The amplitude is simply telling you how well aligned you are, it doesn't say anything about lenses.

Let's multiply both sides of this equation times the mass.

This one gives us the famous formula...Force is equal to Mass times Acceleration.

Top left is proportion between black hole mass, and the luminous stellar mass.

We'll start with something very simple Newton's Law

It's just this nice, simple, expression

The only place to get it from is density.

I'll specify that by v I want to be clear. This is not vector quantity.

Which looks a little bit like Tally Fisher or Faber Jackson relation.

Well F equals ma.

So we can see that they are directly proportional and the mass is that how proportional they are

labeled. The hatched blue area on the left corresponds to replication of the masses.

The final stages, when I ran the samples through a high pressure

Einstein's wrong. Energy doesn't go mass times velocity light square in this dimension.

So velocity ... and there is many ways you might see it defined.

So the net forces on this is F minus ky, and that's equal to the mass of our object times its acceleration.

We could say x is equal to acceleration.

But if we rearrange this formula quickly, we can get to acceleration equals force over mass, which means that for a larger particle a larger mass it requires more force to change its direction.

Interestingly enough, that corresponds to the riot of omega matter to the omega of variance in unknown at large.

We get the force this force, not just this force this was just F equals ma but this force is equal to the mass of our object, times the acceleration of the object plus whatever the spring constant is for the spring plus k times our position, times y.

Those can be understood in terms of merging, random merging of pieces into an elliptical galaxy will both anisotropize g its velocity dis , dispersion.

Plot of stellar masses and directly from integration of visible light versus the nominal masses, which are now inferred.

Therefore, you're not accelerating.

But then you're wondering, well, I know what a force is, you know, force is mass times acceleration.

Plugging these two numbers, into the equation above, gives us cluster masses of the order of ten 14 or ten 15 solar masses.

Mass

zettawatts

das

cs

guilders

forints

litass

latss

If you make the mass larger...if you double it, then your acceleration will be half as much.

Or, for a given force...the less that it will accelerate... the harder it is to change its constant velocity.

So how do we study properties of clusters as a population?

So, this is great, because remember my job is to show there is a lot of mass inside a small volume.

They all yield the same results.

energy, in its mass temp What are you doing?

We could have let y is equal to force and m is equal to... or mass is equal to p.

So fitting dynamical models in detail to galaxies we can figure out exactly what their masses are, and you can plot masses to light ratio versus luminosity or reduced mass, and here they are.

In mathematical terms, Newton's Second Law says that force is the product of mass times acceleration.

And just like that, we have the magnitude of the velocity or we could say the speed of the object as it goes around in a circle

There's a basic, profound acceleration of this evolutionary process.

It's important if you try to model this.