diff --git a/Bilder/fig_dsp.jpg b/Bilder/fig_dsp.jpg new file mode 100644 index 0000000..38798c9 Binary files /dev/null and b/Bilder/fig_dsp.jpg differ diff --git a/Bilder/fig_fft.jpg b/Bilder/fig_fft.jpg new file mode 100644 index 0000000..e892588 Binary files /dev/null and b/Bilder/fig_fft.jpg differ diff --git a/chapter_02.tex b/chapter_02.tex index 42d9403..4341c7c 100644 --- a/chapter_02.tex +++ b/chapter_02.tex @@ -1,12 +1,28 @@ \section{Theoretical Background} -The following subsections shall provide the reader with the theoretical background of digital signal processing to explain the implementation of ANR on a DSP, -We will beginn with the fundamentals of digital signal processing in general, covering transfer-funtions and filters. -To fully understand ANR, a short deep-dive into the LMS algrotihm is indispensable. -From there we will continue into the histroy and the mathematical concepts of ANR, which will bring us the core of ANR, the LMS Algorithm -With this knowledge covered, we will construct the real-world signal flow diagrams and transfer functions, of an implanted CI system essential to implement a functioning ANR on a low-power DSP. -At the end of chapter two, several Python simualtions shall function as a practical demonstrations of the recently presented thereotec background -To accomplish that, we will be relying on the book Digital Signal Processing Fundamentals and Applications 2nd Ed +The following subchapters shall equip the reader with the theoretical foundations of digital signal processing to better understand the following implementation of ANR on a low-power signal processor.\\ \\ +We will beginn with the fundamentals of digital signal processing in general, covering the transfer-funtions and filters.\\ +To fully understand ANR, a short deep-dive into the concepts of Finite Impulse Respone (FIR) and Infinite Impulse Respone (IIR) filters is indispensable.\\ +From this point we will continue into the history and the mathematical concepts of ANR, its realtime feedback possibilities and its use of the Least Mean Square (LMS) Algorithm.\\ +With this knowledge covered, we will design a realstic signal flow diagram and the corresponding transfer functions, of an implanted CI system essential to implement a functioning ANR on a low-power DSP.\\ +At the end of chapter two, high-level Python simualtions shall function as a practical demonstrations of the recently presented thereotical background.\\ \\ +Chapter 2 is relying on the textbook ''Digital Signal Processing Fundamentals and Applications 2nd Ed'' by Tan and Jiang \cite{source_dsp1}. \subsection{Fundamentals of digital signal processing, transfer functions and filters} +Digital Signal Processing (DSP) describes the manipulation of an analog signal trough mathematical approaches after it has been recorded and converted into a digital form. Nearly every part of the modern daily live, be it communication via cellphones, X-Ray imaging or picture editing, is affected by DSP.\\ \\ +\begin{figure}[H] + \centering + \includegraphics[width=0.8\linewidth]{Bilder/fig_dsp.jpg} + \caption{Block diagram of processing an analog input signal to an analog output signal with digital signal processing in between \cite{source_fig_dsp}} + \label{fig:fig_dsp} +\end{figure} +Before digital signal processing can be applied to an analog signal like voice, several steps are required beforehand. An analog signal, continous in both time and amplitude, is passed through a initial filter, which limits the freqency bandwith. An analog-digital converter then samples and quantizies the signal into a digital form, now discrete in time and amplitude. This digital signal can now be processed, before (possibly) being converted to a analog signal again. (refer to figure \ref{fig:fig_dsp}).\\ \\ +A signal (either analog or digital) can be displayed and analyzed in two ways: the time spectrum and the freqency spectrum. The time spectrum shows the amplitude of the signal over time - like the sine waves from figure XXX. If a fast fourier transformation (FFT) is applied to the signal in the time spectrum, we recieve the same signal in the frequency spectrum, now showing the frequencies present in the signal (refer to figure \ref{fig:fig_fft}).\\ \\ +\begin{figure}[H] + \centering + \includegraphics[width=0.8\linewidth]{Bilder/fig_fft.jpg} + \caption{Sampled digital signal in the time spectrum and in the frequency spectrum \cite{source_fig_fft}} + \label{fig:fig_fft} +\end{figure} + \subsection{Explanation of Finite Impulse Response- and Infinite Impulse Response-filters} \subsection{Introduction to Adaptive Nose Reduction} diff --git a/literature.bib b/literature.bib index bdd1df1..1ad7ea1 100644 --- a/literature.bib +++ b/literature.bib @@ -27,4 +27,20 @@ howpublished = {Elsevier Inc.}, year = {2013}, note = {ISBN: 978-0-12-415893-1} +} + +@misc{source_fig_dsp, + author = {Li Tan, Jean Jiang}, + title = {Digital Signal Processing Fundamentals and Applications 2nd Ed}, + howpublished = {Elsevier Inc.}, + year = {2013}, + note = {Page 2-3} +} + +@misc{source_fig_fft, + author = {Li Tan, Jean Jiang}, + title = {Digital Signal Processing Fundamentals and Applications 2nd Ed}, + howpublished = {Elsevier Inc.}, + year = {2013}, + note = {Page 6} } \ No newline at end of file