Difference between revisions of "Theory of Stochastic Signals/Two-Dimensional Random Variables"

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== # OVERVIEW OF THE FOURTH MAIN CHAPTER # ==
 
== # OVERVIEW OF THE FOURTH MAIN CHAPTER # ==
 
<br>
 
<br>
$\Rightarrow \hspace{0.5cm}\text{We are just beginning the English translation of this chapter.}$
+
Now random variables with statistical bindings are treated and illustrated by typical examples.&nbsp;
  
 +
After the general description of two-dimensional random variables,&nbsp; we turn to
 +
#the&nbsp; "auto-correlation function",&nbsp;
 +
#the&nbsp;  "cross-correlation function"
 +
#and the associated spectral functions&nbsp; $($"power-spectral density",&nbsp; "cross power-spectral density"$)$.
  
Now random variables with statistical bindings are treated and illustrated by typical examples.&nbsp; After the general description of two-dimensional random variables, we turn to the autocorrelation function&nbsp; (ACF),&nbsp; the cross correlation function&nbsp; (CCF)&nbsp; and the associated spectral functions&nbsp; (PSD, CPSD)&nbsp;.
 
  
Specifically, it covers:
+
Specifically,&nbsp; this chapter covers:
  
*the statistical description of ''2D random variables'' &nbsp; using the (joint) PDF,
+
*the statistical description of&nbsp; &raquo;two-dimensional random variables&laquo;&nbsp; using the&nbsp; &raquo;joint PDF&laquo;,
*the difference between ''statistical dependence''&nbsp; and ''correlation'', ???
+
*the difference between&nbsp; &raquo;statistical dependence&laquo;&nbsp; and&nbsp; &raquo;correlation&laquo;,  
*the classification features ''stationarity''&nbsp; and ''ergodicity''&nbsp; of stochastic processes,
+
*the classification features&nbsp; &raquo;stationarity&laquo;&nbsp; and&nbsp; &raquo;ergodicity&laquo;&nbsp; of stochastic processes,
*the definitions of ''autocorrelation function''&nbsp; (ACF) and ''power spectral density''&nbsp; (PSD),
+
*the definitions of&nbsp; &raquo;auto-correlation function&laquo;&nbsp; $\rm (ACF)$&nbsp; and&nbsp; &raquo;power-spectral density&laquo;&nbsp; $\rm (PSD)$,
*the definitions of ''cross correlation function''&nbsp; and ''cross power spectral density,'' and
+
*the definitions of&nbsp; &raquo;cross-correlation function&laquo;&nbsp;  $\rm (CCF)$&nbsp;&nbsp; and&nbsp; &raquo;cross power-spectral density&laquo;&nbsp;  $\rm (C&ndash;PSD)$,&nbsp;
*the numerical determination of all these variables in the two- and multi-dimensional cases.
+
*the numerical determination of all these variables in the two- and multi-dimensional case.
  
  
For more information on ''Two-Dimensional Random Variables,'' as well as tasks, simulations, and programming exercises, see
 
  
*Chapter 5: &nbsp; Two-dimensional random variables (program "zwd")
 
*Chapter 9: &nbsp; Stochastic Processes (program "sto")
 
 
 
of the practical course "Simulation Methods in Communications Engineering".&nbsp; This (former) LNT course at the TU Munich is based on
 
 
*the teaching software package&nbsp; [http://en.lntwww.de/downloads/Sonstiges/Programme/LNTsim.zip LNTsim] &nbsp; &rArr; &nbsp; Link refers to the German ZIP&ndash;version of the program,
 
*&nbsp; [http://en.lntwww.de/downloads/Sonstiges/Texte/Praktikum_LNTsim_Teil_A.pdf Internship Guide &ndash; Part A]  &nbsp; &rArr; &nbsp; Link refers to the German PDF&ndash;version with chapter 5:&nbsp; pages 81-97,
 
*the&nbsp; [http://en.lntwww.de/downloads/Sonstiges/Texte/Praktikum_LNTsim_Teil_B.pdf Internship Guide &ndash; Part B]  &nbsp; &rArr; &nbsp; Link refers to the German PDF&ndash;version with chapter 9:&nbsp; pages 207-228.
 
  
  
 
==Properties and examples==
 
==Properties and examples==
 
<br>
 
<br>
As a transition to the&nbsp; [[Theory_of_Stochastic_Signals/Auto-Correlation_Function_(ACF)|correlation functions]]&nbsp; we now consider two random variables&nbsp; $x$&nbsp; and&nbsp; $y$,&nbsp; between which statistical bindings(???) exist.&nbsp; Each of the two random variables can be described on its own with the introduced characteristic variables
+
As a transition to the&nbsp; [[Theory_of_Stochastic_Signals/Auto-Correlation_Function_(ACF)|$\text{correlation functions}$]]&nbsp; we now consider two random variables&nbsp; $x$&nbsp; and&nbsp; $y$,&nbsp; between which statistical dependences exist.&nbsp;  
*corresponding to the second main chapter &nbsp; &rArr; &nbsp;[[Theory_of_Stochastic_Signals/From_Random_Experiment_to_Random_Variable#.23_OVERVIEW_OF_THE_SECOND_MAIN_CHAPTER_.23|Discrete Random Variables]] &nbsp;   
+
 
*but the third main chapter &nbsp; &rArr; &nbsp; [[Theory_of_Stochastic_Signals/Probability_Density_Function#.23_OVERVIEW_OF_THE_THIRD_MAIN_CHAPTER_.23|Continuous Random Variables]].   
+
Each of these two random variables can be described on its own with the introduced characteristic variables corresponding
 +
*to the second main chapter &nbsp; &rArr; &nbsp;[[Theory_of_Stochastic_Signals/From_Random_Experiment_to_Random_Variable#.23_OVERVIEW_OF_THE_SECOND_MAIN_CHAPTER_.23|"Discrete Random Variables"]] &nbsp;   
 +
*and the third main chapter &nbsp; &rArr; &nbsp; [[Theory_of_Stochastic_Signals/Probability_Density_Function#.23_OVERVIEW_OF_THE_THIRD_MAIN_CHAPTER_.23|"Continuous Random Variables"]].   
  
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; To describe the correlations between two variables&nbsp; $x$ &nbsp;and&nbsp; $y$&nbsp; it is convenient to combine the two components into one&nbsp; '''two-dimensional random variable'''&nbsp; $(x, y)$ &nbsp;}.  
+
$\text{Definition:}$&nbsp; To describe the statistical dependences between two variables&nbsp; $x$ &nbsp;and&nbsp; $y$,&nbsp; it is convenient to combine the two components <br> &nbsp; &nbsp; &nbsp; into one &nbsp; &raquo;'''two-dimensional random variable'''&laquo; &nbsp;  or &nbsp; &raquo;'''2D random variable'''&laquo;&nbsp; $(x, y)$.  
*The individual components can be signals such as the real&ndash; and imaginary parts of a phase modulated signal.  
+
*The individual components can be signals such as the real and imaginary parts of a phase modulated signal.  
*But there are a variety of 2Dn random variables in other domains as well, as the following example will show}}  
+
*But there are a variety of two-dimensional random variables in other domains as well,&nbsp; as the following example will show.}}  
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 1:}$&nbsp; The left diagram is from the random experiment&nbsp; "Throwing two dice".&nbsp; Plotted to the right is the number of the first die&nbsp; $(W_1)$,&nbsp; plotted to the top is the sum&nbsp; $S$&nbsp; of both dice.&nbsp; The two components here are each discrete random variables between which there are statistical dependencies(???):
+
$\text{Example 1:}$&nbsp; The left diagram is from the random experiment&nbsp; "Throwing two dice".&nbsp;  
*If&nbsp; $W_1 = 1$, then&nbsp; $S$&nbsp; can only take values between&nbsp; $2$&nbsp; and&nbsp; $7$&nbsp; and each with equal probability.
 
*In contrast, for&nbsp; $W_1 = 6$&nbsp; all values between&nbsp; $7$&nbsp; and&nbsp; $12$&nbsp; are possible, also with equal probability.
 
  
 
[[File: P_ID162__Sto_T_4_1_S1_neu.png |frame| Two examples of statistically dependent random variables]]
 
[[File: P_ID162__Sto_T_4_1_S1_neu.png |frame| Two examples of statistically dependent random variables]]
  
 +
*Plotted to the right is the number of the first die&nbsp; $(W_1)$,&nbsp;
 +
*plotted to the top is the sum&nbsp; $S$&nbsp; of both dice.&nbsp;
  
  
In the right graph, the maximum temperatures of the&nbsp; $31$ days in May 2002 of Munich (to the top) and the Zugspitze (to the right) are contrasted. Both random variables are continuous in value:  
+
The two components here are each discrete random variables between which there are statistical dependencies:  
*although the measurement points are about&nbsp; $\text{100 km}$&nbsp; apart, and on the Zugspitze, due to the different altitudes &nbsp;$($nearly&nbsp; $3000$&nbsp; versus&nbsp; $520$&nbsp; meters$)$&nbsp; is on average about&nbsp; $20$&nbsp; degrees colder than in Munich, one recognizes nevertheless a certain statistical dependence between the two random variables&nbsp; ${\it Θ}_{\rm M}$&nbsp; and&nbsp; ${\it Θ}_{\rm Z}$.
+
*If&nbsp; $W_1 = 1$,&nbsp; then the sum&nbsp; $S$&nbsp; can only take values between&nbsp; $2$&nbsp; and&nbsp; $7$,&nbsp; each with equal probability.
*If it is warm in Munich, then pleasant temperatures are also more likely to be expected on the Zugspitze.&nbsp; However, the relationship is not deterministic:&nbsp; The coldest day in May 2002 was a different day in Munich than the coldest day on the Zugspitze. }}
+
*In contrast,&nbsp; for&nbsp; $W_1 = 6$&nbsp; all values between&nbsp; $7$&nbsp; and&nbsp; $12$&nbsp; are possible,&nbsp; also with equal probability.  
  
