4:31
23. invariant mass
Prof. Sacha Kopp...
published: 07 Aug 2012
Author: utexascnsquest
23. invariant mass
Prof. Sacha Kopp
2:37
Invariant Mass Photons Higgs Boson Field Splits Hydrogen Abstraction BCS Theory
victoriastaffordapsychicinvestigation.wordpress.com theideagirlsays.wordpress.com www.twit...
published: 18 Sep 2012
Author: theideagirlsays
Invariant Mass Photons Higgs Boson Field Splits Hydrogen Abstraction BCS Theory
victoriastaffordapsychicinvestigation.wordpress.com theideagirlsays.wordpress.com www.twitter.com Filmed Sept 17 2012 I am video blogging my research into creating a Higgs Particle with Mass for us to study. Cross Referencing with WOW DATA an alien radio signal from NASA SETI 1977 20 August 2012 333 am edt Hydrogen Abstraction key word to higgs boson particle to remove the main signal and find the fragments of a particle that will stay with mass so we can study it. 20 August 2012 333 am edt Hydrogen Abstraction key word to higgs boson particle to remove the main signal and find the fragments of a particle that will stay with mass so we can study it.
3:07
AATUCAGG: Lesson 34 - Invariant and Relativistic Mass
Invariant and Relativistic Mass are related to the curvature of space by the Aatucagg Fact...
published: 08 Oct 2008
Author: aatucagg
AATUCAGG: Lesson 34 - Invariant and Relativistic Mass
Invariant and Relativistic Mass are related to the curvature of space by the Aatucagg Factor
1:52
Law Of Conservation Of energy in a Simple Pendulum
Check us out at www.tutorvista.com The law of conservation of energy is an empirical law o...
published: 07 May 2010
Author: TutorVista
Law Of Conservation Of energy in a Simple Pendulum
Check us out at www.tutorvista.com The law of conservation of energy is an empirical law of physics. It states that the total amount of energy in an isolated system remains constant over time (is said to be conserved over time). A consequence of this law is that energy can neither be created nor destroyed, it can only be transformed from one state to another. The only thing that can happen to energy in a closed system is that it can change form, for instance chemical energy can become kinetic energy. Albert Einstein's theory of relativity shows that energy and mass are the same thing, and that neither one appears without the other. Thus in closed systems, both mass and energy are conserved separately, just as was understood in pre-relativistic physics. The new feature of relativistic physics is that "matter" particles (such as those constituting atoms) could be converted to non-matter forms of energy, such as light; or kinetic and potential energy (example: heat). However, this conversion does not affect the total mass of systems, since the latter forms of non-matter energy still retain their mass through any such conversion. Today, conservation of energy refers to the conservation of the total system energy over time. This energy includes the energy associated with the rest mass of particles and all other forms of energy in the system. In addition the invariant mass of systems of particles (the mass of the system as seen in its center of mass inertial frame, such as the <b>...</b>
4:43
9/11 Fake: A Squashed Flat Plane
Velocity is the rate of change of position. It is a vector physical quantity; both speed a...
published: 05 Oct 2010
Author: FringeReality
9/11 Fake: A Squashed Flat Plane
Velocity is the rate of change of position. It is a vector physical quantity; both speed and direction are required to define it. In the SI (metric) system, it is measured in meters per second: (m/s) or ms−1. The scalar absolute value (magnitude) of velocity is speed. For example, "5 meters per second" is a scalar and not a vector, whereas "5 meters per second east" is a vector. The kinetic energy of an object is the extra energy which it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its current velocity. Having gained this energy during its acceleration, the body maintains this kinetic energy unless its speed changes. Negative work of the same magnitude would be required to return the body to a state of rest from that velocity. The kinetic energy of a single object is completely frame-dependent (relative). For example, a bullet racing by a non-moving observer has kinetic energy in the reference frame of this observer, but the same bullet has zero kinetic energy in the reference frame which moves with the bullet. The kinetic energy of systems of objects, however, may sometimes not be completely removable by simple choice of reference frame. When this is the case, a residual minimum kinetic energy remains in the system as seen by all observers, and this kinetic energy (if present) contributes to the system's invariant mass, which is seen as the same value in all reference frames, and by all observers. video <b>...</b>
4:43
velocity = squashed flat plane
facebook.com seofollow.net very limited resources - to save on the math... velocity is the...
