This is a "how to guide" for making introductory calculations in classical physics for undergraduates studying the subject.
The calculations are performed in Mathematica, and stress graphical visualization, units, and numerical answers. The techniques show the student how to learn the physics without being hung up on the math. There is a continuing movement to introduce more advanced computational methods into lower-level physics courses. Mathematica is a unique tool in that code is written as "human readable" much like one writes a traditional equation on the board.
The companion code for this book can be found here: https://physics.bu.edu/~rohlf/code.html
Key Features:
. Concise summary of the physics concepts
. Over 300 worked examples in Mathematica
. Tutorial to allow a beginner to produce fast results
The companion code for this book can be found here: https://physics.bu.edu/~rohlf/code.html
Autorentext
> c. At CERN, he worked on the discovery of the W and Z bosons and measurement of their properties. Presently, he is working on the Compact Muon Solenoid (CMS) experiment at the CERN Large Hadron Collider (LHC) which discovered the Higgs boson and is searching for new phenomena beyond the standard model.