Tuesday, November 15, 2011

The Virtual Universe


The Virtual Universe

An abstract of my theory:


“We are living in the same time in two universes: in a Real universe and in a Virtual universe” Adrian Ferent

In Quantum mechanics my theory explains: 'The amplitude of the wave is proportional with the speed of the particle: A =k*v" Adrian Ferent

TIME

The definition of time is one of the most complicated and most intensely debated in the field of natural philosophy.

Time, today is defined as the measure of movement according to an order of anteriority and posteriority (numerous motus secundum prius et posterius).

In general philosophers and scientists agree in this: that the notion of time contains three distinct ideas combined into one indivisible whole. The idea of succession, the idea that time implies continuity and the concept of time represents to us a certainty, a reality, the parts of which succeed each other in a continuous manner.

It is not so important here whether this reality is purely ideal, or is realized outside of us, for we are dealing only with the concept of time.

My question: how this reality that is purely ideal, is realized outside of us?

Philosophers and scientists are divided relating to the objectivity of the concept of time.

The ancient Greek materialists regard time as a being sui generis, independent of all created things and capable of surviving the destruction of them all.

Kant regards time as completely a creation of the knowing subject.

The abstract notion of a relation of aggregated positions between the states of consciousness constitutes the notion of psychological time.

Newton, identify time with the eternity of God.

The truth is time has been a major subject of religion, philosophy and science, but defining it in a non-controversial manner applicable to all fields of study has consistently eluded the greatest scholars.

My theory will explain time in a non-controversial manner applicable to all fields of study.

Einstein explained that if time and space is measured using electromagnetic waves, then due to the constancy of the speed of light, time and space become mathematically entangled together in a certain way, named Minkowsky space.

Two years after Einstein originally proposed the theory of special relativity, Minkowski, a former professor of Einstein, presented the idea of the spacetime coordinate system.

In physics spacetime is any mathematical model that combines space and time into a single continuum.

Spacetimes are the arenas in which all physical events take place; an event is a point in spacetime specified by its time and its place and is independent of any observer.

Spacetime is a four-dimensional coordinate system containing three spatial dimensions and one time dimension.

Einstein said that all of the consequences of special relativity can be derived from examination of the Lorentz transformations.

Here are couple consequences of special relativity:

Time dilatation - the time lapse between two events is dependent on the relative speeds of the observers' reference frames.

The twin paradox - a twin who flies off in a spaceship traveling near the speed of light; when he returns he discovers that his twin has aged much more rapidly than he has.

Length contraction - the dimensions of an object as measured by one observer may differ from the results of measurements of the same object made by another observer.

The inability for matter or information to travel faster than light.

The equivalence of mass and energy, E = mc2 – the energy content of an object at rest with mass m equals mc2.

Time dilatation

Time dilation is the phenomenon where two objects moving relative to each other (or even just a different intensity of gravitational field from each other) experience different rates of time flow.

Here are just a few ways we know time dilation actually takes place:

Clocks in airplanes click at different rates from clocks on the ground.

The Global Positioning System (GPS) has to adjust for time dilation. They have to be programmed to compensate for the time differences based on their speeds and gravitational influences.

In special relativity (far from all gravitational mass), clocks that are moving with respect to an inertial system of observation are measured to be running slower; this effect is described precisely by the Lorentz transformation.

Time dilation due to relative velocity between observers:

In the special theory of relativity, a moving clock is found to be ticking slowly with respect to the observer's clock.

This means the time measured by the clock:

t’ = t( 1 – v2 / c2 )1/2

t’ - the time measured by the moving clock

t - the time measured by the observer's clock

v - the relative velocity between the observer and the moving clock

c - the speed of light

The twin paradox

The twin paradox is an interesting thought experiment, involving two twins one of whom sets out on a journey into space and back. Because of the time dilation effect of relativity, the twin who left experiences a slowing down of time and will actually be much younger than the twin that stayed behind. The reason that this is considered a paradox is that Special Relativity seems to imply that either one can be considered at rest, with the other moving. It does, and it doesn't.

