melissablue274155

melissablue274155

I want the 555 timer to operate at a frequency of 1.5 kHz.
@library add the following components to the project:
  • NE555 Timer IC
  • 2-Pin Terminal Block Connector (for power input)
  • Resistors:
    • R1 = 10kΩ
    • R2 = 100Ω
    • R3 (Current-limiting resistor for output)
  • Capacitors:
    • C1 = 100nF (0.1µF)
    • C2 = 0.1µF (Decoupling capacitor)
  • Diode: 1N4148
  • LED
  • Ground connection
315 days

flux

is thinking...

315d 10:29:40

315 days

Ready.

Sign up to send
explain this project.
zaur96

zaur96

@copilot explain this project.
1y

copilot

Certainly! This project is an example template designed to be used for aerospace electronics applications. The key characteristics and requirements of this project are centered around the stringent demands of aerospace environments, such as high radiation levels, wide temperature ranges, and varied operating voltages. Let's delve into the specifics:
Project Overview
This project is intended for the design of satellite payloads, avionic systems, or space instruments. The following key requirements and constraints are critical for aerospace applications:
  1. Compliance with MIL-STD: Military standards (MIL-STD) are specifications that ensure a product meets specific performance and reliability requirements under extreme conditions.
  2. Radiation Hardening: Components used in the project must be capable of withstanding radiation exposure to ensure reliable operation in space. This usually involves using special materials and design practices.
  3. Extreme Environmental Constraints: The project includes components that must function properly within a wide temperature range and different voltage levels, often seen in aerospace applications.
Specific Requirements
  • Domain Application (Aerospace): The project is tailored specifically for aerospace applications which involve specific requirements for reliability and performance.
  • Compliance (NASA Standards, Radiation Hardness Assurance (RHA)): The design must follow NASA's standards for radiation hardness, which ensures it can survive and function in the radiation environment found in space.
  • Total Ionizing Dose Ratings (20 to 100 kRad): This indicates that components must be able to tolerate a total ionizing dose of radiation ranging from 20 to 100 kilorads.
  • Operating Temperature (-55°C to 125°C): Components must function reliably within this temperature range.
  • Operating Voltage (1V to 57V): The power supply voltage for the components can range from 1V to 57V, accommodating various aerospace power needs.
Project Components
As of now, there are no electrical connections made in this project, meaning it's an empty template. You'll need to add components like microcontrollers, sensors, power supplies, communication modules, etc., and wire them according to the specific requirements of your aerospace application.
Steps to Start Designing
  1. Add Components: Begin by selecting components that meet the aerospace requirements. For example, choose radiation-hardened microcontrollers, voltage regulators, temperature sensors, etc.
  2. Make Connections: Connect the components according to your system requirements. For instance, if designing a satellite payload, connect the sensors, communication modules, etc.
  3. Simulation and Verification: Use the simulation tools in Flux to verify your design's performance under the specified environmental constraints.
  4. Compliance Check: Ensure your design follows MIL-STD, NASA standards, and meets the radiation hardness and temperature requirements.
If you have any specific components in mind or need help starting with a particular part of the design, feel free to ask!
1y
Someone is typing...
https://www.youtube.com/watch?v=qO\_KH8jIUO0
Someone is typing...
4
can you recommend adjustable voltage regulator for this project?
ellobo1212mp

ellobo1212mp

Como formar una celda solar
1y
samahel

samahel

Que puedo hacer con una celda solar
1y
nez1

nez1

holka
1y
1y

copilot

It looks like we're starting from scratch on a complex and specialized aerospace electronics project. Before we dive into specific connections and component selections, let's outline some initial steps and considerations to ensure your design meets the stringent requirements outlined, especially those concerning NASA standards, radiation hardness, MIL-STD compliance, and extreme operating conditions.
Initial Considerations
  1. Selection of Radiation-Hardened Components: Given the total ionizing dose ratings of $20$ to $100$ kRad, all components must be chosen with radiation tolerance in mind. This applies to microcontrollers, memory, power supply components, and even passive components.
  2. Robust Power Management: Operating at voltages between $1$V and $57$V demands a versatile power supply design. Consider using low dropout regulators (LDOs) for low-voltage applications and switching regulators for efficiency at higher voltages. Ensure they can operate within the specified temperature range ($-55$ ºC to $125$ºC).
  3. Thermal Management: The extreme temperature range necessitates careful thermal design. Components should be selected not only for their operating temperature range but also for their thermal resistance. Heat dissipation strategies, possibly including heat sinks or thermal vias, might be necessary.
  4. Compliance and Standardization: Adherence to NASA Standards and MIL-STD for aerospace applications implies a deep focus on reliability, documentation, and rigorous testing. Components and designs should be chosen and verified accordingly.
  5. High-Reliability PCB Design Practices: Utilize design principles such as wide trace widths for power traces, redundant vias, and protection circuits like transient voltage suppressors (TVS) for sensitive inputs to enhance durability and resilience.
Next Steps
With these considerations in mind, the next phase involves identifying and selecting specific components that meet these criteria. For instance:
  • Microcontroller/Processor: Choose one that is radiation-hardened and can operate across the intended temperature ranges.
  • Memory: Opt for radiation-hardened varieties, with EEPROM or FLASH being common choices for non-volatile memory in space applications.
  • Power Supply Components: Identify regulators, capacitors, and inductors that can function at the expected voltages and temperatures.
  • Sensors and Actuators: Ensure they are suitable for aerospace use, potentially requiring custom or specialty parts.
Concrete Design Steps
  1. Block Diagram Creation: Start by creating a high-level block diagram of your system within the Flux project template. This helps in organizing and planning the power distribution, communication buses, and major functional blocks.
  2. Component Selection: Begin selecting components based on the initial considerations above, paying close attention to datasheets for compliance with your project's requirements.
  3. Schematic Design: Once the components are selected, you can start drafting the schematic in Flux. At this stage, specific connections between components will be defined.
Given the starting point and the stringent requirements of your project, do you have specific components in mind already, or would you need suggestions for initial building blocks such as microcontrollers, power management ICs, or sensors?
1y
jharwinbarrozo

jharwinbarrozo

@copilot can you recommend adjustable voltage regulator for this project?
2y

copilot

Certainly, given your project's specifications, it's important to find a voltage regulator that can handle a wide voltage range, extreme temperatures, and substantial radiation exposure. Regulators designed for aerospace applications often provide these features.
The RHFL4913 from STMicroelectronics could be a good choice. It is an adjustable voltage regulator and is spec'd for radiation hardness, with a total ionizing dose rating of up to 300 kRad(Si). Operating temperature is from -55°C to 150°C and it has an input voltage range up to 40V. The output voltage can be set from 1.2V to 37V depending on the values of two external resistors.
Please note that the specified operating voltage of the regulator is slightly less than your maximum required voltage of 57V. Additional components may be necessary to handle voltages above 40V.
Remember, the selection of the proper voltage regulator is crucial to your project, and environment-specific, durability, and power-efficient features should be considered. Always check the complete datasheet for any component before you decide to use it in your project.

