Difference between revisions of "Aufgaben:Exercise 2.2: Binary Bipolar Rectangles"
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:$$\varphi_s(\tau) = \sum_{\lambda = -\infty}^{+\infty}{1}/{T} \cdot \varphi_a(\lambda)\cdot \varphi^{^{\bullet}}_{g_s}(\tau - \lambda \cdot T)\hspace{0.05cm}.$$ | :$$\varphi_s(\tau) = \sum_{\lambda = -\infty}^{+\infty}{1}/{T} \cdot \varphi_a(\lambda)\cdot \varphi^{^{\bullet}}_{g_s}(\tau - \lambda \cdot T)\hspace{0.05cm}.$$ | ||
*The power-spectral density ${\it \Phi}_{s}(f)$ is the Fourier transform of the ACF $\varphi_{s}(\tau)$. | *The power-spectral density ${\it \Phi}_{s}(f)$ is the Fourier transform of the ACF $\varphi_{s}(\tau)$. | ||
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Revision as of 17:35, 13 May 2022
We assume the following signal:
- $$s(t) = \sum_{\nu = -\infty}^{+\infty} a_\nu \cdot g_s ( t - \nu \cdot T) \hspace{0.05cm}.$$
The basic transmission pulse $g_{s}(t)$ is always assumed to be rectangular in this exercise, with the NRZ format (blue signal curves in the graph) as well as the RZ format with duty cycle $T_{\rm S}/T = 0.5$ (red signal curves) to be investigated.
The amplitude coefficients have the following properties:
- They are binary and bipolar: $a_{\nu} \in \{–1, +1\}$.
- The symbols within the sequence $\langle a_{\nu }\rangle$ have no statistical ties.
- The probabilities for the two possible values $±1$ are with $0 < p < 1$:
- $${\rm Pr}(a_\nu = +1) \ = \ p,$$
- $${\rm Pr}(a_\nu = -1) \ = \ 1 - p \hspace{0.05cm}.$$
The three signal sections shown in the graph are valid for $p = 0.75$, $p = 0.50$ and $p = 0.25$.
Throughout this exercise, reference is made to the following descriptive quantities:
- $m_{a} = \E\big[a_{\nu}\big]$ indicates the linear mean (first order moment) of the amplitude coefficients.
- $m_{2a} = \E\big[a_{\nu}^{2}\big]$ is the power (second order moment).
- Thus, the variance $\sigma_{a}^{2} = m_{2a} - m_{a}^{2}$ can also be calculated.
- The discrete ACF of the amplitude coefficients is $\varphi_{a}(\lambda) = \E\big[a_{\nu} \cdot a_{\nu + \lambda} \big]$. It holds here:
- $$\varphi_a(\lambda) = \left\{ \begin{array}{c} m_2 \\ m_1^2 \\ \end{array} \right.\quad \begin{array}{*{1}c} {\rm{for}}\\ {\rm{for}} \\ \end{array} \begin{array}{*{20}c}\lambda = 0, \\ \lambda \ne 0 \hspace{0.05cm}.\\ \end{array}$$
- The energy ACF of the basic transmission pulse is:
- $$\varphi^{^{\bullet}}_{g_s}(\tau) = \left\{ \begin{array}{c} s_0^2 \cdot T_{\rm S} \cdot \left( 1 - {|\tau|}/{T_{\rm S}}\right) \\ 0 \\ \end{array} \right.\quad \begin{array}{*{1}c} {\rm{for}}\\ {\rm{for}} \\ \end{array} \begin{array}{*{20}c}|\tau| \le T_{\rm S} \\ |\tau| \ge T_{\rm S} \hspace{0.05cm}.\\ \end{array}$$
- Thus, for the total ACF of the transmitted signal, we obtain:
- $$\varphi_s(\tau) = \sum_{\lambda = -\infty}^{+\infty}{1}/{T} \cdot \varphi_a(\lambda)\cdot \varphi^{^{\bullet}}_{g_s}(\tau - \lambda \cdot T)\hspace{0.05cm}.$$
- The power-spectral density ${\it \Phi}_{s}(f)$ is the Fourier transform of the ACF $\varphi_{s}(\tau)$.
Note: The exercise belongs to the chapter "Basics of Coded Transmission".
Questions
Solution
- the amplitude coefficients do not depend on each other (this was assumed here),
- all possible amplitude coefficients are equally probable.
In this sense, $s_{0.5}(t)$ is a redundancy-free signal ⇒ solution 2.
