Difference between revisions of "Modulation Methods/Non-Linear Digital Modulation"

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{{Header
 
{{Header
 
|Untermenü=Digital Modulation Methods
 
|Untermenü=Digital Modulation Methods
|Vorherige Seite=Quadratur–Amplitudenmodulation
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|Vorherige Seite=Quadrature Amplitude Modulation
|Nächste Seite=Aufgaben und Klassifizierung
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|Nächste Seite=Tasks and Classification
 
}}
 
}}
==Properties of nonlinear modulation methods==
+
==Properties of non-linear modulation methods==
 
<br>
 
<br>
 
All modulation methods can be alternatively classified as:  
 
All modulation methods can be alternatively classified as:  
Line 16: Line 16:
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; A&nbsp; '''linear modulation method'''&nbsp; is present if any linear combination of signals at modulator input leads to a corresponding linear combination at its output. Otherwise, it is &nbsp; '''non-linear modulation'''. }}
+
$\text{Definitions:}$&nbsp;  
 +
*A&nbsp; &raquo;'''linear modulation method'''&laquo;&nbsp; is present if any linear combination of signals at modulator input leads to a corresponding linear combination at its output.  
 +
*Otherwise,&nbsp; it is a&nbsp; &raquo;'''non-linear modulation'''&laquo;. }}
  
  
At the &nbsp;[[Modulation_Methods/Objectives_of_Modulation_and_Demodulation#Analog_vs._digital_transmission_systems|beginning of the book]]&nbsp; it was already pointed out that the main difference between an analog and a digital modulation method is that in the first one an analog source signal &nbsp;$q(t)$&nbsp; is present and in the second one a digital signal.  However, a closer look will reveal that there are a few more differences between these methods.  This will be discussed in more detail below.
+
At the &nbsp;[[Modulation_Methods/Objectives_of_Modulation_and_Demodulation#Analog_vs._digital_transmission_systems|"beginning of the present book"]]&nbsp; it was already pointed out that the main difference between an analog and a digital modulation method is that
 +
* in the first one an analog source signal &nbsp;$q(t)$&nbsp; is present,&nbsp; and  
 +
*in the second one a digital signal.   
  
 +
 +
However,&nbsp; a closer look will reveal that there are a few more differences between these methods.&nbsp;  This will be discussed in more detail below.
 +
 +
[[File:EN_Mod_T_4_4_S1_neu.png|right|frame| Analog and digital AM, PM and FM methods]]
 
The following diagram shows some of the differences with respect to the classifications given above.
 
The following diagram shows some of the differences with respect to the classifications given above.
[[File:P_ID1737__Mod_T_4_4_S1.png |right|frame| Analog and digital AM, PM and FM methods <b>KORREKTUR</b>]]
 
  
*&nbsp;[[Modulation_Methods/Double-Sideband_Amplitude_Modulation|Analog amplitude modulation]]&nbsp; $\rm (AM)$&nbsp; is a linear method.  The locus curve - that is, the equivalent low-pass signal &nbsp;$s_{\rm TP}(t)$&nbsp; represented in the complex plane - is a straight line.
+
*&nbsp;[[Modulation_Methods/Double-Sideband_Amplitude_Modulation|$\text{Analog amplitude modulation}$]]&nbsp; $\rm (AM)$&nbsp; is a linear method.  The locus curve - that is, the equivalent low-pass signal &nbsp;$s_{\rm TP}(t)$&nbsp; represented in the complex plane - is a straight line.
  
*There are many similarities between &nbsp;[[Modulation_Methods/Phase_Modulation_(PM)|analog phase modulation]]&nbsp; $\rm (PM)$&nbsp; and &nbsp;[[Modulation_Methods/Frequency_Modulation_(FM)|analog frequency modulation]]&nbsp; $\rm (FM)$&nbsp; &nbsp; ⇒  common description as ''angle modulation''&nbsp; $\rm (WM)$.&nbsp; In that case, the locus curve is the arc of a circle.  In harmonic oscillation, there is a line spectrum &nbsp;$S(f)$&nbsp; at multiples of the message frequency&nbsp;$f_{\rm N}$&nbsp; around the carrier frequency &nbsp;$f_{\rm T}$.  
+
*Many similarities between &nbsp;[[Modulation_Methods/Phase_Modulation_(PM)|$\text{analog phase modulation}$]]&nbsp; $\rm (PM)$&nbsp; and &nbsp;[[Modulation_Methods/Frequency_Modulation_(FM)|$\text{analog frequency modulation}$]]&nbsp; $\rm (FM)$ &nbsp; &nbsp; common description&nbsp; "angle modulation"&nbsp; (German:&nbsp; "Winkelmodulation")&nbsp; $\rm (WM)$.&nbsp;
 +
 +
*In that case,&nbsp; the locus curve is an arc of a circle.&nbsp; With a harmonic oscillation,&nbsp; there is a line spectrum &nbsp;$S(f)$&nbsp; at multiples of the message frequency&nbsp;$f_{\rm N}$&nbsp; around the carrier frequency &nbsp;$f_{\rm T}$.  
  
