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How to prove that the following integral assuming $k^2 < 1$ $$\int_{0}^{1} \frac{d x}{\sqrt{1-x^2}\sqrt{1-k^2 x^2}}$$ is convergent?
Assuming[k^2 < 1,
Integrate[1/Sqrt[(1 - x^2)*(1 - k^2*x^2)], {x, 0, 1}]]
EllipticK[k^2]
FunctionRange[{EllipticK[k^2], 0 <= k^2 < 1}, k, y, Reals]
y >= Pi/2
It can also be expressed as how to prove convergence of the following elliptic integral?
EllipticK[k^2], (k^2<1)
In fact the original question asks for demonstrating that the following integral is finite, what Matematica can do simply
FullSimplify[ Integrate[1/(Sqrt[1 - x^2] Sqrt[1 - k^2 x^2]), {x, 0, 1}]
< Infinity,
-1 < k < 1 ]
True
A mathematical proof is comparably easy. We can see that for $\; -1< k<1$ and $\;0\leq x <1$ we have $\frac{1}{ \sqrt{1-k^2 x^2}} \leq \frac{1}{\sqrt{1-k^2}}\;$ and so $$\frac{1}{\sqrt{1-x^2} \sqrt{1-k^2 x^2}} \leq \frac{1}{\sqrt{1-k^2}\sqrt{1-x^2}}$$ and since the both sides of this inequality are nonnegative, integration is a generalization of summation we get $$\int_{0}^{1}\frac{dx}{\sqrt{1-x^2} \sqrt{1-k^2 x^2}} \leq \int_{0}^{1}\frac{dx}{\sqrt{1-k^2}\sqrt{1-x^2}} =\frac{\pi}{2\sqrt{1-k^2}}$$ recalling that $\int_{0}^{1}\frac{dx}{\sqrt{1-x^2}}=\frac{\pi}{2}$
Q.E.D.
A counterpart of a crucial step in the proof can be demonstrated simply as well
Simplify[ 1/(Sqrt[1 - x^2] Sqrt[1 - k^2 x^2])
<= 1/(Sqrt[1 - x^2] Sqrt[1 - k^2]),
-1 < k < 1 && 0 <= x < 1]
True
We've got a better upper bound for the complete elliptic integral of the first kind namely $\frac{\pi}{2 \sqrt{1-k^2}}$. Analogously we can find lower bound of the form $\frac{\pi \arcsin(k)}{2 k}$ and in a slightly different way another lower bound $\frac{\log(\frac{1-k}{1+k})}{2 k}$. The first one works for $x$ close to $0$ and the other one for $x$ close to $1$.
We show all the graphs of appropriate functions on the following plot
Plot[{ EllipticK[k^2], Pi/(2 Sqrt[1 - k^2]), Pi/2 (ArcSin[k]/k),
Log[(1 + k)/(1 - k)]/(2 k)}, {k, 0, 1},
PlotStyle -> {Thick, Dashed, Dashed, Dashed}, AxesOrigin -> {0, 0},
PlotLegends -> "Expressions", PlotRange -> {0, 5}]
Integrate[1/Sqrt[(1 - x^2)*(1 - k^2*x^2)], {x, 0, 1}]
ConditionalExpression[EllipticK[k^2], Re[k^2] <= 1 || k^2 ∉ Reals]
FunctionDomain[EllipticK[k^2], k]
-1 < k < 1
The definition domain just indicated that the EllipticK[k^2] converge only in -1 < k < 1 and divergence outside such interval.
FunctionDomain[EllipticK[k^2], k, Complexes] resulting in -1 + k^2 != 0. It's unclear to me whether the integral Integrate[1/Sqrt[(1 - x^2)*(1 - k^2*x^2)], {x, 0, 1}] converges for such values of k.
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Jan 31, 2022 at 8:33
ClearAll[k]; Integrate[1/Sqrt[(1 - x^2)*(1 - k^2*x^2)], {x, 0, 1}, Assumptions -> k \[Element] Reals && (k^2 > 1 || k^2 < -1)] outputs (-I EllipticK[1 - 1/k^2] + EllipticK[1/k^2])/Abs[k].
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Jan 31, 2022 at 9:59
EllipticK[k^2] does converge for $k>1$ contrary to your statment: "only in -1 < k < 1 and ..."
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Integrate[1/Sqrt[(1 - x^2)*(1 - k^2*x^2)], {x, 0, 1}]$\endgroup$FunctionDomain[EllipticK[k^2], k]$\endgroup$x=1, and it is easuly seen to be integrable by series expansion:In[188]:= Series[1/Sqrt[(1 - x^2) (1 - k^2 x^2)], {x, 1, 1}, Assumptions -> -1 < k < 1] Out[188]= SeriesData[x, 1, { 2^Rational[-1, 2] (1 - k^2)^Rational[-1, 2] (1 - x)^Rational[-1, 2], Rational[-1, 4] 2^Rational[-1, 2] ( 1 - k^2)^Rational[-1, 2] (-1 + k^2)^(-1) (-1 + 5 k^2) ( 1 - x)^Rational[-1, 2]}, 0, 2, 1]$\endgroup$