Saturday, October 31, 2015

Classical Observers See and Quantum Observers Feel Sources

There are both observers and sources in the world in which we live; objective observers who see the world as others see it and subjective sources who feel about the world as it feels only to themselves. While an objective observer can in principle know everything about the way other observers know the world, a subjective source cannot know everything about how other sources feel about the world or how the world feels to other sources as well.

Objective observers get pleasure discovering the world with senses in contact with sources and those sensations are both how observers discover knowledge and feeling about the world as well. There are no limits to what an objective observer can know besides the complexity of that knowledge, but there are limits to what a subjective source can observe about their own feelings about the world. There are even very simple things like observer feelings about the world that a subjective source can never know.

In particular, there is a property of people and matter called quantum phase coherence that entangles an observer with a source and so subjective observers are quantum observers. Although objective or classical observers can know and agree with others about the objective properties of a source, a quantum observer can only ever know the phase coherence of a source relative to their own phase coherence. Therefore quantum observer feelings about source phase is subjective since it is the observer's feeling alone and no other observer will have the same lifetime of experience and development from which their phase derives.

Classical observers suppose that the world as it really is has classical observers and sources pretty much running around on their own in a vast void of empty space and time. Classical observers do not bump into or affect each other very much and when there are couplings, those perturbations are all completely knowable in a classical determinate and causal universe. There is no self energy in a classical universe.

Continuous space and time are the cornerstones for classical observers and they can pretty much agree with other Cartesians about this Cartesian view, which is what makes a classical reality objective and why the world seems so classical. Cartesian action seems rather more like fate or karma than chance and the initial conditions of the CMB creation seem to determine all of what happens; classical action simply happens without any meaning or intent since classical action is determinate.

How a subjective quantum observer actually feels about the world is a subjective relational view that first of all supposes there is a purpose and meaning for everything that happens and there are no completely determinate futures. Quantum observers depend more on what other quantum observers and sources intend to do instead of what the observers and sources happen to be doing at any moment. A subjective quantum observer depends more on their feelings about sources as well as themselves instead of just on source properties at that moment.

A quantum universe cornerstone is with the exchange of energy and matter that are the actions between quantum observers and sources and quantum observers often feel very differently about the world as compared with classical observers. Since quantum feelings result from each of their own unique histories, quantum actions that result from quantum feelings are therefore not fated or determinate and there are instead many possible futures for both quantum observer and source.

There is a long history of discovery about the dual nature of the world of the body and the world of the mind. This is the duality of classical observers and subjective sources; how classical observers see the world really is versus how quantum observers and sources feel together about the world. Quantum observers feel that there is an inner life made up of souls and minds that coexists with an outer life of classical observers in the physical part of the world made up of bodies and brains.

Classical observers believe that since there is no objective evidence for an inner life of sources made up of souls, the actions of the mind are instead simply very complex and yet completely knowable as the brain matter of the same the outer life. Classical observers therefore believe there is really only one material world composed only of completely knowable observers and sources. An objective classical observer can know everything about the world and there is no meaning to any kind of inner life of quantum sources made up of just souls and minds.

However, there are things about a quantum source's inner life that a classical observer can never know. The subjective world that quantum observers discover by feeling and relationships with sources is different from the objective and material world that classical observers discover along with other Cartesians. The classical Cartesian observer can in principle know all objective properties about an object, and yet complex actions of other observers and objects also make up our material world and that complexity therefore limits what classical observers can know. The noise of chaos often confuses and confounds quantum phase noise, but quantum phase noise is different from the noise of chaos.

The quantum observer has feelings about the aether exchanges among people and sources of an inner life as opposed to the classical observer of people and sources of the outer life of things in and of themselves. In the quantum world of feeling based on aether exchange, while most relationships and feelings are objective and therefore knowable, there are many relationships and feelings that are fundamentally unknowable and yet are still a part of our quantum world.

Therefore discourse about the dual natures of objective and subjective reality are often confused by what a classical observer can know about the complexity of  sources as people and relationships of their outer lives and what a quantum observer can never know about their own inner life. Although there are many things about their outer life that classical observers do not yet know, all of these things are still knowable albeit somewhat obscured by complexity and chaos. Yet there are some things about a quantum observer's inner life that are fundamentally unknowable and yet are still a part of the real world.

Although a classical observer can know everything about the path of a person or source in space and time, a quantum observer cannot know everything about the relationships of that person or source with other people or sources over time. Ironically, the things that a quantum observer can never really know are a part of uncertain futures of quantum relationships with other sources.

Saturday, October 24, 2015

Discovery as Meaning and Purpose

People discover life's meaning and purpose in the pleasure of people and objects coupled with an anxiety about the dark void of nothing that is empty space without people or objects. All people and all life get pleasure in and yet also have anxiety about discovery. All life must discover food, drink, shelter, and community among other needs simply to survive and light the dark void and fill an otherwise empty space with people and objects. The pleasure of discovery of the world drives our meaning and purpose and yet we must temper that pleasure with an anxiety of the unknown dark void of empty space. Among the discoveries that are necessary for survival, there are also many dangers lurking.

