Difference between revisions of "Applets:Eye Pattern and Worst-Case Error Probability"

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==Applet Description==
 
==Applet Description==
 
<br>
 
<br>
Das Applet verdeutlicht die Augendiagramme für
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The applet illustrates the eye pattern for different encodings&nbsp;
*verschiedene Codierungen&nbsp; (binär&ndash;redundanzfrei,&nbsp; quaternär&ndash;redundanzfrei,&nbsp; pseudo&ndash;ternär:&nbsp; AMI und Duobinär)&nbsp; sowie
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* binary&nbsp; (redundancy-free),&nbsp;  
*verschiedene Empfangskonzepte&nbsp; (Matched&ndash;Filter&ndash;Empfänger,&nbsp; CRO&ndash;Nyquistsystem,&nbsp; gaußförmiges Empfangsfilter).
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*quaternary&nbsp; (redundancy-free),
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*pseudo&ndash;ternary:&nbsp; (AMI and duobinary)&nbsp;  
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and for various reception concepts&nbsp;
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*Matched Filter receiver,&nbsp;
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*CRO Nyquist system,&nbsp;
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*Gaussian low-pass filter.
  
Das letzte Empfängerkonzept führt zu Impulsinterferenzen, das heißt:&nbsp; Benachbarte Symbole beeinträchtigen sich bei der Symbolentscheidung gegenseitig.
 
  
Solche Impulsinterferenzen und deren Einfluss auf die Fehlerwahrscheinlichkeit lassen sich durch das Augendiagramm sehr einfach erfassen und quantifizieren.&nbsp; Aber auch für die beiden anderen (impulsinterferenzfreien) Systeme lassen sich anhand der Grafiken wichtige Erkenntnisse gewinnen.
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The last reception concept leads to intersymbol interference, that is:&nbsp; Neighboring symbols interfere with each other in symbol decision.  
  
Ausgegeben wird zudem die ungünstigste (&bdquo;worst case&rdquo;) Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$, die bei den binären Nyquistsystemen identisch mit der mittleren  Fehlerwahrscheinlichkeit &nbsp;$p_{\rm M}$&nbsp;  ist und für die beiden anderen Systemvarianten eine geeignete obere Schranke darstellt: &nbsp;$p_{\rm U} \ge p_{\rm M}$.
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Such intersymbol interferences and their influence on the error probability can be captured and quantified very easily by the "eye pattern".&nbsp; But also for the other two (without intersymbol interference) systems important insights can be gained from the graphs.
  
In der &nbsp;$p_{\rm U}$&ndash;Gleichung bedeuten:
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Furthermore, the most unfavorable ("worst case") error probability &nbsp;
*${\rm Q}(x)$&nbsp; ist die&nbsp; [[Stochastische_Signaltheorie/Gaußverteilte_Zufallsgrößen#.C3.9Cberschreitungswahrscheinlichkeit|Komplementäre Gaußsche Fehlerfunktion]].&nbsp; Die normierte Augenöffnung kann Werte zwischen&nbsp; $0 \le ö_{\rm norm}  \le 1$&nbsp; annehmen.
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:$$p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$$
*Der Maximalwert &nbsp;$(ö_{\rm norm} = 1)$&nbsp; gilt für die binären Nyquistsysteme und&nbsp; $ö_{\rm norm}=0$&nbsp; steht für ein &bdquo;geschlossenes Auge&rdquo;.
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*Der normierte Detektionsrauscheffektivwert&nbsp; $\sigma_{\rm norm}$&nbsp; hängt vom einstellbaren Parameter &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$&nbsp; ab, aber auch von der Codierung und vom Empfängerkonzept.   
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is output, which for binary Nyquist systems is identical to the mean error probability &nbsp;$p_{\rm M}$&nbsp; and represents a suitable upper bound for the other system variants: &nbsp;$p_{\rm U} \ge p_{\rm M}$.
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In the &nbsp;$p_{\rm U}$&ndash;equation mean:
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*${\rm Q}(x)$&nbsp; is the&nbsp; [[Applets:Complementary_Gaussian_Error_Functions|"Complementary Gaussian Error Function"]].&nbsp; The normalized eye opening can have values between&nbsp; $0 \le ö_{\rm norm}  \le 1$&nbsp; .
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*The maximum value &nbsp;$(ö_{\rm norm} = 1)$&nbsp; applies to the binary Nyquist system and&nbsp; $ö_{\rm norm}=0$&nbsp; represents a "closed eye".
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*The normalized detection noise rms value&nbsp; $\sigma_{\rm norm}$&nbsp; depends on the adjustable parameter &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$&nbsp; but also on the coding and the receiver concept.  
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==Theoretical Background==
 
==Theoretical Background==
 
<br>
 
<br>
=== Systembeschreibung und Voraussetzungen===
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<br>
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=== System description and prerequisites===
  
Für dieses Applet gilt das unten skizzierte Modell der binären Basisbandübertragung. Zunächst gelten folgende Voraussetzungen:
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The binary baseband transmission model outlined below applies to this applet. First, the following prerequisites apply:
*Die Übertragung erfolgt binär, bipolar und redundanzfrei mit der Bitrate &nbsp;$R_{\rm B} = 1/T$, wobei &nbsp;$T$&nbsp; die Symboldauer angibt.  
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*The transmission is binary, bipolar, and redundancy-free with bit rate &nbsp;$R_{\rm B} = 1/T$, where &nbsp;$T$&nbsp; is the symbol duration.
*Das Sendesignal &nbsp;$s(t)$&nbsp; ist zu allen Zeiten &nbsp;$t$&nbsp; gleich &nbsp;$ \pm s_0$ &nbsp; &rArr; &nbsp; Der Sendegrundimpuls&nbsp; $g_s(t)$&nbsp; ist NRZ&ndash;rechteckförmig mit Amplitude &nbsp;$s_0$&nbsp; und Impulsdauer &nbsp;$T$.  
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*The transmitted signal &nbsp;$s(t)$&nbsp; is equal to &nbsp;$ \pm s_0$ &nbsp; at all times &nbsp;$t$&nbsp; &rArr; &nbsp; The basic transmission pulse&nbsp; $g_s(t)$&nbsp; is NRZ&ndash;rectangular with amplitude &nbsp;$s_0$&nbsp; and pulse duration &nbsp;$T$.  
  
*Das Empfangssignal sei &nbsp;$r(t) = s(t) + n(t)$, wobei der AWGN&ndash;Term &nbsp;$n(t)$&nbsp; durch die (einseitige) Rauschleistungsdichte &nbsp;$N_0$&nbsp; gekennzeichnet ist.
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*Let the received signal be &nbsp;$r(t) = s(t) + n(t)$, where the AWGN term &nbsp;$n(t)$&nbsp; is characterized by the (one-sided) noise power density &nbsp;$N_0$.&nbsp;
*Der Kanalfrequenzgang sei bestmöglich (ideal) und muss nicht weiter berücksichtigt werden: &nbsp;$H_{\rm K}(f) =1$.  
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*Let the channel frequency response be best possible (ideal) and need not be considered further: &nbsp;$H_{\rm K}(f) =1$.  
*Das Empfangsfilter mit der Impulsantwort &nbsp;$h_{\rm E}(t)$&nbsp; formt aus &nbsp;$r(t)$&nbsp; das Detektionssignal &nbsp;$d(t) = d_{\rm S}(t)+ d_{\rm N}(t)$.
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*The receiver filter with the impulse response &nbsp;$h_{\rm E}(t)$&nbsp; forms the detection signal &nbsp;$d(t) = d_{\rm S}(t)+ d_{\rm N}(t)$ from &nbsp;$r(t)$.&nbsp;
* Dieses wird vom Entscheider mit der Entscheiderschwelle &nbsp;$E = 0$&nbsp; zu den äquidistanten Zeiten &nbsp;$\nu \cdot T$&nbsp; ausgewertet.
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* This is evaluated by the decision with the decision threshold &nbsp;$E = 0$&nbsp; at the equidistant times &nbsp;$\nu \cdot T$.&nbsp;  
*Es wird zwischen dem Signalanteil &nbsp;$d_{\rm S}(t)$&nbsp; &ndash; herrührend von &nbsp;$s(t)$&nbsp; &ndash; und dem Rauschanteil &nbsp;$d_{\rm N}(t)$&nbsp; unterschieden, dessen Ursache das AWGN&ndash;Rauschen &nbsp;$n(t)$&nbsp; ist.
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*A distinction is made between the signal component &nbsp;$d_{\rm S}(t)$&nbsp; &ndash; originating from &nbsp;$s(t)$&nbsp; &ndash; and the noise component &nbsp;$d_{\rm N}(t)$,&nbsp; whose cause is the AWGN noise &nbsp;$n(t)$.&nbsp;  
*$d_{\rm S}(t)$&nbsp; kann als gewichtete Summe von gewichteten und jeweils um &nbsp;$T$&nbsp; verschobenen Detektionsgrundimpulsen &nbsp;$g_d(t) = g_s(t) \star h_{\rm E}(t)$&nbsp; dargestellt werden.
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*$d_{\rm S}(t)$&nbsp; can be represented as a weighted sum of weighted basic detection pulses &nbsp;$T$,&nbsp; each shifted by &nbsp;$g_d(t) = g_s(t) \star h_{\rm E}(t)$.&nbsp;
  
*Zur Berechnung der (mittleren) Fehlerwahrscheinlichkeit benötigt man ferner die Varianz&nbsp; $\sigma_d^2 = {\rm E}\big[d_{\rm N}(t)^2\big]$&nbsp; des Detektionsrauschanteils (bei AWGN&ndash;Rauschen).
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*To calculate the (average) error probability, one further needs the variance&nbsp; $\sigma_d^2 = {\rm E}\big[d_{\rm N}(t)^2\big]$&nbsp; of the detection noise component (for AWGN noise).
  
  
===Optimales impulsinterferenzfreies System &ndash; Matched-Filter-Empfänger===
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===Optimal intersymbol interference-free system &ndash; matched filter receiver===
  
Die minimale Fehlerwahrscheinlichkeit ergibt sich für den hier betrachteten Fall &nbsp;$H_{\rm K}(f) =1$&nbsp; mit dem Matched-Filter-Empfänger, also dann, wenn&nbsp; $h_{\rm E}(t)$&nbsp; formgleich mit dem NRZ&ndash;Sendegrundimpuls&nbsp; $g_s(t)$&nbsp; ist. Die rechteckförmige Impulsantwort &nbsp;$h_{\rm E}(t)$&nbsp; hat dann die Dauer&nbsp; $T_{\rm E} = T$&nbsp; und die Höhe&nbsp; $1/T$.  
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The minimum error probability results for the case considered here &nbsp;$H_{\rm K}(f) =1$&nbsp; with the matched filter receiver, i.e. when&nbsp; $h_{\rm E}(t)$&nbsp; is equal in shape to the NRZ basic transmission pulse&nbsp; $g_s(t)$.&nbsp; The rectangular impulse response &nbsp;$h_{\rm E}(t)$&nbsp; then has duration&nbsp; $T_{\rm E} = T$&nbsp; and height&nbsp; $1/T$.  
  
[[Datei:Auge_1neu.png|center|frame|Binäres Basisbandübertragungssystem;&nbsp; die Skizze für &nbsp;$h_{\rm E}(t)$&nbsp; gilt nur für den Matched-Filter-Empfänger ]]  
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[[File:EN_Dig_T_1_4_S1_v2.png|right|frame|Binary baseband transmission system <br> &nbsp; <u>Note:</u>&nbsp; The sketch for &nbsp;$h_{\rm E}(t)$&nbsp; applies only to the matched filter receiver ]]  
  
*Der Detektionsgrundimpuls &nbsp;$g_d(t)$&nbsp; ist dreieckförmig mit dem Maximum&nbsp; $s_0$&nbsp; bei&nbsp; $t=0$&nbsp;; es gilt &nbsp;$g_d(t)=0$&nbsp; für&nbsp; $|t| \ge T$. Aufgrund dieser engen zeitlichen Begrenzung kommt es nicht zu Impulsinterferenzen &nbsp; &rArr; &nbsp; $d_{\rm S}(t = \nu \cdot T) = \pm s_0$ &nbsp; &rArr; &nbsp; der Abstand aller Nutzabtastwerte von der Schwelle &nbsp;$E = 0$&nbsp; ist stets&nbsp; $|d_{\rm S}(t = \nu \cdot T)| = s_0$.  
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*The basic detection pulse &nbsp;$g_d(t)$&nbsp; is triangular with maximum&nbsp; $s_0$&nbsp; at&nbsp; $t=0$&nbsp;; &nbsp;$g_d(t)=0$&nbsp; for&nbsp; $|t| \ge T$. Due to this tight temporal constraint, there is no intersymbol interference &nbsp; &rArr; &nbsp; $d_{\rm S}(t = \nu \cdot T) = \pm s_0$ &nbsp; &rArr; &nbsp; the distance of all useful samples from the threshold &nbsp;$E = 0$&nbsp; is always&nbsp; $|d_{\rm S}(t = \nu \cdot T)| = s_0$.  
*Die Detektionsrauschleistung ist bei dieser Konstellation:
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*The detection noise power for this constellation is:
 
:$$\sigma_d^2 = N_0/2  \cdot \int_{-\infty}^{+\infty} |h_{\rm E}(t)|^2 {\rm d}t = N_0/(2T)=\sigma_{\rm MF}^2.$$
 
:$$\sigma_d^2 = N_0/2  \cdot \int_{-\infty}^{+\infty} |h_{\rm E}(t)|^2 {\rm d}t = N_0/(2T)=\sigma_{\rm MF}^2.$$
*Für die (mittlere) Fehlerwahrscheinlichkeit gilt mit der&nbsp; [[Stochastische_Signaltheorie/Gaußverteilte_Zufallsgrößen#.C3.9Cberschreitungswahrscheinlichkeit|Komplementären Gaußschen Fehlerfunktion]]&nbsp; ${\rm Q}(x)$&nbsp;:
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*For the (average) error probability, using the&nbsp; [[Theory_of_Stochastic_Signals/Gaussian_Distributed_Random_Variables#Exceedance_probability|"Complementary Gaussian Error Function"]]&nbsp; ${\rm Q}(x)$&nbsp;:
 
:$$p_{\rm M} = {\rm Q}\left[\sqrt{{s_0^2}/{\sigma_d^2}}\right ] =  {\rm Q}\left[\sqrt{{2 \cdot s_0^2 \cdot T}/{N_0}}\right ] = {\rm Q}\left[\sqrt{2 \cdot E_{\rm B}/ N_0}\right ].$$   
 
:$$p_{\rm M} = {\rm Q}\left[\sqrt{{s_0^2}/{\sigma_d^2}}\right ] =  {\rm Q}\left[\sqrt{{2 \cdot s_0^2 \cdot T}/{N_0}}\right ] = {\rm Q}\left[\sqrt{2 \cdot E_{\rm B}/ N_0}\right ].$$   
  
Das Applet berücksichtigt diesen Fall mit den Einstellungen&nbsp; &bdquo;nach Spalt&ndash;Tiefpass&rdquo;&nbsp; sowie&nbsp; $T_{\rm E}/T = 1$. Die ausgegebenen Werte sind im Hinblick auf spätere Konstellationen
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The applet considers this case with the settings&nbsp; "after gap&ndash;low-pass"&nbsp; as well as&nbsp; $T_{\rm E}/T = 1$. The output values are with regard to later constellations
*die normierte Augenöffnung&nbsp; $ö_{\rm norm} =1$ &nbsp; &rArr; &nbsp; dies ist der maximal mögliche Wert,  
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*the normalized eye opening&nbsp; $ö_{\rm norm} =1$ &nbsp; &rArr; &nbsp; this is the maximum possible value,
*der normierte Detektionsrauscheffektivwert&nbsp;(gleich der Wurzel aus der Detektionsrauschleistung)&nbsp;  $\sigma_{\rm norm} =\sqrt{1/(2 \cdot E_{\rm B}/ N_0)}$&nbsp; sowie
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*the normalized detection noise rms value&nbsp;(equal to the square root of the detection noise power)&nbsp;  $\sigma_{\rm norm} =\sqrt{1/(2 \cdot E_{\rm B}/ N_0)}$&nbsp; as well as
*die ungünstigste Fehlerwahrscheinlichkeit&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; &rArr; &nbsp; bei impulsinterferenzfreien Systemen stimmen&nbsp; $p_{\rm M}$&nbsp; und &nbsp; $p_{\rm U}$&nbsp; überein.
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*the worst-case error probability&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; &rArr; &nbsp; for intersymbol interference-free systems, &nbsp; $p_{\rm M}$&nbsp; and &nbsp; $p_{\rm U}$&nbsp; agree.
  
