But now exclude all information from outside. Screen out all radiation from the heavens. Pull down the window shade. Then do whatever experiment we will on the movement and collision of particles and the action of electric and magnetic forces in whatever free-float frame we please. We find not the slightest difference in the fit to the laws of physics between measurements made in one free-float frame and those made in another. We arrive at the Principle of Relativity in its negative form:

No test of the laws of physics provides any way whatsoever to distinguish one free-float frame from another.

If the velocity of light is different for different observers, then the observer could tell whether he was at rest or in motion at some constant velocity, simply by determining the velocity of light in his frame of reference.  If the observed velocity of light c' were equal to c then the observer would be in the frame of reference that is at rest. If the observed velocity of light were c' = c − v, then the observer was in a frame of reference that was receding from the rest frame. Finally, if the observed velocity c' = c + v, then the observer would be in a frame of reference that was approaching the rest frame. Obviously these various values of c' would be a violation of the first postulate, since we could now define an absolute rest frame (c' = c), which would be different than all the other inertial frames.

I recommend: Taylor and Wheeler, _Spacetime_Physics_.

          Einstein’s Principle of Relativity says that once the laws of physics have been established in one free-float frame, they can be applied without modification in any other free-float frame. Both the mathematical form of the laws of physics and the numerical values of basic physical constants that these laws contain are the same in every free-float frame. So far as concerns the laws of physics, all free-float frames are equivalent.
          We can tell where we are on Earth by looking out of the window. Where we are in the Milky Way we can tell by the configuration of the Big Dipper and other constellations. How fast and in what direction we are going through the larger framework of the universe we measure with a set of microwave horns pointed to pick up the microwave radiation streaming through space from all sides. But now exclude all information from outside. Screen out all radiation from the heavens. Pull down the window shade. Then do whatever experiment we will on the movement and collision of particles and the action of electric and magnetic forces in whatever free-float frame we please. We find not the slightest difference in the fit to the laws of physics between measurements made in one free-float frame and those made in another. We arrive at the Principle of Relativity in its negative form:

No test of the laws of physics provides any way whatsoever to distinguish one free-float frame from another.

Notice what the Principle of Relativity does not say. It does not say that the time between two events is the same when measured from two different free-float frames.  Neither does it say that space separation between the two events is the same in the two frames. Ordinarily neither time nor space separations are the same in the two frames.

          Different values of some physical quantities between the two frames? Yes, but identical physical laws! For example, the relation between the force acting on a particle and the change in velocity per unit time of that particle follows the same law in the laboratory frame as in the rocket frame. The force is not the same in the two frames.  Neither is the change in velocity per unit time the same. But the law that relates force and change of velocity per unit time is the same in each of the two frames. All the laws of motion are the same in the one free-float frame as in the other.
          Not only the laws of motion but also the laws of electromagnetism and all other Laws of physics hold as true in one free-float frame as in any other such frame. This is what it means to say, "No test of the laws of physics provides any way whatsoever to distinguish one free-float frame from another."
          Deep in the laws of physics are numerical values of fundamental physical constants, such as the elementary charge on the electron and the speed of light. The values of these constants must be the same as measured in overlapping free-float frames in relative motion; otherwise these frames could be distinguished from one another and the Principle of Relativity violated.
          One basic physical constant appears in the law's of electromagnetism: the speed of light in a vacuum, c ~ 299,792,458 meters per second. According to the Principle of Relativity, this value must be the same in all free-float frames in uniform relative motion. Has observation checked this conclusion? Yes, many experiments demonstrate it daily and hourly in every particle-accelerating facility on Earth. Nevertheless, it has taken a long time for people to become accustomed to the apparently absurd idea that there can be one special speed, the speed of light, that has the same value measured in each of two overlapping free-float frames in relative motion.
          Values of the speed of light as measured by laboratory and by rocket observer turn out identical. This agreement has cast a new light on light. Its speed rates no longer as a constant of nature. Instead, today the speed of light ranks as mere conversion factor between the meter and the second, like the factor of conversion from the centimeter to the meter.