==Joint PDF==
+
 
 +
 
 +
In the right diagram,&nbsp; the maximum temperatures of the&nbsp; $31$ days in May 2002 of Munich&nbsp; (to the top)&nbsp; and the mountain&nbsp; "Zugspitze"&nbsp; (to the right)&nbsp; are contrasted.&nbsp; Both random variables are continuous in value:
 +
*Although the measurement points are about&nbsp; $\text{100 km}$&nbsp; apart,&nbsp; and on the Zugspitze,&nbsp; it is on average about &nbsp; $20$&nbsp; degrees colder than in Munich due to the different altitudes &nbsp;$($nearly&nbsp; $3000$&nbsp; versus&nbsp; $520$&nbsp; meters$)$,&nbsp; one recognizes nevertheless a certain statistical dependence between the two random variables&nbsp; ${\it Θ}_{\rm M}$&nbsp; and&nbsp; ${\it Θ}_{\rm Z}$.
 +
*If it is warm in Munich,&nbsp; then pleasant temperatures are also more likely to be expected on the Zugspitze.&nbsp; However,&nbsp; the relationship is not deterministic:&nbsp; The coldest day in May 2002 was a different day in Munich than the coldest day on the Zugspitze. }}
 +
 
 +
==Joint probability density function==
 
<br>
 
<br>
We restrict ourselves here mostly to continuous random variables.&nbsp; However, sometimes the peculiarities of two-dimensional discrete random variables are discussed in more detail.&nbsp; Most of the characteristics previously defined for one-dimensional random variables can be easily extended to two-dimensional variables.  
+
We restrict ourselves here mostly to continuous valued random variables.  
 +
*However,&nbsp; sometimes the peculiarities of two-dimensional discrete random variables are discussed in more detail.&nbsp;  
 +
*Most of the characteristics previously defined for one-dimensional random variables can be easily extended to two-dimensional variables.  
 +
 
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
 
$\text{Definition:}$&nbsp;  
 
$\text{Definition:}$&nbsp;  
The probability density function of the two-dimensional random variable at the location&nbsp; $(x_\mu, y_\mu)$ &nbsp; &rArr; &nbsp; '''joint PDF'''&nbsp; is an extension of the one-dimensional PDF&nbsp; $(∩$&nbsp; denotes logical AND operation$)$:  
+
The&nbsp; probability density function&nbsp; $\rm (PDF)$&nbsp; of the two-dimensional random variable at the location&nbsp; $(x_\mu,\hspace{0.1cm} y_\mu)$ &nbsp; &rArr; &nbsp; &raquo;'''joint PDF'''&laquo; &nbsp; or &nbsp; &raquo;'''2D&ndash;PDF'''&laquo; <br>is an extension of the one-dimensional PDF&nbsp; $(∩$&nbsp; denotes logical&nbsp; "and"&nbsp; operation$)$:  
:$$f_{xy}(x_\mu, \hspace{0.1cm}y_\mu) = \lim_{\left.{\delta x\rightarrow 0 \atop {\delta y\rightarrow 0} }\right. }\frac{ {\rm Pr}\big [ (x_\mu - {\rm \Delta} x/{\rm 2} \le x \le x_\mu + {\rm \Delta} x/{\rm 2}) \cap (y_\mu - {\rm \Delta} y/{\rm 2} \le y \le y_\mu +{\rm \Delta}y/{\rm 2}) \big]  }{ {\rm \delta} \ x\cdot{\rm \Delta} y}.$$
+
:$$f_{xy}(x_\mu, \hspace{0.1cm}y_\mu) = \lim_{\left.{\Delta x\rightarrow 0 \atop {\Delta y\rightarrow 0} }\right.}\frac{ {\rm Pr}\big [ (x_\mu - {\rm \Delta} x/{\rm 2} \le x \le x_\mu + {\rm \Delta} x/{\rm 2}) \cap (y_\mu - {\rm \Delta} y/{\rm 2} \le y \le y_\mu +{\rm \Delta}y/{\rm 2}) \big]  }{ {\rm \Delta} \ x\cdot{\rm \Delta} y}.$$
 
$\rm Note$:
 
$\rm Note$:
*If the 2D random variable is discrete, the definition must be slightly modified:  
+
*If the two-dimensional random variable is discrete,&nbsp; the definition must be slightly modified:  
*For the lower range limits in each case, the "" sign must then be replaced by the "<" sign according to the page&nbsp; [[Theory_of_Stochastic_Signals/Cumulative_Distribution_Function#CDF_for_discrete-valued_random_variables|CDF for discrete random variables]]&nbsp; }}.
+
*For the lower range limits,&nbsp; the&nbsp; "less-than-equal"&nbsp; sign must then be replaced by&nbsp; "less-than"&nbsp; according to the section&nbsp; [[Theory_of_Stochastic_Signals/Cumulative_Distribution_Function#CDF_for_discrete-valued_random_variables|"CDF for discrete-valued random variables"]].&nbsp; }}
  
  
Using this (joint) PDF&nbsp; $f_{xy}(x, y)$&nbsp; statistical dependencies within the two-dimensional random variable&nbsp; $(x, y)$&nbsp; are also fully captured in contrast to the two one-dimensional density functions &nbsp; ⇒ &nbsp; '''marginal probability density functions''':  
+
Using this joint PDF $f_{xy}(x, y)$,&nbsp; statistical dependencies within the two-dimensional random variable&nbsp; $(x,\ y)$&nbsp; are also fully captured in contrast to the two one-dimensional density functions &nbsp; ⇒ &nbsp; &raquo;'''marginal probability density functions'''&laquo; &nbsp; $($or &nbsp; "edge probability density functions"$)$:  
 
:$$f_{x}(x) = \int _{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}y ,$$
 
:$$f_{x}(x) = \int _{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}y ,$$
 
:$$f_{y}(y) = \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x .$$
 
:$$f_{y}(y) = \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x .$$
  
These two marginal density functions&nbsp; $f_x(x)$&nbsp; and&nbsp; $f_y(y)$  
+
These two marginal probability density functions&nbsp; $f_x(x)$&nbsp; and&nbsp; $f_y(y)$  
*provide only statistical information about the individual components&nbsp; $x$&nbsp; and&nbsp; $y$, respectively,
+
*provide only statistical information about the individual components&nbsp; $x$&nbsp; and&nbsp; $y$, resp.
*but not about the bindings between them.  
+
*but not about the statistical bindings between them.  
  
  
==Two-dimensional CDF==
+
==Two-dimensional cumulative distribution function==
 
<br>
 
<br>
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; The&nbsp; '''2D distribution function'''&nbsp; like the 2D PDF, is merely a useful extension of the&nbsp; [[Theory_of_Stochastic_Signals/Cumulative_Distribution_Function#CDF_for_continuous-valued_random_variables|one-dimensional distribution function]]&nbsp; (CDF):  
+
$\text{Definition:}$&nbsp; Like the&nbsp; "2D&ndash;PDF",&nbsp; the&nbsp; &raquo;'''2D cumulative distribution function'''&laquo;&nbsp; is merely a useful extension of the&nbsp; [[Theory_of_Stochastic_Signals/Cumulative_Distribution_Function#CDF_for_continuous-valued_random_variables|$\text{one-dimensional distribution function}$]]&nbsp; $\rm (CDF)$:  
 
:$$F_{xy}(r_{x},r_{y}) = {\rm Pr}\big [(x \le r_{x}) \cap (y \le r_{y}) \big ] .$$}}
 
:$$F_{xy}(r_{x},r_{y}) = {\rm Pr}\big [(x \le r_{x}) \cap (y \le r_{y}) \big ] .$$}}
  
  
The following similarities and differences between the 1D CDF and the 2D CDF emerge:
+
The following similarities and differences between the&nbsp; "1D&ndash;CDF"&nbsp; and the&nbsp; 2D&ndash;CDF"&nbsp; emerge:
*The functional relationship between two-dimensional PDF and two-dimensional CDF is given by integration as in the one-dimensional case, but now in two dimensions.&nbsp; For continuous random variables:  
+
*The functional relationship between two-dimensional PDF and two-dimensional CDF is given by integration as in the one-dimensional case,&nbsp; but now in two dimensions.&nbsp; For continuous valued random variables:  
 
:$$F_{xy}(r_{x},r_{y})=\int_{-\infty}^{r_{y}} \int_{-\infty}^{r_{x}} f_{xy}(x,y) \,\,{\rm d}x \,\, {\rm d}y .$$
 
:$$F_{xy}(r_{x},r_{y})=\int_{-\infty}^{r_{y}} \int_{-\infty}^{r_{x}} f_{xy}(x,y) \,\,{\rm d}x \,\, {\rm d}y .$$
*Inversely, the probability density function can be given from the distribution function by partial differentiation to&nbsp; $r_{x}$&nbsp; and&nbsp; $r_{y}$&nbsp; :
+
*Inversely,&nbsp; the probability density function can be given from the cumulative distribution function by partial differentiation to&nbsp; $r_{x}$&nbsp; and&nbsp; $r_{y}$:
 
