Difference between revisions of "Mobile Communications/The GWSSUS Channel Model"

Generalized system functions of time variant-systems

Linear time-invariant systems  $\rm (LTI)$  can be completely described with only two system functions,

• the transfer function  $H(f)$  and
• the impulse response  $h(t)$   ⇒   after renaming   $h(\tau)$.

In contrast, four different functions are possible with time-variant systems  $\rm (LTV)$ .  A formal distinction of these functions with regard to time and frequency domain representation by lowercase and uppercase letters is thus excluded.

Therefore a nomenclature change will be made, which can be formalized as follows:

• The four possible system functions are uniformly denoted by  $\boldsymbol{\eta}_{12}$ .
  

• The first subindex is either a  $\boldsymbol{\rm V}$  $($because of German  $\rm V\hspace{-0.05cm}$erzögerung   ⇒   delay time  $\tau)$  or  a  $\boldsymbol{\rm F}$  $($frequency  $f)$.
  

• Either a  $\boldsymbol{\rm Z}$  $($because of German  $\rm Z\hspace{-0.05cm}$eit   ⇒   time  $t)$  or a  $\boldsymbol{\rm D}$  $($Doppler frequency  $f_{\rm D})$  is possible as the second subindex.

Since, in contrast to line-based transmission, the system functions of mobile communications cannot be described deterministically, but are statistical variables, the corresponding correlation functions must be considered later on. 

In the following, we will refer to these as  $\boldsymbol{\varphi}_{12}$,  and use the same indices as for the system functions  $\boldsymbol{\eta}_{12}$.

• These formalized designations are inscribed in the graphic in blue letters.
• Additionally, the designations used in other chapters or literature are given  (gray letters).  In the other chapters these are also partly used.

${\rm (1)}$   At the top you can see the  »time-variant impulse response«   ${\eta}_{\rm VZ}(\tau,\hspace{0.05cm} t) \equiv h(\tau,\hspace{0.05cm} t)$  in the  "delay–time range".  The associated auto-correlation function  $\rm (ACF)$  is

\[\varphi_{\rm VZ}(\tau_1, t_1, \tau_2, t_2) = {\rm E} \big[ \eta_{\rm VZ}(\tau_1,\hspace{0.05cm} t_1) \cdot \eta_{\rm VZ}^{\star}(\tau_2, t_2) \big]\hspace{0.05cm}. \]

${\rm (2)}$  For the  "frequency–time representation"  you get the  »time-variant transfer function«   ${\eta}_{\rm FZ}(f,\hspace{0.05cm} t) \equiv H(f,\hspace{0.05cm} t)$. 
         The Fourier transform with respect to  $\tau$  is represented in the graph by  ${\rm F}_\tau\hspace{0.05cm}[ \cdot ]$ .  The Fourier integral is written out in full:

\[\eta_{\rm FZ}(f, \hspace{0.05cm} t) = \int_{-\infty}^{+\infty} \eta_{\rm VZ}(\tau,\hspace{0.05cm} t) \cdot {\rm e}^{- {\rm j}\cdot 2 \pi f \tau}\hspace{0.15cm}{\rm d}\tau \hspace{0.05cm}, \hspace{0.3cm} \text{kurz:} \hspace{0.2cm} \eta_{\rm FZ}(f, t) \hspace{0.2cm} \stackrel{f, \hspace{0.05cm} \tau}{\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} \eta_{\rm VZ}(\tau, t) \hspace{0.05cm}.\]

The ACF of this time-variant transfer function is generally:

\[\varphi_{\rm FZ}(f_1, t_1, f_2, t_2) = {\rm E} \big [ \eta_{\rm FZ}(f_1, t_1) \cdot \eta_{\rm FZ}^{\star}(f_2, t_2) \big ]\hspace{0.05cm}.\]