*&nbsp;[[Modulation_Methods/Linear_Digital_Modulation#ASK_.E2.80.93_Amplitude_Shift_Keying|Digital amplitude modulation]],  referred to as either &nbsp; ''Amplitude Shift Keying''&nbsp; $\rm (ASK)$&nbsp; or as ''On–Off–Keying''&nbsp; $\rm (OOK)$&nbsp;, is also linear.  In the binary case, the locus curve consists of only two points.
+
*[[Modulation_Methods/Linear_Digital_Modulation#ASK_.E2.80.93_Amplitude_Shift_Keying|$\text{Digital amplitude modulation}$]],&nbsp; referred to as either &nbsp; "Amplitude Shift Keying"&nbsp; $\rm (ASK)$&nbsp; or as&nbsp; "On–Off–Keying"&nbsp; $\rm (OOK)$,&nbsp; is also linear.&nbsp; In the binary case,&nbsp; the locus curve consists of only two points.
  
*Since [[Modulation_Methods/Linear_Digital_Modulation#BPSK_.E2.80.93_Binary_Phase_Shift_Keying|binary phase modulation]] $($''Binary Phase Shift Keying'',&nbsp; $\rm BPSK)$  can be represented as&nbsp; $\rm ASK$&nbsp; with bipolar amplitude coefficients, it is also linear.&nbsp; The shape of the BPSK power-spectral density is essentially determined by the magnitude square spectrum &nbsp;$|G_s(f)|^2$&nbsp; of the fundamental transmission pulse.
+
*Since&nbsp; [[Modulation_Methods/Linear_Digital_Modulation#BPSK_.E2.80.93_Binary_Phase_Shift_Keying|$\text{binary phase modulation}$]]&nbsp; $($"Binary Phase Shift Keying",&nbsp; $\rm BPSK)$&nbsp; can be represented as&nbsp; $\rm ASK$&nbsp; with bipolar amplitude coefficients,&nbsp; it is also linear.&nbsp; The shape of the BPSK power-spectral density is essentially determined by the magnitude square spectrum &nbsp;$|G_s(f)|^2$&nbsp; of the basic transmission pulse.
  
*However, this also means: &nbsp;
 
:#&nbsp;  The BPSK spectral function is continuous in &nbsp;$f$, unlike the analog phase modulation of a harmonic oscillation (which only has one frequency!).
 
:#&nbsp; If one were to consider BPSK as (analog) phase modulation with digital source signal &nbsp;$q(t)$&nbsp;, then an infinite number of Bessel line spectra would have to be convolved together to calculate &nbsp;${\it Φ}_s(f)$&nbsp; when  &nbsp;$Q(f)$&nbsp; is represented as an infinite sum of individual frequencies.
 
  
*Since &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Signal_waveforms_for_4.E2.80.93QAM|quadrature amplitude modulation]]&nbsp; with four signal space points &nbsp; $\rm (4–QAM)$&nbsp; can also be described as the sum of two mutually orthogonal, quasi-independent BPSK systems, it too represents a linear modulation scheme.  The same applies to the &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Quadratic_QAM_signal_space_constellations|higher-level QAM methods]]&nbsp; such as &nbsp; $\rm 16–QAM$, &nbsp; $\rm 64–QAM$, ...  
+
::However,&nbsp; this also means: &nbsp; The BPSK spectrum is continuous in $f$,&nbsp; unlike the analog PM of a harmonic oscillation&nbsp; (only one frequency!). &nbsp; If one were to consider BPSK as analog PM with digital source signal &nbsp;$q(t)$,&nbsp; then an infinite number of Bessel line spectra would have to be convolved together to calculate the power-spectral density &nbsp;${\it Φ}_s(f)$&nbsp; when  &nbsp;$Q(f)$&nbsp; is represented as an infinite sum of individual frequencies.
  