The confusion arises not because there are two equally valid inertial rest frames, but (here's the tricky part) because there are three. A lot of explanations of the twin paradox have claimed that it is necessary to include a treatment of accelerations, or involve General Relativity. The three inertial frames are 1) at-home twin 2) the going-away twin and 3) the coming-back twin. It doesn't make any difference that the last two are physically the same twin--they still define different inertial frames.

Length contraction

The length of an object in a moving frame will appear contracted in the direction of motion. The amount of contraction is calculated from the Lorentz transformation; the length is maximum in the frame in which the object is at rest.

l = l0( 1 – v2 / c2 )1/2

l - the length measured by the "other" observer

l0 - the length measured by the observers on reference frame

v - the speed of the object

c - the speed of light in a vacuum

If the object is moving horizontally, then it is the horizontal dimension which is contracted; there would be no contraction of the height of the object.

Time dilation due to gravitation

Gravitational time dilatation: in general relativity clocks at lower potentials in a gravitational field such as in closer proximity to a planet are found to be running slower.

Gravity feels strongest where spacetime is most curved, and it vanishes where spacetime is flat. This is the core of Einstein's theory of general relativity, which is often summed up in words as follows: matter tells spacetime how to curve, and curved spacetime tells matter how to move.

Gravitational time dilation is the effect of time passing at different rates in regions of different gravitational potential; the lower the gravitational potential, the more slowly time passes. The energy of gravitational potential (in joules) is given by mass (in kilograms) multiplied by height (in meters) multiplied by the strength of the gravitational field (in newtons per kilogram).

Because gravitational time dilation is manifested in accelerated frames of reference or, because of the equivalence principle in the gravitational field of massive objects.

The Principle of Equivalence says the gravitational field of the Earth is equivalent to a frame accelerated at g, so over a time t one builds up a velocity v = gt.

A common equation used to determine gravitational time dilation is derived from the Schwarzschild metric, which describes spacetime in the vicinity of a non-rotating massive spherically-symmetric object. The equation is:

t’ = t( 1 – 2GM / (rc2))1/2

t’ – the proper time between events A and B for a slow-ticking observer within the gravitational field

t - the coordinate time between events A and B for a fast-ticking observer at an arbitrarily large distance from the massive object

G – the gravitational constant

M – the mass of the object creating the gravitational field

My theory: Time a complex number

Complex numbers

We will use x and y for real variables and z for complex variables. For example, the equation z = x + yi is to be understood as saying that the complex number z is the sum of the real number x and the real number y times i. In general, the x part of a complex number z = x + yi is called the real part of z; while y is called the imaginary part of z.

We can use the xy-plane to display complex numbers. We'll even call it the complex plane when we use the xy-plane that way.

When we use the xy-plane for the complex plane C, we'll call the x-axis by the name real axis, and the y-axis we'll call the imaginary axis.

Real numbers are to be considered as special cases of complex numbers; they're just the numbers x + yi when y is 0, that is, they're the numbers on the real axis.

The absolute value (or modulus or magnitude) of a complex number z = x+yi is:

r = |z| = ( x2 + y2)1/2

By Pythagoras theorem r is the distance of the point representing the complex number z to the origin.

Polar or Trigonometric or Modulus-Argument forms.

Full polar form: z = r (cos(θ) + i sin(θ))

Polar form is where a complex number is denoted by the length (otherwise known as the magnitude, absolute value, or modulus) and the angle of its vector.

Euler's formula: z = r e

Time cannot be separated from the three dimensions of space, because the observed rate at which time passes for an object depends on the object's velocity relative to the observer and also on the strength of gravitational fields which can slow the passage of time.

The metric determines the geometry of spacetime, as well as determining the geodesics of particles and light beams. About each point (event) on this manifold coordinate charts are used to represent observers in reference frames.

The concept of spacetime combines space and time to a single abstract universe. Mathematically it is a manifold consisting of events which are described by some type of coordinate system. Three spatial dimensions and one temporal dimension are required. Dimensions are independent components of a coordinate grid needed to locate a point in a certain defined space.