1

2y
rey28

rey28

Necesito crearun pcb de audio
1y

copilot

Para crear un PCB de audio, te guiaré en la planificación y diseño básicos. Los PCB de audio pueden variar enormemente en complejidad, desde simples amplificadores hasta sistemas de procesamiento de señales complejas. Para mantener las cosas simples, comenzaremos con un diseño básico de un amplificador de audio mono.
Requisitos del Proyecto
Vamos a definir algunos parámetros simples:
  • Fuente de alimentación: Supongamos que utilizarás una fuente de 5V a 12V.
  • Tipo de señal: Audio mono de línea o señal auxiliar.
  • Salida: Conexión a un altavoz de 8 ohmios.
Componentes Sugeridos
  1. Amplificador de Audio: LM386 es un amplificador de bajo voltaje y corriente pequeña, ideal para tus necesidades. Tiene un rango de voltaje de funcionamiento de 4V a 12V, lo que se ajusta bien a nuestra fuente de alimentación.
  2. Capacitores:
    • Capacitor de entrada (Cin): 0.1uF para eliminar el ruido de la señal de entrada.
    • Capacitor de desacople (Cb): 250uF para estabilizar la salida y filtrar el ruido de baja frecuencia.
    • Capacitor de ganancia (Cg): 10uF para establecer la ganancia del LM386 a un valor predeterminado de 20. Se puede ajustar con diferentes valores si se desea más ganancia.
  3. Resistencias:
    • Resistencia de salida (Rout): 10 ohmios para protección del altavoz.
  4. Entradas/Salidas:
    • Conector de entrada de señal de audio.
    • Conector para la alimentación.
    • Conector para el altavoz.
Diseño Básico del Circuito Conexiones Principales:
  • Alimentación
    • Conecta el pin 6 (Vcc) del LM386 a tu fuente de alimentación positiva.
    • Conecta el pin 4 (GND) a la tierra.
  • Señal de Audio
    • Conecta el capacitor Cin al pin 3 (entrada) del LM386.
    • La otra terminal del Cin se conectará a tu conector de señal de entrada.
  • Salida de Audio
    • Conecta Cb entre el pin 5 (salida) del LM386 y GND.
    • Conecta una resistencia Rout en serie con Cb y el conector del altavoz.
    • Asegúrate de que el otro cable del altavoz esté conectado a GND.
  • Ganancia
    • Conecta un extremo de Cg entre los pines 1 y 8 del LM386.
    • El otro extremo de Cg va a GND.
PCB
  • Diseño
    • Utiliza software como KiCad o el que prefieras para el diseño de tu PCB.
    • Coloca las pistas considerando minimizar cualquier tipo de interferencia en la señal de audio.
    • Asegura una buena conexión a tierra (GND) para evitar bucles de tierra.
  • Routing
    • Mantén el recorrido de las conexiones tan corto y directo como sea posible.
    • Utiliza pistas más anchas para la alimentación y la salida de altavoz para manejar mayores corrientes.
  • Fabricación
    • Una vez diseñado tu PCB, puedes enviarlo a una empresa de fabricación de PCB o intentar métodos de fabricación casera si está dentro de tus capacidades y recursos.
Este es un diseño básico para empezar. Dependiendo de tus necesidades específicas, es posible que desees agregar más componentes, como filtros de paso bajo para mejorar la calidad del audio. Recuerda verificar siempre las hojas de datos de tus componentes para asegurar la correcta conexión y funcionamiento.
1y
rey28

rey28

Placa de audio con leds ritmicos
1y

copilot

Para diseñar una placa de audio con LEDs rítmicos, vamos a seguir unos pasos básicos y te proporcionaré una idea general de cómo puedes conectar los componentes. Este diseño consistirá en un circuito que capaz de recibir señales de audio, procesarlas y luego variar la intensidad o el encendido de LEDs basándose en el ritmo o la amplitud de la señal recibida.
Componentes Básicos:
  • Micrófono: Para capturar el audio ambiental.
  • Amplificador de Audio: Para amplificar la señal capturada por el micrófono.
  • Filtro Pasa-bandas o Detector de Envolvente: Para extraer el ritmo o variaciones de amplitud de la señal de audio.
  • Microcontrolador o Circuito Integrado Especializado: Para procesar la señal y controlar los LEDs.
  • LEDs: Para visualizar el ritmo del audio.
  • Resistencias y Capacitores: Para configuraciones de filtros y conexiones adecuadas.
Paso a Paso para el Diseño:
  1. Entrada de Audio:
    • Conexión del Micrófono: Conecte el micrófono a la entrada del amplificador de audio. Asumiremos un amplificador genérico.
    • Ejemplo: Conectar MIC:OUT a AMP:IN.
  2. Procesamiento de Señal de Audio:
    • El amplificador fortalece la señal del micrófono y la envía al filtro pasa-bandas o al detector de envolvente, que se encargará de extraer el ritmo de la música.
    • Ejemplo: Conectar AMP:OUT a FILTER:IN.
  3. Interpretación y Control:
    • La señal procesada se envía a un microcontrolador, que interpreta los cambios y controla los LEDs en consecuencia.
    • Si estás utilizando un circuito integrado especializado en control de LED rítmico, este paso podría simplificarse.
    • Ejemplo: Conectar FILTER:OUT a MCU:ANALOG_IN.
  4. Control de LEDs:
    • Basado en la señal recibida por el microcontrolador, se activan los LEDs. Puedes usar transistores o controladores de LED, dependiendo de la cantidad y el tipo de LEDs.
    • Ejemplo de conexión básica: Conectar MCU:GPIO_x a LED:ANODE mediante un transistor si es necesario, con la CATODO del LED a GND.
Consideraciones Adicionales:
  • Para LEDs rítmicos, considere usar varios canales o filtros pasa-bandas para diferentes rangos de frecuencia, lo que permite controlar diferentes LEDs o grupos de LEDs basados en diferentes componentes de la señal de audio.
  • Si el proyecto es para aplicaciones avanzadas o comerciales, debes tener en cuenta la elección de componentes que cumplan con los estándares de calidad y seguridad aplicables.
  • El diseño final del PCB dependerá del tamaño de los componentes, el número de LEDs y el espacio disponible para tu proyecto.
Este es un bosquejo general para comenzar con tu diseño de placa de audio con LEDs rítmicos. Las especificaciones detalladas, valores de los componentes (como resistencias y capacitores), y la programación del microcontrolador dependen de tus requisitos exactos y del análisis de la señal de audio deseado.
1y
marco1964

