2. Preparation of perspective
#2.1 The distance-time premise
#2.2 The finite speed of space
#2.3 Visualizing the finite speed of space within the human mind
#2.4 A major motivation for the creation of distance-time theory
#2.5 New testable predictions only made by distance-time theory
The distance-time premise is that distance and time are joined together in nature, possessing dual characteristics of distance and time. This premise contrasts with traditional views which separate time and space. The premise of distance-time may be proven wrong if distance or time can be measured independently. However, if any measurement is accomplished by particle motion, then an independent distance or time measurement has not been achieved since particles travel across distance and time jointly.
The rod (ruler) measurement has been traditionally seen as a measurement of distance
separate from time. However, the location of every part of the rod is communicated by
photons that traverse distance and time. Therefore, rod measurements are dependent on
particle motion. They are not a measurement of distance separate from time. Furthermore,
the difference between locations of physical bodies is always communicated by particle
motion across distance and time. For instance, if I try to determine the difference of
position between the earth's and the moon's surfaces, I may use a light beam or rocket.
Yet, both are groups of particles which cross distance and time and move between the earth
and the moon. Therefore, I would not achieve measurements of distance independent of time.
Consequently, all measurements of distance by an observer in nature are made across a
period of time.
Traditionally, the clock measurement also has been seen as a measurement of time separate
from distance. However, clocks use particle motion in order to measure. The traditional
clock has spindles which sweep across the face of the clock, crossing time and distance
together. Also, a digital electronic clock requires electrons to move across time and
distance jointly. These clocks do not achieve measurements of time independent of
distance.
In the previous examples, measurements of distance or time, which are independent of each other, were not achieved. Therefore, the distance-time premise remains valid. However, traditional theories, such as relativity, do not use particles to define distance and time, and they do not satisfy the distance-time premise; instead, they always separate time from distance.
Later in section 3, I shall define a structure of time and space so that an observer placed in this manifold would literally measure distance and time the same as would be done in nature. Consequently, an observer in this manifold would literally have the same perspective of time and distance as an observer in nature would have via particles, with distance and time combined. Also, any structure of time and space defined in this manner would be compatible with quantum mechanics. In quantum mechanics, an observer always measures a particle's location in space and time via particles. [4, 5] Consequently, a structure of space and time defined by particles is compatible with quantum mechanics. Since relativistic and classical space and time are defined independent of any observer using particles to measure space or time, I can conclude that relativistic and classical space and time are not in agreement with quantum mechanics. In distance-time theory, however, an observer who measures with particles defines space and time. Therefore, distance-time theory also agrees with quantum mechanics.
In our everyday experience, all distance and time can only be observed via particles. In nature, therefore, no distance or time can occur relative to an observer any faster than it can be communicated to that observer. Naturally, I do not discount the possibility that one might think that distance could occur faster than an observer could measure. Nevertheless, the distance would still not exist relative to the observer any faster than the observer could measure it. Also, in our environment, all that is real to an observer is only that which an observer can detect. Thus, in our natural surroundings, neither distance nor time occurs relative to an observer any faster than it can be communicated to that observer. Since no particle moves faster than speed c across space relative to an observer in the universe, then no distance can be defined as occurring faster than speed c in the universe. This contradicts the special theory of relativity. In special relativity, distance is perpendicular to the time axis and it occurs at a single point of time. Consequently, all space in special relativity occurs infinitely fast. This result disagrees with nature and the distance-time theory which I shall further illustrate.
I imagine two brothers, Nathan and Steve, tossing a ball between each other. Nathan wishes to determine the speed at which the gap (distance) occurs between him and Steve. Using light beams and subtracting out the time it takes for the light beam to travel between him and Steve, he synchronizes his watch with Steve's. Next, he tosses the ball as fast as he can towards Steve and measures the time it takes the ball to travel from him to Steve. After dividing the distance that the ball travels by the period of time it travels, he derives the velocity of the ball. This proves that there is a distance occurring between him and Steve at least as fast as the velocity of the ball. Nathan realizes the fastest way he can measure the speed at which the distance occurs between the two of them would be to shine a light between him and Steve. This light is assumed to be traveling in a vacuum. Since all that is real in nature, relative to the Nathan and Steve, is that which is detectable by them, then the gap between them cannot occur any faster than speed c relative to them. This result totally disagrees with special relativity theory. In the latter theory, both Steve and Nathan can be placed in space a distance apart at a single point of time relative to each other. Consequently, the distance between each other would occur infinitely fast relative to either one. This allows both brothers to be located a distance apart faster than they could measure each other's location with a particle. In distance-time theory, however, distance is combined with time and is only defined via particles. Consequently, in distance-time theory, distance occurs over the period of time a particle travels. Therefore, the gap between Nathan and Steve can only happen as fast as Nathan or Steve could measure with a particle.
