrams are more than just simple drawings – they contain electrical connectivity information about the circuit.
You can use this connectivity awareness to verify your design. When you compile a project, the software checks for errors according to the rules set up in the Error Reporting and Connection Matrix tabs of the Options for Project dialog.
When you compile the project any violations that are detected will display in the Messages panel. Main article: Error Reporting. The Error Reporting tab in the Options for Project dialog is used to set up a large range of drafting and component configuration checks. The Report Mode settings show the level of severity of a violation. If you wish to change a setting, click on a Report Mode next to the violation you wish to change and choose the level of severity from the drop-down list.
For this tutorial there is one check that must be changed. The components in the tutorial have been placed from an Altium Vault, and Vault components support the concept of revisions – where a component can be updated and a new revision released. However, the components in the Altium Content Vault are not revisioned, so will fail the Inapplicable Revision State check. For the tutorial, this check must be set to No Report , as shown in the image below.
Configure the Error Reporting tab to detect for design errors when the project is compiled. Main article: Connection Martix. When the design is compiled a list of the pins in each net is built in memory. The type of each pin is detected eg: input, output, passive, etc , and then each net is checked to see if there are pin types that should not be connected to each other, for example an output pin connected to another output pin. The Connection Matrix tab of the Options for Project dialog is where you configure what pin types are allowed to connect to each other.
For example, look down the entries on the right side of the matrix diagram and find Output Pin. Read across this row of the matrix till you get to the Open Collector Pin column.
The square where they intersect is orange, indicating that an Output Pin connected to an Open Collector Pin on your schematic will generate an error condition when the project is compiled. You can set each error type with a separate error level, eg.
Click on a colored square to change the setting, continue to click to move to the next check-level. Set the matrix so that Unconnected Passive Pin generates Error , as shown in the image below. The Connection Matrix defines what electrical conditions are checked for on the schematic, note that the Unconnected – Passive Pin setting is being changed. Main article: Class Generation. The Class Generation tab in the Options for Project dialog is used to configure what type of classes are generated from the design the Comparator and ECO Generation tabs are then used to control if classes are transferred to the PCB.
By default, the software will generate Component classes and Rooms for each schematic sheet, and Net Classes for each bus in the design. For a simple, single-sheet design such as this there is no need to generate a component class or a room – ensure that the Component Classes checkbox is cleared, doing this will also disable the creation of a room for that component class.
Note that this tab of the dialog also includes options for User-Defined Classes. The Class Generation tab is used to configure what classes and rooms are automatically created for the design. Main article: Comparator. The Comparator tab in the Options for Project dialog sets which differences between files will be reported or ignored when a project is compiled.
Generally the only time you will need to change settings in this tab is when you add extra detail to the PCB, such as design rules, and do not want those settings removed during design synchronization. If you need more detailed control, then you can selectively control the comparator using the individual comparison settings.
For this tutorial it is sufficient to confirm that the Ignore Rules Defined in PCB Only option is enabled, as shown in the image below. The Comparator tab is used to configure exactly what differences the comparison engine will check for. Main article: Compiling and Verifying the Design.
Compiling a project checks for drafting and electrical rules errors in the design documents, and details all warnings and errors in the Messages panel. You have set up the rules in the Error Checking and Connection Matrix tabs of the Options for Project dialog, so are now ready to check the design. Use the Messages panel to locate and resolve design errors – double-click on an error to pan and zoom to that object.
To clear all messages from the Messages panel, right-click in the panel and select Clear All. The blank PCB has been added to the project. Add a new PCB to your project. Save the PCB file with a meaningful name. Main article: The Board. There are a number of attributes of this blank board that need to be changed before transferring the design from the schematic editor, including:.
Select the command, position the cursor over the lower-left corner of the board shape left image , then click to define the origin right image. For this design, it is more efficient to edit the existing board shape.
These commands are only available in Board Planning Mode. The resize cursor is shown, use the location information on the Status bar to help you resize the board to 30mm x 30mm. The board size has been defined, and the units, origin and grid have been set. The required layers will be configured shortly. A good approach to defining the shape of a non-rectangular board is to place a series of tracks and arcs for curved boards on the keepout layer. As well as being useful as a placement and routing keep-away barrier, these tracks and arcs can be selected Edit » Select » All on Layer and used to create the board shape using the Design » Board Shape » Define from Selected Objects command.
Main article: Working Between the Schematic and the Board. The design is transferred directly between the schematic editor and the PCB editor, there is no intermediate netlist file created. When you run either of these commands the design is compiled and a set of Engineering Change Orders is created, which:. Once the ECOs have been executed, the components are placed outside the board shape and the nets are created. Before transferring the schematic information to the new blank PCB, make sure all the related libraries for both schematic and PCB are available.
