Difference between revisions of "Mobile Communications/Statistical Bindings within the Rayleigh Process"

Some general remarks on ACF and PSD

The  $r(t)$  and  $r(t+ \Delta t)$  is suitable for describing the inner statistical bonds between the neighboring signal values Autocorrelation Function  $\rm (ACF)$:

\[\varphi_r ({\rm \Delta}t) = {1}/{2} \cdot {\rm E}\big [ r(t) \cdot r^{\star}(t + {\rm \Delta}t)\big ] \hspace{0.05cm}.\]

Compared to the definition under the link above, the following differences can be seen:

• The ACF–variable is here marked with  $\Delta t$  instead of  $\tau$  because in this book we need the „$\tau$” still for the 2D–impulse response  $h(t, \hspace{0.05cm}\tau)$ .
  

• The equivalent low pass–signal  $r(t)$  is complex.   By the factor  $1/2$  however, the AKF  $\varphi_r ({\rm \Delta}t)$  and especially the power  $\varphi_r ({\rm \Delta}t = 0)$  refers to the (real) bandpass–Signal  $r_{\rm BP}(t)$.
  
  

Applying  Rayleigh–Fading–Channel model   $r(t) = s(t) \cdot z(t)$.  This results for its ACF:

\[\varphi_r ({\rm \Delta}t) = {1}/{2} \cdot {\rm E}\big [ s(t) \cdot z(t) \cdot s^{\star}(t + {\rm \Delta}t) \cdot z^{\star}(t + {\rm \Delta}t)\big ] = \varphi_s ({\rm \Delta}t) \cdot \varphi_z ({\rm \Delta}t)\hspace{0.05cm}.\]

For the ACF of the transmitted signal  $s(t)$  and multiplicative factor  $z(t)$  the following definitions apply:

\[ \varphi_s ({\rm \Delta}t)= {1}/{2} \cdot {\rm E}\big [ s(t) \cdot s^{\star}(t + {\rm \Delta}t)\big ] \hspace{0.05cm},\]

\[\varphi_z ({\rm \Delta}t) = {\rm E}\big [ z(t) \cdot z^{\star}(t + {\rm \Delta}t)\big ]\hspace{0.05cm}.\]

The factor  $1/2$  is only to be considered for the ACF calculation of bandpass signals in the equivalent lowpass range, but not for  $\varphi_z ({\rm \Delta}t)$.   Otherwise  $\varphi_r ({\rm \Delta}t) \ne \varphi_s ({\rm \Delta}t) \cdot \varphi_z ({\rm \Delta}t)$  would result in  $\varphi_r ({\rm \Delta}t) $ 

Based on the definition of  $\varphi_z ({\rm \Delta}t) = {\rm E}\big [ z(t) \cdot z^{\star}(t + {\rm \Delta}t)\big ]$  the ACF is always real even with a complex time function  $z(t)$  and also with respect to  $ {\rm \Delta}t$  even.   Let us further consider that

• $z(t) = x(t) + {\rm j} \cdot y(t) $ ,
  

• $x(t)$ and $y(t)$  have the same statistical properties, and
  

• that no statistical bonds exist between  $x(t)$  and  $y(t)$  ,
  
  

so can the ACF of the complex factor  $z(t)$  be written as it follows:

\[\varphi_z ({\rm \Delta}t) = \varphi_x ({\rm \Delta}t) + \varphi_y ({\rm \Delta}t) = 2 \cdot \varphi_x ({\rm \Delta}t) \hspace{0.05cm}.\]

This effect is explained on the next page.

Phenomenological description of the Doppler effect

The statistical bonds within the real "signals"  $x(t)$  and  $y(t)$  or within the complex quantity  $z(t)$  are due to the Doppler effect.  This was predicted theoretically in the middle of the 19th century by the Austrian mathematician, physicist and astronomer  Christian Andreas Doppler  and named after him.

Qualitatively, the Doppler effect can be described as follows:

• If the observer and source approach each other, the frequency increases from the observer's point of view, regardless of whether the observer is moving or the source or both.

• If the source moves away from the observer or the observer moves away from the source, the observer perceives a lower frequency than that actually transmitted.
  
  

In this learning tutorial you can illustrate the subject matter with the interactive applet  To Clarify the Doppler effect .

Ausgangslage:  $\rm (S)$  and  $\rm (E)$  are not moving

Dopplereffekt: $\rm (S)$ moves towards resting $\rm (E)$

$\text{Example 3:}$  The next snapshot shows the case where the transmitter  $\rm (S)$  has moved at constant speed  $v$  from its starting point  $\rm (S_0)$  towards the receiver  $\rm (E)$ 

• The right diagram shows that the frequency  $f_{\rm E}$  (blue oscillation) perceived by the receiver is larger by about  $20\%$  than the frequency  $f_{\rm S}$  at the transmitter (red oscillation).
• Due to the movement of the transmitter, the circles are no longer concentric.

