Logical argument using infinity

Discussion in 'General Philosophy' started by arfa brane, Mar 19, 2019.

  1. arfa brane call me arf Valued Senior Member

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    The Euclidean plane is infinite in extent, so you can have a circle with a radius that gets as close to infinite as you like.

    If you construct a pair of perpendicular lines, they intersect such that a pair of circles with a finite radius exist where each circle is tangent at two points to either line. Any circle tangent to both lines has a centre lying on the line bisecting one of the right angles.

    As the circle radius increases (and the centre gets farther from the point of intersection of the pair of lines) the perpendicular lines are tangent to the circle 90 degrees apart, and as the radius approaches infinity, the points of tangency remain at zero degrees to the circle. But a circle with infinite radius has a straight line between any two points on it, so at infinity the two tangent lines are parallel and 180 degrees apart.
     
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  3. arfa brane call me arf Valued Senior Member

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    To restore a symmetry, you need another line parallel to one of the first two. A circle tangent at two points must lie between the parallel lines, and have the same radius everywhere in the plane.

    However, the two parallel lines are paired with two perpendicular lines which are 180 degrees apart at infinity (divergent), so the locally parallel lines have to be perpendicular in the same place (convergent). So the tangent circle of constant radius shrinks to a point, or prosaically, a constant distance doesn't exist there.
     
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  5. Speakpigeon Valued Senior Member

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    So, where's the logical argument?!
    EB
     
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  7. arfa brane call me arf Valued Senior Member

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    Are you asking what geometry has to do with logic?
    Do you mean what logic can be used with parallel or perpendicular lines? Or with circles tangent to them?

    What exactly are you asking?
     
  8. LaurieAG Registered Senior Member

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    Aristotle said to Zeno "If tyrants apply your paradox to a taxation system we would need infinite money to pay for it" and Zeno responded "My Bad."

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  9. James R Just this guy, you know? Staff Member

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    I don't think I entirely get the point from the word description. Perhaps a diagram would help.
     
  10. arfa brane call me arf Valued Senior Member

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    Ha ha. Like anyone can draw a circle with an infinite radius!
     
  11. LaurieAG Registered Senior Member

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    Replace "need infinite money to pay for it" with "have infinite transactions."
     
  12. James R Just this guy, you know? Staff Member

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    This is the part I don't understand.

    A circle of infinite radius is still a circle. It doesn't turn into a straight line.
     
  13. Write4U Valued Senior Member

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    But is a circle not a ideal object which needs no existence in reality.

    Like Plato's solids?

    Would the question be different if we posited the dimensional geometric properties of an infinite cube?
     
    Last edited: Mar 24, 2019
  14. arfa brane call me arf Valued Senior Member

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    Yes it does, according to my 1st year calculus lecturer (a professor with a Ph.D.).

    For a circle with a large radius, the curvature for any arc of the circle is close to zero, and as the radius increases without limit the curvature along any arc goes to zero. Therefore for a circle with infinite radius, any arc between any two points is a straight line.

    The other way to look at it is as a boundary of the plane. At infinite distance from any point, there is an infinite horizon, a circle with infinite radius that any projected line intersects. Since the circle is infinite, it has no curvature.

    The curvature of a circle with radius R is 1/R. When R = ∞, 1/R = 0. q.e.d.
     
    Last edited: Mar 24, 2019
  15. Write4U Valued Senior Member

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    When R = ∞, 1/R = 0 ?

    What happened to the universe?

    What happens if you draw a perfect circle or a sphere and "inflate" the boundaries infinitely large? Parallell lines anywhere?

    I always thought that a circle is a logical object, not restricted to physics.

    I heard somewhere that any equation that rest on infinity is unsolvable?
     
    Last edited: Mar 24, 2019
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  16. sculptor Valued Senior Member

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    It seems that: Just because it's logical doesn't mean it's rational.
    Is infinity any more real/rational than leprechauns or unicorns?
     
  17. arfa brane call me arf Valued Senior Member

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    7,832
    Not if infinity is assumed to be like any other number (except, paradoxically, infinity isn't a number).

    But that doesn't stop you defining a function with an infinite point in it. Like say, the Mobius transformation whose domain is the complex plane with such a point, at infinity. You can also assume that 1/R is well-defined when R is infinite, or that division by infinity is well-defined.
    Indeed, logic doesn't have to relate rational arguments to rational arguments, it just has to be consistent.

    Is infinity real? Is there more of the universe than we can see? How much more?
     
  18. Write4U Valued Senior Member

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    20,069
    Well, if the universe is finite, then what could possibly be infinite? A permittive condition? Nothing at all?
     
  19. James R Just this guy, you know? Staff Member

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    No. A straight line is the shortest distance between two points. Consider two points on opposite sides of a circle of radius $R$. The straight-line distance between them is $2R$, whereas the distance along the arc is $\pi R$. The distance along the arc is a factor of $\pi /2$ times larger than the straight-line distance, for a given circle of any radius, including a circle of infinite radius.

    Of course, you might point out that if $R\rightarrow \infty$ then the straight-line distance and the distance along the arc are both the same (i.e. both $\infty$) and therefore even though the arc length is $\pi /2$ times larger than the straight-line distance, they are still both the same distance.

    This is the kind of thing that happens when you start talking about infinities. It's probably what's causing your problem with the tangents to the circle that are at right angles.
     
  20. arfa brane call me arf Valued Senior Member

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    7,832
    That doesn't make sense; you can't distinguish the arc length and the straight-line distance like you're trying to do there.
    It isn't a problem, nor is it "my" problem; the tangents at right angles exist locally, where circles have a finite radius.
    --https://math.stackexchange.com/questions/82220/a-circle-with-infinite-radius-is-a-line
     
  21. arfa brane call me arf Valued Senior Member

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    7,832
    Sorry, a typo. that phrase about inversion geometry should read "geometry of the map z ↦ 1/z"
    P.S. If I'm right then James R is wrong with
    . . . since it isn't true for a circle of infinite radius; it doesn't hold because not only is a constant distance meaningless (the distance between parallel lines is zero), but the ratio of a circle to its diameter is also meaningless, there isn't any factor of π/2, at infinity.
     
    Last edited: Mar 25, 2019
  22. arfa brane call me arf Valued Senior Member

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    7,832
    The kind of infinity in the OP is the kind that relies on the notion of projection. Or of a line (a radius R) or pair of lines being extended without limit.

    So define a function, f(R) =1/R. Clearly f decreases as R increases and stays finite. But the limit of f is zero, as R "goes to" infinity, a place, not a number.
    Then show that circles tangent to perpendicular lines, with finite radius r, are in the same place (infinity) when f(r) = 0, as a circle with infinite radius centred on the point of intersection of the two perpendicular lines (the infinite boundary of the plane).
     
  23. Neddy Bate Valued Senior Member

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    I don't understand the OP either. As James R said, all circles have the same shape over a 360 degree arc, regardless of the radius. It seems to me that all Arf is doing when he lets the radius approach infinity, is taking into consideration an arc which spans a smaller and smaller number of degrees of the whole circle. If so, he could do the same with a circle of any finite radius, by simply considering an arc spanning fewer and degrees. This is one of the reasons flat-earthers exist, because at the local level, the curvature of the earth is small enough that it seems flat locally. Or am I missing something here?
     

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