:$$f_{xy}(x,y)=\frac{{\rm d}^{\rm 2} F_{xy}(r_{x},r_{y})}{{\rm d} r_{x} \,\, {\rm d} r_{y}}\Bigg|_{\left.{r_{x}=x \atop {r_{y}=y}}\right.}.$$
 
:$$f_{xy}(x,y)=\frac{{\rm d}^{\rm 2} F_{xy}(r_{x},r_{y})}{{\rm d} r_{x} \,\, {\rm d} r_{y}}\Bigg|_{\left.{r_{x}=x \atop {r_{y}=y}}\right.}.$$
*Relative to the distribution function&nbsp; $F_{xy}(r_{x}, r_{y})$&nbsp; the following limits apply:
+
*Relative to the two-dimensional cumulative distribution function&nbsp; $F_{xy}(r_{x}, r_{y})$&nbsp; the following limits apply:
 
:$$F_{xy}(-\infty,-\infty) = 0,$$
 
:$$F_{xy}(-\infty,-\infty) = 0,$$
 
:$$F_{xy}(r_{\rm x},+\infty)=F_{x}(r_{x} ),$$
 
:$$F_{xy}(r_{\rm x},+\infty)=F_{x}(r_{x} ),$$
 
:$$F_{xy}(+\infty,r_{y})=F_{y}(r_{y} ) ,$$
 
:$$F_{xy}(+\infty,r_{y})=F_{y}(r_{y} ) ,$$
 
:$$F_{xy} (+\infty,+\infty) = 1.$$  
 
:$$F_{xy} (+\infty,+\infty) = 1.$$  
*In the limiting case&nbsp; $($infinitely large&nbsp; $r_{x}$&nbsp; and&nbsp; $r_{y})$&nbsp; Thus, for the 2D CDF, the value&nbsp; $1$.&nbsp; From this, we obtain the&nbsp; '''normalization condition'''&nbsp; for the 2D PDF:  
+
*From the last equation&nbsp; $($infinitely large&nbsp; $r_{x}$&nbsp; and&nbsp; $r_{y})$&nbsp; we obtain the&nbsp; &raquo;'''normalization condition'''&laquo;&nbsp; for the&nbsp; "2D&ndash; PDF":  
 
:$$\int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x \,\,{\rm d}y=1 . $$
 
:$$\int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x \,\,{\rm d}y=1 . $$
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
 
$\text{Conclusion:}$&nbsp; Note the significant difference between one-dimensional and two-dimensional random variables:  
 
$\text{Conclusion:}$&nbsp; Note the significant difference between one-dimensional and two-dimensional random variables:  
*For one-dimensional random variables, the area under the PDF always yields the value&nbsp; $1$.  
+
*For one-dimensional random variables,&nbsp; the area under the PDF always yields the value&nbsp; $1$.  
*For two-dimensional random variables, the PDF volume is always equal&nbsp; $1$.}}  
+
*For two-dimensional random variables,&nbsp; the PDF volume is always equal to&nbsp; $1$.}}  
  
==PDF and CDF for statistically independent components==
+
==PDF for statistically independent components==
 
<br>
 
<br>
For statistically independent components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; the following holds for the joint probability according to the elementary laws of statistics if&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are continuous in value:  
+
For statistically independent components&nbsp; $x$,&nbsp; $y$&nbsp; the following holds for the joint probability according to the elementary laws of statistics if&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are continuous in value:  
 
:$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap( y_{\rm 1}\le y\le y_{\rm 2})\big] ={\rm Pr} (x_{\rm 1}\le x \le x_{\rm 2}) \cdot {\rm Pr}(y_{\rm 1}\le y\le y_{\rm 2}) .$$
 
:$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap( y_{\rm 1}\le y\le y_{\rm 2})\big] ={\rm Pr} (x_{\rm 1}\le x \le x_{\rm 2}) \cdot {\rm Pr}(y_{\rm 1}\le y\le y_{\rm 2}) .$$
For this, independent components can also be written:  
+
For this,&nbsp; in the case of independent components can also be written:  
 
:$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap(y_{\rm 1}\le y\le y_{\rm 2})\big] =\int _{x_{\rm 1}}^{x_{\rm 2}}f_{x}(x) \,{\rm d}x\cdot \int_{y_{\rm 1}}^{y_{\rm 2}} f_{y}(y) \, {\rm d}y.$$
 
:$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap(y_{\rm 1}\le y\le y_{\rm 2})\big] =\int _{x_{\rm 1}}^{x_{\rm 2}}f_{x}(x) \,{\rm d}x\cdot \int_{y_{\rm 1}}^{y_{\rm 2}} f_{y}(y) \, {\rm d}y.$$
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; It follows that for&nbsp; '''statistical independence'''&nbsp; the following condition must be satisfied with respect to the 2D probability density function:  
+
$\text{Definition:}$&nbsp; It follows that for&nbsp; &raquo;'''statistical independence'''&laquo;&nbsp; the following condition must be satisfied with respect to the&nbsp; &raquo;'''two-dimensional probability density function'''&laquo;:  
 
:$$f_{xy}(x,y)=f_{x}(x) \cdot f_y(y) .$$}}
 
:$$f_{xy}(x,y)=f_{x}(x) \cdot f_y(y) .$$}}
  
  
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 2:}$&nbsp; In the graph, the instantaneous values of a two-dimensional random variable are plotted as points in the&nbsp; $(x, y)$&ndash;plane.  
+
$\text{Example 2:}$&nbsp; In the graph,&nbsp; the instantaneous values of a two-dimensional random variable are plotted as points in the&nbsp; $(x,\, y)$&ndash;plane.  
*Ranges with many points, which accordingly appear dark, indicate large values of the 2D PDF&nbsp; $f_{xy}(x, y)$.  
+
*Ranges with many points,&nbsp; which accordingly appear dark,&nbsp; indicate large values of the two-dimensional PDF&nbsp; $f_{xy}(x,\, y)$.  
*In contrast, the random variable&nbsp; $(x, y)$&nbsp; has relatively few components in rather bright areas.  
+
*In contrast,&nbsp; the random variable&nbsp; $(x,\, y)$&nbsp; has relatively few components in rather bright areas.  
 
 
 
 
[[File:P_ID153__Sto_T_4_1_S4_nochmals_neu.png |frame| Statistically independent components: &nbsp;$f_{xy}(x,y)$, $f_{x}(x)$&nbsp; and&nbsp;$f_{y}(y)$]]
 
  
 +
[[File:P_ID153__Sto_T_4_1_S4_nochmals_neu.png |frame| Statistically independent components: &nbsp;$f_{xy}(x, y)$, $f_{x}(x)$&nbsp; and&nbsp;$f_{y}(y)$]]
 +
<br>
 
The graph can be interpreted as follows:
 
The graph can be interpreted as follows:
*The marginal probability densities&nbsp; $f_{x}(x)$&nbsp; and&nbsp; $f_{y}(y)$&nbsp; already indicate that both&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are Gaussian and zero mean, and that the random variable&nbsp; $x$&nbsp; has a larger standard deviation than&nbsp; $y$&nbsp; .  
+
*The marginal probability densities&nbsp; $f_{x}(x)$&nbsp; and&nbsp; $f_{y}(y)$&nbsp; already indicate that both&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are Gaussian and zero mean,&nbsp; and that the random variable&nbsp; $x$&nbsp; has a larger standard deviation than&nbsp; $y$.  
*$f_{x}(x)$&nbsp; and&nbsp; $f_{y}(y)$&nbsp; however, do not provide information on whether or not statistical bindings exist for the random variable&nbsp; $(x, y)$&nbsp;.  
+
*$f_{x}(x)$&nbsp; and&nbsp; $f_{y}(y)$&nbsp; do not provide information on whether or not statistical bindings exist for the random variable&nbsp; $(x,\, y)$.  
*However, using the 2D PDF&nbsp; $f_{xy}(x,y)$&nbsp; one can see that there are no statistical bindings between the two components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; here.  
+
*However,&nbsp; using the&nbsp; "2D-PDF"&nbsp; $f_{xy}(x,\, y)$&nbsp; one can see that here there are no statistical bindings between the two components&nbsp; $x$&nbsp; and&nbsp; $y$.  
*With statistical independence, any cut through&nbsp; $f_{xy}(x, y)$&nbsp; parallel to&nbsp; $y$-axis yields a function that is equal in shape to the edge PDF&nbsp; $f_{y}(y)$.&nbsp; Similarly, all cuts parallel to&nbsp; $x$-axis are equal in shape to&nbsp; $f_{x}(x)$.  
+
*With statistical independence,&nbsp; any cut through&nbsp; $f_{xy}(x, y)$&nbsp; parallel to&nbsp; $y$&ndash;axis yields a function that is equal in shape to the marginal PDF&nbsp; $f_{y}(y)$.&nbsp; Similarly,&nbsp; all cuts parallel to&nbsp; $x$&ndash;axis are equal in shape to&nbsp; $f_{x}(x)$.  
 
