From dee58ec0975e05014a35aa9a633e65c5c45f24d3 Mon Sep 17 00:00:00 2001
From: Christian Bager Bach Houmann <christian@bagerbach.com>
Date: Thu, 13 Jun 2024 11:36:10 +0200
Subject: [PATCH] fixes 2

---
 report_thesis/src/sections/problem_definition.tex | 2 +-
 1 file changed, 1 insertion(+), 1 deletion(-)

diff --git a/report_thesis/src/sections/problem_definition.tex b/report_thesis/src/sections/problem_definition.tex
index 94422e71..657ba2ac 100644
--- a/report_thesis/src/sections/problem_definition.tex
+++ b/report_thesis/src/sections/problem_definition.tex
@@ -11,7 +11,7 @@ \section{Problem Definition}\label{sec:problem_definition}
 Lastly, \citet{sunMachineLearningTransfer2021} demonstrated the efficacy of transfer learning in overcoming matrix effects and improving model robustness for rock classification on Mars. Their findings suggest that similar improvements can be achieved in oxide quantification by leveraging knowledge from related domains.
 Studies such as these provide a strong foundation for our assumption that addressing the identified challenges will lead to significant improvements in the accuracy and robustness of predicting elemental concentrations from \gls{libs} data.
 
-\subsection{Quantification based on \gls{libs} data}\label{subsec:quantification}
+\subsection{Quantification Based on LIBS Data}\label{subsec:quantification}
 \gls{libs} spectral data provides intensity readings across a spectrum of wavelengths in the form of Clean, Calibrated Spectra \cite{andersonImprovedAccuracyQuantitative2017}, as described by \citet{wiensPreflightCalibrationInitial2013}.
 The wavelength intensities are quantified in units of photon/shot/mm\textsuperscript{2}/sr/nm.