${\rm (3)}$  The  »Scatter–Function«  ${\eta}_{\rm VD}(\tau,\hspace{0.05cm} f_{\rm D}) \equiv s(\tau,\hspace{0.05cm} f_{\rm D})$  corresponding to the left block describes the mobile communications channel in the  "delay–Doppler area".  
         $f_{\rm D}$  describes the  $\text{Doppler frequency}$.   The scatter function results from  ${\eta}_{\rm VZ}(\tau,\hspace{0.05cm} t)$  through Fourier transformation with respect to the second parameter  $t$:

\[ \eta_{\rm VD}(\tau, f_{\rm D}) \hspace{0.2cm} \stackrel{f_{\rm D}, \hspace{0.05cm}t}{\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} \eta_{\rm VZ}(\tau, t)\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \varphi_{\rm VD}(\tau_1, f_{\rm D_1}, \tau_2, f_{\rm D_2}) = {\rm E} \left [ \eta_{\rm VD}(\tau_1, f_{\rm D_1}) \cdot \eta_{\rm VD}^{\star}(\tau_2, f_{\rm D_2}) \right ] \hspace{0.05cm}.\]

${\rm (4)}$  Finally, we consider the so-called  »frequency-variant transfer function«  $\eta_{\rm FD}(f, f_{\rm D})$, i.e. the  "frequency–Doppler representation". 
         According to the graph, this can be reached in two ways:

$$\eta_{\rm FD}(f, f_{\rm D}) \hspace{0.2cm} \stackrel{f_{\rm D}, \hspace{0.05cm}t}{\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} \eta_{\rm FZ}(f, t)\hspace{0.05cm},\hspace{0.5cm}\eta_{\rm FD}(f, f_{\rm D}) \hspace{0.2cm} \stackrel{f, \hspace{0.05cm}\tau}{\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} \eta_{\rm VD}(\tau, f_{\rm D})\hspace{0.05cm}.$$

Simplifications due to the GWSSUS requirements

The general relationship between the four system functions is very complicated due to non-stationary effects.

Compared to the general model, some limitations have to be made in order to arrive at a suitable model for the mobile communications channel from which relevant statements for practical applications can be derived.

The following definitions lead to the  $\rm GWSSUS$ model 
$( \rm G$aussian  $\rm W$ide  $\rm S$ense  $\rm S$tationary  $\rm U$ncorrelated  $\rm S$cattering$)$:

• The random process of the channel impulse response  $h(\tau,\hspace{0.1cm} t) = {\eta}_{\rm VZ}(\tau,\hspace{0.1cm} t)$  is generally assumed to be complex  (i.e., description in the equivalent low-pass range),  Gaussian  $($identifier  $\rm G)$  and zero-mean  (Rayleigh, not Rice, that means, no line of sight) .
  

• The random process is weakly stationary  ⇒   its characteristics change only slightly with time, and the ACF  $ {\varphi}_{\rm VZ}(\tau_1,\hspace{0.05cm} t_1,\hspace{0.05cm}\tau_2,\hspace{0.05cm} t_2)$  of the time-variant impulse response does not depend on the absolute times  $t_1$  and  $t_2$  but only on the time difference  $\Delta t = t_2 - t_1$.   This is indicated by the identifier  $\rm WSS$    ⇒   $\rm W$ide $\rm S$ense $\rm S$tationary.
  

• The individual echoes due to multipath propagation are uncorrelated, which is expressed by the identifier  $\rm US$   ⇒   $\rm U$ncorrelated $\rm S$cattering.

The mobile communications channel can be described in full according to this graph.  The individual power-spectral densities  (labeled blue)  and the correlation function  (labeled red)  is explained in detail in the following sections.

