The Sound of Light – Musical Universe

There is much we still don’t know or understand about our Universe, from the underlying energy source to the size, shape and actual age, but the 3^rd millennium will bring us many new and exciting discoveries. Why are we here, how did it all come about, and where does it lead us? Humankind has been asking these questions since the dawn of civilization. And throughout the ages, a host of groundbreaking inventions and wondrous discoveries have brought us countless advancements, but the remaining quantum connections and energetical mysteries will still take some time.

Contact Report 228 – Monday, 1st May 1989, 18:05 hrs

Billy:
…Our astronomical scientists continue to stubbornly claim that our universe is only just 8–15 billion (8,000,000,000-15,000,000,000) years old. They have no idea that the visible universe is only one of seven universe belts. They have no idea whatsoever about our material universe belt in which we exist materially, while on the inside and outside of our visible material universe belt there are six other and more subtle belts. Also our scientists have no idea that the total universe is a double-spiral and egg-shaped Creation, etc. The total universe with an age of about 46 Trillion (46,000,000,000,000) years, calculated from the big bang until today, is expanding until the time of 155.5 Trillion (155,500,000,000,000) years, only to collapse again through a contraction. During its expansion, the matter belt, or our visible universe, is constantly renewed by a seemingly endless process of change and thus always remains young. The oldest matter that you have found is almost 40 billion (40,000,000,000) years old, while we here on Earth have not yet come into possession of any such matter and therefore our scientists are also living in erroneous assumptions. Now, after my long speech, my question is when, after the creation of the matter belt or our visible material universe, the first celestial bodies were formed. In my opinion, this process should have happened very quickly.

Quetzal:
78. This is unknown to us, and besides, your question cannot be answered in this wise either.
79. You have to assume that the last great process of change and renewal of the material universe, i.e. our visible material universe, took place approximately 17 billion (17,000,000,000) years ago.
80. In the process, new stars formed again in the inner of the outer areas of the material universe belt – not in the outermost of the direct transformation area – at a distance of about 14 billion (14,000,000,000) light-years from the SOL-system, which began to radiate and shine after about 187 million (187,000,000) years of the last great transformation process.
81. And these stars will also be discovered by terrestrial astronomical scientists in the coming decades.
82. Only they will unfortunately – as so often before – draw the wrong conclusions from them again.

Artist’s Impression of the Creational Spiral

double spiral structure of the Creation — Image Credit: Occult Chemistry by Annie Besant & C. W. Leadbeater

Complete Universe

In my attempt to offer a new idea, while making connections to things we already know, it is my hope that someone out there will gain new insights that may lead to new discoveries. I suspect that it’s not a new idea at all, but maybe it’s time to revisit.

Have you ever wondered why the Universe is so vast when only a sparse number of planets are inhabited? Why is there such an abundance of space, energy and cosmic objects, not to mention a multitude of dimensions? I would assume that much like a planet or galaxy, everything is turning, swirling, growing, becoming and passing away in perfect harmony. From the smallest quantum particle to the largest objects in space, every inch of the Universe is necessary for expansion, contraction, development of life and evolution. And like our planet that provides us food, water and shelter, the Universe provides the energy and elements for all existence and evolution. It will also someday provide us with the needed energy when we leave the safety of our planet to travel the great vastness of space. It’s always in pursuit of unlocking the mysteries of space, time and life itself that drives the human being forward.

So how do the Plejaren travel through space? In recent years they’ve found new ways of traversing the great expanse, but we are a long way off from inventing similar types of devices and apparatus. From what we do know, their tachyon drive can’t be used when they are in range of a solar system or inside the solar system. It is reserved for the vastness of interstellar and intergalactic space. A tachyon drive is based on electron energy, which exists on all planets, stars and in all forms of life, as well as in inexhaustible form in the entire universe. We too will make new discoveries which involve electron energy, but for the purpose of this article, I want to focus on the normal drive that some of their beamships were using. These drives would enable us to one day travel to Mars or other Sol system planets without taking months or years to get there.

Contact Report 004 – Saturday, 15th February 1975, 01:48 hrs

Billy:
…But how does such a hyperdrive actually work, and what about the normal drive?

