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A fish curve is an ellipse negative pedal curve that is shaped like a fish. In a fish curve, the pedal point is at the focus for the special case of the squared eccentricity $e^{2}={\tfrac {1}{2}}$ .^[1] The parametric equations for a fish curve correspond to those of the associated ellipse.

Equations

For an ellipse with the parametric equations $\textstyle {x=a\cos(t),\qquad y={\frac {a\sin(t)}{\sqrt {2}}}},$ the corresponding fish curve has parametric equations $\textstyle {x=a\cos(t)-{\frac {a\sin ^{2}(t)}{\sqrt {2}}},\qquad y=a\cos(t)\sin(t)}.$

When the origin is translated to the node (the crossing point), the Cartesian equation can be written as:^[2]^[3] $\left(2x^{2}+y^{2}\right)^{2}-2{\sqrt {2}}ax\left(2x^{2}-3y^{2}\right)+2a^{2}\left(y^{2}-x^{2}\right)=0.$

Properties

Area

The area of a fish curve is given by: ${\begin{aligned}A&={\frac {1}{2}}\left|\int {\left(xy'-yx'\right)dt}\right|\\&={\frac {1}{8}}a^{2}\left|\int {\left[3\cos(t)+\cos(3t)+2{\sqrt {2}}\sin ^{2}(t)\right]dt}\right|,\end{aligned}}$ so the area of the tail and head are given by: ${\begin{aligned}A_{\text{Tail}}&=\left({\frac {2}{3}}-{\frac {\pi }{4{\sqrt {2}}}}\right)a^{2},\\A_{\text{Head}}&=\left({\frac {2}{3}}+{\frac {\pi }{4{\sqrt {2}}}}\right)a^{2},\end{aligned}}$ giving the overall area for the fish as:^[2] $A={\frac {4}{3}}a^{2}.$

Curvature, arc length, and tangential angle

The arc length of the curve is given by $a{\sqrt {2}}\left({\frac {1}{2}}\pi +3\right).$

The curvature of a fish curve is given by: $K(t)={\frac {2{\sqrt {2}}+3\cos(t)-\cos(3t)}{2a\left[\cos ^{4}t+\sin ^{2}t+\sin ^{4}t+{\sqrt {2}}\sin(t)\sin(2t)\right]^{\frac {3}{2}}}},$ and the tangential angle is given by: $\phi (t)=\pi -\arg \left({\sqrt {2}}-1-{\frac {2}{\left(1+{\sqrt {2}}\right)e^{it}-1}}\right),$ where $\arg(z)$ is the complex argument.

References

^ Lockwood, E. H. (1957). "Negative Pedal Curve of the Ellipse with Respect to a Focus". Math. Gaz. 41: 254–257. doi:10.1017/S0025557200037293. S2CID 125623811.
^ ^a ^b Weisstein, Eric W. "Fish Curve". MathWorld. Retrieved May 23, 2010.
^ Lockwood, E. H. (1967). A Book of Curves. Cambridge, England: Cambridge University Press. p. 157.

[lockwood-1] Lockwood, E. H. (1957). "Negative Pedal Curve of the Ellipse with Respect to a Focus". Math. Gaz. 41: 254–257. doi:10.1017/S0025557200037293. S2CID 125623811.

[fish-2] Weisstein, Eric W. "Fish Curve". MathWorld. Retrieved May 23, 2010.

[book-3] Lockwood, E. H. (1967). A Book of Curves. Cambridge, England: Cambridge University Press. p. 157.