+
*This fact is equivalent to saying that in this example&nbsp; $f_{xy}(x,\, y)$&nbsp; can be represented as the product of the two marginal probability densities: &nbsp;  
*This fact is equivalent to saying that in this example&nbsp; $f_{xy}(x, y)$&nbsp; can be represented as the product of the two marginal probability densities: &nbsp; $f_{xy}(x,y)=f_{x}(x) \cdot f_y(y) .$}}
+
:$$f_{xy}(x,\, y)=f_{x}(x) \cdot f_y(y) .$$}}
  
==PDF and CDF for statistically dependent components==
+
==PDF for statistically dependent components==
 
<br>
 
<br>
If there are statistical bindings between&nbsp; $x$&nbsp; and&nbsp; $y$, then different cuts parallel to&nbsp; $x$&ndash; and&nbsp; $y$&ndash;axis, respectively, yield different, non-shape equivalent functions.&nbsp; In this case, of course, the joint PDF cannot be described as a product of the two (one-dimensional) marginal probability densities either.
+
If there are statistical bindings between&nbsp; $x$&nbsp; and&nbsp; $y$,&nbsp; then different cuts parallel to&nbsp; $x$&ndash; and&nbsp; $y$&ndash;axis,&nbsp; resp.,&nbsp; yield different&nbsp; (non-shape equivalent)&nbsp; functions.&nbsp; In this case,&nbsp; of course,&nbsp; the joint PDF cannot be described as a product of the two&nbsp; (one-dimensional)&nbsp; marginal probability densities functions either.
  
[[File:P_ID156__Sto_T_4_1_S5_neu.png |right|frame|Statistically dependent components: &nbsp;$f_{xy}(x,y)$, $f_{x}(x)$,&nbsp; $f_{y}(y)$ ]]
+
{{GraueBox|TEXT=
{{GraueBox|TEXT=
+
$\text{Example 3:}$&nbsp; The graph shows the instantaneous values of a two-dimensional random variable in the&nbsp; $(x, y)$&ndash;plane.
$\text{Example 3:}$&nbsp; The graph shows the instantaneous values of a two-dimensional random variable in the&nbsp; $(x, y)$&ndash;plane, where now, unlike&nbsp; $\text{Example 2}$&nbsp; there are statistical bindings between&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; .  
+
[[File:P_ID156__Sto_T_4_1_S5_neu.png |right|frame|Statistically dependent components: &nbsp;$f_{xy}(x, y)$, $f_{x}(x)$,&nbsp; $f_{y}(y)$ ]]  
*The 2D random variable takes all 2D values with equal probability in the parallelogram drawn in blue.  
+
<br>Now,&nbsp; unlike&nbsp; $\text{Example 2}$&nbsp; there are statistical bindings between&nbsp; $x$&nbsp; and&nbsp; $y$.  
 +
*The two-dimensional random variable takes all&nbsp; "2D" values with equal probability in the parallelogram drawn in blue.  
 
*No values are possible outside the parallelogram.  
 
*No values are possible outside the parallelogram.  
  
  
One recognizes from this representation:
+
<br>One recognizes from this representation:
*Integration over $f_{xy}(x, y)$&nbsp; parallel to&nbsp; $x$&ndash;axis leads to the triangular marginal density $f_{y}(y)$, integration parallel to&nbsp; $y$&ndash;axis to the trapezoidal PDF$f_{x}(x)$.  
+
#Integration over $f_{xy}(x, y)$&nbsp; parallel to the&nbsp; $x$&ndash;axis leads to the triangular marginal PDF&nbsp; $f_{y}(y)$,&nbsp; integration parallel to&nbsp; $y$&ndash;axis to the trapezoidal PDF $f_{x}(x)$.  
*From the 2D PDF$f_{xy}(x, y)$&nbsp; it can already be guessed that for each&nbsp; $x$&ndash;value on statistical average a different&nbsp; $y$&ndash;value is to be expected.  
+
#From the joint PDF $f_{xy}(x, y)$&nbsp; it can already be guessed that for each&nbsp; $x$&ndash;value on statistical average, a different&nbsp; $y$&ndash;value is to be expected.  
*This means that here the components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are statistically dependent on each other. }}
+
#This means that the components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are statistically dependent on each other. }}
  
 
==Expected values of two-dimensional random variables==
 
==Expected values of two-dimensional random variables==
 
<br>
 
<br>
A special case of statistical dependence is ''correlation''.  
+
A special case of statistical dependence is&nbsp; "correlation".  
  
 
{{BlaueBox|TEXT=  
 
{{BlaueBox|TEXT=  
$\text{Definition:}$&nbsp; Under&nbsp; '''correlation'''&nbsp; one understands a ''linear dependence''&nbsp; between the individual components&nbsp; $x$&nbsp; and&nbsp; $y$.  
+
$\text{Definition:}$&nbsp; Under&nbsp; &raquo;'''correlation'''&laquo;&nbsp; one understands a&nbsp; "linear dependence"&nbsp; between the individual components&nbsp; $x$&nbsp; and&nbsp; $y$.  
 
*Correlated random variables are thus always also statistically dependent.  
 
*Correlated random variables are thus always also statistically dependent.  
*But not every statistical dependence implies correlation at the same time}}.
+
*But not every statistical dependence implies correlation at the same time.}}  
  
  
To quantitatively capture correlation, one uses various expected values of the 2D random variable&nbsp; $(x, y)$.  
+
To quantitatively capture correlation,&nbsp; one uses various expected values of the two-dimensional random variable&nbsp; $(x, y)$.  
  
These are defined analogously to the one-dimensional case.    
+
These are defined analogously to the one-dimensional case,    
*according to&nbsp; [[Theory_of_Stochastic_Signals/Moments_of_a_Discrete_Random_Variable|Chapter 2]]&nbsp; (for discrete value random variables).  
+
*according to&nbsp; [[Theory_of_Stochastic_Signals/Moments_of_a_Discrete_Random_Variable|"Chapter 2"]]&nbsp; (for discrete valued random variables).  
*bzw.&nbsp; [[Theory_of_Stochastic_Signals/Expected_Values_and_Moments|Chapter 3]]&nbsp; (for continuous value random variables):
+
*and&nbsp; [[Theory_of_Stochastic_Signals/Expected_Values_and_Moments|"Chapter 3"]]&nbsp; (for continuous valued random variables):
 
   
 
   
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; For the (non-centered)&nbsp; '''moments'''&nbsp; the relation holds:  
+
$\text{Definition:}$&nbsp; For the&nbsp; (non-centered)&nbsp; &raquo;'''moments'''&laquo;&nbsp; the following relation holds:  
 
:$$m_{kl}={\rm E}\big[x^k\cdot y^l\big]=\int_{-\infty}^{+\infty}\hspace{0.2cm}\int_{-\infty}^{+\infty} x\hspace{0.05cm}^{k} \cdot y\hspace{0.05cm}^{l} \cdot f_{xy}(x,y) \, {\rm d}x\, {\rm d}y.$$
 
:$$m_{kl}={\rm E}\big[x^k\cdot y^l\big]=\int_{-\infty}^{+\infty}\hspace{0.2cm}\int_{-\infty}^{+\infty} x\hspace{0.05cm}^{k} \cdot y\hspace{0.05cm}^{l} \cdot f_{xy}(x,y) \, {\rm d}x\, {\rm d}y.$$
Thus, the two linear means are&nbsp; $m_x = m_{10}$&nbsp; and&nbsp; $m_y = m_{01}.$ }}  
+
Thus,&nbsp; the two linear means are&nbsp; $m_x = m_{10}$&nbsp; and&nbsp; $m_y = m_{01}.$ }}  
  
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{definition:}$&nbsp; The&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; related&nbsp; '''central moments'''&nbsp; respectively are:  
+
$\text{Definition:}$&nbsp; The&nbsp; &raquo;'''central moments'''&laquo;&nbsp; $($related to&nbsp; $m_x$&nbsp; and&nbsp; $m_y)$&nbsp;   are:  
 
:$$\mu_{kl} = {\rm E}\big[(x-m_{x})\hspace{0.05cm}^k \cdot (y-m_{y})\hspace{0.05cm}^l\big] .$$
 
:$$\mu_{kl} = {\rm E}\big[(x-m_{x})\hspace{0.05cm}^k \cdot (y-m_{y})\hspace{0.05cm}^l\big] .$$
In this general definition equation, the variances&nbsp; $σ_x^2$&nbsp; and&nbsp; $σ_y^2$&nbsp; of the two individual components are included by&nbsp; $\mu_{20}$&nbsp; and&nbsp; $\mu_{02}$&nbsp; respectively. }}
+
In this general definition equation,&nbsp; the variances&nbsp; $σ_x^2$&nbsp; and&nbsp; $σ_y^2$&nbsp; of the two individual components are included by&nbsp; $\mu_{20}$&nbsp; and&nbsp; $\mu_{02}$,&nbsp; resp. }}
  
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; Of particular importance is the&nbsp; '''covariance'''&nbsp; $(k = l = 1)$, which is a measure of the ''linear statistical dependence''&nbsp; between the random variables&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; :
+
$\text{Definition:}$&nbsp; Of particular importance is the&nbsp; &raquo;'''covariance'''&laquo;&nbsp; $(k = l = 1)$,&nbsp; which is a measure of the&nbsp; "linear statistical dependence"&nbsp; between the variables&nbsp; $x$&nbsp; and&nbsp; $y$:
 
:$$\mu_{11} = {\rm E}\big[(x-m_{x})\cdot(y-m_{y})\big] = \int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} (x-m_{x}) \cdot (y-m_{y})\cdot f_{xy}(x,y) \,{\rm d}x \, {\rm d}y .$$
 
