LaTeX templates and examples — Math

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To get the correct answer one must ask the correct question. In the field of Quantum Gravity the question has been how do we quantize General Relativity or derive a quantum theory which becomes General Relativity at low energies. Observing that Quantum Field Theory was the result of making Quantum Mechanics into a relativistic theory, I asked myself why not make QFT obey the principles of GR? I answered this question with a model I call Relativization. In a series of three papers I presented an answer to this alternative question which gives finite results for everything from black holes to particle physics. Presented at the April meeting of the American Physical Society

El presengte trabajo tiene como objetivo dar a conocer las bondades de los modelos Logit y probit dentro del campo de la estimación de modelos con variable endógena discreta dicotómica. Template Details: The Legrand Orange Book LaTeX Template Version 2.0 (9/2/15) This template has been downloaded from: http://www.LaTeXTemplates.com Mathias Legrand (legrand.mathias@gmail.com) with modifications by: Vel (vel@latextemplates.com) License: CC BY-NC-SA 3.0 (http://creativecommons.org/licenses/by-nc-sa/3.0/)

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This template does not comply with the design manual at the University of Oslo from 2022. Template for master's theses written at the Department of Mathematics at the University of Oslo. Useful tips for large documents: https://github.com/martinhelso/Introduction-to-LaTeX/blob/master/large-documents.md

50 quadratische Gleichungen werden automatisch erzeugt. So geht's: Wenn rechts die Vorschau erscheint, oben PDF anklicken. 50 quadratic equations will be created automatically. Please wait until you see the preview. Then click on PDF to save the file.

Aufgaben zum Thema Grundrechenarten werden mit LuaLaTeX automatisch erzeugt. LuaLaTex provides math problems for the four basic arithmetical operations automatically.

Muons compose the penetrating component of Cosmic Rays. At sea level, they constitute the largest part of Secondary Cosmic Rays, giving an average flux of ≈ 100 m−2s−1sr−1. The aim of our experiment is to estimate, from muon decay, the mean lifetime and the mass of invisible products. Our experimental setup includes four detectors: three of them are plastic scintillators and compose the trigger system, while the last one is a liquid scintillator which measures the particles energy. All these scintillators are read by photomultipliers. Trigger and pulse thresholds are computed by logical and temporal modules in a VME crate. The Data Acquisition System has been verified to work properly. It is composed of two fADCs modules, one I/O Register, one Motorola computer and a Farm. The liquid scintillator has been calibrated in energy using both passing muons and 60CO gamma source. Thanks to the charge-energy conversion factor we estimated electron energy spectrum. In particular we selected a sample of decay events by estimating muon mean lifetime τμ = 2.19 ± 0.34 μs; then we finally extrapolated an upper limit for invisible products mass mν < 5.99 ± 0.73 MeV/c2.