Friday, May 25, 2012

What Is Gravity


One of the problems with gravity is that no one knows how it is constructed. Gravity appears to us as a weak force. The function of gravity in our space-time world is to keep things in place in space, yet allow us to move around without expending undue amounts of energy. This is the reason that in our space based world gravity is weak in comparison to other forces. We know that large objects such as the earth bend space and that action increases the pull of gravity in that location. Large objects such as the earth also shorten time. Time is the only force that travels outward in one direction. Let's suppose that when a large mass such as earth travels through a field called space, that it also causes time to shorten. This shortening of time causes time to form a spiral called time torsion. This happens because time wants to travel in a straight direction but it can only do so if it spirals which causes time torsion. This time torsion or springiness is what you and I experience as gravity. When the earth moves on in its' orbit, the time torsion returns to normal and the gravity disappears.

In summary:


  1. A mass bends / flexes space which is a field.

  2. A mass twists time causing torsion because time wants to travel in a straight line.

  3. We see that time torsion as gravity.

The quantum world is the reverse of the real world. Space only exists as a marker. In the quantum world we think of space as right here or over there. We can't travel through space in the quantum world to get from here to there because space doesn't physically exist in the quantum world. The quantum world is based on energy and time and as such could be called an energy-time world . We could consider that an energy-time world is energy at a certain time. Time in the quantum world involves the past, present and future. Quantum particles, as balls of energy, show all the states, possibilities and information at the same time. This process is called superposition and is equivalent to our being able to go anywhere at any time under all conditions in our real world of space. Another concept in the quantum world is something I call superlocation. Since space doesn't physically exist in the quantum world more than one thing can exist at the same spot or location. Time torsion functioning as quantum gravity in the quantum world is used to keep all the states, possibilities and information separate if more than one thing exists at the same superlocation. Time with different torsions surrounds all the individual states, possibilities and information keeping them all separate.

In summary:


  1. More than one thing can exist in the same physical space in the quantum world

  2. Time torsion surrounds each quantum particle's state, possibilities, and information at the same physical space in the quantum world.

  3. Time torsion is quantum gravity in the quantum gravity world.

Friday, May 18, 2012

Sum Of Prime Number Digits To One Digit


Prime numbers are numbers which can only be divided by themselves and the number ( 1 ). The first five ( 5 ) single digit prime numbers are ( 1, 2, 3, 5, 7 ). The total of the single digit prime number digit's are ( 1 + 2 + 3 + 5 + 7 = 18 ). For two digit prime numbers ( 11, 13, 17, 19 ) or one's over two digits like ( 137) you will find their digits will add to one of ( 1, 2, 4, 5, 7, 8 ). The sum of these digits are ( 1 + 2 + 4 + 5 + 7 + 8 = 27 ). You will notice for prime numbers over one ( 1 ) digit, that none of the single prime number digits total 3 or a multiple of 3. For the first five ( 5 ) single digit prime numbers ( 1, 2, 3, 5, 7 ), there is one even prime number ( 2 ) and ( 4 ) odd prime numbers. Since the total of the digits of single digit prime numbers are the same, you have more odd totals ( 4 ) than even ( 1 ) which is for the prime number 2. For prime numbers greater than one digit you have ( 3) even totals ( 2, 4, 8 ) and ( 4 ) odd ( 1, 3, 5, 7 ). Two researchers from the Institute of Mathématics of Luminy have recently made an important breakthrough regarding a conjecture formulated in 1968 by the Russian mathematician Alexandre Gelfond concerning the sum of digits of prime numbers. In particular, they have demonstrated that, on average, there are as many prime numbers for which the sum of digits is even as prime numbers for which it is odd. Since prime numbers may have different one digit totals that aren't in sequence, even though the prime numbers are linear they are probably correct on average ( 3 even one digit totals – 2, 4 8 ), ( 4 odd one digit totals – 1, 3, 5, 7 ).

Here's some more interesting stuff:
  1. Prime numbers, if they are prime numbers, have the numbers 1, 3, 7, 9 in column 0 ( farthest right column ).
  2. Except for prime number ( 3 ) , if the sum of the digits of any number ending in 1, 3, 7, 9, total a multiple of 3, ( for instance total 6, 9, 12, etc. ) it isn’t a prime number. If a number ending in 1, 3, 7, 9 in column zero (0), isn’t a prime number it can usually be evenly divided by a number with 1, 3, 7, 9 in column (0).
  3. The sum of the one digit prime's digits ( 1, 2, 3, 5, 7 ) total 18 ( 1 + 2 + 3 + 5 + 7 = 18 ). The sum of the more than one digit prime's digits ( 1, 2, 4, 5, 7, 8 ) total 27 ( 1 + 2 + 4 +5 + 7 + 8 = 27 ). 9 divides evenly into 18 ( 18 / 9 = 2 ) and evenly into 27 ( 27 / 9 = 3 ). 9 is the only number that isn't a prime digit that appears in column 0 ( far right column ) of a prime number.