:$$\mu_{11} = {\rm E}\big[(x-m_{x})\cdot(y-m_{y})\big] = \int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} (x-m_{x}) \cdot (y-m_{y})\cdot f_{xy}(x,y) \,{\rm d}x \, {\rm d}y .$$
In the following, we also denote the covariance&nbsp; $\mu_{11}$&nbsp; in part by&nbsp; $\mu_{xy}$, if the covariance refers to the random variables&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp;}}  
+
In the following,&nbsp; we also denote the covariance&nbsp; $\mu_{11}$&nbsp; in part by&nbsp; "$\mu_{xy}$",&nbsp; if the covariance refers to the random variables&nbsp; $x$&nbsp; and&nbsp; $y$.}}  
  
  
 
Notes:
 
Notes:
*The covariance&nbsp; $\mu_{11}=\mu_{xy}$&nbsp; is related to the non-centered moment $m_{11} = m_{xy} = {\rm E}\big[x \cdot y\big]$ as follows:  
+
*The covariance&nbsp; $\mu_{11}=\mu_{xy}$&nbsp; is related to the non-centered moment&nbsp; $m_{11} = m_{xy} = {\rm E}\big[x \cdot y\big]$&nbsp; as follows:  
 
:$$\mu_{xy} = m_{xy} -m_{x }\cdot m_{y}.$$
 
:$$\mu_{xy} = m_{xy} -m_{x }\cdot m_{y}.$$
  
*This equation is enormously advantageous for numerical evaluations, since&nbsp; $m_{xy}$,&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; can be found from the sequences&nbsp; $〈x_v〉$&nbsp; and&nbsp; $〈y_v〉$&nbsp; in a single run.  
+
*This equation is enormously advantageous for numerical evaluations,&nbsp; since&nbsp; $m_{xy}$,&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; can be found from the sequences&nbsp; $〈x_v〉$&nbsp; and&nbsp; $〈y_v〉$&nbsp; in a single run.  
*On the other hand, if one were to calculate the covariance&nbsp; $\mu_{xy}$&nbsp; according to the above definition equation, one would have to find the mean values&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; in a first run and could then only calculate the expected value&nbsp; ${\rm E}\big[(x - m_x) \cdot (y - m_y)\big]$&nbsp; in a second run.  
+
*On the other hand,&nbsp; if one were to calculate the covariance&nbsp; $\mu_{xy}$&nbsp; according to the above definition equation,&nbsp; one would have to find the mean values&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; in a first run and could then only calculate the expected value&nbsp; ${\rm E}\big[(x - m_x) \cdot (y - m_y)\big]$&nbsp; in a second run.  
  
  
[[File:P_ID628__Sto_T_4_1_S6Neu.png |right|frame|Example 2D expected values]]
 
 
{{GraueBox|TEXT=   
 
{{GraueBox|TEXT=   
$\text{Example 4:}$&nbsp; In the first two rows of the table, the respective first elements of two random sequences&nbsp; $〈x_ν〉$&nbsp; and&nbsp; $〈y_ν〉$&nbsp; are entered.&nbsp; In the last row, the respective products&nbsp; $x_ν - y_ν$&nbsp; are given.  
+
$\text{Example 4:}$&nbsp; In the first two rows of the table,&nbsp; the first elements of two random sequences&nbsp; $〈x_ν〉$&nbsp; and&nbsp; $〈y_ν〉$&nbsp; are entered.&nbsp; In the last row, the respective products&nbsp; $x_ν - y_ν$&nbsp; are given.  
   
+
[[File:P_ID628__Sto_T_4_1_S6Neu.png |right|frame|Example for two-dimensional expected values]]  
*By averaging over the ten sequence elements in each case, one obtains&nbsp;  
+
*By averaging over ten sequence elements in each case,&nbsp; one obtains&nbsp;  
 
:$$m_x =0.5,\ \ m_y = 1, \ \ m_{xy} = 0.69.$$
 
:$$m_x =0.5,\ \ m_y = 1, \ \ m_{xy} = 0.69.$$
 
*This directly results in the value for the covariance:
 
*This directly results in the value for the covariance:
 
:$$\mu_{xy} = 0.69 - 0.5 · 1 = 0.19.$$  
 
:$$\mu_{xy} = 0.69 - 0.5 · 1 = 0.19.$$  
<br clear=all>
+
 
Without knowledge of the equation&nbsp; $\mu_{xy} = m_{xy} - m_x\cdot m_y$&nbsp; one would have had to first determine the mean values&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; in the first run,<br>in order to then determine the covariance&nbsp; $\mu_{xy}$&nbsp; as the expected value of the product of the zero mean variables in a second run.}}
+
Without knowledge of the equation&nbsp; $\mu_{xy} = m_{xy} - m_x\cdot m_y$&nbsp; one would have had to first determine the means&nbsp; $m_x$&nbsp; and&nbsp; $m_y$&nbsp; in the first run,&nbsp; and then determine the covariance&nbsp; $\mu_{xy}$&nbsp; as the expected value of the product of the zero mean variables in a second run.}}
  
 
==Correlation coefficient==
 
==Correlation coefficient==
 
<br>
 
<br>
With statistical independence of the two components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; the covariance&nbsp; $\mu_{xy} \equiv 0$.&nbsp; This case has already been considered in&nbsp; $\text{Example 2}$&nbsp; on the&nbsp; [[Theory_of_Stochastic_Signals/Two-Dimensional_Random_Variables#PDF_and_CDF_for_statistically_independent_components|PDF and CDF for statistically independent components]]&nbsp; page.
+
With statistical independence of the two components&nbsp; $x$&nbsp; and&nbsp; $y$ &nbsp; the covariance&nbsp; $\mu_{xy} \equiv 0$.&nbsp; This case has already been considered in&nbsp; $\text{Example 2}$&nbsp; in the section&nbsp; [[Theory_of_Stochastic_Signals/Two-Dimensional_Random_Variables#PDF_for_statistically_independent_components|"PDF for statistically independent components"]].
  
*But the result&nbsp; $\mu_{xy} = 0$&nbsp; is also possible for statistically dependent components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; namely when they are uncorrelated, i.e.&nbsp; ''linearly independent''&nbsp;.  
+
*But the result&nbsp; $\mu_{xy} = 0$&nbsp; is also possible for statistically dependent components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; namely when they are uncorrelated,&nbsp; i.e.&nbsp; "linearly independent".  
*The statistical dependence is then not of first order, but of higher order, for example corresponding to the equation&nbsp; $y=x^2.$
+
*The statistical dependence is then not of first order,&nbsp; but of higher order,&nbsp; for example corresponding to the equation&nbsp; $y=x^2.$
  
  
One speaks of&nbsp; '''complete correlation''' when the (deterministic) dependence between&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; is expressed by the equation&nbsp; $y = K · x$&nbsp; . Then the covariance is given by:
+
One speaks of&nbsp; &raquo;'''complete correlation'''&laquo;&nbsp; when the&nbsp; (deterministic)&nbsp; dependence between&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; is expressed by the equation&nbsp; $y = K · x$.&nbsp; Then the covariance is given by:
* $\mu_{xy} = σ_x · σ_y$&nbsp; with positive value of&nbsp; $K$,  
+
* $\mu_{xy} = σ_x · σ_y$&nbsp; with positive&nbsp; $K$&nbsp; value,  
* $\mu_{xy} = - σ_x · σ_y$&nbsp; with negative&nbsp; $K$&ndash;value.   
+
* $\mu_{xy} = - σ_x · σ_y$&nbsp; with negative&nbsp; $K$&nbsp; value.   
  
  
Therefore, instead of covariance, one often uses the so-called correlation coefficient as a descriptive variable.  
+
Therefore,&nbsp;  instead of the&nbsp; "covariance"&nbsp; one often uses the so-called&nbsp; "correlation coefficient"&nbsp; as descriptive quantity.  
  
 
{{BlaueBox|TEXT=   
 
{{BlaueBox|TEXT=   
$\text{Definition:}$&nbsp; The&nbsp; '''correlation coefficient'''&nbsp; is the quotient of the covariance&nbsp; $\mu_{xy}$&nbsp; and the product of the rms values&nbsp; $σ_x$&nbsp; and&nbsp; $σ_y$&nbsp; of the two components:  
+
$\text{Definition:}$&nbsp; The&nbsp; &raquo;'''correlation coefficient'''&laquo;&nbsp; is the quotient of the covariance&nbsp; $\mu_{xy}$&nbsp; and the product of the standard deviations&nbsp; $σ_x$&nbsp; and&nbsp; $σ_y$&nbsp; of the two components:  
 
:$$\rho_{xy}=\frac{\mu_{xy} }{\sigma_x \cdot \sigma_y}.$$}}
 
:$$\rho_{xy}=\frac{\mu_{xy} }{\sigma_x \cdot \sigma_y}.$$}}
  
  
 
The correlation coefficient&nbsp; $\rho_{xy}$&nbsp; has the following properties:  
 
The correlation coefficient&nbsp; $\rho_{xy}$&nbsp; has the following properties:  
*Because of normalization, &nbsp; $-1 \le ρ_{xy} ≤ +1$ always holds.  
+
*Because of normalization, &nbsp; $-1 \le ρ_{xy} ≤ +1$&nbsp; always holds.  
*If the two random variables&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are uncorrelated, then&nbsp; $ρ_{xy} = 0$.  
+
*If the two random variables&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are uncorrelated,&nbsp; then&nbsp; $ρ_{xy} = 0$.  
*For strict linear dependence between&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; is&nbsp; $ρ_{xy}= ±1$ &nbsp; &rArr; &nbsp; complete correlation.
+
*For strict linear dependence between&nbsp; $x$&nbsp; and&nbsp; $y$ &nbsp; &rArr; &nbsp; $ρ_{xy}= ±1$ &nbsp; &rArr; &nbsp; complete correlation.
*A positive correlation coefficient means that when&nbsp; $x$ is larger, on statistical average&nbsp; $y$&nbsp; is also larger than when&nbsp; $x$ is smaller.  
+
*A positive correlation coefficient means that when&nbsp; $x$&nbsp; is larger,&nbsp; on statistical average,&nbsp; $y$&nbsp; is also larger than when&nbsp; $x$&nbsp; is smaller.  
*In contrast, a negative correlation coefficient expresses that&nbsp; $y$&nbsp; becomes smaller on average as&nbsp; $x$&nbsp; increases.   
+
*In contrast,&nbsp; a negative correlation coefficient expresses that&nbsp; $y$&nbsp; becomes smaller on average as&nbsp; $x$&nbsp; increases.   
  