An event indicates a physical situation or occurrence, located at a specific point in space and time. For example a cup breaking on the floor is an event; it occurs at a unique place and a unique time, in a given frame of reference.

In a Euclidian space the separation between two points is measured by the distance between the two points. A distance is purely spatial and is always positive. In spacetime, the separation between two events is measured by the interval between the two events, which takes into account not only the spatial separation between the events, but also their temporal separation.

A world line is a curve in spacetime which traces out the (time) history of a particle, observer or small object.

A time-like curve can be understood as one where the interval between any two infinitesimally close events on the curve is time-like.

You learned, we saw until now that time is a real number and has one dimension.

I considered time as a complex number having a real part and an imaginary part.

The real time is the time is the time in our universe; it is the time measured by your clock, by the atomic clocks…Einstein in the Relativity theory is using the real time.

The imaginary time is the clock of the Virtual (Imaginary) Universe.

How I came at this conclusion that time is a complex number?

The observed rate at which time passes for an object depends on the object's velocity relative to the observer and also on the strength of gravitational fields which can slow the passage of time. I defined this one the real time.

When the real time is changing the virtual (imaginary) time is changing too but in opposite direction, in the Virtual (Imaginary) universe.

My idea: when the time and the length of object are changing in our universe, like a conservation law in the Virtual universe the time and the length for that object will change in opposite direction.

I define time (the absolute time) as a complex number: z = x + yi

From Special Relativity we know:

x – is the real time in our Real universe

x = t( 1 – v2 / c2 )1/2

Nothing changed until now.

But the imaginary time:

y – is the imaginary time

y = t(v2 / c2 )1/2

How you can see the imaginary time is proportional with the energy of the object mv2 .

More speed, more energy has an object, a system in the Real universe, the real time will decrease and the imaginary time in the Virtual universe will increase. This means more Events will experience the object, the system in the Virtual universe.

The polar form of time: z = t (cos(θ) + i sin(θ))

Where cos(θ) = x / t this means: cos(θ) = t( 1 – v2 / c2 )1/2 / t = ( 1 – v2 / c2 )1/2

sin(θ) = y / t this means: sin(θ) = t(v2 / c2 )1/2 / t = (v2 / c2 )1/2 = v / c

|z| = ( x2 + y2)1/2 = t (1 – v2 / c2 + v2 / c2)1/2 = t

This means time as complex number: z = t(( 1 – v2 / c2 )1/2 + i(v2 / c2 )1/2)

The energy E = mc2

If e = 2( m v2 / 2) we have:

z = t((1 – e / E) 1/2 + i(e / E )1/2) this is time depending of energy.

If a = (e / E )1/2 we have:

z = t((1 – a2) 1/2 + ia)

Now we can write the equation of time t as a complex number:

t = t0*((1 – a2) 1/2 + i*a)

t0 – is the absolute time; a = v / c


From General Relativity we know:

t’ = t( 1 – 2GM / (rc2))1/2

My theory: time is a complex number: z = x + yi

x – is the real time in our Real universe

x = t( 1 – 2GM / (rc2))1/2

y – is the imaginary time

y = t( 2GM / (rc2))1/2

The polar form of time: z = t (cos(θ) + i sin(θ))

Where: cos(θ) = x / t this means: cos(θ) = t( 1 – 2GM / (rc2))1/2 / t = ( 1 – 2GM / (rc2))1/2

sin(θ) = y / t this means: sin(θ) = t( 2GM / (rc2))1/2 / t = ( 2GM / (rc2))1/2

z = t(( 1 – 2GM / (rc2))1/2 + i( 2GM / (rc2))1/2)

The lower the gravitational potential, the more slowly time passes in the Real universe, but in the Virtual universe the time passes faster. This means more Events will experience the object, the system in the Virtual universe.