Saturday, May 12, 2012

Cause & Effect In Quantum Time Is Sometimes Reversed


In our real world, everything has to do with space. Space has three dimensions. We can describe things in space as being right here or over there. If we see someone as we walk along, we can describe them as being behind us, beside us, or in front of us. In other words, each of us are familiar with the concept of space and can describe things as being in space in many ways. Time in our world is used as a marker which we see in clocks or as a time location in 3 dimensional space. To state the obvious, if I'm to meet you at a coffee shop I'd better know at what time. Our real world is essentially about space-time or space and time since we can move through space in all directions at any time. The quantum world is the reverse of the real world. Space is like time in our real world. Space only exists as a marker. In the quantum world we think of space as right here or over there. We can't travel through space in the quantum world to get from here to there because space doesn't physically exist in the quantum world. Time in the quantum world involves the past, present and future. Quantum particles show all the states, possibilities and information at the same time. This process is called superposition and is equivalent to our being able to go anywhere at any time under all conditions in our real world of space. Another concept in the quantum world is something I call superlocation. Since space doesn't physically exist in the quantum world more than one thing can exist at the same spot or location. This is equivalent in the real word to being able to build something like a house at the same location using different materials. Travel in the quantum world is done through a process called entanglement, because the quantum world can't move through physical space because physical space doesn't exist . If I have a quantum particle here and another particle over there, I can entangle my particle with the other particle to make both particles have the same states, possibilities, and information at the same time. This process of entanglement of two quantum particles also involve quantum time being in the present, past, and future and moving between the present, future and past.

This is how it works but it gets confusing:

  1. Alice has a quantum particle which is in the present.
  2. Alice entangles her present quantum particle with another quantum particle that is in the present now, but it travels to the future during the entanglement procedure through quantum time since physical space in the quantum world is non-existent. This happens because entanglement takes time which can only be used by traveling from the present to the future because physical space in the quantum world is non-existent.
  3. Alice's future entangled particle is given to Victor. The entangled particle is in the present as far as Victor is concerned because he received the entangled particle now.
  4. Alice's original quantum particle is now in the past.

Bob goes through the same procedure and gives his entangled particle to Victor. Both Bob's and Alice's original quantum particles are now moved to the past and Bob and Alice's entangled quantum particles being held by Victor are in the present. Bob and Alice's entangled particles now held by Victor in the present are the effects of the original entanglement. So far so good. We have Bob and Alice's original quantum particles in the past and they are the cause. If Victor, who has Alice and Bob's separately entangled quantum particles in the present, measures Alice's and Bob's separately entangled quantum particles without causing entanglement, Alice and Bob's original quantum particles don't change while in the past thereby adulterating history. If Victor, who has Alice and Bob's separately entangled quantum particles in the present, measures Alice's and Bob's separately entangled quantum particles causing entanglement, Alice and Bob's original quantum particles change while in the past adulterating history. Thus the cause in the present quantum time world has created an effect in the past and thereby altered history. In our real world, which is space centered location the cause always precedes the the space location of the effect. The cause in our space centered real world if in the past has an effect on the present and future. If the cause is in the present the effect is in the future. In a quantum world which is time centered, cause can alter effect which is in the past.

In summary:

  1. Bob goes through the same procedure that Alice went through.
  2. Quantum Time has no physical space, so when you finish doing something you move it into the past.
  3. Bob moves his original quantum particle into past quantum time.
  4. Alice's and Bob's entangled quantum particles are given to Victor who is in the quantum time present.
  5. When Victor measures the entangled quantum particles showing all states, possibilities, information one state, possibility, information is arbitrarily chosen.
  6. If Victor measures the entangled quantum particles without entangling them, then one state, possibility, information also appears in the original quantum particles that are in the quantum time past.
  7. If Victor measures the entangled quantum particles and also entangling them, then one different state, possibility, information appears in the original quantum particles that are in the quantum past.
  8. This entanglement alters the quantum time history.
  9. Here's the tricky part. Alice and Bob's original quantum particle was the cause and when the entangled quantum particles were created, they were the effect.
  10. Alice and Bob's original quantum particle was moved to the quantum time past and is still the effect. So far so good.
  11. When Victor measured the Alice and Bob's separately entangled quantum particles and entangled them he created a cause that altered quantum time history.
  12. Here's the tricky part. Since Alice and Bob's quantum time particles were located in the past, Victor altered the original effect with a cause located in the present.
  13. Thus a cause located in the present caused an effect that was located in the past.
  14. In our space centered real world the location of the cause always precedes the location of the effect. Since the location of the cause was in the quantum world present, it did not precede the location of the effect which was in the quantum world past.



