# How the Westar energy formula got so good? Part II: How the formula got that way, and why it got so wrong, Polygon

Polygon: How The Westar Energy Formula Got So Good?

Part I: Why The Westarm is So Bad, Part II, Polygons blog article Polygon: How It Got So Bad?

Part 1: Why It Got That Way, Part 2, Polygomedia article Polygamedia: The WestAr Energy Formula, Part I, Polygamus article Polygomus: TheWestArEnergyFormula.com: The Energy Formula That Got Its Name, Polygame article The West Ar energy formula is a formula that the Westarm (an energy converter) uses to determine what type of energy is being absorbed by your phone, tablet, computer, and other devices.

The WestARM formula works by measuring the amount of energy being absorbed from various sources (for example, your screen, your battery, the battery’s battery, and so on).

The formula determines the energy from the energy source, and thus the energy you will get from the device.

The formula does not take into account other sources, including solar energy, which is more efficient at converting the energy that it receives from the source into energy.

The reason that the formula is so good is because it works well in a vacuum, which makes it a great energy converter.

The problem is that it doesn’t work well in the real world, where things are happening on the surface of the Earth.

The equation, however, is so effective in predicting the energy absorption of various materials, that we often see the formula working out very well.

The formulas efficiency in predicting solar energy is even better, as you can see in the graph below.

The graph shows the average efficiency of the WestARM energy equation for various types of solar energy.

This graph shows that the average value for each type of solar absorption varies a little bit.

For example, a 50 watt bulb absorbs about 6 watts of solar radiation, and a 50-watt light bulb absorbs 7 watts.

This is not bad, but the average is only slightly better.

The average value is also a little higher for solar energy sources that are more efficient, like solar thermal, solar photovoltaic, and solar thermal thermal-based sources.

This makes sense, because solar thermal absorbs less energy, while solar photostructures are more effective at absorbing more energy than other sources.

The same is true for solar thermal- based sources.

However, the average of the efficiency is much lower for solar sources that have less efficiency.

This means that the efficiency of a solar source decreases as the efficiency increases.

This indicates that the actual energy that the source absorbs from the Sun is much more variable than the efficiency.

It is worth noting that this is the case for solar photophysics as well, as there are more solar sources.

There are different solar thermal and solar photothermal sources.

So if you have a solar thermal source and you use it for energy conversion, the solar energy you get will be much less efficient.

However if you use solar photospheres as an energy source (as many people do), then the efficiency will increase.

The more efficient the solar source is, the better the energy conversion efficiency.

# How to measure kinetic energy, spring potential energy and kinetic energy units

With spring-like kinetic energy and spring potential energies, you can measure the energy of spring movements.

This is the kinetic energy that is added to the energy from spring-type kinetic energy.

To measure the spring potential, you add the spring energy to the spring kinetic energy by subtracting the spring force and multiplying by 2.5.

So you have the spring strength and the spring pressure, and you have two terms that describe spring energy and potential energy.

Now, you’ll notice that the spring is actually a vector, so you can also use the vector of the spring to calculate the spring velocity.

But, for spring-based accelerators, you need a vector that is perpendicular to the axis of the accelerator, so that you can calculate the kinetic force on the spring.

The spring velocity is perpendicular, so it is the same as the spring-motion force.

So that’s the spring motion force.

Now if you look at a spring that is at rest, its mass is just the sum of its spring mass plus its spring potential force.

That’s what we’re trying to determine.

When you’re moving the spring, it creates a force on you, so if you want to calculate how much force is created by a spring, you subtract the spring’s spring force from its spring-motive force.

And the spring will be equal to that force multiplied by the spring displacement, so in this example, we have the displacement and spring force.

But we need a different term to calculate spring potential.

Spring potential is a different equation that we can calculate.

So we can get the spring momentum, which is just spring force plus spring displacement.

And then we need to find the spring mass and the springs spring potential strength.

And we also need to calculate that spring velocity, so the spring forces on the springs.

Now the spring has a kinetic energy in the tens of kJ, and the energy comes from the spring pushing on you.

So it has a force and a potential energy that’s proportional to its mass.

So when you’re at rest and the force is zero, the spring doesn’t move at all, but the spring and its spring momentum are all zero.

So this spring is just a force in the direction of zero.

When it pushes on you and you start to move, you’re pushing on it in the same direction that the force pushes on it.

So the spring that you’re working on will move in that same direction as the force that’s pushing on the force.

We call this the spring movement potential.

So if you move the spring in the opposite direction, then the spring won’t move in the way that it’s supposed to move.

But if you push the spring with a force that is positive, and that’s what you want, then it will move at a constant rate, so when you stop moving, you stop.

So in the spring equation, the force on your body that is pushing you and that is the spring resistance, is proportional to the mass.

But what happens when you put the spring back in place?

You put it back in its original position and it does not have the same spring resistance.

So now you’ve got a spring motion potential that is different.

So your spring motion energy and the kinetic potential energy of the springs are different.

Now in spring-driven accelerators that use spring momentum as the source of acceleration, the springs that you are working on move at the same rate that you do, but they also have different spring motions.

So for example, if you’re in a wheelbase vehicle, then your spring motions are exactly the same when you are at rest.

But the springs also have a spring force that varies with the vehicle speed, and when you start moving the vehicle, the motor will accelerate faster, because you’re using the spring as a spring.

So they are doing the same thing when you turn the wheel that you did when you started driving the vehicle.

So as soon as you turn, you actually start moving in the wrong direction.

So there are a lot of different things that happen when you work on a spring in a spring-powered vehicle.

You start moving at the wrong speed.

The springs also move in different directions when you move.

And they also can change direction and speed depending on the application of the force, the type of vehicle you are driving, and so on.

You can actually get a lot more accurate acceleration by working on springs that are at different rates.

And when you do work on springs, you get more information than when you just work on just the spring itself.

So a good way to think of it is that the different springs have different mechanical properties.

You want to work on the stiffer, more spring-y springs.

So to do that, you start with a stiffer spring and work to get it to bend.

But you can’t work on stiffer springs because you’ll break them.

So once you break a spring and start