Auto-correlation function of the time-variant impulse response

We now consider the  $\text{auto-correlation function}$  $\rm (ACF)$  of the time-variant impulse response   ⇒   $h(\tau,\hspace{0.1cm} t) = {\eta}_{\rm VZ}(\tau,\hspace{0.1cm} t)$  more closely.  It shows:

• Based on the  $\rm WSS$ property, the auto-correlation function can be written with  $\Delta t = t_2 - t_1$ :

\[\varphi_{\rm VZ}(\tau_1, t_1, \tau_2, t_2) = \varphi_{\rm VZ}(\tau_1, \tau_2, \Delta t)\hspace{0.05cm}.\]

• Since the echoes were assumed to be independent of each other  $\rm (US$ property$)$, the impulse response can be assumed to be uncorrelated with respect to the delays  $\tau_1$  and  $\tau_2$.  Then:

\[\varphi_{\rm VZ}(\tau_1, \tau_2, \Delta t) = 0 \hspace{0.35cm}{\rm f\ddot{u}r}\hspace{0.35cm} \tau_1 \ne \tau_2\hspace{0.05cm}. \]

• If one now replaces  $\tau_1$  with  $\tau$  and  $\tau_2$  with  $\tau + \Delta \tau$, this auto-correlation function can be represented in the following way:

\[\varphi_{\rm VZ}(\Delta \tau, \Delta t) = \delta(\Delta \tau) \cdot {\it \Phi}_{\rm VZ}(\tau, \Delta t) \hspace{0.05cm}. \]

• Because of the convolution property of the Dirac delta function, the ACF for  $\tau_1 \ne \tau_2$   ⇒   $\Delta \tau \ne 0$ disappears.

• $ {\it \Phi}_{\rm VZ}(\tau, \Delta t) \hspace{0.1cm}$  is the  »delay–time's cross power-spectral density«, which depends on the delay  $\tau \ (= \tau_1 =\tau_2)$  and on the time difference  $\Delta t = t_2 - t_1$ .

In the overview in the last section, the  »delay–time's cross power-spectral density«  ${\it \Phi}_{\rm VZ}(\tau, \Delta t) $  can be seen in the top middle.

• Since  $\eta_{\rm VZ}(\tau, t) $,  like any  $\text{impulse response}$,  has the unit  $\rm [1/s]$ , the auto-correlation function has the unit  $\rm [1/s^2]$:

\[\varphi_{\rm VZ}(\Delta \tau, \Delta t) = {\rm E} \left [ \eta_{\rm VZ}(\tau, t) \cdot \eta_{\rm VZ}^{\star}(\tau + \Delta \tau, t + \Delta t) \right ].\]

• But since the Dirac delta function with the time argument   $\delta(\Delta \tau)$ also has the unit  $\rm [1/s]$  the delay–time's cross power-spectral density  ${\it \Phi}_{\rm VZ}(\tau, \Delta t) $  also has the unit $\rm [1/s]$:

\[\varphi_{\rm VZ}(\Delta \tau, \Delta t) = \delta(\Delta \tau) \cdot {\it \Phi}_{\rm VZ}(\tau, \Delta t) \hspace{0.05cm}.\]

Power-spectral density of the time-variant impulse response

One obtains the   »delay's power-spectral density«   ${\it \Phi}_{\rm V}(\Delta \tau)$  by setting the second parameter of  ${\it \Phi}_{\rm VZ}(\Delta \tau, \Delta t)$  to  $\Delta t = 0$ .  The graphic on the right shows an exemplary curve.

The delay's power-spectral density is a central quantity for the description of the mobile communications channel.  This has the following characteristics:

• ${\it \Phi}_{\rm V}(\Delta \tau_0)$  is a measure for the "power" of those signal components which are delayed by  $\tau_0$ .  For this purpose, an implicit averaging over all Doppler frequencies  $(f_{\rm D})$  is carried out.
  

• The delay's power-spectral density  ${\it \Phi}_{\rm V}(\Delta \tau)$  has, like  ${\it \Phi}_{\rm VZ}(\Delta \tau, \Delta t)$ , the unit  $\rm [1/s]$.   It characterizes the power distribution over all possible delays  $\tau$.
  

• In the graphic, the power  $ P_0 \approx {\it \Phi}_{\rm V}(\Delta \tau_0)\cdot \Delta \tau$  of those signal components that arrive at the receiver via any path with a delay between  $\tau_0 \pm \Delta \tau/2$. 
  