marco1964

Build logo with inic
1y

copilot

¡Claro! Vamos a crear un logo sencillo usando las iniciales "INIC". Aquí hay una idea para un diseño de un logo estilizado:
  1. Esquema Básico del Logo:
    • La letra "I" puede ser una línea vertical simple.
    • La letra "N" puede ser una línea con un ángulo hacia arriba.
    • La letra "I" sigue como una línea vertical.
    • La letra "C" puede ser un arco o un semicírculo.
Empezaremos con un diseño básico usando caracteres ASCII para visualización.
   I   N N   I
   I  N  N   I
   I N   N   I
   I N   N   I
   I N   N   I
Podemos hacer el diseño más atractivo con un enfoque gráfico orientado a PCB. Si estás usando un software de diseño PCB como Flux para implementar un logo, podrías usar las siguientes directrices:
  1. Rutas de PCB: Utiliza rutas para crear los caracteres.
  2. Componentes decorativos: Integra componentes LED o resistencias decorativas para darle brillo y funcionalidad al logo.
  3. Polígonos y rellenos: Usa polígonos para crear formas complejas.
Paso a Paso en Flux:
  1. Abrir Flux: Inicia sesión en tu cuenta de Flux.
  2. Crear nuevo proyecto: Selecciona una nueva plantilla o un proyecto en blanco.
  3. Dibujo de caracteres:
    • Usa herramientas de dibujo para crear las rutas que formarán las letras "I", "N", "I", "C".
    • Ajusta los anchos de las rutas para lograr el efecto deseado.
Ejemplo en ASCII del Texto en Vector a un logo decorativo gráfico en PCB:
- Trace una línea vertical para "I".
- Trace líneas en ángulo y horizontales conectadas para formar "N".
- Repita la línea vertical para otra "I".
- Dibuje un arco o semicírculo para "C".
- Coloque LEDs justo encima de cada letra para iluminar el logo.
Implementación en Flux
  1. Diseña las letras:
    • Dibuja cada letra usando herramientas de trazado en Flux.
  2. Añade LEDs:
    • Inserta LEDs encima de las letras como decoración, conectándolos adecuadamente.
  3. Ajustes finales:
    • Asegúrate de que las conexiones están correctas y que las rutas no cortocircuiten.
    • Agrega cualquier componente decorativo que desees.
Ejemplo de Conexiones
  • Conexión básica de LEDs:
    1. Conecta el ánodo de cada LED a la fuente de alimentación.
    2. Conecta el cátodo de cada LED al pin de control del microcontrolador para manejar el encendido.
Ejemplo de conexión en lista:
  • Conecta LED1:Anode a +V.
  • Conecta LED1:Cathode a MCU:GPIO1.
  • Conecta LED2:Anode a +V.
  • Conecta LED2:Cathode a MCU:GPIO2.
Este diseño proporcionará una base para comenzar a construir un logo con iniciales en tu PCB. Puedes estilizar más el diseño y hacer ajustes según tus preferencias.
1y
Someone is typing...
2
explain this project.
pawels1991

pawels1991

@copilot explain this project.
1y

copilot

Sure, here's a breakdown of the key elements within your aerospace electronics project:
Project Overview
This project template is geared towards the design and development of satellite payloads, avionic systems, or space instruments. It takes into account the stringent requirements of aerospace applications, such as adherence to MIL-STD (military standards), radiation hardening, and the ability to operate under extreme environmental conditions.
Key Project Requirements
  1. Domain Application: Aerospace
    • This indicates that the project is meant for aerospace applications, implying high reliability and specific operational requirements.
  2. Compliance
    • NASA Standards, Radiation Hardness Assurance (RHA): Ensures that the electronic components and systems meet stringent NASA standards for resistance to radiation.
  3. Total Ionizing Dose Ratings
    • 20 to 100 kilorad (kRad): The components must be able to withstand an ionizing radiation dose between 20 and 100 kRad without degradation.
  4. Operating Temperature
    • -55 ºC to 125ºC: The electronics must operate reliably within this wide temperature range, typical for aerospace environments.
  5. Operating Voltage
    • 1V to 57V: The circuit must handle a broad range of operating voltages, providing flexibility in power supply options.
Project Components
Currently, no electrical connections have been made in this project yet. This implies that the design phase is still in its early stages.
Next Steps
Given the constraints and requirements:
  1. Component Selection
    • Choose components rated for aerospace applications and compliant with the specified radiation and temperature requirements (e.g., MIL-STD-883 for microelectronics).
  2. Initial Schematic Design
    • Define the core functionality of your system (e.g., signal processing, communication).
    • Establish major blocks like power management, signal conditioning, and data processing.
  3. Parasitic Considerations
    • When designing the PCB, pay attention to parasitic elements as they can significantly impact performance, especially in space environments.
Tools and Compliance
  • Use Simulation Tools: Prior to physical prototyping, employ simulation tools to validate design under specified conditions.
  • Design Reviews: Conduct thorough design reviews for compliance with NASA and MIL-STD requirements.
Feel free to ask if you have any specific questions or need guidance on a particular aspect of the design process!
1y
4589

4589

𝐜𝐚𝐫𝐫𝐨𝐳𝐳𝐚
1y

copilot

It seems like you've mentioned "carrozza," which means "coach" in Italian or could possibly relate to something very specific. Since we're discussing an aerospace electronics project, could you provide a bit more context or clarify how "carrozza" fits into your query? If it's a component, subsystem, or term related to your project, I'd love to help further!
1y
Someone is typing...
13
What is the voltage required for this project?
mkungulwar

mkungulwar

@copilot What is the voltage required for this project?
1y

copilot

Based on the project requirements you provided, the operating voltage for this aerospace electronics project ranges from 1V to 57V.
To proceed, we need to understand which specific components you plan to use and what their voltage requirements are. This will help in selecting power regulators and ensuring proper voltage levels throughout the circuit.
Do you have specific components or subsystems in mind that you'd like to include in your project?
1y
Someone is typing...
12
WHat is this?
mkungulwar

mkungulwar

@copilot WHat is this?
1y

copilot

This is a project template designed for aerospace electronics using Flux. It includes specific properties and requirements for creating satellite payloads, avionic systems, or space instruments. Key considerations include MIL-STD compliance, radiation hardening, extreme environmental constraints, NASA standards, and specific operating conditions.
Project Properties and Requirements
  • Domain Application: Aerospace
  • Compliance: NASA Standards, Radiation Hardness Assurance (RHA)
  • Total Ionizing Dose Ratings: 20 to 100 kilorad (kRad)
  • Operating Temperature: -55 ºC to 125ºC
  • Operating Voltage: 1V to 57V
Currently, no electrical connections have been made in this project. You can modify the project properties to adapt to specific needs and start designing your aerospace electronics system.
How would you like to proceed with this project? Do you need assistance with specific components, connections, or design considerations?
1y
Someone is typing...
11
whats better resistor to energize led in 12v
randy607928

randy607928

@copilot whats better resistor to energize led in 12v
1y

copilot

To select the appropriate resistor value to use with an LED in a 12V circuit, you'll need to know a couple of key parameters of the LED:
  1. Forward Voltage ($V_F$): Typical values are around 2V for red LEDs, and can be higher for LEDs of other colors, up to around 3.3V for blue and white LEDs.
  2. Forward Current ($I_F$): This is the desired operating current for the LED. A common value is 20mA (0.02A) for many standard LEDs, but always check the datasheet for your specific LED.
Given the above, the formula to calculate the series resistor value ($R$) is:
R=VsourceVFIFR = \frac{V_{source} - V_F}{I_F}
Assuming a forward voltage ($V_F$) of 2V and a current ($I_F$) of 20mA for a typical red LED:
R=12V2V0.02A=10V0.02A=500ΩR = \frac{12V - 2V}{0.02A} = \frac{10V}{0.02A} = 500\Omega
So, you would use a 500$\Omega$ resistor. It's also a good practice to check the power dissipation in the resistor to make sure it won't overheat:
P=IF2×R=(0.02A)2×500Ω=0.2WP = I_F^2 \times R = (0.02A)^2 \times 500\Omega = 0.2W
A 1/4 watt (0.25W) resistor would typically suffice, but using a 1/2 watt (0.5W) resistor provides an extra margin for safety.
Please adjust this calculation based on the specific LED you're using, particularly if the forward voltage or desired current is different.
1y
Someone is typing...
8
can ypu make me a Movi Map Display for an MFD in an aircraft?
6002291274

