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New tidal question
Nutation is most easily seen as an annalemma but how does this affect
the tides? What am I talking about anyway? Cheers |
New tidal question
Don't forget about gravitational delay.
"Navigator" wrote in message ... Nutation is most easily seen as an annalemma but how does this affect the tides? What am I talking about anyway? Cheers |
New tidal question
Now there's a thought. Would that the Gilligan were here to discuss such
relatively massive subjects. Cheers Bob Crantz wrote: Don't forget about gravitational delay. "Navigator" wrote in message ... Nutation is most easily seen as an annalemma but how does this affect the tides? What am I talking about anyway? Cheers |
New tidal question
The gravitational delay is, in part, the cause of ultimate doom!
The earth will stop rotating and the moon will be flung from its orbit. Read all about it he http://athene.as.arizona.edu/~lclose...202/lect6.html What ever happened to Gilligan? Here used to be here frequently years ago. BC "Navigator" wrote in message ... Now there's a thought. Would that the Gilligan were here to discuss such relatively massive subjects. Cheers Bob Crantz wrote: Don't forget about gravitational delay. "Navigator" wrote in message ... Nutation is most easily seen as an annalemma but how does this affect the tides? What am I talking about anyway? Cheers |
New tidal question
Bob Crantz wrote:
What ever happened to Gilligan? Here used to be here frequently years ago. He went to the sock shop and bought lots. -- Wally www.forthsailing.com www.wally.myby.co.uk |
New tidal question
Navigator wrote:
Nutation is most easily seen as an annalemma but how does this affect the tides? I'll take a stab at: the gravitational effects on the tides have a period that can be reasonably approximated to 93 years. What am I talking about anyway? Differences between solar and lunar declination at a given point in time? -- Wally www.forthsailing.com www.wally.myby.co.uk |
New tidal question
Perhaps you might tell Doug, Jeff and other people interested in tides
what Nutation has to do with an annalemma first? Cheers Wally wrote: Navigator wrote: Nutation is most easily seen as an annalemma but how does this affect the tides? I'll take a stab at: the gravitational effects on the tides have a period that can be reasonably approximated to 93 years. What am I talking about anyway? Differences between solar and lunar declination at a given point in time? |
New tidal question
That site is a bit weak on tidal issues. Gilligan is much quieter since
he lost Neal. Cheers Bob Crantz wrote: The gravitational delay is, in part, the cause of ultimate doom! The earth will stop rotating and the moon will be flung from its orbit. Read all about it he http://athene.as.arizona.edu/~lclose...202/lect6.html What ever happened to Gilligan? Here used to be here frequently years ago. BC "Navigator" wrote in message ... Now there's a thought. Would that the Gilligan were here to discuss such relatively massive subjects. Cheers Bob Crantz wrote: Don't forget about gravitational delay. "Navigator" wrote in message ... Nutation is most easily seen as an annalemma but how does this affect the tides? What am I talking about anyway? Cheers |
New tidal question
Navigator wrote:
Perhaps you might tell Doug, Jeff and other people interested in tides what Nutation has to do with an annalemma first? I'll give it a go... An analemma is a bendy curve thing which plots the declination of a body against time. The analemma for the sun is a figure-8 shape, the crossover of the figure-8 indicating when the sun crosses the equator twice a year. An analemma for a lunar month would have a similar shape. However, because the moon's orbit nutates, the curve is rather more complex and covers a longer period. The complexity comes about because the point at which the moon crosses the equator constatly changes - the path of the orbit itself slowly rotates around the earth. This rotation of the orbit is called nutation. The nutation period of the moon's orbit is generally given as 18.61 years. The tides are nominally a function of the gravitational pulls of the moon and sun working together (modifed by things like local geography). Given that there are springs and neaps, we can see that the relative positions of the two bodies in the sky have an effect on how much 'pull' there is at a given time. Note that, if there was no moon, the gravitational factor in the tidal cycle would be solar - much more constant and easy to predict. It strikes me that neaps don't occur simply as a result of 'less pull' on the tidal bulge, but that there is some pull from one body, and some from another which is at a different point in the sky - the main bulge mght be following the moon, but there is a secondary bulge following the sun. Were it otherwise, there would be no springs and neaps. As noted in another post, the sun and moon don't simply make their way around the equator, but travel through paths that are each at an angle to the equator. Logically, this means that the direction of their gravitational pulls is not perpindicular to the equator, but is nominally in the direction of each body. Although the primary effect, springs and neaps, is seen in terms of the position of each body around the sky - the Right Ascension (RA) of each - there must be a similar, though less pronounced, effect as each body follows its path above and below the equator. For instance, there are springs at many times, but springs when there is a solar eclipse wll be different from springs when the sun is, say at it's highest declination (summer in the northern hemisphere) and the moon is at its lowest. In other words, the bodies might be at the same RA, but their disparate declinations will 'spread' the gravitational pull, some above the equator, some below. When they're perfectly aligned during a solar eclipse, the pulls are concentrated into a single direction. While the sun's path is straightforward, the combined effect of the sun and moon goes through a huge range of alignments - the sun might pass over a given point every year, but, due to nutation, the moon will be in a different relative position compared to last year. Also, because the moon's nutation period is 18.61 years, when the moon's cycle starts to repeat, it's out of sync with that of the sun. Since this stuff, with its talk of periods, is all very cyclical, one naturally wonders if there is maybe a 'grand cycle' that can be derived, even if it's only an approximation. Note that the sun has a yearly period, and that the moon's nutation period is measured in years - 18.61. To derive an approximate period for a 'grand cycle', one simply has to multiply 18.61 by a number that will give a result that is close to a whole number of years. The first resonable approximation is arrived at when we multply 18.61 by 5, giving 93.05 years. Rounding for convenience, this means that, for a given start point, the combined solar and lunar cycle starts to repeat after 93 years, or 5 nutations - the two bodies will have the same delination and RA that they had at our start point. -- Wally www.forthsailing.com www.wally.myby.co.uk |
New tidal question
Wally wrote:
An analemma is a bendy curve thing which plots the declination of a body against time. Um, make that against RA - that's why it would be a figure-8. Against time would just make it a wavy line. -- Wally www.forthsailing.com www.wally.myby.co.uk |
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