  
$\text{Unterschiede bei den Mehrstufensystemen}$
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$\text{Differences in the multi-level systems}$
*Es gibt &nbsp;$M\hspace{-0.1cm}-\hspace{-0.1cm}1$ Augen und eben so viele Schwellen &nbsp; &rArr; &nbsp; $ö_{\rm norm} =1/(M\hspace{-0.1cm}-\hspace{-0.1cm}1)$&nbsp; &rArr; &nbsp; $M=4$:&nbsp; Quaternärsystem,&nbsp; $M=3$:&nbsp; AMI-Code, Duobinärcode.
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*There are &nbsp;$M\hspace{-0.1cm}-\hspace{-0.1cm}1$ eyes and just as many thresholds &nbsp; &rArr; &nbsp; $ö_{\rm norm} =1/(M\hspace{-0.1cm}-\hspace{-0.1cm}1)$&nbsp; &rArr; &nbsp; $M=4$:&nbsp; quaternary system,&nbsp; $M=3$:&nbsp; AMI code, duobinary code.
*Der normierte Detektionsrauscheffektivwert&nbsp; $\sigma_{\rm norm}$&nbsp; ist beim Quaternärsystem um den Faktor &nbsp;$\sqrt{5/9} \approx 0.745$&nbsp; kleiner als beim Binärsystem.
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*The normalized detection noise rms value&nbsp; $\sigma_{\rm norm}$&nbsp; is smaller by a factor of &nbsp;$\sqrt{5/9} \approx 0.745$&nbsp; for the quaternary system than for the binary system.
*Beim AMI-Code und dem Duobinärcode hat dieser Verbesserungsfaktor, der auf das kleinere &nbsp;$E_{\rm B}/ N_0$&nbsp; zurückgeht, den Wert &nbsp;$\sqrt{1/2} \approx 0.707$.  
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*For the AMI code and the duobinary code, this improvement factor, which goes back to the smaller &nbsp;$E_{\rm B}/ N_0$,&nbsp; has the value &nbsp;$\sqrt{1/2} \approx 0.707$.  
  
 
<br>
 
<br>
===Nyquist&ndash;System mit Cosinus-Rolloff-Gesamtfrequenzgang===
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===Nyquist system with raised cosine overall frequency response===
  
[[Datei:Auge_2_neu.png|right|frame|Cosinus-Rolloff-Gesamtfrequenzgang ]]  
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[[File:EN_Auge_2.png|right|frame|Raised cosine overall frequency response]]  
  
Wir setzen voraus, dass der Gesamtfrequenzgang zwischen der diracförmigen Quelle bis zum Entscheider  den Verlauf eines&nbsp; [[Lineare_zeitinvariante_Systeme/Einige_systemtheoretische_Tiefpassfunktionen#Cosinus-Rolloff-Tiefpass|Cosinus-Rolloff-Tiefpasses]]&nbsp; hat &nbsp; &rArr; &nbsp; $H_{\rm S}(f)\cdot H_{\rm E}(f) = H_{\rm CRO}(f)$&nbsp;.
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We assume that the overall frequency response between the Dirac-shaped source to the decision has the shape of a&nbsp; [[Linear_and_Time_Invariant_Systems/Some_Low-Pass_Functions_in_Systems_Theory#Raised-cosine_low-pass_filter|"raised cosine low-pass"]]&nbsp; &nbsp; &rArr; &nbsp; $H_{\rm S}(f)\cdot H_{\rm E}(f) = H_{\rm CRO}(f)$&nbsp;.
*Der Flankenabfall von &nbsp;$H_{\rm CRO}(f)$&nbsp; ist punktsymmetrisch um die Nyquistfrequenz&nbsp; $1/(2T)$. Je größer der Rolloff-Faktor &nbsp;$r_{ \hspace {-0.05cm}f}$&nbsp; ist, um so flacher verläuft die Nyquistflanke.  
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*The rolloff of &nbsp;$H_{\rm CRO}(f)$&nbsp; is point symmetric about the Nyquist frequency&nbsp; $1/(2T)$. The larger the rolloff factor &nbsp;$r_{ \hspace {-0.05cm}f}$,&nbsp; ithe flatter the Nyquist slope.
*Der Detektionsgrundimpuls &nbsp;$g_d(t) = s_0 \cdot T \cdot {\mathcal F}^{-1}\big[H_{\rm CRO}(f)\big]$&nbsp; hat unabhängig von &nbsp;$r_{ \hspace {-0.05cm}f}$&nbsp;  zu den Zeiten &nbsp;$\nu \cdot T$&nbsp; Nullstellen.&nbsp; Weitere Nulldurchgänge gibt es abhängig von &nbsp;$r_{ \hspace {-0.05cm}f}$.&nbsp; Für den Impuls gilt:  
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*The basic detection pulse &nbsp;$g_d(t) = s_0 \cdot T \cdot {\mathcal F}^{-1}\big[H_{\rm CRO}(f)\big]$&nbsp; has zeros at times &nbsp;$\nu \cdot T$&nbsp; independent of &nbsp;$r_{ \hspace {-0.05cm}f}$.&nbsp; There are further zero crossings depending on &nbsp;$r_{ \hspace {-0.05cm}f}$.&nbsp; For the pulse holds:
:$$g_d(t) = s_0 \hspace{-0.05cm}\cdot\hspace{-0.05cm} {\rm si}(\pi \hspace{-0.05cm}\cdot\hspace{-0.05cm} t/T )\hspace{-0.05cm}\cdot\hspace{-0.05cm}\frac {\cos(\pi \cdot r_{\hspace{-0.05cm}f} \cdot t/T )}{1 - (2 \cdot
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:$$g_d(t) = s_0 \hspace{-0.05cm}\cdot\hspace{-0.05cm} {\rm sinc}(  t/T )\hspace{-0.05cm}\cdot\hspace{-0.05cm}\frac {\cos(\pi \cdot r_{\hspace{-0.05cm}f} \cdot t/T )}{1 - (2 \cdot
 
r_{\hspace{-0.05cm}f} \cdot t/T)^2}.$$  
 
r_{\hspace{-0.05cm}f} \cdot t/T)^2}.$$  
*Daraus folgt:&nbsp; Wie beim Matched-Filter-Empfänger ist  das Auge maximal geöffnet &nbsp; &rArr; &nbsp; $ö_{\rm norm} =1$.
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*It follows:&nbsp; As with the matched filter receiver, the eye is maximally open &nbsp; &rArr; &nbsp; $ö_{\rm norm} =1$.
 
 
  
[[Datei:Auge_3.png|right|frame|Zur Optimierung des Rolloff-Faktors ]]
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[[File:EN_Dig_T_1_4_S6.png|right|frame|Optimizing the  rolloff factor]]
Betrachten wir nun die Rauschleistung vor dem Entscheider. Für diese gilt:
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Let us now consider the noise power before the decision. For this holds:
  
 
:$$\sigma_d^2 = N_0/2 \cdot \int_{-\infty}^{+\infty} |H_{\rm E}(f)|^2 {\rm d}f  = N_0/2 \cdot \int_{-\infty}^{+\infty} \frac{|H_{\rm CRO}(f)|^2}{|H_{\rm S}(f)|^2} {\rm d}f.$$  
 
:$$\sigma_d^2 = N_0/2 \cdot \int_{-\infty}^{+\infty} |H_{\rm E}(f)|^2 {\rm d}f  = N_0/2 \cdot \int_{-\infty}^{+\infty} \frac{|H_{\rm CRO}(f)|^2}{|H_{\rm S}(f)|^2} {\rm d}f.$$  
  
Die Grafik zeigt die Leistungsübertragungsfunktion &nbsp;$|H_{\rm E}(f)|^2$&nbsp; für drei verschiedene Rolloff&ndash;Faktoren
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The graph shows the power transfer function &nbsp;$|H_{\rm E}(f)|^2$&nbsp; for three different rolloff factors
  
*  $r_{ \hspace {-0.05cm}f}=0$ &nbsp; &rArr; &nbsp; grüne Kurve,
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*  $r_{ \hspace {-0.05cm}f}=0$ &nbsp; &rArr; &nbsp; green curve,
* $r_{ \hspace {-0.05cm}f}=1$ &nbsp; &rArr; &nbsp; rote Kurve,
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* $r_{ \hspace {-0.05cm}f}=1$ &nbsp; &rArr; &nbsp; red curve,
* $r_{ \hspace {-0.05cm}f}=0.8$ &nbsp; &rArr; &nbsp; blaue Kurve.
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* $r_{ \hspace {-0.05cm}f}=0.8$ &nbsp; &rArr; &nbsp; blue curve.
  
  
Die Flächen unter diesen Kurven sind jeweils ein Maß für die Rauschleistung &nbsp;$\sigma_d^2$.&nbsp; Das grau hinterlegte Rechteck markiert den kleinsten Wert &nbsp;$\sigma_d^2 =\sigma_{\rm MF}^2$, der sich auch mit dem Matched-Filter-Empfänger ergeben hat.  
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The areas under these curves are each a measure of the noise power &nbsp;$\sigma_d^2$.&nbsp; The rectangle with a gray background marks the smallest value &nbsp;$\sigma_d^2 =\sigma_{\rm MF}^2$, which also resulted with the matched filter receiver.
 
<br clear=all>
 
<br clear=all>
Man erkennt aus dieser Darstellung:
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One can see from this plot:
*Der Rolloff&ndash;Faktor &nbsp;$r_{\hspace{-0.05cm}f} = 0$&nbsp; (Rechteck&ndash;Frequenzgang) führt trotz des sehr schmalen Empfangsfilters zu &nbsp;$\sigma_d^2 =K \cdot \sigma_{\rm MF}^2$&nbsp; mit &nbsp;$K  \approx 1.5$, da &nbsp;$|H_{\rm E}(f)|^2$&nbsp; mit wachsendem &nbsp;$f$&nbsp; steil ansteigt. Der Grund für diese Rauschleistungsanhebung ist die Funktion &nbsp;$\rm si^2(\pi f T)$&nbsp; im Nenner, die zur Kompensation des &nbsp;$|H_{\rm S}(f)|^2$&ndash;Abfalls erforderlich ist. <br>
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*The rolloff factor &nbsp;$r_{\hspace{-0.05cm}f} = 0$&nbsp; (rectangular frequency response) leads to &nbsp;$\sigma_d^2 =K \cdot \sigma_{\rm MF}^2$&nbsp; with &nbsp;$K  \approx 1.5$ despite the very narrow receiver filter, since &nbsp;$|H_{\rm E}(f)|^2$&nbsp; increases steeply as &nbsp;$f$&nbsp; increases. The reason for this noise power increase is the &nbsp;$\rm sinc^2(f T)$&nbsp; function in the denominator, which is required to compensate for the &nbsp;$|H_{\rm S}(f)|^2$&ndash;decay. <br>
* Da die Fläche unter der roten Kurve kleiner ist als die unter der grünen Kurve, führt &nbsp;$r_{\hspace{-0.05cm}f} = 1$&nbsp; trotz dopplelt  so breitem Spektrum zu einer kleineren Rauschleistung: &nbsp;$K \approx 1.23$.&nbsp; Für &nbsp;$r_{\hspace{-0.05cm}f} \approx 0.8$ ergibt sich noch ein geringfügig besserer Wert. Hierfür erreicht man den bestmöglichen Kompromiss zwischen Bandbreite und Überhöhung.
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* Since the area under the red curve is smaller than that under the green curve, &nbsp;$r_{\hspace{-0.05cm}f} = 1$&nbsp; leads to a smaller noise power despite a spectrum twice as wide: &nbsp;$K \approx 1.23$.&nbsp; For &nbsp;$r_{\hspace{-0.05cm}f} \approx 0.8$, a slightly better value results. For this, the best possible compromise between bandwidth and excess noise is achieved.
*Der normierte Detektionsrauscheffektivwert lautet somit für den Rolloff&ndash;Faktor&nbsp; $r_{ \hspace {-0.05cm}f}$: &nbsp; $\sigma_{\rm norm} =\sqrt{K(r_f)/(2 \cdot E_{\rm B}/ N_0)}$. <br>
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*The normalized detection noise rms value is thus for the rolloff factor&nbsp; $r_{ \hspace {-0.05cm}f}$: &nbsp; $\sigma_{\rm norm} =\sqrt{K(r_f)/(2 \cdot E_{\rm B}/ N_0)}$. <br>
*Auch hier stimmt die ungünstigste Fehlerwahrscheinlichkeit&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; exakt mit der mittleren Fehlerwahrscheinlichkeit&nbsp; $p_{\rm M}$&nbsp; überein.
+
*Again, the worst-case error probability&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; coincides exactly with the mean error probability&nbsp; $p_{\rm M}$.&nbsp;  
  
  
$\text{Unterschiede bei den Mehrstufensystemen}$
+
$\text{Differences in the multi-level systems}$
  
Alle Anmerkungen im Abschnitt $2.2$ gelten in gleicher Weise für das &bdquo;Nyquist&ndash;System mit Cosinus-Rolloff-Gesamtfrequenzgang&rdquo;.  
+
All remarks in section $2.2$ apply in the same way to the "Nyquist system with raised cosine total frequency response".
  
  
===Impulsinterferenzbehaftetes System mit Gauß-Empfangsfilter===
+
===Intersymbol interference system with Gaussian receiver filter===
  
[[Datei:Auge_4.png|right|frame|System mit gaußförmigem Empfangsfilter ]]
+
[[File:EN_Auge_4_neu.png|right|frame|System with Gaussian receiver filter]]
  
Wir gehen vom rechts skizzierten Blockschaltbild aus. Weiter soll gelten:
+
We start from the block diagram sketched on the right. Further it shall be valid:
*Rechteckförmiger NRZ&ndash;Sendegrundimpuls &nbsp;$g_s(t)$&nbsp; mit der Höhe &nbsp;$s_0$&nbsp; und der Dauer &nbsp;$T$:
+
*Rectangular NRZ basic transmission pulse &nbsp;$g_s(t)$&nbsp; with height &nbsp;$s_0$&nbsp; and duration &nbsp;$T$:
:$$H_{\rm S}(f) = {\rm si}(\pi f T).$$
+
:$$H_{\rm S}(f) = {\rm sinc}(f T).$$
*Gaußförmiges Empfangsfilter mit der Grenzfrequenz &nbsp;$f_{\rm G}$:  
+
*Gaussian receiver filter with cutoff frequency &nbsp;$f_{\rm G}$:  
 
:$$H_{\rm E}(f) = H_{\rm G}(f) = {\rm e}^{-  \pi  \hspace{0.05cm}\cdot \hspace{0.03cm} f^2/(2\hspace{0.05cm}\cdot \hspace{0.03cm}f_{\rm G})^2 } \hspace{0.2cm} \bullet\!\!-\!\!\!-\!\!\!-\!\!\circ
 
:$$H_{\rm E}(f) = H_{\rm G}(f) = {\rm e}^{-  \pi  \hspace{0.05cm}\cdot \hspace{0.03cm} f^2/(2\hspace{0.05cm}\cdot \hspace{0.03cm}f_{\rm G})^2 } \hspace{0.2cm} \bullet\!\!-\!\!\!-\!\!\!-\!\!\circ
 
  \hspace{0.2cm}h_{\rm E}(t) = h_{\rm G}(t) = {\rm e}^{- \pi  \cdot (2\hspace{0.05cm}\cdot \hspace{0.03cm}
 
  \hspace{0.2cm}h_{\rm E}(t) = h_{\rm G}(t) = {\rm e}^{- \pi  \cdot (2\hspace{0.05cm}\cdot \hspace{0.03cm}
Line 112: Line 123:
 
   \hspace{0.05cm}.$$
 
   \hspace{0.05cm}.$$
  
Aufgrund der hier getroffenen Voraussetzungen gilt für den Detektionsgrundimpuls:
+
Based on the assumptions made here, the following applies to the basic detection pulse:
  
[[Datei:Auge_5_neu.png|right|frame|Frequenzgang und Impulsantwort des Empfangsfilters ]]
+
[[File:Auge_5_neu.png|right|frame|Frequency response and impulse response of the receiver filter]]
 
:$$g_d(t) = s_0 \cdot T \cdot \big [h_{\rm S}(t) \star h_{\rm G}(t)\big ] = 2 f_{\rm G} \cdot s_0 \cdot \int_{t-T/2}^{t+T/2}
 
:$$g_d(t) = s_0 \cdot T \cdot \big [h_{\rm S}(t) \star h_{\rm G}(t)\big ] = 2 f_{\rm G} \cdot s_0 \cdot \int_{t-T/2}^{t+T/2}
 
{\rm e}^{- \pi  \hspace{0.05cm}\cdot\hspace{0.05cm} (2 \hspace{0.05cm}\cdot\hspace{0.02cm}
 
{\rm e}^{- \pi  \hspace{0.05cm}\cdot\hspace{0.05cm} (2 \hspace{0.05cm}\cdot\hspace{0.02cm}
 
  f_{\rm G}\hspace{0.05cm}\cdot\hspace{0.02cm} \tau )^2} \,{\rm d} \tau \hspace{0.05cm}.$$
 
  f_{\rm G}\hspace{0.05cm}\cdot\hspace{0.02cm} \tau )^2} \,{\rm d} \tau \hspace{0.05cm}.$$
  
