In a statement, "... time is nonexistent.": - Replied.
Yes, time is non-existent in reality. This means not in real existence or not in actual existence. However, the concept of time is in its abstract form. - Abstraction is the process of considering concepts divested from its reference to real world objects. -
So time is not dependent on reality with which it might originally have been connected.
While events invoke time.
Soumendra Nath Thakur¹+ Priyanka Samal² Deep Bhattacharjee
¹Tagore's Electronic Lab. India
²Berhampur University, India
³INS Research, Department of Geometry & Topology, India ³Electro Gravitational Space Propulsion Laboratory, India ³Actual Intelligence Division, CXAI Technologies Ltd, Cyprus
+Corresponding author ¹postmasterenator@gmail.com ¹postmasterenator@telitnetwork.in
²priyankasamal9437@gmail.com
³itsdeep@live.co
¹ ² ³The authors have no conflict of interests related to this paper
MAY 2023
REFERENCE – 20 TITLES
Comments: Minor errors rectified; Equations formatted; Version 2.1
DOI https://doi.org/10.36227/techrxiv.22492066.v1
Keywords: phase shift, relativistic effects, wavelength dilation, piezoelectric crystal oscillator,
Introduction:
The Theory of Relativity adopts Minkowski spacetime that combines three-dimensional Euclidean space and fourth dimensional time into a four-dimensional manifold, wherein time is robbed of its independence, rather considered 'natural'.
The Theory of Relativity also conveys that the proper time is dependent on relativistic effects and expressed as π‘ < π‘′, where t' is time dilation. The equation of time dilation is π‘՚ = π‘/√(1 − π£²/π²) where π‘′ is dilated time, π‘ is proper time, v is relative speed, and c is the speed of light in free space.
The points in consideration here are –
The conjectural equation of time dilation was based on Doppler's formula, which failed to identify any cause of time distortion. Whereas the wave equation; in the properties of a wave, in combination with the Planck equation has been able to successfully identify the distorted frequencies due to the relativistic effect that has the influence factor. The distorted frequencies in the equation yield a relative value of time for the corresponding wavelength dilation, which is erroneously known as time dilation.
This expression for time in time dilation contradicts the expression t=t' as in classical mechanics, where time is absolute. Stephen Hawking upheld the concept of imaginary time in his book "The Universe in a Nutshell". Time is defined as the indefinite continued progression of events in the past, present and future existences and considered as a whole, succeeding in irreversible and uniformed succession, which is referred to in the fourth dimension above the three spatial dimensions. Therefore, events invoke time but not vice versa. What special relativity represents in time dilation is not time, and time dilation does not have time. It is rather error in the clock oscillation.
Counterexamples such as experiments made on piezoelectric crystal oscillators show that wave distortions correspond to time distortions due to relativistic effects, thus disproving the conjectural equation of time dilation; and invalidates time dilation altogether. The time dilation equation π‘՚ = π‘/√(1 − π£²/π²) is wrong.
A scientific misconception in time dilation:
Events invoke time. The defect in the equation π‘՚ = π‘/√(1 − π£²/π²) is that relativistic effects, such as speed or gravity of the real events, can never interact with the proper time (π‘) referred to in the fourth dimension. This means, the {1/√(1 − π£²/π²)} part of the equation cannot influence or interact with the proper time (π‘) to enlarge it and get the time dilation (π‘′) as in the equation. The piezoelectric crystal oscillators show that the error in wave corresponds to time shift due to relativistic effects.
The observations made on the effect of dark energy do not show anti-gravity, caused by dark energy, affects time in any manner, except causing enlargement in the wavelength due to expansion of space. It is naturally unauthorized and disprovable to enlarge the scale of proper time, instead of distortion in the wavelength of clock oscillation.Even very small changes in the gravitational forces (G-force) cause internal particles of matter to interact with each other, which is known to cause stresses and associated deformations in the internal matter.
Wavelength distortions, due to the phase shift in relative frequencies, correspond exactly to time distortion; through the relationship π ∝ π, where π denotes the wavelength and π denotes the period of oscillation of the wave. So that relativistic effects, such as speed or gravitational potential differences, affect the clock mechanism because of phase shifts in the frequencies and corresponding increase in the wavelength of the clock oscillation, resulting errors in reading of the clock time, but incorrectly perceived as time dilation.
