memex/0_inbox/books/TWOW/html/26 Empirical equivalence of different models of the general theory of relativity.html

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<p lang="en-US" class="western" align="left" style="margin-left: 1.27cm; margin-right: 2.54cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt"><font color="#993366"><font face="Verdana, sans-serif"><b>E<img src="data:image/png;base64,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" name="TtsOtkCLGtr_10" align="right" hspace="5" width="400" height="38" border="0">mpirical
equivalence of different models of the general theory of relativity
(GTR). </b></font></font>This explanation of the old and new
gravitational phenomena has assumed that nothing exists but two,
opposite kinds of substances enduring through time. But the capacity
of spatiomaterialism to explain those phenomena does not necessarily
mean that it is equivalent to a single model of GTR on the received
geometrical interpretation (which explains gravitation as a curvature
in four dimensional spacetime). Thus, it remains to be seen why there
are infinitely many different, observationally equivalent models of
GTR for any particular universe, or why “general relativity” (in
one sense) seems to be true. </font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">Since
this explanation of gravitation is based on the spatiomaterialist
explanation of the truth of STR, space is assumed to be a substance,
and we are liberty to take as our reference frame the inertial frame
at rest in space outside of gravitational influences where the
one-way velocity of light is the same both ways in every direction.
That inertial frame is at rest relative to the inherent motion in
space, and the inherent motion itself is at rest relative to space
(in other words, that inertial frame is at rest relative to the
ether, which, in turn, is at rest relative to space). The times and
places of events assigned by observers on such an “absolute
reference frame” would be accurate, because his clocks would not by
mis-synchronized</font></font></font></p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">Consider a
gravitational field imposed by a gravitating body of some kind. It
will be accelerating the inherent motion (or ether) toward itself
according to the inverse square law. Of all the reference frames that
would be accelerated toward the gravitating body, the one with the
most accurate times and places of events would be the one that is at
rest relative to the inherent motion itself (or the ether) as it is
being accelerated toward the center of gravitation. To be sure, such
a reference frame could not have clocks synchronized everywhere,
since any large rigid object would be torn apart by the difference in
forces acting at different points. But if observers on that reference
frame could use GTR (or this ontological explanation of the
gravitational force) together with light signals received from other
objects to figure out where and when events occur throughout the
gravitational field. That is, they would determine the “simultaneity
hypersurface in curved spacetime” from their reference frame, and
since that would correspond to what is really happening to substances
at that moment as they endure through time, their reference frame can
be called the “absolute model” for GTR, by analogy to the
inertial frame of the absolute observer in STR. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">The reason
that there are many different empirically equivalent models for any
such situation is that there are other reference frames which differ
from the absolute reference frame only by have a velocity relative to
the inherent motion itself that is being accelerated inward. They are
empirically equivalent locally, because they suffer Lorentz
distortions that mask their velocity relative to the inherent motion.
And observers on each of them could use GTR together with information
received from events elsewhere to determine their “simultaneity
hypersurface in curved spacetime.” They would all disagree with one
another, like different inertial observers outside gravitation, and
there would be no way for them to tell by experiment which reference
frame was the absolute reference frame. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">That is,
each possible model of GTR is adapted to the trajectory of one of the
many different particles that could be in inertial motion at any
point, and their different velocities relative to the inherent motion
would give them, incipiently, at least, different standards of
simultaneity (that is, each determines a different “simultaneity
hypersurface in curved spacetime”). Any pair of such reference
frames may have a high velocity relative to one another as they pass
one another at that point, but each would observe Lorentz distortions
occurring in the other reference frame, and thus, the symmetry
between them would make it impossible to for them to tell which
reference frame is at rest relative to the inherent motion in space
that is being accelerated toward the center of gravitation. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">This
explains why models based on different reference frames are
empirically equivalent as far as different velocities relative to the
inherent motion is concerned. But neither can anything known about
the effects of the gravitational force be used to distinguish one
reference frame from another. Even of observers on the reference
frames accepted the spatiomaterialist explanation of the nature of
gravitation as an acceleration of the inherent motion by the
gravitating body, that would not single out the absolute reference
frame from the rest. (Or if the observers think in terms of GTR and
see gravitation as a “curvature of spacetime” caused by
gravitating bodies, that does not compromise their empirical
equivalence.) </font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">The
absolute model cannot be assumed to be the one based on the local
inertial frame that would result from accelerating all the way in
from being at rest outside the gravitational field, for the
gravitating body may itself have a non-zero velocity relative to the
inherent motion in unstressed space. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">It might
seem possible to measure an object’s velocity relative to the
inherent motion by using the gravitational time dilation of objects
at rest in the gravitational field to determine their velocity
relative to the inherent motion. But that will detect only the
increase in the velocity of the inherent motion as a result of being
accelerated toward the center of gravity to that point from outside
the gravitational field, and that will not determine whether the
gravitational field itself is in motion relative to the inherent
motion outside gravitation. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">Or it would
be possible, in principle, to use the difference between light
signals and gravitational signals to detect absolute rest, if
gravitational forces propagated at a different velocity from light.