Die Integration führt zum Ergebnis:
+
The integration leads to the result:
  
 
:$$g_d(t) =  s_0 \cdot \big [ {\rm Q} \left (  2 \cdot \sqrt {2 \pi}
 
:$$g_d(t) =  s_0 \cdot \big [ {\rm Q} \left (  2 \cdot \sqrt {2 \pi}
Line 126: Line 137:
 
)\right ) \big ],$$
 
)\right ) \big ],$$
  
unter Verwendung der komplementären Gaußschen Fehlerfunktion
+
using the complementary Gaussian error function
  
 
:$${\rm Q} (x) = \frac{\rm 1}{\sqrt{\rm 2\pi}}\int_{\it
 
:$${\rm Q} (x) = \frac{\rm 1}{\sqrt{\rm 2\pi}}\int_{\it
Line 132: Line 143:
 
\hspace{0.05cm}.$$
 
\hspace{0.05cm}.$$
  
Das Modul &nbsp;[[Applets:Komplementäre_Gaußsche_Fehlerfunktionen|Komplementäre Gaußsche Fehlerfunktionen]]&nbsp; liefert die Zahlenwerte von &nbsp;${\rm Q} (x)$.<br>
+
The module &nbsp;[[Applets:Komplementäre_Gaußsche_Fehlerfunktionen|"Complementary Gaussian Error Functions"]]&nbsp; provides the numerical values of &nbsp;${\rm Q} (x)$.<br>
*Dieser Detektionsgrundimpuls bewirkt&nbsp; [[Digitalsignalübertragung/Ursachen_und_Auswirkungen_von_Impulsinterferenzen#Definition_des_Begriffs_.E2.80.9EImpulsinterferenz.E2.80.9D|Impulsinterferenzen]].  
+
*This basic detection pulse causes&nbsp; [[Digital_Signal_Transmission/Causes_and_Effects_of_Intersymbol_Interference#Definition_of_the_term_.22Intersymbol_Interference.22|"intersymbol interference"]].  
*Darunter versteht man, dass die  Symbolentscheidung durch die Ausläufer benachbarter Impulse beeinflusst wird. Während bei impulsinterferenzfreien Übertragungssystemen jedes Symbol mit gleicher Wahrscheinlichkeit &ndash; nämlich der mittleren Fehlerwahrscheinlichkeit &nbsp;$p_{\rm M}$&nbsp; &ndash;  verfälscht wird, gibt es günstige Symbolkombinationen mit der Verfälschungswahrscheinlichkeit &nbsp;${\rm Pr}(v_{\nu} \ne q_{\nu}) < p_{\rm M}$.  
+
*This is understood to mean that the symbol decision is influenced by the spurs of neighboring pulses. While in intersymbol interference free transmission systems each symbol is falsified with the same probability &ndash; namely the mean error probability &nbsp;$p_{\rm M}$&nbsp; &ndash;  there are favorable symbol combinations with the falsification probability &nbsp;${\rm Pr}(v_{\nu} \ne q_{\nu}) < p_{\rm M}$.  
*Andere Symbolkombinationen erhöhen dagegen die Verfälschungswahrscheinlichkeit erheblich.
+
*In contrast, other symbol combinations increase the falsification probability significantly.
  
  
[[Datei:Auge_6.png|right|frame|Binäres Auge $($Gaußtiefpass,&nbsp; $f_{\rm G}/R_{\rm B} = 0.35)$.]]
+
[[File:Auge_6.png|right|frame|Binary eye $($Gaussian low-pass,&nbsp; $f_{\rm G}/R_{\rm B} = 0.35)$.]]
Die Impulsinterferenzen lassen sich durch das sogenannte &nbsp;'''Augendiagramm'''&nbsp; sehr einfach erfassen und analysieren.  Diese stehen im Mittelpunkt dieses Applets. Alle wichtigen Informationen finden Sie &nbsp;[[Digitalsignalübertragung/Fehlerwahrscheinlichkeit_unter_Berücksichtigung_von_Impulsinterferenzen#Definition_und_Aussagen_des_Augendiagramms|hier]].  
+
The intersymbol interferences can be captured and analyzed very easily by the so-called &nbsp;'''eye diagram'''.&nbsp; These are the focus of this applet. All important information can be found &nbsp;[[Digital_Signal_Transmission/Error_Probability_with_Intersymbol_Interference#Definition_and_statements_of_the_eye_diagram|"here"]].  
*Das Augendiagramm entsteht, wenn man alle Abschnitte des Detektionsnutzsignals&nbsp; $d_{\rm S}(t)$&nbsp; der Länge&nbsp; $2T$&nbsp; übereinander zeichnet. Die Entstehung können Sie sich im Programm mit &bdquo;Einzelschritt&rdquo; verdeutlichen.
+
*The eye diagram is created by drawing all sections of the detection useful signal&nbsp; $d_{\rm S}(t)$&nbsp; of length&nbsp; $2T$&nbsp; on top of each other. You can visualize the formation in the program with "single step".
  
* Ein Maß für die Stärke der Impulsinterferenzen ist die ''vertikale Augenöffnung''. Für den symmetrischen Binärfall gilt mit&nbsp; $g_\nu = g_d(\pm \nu \cdot T)$&nbsp; und geeigneter Normierung:
+
* A measure for the strength of the intersymbol interference is the ''vertical eye opening''. For the symmetric binary case, with&nbsp; $g_\nu = g_d(\pm \nu \cdot T)$&nbsp; and appropriate normalization:
 
:$$ ö_{\rm norm} = g_0 -2 \cdot (|g_1| + |g_2| + \text{...}).$$
 
:$$ ö_{\rm norm} = g_0 -2 \cdot (|g_1| + |g_2| + \text{...}).$$
* Mit größerer Grenzfrequenz stören sich die Impulse weniger und &nbsp;$ ö_{\rm norm}$&nbsp; nimmt kontinuierlich zu. Gleichzeitig wird bei größerem&nbsp; $f_{\rm G}/R_{\rm B}$&nbsp; auch der (normierte) Detektionsrauscheffektivwert größer:
+
* With larger cutoff frequency, the pulses interfere less and &nbsp;$ ö_{\rm norm}$&nbsp; increases continuously. At the same time, with larger&nbsp; $f_{\rm G}/R_{\rm B}$,&nbsp; the (normalized) detection noise rms value also becomes larger:
 
:$$ \sigma_{\rm norm} = \sqrt{\frac{f_{\rm G}/R_{\rm B}}{\sqrt{2} \cdot E_{\rm B}/N_{\rm 0}}}.$$   
 
:$$ \sigma_{\rm norm} = \sqrt{\frac{f_{\rm G}/R_{\rm B}}{\sqrt{2} \cdot E_{\rm B}/N_{\rm 0}}}.$$   
*Die ungünstigste Fehlerwahrscheinlichkeit&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; &rArr; &nbsp; &bdquo;Worst Case&rdquo; liegt meist deutlich über der mittleren Fehlerwahrscheinlichkeit&nbsp; $p_{\rm M}$.
+
*The worst-case error probability&nbsp; $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$ &nbsp; &rArr; &nbsp; "Worst Case" is usually significantly higher than the mean error probability&nbsp; $p_{\rm M}$.
 +
 
  
 +
$\text{Differences in the redundancy-free quaternary system}$
 +
*For&nbsp; $M=4$,&nbsp; other basic pulse values result. <br>''Example'': &nbsp; &nbsp; With &nbsp;$M=4, \ f_{\rm G}/R_{\rm B}=0.4$&nbsp; basic pulse values&nbsp; $g_0 = 0.955, \ g_1 = 0.022$&nbsp; are identical with&nbsp; $M=2, \ f_{\rm G}/R_{\rm B}=0.8$.
 +
* There are now three eye openings and just as many thresholds.&nbsp; The equation for the normalized eye opening is now:&nbsp; &nbsp;$ ö_{\rm norm} = g_0/3 -2 \cdot (|g_1| + |g_2| + \text{...}).$
 +
*The normalized detection noise rms&nbsp; $\sigma_{\rm norm}$&nbsp; is again a factor of &nbsp;$\sqrt{5/9} \approx 0.745$&nbsp; smaller for the quaternary system than for the binary system.
  
$\text{Unterschiede beim redundanzfreien Quaternärsystem}$
 
*Für&nbsp; $M=4$&nbsp; ergeben sich andere Grundimpulswerte. <br>''Beispiel'': &nbsp; &nbsp; Mit &nbsp;$M=4, \ f_{\rm G}/R_{\rm B}=0.4$&nbsp; sind Grundimpulswerte&nbsp; $g_0 = 0.955, \ g_1 = 0.022$&nbsp; identisch mit&nbsp; $M=2, \ f_{\rm G}/R_{\rm B}=0.8$.
 
* Es gibt nun drei Augenöffnungen und eben so viele Schwellen.&nbsp; Die Gleichung für die normierte Augenöffnung lautet nun:&nbsp; &nbsp;$ ö_{\rm norm} = g_0/3 -2 \cdot (|g_1| + |g_2| + \text{...}).$
 
*Der normierte Detektionsrauscheffektivwert&nbsp; $\sigma_{\rm norm}$&nbsp; ist beim Quaternärsystem wieder um den Faktor &nbsp;$\sqrt{5/9} \approx 0.745$&nbsp; kleiner als beim Binärsystem.
 
  
 +
===Pseudo-ternary codes===
  
===Pseudoternärcodes===
+
In symbolwise coding, each incoming source symbol &nbsp;$q_\nu$&nbsp; generates an encoder symbol &nbsp;$c_\nu$&nbsp; that depends not only on the current input symbol &nbsp;$q_\nu$&nbsp; but also on the &nbsp;$N_{\rm C}$&nbsp; preceding symbols &nbsp;$q_{\nu-1}$, ... , $q_{\nu-N_{\rm C}} $.&nbsp; &nbsp;$N_{\rm C}$&nbsp; is referred to as the ''order''&nbsp; of the code.&nbsp; It is typical for a symbolwise coding that
 +
[[File:EN_Dig_T_2_4_S1_v26.png|right|frame|Block diagram and equivalent circuit of a pseudo-ternary encoder|class=fit]]
  
Bei der symbolweisen Codierung wird mit jedem ankommenden Quellensymbol &nbsp;$q_\nu$&nbsp; ein Codesymbol &nbsp;$c_\nu$&nbsp; erzeugt, das außer vom aktuellen Eingangssymbol &nbsp;$q_\nu$&nbsp; auch von den &nbsp;$N_{\rm C}$&nbsp; vorangegangenen Symbolen &nbsp;$q_{\nu-1}$, ... , $q_{\nu-N_{\rm C}} $&nbsp; abhängt. &nbsp;$N_{\rm C}$&nbsp; bezeichnet man als die ''Ordnung''&nbsp; des Codes.&nbsp; Typisch für eine symbolweise Codierung ist, dass
+
*the symbol duration &nbsp;$T$&nbsp; of the encoded signal (and of the transmitted signal) coincides with the bit duration &nbsp;$T_{\rm B}$&nbsp; of the binary source signal, and
*die Symboldauer &nbsp;$T$&nbsp; des Codersignals (und des Sendesignals) mit der Bitdauer &nbsp;$T_{\rm B}$&nbsp; des binären Quellensignals übereinstimmt, und
+
*coding and decoding do not lead to major time delays, which are unavoidable when block codes are used.<br><br>
*Codierung und Decodierung nicht zu größeren Zeitverzögerungen führen, die bei Verwendung von Blockcodes unvermeidbar sind.<br><br>
 
  
[[Datei:P_ID1343__Dig_T_2_4_S1_v1.png|center|frame|Blockschaltbild und Ersatzschaltbild eines Pseudoternärcoders|class=fit]]
 
  
Besondere Bedeutung besitzen ''Pseudoternärcodes'' &nbsp; &rArr; &nbsp;  Stufenzahl &nbsp;$M = 3$, die durch das Blockschaltbild entsprechend der linken Grafik beschreibbar sind. In der rechten Grafik ist ein Ersatzschaltbild angegeben, das für eine Analyse dieser Codes sehr gut geeignet ist. Genaueres hierzu finden Sie im&nbsp; [[Digitalsignalübertragung/Symbolweise_Codierung_mit_Pseudoternärcodes|$\rm LNTwww$&ndash;Theorieteil]].&nbsp; Fazit:
+
Special importance has ''pseudo-ternary codes'' &nbsp; &rArr; &nbsp;  level number &nbsp;$M = 3$, which can be described by the block diagram according to the left graphic. In the right graphic an equivalent circuit is given, which is very suitable for an analysis of these codes. More details can be found in the&nbsp; [[Digital_Signal_Transmission/Symbolwise_Coding_with_Pseudo-Ternary_Codes|"$\rm LNTwww$ theory section"]].&nbsp; Conclusion:
  
*Umcodierung von binär &nbsp;$(M_q = 2)$&nbsp; auf ternär &nbsp;$(M = M_c = 3)$:  
+
*Recoding from binary &nbsp;$(M_q = 2)$&nbsp; to ternary &nbsp;$(M = M_c = 3)$:  
 
:$$q_\nu \in \{-1, +1\},\hspace{0.5cm} c_\nu \in \{-1, \ 0,  +1\}\hspace{0.05cm}.$$
 
:$$q_\nu \in \{-1, +1\},\hspace{0.5cm} c_\nu \in \{-1, \ 0,  +1\}\hspace{0.05cm}.$$
  
*Die relative Coderedundanz ist für alle Pseudoternärcodes gleich:  
+
*The relative code redundancy is the same for all pseudo-ternary codes:
 
:$$ r_c = 1 -1/\log_2\hspace{0.05cm}(3) \approx 36.9 \%\hspace{0.05cm}.$$
 
:$$ r_c = 1 -1/\log_2\hspace{0.05cm}(3) \approx 36.9 \%\hspace{0.05cm}.$$
  
Anhand des Codeparameters &nbsp;$K_{\rm C}$&nbsp; werden verschiedene Pseudoternärcodes erster Ordnung &nbsp;$(N_{\rm C} = 1)$&nbsp; charakterisiert.
+
Based on the code parameter &nbsp;$K_{\rm C}$,&nbsp; different first-order pseudo-ternary codes &nbsp;$(N_{\rm C} = 1)$&nbsp; are characterized.
  
  
[[Datei:Auge_16.png|right|frame|Signale bei der AMI-Codierung|class=fit]]
+
[[File:Auge_16.png|right|frame|Signals in AMI coding|class=fit]]
$\Rightarrow \ \ K_{\rm C} = 1\text{:  AMI&ndash;Code}$&nbsp; (von: &nbsp; ''Alternate Mark Inversion'')
+
$\Rightarrow \ \ K_{\rm C} = 1\text{:  AMI code}$&nbsp; (from: &nbsp; ''Alternate Mark Inversion'')
  
Die Grafik zeigt oben das binäre Quellensignal &nbsp;$q(t)$. Darunter sind dargestellt:
+
The graph shows the binary source signal &nbsp;$q(t)$ at the top. Below are shown:
* das ebenfalls binäre Signal &nbsp;$b(t)$&nbsp; nach dem Vorcodierer, und
+
* the likewise binary signal &nbsp;$b(t)$&nbsp; after the pre-encoder, and
* das Codersignal &nbsp;$c(t) = s(t)$&nbsp; des AMI&ndash;Codes.  
+
* the encoded signal &nbsp;$c(t) = s(t)$&nbsp; of the AMI code.
  
