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GH from MO
GH from MO
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In the book R. M. Young,: An introduction to non-harmonic Fourier series, I came across the following problem (page 18):

Problem. Show that the sequence $\left \{ \frac{1}{x+1},\frac{1}{x+2},\frac{1}{x+3}, \dots \right \}$ is complete in $L^2[0,1]$.

I tried to apply the Müntz-SzaszSzász theorem but it didn't work out. Any ideas or approaches how to show completeness here? Thanks!

In the book R. M. Young, An introduction to non-harmonic Fourier series, I came across the following problem (page 18):

Problem. Show that the sequence $\left \{ \frac{1}{x+1},\frac{1}{x+2},\frac{1}{x+3}, \dots \right \}$ is complete in $L^2[0,1]$.

I tried to apply the Müntz-Szasz theorem but it didn't work out. Any ideas or approaches how to show completeness here? Thanks!

In the book R. M. Young: An introduction to non-harmonic Fourier series, I came across the following problem (page 18):

Problem. Show that the sequence $\left \{ \frac{1}{x+1},\frac{1}{x+2},\frac{1}{x+3}, \dots \right \}$ is complete in $L^2[0,1]$.

I tried to apply the Müntz-Szász theorem but it didn't work out. Any ideas or approaches how to show completeness here? Thanks!

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Muzi
Muzi
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Completeness of the sequence $\left \{ \frac{1}{x+1},\frac{1}{x+2},\frac{1}{x+3}, \dots \right \}$ in $L^2[0,1]$

In the book R. M. Young, An introduction to non-harmonic Fourier series, I came across the following problem (page 18):

Problem. Show that the sequence $\left \{ \frac{1}{x+1},\frac{1}{x+2},\frac{1}{x+3}, \dots \right \}$ is complete in $L^2[0,1]$.

I tried to apply the Müntz-Szasz theorem but it didn't work out. Any ideas or approaches how to show completeness here? Thanks!