adaptation of the assignments to the modern times

projects/disclaimer.tex

@@ -8,26 +8,28 @@
       \vspace{1ex}
 
       The {\bf code} and the {\bf presentation} should be uploaded to
-      ILIAS at latest on Thursday, November 6th, 10:00h.
-      The presentations start on Thursday 11:00h. Please hand in
-      your presentation as a pdf file. Bundle everything into a
-      {\em single} zip-file.
+      ILIAS at latest on Thursday, November 5th, 13:00h.  The
+      presentations start on Thursday 13:00h. Please hand in your
+      presentation as a pdf file. Bundle everything (the pdf and the
+      code) into a {\em single} zip-file.
 
       \vspace{1ex}
 
       The {\bf code} should be exectuable without any further
-      adjustments from us. This means that you need to include all
+      adjustments from our side. This means that you need to include all
       additional functions you wrote and the data into the
-      zip-file. A single {\em main script} should produce the same
+      zip-file. A single {\em main} script should produce the same
       {\em figures} that you use in your slides. The figures should
       follow the guidelines for proper plotting as discussed in the
-      first statistics lecture. The code should be properly commented
+      course. The code should be properly commented
       and comprehensible by third persons (use proper and consistent
-      variable names).
+      variable and function names).
 
       \vspace{1ex} \textbf{Please write your name and matriculation
-      number as a comment at the top of a script called \texttt{main.m}.}
-      The \texttt{main.m} script then should call all your scripts.
+      number as a comment at the top of a script called
+      \texttt{main.m}.}  The \texttt{main.m} script then should
+      coordinate the execution of your analysis by e.g. calling
+      sub-scripts and functions with appropriate parameters.
 
       \vspace{1ex}
       

projects/project_adaptation_fit/adaptation_fit.tex

@@ -6,8 +6,8 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
 \firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
@@ -44,15 +44,14 @@ electroreceptors of the weakly electric fish \textit{Apteronotus
   certain intensity, i.e. the \textit{contrast} which is also stored
   in the file.
   \begin{parts}
-    \part Estimate for each stimulus intensity the  
-    PSTH and plot it. You will see that there are three parts.  (i)
-    The first 200 ms is the baseline (no stimulus) activity. (ii)
-    During the next 1000 ms the stimulus was switched on. (iii) After
-    stimulus offset the neuronal activity was recorded for further 825
-    ms.
-    \part Estimate the adaptation time-constant of the adaptation for 
-    both the stimulus on- and offset. To do this fit an exponential
-    function to the data. For the decay use:
+    \part Estimate for each stimulus intensity the PSTH and plot
+    it. You will see that there are three parts.  (i) The first
+    200\,ms is the baseline (no stimulus) activity. (ii) During the
+    next 1000\,ms the stimulus was switched on. (iii) After stimulus
+    offset the neuronal activity was recorded for further 825\,ms.
+    \part Estimate the adaptation time-constant for both the stimulus
+    on- and offset. To do this fit an exponential function to the
+    data. For the decay use:
     \begin{equation}
        f_{A,\tau,y_0}(t) = y_0 + A \cdot e^{-\frac{t}{\tau}},
     \end{equation}
@@ -62,7 +61,7 @@ electroreceptors of the weakly electric fish \textit{Apteronotus
     \begin{equation}
        f_{A,\tau, y_0}(t) = y_0 + A \cdot \left(1 - e^{-\frac{t}{\tau}}\right ),
     \end{equation}
-    \part Plot the decays into the data.
+    \part Plot the best fits into the data.
     \part Plot the estimated time-constants as a function of stimulus intensity.
   \end{parts}
 \end{questions}

projects/project_eod/eod.tex

@@ -6,10 +6,10 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
-\firstpagefooter{}{}{{\bf Supervisor:} Fabian Sinz}
+\firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
 \pointsinmargin
 \bracketedpoints
@@ -38,8 +38,9 @@
   \begin{parts}
     \part Load and plot the data in an appropriate way. Time is in
     seconds and the voltage is in mV/cm.
-    \part Fit the following curve to the eod (select a smaller time
-    window for fitting, not the entire trace) using least squares:
+    \part Fit the following curve to the eod (select a small time
+    window, a few tens of milliseconds, for fitting, not the entire
+    trace) using least squares:
     $$f_{\omega_0,b_0,\varphi_1, ...,\varphi_n}(t) = b_0 +
     \sum_{j=1}^n \sin(2\pi j\omega_0\cdot t + \varphi_j ).$$
     $\omega_0$ is called {\em fundamental frequency}. The single terms

projects/project_numbers/numbers.tex

@@ -6,10 +6,10 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
-\firstpagefooter{}{}{{\bf Supervisor:} Fabian Sinz}
+\firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
 \pointsinmargin
 \bracketedpoints
@@ -37,24 +37,20 @@
   macaque prefrontal cortex (data courtesy of Prof. Nieder). The task
   of the monkey was to discriminate point-sets with 1 to 4 points. The
   first column contains the number of points shown plus one. The
-  remaining columns contain the spike response across 1300ms. During
-  the first 500ms the monkey was fixating a target. The next 800ms the
-  stimulus was shown. This was followed by 1000ms delay time before
+  remaining columns contain the spike response across 1300\,ms. During
+  the first 500\,ms the monkey was fixating a target. The next 800\,ms the
+  stimulus was shown. This was followed by 1000\,ms delay time before
   the monkey was allowed to respond.
   