  
Man erkennt das einfache AMI&ndash;Codierprinzip:
+
One can see the simple AMI coding principle:
*Jeder Binärwert&nbsp; &bdquo;&ndash;1&rdquo; &nbsp;von $q(t)$  &nbsp; &rArr; &nbsp; Symbol &nbsp;$\rm L$&nbsp; wird durch den ternären Amplitudenkoeffizienten &nbsp;$a_\nu = 0$&nbsp; codiert.<br>
+
*Each binary value&nbsp; "&ndash;1" &nbsp;of $q(t)$  &nbsp; &rArr; &nbsp; symbol &nbsp;$\rm L$&nbsp; is encoded by the ternary amplitude coefficient &nbsp;$a_\nu = 0$.&nbsp; <br>
*Der Binärwert&nbsp; &bdquo;+1&rdquo; &nbsp;von &nbsp;$q(t)$ &nbsp; &rArr; &nbsp; Symbol &nbsp;$\rm H$&nbsp; wird alternierend mit &nbsp;$a_\nu = +1$&nbsp; und &nbsp;$a_\nu = -1$&nbsp; dargestellt.<br><br>
+
*The binary value&nbsp; "+1" &nbsp;of &nbsp;$q(t)$ &nbsp; &rArr; &nbsp; symbol &nbsp;$\rm H$&nbsp; is alternately represented by &nbsp;$a_\nu = +1$&nbsp; and &nbsp;$a_\nu = -1$.&nbsp; <br><br>
  
Damit wird sichergestellt, dass im AMI&ndash;codierten Signal keine langen&nbsp; &bdquo;+1&rdquo;&ndash;&nbsp; bzw.&nbsp; &bdquo;&ndash;1&rdquo;&ndash;Sequenzen enthalten sind, was bei einem gleichsignalfreien Kanal problematisch wäre.&nbsp;
+
This ensures that there are no long&nbsp; "+1"&ndash;&nbsp; or&nbsp; "&ndash;1" sequences in the AMI-encoded signal, which would be problematic for an DC signal-free channel.&nbsp;
 
<br>
 
<br>
[[Datei:Auge_16a.png|left|frame|class=fit]]
+
[[File:EN_Auge_16a.png|left|frame| |class=fit]]
  
  
Links ist das Augendiagramm dargestellt.
+
The eye diagram is shown on the left.
::*&nbsp;Es gibt zwei Augenöffnungen und zwei Schwellen.
+
::*&nbsp;There are two eye openings and two thresholds.
::*&nbsp;Die normierte Augenöffnung ist&nbsp; $ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1)$, wobei&nbsp; $g_0 = g_d(t=0)$&nbsp; den Hauptwert des Detektionsgrundimpulses bezeichnet und&nbsp; $g_1 = g_d(t=\pm T)$&nbsp; die relevanten Vor- und Nachläufer, die das Auge vertikal begrenzen.
+
::*&nbsp;The normalized eye opening is&nbsp; $ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1)$, where&nbsp; $g_0 = g_d(t=0)$&nbsp; denotes the main value of the basic detection pulse and&nbsp; $g_1 = g_d(t=\pm T)$&nbsp; denotes the relevant precursors and postcursors that vertically limit the eye.
  
::*&nbsp;Die normierte Augenöffnung ist somit deutlich kleiner als beim vergleichbaren Binäsystem &nbsp; &rArr; &nbsp; $ö_{\rm norm}= g_0 -2 \cdot g_1$.
+
::*&nbsp;The normalized eye opening is thus significantly smaller than for the comparable binary system &nbsp; &rArr; &nbsp; $ö_{\rm norm}= g_0 -2 \cdot g_1$.
::*&nbsp;Der normierte Rauscheffektivwert &nbsp;$\sigma_{\rm norm}$&nbsp; ist um den Faktor &nbsp;$\sqrt{1/2} \approx 0.707$&nbsp; kleiner als beim vergleichbaren Binäsystem.
+
::*&nbsp;The normalized noise rms &nbsp;$\sigma_{\rm norm}$&nbsp; is smaller than for the comparable binary system by a factor of &nbsp;$\sqrt{1/2} \approx 0.707$.&nbsp;  
 
<br clear=all>  
 
<br clear=all>  
[[Datei:Auge_17.png|right|frame|Signale bei der Duobinärcodierung|class=fit]]
+
[[File:Auge_17.png|right|frame|Signals in duobinary coding|class=fit]]
  
$\Rightarrow \ \ K_{\rm C} = -1\text{:  Duobinärcode}$&nbsp;  
+
$\Rightarrow \ \ K_{\rm C} = -1\text{:  duobinary code}$&nbsp;  
  
Aus der rechten Grafik mit den Signalverläufen erkennt man:  
+
From the right graph with the signal curves one recognizes:
*Hier können beliebig viele Symbole gleicher Polarität&nbsp; (&bdquo;+1&rdquo; bzw. &bdquo;&ndash;1&rdquo;)&nbsp; direkt aufeinanderfolgen &nbsp; &rArr; &nbsp; der Duobinärcode ist nicht gleichsignalfrei.&nbsp;  
+
*Here, any number of symbols of the same polarity&nbsp; ("+1" or "&ndash;1")&nbsp; can directly follow each other &nbsp; &rArr; &nbsp; the duobinary code is not free of DC signals.&nbsp;  
*Dagegen tritt beim Duobinärcode die alternierende Folge&nbsp;  &bdquo; ... , +1, &ndash;1, +1, &ndash;1, +1, ... &rdquo;&nbsp;  nicht auf, die hinsichtlich Impulsinterferenzen besonders störend ist.
+
*In contrast, the alternating sequence&nbsp;  " ... , +1, &ndash;1, +1, &ndash;1, +1, ... "&nbsp;  does not occur, which is particularly disturbing with regard to intersymbol interference.
*&nbsp;Auch die Duobinärcode&ndash;Folge besteht zu 50% aus Nullen. Der Verbesserungsfaktor durch das kleinere &nbsp;$E_{\rm B}/ N_0$&nbsp; ist wie beim AMI-Code gleich&nbsp; $\sqrt{1/2} \approx 0.707$.  
+
*&nbsp;Also the duobinary encoded sequence consists to 50% of zeros. The enhancement factor due to the smaller &nbsp;$E_{\rm B}/ N_0$&nbsp; is equal to&nbsp; $\sqrt{1/2} \approx 0.707$, as in the AMI code.
  
[[Datei:Auge_17a.png|left|frame|class=fit]]
+
[[File:EN_Auge_17a.png|left|frame| |class=fit]]
 
<br>
 
<br>
Links ist das Augendiagramm dargestellt.
+
The eye diagram is shown on the left.
::*&nbsp;Es gibt wieder zwei &bdquo;Augen&rdquo; und zwei Schwellen.
+
::*&nbsp;There are again two "eyes" and two thresholds.
::*&nbsp;Die Augenöffnung ist &nbsp; $ö_{\rm norm}= 1/2 \cdot (g_0 - g_1)$.
+
::*&nbsp;The eye opening is &nbsp; $ö_{\rm norm}= 1/2 \cdot (g_0 - g_1)$.
*$ö_{\rm norm}$&nbsp; ist also größer als beim AMI&ndash;Code und auch wie  beim vergleichbaren Binäsystem.
+
*$ö_{\rm norm}$&nbsp; is thus larger than in the AMI code and also as in the comparable binary system.
*Nachteilig gegenüber dem AMI&ndash;Code ist allerdings, dass er nicht gleichsignalfrei ist.
+
*A disadvantage compared to the AMI code, however, is that it is not  DC signal-free.
 +
 
  
  
  
 
==Exercises==
 
==Exercises==
<br>
 
  
* First select the number&nbsp; $(1,\text{...}, 7)$&nbsp; of the exercise.&nbsp; The number&nbsp; $0$&nbsp; corresponds to a "Reset":&nbsp; Same setting as at program start.
+
* First select the number&nbsp; $(1,\ 2, \text{...})$&nbsp; of the exercise.&nbsp; The number&nbsp; $0$&nbsp; corresponds to a "Reset":&nbsp; Same setting as at program start.
 
*A task description is displayed.&nbsp; The parameter values ​​are adjusted.&nbsp; Solution after pressing "Show solution". <br>
 
*A task description is displayed.&nbsp; The parameter values ​​are adjusted.&nbsp; Solution after pressing "Show solution". <br>
  
  
 
{{BlueBox|TEXT=
 
{{BlueBox|TEXT=
'''(1)'''&nbsp; Explain the occurrence of the eye pattern for&nbsp; $M=2 \text{, behind a Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$. For this, select "step by step". }}
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'''(1)'''&nbsp; Explain the occurrence of the eye pattern for&nbsp; $M=2 \text{, Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$. For this, select "step&ndash;by&ndash;step". }}
  
::*&nbsp;The eye pattern is obtained by dividing the detection signal&nbsp; $d_{\rm S}(t)$&nbsp; (without noise) into pieces of duration&nbsp; $2T$&nbsp; and drawing these pieces on top of each other.
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::*&nbsp;The eye pattern is obtained by dividing the "useful" signal&nbsp; $d_{\rm S}(t)$&nbsp; (without noise) into pieces of duration&nbsp; $2T$&nbsp; and drawing these pieces on top of each other.
 
::*&nbsp;In&nbsp; $d_{\rm S}(t)$&nbsp; all&nbsp; "five bit combinations"&nbsp; must be contained &nbsp; &rArr; &nbsp; at least&nbsp; $2^5 = 32$&nbsp; pieces &nbsp; &rArr; &nbsp; at most&nbsp; $32$&nbsp; distinguishable lines.
 
::*&nbsp;In&nbsp; $d_{\rm S}(t)$&nbsp; all&nbsp; "five bit combinations"&nbsp; must be contained &nbsp; &rArr; &nbsp; at least&nbsp; $2^5 = 32$&nbsp; pieces &nbsp; &rArr; &nbsp; at most&nbsp; $32$&nbsp; distinguishable lines.
 
::*&nbsp;The eye pattern evaluates the transient response of the signal.&nbsp; The larger the (normalized) eye opening, the smaller are the intersymbol interferences.  
 
::*&nbsp;The eye pattern evaluates the transient response of the signal.&nbsp; The larger the (normalized) eye opening, the smaller are the intersymbol interferences.  
  
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'''(1)'''&nbsp; Verdeutlichen Sie sich die Entstehung des Augendiagramms für&nbsp; $M=2 \text{, nach Gauß&ndash;TP, }f_{\rm G}/R_{\rm B} = 0.48$. Wählen Sie hierfür &bdquo;Einzelschritt&rdquo;. }}
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'''(2)'''&nbsp; Same setting as in&nbsp; $(1)$. In addition, &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$.&nbsp; Evaluate the output characteristics&nbsp; $ö_{\rm norm}$,&nbsp; $\sigma_{\rm norm}$,&nbsp; and &nbsp;$p_{\rm U}$.}}
  
::*&nbsp;Dieses Augendiagramm ergibt sich, wenn man das Detektionsnutzsignal&nbsp; $d_{\rm S}(t)$&nbsp; in Stücke der Dauer&nbsp; $2T$&nbsp; unterteilt und diese Teile übereinander zeichnet.
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::*&nbsp;$ö_{\rm norm}= 0.542$&nbsp; indicates that symbol detection is affected by adjacent pulses.  For binary systems without intersymbol interference: &nbsp;$ö_{\rm norm}= 1$.  
::*&nbsp;In&nbsp; $d_{\rm S}(t)$&nbsp; müssen alle &bdquo;Fünf&ndash;Bit&ndash;Kombinationen&rdquo; enthalten sein &nbsp; &rArr; &nbsp; mindestens&nbsp; $2^5 = 32$&nbsp; Teilstücke &nbsp; &rArr; &nbsp; maximal&nbsp; $32$&nbsp; unterscheidbare Linien.
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::*&nbsp;The eye opening indicates only the signal&nbsp; $d_{\rm S}(t)$&nbsp; without noise.&nbsp; The noise influence is captured by &nbsp;$\sigma_{\rm norm}= 0.184$&nbsp;. This value should be as small as possible.
::*&nbsp;Das Diagramm bewertet das Einschwingverhalten des Nutzsignals. Je größer die (normierte) Augenöffnung ist, desto weniger Impulsinterferenzen gibt es.  
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::*&nbsp;The error probability &nbsp;$p_{\rm U} = {\rm Q}(ö_{\rm norm}/\sigma_{\rm norm}\approx 0.16\%)$&nbsp; refers solely to the "worst-case sequences", for Gaussian low&ndash;pass e.g. &nbsp;$\text{...}\ , -1, -1, +1, -1, -1, \text{...}$.
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::*&nbsp;Other sequences are less distorted &nbsp; &rArr; &nbsp; the mean error probability &nbsp;$p_{\rm M}$&nbsp; is (usually) significantly smaller than&nbsp;$p_{\rm U}$&nbsp; (describing the worst case).
  
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'''(2)'''&nbsp; Gleiche Einstellung wie in&nbsp; '''(1)'''. Zusätzlich gilt &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$. Bewerten Sie die ausgegebenen Größen&nbsp; $ö_{\rm norm}$,&nbsp; $\sigma_{\rm norm}$&nbsp; und &nbsp;$p_{\rm U}$.}}
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'''(3)'''&nbsp; The last settings remain.&nbsp; With which &nbsp;$f_{\rm G}/R_{\rm B}$&nbsp; value does the worst case error probability &nbsp;$p_{\rm U}$&nbsp; become minimal?&nbsp; Consider also the eye pattern.}}
  
::*&nbsp;$ö_{\rm norm}= 0.542$&nbsp; zeigt an, dass die Symboldetektion durch benachbarte Impulse beeinträchtigt wird.  Für impulsinterferenzfreie Binärsysteme gilt  &nbsp;$ö_{\rm norm}= 1$.  
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::*&nbsp;The minimum value &nbsp;$p_{\rm U, \ min} \approx 0.65 \cdot 10^{-4}$&nbsp; is obtained for &nbsp;$f_{\rm G}/R_{\rm B} \approx 0.8$, and this is almost independent of the setting of &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$.
::*&nbsp;Die Augenöffnung kennzeichnet nur das Nutzsignal. Der Rauscheinfluss wird durch &nbsp;$\sigma_{\rm norm}= 0.184$&nbsp; erfasst. Dieser Wert sollte möglichst klein sein.
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::*&nbsp;The normalized noise rms value does increase compared to the experiment &nbsp;$(2)$&nbsp; from &nbsp;$\sigma_{\rm norm}= 0.168$&nbsp; to &nbsp;$\sigma_{\rm norm}= 0.238$.
::*&nbsp;Die Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U} = {\rm Q}(ö_{\rm norm}/\sigma_{\rm norm}\approx 0.16\%)$&nbsp; bezieht sich allein auf die &bdquo;ungünstigsten Folgen&rdquo;, bei &bdquo;Gauß&rdquo; z. B. &nbsp;$-1, -1, +1, -1, -1$.  
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::*&nbsp;However, this is more than compensated by the larger eye opening &nbsp;$ö_{\rm norm}= 0.91$&nbsp; compared to &nbsp;$ö_{\rm norm}= 0.542$&nbsp; $($magnification factor $\approx 1.68)$.
::*&nbsp;Andere Folgen werden weniger verfälscht &nbsp; &rArr; &nbsp; die mittlere Fehlerwahrscheinlichkeit &nbsp;$p_{\rm M}$&nbsp; ist (meist) deutlich kleiner als&nbsp;$p_{\rm U}$&nbsp; (beschreibt den &bdquo;''Worst Case''&rdquo;).
 
  
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'''(3)'''&nbsp; Die letzten Einstellungen bleiben. Mit welchem &nbsp;$f_{\rm G}/R_{\rm B}$&ndash;Wert wird die ungünstigste Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U}$&nbsp; minimal? Auch das Augendiagramm betrachten.}}
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'''(4)'''&nbsp; Which cutoff frequencies &nbsp;$(f_{\rm G}/R_{\rm B})$&nbsp; result in a completely inadequate error probability &nbsp;$p_{\rm U} \approx 50\%$&nbsp;? Look at the eye pattern again&nbsp; ("Overall view").}}
  
::*&nbsp;Der minimale Wert  &nbsp;$p_{\rm U, \ min} \approx 0.65 \cdot 10^{-4}$&nbsp; ergibt sich für &nbsp;$f_{\rm G}/R_{\rm B} \approx 0.8$, und zwar nahezu unabhängig vom eingestellten &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$.
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::*&nbsp;For &nbsp;$f_{\rm G}/R_{\rm B}<0.28$&nbsp; we get a "closed eye" &nbsp;$(ö_{\rm norm}= 0)$&nbsp; and thus a worst case error probability on the order of &nbsp;$50\%$.
::*&nbsp;Der normierte Rauscheffektivwert steigt zwar gegenüber dem Versuch &nbsp;'''(2)'''&nbsp; von &nbsp;$\sigma_{\rm norm}= 0.168$&nbsp; auf &nbsp;$\sigma_{\rm norm}= 0.238$&nbsp; an.
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::*&nbsp;The decision on unfavorably framed bits must then be random, even with low noise &nbsp;$(10 \cdot \lg \ E_{\rm B}/N_0 = 16 \ {\rm dB})$.
::*&nbsp;Dies wird aber durch die größere Augenöffnung &nbsp;$ö_{\rm norm}= 0.91$&nbsp; gegenüber &nbsp;$ö_{\rm norm}= 0.542$&nbsp; mehr als ausgeglichen&nbsp; $($Vergrößerungsfaktor $\approx 1.68)$.
 