 For the observer standing on the ground, the two lightning bolts strike the front and back of the train at the same time. Therefore for him the distance between the char marks on the track constitutes a valid measure of the length of the train.  In contrast, the observer riding on the train measures the front lightning bolt to strike first, the rear bolt later. The rider on the train exclaims to her Earth-based colleague, “See here! Your front mark was made before the back mark — since the flash from the front reached me (at the middle of the train) before the flash from the back reached me. Of course the train moved during the time lapse between these two lightning strikes. By the time the stroke fell at the back of the train, the front of the train had moved well past the front char mark on the track. Therefore your measurement of the length of the train is too small. The train is really longer than you measured.”

 

Then every event which takes place along the line also takes place at a particular point of the train.

Today the meter is defined as the distance light travels in a vacuum in the fraction 1/299,792,458 of a cesium-defined second.

We were led to that conflict by the considerations of [Chapter] 6, which are now no longer tenable. In that section we concluded that the man in the carriage, who traverses the distance w per second relative to the carriage, traverses the same distance also with respect to the embankment in each second of time. But, according to the foregoing considerations, the time required by a particular occurrence with respect to the carriage must not be considered equal to the duration of the same occurrence as judged from the embankment (as reference-body). Hence it cannot be contended that the man in walking travels the distance w relative to the railway line in a time which is equal to one second as judged from the embankment.

The definition of a second does not change with frame, and _IS_ the same in every frame. "Time dilation" is NOT about "the length of a second varying" or a "clock tick rate varying" -- it is about the GEOMETRICAL PROJECTION involved in making the measurement.

     We are thus led also to a definition of "time" in physics. For this purpose we suppose that clocks of identical construction are placed at the points A, B and C of the railway line (co-ordinate system) and that they are set in such a manner that the positions of their pointers are simultaneously (in the above sense) the same. Under these conditions we understand by the " time " of an event the reading (position of the hands) of that one of these clocks which is in the immediate vicinity (in space) of the event. In this manner a time-value is associated with every event which is essentially capable of observation.
     This stipulation contains a further physical hypothesis, the validity of which will hardly be doubted without empirical evidence to the contrary. It has been assumed that all these clocks go at the same rate if they are of identical construction. Stated more exactly: When two clocks arranged at rest in different places of a reference-body are set in such a manner that a particular position of the pointers of the one clock is simultaneous (in the above sense) with the same position, of the pointers of the other clock, then identical "settings" are always simultaneous (in the sense of the above definition).    

We suppose further, that, when three events A, B and C occur in different places in such a manner that A is simultaneous with B and B is simultaneous with C (simultaneous in the sense of the above definition), then the criterion for the simultaneity of the pair of events A, C is also satisfied. This assumption is a physical hypothesis about the the of propagation of light: it must certainly be fulfilled if we are to maintain the law of the constancy of the velocity of light in vacuo.

YOU just don't read the experiments and understand HOW THEY WERE ACTUALLY  PERFORMED. NONE of them measure what you claim -- they do NOT compare clocks' tick rates, they compare one clock to SIGNALS from the other clock. 

By repeatedly ignoring ESSENTIAL aspects of these experiment you have confused yourself. The ENTIRE effect is in the SIGNALS AND HOW THEY ARE MEASURED, not in the clocks.

The other experiments ALL compare one clock to SIGNALS FROM ANOTHER CLOCK. And the physics PURELY AFFECTS THE SIGNALS AND HOW THEY ARE MEASURED, not the clocks. In EACH of these experiments, the clocks all tick at the same rate, but the MEASUREMENTS involve SIGNALS which affect the results.

 I repeat: to measure a clock's tick rate you MUST have the
        clock sitting right next to the measuring instrument. NONE
        of these experiments did that, they ALL used SIGNALS.

Yes, many of these authors wrote papers which were not careful to distinguish between "effects on the clocks" and the actual effects on the SIGNALS they used.  But SR and GR are quite clear on this (signals are affected, clocks are not);

If Einstein's constant-speed-of-light postulate is false, modern physics is pseudoscience (true science was killed in 1905).

Is Einstein's constant-speed-of-light postulate false? Of course, this is obvious. Consider the following setup:

A light source emits a series of pulses equally distanced from one another. A stationary observer (receiver) measures the frequency:

The observer starts moving with constant speed towards the light source and measures the frequency again:

Premise 1 (Doppler effect; experimentally confirmed): The moving observer measures the frequency to be higher.

