The Secret of the Universe [2008] Slides 1 of 2

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Written Content (C) 2008 Jeremy Stride

	Slide 1 Coral Castle
	Slide 2 Edward Leedskalnin knew the secrets of the ancient builders. The secret of all secrets.
	Slide 3 Let's see what clues Ed has left behind for us.
	Slide 4 The word admission has been shortened by Edward Leedskalnin to three letters - ADM.
	Slide 5 ADM, when reduced to numbers, gives a result of 144.
	Slide 6 A = 1, D = 4, M = 4.
	Slide 7 The number 144 is the most important number with respect to how this technology functions.
	Slide 8 The cutaway at the top, the potision of the 144 (ADM), and the DROP BELOW point are all precise, deliberate clues.
	Slide 9 Edward Leedskalnin left these clues so that the solution could be rediscovered one day.
	Slide 10 Where are the clues?
	Slide 11 Just as incredible, I have found another source of precisely the same information.
	Slide 12 The secrets of magnetism are on these walls.
	Slide 13 It's them freemasons.(The Grand Lodge, Philadelphia - Norman Hall Room)
	Slide 14 Clues at Coral Castle
	Slide 15 This is a rotating wheel of magnets. We call it the flywheel.
	Slide 16 It is part of the actual decide that Ed built and used to nullify the weight of enormous stones.
	Slide 17 The flywheel consists of U-shapped magnets divided into 24 parts.
	Slide 18 The position of everything in it becomes very interesting once we understand some of the clues.
	Slide 19 The shape of a hexagram, The Star of David, is all over Coral Castle.
	Slide 20 Outside the front, above the bathrub, and in the water.
	Slide 21 From a technical, constructive perspective, these are the six points we are interested in.
	Slide 22 You can see them here.
	Slide 23 We find this same star pattern in the center of the flywheel itself.
	Slide 24 The "star" is covered in the magnetic fields of the 24 magnets surrounding it.
	Slide 25 The poles of all the magnets are bent so that they point outwards.
	Slide 26 This means that there are 24 North Poles, and 24 South Poles, pointing outwards.
	Slide 27 This gives us a total of 48 streams of 'magnets' pointing outwards from the star.
	Slide 28 There are exactly 48 streams of 'magnets' around this star.(Please, count them!)
	Slide 29 Both North and South magnetism is shown by the two variations. (24 of each.)
	Slide 30 These 'individual magnets' as Leedskalnin would call them, are depicted exactly like this in his book, 'Magnetic Current'.
	Slide 31 We can take this symbolism in the temple much, much further.(Just in case you had any doubts.)
	Slide 32 The book 'Magnetic Current', written and published by Edward Leedskalnin in 1945, shows the way 'magnets' travel in a wire.
	Slide 33 It's those beads of magnetism.
	Slide 34 Outside the front of Coral Castle, a large sign greets visitors.
	Slide 35 The sign has a drawing of the sun with 16 points.
	Slide 36 Just above the star...
	Slide 37 Now it's really a party!
	Slide 38 The 16-fold pattern can be generated by the star.This is the patern we need to interact with! (Using a pyramid shape)
	Slide 39 Note: This is a masons Level.
	Slide 40 We don't have to go far. It's on the same sign, with the sun. Another clue.
	Slide 41 RING BELL.
	Slide 42 Ring it twice.
	Slide 43 Notice how the drop point is at the bottom part of the star.
	Slide 44 Incredible. Clues are hidden in the alignment.
	Slide 45 In short, the Norman Hall room at the Grand Masonic Lodge in Philadelphia is dedicated to this great secret.
	Slide 46 Just like Coral Castle.
	Slide 47 Now that cat's really out of the bag.(I hope those masons with the funny hats don't mind...)
	Slide 48 ...and the roof is covered in pyramids, but first...
	Slide 49 The Numbers
	Slide 50 Engraved on a wall at Coral Castle, Edward Leedskalnin left another clue.
	Slide 51 This is the most important clue at the entire site.
	Slide 52 7129 6105195
	Slide 53 7129 6105195. Many have theorized.
	Slide 54 For the first time anywhere, I will show you exactly what these numbers mean, and how they apply to the Secret of the Universe.
	Slide 55 7129 6105195. These are two separate , but related sets of numbers.
	Slide 56 The initial answers can be found in prime numbers.