• Normalizing the power-spectral density  ${\it \Phi}_{\rm V}(\Delta \tau)$  in such a way that the area is  $1$  results in the probability density function  $\rm (PDF)$ of the delay time:

\[{\rm PDF}_{\rm V}(\tau) = \frac{{\it \Phi}_{\rm V}(\tau)}{\int_{0 }^{\infty}{\it \Phi}_{\rm V}(\tau)\hspace{0.15cm}{\rm d}\tau} \hspace{0.05cm}.\]

Note on nomenclature:

• In the book  "Stochastic Signal Theory"  we would have denoted this  $\text{probability density function}$  with $f_\tau(\tau)$.
• To make the relation between  ${\it \Phi}_{\rm V}(\Delta \tau)$  and the PDF clear and to avoid confusion with the frequency $f$  we use the nomenclature given here.
  

ACF and PSD of the frequency-variant transfer function

The system function   $\eta_{\rm FD}(f, f_{\rm D})$  described in the  "overview in the first section of this chapter"  is also known as the  "Frequency-variant Transfer Function"  where the adjective  "frequency-variant"  refers to the Doppler frequency $f_{\rm D}$.

The associated auto-correlation function  $\rm (ACF)$  is defined as follows:

\[\varphi_{\rm FD}(f_1, f_{\rm D_1}, f_2, f_{\rm D_2}) = {\rm E} \left [ \eta_{\rm FD}(f_1, f_{\rm D_1}) \cdot \eta_{\rm FZ}^{\star}(f_2, f_{\rm D_2}) \right ]\hspace{0.05cm}. \]

By similar considerations as in the  "previous section"  this auto-correlation function can be represented under GWSSUS conditions as follows

\[\varphi_{\rm FD}(\Delta f, \Delta f_{\rm D}) = \delta(\Delta f_{\rm D}) \cdot {\it \Phi}_{\rm FD}(\Delta f, f_{\rm D}) \hspace{0.05cm}.\]

The following applies:

• ${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})$  is the so-called  »frequency–Doppler's cross power-spectral density«, which is highlighted in the graphic by a yellow background.
  

• The first argument  $\Delta f = f_2 - f_1$  takes into account that ACF and PSD depend only on the frequency difference due to the  "stationarity" .

• The factor  $\delta (\Delta f_{\rm D})$  with  $\Delta f_{\rm D} = f_{\rm D_2} - f_{\rm D_1}$  expresses the  "uncorrelation of the PSD"  with respect to the Doppler shift.
  

• You get from  ${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})$  to  »Doppler's power-spectral density«   ${\it \Phi}_{\rm D}(f_{\rm D})$  if you set  $\Delta f= 0$. 

• The Doppler's power-spectral density  ${\it \Phi}_{\rm D}(f_{\rm D})$  indicates the power with which individual Doppler frequencies occur.
  

• The  probability density function  $\rm (PDF)$  of the Doppler frequency is obtained from  ${\it \Phi}_{\rm D}(f_{\rm D})$  by suitable normalization.   The PDF has like  ${\it \Phi}_{\rm D}(f_{\rm D})$  the unit  $\rm [1/Hz]$. 

\[{\rm PDF}_{\rm D}(f_{\rm D}) = \frac{{\it \Phi}_{\rm D}(f_{\rm D})}{\int_{-\infty }^{+\infty}{\it \Phi}_{\rm D}(f_{\rm D})\hspace{0.15cm}{\rm d}f_{\rm D}} \hspace{0.05cm}.\]

• Often, for example for a vertical monopulse antenna in an isotropically scattered field, the  ${\it \Phi}_{\rm D}(f_{\rm D})$  is given by the  $\text{Jakes spectrum}$ .
  

The frequency–Doppler's cross power-spectral density  ${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})$  is highlighted in yellow.  The Fourier connections to the neighboring GWSSUS system description functions  ${\it \Phi}_{\rm VD}(\tau, f_{\rm D})$  and  ${\it \varphi}_{\rm FZ}(\Delta f, \Delta t)$ are also marked.

