Suggest a change

These fields are all optional and need only
be supplied if you would like a direct reply.

Subject
Your email address
Your real name

You must answer this!

If you don't, my spam filtering will
ensure that I never see your email.

What's 8 plus five (in digits only)?

Please make your changes here and then
Editing tips and layout rules.

File: TheForeAftTide

''' <link rel="alternate" type="application/rss+xml"
'''       href="/rss.xml" title="RSS Feed">

********> width="25%"
|>>
''' <a title="Subscribe to my feed"
'''    rel="alternate"
'''    href="https://www.solipsys.co.uk/rss.xml">
'''    <img style="border-width: 0px;"
'''         src="https://www.feedburner.com/fb/images/pub/feed-icon32x32.png"
'''         align="middle"
'''         alt="" />Subscribe!</a>
_
''' <a href="https://twitter.com/ColinTheMathmo">
''' <img src="https://www.solipsys.co.uk/new/images/TwitterButton.png"
'''      title="By: TwitterButtons.net"
'''      width="212" height="69"
'''      alt="@ColinTheMathmo"
'''     /></a>
<<|
----
My latest posts can be
found here:
  * ColinsBlog
----
Previous blog posts:
  * TheSidewaysTide
  * WrappingUpWrappingUpTheEarth
  * TheOtherWrappingTheEarthProblem
  * WrappingTheEarth
  * TheRingOfSteel
  * RoundingUpTheRopes
  * OtherOtherOtherRopeAroundTheEarth
  * RopeAroundTheEarthRefined
  * TheOtherRopeAroundTheEarth
  * ElementaryEstimates
  * LatitudeCorrection
  * JustGiveMeTheAnswer
  * MoreMusingOnPollardRho
  * IdleThoughtsAboutPollardRho
  * WhenOptimisingCodeMeasure
  * ADogCalledMixture
  * AnotherPayPalScam
  * WhyTopPostingHasWon
  * UnexpectedInteractionOfFeatures
  * ArchimedesHatBoxTheorem
  * ConsideringASphere
  * ToLinkOrNotToLink
  * GenericAdviceForWritingAThesis
  * JustTeachMyChildTheMaths
  * NotASpectatorSport
  * LeftTruncatablePrime
  * TheDoctorAndTheLawyer
  * FourPointsTwoDistancesProof
  * MeetingRonGraham
  * NapkinRingVersusSphericalCap
  * TheFourPointsPuzzle
  * RadiusOfTheEarthPartTwo
  * GrepTimingAnomaly
  * TheRadiusOfTheEarth
  * ThisWorksToCureMyHiccoughs
  * PerhapsWeSavedOne
  * ThinkingAboutMastodon
  * DisappearingTrainsOnVirgin
  * TheIndependenceGame
  * OneOfMyFavouritePuzzles
  * ThinkingAboutRecursion
  * MemorisingTheTube
  * SpikeySpheres
  * SurprisinglyQuick
  * AnUnexpectedFraction
  * YouHaveToAdmireTheirOptimism
  * RepresentativesMatter
  * PythagorasByIncircle
  * APuzzleAboutPuzzles
  * HowNotToDoTwitter
  * Calculating52FactorialByHand
  * SmallThingsMightNotBeSoSmall
  * NotIfYouHurry
  * FactoringViaGraphThreeColouring
  * AnotherProofOfTheDoodleTheorem
  * WhenObviousIsNotObvious
  * GraphThreeColouring
  * TheDoodleTheorem
  * BeCarefulWhatYouSay
  * TheMutilatedChessboardRevisited
  * AMirrorCopied
  * TheOtherOtherRopeAroundTheEarth
  * PhotocopyAMirror
  * ThePointOfTheBanachTarskiTheorem
  * SieveOfEratosthenesInPython
  * FastPerrinTest
  * RussianPeasantMultiplication
  * FindingPerrinPseudoPrimes_Part2
  * FindingPerrinPseudoPrimes_Part1
  * TheUnwiseUpdate
  * MilesPerGallon
  * TrackingAnItemOnHackerNews
  * HackerNewsUserAges
  * PokingTheDustyCorners
  * ThereIsNoTimeForThis
  * PublicallySharingLinks
  * LearningTimesTables
  * GracefulDegradation
  * DiagrammingMathsTopics
  * OnTheRack
  * SquareRootByLongDivision
  * BeyondTheBoundary
  * FillInTheGaps
  * SoftwareChecklist
  * NASASpaceCrews
  * TheBirthdayParadox
  * TheTrapeziumConundrum
  * RevisitingTheAnt
  * TheAntAndTheRubberBand
  * IrrationalsExist
  * MultipleChoiceProbabilityPuzzle
  * RandomEratosthenes
  * WrappingUpSquareDissection
  * DissectingASquarePart2
  * DissectingACircle
  * DissectingASquare
  * AnOddityInTennis
  * DecisionTreeForTennis
  * DecisionTreesInGames
  * AMatterOfConvention
  * DoYouNourishOrTarnish
  * BinarySearchReconsidered
  * TwoEqualsFour
  * TheLostPropertyOffice
  * TheForgivingUserInterface
  * SettingUpRSS
  * WithdrawingFromHackerNews
----
Additionally, some earlier writings:
  * RandomWritings.
  * ColinsBlog2010
  * ColinsBlog2009
  * ColinsBlog2008
  * ColinsBlog2007
  * ColinsBlogBefore2007
********
!! The "Fore-Aft" Tide