This result agrees with our actual everyday experience. In our natural environment, no object can have a location relative to an observer until that observer detects the objects locations via a particle. Consequently, the gap between an observer and any object cannot occur any faster than can be measured with a particle. Therefore, distance cannot be perceived to occur infinitely fast in nature and distance-time theory. Since distance is defined throughout the three dimensions of space, the speed of space has a finite speed no faster than speed c in distance-time theory and our everyday environment. Only an infinitesimal space can be perceived to occur at infinite speed in distance-time theory and our everyday environment. In other words, relative to Nathan or Steve, the distance between them at a single point of time of the present (the now) has not yet occurred, and thus the gap between them is shrunk to zero in distance-time theory and nature.
Later in subsections 3.8 and 3.10, I will delineate more about the finite speed of space and about an infinitely quick, infinitesimal space as I delve into the characteristics of the distance-time manifold. Also, since some may assume that the concept of a finite speed of space refers to the concept of an expanding universe, I must emphatically declare that this reasoning is completely without merit. (See subsection 3.9.)
2.3
Visualizing the finite speed of space within the human mind
In order to fully appreciate the concept of a finite speed of space, you must first
realized that within the model construction of relativity and classical theories space is
assumed to be infinitely fast. It may seem to some people that an observer at the origin
of a coordinate frame can record the light signals he gets on his retina, apply his
assumption about light propagation being at speed c, and infer space-time
coordinates for the sources that sent him the signals. In that way, he can come up with space-time
coordinates that have finite difference in space but no difference in time. The
underlined part is an assumption that traditional theories make about the speed at which
the distance (gap) occurs between coordinates. These theories are assuming the distance
between coordinates is occurring at an instant ("no difference in time").
Consequently, the distance is assumed to be occurring at an infinite speed. However, it is
not necessary to assume that distance occurs infinitely fast, since there is absolutely no
physical evidence that supports the concept of an infinite speed of space.
The problem with seeing the assumptions people make is that they often are not aware they
are making them. The human mind is limited in what it can visualize. For instance, I
cannot literally imagine four dimensions. In my mind, I actually can only visualize three
dimensions. In order to work in four dimensions, scientists use the mathematics created in
three dimensions, and then extend this mathematics to both imagine and work with an extra
dimension. Therefore, these scientists actually never directly visualize four dimensions.
They only use the mathematics for four dimensions. Analogous to the manner in which these
scientists work, we cannot literally visualize a space of finite speed. The simple reason
for this is that not only does the human mind visualizes solely three dimensions, but the
human mind also only imagines a space which is infinitely fast. In other words, a whole
space that is always there (happening at an instant) is what our minds solely visualize.
As a result, it is quite easy to assume that space is infinitely fast without realizing I
have made this assumption.
In order to perceive the concept of a finite speed of space, I need to rely primarily on
mathematics. Within distance-time theory, I define distance as equivalent to time,
according to the equation D=cT. Rearranging this equation, I derive D/T=c. I interpret
this latter arrangement to mean that the rate of distance occurring per period of time is
equal to speed c. In the model construction of distance-time theory,
therefore, distance happens over a period of time and at a speed c. Distance does not
happen at an instant within distance-time theory.
It is extremely difficult for the human mind to perceive distance not occurring between
two coordinates at an infinite speed, since every model construction of space and time I
try to conceptualize is embedded within a space of infinite speed as pictured in my mind.
As a result, I can be easily fooled. The way to deal with the dilemma of this erroneous
picture of space in my mind is to mainly rely on the mathematical interpretation I have
mentioned.
As I mentioned earlier, within the construction model of distance-time theory distance is
defined as not occurring instantaneously between locations in space. At an infinite speed
(single point of time), therefore, I define distance as contracted to an infinitesimal
point between all locations in space (an infinitesimal space). Distance is essentially an
abstract concept that represents the magnitude of the difference between distinct
coordinates in space. Since distance occurring between coordinates at an infinite speed is
contracted towards zero, there is no distinction between coordinates at any single point
of time. In other words, there is zero distance between different coordinate locations at
an instantaneous speed. Space as people normally experience it should not be
conceptualized to exist at a single point of time. Only a space that has contracted to an
infinitesimal point should be pictured as existing at an infinite speed. The space I live
within everyday exists solely at a finite speed, but never does this space that I always
see happen at an infinite speed. Space is not occurred yet at speeds faster than speed c,
which is the speed of space. Some people maybe perplexed about how could there be an
infinitesimal space existing at any instant of time. For instance, how could the human
body exist within a space that has contracted to a single point? The human body would
exist only within a space of finite speed. As a result, all the actions and reactions
transpiring within the body could not happen any faster than speed c.