  
[[File:P_ID232__Sto_T_4_1_S7a_neu.png |right|frame| Gaussian 2D PDF with correlation]]
 
 
{{GraueBox|TEXT=  
 
{{GraueBox|TEXT=  
 +
[[File:P_ID232__Sto_T_4_1_S7a_neu.png |right|frame| Two-dimensional Gaussian PDF with correlation]]
 
$\text{Example 5:}$&nbsp; The following conditions apply:
 
$\text{Example 5:}$&nbsp; The following conditions apply:
*The considered components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; each have a Gaussian PDF.
+
#The considered components&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; each have a Gaussian PDF.
*The two standard deviations are different&nbsp; $(σ_y < σ_x)$.  
+
#The two standard deviations are different&nbsp; $(σ_y < σ_x)$.  
*The correlation coefficient is&nbsp; $ρ_{xy} = 0.8$.  
+
#The correlation coefficient is&nbsp; $ρ_{xy} = 0.8$.  
  
  
Unlike the&nbsp; [[Theory_of_Stochastic_Signals/Two-Dimensional_Random_Variables#PDF_and_CDF_for_statistically_independent_components| Example 2]]&nbsp; with statistically independent components &nbsp; &rArr; &nbsp; $ρ_{xy} = 0$&nbsp; $($drotz&nbsp; $σ_y < σ_x)$&nbsp; one recognizes that here with larger&nbsp; $x$-value on statistical average also&nbsp; $y$&nbsp; is larger than with smaller&nbsp; $x$.}}
+
Unlike&nbsp; [[Theory_of_Stochastic_Signals/Two-Dimensional_Random_Variables#PDF_for_statistically_independent_components|$\text{Example 2}$]]&nbsp; with statistically independent components &nbsp; &rArr; &nbsp; $ρ_{xy} = 0$&nbsp; $($even though&nbsp; $σ_y < σ_x)$&nbsp; one recognizes that here
 +
*with larger&nbsp; $x$&ndash;value, on statistical average,&nbsp; $y$&nbsp; is also larger  
 +
*than with a smaller&nbsp; $x$&ndash;value.}}
  
  
==Correlation line==
+
==Regression line==
 
<br>
 
<br>
[[File: P_ID1089__Sto_T_4_1_S7b_neu.png |frame| Gaussian 2D PDF with correlation line]]
 
 
{{BlaueBox|TEXT=  
 
{{BlaueBox|TEXT=  
$\text{Definition:}$&nbsp; A&nbsp; '''correlation line'''&nbsp; is the straight line&nbsp; $y = K(x)$&nbsp; in the&nbsp; $(x, y)$&ndash;plane through the "midpoint"&nbsp; $(m_x, m_y)$. Sometimes this straight line is also called&nbsp; ''regression line''&nbsp;.
+
$\text{Definition:}$&nbsp; The&nbsp; &raquo;'''regression line'''&laquo;&nbsp; &ndash; sometimes called&nbsp; "correlation line" &ndash;&nbsp; is the straight line&nbsp; $y = K(x)$&nbsp; in the&nbsp; $(x, y)$&ndash;plane through the&nbsp; "midpoint"&nbsp; $(m_x, m_y)$.&nbsp;  
 
+
[[File: EN_Sto_T_4_1_S7neu.png |frame|Two-dimensional Gaussian PDF with regression line&nbsp; $\rm (RL)$ ]]
The correlation line has the following properties:   
+
The regression line has the following properties:   
  
*The mean square deviation(error???) from this straight line - viewed in&nbsp; $y$&ndash;direction and averaged over all&nbsp; $N$&nbsp; points - is minimal:  
+
*The mean square deviation from this straight line&nbsp; - viewed in&nbsp; $y$&ndash;direction and averaged over all&nbsp; $N$&nbsp; points -&nbsp; is minimal:  
 
:$$\overline{\varepsilon_y^{\rm 2} }=\frac{\rm 1}{N} \cdot \sum_{\nu=\rm 1}^{N}\; \;\big [y_\nu - K(x_{\nu})\big ]^{\rm 2}={\rm minimum}.$$
 
:$$\overline{\varepsilon_y^{\rm 2} }=\frac{\rm 1}{N} \cdot \sum_{\nu=\rm 1}^{N}\; \;\big [y_\nu - K(x_{\nu})\big ]^{\rm 2}={\rm minimum}.$$
*The correlation straight line can be interpreted as a kind of&nbsp; "statistical symmetry axis"&nbsp;. The equation of the straight line is:  
+
*The regression line can be interpreted as a kind of&nbsp; "statistical symmetry axis".&nbsp; The equation of the straight line is:  
:$$y=K(x)=\frac{\sigma_y}{\sigma_x}\cdot\rho_{xy}\cdot(x - m_x)+m_y.$$}}
+
:$$y=K(x)=\frac{\sigma_y}{\sigma_x}\cdot\rho_{xy}\cdot(x - m_x)+m_y.$$
 
+
*The angle taken by the regression line to the&nbsp; $x$&ndash;axis is:
 +
:$$\theta_{y\hspace{0.05cm}\rightarrow \hspace{0.05cm}x}={\rm arctan}\ (\frac{\sigma_{y} }{\sigma_{x} }\cdot \rho_{xy}).$$}}
  
The angle taken by the correlation line to the&nbsp; $x$&ndash;axis is:
 
:$$\theta_{y\hspace{0.05cm}\rightarrow \hspace{0.05cm}x}={\rm arctan}\ (\frac{\sigma_{y} }{\sigma_{x} }\cdot \rho_{xy}).$$
 
  
By this nomenclature it should be made clear that we are dealing here with the regression of&nbsp; $y$&nbsp; on&nbsp; $x$&nbsp; .  
+
By this nomenclature it should be made clear that we are dealing here with the regression of&nbsp; $y$&nbsp; on&nbsp; $x$.  
  
*The regression in the opposite direction - that is, from&nbsp; $x$&nbsp; to&nbsp; $y$ - on the other hand, means the minimization of the mean square deviation in&nbsp; $x$ direction.  
+
*The regression in the opposite direction&nbsp;  &ndash; that is, from&nbsp; $x$&nbsp; to&nbsp; $y$ &ndash;&nbsp;  on the other hand,&nbsp;  means the minimization of the mean square deviation in&nbsp; $x$&ndash;direction.  
  
*The interactive applet&nbsp; [[Applets:Korrelationskoeffizient_%26_Regressionsgerade|Correlation Coefficient and Regression Line]]&nbsp; illustrates that in general&nbsp; $($if&nbsp; $σ_y \ne σ_x)$&nbsp; for the regression of&nbsp; $x$&nbsp; on&nbsp; $y$&nbsp; will result in a different angle and thus a different regression line:  
+
*The&nbsp; (German language)&nbsp;  applet&nbsp; [[Applets:Korrelation_und_Regressionsgerade|"Korrelation und Regressionsgerade"]] &nbsp; &rArr; &nbsp; "Correlation Coefficient and Regression Line"&nbsp; illustrates <br>that in general&nbsp; $($if&nbsp; $σ_y \ne σ_x)$&nbsp; for the regression of&nbsp; $x$&nbsp; on&nbsp; $y$&nbsp; will result in a different angle and thus a different regression line:  
 
:$$\theta_{x\hspace{0.05cm}\rightarrow \hspace{0.05cm} y}={\rm arctan}\ (\frac{\sigma_{x}}{\sigma_{y}}\cdot \rho_{xy}).$$
 
:$$\theta_{x\hspace{0.05cm}\rightarrow \hspace{0.05cm} y}={\rm arctan}\ (\frac{\sigma_{x}}{\sigma_{y}}\cdot \rho_{xy}).$$
  

Latest revision as of 14:38, 21 December 2022

# OVERVIEW OF THE FOURTH MAIN CHAPTER #


Now random variables with statistical bindings are treated and illustrated by typical examples. 

After the general description of two-dimensional random variables,  we turn to

  1. the  "auto-correlation function", 
  2. the  "cross-correlation function"
  3. and the associated spectral functions  $($"power-spectral density",  "cross power-spectral density"$)$.


Specifically,  this chapter covers:

  • the statistical description of  »two-dimensional random variables«  using the  »joint PDF«,
  • the difference between  »statistical dependence«  and  »correlation«,
  • the classification features  »stationarity«  and  »ergodicity«  of stochastic processes,
  • the definitions of  »auto-correlation function«  $\rm (ACF)$  and  »power-spectral density«  $\rm (PSD)$,
  • the definitions of  »cross-correlation function«  $\rm (CCF)$   and  »cross power-spectral density«  $\rm (C–PSD)$, 
  • the numerical determination of all these variables in the two- and multi-dimensional case.