Since only the Altium Content Vault is used in this tutorial, the required Vault is already available. As the Vault includes the symbol and the footprint, then the footprints required for the tutorial are also available. For example, if you want the component designators for all of your PCB designs to be 1.
Once all of the ECOs have been executed the components and nets will appear in the PCB workspace, just to the right of the board outline, as shown in the image above. Before you start positioning the components on the board you need to configure certain PCB workspace and board settings, such as the layers, grids and design rules. Main article: View Configurations. As well as the the layers used to fabricate the board, including: signal, power plane, mask and silkscreen layers, the PCB Editor also supports numerous other non-electrical layers.
The layers are often grouped in the following way:. The display attributes of all layers are configured in the View Configurations dialog. To open the dialog:. Press the L shortcut to open the View Configurations dialog. As well as the layer display state and color settings, the View Configurations dialog also gives access to other display settings, including:. Configure other view options, such as the display of net names on pads and tracks. Main article: Layer Stack Manager.
As well as the signal and power plane solid copper layers, the PCB Editor also includes soldermask and silkscreen physical layers – these are all fabricated to make the physical board.
The arrangement of these layers is referred to as the Layer Stack. The tutorial PCB is a simple design and can be routed as a single-sided or double-sided board. The layer thicknesses shown below have been edited to use sensible metric values. The properties of the physical layers are defined in the Layer Stack Manager. To edit a cell either: double-click in the cell; or select the cell and press F2 to show the dropdown or edit the value.
The next step is to select a grid that is suitable for placing and routing the components. All the objects placed in the PCB workspace are placed on the current snap grid. Traditionally, the grid was selected to suit the component pin pitch and the routing technology that you planned to use for the board – that is, how wide do the tracks need to be, and what clearance is needed between tracks.
The basic idea is to have both the tracks and clearances as wide as possible, to lower the fabriction costs and improve the reliability. Over time, components and their pins have dramatically shrunk in size, as has the spacing of their pins. The component dimensions and the spacing of their pins has moved from being predominantly imperial with thru-hole pins, to being more-often metric dimensions with surface mount pins.
If you are starting out a new board design, unless there is a strong reason, such as designing a replacement board to fit into an existing imperial product, you are better off working in metric.
Because the older, imperial components have big pins with lots of room between them. Also, the PCB editor can easily handle routing to off-grid pins, so working with imperial components on a metric board is not onerous. For a design such as this simple tutorial circuit, practical grid and design rule settings would be:. While it might be tempting to select a very fine routing grid so that routing can effectively be placed anywhere, this is not a good approach.
Select View » Toggle Units or press the Q shortcut key to toggle the workspace units between metric and imperial. Altium Designer allows multiple snap grids to be defined. As well as defining the type of grid, you can also define the area where that grid applies.
Note that the Default grid always applies to the entire workspace, even though it is only displayed over the board shape. Since only one grid can be used at a time, grids also have a priority which is used to determine which grid should be applied when they overlap.
There are also controls for defining if a grid is for all objects, components only, or non-components only. Grids are created and managed in the Grid Manager. Multiple grids can be configured in the Grid Manager , an image of these 3 grids is shown on the right click to enlarge. Right-click to add, remove and manage grids, double-click to edit an existing grid. Set the Snap Grid to 1 mm, ready to position the components. The PCB Editor is a rules-driven environment, meaning that as you perform actions that change the design, such as placing tracks, moving components, or autorouting the board, the software monitors each action and checks to see if the design still complies with the design rules.
If it does not, then the error is immediately highlighted as a violation. Setting up the design rules before you start working on the board allows you to remain focused on the task of designing, confident in the knowledge that any design errors will immediately be flagged for your attention.
The rules are divided into 10 categories, which can then be further divided into design rule types. Main article: Width. The width of the routing is controlled by the applicable routing width design rule, which the software automatically selects when you run the Interactive Routing command and click on a net.
When you are configuring the rules, the basic approach is to set the lowest priority rule to target the largest number of nets, and then add higher-priority rules to target nets with special width requirements, such as power nets.
There is no issue if a net is targetted by multiple rules, the software always looks for and only applies the highest priority rule. For example, the tutorial design includes a number of signal nets, and two power nets. The default routing width rule can be configured at 0. This rule will target all nets in the design by setting the rule scope to All.