  
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'''(4)'''&nbsp; Für welche Grenzfrequenzen &nbsp;$(f_{\rm G}/R_{\rm B})$&nbsp; ergibt sich eine völlig unzureichende Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U} \approx 50\%$&nbsp;? Auch das Augendiagramm betrachten.}}
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'''(5)'''&nbsp; Now select the settings&nbsp; $M=2 \text{, Matched Filter receiver, }T_{\rm E}/T = 1$, &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; and&nbsp; "Overall view". Interpret the results. }}
  
::*&nbsp;Für &nbsp;$f_{\rm G}/R_{\rm B}<0.28$&nbsp; ergibt sich ein geschlossenes Auge &nbsp;$(ö_{\rm norm}= 0)$&nbsp; und damit eine worst&ndash;case Fehlerwahrscheinlichkeit in der Größenordnung von &nbsp;$50\%$.
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::*&nbsp;The basic detection  impulse&nbsp; $g_d(t)$&nbsp; is triangular and the eye is "fully open".&nbsp; Consequently, the normalized eye opening is &nbsp;$ö_{\rm norm}= 1.$
::*&nbsp;Die Entscheidung über ungünstig eingerahmte Bit muss dann zufällig erfolgen, auch bei geringem Rauschen &nbsp;$(10 \cdot \lg \ E_{\rm B}/N_0 = 16 \ {\rm dB})$.
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::*&nbsp;From&nbsp; $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; it follows&nbsp;$E_{\rm B}/N_0 = 10$ &nbsp; &rArr; &nbsp; $\sigma_{\rm norm} =\sqrt{1/(2\cdot E_{\rm B}/ N_0)} = \sqrt{0.05} \approx 0.224 $&nbsp; &rArr; &nbsp; $p_{\rm U} = {\rm Q}(4.47) \approx 3.9 \cdot 10^{-6}.$
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::*&nbsp;This&nbsp; $p_{\rm U}$&nbsp;value is by a factor&nbsp; $15$&nbsp; better than in&nbsp; $(3)$. &nbsp; But:&nbsp; For &nbsp;$H_{\rm K}(f) \ne 1$&nbsp; this so&ndash;called "Matched Filter Receiver" is not applicable.
  
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'''(5)'''&nbsp; Wählen Sie nun die Einstellungen&nbsp; $M=2 \text{, nach Spalt&ndash;TP, }T_{\rm E}/T = 1$, &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; sowie &bdquo;Auge &ndash; Gesamt&rdquo;. Interpretieren Sie die Ergebnisse. }}
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'''(6)'''&nbsp; Same settings as in&nbsp; $(5)$.&nbsp; Now vary&nbsp; $T_{\rm E}/T$&nbsp; in the range between&nbsp; $0.5$&nbsp; and&nbsp; $1.5$.&nbsp; Interpret the results.}}
  
::*&nbsp;Der Detektionsgrundimpuls ist dreieckförmig und das Auge vollständig geöffnet. Die normierte Augenöffnung ist demzufolge &nbsp;$ö_{\rm norm}= 1.$
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::*&nbsp;For &nbsp;$T_{\rm E}/T < 1$&nbsp;, &nbsp;$ö_{\rm norm}= 1$&nbsp; still holds.&nbsp; But &nbsp;$\sigma_{\rm norm}$&nbsp; becomes larger, for example &nbsp;$\sigma_{\rm norm} = 0.316$&nbsp; for &nbsp;$T_{\rm E}/T =0.5$ &nbsp; &rArr; &nbsp; the filter is too broadband!
::*&nbsp;Aus&nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; folgt&nbsp;$E_{\rm B}/N_0 = 10$ &nbsp; &rArr; &nbsp; $\sigma_{\rm norm} =\sqrt{1/(2\cdot E_{\rm B}/ N_0)} = \sqrt{0.05} \approx 0.224 $&nbsp; &rArr; &nbsp; $p_{\rm U} = {\rm Q}(4.47) \approx 3.9 \cdot 10^{-6}.$
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::*&nbsp;$T_{\rm E}/T > 1$&nbsp; results in a smaller &nbsp;$\sigma_{\rm norm}$&nbsp; compared to&nbsp; $(5)$.&nbsp; But the "eye" is no longer open, e.g. &nbsp;$T_{\rm E}/T =1.25$: &nbsp; $ö_{\rm norm}= g_0 - 2 \cdot g_1 = 0.6$.
::*&nbsp;Dieser Wert ist um den Faktor&nbsp; $15$&nbsp; besser als in '''(3)'''. &nbsp; Aber:&nbsp; Bei &nbsp;$H_{\rm K}(f) \ne 1$&nbsp; ist der Matched-Filter-Empfänger so nicht anwendbar.
 
  
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'''(6)'''&nbsp; Gleiche Einstellung wie in&nbsp; '''(5)'''. Variieren Sie nun&nbsp; $T_{\rm E}/T$&nbsp; im Bereich zwischen&nbsp; $0.5$&nbsp; und&nbsp; $1.5$. Interpretieren Sie die Ergebnisse.}}
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'''(7)'''&nbsp; Now select the settings&nbsp; $M=2 \text{, CRO Nyquist system, }r_f = 0.2$&nbsp; and&nbsp; "Overall view". Interpret the eye pattern, also for other&nbsp; $r_f$ values. }}
  
::*&nbsp;Für &nbsp;$T_{\rm E}/T < 1$&nbsp; gilt weiterhin &nbsp;$ö_{\rm norm}= 1$. Aber &nbsp;$\sigma_{\rm norm}$&nbsp; wird größer, zum Beispiel &nbsp;$\sigma_{\rm norm} = 0.316$&nbsp; für &nbsp;$T_{\rm E}/T =0.5$ &nbsp; &rArr; &nbsp; das Filter ist zu breitbandig!
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::*&nbsp;Unlike &nbsp;$(6)$&nbsp; here the basic detection impulse is not zero for &nbsp;$|t|>T$,&nbsp; but &nbsp;$g_d(t)$&nbsp; has equidistant zero crossings: &nbsp;$g_0 = 1, \ g_1 = g_2 = 0$ &nbsp; &rArr; &nbsp; '''Nyquist system'''.
::*&nbsp;Für &nbsp;$T_{\rm E}/T > 1$&nbsp; ergibt sich im Vergleich zu&nbsp; '''(5)'''&nbsp; ein kleineres &nbsp;$\sigma_{\rm norm}$. Aber Das Auge ist nicht mehr geöffnet. &nbsp;$T_{\rm E}/T =1.25$: &nbsp;$ö_{\rm norm}= g_0 - 2 \cdot g_1 = 0.6$.
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::*&nbsp;All &nbsp;$32$&nbsp; eye lines pass through only two points at &nbsp;$t=0$.&nbsp; The vertical eye opening is maximum for all&nbsp; $r_f$&nbsp; &nbsp; &rArr; &nbsp; &nbsp;$ö_{\rm norm}= 1$.
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::*&nbsp;In contrast, the horizontal eye opening increases with &nbsp;$r_f$&nbsp; and is for &nbsp;$r_f = 1$&nbsp; maximum equal to &nbsp;$T$ &nbsp; &rArr; &nbsp; the phase jitter has no influence in this case.
  
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'''(7)'''&nbsp; Wählen Sie nun die Einstellungen&nbsp; $M=2 \text{, CRO&ndash;Nyquist, }r_f = 0.2$&nbsp; sowie &bdquo;Auge &ndash; Gesamt&rdquo;. Interpretieren Sie das Augendiagramm, auch für andere&nbsp; $r_f$&ndash;Werte. }}
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'''(8)'''&nbsp; Same setting as in&nbsp; $(7)$.&nbsp; Now vary&nbsp; $r_f$&nbsp; with respect to minimum error probability.&nbsp; Interpret the results.}}
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::*$ö_{\rm norm}= 1$&nbsp; always holds.&nbsp;  In contrast, &nbsp;$\sigma_{\rm norm}$&nbsp; shows a slight dependence on &nbsp;$r_f$.&nbsp; The minimum &nbsp;$\sigma_{\rm norm}=0.236$&nbsp; results for &nbsp;$r_f = 0.9$ &nbsp; &rArr; &nbsp; $p_{\rm U}  \approx 1.1 \cdot 10^{-5}.$
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::*&nbsp;Compared to the best possible case according to &nbsp;$(5)$ &nbsp; &rArr; &nbsp; "Matched Filter Receiver"&nbsp; $p_{\rm U}$&nbsp; is three times larger, although &nbsp;$\sigma_{\rm norm}$&nbsp; is only larger by about &nbsp;$5\%$.
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::*&nbsp;The larger &nbsp;$\sigma_{\rm norm}$ value is due to the exaggeration of the noise PDS to compensate for the drop through the transmitter frequency response &nbsp;$H_{\rm S}(f)$.
  
::*&nbsp;Im Gegensatz zu &nbsp;'''(6)'''&nbsp; ist hier der Grundimpuls für &nbsp;$|t|>T$&nbsp; nicht Null, aber &nbsp;$g_d(t)$&nbsp; hat äquidistane Nulldurchgänge: &nbsp;$g_0 = 1, \ g_1 = g_2 = 0$ &nbsp; &rArr; &nbsp; '''Nyquistsystem'''.
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::*&nbsp;Alle &nbsp;$32$&nbsp; Augenlinien gehen bei &nbsp;$t=0$&nbsp; durch nur zwei Punkte. Die vertikale Augenöffnung ist für alle&nbsp; $r_f$&nbsp;  maximal &nbsp; &rArr; &nbsp; &nbsp;$ö_{\rm norm}= 1$.
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'''(9)'''&nbsp; Select the settings&nbsp; $M=4 \text{, Matched Filter receiver, }T_{\rm E}/T = 1$, &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; and&nbsp; $12 \ {\rm dB}$.&nbsp; Interpret the results. }}
::*&nbsp;Dagegen nimmt die horizontale Augenöffnung mit &nbsp;$r_f$&nbsp; zu und ist &nbsp;$r_f = 1$&nbsp; maximal gleich &nbsp;$T$ &nbsp; &rArr; &nbsp; Phasenjitter hat in diesem Fall nur geringen Einfluss.
 
  
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::*&nbsp;Now there are three eye openings.&nbsp; Compared to &nbsp;$(5)$&nbsp; &nbsp;$ö_{\rm norm}$&nbsp; is thus smaller by a factor of&nbsp; $3$.&nbsp; $\sigma_{\rm norm}$&nbsp; on the other hand, only by a factor of&nbsp; $\sqrt{5/9)} \approx 0.75$.
'''(8)'''&nbsp; Gleiche Einstellung wie in&nbsp; '''(7)'''. Variieren Sie nun &nbsp;$r_f$&nbsp; im Hinblick auf minimale Fehlerwahrscheinlichkeit. Interpretieren Sie die Ergebnisse.}}
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::*&nbsp;For &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; the&nbsp; (worst&ndash;case)&nbsp; error probability is &nbsp;$p_{\rm U} \approx 2.27\%$&nbsp; and for &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$&nbsp; approx. &nbsp;$0.59\%$.
::*&nbsp;$ö_{\rm norm}= 1$&nbsp; gilt stets.  Dagegen zeigt &nbsp;$\sigma_{\rm norm}$&nbsp; eine leichte Abhängigkeit von &nbsp;$r_f$.&nbsp; DasMinimum &nbsp;$\sigma_{\rm norm}=0.236$&nbsp; ergibt sich für &nbsp;$r_f = 0.9$ &nbsp; &rArr; &nbsp; $p_{\rm U} \approx 1.1 \cdot 10^{-5}.$
 
::*&nbsp;Gegenüber dem bestmöglichen Fall gemäß &nbsp;'''(7)'''&nbsp; &bdquo;Matched&ndash;Filter&ndash;Empfänger&rdquo; ist&nbsp; $p_{\rm U}$&nbsp; dreimal so groß, obwohl &nbsp;$\sigma_{\rm norm}$&nbsp; nur um ca. &nbsp;$5\%$&nbsp; größer ist.
 
::*&nbsp;Der größere &nbsp;$\sigma_{\rm norm}$&ndash;Wert geht auf die Überhöhung des Rausch&ndash;LDS zurück, um den Abfall durch den Sender&ndash;Frequenzgang &nbsp;$H_{\rm S}(f)$&nbsp; auszugleichen.  
 
  
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'''(9)'''&nbsp; Wählen Sie die Einstellungen&nbsp; $M=4 \text{, nach Spalt&ndash;TP, }T_{\rm E}/T = 1$, &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; und&nbsp; $12 \ {\rm dB}$.&nbsp; Interpretieren Sie die Ergebnisse. }}
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'''(10)'''&nbsp; For the remaining tasks, always &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$. Consider the eye pattern&nbsp; ("overall view")&nbsp; for &nbsp;$M=4 \text{, CRO Nyquist system, }r_f = 0.5$. }}
  
::*&nbsp;Es gibt nun drei Augenöffnungen. Gegenüber &nbsp;'''(5)'''&nbsp; ist also &nbsp;$ö_{\rm norm}$&nbsp; um den Faktor&nbsp; $3$&nbsp; kleiner, &nbsp;$\sigma_{\rm norm}$&nbsp; dagegen nur um etwa den Faktor&nbsp; $\sqrt{5/9)} \approx 0.75$.
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::*&nbsp;In the analyzed&nbsp; $d_{\rm S}(t)$&nbsp; region all&nbsp; "five symbol combinations"&nbsp; must be contained &nbsp; &rArr; &nbsp; minimum&nbsp; $4^5 = 1024$&nbsp; parts &nbsp; &rArr; &nbsp; maximum&nbsp; $1024$&nbsp; distinguishable lines.
::*&nbsp;Für &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$&nbsp; ergibt sich nun die Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U}  \approx 2.27\%$&nbsp; und für &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$&nbsp; nur mehr &nbsp;$0.59\%$.
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::*&nbsp;All &nbsp;$1024$&nbsp; eye lines pass through only four points at &nbsp;$t=0$&nbsp;&nbsp; $ö_{\rm norm}= 0.333$.&nbsp; $\sigma_{\rm norm} = 0.143$&nbsp; is slightly larger than in&nbsp; $(9)$&nbsp; &rArr; &nbsp; $p_{\rm U}  \approx 1\%$.
  
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'''(10)'''&nbsp; Für die restlichen Aufgaben gelte stets &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$. Betrachten Sie das Augendiagramm für &nbsp;$M=4 \text{, CRO&ndash;Nyquist, }r_f = 0.5$. }}
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'''(11)'''&nbsp; Select the settings&nbsp; $M=4 \text{, Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$&nbsp; and vary &nbsp;$f_{\rm G}/R_{\rm B}$.&nbsp; Interpret the results. }}
  
::*&nbsp;In&nbsp; $d_{\rm S}(t)$&nbsp; müssen alle &bdquo;Fünf&ndash;'''Symbol'''&ndash;Kombinationen&rdquo; enthalten sein &nbsp; &rArr; &nbsp; mindestens&nbsp; $4^5 = 1024$&nbsp; Teilstücke &nbsp; &rArr; &nbsp; maximal&nbsp; $1024$&nbsp; unterscheidbare Linien.
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::*&nbsp;$f_{\rm G}/R_{\rm B}=0.48$&nbsp; leads to the minimum error probability &nbsp;$p_{\rm U} \approx 0.21\%$.&nbsp; $\text{Compromise between}$ &nbsp;$ö_{\rm norm}= 0.312$&nbsp; and &nbsp;$\sigma_{\rm norm}= 0.109$.
::*&nbsp;Alle &nbsp;$1024$&nbsp; Augenlinien gehen bei &nbsp;$t=0$&nbsp; durch nur vier Punkte: &nbsp;$ö_{\rm norm}= 0.333$.&nbsp;$\sigma_{\rm norm} = 0.143$&nbsp; ist etwas größer als in&nbsp; '''(9)'''&nbsp; &rArr; &nbsp; ebenso &nbsp;$p_{\rm U}  \approx 1\%$.
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::*&nbsp;If the cutoff frequency is too small, intersymbol interference dominates.&nbsp; Example: &nbsp;$f_{\rm G}/R_{\rm B}= 0.3$:&nbsp; $ö_{\rm norm}= 0.157; $&nbsp;$\sigma_{\rm norm}= 0.086$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U}  \approx 3.5\%$.
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::*&nbsp;If the cutoff frequency is too high, noise dominates.&nbsp; Example: &nbsp;$f_{\rm G}/R_{\rm B}= 1.0$:&nbsp; $ö_{\rm norm}= 0.333; $&nbsp;$\sigma_{\rm norm}= 0.157$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U}  \approx 1.7\%$.
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::*&nbsp;From the comparison with&nbsp; $(9)$&nbsp; one can see:&nbsp; $\text{With quaternary coding it is more convenient to allow intersymbol interference}$.
  
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'''(11)'''&nbsp; Wählen Sie die Einstellungen&nbsp; $M=4 \text{, nach Gauß&ndash;TP, }f_{\rm G}/R_{\rm B} = 0.48$&nbsp; und variieren Sie &nbsp;$f_{\rm G}/R_{\rm B}$. &nbsp; Interpretieren Sie die Ergebnisse. }}
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'''(12)'''&nbsp; What differences does the eye pattern show for&nbsp; $M=3 \text{ (AMI code), Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$&nbsp; compared to the binary system&nbsp; $(1)$? Interpretation. }}
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::*&nbsp;The basic detection impulse&nbsp; $g_d(t)$&nbsp; is the same in both cases.&nbsp; The sample values are respectively&nbsp; $g_0 = 0.771, \ g_1 = 0.114$.
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::*&nbsp;With the AMI code, there are two eye openings with each &nbsp;$ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1) = 0.214$.&nbsp; With the binary code:&nbsp; $ö_{\rm norm}= g_0 -2 \cdot g_1 = 0.543$.
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::*&nbsp;The AMI sequence consists of&nbsp; $50\%$&nbsp; zeros.&nbsp; The symbols &nbsp;$+1$&nbsp; and&nbsp; $-1$&nbsp; alternate &nbsp; &rArr; &nbsp; there is no long &nbsp;$+1$&nbsp; sequence and no long &nbsp;$-1$&nbsp; sequence.  
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::*&nbsp;Therein lies the only advantage of the AMI code:&nbsp; This can also be applied to a channel with&nbsp; $H_{\rm K}(f= 0)=0$&nbsp; &rArr; &nbsp; a DC signal is suppressed.
  