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@@ Line 1: / Line 1: @@
-[[Image:Fish curve.svg|right|thumb|180px|The fish curve]]
+[[File:Fish curve.svg|thumb|The fish curve with scale parameter ''a'' = 1]]
+A '''fish curve''' is an ellipse [[negative pedal curve]] that is shaped like a [[fish]]. In a fish curve, the pedal point is at the [[focus (geometry)|focus]] for the special case of the squared [[eccentricity (geometry)|eccentricity]] <math>e^2=\tfrac{1}{2}</math>.{{r|lockwood}} The [[parametric equation]]s for a fish curve correspond to those of the associated [[ellipse]].
-A '''fish curve''' is an ellipse negative pedal curve that is shaped like a [[fish]]. In a fish curve, the pedal point is at the focus for the special case of the eccentricity <math>e^2=\frac{1}{2}</math>.<ref>Lockwood, E. H. "Negative Pedal Curve of the Ellipse with Respect to a Focus." Math. Gaz. 41, 254-257, 1957.</ref> Fish curves can correspond to ellipses with parametric equations.  In mathematics, parametric equations are a method of expressing a set of related quantities as explicit functions of a number of independent variables, known as “parameters.”<ref>Lockwood, E. H. A Book of Curves. Cambridge, England: Cambridge University Press, p. 157, 1967.</ref><ref>Weisstein, Eric W. “Parametric Equations.” From MathWorld – a Wolfram Web Resource. http://mathworld.wolfram.com/ParametricEquations.html accessed 5/23/2010</ref> For example, rather than a function relating variables ''x'' and ''y'' in a [[Cartesian coordinate system]] such as <math>y=f(x)</math>, a parametric equation describes a position along the curve at time ''t'' by <math>x=g(t)</math> and <math>y=h(t)</math>. Then x and y are related to each other through their dependence on the parameter ''t''. The fish curve is a kinematical example, using a time parameter to determine the position, velocity, and other information about a body in motion.
 ==Equations==
-For an ellipse with the parametric equations:
+For an ellipse with the parametric equations
-:<math>\textstyle {x=a\cos(t)-\frac {a\sin^2 (t)}{\sqrt 2}, \qquad y=a\cos(t)\sin(t)}</math>
+<math display="block">\textstyle {x=a\cos(t), \qquad y=\frac {a\sin(t)}{\sqrt {2}}},</math>
+the corresponding fish curve has parametric equations
+<math display="block">\textstyle {x=a\cos(t)-\frac {a\sin^2 (t)}{\sqrt 2}, \qquad y=a\cos(t)\sin(t)}.</math>
+When the origin is [[translation of axes|translated]] to the node (the crossing point), the [[Cartesian equation]] can be written as:{{r|fish|book}}
-the corresponding fish curve has parametric equations:
+<math display="block">\left(2x^2+y^2\right)^2-2 \sqrt {2} ax\left(2x^2-3y^2\right)+2a^2\left(y^2-x^2\right)=0.</math>
-:<math>\textstyle {x=\cos(t), \qquad y=\frac {a\sin(t)}{\sqrt {2}}}</math>
+== Properties ==
-and the Cartesian equation is:
+=== Area ===
-:<math>-2a^4 \sqrt {2} a^3 x-2a^2\left(x^2-5y^2\right)+\left(2x^2+y^2\right)^2+2 \sqrt {2} ax\left(2x^2-3y^2\right)+2a^2\left(y^2-x^2\right)=0</math>,
-which, when the origin is translated to the node, can be written as:<ref>Weisstein, Eric W. “Fish Curve.” From MathWorld – a Wolfram Web Resource. http://mathworld.wolfram.com/FishCurve.html accessed 5/23/2010</ref><ref>Lockwood, E. H. A Book of Curves. Cambridge, England: Cambridge University Press, p. 157, 1967.</ref>
-:<math>\left(2x^2+y^2\right)^2+2 \sqrt {2} ax\left(2x^2-3y^2\right)+2a^2\left(y^2-x^2\right)=0</math>
-==Area==
 The area of a fish curve is given by:
+<math display="block">
+ \begin{align}
-<math>A=\frac {1}{2}\left|\int{\left(xy'-yx'\right)dt}\right|</math>
+ A &= \frac {1}{2}\left|\int{\left(xy'-yx'\right)dt}\right| \\
-<math>=\frac {1}{8}a^2\left|\int{\left[3\cos(t)+\cos(3t)+2\sqrt {2}\sin^2(t)\right]dt}\right|</math>,
