by neufer » Wed Oct 07, 2015 5:27 pm
Ron-Astro Pharmacist wrote:
Wow. Is this what our sky would look like if time was
quantized?
It would have quite a different look.
https://en.wikipedia.org/wiki/Frame_rate wrote:
<<Frame rate is the frequency (rate) at which an imaging device displays consecutive images. The human eye and its brain interface, the human visual system, can process 10 to 12 separate images per second, perceiving them individually. Persistence of vision creates an illusion of continuity, allowing a sequence of still images to give the impression of motion.
Early silent films had stated frame rates anywhere from 16 to
24 FPS. These frame rates were enough for the sense of motion, but it was perceived as jerky motion. By using projectors with dual- and triple-blade shutters, the rate was multiplied two or three times as seen by the audience.
Thomas Edison said that 46 frames per second was the minimum needed by the visual cortex: "Anything less will strain the eye."
When sound film was introduced in 1926, variations in film speed were no longer tolerated as the human ear is more sensitive to changes in audio frequency. Many theaters were then showing silent films at 22 to 26 FPS which is why
24 FPS was chosen for sound. From 1927 to 1930, as various studios updated equipment, the rate of
24 FPS became standard for 35 mm sound film. At
24 FPS the film travels through the projector at a rate of 456 millimetres (18.0 in) per second. This allowed for simple two-blade shutters to give a projected series of images at 48 per second, satisfying Edison's recommendation.
Many modern 35 mm film projectors use three-blade shutters to give 72 images per second—each frame is flashed on screen three times. Historical experiments in frame rates that were not widely accepted were Maxivision 48 and Showscan, developed by 2001: A Space Odyssey special effects creator Douglas Trumbull.>>
https://en.wikipedia.org/wiki/Chronon wrote:
<<A chronon is a proposed quantum of time, that is, a discrete and indivisible "unit" of time as part of a hypothesis that proposes that time is not continuous. The term was introduced in this sense by Robert Lévi in 1927. Many physicists have suggested that a discrete model of time might work, especially when considering the combination of quantum mechanics with general relativity to produce a theory of quantum gravity. Henry Margenau in 1950 suggested that the chronon might be the time [9.41×10
−24 seconds] for light to travel the classical radius of an electron:
In Piero Caldirola's model, one chronon corresponds to about 6.27×10
−24 seconds for an electron. This is much longer than the Planck time, which is only about 5.39×10
-44 seconds. The Planck time is a theoretical lower-bound on the length of time that could exist between two connected events, but it is not a quantization of time itself since there is no requirement that the time between two events be separated by a discrete number of Planck times. For example, ordered pairs of events (A, B) and (B, C) could each be separated by slightly more than 1 Planck time: this would produce a measurement limit of 1 Planck time between A and B or B and C, but a limit of 3 Planck times between A and C. Additionally, the Planck time is a universal quantization of time itself, whereas the chronon is a quantization of the evolution in a system along its world line. Consequently, the value of the chronon, like other quantized observables in quantum mechanics, is a function of the system under consideration, particularly its boundary conditions. The value for the chronon, θ
0, is calculated from:
From this formula, it can be seen that the nature of the moving particle being considered must be specified since
the value of the chronon depends on the particle's charge and mass.
Caldirola claims the chronon has important implications for quantum mechanics, in particular that it allows for a clear answer to the question of whether a free-falling charged particle does or does not emit radiation. This model supposedly avoids the difficulties met by Abraham–Lorentz's and Dirac's approaches to the problem, and
provides a natural explication of quantum decoherence.>>
[quote="Ron-Astro Pharmacist"]
Wow. Is this what our sky would look like if time was [url=http://www.scientificamerican.com/article/is-time-quantized-in-othe/]quantized[/url]?
It would have quite a different look.[/quote][quote=" https://en.wikipedia.org/wiki/Frame_rate"]
<<Frame rate is the frequency (rate) at which an imaging device displays consecutive images. The human eye and its brain interface, the human visual system, can process 10 to 12 separate images per second, perceiving them individually. Persistence of vision creates an illusion of continuity, allowing a sequence of still images to give the impression of motion.