Properties and examples


As a transition to the  $\text{correlation functions}$  we now consider two random variables  $x$  and  $y$,  between which statistical dependences exist. 

Each of these two random variables can be described on its own with the introduced characteristic variables corresponding


$\text{Definition:}$  To describe the statistical dependences between two variables  $x$  and  $y$,  it is convenient to combine the two components
      into one   »two-dimensional random variable«   or   »2D random variable«  $(x, y)$.

  • The individual components can be signals such as the real and imaginary parts of a phase modulated signal.
  • But there are a variety of two-dimensional random variables in other domains as well,  as the following example will show.


$\text{Example 1:}$  The left diagram is from the random experiment  "Throwing two dice". 

Two examples of statistically dependent random variables
  • Plotted to the right is the number of the first die  $(W_1)$, 
  • plotted to the top is the sum  $S$  of both dice. 


The two components here are each discrete random variables between which there are statistical dependencies:

  • If  $W_1 = 1$,  then the sum  $S$  can only take values between  $2$  and  $7$,  each with equal probability.
  • In contrast,  for  $W_1 = 6$  all values between  $7$  and  $12$  are possible,  also with equal probability.


In the right diagram,  the maximum temperatures of the  $31$ days in May 2002 of Munich  (to the top)  and the mountain  "Zugspitze"  (to the right)  are contrasted.  Both random variables are continuous in value:

  • Although the measurement points are about  $\text{100 km}$  apart,  and on the Zugspitze,  it is on average about   $20$  degrees colder than in Munich due to the different altitudes  $($nearly  $3000$  versus  $520$  meters$)$,  one recognizes nevertheless a certain statistical dependence between the two random variables  ${\it Θ}_{\rm M}$  and  ${\it Θ}_{\rm Z}$.
  • If it is warm in Munich,  then pleasant temperatures are also more likely to be expected on the Zugspitze.  However,  the relationship is not deterministic:  The coldest day in May 2002 was a different day in Munich than the coldest day on the Zugspitze.

Joint probability density function


We restrict ourselves here mostly to continuous valued random variables.

  • However,  sometimes the peculiarities of two-dimensional discrete random variables are discussed in more detail. 
  • Most of the characteristics previously defined for one-dimensional random variables can be easily extended to two-dimensional variables.


$\text{Definition:}$  The  probability density function  $\rm (PDF)$  of the two-dimensional random variable at the location  $(x_\mu,\hspace{0.1cm} y_\mu)$   ⇒   »joint PDF«   or   »2D–PDF«
is an extension of the one-dimensional PDF  $(∩$  denotes logical  "and"  operation$)$:

$$f_{xy}(x_\mu, \hspace{0.1cm}y_\mu) = \lim_{\left.{\Delta x\rightarrow 0 \atop {\Delta y\rightarrow 0} }\right.}\frac{ {\rm Pr}\big [ (x_\mu - {\rm \Delta} x/{\rm 2} \le x \le x_\mu + {\rm \Delta} x/{\rm 2}) \cap (y_\mu - {\rm \Delta} y/{\rm 2} \le y \le y_\mu +{\rm \Delta}y/{\rm 2}) \big] }{ {\rm \Delta} \ x\cdot{\rm \Delta} y}.$$

$\rm Note$:

  • If the two-dimensional random variable is discrete,  the definition must be slightly modified:
  • For the lower range limits,  the  "less-than-equal"  sign must then be replaced by  "less-than"  according to the section  "CDF for discrete-valued random variables"


Using this joint PDF $f_{xy}(x, y)$,  statistical dependencies within the two-dimensional random variable  $(x,\ y)$  are also fully captured in contrast to the two one-dimensional density functions   ⇒   »marginal probability density functions«   $($or   "edge probability density functions"$)$:

$$f_{x}(x) = \int _{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}y ,$$
$$f_{y}(y) = \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x .$$

These two marginal probability density functions  $f_x(x)$  and  $f_y(y)$

  • provide only statistical information about the individual components  $x$  and  $y$, resp.
  • but not about the statistical bindings between them.


Two-dimensional cumulative distribution function


$\text{Definition:}$  Like the  "2D–PDF",  the  »2D cumulative distribution function«  is merely a useful extension of the  $\text{one-dimensional distribution function}$  $\rm (CDF)$:

$$F_{xy}(r_{x},r_{y}) = {\rm Pr}\big [(x \le r_{x}) \cap (y \le r_{y}) \big ] .$$


The following similarities and differences between the  "1D–CDF"  and the  2D–CDF"  emerge:

  • The functional relationship between two-dimensional PDF and two-dimensional CDF is given by integration as in the one-dimensional case,  but now in two dimensions.  For continuous valued random variables:
$$F_{xy}(r_{x},r_{y})=\int_{-\infty}^{r_{y}} \int_{-\infty}^{r_{x}} f_{xy}(x,y) \,\,{\rm d}x \,\, {\rm d}y .$$
  • Inversely,  the probability density function can be given from the cumulative distribution function by partial differentiation to  $r_{x}$  and  $r_{y}$:
$$f_{xy}(x,y)=\frac{{\rm d}^{\rm 2} F_{xy}(r_{x},r_{y})}{{\rm d} r_{x} \,\, {\rm d} r_{y}}\Bigg|_{\left.{r_{x}=x \atop {r_{y}=y}}\right.}.$$
  • Relative to the two-dimensional cumulative distribution function  $F_{xy}(r_{x}, r_{y})$  the following limits apply:
$$F_{xy}(-\infty,-\infty) = 0,$$
$$F_{xy}(r_{\rm x},+\infty)=F_{x}(r_{x} ),$$
$$F_{xy}(+\infty,r_{y})=F_{y}(r_{y} ) ,$$
$$F_{xy} (+\infty,+\infty) = 1.$$
  • From the last equation  $($infinitely large  $r_{x}$  and  $r_{y})$  we obtain the  »normalization condition«  for the  "2D– PDF":
$$\int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} f_{xy}(x,y) \,\,{\rm d}x \,\,{\rm d}y=1 . $$

$\text{Conclusion:}$  Note the significant difference between one-dimensional and two-dimensional random variables:

  • For one-dimensional random variables,  the area under the PDF always yields the value  $1$.
  • For two-dimensional random variables,  the PDF volume is always equal to  $1$.

PDF for statistically independent components


For statistically independent components  $x$,  $y$  the following holds for the joint probability according to the elementary laws of statistics if  $x$  and  $y$  are continuous in value:

$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap( y_{\rm 1}\le y\le y_{\rm 2})\big] ={\rm Pr} (x_{\rm 1}\le x \le x_{\rm 2}) \cdot {\rm Pr}(y_{\rm 1}\le y\le y_{\rm 2}) .$$

For this,  in the case of independent components can also be written:

$${\rm Pr} \big[(x_{\rm 1}\le x \le x_{\rm 2}) \cap(y_{\rm 1}\le y\le y_{\rm 2})\big] =\int _{x_{\rm 1}}^{x_{\rm 2}}f_{x}(x) \,{\rm d}x\cdot \int_{y_{\rm 1}}^{y_{\rm 2}} f_{y}(y) \, {\rm d}y.$$

$\text{Definition:}$  It follows that for  »statistical independence«  the following condition must be satisfied with respect to the  »two-dimensional probability density function«:

$$f_{xy}(x,y)=f_{x}(x) \cdot f_y(y) .$$


$\text{Example 2:}$  In the graph,  the instantaneous values of a two-dimensional random variable are plotted as points in the  $(x,\, y)$–plane.

  • Ranges with many points,  which accordingly appear dark,  indicate large values of the two-dimensional PDF  $f_{xy}(x,\, y)$.
  • In contrast,  the random variable  $(x,\, y)$  has relatively few components in rather bright areas.
Statistically independent components:  $f_{xy}(x, y)$, $f_{x}(x)$  and $f_{y}(y)$


The graph can be interpreted as follows:

  • The marginal probability densities  $f_{x}(x)$  and  $f_{y}(y)$  already indicate that both  $x$  and  $y$  are Gaussian and zero mean,  and that the random variable  $x$  has a larger standard deviation than  $y$.
  • $f_{x}(x)$  and  $f_{y}(y)$  do not provide information on whether or not statistical bindings exist for the random variable  $(x,\, y)$.
  • However,  using the  "2D-PDF"  $f_{xy}(x,\, y)$  one can see that here there are no statistical bindings between the two components  $x$  and  $y$.
  • With statistical independence,  any cut through  $f_{xy}(x, y)$  parallel to  $y$–axis yields a function that is equal in shape to the marginal PDF  $f_{y}(y)$.  Similarly,  all cuts parallel to  $x$–axis are equal in shape to  $f_{x}(x)$.
  • This fact is equivalent to saying that in this example  $f_{xy}(x,\, y)$  can be represented as the product of the two marginal probability densities:  
$$f_{xy}(x,\, y)=f_{x}(x) \cdot f_y(y) .$$

PDF for statistically dependent components


If there are statistical bindings between  $x$  and  $y$,  then different cuts parallel to  $x$– and  $y$–axis,  resp.,  yield different  (non-shape equivalent)  functions.  In this case,  of course,  the joint PDF cannot be described as a product of the two  (one-dimensional)  marginal probability densities functions either.

$\text{Example 3:}$  The graph shows the instantaneous values of a two-dimensional random variable in the  $(x, y)$–plane.

