[4] **viXra:1002.0049 [pdf]**
*submitted on 22 Feb 2010*

**Authors:** Antoine Acke

**Comments:** 22 Pages.

In the paper GRAVITATION AND ELECTROMAGNETISM (viXra-classical
physics:1001.0017), we explained the gravitational and the electromagnetic phenomena
through the mediation of "informatons". We started from the hypothesis that any material
object manifests itself in space by emitting informatons. These are dot-shaped entities that
rush away with the speed of light carrying "information" about the position, the velocity
and - if it is electrically charged - the electrical charge of the emitter. We showed that informatons
constitute the gravitational and the electromagnetic fields which make the interactions
possible.
In this paper we extend the theory to interactions between - electrically neutral - moving
objects in relativistic situations.

**Category:** Classical Physics

[3] **viXra:1002.0043 [pdf]**
*submitted on 19 Feb 2010*

**Authors:** Anthony Pinedo Araujo

**Comments:** 7 pages. This article was written in Spanish. It was published in ECIPERU, vol 6, num 2, pp 68-76.August 2009.

There are two types of systems of electric aerogeneration by using wind turbines, one is called horizontal axis wind turbine (HAWT)
and the other one is called vertical axis wind turbine (VAWT). Both of them have advantages and disadvantages depending on many
factors. Since the second one had produced lees power than the first one, they were ignored. However, the adaptation of a levitation
system and a new system of magnetic induction made VAWT increase the power produced and exceed the HAWT. Although VAWT
models were studied enough in the design and experimental scheme, there is no solid explanation, based on basic principles, on the
operation of the VAWT. In this paper is proposed a theoretical model of VAWT operation. Therefore, three studies are done: the
interaction between wind and blades of the turbine, the magnetic levitation system and the energy production by magnetic induction.
Those studies make us able to know and predict the operation of those systems. Since, we shall know how many factors are affecting
the efficiency of the system; we shall be able to control those parameters in order to get the best efficiency.

**Category:** Classical Physics

[2] **viXra:1002.0008 [pdf]**
*submitted on 4 Feb 2010*

**Authors:** Constantinos Ragazas

**Comments:** 2 pages

In another paper we derived Planck's Law and showed that it is an exact mathematical
identity that describes the interaction of energy. In that derivation the quantity,
the 'accumulation of energy', played a prominent role. This quantity was defined as a
time-integral of energy, while energy was the primary quantity. In this note we consider
instead that this is the primary physical quantity (prime physis) and define in terms of
it energy, momentum and force. From these we go on to mathematically derive such basic
laws of Physics as Conservation of Energy and Momentum and Newton's Second Law of Motion.
We also make promising connections with the Schrodinger Equation and derive a relationship
between energy, mass and velocity. Underlying all this is the conviction that 'measurement'
is what connects Mathematics with Physics. It's what makes mathematical derivations
relevant to physics. If so, it should then be that all Basic Law of Physics are Mathematical
Identities that describe the interactions of measurement. This we are able to show for
Planck's Law, Conservation of Energy and Momentum, Newton's Second Law of Motion, and the
Quantization of Energy Hypothesis.

**Category:** Classical Physics

[1] **viXra:1002.0004 [pdf]**
*submitted on 2 Feb 2010*

**Authors:** Constantinos Ragazas

**Comments:** 6 pages

Whereas globally energy propagates continuously as a wave, in this note we consider that
energy can be represented locally by an exponential of time. Using such representation we
are able to show that Planck's Formula for blackbody radiation is an exact mathematical
identity. We are also able to explain the photoelectric effect without the photon hypothesis
and derive an equation relating the photoelectric current to the intensity and frequency of
radiation. This equation conforms well with graphical characteristics of the actual
experimental data. Moreover, this representation of energy explains the quantum hypothesis,
provides a simple intuitive explanation of the double-slit experiment and permits a definition
of the temperature of radiation. It also explains the physical meaning of Planck's constant
h and why it exists.

**Category:** Classical Physics