See Appendix A for further discussion about this topic.
Since a four-dimensional space-time continuum in general relativity theory assumes that space is infinitely fast, an infinitesimal space existing at an infinite speed cannot be derived from the theory of general relativity. Therefore, this infinitesimal space is an independent concept from the concept of a singularity found in general relativity theory. I spend some time answering questions regarding an infinitesimal space in subsections 3.10 thru 3.13.
2.4 A major
motivation for the creation of distance-time theory
I claim that distance-time theory is a more accurate theory than the theory of special relativity. This assertion should not be seen as direct challenge of special relativity theory. However, distance-time is a direct challenge to the four-dimensional space-time continuum, the latter of which is far more similar to the classical space and time theory than is distance-time theory. The four-dimensional space-time continuum and classical space and time always give an exact location and speed of a particle. Thus, they do not agree with Heisenberg's uncertainty principle and do not predict the probabilistic location of a particle. Also, the minimum requirements to be a quantum theory of time and space is that it agree with elementary quantum theory principles. Consequently, the four-dimensional space-time continuum is not a quantum structure but a classical structure. In contrast, the distance-time theory agrees with Heisenberg's uncertainty principle and predicts that particles will have a probabilistic location until their position is measured by an observer. Then the probabilistic location of the particle collapses relative to the observer which is also predicted by distance-time theory. It is important to note that the structure of time and space, found within distance-time theory, possesses these quantum properties mostly without relying on quantum theory. The principles of quantum theory are for the most part only mentioned as a reference point for predictions made by distance-time theory. These characteristics of distance-time theory are significant, and they lead me to conclude that distance-time theory agrees more with elementary quantum theory than with classical space and time. Therefore, it is not a classical theory but a quantum theory. Furthermore, quantum theory by itself is not a structure of time and space, yet it does make inferences about time and space. Both Heisenberg's uncertainty principle and the probabilistic location of a particle are essentially laws stating the relationship of a particle to space and time. These laws about a particle's relationship to space and time are significant! Yet, special relativity does not predict these laws. On the other hand, distance-time theory does predict these laws. This prediction of quantum laws does not mean that distance-time theory is a form of relativistic quantum mechanics. Relativistic quantum mechanics is essentially applying relativity to quantum theory. In contrast, distance-time theory is not about applying relativity to quantum theory. Instead, it is about a novel structure of time and space with intrinsic quantum characteristics, and it makes new predictions not found elsewhere.
In later subsections, I will define distance and time in distance-time theory as continuous. However, since quantum mechanics does not predict that distance and time necessarily come in quantified amounts, then a quantum theory of time and space may define time and space as continuous. In section 3 and 4 of my paper, I will describe further the relationship of distance-time theory and quantum theory. Although distance-time theory is a quantum theory, and, as such a direct challenge to the four-dimensional space-time continuum, it still predicts the experimentally proven results of special relativity. Furthermore, since it does predict quantum and special relativistic results, it may, in fact, be a more accurate theory of time and space than the theory of special relativity.
Another important item is the search for a quantum theory of gravity. Since modern gravitational theories rely on a warping of space and time, it is important that a quantum theory of space and time be found if a quantum theory of gravity is ever to be realized.
2.5 New
testable predictions only made by distance-time theory
In order to separate distance-time from special relativity and quantum theory, it must make predictions which neither special relativity or quantum theory can make. One such prediction is the speed of quantum tunneling. The speed of quantum tunneling is given by Eq. 27, which states that quantum tunneling cannot occur slower than speed c. Along with this prediction, I give solutions to causality paradoxes for tunneling faster-than-light. Also, I predict that the De Broglie's matter-wave placed in a distance-time manifold is nondispersive. Traditionally, De Broglie's matter-wave is generally perceived as a dispersive wave because it is always embedded in a four-dimensional space-time continuum. Furthermore, I define a reference frame for light that predicts that photons only influence each other under certain conditions. These conditions I describe in section 6 which deals with photonic reference frames. Moreover, in that same section, I predict that the law of cause and effect do not apply to the photon. Since distance-time theory makes predictions not made elsewhere, it is a new theory.