Real events in space never reach the fourth direction of time, either through interactions or relativistic effects such as motion or gravity. Events within space will not have a natural reach toward the dimension of proper time, so that eventual effects can never affect proper time beyond its ideal succession, to obtain time dilation. A clock reading should always follow the order of time sequence; otherwise, the external distortion will cause incorrect readings in the clock mechanism. The dimension of time is considered abstract rather, conceptual.
It would be wrong to try to change proper time like in the conjectural equation of time dilation. Relativistic effects cannot interact with proper time to get time dilation. Apart from this, the concept of time dilation defies the conventional scientific definition of time involving existence and events. Proper time should never be stripped of its independence and retained as 'natural' even in the four-dimensional continuum of spacetime. There is no time dilation anywhere; instead, the dilation of the wavelength of the clock oscillation causing errors in the clock time. Wavelength distortions mathematically correspond exactly to time distortions; as in π ∝ π.
General Foundations:
Time is called π, the period of oscillation, so that π = 2π/π. The reciprocal of the period, or the frequency π,in oscillations per second, is given by the expression π = 1/π = π/2π = πΈ/β = π£/π. Where h is Planck constant, π, π£, π, π and πΈ respectively represent frequency, velocity, wavelength, time period and Energy of the wave.Doppler shift is the change in frequency of a wave in relation to an observer who is moving relative to the wave source.
Time distortion always originates from wavelength distortion but the time dilation of special relativity is not understood from wavelength distortion and so it does not follow the general rules.
Special relativity does not escape the fundamental equivalence between wavelengths and time, which is much more general than special relativity.
Distortions of wavelengths exactly correspond to time distortions Ξ»∝T.
Time is the indefinite continued progress of existence and events in the past, present, and future regarded as a whole, succeeding in irreversible and uniformed succession, referred to in the fourth dimension above three spatial dimensions. Therefore, time is not what special relativity presents as in time dilation and there is no time in time dilation. It is rather error the in wave.
Time is an imperceptible fourth dimensional concept so protected from relativistic effects like speed or gravity, nor it subject to real interference or influence or interaction with the cosmic events. The events rather invoke time.
The term cosmic time signifies a relationship between the time since the Big Bang and the events within the Universe. The distortion in proper time always originates from wavelength distortion, including in special relativity, and therefore proper time subject to synchronization with ideal time in near approximation, as done with the atomic clocks.
Eperimental result
Experiments made in electronic laboratories on piezoelectric crystal oscillators show that the wave corresponds to time shift due to relativistic effects.
We get the wavelength π of a wave is directly proportional to the time period T of the wave, that is π ∝ π, derived from the wave equation π = π£/π = 1/π = πΈ/β where h is Planck constant and π, π£, π, π and πΈ represent frequency, velocity, wavelength, time period and Energy of the wave respectively.
Whereas the time interval π(πππ) for 1° of phase is inversely proportional to the frequency (π). We get a wave corresponding to the time shift
For example, 1° phase shift on a 5 MHz wave corresponds to a time shift of 555 picoseconds (ps).
We know, 1° phase shift = π/360. As π = 1/π,
Therefore, for 1° phase shift for a wave having a frequency π = 5 ππ»π§, and so wavelength π = 59.95 π, the time shift (time delay) π₯π‘ = 555 ππ (approx).
Moreover, for 360° phase shift or, 1 complete cycle for a wave having frequency 1Hz (of a 9192631770 Hz wave); the time shift (time delay) π₯π‘ = 0.0000001087827757077666 ms (approx).
Conclusion:
References:
Abstract:
This research report delves into the concepts of infinity (∞) and zero (0) and their profound significance in mathematics and physics. Infinity represents an unbounded, limitless quantity, while zero is the absence of quantity. Both concepts are essential in mathematical modeling and the exploration of the physical universe. Additionally, the report explores the concept of negative zero (-0) and negative infinity (-∞) and how they are used in specific contexts.
