The observer cannot change the truth simply by observing, the expansion of time is a visual experience. Our theories are based on the assumption that light travels from the source to reach us, but our vision is a biological sense and, not a physical product.
An observer relies on the brain - eye coordination to visualize the physical characteristics of the light source. A personal vision cannot be printed, or any fact can be altered.
To understand why the 'Theory of relativity', and all the theories based on the speed of light is not just a fiction of our imagination, we must first understand how our eyes work in relation to the available light, which is ubiquitous and, does not depend on any specific time of day / night or any specific light source. Sight is available in the deepest part of the ocean, and darkest at night.
How is the 'eye' seen?
How does one eye see? Any eye, human and animal alike.
The exchange between the environment and our body makes this sense, called ‘Vision’. Our body is completely dependent on this perception to understand the surroundings. Before we can use any other senses, we must, before we touch, or smell, or taste. Aside from hearing (sound), where we believe the journey is slower than Light, all other senses in the body depend on sight for its accuracy. So, what is the concept of this vision in our body?
For our eyes to experience a vision, the most important part is the light and the source of light. Not only is it about sight as in B&W but, the colors also vary depending on the light source. We do not lose sight, regardless of outside conditions. There is no time in total darkness. Although our only source of light 'the' has a limited duration above our head but, there never comes a time when we start to lose our sight for lack of sunlight.
So, a very important question arises here. Do we really rely on the Sun for our vision, so Light, or do we have an alternate source? Or, Do we need an external source of light for our biological sense 'Income' - Insight?
Vision - is the coordination between the organ eye and, the brain. It is independent of all external factors, including Sunlight and Moonlight or, any person who makes lighting devices.
The eye - is a heat sensor, and translating this meaning of our brain is called sight.
Every lifestyle that possesses completely unique in their own meaning is called 'See'. What my brain sees in the color Orange, is unique to me, there are no ways to compare my Orange to your Orange. It can be completely different colors.
The second part of the theory is 'Speed' that is 'Distance' to 'Time'.
What is 'time' and where did it start?
"The measurement of time began with the invention of the sundials in ancient Egypt some time before 1500 BC. However, the time measured by the Egyptians is not the same as the time measured in today's clocks. For the Egyptians , and indeed for an additional three thousand years, the basic unit of time is the period of daylight. "
Time: is a human-based subject, which is the basis of a topic called 'Science'. The invention of time lies in our history as we forget the very fact that ‘time’ is not a cosmic event, but a system of man-made calculations.
Time was invented by people to monitor their daily work and, to sell their ‘labor’ in an arbitrary manner. Later 'time' is integrated into the world map to make the basis for calculating distance based on time.
"These were the Greek geographers of the third century BC, who used astronomical calculations to draw the three reference lines on their world maps - the three latitude lines now known as the equator and the tropics. of Cancer and Capricorn. Subsequently added latitude lines east of Eratosthenes, positioned to operate on familiar landmarks. A century later, mathematics made the system more regular, by making lines that were evenly spaced and truly parallel, not determined by the lay of the earth or the places that people found important. He also added a system of north-south longitude lines, running from pole to pole, and divided 360 degrees of both latitude and longitude into smaller segments, each degree divided into 60 minutes and every minute in 60 seconds. (Both the 360 degree circle and the 60-fold division of degrees and minutes came from the fourth century BC sexagesimal system of counting in Babylon, adopted because of the ease of dividing the whole number 60 and 360 .) "
Since the earth produces a complete revolution every twenty-four hours, we make it the basis of distance calculations as well, every single hour it rotates to fifteen degrees of longitude.
This means that each level of longitude corresponds to four minutes of time. The time: 14th century until the advent of watches, in the 14th century AD, one hour was a variable concept. This is a practical division of the sun into 12 segments (12 is the most convenient number for dividing into fractions, as it is divided into 2, 3 and 4). For the same reason 60, divided by 2, 3, 4 and 5, has become a larger measurement framework since the Babylonian times.
The traditional concept of time, as a twelfth hour between dawn and dusk, is useful in terms of daily time keeping. Approximate appointments are easy to make, at times easy to understand. Noon is always the sixth hour. Half past seven in the afternoon is the ninth hour - popular among Christians as the time of Jesus' death on the Cross.