The formula for the escape velocity from a spherical object like a moon, planet, or star, is

v2 = 2GM/r

This means: z = x + yi

x = t( 1 – 2GM / (rc2))1/2 = t( 1 – v2 / c2 )1/2

y = t( 2GM / (rc2))1/2 = t(v2 / c2 )1/2

The principle of equivalence say gravitation is (locally) equivalent to acceleration; higher gravitation means higher acceleration, means higher speed what means higher energy.

Now I can explain the Twin paradox: for the twin who experience the acceleration and high speed the time runs slower (time dilation).

My theory is important for quantum mechanics where the particles have high speed.

Because we have a Virtual time we have a Virtual space, a Virtual universe:

I define length a complex number: z = r (cos(θ) + i sin(θ))

From Special Relativity we know:

The real length, real dimension: l = l0( 1 – v2 / c2 )1/2

Where: r = l0

cos(θ) = l0( 1 – v2 / c2 )1/2 / l0 = ( 1 – v2 / c2 )1/2

sin(θ) = l0( v2 / c2 )1/2 / l0 = ( v2 / c2 )1/2

In the same way we have length as complex number:

The equation of space:

‘ l = l0*((1 – a2) 1/2 + i*a) where l0 – is the absolute length; a = v / c ‘ Adrian Ferent

More speed, energy has an object, a system in the Real universe, the real length will decrease and the imaginary length in the Virtual universe will increase. This means more Events will experience the object, the system in the Virtual universe.

Mass as a complex number in my theory:

m = mr + mi = m0( 1 / ( 1 – v2 / c2 )1/2 + i( – v2 / c2 )1/2 / ( 1 – v2 / c2 )1/2)

mr – the real mass

mi – the virtual mass

m = m0( 1 / ( 1 – v2 / c2 )1/2 – (v / c) / ( 1 – v2 / c2 )1/2)

This means the virtual mass is a negative mass and this is a proof for Dark energy.

In theoretical physics, negative mass is a hypothetical concept of matter whose mass is of opposite sign to the mass of the normal matter.

Newton's law of universal gravitation: every point mass in the universe attracts every other point mass with a force that is directly proportional to the product of their masses and inversely proportional to the square of the distance between them.

But if one object has negative mass, the objects with negative mass M will be repelled by the object with positive mass m:

F = - G(M*m)/r^2

where r as the distance between the two objects and G as the gravitational constant.

I can say this negative mass is the source for the Dark energy.

Dark energy is a form of energy that permeates all of space and tends to accelerate the expansion of the universe (Nobel Prize this year).

Dark energy currently accounts for 73% of the total mass-energy of the universe.

I can fly to planet Jupiter in less than 1 hour:

My equation is very important:

m = m0( 1 / ( 1 – v2 / c2 )1/2 – (v / c) / ( 1 – v2 / c2 )1/2)

m = m0 ( 1 – v / c) / ( 1 – v2 / c2 )1/2

m = m0 ( 1 – v / c )1/2 / ( 1 + v / c )1/2

This equation is very important because is the first proof that we can travel close to the speed of light.

All the theories until now explained that close to the speed of light the mass of the spaceship, rocket ship… will be infinite.

My equation demonstrates that close to the speed of light the mass of the spaceship will be close to zero. The secret is this equation connecting the mass and the negative mass.

That is why the UFOs can move in any direction very fast; it is a lot of Dark energy in the universe.

This means I can fly to planet Jupiter in less than one hour.

I can proclaim myself the owner of the planets Mars, Jupiter, Neptune…because I discovered the way to go there.

Time travel

With my equation I am certain that time travel to the future is possible.

It might come as a surprise to you that traveling forward in time is easier than back in time.

Of course, getting to the future by high speed space travel does not require the future to be already out there waiting for you. What it means is that you move out of everyone else’s time frame and into one in which time moves more slowly.

To you, time is going by at its normal rate on the rocket and if you were able to look out of the window you would, paradoxically, see the time outside going by more slowly!

So your rocket clock, traveling to Jupiter at very high speed, had measured two hours while all Earthbound clocks had counted off forty years.

How can this be? Can time really slow down inside your rocket due to its high speed? If so, this means that, for all intents and purposes, you will have leapt forty years into the future!

