I think so, yes...When we find the tangent line it is in relation to the surrounding points around the point of interest
Huh ?For a circle tangent line is line that cuts through a single point only but in a parabola this cannot be true because the tangent "scrapes" the neighboring points also
fresh_42 said:There are many somehow strange facts when it comes to dimensions, zero in this case. E.g. our concept of points lead to a homeomorphism between a single and two balls, all three of the same size. (One needs the axiom of choice as well, but the concept of points and orbits is crucial.)
Yes, and yes homeomorphism was wrong. Sorry, wrong mapping.micromass said:What the hell are you talking about? There is no homeomorphism between a single and two balls. Are you trying to explain the Banach-Tarski paradox? That has nothing to do with what you just said.
fresh_42 said:Edit: Homeomorphism isn't plain wrong but trivial, so it's not a major aspect.
As far as I remember the two shared exactly one point where they touched which makes it homeomorph. If my memory is false, of course then it's not.micromass said:No, it is plain wrong. There is no homeomorphism between "one ball" and "two balls".
fresh_42 said:As far as I remember the two shared exactly one point where they touched which makes it homeomorph. If my memory is false, of course then it's not.
Spheres are not. Balls are. 1 ball ↔ 2 touching balls.micromass said:You mean "one ball" and "two balls sharing a point"? Those are not homeomorphic.
fresh_42 said:Spheres are not. Balls are. 1 ball ↔ 2 touching balls.
In this case I claim the opposite. However, using polar coordinates ... It's certainly easier than it is to make a coffee cup out of a ring.micromass said:Prove it.
Maybe if by touching you mean they share a sort of tubular neighborhood that joins the two, meaning that the intersection set is uncountable. If the two balls are just tangent to each other (meaning the two intersect at a single point) , then a standard argument for why the two are not homeomorphic is that the two tangent balls can be disconnected by removing just one point (the point of tangency), while there is no similar point for the single ball. But I do get your point about searching " a ball and two balls touching" yikes for those search results.fresh_42 said:Spheres are not. Balls are. 1 ball ↔ 2 touching balls.
One point is enough. You double the ball and then compress it like with a belt into two balls sharing a common point in 0. If I were better on spherical coordinates I could write down the mapping. (How far (euclidean metric) is a point on a sphere with radius 1 and center in (1/2,0,0) away from (0,0,0)? If that is d then you get the image points by 1/(2d) times all diameters in the domain ball. The singularity can be continuously filled by mapping 0 to 0.)WWGD said:Maybe if by touching you mean they share a sort of tubular neighborhood that joins the two. But I do get your point about searching " a ball and two balls touching" yikes for those search results.
fresh_42 said:One point is enough.
But how do you address the 1-connectivity issue? k-connectivity is a homeomorphism invariant.fresh_42 said:One point is enough. You double the ball and then compress it like with a belt into two balls sharing a common point in 0. If I were better on spherical coordinates I could write down the mapping. (How far (euclidean metric) is a point on a sphere with radius 1 and center in (1/2,0,0) away from (0,0,0)? If that is d then you get the image points by 1/(2d) times all diameters in the domain ball. The singularity can be continuously filled by mapping 0 to 0.)
I mapped the center of the single ball onto the touching point. I can't see where it shouldn't be continuous or not one to one. Ah, I think I got it. One cannot compress [0,1] on {1/2}. Damn, that was a tough one. Thanks for your patience.micromass said:It's not. WWGD's proof shows this.
Yes, that counters injection, aka 1-1-ness.fresh_42 said:I mapped the center of the single ball onto the touching point. I can't see where it shouldn't be continuous or not one to one. Ah, I think I got it. One cannot compress [0,1] on {1/2}. Damn, that was a tough one. Thanks for your patience.
A tangent at a single point is a line that touches a curve at only one point and is parallel to the curve's slope at that point.
A tangent at a single point is calculated by finding the slope of the curve at that point using calculus or by using the formula for slope, which is rise over run (change in y over change in x).
A tangent at a single point helps us understand the behavior of a curve at that specific point. It can also be used to find the rate of change of the curve at that point.
No, a curve can only have one tangent at a single point. This is because a tangent must touch the curve at only one point and be parallel to the slope of the curve at that point.
A tangent at a single point is used in various fields such as engineering, physics, and economics to analyze and model real-world phenomena. It can help determine the maximum or minimum values of a function, and also be used to approximate the behavior of a curve near a specific point.