The problem with traditional time is that it varies in length every day. And one hour during the day is different from one at night (also divided into twelve equal hours). A clock will not reflect this variation, but it may offer something more useful. It can provide every day something that naturally happens only twice a year, in the spring and autumn equinox, if the 12 hours of the day and the 12 hours of the night are the same length.
In the 14th century, along with the first practical clocks, the meaning of an hour gradually changed. It becomes a certain period of time, a twenty-four of a full solar cycle from dawn to dusk. And the sun is considered to be 24 hours, even though it still features clock faces as two twelves.
Minutes and seconds: 14th - 16th century
Although the first clocks can measure periods of less than an hour, but later the quarter-hours are enticing that seem insufficient. With the advent of dials for clock faces, in the 14th century, something like a minute was needed. The Middle Ages, through a captivating route from Babylon, inherited a scientific dimension measurement based on 60. In medieval Latin the unit of a sixty is pars minuta prima ('first fraction'), and that sixty is pars minutes secunda ('second fraction'). Thus, in a principle 3000 years old, minutes and seconds are found in time.
Minutes have been mentioned since the 14th century, but the clocks are not accurate enough for anyone to bother about seconds until two centuries later.
"Why does time always move forward?"
Whereas, the earth is constantly moving in one direction (24 X 7). So we are still tracking this phenomenon in the same direction, called 'TIME' …… ..
What is the distance / length?
Length - Length is the most necessary measure of daily life, and units of length in many countries still reflects the first elementary method of humanity. The inch is thumb. The foot speaks for itself. The yard is closely related to a human pace, but also originated from two elbows (arm size). The mile is derived from the Roman mille passus - a ‘thousand feet’, approximately one mile because the Romans refer to a pace as two steps, turning the pedestrian on both feet. With measurements like these, it is easy to explain how far the next village is and to exercise if something can get through a door.
For complex problems in measuring civilization - checking the land to register property rights, or selling a commodity according to length - a more accurate unit is required.
The solution is a rod or bar, of exact length, kept in a central public place. From the 'standard' other identical rods can be copied and distributed through the community. In Egypt and Mesopotamia these standards were kept in temples.
The basic unit of length in both civilizations is the elbow, based on an arm measured from elbow to the tip of the middle finger. When a length like this is standardized, it is usually the size of the king first taken as standard. Gravity is a name of a powerless. There is no gravity, this is the weight of the wind above, keeping us 'drowning', we are not stuck anywhere, or otherwise we can not learn to walk. Barometer and atmospheric pressure: 1643-1646
Like many significant findings, the principle of the barometer is inadvertently followed. Evangelista Torricelli, Galileo's assistant at the end of his life, was interested in why it was harder to pump water from a well where the water was farther below ground level. He suspects that the reason may be the weight of the extra column of air above the water, and he describes a method of testing this theory.
He filled a glass of mercury tube. Immerse it in a mercury bath, and raise the sealing end to a vertical position, he finds that the mercury has slipped slightly into the tube. Consequently, the weight of the mercury air in the bath supports the weight of the mercury column in the tube. If this is true, then the space in the glass tube above the mercury column should be a vacuum. This plunged him into immediate controversy with the traditionalists, who were married to the ancient theory - which goes back to Aristotle - that ‘nature is disgusted with a vacuum’. But it also urges von Guericke, over the next decade, to develop the vacuum pump.
The concept of variable atmospheric pressure occurred to Torricelli when he noticed, in 1643, that the height of his column of mercury sometimes varied slightly from its normal level, to 760 mm above the level of mercury in the bath. Observation suggests that these variations are closely related to changes in weather. The barometer was born. With the concept established that air is heavy, Torricelli predicted that there should be less atmospheric pressure at higher altitudes. It is not hard to imagine an experiment that would try it, but the popularity of verifying point 1646 was attached to Blaise Pascal - even though he was not the one conducting the research.
Having a weak constitution, Pascal urged his more stable brother-in-law to drive a barometer at various levels of the 4000-foot Puy de Dôme, near Clermont, and to read. The brother-in-law comes down from the mountain with the good news that the readings are really different. Atmospheric pressure varies with altitude.