While you are in this state, time outside is ticking by more quickly and the future is unfolding at high speed. When you rejoin your original time frame you will have reached the future more quickly than everyone else.

This means after two hours flight to Jupiter you will find your children older than you!

Conclusions:

We are living in 2 universes: the Real universe and the Virtual universe.

Until now you learned only about the Real universe because the science defines only the real time and the real space.

The equation of time:

‘ t = t0*((1 – a2) 1/2 + i*a) where: t0 – is the absolute time; a = v / c ’ Adrian Ferent

Your clocks, the atomic clocks…show the real time.

My theory is important for quantum mechanics where the particles have high speed.

We are moving between buildings. When we are inside a big church, inside a pyramid… we experience a lower gravitational potential and the more slowly time passes in the Real universe, but in the Virtual universe the time passes faster. This means more Events will experience the object, we as a system in the Virtual universe.

Now you understand why people in the past built big temples, churches…because they ‘felt’, they ‘realized’ that the gravitational potential influence the time flow and the number of Events experienced by them. They experienced more Events: in the Virtual universe.

That is why the saints were living in caves to experience more spiritual Events in the Virtual universe.

From here we can come to a huge number of conclusions related to religions, to spirituality, afterlife…

The time has been a major subject of religion, philosophy and science, but defining it in a non-controversial manner applicable to all fields of study has consistently eluded the greatest scholars.

With my theory I am certain that time travel to the future is possible.

My theory explains time in a non-controversial manner applicable to all fields of study.


Friday, October 21, 2011


Quantum consciousness

An abstract of my theory:

‘When a consciousness state will become certitude, it will be a consciousness qubit in the higher plane of our consciousness’ Adrian Ferent

The correlations between system and environment are the mechanism behind the process, the development…

Intuitive experiences often address questions relating to the meaning and purpose of life. But the experiences are private and unique; although different individuals may have similar experiences, each has his own separate experience which is difficult to put into words and describe to another. It is this privateness, this inaccessibility to public scrutiny that is the weakness of intuitive knowledge.

How many puzzles you solve is not as important as how many you enjoy thinking about.

The nature of consciousness can not be sufficiently understood within the framework of classical physics but must be sought within the alternative representation of physical reality provided by quantum mechanics.

If you stretch a string and pluck it, it produces a tone having a pitch related to its first mode (pattern) of vibration. If you divide the string into two or three equal parts, the string produces tones that are harmonious with the first tone because their pitches are

related to the second and third patterns of vibration of the string, respectively. This simple discovery had a profound effect on Pythagoras of Samos and his followers. It was an unexpected but profound connection between numbers and nature, and it led Pythagoras to conclude that there is a harmony in nature. Nature he thought is commanded by numbers.

The scientists have argued that the subjective, phenomenal states that make up the life of the mind are intimately linked to the information expressed at that time by the brain.

Science seeks to understand the physical world from which sensory data originate. It seeks to find a relatively few laws and general principles through which the broad range of phenomena can be understood. To facilitate this understanding, science uses the laws to create models of reality.

The quantum consciousness theory proposes that classical mechanics cannot explain the consciousness, while quantum mechanical phenomena, such as quantum entanglement and superposition can play an important part in the brain's function, and could form the basis to explain the consciousness.

Quantum phenomena have some remarkable functional properties, such as nondeterminism and nonlocality.

The amount of integrated information that an individual possesses corresponds to its level of consciousness.

In the holistic nature of quantum mechanics and the phenomenon of entanglement, particles that have interacted continue to have their natures depend upon each other even after their separation. This model is explaining the coherence of consciousness, but also can be invoked as a more general challenge to the atomistic conception of traditional physics according to which the properties of wholes are to be explained by appeal to the properties of their parts plus their mode of combination.

Entanglement is a nonlocal property that allows a set of qubits to express higher correlation than is possible in classical systems.

The states in which a qubit may be measured are known as basis states (or basis vectors).