Early silent films had stated frame rates anywhere from 16 to [b][color=#FF00FF]24[/color][/b] FPS. These frame rates were enough for the sense of motion, but it was perceived as jerky motion. By using projectors with dual- and triple-blade shutters, the rate was multiplied two or three times as seen by the audience. [b]Thomas Edison said that [u]46 frames per second[/u] was the minimum needed by the visual cortex: "[i][color=#0000FF]Anything less will strain the eye.[/color][/i]"[/b]
When sound film was introduced in 1926, variations in film speed were no longer tolerated as the human ear is more sensitive to changes in audio frequency. Many theaters were then showing silent films at 22 to 26 FPS which is why [b][color=#FF00FF]24[/color][/b] FPS was chosen for sound. From 1927 to 1930, as various studios updated equipment, the rate of [b][color=#FF00FF]24[/color][/b] FPS became standard for 35 mm sound film. At [b][color=#FF00FF]24[/color][/b] FPS the film travels through the projector at a rate of 456 millimetres (18.0 in) per second. This allowed for simple two-blade shutters to give a projected series of images at 48 per second, satisfying Edison's recommendation. [b]Many modern 35 mm film projectors use three-blade shutters to give 72 images per second—each frame is flashed on screen three times.[/b] Historical experiments in frame rates that were not widely accepted were Maxivision 48 and Showscan, developed by 2001: A Space Odyssey special effects creator Douglas Trumbull.>>[/quote][quote=" https://en.wikipedia.org/wiki/Chronon"]
<<A chronon is a proposed quantum of time, that is, a discrete and indivisible "unit" of time as part of a hypothesis that proposes that time is not continuous. The term was introduced in this sense by Robert Lévi in 1927. Many physicists have suggested that a discrete model of time might work, especially when considering the combination of quantum mechanics with general relativity to produce a theory of quantum gravity. Henry Margenau in 1950 suggested that the chronon might be the time [9.41×10[sup]−[b][color=#FF00FF]24[/color][/b][/sup] seconds] for light to travel the classical radius of an electron:
[c][img]https://upload.wikimedia.org/math/e/5/9/e5974fdb06573ebf85b000b4c757f5fd.png[/img][/c]
In Piero Caldirola's model, one chronon corresponds to about 6.27×10[sup]−[b][color=#FF00FF]24[/color][/b][/sup] seconds for an electron. This is much longer than the Planck time, which is only about 5.39×10[sup]-44[/sup] seconds. The Planck time is a theoretical lower-bound on the length of time that could exist between two connected events, but it is not a quantization of time itself since there is no requirement that the time between two events be separated by a discrete number of Planck times. For example, ordered pairs of events (A, B) and (B, C) could each be separated by slightly more than 1 Planck time: this would produce a measurement limit of 1 Planck time between A and B or B and C, but a limit of 3 Planck times between A and C. Additionally, the Planck time is a universal quantization of time itself, whereas the chronon is a quantization of the evolution in a system along its world line. Consequently, the value of the chronon, like other quantized observables in quantum mechanics, is a function of the system under consideration, particularly its boundary conditions. The value for the chronon, θ[sub]0[/sub], is calculated from:
[c][img]https://upload.wikimedia.org/math/1/7/1/171e94936706af3b0024697a285766ca.png[/img][/c]
From this formula, it can be seen that the nature of the moving particle being considered must be specified since [u]the value of the chronon depends on the particle's charge and mass[/u].
Caldirola claims the chronon has important implications for quantum mechanics, in particular that it allows for a clear answer to the question of whether a free-falling charged particle does or does not emit radiation. This model supposedly avoids the difficulties met by Abraham–Lorentz's and Dirac's approaches to the problem, and [b][u][color=#0000FF]provides a natural explication of quantum decoherence[/color][/u][/b].>>[/quote]