1. Introduction
Explanation of infinity (∞) as an unbounded concept
Introduction of zero (0) as the absence of quantity
Importance of these concepts in mathematics and physics
2. Infinity (∞)
Mathematical usage of infinity in limits, calculus, and set theory
The extended real number system and arithmetic operations involving infinity
Infinity in the context of transfinite numbers and cardinality
Practical applications in physics, including singularities and cosmology
3. Zero (0)
Zero as the additive identity and its role in arithmetic
Use of zero as a placeholder in the decimal number system
Zero as a starting point for counting and its presence in coordinate systems.
Significance of zero in algebraic structures
4. Negative Zero (-0)
Explanation of negative zero as a value slightly less than zero
Use of negative zero in numerical calculations and computer science
How negative zero interacts with arithmetic operations
Relevance of negative zero in ensuring consistency in mathematical operations
5. Negative Infinity (-∞)
Definition of negative infinity as values infinitely small or unbounded in the negative direction
Use of negative infinity in limits and calculus
Representation of negative infinity in graphical contexts
Arithmetic operations involving negative infinity
6. Existence and Philosophical Views
Discussion of the existence of zero and infinity as abstract concepts
Philosophical interpretations and debates regarding these concepts
Theological, existential, and mystic perspectives on infinity
Anti-dialectical philosophers' critical views on infinity
7. Conclusion
Recapitulation of the importance of infinity and zero in mathematics and physics
Acknowledgment of their abstract and foundational nature
Consideration of the ongoing philosophical and scientific discussions surrounding these concepts
8. References
This research report provides a comprehensive understanding of infinity, zero, and their roles in mathematics and physics, offering insights into their abstract nature, practical applications, and philosophical interpretations.
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Addendum
Infinity (∞):
Infinity is not a real number but rather a concept used to describe something that goes on without bound or limit. It represents an unbounded, limitless quantity.
In calculus, infinity is often used to represent limits. For example, the limit of a function f(x) as x approaches infinity can be written as lim(x → ∞) f(x). This indicates that as x becomes larger and larger without bound, f(x) also becomes larger without bound.
There are different types of infinity in mathematics, such as countable infinity (as in the set of all natural numbers) and uncountable infinity (as in the real numbers).
Zero (0):
Zero is a real number and is represented by the digit "0." It is the additive identity, meaning that when you add zero to any number, it does not change the value of that number. For example, 5 + 0 = 5
In the context of arithmetic and algebra, zero serves as the point on the number line where no quantity or magnitude exists.
Zero is also used to denote the absence of a quantity. For example, if you have zero apples, it means you have no apples.
In mathematics, zero is crucial for various operations, including addition, subtraction, multiplication, and division. It is the starting point for counting and forms the basis for our number system.
These definitions are foundational in mathematics and are used to perform a wide range of mathematical operations and calculations. Zero and infinity have unique properties and are essential concepts in various mathematical theories and applications.
Negative zero (-0) is a concept in mathematics that represents a value that is less than zero but very close to it, almost indistinguishable from zero. It is often used in certain numerical calculations and computer science to account for rounding and precision issues. Negative zero is not a separate number like positive zero (0); rather, it is a notation used to indicate a value that is very slightly below zero.
Here are some key points about negative zero:
Representation: In mathematical notation, negative zero is typically written as -0.
Significance: Negative zero is used to indicate that a value is very close to zero but slightly less than it. It arises in situations where calculations or measurements result in values that are extremely small but still distinguishable from zero when considering the precision of the measurement or calculation.
Real-World Examples: Negative zero is often encountered in computer programming and numerical analysis. For example, in floating-point arithmetic, when the result of a calculation is extremely close to zero but not exactly zero due to rounding errors, it may be represented as negative zero to indicate its proximity to the negative side of the number line.
Arithmetic Operations: Negative zero behaves like zero in most arithmetic operations. For example, -0 + 0 = 0, -0 - 0 = 0, -0 * 5 = 0, and so on It is essentially treated as a special case of zero.
Practical Use: While negative zero has mathematical utility in specific contexts, it is not commonly encountered in everyday mathematics. In many cases, it is used to ensure that certain mathematical operations and algorithms behave consistently in the presence of very small values that approach zero.