   \begin{parts}
     \part Plot the data in an appropriate way. 
     \part Sort the trials according to the stimulus presented and
     compute the firing rate (in Hz) in the time interval
-    500-1300ms. Plot the firing rate in an appropriate way. 
+    500-1300\,ms. Plot the firing rate in an appropriate way. 
     \part Use an appropriate test to determine whether the firing rate
     in that interval is significantly different for 1 vs. 4 points
     shown.
   \end{parts}
 \end{questions}
 
-
-
-
-
 \end{document}

projects/project_onset_fi/onset_fi.tex

@@ -6,8 +6,8 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
 \firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
@@ -37,19 +37,19 @@ of the stimulus \textbf{I}ntensity.
 
 \begin{questions}
   \question In the accompanying datasets you find the
-  \textit{spike\_times} of an P-unit electrorecptor of the weakly
+  \textit{spike\_times} of an P-unit electroreceptor of the weakly
   electric fish \textit{Apteronotus leptorhynchus} to a stimulus of a
   certain intensity, i.e. the \textit{contrast}. 
   \begin{parts}
     \part For each stimulus intensity estimate the average response
     (PSTH) and plot it. You will see that there are three parts.  (i)
-    The first 200 ms is the baseline (no stimulus) activity. (ii)
-    During the next 1000 ms the stimulus was switched on. (iii) After
-    stimulus offset the neuronal activity was recorded for further 825
-    ms.
-    \part Extract the neuron's activity in the first 50 ms after stimulus onset
-    and plot it against the stimulus intensity, respectively the
-    contrast, in an appropriate way.
+    The first 200\,ms is the baseline (no stimulus) activity. (ii)
+    During the next 1000\,ms the stimulus was switched on. (iii) After
+    stimulus offset the neuronal activity was recorded for further
+    825\,ms.
+    \part Extract the neuron's activity in the first 50\,ms after
+    stimulus onset and plot it against the stimulus intensity,
+    respectively the contrast, in an appropriate way.
     \part Fit a Boltzmann function to the FI-curve. The Boltzmann function
     is defined as:
     \begin{equation}
@@ -62,8 +62,4 @@ of the stimulus \textbf{I}ntensity.
   \end{parts}
 \end{questions}
 
-
-
-
-
 \end{document}

projects/project_stimulus_reconstruction/stimulus_reconstruction.tex

@@ -6,8 +6,8 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
 \firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
@@ -31,8 +31,16 @@
 
 %%%%%%%%%%%%%% Questions %%%%%%%%%%%%%%%%%%%%%%%%%
 \section*{Reverse reconstruction of the stimulus evoking neuronal responses.}
-During the course we have used the Spike-Triggered-Average to
+To analyse encoding properties of a neuron one often calculates the
+Spike-Triggered-Average (STA).
+\[ STA(\tau) = \frac{1}{\langle n \rangle} \left\langle
+  \displaystyle\sum_{i=1}^{n}{s(t_i - \tau)} \right\rangle \] 
+
+The STA is the average stimulus that led to a spike in the neuron and
+can calculated by cutting out snippets form the stimulus centered on
+the respective spike time. The Spike-Triggered-Average can be used to
 reconstruct the stimulus a neuron has been stimulated with.
+
 \begin{questions}
   \question In the accompanying files you find the spike responses of
   P-units and pyramidal neurons of the weakly electric fish

projects/project_vector_strength/vector_strength.tex

@@ -6,8 +6,8 @@
 \pagestyle{headandfoot}
 \runningheadrule
 \firstpageheadrule
-\firstpageheader{Scientific Computing}{Project Assignment}{11/05/2014
-  -- 11/06/2014}
+\firstpageheader{Scientific Computing}{Project Assignment}{11/02/2015
+  -- 11/05/2015}
 %\runningheader{Homework 01}{Page \thepage\ of \numpages}{23. October 2014}
 \firstpagefooter{}{}{{\bf Supervisor:} Jan Grewe}
 \runningfooter{}{}{}
@@ -31,7 +31,7 @@
 
 %%%%%%%%%%%%%% Questions %%%%%%%%%%%%%%%%%%%%%%%%%
 \section*{Quantifying the coupling of action potentials to the EOD.}
-P-unit electrorecptors are driven by the fish's self-generated field,
+P-unit electroreceptors are driven by the fish's self-generated field,
 the EOD. In this project you have to quantify the strength of this
 coulpling using the \textbf{vector strength}:
 \begin{equation}
@@ -46,7 +46,7 @@ locking, respectively.
 
 \begin{questions}
   \question In the accompanying datasets you find recrordings of the
-  ``baseline'' activity of P-unit electrorecptors of different weakly
+  ``baseline'' activity of P-unit electroreceptors of different weakly
   electric fish of the species \textit{Apteronotus leptorhynchus}.
   The files further contain respective recordings of the \textit{eod},
   i.e. the fish's field.