Dr. Vlasak's brief comments regarding his work: "The material in my books is all based on measurements made by other scientists, which has been thoroughly verified and accepted by the scientific community and my own extensive laboratory and field measurements throughout the years. These scientific models and methods include Planck's Radiation Equation, electronic theory, the antenna electromagnetic wave equations, Coulomb's Law, Maxwell's equations, Ampere's Law, Lenz's Law, the Bohr Atom, Parseval's formula, the Rydberg series of spectral lines and Einstein's equations. In order to find the truth, all possibilities must be considered and theory must conform to all measurements (as Planck had emphasized). This statement should also apply to the methods of Quantum Mechanics, whereas the methodology is limited to a narrow range of possibilities. The manipulations and analysis of the Schrodinger equation, for instance, require certain limiting assumptions and may therefore be incorrect or inaccurate.

The key to my analysis is the derivation of the exact position(s) and velocitie(s) of the electron in the hydrogen atom, whereas in quantum mechanics it is defined only as being located somewhere on a probable spherical surface having a probable radius (nevertheless, religiously believed by many physicists). Some analyses are commonly based on the solutions to second order differential equations, but this method is subject to the high sensitivity of coefficients, resulting in questionable accuracy and potential subsequent misinterpretation (Hilbert and Courant). Another problem occurs with the accepted method of separation of variables for solving the 3-dimensional equation of quantum mechanics (4-dimensional for space and time), which is based on an important assumption that limits the conditions for the variables (look for some future details on this elementary problem on this web site). Other possibilities exist, including the proposition that there is a term missing in some of Maxwell's equations that is necessary to account for the transverse properties of radiation. The Fitzgerald/Lorentz Contraction and Einstein's relativity equations also appear to have missing terms or incorrect coefficients that can account for the transverse properties.It possible to accomplish this task through the process of "characterization", of which most electrical engineers are quite familiar. This will take a new and different approach to the problem, wherein exact positions and velocities will be determined"