Statistically dependent components:  $f_{xy}(x, y)$, $f_{x}(x)$,  $f_{y}(y)$


Now,  unlike  $\text{Example 2}$  there are statistical bindings between  $x$  and  $y$.

  • The two-dimensional random variable takes all  "2D" values with equal probability in the parallelogram drawn in blue.
  • No values are possible outside the parallelogram.



One recognizes from this representation:

  1. Integration over $f_{xy}(x, y)$  parallel to the  $x$–axis leads to the triangular marginal PDF  $f_{y}(y)$,  integration parallel to  $y$–axis to the trapezoidal PDF $f_{x}(x)$.
  2. From the joint PDF $f_{xy}(x, y)$  it can already be guessed that for each  $x$–value on statistical average, a different  $y$–value is to be expected.
  3. This means that the components  $x$  and  $y$  are statistically dependent on each other.

Expected values of two-dimensional random variables


A special case of statistical dependence is  "correlation".

$\text{Definition:}$  Under  »correlation«  one understands a  "linear dependence"  between the individual components  $x$  and  $y$.

  • Correlated random variables are thus always also statistically dependent.
  • But not every statistical dependence implies correlation at the same time.


To quantitatively capture correlation,  one uses various expected values of the two-dimensional random variable  $(x, y)$.

These are defined analogously to the one-dimensional case,

  • according to  "Chapter 2"  (for discrete valued random variables).
  • and  "Chapter 3"  (for continuous valued random variables):


$\text{Definition:}$  For the  (non-centered)  »moments«  the following relation holds:

$$m_{kl}={\rm E}\big[x^k\cdot y^l\big]=\int_{-\infty}^{+\infty}\hspace{0.2cm}\int_{-\infty}^{+\infty} x\hspace{0.05cm}^{k} \cdot y\hspace{0.05cm}^{l} \cdot f_{xy}(x,y) \, {\rm d}x\, {\rm d}y.$$

Thus,  the two linear means are  $m_x = m_{10}$  and  $m_y = m_{01}.$


$\text{Definition:}$  The  »central moments«  $($related to  $m_x$  and  $m_y)$  are:

$$\mu_{kl} = {\rm E}\big[(x-m_{x})\hspace{0.05cm}^k \cdot (y-m_{y})\hspace{0.05cm}^l\big] .$$

In this general definition equation,  the variances  $σ_x^2$  and  $σ_y^2$  of the two individual components are included by  $\mu_{20}$  and  $\mu_{02}$,  resp.


$\text{Definition:}$  Of particular importance is the  »covariance«  $(k = l = 1)$,  which is a measure of the  "linear statistical dependence"  between the variables  $x$  and  $y$:

$$\mu_{11} = {\rm E}\big[(x-m_{x})\cdot(y-m_{y})\big] = \int_{-\infty}^{+\infty} \int_{-\infty}^{+\infty} (x-m_{x}) \cdot (y-m_{y})\cdot f_{xy}(x,y) \,{\rm d}x \, {\rm d}y .$$

In the following,  we also denote the covariance  $\mu_{11}$  in part by  "$\mu_{xy}$",  if the covariance refers to the random variables  $x$  and  $y$.


Notes:

  • The covariance  $\mu_{11}=\mu_{xy}$  is related to the non-centered moment  $m_{11} = m_{xy} = {\rm E}\big[x \cdot y\big]$  as follows:
$$\mu_{xy} = m_{xy} -m_{x }\cdot m_{y}.$$
  • This equation is enormously advantageous for numerical evaluations,  since  $m_{xy}$,  $m_x$  and  $m_y$  can be found from the sequences  $〈x_v〉$  and  $〈y_v〉$  in a single run.
  • On the other hand,  if one were to calculate the covariance  $\mu_{xy}$  according to the above definition equation,  one would have to find the mean values  $m_x$  and  $m_y$  in a first run and could then only calculate the expected value  ${\rm E}\big[(x - m_x) \cdot (y - m_y)\big]$  in a second run.


$\text{Example 4:}$  In the first two rows of the table,  the first elements of two random sequences  $〈x_ν〉$  and  $〈y_ν〉$  are entered.  In the last row, the respective products  $x_ν - y_ν$  are given.

Example for two-dimensional expected values
  • By averaging over ten sequence elements in each case,  one obtains 
$$m_x =0.5,\ \ m_y = 1, \ \ m_{xy} = 0.69.$$
  • This directly results in the value for the covariance:
$$\mu_{xy} = 0.69 - 0.5 · 1 = 0.19.$$

Without knowledge of the equation  $\mu_{xy} = m_{xy} - m_x\cdot m_y$  one would have had to first determine the means  $m_x$  and  $m_y$  in the first run,  and then determine the covariance  $\mu_{xy}$  as the expected value of the product of the zero mean variables in a second run.

Correlation coefficient


With statistical independence of the two components  $x$  and  $y$   the covariance  $\mu_{xy} \equiv 0$.  This case has already been considered in  $\text{Example 2}$  in the section  "PDF for statistically independent components".

  • But the result  $\mu_{xy} = 0$  is also possible for statistically dependent components  $x$  and  $y$  namely when they are uncorrelated,  i.e.  "linearly independent".
  • The statistical dependence is then not of first order,  but of higher order,  for example corresponding to the equation  $y=x^2.$


One speaks of  »complete correlation«  when the  (deterministic)  dependence between  $x$  and  $y$  is expressed by the equation  $y = K · x$.  Then the covariance is given by:

  • $\mu_{xy} = σ_x · σ_y$  with positive  $K$  value,
  • $\mu_{xy} = - σ_x · σ_y$  with negative  $K$  value.


Therefore,  instead of the  "covariance"  one often uses the so-called  "correlation coefficient"  as descriptive quantity.

$\text{Definition:}$  The  »correlation coefficient«  is the quotient of the covariance  $\mu_{xy}$  and the product of the standard deviations  $σ_x$  and  $σ_y$  of the two components:

$$\rho_{xy}=\frac{\mu_{xy} }{\sigma_x \cdot \sigma_y}.$$


The correlation coefficient  $\rho_{xy}$  has the following properties:

  • Because of normalization,   $-1 \le ρ_{xy} ≤ +1$  always holds.
  • If the two random variables  $x$  and  $y$  are uncorrelated,  then  $ρ_{xy} = 0$.
  • For strict linear dependence between  $x$  and  $y$   ⇒   $ρ_{xy}= ±1$   ⇒   complete correlation.
  • A positive correlation coefficient means that when  $x$  is larger,  on statistical average,  $y$  is also larger than when  $x$  is smaller.
  • In contrast,  a negative correlation coefficient expresses that  $y$  becomes smaller on average as  $x$  increases.


Two-dimensional Gaussian PDF with correlation

$\text{Example 5:}$  The following conditions apply:

  1. The considered components  $x$  and  $y$  each have a Gaussian PDF.
  2. The two standard deviations are different  $(σ_y < σ_x)$.
  3. The correlation coefficient is  $ρ_{xy} = 0.8$.


Unlike  $\text{Example 2}$  with statistically independent components   ⇒   $ρ_{xy} = 0$  $($even though  $σ_y < σ_x)$  one recognizes that here

  • with larger  $x$–value, on statistical average,  $y$  is also larger
  • than with a smaller  $x$–value.


Regression line


$\text{Definition:}$  The  »regression line«  – sometimes called  "correlation line" –  is the straight line  $y = K(x)$  in the  $(x, y)$–plane through the  "midpoint"  $(m_x, m_y)$. 

Two-dimensional Gaussian PDF with regression line  $\rm (RL)$

The regression line has the following properties:

  • The mean square deviation from this straight line  - viewed in  $y$–direction and averaged over all  $N$  points -  is minimal:
$$\overline{\varepsilon_y^{\rm 2} }=\frac{\rm 1}{N} \cdot \sum_{\nu=\rm 1}^{N}\; \;\big [y_\nu - K(x_{\nu})\big ]^{\rm 2}={\rm minimum}.$$
  • The regression line can be interpreted as a kind of  "statistical symmetry axis".  The equation of the straight line is:
$$y=K(x)=\frac{\sigma_y}{\sigma_x}\cdot\rho_{xy}\cdot(x - m_x)+m_y.$$
  • The angle taken by the regression line to the  $x$–axis is:
$$\theta_{y\hspace{0.05cm}\rightarrow \hspace{0.05cm}x}={\rm arctan}\ (\frac{\sigma_{y} }{\sigma_{x} }\cdot \rho_{xy}).$$


By this nomenclature it should be made clear that we are dealing here with the regression of  $y$  on  $x$.

  • The regression in the opposite direction  – that is, from  $x$  to  $y$ –  on the other hand,  means the minimization of the mean square deviation in  $x$–direction.
  • The  (German language)  applet  "Korrelation und Regressionsgerade"   ⇒   "Correlation Coefficient and Regression Line"  illustrates
    that in general  $($if  $σ_y \ne σ_x)$  for the regression of  $x$  on  $y$  will result in a different angle and thus a different regression line:
$$\theta_{x\hspace{0.05cm}\rightarrow \hspace{0.05cm} y}={\rm arctan}\ (\frac{\sigma_{x}}{\sigma_{y}}\cdot \rho_{xy}).$$


Exercises for the chapter


Exercise 4.1: Triangular (x, y) Area

Exercise 4.1Z: Appointment to Breakfast

Exercise 4.2: Triangle Area again

Exercise 4.2Z: Correlation between "x" and "e to the Power of x"

Exercise 4.3: Algebraic and Modulo Sum

Exercise 4.3Z: Dirac-shaped 2D PDF