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Научный форум dxdyМатематика, Физика, Computer Science, Machine Learning, LaTeX, Механика и Техника, Химия,Биология и Медицина, Экономика и Финансовая Математика, Гуманитарные науки |
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| Страница 1 из 1 |
[ Сообщений: 8 ] |
12.03.2010, 22:29 
![$[0,1]$](https://dxdy-03.korotkov.co.uk/f/a/c/f/acf5ce819219b95070be2dbeb8a671e982.png "$[0,1]$")
:![$\[\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]$](https://dxdy-04.korotkov.co.uk/f/b/8/4/b84dcc998cc6a57863d5df346d05bca382.png "$\[\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]$")
, где ![$\[\left\{ {{r_n}} \right\}_{n = 1}^\infty \]
$](https://dxdy-01.korotkov.co.uk/f/0/8/1/0813c0d3a41e839590efdad11b1274ce82.png "$\[\left\{ {{r_n}} \right\}_{n = 1}^\infty \]
$")
- рациональные числа на ![$\[\left\{ {{r_{{n_k}}}} \right\}\]
$](https://dxdy-01.korotkov.co.uk/f/c/d/b/cdb089883cd7c0f0087248f0e9f28c2c82.png "$\[\left\{ {{r_{{n_k}}}} \right\}\]
$")
, которая стремится (пусть к иррациональному числу) 
очень быстро, так, что ![$\[\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \geqslant \sum\limits_{k = 1}^\infty {\frac{1}
{{{n_k}^2{{\left| {x - {r_{{n_k}}}} \right|}^{1/2}}}}} = + \infty \]$](https://dxdy-03.korotkov.co.uk/f/a/6/c/a6c0bc9b8f2dd1a16bea0541b742551b82.png "$\[\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \geqslant \sum\limits_{k = 1}^\infty {\frac{1}
{{{n_k}^2{{\left| {x - {r_{{n_k}}}} \right|}^{1/2}}}}} = + \infty \]$")
к 
растет так быстрее, чем 
для некоторых подходящих нам 
.![$\[{f_m}\left( x \right) = \sum\limits_{n = 1}^m {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]$](https://dxdy-04.korotkov.co.uk/f/3/d/4/3d4d8f2c1dec7f4471158d3c5b35f5db82.png "$\[{f_m}\left( x \right) = \sum\limits_{n = 1}^m {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]$")
, ![$\[f\left( x \right) = \mathop {\lim }\limits_{m \to \infty } \sum\limits_{n = 1}^m {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} = \sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]
$](https://dxdy-01.korotkov.co.uk/f/8/f/d/8fd3e6476f772957d9236f6186cccf7082.png "$\[f\left( x \right) = \mathop {\lim }\limits_{m \to \infty } \sum\limits_{n = 1}^m {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} = \sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} \]
$")
, ![$\[\mathop {\lim }\limits_{m \to \infty } \int\limits_{\left[ {0,1} \right]} {{f_m}\left( x \right)d\mu } = \int\limits_{\left[ {0,1} \right]} {f\left( x \right)d\mu } \]$](https://dxdy-03.korotkov.co.uk/f/2/5/a/25ade408ed0c365c7ef014358ba720fe82.png "$\[\mathop {\lim }\limits_{m \to \infty } \int\limits_{\left[ {0,1} \right]} {{f_m}\left( x \right)d\mu } = \int\limits_{\left[ {0,1} \right]} {f\left( x \right)d\mu } \]$")
, так?![$\[\int\limits_{\left[ {0,1} \right]} {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} d\mu = \frac{2}
{{{n^2}}}\left( {\sqrt {{r_n}} + \sqrt {1 - {r_n}} } \right)\]$](https://dxdy-01.korotkov.co.uk/f/0/7/0/070cb3272ac44ee39a937d8ffea6256182.png "$\[\int\limits_{\left[ {0,1} \right]} {\frac{1}
{{{n^2}{{\left| {x - {r_n}} \right|}^{1/2}}}}} d\mu = \frac{2}
{{{n^2}}}\left( {\sqrt {{r_n}} + \sqrt {1 - {r_n}} } \right)\]$")
![$\[\mathop {\lim }\limits_{m \to \infty } \int\limits_{\left[ {0,1} \right]} {{f_m}\left( x \right)} d\mu = \sum\limits_{n = 1}^\infty {\frac{{2\left( {\sqrt {{r_n}} + \sqrt {1 - {r_n}} } \right)}}
{{{n^2}}}} \leqslant 4\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}}}} < + \infty \]$](https://dxdy-01.korotkov.co.uk/f/4/9/d/49d831cef4b98d0c9c4822d8ef65882882.png "$\[\mathop {\lim }\limits_{m \to \infty } \int\limits_{\left[ {0,1} \right]} {{f_m}\left( x \right)} d\mu = \sum\limits_{n = 1}^\infty {\frac{{2\left( {\sqrt {{r_n}} + \sqrt {1 - {r_n}} } \right)}}
{{{n^2}}}} \leqslant 4\sum\limits_{n = 1}^\infty {\frac{1}
{{{n^2}}}} < + \infty \]$")
![$\[\int\limits_{\left[ {0,1} \right]} {f\left( x \right)d\mu } \]$](https://dxdy-04.korotkov.co.uk/f/f/8/2/f825888a5d83b6bd748af72cad20203882.png "$\[\int\limits_{\left[ {0,1} \right]} {f\left( x \right)d\mu } \]$")
конечен. А значит и ![$\[{f\left( x \right)}\]$](https://dxdy-02.korotkov.co.uk/f/1/5/5/1555087cf5e2cd33f3d18e2103549e1882.png "$\[{f\left( x \right)}\]$")
конечна почти всюду, т.е. соответствующий ряд сходится почти всюду.