	Slide 57 The solution also related to:The Golden Ratio, Phi (1.618), The Square Root of Phi (1.272), Ed's Flywheel, The resulting 16-fold pattern, A Pyramid and a Right Angle, and Prime Quadruplets.
	Slide 58 Because the flywheel is divided over the 24 magnets, each magnet takes up 15 degrees.
	Slide 59 360°/24 magnets = 15° for each magnet.
	Slide 60 By starting at 15°, magnet 1 is at 15°, magnet 2 is at 30°, magnet 3 is at 45°, and so on.
	Slide 61 We can draw these angles into a circle that represents our flywheel.
	Slide 62 15°, 30°, 45°, 60°, 75°, ... 360°
	Slide 63 With this, we can begin to apply the secrets.
	Slide 64 The Secret of the Numbers
	Slide 65 7129 6105195. The first step is to understand how the numbers need to be divided.
	Slide 66 7 1296 105 195
	Slide 67 Prime NumbersA prime number is any whole number that has only two divisors: 1 and itself.
	Slide 68 The first 24 prime numbers are:2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, ,53, 59, 61, 67, 71, 73, 79, 83, 89.
	Slide 69 7 129. The sequence of numbers that relate to this part of the code will now be revealed.
	Slide 70 The Sequence of Prime Sums
	Slide 71 By adding primes together, we arrive at an important sequence of numbers.
	Slide 72 The first number in the sequence is:The first prime number on its own. 2
	Slide 73 The second number in the sequence is:The first prime number plus the second prime number. 2 + 3 = 5
	Slide 74 The third number in the sequence is:The first, second, and third prime numbers added together. 2 + 3 + 5 = 10
	Slide 75 This continues...
	Slide 76 Here are the first 24 numbers generated by adding prime numbers in this way.
	Slide 77 The Sequence of Prime Sums 2, 5, 10, 17, 28, 41, 58, 77, 100, 129, 160, 197, 238, 281, 328, 381, 440, 501, 568, 639, 712, 791, 874, 963.
	Slide 78 Back to the Code
	Slide 79 7 129 Everything in this part of the code derives from the sequence of adding prime numbers.
	Slide 80 7 129 There is where the 129 comes from.
	Slide 81 7 129 This is where the 129 comes from.
	Slide 82 The Sequence of Prime Sums 129 The validity of this sequence will also be reconfirmed later.
	Slide 83 We need to add these new values onto our circular chart.
	Slide 84 17, 28, 41, 58...
	Slide 85 129 falls in line with 150°.
	Slide 86 129 at 150°.
	Slide 87 On our wheel, we now have degrees and the sequence of prime sums. Both of these are spread over the 24 parts of the wheel.
	Slide 88 Right Angles at Coral Castle
	Slide 89 Edward Leedskalnin left clues about 90° right angles.
	Slide 90 Proudly set upon the North Wall.
	Slide 91 From the center of the star.
	Slide 92 6 105 195 There is a right angle of 90 degrees in these numbers.
	Slide 93 6 105 195 What about this part of the code?
	Slide 94 These are 90° apart, creating a right angle. They also both happen to be intervals of 15, fitting perfectly into our wheel.
	Slide 95 150 degrees to 195 degrees.
	Slide 96 7 129 6 105 195 The 129 value is in the exact center of the right angle created by 105 degrees and 195 degrees.
	Slide 97 105° to 195°.
	Slide 98 What else is so special about a right angle around 105° to 195°
	Slide 99 There is much more to this angle than meets the eye...
	Slide 100 And it's GOLDEN. 1.618
	Slide 101 Prime Quadruplets
	Slide 102 Prime Quadruplets are one of the most important keys to understanding the code.
	Slide 103 6 105 195 This line of the code is all about prime quadruplets (and angles).
	Slide 104 A prime quadruplet is not as complicated as it might sound.
	Slide 105 When you have 4 normal prime numbers as close as they can possibly be, you have a prime quadruplet.
	Slide 106 Simply, a prime quadruplet is a set of 4 prime numbers that are very close together.
	Slide 107 An example prime quadruplet. 821, 823, 827, 829. All values in a prime quadruplet are prime numbers.
	Slide 108 Prime Quadruplets are very rare. So rare, that there are only 7 prime quadruplets under 2000.
