Share This Article
I have been a scientist for all my life, but I have never been a scientist that focuses only on electromagnetic fields. That is, until recently when I was in a science club called the Electric Power Society. We had to use a whole new level of science to make our presentation.
I have been an engineer for all my life, but I have never been an engineer that focuses only on mechanical engineering. That is, until recently when I was in a scientific club called the Engineering Society of America and we had to make our presentations using a whole new level of engineering theory. It was really easy.
A field is a way of measuring electric current. Now, for the benefit of the uninitiated, a field is the direction you would like to take when pulling a wire or a conductor through a magnetic field. Now, the magnetic field and the electric field are the same thing, but the difference is that the electric field is measured in volts and the magnetic field in gauss. So if you have a field measured in volts, you can use it to measure electric current using a voltmeter.
I don’t know about you, but that doesn’t really sound like a lot of fun.
In the context of electric fields, gauss law is a name we gave to the equation that describes how the strength of electric fields varies with distance. Gauss law, however, is not a law. It is a mathematical relationship that was derived in 1820 by Thomas Gauss, with the intent of being used as a tool for creating electrical machines.
It is said that if you create a field that is close to the Gaussian curve (the equation that describes how the strength of the electric field varies with distance), you can get a field that is very close to the Gaussian curve, which is exactly the same thing. In other words, just by using the equation, you can get a field that is very close to the Gaussian curve, which is the same thing.
The theory of Gauss law that I have used in this post is based on the theory that I talked about in my previous post in which I talked about how electric fields are created by photons. So it isn’t actually a new theory of electric fields. It’s just a new way of talking about electric field.
So, just because the equation says that a field is Gaussian, that does not mean that that field is what is called a Gaussian field. For instance, if you had a field that was very far from Gaussian, it would be very different from the Gaussian curve you see when you do this. So this is another way of saying that Gauss law is for fields far from Gaussian. I have more links over at my website where I have explained this theory in detail.
Gauss law is a law that describes the way an electric field is changing as it is applied to a given object. For a field to be called Gaussian, you have to have a very small amount of variation in the electric field. Gaussians are often used to describe the field of a capacitor which is connected in parallel with a resistor. The capacitor is charged and the resistor is allowed to discharge.
The formula for the electric field of a capacitor is very much like the formula for the electric field of a resistor. It is a linear function of the applied electric field and has a peak and a valley. If you look at the formula for the electric field of a capacitor, you will see that the peak and valley have a similar shape. When you think about this, you realize that the same is true for the electric field of a capacitor.