Arc length, curvature and area: Difference between revisions
From Elliptic Curve Crypto
m Rational Point moved page Arc length and curvature to Arc length, curvature and area: mention area |
Metes and bounds |
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Computing | == “Metes and bounds” == | ||
Computing arc lengths and areas on elliptic curves is in general very difficult and involves transcendental [[elliptic function]]s and [[elliptic integrals]]. If ''y''=''f''(''x''), then the arc length ''s'' of the function plot may be computed as | |||
:<math>s = \int \sqrt{dx^2+dy^2} | :<math>s = \int \sqrt{dx^2+dy^2} | ||
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where the radius of the osculating circle is ''r''=1/''κ'' when ''f’’''(''x'')≠0. | where the radius of the osculating circle is ''r''=1/''κ'' when ''f’’''(''x'')≠0. | ||
To be continued ... | |||
Latest revision as of 15:45, 30 December 2024
“Metes and bounds”
Computing arc lengths and areas on elliptic curves is in general very difficult and involves transcendental elliptic functions and elliptic integrals. If y=f(x), then the arc length s of the function plot may be computed as
and the curvature as
where the radius of the osculating circle is r=1/κ when f’’(x)≠0.
To be continued ...