published: 20 Jan 2010
Author: spineyExtra
velocity = squashed flat plane
facebook.com seofollow.net very limited resources - to save on the math... velocity is the rate of change of position. It is a vector physical quantity; both speed and direction are required to define it. In the SI (metric) system, it is measured in meters per second: (m/s) or ms−1. The scalar absolute value (magnitude) of velocity is speed. For example, "5 meters per second" is a scalar and not a vector, whereas "5 meters per second east" is a vector. The kinetic energy of an object is the extra energy which it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its current velocity. Having gained this energy during its acceleration, the body maintains this kinetic energy unless its speed changes. Negative work of the same magnitude would be required to return the body to a state of rest from that velocity. The kinetic energy of a single object is completely frame-dependent (relative). For example, a bullet racing by a non-moving observer has kinetic energy in the reference frame of this observer, but the same bullet has zero kinetic energy in the reference frame which moves with the bullet. The kinetic energy of systems of objects, however, may sometimes not be completely removable by simple choice of reference frame. When this is the case, a residual minimum kinetic energy remains in the system as seen by all observers, and this kinetic energy (if present) contributes to the system's invariant mass, which is <b>...</b>
72:32
Supersymmetry, Extra Dimensions and the Origin of Mass
Google Tech Talks June 18, 2007 ABSTRACT "Supersymmetry, Extra Dimensions and the Ori...
published: 25 Jul 2007
Author: Google
Supersymmetry, Extra Dimensions and the Origin of Mass
Google Tech Talks June 18, 2007 ABSTRACT "Supersymmetry, Extra Dimensions and the Origin of Mass: Exploring the Nature of the Universe Using PetaScale Data Analysis" The Large Hadron Collider (LHC), scheduled to begin operation in Summer 2008, will collide protons at energies not accessible since the time of the early Universe. The study of the reactions produced at the LHC has the potential to revolutionize our understanding of the most fundamental forces in nature. The ATLAS experiment, currently being installed at the LHC, is designed to detect collisions at the LHC, to collect the relevant data and to provide a unified framework for the reconstruction and analysis of these data. This talk...
0:23
Z boson candidate event seen by CMS - LHC - CERN
Z produced by the 2 proton collision. The Z then disintegrated in e- and e+. Electrons Pt ...
published: 09 May 2010
Author: CP3UCLouvain
Z boson candidate event seen by CMS - LHC - CERN
Z produced by the 2 proton collision. The Z then disintegrated in e- and e+. Electrons Pt = 34.0 and 31.9GeV/c. Invariant mass = 91.2 GeV/c². Electrons: energy deposits in green in the electromagnetic calorimeter.
1:33
Zen's Collection
The kinetic energy of an object is the energy which it possesses due to its motion.[1] It ...
published: 12 Nov 2011
Author: xuishiro
Zen's Collection
The kinetic energy of an object is the energy which it possesses due to its motion.[1] It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its acceleration, the body maintains this kinetic energy unless its speed changes. The same amount of work is done by the body in decelerating from its current speed to a state of rest. The speed, and thus the kinetic energy of a single object is frame-dependent (relative): it can take any non-negative value, by choosing a suitable inertial frame of reference. For example, a bullet passing an observer has kinetic energy in the reference frame of this observer. The same bullet is stationary from the point of view of an observer moving with the same velocity as the bullet, and so has zero kinetic energy.[2] By contrast, the total kinetic energy of a system of objects cannot be reduced to zero by a suitable choice of the inertial reference frame, unless all the objects have the same velocity. In any other case the total kinetic energy has a non-zero minimum, as no inertial reference frame can be chosen in which all the objects are stationary. This minimum kinetic energy contributes to the system's invariant mass, which is independent of the reference frame. In classical mechanics, the kinetic energy of a non-rotating object of mass m traveling at a speed v is mv2/2. In relativistic mechanics, this is only a good approximation when v is much less than the <b>...</b>
49:42
12. Stellar Mass Black Holes
Frontiers/Controversies in Astrophysics (ASTR 160) One last key concept in Special Relativ...
published: 29 Sep 2008
Author: YaleCourses
12. Stellar Mass Black Holes
Frontiers/Controversies in Astrophysics (ASTR 160) One last key concept in Special Relativity is introduced before discussion turns again to black celestial bodies (black holes in particular) that manifest the relativistic effects students have learned about in the previous lectures. The new concept deals with describing events in a coordinate system of space and time. A mathematical explanation is given for how space and time reverse inside the Schwarzschild radius through sign changes in the metric. Evidence for General Relativity is offered from astronomical objects. The predicted presence and subsequent discovery of Neptune as proof of General Relativity are discussed, and stellar mass black holes are introduced. 00:00 - Chapter 1. Invariance in Special Relativity 10:10 - Chapter 2. Invariant Intervals and the Schwarzschild Metric 21:01 - Chapter 3. Schwarzschild Sign Changes and Space-Time Reversals 36:27 - Chapter 4. Evidence for General Relativity in Astronomy Complete course materials are available at the Open Yale Courses website: open.yale.edu This course was recorded in Spring 2007.