A qubit or quantum bit is the analog of a bit for quantum computation. Different than an ordinary bit which has two possible values called 0 and 1, a qubit may assume values of the form a|0 + b|1 where a and b are arbitrary complex numbers satisfying |a|2 + |b|2 = 1.

Mental events are a `prior level' of `implicit events' whose operation is needed in order to produce the potentialities for physical events.

Consciousness is exercising top level control over neural excitation in the brain.

Brain acts as a quantum computer and that quantum coherence is related to consciousness in a fundamental way.

Consciousness states are highly differentiated; they are informationally very rich. This information is highly integrated.

It basically explains the unity of consciousness,

Evolution favors higher consciousness evolution

A quantum system is moving from a superposition of multiple possible states to a single definite state, without the intervention of an observer or measurement.

Conscious systems and conscious mental states both involve many diverse forms of unity.

To make precise quantitative statements about nature, we must define the concept of probability in a quantitative way. Consider an experiment having a number of different possible outcomes or results. Here, the probability of a particular result is simply the expected fraction of occurrences of that result out of a very large number of repetitions or trials of the experiment. Thus one could experimentally determine the probability by making a large number of trials and finding the fraction of occurrences of the desired result.

The probability of a particular event is the ratio of the number of ways this event can occur, to the total number of ways o/l possible events can occur.

The probability of an event that is certain is equal to 1.

In the absence of any contrary information, equivalent possibilities may be assumed to have equal probabilities.

A probability space is a measure space such that the measure of the whole space is equal to one.

A bit is the basic unit of computer information. Regardless of its physical realization a bit always have two states 0 or 1.

The qubit has some similarities to a classical bit but is very different. Like a bit a qubit can have two possible values, a 0 or a 1. The difference is that whereas a bit must be either 0 or 1, a qubit can have the values 0, 1, or a superposition of both.

In a classical computer a bit would have to be in one state(0) or the other(1), but quantum mechanics allows the qubit to be in a superposition of both states at the same time, a property which is fundamental to quantum computing.

The qubit state is a linear superposition of the basis states. This means that the qubit can be represented as a linear combination of form |0 and |1:

|ψ› = a|0 + b|1

where a and b are probability amplitudes and both are complex numbers..

When we measure this qubit in the standard basis, the probability of outcome |0 is |a|2 and the probability of outcome |1is |b|2. Because the absolute squares of the amplitudes equate to probabilities, it follows that a and b must be constrained by the equation:

|a|2 + |b|2 = 1.

because this ensures you must measure either one state or the other.

Bloch sphere is the representation of a qubit.

The north and south poles of the Bloch sphere are chosen to correspond to the standard basis vectors |0› and |1›.

The pure states of the system correspond to the points on the surface of the sphere; the interior points correspond to the mixed states.

Between a qubit and a classical bit an important distinguishing feature is that multiple qubits can exhibit quantum entanglement. And entanglement is a nonlocal property that allows a set of qubits to express higher correlation than is possible in classical systems.

When multiple qubits exhibit quantum entanglement, each qubit is in this state it can be thought of as existing in two universes, as a 0 in one universe and as a 1 in the other. Any operation on such a qubit in fact acts on both values at the same time. The major point being that by performing the single operation on the qubit, we have performed the operation on two different values. Similarly a two-qubit system would perform the operation on 4 values, and a three-qubit system on eight values.

A quantum state is a set of mathematical variables that fully describes a quantum system; a quantum state of a system characterized by a set of quantum numbers and represented by an eigenfunction.

The state of the system is represented by a single vector known as a ket.

In any vector space if a basis is chosen for the Hilbert space of a system, then any ket can be expanded as a linear combination of those basis elements.

The energy of each state is precise within the limits imposed by the uncertainty principle but may be changed by applying a field of force.

That is why different quantum states for a physical system show discrete differences in the value of the variables used to define the state. The spin of an isolated electron can take on one of only two values; there are no other quantum states available for the electron and no intermediate values, since spin is quantized. The quantum state is sometimes described by a set of quantum numbers that pick out the appropriate values for describing the state.