IEEE 754 Standard: In computer science and floating-point arithmetic, the IEEE 754 standard for representing real numbers includes a signed zero representation, which allows for both positive and negative zero. This is particularly useful in ensuring that mathematical operations involving zero behave predictably in various numerical computations.
In summary, negative zero is a mathematical notation used to represent values that are very close to zero but slightly less than zero. It is mainly encountered in computer science and numerical analysis to address precision and rounding issues, ensuring consistent behavior in mathematical operations involving small values.
Negative infinity (-∞) is a mathematical concept used to represent values that are infinitely small or unbounded in the negative direction on the number line. It is the counterpart of positive infinity (∞), which represents values that are infinitely large or unbounded in the positive direction.
Here are some key points about the concept of negative infinity:
Symbol: Negative infinity is typically denoted as -∞.
Mathematical Usage: Negative infinity is used in various mathematical contexts, especially in limits and calculus. For example, when discussing the behavior of a function as it approaches negative infinity, you might write lim f(x) as x approaches -∞.
Representation: In graphical representations, the negative infinity symbol (-∞) is used to indicate that a function or a value continues indefinitely in the negative direction, approaching smaller and smaller negative values without bound.
Arithmetic Operations: Negative infinity interacts with arithmetic operations in a specific way. For example:
Negative infinity minus a finite number: -∞ - a = -∞ (It remains at negative infinity).
Negative infinity plus a finite number: -∞ + a = -∞ (It remains at negative infinity).
Negative infinity times a finite number: -∞ * a = ∞ if a < 0 (It becomes positive infinity) and -∞ * a = -∞ if a > 0 (It remains at negative infinity).
Negative infinity divided by a finite number: -∞ / a = ∞ if a < 0 (It becomes positive infinity) and -∞ / a = -∞ if a > 0 (It remains at negative infinity).
Limit Notation: Negative infinity is often used in the context of limits to describe how a function behaves as its input approaches negative infinity. For example, lim f(x) as x approaches -∞ represents the limit of the function f(x) as x gets smaller and smaller in the negative direction.
Real-World Analogies: While negative infinity is a useful mathematical concept, it doesn't have a direct real-world counterpart. It's a way of describing values that are becoming increasingly negative without bound.
In summary, negative infinity is a mathematical concept representing values that are infinitely small or unbounded in the negative direction on the number line. It is a fundamental element in calculus, limits, and mathematical analysis, helping to describe how functions behave as they approach infinitely negative values.
Existence of Zero (0):
The existence of zero as a mathematical concept is well-established and widely accepted in mathematics. Zero represents the absence of quantity or a neutral element in various mathematical operations. It is a fundamental part of the decimal number system and is used in arithmetic, algebra, calculus, and many other mathematical disciplines.
In the context of philosophy and mathematics, zero can be considered as an abstract concept that represents the absence of value or quantity. It is not a physical object but a mathematical idea used to describe the absence of something.
Existence of Infinity (∞):
The concept of infinity (∞) is more abstract and complex. In mathematics, infinity is used to describe something that is unbounded or limitless. It is not a specific number but a symbol that represents an idea of going on forever without an endpoint. For example, the set of natural numbers (1, 2, 3 ...) is considered to be infinite.
In calculus and mathematical analysis, limits involving infinity are used to describe the behavior of functions as they approach infinitely large or small values. However, infinity is not a real number, and mathematical operations involving infinity must be carefully defined to avoid paradoxes.
From a philosophical perspective, the existence of infinity has been a topic of debate. Some philosophers argue that infinity is an abstract concept that exists only in human thought and mathematics, while others contend that it reflects the potentially unbounded nature of the universe.
In summary, zero is a well-established mathematical concept used to represent the absence of value, while infinity is a more abstract idea used to describe unboundedness or limitless quantities. Both concepts exist within the framework of mathematics and human thought, but their ontological status in the physical world is a matter of philosophical discussion and interpretation.
Infinity (∞):
Unboundedness: Infinity represents the concept of being unbounded or limitless. It is not a specific number but rather a symbol used to describe something that goes on forever without an endpoint.
Limit Notation: In calculus and mathematical analysis, infinity is often used in limit notation. For example, the limit as variable approaches infinity (lim x → ∞) is used to describe how a function behaves as it approaches an infinitely large value of x.