6002291274

Maniksikdar
1y
marconix2010

marconix2010

@copilot can ypu make me a Movi Map Display for an MFD in an aircraft?
1y

copilot

Creating a Movi Map Display for a Multi-Function Display (MFD) in an aircraft involves a complex interplay of both hardware and software components. Assuming you want guidance for the basic hardware components and their connections, here’s how it can be done:
Hardware Components:
  1. Microcontroller: A powerful microcontroller to handle the decoding and processing of the moving map data. An example could be the 'STM32F' series, known for their high performance and extensive I/O capabilities.
  2. Graphics Processing Unit (GPU): The GPU processes the map data and outputs it to the display. For radiation hardness and reliability in an aerospace environment, a component like the GR712RC from Cobham Gaisler can be considered.
  3. RAM and Flash Memory: Sufficient memory to store map data and provide buffering for the GPU. Rad-hardened components complying with your outlined requirements should be used.
  4. Display Module: An avionics-grade LCD or OLED display to present the information.
  5. Interfaces: Various interfaces for connectivity and data transmission would be required, including connections (like SPI, I2C, UART) to GPS, other avionic systems, and storage for map data.
Core Connections:
  1. Connect MCU:SPI to GPU:SPI (To send map data to the GPU for processing)
  2. Connect GPU:Video_Output to Display_Module:Video_Input (To display the processed images)
  3. Connect MCU:UART/I2C/SPI to Storage:UART/I2C/SPI (To fetch map data)
  4. Connect MCU:UART/I2C/SPI to GPS_Module:UART/I2C/SPI (To get real-time position data)
Disclaimer: The provided information is intended to be informative and suggestive. An actual implementation would demand extensive validation, safety consideration, compliance with regulations, more detailed analysis of power requirements, data rates, etc. Also, redundancy and failsafe mechanisms are not covered but are very essential for aerospace application.
Creating this schematic in Flux will allow you to make adjustments as required and add further details to your design. It is important to remember that this is a very generalized implementation and the specific needs of your project may change the necessary components and their interconnections.
Please also note that my recommendations are based on typical values. In case you have more specific preferences or constraints, you should customize accordingly.
1y
marconix2010

marconix2010

can you do it for me?
1y

copilot

I'm sorry for any misunderstanding. However, I'm here to assist you throughout the process and can guide you on how to make practical modifications to your Flux project:
Here are the steps to create a Movi Map Display for an MFD in Flux:
  1. Add Components: Start by utilizing the 'Add Component' feature in Flux to add the necessary components to your board. As previously stated, you will need a microcontroller, a GPU, RAM and Flash memory, a display module, and the required interface components.
  2. Set Parameters: Next, set the design parameters for each component according to their specifications. This will include things like operating voltage and power, radiation tolerance, operating temperature, etc.
  3. Connect Components: Connect the components as outlined in my previous instructions using the 'Wire' tool in Flux. You should label each connection correctly.
  4. Validation: Finally, double-check all connections, ensure parameters are correctly set and that everything is set up as it should be. Run a Verification to validate that all components are properly connected and operating within their parameters.
Please note, this is a basic guide on setting up the components for a MFD Movi Map Display in Flux, and depending on the specific components you're using, you may need to adjust these steps accordingly.
Should you encounter any issues or if you have more questions, do not hesitate to ask. I'm here to help you.
1y
marconix2010

marconix2010

create the proyect for me
1y

copilot

I'm sorry, but creating a project on your behalf in Flux might not be possible through this form of communication. Flux is an interactive browser-based tool that requires direct user interactions. However, I can certainly guide you step by step in creating this project:
Step 1: Start a new project in Flux
  • Go to the Flux dashboard, click on the 'New Project' button and choose 'Blank Project'.
  • Name your project, e.g., "Movi Map Display".
Step 2: Add Components
  • Click on 'Add Component' and then 'Search for More Components'. Add the microcontroller (STM32F series), GPU (GR712RC), RAM and Flash Memory, Display Module, and any needed interfaces (SPI, I2C, UART).
Step 3: Set Parameters
  • Click on each component in turn and set its parameters as per your application requirements including their respective operating voltage and temperature ranges, and total Ionizing dose.
Step 4: Connect Components
  • Use the 'Wire' tool and connect the components using the following guide:
    1. Connect MCU:SPI to GPU:SPI.
    2. Connect GPU:Video_Output to Display_Module:Video_Input.
    3. Connect MCU:UART/I2C/SPI to Storage:UART/I2C/SPI.
    4. Connect MCU:UART/I2C/SPI to GPS_Module:UART/I2C/SPI.
Step 5: Verification
  • You can now verify the connections by running the 'Design Rule Check' for any errors. Correct if any are found, and rerun the check.
Remember, these are the general steps that any project in Flux could follow. Depending upon the specifics of your components and their connections, you may need to adapt these steps a bit. This should give you a great starting point for your "Movi Map Display" project!
1y
marconix2010

marconix2010

please make me the schematic here
1y

copilot

While I can guide you in detail and collaborate with you to create a conceptual schematic, I'm unable to physically design the schematic diagram on a CAD tool for you. However, I can certainly provide a textual outline of how your schematic might look:
  1. Microcontroller (MCU): Start with your microcontroller symbol. No matter your choice of microcontroller, it will have various pins for power, ground, SPI, I2C, UART, and the like. Ensure these are connected as required.
  2. GPU: Introduce a symbol for the GPU. It will have specific SPI, video output, power, and ground pins. The SPI input of the GPU should be connected to the SPI output of the MCU, and the video output of the GPU should link to the Video input of the Display module.
  3. RAM and Flash Memory: Add symbols for RAM and Flash memory. They will have control (perhaps SPI/I2C/UART), power, and ground pins. Connect their control pins to the appropriate MCU control pins.
  4. Display Module: Include a symbol for the Display Module. It will have power, ground, and video input pins. Link the video input to the GPU's video output.
  5. GPS Module: Finally, add the GPS Module and connect its control pins (maybe SPI/I2C/UART, depending on the module) to the MCU.
  6. Power: Make sure all devices are properly powered by their required supply.
With this guideline, you can put together a schematic for your project using your preferred electronics CAD tool. These instructions are general, as I'm not aware of the exact parts and their specifications you're using. Certain components might require different control and data signals, or multiple power lines. Perfect your designs by strictly following the specific data sheets.
If there are specific parts you need help with, or you require more detailed design advice, don't hesitate to ask!
1y
Someone is typing...
6
I need synchronous step-down converter for this project.
1y
samahel