We refer here to the interactive applet  "The Doppler Effect".

ACF and PSD of the delay-Doppler function

The system function shown in the  "overview in the first section of this chapter"  on the left hand side was named  $\eta_{\rm VD}(\tau, f_{\rm D})$ .  

The auto-correlation function  $\rm (ACF)$  of this delay–Doppler function can be written with  $\Delta \tau = \tau_2 - \tau_1$  and  $\Delta f_{\rm D} = f_{\rm D2} - f_{\rm D1}$  taking into account the GWSSUS properties with  $\Delta \tau = \tau_2 - \tau_1$  and  $\Delta f_{\rm D} = f_{\rm D2} - f_{\rm D1}$  as follows

\[\varphi_{\rm VD}(\tau_1, f_{\rm D_1}, \tau_2, f_{\rm D_2}) = \varphi_{\rm VD}(\Delta \tau, \Delta f_{\rm D}) = \delta(\Delta \tau) \cdot {\rm \delta}(\Delta f_{\rm D}) \cdot {\it \Phi}_{\rm VD}(\tau, f_{\rm D}) \hspace{0.05cm}.\]

It should be noted about this equation:

• The first Dirac delta function  $\delta (\Delta \tau)$  takes into account that the delays are uncorrelated  ("Uncorrelated Scattering").

• The second Dirac delta function  $\delta (\Delta f_{\rm D})$  follows from the stationarity  ("Wide Sense Stationary").
  

• The delay–Doppler's power-spectral density  ${\it \Phi}_{\rm VD}(\tau, f_{\rm D})$ , also called  »Scatter Function«  can be calculated from  ${\it \Phi}_{\rm VZ}(\tau, \Delta t)$  or ${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})$  as follows:

\[{\it \Phi}_{\rm VD}(\tau, f_{\rm D}) ={\rm F}_{\Delta t} \big [ {\it \Phi}_{\rm VZ}(\tau, \Delta t) \big ] = \int_{-\infty}^{+\infty} {\it \Phi}_{\rm VZ}(\tau, \Delta t) \cdot {\rm e}^{- {\rm j}\hspace{0.05cm}\cdot \hspace{0.05cm}2 \pi \hspace{0.05cm}\cdot \hspace{0.05cm}f_{\rm D} \hspace{0.05cm}\cdot \hspace{0.05cm}\Delta t}\hspace{0.15cm}{\rm d}\Delta t \hspace{0.05cm},\]

\[{\it \Phi}_{\rm VD}(\tau, f_{\rm D}) = {\rm F}_{f_{\rm D}}^{-1} \big [ {\it \Phi}_{\rm FD}(\Delta f, f_{\rm D}) \big ] = \int_{-\infty}^{+\infty} {\it \Phi}_{\rm FD}(\Delta f, f_{\rm D}) \cdot {\rm e}^{+{\rm j}\hspace{0.05cm}\cdot \hspace{0.05cm} 2 \pi \hspace{0.05cm}\cdot \hspace{0.05cm} \tau \hspace{0.05cm}\cdot \hspace{0.05cm} \Delta f}\hspace{0.15cm}{\rm d}\Delta f \hspace{0.05cm}. \]

• Both, the system function  $\eta_{\rm VD}(\tau, f_{\rm D})$  and the derived functions  $\varphi _{\rm VD}(\Delta \tau, \Delta f_{\rm D})$  and  ${\it \Phi}_{\rm VD}(\tau, f_{\rm D})$,  are dimensionless.   For more information on this,  see the specification for  "Exercise 2.6".

• Furthermore, if the GWSSUS requirements are met, the scatter function is equal to the product of the delay's and Doppler's PSDs:

\[{\it \Phi}_{\rm VD}(\tau, f_{\rm D}) = {\it \Phi}_{\rm V}(\tau) \cdot {\it \Phi}_{\rm D}(f_{\rm D})\hspace{0.05cm}.\]

ACF and PSD of the time-variant transfer function

The following diagram shows all the relationships between the individual power-spectral densities once again in compact form.

