fixed many index entries

likelihood/lecture/likelihood.tex

@@ -26,15 +26,16 @@ parameters $\theta$. This could be the normal distribution
 defined by the mean $\mu$ and the standard deviation $\sigma$ as
 parameters $\theta$.  If the $n$ independent observations of $x_1,
 x_2, \ldots x_n$ originate from the same probability density
-distribution (they are \enterm{i.i.d.} independent and identically
-distributed) then the conditional probability $p(x_1,x_2, \ldots
+distribution (they are \enterm[i.i.d.|see{independent and identically
+distributed}]{i.i.d.}, \enterm{independent and identically
+distributed}) then the conditional probability $p(x_1,x_2, \ldots
 x_n|\theta)$ of observing $x_1, x_2, \ldots x_n$ given a specific
 $\theta$ is given by
 \begin{equation}
   p(x_1,x_2, \ldots x_n|\theta) = p(x_1|\theta) \cdot p(x_2|\theta)
   \ldots p(x_n|\theta) = \prod_{i=1}^n p(x_i|\theta) \; .
 \end{equation}
-Vice versa, the \enterm{likelihood} of the parameters $\theta$
+Vice versa, the \entermde{Likelihood}{likelihood} of the parameters $\theta$
 given the observed data $x_1, x_2, \ldots x_n$ is
 \begin{equation}
   {\cal L}(\theta|x_1,x_2, \ldots x_n) = p(x_1,x_2, \ldots x_n|\theta) \; .
@@ -57,7 +58,7 @@ The position of a function's maximum does not change when the values
 of the function are transformed by a strictly monotonously rising
 function such as the logarithm. For numerical and reasons that we will
 discuss below, we commonly search for the maximum of the logarithm of
-the likelihood (\enterm{log-likelihood}):
+the likelihood (\entermde[likelihood!log-]{Likelihood!Log-}{log-likelihood}):
 
 \begin{eqnarray}
   \theta_{mle} & = & \text{argmax}_{\theta}\; {\cal L}(\theta|x_1,x_2, \ldots x_n) \nonumber \\
@@ -136,9 +137,10 @@ from the data.
 For non-Gaussian distributions (e.g. a Gamma-distribution), however,
 such simple analytical expressions for the parameters of the
 distribution do not exist, e.g. the shape parameter of a
-\enterm{Gamma-distribution}. How do we fit such a distribution to
-some data? That is, how should we compute the values of the parameters
-of the distribution, given the data?
+\entermde[distribution!Gamma-]{Verteilung!Gamma-}{Gamma-distribution}. How
+do we fit such a distribution to some data? That is, how should we
+compute the values of the parameters of the distribution, given the
+data?
 
 A first guess could be to fit the probability density function by
 minimization of the squared difference to a histogram of the measured
@@ -289,10 +291,10 @@ out of \eqnref{mleslope} and we get
 To see what this expression is, we need to standardize the data. We
 make the data mean free and normalize them to their standard
 deviation, i.e. $x \mapsto (x - \bar x)/\sigma_x$. The resulting
-numbers are also called \enterm[z-values]{$z$-values} or $z$-scores and they
-have the property $\bar x = 0$ and $\sigma_x = 1$. $z$-scores are
-often used in Biology to make quantities that differ in their units
-comparable. For standardized data the variance
+numbers are also called \entermde[z-values]{z-Wert}{$z$-values} or
+$z$-scores and they have the property $\bar x = 0$ and $\sigma_x =
+1$. $z$-scores are often used in Biology to make quantities that
+differ in their units comparable. For standardized data the variance
 \[ \sigma_x^2 = \frac{1}{n} \sum_{i=1}^n (x_i - \bar x)^2 = \frac{1}{n} \sum_{i=1}^n x_i^2 = 1 \]
 is given by the mean squared data and equals one.
 The covariance between $x$ and $y$ also simplifies to