::*&nbsp;$f_{\rm G}/R_{\rm B}=0.48$&nbsp; führt zur minimalen Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U}  \approx 0.21\%$.&nbsp; Kompromiss zwischen &nbsp;$ö_{\rm norm}= 0.312$&nbsp; und &nbsp;$\sigma_{\rm norm}= 0.109$.
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::*&nbsp;Bei zu kleiner Grenzfrequenz dominieren die Impulsinterferenzen.&nbsp; Beispiel: &nbsp;$f_{\rm G}/R_{\rm B}= 0.3$:&nbsp; $ö_{\rm norm}= 0.157; $&nbsp;$\sigma_{\rm norm}= 0.086$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U}  \approx 3.5\%$.
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'''(13)'''&nbsp; Same setting as in&nbsp; $(12)$.&nbsp; Select additionally &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$.&nbsp; Analyze the worst-case error probability of the AMI code. }}
::*&nbsp;Bei zu großer Grenzfrequenz dominiert das Rauschen.&nbsp; Beispiel: &nbsp;$f_{\rm G}/R_{\rm B}= 1.0$:&nbsp; $ö_{\rm norm}= 0.333; $&nbsp;$\sigma_{\rm norm}= 0.157$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U} \approx 1.7\%$.
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::*&nbsp;Despite smaller &nbsp;$\sigma_{\rm norm} = 0.103$&nbsp; the AMI code has higher error probability &nbsp;$p_{\rm U} \approx 2\%$&nbsp; than the binary code: &nbsp;$\sigma_{\rm norm} = 0.146, \ p_{\rm U}  \approx \cdot 10^{-4}.$
::*&nbsp;Aus dem Vergleich mit&nbsp; '''(9)'''&nbsp; erkennt man:&nbsp; '''Bei Quaternärcodierung ist es günstiger, Impulsinterferenzen zuzulassen'''.  
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::*&nbsp;$f_{\rm G}/R_{\rm B}<0.34$&nbsp; results in a closed eye &nbsp;$(ö_{\rm norm}= 0)$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U} =50\%$.&nbsp; With binary coding:&nbsp; For &nbsp;$f_{\rm G}/R_{\rm B}>0.34$&nbsp; the eye is open.
  
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'''(12)'''&nbsp; Welche Unterschiede zeigt das Auge für&nbsp; $M=3 \text{ (AMI-Code), nach Gauß&ndash;TP, }f_{\rm G}/R_{\rm B} = 0.48$&nbsp; gegenüber dem vergleichbaren Binärsystem? Interpretation. }}
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'''(14)'''&nbsp; What differences does the eye pattern show for&nbsp; $M=3 \text{ (Duobinary code), Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.30$&nbsp; compared to the binary system&nbsp; '''(1)'''?  }}
::*&nbsp;Der Detektionsgrundimpuls&nbsp; $g_d(t)$&nbsp; ist in beiden Fällen gleich. Die Abtastwerte sind jeweils&nbsp; $g_0 = 0.771, \ g_1 = 0.114$.
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::*&nbsp;With redundancy-free binary code:&nbsp; $ö_{\rm norm}= 0.096, \ \sigma_{\rm norm} = 0.116 \ p_{\rm U} \approx 20\% $. &nbsp; With Duobinary code:&nbsp; $ö_{\rm norm}= 0.167, \ \sigma_{\rm norm} = 0.082 \ p_{\rm U} \approx 2\% $.
::*&nbsp;Beim AMI&ndash;Code gibt es zwei Augenöffnungen mit je &nbsp;$ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1) = 0.214$.&nbsp; Beim Binärcode:&nbsp;  $ö_{\rm norm}= g_0 -2 \cdot g_1 = 0.543$.
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::*In particular, with small &nbsp;$f_{\rm G}/R_{\rm B}$&nbsp; the Duobinary code gives good results, since the transitions from &nbsp;$+1$&nbsp; to &nbsp;$-1$&nbsp; (and vice versa) are absent in the eye pattern.
::*&nbsp;Die AMI&ndash;Folge besteht zu 50% aus Nullen. Die Symbole &nbsp;$+1$&nbsp; und&nbsp; $-1$&nbsp; wechseln sich ab &nbsp; &rArr; &nbsp; es gibt keine lange &nbsp;$+1$&ndash;Folge und keine lange &nbsp;$-1$&ndash;Folge.  
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::*Even with &nbsp;$f_{\rm G}/R_{\rm B}=0.2$&nbsp; the eye is open.&nbsp; But in contrast to AMI&nbsp; the Duobinary code is not applicable with a DC-free channel &nbsp; &rArr; &nbsp; $H_{\rm K}(f= 0)=0$.
::*&nbsp;Darin liegt der einzige Vorteil des AMI&ndash;Codes:&nbsp; Dieser kann auch bei einem gleichsignalfreien Kanal &nbsp; &rArr; &nbsp; $H_{\rm K}(f= 0)=0$&nbsp; angewendet werden.
 
 
 
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'''(13)'''&nbsp; Gleiche Einstellung wie in&nbsp; '''(12)''', zudem &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$. Analysieren Sie die Fehlerwahrscheinlichkeit des AMI&ndash;Codes. }}
 
::*&nbsp;Trotz kleinerem &nbsp;$\sigma_{\rm norm} = 0.103$&nbsp; hat der AMI&ndash;Code eine höhere Fehlerwahrscheinlichkeit &nbsp;$p_{\rm U}  \approx 2\%$&nbsp; als der Binärcode: &nbsp;$\sigma_{\rm norm} = 0.146, \ p_{\rm U}  \approx \cdot 10^{-4}.$
 
::*&nbsp;Für &nbsp;$f_{\rm G}/R_{\rm B}<0.34$&nbsp; ergibt sich ein geschlossenes Auge &nbsp;$(ö_{\rm norm}= 0)$&nbsp; &rArr; &nbsp; &nbsp;$p_{\rm U} =50\%$. Beim Binärcode:&nbsp; Für &nbsp;$f_{\rm G}/R_{\rm B}>0.34$&nbsp; ist das Auge geöffnet.
 
  
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'''(14)'''&nbsp; Welche Unterschiede zeigt das Auge für&nbsp; $M=3 \text{ (Duobinärcode), nach Gauß&ndash;TP, }f_{\rm G}/R_{\rm B} = 0.30$&nbsp; gegenüber dem vergleichbaren Binärsystem?  }}
 
::*&nbsp;Redundanzfreier Binärcode:&nbsp; $ö_{\rm norm}= 0.096, \  \sigma_{\rm norm} = 0.116 \ p_{\rm U} \approx 20\% $ &nbsp; &nbsp; &nbsp; Duobinärcode:&nbsp; $ö_{\rm norm}= 0.167, \  \sigma_{\rm norm} = 0.082 \ p_{\rm U} \approx 2\% $.
 
::*Insbesondere bei kleinem &nbsp;$f_{\rm G}/R_{\rm B}$&nbsp; liefert der Duobinärcode gute Ergebnisse, da die Übergänge von &nbsp;$+1$&nbsp; nach &nbsp;$-1$&nbsp; (und umgekehrt) im Auge fehlen.
 
::*Selbst mit &nbsp;$f_{\rm G}/R_{\rm B}=0.2$&nbsp; ist das Auge noch geöffnet. Im Gegensatz zum AMI&ndash;Code&nbsp; ist aber &bdquo;Duobinär&rdquo; bei gleichsignalfreiem Kanal nicht anwendbar.
 
  
 
==Applet Manual==
 
==Applet Manual==
 
<br>
 
<br>
[[Datei:Anleitung_Auge.png|right|600px]]
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[[File:Anleitung_Auge.png|right|600px|frame|Screenshot of the German version]]
&nbsp; &nbsp; '''(A)''' &nbsp; &nbsp; Auswahl: &nbsp; Codierung <br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(binär,&nbsp; quaternär,&nbsp; AMI&ndash;Code,&nbsp; Duobinärcode)  
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&nbsp; &nbsp; '''(A)''' &nbsp; &nbsp; Selection: &nbsp; Encoding <br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(binary,&nbsp; quaternary,&nbsp; AMI code,&nbsp; duobinary code)  
  
&nbsp; &nbsp; '''(B)''' &nbsp; &nbsp; Auswahl: &nbsp; Detektionsgrundimpuls<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; (nach Gauß&ndash;TP,&nbsp; CRO&ndash;Nyquist,&nbsp; nach Spalt&ndash;TP}
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&nbsp; &nbsp; '''(B)''' &nbsp; &nbsp; Selection: &nbsp; Basic detection pulse<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; (according to Gauss&ndash;TP,&nbsp; CRO&ndash;Nyquist,&nbsp; according to gap&ndash;TP}
  
&nbsp; &nbsp; '''(C)''' &nbsp; &nbsp; Prametereingabe zu&nbsp; '''(B)'''<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(Grenzfrequenz,&nbsp; Rolloff&ndash;Faktor,&nbsp; Rechteckdauer)   
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&nbsp; &nbsp; '''(C)''' &nbsp; &nbsp; Parameter input for&nbsp; '''(B)'''<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(cutoff frequency,&nbsp; rolloff factor,&nbsp; rectangular duration)   
  
&nbsp; &nbsp; '''(D)''' &nbsp; &nbsp; Steuerung der Augendiagrammdarstellung<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(Start,&nbsp; Pause/Weiter,&nbsp; Einzelschritt,&nbsp; Gesamt,&nbsp; Reset)
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&nbsp; &nbsp; '''(D)''' &nbsp; &nbsp; Control of the eye diagram display<br>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;(start,&nbsp; pause/continue,&nbsp; single step,&nbsp; total,&nbsp; reset)
  
&nbsp; &nbsp; '''(E)''' &nbsp; &nbsp; Geschwindigkeit der Augendiagrammdarstellung
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&nbsp; &nbsp; '''(E)''' &nbsp; &nbsp; Speed of the eye diagram display
  
&nbsp; &nbsp; '''(F)''' &nbsp; &nbsp; Darstellung:&nbsp; Detektionsgrundimpuls &nbsp;$g_d(t)$  
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&nbsp; &nbsp; '''(F)''' &nbsp; &nbsp; Display:&nbsp; basic detection pulse &nbsp;$g_d(t)$  
  
&nbsp; &nbsp; '''(G)''' &nbsp; &nbsp; Darstellung:&nbsp; Detektionsnutzsignal &nbsp;$d_{\rm S}(t - \nu \cdot T)$
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&nbsp; &nbsp; '''(G)''' &nbsp; &nbsp; Display:&nbsp; detection useful signal &nbsp;$d_{\rm S}(t - \nu \cdot T)$
  
&nbsp; &nbsp; '''(H)''' &nbsp; &nbsp; Darstellung:&nbsp; Augendiagramm im Bereich &nbsp;$\pm T$
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&nbsp; &nbsp; '''(H)''' &nbsp; &nbsp; Display:&nbsp; eye diagram in the range &nbsp;$\pm T$
  
&nbsp; &nbsp; '''( I )''' &nbsp; &nbsp; Numerikausgabe:&nbsp; $ö_{\rm norm}$&nbsp; (normierte Augenöffnung)   
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&nbsp; &nbsp; '''( I )''' &nbsp; &nbsp; Numerical output:&nbsp; $ö_{\rm norm}$&nbsp; (normalized eye opening)   
  
&nbsp; &nbsp; '''(J)''' &nbsp; &nbsp; Prametereingabe &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$&nbsp; für&nbsp; '''(K)'''
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&nbsp; &nbsp; '''(J)''' &nbsp; &nbsp; Parameter input &nbsp;$10 \cdot \lg \ E_{\rm B}/N_0$&nbsp; for&nbsp; '''(K)'''
  
&nbsp; &nbsp; '''(K)''' &nbsp; &nbsp; Numerikausgabe:&nbsp; $\sigma_{\rm norm}$&nbsp; (normierter Rauscheffektivwert)
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&nbsp; &nbsp; '''(K)''' &nbsp; &nbsp; Numerical output:&nbsp; $\sigma_{\rm norm}$&nbsp; (normalized noise rms)
  
&nbsp; &nbsp; '''(L)''' &nbsp; &nbsp; Numerikausgabe:&nbsp; $p_{\rm U}$&nbsp; (ungünstigste Fehlerwahrscheinlichkeit)
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&nbsp; &nbsp; '''(L)''' &nbsp; &nbsp; Numerical output:&nbsp; $p_{\rm U}$&nbsp; (worst-case error probability)
  
&nbsp; &nbsp; '''(M)''' &nbsp; &nbsp; Bereich für die Versuchsdurchführung: &nbsp;  Aufgabenauswahl
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&nbsp; &nbsp; '''(M)''' &nbsp; &nbsp; Range for experimental performance: &nbsp;  task selection
  
&nbsp; &nbsp; '''(N)''' &nbsp; &nbsp; Bereich für die Versuchsdurchführung: &nbsp;  Aufgabenstellung
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&nbsp; &nbsp; '''(N)''' &nbsp; &nbsp; Range for experimental performance: &nbsp;  task description
  
&nbsp; &nbsp; '''(O)''' &nbsp; &nbsp; Bereich für die Versuchsdurchführung: &nbsp;  Musterlösung einblenden
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&nbsp; &nbsp; '''(O)''' &nbsp; &nbsp; Range for experimental performance: &nbsp;  Show sample solution
 
<br clear=all>
 
<br clear=all>
 
==About the Authors==
 
==About the Authors==
Dieses interaktive Berechnungstool  wurde am&nbsp; [http://www.lnt.ei.tum.de/startseite Lehrstuhl für Nachrichtentechnik]&nbsp; der&nbsp; [https://www.tum.de/ Technischen Universität München]&nbsp; konzipiert und realisiert.
 
*Die erste Version wurde 2008 von&nbsp; [[Biografien_und_Bibliografien/An_LNTwww_beteiligte_Studierende#Thomas_Gro.C3.9Fer_.28Diplomarbeit_LB_2006.2C_danach_freie_Mitarbeit_bis_2010.29|Thomas Großer]]&nbsp; im Rahmen einer Werkstudententätigkeit mit &bdquo;FlashMX&ndash;Actionscript&rdquo; erstellt (Betreuer:&nbsp; [[Biografien_und_Bibliografien/An_LNTwww_beteiligte_Mitarbeiter_und_Dozenten#Prof._Dr.-Ing._habil._G.C3.BCnter_S.C3.B6der_.28am_LNT_seit_1974.29|Günter Söder]]).
 
* 2019 wurde das Programm  von&nbsp; [[Biografien_und_Bibliografien/An_LNTwww_beteiligte_Studierende#Carolin_Mirschina_.28Ingenieurspraxis_Math_2019.2C_danach_Werkstudentin.29|Carolin Mirschina]]&nbsp; im Rahmen einer Werkstudententätigkeit auf  &bdquo;HTML5&rdquo; umgesetzt und neu gestaltet (Betreuer:&nbsp; [[Biografien_und_Bibliografien/Beteiligte_der_Professur_Leitungsgebundene_%C3%9Cbertragungstechnik#Tasn.C3.A1d_Kernetzky.2C_M.Sc._.28bei_L.C3.9CT_seit_2014.29|Tasnád Kernetzky]]).
 
  
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This interactive calculation tool was designed and implemented at the&nbsp; [https://www.ei.tum.de/en/lnt/home/ Institute for Communications Engineering]&nbsp; at the&nbsp; [https://www.tum.de/en Technical University of Munich].
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*The first version was created in 2008 by [[Biographies_and_Bibliographies/Students_involved_in_LNTwww#Thomas_Gro.C3.9Fer_.28Diplomarbeit_LB_2006.2C_danach_freie_Mitarbeit_bis_2010.29|Thomas Großer]]&nbsp; as part of his diploma thesis with “FlashMX – Actionscript” (Supervisor: [[Biographies_and_Bibliographies/LNTwww_members_from_LNT#Prof._Dr.-Ing._habil._G.C3.BCnter_S.C3.B6der_.28am_LNT_seit_1974.29|Günter Söder]]).
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*Last revision and English version 2020/2021 by&nbsp; [[Biographies_and_Bibliographies/Students_involved_in_LNTwww#Carolin_Mirschina_.28Ingenieurspraxis_Math_2019.2C_danach_Werkstudentin.29|Carolin Mirschina]]&nbsp; in the context of a working student activity.&nbsp;
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The conversion of this applet to HTML 5 was financially supported by&nbsp; [https://www.ei.tum.de/studium/studienzuschuesse/ Studienzuschüsse]&nbsp; ("study grants")&nbsp; of the TUM Faculty EI.&nbsp; We thank.
  
