​​A Wave Curvature Equation for Unification​​Author: C.R. Kunferman​​
Part One: The Gravitational Potential Pressure Wave
​​​​A mathematical comparison of measurements and calculations.
The relationship between various fields can first be seen when drawing up a comparison chart of shared properties. There exist not only similar correlations, but in some cases identical forms of computation used to quantify and study some of the basic fundamentals.​
​​
​These comparisons do not imply that the forces are related in terms of occurrence or functionality, they are simply to illustrate the ways we can observe them in similar ways, to find commonalities among them. The comparisons will allow us to discern key differences, and also key areas of likeness in which we could apply similar methods and experimentation towards.​
​​
​To begin our comparison we take a look at two well known and observable phenomena with an abundance of similar attributes. ​
​​
​Key Commonalities in the Comparison Of Attributes (Gravity, Sound):
Attribute
Gravity
Sound
Key Commonality
Propagation
Gravitational Waves
Longitudinal Waves
Wave Propagation
Speed
Speed of Light
Speed of Sound
Frequency
Gravitational Wave Frequency
Acoustic Frequency
Frequency
Amplitude
Strength of gravitational field
Sound pressure level
Attenuation
Inverse Square Law
Weakens with distance
Inverse Square Law
Detection
Laser Interferometer
Laser Doppler Vibratory
Laser Detection
Source
Massive object collisions
Vibrating objects
Vibration Source
Wave Type
Transverse
Longitudinal
EnergyTransfer
Transfers gravitational energy
Transfers acoustic energy
Energy Transfer
Mathmatical Description
General Relativity
Hooke's Law
Oscillatory Calculations
In the above comparison chart, we find that sound and gravity share some key components of behavior: Wave Propagation, Frequency, Inverse Square Law, and Energy transfer. Both can be measured and detected with the use of lasers as well.
​
Given the abundance of correlations, we then look to the calculations and to that of the mathematical descriptions for both, and here we find correlations aside from the systems of measurements.
​
By drawing a detailed comparison chart containing calculations it presents additional correlations on calculative level to which we apply our measurements and make out predictions with great accuracy.

Calculations of Gravity vs. Sound

"Attribute"
"Gravity"
"Sound"
"Key Commonality"
"General Calculations"
G
μν
+Λ
g
μν

8πG
4
c
T
μν
"△P = △ Pmax sin(kx∓ωt +ϕ)"
​
"Frequency"
F
gω

ω
2π
F
v
λ
"Measured in Frequency"
"Energy"
"∇PE = mgh"
"P = EλT"
""
"Amplitude"
h∝
1
r
A∝
1
r
"Amplitude Proportion"
"Speed of Propagation"
c≈3
8
10
ms
c≈343ms
"Speed Approximation"
"Detection"
δ
L
L
δP
"Laser Detection"
"Waveform"
"h(t)"
"p(t)"
"Wave as a Function of Time"
"Attenuation"
1
2
r
1
2
r
"Inverse Square Law"
Of particular interest: Many of the equations are so similar that variables can be swapped, or cross applied between these fundamentally different fields, but still hold the same principle calculations.​​​​For instance, by taking Hooke's law and applying it to gravity, we can determine the position of the first object given the starting position of where the gravity is emitted. Likewise, we can apply Newton’s Law of gravitation to sound force, and thanks to the Inverse Square Law they share we are able to successfully calculate how much force it takes for a sound wave to knock down a wall. The base equations would remain the same, while the interpretation and exact amounts calculated would differ.​​​​Using Newton’s Gravitational law for Sound:​​​​F = Force based on an inverse square law with respect to distance = F​​​​G = A proportionally constant  = C​​​​m1 = Density of first object = p1​​​​m2 Density of second object = p2​​​​r = Distance between objects. = r​​​​Gravity
FG
m
1
m
2
2
r
​​​​Sound
FC
p
1
p
2
2
r
​​​​Likewise, we can do a similar substitution using Hooke's law for calculating the force of gravity:​​​​F = Force based on an inverse square law with respect to distance. = F​​​​k = Constant = G​​​​x = Displacement =
m
1
m
2
2
r
= x​​​​Sound F=−kx​​​​Gravity F=−Gx​​​​The dimensional correlations continue with Amplitude, as does the similarity in Waveform, again with only the variables, scale and our interpretations providing the difference. Fundamentally, and mathematically however, the numbers crunch the same.  Here we will show the two separated by parentheses and the calculation variables or parts they share in brackets.​​​​(Sound) vs. (Gravity) [shared between brackets]​​​​Amplitude:​​​​(A)(h)[
1
r
]​​​​Wave Form:​​​​(p)(h)[t]​​​​With Wave Equation, Frequency, Amplitude, Waveform and Attenuation all showing correlation, it hints towards a common underlying fundamental force at work, and suggests the two forces may be of the same characteristic composition. ​​​​The similarities in the behavior of both occurring on two completely different scales and speeds are striking enough to tempt the observer into thinking they may be the same force. ​​​​These correlations however do not account for the difference in propagation through mediums initially, as it is well known that sound cannot travel through a vacuum. ​​​​By expanding the comparison chart to encompass other fields, we find that many still share the same calculations.  Each is symbolically represented as a separate field with the first variable denoting this, as they exist as separate forces in nature.​​​​Due to its property of requiring a medium and its inability to propagate through space sound is often held at arms length separately from these forces, but is still worth noting for its wave properties and calculations to better illustrate the behavior of the larger forces in our minds and imagination.​​

