a fundamental, primary, or general law or truth from which others are derived:the principles of modern physics.

Smolin and Unger believe this crisis is real — and it's acute. They pull no punches in their sense that the lack of empirical data has led the field astray. As they put it:

    "Science is corrupted when it abandons the discipline of empirical validation or dis-confirmation. It is also weakened when it mistakes its assumptions for facts and its ready-made philosophy for the way things are."

Thus, the goal of The Singular Universe and The Reality of Time is to take a giant philosophical step back and see if a new and more promising direction can be found. For the two thinkers, such a new direction can be spelled out in three bold claims about the world.

1. There is only one universe.
2. Time is real.
3. Mathematics is selectively real.

1.  The "visible universe" is just part of "the Big Bang Universe."
2.  Time and Time Dilation are real.
3.  Mathematics is just a tool, not holy writ.

"One of the towering great achievements of the human mind in our understanding of the universe is Einstein's theories of relativity. It makes only two assumptions: That the speed of light in a vacuum is constant no matter who is doing the measurement and no matter in what direction you are moving or how fast. You always get the same measurement for the speed of light. That's Assumption 1 which by the way the experiment has shown to be true. Assumption 2: The laws of physics are the same for all observers in uniform motion relative to one another. Those are the only two tenets that you have to buy into."

To continue our discussion of the Lorentz transformation and relativistic effects, we consider a famous so-called “paradox” of Peter and Paul, who are supposed to be twins, born at the same time. When they are old enough to drive a space ship, Paul flies away at very high speed. Because Peter, who is left on the ground, sees Paul going so fast, all of Paul’s clocks appear to go slower, his heart beats go slower, his thoughts go slower, everything goes slower, from Peter’s point of view. Of course, Paul notices nothing unusual, but if he travels around and about for a while and then comes back, he will be younger than Peter, the man on the ground! That is actually right; it is one of the consequences of the theory of relativity which has been clearly demonstrated. Just as the mu-mesons last longer when they are moving, so also will Paul last longer when he is moving. This is called a “paradox” only by the people who believe that the principle of relativity means that all motion is relative; they say, “Heh, heh, heh, from the point of view of Paul, can’t we say that Peter was moving and should therefore appear to age more slowly? By symmetry, the only possible result is that both should be the same age when they meet.” But in order for them to come back together and make the comparison, Paul must either stop at the end of the trip and make a comparison of clocks or, more simply, he has to come back, and the one who comes back must be the man who was moving, and he knows this, because he had to turn around. When he turned around, all kinds of unusual things happened in his space ship—the rockets went off, things jammed up against one wall, and so on—while Peter felt nothing.

So the way to state the rule is to say that the man who has felt the accelerations, who has seen things fall against the walls, and so on, is the one who would be the younger; that is the difference between them in an “absolute” sense, and it is certainly correct.

#1. University Physics with Modern Physics by Young, Freedman & Lewis Ford

#2.  Physics for Scientists and Engineers with Modern Physics by Douglas C. Giancoli

#3. Fundamentals of Physics by David Halliday, Robert Resnick and Jearl Walker

#4. Physics for Scientists and Engineers: A Strategic Approach by Randall D. Knight 

#5. The Feynman Lectures on Physics by Richard Feynman

Einstein's first postulate, called the principle of relativity, states: The laws of physics are the same in every inertial frame of reference.  If the laws differed, the difference would distinguish one inertial frame from the others or make one frame somehow more "correct" than another.   

Einstein's second postulate states: The speed of light in a vacuum is the same in all inertial frames of reference and is independent of the motion of the source.

This result contradicts our elementary notion of relative velocities, and it may not appear to agree with common sense.  But "common sense" is intuition based on everyday experience, and this does not usually include measurements of the speed of light.

First postulate (the relativity principle): The laws of physics have the same form in all inertial reference frames.

The first postulate can also be stated as: There is no experiment you can do in an inertial reference frame to tell if you are at rest or moving uniformly at constant velocity.

The second postulate is consistent with the first:

Second postulate (constancy of the speed of light): Light propagates through empty space with a definite speed c independent of the speed of the source or observer.

These two postulates form the foundation of Einstein’s special theory of relativity. It is called “special” to distinguish it from his later “general theory of relativity,” which deals with noninertial (accelerating) reference frames (Chapter 44). The special theory, which is what we discuss here, deals only with inertial frames.