This has already been discussed in the last sections:

• the  $\text{delay–time's cross-power-spectral density}$:

$${\it \Phi}_{\rm VZ}(\tau, \Delta t)\hspace{0.55cm}\Rightarrow \hspace{0.3cm}\text{with} \hspace{0.2cm}\Delta t = 0\text{:} \hspace{0.2cm} {\it \Phi}_{\rm V}(\tau),$$

• the  $\text{frequency–Doppler's cross-power-spectral density}$:

$${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})\hspace{0.3cm}\Rightarrow \hspace{0.3cm}\text{with} \hspace{0.2cm}\Delta f = 0\text{:} \hspace{0.2cm} {\it \Phi}_{\rm D}( f_{\rm D}),$$

• the  $\text{delay–Doppler's cross-power-spectral density}$ :

$${\it \Phi}_{\rm VD}(\tau, f_{\rm D})= {\it \Phi}_{\rm V}(\tau) \cdot {\it \Phi}_{\rm D}(f_{\rm D})\hspace{0.05cm}.$$

The  »frequency–time's correlation function«  (marked yellow in the adjacent graph)  has not yet been considered:

\[\varphi_{\rm FZ}(f_1, t_1, f_2, t_2) = {\rm E} \left [ \eta_{\rm FZ}(f_1, t_1) \cdot \eta_{\rm FZ}^{\star}(f_2, t_2) \right ]\hspace{0.05cm}.\]

Considering again the GWSSUS simplifications and the identity  $\eta_{\rm FZ}(f, \hspace{0.05cm}t) \equiv H(f, \hspace{0.05cm}t)$, the ACF can be also written with  $\Delta f = f_2 - f_1$  and  $\Delta t = t_2 - t_1$  as follows:

\[\varphi_{\rm FZ}(f_1, t_1, f_2, t_2) \hspace{0.3cm} \Rightarrow \hspace{0.3cm}\varphi_{\rm FZ}(\Delta f, \Delta t) = {\rm E} \big [ H(f, t) \cdot H^{\star}(f + \Delta f, t + \Delta t) \big ]\hspace{0.05cm}.\]

It should be noted in this respect:

• You already can see from the name that  $\varphi_{\rm FZ}(\Delta f, \Delta t)$  is a correlation function and not a PSD like the functions  ${\it \Phi}_{\rm VZ}(\tau, \Delta t)$,  ${\it \Phi}_{\rm FD}(\Delta f, f_{\rm D})$  and  ${\it \Phi}_{\rm VD}(\tau, f_{\rm D})$.
  

• The Fourier relationships with the neighboring functions are:

\[{\it \Phi}_{\rm VZ}(\tau, \Delta t) \hspace{0.2cm} \stackrel{\tau, \hspace{0.05cm}\Delta f}{\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet} \hspace{0.2cm} \varphi_{\rm FZ}(\Delta f, \hspace{0.05cm}\Delta t) \hspace{0.2cm} \stackrel{\Delta t,\hspace{0.05cm} f_{\rm D}}{\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet} \hspace{0.2cm} {\it \Phi}_{\rm FD}(\Delta f,\hspace{0.05cm} f_{\rm D}) \hspace{0.05cm}.\]

• If you set the parameters  $\Delta t = 0$  or  $\Delta f = 0$  in this two–dimensional function, the separate correlation functions for the frequency domain or the time domain result:

$$\varphi_{\rm F}(\Delta f) = \varphi_{\rm FZ}(\Delta f, \Delta t = 0) \hspace{0.05cm},\hspace{0.5cm} \varphi_{\rm Z}(\Delta t) = \varphi_{\rm FZ}(\Delta f = 0, \Delta t ) \hspace{0.05cm}.$$

• From the graph it is also clear that these correlation functions correspond to the derived power-spectral densities via the Fourier transform:

\[\varphi_{\rm F}(\Delta f) \hspace{0.2cm} {\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} {\it \Phi}_{\rm V}(\tau)\hspace{0.05cm}, \hspace{0.4cm}\varphi_{\rm Z}(\Delta t) \hspace{0.2cm} {\circ\!\!-\!\!\!-\!\!\!-\!\!\bullet} \hspace{0.2cm} {\it \Phi}_{\rm D}(f_{\rm D})\hspace{0.05cm}.\]

Parameters of the GWSSUS model

According to the results in the last section, the mobile channel is replaced by

• the delay's power-spectral density  ${\it \Phi}_{\rm V}(\tau)$  and
  

• the Doppler's power-spectral density  ${\it \Phi}_{\rm D}(f_{\rm D})$.
  