*Higher-level &nbsp; ''Phase Shift Keying'', such as &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Other_signal_space_constellations|$\rm 8–PSK$]], is linear only in special cases, see [Klo01]<ref name="Klo01">Klostermeyer, R.: ''Digitale Modulation''. Braunschweig: Vieweg, 2001.</ref>.&nbsp;  Digital frequency modulation&nbsp; $($''Frequency Shift Keying'',&nbsp; $\rm FSK)$&nbsp; is always nonlinear.  This method is described below, where we restrict our focus to the binary case&nbsp; $\rm (2-FSK)$&nbsp; beschränken.
+
*Since &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Signal_waveforms_for_4.E2.80.93QAM|$\text{quadrature amplitude modulation}$]]&nbsp; with four signal space points &nbsp; $\rm (4–QAM)$&nbsp; can also be described as the sum of two mutually orthogonal,&nbsp; quasi-independent BPSK systems,&nbsp; it too represents a linear modulation scheme.&nbsp;  The same applies to the &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Quadratic_QAM_signal_space_constellations|$\text{higher-level QAM methods}$]]&nbsp; such as&nbsp; $\rm 16–QAM$,&nbsp; $\rm 64–QAM$, ...
 +
 
 +
*Higher-level &nbsp; "Phase Shift Keying",&nbsp; such as &nbsp;[[Modulation_Methods/Quadrature_Amplitude_Modulation#Other_signal_space_constellations|$\rm 8–PSK$]],&nbsp; is linear only in special cases, see [Klo01]<ref name="Klo01">Klostermeyer, R.:&nbsp; Digitale Modulation.&nbsp; Braunschweig: Vieweg, 2001.</ref>.&nbsp;  Digital frequency modulation&nbsp; $($"Frequency Shift Keying",&nbsp; $\rm FSK)$&nbsp; is always non-linear.&nbsp; This method is described below,&nbsp; where we restrict our focus to the binary case&nbsp; $\rm (2-FSK)$&nbsp;.
  
 
==FSK – Frequency Shift Keying==
 
==FSK – Frequency Shift Keying==
 
<br>
 
<br>
Now we assume
+
{{BlaueBox|TEXT=
 +
$\text{Now we assume:}$&nbsp;
 +
 
 
*the transmitted signal of the analog frequency modulation,
 
*the transmitted signal of the analog frequency modulation,
:$$s(t) =  s_0 \cdot \cos\hspace{-0.05cm}\big [\psi(t)\big ] \hspace{0.2cm} {\rm with} \hspace{0.2cm} \psi(t) = 2\pi  f_{\rm T}  \hspace{0.05cm}t + K_{\rm FM} \cdot \int q(t)\hspace{0.1cm} {\rm d}t,$$
+
:$$s(t) =  s_0 \cdot \cos\hspace{-0.05cm}\big [\psi(t)\big ] \hspace{0.5cm} {\rm with} \hspace{0.5cm} \psi(t) = 2\pi  f_{\rm T}  \hspace{0.05cm}t + K_{\rm FM} \cdot \int q(t)\hspace{0.1cm} {\rm d}t,$$
*the rectangular binary signal with  &nbsp;$a_ν ∈ \{+1, –1\}$ &nbsp; ⇒ &nbsp; bipolar signaling:  
+
*the rectangular binary source signal with  &nbsp;$a_ν ∈ \{+1, –1\}$ &nbsp; ⇒ &nbsp; bipolar signaling:  
 
:$$q(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_s (t - \nu
 
:$$q(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_s (t - \nu
\cdot T) \hspace{0.2cm} {\rm with} \hspace{0.2cm} g_s(t) = \left\{ \begin{array}{l} A  \\ 0 \\  \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for}} \\{\rm{for}}  \\ \end{array}\begin{array}{*{10}c}
+
\cdot T) \hspace{0.5cm} {\rm with} \hspace{0.5cm} g_s(t) = \left\{ \begin{array}{l} A  \\ 0 \\  \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for} } \\{\rm{ } }  \\ \end{array}\begin{array}{*{10}c}
0 < t < T\hspace{0.05cm},  \\ {\rm otherwise} \hspace{0.05cm}. \\ \end{array}$$
+
\hspace{0.05cm}0 < t < T\hspace{0.05cm},  \\ {\rm otherwise} \hspace{0.05cm}. \\ \end{array}$$}}
Summarizing the amplitude &nbsp;$A$&nbsp;  and the modulator constant &nbsp;$K_{\rm FM}$&nbsp; into the frequency deviation (see below for definition)
+
 