But since the force that accelerates the inherent motion in space
propagates through the inherent motion at the same velocity as light,
its effects are explained equivalently by each model in the same way
as light. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">The
equivalence of inertial frames that Einstein meant by “general
relativity” can be explained, therefore, by special relativity.
That is, the empirical equivalence of different models of GTR can be
explained as the empirical equivalence of local inertial reference
frames that have different constant velocities relative to the
accelerating inherent motion. There is no way to determine which of
their standards of simultaneity is correct, for there is no way to
detect rest relative to the inherent motion. And none of the
interactions between space and matter that constitute the force of
gravity betrays which reference frame is the absolute model. </font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">Though
gravitation just happens to work in such a way that absolute rest
relative to the inherent motion cannot be detected, the fact that it
works that way could explain why Einstein was able to deduce his law
describing the unexpected effects of gravitation from the assumption
that all different local inertial frames are equivalent, or “general”
relativity. </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">The
spatiomaterialist explanation of gravitation has been presented as an
ontological explanation of the truth of Einstein’s general theory
of relativity. Since what is crucial to such an ontological
explanation is identifying the aspects of the substances constituting
the world to which the theory corresponds, I have presented only a
qualitative argument. I have shown how GTR could be true, even if
nothing existed but substances enduring through time, and every
possible photon has a determinate location and velocity in absolute
space at each moment as it is present (because the inherent motion
itself is accelerated and, thus, moving through space). Though I have
said enough about the quantitative factors to make clear how it would
predict the same quantitatively precise measurements, I have not
shown mathematically that it is equivalent.</font></font></font></p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">That
is an exercise I leave up to mathematically inclined readers. It
affords an opportunity to refute ontological philosophy, for if it
can be shown that there is no way that the acceleration of the
inherent motion in space can yield the quantitatively correct
predictions for all the relevant phenomena, we will have defaulted on
the mortgage we took out to use spatiomaterialism as the foundation
for the necessary truths of ontological philosophy, and the project
will have failed. I see not reason to belief that that can be done.
But like any basically empirical argument, ontological philosophy is
vulnerable to empirical falsification, and thus, it must stand up to
such challenges. </font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 1.27cm; margin-right: 2.54cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">We
can also see, at this point, why philosophers of science have not
recognized the superiority of substantivalism about space to
substantivalism about their spacetime. Instead of inferring to the
best ontological explanation of everything in nature, they have let
their ontology be determined by realism about the highly mathematical
theories that physics has accepted as the best efficient-cause
explanation of what happens in nature. Philosophers of spacetime
simply assume that every theory about space and time, including
Newton’s (and, thus, spatiomaterialism), can be represented as just
another variety of spacetime theory using differential geometry.<sup><a class="sdendnoteanc" name="sdendnote1anc" href="#sdendnote1sym"><sup>i</sup></a></sup>
</font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">What
spatiomaterialism offers, however, is a different kind of model of
GTR. It explains ontologically why Einstein’s field equations are
true by showing how gravitational phenomena can be constituted by
space and matter as substances that exist only at the present moment.