  

By suitable normalization to the respective area  $1$  the density functions result with respect to the delay time  $\tau$  or the Doppler frequency $f_{\rm D}$.

Characteristic values can be derived from the power-spectral densities or the corresponding correlation functions.  The most important ones are listed here:

Let us now consider the time variance characteristics derived from the time correlation function  $\varphi_{\rm Z}(\Delta t)$  or from the Doppler's power-spectral density  ${\it \Phi}_{\rm D}(f_{\rm D})$ :

Simulation according to the GWSSUS model

The  »Monte–Carlo method«,  here described for the simulation of a GWSSUS mobile communication channel, is based on work by Rice  [Ric44]^[1]  and  Höher [Höh90]^[2].

• The two–dimensional impulse response is represented by a sum of  $M$  complex exponential functions.  $M$  can be interpreted as the number of different paths:

\[h(\tau,\ t)= \frac{1}{\sqrt {M}} \cdot \sum_{m=1}^{M} \alpha_m \cdot \delta (t - \tau_m) \cdot {\rm e}^{{\rm j} \hspace{0.05cm} \phi_{m} }\cdot {\rm e}^{ {\rm j} \hspace{0.05cm}2 \pi f_{{\rm D},\hspace{0.05cm} m} t} \hspace{0.05cm}. \]

• First, the delays  $\tau_m$,  the attenuation factors  $\alpha_m$,  the equally distributed phases  $\phi_m$  and the Doppler frequencies  $f_{{\rm D},\hspace{0.1cm} m}$  will be randomly generated according to the GWSSUS specifications.  The base for the random generation of the Doppler frequencies  $f_{{\rm D},\hspace{0.1cm} m}$  is the  $\text{Jakes spectrum}$  ${\it \Phi}_{\rm D}(f_{\rm D})$, which, appropiately normalized, simultaneously indicates the probability density function  $\rm (PDF)$  of the Doppler frequencies.
  

• Because of  ${\it \Phi}_{\rm VD}(\tau, f_{\rm D}) = {\it \Phi}_{\rm V}(\tau) \cdot {\it \Phi}_{\rm D}(f_{\rm D})$  the delay time  $\tau_m$  is independent of the Doppler frequency  $f_{{\rm D},\hspace{0.1cm} m}$  for all  $m$.  This is valid with good approximation for terrestrial land mobile communication.  For the random generation of the parameters  $\alpha_m$  and  $\tau_m$,  which determine the delay–power-spectral density  $ {\it \Phi}_{\rm V}(\tau)$  the following  $\text{COST profiles}$  are available:   $\rm RA$  ("Rural Area"),  $\rm TU$  ("Typical Urban"),  $\rm BU$  ("Bad Urban")  and  $\rm HT$  ("Hilly Terrain").
  

• The greater the number of different paths   $M$  is chosen for the simulation, the better a real impulse response is approximated by the above equation.  However, the higher accuracy of the simulation is at the expense of its duration.  In the literature, favorable values are given for $M$  between  $100$  and  $600$ .
  

Exercises for the chapter

Exercise 2.5: Scatter Function

Exercise 2.5Z: Multi-Path Scenario

Exercise 2.6: Dimensions in GWSSUS

Exercise 2.7: Coherence Bandwidth

Exercise 2.7Z: Coherence Bandwidth of the LTI Two-Path Channel

Exercise 2.8: COST Delay Models

Exercise 2.9: Coherence Time

References