diff --git a/templates/latex/result_sens/en-heading.tex b/templates/latex/result_sens/en-heading.tex
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+\section{Result of the calibration}
diff --git a/templates/latex/result_sens/en-para_0-alt_0-result.tex b/templates/latex/result_sens/en-para_0-alt_0-result.tex
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+The results of the measurements are given in the following table. 
+\(U(S)/S\) is the uncertainty of the expanded relative measurement uncertainty
+with coverage factor \(k = 2\) at the time of calibration. Included is the repeatability of the measurement under
+otherwise identical conditions (\(p_\text{cal}, T\)).
+
+(((Device.Text.uncertainty)))
+
+\printResultTable
diff --git a/templates/latex/sens/en-heading.tex b/templates/latex/sens/en-heading.tex
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+++ b/templates/latex/sens/en-heading.tex
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+\section{Gauge sensitivity}
diff --git a/templates/latex/sens/en-para_0-alt_0-sigma.tex b/templates/latex/sens/en-para_0-alt_0-sigma.tex
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+The gauge sensitivity \(S\) was calculated according to:
+\[S = \frac{i_\text{c} - i_\text{r}}{i_\text{e}\,p_\text{cal}}\]
+with \(i_\text{c}\) the collector current at calibration pressure \(p_\text{cal}\), \(i_\text{r}\) the collector current
+at residual pressure and \(i_\text{e}\) the emmission current. The gauge sensitivity during use \(S(T_\text{ch})\) is obtained
+from the gas temperature \(T_\text{ch}\) (in kelvins)
+via: \[S(T_\text{ch}) = S(T_0)\frac{T_0}{T_\text{ch}}\]
+with \(T_0\) the gas temperature during calibration.