samahel

@copilot has un proyecto que incluya una celda solar de 6 voltios
1y

copilot

Para incluir una celda solar de 6 voltios en tu proyecto aeroespacial, ten en cuenta las especificaciones y restricciones dadas, como la resistencia a la radiación, las normas de la NASA, y el amplio rango de temperaturas operativas. Aquí tienes una propuesta básica de integración para una celda solar dentro de tu esquema:
  1. Elección de la Celda Solar: Asegúrate de que la celda solar de 6v esté clasificada para un rango de temperatura operativa de -55°C a 125°C y cumpla con los estándares de dureza de radiación especificados (20 a 100 kRad). Para proyectos aeroespaciales, podría ser útil buscar celdas solares específicamente diseñadas para aplicaciones espaciales, ya que estas a menudo ya cumplen con tales criterios.
  2. Regulador de Voltaje: Para mantener un voltaje de operación seguro y estable para otros componentes electrónicos, considera la inclusión de un regulador de voltaje que pueda manejar las variaciones en la salida de la celda solar. Esto es especialmente importante en aplicaciones aeroespaciales donde las condiciones de iluminación pueden variar significativamente. Un regulador con un amplio rango de voltaje de entrada (por ejemplo, 1V a 57V) sería adecuado, asegurándote de que también cumpla con las especificaciones de temperatura y radiación.
  3. Protección y Aislamiento: Dependiendo de tu diseño específico y los requisitos de la carga útil, podrías necesitar implementar circuitos de protección adicionales alrededor de la celda solar para proteger contra sobrevoltajes, reversión de corriente, etc. Considera también el aislamiento eléctrico y térmico según sea necesario para la seguridad y la eficiencia del sistema.
  4. Conexiones Eléctricas y Mecánicas: Dadas las condiciones extremas que se pueden encontrar en aplicaciones aeroespaciales, asegúrate de que todas las conexiones eléctricas y mecánicas sean robustas, seguras y capaces de soportar vibraciones, radiación y cambios extremos de temperatura. Los conectores y cables deben ser de alta calidad y adecuados para uso en el espacio.
  5. Monitoreo y Control: Considera integrar un sistema de monitoreo en tu circuito que pueda leer la salida de voltaje y corriente de la celda solar en tiempo real. Esto te permitirá ajustar dinámicamente las cargas o cambiar a fuentes de energía alternativas si la celda solar no puede generar suficiente energía debido a condiciones de sombra o daño.
  6. Prueba y Validación: Finalmente, asegúrate de realizar pruebas exhaustivas de tu sistema bajo varias condiciones ambientales para validar el rendimiento de la celda solar y su integración con otros componentes del sistema. Pruebas en cámaras de vacío y exposición a radiación simulada serán cruciales para garantizar la fiabilidad a largo plazo en el espacio.
Esquema de Conexión Sugerido:
  • Celda Solar (SOL1): Conectar la salida positiva de SOL1 al input del Regulador de Voltaje (VR1:IN), y el terminal negativo a tierra (GND).
  • Regulador de Voltaje (VR1): Conectar VR1:OUT a la línea de alimentación del sistema (+V).
  • Protección y Monitoreo: Incluir componentes adicionales como diodos de bloqueo o circuitos de monitoreo según sea necesario para proteger y supervisar la celda solar y la carga útil.
Recuerda verificar las hojas de datos de todos los componentes para asegurarte de que cumplen con los requisitos de tu proyecto aeroespacial. También considera la redundancia en componentes críticos para mejorar la fiabilidad del sistema en un entorno tan desafiante.
1y
cordelia878879

cordelia878879

ststic de voltage
1y
jeramu71

jeramu71

Dame un circuito con el integrado aoz1050pi en el cual en la entradas tenga 12 voltios y en la salida tenga 5 voltios
1y
1y

copilot

The image you've provided shows a populated printed circuit board (PCB) with various electronic components and conductive tracks. Here are some observations about the PCB components and potential concerns:
  1. Integrated Circuits: There are several ICs on the board, one of them being in a through-hole package while others are in surface-mount packages. The ICs are likely responsible for the majority of the processing and control functionality of this circuit.
  2. Passive Components: Various resistors and capacitors are distributed throughout the board, likely for filtering, biasing, and decoupling purposes.
  3. LED: There's an LED diffused with a white dome-like material, probably to spread out the emitted light.
  4. Soldering Quality: There are areas where the soldering quality is not ideal. Some joints appear to have excess solder or could be considered "cold joints," meaning that the solder did not properly reflow, which can lead to unreliable connections.
  5. Flux Residue: There seems to be some residue around the components, possibly from the flux used during soldering. Flux residue can sometimes lead to corrosion or conductivity issues if not properly cleaned, especially in an aerospace context where reliability is paramount.
  6. Damage or Modification: There appears to be a damaged component or some sort of rework might have been done on the IC in the lower part of the image, evidenced by the excessive and patchy solder application.
Based on the type of components and the overall look of the circuit, this PCB could serve a variety of purposes. However, without a schematic or further context, it's hard to determine the exact function.
For aerospace applications, as indicated in your project description, it would be crucial to address the soldering and possible contamination issues to ensure long-term reliability under harsh conditions. In addition, the selection of each component would need to meet NASA standards and be rated for radiation hardness, as well as operating within the specified temperature and voltage ranges.
1y
alejandroalme

alejandroalme

Que puedo hacer?
2y
jharwinbarrozo

jharwinbarrozo

@copilot I need synchronous step-down converter for this project.
2y

copilot

Sure, considering your project requirements, I suggest to use the TPS7H3301-SP from Texas Instruments. It is a radiation-hardened, 1-A, point-of-load, synchronous, step-down DC-DC converter. Here is why it would be suitable for your satellite power system:
  1. Radiation Hardness: This converter is specifically designed for space applications which meets your radiation hardness assurance (RHA) requirement. It has a Total Ionizing Dose (TID) of up to 100 kRad, which falls within your required range.
  2. Operating temperature: The device operates within a temperature range of -55 to 125 degrees Celsius, which aligns with your project requirements.
  3. Operating voltage: The input voltage range of the TPS7H3301-SP is from 3 to 6V and it offers adjustable output voltage down to 0.8V. For your maximum operating voltage requirement of 57V, you would need a front-end DC/DC converter or a linear regulator.
Remember to choose a space grade version of the component to comply with NASA standards.
Also please consider that you may need additional components (like inductors, capacitors, resistors) around the converter, according to the manufacturer's datasheet, for input/output stabilization, set the output voltage, and provide noise filtering.
Note: Before deciding upon a component, please cross-verify with the datasheet and your project requirements.
2y
jorgegarciam08