Therefore we must also have a certain anxiety about the world that we discover in order to avoid danger and injury. No matter how pleasant a discovery might be, we also need a certain anxiety about our discoveries in order to avoid walking off of cliffs and in front of traffic. We survive and discover meaning and purpose with both the pleasure and anxiety of discovery.

There are many inexplicable questions that have no unique answers. Some of these questions are:

Why is the universe the way that it is? 
Why are we here?
Why are we right here right now?
Why is it us who is right here right now?
What is the universe origin?
What is the universe destiny?
What is the meaning and purpose of the universe?

We ask these questions as part of the pleasure of discovery but these questions all represent the unknowable parts of the universe about which we can feel but can never really know. Although the pleasure of discovery provides an innate meaning and purpose, we can never know why that is. All we can really know is that is simply the way the universe is.

It helps to have a theory of the mind in order to understand how the pleasure and anxiety of emotion are what drive the primitive mind. It is the feeling of our primitive mind by which we make the choices that we make...

Saturday, October 17, 2015

Stonehenge and the Full Moon

In our modern age, we tell time largely by the passage of the sun and the solar day and that means that the sun and not the moon largely determines our modern time. However, people have always used the moon as a way to tell time along with the sun and the legacy of lunar time persists in the calendar month as one cycle of the moon and week as a moon quarter. As a result, lunar time is still deeply embedded into the consciousness of humanity along with solar time. 

Stonehenge is an ancient solar and lunar calendar in Wiltshire, England, that is an arrangement of stones called henges and holes for wooden henges that tell both solar and lunar times. Constructed around 2,600 BCE (over 4,600 years ago) and used for over 1,000 years, the main alignment of Stonehenge shows the directions of the summer and winter solstices as well as spring and autumn equinoxes as shown in the figure below. This alignment with the solstices tells a solar time of year by the sunrise and sunsets of solstices and equinoxes at right angles to the solstices, the four solar celebrations of the ancient Druids.

Stonehenge also tells lunar time with an inner circle of 30 Sarsen stone henges that represent the 29-30 days of the lunar period along with an outer circle of 56 Aubrey pits (wooden henges) that count moon periods and lunar years. Since there are 14 moons for each lunar year, the Aubrey circle counts 4 lunar years with its 56 pits. There are also 7 lunar years for every 8 solar years for the winter/summer solstices of the Stonehenge calendar and that product shows 7 x 8 = 56 lunar solar yrs.

The 56 Aubrey pits allowed Stonehenge to count both the 4 solar celebrations of solstices and equinoxes along with the four interspersed lunar celebrations for 14 solar years and 4 lunar years. The Stonehenge calendar included one lunar celebration as one of the full moons between each pair of solar celebration for a total 8 celebrations that are the same in the modern Druid wheel of 8. Today's modern holidays reflect the 8 celebrations from the ancients.

In principle, there are three full moons on average between each solar celebration, but since the full moon period shifts as much as one moon relative to the solar month, it is important to sometimes choose the first full moon and sometimes the second full moon. That meant that the lunar celebrations would better synchronize with the solar celebrations.
In addition to being a solar calendar of the 4 solar celebrations of solstices and equinoxes, Stonehenge also counted days in a moon period as well as moons in a lunar year in order to intercollate four lunar celebrations. A lunar calendar counts the 14 moons for each lunar year, which means 4 lunar years in the 56 Aubrey holes along with 14 solar years by counting 4 solar celebrations. Solar solstices and equinoxes along with full moons have all traditionally marked Druid ceremonies and that tradition continues today for many modern holidays. From the Chinese New Year’s to Easter and Yom Kippur, the cycles of the moon therefore continue to impact human behavior. Even today, knowledge of the full moon is further helpful for harvesting and hunting and other outdoor activities as well as prediction of the ocean tide.

Many people have proposed that the Stonehenge calendar also predicts solar and lunar eclipses. While it is certainly possible to use a Stonehenge solar-lunar calendar to predict lunar and solar eclipses, eclipse predictions need further knowledge of a third cycle, the Saros 18 yr cycle, and discerning the Saros cycle necessitates centuries of fairly accurate astronomical observations. The day of solar and lunar eclipses repeat every Saros cycle of 18 years and this period predicts both lunar and solar eclipses. During each 18 year Saros cycle, there are about 40 eclipses and so the Saros cycle requires not only a fairly accurate calendar, it requires several centuries of careful observation with reasonably clear skies.