	Slide 109 Prime Quadruplets under 2000 1: 5, 7, 11, 13 2: 11, 13, 17, 193: 101, 103, 107, 1094: 191, 193, 197, 1995: 821, 823, 827, 8296: 1481, 1483, 1487, 14897: 1871, 1873, 1877, 1879
	Slide 110 The Centers of Prime Quadruplets
	Slide 111 The magic starts to happen when we look at the values in the center of each prime quadruplet.
	Slide 112 Example: 821, 823, 827, 829 In this prime quadruplet, the two middle values are 823, 827.
	Slide 113 821, 823, [825], 827, 829 This means that thee center value would be 825, half way between 823 and 827.
	Slide 114 821, 823, [825], 827, 829 Note that the center values of prime quadruplets (like 825) are not prime numbers themselves.(825 is not prime, but 821, 823, 827 and 829 are.)
	Slide 115 Simply: Prime quadruplets are holding very special numbers at their centers!
	Slide 116 This is where the magic happens.
	Slide 117 Prime Quadruplets Center Values 1: 5, 7, [9], 11, 132: 11, 13, [15], 17, 193: 101, 103, [105], 107, 1094: 191, 193, [195], 197, 1995: 821, 823, [825], 827, 8296: 1481, 1483, [1485], 1487, 14897: 1871, 1873, [1875],1877, 1879
	Slide 118 Soon, for the first time, I will show you were the Golden Ratio, Phi, is hiding (twice) in the prime quadruplets! Both times in the very centers of the prime quadruplets! (Never anywhere else.)
	Slide 119 The Centers of Prime Quadruplets Correspond with Angles
	Slide 120 6 105 195 Remember this?
	Slide 121 105 195 Both of these numbers are at the centers of prime quadruplets!
	Slide 122 1: 5, 7, [9], 11, 132: 11, 13, [15], 17, 193: 101, 103, [105], 107, 1094: 191, 193, [195], 197, 199 5: 821, 823, [825], 827, 829 6: 1481, 1483, [1485], 1487, 14897: 1871, 1873, [1875],1877, 1879
	Slide 123 Remember - there are only 7 prime quadruplets under 2000. And these numbers from Ed's code (105 and 195) both fall into their centers! The odds? Astronomical! And just to rub it in for sure, they also make Phi, as you will see...
	Slide 124 105 195 Before, I also showed that these two values form a right angle around 129.
	Slide 125 105° to 195°
	Slide 126 This part of the code 6 105 195 is important with respect to both angles AND prime quadruplets.
	Slide 127 Now we know the following relationships.
	Slide 128 7 129 - The sequence of prime sums. 6 105 195 - Prime quadruplets and angles.
	Slide 129 7 129 6 105 195 These facts are confirmed again when we examine the meaning of the 7 and the 6.
	Slide 130 Prime Sequence Numbers
	Slide 131 You have seen that prime numbers are important to many aspects of the solution.
	Slide 132 However, it is not just the prime numbers themselves that are important.
	Slide 133 Their actual position in the prime number sequence is highly significant!
	Slide 134 Sequence Number \| Prime Number 1 \| 2 2 \| 33 \| 54 \| 75 \| 116 \| 13
	Slide 135 This can be called the Prime Sequence Number.
	Slide 136 It's simple. The 10th prime number (29) has a prime sequence number of 10, and so on. Because it is the 10th prime number.
	Slide 137 Phi in prime quadruplets.
	Slide 138 Remember the prime quadruplets?
	Slide 139 1: 5, 7, [9], 11, 132: 11, 13, [15], 17, 193: 101, 103, [105], 107, 1094: 191, 193, [195], 197, 1995: 821, 823, [825], 827, 8296: 1481, 1483, [1485], 1487, 14897: 1871, 1873, [1875],1877, 1879
	Slide 140 To find Phi we need to look at the Prime Sequence Numbers of the values in the Prime Quadruplets.
	Slide 141 This table shows the prime sequence numbers next to the prime numbers that make up the prime quadruplets.
	Slide 142 As an example: The second prime quadruplet is: 11, 13, 17, 19 These values have prime sequence numbers of: 5, 6, 7, 8
	Slide 143 What about the centers of the prime quadruplets?
	Slide 144 The centers of prime quadruplets aren't prime numbers, but we need to assign them prime sequence numbers as well. (For the secrets to be revealed!)
	Slide 145 6 105 195 We are now going to examine the two prime quadruplets that are related to this part of the code.