What is entangled is the observable of the system. An observable in quantum mechanics is represented typically by a Hermitian operator, and the system being entangled typically will produce an eigenvalue of the system.

Quantum mechanics predicts correlated outcomes in space-like separated regions for experiments using two-particle entangled states. Quantum correlations somehow reveal dependence between the events, or logical order.

The Law of Polarity states that opposites are really two extremes of the same thing.

Life is made of frequencies. Look at my wavefunction:

‘I am a WAVE and the wave function is:

|ψ> = c1 |Φ1> + c2|Φ2> + c3|Φ3> + c4|Φ4> + c5|Φ5> + c6|Φ6> + c7|Φ7>

are 7 states |Φi > because are 7 major chakras or energy centers.’ Adrian Ferent

There is neither good nor evil; there is only wisdom and ignorance.

Matthew 5:45

‘So that you will become children of your Father in heaven, because he makes his sun rise on both evil and good people, and he lets rain fall on the righteous and the unrighteous.’

I consider the consciousness a probability space and the measure of the whole space is equal to one and because of the consciousness polarity I will define the qubit of consciousness and the consciousness states keeping the analogy with the qubits and the quantum states from quantum mechanics.

I define a qubit of consciousness as an event in our life.

The quantum state-vector corresponds more or less directly to whatever exists in reality, and that it is in fact all that exists in reality.

What is in the present state of human consciousness appears to have two poles the positive and negative poles, good and evil, heaven and hell, life and death, light and darkness, day and night, white and black, South and North, peace and war, yes and no, positive and negative, etc.

In everything there are two poles, or opposite aspects, and opposites are really only the two extremes of the same thing.

To represent the state of an n-qubit consciousness system on a classical computer would require the storage of 2ncomplex coefficients. Although this fact may seem to indicate that qubits can hold exponentially more information than their classical counterparts.

If you measure the three consciousness qubits, you will observe a three-bit string. The probability of measuring a given string is the squared magnitude of that string's coefficient ( the probability of measuring 000 = |a|2 , the probability of measuring 001 = |b|2 etc.). Measuring a consciousness quantum state described by complex coefficients (a,b,...,h) gives the classical probability distribution ( |a|2, |b|2,…, |h|2 ) and we say that the consciousness quantum state collapses to a classical state as a result of making the measurement(the event happened in your life).

For example an eight-dimensional vector can be specified in many different ways depending on what basis is chosen for the space. The basis of bit strings (e.g., 000, 001,…,111) is known as the computational basis.

Here is an example, the state ( a.b,c,d,e,f,g,h ) in the computational basis can be written as:

a|000› + b|001› + c|010› + d|011› + e|100› + f|101› + g|110› + h|111

where: |011= ( 0. 0, 0, 1, 0, 0, 0, 0 )

The mathematical formalism of quantum theory provides an algorithm for computing the probabilities of outcomes of measurements made in experiments.

For example before a quantum object is measured, it does not have definite characteristics. Instead, it exists in a superposition of multiple mutually contradictory states—allowing it to be in two places at once.

‘When a consciousness state will become certitude, it will be a consciousness qubit in the higher plane of our consciousness’ Adrian Ferent

When a consciousness state will become certitude?

When an event is repeating in your life and you will understand it, this means ‘we learned the lesson’ and we will move to a higher plane of consciousness, with more consciousness qubits and more consciousness states with higher value, with higher quality…

People with higher consciousness will have more consciences qubits and more consciousness states.

‘Our evolution level is our consciousness level’ Adrian Ferent

If you have N consciousness qubits in the higher consciousness plane you will have 2N consciousness qubits.

Because of evolution (another proof for my evolution theory) here on earth people have less consciousness qubits and less consciousness states than those who are in heaven.

That is why Jesus said:

Mathew 11:11 ‘I tell you the truth: Among those born of women there has not risen anyone greater than John the Baptist; yet he who is least in the kingdom of heaven is greater than he.’

Because John the Baptist had at that time less consciousness qubits and less consciousness states than those who are in the kingdom of heaven.