It is not clear that the knowledge of the Saros cycle of eclipses was available to the ancients of Stonehenge and the less than optimum visibility of the sunrise, sunsets, moonrise, and moonsets in that climate would suggest that eclipse predictions would have been very unlikely. Since predicting the time of year and phase of the moon did offer distinct survival advantages, Stonehenge makes perfect sense as both a solar and lunar calendar. However, the precision of the Stonehenge calendar does not seem consistent with the long-term observations needed for eclipse predictions.

Humanity today adjusts our modern calendar month to the rhythm of the solar day and year and we have therefore lost much of the ancient lunar rhythms that tell time with the variable periods of the full moon. A solar calendar month averages 30.4 days each over a non-leap 365 day year, whereas the actual lunar month is 29.53 days for an average full moon period. And yet the periods of the full moon still affect things that happen to humanity. For example, the average female menstrual period is 29.1 days and is closer to the 29.5 days of the average full moon than to the 30.4 days of our average calendar month. In fact, the average gravity period of the lunar orbit is 27.6 days, which is also an important cycle for the changes of full moon periods.

There is a cyclic variation of the period of the full moon due to the coupling of both lunar and solar periods and it is that variation of the full moon period that affects the tides and weather patterns associated with those tidal flows. So the full moon period does have demonstrable affects on human behavior and there is a long history that associates phases of the moon with various behaviors. The word lunacy, after all, comes from the lunar root and the poetry and behavior of people has long association with the lunar phase.

The cycles of lunar full moon period or number of days, though, do not have the same popular following as does following the phases of the moon. The cycles of the lunar period are mainly due to a beating of the period of the full moon, 29.53 days, with the period of the gravity moon orbit, 27.55 days. These two lunar periods result in two beat cycles of 1.13 and 8.85 yrs and that means that there are roughly seven lunar years as cycles of moon periods for every eight solar years. This means that there are 56 moons in 4 lunar years along with 14 solar years with 4 solstices/equinoxes to make the 56 solar celebrations in 14 solar years. There are also 4 lunar celebrations to make up the 8 celebrations of each Druid year.

The Chinese lunar calendar is several thousand years old and places the winter solstice in the eleventh lunar month, which means the New Year is usually the second new moon after the winter solstice. The Christian Easter is the Sunday following the first full moon after the spring equinox, but as determined by the ancient Nicene and not a modern calendar. There are many other religious holidays that remain anchored to the full moon period and so continue to affect human behavior.

The fractional periods of the moon relative to the solar periods make moon predictions difficult. Lunar calendars are always therefore more complex than solar calendars and this was true for ancient peoples of the Stonehenge. Knowledge of the Saros eclipse period of 18.03 years predicts both lunar and solar eclipses, traditional harbingers of fortune, but the Saros period takes many years of observation. The Saros period comes from the moon period between when it crosses the sun's path, which is 27.2 days. This lunar cycle beats at 18.6 yrs and 18 yrs is the intersection of the three lunar periods.

The variability of the period of the full moon is quite well known and largely due to the beating of the full moon period of 29.53 days with the period of the lunar gravity orbit of 27.55 days. The beating of these two frequencies results in a variation of full moon periods with cycles of both 1.13 and 8.85 years as shown in the figure. The precise measurement of the earth-moon distance with a reflected laser pulse has shown that the earth-moon distance increases by 38 mm per year. Given the 384,400 km average earth-moon distance, 38 mm/yr means that the moon orbit period slows by 0.31 ppb/yr, very close to the expected 0.26 ppb/yr of classical aethertime decay, but far less than the variability due to other factors.

This figure shows the period of full moons as a function of fractional solstice year where each year begins on the winter solstice, Dec. 20th. The coincidence of the winter solstice with a peak in the full moon period occurs every 8 solar years, but only seven lunar years. This fundamental difference between solar and lunar periods is what the stone and wooden henges seems to represent.

Sunday, October 4, 2015

Aethertime Quantum Entanglement and Phase Coherence

Phase coherence is a property of quantum sources that classical sources do not seem to have, but in fact phase coherence affects all observers and sources in the universe, just in different ways. Instead of the single knowable state of a classical source, say a red color, two quantum sources with coherent phase can exist in a coherent superposition of states, say both red and blue. This entanglement can occur even though those the quantum sources might be located across the universe from each other.

The exact object color of one source is unknowable until an observer sees that source as red or blue. The observation of one of two coherent source superposition states as red then immediately determines the other source state as blue even across the universe. Before the measurement, though, the two sources existed as a superposition of both red and blue and so the exact state of both sources in the past is unknowable.

There is a knowable phase coherence that two classical objects also exhibit, but for classical objects in general relativity, all reality is determinate and therefore classical coherent states are knowable. A classical observer might not know which of two a classical sources is red or blue, but that classical knowledge is always knowable. That is, once an observer sees one classical source as red, they also immediately know that the other classical source is blue even if the other classical source lies across the universe. However, the colors for each of the two classical sources were always classically knowable and once an observer sees a classical source as red, they know that it was always red. There are no superposition states for classical sources nor is there any decay of the phase coherence between two classical sources except due to perturbations from other sources.