Infinite Sets: In set theory, there are different sizes of infinity. For example, the set of natural numbers (1, 2, 3 ...) is countably infinite, while the set of real numbers is unaccountably infinite. These distinctions are made using concepts like cardinality.
Geometric Infinity: In geometry, infinity can be used to describe points at an infinite distance, such as the vanishing point in perspective drawing or points on the projective plane.
Zero (0):
Additive Identity: Zero is a real number and serves as the additive identity. When you add zero to any number, it does not change the value of that number. For example, 5 + 0 = 5
Place Value: Zero is a crucial digit in the decimal number system. It is used as a placeholder to denote the absence of a value in a particular place. For instance, in the number 205, zero is used to indicate that there are no tens between the two and the five.
Arithmetic Operations: Zero plays a fundamental role in arithmetic operations. It is the starting point for counting, and various mathematical operations involving zero are defined, such as addition, subtraction, multiplication, and division.
Origin in Coordinate Systems: In coordinate geometry, zero represents the origin (0, 0) of a Cartesian plane. It is the point where the x and y axes intersects.
Neutral Element: In algebraic structures like groups and rings, zero often serves as the neutral element for addition, meaning that adding zero to any element leaves that element unchanged.
Both infinity and zero are abstract concepts that have practical implications in mathematics and the sciences. They are used to describe extremes, limits, and the absence of values, making them indispensable tools for mathematical modeling and problem-solving.
Infinity (∞):
Infinity represents a concept of boundlessness or an unbounded quantity. It is not a specific number but rather a symbol used to describe something that goes on endlessly.
In mathematics, infinity is used to describe values or limits that become larger without bound. For example, the limit of 1/x as x approaches zero is often represented as ∞ because as x gets closer to zero, 1/x becomes larger and larger.
Infinity can also be used to describe infinite sets, such as the set of all natural numbers (1, 2, 3 ...), which has no end.
Infinity is an abstract concept and is not a real number that can be used in calculations like other finite numbers.
Zero (0):
Zero represents the absence or lack of quantity. It is the point on the number line where no magnitude or value exists.
In mathematics, zero is a real number and a fundamental part of arithmetic. It serves as an additive identity, meaning that when you add zero to any number, it does not change the value of that number. For example, 5 + 0 = 5
Zero also plays a crucial role in algebra, calculus, and many other branches of mathematics.
In philosophy and other fields, zero can symbolize emptiness, nothingness, or the starting point of existence.
Infinity and zero are often discussed in philosophical and mathematical contexts to explore the boundaries of what can be comprehended and calculated. They are fundamental concepts that have sparked numerous debates and inquiries throughout history.
Infinity as a Divine Attribute: In many theological traditions, God is considered infinite. This means that God is not limited by time, space, or any other finite qualities. God's infinity is often seen as a fundamental aspect of His nature. This view of infinity is prominent in monotheistic religions like Christianity, Judaism, and Islam.
Infinity and Creation: Theological discussions often revolve around the relationship between the infinite God and the finite created world. The act of creation is sometimes seen as God's way of expressing His infinity while allowing for finite existence. The finite world is contingent upon the infinite God.
Infinity and Human Understanding: Many theologians acknowledge that human beings have limited understanding and finite perspectives. In this view, the infinite nature of God is something that transcends human comprehension. Attempts to describe or understand the infinite are seen as limited by human language and thought.
Infinity and Mysticism: In some mystical traditions within various religions, the contemplation of the infinite is a central practice. Mystics seek direct, personal experiences of the divine, often described as encountering the infinite. For example, in Christian mysticism, there is a focus on experiencing the infinite love of God.
Infinity and Religious Symbols: Some religious symbols and concepts are associated with infinity. For example, the ouroboros (a serpent or dragon eating its tail) is a symbol of infinity and is sometimes interpreted in religious contexts as representing cycles of creation and renewal.
Infinity and Cosmology: Theological views may also intersect with cosmological questions about the universe's infinity or finitude. Some theologians engage with scientific discoveries about the cosmos and consider how these findings relate to religious understandings of infinity.