To treat spatiomaterialism as the belief in a “simultaneity
hypersurface in a four dimensional spacetime manifold” is to
abstract from such basic ontological issues as the nature of
existence and time and to judge these theories only as
efficient-cause explanations, that is, by their predictions of
precise measurements.<sup><a class="sdendnoteanc" name="sdendnote2anc" href="#sdendnote2sym"><sup>ii</sup></a></sup>
</font></font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 2.54cm; margin-right: 1.27cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif"><font size="3" style="font-size: 12pt">And
when we judge all these theories by their capacity, as ontological
theories, to account for <i>everything </i>observable about the
world, including real change, the empirical superiority of an
ontology of enduring substances is obvious, as we have seen, because
of its explanation of the nature of time and existence.</font></font></font></p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">Spacetime,
whether curved or flat, cannot explain how the present is different
from the past and the future, because spacetime cannot be a substance
enduring through time as long as time is part of its structure. Thus,
neither can it explain real change, because nothing ever comes into
existence as time passes nor goes out of existence. (And as we have
seen, attempts to avoid falsification by our experience of real
change by adding subjective substances to the ontology makes it more
complex encounters problems relating eternal and enduring substances
as a single world, and is in any case <i>ad hoc</i>.) </font></font>
</p>
<p lang="en-US" class="western" align="left" style="margin-left: 3.81cm; margin-right: 2.03cm; margin-top: 0.49cm; margin-bottom: 0.49cm; line-height: 100%; widows: 0; orphans: 0">
<font color="#000000"><font face="Times New Roman, serif">Spatiomaterialism
differs ontologically from Einstein’s GTR in just the way required
to explain real change. Though it explains gravitation in much the
way Einstein proposed — as an effect of the container of material
objects on the path they follow — it replaces curved spacetime with
an acceleration of the inherent motion itself. Since that is nothing
but an aspect of space and matter as substances enduring through
time, given how they are related, it explain why the present is
different from the past and the future and “real change” is
ontologically possible. </font></font>
</p>
<div id="sdendnote1">
	<p lang="en-US" class="sdendnote-western" style="margin-top: 0cm; margin-bottom: 0.25cm">
	<a class="sdendnotesym" name="sdendnote1sym" href="#sdendnote1anc">i</a><span lang="en-US">
	See, for example, </span><a href="/F:/Philosophy/Existentialism/The%20Wholeness%20Of%20the%20World/www.twow.net/ObjText/#Friedman"><font color="#0000ff"><span lang="en-US"><u>Friedman</u></span></font></a><span lang="en-US">
	(1983) and John </span><a href="/F:/Philosophy/Existentialism/The%20Wholeness%20Of%20the%20World/www.twow.net/ObjText/#Friedman"><font color="#0000ff"><span lang="en-US"><u>Earman</u></span></font></a><span lang="en-US">
	(1989).</span></p>
</div>
<div id="sdendnote2">
	<p lang="en-US" class="sdendnote-western" style="margin-top: 0cm; margin-bottom: 0.25cm">
	<a class="sdendnotesym" name="sdendnote2sym" href="#sdendnote2anc">ii</a><span lang="en-US">
	</span><a href="/F:/Philosophy/Existentialism/The%20Wholeness%20Of%20the%20World/www.twow.net/ObjText/#Friedman"><font color="#0000ff"><span lang="en-US"><u>Friedman</u></span></font></a><span lang="en-US">
	(1983) argues that the four-dimensional continuously differentiable
	manifold, </span><span lang="en-US"><i>M</i></span><span lang="en-US">,
	itself is all that should be taken as “absolute” in the sense of
	being a “geometrical structure that is fixed independently of the
	events occurring within space-time” (65). That is the only
	structure that spacetime has to have in order for the equations of
	GTR to predict the gravitational trajectories of bits of matter
	precisely (and provide the curved spacetime in which other laws of
	physics hold). Focusing on the mathematics of GTR and the scientific
	inference to the best efficient cause explanation, he does not
	consider what structure spacetime must have to be adequate
	ontologically and explain “real change”. That requires a further
	structure about spacetime to be absolute, an “ontological
	structure”, namely, the one in which spacetime consists of a
	three-dimensional substance (containing bits of matter) and exists
	only at the present moment.</span></p>
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