That’s pretty much the same in most fields, especially in the engineering direction. Idealized gases are idealized, steel beams are assumed to have a certain stiffness just by convention, and your entire existence is represented by a bunch of form fields stored in a database somewhere.
Isn’t a lot of engineering basically applied physics though anyway? Just reversed, such that rather than studying or predicting how a physical system should behave, you’re trying to take what has been learned over time and use it to work backwards to create a system that exhibits desired behavior
In the sense, medicine is applied physics, just as everything else.
Thing is, you always break down a problem into just enough details to solve the problem. Not more. No physicist studying, say, airflow over the Atlantic will take quantum effects or relativistic effects into account. Magnetic fields are also ignored. Even clouds are surprisingly “low res” in most simulations.
That’s pretty much the same in most fields, especially in the engineering direction. Idealized gases are idealized, steel beams are assumed to have a certain stiffness just by convention, and your entire existence is represented by a bunch of form fields stored in a database somewhere.
Isn’t a lot of engineering basically applied physics though anyway? Just reversed, such that rather than studying or predicting how a physical system should behave, you’re trying to take what has been learned over time and use it to work backwards to create a system that exhibits desired behavior
In the sense, medicine is applied physics, just as everything else.
Thing is, you always break down a problem into just enough details to solve the problem. Not more. No physicist studying, say, airflow over the Atlantic will take quantum effects or relativistic effects into account. Magnetic fields are also ignored. Even clouds are surprisingly “low res” in most simulations.