The second postulate may seem hard to accept, for it seems to violate common sense. First of all, we have to think of light traveling through empty space. Giving up the ether is not too hard, however, since it had never been detected. But the second postulate also tells us that the speed of light in vacuum is always the same, 3.00 X 10⁸m/s, no matter what the speed of the observer or the source. Thus, a person traveling toward or away from a source of light will measure the same speed for that light as someone at rest with respect to the source. This conflicts with our everyday experience: we would expect to have to add in the velocity of the observer. On the other hand, perhaps we can’t expect our everyday experience to be helpful when dealing with the high velocity of light.

All experimenters, regardless of how they move with respect to each other, find that all light waves, regardless of the source, travel in their
reference frame with the same speed c.  If Cathy's velocity toward Bill and away from Amy is v = 0.9c, Cathy finds, by making measurements in her reference frame, that the light from Bill approaches her at speed c, not at c + v = 1.9c.  And the light from Amy, which left Amy at speed c, catches up from behind at c relative to Cathy, not the c - v = 0.1c you would have expected.

Although this prediction goes against all shreds of common sense, the experimental evidence for it is strong.  Laboratory experiments are difficult because even the highest laboratory speed is insignificant in comparison to c.

1. The principle of relativity: The laws of physics must be the same in all inertial reference frames.

2. The constancy of the speed of light: The speed of light in vacuum has the same value, c = 3.00 X 10⁸ m/s, in all inertial frames, regardless of the velocity of the observer or the velocity of the source emitting the light. 

The first postulate asserts that all the laws of physics—those dealing with mechanics, electricity and magnetism, optics, thermodynamics, and so on — are the same in all reference frames moving with constant velocity relative to one another. This postulate is a sweeping generalization of the principle of Galilean relativity, which refers only to the laws of mechanics. From an experimental point of view, Einstein’s principle of relativity means that any kind of experiment (measuring the speed of light, for example) performed in a laboratory at rest must give the same result when performed in a laboratory moving at a constant velocity past the first one. Hence, no preferred inertial reference frame exists, and it is impossible to detect absolute motion.

2. The Speed of Light Postulate: The speed of light in vacuum has the same value c in all directions and in all inertial reference frames.

We can also phrase this postulate to say that there is in nature an ultimate speed c, the same in all directions and in all inertial reference frames. Light happens to travel at this ultimate speed.

While it does the job overall, I found another tool to be a far better alternative. I thought other users might also appreciate it if you update your page. 

The speed of light in a vacuum has the same value, c = 2.997 924 58 x 108 m/s, in all inertial reference frames, regardless of the velocity of the observer or the velocity of the source emitting the light.

Second postulate: The speed of light is a constant and will be the same for all observers independent of their motion relative to the light source.

Light is always propagated in empty space with a definite velocity c which is independent of the state of motion of the emitting body. 

If at the point A of space there is a clock, an observer at A can determine the time values of events in the immediate proximity of A by finding the positions of the hands which are simultaneous with these events. If there is at the point B of space another clock in all respects resembling the one at A, it is possible for an observer at B to determine the time values of events in the immediate neighbourhood of B. But it is not possible without further assumption to compare, in respect of time, an event at A with an event at B. We have so far defined only an “A time” and a “B time.” We have not defined a common “time” for A and B, for the latter cannot be defined at all unless we establish by definition that the “time” required by light to travel from A to B equals the “time” it requires to travel from B to A.

We assume that this definition of synchronism is free from contradictions, and possible for any number of points; and that the following relations are universally valid:—

1. If the clock at B synchronizes with the clock at A, the clock at A synchronizes with the clock at B.

2. If the clock at A synchronizes with the clock at B and also with the clock at C, the clocks at B and C also synchronize with each other.

Thus with the help of certain imaginary physical experiments we have settled what is to be understood by synchronous stationary clocks located at different places, and have evidently obtained a definition of “simultaneous,” or “synchronous,” and of “time.” The “time” of an event is that which is given simultaneously with the event by a stationary clock located at the place of the event, this clock being synchronous, and indeed synchronous for all time determinations, with a specified stationary clock.

A---------->----------B  
Equals
A----------<----------B

A---------->----------B

A-A2------<----------B

   A2-A----------<----------B

Let us consider the case of two [coordinate systems] starting from a known position and moving uniformly, one relative to the other, with a known velocity. One who prefers concrete pictures can safely think of a ship or a train moving relative to the earth. The laws of mechanics can be confirmed experimentally with the same degree of accuracy, on the earth or in a train or on a ship moving uniformly. But some difficulty arises if the observers of two systems begin to discuss observations of the same event from the point of view of their different [coordinate sytems]. Each would like to translate the other’s observations into his own language.