Premise 2 (obviously true): The formula (measured frequency) = (speed of the pulses relative to the observer)/(distance between the pulses) is correct.

Conclusion: The speed of the pulses relative to the moving observer is higher than relative to the stationary observer. In other words, the speed of light varies with the speed of the observer, in violation of Einstein's relativity.

Pentcho Valev 

Is The Speed of Light Everywhere the Same?

The short answer is that it depends on who is doing the measuring: the speed of light is only guaranteed to have a value of 299,792,458 m/s in a vacuum when measured by someone situated right next to it.    

Manuscripts that question well-established physical principles are outside the purview of AJP and should be submitted to a more specialized journal for consideration.

"The Higgs Fake - How Particle Physicists Fooled the Nobel Committee" by Alexander Unzicker

"Bankrupting Physics: How Today's Top Scientists are Gambling Away Their Credibility" by Alexander Unzicker

"The Trouble With Physics: The Rise of String Theory, The Fall of a Science, and What Comes Next" by Lee Smolin

"Not Even Wrong: The Failure of String Theory and the Search for Unity in Physical Law for Unity in Physical Law" by Peter Woit

"Fashion, Faith, and Fantasy in the New Physics of the Universe" by Roger Penrose

"The Outer Limits of Reason: What Science, Mathematics, and Logic Cannot Tell Us"  by Noson S. Yanofsky

"A Beginner's Guide to Reality" by Jim Baggott

"Reality Is Not What It Seems: The Journey to Quantum Gravity" by Carlo Rovelli      

"On Space and Time" by Shahan Majid, Roger Penrose and others.

"The Road to Reality: A Complete Guide to the Laws of the Universe" by Roger Penrose

"Time Reborn: From the Crisis in Physics to the Future of the Universe" by Lee Smolin

"The Singular Universe and the Reality of Time" by Roberto Mangabeira Unger and Lee Smolin

"Origins: The Scientific Story of Creation" by Jim Baggott

Since quantum theory was first proposed, a debate has raged between those who accept this way of doing science and those who reject it.  Many of the founders of quantum mechanics, including Einstein, Erwin Shrödinger, and Louis de Broglie, found this approach to to physics repugnant.  They were realists.  For them quantum theory, no matter how well it worked, was not a complete theory, because it did not provide a picture of reality absent our interaction with it.  On the other side were Neils Bohr, Werner Heisenberg, and many others.  Rather than being appalled, they embraced this new way of doing science.

This whole issue goes under the name the foundational problems of quantum mechanics.  It is the second great problem of contemporary physics.

Problem 2: Resolve the problems in the foundations of quantum mechanics, either by making sense of the theory as it stands or by inventing a new theory that does make sense.

There are unfortunately not many physicists who work on this problem.  This is sometimes taken as an indication that the problem is either solved or unimportant.  Neither is true.  This is probably the most serious problem facing modern science.

While completing my German manuscript, I discovered Sheilla Jones’s The Quantum Ten, an excellent history of quantum mechanics. What really impressed me was how persuasively she explained the way modern theoretical physics has gone astray since the late 1920s.

At this point, it’s worth adding some clarity to the terms physicists use to talk about quantum science. They often treat the phrases “quantum mechanics,” “quantum theory” and “quantum physics” as if they were interchangeable, which they are not. Throughout this book, “quantum mechanics” is defined as the set of rules for how the physics and mathematics are used to make testable predictions; these rules have been used to unparalleled fruitfulness since their development in the 1920s. “Quantum theory” is defined as the explanation for why the quantum world behaves the way it does; this exercise is still fraught with controversy. “Quantum physics” is the whole package—the mechanics and the theory.

the editors had to conclude that this work is not suitable for publication in Foundations of Physics.

This question leads to a quite definite positive answer, and to a perfectly definite transformation law for the space-time magnitudes of an event when changing over from one body of reference to another.

Diese Frage führt zu einer bejahenden, ganz bestimmten Antwort, zu einem ganz bestimmten Verwandlungsgesetz für die Raum-Zeit-Größen eines Ereignisses beim Ubergang von einem Bezugskörper zu einem anderen.