+ &= \frac {1}{8}a^2\left|\int{\left[3\cos(t)+\cos(3t)+2\sqrt {2}\sin^2(t)\right]dt}\right|,
+\end{align} </math>
 so the area of the tail and head are given by:
+<math display="block">
+ \begin{align}
+ A_{\text{Tail}} &= \left(\frac {2}{3}-\frac {\pi}{4\sqrt {2}}\right)a^2, \\
+ A_{\text{Head}} &= \left(\frac {2}{3}+\frac {\pi}{4\sqrt {2}}\right)a^2,
+ \end{align} </math>
+giving the overall area for the fish as:{{r|fish}}
+<math display="block"> A = \frac {4}{3}a^2.</math>
+=== Curvature, arc length, and tangential angle ===
-<math>A_{\mathrm{Tail}}=\left(\frac {2}{3}-\frac {\pi}{4\sqrt {2}}\right)a^2</math>
+The arc length of the curve is given by
-<math>A_{\mathrm{Head}}=\left(\frac {2}{3}+\frac {\pi}{4\sqrt {2}}\right)a^2</math>
+<math display="block"> a\sqrt {2}\left(\frac {1}{2}\pi+3\right). </math>
-giving the overall area for the fish as:
-<math>A=\frac {4}{3}a^2</math>.<ref>Weisstein, Eric W. “Fish Curve.” From MathWorld – a Wolfram Web Resource. http://mathworld.wolfram.com/FishCurve.html accessed 5/23/2010</ref>
-==Curvature, arc length, and tangential angle==
-The arc length of the curve is given by <math>a\sqrt {2}\left(\frac {1}{2}\pi+3\right)</math>.
 The curvature of a fish curve is given by:
+<math display="block"> K(t) = \frac {2\sqrt {2}+3\cos(t)-\cos(3t)}{2a\left[\cos^4 t+\sin^2 t+\sin^4 t+\sqrt {2}\sin(t)\sin(2t)\right]^\frac {3}{2}},</math>
-<math>K(t)=\frac {2\sqrt {2}+3\cos(t)-\cos(3t)}{2a\left[\cos^4 t+\sin^2 t+\sin^4 t+\sqrt {2}\sin(t)\sin(2t)\right]^\frac {3}{2}}</math>,
 and the tangential angle is given by:
-<math>\phi(t)=\pi-\arg\left(\sqrt {2}-1-\frac {2}{\left(1+\sqrt {2}\right)e^{it} -1}\right)</math>
+<math display="block"> \phi(t)=\pi-\arg\left(\sqrt {2}-1-\frac {2}{\left(1+\sqrt {2}\right)e^{it} -1}\right), </math>
 where <math>\arg(z)</math> is the complex argument.
+==References==
-==Conversion from two parametric equations to a single equation==
+{{Reflist|refs=
+<ref name=book>{{cite book
-Converting a set of parametric equations involves eliminating the variable t from the simultaneous equations <math>x=x(t), y=y(t)</math>. If one of these equations can be solved for t, the expression obtained can be substituted into the other equation to obtain an equation involving x and y only. If x(t) and y(t) are rational functions then the techniques of the [[Theory of Equations]] such as [[resultants]] can be used to eliminate ''t''. This is possible for the parametric equations describing the fish curve, as shown above.
+ | last = Lockwood | first = E. H.
+ | title = A Book of Curves
+ | location = Cambridge, England
+ | publisher = Cambridge University Press
+ | page = 157
+ | year = 1967
+}}</ref>
+<ref name=fish>{{cite web
-==Usefulness==
+ | last = Weisstein | first = Eric W.
+ | title = Fish Curve
+ | publisher = MathWorld
+ | url = http://mathworld.wolfram.com/FishCurve.html
+ | accessdate = May 23, 2010
+}}</ref>
+<ref name=lockwood>{{cite journal
-The fish curve itself may not have any known applications to physical systems, but parametric equations in general do. Using parametric equations to express curves is practical as well as efficient; for example, one can integrate and differentiate such curves termwise. In general, a parametric curve is a function of one independent parameter, which is usually represented by ''t'', while the symbols ''u'' and ''v'' are commonly used for parametric equations in two parameters.
+ | last = Lockwood | first = E. H.
+ | title = Negative Pedal Curve of the Ellipse with Respect to a Focus
+ | journal = Math. Gaz.
+ | pages = 254–257
+ | volume = 41
+ | year = 1957
+ | doi = 10.1017/S0025557200037293
+ | s2cid = 125623811
+}}</ref>
+}}
-==References==
-{{Reflist}}
-[[Category:Curves]]
+[[Category:Plane curves]]