- Thus, here the entropy (the average information content per transmitted binary symbol) is at most equal to the decision content:
- $$H_{\rm max} = {1}/{2}\cdot {\rm log}_2 (2)+{1}/{2}\cdot {\rm log}_2 (2) = 1 \,\,{\rm bit/binary symbol} \hspace{0.05cm}.$$
- In contrast, the entropies of the other two binary signals are:
- $$H = \ \frac{3}{4}\cdot {\rm log}_2 (\frac{4}{3})+ \frac{1}{4}\cdot {\rm log}_2 (4) = \left( \frac{3}{4} + \frac{1}{4}\right)\cdot {\rm log}_2 (4) - \frac{3}{4}\cdot{\rm log}_2 (3) =$$
- $$ \hspace{0.5cm} = \ 2 - \frac{3}{4}\cdot{\rm log}_2 (3) = 0.811 \,\,{\rm bit/binary symbol} \hspace{0.05cm}.$$
- From this, the relative redundancy of these signals is:
- $$r = \frac{H_{\rm max} - H}{H_{\rm max}}\hspace{0.15cm} \approx 18.9\%\hspace{0.05cm}.$$
(2) The quadratic mean is equal to $m_{2a} = 1$ independent of $p$:
- $$m_{2a}={\rm E}[a_\nu^2] = p \cdot (+1)^2 + (1-p)\cdot (-1)^2 \hspace{0.15cm}\underline { = 1 \hspace{0.05cm}}.$$
(3) For the linear mean value we get
- $$m_{a}={\rm E}[a_\nu] = p \cdot (+1) + (1-p)\cdot (-1) = 2 p -1 \hspace{0.05cm}.$$
- $$\Rightarrow \hspace{0.3cm} p = 0.75\text{:} \hspace{0.4cm} m_{a}\hspace{0.15cm}\underline {=0.50},\hspace{0.2cm} p = 0.50\text{:} \hspace{0.4cm} m_{a}\hspace{0.15cm}\underline {=0},\hspace{0.2cm} p = 0.25\text{:} \hspace{0.4cm} m_{a}\hspace{0.15cm}\underline { =-0.50 \hspace{0.05cm}}.$$
(4) Using the results from (2) and (4), we obtain:
- $$p = 0.75\text{:} \hspace{0.4cm} \sigma_{a}^2 \hspace{0.15cm}\underline {=0.75},$$
- $$ p = 0.50\text{:} \hspace{0.4cm} \sigma_{a}^2\hspace{0.15cm} \underline { =1.00 \hspace{0.05cm}},$$
- $$ p = 0.25\text{:} \hspace{0.4cm} \sigma_{a}^2 \hspace{0.15cm}\underline {=0.75}.$$
(5) Only the first two statements are correct:
- For $p = 0.5$, $\varphi_{a}(\lambda = 0) = 1$ and $\varphi_{a}(\lambda \neq 0) = 0$. It follows that:
- $$\varphi_s(\tau) = \frac{1}{T} \cdot \varphi^{^{\bullet}}_{gs}(\tau )\hspace{0.05cm}.$$
- This results in a triangular ACF and a ${\rm si}^{2}$–shaped PSD for both the NRZ and RZ basic pulses.
- The area under the PSD is smaller by a factor of $T_{\rm S}/T$ for the RZ pulse than for the NRZ pulse, since the ACF values also differ by this factor at $\tau = 0$.
- The PSD is continuous in both cases because the ACF does not contain a DC component or periodic components.
(6) All statements except the third are correct:
- For $p = 0.75$, the ACF $\varphi_{s}(\tau)$ is composed of infinitely many triangular functions, all of which have the same height $s_{0}^{2}/4$ except for the middle triangle around $\tau = 0$.
- According to the sketch, one can combine all these triangle functions into a DC component of height $m_{a}^{2} \cdot s_{0}^{2} = s_{0}^{2}/4$ and a single triangle around $\tau = 0$ with height $\sigma_{a}^{2} \cdot s_{0}^{2} = 3/4 · s_{0}^{2}$.
- In the PSD, this leads to a continuous ${\rm si}^{2}$–shaped component and a Dirac delta function at $f = 0$. The weight of this Dirac is $s_{0}^{2}/4$.
- For $p = 0.25$ we get the same ACF as with $p = 0.75$, since both the quadratic mean $m_{2a} = 1$ and $m_{a}^{2} = 0.25$ coincide. Thus, of course, the power-spectral densities also match.
(7) Both proposed solutions are correct::
- With the RZ duty cycle $T_{\rm S}/T = 0.5$ the sketched ACF is obtained, which can also be represented by a periodic triangular function of height $s_{0}^{2}/8$ (with red filling) and a single triangular pulse of height $3/8 \cdot s_{0}^{2}$ (green filling).
- This non-periodic component leads to a continuous, ${\rm si}^{2}$–shaped PSD with zeros at multiples of $2/T$.
- The periodic triangular ACF causes Dirac delta functions in the PSD at multiples of $1/T$.
- However, due to the antimetry of the periodic component, the Dirac delta functions at multiples of $2/T$ each have weight $0$.
- The weights of the Dirac delta functions at distance $1/T$ are proportional to the continuous PSD component.