The present book is intended, as far as possible, to give an exact insight into the theory of Relativity to those readers who, from a general scientific and philosophical point of view, are interested in the theory, but who are not conversant with the mathematical apparatus of theoretical physics.  The work presumes a standard of education corresponding to that of a university matriculation examination, and, despite the shortness of the book, a fair amount of patience and force of will on the part of the reader.

the yearly movement of the apparent position of the fixed stars resulting from the motion of the earth round the sun (aberration), and to the influence of the radial components of the relative motions of the fixed stars with respect to the earth on the colour of the light reaching us from them. The latter effect manifests itself in a slight displacement of the spectral lines of the light transmitted to us from a fixed star, as compared with the position of the same spectral lines when they are produced by a terrestrial source of light (Doppler principle).

the branch of science concerned with the nature and properties of matter and energy. The subject matter of physics, distinguished from that of chemistry and biology, includes mechanics, heat, light and other radiation, sound, electricity, magnetism, and the structure of atoms.

Light travelling towards a gravitating object will be blueshifted as the effects of gravity grow stronger.

In an elevator that is rapidly accelerating upwards, a beam of light emitted from one side of the elevator would strike the other side slightly lower down, because in the time it takes for the light to travel from one side to the other, the elevator has moved upwards.

The author wrote a lot of things with which I would tend to agree, but he also says a few things with which I do not fully agree.  And sometimes we are in total disagreement.      

When we deal with physics, we must ask: Do rules other than the ones imposed by mathematical logic exist? Yes, there are in physics some elements that do not exist in mathematics. Physics deals with concepts such as mass, length, time and energy. These concepts correspond in our mind to images different from the ones represented by mathematical relations. They have a different representation in our mind because they must be submitted to external tests. They have to comply with observational results. There is no equivalence in mathematics. A mathematical demonstration never implies any experimentation. Mathematics simply deals with the calculation of relations between those concepts.

Mathematics allows the calculation of things that cannot exist. Here are some examples. Physically, it does not make sense to consider negative or imaginary masses although mathematics can calculate them.

We also try to find a cause for any physical phenomenon. However, the physical cause of the phenomenon is irrelevant in mathematics.

Me:  If A = B, then B = A.  In REAL LIFE, things are NOT reciprocal. There is CAUSE AND EFFECT.  

Other guy: Cause and effect have nothing to do with relativity, so this is non sequitur.

Me: Cause and effect are WHAT RELATIVITY IS ALL ABOUT.  We have different views of WHEN things happen, and the CAUSE of those different views is TIME DILATION.

The contradictions found in modern science are so absurd that most physicists assume that somebody must certainly have solved them long ago. The degree of indifference of most physicists about these contradictions is phenomenal.

"Causality is the basis of all scientific work. Causality is the condition that renders science possible."

     During their undergraduate studies, physicists are gradually taught to accept interpretations that appear more and more surprising (absurd). They are misled by the fact that the equations used in physics lead to predictions that are compatible with observations. Physicists are taught to believe that when an equation gives a correct prediction, it proves that the model is correct (even if the model is absurd). Furthermore, they claim that, since the working model is absurd, one must conclude that Nature is absurd.
     The philosophy of science and the lack of causality are subjects almost completely avoided in classrooms where physics is taught.

Einstein's relativity assumes new mathematical hypotheses and ignores completely the concept of models to describe physical reality. Einstein supposed that time and space can be distorted and that simultaneity is relative but he did not give any serious description of what this really means physically. In Newton's time, physical descriptions of phenomena were accompanied by mathematical equations giving quantitative predictions corresponding to those physical descriptions. Einstein's relativity claims that nature can be described with mathematical equations without any physical description. There is a complete abandon of all the physical models that made physics understandable in Newton's time.

      There is as yet no observational or experimental evidence for many of the concepts of contemporary theoretical physics, such as super-symmetric particles, superstrings, the multiverse, the universe as information, the holographic principle or the anthropic cosmological principle. For some of the wilder speculations of the theorists there can by definition never be any such evidence.
      This stuff is not only not true, it is not even science. I call it ‘fairytale physics’. It is arguably borderline confidence-trickery. 

To repeat one last time, reality is a metaphysical concept — it lies beyond the grasp of science. When we adopt specific beliefs about reality, what we are actually doing is adopting a specific philosophical position.

