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Strategies & Market Trends : 2026 TeoTwawKi ... 2032 Darkest Interregnum -- Ignore unavailable to you. Want to Upgrade?

To: dvdw© who wrote (91757)	6/21/2012 1:21:36 PM
From: elmatador	Read Replies (1) \| Respond to of 219583

Lula told the same about international financiers and IMF, they knew it all only when it was to be applied to the indebted countries. When debt came close to home they did not know how to deal with it. And to add a bit of salt to the wound, he continued, this ciris was made by the white and blue eyed. Meaning this cris is not negro stuff...

To: dvdw© who wrote (91757)

6/21/2012 10:14:03 PM

From: dvdw©

Read Replies (1) | Respond to of 219583

knock knock....

who is there?

Erwin ...i have a message for Peak,

Oh...ok, Mr Oilisnotin...

ES...oh shucks sorry i missed him ...let me slip this note under the door, please make sure Mr Peak Oilisnotin, reads and understand s this...

tell em that ES stoped by as promised...and thanks..

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For a more general introduction to the topic, please see Introduction to quantum mechanics.
Quantum mechanics

Uncertainty principle

Introduction
Glossary · History

Background [show]

Fundamental concepts [show]

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In quantum mechanics, the Schrödinger equation is an equation that describes how the quantum state of a physical system changes with time. It was formulated in late 1925, and published in 1926, by the Austrian physicist Erwin Schrödinger.

In classical mechanics, the equation of motion is Newton's second law, and equivalent formulations are the Euler-Lagrange equations and Hamilton's equations. In all these formulations, they are used to solve for the motion of a mechanical system, and mathematically predict what the system will do at any time beyond the initial settings and configuration of the system.

In quantum mechanics, the analogue of Newton's law is Schrödinger's equation for a quantum system, usually atoms, molecules, and subatomic particles; free, bound, or localized. It is not a simple algebraic equation, but (in general) a linear partial differential equation. The differential equation encases the wavefunction of the system, also called the quantum state or state vector.

In the standard interpretation of quantum mechanics, the wavefunction is the most complete description that can be given to a physical system. Solutions to Schrödinger's equation describe not only molecular, atomic, and subatomic systems, but also macroscopic systems, possibly even the whole universe. [1]

Like Newton's Second law, the Schrödinger equation can be mathematically transformed into other formulations such as Werner Heisenberg's matrix mechanics, and Richard Feynman's path integral formulation. Also like Newton's Second law, the Schrödinger equation describes time in a way that is inconvenient for relativistic theories, a problem that is not as severe in matrix mechanics and completely absent in the path integral formulations says its important...