‘A saint has enough consciousness states to answer to everybody’s prayer’ Adrian Ferent

‘God has enough consciousness states to answer to every consciousness in the Universe’ Adrian Ferent

Friday, April 22, 2011

Special theory of relativity: space and time quantization

An abstract of my theory:

Special relativity is the theory of measurement in inertial frames of reference proposed in 1905 by Einstein.

In his initial presentation in 1905 he expressed these postulates:

The Principle of Relativity – The laws by which the states of physical systems undergo change are not affected, whether these changes of state be referred to the one or the other of two systems in uniform translatory motion relative to each other.

The Principle of Invariant Light Speed – "... light is always propagated in empty space with a definite velocity [speed] c which is independent of the state of motion of the emitting body." (from the preface). That is, light in vacuum propagates with the speed c (a fixed constant, independent of direction) in at least one system of inertial coordinates (the "stationary system"), regardless of the state of motion of the light source.

The special theory of relativity is contained in the postulate:

The laws of physics are invariant with respect to Lorentz transformations (for the transition from one inertial system to any other arbitrarily chosen inertial system).

The special theory of relativity has a wide range of consequences which have been experimentally verified such as length contraction and time dilatation.

For simplicity, we will restrict consideration motion in one direction.

Observers are simply people or instruments capable of making and recording measurements.

Length contraction

The length of an object in a moving frame will appear contracted in the direction of motion. The amount of contraction is calculated from the Lorentz transformation; the length is maximum in the frame in which the object is at rest.

l = l0( 1 – v2 / c2 )1/2

where: l = the length measured by the "other" observer

l0 = the length measured by the observers on reference frame

v = the speed of the object

c = the speed of light in a vacuum ( c = 2.99792458 × 108 m s−1 )

If the object is moving horizontally, then it is the horizontal dimension which is contracted; there would be no contraction of the height of the object.

For example if a spaceship in motion has the speed v = 0.95c and l0 = 17.6 m (for you inside the spaceship), for an observer on earth the spaceship has l = 5.5 m.

Time dilatation

The time lapse between two events is not invariant from one observer to another but is dependent on the relative speeds of the observers' reference frames.

Consider a clock consisting of two mirrors A and B, between which a light pulse is bouncing. The distance between the mirrors is L and the clock ticks once each time it hits a given mirror.

In the frame where the clock is at rest the period of the clock:

Δt = 2L / c

From the frame of reference of a moving observer traveling at the speed v the light pulse traces out a longer, angled path, the period of the clock:

Δt’ = Δt / ( 1 – v2 / c2 )1/2

This means for the moving observer the period of the clock is longer than in the frame of the clock itself.

Planes travel about a million times more slowly than c but atomic clocks are very precise and so this tiny effect can actually be measured.

The twin paradox: there are two twin brothers. On their thirtieth birthday, one of the brothers goes on a space journey in a rocket that travels at 99% of the speed of light. The space traveler stays on his journey for precisely one year, whereupon he returns to Earth on his 31st birthday. On Earth seven years have elapsed, so his twin brother is 37 years old at the time of his arrival.

Space and time quantization

I formulated a postulate in Special theory of relativity: in any frame of reference the Planck constants are the same.

This means for the frame of reference at rest and for the frame of reference moving with the speed v, the Planck length and the Planck time are the same.

This means in any frame of reference a spaceship can not travel in time less than the Planck time and in space can not move less than the Planck length.

Length contraction

Because any system can not attain the speed of light:

l = l0( 1 – v2 / c2 )1/2 and l > lP

Planck length lP = 1.6162 × 10−35 m

This means l0( 1 – v2 / c2 )1/2 > lP

Time dilatation

Because the period of the clock

Δt’ = Δt / ( 1 – v2 / c2 )1/2

This means the time measured by the clock:

t’ = t( 1 – v2 / c2 )1/2 and t’ > tP

Planck time tP = 5.39124 × 10−44 s

This means t( 1 – v2 / c2 )1/2 > tP