Our new assumptions are:

(1) The velocity of light in vacuo is the same in all [coordinate systems] moving uniformly, relative to each other.

(2) All laws of nature are the same in all [coordinate systems]  moving uniformly, relative to each other.

The relativity theory begins with these two assumptions.

Einstein A. and Infeld L.: The Evolution of Physics (Simon and Schuster New York)

The scenario
. Let's have two clocks which are synchronized according to Einstein's procedure in each of two inertial frames of reference.
. Let the clocks be a proper distance d from each other in their respective frames.
. Let the frames move with the relative speed v.

Regarding the time, since is fix, compartment and vacuumed, twin paradox show that both brothers has the same age after on of them is going into space. It must be taken in advance that the time is absolute, compartmented and also every each planet has its own spaces: atmospehric and extraatmospheric. First of all, we must define what does mean „outer” and then we can understand the time in and out of planet.   

"About 15 billion years ago a tremendous explosion started the expansion of the universe. This explosion is known as the Big Bang. At the point of this event all of the matter and energy of space was contained at ONE POINT."

Source: http://umich.edu/~gs265/bigbang.htm

"In 1927, an astronomer named Georges Lemaître had a big idea. He said that a very long time ago, the universe started as just a SINGLE POINT. He said the universe stretched and expanded to get as big as it is now, and that it could keep on stretching."

Source: https://spaceplace.nasa.gov/big-bang/en/

"Although space may have been concentrated into a SINGLE POINT at the Big Bang, it is equally possible that space was infinite at the Big Bang. In both scenarios the space was completely filled with matter which began to expand."

Source: "http://www.atlasoftheuniverse.com/bigbang.html

"The most important concept to get across when talking about the big bang is expansion. Many people think that the big bang is about a moment in which all the matter and energy in the universe was concentrated in a tiny POINT. Then this POINT exploded, shooting matter across space, and the universe was born. In fact, the big bang explains the expansion of space itself, which in turn means everything contained within space is spreading apart from everything else."

Source: http://science.howstuffworks.com/dictionary/astronomy-terms/big-bang-theory1.htm

"The big bang theory describes the creation of everything in the universe. According to this theory, all the matter in the universe came into existence at the same time during an event known as the big bang, which happened about 13.7 billion years ago.

"At that time, all matter was compacted into a SINGLE POINT with infinite density and intense heat called a singularity."

Source: http://why-sci.com/big-bang/

The Big Bang did not happen at a point. Instead it happened everywhere in the universe at the same time. Consequences of this include:

The universe doesn't have a centre: the Big Bang didn't happen at a point so there is no central point in the universe that it is expanding from.

The universe didn't shrink down to a point at the Big Bang, it's just that the spacing between any two randomly selected spacetime points shrank down to zero. 

Each car is at rest in an inertial coordinate system, which is a system of space and time coordinates in terms of which Newton's equations of motion are valid in the low speed limit.  Knowing that the speed of a pulse of light is c in terms of one system of inertial coordinates (say, the system in which the police car is at rest), what is the speed of that pulse in terms of another system of inertial coordinates (say, the system in which the target car is at rest)?

The answer depends on how inertial coordinate systems are related to each other.  If energy did not have inertia, then they would be related by a Galilean transformation, and the speed in the target system would be c+v, but energy actually DOES have inertia (E = mc^2), so inertial coordinates are related by Lorentz transformations, and hence the speed is c in terms of every system of inertial coordinates.  

E-A-B--------------------------M

E---------------------------M---Z

How weird is the invariance of the speed of light? Is the principle of Special Relativity really counter-intuitive?

The red dashes in front of the flying saucer are the photons from the saucer's headlights.  They travel slightly faster than the saucer as the saucer moves toward the observer.  As I see it, there is nothing really "counter-intuitive" about what is going on in the illustration.  Once you understand that the emitter (the flying saucer) cannot cause light to travel faster than c (the maximum speed of light), everything is pretty straightforward.

Under the illustration is this (sort of) answer to the questions asked:

It depends on how one expresses it, and to whose intuition one appeals. For example, it does seem counter-intuitive that the speed of light does not depend on the motion of the observer. In our animation, Zoe turns on the headlights of her space ship. She measures the speed of light from her headlights as c with respect to her. Jasper sees her travelling towards him at (let's say) v. He measures the speed of light from her headlights as c. No, not c+v, but just c. Surely this is counter-intuitive? Maybe even crazy? Surely relative speeds add up?