Dopplereffekt: $\rm (S)$ moves away from the resting $\rm (E)$

• The scenario shown on the left results when the transmitter  $\rm (S)$  moves away from the receiver  $\rm (E)$    Then the received frequency  $f_{\rm E}$  (blue oscillation) is about  $20\%$  smaller than the transmitted frequency  $f_{\rm S}$.
  

Doppler frequency and its distribution

We summarize the statements of the last page again briefly, whereby we start from the second, i.e. the non–relativistic equation:

• A relative movement between transmitter (source) and receiver (observer) results in a shift by the Doppler frequency  $f_{\rm D} = f_{\rm E} - f_{\rm S}$.

• A positive Doppler frequency  $(f_{\rm E} > f_{\rm S})$  results when transmitter and receiver  (relative)  move towards each other.  A negative Doppler frequency  $(f_{\rm E} < f_{\rm S})$  means that transmitter and receiver  (directly or at an angle)  move away from each other.
  

• The maximum frequency shift occurs when transmitter and receiver move directly towards each other   ⇒   angle  $\alpha = 0^\circ$.   This maximum value depends first approximation on the transmission frequency  $ f_{\rm S}$  and the speed  $v$  depends   $(c = 3 \cdot 10^8 \, {\rm m/s}$  indicates the speed of light$)$:

\[f_{\rm D, \hspace{0.05cm} max} = f_{\rm S} \cdot {v}/{c} \hspace{0.05cm}.\]

• If the relative movement takes place at any angle  $\alpha$  to the connecting line transmitter–receiver, a Doppler shift of

\[f_{\rm D} = f_{\rm E} - f_{\rm S} = f_{\rm D, \hspace{0.05cm} max} \cdot \cos(\alpha) \hspace{0.3cm} \Rightarrow \hspace{0.3cm} - \hspace{-0.05cm}f_{\rm D, \hspace{0.05cm} max} \le f_{\rm D} \le + \hspace{-0.05cm}f_{\rm D, \hspace{0.05cm} max} \hspace{0.05cm}.\]

$\text{Conclusion:}$  Assuming equal probable directions of motion  $($Equal distribution for the angle  $\alpha$  in the range  $- \pi \le \alpha \le +\pi)$  the probability density function  $($here denoted with "wdf" (from the german WahrscheinlichkeitsDichteFunktion)$)$  the Doppler frequency in the range  $- f_\text{D, max} \le f_{\rm D} \le + f_\text{D, max}$:

\[{\rm wdf}(f_{\rm D}) = \frac{1}{2\pi \cdot f_{\rm D, \hspace{0.05cm} max} \cdot \sqrt {1 - (f_{\rm D}/f_{\rm D, \hspace{0.05cm} max})^2 } } \hspace{0.05cm}.\]

Outside the range between  $-f_{\rm D}$  and  $+f_{\rm D}$  the probability density function always has the value zero.

$\text{Derivation:}$  The resulting Doppler frequency depending on the angle of movement  $\alpha$  is

To calculate the probability density function of the Doppler frequency

\[f_{\rm D} = f_{\rm D, \hspace{0.05cm} max} \cdot \cos(\alpha) = g(\alpha) \hspace{0.05cm}.\]

We refer to this function as  $g(\alpha)$  and assume that

• $\alpha$  takes all angle values between  $\pm \pi$ 
• with equal probability   ⇒   equal distribution.&nbsp

Then for the probability of the Doppler frequency according to the chapter  Transformation of Random Variables  in the book "Stochastic Signal Theory":

\[{\rm wdf}(f_{\rm D})=\frac{ {\rm wdf}(\alpha)}{\vert g\hspace{0.08cm}'(\alpha)\vert}\Bigg \vert_{\hspace{0.1cm} \alpha=h(f_{\rm D})} \hspace{0.05cm}\]

• the derivative  $g\hspace{0.08cm}'(\alpha)= - f_\text{D, max} \cdot \sin(\alpha)$, and
• the inverse function  $ \alpha = h(f_{\rm D})$.

In the example the inverse function is

$$ \alpha = \arccos(f_{\rm D}/f_{\rm D, \hspace{0.05cm} max}).$$

The diagram illustrates the calculation procedure for determining the Doppler frequency's PDF:

• Since the characteristic curve between the Doppler frequency  $f_{\rm D}$  and the angle  $\alpha$   ⇒   $ g(\alpha) = f_{\rm D, \hspace{0.05cm} max} \cdot \cos(\alpha)$  is limited by the value  $f_{\rm D, \hspace{0.05cm} max}$  is for  $f_{\rm D}$  no value outside this range possible.
  