jorgegarciam08

Me ayudas con la conexión de los siguientes sensores con la esp32 de 36 pibes, los sensores son:
2y

copilot

Por supuesto, estaría encantado de ayudarte, pero necesito que me proporcionaras más información sobre los sensores que planeas usar con tu ESP32. Por favor indícame sus nombres o modelos para que pueda brindarte las mejores recomendaciones posibles.
Source(s):
https://www.flux.ai/p/blog/esp32-pinout-everything-you-need-to-know https://www.flux.ai/p/projects
2y
jorgegarciam08

jorgegarciam08

Los sensores son: 2 sensores de flujos YFS201C
2 sensores de temperatura tipo sonda DS18B20
1 sensor modulo DS18B20 para medir temperatura ambiente
2 sensores de presión de agua gravity 0 - 1,6MPA
1 sensor de corriente GY-712-20A
1 sensor de voltaje fz0430 0-25V
2y

copilot

Claro, aquí te dejo algunas sugerencias de cómo podrías conectar estos sensores a tu ESP32 de 36 pines:
  1. Sensores de flujo YF-S201C: Estos son sensores de flujo de agua con un interruptor de tipo "hall effect". Se pueden conectar a cualquier pin digital de tu ESP32. Los pines de alimentación se conectan a VCC(3.3V) y GND. El pin de señal (Signal) va a algún pin GPIO.
Ejemplo de conexión:
  • YF-S201C VCC -> ESP32 3.3V
  • YF-S201C GND -> ESP32 GND
  • YF-S201C Signal -> ESP32 GPIO (por ejemplo, GPIO4 y GPIO5)
  1. Sensores DS18B20 (sonda y módulo): Estos son sensores de temperatura de 1-Wire. Necesitarás un pin para el bus de datos 1-Wire.
Ejemplo de conexión es igual tanto para sonda como para módulo:
  • DS18B20 VCC -> ESP32 3.3V
  • DS18B20 GND -> ESP32 GND
  • DS18B20 Data -> ESP32 GPIO (por ejemplo, GPIO2)
  1. Sensores de presión de agua Gravity 0 - 1,6MPA: Estos sensores optan por una salida analógica, así que debes conectar los sensores a un pin ADC.
Ejemplo de conexión:
  • Sensor VCC -> ESP32 3.3V
  • Sensor GND -> ESP32 GND
  • Sensor Signal -> ESP32 ADC (por ejemplo, GPIO32 y GPIO33)
  1. Sensor de corriente GY-712-20A: Este sensor utiliza una salida analógica, así que debes conectar el sensor a un pin ADC.
Ejemplo de conexión:
  • GY-712 VCC -> ESP32 3.3V
  • GY-712 GND -> ESP32 GND
  • GY-712 Signal -> ESP32 ADC (por ejemplo, GPIO34)
  1. Sensor de voltaje fz0430 0-25V: Este sensor también utiliza una salida analógica, así que debes conectar el sensor a un pin ADC.
Ejemplo de conexión:
  • fz0430 VCC -> ESP32 3.3V
  • fz0430 GND -> ESP32 GND
  • fz0430 Signal -> ESP32 ADC (por ejemplo, GPIO35)
Por favor, verifica en las hojas de datos de los sensores si se necesitan resistencias de pull-up o pull-down. También, puedes usar las sugerencias de conexión como guía y asignar los pines de acuerdo a tus necesidades en tu proyecto.
Por último, recuerda que la ESP32 tiene un voltaje de operación de 3.3V, por lo que la tensión de salida de los sensores debe ser compatible. En caso de que algún sensor genere una salida mayor a 3.3V, necesitarás utilizar un divisor de voltaje para evitar dañar el ESP32. Por otro lado, si el sensor utiliza una comunicación de 5V, puedes requerir un chip de cambio de nivel.
Source(s):
https://www.flux.ai/p/blog/esp32-pinout-everything-you-need-to-know https://www.flux.ai/p/projects
2y
Someone is typing...
3
https://cdn2.flux.ai/flux-comment-files/files/commentFileId-47b6106c851561e34d4d...
1y

copilot

The image you've provided is a wiring diagram for a Weather Station using a Raspberry Pi 4 in conjunction with an ADS1115 ADC module and a Yaesu 550/250 radio. The diagram includes connections for various components and peripheral devices, indicating how they should be wired together. The project seems to involve capturing and processing weather-related data, as well as communication via the radio transceiver.
Here are some key points from the diagram:
  • The Raspberry Pi's GPIO pins are used for different functions such as I2C communication (GPIO2 - SDA, GPIO3 - SCL) and GPIO control (GPIO4, GPIO17, GPIO22, GPIO27).
  • The ADS1115 ADC is connected to the Raspberry Pi via I2C with VCC (power), GND (ground), SCL (clock), and SDA (data) lines.
  • There is also a MOSFET (AQY211EH) being used as a switch, controlled by the Raspberry Pi's GPIO17.
  • The audio connector pins are connected to the Raspberry Pi via resistors and capacitors, which are likely used for signal conditioning.
  • The "Speaker," "Clone," "Mic/PTT," and "Ground" connections indicate interfacing with the Yaesu radio for audio input/output and push-to-talk functionality.
If you need to recreate this wiring in Flux, you would begin by adding these components to your schematic and then making the connections as shown in the diagram. If there is a specific aspect or connection you would like to focus on, please let me know so that I can provide a more detailed explanation or instructions.
1y
agusflap

agusflap

haceme las conexciones
1y

copilot

To recreate the connections indicated in the wiring diagram using the Flux tool, you would place the components such as a Raspberry Pi (with appropriate GPIO header), an ADS1115 ADC module, MOSFET (AQY211EH), and various passive components like resistors and capacitors onto your schematic. Once the components are placed, you would wire them as follows:
  • Connect Raspberry Pi I2C interface to ADS1115:
    • Connect RPi:GPIO2 (SDA) to ADS1115:SDA
    • Connect RPi:GPIO3 (SCL) to ADS1115:SCL
  • Connect power and ground to ADS1115:
    • Connect RPi:3V3 to ADS1115:VCC
    • Connect RPi:GND to ADS1115:GND
  • Connect MOSFET to control interface:
    • Connect RPi:GPIO17 to MOSFET:AQY211EH:IN
    • Connect MOSFET:AQY211EH:OUT to the desired load (not clearly specified in this diagram)
  • Connect audio interface to Raspberry Pi through resistors and capacitors (values and specific connections depend on the required signal conditioning, which is not fully detailed in the image provided):
    • Connect RPi:GPIO pins to Audio Connector via resistors/capacitors network
  • Connect to Yaesu radio interface (note that specific connections to the radio will depend on the model and might need customization):
    • Connect specific GPIO pins to the Speaker, Clone, Mic/PTT and Ground contacts on the Yaesu Connector as necessary
Please note that the actual values for resistors and capacitors and any additional components needed for filtering, decoupling, or protection are not specified in the diagram and would need to be determined based on the specifics of the audio signals and the requirements of both the Raspberry Pi and the radio interface.
It is also important to keep in mind that this wiring is a guide, and depending on the actual models and interfaces of your Raspberry Pi and Yaesu radio, the wiring might need adjustments. Additionally, interfacing with radio equipment typically requires careful consideration of signal levels, impedance matching, and may include additional components for proper interfacing which are not included in the provided wiring diagram.
1y
Someone is typing...
7
hi
alejandroflores-122905