Infinity and Afterlife: In many religious traditions, the afterlife is often depicted as an existence that transcends earthly limitations, sometimes described as eternal or infinite life. The concept of infinity can play a significant role in discussions about the nature of the afterlife.
Infinity and Moral Attributes: In addition to God's infinity, theologians may discuss God's moral attributes, such as infinite love, mercy, or justice. These attributes are understood as extending infinitely, meaning that they are not limited or finite in any way.
It's important to note that theological views on infinity can be highly nuanced and may vary widely within and between religious traditions. Different theologians may emphasize different aspects of infinity in their theological reflections, and theological interpretations can evolve over time in response to changing philosophical and scientific perspectives.
Anti-dialectical philosophers often take a different view of infinity compared to those who embrace dialectical or Hegelian philosophies. While dialectical philosophies, like Hegelianism, see infinity as an essential and dynamic aspect of reality, anti-dialectical philosophies tend to be more critical of this perspective. Here are some ways in which anti-dialectical philosophers might view infinity:
Rejecting Metaphysical Claims: Many anti-dialectical philosophers reject metaphysical claims that involve the concept of infinity They may argue that infinity is an abstract and potentially incoherent concept that doesn't have a place in a rigorous philosophical framework. They might contend that infinity is a human invention that doesn't correspond to any actual state of affairs in the world.
Emphasis on Finitude: Anti-dialectical philosophers often emphasize the importance of finitude and limitations. They argue that the finite and determinate aspects of reality are what can be known and understood, while the infinite remains unknowable and, therefore, irrelevant or misleading. This perspective is sometimes associated with positivist and empiricist philosophies.
Critique of Hegelian Dialectics: Anti-dialectical philosophers frequently critique Hegelian dialectics, which relies on the concept of an evolving and infinite Absolute or World Spirit. They may argue that this idea is overly speculative and lacks empirical grounding. Instead, they might advocate for a more empirical and scientific approach to philosophy.
Concerns about Paradoxes: Some anti-dialectical philosophers raise concerns about paradoxes and contradictions that can arise when dealing with infinity. The concept of infinity can lead to logical and conceptual problems, such as Zeno's paradoxes, which they see as evidence that infinity is problematic and should be treated with caution.
Preference for Empirical Observation: Anti-dialectical philosophers often place a strong emphasis on empirical observation and the scientific method. They argue that philosophical claims about infinity should be grounded in empirical evidence and testable hypotheses rather than abstract metaphysical speculation.
Epistemological Skepticism: Some anti-dialectical philosophers may adopt an epistemological stance that questions our ability to know or make meaningful claims about infinity. They argue that since infinity is beyond the scope of human experience and understanding, it is not a valid subject of philosophical inquiry.
Existentialist Concerns: Existentialist philosophers, who are often critical of systematic philosophies like Hegelianism, may see infinity as an abstract and impersonal concept that lacks the authenticity and concrete existence they seek to address in their philosophies.
It's important to note that anti-dialectical philosophers can have diverse views on infinity, and not all of them reject the concept outright. Some may engage with infinity in limited ways or propose alternative understandings of the concept. Additionally, the specific views of anti-dialectical philosophers can vary widely depending on their philosophical traditions and individual perspectives.
In physics, infinity (∞) is often encountered as a mathematical concept used to describe certain physical phenomena and mathematical limits. Physicists use infinity in various contexts to simplify equations, describe the behavior of physical systems, and understand the universe. Here are some ways in which physicists view and use infinity:
Infinite Energy and Divergent Integrals:
In some physical theories, infinities can arise when trying to calculate quantities like energy. For example, in classical electromagnetism, the electric field of an infinite uniformly charged plane is infinite at the plane's surface. Physicists have developed techniques like renormalization to deal with these infinities and make meaningful predictions.
Gravitational Singularities:
In the theory of general relativity, which describes the gravitational force, there are solutions known as singularities. Black hole singularities, such as the one at the center of a black hole, are often described as having infinite density and curvature.
Infinite Universes and Cosmology:
In cosmology, the study of the universe as a whole, the concept of infinity is encountered in various ways. The universe's size may be infinite (infinite expansion), or it may have a finite size but no boundary (a closed universe). The Big Bang singularity is often described as an infinitely dense and hot state from which the universe expanded.
