That would probably be a slide-rule (slip-stick in common usage). It's what I had to use in high-school. There's one little bugger running around here who collects them and loves them more than women (except for his lovely wife, of course). In fact, his avatar is a picture of one.Ponderer said:My uncle used to tell me during his early days as a scientist how they would use these wooden gadgets to solve math equations.
##E=mc^2## may not be the most logical starting point in the logical progression of special relativity... it's more of a destination. However, Google will find you some nice derivations and SR doesn't have to require a lot of math; there are quite good presentations that use nothing more than high school algebra.Ponderer said:Actually it just occurred to me that it would be interesting to see how E = m c^2 is derived.
Theoretical physics is a branch of physics that uses mathematical models and concepts to explain and predict the behavior of physical systems, without the need for direct experimentation. It is concerned with understanding the fundamental laws of nature and the underlying principles that govern the universe.
Theoretical physics helps us to develop a more complete understanding of the universe by providing explanations for observed phenomena and making predictions about new phenomena that have yet to be observed. It also helps us to unify different theories and concepts, leading to a more comprehensive understanding of the laws of nature.
Some examples of theoretical physics include quantum mechanics, general relativity, and string theory. These theories have helped us to understand the behavior of particles at the atomic and subatomic level, the structure of the universe on a large scale, and the fundamental nature of matter and energy.
Mathematics plays a crucial role in theoretical physics, as it provides the language and tools necessary to formulate and solve complex problems and equations. Theoretical physicists use mathematical concepts such as calculus, differential equations, and linear algebra to develop models and make predictions about the behavior of physical systems.
Theoretical physics has a significant impact on technological advancements, as many of the theories and concepts developed in this field have practical applications. For example, the principles of quantum mechanics have led to the development of technologies such as transistors, lasers, and computer memory. Theoretical physics also contributes to advancements in fields such as astrophysics, materials science, and engineering.