0:24
Fast Scale-Invariant Object Recognition
Combining Harris Interest Points and the SIFT Descriptor for Fast Scale-Invariant Object R...
published: 24 Jun 2010
Author: HumanoidRobots
Fast Scale-Invariant Object Recognition
Combining Harris Interest Points and the SIFT Descriptor for Fast Scale-Invariant Object Recognition.
1:15
Online Walking Gait Generation with Predefined Variable Height of the Center of Mass
www.robotik.jku.at For biped robots one main issue is the generation of stable trajectorie...
published: 25 Nov 2011
Author: robinJKU
Online Walking Gait Generation with Predefined Variable Height of the Center of Mass
www.robotik.jku.at For biped robots one main issue is the generation of stable trajectories for the center of mass (CoM). Several different approaches based on the zero moment point (ZMP) scheme have been presented in the past. Due to the complex dynamic structure of bipedal robots, most of the considered algorithms use a simplified time invariant linear model to approximate the dynamics of the system. This model is extended to a time variant one and then used to generate stable CoM trajectories with variable predefined CoM height. This allows to generate trajectories online for walking underneath obstacles with more accuracy. It is shown that using this extended scheme it is possible to overcome some kinematic limits as joint speed in the knee or the maximum step length for common walking. Published at the International Conference on Intelligent Robotics and Applications 2011 (ICIRA)
5:01
AATUCAGG: Lesson 35 - The Equivalence of Mass
Aatucagg believes that all mass reacts to the curvature of space in the same way because a...
published: 10 Oct 2008
Author: aatucagg
AATUCAGG: Lesson 35 - The Equivalence of Mass
Aatucagg believes that all mass reacts to the curvature of space in the same way because all mass is equivalent
0:19
PROTON AKA GHOST SCIENCE
hypertextbook.com Amaze yourself the actual diameter of unknown,never proven material/part...
published: 20 Nov 2011
Author: orgolioitalia1
PROTON AKA GHOST SCIENCE
hypertextbook.com Amaze yourself the actual diameter of unknown,never proven material/particle:-) In quantum chromodynamics, the modern theory of the nuclear force, most of the mass of the proton and the neutron is explained by special relativity. The mass of the proton is about eighty times greater than the sum of the rest masses of the quarks that make it up, while the gluons have zero rest mass. The extra energy of the quarks and gluons in a region within a proton, as compared to the energy of the quarks and gluons in the QCD vacuum, accounts for over 98% of the mass. The rest mass of the proton is thus the invariant mass of the system of moving quarks and gluons which make up the particle, and in such systems, even the energy of massless particles is still measured as part of the rest mass of the system. The internal dynamics of the proton are complicated, because they are determined by the quarks' exchanging gluons, and interacting with various vacuum condensates. Lattice QCD provides a way of calculating the mass of the proton directly from the theory to any accuracy, in principle. The most recent calculations[7][8] claim that the mass is determined to better than 4% accuracy, arguably accurate to 1% (see Figure S5 in Dürr et al.[8]). These claims are still controversial, because the calculations cannot yet be done with quarks as light as they are in the real world. This means that the predictions are found by a process of extrapolation, which can introduce <b>...</b>
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8:00
Higgs Boson Discovery announcement by Peter Higgs
4th of July 2012, this is the day the Higgs Boson was discovered by the human race. After ...
