results somewhat done, I guess

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Tom Selier 2024-02-03 16:08:35 +01:00
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commit f71bb93d94
4 changed files with 81 additions and 9 deletions

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@ -112,7 +112,7 @@
$N$ is the total amount of samples. $N$ is the total amount of samples.
\subsection{Ripple characteristics} \subsection{Ripple characteristics} \label{section:ripple}
\begin{Figure} \begin{Figure}
\centering \centering
\includegraphics[scale=0.5]{RIPPLE.png} \includegraphics[scale=0.5]{RIPPLE.png}
@ -143,7 +143,7 @@
preparing the signal for the FFT. preparing the signal for the FFT.
\subsection{Start up} \subsection{Start up} \label{section:start_up}
The last characteristics is the start up, specifically the different rise times The last characteristics is the start up, specifically the different rise times
under load. The voltage was measured at the output as the supply was turned on. under load. The voltage was measured at the output as the supply was turned on.
@ -176,14 +176,14 @@
an unexplained jump back to a higher percentage. an unexplained jump back to a higher percentage.
\subsection{Noise} \subsection{Noise} \label{section:result_noise}
\begin{Figure} \begin{Figure}
\centering \centering
\includegraphics[scale=0.5]{SNR_LOADVSPKPK.jpg} \includegraphics[scale=0.5]{SNR_LOADVSPKPK.jpg}
\captionof{figure}{WIP} \captionof{figure}{WIP}
\label{fig:noise_pkpk} \label{fig:noise_pkpk}
\end{Figure} \end{Figure}
\noindent The results for the efficiency measurements, as described in section \noindent The results for the noise measurements, as described in section
\ref{section:peak_to_peak} are displayed in figure \ref{fig:noise_pkpk}. \ref{section:peak_to_peak} are displayed in figure \ref{fig:noise_pkpk}.
The peak to peak voltage is a significant fraction of the output voltage, The peak to peak voltage is a significant fraction of the output voltage,
with $3V$ peaking at $33\%$. It seems there is a relation between peak to with $3V$ peaking at $33\%$. It seems there is a relation between peak to
@ -196,13 +196,85 @@
\captionof{figure}{WIP} \captionof{figure}{WIP}
\label{fig:noise_sd} \label{fig:noise_sd}
\end{Figure} \end{Figure}
\noindent The results for the efficiency measurements, as described in section \noindent The results for the noise measurements, as described in section
\ref{section:standard_devation} are displayed in figure \ref{fig:noise_sd}. \ref{section:standard_devation} are displayed in figure \ref{fig:noise_sd}.
Although the voltage peaks are high, the noise's standard deviation is in the Although the voltage peaks are high, the standard deviation of the noise is
range of millivolts. The trend that a higher output voltage has more noise in the range of millivolts. The trend that a higher output voltage has more
is continued in this graph. noise is continued in this graph.
\subsection{Ripple} \subsection{Ripple}
\begin{Figure}
\centering
\includegraphics[scale=0.5]{RIPPLE_LOADVSPKPK.jpg}
\captionof{figure}{WIP}
\label{fig:ripple_pkpk}
\end{Figure}
\noindent The results for the ripple measurements, as described in section
\ref{section:ripple} are displayed in figure \ref{fig:ripple_pkpk}. The
voltage level in the graph seems to confirm that the peak to peak noise,
seen in section \ref{section:result_noise} is caused by the ripple.
\begin{Figure}
\centering
\includegraphics[scale=0.5]{RIPPLE_LOADVSFREQ.jpg}
\captionof{figure}{WIP}
\label{fig:ripple_freq}
\end{Figure}
\noindent The frequency of the ripple is roughly $38 MHz$ and independant of
the load. To figure out if this ripple is caused by the combination of the
inductor and the capactitor the following equation can be used.
\begin{equation}
f = \frac{1}{2 \pi \sqrt{LC}}
\end{equation}
Using the values from figure \ref{fig:schematic_full}, the resonating frequency
of the circuit should be around $27KHz$. Thus, this cannot be the cause of
the high frequency. As the frequency of the ripple is magnitudes higher
than the LC-circuit's resosonant frequency, what is seen is most likely the
Self Resonating Frequency (SRF) of the inductor. Typically the SRF is
$>10 MHz$, so that could be a probable source of the high frequencies.
\subsection{Start Up}
\begin{Figure}
\centering
\includegraphics[scale=0.5]{TRANSIENT_RISE_10_MA.jpg}
\captionof{figure}{WIP}
\label{fig:start_10}
\end{Figure}
\begin{Figure}
\centering
\includegraphics[scale=0.5]{TRANSIENT_RISE_50_MA.jpg}
\captionof{figure}{WIP}
\label{fig:start_50}
\end{Figure}
\begin{center}
\captionof{table}{$10 mA$}
\label{table:start_10}
\begin{tabular}{llll}
Metric & $\tau$ & $2\tau$ & Rise time \\
Percentage [$\%$] & 63 & 95 & 90 \\
Time [$s$] & 0.031 & 0.075 & 0.053 \\
\end{tabular}
\end{center}
\begin{center}
\captionof{table}{$50 mA$}
\label{table:start_50}
\begin{tabular}{llll}
Metric & $\tau$ & $2\tau$ & Rise time \\
Percentage [$\%$] & 63 & 95 & 90 \\
Time [$s$] & 0.033 & 0.048 & 0.043 \\
\end{tabular}
\end{center}
\noindent The results for the start up measurements, as described in section
\ref{section:start_up} are displayed in figure \ref{fig:start_10} and
\ref{fig:start_50}, and table \ref{table:start_10} and \ref{table:start_50}.
Counterintuitively, the rise time is shorter with a higher load.
\section{Conclusion} \section{Conclusion}
\lipsum[3-4] \lipsum[3-4]