:$${\rm \Delta}f_{\rm A} =  \frac{A \cdot K_{\rm FM}}{2 \pi}$$
+
 
then the das&nbsp; '''FSK transmit signal'''&nbsp; in the &nbsp;$ν$–th time interval is:
+
*Summarizing the amplitude &nbsp;$A$&nbsp;  and the modulator constant &nbsp;$K_{\rm FM}$&nbsp; into the&nbsp; "frequency deviation" (see below for definition)
:$$s(t) =  s_0 \cdot \cos\hspace{-0.05cm}\big [2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} ) \big ]\hspace{0.05cm}.$$
+
::$${\rm \Delta}f_{\rm A} =  \frac{A \cdot K_{\rm FM}}{2 \pi},$$
This can be calculated with the two possible signal frequencies
+
:then the&nbsp; &raquo;'''FSK transmitted signal'''&laquo;&nbsp; in the &nbsp;$ν$–th time interval is:
:$$f_{\rm +1} = f_{\rm T} +{\rm \Delta}f_{\rm A} \hspace{0.05cm},
+
::$$s(t) =  s_0 \cdot \cos\hspace{-0.05cm}\big [2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} ) \big ]\hspace{0.05cm}.$$
 +
*This can be calculated with the two possible signal frequencies
 +
::$$f_{\rm +1} = f_{\rm T} +{\rm \Delta}f_{\rm A} \hspace{0.05cm},
 
\hspace{0.2cm}f_{\rm -1} = f_{\rm T} -{\rm \Delta}f_{\rm A}$$
 
\hspace{0.2cm}f_{\rm -1} = f_{\rm T} -{\rm \Delta}f_{\rm A}$$
and written as:  
+
:and written as:  
:$$s(t) = \left\{ \begin{array}{l} s_0 \cdot \cos (2 \pi  \cdot f_{\rm +1} \cdot  t )  \\  s_0 \cdot \cos (2 \pi  \cdot f_{\rm -1} \cdot  t ) \\  \end{array} \right.\quad \begin{array}{*{5}c}{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}}  \\ \end{array}\begin{array}{*{10}c} a_{ \nu} = +1 \hspace{0.05cm},  \\ a_{ \nu} = -1\hspace{0.05cm}.  \\ \end{array}$$
+
::$$s(t) = \left\{ \begin{array}{l} s_0 \cdot \cos (2 \pi  \cdot f_{\rm +1} \cdot  t )  \\  s_0 \cdot \cos (2 \pi  \cdot f_{\rm -1} \cdot  t ) \\  \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for}} \\{\rm{for}}  \\ \end{array}\begin{array}{*{10}c} \hspace{0.05cm}a_{ \nu} = +1 \hspace{0.05cm},  \\ \hspace{0.05cm}a_{ \nu} = -1\hspace{0.05cm}.  \\ \end{array}$$
*Thus, at any given time, only one of the two frequencies &nbsp;$f_{+1}$&nbsp; and &nbsp;$f_{–1}$&nbsp; arises.&nbsp;  
+
*Thus,&nbsp; at any given time,&nbsp; only one of the two frequencies &nbsp;$f_{+1}$&nbsp; and &nbsp;$f_{–1}$&nbsp; arises.&nbsp; The carrier frequency&nbsp; $f_{\rm T}$&nbsp;  itself does not occur in the signal.
*The carrier frequency &nbsp; $f_{\rm T}$&nbsp;  itself does not occur in the signal.
 