Friday, May 04, 2012

A Quantum Solution For The Riemann Hypothesis


The Riemann Hypothesis equation is constructed for our 4 dimensional world in which space is the prime criteria. The thrust of the Riemann Hypothesis is to prove that all the zeros lie on the line ( y = ½ ) and if they do there is some relationship to zeros, primes and energy. Maybe if we took a look at the Riemann hypothesis from a quantum viewpoint we can resolve it.

The quantum world is all about energy-time. The energy in the quantum world shows all the states , possibilities or information at one spot or superlocation at the same time because physical space doesn't exist. It exists in the abstract in as much as we can say something is right here or over there but we can't travel through space because it doesn't exist.

The universe is built on the number 3. What this means is that when we consider a welter of possibilities most decisions come down to:

  1. Yes – 1
  2. No – 0
  3. Maybe – ½ .

In the case of the Riemann hypothesis since quantum energy shows all the states, possibilities or information the zero is always ( yes – 1 ), no ( no – 0 ) or Maybe ( ½ ) in the same superlocation since space doesn't physically exist except in the abstract.

Riemann used the formula ( s = ½ + it ) in his real world formula. The “i” in “it” represented the imaginary space dimension. In electronic formulas the “i” represents time ( -1 ). In the quantum world we only have energy and not space because space doesn't physically exist except in the abstract. Time in the quantum world has the energy value of 9 since space doesn't exist. Riemann said the zeros have something to do with the oscillation of the primes around their expected ( superlocation ) position. Riemann said that the zeros lie on the line ( y = ½ ) in the real world where space is the primary criteria. In the quantum world the primary criteria is all states, possibilities or information.

Combining all quantum realities, states or information in the quantum world we arrange the quantum energy levels by using the digits ( ½ , 0, 9 ) as a multiplier . ( ½ ) means Maybe. Maybe the prime is in that superlocation. ( 0 ) is Riemann's zero ( 0 ) which is in the same superlocation. ( 9 ) is the quantum value of time in that superlocation.

Here's how it works with primes using quantum time = 9.

  1. 1 X .99 = .99 – Location ( 1 )
  2. 2 X .99 = 1.98 – Location ( 2 )
  3. 3 X .99 = 2.97 - Location ( 3 )

Using the digits ( ½ , 0, 9 ) this is how it works:

  1. 5 X ( .509999 ) = 2.549995 – Location (4)
  2. 7 X ( .509999 ) = 3.569993 – Location ( 5 )
  3. 11 X ( .509999 ) = 5.609989 – Location ( 6 )

This basic principle calculates the position of the primes fairly accurately up to prime 31.

Using the same multipliers on the next prime ( 37 ) we get ( 37 X .509999 = 18.869963. Prime ( 37 ) is actually the 13th prime. Riemann said that the zeros can be manipulated ( positions changed or zeros added ). If we take ( .509999 ) and multiply it by itself ( ( .509999 X .509999 = .26009898 ).

  1. ( 37 X .509999 X .509999 = 9.62366226 ( 13 )

This calculation shows that the calculated position is short of the true position by about ( 13 – 9.62366226 = 3.37633774 ). The difference is approximately equal to Pi ( 3.141592654 ). In some calculations the difference is about the natural number ( e ) ( 2.71828`828 ).

In summary, Riemann's intuition told him that the zeros had a real value of ( ½ ) which was true since the digit ( ½ ) is used in the calculation. ( ½ ) in the quantum world is maybe and is a quantum constant. ( 9 ) in the quantum world is the quantum value of time and is a constant. ( 0 ) in the quantum world is a variable because although it appears as a constant, its' digital position can be changed and hence ( 0 ) is a quantum variable. Riemann's intuition also told him that the zeros can be manipulated ( position changed or zeros added ) which is also true. What Riemann missed was that the calculation involved the number 9 and that Pi ( 3.141592654 ) and the natural number ( e ) ( 2.718281828 ) might have to be added or subtracted from the final answer. Riemann also missed that powers would also have to be used.

In general for calculating the location of any prime you:

  1. Count the number of digits in a prime number. For instance 7919 has 4 digits. Subtract 1 from the number of digits ( 4 - 1 = 3 ) for 7919. Form another number equal to the number of digits in 7919 ( 4 ) by putting ( .5 ) in the far left column and 9 in the far right column. ( .5—9 ). Fill the middle with Riemann Hypothesis zeros ( 0 ) forming a four digit number ( .5009 ). Raise ( .5009 ) to the power of 3 ( which is the number of digits in 7919 ( 4 ) minus 1 ( 4 - 1 = 3 ). ( .5009 ) ^ 3 = .125676215. Multiply 7919 X .125676215 which equals 995.2299524. 7919 is the 1000th prime. If you add Pi ( 3.141592654 ) to 995.2299524 you get ( 998.3715451 ) which is ( 1000 – 998.371545 = 1.628454946 ) short of 1000.