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\[\sqrt{-g}= \sqrt{h}\]
\[56(1986)1319\]
\[n= \frac{n_2}{n_1-1}= \frac{n_3}{n_1-1}\]
\[d^2x \sqrt{h(x)}\]
\[4n= \frac{2n \times 2n}{n}\]
\[\frac{| \sin \Delta|}{ \sin \Delta}\]
\[z= \frac{1}{ \sqrt{2}}(x+iy)\]
\[\theta=2 \alpha_1+4 \alpha_2+6 \alpha_3+5 \alpha 4+4_ \alpha 6+2_ \alpha 7+3 \alpha_5\]
\[x \rightarrow-1\]
\[\sqrt{1+z^2}\]
\[z=x-iy\]
\[\pm i \sqrt{2n}\]
\[A^{-1}_{ \frac{3}{5}}A^{1}_{- \frac{3}{5}}\]
\[m \geq \sqrt{ \frac{3}{2}}H\]
\[\cos(kX)\]
\[\frac{( k-i_1+1)(k-i_1+2)}{2}\]
\[\int A_z\]
\[129106\]
\[\frac{30}{3072}\]
\[b \geq \frac{1}{a-1}\]
\[\cosk_nx^5\]
\[3 \times 4+r-4\]
\[v \leq x\]
\[w=x^2+ix^3\]
\[A^{-1}_{+ \frac{4}{5}}\]
\[\lim_{r \rightarrow 0}f(r)= \sqrt{r}\]
\[(- \frac{1}{4},- \frac{3}{4})\]
\[p_{0}=(2n+1) \pi T= \frac{(2n+1) \pi}{ \beta}\]
\[0<a+ \frac{1}{2}< \frac{1}{2}\]
\[n!L_n^{(m-n)}(z)=(-z)^{n-m}m!L_m^{(n-m)}(z)\]
\[- \pi \leqy \leq \pi\]
\[- \frac{ \sin \alpha( \infty)}{2 \pi}\]
\[v(z)=z^{n+1}-(-1)^nz^{-n+1}\]
\[4+n\]
\[(a+b)\]
\[X=x_0(x-x_0)\]
\[\phi_0=dx^{136}+dx^{235}+dx^{145}-dx^{246}\]
\[\frac{1}{ \sqrt 3}\]
\[\int^{ \infty}_{0} duV(u)u^{ \frac{d}{2}-2} \neq 0\]
\[(x^6,x^7,x^8,x^9)\]
\[b \rightarrow 1\]
\[-0.998\]
\[V(x)=v_px^p+v_{p-1}x^{p-1}+ \ldots\]
\[j=|q|- \frac{1}{2}+p>|q|- \frac{1}{2}\]
\[(x-1)^{2}-32x \gt0\]
\[x^3=- \frac{1}{48} \frac{v^6}{ \alpha_1}\]
\[any\]
\[x^{ \prime}=(ax+b)(cx+d)^{-1}\]
\[\cos2p \thetak\]
\[z=x^2+ix^3\]
\[( \frac{p2^{-p}}{1+p}+1)\]
\[(x^1-x^2)\]
\[c \times(a-b)\]
\[\frac{1}{n!}\]
\[m^2n^2+4mx_1^2x^3=-4y_1^2y_3\]
\[x \pm iy\]
\[(1+1)+(5 \times0)\]
\[\frac{43}{9}\]
\[y \rightarrow ky\]
\[c= \frac{1}{2} \left(1- \frac{1}{2N} \right)\]
\[(x^3+ix^6)\]
\[3x_B=12x_A=4x_C\]
\[- \frac{(3+z^2)^2}{16}\]
\[b= \frac{1}{ \sqrt{2}}(A-B)\]
\[\int d^2x\]
\[(2k+1) \times(2k+1)\]
\[f= \sum_{n=1}^{ \infty}a_n(f)q^n\]
\[1^3+1^3+(-2)^3=-6\]
\[s_{b}s_{ab}+s_{ab}s_{b}=0\]
\[f=z^1( \cos \theta z^2+ \sin \theta z^1)\]
\[u(x-y)\]
\[\sum_{k=1}^{ \infty}(-1)^k \frac{1}{w^{2k+1}}=- \frac1w \frac1{1+w^2}\]
\[h_{xx}=-h_{yy} \neq0\]
\[(c-3) \times c\]
\[1 \times(6-3-1)\]
\[n \geq 9\]
\[f=f_a+f_b+f_c\]
\[x= \frac{2 \pi}{ \sqrt{2}}(n+ \frac{1}{2})\]
\[\beta=2- \sqrt3\]
\[[t^a,t^b]=if^{abc}t^c\]
\[dx_{n}^2-dx_{n+1}^2\]
\[2 \times7\]
\[z=x_{21}x_{13}^{-1}x_{34}x_{42}^{-1}\]
\[x^1 \ldots x^5\]
\[x^{-n}\]
\[(a-b)-(k-b-c) \times(a-b)=(a-k+c) \times(a-b)\]
\[y=f(x)\]
\[\frac{1}{2}(r-1)(r+1)(r+2)\]
\[cab=(abc)^{c}\]
\[e^{-2q^{ \prime}(1-y)}<e^{-2 \sqrt{v}(1-y)}\]
\[(y_{12}^2)^{-p}(y_{13}^2)^{p}\]
\[- \frac{1}{3}\]
\[[3,- \frac{27}{4}, \frac{171}{14},- \frac{729}{40}, \frac{729}{70}]\]
\[y(x)=a_i(x)\]
\[r^2= \sum_iy^i y^i\]
\[(n-1)+4=n+3\]
\[n2^{n-1}+1-2^n\]
\[\beta=y-x\]
\[\alpha_3+2 \alpha_4+ \alpha_5+2 \alpha_6+ \alpha_7\]
\[V(x)=v_px^p+v_{p-1}x^{p-1}+ \ldots\]
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