Semjase:
56. Unfortunately, I am not allowed to tell you any details about that.
57. If the Earth scientists had more specific details, then they would solve their propulsion problems in a very short time.
58. But this is neither in our nor in the cosmic interest, because the Earth-human is still not free and not mature enough to fly around in the outer space.
59. However, at the given time, which is not too far away any more, s/he will find the solution of her/his problem all by herself/himself.
60. I may only tell you so much that very many of your scientists are nevertheless already on the right track and are theoretically working and researching on the necessary drives.
61. I may also tell you that these also concern drives that are already known in their basic features within your initiated scientific circles as light-emission drives and as tachyon drives.
62. The light-emission drive serves as normal drive and has the function of moving the beamship to planets or within their vicinity, up to 153 million kilometres of distance, so up to the safety limit.
63. Beyond that, the tachyon drive, among other things, is put into operation, if greater distances are to be bridged.
64. This is one of the hyperdrives, capable of controlling hyperspace as well as space and time.
65. We call these two drives by other names, but the sense remains the same.
66. We have a different language than the Earth-humans, and so I have to explain it to you in the terms that you understand.

Contact Report 055 – Monday, 14th June 1976, 10:37 hrs

Billy:
Now another question: You explained to me at the beginning of our acquaintance that your beamships are equipped with a light emitting drive and further with a tachyon drive. Is that why you call the ships beamships?

Semjase:
147. No, because the drives you mentioned do not correspond to direct beam drives.
148. The beam drives were of a different kind, and we have not used them for about 400 years, although we have kept the name beamships for ourselves.
149. My ship, which I still had in my possession at our first encounter, was still half radiant, which is why you were able to see the radiations.
150. However, these were only highly concentrated light beams.
151. My last ship already had an antigravity propulsion based on the principle of repulsion.
152. However, this drive was only suitable for planetary flight, while the tachyon drive was retained for free space.
153. The present ship is equipped with an antimatter propulsion system for free space, which was developed more than 50,000 years ago.

Contact Report 104 – Saturday, 18th March 1978, 03:32 hrs

Billy:
I do, Quetzal, but you know that when I take pictures in the ship, they are always very blurred and blurred afterwards. Is there no other possibility, do you know that I might be able to get off?

Quetzal:
104. You have the best overview from above, here from the ship.
105. On the other hand this time you will bring sharp and clear pictures onto your film, because the propulsion of this ship does not affect your film by radiating.
106. You just have to make sure that you do not photograph directly under the drive surface, because the very strong light radiation could affect the film.
107. The slightest damage to the film could be that the finished images would appear to be illuminated by a light source.
108. In the worst case an overexposure would occur.

There are loads of hints, suggestions and puzzle pieces throughout the contact reports. The human beings who are paying attention have known this for a long time. In order to find the missing pieces and solve many of our problems, we should bring our thoughts and ideas together in the way that Creation meant for us to do. When humanity finally comes together as one civilization, the time of great progress will begin. By connecting known information to new scientific data, I hope to spark the researchers, scientists, astronomers and lovers of progress into action. We’ll need the mathematicians, too.

The Plejaren were using light-emission drives to move around the solar system at high but safe speeds. That means that they were somehow harnessing and discharging different wavelengths of light through their light-emitting propulsion drives. But which wavelengths and frequencies were they using? And how exactly were they doing it? The contact reports have given us a great wealth of information. Some of the answers are right at our fingertips, so it’s time for the puzzle lovers to get involved.

So far, we know that the light-emission drives are harnessing and discharging light, which in turn creates an inexhaustible energy source that propels their beamships at great speeds. These light drives go way beyond your grandpa’s solar panel.

As can be seen in the image above of the WCUFO, they are using a mix of crystals and lenses in the 3 primary colors of light, red, blue and green. We can only assume that these crystals are gathering, mixing and dispersing light from multiple wavelengths in order to create a unique range of frequencies or vibrations. The energy from light is inversely proportional to the wavelength. On the visible light spectrum, red has the lowest energy and blue (indigo and violet) have the highest energy. The higher the frequency the more cycles per second, and the more cycles per second the shorter the wavelength.