The image below shows the summary of these two rules, the detail is shown in the images in the following two collapsible sections. Two Routing Width design rules have been defined, the lowest priority rule targets All nets, the higher priority rule targets objects in the 12V net or the GND net. Use these if you prefer to have some flexibility during routing, for example when you need to neck a route down, or use a smaller via in a tight area of the board.
Note that you always remain constrained by the design rules, if you enter a value larger or smaller than permitted by the applicable design rule it will be clipped to the nearest rule value. Avoid using the Min and Max settings to define a single rule to suit all sizes required in the entire design, doing this means you forgo the ability to get the software to monitor that each design object is appropriately sized for its task.
The default Routing Width design rule has been configured. This Width rule targets the power nets. Main article: Clearance Constraint. The next step is to define how close electrical objects that belong to different nets, can be to each other. This requirement is handled by the Electrical Clearance Constraint, for the tutorial a clearance of 0. Note that entering a value into the Minimum Clearance field will automatically apply that value to all of the fields in the grid region at the bottom of the dialog.
You only need to edit in the grid region when you need to define a clearance based on the object-type. The electrical clearance constraint is defined between objects. Switch the Constraints to Advanced to display all object kinds.
Main article: Routing Via Style. As you route and change layers a via is automatically added, in this situation the via properties are defined by the applicable Routing Via Style design rule. If you place a via from the Place menu, its values are defined by the in-built default primitive settings. For the tutorial, you will configure the Routing Via Style design rule.
A single routing via is suitable for all nets in this design. You might have noticed that the transistor pads are showing that there is a violation. Right-click over a violation and select the Violations in the right-click menu, as shown below. The details show that there is a:. Right-click on a violation to examine what rule is being violated, and the violation conditions.
In this image the display is in single layer mode, with the multi-layer as the active layer. This violation will be discussed and resolved shortly. If you find the violation markers distracting, you can clear them by running the Tools » Reset Error Markers command.
This command only clears the marker, it does not hide or remove the actual error. The error will be flagged again the next time you perform an edit action that runs the online DRC such as moving the component , or when you run the batch DRC.
Altium Designer’s internal defaults for a new board are Imperial. That means when you switch to Metric, settings such as the Soldermask expansion will change from rounded values like 4mil, to 0.
While that least significant digit, such as 0. Select Design Rules at the top of the tree on the left of the PCB Rules and Constraints Editor , then you can scan down the Attributes column for all of the rules and quickly locate any that need their values adjusted.
Design rules can also be exported and stored in a. Select the rules you wish to export using the standard Windows selection techniques, then click OK to export the selected rules. While you could argue about the percentage of each, it is generally accepted that good component placement is critical for good board design.
Keep in mind that you may need to tune the placement as you route too. When you click and hold on a component to move it, if the Snap to Center option is on, then the component will move to be held by its reference point. The reference point is the 0,0 coordinate of the component, when it was built in the library editor. The Smart Component Snap option allows you to override this snap to center behavior and snap to the nearest component pad instead, handy when you need to position a specific pad in a specific location.
Enable Snap to Center to always hold the component by its reference point. Smart Component Snap is helpful when you need to align by a specific pad. Components positioned on the board. Select, then align and space the resistors. Selected objects can also be moved using the keyboard rather than the mouse. To do this, hold Ctrl , then each time you press an Arrow key the selection will move 1 grid step in the direction of that arrow.
Include the Shift key to move selected objects in 10x Snap Grid steps. When you are moving a component with the mouse, you can constrain it to an axis by holding the Alt key. The component will attempt to hold the same horizontal axis if moving horizontally or vertical axis if moving vertically – move it further from the axis to override this behavior, or release the Alt key. Main article: Interactive Routing. Routing is the process of laying tracks and vias on the board to connect the component pins.
The PCB editor makes this job easy by providing sophisticated interactive routing tools, as well as the topological autorouter, which optimally routes the whole or part of a board at the click of a button.
While autorouting provides an easy and powerful way to route a board, there will be situations where you will need exact control over the placement of tracks. In these situations you can manually route part or all of your board. In this section of the tutorial, you will manually route the entire board single-sided, with all tracks on the top layer.
The Interactive Routing tools help maximize routing efficiency and flexibility in an intuitive way, including cursor guidance for track placement, single-click routing of the connection, pushing obstacles, automatically following existing connections, all in accordance with applicable design rules. Configure the interactive routing options.
Time to set the Snap Grid to a value that is suitable for routing. A simple animation showing the board being routed. Note how the segments are displayed differently. Keep an eye on the Status bar , it displays important information during interactive routing, including:. The PCB editor’s Interactive Routing engine supports a number of different modes, with each mode helping the designer deal with particular situations.