In our last post we saw that when we're in orbit, if we throw
a ball very gently in exactly the right direction, somehow it
bounces back and forth through our position.  We experience a
fictitious force, pulling the ball back to a resting position,
so it moves in Simple Harmonic Motion.

So remember the setup.  You're in orbit around the Earth with
the International Space Station, and you have a juggling ball.
(Don't ask).  You hold it next to your helmet and release it,
and it just stays there, apparently floating.

Now gently push the ball *ahead* of you in orbit.  In effect
you are throwing the ball away from you, and once again, the
expectation is that it will drift away from you in a straight
line at a constant speed.  And once again, it doesn't.

!! So what happens this time?

Well, it depends.

[[[>
https://www.solipsys.co.uk/images/HohmannTransferFirstBurnOrbit.jpg
----
|>> Exactly tangential <<|
]]]
If the throw of the ball is *exactly* tangentially to your current
path then you've added a little energy to its orbit.  It then has
a slightly elliptical orbit, tangent with yours, and so it takes a
little longer to return to its starting point.  You initially see
it going away from you, then it apparently rises a little, and
seems to slow down.  You overtake on the underside - you might
think of it as undertaking(!) - and it falls behind you.  This is
the first stage of a Hohmann transfer orbit to an orbit that is
microscopically higher - it would normally be matched by an exactly
identical "burn" at it's apogee, the highest point in its orbit.

So if we throw the ball exactly tangentially, that's what happens.
The ball ends up in an elliptical orbit, but it's a slightly slower
orbit.

So let's tweak our direction slightly, let's add a tiny "upwards"
component.  The throw of the ball is not exactly tangential, but it
does end up in an elliptical orbit. More, we can arrange this angle
so that the period of that orbit is identical to ours.  If the throw
is gentle enough the angle to our path is tiny.  What happens then?

Remember, we're assuming that we've injected it into an orbit that
has the same period as ours, 92 minutes.

This time the ball starts off travelling away from you, but again,
it apparently slows down, and again, it comes to a complete halt in
23 (or so) minutes.  Then it starts to come back.  It passes you
(or you overtake it) and it starts to fall behind.  As last time it
again slows down, comes to a complete stop, and returns.  Because
the orbital periods match, a complete cycle takes about 92 minutes,
and if you have indeed got the direction exactly right (and that's
inhumanly accurate, I admin) the ball will gently oscillate through
your position, completing a cycle every 92 (or so) minutes.  Again,
Simple Harmonic Motion.

But what's happening this time?

[[[<30
https://www.solipsys.co.uk/images/ForeAftTideA.png
----
|>> The orbits after the push <<|
]]]
This time instead of changing the orientation of the orbit, we're
keeping it in the same plane, but changing it from a (conceptually)
perfect circle to an ever-so-slightly non-circle ... an ellipse. The
diagram at left shows the idea, two orbits that are very nearly the
same shape and that stay close together the entire time.  But the
orbital times match, so they stay "in sync".

[[[>30
https://www.solipsys.co.uk/images/ForeAftTideB.png
----
|>> Exaggerated for clarity <<|
]]]
The diagram at right shows the same configuration, but with the
eccentricity of the ellipse greatly exaggerated to show the effect.

Now we use the fact that the orbital period is determined only by
the length of the semi-major-axis, so provided the ellipse is as
wide as the circle, the orbital period will be identical.

Remember, we're assuming that our gentle "push" of the juggling ball
hasn't altered its orbital period, so that means the "width" of the
ellipse that it now has as its orbit must be same as that of the
circular orbit. That, in turn, means that some of the ellipse will
be outside the circle, and some inside.  The result is that the paths
will cross twice.  In one case the ball will depart forwards, and in
the other we will overtake the ball.

!! Another way to understand it

Can we understand this in simple, local dynamics?  Yes.

By pushing the ball ahead of us we are giving it a little more speed,
so it will rise into a slightly higher orbit.  But now it doesn't have
enough speed to stay at that greater altitude, and while it initially
gets away, the higher orbit is a slower orbit, so we catch up.  Then
it falls to a lower, slightly faster orbit, catches up with us, and so
the cycle repeats. This also requires that our "push" is not exactly
tangential, otherwise we get the Hohmann Transfer Orbit as mentioned
above.  Tricky this, isn't it!

From the outside looking in it's a simple case of slightly different,
overlapping orbits with the same orbital period.  But from our point
of view it's as if there is a mysterious force pulling the ball back
to us, and it bounces back-n-forth in Simple Harmonic Motion.