Shared Function and Wave type of Various Field Calculations

"Force (Amplitude)"
"Unique Variable"
"Shared ∝"
"Gravity"
"h"
1
r
"Gravitational Potential"
"φ"
1
r
"Sound"
"A"
1
r
"Electric Fields"
"E"
1
r
"Magnetic Fields"
"B"
1
r
Also of note, we find a correlation pertaining to propagation in the way we measure the speed of propagation for Gravity, Electricity, and Magnetism, all propagating at the speed of light. And although it is not as accurate, we can apply the same speed measurement to sound as well, denoting a difference in scale. As such we can also include sound on the comparison chart for propagation speeds to illustrate that there is commonality among wave forms from all walks of different forces.
The previously noted comparisons raise an interesting implication about much of the measurements and calculations. While our interpretations have placed these areas of study into separate fields, on a numerical, and mathematical base level they calculate and in most cases share properties that are all calculated the same, beyond the simple property of being a wave.
​
Given the success of applying Hooke’s law to gravity we find that it can form a sound framework in order to unify a way of calculating the forces of waves and the effect it has on matter through a similar expression:​
​​
​F = -cx​
​​
​where:​
​​
​F is the force of the fundamental,​
​​
​For: ​
​Light: F = Radiation Pressure,​
​Gravity F = Gravitational Force,​
​Magnetism F= Lorentz Force​
​Heat: F = Energy Transfer​
​​
​c is the constant,​
​​
​For:​
​Light: c = Light Speed,​
​Gravity: c = Gravitational Constant,​
​Magnetism: c = Field Strength,​
​Heat: c = Material Density​
​​
​and where:​
​​
​x is the effect of the force on matter​
​For:​
​Light: x = (I*p) where I = Intensity, p=Photon Momentum​
​Gravity: x = m1m2/(r*r)​
​Magnetic: x = (I*L) where I = Current and L = Length​
​Heat: x = Expansion​
​
While we do observe differences in the way they affect materials and react to outside forces, the correlations in calculating do suggest that beyond the wave properties of each there is an underlying fundamental or mechanism at work.
​
While gravity shares the properties of propagation and speed with the other transverse waves, under observation and even calculation its clear that gravity exhibits influence and effects that appears more consistent with the behavior of longitudinal waves, and we find a great many more correlations in calculating it with sound.
​
Therefore, the author proposes that a longitudinal wave component may be present within the force of gravity.
​
Under that consideration, a possibility arises. One that can propagate even through the vacuum of space, exerting force on the space time curvature, and moving matter:

Hypothesis

★

Over time gravitational waves excite the gravitational potential producing a longitudinal pressure wave that travels at the speed of light propagating over oscillating electric and magnetic fields.

Methods

Results

Using the calculations and the capabilities of this platform we can produce the following interactive visuals that provide a clear picture.

Discussion

Given these characteristics, it becomes easier to imagine and perceive how gravity is affecting the world around us, as large waves surround us having traveled so far that they have become a weak force. Echoes of a time in the distant past when collisions on a scale unimaginable ruled the galaxy and the stars.
​
The gravitational waves over time exciting the potential producing the force we still see exerted upon larger masses and even small ones albeit imperceptible in their magnitude as they tower and span above and below us, the quiet unheard hum holding the universe together.
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It raises questions, such as: ”How do we measure things of such a magnitude outside of the numerical values we can explore?” or “Can we still simply observe the effects, comfortable in knowing that it is always there, all around us, being fundamental as a part of our reality and truth in the simplicity of our numbers and calculations?” This may very well be the decision before us, nevertheless we continue our exploration through numbers.

Future Work

Having expressed and charted the potential gravitational pressure wave, this provides us with a primordial form of influence that can be represented by a simple sine wave, similar to a sound wave on earth, with the same calculations of a longitudinal form and similar characteristics in terms of its effect on matter.
​
In the next paper, the author will present some simple experiments to illustrate the effects of these new waves on matter and the space time curvature.
​
By taking small and familiar examples from experiments designed normally for sound, they will be scaled up and sped up to match the force of gravity.
​
To further explore this phenomenon the author will present how frequency may play a part and reveal findings with very significant implications including but not limited to why Saturn has rings and why Jupiter has a giant eye.
​
The author will also continue presenting the journey towards discovering the wave that underlies it all with the addition of magnetism to the simulations showing correlations and an even lesser known possibility of interaction.
​

Conclusion

The potential gravitational pressure waves hold (for lack of a better term) much potential to help explain the mechanisms and the outer workings of gravity.​
​​
​In the spirit of science the author looks forward to seeing what other researchers may find in their exploration of this potential and hopes that it may not only improve our cosmological models, but also humanities understanding as a whole.​
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​Or perhaps not as it may be, for there are 999 ways to incorrectly make a light bulb, and every mistake is another step forward in finding a solution.​
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​Thanks to Wolfram, researchers now have a lab just above those standing on the shoulders of giants, to build and test all that and more from anywhere in the world, in the WolframCloud.​
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​And that is where the journey of discovery begins.
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  • note: There was a small typographical error in the first provided simulations, it has been corrected as of 01/09/2025