• When transforming random variables, a distinction must be made between areas with positive and negative slopes of the transformation's characteristic curve.   The  $\alpha$–values between  $-\pi$  and  $0$   $($positive gradient of the transformation characteristic $)$between the Doppler frequency  $f_{\rm D}$  and the angle  $\alpha$  provide the result

\[{\rm wdf}(f_{\rm D})=\frac{1/(2\pi)}{f_{\rm D, \hspace{0.05cm} max} \cdot \sin(\alpha)} \Bigg \vert_{\hspace{0.1cm} \alpha=\arccos(f_{\rm D}/f_{\rm D, \hspace{0.05cm} max})} = \frac{(2\pi \cdot f_{\rm D, \hspace{0.05cm} max} )^{-1} }{ \sin(\arccos(f_{\rm D}/f_{\rm D, \hspace{0.05cm} max}))} = \frac{1}{2\pi \cdot f_{\rm D, \hspace{0.05cm} max} \cdot \sqrt { 1 - (f_{\rm D}/f_{\rm D, \hspace{0.05cm} max})^2 } } \hspace{0.05cm}.\]

• For reasons of symmetry, the positive  $\alpha$–area contributes in the same way, so that the inner total area is:

\[{\rm wdf}(f_{\rm D}) = \frac{1}{\pi \cdot f_{\rm D, \hspace{0.05cm} max} \cdot \sqrt { 1 - (f_{\rm D}/f_{\rm D, \hspace{0.05cm} max})^2 } } \hspace{0.05cm}.\]

• If   $\alpha$  takes values around  $\pm \pi/2$  it results in a small Doppler frequency   ⇒   $f_{\rm D} \approx 0$   $($violet marking$)$.  But, because of the relatively large gradient of the cosine curve   $g(\alpha)$  at  $\alpha = \pm \pi/2$   the PDF–value at  $f_{\rm D} \approx 0$  ist very small.
  

• Small angles   $($um  $\alpha \approx 0)$   however, lead to the maximum Doppler frequency   ⇒   $f_{\rm D} \approx f_{\rm D, \hspace{0.05cm} max}$   $($red marker$)$.  Because of the nearly horizontal characteristic curve  $g(\alpha)$  the  $f_{\rm D}$–PDF is clearly larger here.  For  $f_{\rm D} \equiv f_{\rm D, \hspace{0.05cm} max}$  this even results in an infinitely large value.
  

• On the other hand, if   $\alpha$  takes values around  $\pm \pi$  it leads to the Doppler frequency  $f_{\rm D} \approx -f_{\rm D, \hspace{0.05cm} max}$   $($green marker$)$.  Again the characteristic curve is nearly horizontal and again it results in a large PDF–value.

ACF und PSD with Rayleigh–Fading

We now assume an antenna with the same radiation in all directions; the Doppler–PSD is then identical in shape to the PDF of the Doppler frequencies.

For  ${\it \Phi}_x(f_{\rm D})$  the PDF must still be multiplied by the power  $\sigma^2$  of the Gaussian process, and the resulting PSD  ${\it \Phi}_z(f_{\rm D})$  of the complex factor  $z(t) = x(t) + {\rm j} \cdot y(t) $  can be written after doubling as:

\[{\it \Phi}_z(f_{\rm D}) = \left\{ \begin{array}{c} (2\sigma^2)/( \pi \cdot f_{\rm D, \hspace{0.05cm} max}) \cdot \left [ 1 - (f_{\rm D}/f_{\rm D, \hspace{0.05cm} max})^2 \right ]^{-0.5} \\ 0 \end{array} \right.\quad \begin{array}{*{1}c} {\rm f\ddot{u}r}\hspace{0.15cm} |f_{\rm D}| \le f_{\rm D, \hspace{0.05cm} max} \\ {\rm sonst} \\ \end{array} \hspace{0.05cm}.\]

This process is named after  William C. Jakes Jr.  the  Jakes–Spectrum.  The doubling is necessary, because up to now only the contribution of the real part  $x(t)$  was considered.

The corresponding autocorrelation function (ACF) is obtained after a   Fourier inverse transformation:

\[\varphi_z ({\rm \Delta}t) = 2 \sigma^2 \cdot {\rm J_0}(2\pi \cdot f_{\rm D, \hspace{0.05cm} max} \cdot {\rm \Delta}t)\hspace{0.05cm},\]

with the  Bessel function of first kind and zero order  (first equation:  definition,  second equation:  series expansion):

\[{\rm J }_0 (u) = \frac{1}{ 2\pi} \cdot \int_{0}^{2\pi} {\rm e }^{- {\rm j }\hspace{0.03cm}\cdot \hspace{0.03cm}u \hspace{0.03cm}\cdot \hspace{0.03cm}\cos(\alpha)} \,{\rm d} \alpha \hspace{0.2cm} = \hspace{0.2cm} \sum_{k = 0}^{\infty} \frac{(-1)^k \cdot (u/2)^{2k}}{k! \cdot \Gamma (k+1)} \hspace{0.05cm}.\]

The numerical values of this function can be obtained with the  applet of the same name.

Doppler-PSD and time function (magnitude in dB) for Rayleigh fading with Doppler effect

The right picture shows the logarithmic absolute value of  $z(t)$:

• You can see that the red curve fades twice as fast.
• The Rayleigh–PDF (amplitude distribution) is independent of  $f_{\rm D, \hspace{0.05cm} max}$  and therefore the same for both cases.}}
  

Excercises to the chapter

Excercise 1.4: Rayleigh–PDF and Jakes–SD

Excercise 1.4Z: On the Doppler effect

Excercise 1.5: Reproduction of the Jakes spectrum