Die Umsetzung dieses Applets auf HTML 5 wurde durch&nbsp; [https://www.ei.tum.de/studium/studienzuschuesse/ Studienzuschüsse]&nbsp; der Fakultät EI der TU München finanziell unterstützt. Wir bedanken uns.
 
  
  
 
==Once again: Open Applet in new Tab==
 
==Once again: Open Applet in new Tab==
 
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{{LntAppletLinkEnDe|eyeDiagram_en|eyeDiagram}}
{{LntAppletLink|eyeDiagram}}
 

Latest revision as of 15:06, 17 January 2024

Open Applet in new Tab   Deutsche Version Öffnen

Applet Description


The applet illustrates the eye pattern for different encodings 

  • binary  (redundancy-free), 
  • quaternary  (redundancy-free),
  • pseudo–ternary:  (AMI and duobinary) 


and for various reception concepts 

  • Matched Filter receiver, 
  • CRO Nyquist system, 
  • Gaussian low-pass filter.


The last reception concept leads to intersymbol interference, that is:  Neighboring symbols interfere with each other in symbol decision.

Such intersymbol interferences and their influence on the error probability can be captured and quantified very easily by the "eye pattern".  But also for the other two (without intersymbol interference) systems important insights can be gained from the graphs.

Furthermore, the most unfavorable ("worst case") error probability  

$$p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$$

is output, which for binary Nyquist systems is identical to the mean error probability  $p_{\rm M}$  and represents a suitable upper bound for the other system variants:  $p_{\rm U} \ge p_{\rm M}$.

In the  $p_{\rm U}$–equation mean:

  • ${\rm Q}(x)$  is the  "Complementary Gaussian Error Function".  The normalized eye opening can have values between  $0 \le ö_{\rm norm} \le 1$  .
  • The maximum value  $(ö_{\rm norm} = 1)$  applies to the binary Nyquist system and  $ö_{\rm norm}=0$  represents a "closed eye".
  • The normalized detection noise rms value  $\sigma_{\rm norm}$  depends on the adjustable parameter  $10 \cdot \lg \ E_{\rm B}/N_0$  but also on the coding and the receiver concept.


Theoretical Background



System description and prerequisites

The binary baseband transmission model outlined below applies to this applet. First, the following prerequisites apply:

  • The transmission is binary, bipolar, and redundancy-free with bit rate  $R_{\rm B} = 1/T$, where  $T$  is the symbol duration.
  • The transmitted signal  $s(t)$  is equal to  $ \pm s_0$   at all times  $t$  ⇒   The basic transmission pulse  $g_s(t)$  is NRZ–rectangular with amplitude  $s_0$  and pulse duration  $T$.
  • Let the received signal be  $r(t) = s(t) + n(t)$, where the AWGN term  $n(t)$  is characterized by the (one-sided) noise power density  $N_0$. 
  • Let the channel frequency response be best possible (ideal) and need not be considered further:  $H_{\rm K}(f) =1$.
  • The receiver filter with the impulse response  $h_{\rm E}(t)$  forms the detection signal  $d(t) = d_{\rm S}(t)+ d_{\rm N}(t)$ from  $r(t)$. 
  • This is evaluated by the decision with the decision threshold  $E = 0$  at the equidistant times  $\nu \cdot T$. 
  • A distinction is made between the signal component  $d_{\rm S}(t)$  – originating from  $s(t)$  – and the noise component  $d_{\rm N}(t)$,  whose cause is the AWGN noise  $n(t)$. 
  • $d_{\rm S}(t)$  can be represented as a weighted sum of weighted basic detection pulses  $T$,  each shifted by  $g_d(t) = g_s(t) \star h_{\rm E}(t)$. 
  • To calculate the (average) error probability, one further needs the variance  $\sigma_d^2 = {\rm E}\big[d_{\rm N}(t)^2\big]$  of the detection noise component (for AWGN noise).


Optimal intersymbol interference-free system – matched filter receiver

The minimum error probability results for the case considered here  $H_{\rm K}(f) =1$  with the matched filter receiver, i.e. when  $h_{\rm E}(t)$  is equal in shape to the NRZ basic transmission pulse  $g_s(t)$.  The rectangular impulse response  $h_{\rm E}(t)$  then has duration  $T_{\rm E} = T$  and height  $1/T$.

Binary baseband transmission system
  Note:  The sketch for  $h_{\rm E}(t)$  applies only to the matched filter receiver
  • The basic detection pulse  $g_d(t)$  is triangular with maximum  $s_0$  at  $t=0$ ;  $g_d(t)=0$  for  $|t| \ge T$. Due to this tight temporal constraint, there is no intersymbol interference   ⇒   $d_{\rm S}(t = \nu \cdot T) = \pm s_0$   ⇒   the distance of all useful samples from the threshold  $E = 0$  is always  $|d_{\rm S}(t = \nu \cdot T)| = s_0$.
  • The detection noise power for this constellation is:
$$\sigma_d^2 = N_0/2 \cdot \int_{-\infty}^{+\infty} |h_{\rm E}(t)|^2 {\rm d}t = N_0/(2T)=\sigma_{\rm MF}^2.$$
$$p_{\rm M} = {\rm Q}\left[\sqrt{{s_0^2}/{\sigma_d^2}}\right ] = {\rm Q}\left[\sqrt{{2 \cdot s_0^2 \cdot T}/{N_0}}\right ] = {\rm Q}\left[\sqrt{2 \cdot E_{\rm B}/ N_0}\right ].$$

The applet considers this case with the settings  "after gap–low-pass"  as well as  $T_{\rm E}/T = 1$. The output values are with regard to later constellations

  • the normalized eye opening  $ö_{\rm norm} =1$   ⇒   this is the maximum possible value,
  • the normalized detection noise rms value (equal to the square root of the detection noise power)  $\sigma_{\rm norm} =\sqrt{1/(2 \cdot E_{\rm B}/ N_0)}$  as well as
  • the worst-case error probability  $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$   ⇒   for intersymbol interference-free systems,   $p_{\rm M}$  and   $p_{\rm U}$  agree.


$\text{Differences in the multi-level systems}$

  • There are  $M\hspace{-0.1cm}-\hspace{-0.1cm}1$ eyes and just as many thresholds   ⇒   $ö_{\rm norm} =1/(M\hspace{-0.1cm}-\hspace{-0.1cm}1)$  ⇒   $M=4$:  quaternary system,  $M=3$:  AMI code, duobinary code.
  • The normalized detection noise rms value  $\sigma_{\rm norm}$  is smaller by a factor of  $\sqrt{5/9} \approx 0.745$  for the quaternary system than for the binary system.
  • For the AMI code and the duobinary code, this improvement factor, which goes back to the smaller  $E_{\rm B}/ N_0$,  has the value  $\sqrt{1/2} \approx 0.707$.


Nyquist system with raised cosine overall frequency response

Raised cosine overall frequency response

We assume that the overall frequency response between the Dirac-shaped source to the decision has the shape of a  "raised cosine low-pass"    ⇒   $H_{\rm S}(f)\cdot H_{\rm E}(f) = H_{\rm CRO}(f)$ .

  • The rolloff of  $H_{\rm CRO}(f)$  is point symmetric about the Nyquist frequency  $1/(2T)$. The larger the rolloff factor  $r_{ \hspace {-0.05cm}f}$,  ithe flatter the Nyquist slope.
  • The basic detection pulse  $g_d(t) = s_0 \cdot T \cdot {\mathcal F}^{-1}\big[H_{\rm CRO}(f)\big]$  has zeros at times  $\nu \cdot T$  independent of  $r_{ \hspace {-0.05cm}f}$.  There are further zero crossings depending on  $r_{ \hspace {-0.05cm}f}$.  For the pulse holds:
$$g_d(t) = s_0 \hspace{-0.05cm}\cdot\hspace{-0.05cm} {\rm sinc}( t/T )\hspace{-0.05cm}\cdot\hspace{-0.05cm}\frac {\cos(\pi \cdot r_{\hspace{-0.05cm}f} \cdot t/T )}{1 - (2 \cdot r_{\hspace{-0.05cm}f} \cdot t/T)^2}.$$
  • It follows:  As with the matched filter receiver, the eye is maximally open   ⇒   $ö_{\rm norm} =1$.
Optimizing the rolloff factor

Let us now consider the noise power before the decision. For this holds:

$$\sigma_d^2 = N_0/2 \cdot \int_{-\infty}^{+\infty} |H_{\rm E}(f)|^2 {\rm d}f = N_0/2 \cdot \int_{-\infty}^{+\infty} \frac{|H_{\rm CRO}(f)|^2}{|H_{\rm S}(f)|^2} {\rm d}f.$$

The graph shows the power transfer function  $|H_{\rm E}(f)|^2$  for three different rolloff factors

  • $r_{ \hspace {-0.05cm}f}=0$   ⇒   green curve,
  • $r_{ \hspace {-0.05cm}f}=1$   ⇒   red curve,
  • $r_{ \hspace {-0.05cm}f}=0.8$   ⇒   blue curve.


The areas under these curves are each a measure of the noise power  $\sigma_d^2$.  The rectangle with a gray background marks the smallest value  $\sigma_d^2 =\sigma_{\rm MF}^2$, which also resulted with the matched filter receiver.
One can see from this plot:

  • The rolloff factor  $r_{\hspace{-0.05cm}f} = 0$  (rectangular frequency response) leads to  $\sigma_d^2 =K \cdot \sigma_{\rm MF}^2$  with  $K \approx 1.5$ despite the very narrow receiver filter, since  $|H_{\rm E}(f)|^2$  increases steeply as  $f$  increases. The reason for this noise power increase is the  $\rm sinc^2(f T)$  function in the denominator, which is required to compensate for the  $|H_{\rm S}(f)|^2$–decay.
  • Since the area under the red curve is smaller than that under the green curve,  $r_{\hspace{-0.05cm}f} = 1$  leads to a smaller noise power despite a spectrum twice as wide:  $K \approx 1.23$.  For  $r_{\hspace{-0.05cm}f} \approx 0.8$, a slightly better value results. For this, the best possible compromise between bandwidth and excess noise is achieved.
  • The normalized detection noise rms value is thus for the rolloff factor  $r_{ \hspace {-0.05cm}f}$:   $\sigma_{\rm norm} =\sqrt{K(r_f)/(2 \cdot E_{\rm B}/ N_0)}$.
  • Again, the worst-case error probability  $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$   coincides exactly with the mean error probability  $p_{\rm M}$. 


$\text{Differences in the multi-level systems}$

All remarks in section $2.2$ apply in the same way to the "Nyquist system with raised cosine total frequency response".


Intersymbol interference system with Gaussian receiver filter

System with Gaussian receiver filter

We start from the block diagram sketched on the right. Further it shall be valid:

  • Rectangular NRZ basic transmission pulse  $g_s(t)$  with height  $s_0$  and duration  $T$:
$$H_{\rm S}(f) = {\rm sinc}(f T).$$
  • Gaussian receiver filter with cutoff frequency  $f_{\rm G}$:
$$H_{\rm E}(f) = H_{\rm G}(f) = {\rm e}^{- \pi \hspace{0.05cm}\cdot \hspace{0.03cm} f^2/(2\hspace{0.05cm}\cdot \hspace{0.03cm}f_{\rm G})^2 } \hspace{0.2cm} \bullet\!\!-\!\!\!-\!\!\!-\!\!\circ \hspace{0.2cm}h_{\rm E}(t) = h_{\rm G}(t) = {\rm e}^{- \pi \cdot (2\hspace{0.05cm}\cdot \hspace{0.03cm} f_{\rm G}\hspace{0.05cm}\cdot \hspace{0.02cm} t)^2} \hspace{0.05cm}.$$

Based on the assumptions made here, the following applies to the basic detection pulse:

Frequency response and impulse response of the receiver filter
$$g_d(t) = s_0 \cdot T \cdot \big [h_{\rm S}(t) \star h_{\rm G}(t)\big ] = 2 f_{\rm G} \cdot s_0 \cdot \int_{t-T/2}^{t+T/2} {\rm e}^{- \pi \hspace{0.05cm}\cdot\hspace{0.05cm} (2 \hspace{0.05cm}\cdot\hspace{0.02cm} f_{\rm G}\hspace{0.05cm}\cdot\hspace{0.02cm} \tau )^2} \,{\rm d} \tau \hspace{0.05cm}.$$

The integration leads to the result:

$$g_d(t) = s_0 \cdot \big [ {\rm Q} \left ( 2 \cdot \sqrt {2 \pi} \cdot f_{\rm G}\cdot ( t - {T}/{2})\right )- {\rm Q} \left ( 2 \cdot \sqrt {2 \pi} \cdot f_{\rm G}\cdot ( t + {T}/{2} )\right ) \big ],$$

using the complementary Gaussian error function

$${\rm Q} (x) = \frac{\rm 1}{\sqrt{\rm 2\pi}}\int_{\it x}^{+\infty}\rm e^{\it -u^{\rm 2}/\rm 2}\,d {\it u} \hspace{0.05cm}.$$

The module  "Complementary Gaussian Error Functions"  provides the numerical values of  ${\rm Q} (x)$.

  • This basic detection pulse causes  "intersymbol interference".
  • This is understood to mean that the symbol decision is influenced by the spurs of neighboring pulses. While in intersymbol interference free transmission systems each symbol is falsified with the same probability – namely the mean error probability  $p_{\rm M}$  – there are favorable symbol combinations with the falsification probability  ${\rm Pr}(v_{\nu} \ne q_{\nu}) < p_{\rm M}$.
  • In contrast, other symbol combinations increase the falsification probability significantly.


Binary eye $($Gaussian low-pass,  $f_{\rm G}/R_{\rm B} = 0.35)$.

The intersymbol interferences can be captured and analyzed very easily by the so-called  eye diagram.  These are the focus of this applet. All important information can be found  "here".

  • The eye diagram is created by drawing all sections of the detection useful signal  $d_{\rm S}(t)$  of length  $2T$  on top of each other. You can visualize the formation in the program with "single step".
  • A measure for the strength of the intersymbol interference is the vertical eye opening. For the symmetric binary case, with  $g_\nu = g_d(\pm \nu \cdot T)$  and appropriate normalization:
$$ ö_{\rm norm} = g_0 -2 \cdot (|g_1| + |g_2| + \text{...}).$$
  • With larger cutoff frequency, the pulses interfere less and  $ ö_{\rm norm}$  increases continuously. At the same time, with larger  $f_{\rm G}/R_{\rm B}$,  the (normalized) detection noise rms value also becomes larger:
$$ \sigma_{\rm norm} = \sqrt{\frac{f_{\rm G}/R_{\rm B}}{\sqrt{2} \cdot E_{\rm B}/N_{\rm 0}}}.$$
  • The worst-case error probability  $p_{\rm U} = {\rm Q}\left[ö_{\rm norm}/\sigma_{\rm norm} \right ]$   ⇒   "Worst Case" is usually significantly higher than the mean error probability  $p_{\rm M}$.


$\text{Differences in the redundancy-free quaternary system}$

  • For  $M=4$,  other basic pulse values result.
    Example:     With  $M=4, \ f_{\rm G}/R_{\rm B}=0.4$  basic pulse values  $g_0 = 0.955, \ g_1 = 0.022$  are identical with  $M=2, \ f_{\rm G}/R_{\rm B}=0.8$.
  • There are now three eye openings and just as many thresholds.  The equation for the normalized eye opening is now:   $ ö_{\rm norm} = g_0/3 -2 \cdot (|g_1| + |g_2| + \text{...}).$
  • The normalized detection noise rms  $\sigma_{\rm norm}$  is again a factor of  $\sqrt{5/9} \approx 0.745$  smaller for the quaternary system than for the binary system.


Pseudo-ternary codes

In symbolwise coding, each incoming source symbol  $q_\nu$  generates an encoder symbol  $c_\nu$  that depends not only on the current input symbol  $q_\nu$  but also on the  $N_{\rm C}$  preceding symbols  $q_{\nu-1}$, ... , $q_{\nu-N_{\rm C}} $.   $N_{\rm C}$  is referred to as the order  of the code.  It is typical for a symbolwise coding that

Block diagram and equivalent circuit of a pseudo-ternary encoder
  • the symbol duration  $T$  of the encoded signal (and of the transmitted signal) coincides with the bit duration  $T_{\rm B}$  of the binary source signal, and
  • coding and decoding do not lead to major time delays, which are unavoidable when block codes are used.