To modify an existing route, there are two approaches, either: reroute , or re-arrange. A simple animation showing the Loop Removal feature being used to modify existing routing.
Note that there are situations where you may want to create loops, for example power net routing. If necessary, Loop Removal can be disabled for an individual net by editing that net in the PCB panel. To access the option set the panel to Nets mode, then double click on the net name in the panel to open the Edit Net dialog. An animation showing track dragging being used to tidy up existing routing. An example of dragging multiple tracks, by setting the routing conflict mode to Push.
Before you begin exploring the autorouter, save your board so you can return to the interactively routed version if you want. Altium Designer also includes a topological autorouter. A topological autorouter uses a different method of mapping the routing space – one that is not geometrically constrained. Rather than using workspace coordinate information as a frame of reference dividing it into a grid , a topological autorouter builds a map using only the relative positions of the obstacles in the space, without reference to their coordinates.
Topological mapping is a spatial-analysis technique that triangulates the space between adjacent obstacles. This triangulated map is then used by the routing algorithms to “weave” between the obstacle pairs, from the start route point to the end route point.
The greatest strengths of this approach are that the map is shape independent the obstacles and routing paths can be any shape and the space can be traversed at any angle – the routing algorithms are not restricted to purely vertical or horizontal paths, as with a rectilinear expansion routers. Translating this into a user interface, the router has a number of different routing passes available; such as Fan Out to Plane, Main, Memory, Spread, Recorner, and so on.
These are bundled together to create a Routing Strategy, which the designer can then run on their board. There are a number of pre-defined strategies already available in the Routing Strategies dialog, and new ones are easily created using the Strategy Editor. Select an existing routing strategy, or create a new one in the Strategy Editor. Note that the default strategies cannot be edited, duplicate one to explore the strategies. Before you begin the download process, you need to sign up for a free user account on the Altium website.
Join the Altium community of engineers and designers through this link. After signing up with the Altium community, login to your account through this link.
Have a closer look at the features and advantages of Altium Designer before you proceed to the next step. After approving the components and benefits of Altium Designer, you can download the Altium software from the Download Page. When you have finished downloading the Altium Designer software, you should run it on your computer by pressing the Yes button on the pop-up window.
Consequently, you will see a page welcoming you to the Installer. Hit the Next button to continue. Next, navigate to the Design Functionality to choose your preferred functionality and press the tab labeled Next.
You have successfully finished the download and installation process. If it is your first time to run Altium Designers on your device, a License Management Panel will show up, implying that you are using an invalid license. Sign in to your Altium account that you created earlier to access a list of valid permissions. For instance, the project template, Multivibrator. For the purpose of the next steps, you need to add a schematic sheet to your project, as shown below.
In the first place, you should set up the right document options, such as the sheet size and Snap, before you begin drawing your PCB. The elements that you will add to the PCB appear as schematic symbols in the design capture process. You can either:. Unlike other PCB design tools, you can place library components from existing libraries In Altium, such as:. Those in the current project- use the components of a library belonging to a particular project in any running project.
In this case, you should install the libraries in the Installed section within the Available Libraries panel. To access the dialog, hit the Libraries tab on the Libraries window. If you are unable to view the forum, navigate to the Panels, and click Libraries. Using the Place tab- position and press to insert the component floating on your cursor. After placing it, right-click to leave the placement mode. Double-clicking- by double-clicking the Components tab in the window’s component section, you will see them floating on your cursor.
You need to position it appropriately and press to insert it. Then right-click to leave the placement mode. Clicking and dragging- you can also place components on the Schematic from the Libraries panel by clicking and dragging the Schematic element.
However, you should hold your cursor down and release it to put your component. Right-click the component and choose Place to float it on your cursor.
Then position it appropriately and press to insert. When the Explorer window floats on your workspace, it will quickly fade to enable you to view the schematic drop components. Right-click to leave the placement status.
Click and drag- You can also click and remove parts from the Explorer window and place them on the Schematic. You should hold your cursor down and release it to set the component. Welcome to the world of electronic product development in Altium’s world-class electronic design software. This tutorial will help you get started by taking you through the entire process of designing a simple PCB — from idea to output files. The design for which you will be creating the schematic and designing a printed circuit board PCB is a simple astable multivibrator.
The circuit is shown below; it uses two general purpose NPN transistors configured as a self-running astable multivibrator.
Circuit for the multivibrator. The animation of the designed PCB. Altium Designer can connect to a Workspace for providing a single, secure data source and storage while affording unparalleled collaboration.