When we invoke entities that we can’t directly perceive, such as photons or electrons, we learn to appreciate that we can’t know anything of these entities as things-in-themselves. We may nevertheless choose to assume that they exist.

In 2009, Britain’s Science Council announced that after a year of deliberations, it had come up with a definition of science, perhaps the first such definition ever published: "Science is the pursuit of knowledge and understanding of the natural and social world following a systematic methodology based on evidence." 

What amazes me is that I can find very few people who are also arguing to have the mathematicians stop teaching nonsense.

if you intend to submit, or have submitted, your article to a journal then you should verify that the license you select during arXiv submission does not conflict with the journal's license or copyright transfer agreement.

It ain't what you don't know that gets you into trouble.  It's what you know for sure that just ain't so.   

Einstein argued in his theory of special relativity that space and time constituted one four-dimensional reality, spacetime. He postulated that the speed of light was constant (300,000 kilometers per second). Even if a person were approaching you on a superfast train going at 50 percent of the speed of light (150,000 kilometers per second), shining a headlight in your face, you and he would come up with the same figure for the speed of light. This is very nonintuitive, as you would think that since the train is approaching you, you who are observing the light aimed at you would have to add 300,000 and 150,000, which would lead to 450,000 kilometers per second. But that is not the case — according to Einstein, 300,000 plus 150,000 is still 300,000!

One famous test was made by Russian astronomers in 1955, using light from opposite sides of the rotating sun.  One edge of our sun is always moving toward us, the other edge always moving away.  It was found that light from both edges travels to the earth with the same velocity.

I STILL don't see anything from MIT about it? How do you account for that?

I assume MIT teaches what everyone else teaches, because they don't know any better.

2. The speed of light is the same in all frames of reference.

Postulate 2: The speed of light in empty space always has the same value c.

2. The speed of light is the same for “everybody.” 

2. Doppler Shift of Electromagnetic Radiation:

Electromagnetic radiation travels at the speed of light, c, in vacuum. If a source of light has a velocity component towards you, the frequencies that you will observe will be higher than those of the emitted radiation, and the received wavelengths will be shorter (blue-shift) than the emitted wavelengths. If the source is receding from you the received wavelength is longer (red-shift).

I now want to change to electromagnetic waves.  Electromagnetic waves travel with the speed of light, which is 300,000 kilometers per second.  And if you want to treat that correctly, you would have to use Special Relativity.  In the case of sound, I stressed repeatedly that you in the audience should not move, but that the sound source is moving.  In the case of electromagnetic radiation, when you deal with the speed of light, you don't have to ask that question.  It is a meaningless question in relativity to ask whether you are moving relative to me or whether I am moving relative to you, it doesn't matter.  All that matters in Special Relativity is the relative motion.  So, you can always think of yourself as standing still and make the source of electromagnetic radiation move to you or away from you, relative to you.

In astronomy, in optical astronomy, we cannot measure the period or the frequency of optical light.  All we can measure is the wavelength.

if we do not hear from you by May 25, we will withdraw your paper from publication in [our journal].

Following the instructions contained in your e-mail of 20 May 2017, I would like to inform you that the above paper has been withdrawn from publication in [our journal].

12:04 p.m.           Bilbao, Spain  
12:38 p.m.           Bayern, Germany     
1:11 p.m.             Palo Alto, CA       
2:32 p.m.             Denver, CO    
2:33 p.m.             Grimstad, Norway    
3:30 p.m.             Naperville, IL      
4:21 p.m.             Richmond, BC, Canada
4:42 p.m.             Dayton, OH          
8:35 p.m.             Montreal, Canada    
10:19 p.m.           Toronto, Ontario    

  

So, I'm just going to continue revising my paper on Einstein's Second Postulate to include illustrations.  It isn't just a matter of plunking in some illustrations.  The illustrations need to be explained, and that results in changing the way a lot of other things are explained.  In some ways, "a picture is worth a thousand words," but in other ways a picture can provide a different way of looking at things, which can generate an additional thousand words of clarification.

I also found that I needed to really understand how an interferometer works.   I need to understand it well enough to explain in a few words what takes pages of explanation elsewhere.  But, it is all very interesting, and I have no deadlines, so I can study things at my leisure.