Classical determinate sources in general relativity do not appear to show quantum phase coherence, but really it is the decoherence of quantum phase that makes quantum sources different from classical sources, not really phase coherence per se. After all, two classical sources with coherent colors also remain perfectly coherent in a determinate classical universe in the absence of perturbations. Those two coherent colors represent determinate geodesic paths for general relativity as well.

On the one hand, correlated colors for two classical sources represent something that an observer can know about each source. Even though the observer might not know the color of either source to begin with, once seeing that a classical object is red, the classical observer also then immediately knows that classical sources was always red. The observer also then immediately knows that the source's coherent twin's color was blue even across the universe and that twin had its classical correlation for the same period of time.

Unlike two classical sources, two coherent quantum sources somehow oscillate between those coherent color states as a superposition of amplitudes and do not exist as either one or the other colors until an observation or some other action dephases them. In the quantum universe, dephasing is an inextricable part of seeing or measuring the color of a quantum source and immediately tells the observer the state of its coherent twin even across the universe. Since decoherence is an inextricable part of all sources in the universe, observers can never be absolutely certain about the natures of objects that they sense. That is because neither quantum twin existed as red nor blue prior to the measurement or action that dephased one of the sources into a red or blue state.

The mystery of quantum entanglement has to do not really with why a quantum source can be either of two colors or how two quantum sources can remain coherent with each other across time and space. The mystery of quantum entanglement has to do with even when an observer sees that an source is red, they still simply cannot know that that same source was always red before they observed it. As soon as the nearby quantum object is red for certain, the distant source decoheres to blue and stops its oscillation between red and blue. The distant quantum source can now only be blue even though before that time, it's state was not knowable.

Although quantum charge is a local force with very fast decoherence, quantum gravity is a long range force that has a much slower decoherence. In aethertime, every quantum charge state like red and blue with very fast decoherence has a complementary quantum gravity state with much slower decoherence. In fact, quantum gravity states exist with the decoherence times of the universe. While quantum charge is a very local force, quantum phase is also part of the glue that holds the universe together.

The color of a red source is due to a large number of photons of light across a wide spectrum of light around that red color. When we see a classical source as red, we sense only a very small fraction of a very large number of photons emanating from that red source. For such large and macroscopic classical sources as red apples, a red color is a property of a very large number of particles at the surface of that source.

In contrast to the color of a classical source, the color of a quantum source may be due to just one photon of light interacting with a single particle. Since observer eyes are not sensitive to just one photon, observers must use spectrometers to know whether a single particle is red or blue. That single photon still represents a whole spectrum of frequencies superimposed as a single time pulse that bonds the observer to the particle for some period of decoherence. During that superposition between the observer and the particle, the observer oscillates along with the particle between the possible futures of red or blue. When the observer becomes decoherent from the particle, that leaves the observer in the red or blue state as well as the quantum gravity state that goes along with the color.

The phase coherence of a quantum source decays as a result of not only measurement, but also due to perturbations with other objects just like perturbations affect the classical spins of objects. The decay of phase coherence is due to the classical noise of chaos as well as quantum phase noise and there is simply no classical meaning for quantum phase noise.

The meandering decay of earth's spin period means that a day has varied from +1.4 to -1.5 ms every year over the last 43 years (see figure below) and there are many different factors that perturb Earth's spin by as much as 4 ms per day. In a determinate classical universe, all of these perturbations are knowable and even in a quantum universe, most of these perturbations are likewise knowable. However the quantum dephasing of the universe at 0.255 ppb/yr has no cause other than being simply a property of the universe. Quantum decoherence is an assumption Earth's spin decay that is an unconditioned axiom of the universe.

According to reports, the Earth day has lost from 1.7 ms [0.20 ppb/yr, McCarthy and Seidelmann, 2009] to 2.4 ms [0.28 ppb/yr, Stephenson and Morrison, 1984] over the last 100 years, both decays are consistent with the classical 0.26 ppb/yr decoherence of aethertime within the uncertainty of the measurements. The dephasing of the universe represents phase information that is lost to observers of that same universe since observers dephase along with all other sources in the universe. However, the local decoherence rate does show up in various decays of matter and force and those measurements do provide an absolute velocity relative to the aethertime universe boundary. The shrinking of the universe in this epoch is what defines the speed of light, c, in aethertime.

Therefore, quantum entanglement and decoherence both represent a loss of information as quantum phase noise and so observers cannot know all quantum phase perturbations. While classical entanglement represents knowable perturbations with a determinate universe of local cause and effect, quantum entanglement also involves decoherence of quantum phase commensurate with the universe decay.