published: 04 Jul 2012
Author: MuonRay
Higgs Boson Discovery announcement by Peter Higgs
4th of July 2012, this is the day the Higgs Boson was discovered by the human race. After 45 years of searching, Peter Higgs can now announce to the world how he has seen the culmination of his life's work finally blossom into a tangible result, a result which has brought an all too human emotion to this triumph. Francois Englert, Carl Hagen and Gerald Guralnik are also present in this announcement, who created the theory along with Robert Brout. For this reason it will most likely be renamed the HEB-Boson. The Higgs field and resulting Higgs boson are a vital part of the Electroweak Interaction and the Standard Model of Particle Physics. In the absence of the Higgs field, when a Local Gauge is applied to the Lagrangian of the Electroweak Interaction we are left with force-carrying bosons that are massive, the W and Z Bosons with masses of ~80GeV and ~90GeV respectively. This would be okay for the Photon as it has no mass. The Higgs mechanism was the most favoured explanation for solving this problem. In brief, the Higgs field is introduced to 'break' the symmetry of the Electroweak theory, which allows particles to have mass. This Higgs mechanism is important as it not only explains how the heavy bosons become massive but also provides an explanation as to how the fermions come to have mass. The Mechanism of the interaction is simple to understand. Where the Electroweak Interaction couples to electric and weak (or flavour) charges and the Strong Interaction couples to <b>...</b>
0:36
Higgs Boson Explained: How The Higgs Field Works
The Higgs Boson Explained in layman's terms. see here for How the Higgs Boson was foun...
published: 04 Jul 2012
Author: MuonRay
Higgs Boson Explained: How The Higgs Field Works
The Higgs Boson Explained in layman's terms. see here for How the Higgs Boson was found: www.youtube.com Higgs bosons exist in the fabric of the space-time continuum, trapped in the quantum vacuum state energy, waiting to be extracted via elementary interactions with particles such as a proton, electron, or vector boson such as the W and Z Bosons. Photons (light particles) do not interact with this field, and hence they do not have mass. If the Higgs Boson did not exist, matter particles would have no structure, all matter in the universe would form a cosmic soup that would expand with the rest of the universe at the speed of light. Such a simple idea that has such powerful consequences on reality arose from the brilliant mind of Professor Peter Higgs and was discovered by the particle's decay signal detected The Atlas and CMS detectors at CERN. The Mechanism of the interaction is simple to understand. Where the Electroweak Interaction couples to electric and weak (flavour) charges and the Strong Interaction couples to colour charge, the Higgs interaction couples to mass. The process by which the Higgs gives fermions mass is via the Yukawa potential, a kind of "Cosmic Voltage" that permeates spacetime. This potential gives the coupling strength of the Higgs to all types of fermions, the stronger the coupling, the more mass the particle will have. Hence the Higgs Boson couples more strongly to more massive particles; the massive energies (8 TeV) of the LHC were necessary <b>...</b>
9:11
Simulated Reality Hologram Matrix State Space
Introducing quantization directly on the spacetime level via Einstein-Maxwell gravitoelect...
published: 10 Jul 2010
Author: capnarness
Simulated Reality Hologram Matrix State Space
Introducing quantization directly on the spacetime level via Einstein-Maxwell gravitoelectromagnetic total spin-stress pressure energy (mass) density tensor Hilbert (4D ± 4Di) hologram interference field stationary state domain of universal wave function. S-matrix in-states/out-states eigenvalue range, features (moment of inertia x angular velocity) SO(1, 3)ij self-adjoint operator integrations, generating Dirac-Noether conserved angular momentum observables in material coordinates. Fundamental quantum continuum equation returns gravitoelectromagnetic spectrum photon SO(1, 3)yy principle spin axis eigenvalues in units of Maxwell stress tensor pascals. New origin of electron-positron wave-particle mass-charge via energization of SO(1, 3)zz principle spin axis angular momentum, invariant throughout inertial dynamics of electromagnetic and gravitational fields being inversely compressive/dispersive of cosmological constant vacuum energy density tensor pressure, according to principle quantum number n. Fourier inverse transform frequency domain basis, for time domain continuous creation (continuous automorphing) evolution operator spacetime events of the continuous now. In thought experiment test vs. general theory via pp-waves microlensing problem, wherein light-to-light gravitational attraction is four times matter-to-matter attraction, hypothesis predicts null microlensing result in area general theory known to break down on microscopic scale. MindPapers 8.3a <b>...</b>
2:07
Robotic dog Aibo from Slovakia is already prepared for euro :-)
Robotic dog Sony Aibo ERS7 is counting slovak banknotes and also converting the result val...
published: 29 Oct 2008
Author: tomasreiff
Robotic dog Aibo from Slovakia is already prepared for euro :-)
Robotic dog Sony Aibo ERS7 is counting slovak banknotes and also converting the result value to euro. You can find more information at brain.fei.tuke.sk
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