alejandroflores-122905

Create pseudocode to calculate area
1y
2y
shielup03

shielup03

What is happening here
2y
2y
Someone is typing...
5
New Comment
Someone is typing...
16
how do I use Flux?
sreekarp

sreekarp

@copilot how do I use Flux?
1y

copilot

Flux is an intuitive platform for designing electronic circuit schematics and PCB layouts. Here's a step-by-step guide to help you get started:
1. Create an Account
Visit Flux's signup page and create an account by entering your username, email, and password. You also have the option to sign up using your Google account {d1a60ae999275e1295e4b971039878e9}\{d1a60ae9-9927-5e12-95e4-b971039878e9\}.
2. Getting Started with a Project
  • Create a New Project: Start a new project by clicking on the "New Project" button once you're logged in.
  • Explore the Canvas: You will be directed to the schematic editor canvas. This is where you'll draw your circuit designs.
3. Adding Components
  • Library: Use the library to find components. You can drag and drop components onto the canvas.
4. Connecting Components
  • Wire Tool: Use the wire tool to connect the pins of different components. Click on a pin, drag to another pin, and release to create a connection.
5. Simulating Your Circuit
  • Simulator: To test your circuit, use the simulator in Flux. This allows you to see how your circuit will behave in real-world conditions. For an in-depth tutorial on how the simulation models work, check out the detailed guide on how the simulator runs{1bda9486929952b49e6a4df9dce3916a}\{1bda9486-9299-52b4-9e6a-4df9dce3916a\}.
6. Routing and Positioning
  • PCB Layout: Once your schematic is complete, you can move to the PCB layout mode. This involves positioning components on a board and routing the traces between them{a12ed4f017d855aeac168e03539e2aec}\{a12ed4f0-17d8-55ae-ac16-8e03539e2aec\}.
7. Asking for Help
  • Community Support: If you run into any issues, the best place for support is the Flux Slack community. Here, you can ask questions directly to the Flux team and meet other engineers and designers{40270386861f5b3894555f85836dd6cc}\{40270386-861f-5b38-9455-5f85836dd6cc\}.
  • Video Tutorials: There are plenty of video tutorials available on Flux's YouTube channel that cover the basics as well as advanced features{620ba60476935c8b9a4b164874ae35b0}\{620ba604-7693-5c8b-9a4b-164874ae35b0\}.
8. Executing Flux Copilot's Suggestions
  • Take Action Button: When using Flux Copilot, you can automatically apply suggested connections by clicking on the "Take Action" button{746c6d9d636459be9640b7e2ae4574b1}\{746c6d9d-6364-59be-9640-b7e2ae4574b1\}.
Feel free to ask more specific questions about any of these steps or explain what you’re trying to achieve, and I can provide more detailed guidance!
1y
Someone is typing...
10
15
here is the block diagram I am working on. provide the schematic for this ? htt...
1y

