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
It looks like you've provided a template for an aerospace electronics project with specific requirements but haven't asked a specific question or requested assistance on a particular aspect of your project yet. How can I assist you with your satellite payload, avionic system, or space instrument design? Whether you're looking for advice on selecting components that meet the MIL-STD or NASA standards, or assistance on how to start laying out your circuit in flux.ai, I'm here to help. Please provide me with more details about what you're looking to achieve.
It seems there might have been a misunderstanding in your request. If you’re looking for guidance on choosing an Integrated Circuit (IC) that fits your aerospace project requirements, here are some general considerations and tips that could assist you:
IC Selection for Aerospace Projects
Given the stringent requirements for aerospace applications, such as compliance with NASA standards, radiation hardness, and extreme operating temperatures, selecting the right ICs is crucial. Here’s what to consider:
Radiation Hardness: Look for ICs specifically designed for space applications. These components have been tested and rated for total ionizing dose (TID) levels within your specified range of $20$ to $100$ kRad. Manufacturers like Xilinx and Microchip have lines of radiation-hardened (rad-hard) products.
Operating Temperature Range: Ensure the IC can operate within the specified range of −55ºC to 125ºC. This is critical for ensuring functionality in the harsh thermal environment of space.
Voltage Requirements: Your operating voltage range is quite wide ($1$V to $57$V). This specification will factor into your selection depending on your circuit’s power supply design. Ensure the IC can handle the voltages it will encounter in your application.
Compliance and Standards: Besides meeting physical and electrical requirements, the chosen IC must comply with relevant aerospace standards (e.g., MIL-STD for military applications, NASA standards for space applications).
Starting Point
Microcontroller/Microprocessor: If your project requires processing capability, consider rad-hard microprocessors. Example: Microchip’s ATSAMV71Q21RT is suitable for high-performance space applications, meeting your temperature and radiation requirements.
Memory ICs: For data storage, rad-hardened EEPROM or flash memory could be a good start. Example: STMicroelectronics M28W160ECT offers a wide range of operating temperatures and is suitable for high-reliability applications.
Linear and Mixed-Signal ICs: For power management, analog-to-digital conversion, etc., look at manufacturers that specialize in aerospace-grade components. Example: Texas Instruments’s SM74611 smart diode controller is designed for high-temperature operation and could fit into power management designs.
Next Steps
Identify specific functionalities needed in your project. Is it processing, memory, power management, communication, or something else?
Narrow down to specific parts within those functionalities that meet the aerospace criteria.
Review datasheets and manufacturers' guides for radiation hardness, temperature range, and other relevant specifications.
Consider redundancy and fail-safes in your design to enhance reliability in space conditions.
Can you specify the type of IC or functionality you’re aiming to incorporate into your aerospace project? This will help me provide more targeted advice.