Sunday, February 19, 2017
A quantum theory of feeling needs to define the nature of superposition and entanglement for people's feelings for each other. Any choice that you make in life involves the superposition of two possible futures; one to excite action and the other to inhibit action. Therefore quantum feeling necessarily means that choice involves the superposition or entanglement of two quantum states of feeling and the subsequent decay of that superposition into one or the other futures.
Since emotion is the basic mechanism the drives feeling and therefore determines choice in the primitive brain, we need a simple model of emotion to describe quantum feeling. The integration of five emotion dimensions represents human feeling reasonably well with the notion that feeling is how we choose to excite or inhibit action and therefore feeling is singular even while emotion has five dimensions. While rational thought occupies much of consciousness, the primitive thought of emotion and memory are how people really choose with quantum free will.
The further machine of consciousness is why we are aware and why we can make choices and why consciousness is fundamentally entangles quantum emotions and feelings. The emotions of pleasure and anxiety are the most important emotions that determine survival. People get pleasure in discovering the world, pleasure in breathing, pleasure in drinking, and pleasure in eating. However, people are also anxious about the dangers of the world, anxious about breathing foul air, anxious about bad water, and anxious about toxic food. Without anxiety, people would take risks that would lead to injury or death even though we do not desire excessive anxiety.
For family and community, compassion and selfishness are the extremes of these important emotions. Compassion is how people bond and selfishness is how people conflict. Yet all people must be selfish to the extent of survival and even more selfish to accumulate and share their wealth with compassion.
Anger and serenity are very important emotions that help people set limits for other's behaviors. People get angry when they feel injustice or unfairness and people experience serenity when they are satisfied and happy with life.
We maintain a social order with the emotions of pride and shame for belonging and setting standards and ethics that help people bond to civilization. Civilization's laws and norms are a kind of contract that we believe in and pride and shame are the emotions that drive choices to keep that contract.
Finally, joy and misery are sort of the kind of residual emotions that help people be satisfied or dissatisfied with actions in their lives. Misery can drive people to make changes in their lives just as joy can show that life is desirable.
The emotion spectrum below shows how this set of five emotion dimensions reduces to a singular feeling and by that singular feeling, we choose to excite or inhibit an action.
The primitive brain makes our decisions for us with a set of very specialized brain organs that all come together into the amygdala, which is the decision point where quantum superposition drives quantum free will. The caudate and thalmus are both important for emotion and of course, the hypocampus entangles choice with the long term memories that also contribute.
While people often believe that choice lies in the rational cerebral brain that forms the aware matter of moments of thought, science tells us that people actually choose to excite or inhibit action before they become conscious of their choice.
Friday, February 17, 2017
There are really two very different approaches for predicting how things happen in the universe; classical determinism with its knowable chaos and quantum probability with its unknowable phase noise. Classical predictions are very familiar and are the typical ways that we experience the universe and every classical effect has a knowable classical cause. Quantum predictions can be quite different from classical predictions since quantum actions happen with only likely and not certain causes and therefore not absolutely knowable. The challenge for this new quantavangelism is to promote the belief that some things happen for unknowable causes.
In a classical determinate prediction, observers and sources are completely interchangeable and all things happen with fundamentally knowable, albeit sometimes very complex and chaotic, causes. Although the chaos of classical noise does limit even what a classical observer can know, in a determinate classical universe, everything happens because of a knowable cause and even noise is ultimately knowable. Gravity action is largely classical and so how we perceive the world is also largely classical and so it is quite natural to suppose that is the way the universe must be as well. However, quantum logic tells us otherwise...
An electron always exists in a superposition of up and down spin states in an orbit around a nucleus as shown is an example of the duality of classical and quantum predictions. Classically, the electron has a knowable path as an orbit around a nucleus, but the quantum path of the electron has both wave and particle properties. The quantum electron exists in symmetric sphere around the nucleus in an S orbit is a superposition spin state, but the spin state exists in one side of a charge plane in a P orbit as up and the other side as down.
Excitation of the electron into each successive orbit reduces the classical electron velocity by a factor of two and therefore its kinetic energy by four until eventual ionization. The complementary capture of an electron into the S ground state occurred with the emission of a photon and that photon phase entangles the spin phase of the electron. Since the universe is actually not classical, quantum observers and sources are not interchangeable for quantum probabilistic predictions.
In other words, a quantum observer of an electron path or spin cannot predict a precise but only a likely quantum future for that spin. Quantum observer and source are inextricably entangled in the surreal quantum world. Although the chaos of classical noise also limits what a quantum observer can know about a source, in addition, there is quantum phase noise. Unlike the chaos of classical noise, quantum phase noise entangles an observer with a source in ways that the observer cannot ever know. Fundamentally this means that there are quantum effects for an action that do not have knowable causes.
Things happen in the universe because of the actions of both classical gravity biphotons and quantum charge photons. Since gravity biphotons and charge photons are very different magnitudes of force, mainstream science treats them as two very different forces and this also means that there are two very different kinds of observers; one for classical gravity and another for quantum charge. Without a unified photon exchange force that explains both gravity and charge, a classical observer will not see a source the same way as a quantum observer sees the same source.