1.**Safety and Compliance: Ensuring the component meets industry standards and regulatory requirements (e.g., FAA, EASA) is non-negotiable. 2.Weight Optimization: Weight plays a significant role in aerospace performance. 3.Durability and Reliability: Aerospace component are exposed to harsh environmental conditions.This point to be Noted. 4.Manufacturing Feasibility: Given the tight budget, prioritize features that are cost-effective to manufacture. 5.Simplicity and Functionality: Minimize complexity in the design to reduce the potential for manufacturing errors and lower the overall cost. 6.Testing and Validation: Allocate some budget for testing and validation to ensure the component performs as expected under real-world conditions.

The top priority is obviously it's FUNCTIONALITY. for being a component in aerospace, one must focus on its effectiveness in the system and air-worthiness. Other features are optional or add-ons only.

Safety is of the utmost prority. Failure of components operating in extreme environments such as an engine component can have fatal consequences. Components should meet the regulatory requirements set forth by the FAA, EASA, and others. Design data should also be reviewed by SMEs. Weight reduction is another important feature. Utilizing materials such as composites and alloys can help reduce costs incurred while an aircraft is in service. For instance, composite aircraft directly enhance fuel efficiency, in turn saving costs.

The engineering costs depends of the final number components, for a military or space project with a mínimum number of components the engineering costs are important. For civil projects with a high level of components the cost derivated from the manufacturing and material selection are the main costs. For that, depend of the project the engineering costs could be very relevant depend of the number of assemblies to manufacture.