Special importance has pseudo-ternary codes   ⇒   level number  $M = 3$, which can be described by the block diagram according to the left graphic. In the right graphic an equivalent circuit is given, which is very suitable for an analysis of these codes. More details can be found in the  "$\rm LNTwww$ theory section".  Conclusion:

  • Recoding from binary  $(M_q = 2)$  to ternary  $(M = M_c = 3)$:
$$q_\nu \in \{-1, +1\},\hspace{0.5cm} c_\nu \in \{-1, \ 0, +1\}\hspace{0.05cm}.$$
  • The relative code redundancy is the same for all pseudo-ternary codes:
$$ r_c = 1 -1/\log_2\hspace{0.05cm}(3) \approx 36.9 \%\hspace{0.05cm}.$$

Based on the code parameter  $K_{\rm C}$,  different first-order pseudo-ternary codes  $(N_{\rm C} = 1)$  are characterized.


Signals in AMI coding

$\Rightarrow \ \ K_{\rm C} = 1\text{: AMI code}$  (from:   Alternate Mark Inversion)

The graph shows the binary source signal  $q(t)$ at the top. Below are shown:

  • the likewise binary signal  $b(t)$  after the pre-encoder, and
  • the encoded signal  $c(t) = s(t)$  of the AMI code.


One can see the simple AMI coding principle:

  • Each binary value  "–1"  of $q(t)$   ⇒   symbol  $\rm L$  is encoded by the ternary amplitude coefficient  $a_\nu = 0$. 
  • The binary value  "+1"  of  $q(t)$   ⇒   symbol  $\rm H$  is alternately represented by  $a_\nu = +1$  and  $a_\nu = -1$. 

This ensures that there are no long  "+1"–  or  "–1" sequences in the AMI-encoded signal, which would be problematic for an DC signal-free channel. 

EN Auge 16a.png


The eye diagram is shown on the left.

  •  There are two eye openings and two thresholds.
  •  The normalized eye opening is  $ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1)$, where  $g_0 = g_d(t=0)$  denotes the main value of the basic detection pulse and  $g_1 = g_d(t=\pm T)$  denotes the relevant precursors and postcursors that vertically limit the eye.
  •  The normalized eye opening is thus significantly smaller than for the comparable binary system   ⇒   $ö_{\rm norm}= g_0 -2 \cdot g_1$.
  •  The normalized noise rms  $\sigma_{\rm norm}$  is smaller than for the comparable binary system by a factor of  $\sqrt{1/2} \approx 0.707$. 


Signals in duobinary coding

$\Rightarrow \ \ K_{\rm C} = -1\text{: duobinary code}$ 

From the right graph with the signal curves one recognizes:

  • Here, any number of symbols of the same polarity  ("+1" or "–1")  can directly follow each other   ⇒   the duobinary code is not free of DC signals. 
  • In contrast, the alternating sequence  " ... , +1, –1, +1, –1, +1, ... "  does not occur, which is particularly disturbing with regard to intersymbol interference.
  •  Also the duobinary encoded sequence consists to 50% of zeros. The enhancement factor due to the smaller  $E_{\rm B}/ N_0$  is equal to  $\sqrt{1/2} \approx 0.707$, as in the AMI code.
EN Auge 17a.png


The eye diagram is shown on the left.

  •  There are again two "eyes" and two thresholds.
  •  The eye opening is   $ö_{\rm norm}= 1/2 \cdot (g_0 - g_1)$.
  • $ö_{\rm norm}$  is thus larger than in the AMI code and also as in the comparable binary system.
  • A disadvantage compared to the AMI code, however, is that it is not DC signal-free.



Exercises

  • First select the number  $(1,\ 2, \text{...})$  of the exercise.  The number  $0$  corresponds to a "Reset":  Same setting as at program start.
  • A task description is displayed.  The parameter values ​​are adjusted.  Solution after pressing "Show solution".


(1)  Explain the occurrence of the eye pattern for  $M=2 \text{, Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$. For this, select "step–by–step".

  •  The eye pattern is obtained by dividing the "useful" signal  $d_{\rm S}(t)$  (without noise) into pieces of duration  $2T$  and drawing these pieces on top of each other.
  •  In  $d_{\rm S}(t)$  all  "five bit combinations"  must be contained   ⇒   at least  $2^5 = 32$  pieces   ⇒   at most  $32$  distinguishable lines.
  •  The eye pattern evaluates the transient response of the signal.  The larger the (normalized) eye opening, the smaller are the intersymbol interferences.

(2)  Same setting as in  $(1)$. In addition,  $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$.  Evaluate the output characteristics  $ö_{\rm norm}$,  $\sigma_{\rm norm}$,  and  $p_{\rm U}$.

  •  $ö_{\rm norm}= 0.542$  indicates that symbol detection is affected by adjacent pulses. For binary systems without intersymbol interference:  $ö_{\rm norm}= 1$.
  •  The eye opening indicates only the signal  $d_{\rm S}(t)$  without noise.  The noise influence is captured by  $\sigma_{\rm norm}= 0.184$ . This value should be as small as possible.
  •  The error probability  $p_{\rm U} = {\rm Q}(ö_{\rm norm}/\sigma_{\rm norm}\approx 0.16\%)$  refers solely to the "worst-case sequences", for Gaussian low–pass e.g.  $\text{...}\ , -1, -1, +1, -1, -1, \text{...}$.
  •  Other sequences are less distorted   ⇒   the mean error probability  $p_{\rm M}$  is (usually) significantly smaller than $p_{\rm U}$  (describing the worst case).

(3)  The last settings remain.  With which  $f_{\rm G}/R_{\rm B}$  value does the worst case error probability  $p_{\rm U}$  become minimal?  Consider also the eye pattern.

  •  The minimum value  $p_{\rm U, \ min} \approx 0.65 \cdot 10^{-4}$  is obtained for  $f_{\rm G}/R_{\rm B} \approx 0.8$, and this is almost independent of the setting of  $10 \cdot \lg \ E_{\rm B}/N_0$.
  •  The normalized noise rms value does increase compared to the experiment  $(2)$  from  $\sigma_{\rm norm}= 0.168$  to  $\sigma_{\rm norm}= 0.238$.
  •  However, this is more than compensated by the larger eye opening  $ö_{\rm norm}= 0.91$  compared to  $ö_{\rm norm}= 0.542$  $($magnification factor $\approx 1.68)$.

(4)  Which cutoff frequencies  $(f_{\rm G}/R_{\rm B})$  result in a completely inadequate error probability  $p_{\rm U} \approx 50\%$ ? Look at the eye pattern again  ("Overall view").

  •  For  $f_{\rm G}/R_{\rm B}<0.28$  we get a "closed eye"  $(ö_{\rm norm}= 0)$  and thus a worst case error probability on the order of  $50\%$.
  •  The decision on unfavorably framed bits must then be random, even with low noise  $(10 \cdot \lg \ E_{\rm B}/N_0 = 16 \ {\rm dB})$.

(5)  Now select the settings  $M=2 \text{, Matched Filter receiver, }T_{\rm E}/T = 1$,  $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$  and  "Overall view". Interpret the results.

  •  The basic detection impulse  $g_d(t)$  is triangular and the eye is "fully open".  Consequently, the normalized eye opening is  $ö_{\rm norm}= 1.$
  •  From  $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$  it follows $E_{\rm B}/N_0 = 10$   ⇒   $\sigma_{\rm norm} =\sqrt{1/(2\cdot E_{\rm B}/ N_0)} = \sqrt{0.05} \approx 0.224 $  ⇒   $p_{\rm U} = {\rm Q}(4.47) \approx 3.9 \cdot 10^{-6}.$
  •  This  $p_{\rm U}$ value is by a factor  $15$  better than in  $(3)$.   But:  For  $H_{\rm K}(f) \ne 1$  this so–called "Matched Filter Receiver" is not applicable.

(6)  Same settings as in  $(5)$.  Now vary  $T_{\rm E}/T$  in the range between  $0.5$  and  $1.5$.  Interpret the results.

  •  For  $T_{\rm E}/T < 1$ ,  $ö_{\rm norm}= 1$  still holds.  But  $\sigma_{\rm norm}$  becomes larger, for example  $\sigma_{\rm norm} = 0.316$  for  $T_{\rm E}/T =0.5$   ⇒   the filter is too broadband!
  •  $T_{\rm E}/T > 1$  results in a smaller  $\sigma_{\rm norm}$  compared to  $(5)$.  But the "eye" is no longer open, e.g.  $T_{\rm E}/T =1.25$:   $ö_{\rm norm}= g_0 - 2 \cdot g_1 = 0.6$.

(7)  Now select the settings  $M=2 \text{, CRO Nyquist system, }r_f = 0.2$  and  "Overall view". Interpret the eye pattern, also for other  $r_f$ values.

  •  Unlike  $(6)$  here the basic detection impulse is not zero for  $|t|>T$,  but  $g_d(t)$  has equidistant zero crossings:  $g_0 = 1, \ g_1 = g_2 = 0$   ⇒   Nyquist system.
  •  All  $32$  eye lines pass through only two points at  $t=0$.  The vertical eye opening is maximum for all  $r_f$    ⇒    $ö_{\rm norm}= 1$.
  •  In contrast, the horizontal eye opening increases with  $r_f$  and is for  $r_f = 1$  maximum equal to  $T$   ⇒   the phase jitter has no influence in this case.

(8)  Same setting as in  $(7)$.  Now vary  $r_f$  with respect to minimum error probability.  Interpret the results.

  • $ö_{\rm norm}= 1$  always holds.  In contrast,  $\sigma_{\rm norm}$  shows a slight dependence on  $r_f$.  The minimum  $\sigma_{\rm norm}=0.236$  results for  $r_f = 0.9$   ⇒   $p_{\rm U} \approx 1.1 \cdot 10^{-5}.$
  •  Compared to the best possible case according to  $(5)$   ⇒   "Matched Filter Receiver"  $p_{\rm U}$  is three times larger, although  $\sigma_{\rm norm}$  is only larger by about  $5\%$.
  •  The larger  $\sigma_{\rm norm}$ value is due to the exaggeration of the noise PDS to compensate for the drop through the transmitter frequency response  $H_{\rm S}(f)$.

(9)  Select the settings  $M=4 \text{, Matched Filter receiver, }T_{\rm E}/T = 1$,  $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$  and  $12 \ {\rm dB}$.  Interpret the results.

  •  Now there are three eye openings.  Compared to  $(5)$   $ö_{\rm norm}$  is thus smaller by a factor of  $3$.  $\sigma_{\rm norm}$  on the other hand, only by a factor of  $\sqrt{5/9)} \approx 0.75$.
  •  For  $10 \cdot \lg \ E_{\rm B}/N_0 = 10 \ {\rm dB}$  the  (worst–case)  error probability is  $p_{\rm U} \approx 2.27\%$  and for  $10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$  approx.  $0.59\%$.

(10)  For the remaining tasks, always  $10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$. Consider the eye pattern  ("overall view")  for  $M=4 \text{, CRO Nyquist system, }r_f = 0.5$.

  •  In the analyzed  $d_{\rm S}(t)$  region all  "five symbol combinations"  must be contained   ⇒   minimum  $4^5 = 1024$  parts   ⇒   maximum  $1024$  distinguishable lines.
  •  All  $1024$  eye lines pass through only four points at  $t=0$ :   $ö_{\rm norm}= 0.333$.  $\sigma_{\rm norm} = 0.143$  is slightly larger than in  $(9)$  ⇒   $p_{\rm U} \approx 1\%$.

(11)  Select the settings  $M=4 \text{, Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$  and vary  $f_{\rm G}/R_{\rm B}$.  Interpret the results.

  •  $f_{\rm G}/R_{\rm B}=0.48$  leads to the minimum error probability  $p_{\rm U} \approx 0.21\%$.  $\text{Compromise between}$  $ö_{\rm norm}= 0.312$  and  $\sigma_{\rm norm}= 0.109$.
  •  If the cutoff frequency is too small, intersymbol interference dominates.  Example:  $f_{\rm G}/R_{\rm B}= 0.3$:  $ö_{\rm norm}= 0.157; $ $\sigma_{\rm norm}= 0.086$  ⇒    $p_{\rm U} \approx 3.5\%$.
  •  If the cutoff frequency is too high, noise dominates.  Example:  $f_{\rm G}/R_{\rm B}= 1.0$:  $ö_{\rm norm}= 0.333; $ $\sigma_{\rm norm}= 0.157$  ⇒    $p_{\rm U} \approx 1.7\%$.
  •  From the comparison with  $(9)$  one can see:  $\text{With quaternary coding it is more convenient to allow intersymbol interference}$.

(12)  What differences does the eye pattern show for  $M=3 \text{ (AMI code), Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.48$  compared to the binary system  $(1)$? Interpretation.

  •  The basic detection impulse  $g_d(t)$  is the same in both cases.  The sample values are respectively  $g_0 = 0.771, \ g_1 = 0.114$.
  •  With the AMI code, there are two eye openings with each  $ö_{\rm norm}= 1/2 \cdot (g_0 -3 \cdot g_1) = 0.214$.  With the binary code:  $ö_{\rm norm}= g_0 -2 \cdot g_1 = 0.543$.
  •  The AMI sequence consists of  $50\%$  zeros.  The symbols  $+1$  and  $-1$  alternate   ⇒   there is no long  $+1$  sequence and no long  $-1$  sequence.
  •  Therein lies the only advantage of the AMI code:  This can also be applied to a channel with  $H_{\rm K}(f= 0)=0$  ⇒   a DC signal is suppressed.

(13)  Same setting as in  $(12)$.  Select additionally  $10 \cdot \lg \ E_{\rm B}/N_0 = 12 \ {\rm dB}$.  Analyze the worst-case error probability of the AMI code.

  •  Despite smaller  $\sigma_{\rm norm} = 0.103$  the AMI code has higher error probability  $p_{\rm U} \approx 2\%$  than the binary code:  $\sigma_{\rm norm} = 0.146, \ p_{\rm U} \approx \cdot 10^{-4}.$
  •  $f_{\rm G}/R_{\rm B}<0.34$  results in a closed eye  $(ö_{\rm norm}= 0)$  ⇒    $p_{\rm U} =50\%$.  With binary coding:  For  $f_{\rm G}/R_{\rm B}>0.34$  the eye is open.

(14)  What differences does the eye pattern show for  $M=3 \text{ (Duobinary code), Gaussian low-pass, }f_{\rm G}/R_{\rm B} = 0.30$  compared to the binary system  (1)?

  •  With redundancy-free binary code:  $ö_{\rm norm}= 0.096, \ \sigma_{\rm norm} = 0.116 \ p_{\rm U} \approx 20\% $.   With Duobinary code:  $ö_{\rm norm}= 0.167, \ \sigma_{\rm norm} = 0.082 \ p_{\rm U} \approx 2\% $.
  • In particular, with small  $f_{\rm G}/R_{\rm B}$  the Duobinary code gives good results, since the transitions from  $+1$  to  $-1$  (and vice versa) are absent in the eye pattern.
  • Even with  $f_{\rm G}/R_{\rm B}=0.2$  the eye is open.  But in contrast to AMI  the Duobinary code is not applicable with a DC-free channel   ⇒   $H_{\rm K}(f= 0)=0$.


Applet Manual


Screenshot of the German version

    (A)     Selection:   Encoding
                   (binary,  quaternary,  AMI code,  duobinary code)

    (B)     Selection:   Basic detection pulse
                    (according to Gauss–TP,  CRO–Nyquist,  according to gap–TP}

    (C)     Parameter input for  (B)
                   (cutoff frequency,  rolloff factor,  rectangular duration)

    (D)     Control of the eye diagram display
                   (start,  pause/continue,  single step,  total,  reset)

    (E)     Speed of the eye diagram display

    (F)     Display:  basic detection pulse  $g_d(t)$

    (G)     Display:  detection useful signal  $d_{\rm S}(t - \nu \cdot T)$

    (H)     Display:  eye diagram in the range  $\pm T$

    ( I )     Numerical output:  $ö_{\rm norm}$  (normalized eye opening)

    (J)     Parameter input  $10 \cdot \lg \ E_{\rm B}/N_0$  for  (K)

    (K)     Numerical output:  $\sigma_{\rm norm}$  (normalized noise rms)

    (L)     Numerical output:  $p_{\rm U}$  (worst-case error probability)

    (M)     Range for experimental performance:   task selection

    (N)     Range for experimental performance:   task description

    (O)     Range for experimental performance:   Show sample solution

About the Authors

This interactive calculation tool was designed and implemented at the  Institute for Communications Engineering  at the  Technical University of Munich.

  • The first version was created in 2008 by Thomas Großer  as part of his diploma thesis with “FlashMX – Actionscript” (Supervisor: Günter Söder).
  • Last revision and English version 2020/2021 by  Carolin Mirschina  in the context of a working student activity. 


The conversion of this applet to HTML 5 was financially supported by  Studienzuschüsse  ("study grants")  of the TUM Faculty EI.  We thank.


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