!! Quantifying the force

So how big is this mysterious force?  Since the period of bounce is
the same as the orbital period, exactly the same calculation works as
last time, and we get exactly the same equation for the force.

So in each direction, sideways and fore-aft, we have an inwards
acceleration of about $1.3x10^{-6} ms^{-2}$ for every metre of
displacement.  Again, not a lot, but enough to have to know
about in some cases.

!! Comparing with gravity

Some people wonder if the Simple Harmonic Motion is caused by
the gravitational attraction of you, or of the Space Station.
We can calculate what mass is needed to have the same attractive
force at one metre.  The formula is Newton's universal law of
gravitation:

* $F=\frac{G~M_1~M_2}{R^2}$.

Using $G\approx 6.673 \times 10^{-11} N\cdot m^2kg^2$, to get
a force of about $1.3x10^{-6} ms^{-2}$ at a distance of 1 metre
we need a mass of about 20,000 kg.  Admittedly that's not huge,
but remember that gravitational attraction falls off with the
*square* of the distance, whereas this tidal force *grows* with
distance (up to a point). So while the gravitational force from
the ISS is relevant when you're very, very close, you have to
be *so* close that you're actually inside, and then all bets
are off.

So no, the gravitational attraction of the ISS isn't really
relevant.

Whew!

!! And next?

In our next post we'll look at the remaining direction - "up"
and "down".

!! Acknowledgements

My thanks to
Neil Walker
for doing the initial calculations of gravitational attraction,
''' Ben Ashforth    (<a href="https://twitter.com/WoollyBenguin">Twitter</a>)
for a correction about the orbital period, and the "exaggerated" diagram,
and
''' Bill Mullins    (<a href="https://twitter.com/mullins_bill">Twitter</a>)
for conversations about transfer orbits, /etc./

Their contributions made this post much better than it might have been.

----

|>>
| |>> <<<< Prev <<<< ---- TheSidewaysTide <<| | : | |>> >>>> Next >>>> ---- TheUpDownTides ... <<| |
----
********>
''' <a href="https://mathstodon.xyz/@ColinTheMathmo">
''' <img src="https://www.solipsys.co.uk/images/Mastodon_Mascot.png"
'''      width="256" height="280"
'''      alt="https://mathstodon.xyz/@ColinTheMathmo"
'''     /></a>
********
''' <a href="https://mathstodon.xyz/@ColinTheMathmo/">You can follow me on Mathstodon.</a>
_ _ _ _
[[[>
''' <a href="https://twitter.com/ColinTheMathmo">Of course, you can also<br>follow me on twitter:</a>

''' <a href="https://twitter.com/ColinTheMathmo">
''' <img src="https://www.solipsys.co.uk/new/images/TwitterButton.png"
'''      title="By: TwitterButtons.net"
'''      width="212" height="69"
'''      alt="@ColinTheMathmo"
'''     /></a>
''' <img src="/cgi-bin/CountHits.py?TheForeAftTide" alt="" />
]]]
********<

----

!! Send us a comment ...

''' <form action="https://www.solipsys.co.uk/cgi-bin/FormMail.pl" method=post>
''' <input type=hidden name="recipient"               value="colinsblogcomment@solipsys.co.uk" >
''' <input type=hidden name="subject"                 value="Blog comment : TheForeAftTide"         >
''' <input type=hidden name="redirect"                value="https://www.solipsys.co.uk/new/ThankYouForYourComment.html" >
''' <input type=hidden name="missing_fields_redirect" value="https://www.solipsys.co.uk/RequestError.html">
''' <input type=hidden name="env_report"              value="REMOTE_HOST, REMOTE_ADDR, HTTP_USER_AGENT"  >
''' <input type=hidden name="print_blank_fields"      value="1"                                          >

********> width="47%"
You can send us a message here. It doesn't get published,
it just sends us an email, and is an easy way to ask any
questions, or make any comments, without having to send a
separate email. So just fill in the boxes and then
''' <font size="+4"><INPUT TYPE="submit" VALUE="CLICK HERE TO SEND"></font>
******** width="53%"
********<

''' <table cellpadding="5">
'''   <tr>
'''     <td valign="top">Your name </td> <td valign="top">:</td>
'''     <td> <input type=text name="realname" size="48"> </td>
'''   <tr>
'''     <td valign="top">Email </td> <td valign="top">:</td>
'''     <td> <input type=text name="email" size="48"> </td>
'''     </tr>
'''   <tr>
'''     <td valign="top">Message </td> <td valign="top">:</td>
'''     <td> <TEXTAREA NAME="Message" ROWS=10 COLS=64></TEXTAREA> </td>
'''     </tr>
'''   </table>

''' <center>
'''   <font size="+4">
'''     <INPUT TYPE="submit" VALUE="CLICK HERE TO SEND">
'''     </font>
'''   </center>
''' </form>

********<