I highlighted in red the passage that bothered me.  Jasper (the observer) is not moving.  Einstein stated that the speed of light does not depend upon the motion of the emitter.  Why mention the observer?  Zoe's ship is moving, and since the ship is the emitter of the light, the light travels away from Zoe slower than it approaches Jasper.  I agreed with virtually everything on the page except that one clause.

At the end of the web page, it says this:

How can Jasper and Zoe's 'speedometers' both get the same value of the speed of light? Just looking at it, I can see that the red dot is approaching Jasper faster than it is leaving Zoe. How do they get the same answer? 

The answer is time dilation. We are looking at this animation from Jasper's frame of reference and, according to Jasper, time runs slowly for Zoe. Zoe's clocks, including the timing mechanism of her 'speedometer', run slowly. So Zoe records the same value for the speed of light.

That's right.  I fully agree!  But Jasper is standing still.  Of course, we all know he is really moving around the earth as it spins on its axis, and he is moving around the sun as the earth moves in its orbit, but relative to the flying saucer he is virtually standing still.  Any movement due to the earth's movement is irrelevant.  So, why complicate the problem by suggesting he's moving? 

I decided to ask the people who run the web site.  I sent them an email suggesting it was a mistake to have Jasper as a "moving observer," and I received the following reply:

Thanks for writing, Ed.
No mistake.
I’m busy. End of correspondance.

That's the same answer I get from local college physics professors -- if they respond at all, most don't.

And discussions on Google's forum just end up with opinions and personal attacks.  Here's one response I got when I told them I was fed up:

I guess that, as usual, every wise person here will try to make you realize that you're wrong on the basics, and that you will stubbornly persist in your incompetence, ignorance and arrogance.

Yes, I will stubbornly persist until I can find someone who can explain to me where I am wrong, or until I figure out for myself that I'm wrong.  Or maybe I'll somehow convince others that I'm right.  Until then, I'll be getting back to working scientific papers, instead of arguing with people who cannot explain anything and can do nothing other state opinions and launch personal attacks.

     “Right. So if we go really fast on the walk, my clock goes all slow, and when we get back, I’ll be younger than the puppy.”
     “Well, no. For one thing, the effect only works on clocks that are moving relative to you. You would see a light clock at the house ticking slow, but SteelyKid would see your clock running slow.”
     “Yeah, but she’s just a puppy and is easily fooled. My clock is the one that’s really moving.”
     “No, she’d be right. As long as you’re moving relative to her, any measurement she makes will show your clock running slow, and any measurement you do will show her clock running slow. There is no absolute frame of reference, just relative motion.”
     “Wait, we each see the other’s clock running slow?”
     “As long as you’re moving at constant speed relative to one another, yes. And you’re both right.”
     “So how do we decide which of us is younger?”
     “Well, in a real experiment, the process of speeding up and slowing down makes your frame of reference distinguishable from hers, so if you take off from the house, accelerate up to very fast speed, then decelerate and return to the house, your clock will end up showing less elapsed time than hers, but—”
     “I knew it! Let’s go, so I can be younger than the puppy!”
     “But, ‘fast’ in this context means ‘at a speed comparable to the speed of light.’ Even at our current—exceedingly brisk—walking pace, we’re not going more than a few meters per second. Which means you would need to walk for a billion years to gain one second on SteelyKid.”
     Emmy stops dead. “A billion years?”
     “A billion years.”
     “That’s a long time.” She thinks for a minute. “I’m good with that. I like long walks.” She takes off again and just about pulls me off balance.

Person-A:  Einstein's Second Postulate is not what you claim it to be.
Person-B: Yes, it is.
Person-A. No, it is not.
Person-B: Yes, it is.
Person-A. No, it is not.
Person-B: Yes, it is.
Person-A: No it is not.

I present facts and evidence supporting a theory.
Person-B: That means nothing.
I present more facts and evidence.
Person-B: That means nothing.
I present still more facts and evidence.
Person-B: That means nothing.
I ask WHY it means nothing.
Person-B: You are just too stupid to understand.

     I used to believe in the essential unreality of time. Indeed, I went into physics because as an adolescent I yearned to exchange the timebound, human world, which I saw as ugly and inhospitable, for a world of pure, timeless truth. Later in life, I discovered that it was pretty nice to be human and the need for transcendent escape faded.
     More to the point, I no longer believe that time is unreal. In fact, I have swung to the opposite view: Not only is time real, but nothing we know or experience gets closer to the heart of nature than the reality of time.

Scientists think in time when we conceive of our task as the invention of novel ideas to describe newly discovered phenomena, and of novel mathematical structures to express them. If we think outside time, we believe these ideas somehow existed before we invented them. If we think in time, we see no reason to presume that.