Unsure of how this method works exactly, we are getting closer to discovering which light waves were being harnessed. In fact, we’ve had a large piece of the puzzle for a long time, but some of the pieces are still missing…for now.

If you want to find the secrets of the universe, think in terms of energy, frequency and vibration.

– Nicola Tesla

Whether you understand the power of crystals or not, science backs the unmistakable ability of crystals to transform, absorb, amplify and transmit energy.

A Piece of the Puzzle

Excerpt from: Beamship Sounds, The Future of Mankind

Now, the sound specialists examined this new segment of the recorded sounds and found the same as the previous teams. They found these sounds to be truly unique in three respects:

1. There were at least thirty or more discrete frequencies in a random and constantly shifting mix that ranged from 4 to 2170 Hz, but varied on average between 470 and 1452 Hz.
2. The amplitude of these frequencies was also constantly changing, whereby the dominance alternated.
3. The wave shape was also constantly changing in a random, periodic rhythm that caused a characteristic beat. The wave pattern in the oscilloscope showed this constant and random shift in frequency, in which the principal waves of all frequencies came together in perfect synchronization at one moment, only to travel at the next moment in different directions and stages, thereby generating different patterns-at one moment seemingly moving in a cluster in one direction and, at the next moment, in the other direction. Then they gradually expanded until, for one moment, they formed a mutually precise and evenly distributed pattern, only then to move again into different relationships. Although these changes appeared to be random and were not repeated in a particular order, they always appeared in geometric relationship to one another.

The strange whirring sounds of the Pleiadian-Plejaren spaceships could be recorded several times on tape, for example, twice during the spring of 1976 (at the Frecht Nature Preserve near Hinwil on Good Friday and at Schmärbüel-Maiwinkel on April 14th), and, finally, on July 7, 1980, in Ober-Sädelegg near Schmidrüti…

Normally, Meier does not hear such loud ship noises, certainly not for such a long time. At the most, there is usually a very short noise when the spaceship lands or takes off. This demonstration was intentionally given for the purpose of the tape recording.

Beamship Sound Recording

Spectrogram of the Beamship Sound

I have a hunch that the demonstration was given for more than just the tape recording. By analyzing the sound frequencies and comparing them to newly discovered scientific data, we should now have a better understanding of the type of light waves that the Plejaren were using. It is my assumption that the sounds we are hearing from the Beamship recording are the discharge sounds of specific wavelengths of light, which can be translated into sound.

I have no special talent. I am only passionately curious.

– Albert Einstein

Data Sonification – The process of translating data into sound

Excerpt from: Data Sonification: Sounds from Around the Milky Way, NASA

The center of our Milky Way galaxy is too distant for us to visit in person, but we can still explore it. Telescopes give us a chance to see what the Galactic Center looks like in different types of light. By translating the inherently digital data (in the form of ones and zeroes) captured by telescopes in space into images, astronomers create visual representations that would otherwise be invisible to us.

But what about experiencing these data with other senses like hearing? Sonification is the process that translates data into sound, and a new project brings the center of the Milky Way to listeners for the first time. The translation begins on the left side of the image and moves to the right, with the sounds representing the position and brightness of the sources. The light of objects located towards the top of the image are heard as higher pitches while the intensity of the light controls the volume. Stars and compact sources are converted to individual notes while extended clouds of gas and dust produce an evolving drone. The crescendo happens when we reach the bright region to the lower right of the image. This is where the 4-million-solar-mass supermassive black hole at the center of the Galaxy, known as Sagittarius A (A-star), resides, and where the clouds of gas and dust are the brightest.

The sonification scans across the three-tiered image, with each wavelength mapped to a different range of audible tones. Radio waves are mapped to the lowest tones, visible data to medium tones, and X-rays to the highest tones. The brightest part of the image corresponds to the loudest portion of the sonification, which is where astronomers find the 6.5-billion solar mass black hole.

You can hear the intensity and tone changes when the line crosses the supermassive black hole, as pointed out in the still shot below.

In this second video below, listen as the sound intensifies and changes at it passes over the supermassive black hole and the light that expands out from it. It’s shown in three different forms of light, X-ray, optical, and radio waves. It’s breathtakingly beautiful as well.