	Slide 146 6 105 195 Recall that the 105 and 195 both happen to be at the centers of two consecutive prime quadruplets.
	Slide 147 By using the associated prime quadruplets, we can find Phi. And this only works for the two prime quadruplets from Ed's Code. (None of the others!)
	Slide 148 This table shows the prime sequence numbers next to the values of this quadruplet.101 [26], 103 [27], 105 [?], 107 [28], 109 [29]191 [43], 193 [44], 195 [?]. 197 [45], 199 [46]
	Slide 149 7129 6105195 Engraved by Edward Leedskalnin.
	Slide 150 Phi at Last
	Slide 151 We will now assign Prime Sequence Numbers to the center values of the Prime Quadruplets.
	Slide 152 The first prime quadruplet here is 101, 103, 107, 109. 101 [26], 103 [27], 105 [?], 107 [28], 109 [29] 191 [43], 193 [44], 195 [?]. 197 [45], 199 [46] It's prime numbers are at prime sequence positions 26, 27, 28 and 29.
	Slide 153 The center value of the first prime quadruplets is 105.101 [26], 103 [27], 105 [?], 107 [28], 109 [29]191 [43], 193 [44], 195 [?]. 197 [45], 199 [46] It is surrounded by prime numbers that have sequence positions 27 and 28.
	Slide 154 So we assign 105 a prime sequence position of 27.5. 101 [26], 103 [27], 105 [?], 107 [28], 109 [29]191 [43], 193 [44], 195 [?]. 197 [45], 199 [46]We do the same for 195. The center of 44 and 45 is 44.5.
	Slide 155 We now have prime sequence numbers for the 105 and 195. 101 [26], 103 [27], 105 [27.5], 107 [28], 109 [29]191 [43], 193 [44], 195 [44.5]. 197 [45], 199 [46] 27.5 and 44.5
	Slide 156 The ratio of these numbers is precisely... Phi.
	Slide 157 44.5/27.5 = 1.618
	Slide 158 Prime Quadruplets help to define the very reality we exist in.
	Slide 159 6 105 195 And Edward Leedskalnin knew all about them.
	Slide 160 7 129 6 105 195101 [26], 103 [27], 105 [27.5] , 107 [28], 109 [29] 191 [43], 193 [44], 195 [44.5] . 197 [45], 199 [46] Phi in the center.
	Slide 161 This alone, is far beyond the possibility of coincidence.
	Slide 162 Everything else fits into the prime quadruplets as well.
	Slide 163 ADM.10c. DROP BELOW. Remember ADM = 144.
	Slide 164 ADM.10c. DROP BELOW. There are sets of prime quadruplets at prime sequence positions 144 and 288.
	Slide 165 ADM.10c. DROP BELOW. (This is amazing, remember - there are only 7 prime quadruplet sets under 2000.)
	Slide 166 And every single one deserves extensive study.
	Slide 167 1: 5, 7, [9], 11, 132: 11, 13, [15], 17, 193: 101, 103, [105], 107, 1094: 191, 193, [195], 197, 1995: 821, 823, [825], 827, 8296: 1481, 1483, [1485], 1487, 14897: 1871, 1873, [1875],1877, 1879
	Slide 168 And then I'll show you how 144
	Slide 169 Makes Phi.
	Slide 170 Again!
	Slide 171 The magic is being held in at the center of the prime quadruplets.
	Slide 172 The Pyramid and the Right Angles.
	Slide 173 A pyramid shape, like the Great Pyramid in Egypt, has a slope angle of 51.83°
	Slide 174 From a side perspective...
	Slide 175 51.83°
	Slide 176 If a right angle is drawn from the center of the base, it creates a division through each side.
	Slide 177 51.83°
	Slide 178 The ratio of the two divisions created is always the same: 1.272 : 1.0
	Slide 179 Length: 1.272 / Length 1.0 51.83°
	Slide 180 For example: If the total slope length of the pyramid side is 2272, it will be divided as: 1272 in the upper portion, and 1000 in the lower portion.
	Slide 181 Where the total slope length is 2272: 1272 and 1000.
	Slide 182 There is something else you should know about 1.272.
	Slide 183 It is the square root of Phi! SqRt(1.618) = 1.272
	Slide 184 We have a direct connection: Right Angles The Pyramid ShapeThe Square Root of Phi (1.272)

Continue to part 2 of 2.