Power net portal is a special schematic object used to define a power or ground net. Power ports allow you to conveniently indicate a power net at any location in the design. Power nets of the same designator automatically connect throughout your design #portal #power
A generic fixed inductor for rapid developing circuit topology. *You can now change the footprint and 3D model at the top level anytime you want. This is the power of #generics
To use Flux effectively, here's a basic step-by-step guide:
Create an account: Head over to the Flux website and sign up for an account. You'll need this to access both the software and the community features.
Open the schematic editor: After you've logged in, you can start a new project by clicking on "New Project". This will open the schematic editor where you can design your electronic circuits.
Place components on the schematic: On the left-hand side, you'll see a toolbar with different components. You can drag and drop these onto the schematic.
Connect components: Once you've placed your components, you can connect them by drawing wires between their connection points (usually represented by circles or squares).
Simulate circuits: Once your schematic is complete, you can simulate your circuit to see how it operates under various conditions.
Create PCB layout: After your simulation, you can then create a PCB layout based on the schematic. This allows you to physically arrange your components and routes the connections between them.
Export for manufacturing: Once your PCB layout is complete, you can export your design in a format suitable for manufacturing.
Ask for help: If you come across any issues, feel free to ask your questions in this comment thread or on the Flux community Slack.
For more in-depth tutorials and to get started on your first project in Flux, you can check out the Flux documentation and the YouTube tutorials provided by Flux[1], [2].
Remember to use the 'Take Action' button if the Copilot suggests specific connections in your schematic and you want it to do those for you[3].
Please let me know if you have any specific questions about any features of Flux, I'm here to help!
The current project description provided does not mention any reset or enable pins in the schematic. Hence, I was not able to check for the inclusion of any external pull-up or pull-down resistors associated with the reset/enable pins.
However, I can provide some general recommendations on adding pull-up or pull-down resistors for the reset or enable pins. These would be some action items you can take:
Identify any reset or enable pins in your circuit. If any, they often can be found on components like MCUs, logic gates, or other digital ICs.
For each of these pins, add an external pull-up or pull-down resistor as appropriate:
Enable pins typically requires a pull-up resistor to ensure a default 'HIGH' state when not actively being pulled low.
Reset pins usually require a pull-down resistor to ensure the system doesn't unexpectedly enter a reset state due to electrical noise.
Ensure values of resistors are suitable for your power supply and load currents. Common resistor values for pull-up or pull-down configurations are typically in the range of 4.7k ohms to 10k ohms.
Verify that the chosen resistors do not breach any pin input current limitations of the connected devices.
Once resistors are added in your Flux project, check the correctness of their connections and polarities.
Finally, simulate the design to ensure correct operation of the reset/enable function.
As you refine your schematic with additional components, I would recommend keeping these points in mind.
10mo
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@jharwinbarrozo this part is self refferential. Please remove Batt1
To use Flux, you start by creating an account or logging in if you already have one. Here are some steps to get you started:
Sign Up or Log In: Visit Flux's signup page to create an account. You can sign up by entering your username, email, and password, or by linking your Google account.
Get Familiar with the Interface:
Schematic Design: Use the library to drag and drop components onto your schematic canvas.
PCB Layout: Once your schematic is complete, you can switch to PCB layout mode to position and route your board.
Learn and Explore:
Documentation and Tutorials: Access tutorials and documentation to help you get started.
Videos and Support: Check out Flux's YouTube channel for video tutorials or join the Flux Slack community for support and to meet other users.
Experiment and Design: Start by creating simple circuits and gradually move on to more complex projects as you become more comfortable with the tool.
Let me know if you have specific questions or need help with a particular feature!
3mo
CREA UN CIRCUITO CON 3 RESISTENSIAS DE 100 OHMIOS Y 3 BATERIAS DE 9VOLTIOS USAND...
CREA UN CIRCUITO CON 3 RESISTENSIAS DE 100 OHMIOS Y 3 BATERIAS DE 9VOLTIOS USANDO LAS LEYES DE KIRCHHOFF PARA VER POR DONDE ENTRA LA CORRIENTE Y POR DONDE SALE
4mo
Create a circuit diagram comprising of a diffuse photoelectric sensor to act as ...
Sure, I can help create a high-level mermaid block diagram for your project. From the provided project details, your circuit has a battery holder and two unspecified pins. Here’s a high-level diagram:
This diagram shows the connections from the battery holder 1070TR to two pins labeled + and -. Would you like to add any additional components or connections?
No worries! If Flux doesn't have a specific part, we can use equivalent components or generic placeholders. For a diffuse photoelectric sensor, you can model its behavior using a generic proximity sensor.
Here’s how you can modify the existing plan using a generic proximity sensor:
Signal Pin to one of MCU:Digital Input pins (e.g., D2).
Buzzer:
Positive Terminal to MCU:Digital Output (e.g., D3).
Negative Terminal to MCU:GND.
Textual Connections:
Connect $BATT1:1$ to MCU:VCC.
Connect $BATT1:2$ to MCU:GND.
Connect Sensor:VCC to MCU:VCC.
Connect Sensor:GND to MCU:GND.
Connect Sensor:Signal to MCU:D2.
Connect Buzzer:Positive to MCU:D3.
Connect Buzzer:Negative to MCU:GND.
Mermaid Diagram:
Below is the updated Mermaid syntax for the high-level block diagram:
This diagram reflects your project's power, sensor, and feedback connections in a simplified way. Would you like to proceed with this, or need further customizations?
Hey, I'm copilot! I can help you with all kinds of stuff in your project. Reach me at any time by tagging me on comments or in the chat with my handle, @copilot.
En Flux, puedes crear diagramas como esquemas y diagramas de bloques para representar tus circuitos y diseños de PCB. Si tienes en mente un tipo de diagrama específico que te gustaría crear, por favor házmelo saber.
Por ejemplo, si deseas hacer un diagrama de bloques para un sistema, puedo mostrarte cómo sería usando un diagrama de mermaid. Solo necesito que me digas los componentes o bloques que deseas incluir y las conexiones entre ellos.
¿Hay algún tipo de diagrama en específico que quisieras crear o algo en particular en lo que necesites ayuda?
Para crear un diagrama que incluya un pulsador abierto, también conocido como un interruptor normalmente abierto, podrías necesitar un diagrama de bloques o un esquema que lo represente. En un esquema, el pulsador abierto se utiliza para cerrar un circuito cuando se presiona, permitiendo el flujo de corriente.
Si quieres, puedo ayudarte a diseñar un esquema simple que incluya un pulsador abierto. Este esquema podría también incluir un LED que se encienda cuando el pulsador esté presionado. Aquí te dejo una posible configuración:
Pulsador (Normalmente Abierto)
LED
Resistor para limitar la corriente del LED
Fuente de voltaje como una batería
¿Te gustaría que cree un diagrama de ejemplo para ti, o hay algo más específico que te gustaría incluir o modificar en el diseño?
25d
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Passive Components
Resistor Power Rating
Beta
Checks that the power traveling across a given resistor is under its rating with 50% headroom.
pekarthik
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