The image in visual form contains three panels that are, from top to bottom, X-rays from Chandra, optical light from NASA’s Hubble Space Telescope, and radio waves from the Atacama Large Millimeter Array in Chile. The brightest region on the left of the image is where the black hole is found, and the structure to the upper right is a jet produced by the black hole. The jet is produced by material falling onto the black hole. The sonification scans across the three-tiered image from left to right, with each wavelength mapped to a different range of audible tones. Radio waves are mapped to the lowest tones, optical data to medium tones, and X-rays detected by Chandra to the highest tones. The brightest part of the image corresponds to the loudest portion of the sonification, which is where astronomers find the 6.5-billion solar mass black hole that EHT imaged. Source: New NASA Black Hole Sonifications with a Remix

Now that we have an understanding of data sonification and how we can interpret different sound frequencies that are coming from different objects at different wavelengths, it brings me to the 3rd video. You’ll want to pay close attention to the remaining videos as the point of this entire article will become very clear.

The Whirlpool Galaxy (M51) is named for its face-on orientation to Earth, which reveals its winding spiral arms. The sonification begins at the top of the image and moves radially around the image in a clockwise direction. The radius is mapped to notes of a melodic minor scale. Each wavelength of light in the image is mapped to a limited range of pitches, from low to high pitch, which corresponds to low to high light frequency: infrared, optical, ultraviolet, and then X-ray. The sequence begins with sounds from all four types of light… Source: Explore – From Space to Sound

Let’s take it a little further and separate out the different light waves. We’ll start with infrared, from the Spitzer telescope, because who doesn’t love infrared.

Infrared (IR), sometimes called infrared light, is electromagnetic radiation (EMR) with wavelengths longer than those of visible light. It is therefore invisible to the human eye. IR is generally understood to encompass wavelengths from around 1 millimeter (300 GHz) to the nominal red edge of the visible spectrum, around 700 nanometers (430 THz). Wikipedia

Next we have the optical light, otherwise known as the visible light spectrum. This is brought to you by the Hubble telescope. Some of the most beautiful tones are coming from the optical light range.

The visible spectrum is the portion of the electromagnetic spectrum that is visible to the human eye. Electromagnetic radiation in this range of wavelengths is called visible light or simply light. A typical human eye will respond to wavelengths from about 380 to about 750 nanometers. Wikipedia

Next on the list is the ultra-violet light, from the GALEX telescope. This is one of my personal favorites.

Ultraviolet (UV) is a form of electromagnetic radiation with wavelength from 10 nm (with a corresponding frequency around 30 PHz) to 400 nm (750 THz), shorter than that of visible light, but longer than X-rays. UV radiation is present in sunlight, and constitutes about 10% of the total electromagnetic radiation output from the Sun. Wikipedia

Last but not least, and straight from a sci-fi movie, I present you with the X-ray spectrum. This enchanting sonification is brought to you by the Chandra X-ray telescope.

X-ray, or, much less commonly, X-radiation, is a penetrating form of high-energy electromagnetic radiation. Most X-rays have a wavelength ranging from 10 picometers to 10 nanometers, corresponding to frequencies in the range 30 petahertz to 30 exahertz (30×10¹⁵ Hz to 30×10¹⁸ Hz) and energies in the range 145 eV to 124 keV. X-ray wavelengths are shorter than those of UV rays and typically longer than those of gamma rays. Wikipedia

As you can see, or hear, the connections to the beamship sounds are undeniable in the X-ray and Ultraviolet spectrum. It appears that light is being harnessed from certain points on those spectrums, and when it’s discharged as sound, it creates a specific tone or frequency. This new scientific data can be used to help us narrow down which wavelengths they are using. There’s also the issue of correcting pi (π), so there’s no doubt that we have our work cut out for us.

Nothing in life is to be feared; it is only to be understood.

– Marie Curie

It’s undeniable that the sound of light is beautiful and harmonic. The next time you gaze up at the night sky with your telescope or naked eye, consider how many civilizations are out there flying around as the real explorers that humans were meant to be. Many are there because they worked together and evolved to highly advanced civilizations.

The answers to many mysteries are all around us, but we must first solve our problems here so we too can become true human beings.