copilot

I understand you need a schematic based on the provided block diagram. Here's a step-by-step outline to help you build the schematic in Flux:
Step 1: Define Major Components
Based on your block diagram, here are the major components the schematic will need:
  1. 11 STM32F405RG microcontroller
    • UART connections
    • SPI connections
    • I2C connections
    • GPIOs
  2. 22 FPGA
    • JTAG connections
    • External clock connections
  3. 33 IMU Sensor
    • I2C connections
  4. 44 Power Management ICs
  5. 55 USB-Port
  6. 66 Ethernet PHY
  7. 77 SDRAM
  8. 88 ADC
  9. 99 Environmental Sensors (Temp, Pressure, etc.)
  10. 1010 Connectors and JTAG ports
Step 2: Connect Components
Specific connections based on block diagram signals:
  1. STM32F405RG:
    • UART:
      • UART1\text{UART1} - Pins: TX, RX
      • UART2\text{UART2} - Pins: TX, RX
      • UART3\text{UART3} - Pins: TX, RX
    • SPI:
      • SPI1\text{SPI1} - Pins: SCK, MISO, MOSI, NSS
    • I2C:
      • I2C1\text{I2C1} - Pins: SCL, SDA
    • GPIOs - Configurable based on the design
  2. FPGA:
    • JTAG:
      • TDI, TDO, TCK, TMS
    • Clocks and other signals:
  3. IMU Sensor (Connected via I2C):
    • Connect IMU:SDA to STM32F405RG:I2C1_SDA
    • Connect IMU:SCL to STM32F405RG:I2C1_SCL
  4. Power Management:
    • Connect correspondingly (+3.3V, +1.8V) to the power rails of MCU, FPGA, and other sensors.
  5. USB Port:
    • Connect USB:DP and USB:DM to the corresponding pins of STM32F405RG
  6. Ethernet PHY:
    • Connect ETH_PHY:TX+, ETH_PHY:TX-, ETH_PHY:RX+, ETH_PHY:RX- to respective pins on the microcontroller or FPGA
  7. SDRAM:
    • Connect SDRAM:A[xx] and D[xx] to corresponding microcontroller/FPGA pins.
  8. ADC:
    • Connect ADC:IN[xx] to various sensors or input signals
  9. Environmental Sensors:
    • Connect Sensors to required ADC inputs or GPIOs as per the design
  10. Connectors and JTAG Ports:
    • Design as per standard JTAG and connector pinout.
Step 3: Schematic Draft
Create a new schematic in Flux using the above steps and connect the components as directed.
Step 4: Verification
Always verify each connection to make sure they align with the pin functions and expect design logic.
Here's a Start for You:
  • STM32F405RG Connections
    • Connect STM32F405RG:VDD to the 3.3V rail.
    • Connect STM32F405RG:GND to the ground rail.
    • Connect STM32F405RG:USART1_TX to UART1_TX.
    • Connect STM32F405RG:USART1_RX to UART1_RX.
    • And so on for SPI, I2C, and GPIO connections.
  • FPGA Connections
    • Connect FPGA:TDI to the JTAG TDI line.
    • Connect FPGA:TDO to the JTAG TDO line.
    • And so on for JTAG, clock lines, etc.
By following the above steps and connecting each component pin to the appropriate destinations as per your block diagram, you should be able to create a detailed schematic.
In case you need a specific schematic file, I recommend starting by using Flux's graphical tool to place each component and wire according to this plan. If you encounter any specific queries regarding certain connections or need further clarification, feel free to ask!
1y
Someone is typing...
  • Ground
    Ground
    A common return path for electric current. Commonly known as ground.
    jharwinbarrozo
    20.5M
  • Net Portal
    Net Portal
    Wirelessly connects nets on schematic. Used to organize schematics and separate functional blocks. To wirelessly connect net portals, give them same designator. #portal
    jharwinbarrozo
    43.0M
  • Power Net Portal
    Power Net Portal
    Wirelessly connects power nets on schematic. Identical to the net portal, but with a power symbol. Used to organize schematics and separate functional blocks. To wirelessly connect power net portals, give them the same designator. #portal #power
    jharwinbarrozo
    11.4M
  • Generic Resistor
    Generic Resistor
    A generic fixed resistor for rapid developing circuit topology. Save precious design time by seamlessly add more information to this part (value, footprint, etc.) as it becomes available. Standard resistor values: 1.0Ω 10Ω 100Ω 1.0kΩ 10kΩ 100kΩ 1.0MΩ 1.1Ω 11Ω 110Ω 1.1kΩ 11kΩ 110kΩ 1.1MΩ 1.2Ω 12Ω 120Ω 1.2kΩ 12kΩ 120kΩ 1.2MΩ 1.3Ω 13Ω 130Ω 1.3kΩ 13kΩ 130kΩ 1.3MΩ 1.5Ω 15Ω 150Ω 1.5kΩ 15kΩ 150kΩ 1.5MΩ 1.6Ω 16Ω 160Ω 1.6kΩ 16kΩ 160kΩ 1.6MΩ 1.8Ω 18Ω 180Ω 1.8KΩ 18kΩ 180kΩ 1.8MΩ 2.0Ω 20Ω 200Ω 2.0kΩ 20kΩ 200kΩ 2.0MΩ 2.2Ω 22Ω 220Ω 2.2kΩ 22kΩ 220kΩ 2.2MΩ 2.4Ω 24Ω 240Ω 2.4kΩ 24kΩ 240kΩ 2.4MΩ 2.7Ω 27Ω 270Ω 2.7kΩ 27kΩ 270kΩ 2.7MΩ 3.0Ω 30Ω 300Ω 3.0KΩ 30KΩ 300KΩ 3.0MΩ 3.3Ω 33Ω 330Ω 3.3kΩ 33kΩ 330kΩ 3.3MΩ 3.6Ω 36Ω 360Ω 3.6kΩ 36kΩ 360kΩ 3.6MΩ 3.9Ω 39Ω 390Ω 3.9kΩ 39kΩ 390kΩ 3.9MΩ 4.3Ω 43Ω 430Ω 4.3kΩ 43KΩ 430KΩ 4.3MΩ 4.7Ω 47Ω 470Ω 4.7kΩ 47kΩ 470kΩ 4.7MΩ 5.1Ω 51Ω 510Ω 5.1kΩ 51kΩ 510kΩ 5.1MΩ 5.6Ω 56Ω 560Ω 5.6kΩ 56kΩ 560kΩ 5.6MΩ 6.2Ω 62Ω 620Ω 6.2kΩ 62KΩ 620KΩ 6.2MΩ 6.8Ω 68Ω 680Ω 6.8kΩ 68kΩ 680kΩ 6.8MΩ 7.5Ω 75Ω 750Ω 7.5kΩ 75kΩ 750kΩ 7.5MΩ 8.2Ω 82Ω 820Ω 8.2kΩ 82kΩ 820kΩ 8.2MΩ 9.1Ω 91Ω 910Ω 9.1kΩ 91kΩ 910kΩ 9.1MΩ #generics #CommonPartsLibrary
    jharwinbarrozo
    1.5M
  • Generic Capacitor
    Generic Capacitor
    A generic fixed capacitor ideal for rapid circuit topology development. You can choose between polarized and non-polarized types, its symbol and the footprint will automatically adapt based on your selection. Supported options include standard SMD sizes for ceramic capacitors (e.g., 0402, 0603, 0805), SMD sizes for aluminum electrolytic capacitors, and through-hole footprints for polarized capacitors. Save precious design time by seamlessly add more information to this part (value, footprint, etc.) as it becomes available. Standard capacitor values: 1.0pF 10pF 100pF 1000pF 0.01uF 0.1uF 1.0uF 10uF 100uF 1000uF 10,000uF 1.1pF 11pF 110pF 1100pF 1.2pF 12pF 120pF 1200pF 1.3pF 13pF 130pF 1300pF 1.5pF 15pF 150pF 1500pF 0.015uF 0.15uF 1.5uF 15uF 150uF 1500uF 1.6pF 16pF 160pF 1600pF 1.8pF 18pF 180pF 1800pF 2.0pF 20pF 200pF 2000pF 2.2pF 22pF 20pF 2200pF 0.022uF 0.22uF 2.2uF 22uF 220uF 2200uF 2.4pF 24pF 240pF 2400pF 2.7pF 27pF 270pF 2700pF 3.0pF 30pF 300pF 3000pF 3.3pF 33pF 330pF 3300pF 0.033uF 0.33uF 3.3uF 33uF 330uF 3300uF 3.6pF 36pF 360pF 3600pF 3.9pF 39pF 390pF 3900pF 4.3pF 43pF 430pF 4300pF 4.7pF 47pF 470pF 4700pF 0.047uF 0.47uF 4.7uF 47uF 470uF 4700uF 5.1pF 51pF 510pF 5100pF 5.6pF 56pF 560pF 5600pF 6.2pF 62pF 620pF 6200pF 6.8pF 68pF 680pF 6800pF 0.068uF 0.68uF 6.8uF 68uF 680uF 6800uF 7.5pF 75pF 750pF 7500pF 8.2pF 82pF 820pF 8200pF 9.1pF 91pF 910pF 9100pF #generics #CommonPartsLibrary
    jharwinbarrozo
    1.5M
  • Generic Inductor
    Generic Inductor
    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
    jharwinbarrozo
    15.1k
  • Terminal
    Terminal
    An electrical connector acting as reusable interface to a conductor and creating a point where external circuits can be connected.
    natarius
  • RMCF0805JT47K0
    RMCF0805JT47K0
    47 kOhms ±5% 0.125W, 1/8W Chip Resistor 0805 (2012 Metric) Automotive AEC-Q200 Thick Film #forLedBlink
    jharwinbarrozo
    1.2M
  • 875105359001
    875105359001
    10uF Capacitor Aluminum Polymer 20% 16V SMD 5x5.3mm #forLedBlink #commonpartslibrary #capacitor #aluminumpolymer #radialcan
    jharwinbarrozo
    1.2M
  • CTL1206FYW1T
    CTL1206FYW1T
    Yellow 595nm LED Indication - Discrete 1.7V 1206 (3216 Metric) #forLedBlink
    jharwinbarrozo
    1.1M

Inspect

Aerospace Electronics | Copilot Preset

Aerospace Electronics | Copilot Preset
Description

Created
Last updated by pawels1991
2 Contributor(s)
jharwinbarrozo
pawels1991

Controls

Properties

Domain Application
Aerospace
Compliance
NASA Standards, Radiation Hardness Assurance (RHA)
Operating Voltage
1V to 57V
Operating Temperature
-55 ºC to 125ºC
Total Ionizing Dose Ratings
20 to 100 kilorad (kRad)

Availability & Pricing

DistributorQty 1

Assets