If it is deemed suitable for our journal, it will be sent for peer review and we will endeavour to send you a first decision within three months

If your manuscript is not considered suitable for our journal (to be decided by the editorial board), we will let you know as soon as possible.

I have looked at this paper. I can predict that no reputable peer-reviewed physics journal will publish it, because it makes so many very basic errors, and its basic approach is just plain wrong -- he attempts to distinguish what he thinks is an "emitter only theory" from what is taught in many classes; the error is LAKE'S, and Einstein's ACTUAL theory is not at all "emitter only" (quite the opposite, because he EXPLICITLY shows that the (vacuum) speed of
light is c in EVERY inertial frame, not just that of the emitter).

As I have said before, Ed Lake cannot read, and this paper displays that repeatedly. I'll only point out a few places where it is just plain wrong, and in direct conflict with Einstein's 1905 paper.

Lake titles section II "Einstein's Emitter Only Theory", but that is a
falsehood, and this "emitter only theory" is PURE FABRICATION on the part of Ed Lake, Einstein had NOTHING TO DO WITH IT.

To start with, Lake uses the WRONG STATEMENT of Einstein's postulates -- he used Einstein's INTRODUCTION to them, not the actual statements (which are in section I.2). Lake claims "Einstein said nothing about what any other observer might see or measure." which is true for the introduction, but BLATANTLY FALSE for the
paper itself -- Lake OBVIOUSLY did not read Einstein's paper.

For instance, in Section I.3 Einstein says "We now have to prove that any ray of light, measured in the moving system, is propagated with the velocity c", and then does so by considering a spherical wave in the "stationary system", concluding "The wave under consideration is therefore no less a spherical wave with velocity of propagation c when viewed in the moving system."

Lake claims "The emitting body’s velocity (referred to as v) cannot be added to the speed of light being emitted, since c + v would produce a speed greater than the maximum that light can travel." -- he OBVIOUSLY did not read Einstein's paper, as in section I.5 Einstein derives the equation for the composition of velocities, and says "the velocity of light c cannot be altered by composition with a velocity less than that of light". So the emitting body's velocity is NOT "added to the speed of light being emitted", it is COMPOSED as Einstein showed, and the result of the composition is c.

Lake claims "an observer approaching the source of light will measure the light to arrive at c + v, where v is his velocity, and if the observer is moving away from the source of the light, he will measure the light to arrive at c – v" -- this is ENTIRELY DUE TO LAKE, and is INCONSISTENT with what Einstein said in his paper: Einstein showed that the (vacuum) speed of light is c relative to both his "stationary system" and his "moving system", and since these are both
arbitrary, relative to ANY inertial system.

Lake completely missed the basic point of Einstein's paper, and claims:

When Einstein wrote that the Second Postulate “is only apparently irreconcilable with” the First Postulate, he seems to have been referring to the fact that while the observer standing next to the emitter measures light he emits as moving at a speed that is independent of his own speed, that fact does not necessarily apply to light he may measure coming from another source outside of his frame of reference.

This is completely wrong, and Lake is just fantasizing, not reading Einstein's paper. Einstein was discussing the APPARENT inconsistency between his two postulates: until this paper people assumed the PoR required Galilean invariance, and that is indeed inconsistent with Einstein's second postulate -- the paper shows that there is no inconsistency when one uses Lorentz invariance.  Einstein showed the OPPOSITE of Lake's claim: that an observer will measure the (vacuum) speed of light to be c, regardless of whether it is emitted by a source at rest in the observer's frame, or moving relative to it. Indeed this is the statement of Einstein's second postulate, which Lake has OBVIOUSLY NEVER READ:

   2. Any ray of light moves in the “stationary” system of coordinates
      with the determined velocity c, whether the ray be emitted by a
      stationary or by a moving body.

As Lake is so profoundly confused, I'll spell it out: consider the observer's frame  to be the "stationary system". This second postulate then says the observer will measure light to propagate at c in his frame, even when the source of the light is not at rest in his frame. So it DOES apply "to light he may measure coming from another source outside of his frame of reference".

Lake's paper is hopeless. He needs to learn how to read, and then needs to actually READ and LEARN about the subject before attempting to write about it.