To rebel against the precariousness of life, to reject uncertainty, to adopt a zero tolerance to risk, to imagine that life can be organized to completely eliminate danger, is to think outside time.  

As we move on to more sophisticated subjects, readers are advised, if confused, to do what scientists learn to do, which is to skim or skip ahead to a point where the text becomes clearer to them.

Should we simply recognize mathematics for the religious activity it is? Or should we be concerned when the most rational of our thinkers, the mathematicians, speak of what they do as if it were the route to transcendence from the bounds of human life?

Mathematics, then, entered science as an expression of a belief in the timeless perfection of the heavens. Useful as mathematics has turned out to be, the postulation of timeless mathematical laws is never completely innocent, for it always carries a trace of the metaphysical fantasy of transcendence from our earthly world to one of perfect forms.

     In my view, the best way to explain quantum mechanics is to start by talking about what science is for. Many of us think the purpose of science is to describe how nature really is — to give a picture of the world that we can believe would be true, even were we not here to see it. If you think of science that way, you’ll be disappointed by quantum mechanics, because it gives no picture of what is going on in an individual experiment.
     Niels Bohr, one of the founders of quantum theory, argued that those who were disappointed in this way had the wrong idea of what science is for. The problem is not the theory but what we expect a theory to do for us. Bohr proclaimed that the purpose of a scientific theory is not to describe nature but to give us rules for manipulating objects in the world and a language we can use to communicate the results.

The theory in which laws evolve is called cosmological natural selection, which I developed in the late 1980s and published in 1992. In that paper, I made a few predictions, which could have been falsified in the two decades since but have not been. This of course doesn’t prove the theory is correct, but at least I showed that a theory of evolving laws can explain and predict real features of our world.

The basic hypothesis of cosmological natural selection is that universes reproduce by the creation of new universes inside black holes. Our universe is thus a descendant of another universe, born in one of its black holes, and every black hole in our universe is the seed of a new universe. This is a scenario within which we can apply the principles of natural selection.

The fitness of a universe is then a measure of how many black holes it spawns.

Newly-discovered satellite photos may have given scientists a fresh clue as to the location of Malaysian Airlines 370, one of the world's most famous aviation mysteries.

The four satellite photos, shot less than a month after MH370 disappeared in 2014, show 70 objects drifting on the ocean in the vicinity of the predicted crash zone, the Australian Transport Safety Bureau (ATSB) said Wednesday.

For many years after Newton, partial reflection by two surfaces was happily explained by a theory of waves, but when experiments were made with very weak light hitting photomultipliers, the wave theory collapsed: as the light got dimmer and dimmer, the photomultipliers kept making full-sized clicks—there were just fewer of them. Light behaved as particles.

The first important feature about light is that it appears to be particles: when very weak monochromatic light (light of one color) hits a detector, the detector makes equally loud clicks less and less often as the light gets dimmer.

I used to believe in the essential unreality of time. Indeed, I went into physics because as an adolescent I yearned to exchange the time- bound, human world, which I saw as ugly and inhospitable, for a world of pure, timeless truth. Later in life, I discovered that it was pretty nice to be human and the need for transcendent escape faded. More to the point, I no longer believe that time is unreal. In fact, I have swung to the opposite view: Not only is time real, but nothing we know or experience gets closer to the heart of nature than the reality of time.

Nature – 1 day. Rejected.

Science – 3 days. Rejected.

Physics Essays – 5½ months.  Withdrawn on May 20, 2017

Journal 4 – 25 days. Rejected.

Journal 5 – 1 day.  Rejected.

Journal 6 – 3 days.  Rejected.

Journal 7 – 2 days.  Rejected.

Journal 8 – Submitted on August 2, 2017.

Another way of stating Einstein’s postulate is that There is no experiment we can perform to tell us which inertial frame is moving and which is at rest. There is no ‘preferred’ inertial frame. All we can
talk about is the relative motion of two inertial frames.

The significance of this result is that the time interval measured in the frame in which the clock is moving is greater than that measured in the frame in which the clock is at rest. Suppose we have two identical clocks. If we keep one at rest (with respect to us) and let the other one move, the moving clock appears to run slow. It is important to realize that the situation is perfectly symmetric. If there is an observer traveling with each clock, each observer sees the other clock running slow. This effect is called time dilation.

Magueijo was scathing about string theory, describing it as ‘like intellectual masturbation.’ He doesn’t like string theory for sociological reasons, his main objection being that it is completely disconnected from experiment, making it hard, or impossible, to confirm or disprove.