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Create the page "Sqrt(2)" on this wiki! See also the search results found.
- \((2) ~ ~ ~ \displaystyle A+B z= \lim_{M\rightarrow \infty} \frac{M A+ M B}{M+z} \frac{\frac{-A^2+A v-A w+u}{B^2}+\frac{v-A}{B} z}{\frac{A+w}{B}+z}\)5 KB (830 words) - 18:44, 30 July 2019
- https://www.morebooks.de/store/gb/book/superfunctions/isbn/978-620-2-67286-3 [[File:978-620-2-67286-3-full.jpg|440px]]15 KB (2,166 words) - 20:33, 16 July 2023
- \(\mathrm{mori}(z)=\displaystyle \frac{ J_0 (L_1 z)}{1-z^2}\) where \(L_1\approx 2.4\) is first zero of the Bessel function, \(J_0(L_1)\!=\!0~\).3 KB (456 words) - 18:44, 30 July 2019
- return D + (153*m+2)/5 + 365*y + y/4 - y/100 + y/400 - 32045 - 2400000; } \rm Qu\! & 233.214 - 0.908933 x - 0.00361841 x^2 & 3.94609& 5.84960\\5 KB (433 words) - 18:47, 30 July 2019
- \((2) ~ ~ ~ \rho(x,t)=F(\mathrm e^x,t)~ \mathrm e^x\) From equation (2), the distribution \(F\) can be expressed through the new function \(\rho\)5 KB (865 words) - 18:44, 30 July 2019
- ...\frac{1}{2}\mathrm{Lof}(z)-\mathrm{Lof}\Big(\frac{z}{2}\Big)-\frac{\ln(2)}{2} z \right)\) \frac{2^{-z/2}\,\sqrt{z!}}6 KB (883 words) - 18:44, 30 July 2019
- where \(\psi_n(z)=\frac{1}{\sqrt{N_n}}\)[[HermiteH]]\(_n(z)\, \exp(-z^2/2)\) is [[oscillator function]], {2^n \sqrt{\pi}}6 KB (770 words) - 18:44, 30 July 2019
- [[File:2014ruble15t.png|240px]]Fig.2. Fitting from 2014.12.14 ...sere loaded, see Fig.1; then, the data for Euro and then for Yen, see Fig.2. and Fig.3.18 KB (2,080 words) - 13:48, 1 February 2022
- {2.000000000000000, 0.3333333333333333, 0.1500000000000000, 0.0892857142857142 M=29; qq=.5-.5*z; q=sqrt(qq); s=c[M]*q; for(m=M-1;m>0;m--) {s+=c[m]; s*=qq;}4 KB (488 words) - 06:58, 1 December 2018
- 8.173825669330684e-9, -2.0624513960198102e-8, //11 -2.5497322696797093e-10,6.897078914225712e-11, //152 KB (354 words) - 06:58, 1 December 2018
- [[File:Arqnem20zt.jpg|400px|thumb|\(u\!+\!\mathrm i v=\mathrm{ArqNem}_{2}(x\!+\!\mathrm i y)\)]] \(q\!=\!2\).7 KB (1,319 words) - 18:46, 30 July 2019
- ...pg|200px|thumb|Thick green curve: \(y=\eta^x\); thin red curve: \(y=(\sqrt{2})^x\)]] These pictures look similar to those for the case \(b=\sqrt{2}\approx 1.414\), see article [[Base sqrt2]].4 KB (559 words) - 17:10, 10 August 2020
- ...apT.png|300px|thumb|[[Complex map|Map]] of [[exponent]] to base \(b=\sqrt{2}\); lines of constant \(u\) and lines of constant \(v\) show ...00.jpg|300px|thumb|[[Complex map|Map]] of [[Logarithm]] to base \(b=\sqrt{2}\); lines of constant \(u\) and lines of constant \(v\) show3 KB (557 words) - 18:46, 30 July 2019
- \(T_{n+1}(x)=2 x T_n(x)-T_{n-1}(x)\) ...)\, \sin(x\, y)\, \frac{\mathrm d x}{\sqrt{1\!-\!x^2}} = (-1)^n \frac{\pi}{2}\, J_{2n+1}(y)1 KB (186 words) - 18:48, 30 July 2019
- </ref> and \(~y=\sin^n(\pi/2)-\sin^n(x)~\) with \(~n\!=\!100~\) http://www.ams.org/journals/mcom/2010-79-271/S0025-5718-10-02342-2/home.html<br>7 KB (1,031 words) - 03:16, 12 May 2021
- ...ansform, refers to the integral transform with kernel \(K(x,y)=\sqrt{\frac{2}{\pi}} \cos(xy)\); \(\displaystyle g(x)=\,\)[[CosFT]]\(f\,(x) \displaystyle =\sqrt{\frac{2}{\pi}} \int_0^\infty \cos(xy) \, f(y) \, \mathrm d y\)3 KB (468 words) - 18:47, 30 July 2019
- X[n_] = BesselJZero[0,n]/Sqrt[S]; W[n_] = Sqrt[2./S]/Abs[BesselJ[1, BesselJZero[0,n]]];8 KB (1,153 words) - 18:44, 30 July 2019
- [[ackermann]]\(_{2,x}(y)=x\, y\) \frac{\exp(\mathrm i x) + \exp(-\mathrm i x)}{2}\)3 KB (496 words) - 18:45, 30 July 2019
- Let \(~ T(z)=z+b z^2 + c z^3+..\) T[z_] = z + b z^2 + c z^3;11 KB (1,715 words) - 18:44, 30 July 2019
- \( F''+ 2 \mathrm i \dot F=0\) then, assuming some large positive \(M\), expression \(M^2 z/k\) has sense of the coordinate along the propagation of wave, and \(M x/8 KB (1,216 words) - 18:43, 30 July 2019