Infinite Quantum States:
In quantum mechanics, the mathematical formalism involves infinite-dimensional vector spaces. Particles such as electrons are described by wave functions that exist in these infinite-dimensional spaces, allowing them to occupy an infinite number of quantum states.
Limits and Asymptotic Behavior:
In many physical theories, infinity is used in the context of limits and asymptotic behavior. For example, when studying the behavior of a system as it approaches very high energies or very small distances, physicists use the concept of infinity to describe how certain quantities diverge or become very large.
Infinity in Thermodynamics:
In thermodynamics, infinity can be used to describe idealized situations, such as an ideal gas with infinite temperature or an infinite heat reservoir. These idealizations are useful for making predictions and simplifying calculations.
Infinite Expansion of the Universe:
The expansion of the universe is described as an ongoing process, and the concept of an infinite universe is used to explain its expansion over vast distances and timescales.
It's important to note that while physicists use infinity as a mathematical tool to describe physical systems and make predictions, they are also aware that infinities in their equations often signal unresolved issues or limitations in current theories. In many cases, the concept of infinity may be replaced or modified when more advanced theories are developed to describe the fundamental nature of the universe. As such, physicists are continually working to refine their understanding of how infinity fits into the physical world.
Infinity (∞) is a concept in mathematics that represents an unbounded or limitless quantity or value. It is not a specific number but a symbol used to describe something that goes on forever without any finite limit. Infinity is used in various branches of mathematics, including calculus, set theory, and number theory, to represent the idea of an uncountable or unlimited quantity.
Here are some key points and mathematical concepts related to infinity:
Infinity in Calculus:
In calculus, infinity is often used to describe limits. For example, when you take the limit of a function as it approaches a certain value, it may approach infinity if the function grows without bound.
Infinite Series:
Infinite series is a sum of an infinite sequence of numbers. For example, the sum of all positive integers (1 + 2 + 3 + 4 + ...) is said to be infinite (∞).
Infinity in Set Theory:
In set theory, infinity is used to describe infinite sets. The set of natural numbers (0, 1, 2, 3 ...) is an example of an infinite set.
Extended Real Numbers:
In the extended real number system, infinity is treated as a valid mathematical concept. It is used to represent values that are unbounded in both the positive and negative directions. For example, in this system, you might have positive infinity (+∞), negative infinity (-∞), and arithmetic operations involving infinity.
Limits and Asymptotes:
Infinity is often used to describe limits and asymptotic behavior in mathematics. For instance, in the study of functions, you might encounter vertical asymptotes, which are lines approaching infinity.
Cardinality and Infinite Sets:
Georg Cantor, a mathematician, made significant contributions to the study of infinite sets and their cardinalities. He introduced the concept of different sizes of infinity, such as countable infinity (the size of the set of natural numbers) and uncountable infinity (the size of the real numbers).
Transfinite Numbers:
Transfinite numbers are used in set theory to describe different sizes of infinity. Aleph-null (β΅₀) represents the cardinality of countable sets, while larger transfinite numbers represent larger infinities.
It's important to note that while infinity is a useful mathematical concept, it's not a real number that can be used in ordinary arithmetic. Instead, it is a symbol representing the idea of limitless or unbounded quantities and is a foundational concept in many areas of mathematics.
Moreover, if we have to honour the constant speed of light (c), then we will have the natural right to honour the uniformity in the progression of time (t=T/360) too, as any additional condition imposed on the equation (on c) needs to be applicable to (T) too.
And in case of ideal value of wavelength, constancy for the speed of light (c) and uniformity for the progression of time (T) won't be disturbed.
But if the wavelength changes it's value, the value of time period (T) too would he changed - only if c is constant. And such change in wavelength would be considered due some external distortion - as an error - and not an ideal condition.
That is why time dilation is impossible, but it is rather wavelength dilation due to external influence that caused error in the wavelength.
So it is wavelength distortion than time dilation when wavelength distortions correspond to time distortion. It is more of distortion than dilation.
Hope you understand the essence of the post.
I have my published paper invalidating time dilation through other method though.
The significance in wavelength dilation is
Ξt = T/360 (for 1° phase shift)
- this invalidates time dilation.
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