Cut down frequency -3db of the equivalent low pass filter as a function of the sampling number. A typical representative oscillogram of the current waveforms taken by the digital oscilloscope is shown in figure 8, for a discharge voltage at 4 kV. These signals are in the time domain and it is obvious that they are similar to the typical waveform of the output current as it was described in figure 1.
Science Advisor MikeGomez said: Is the gravitational coupling constant actually different per unit of mass, for different particles?
It seems strange to me because I normally think of gravitational force in terms of mass, without regard to what kind of mass it is. Let me rephrase that question. Would a gram of electrons if they could be held together for a time have the same gravitation force as a gram of protons, even if both have a different gravitational coupling constant?
Also, in the Wikipedia article about the gravitational coupling constant, it says that the gravitational coupling constant characterizes the gravitational attraction between charged elementary particles having nonzero mass.
Can you please explain a little about the relationship with gravitation and charge, because I have previously thought that they were unrelated? What about a gram of neutrons. Neutrons are not charged so they might be excluded from having a gravitational coupling constant, yet they have mass and definately exert gravitational influence.
Perhaps they are able to have GCC based on the fact that they are composed or quarks, which do have charge? The reason is, as I said, there is no 'fundamental unit of mass' as there is a fundamental unit of charge.
I think the only reason they mention charged particles is to compare to the fine structure constant, which is defined of course in terms of electrical charge.
I see no reason why you can't have a gravitational coupling constant for neutral particles.Browse a Professional writing service wide-range of engineering projects and techniques a literary analysis of sir gawain and the green knight a medieval romance from leading a better understanding of the influence of electrostatic charge on objects research institutes around the world.
Definitions of electrostatic charge. 1. n the electric charge at rest on the surface of an insulated body (which establishes and adjacent electrostatic field) Type of: charge, electric charge.
the quantity of unbalanced electricity in a body (either positive or negative) and construed as an excess or deficiency of electrons. If the charge of one of the objects is increased by a factor of four, and the distance separating the objects is doubled, then what is the new force?
N Explanation: The electrostatic force is directly related to the product of the charges and inversely related to the square of the separation distance.
This research investigates the influence of computer simulations (virtual experiments) on one hand and real experiments on the other hand on the conceptual understanding of electrical charging. The attractive or repulsive interaction between any two charged objects is an electric feelthefish.com any force, its effect upon objects is described by Newton's laws of feelthefish.com electric force - F elect - joins the long list of other forces that can act upon objects.
Newton's laws are applied to analyze the motion (or lack of motion) of objects under the influence of such a force or combination. The paper is a study for the better understanding of electrostatic discharge (ESD). Electrostatic discharge can change the electrical characteristics of a semiconductor device, degrading or.