## Newton Derives Universal Gravitation Constant and Mass of Earth

Skeptics did not believe Newton’s theories of gravitation to be true, but his figures proved valid.

The radius of the Earth has been known since ancient times and the distance to the moon has also been calculated.

Therefore Newton could use these numbers in a clever way to calculate both the universal gravitation constant and the mass of the earth.

When he plugged in numbers it showed that they resulted in the period of the moon being 1/13 of a year, which is accurate.

In a similar way you can often times manipulate multiple variables using known data (like using the calculus technique of summing shells to obtain a volume) to obtain solutions.

## Natural Frequency Introduction

All objects that oscillate have something called a natural frequency.

At this frequency they will experience resonance and start oscillating with increasing magnitude towards infinity, or in the case of something like a bridge until it breaks.

In another instance, a snare drum can be sitting motionless, but if a saxophone player near it plays a certain tone that happens to match its natural frequency (or a multiple of it) then the snare drum will start vibrating.

## Physics Mathematics Notation Euler Sine Cosine

When writing mathematical expressions, numbers and formulas that look quite different can mean the same thing.

For instance, power series (an infinite series of terms added together) can be used to represent things like the natural log (ln).

That is actually how devices such as calculators compute numbers.

Likewise e with imaginary exponents is used as part of an expressions by Euler for sine and cosine.

## Pendulum Motion and Simple Harmonic Approximation

Technically the movement of a pendulum doesn’t quite match simple harmonic motion.

However, if the angle theta is small enough,  θ~sin(θ)

In fact for angles less than 15 degrees the error will be less than one percent.

Thus a simple pendulum essentially displays SHM (simple harmonic motion).

Such approximations are very useful in certain applications, especially in engineering, where such a small amount of error can be tolerable.

## Fear and Physics

(from mozzercork on flickr)

If you have a tough physics problem, you might hesitate to even start it.

Use lots of paper and just write down what comes to your mind.

It might be completely wrong, but it doesn’t matter, you’ll find out pretty quickly by doing simple checks (dimensional analysis, feasibility, etc)

Thomas Edison tried 10,000 materials for filaments before getting the electric light to work.

And complex physics problems can get somewhat ridiculous.

If you start a problem earlier, it will be in the back of your head.

Professor Barber even told us that he has gone to sleep and woken up with the answer.

## Simple Harmonic Motion SHO

Many things exhibit something that resembles simple harmonic motion (abbreviated SHO).

Waves rise and fall with a regular pattern and a slinky oscillates.

To analyze simple harmonic motion, we turn to the sine and cosine functions which are also periodic.

With a bit of tweaking, according to different amplitudes and starting points, a harmonic motion equation can describe such periodic functions.

However, such methods only work for small displacements.

When the displacements get large enough, nonlinear effects come into play.

## Phil Kesten Physics 32 Class at Santa Clara University

Hi Neal,
Okay, the pressure’s on:  I told my students about your site!  And yes, I’m teaching 32 this quarter, so anything you add on SHM, fluids, gravitation, waves, light, sound…  they’ll be looking!

prk

In light of this news, I will start to talk about Physics 32 stuff.

As far as my connection to Dr. Kesten, he was my advisor at Santa Clara and I took physics 31, 32, 33, and 34 from him.

Right now I am doing an MS in applied physics.

If I am unclear, let me know and leave comments!

I can even make videos, but only if I feel it is worth my time for now.