55 lines
1.6 KiB
TeX
55 lines
1.6 KiB
TeX
\section{Auswertung}
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\subsection{Experiment 1}
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\subsection{Experiment 2}
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\subsection{Experiment 3}
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First the resolution limit has to be measured:
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\begin{align*}
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B_{1} & = 0,3 \cdot 10^-3 m \\
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B_{2} & = 0,6 \cdot 10^-3 m \\
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B &= (0,45 \pm 0,15) \cdot 10^-3 m
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\end{align*}
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Using the eqation $\ref{7}$ $\epsilon$ is calculated:
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\begin{align*}
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tan(\epsilon) & = 4,5 \cdot 10^-3 \\
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\sigma tan(\epsilon) &= (\sigma B)/2 + \sigma f_{ob} \\
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&= 0,19 \\
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\Delta tan(\epsilon) &= 8,55 \cdot 10^-4 \\
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tan(\epsilon) & = (4,5 \cdot 10^-3 \pm 8,55 \cdot 10^-4) \\
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\epsilon &= 0,26 \circ \\
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\Delta \epsilon + \epsilon &= arctan(4,5 \cdot 10^-3 + 8,55 \cdot 10^-4) \\
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&= 0,31 \circ \\
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\Delta \epsilon &= 0,05 \circ \\
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\epsilon &= (0,26 \pm 0,05) \circ
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\end{align*}
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Since the diffraction index n for air is equal to one, the numercal aperture is equal to sin($\epsilon$) (see $\ref{8.1}$):
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\begin{align*}
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A & = 4,54 \cdot 10^-3 \\
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\Delta A + A & = sin(\epsilon + \Delta \epsilon) \\
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&= 5,41 \cdot 10^-3 \\
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\Delta A &= 8,72 \cdot 10^-4 \\
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A & = (4,54 \pm 0,87 ) \cdot 10^-3
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\end{align*}
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According to $\ref{8}$, knowing that the wavelength $\lambda$ is equal to 1, all the necessary values to calculate
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$d_{min}$ are availalble:
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\begin{align*}
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d_{min} & = 1,21 \cdot 10^-4 m \\
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d_{min} + \Delta d_{min} & = \frac{550 \cdot 10^-9 m}{sin(\epsilon - \Delta \epsilon)} \\
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\Delta d_{min} &= 2,9 \cdot 10^-4 m \\
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d_{min} & = (1,21 \pm 2,9) \cdot 10^-4
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\end{align*}
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$d_{min}$ is a smaller value than the grid constant d.
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\newpage
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