  
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; The&nbsp; '''frequency deviation''' &nbsp;$Δf_{\rm A}$&nbsp; is defined in the same way as for analog frequency modulation, namely as the maximum deviation of the instantaneous frequency &nbsp;$f_{\rm A}(t)$&nbsp;  from the carrier frequency &nbsp;$f_{\rm T}$.  Sometimes the frequency deviation is also referred to as &nbsp;$Δf$&nbsp;or &nbsp;$F$&nbsp;  in the literature. }}
+
$\text{Definition:}$&nbsp; The&nbsp; &raquo;'''frequency deviation'''&laquo; &nbsp;$Δf_{\rm A}$&nbsp;  
 +
*is defined in the same way as for analog frequency modulation, namely  
 +
*as the maximum deviation of the instantaneous frequency &nbsp;$f_{\rm A}(t)$&nbsp;  from the carrier frequency &nbsp;$f_{\rm T}$:
 +
::$$ {\rm \Delta}f_{\rm A} =f_{\rm +1} - f_{\rm T}\hspace{0.05cm},
 +
\hspace{0.2cm}f_{\rm -1} = f_{\rm T} -f_{\rm -1}.$$
  
 +
Sometimes,&nbsp; the&nbsp; &raquo;'''total frequency deviation'''&laquo;&nbsp; $ 2 \cdot {\rm \Delta}f_{\rm A} =f_{\rm +1} - f_{\rm -1}$&nbsp; is used in the literature. }}
  
Another important descriptive quantity in this context is the "modulation index", which was also already defined for analog frequency modulation as &nbsp;$η = Δf_{\rm A}/f_{\rm N}$&nbsp;.&nbsp; For FSK, a slightly different definition is required, which is taken into account here with a different variable symbol: &nbsp; $η &nbsp; ⇒ &nbsp; h$.
+
 
 +
Another important descriptive quantity in this context is the&nbsp; "modulation index",&nbsp; which was also already defined for analog frequency modulation as &nbsp;$η = Δf_{\rm A}/f_{\rm N}.$ &nbsp; &nbsp; For FSK,&nbsp; a slightly different definition is required,&nbsp; which is taken into account here with a different variable symbol: &nbsp; $η &nbsp; ⇒ &nbsp; h$.
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; For digital frequency modulation (FSK), the&nbsp; '''modulation index''' &nbsp; $h$&nbsp; denotes the ratio of the total frequency deviation and the symbol rate &nbsp;$1/T$:
+
$\text{Definitions:}$&nbsp;  
 +
*For digital frequency modulation&nbsp; $\rm  (FSK)$,&nbsp; the&nbsp; &raquo;'''modulation index'''&laquo; &nbsp; $h$&nbsp; denotes the ratio of the total frequency deviation and the symbol rate &nbsp;$1/T$:
 
:$$h  =  \frac{2 \cdot {\rm \Delta}f_{\rm A} }{1/T} = 2 \cdot {\rm \Delta}f_{\rm A}\cdot T \hspace{0.05cm}.$$  
 
:$$h  =  \frac{2 \cdot {\rm \Delta}f_{\rm A} }{1/T} = 2 \cdot {\rm \Delta}f_{\rm A}\cdot T \hspace{0.05cm}.$$  
Sometimes &nbsp;$h$&nbsp; is also referred to as '''phase deviation''' in the literature. }}
+
*Sometimes &nbsp;$h$&nbsp; is also referred to as &raquo;'''phase deviation'''&laquo; in the literature. }}
  
  
[[File:P_ID1729__Mod_T_4_4_S2_neu.png |right|frame| Signal waveforms &nbsp;$q(t)$, &nbsp;$z(t)$&nbsp; and &nbsp;$s(t)$&nbsp; for binary FSK]]
 
 
{{GraueBox|TEXT=
 
{{GraueBox|TEXT=
 
$\text{Example 1:}$&nbsp; The graph below shows the FSK transmitted signal &nbsp;$s(t)$&nbsp; for  
 
$\text{Example 1:}$&nbsp; The graph below shows the FSK transmitted signal &nbsp;$s(t)$&nbsp; for  
*the binary source signal &nbsp;$q(t)$&nbsp; sketched above with amplitude values &nbsp;$\pm A =\pm  1 \ \rm V$, and
+
*the binary source signal &nbsp;$q(t)$&nbsp; sketched above with amplitude values &nbsp;$\pm A =\pm  1 \ \rm V$,&nbsp; and
 
*the carrier signal &nbsp;$z(t)$&nbsp; drawn below with four oscillations per symbol duration&nbsp; $(f_{\rm T} · T = 4)$.  
 
*the carrier signal &nbsp;$z(t)$&nbsp; drawn below with four oscillations per symbol duration&nbsp; $(f_{\rm T} · T = 4)$.  
 +
[[File:P_ID1729__Mod_T_4_4_S2_neu.png |right|frame|Binary FSK signals &nbsp;$q(t)$, &nbsp;$z(t)$&nbsp; and &nbsp;$s(t)$]]
  
 +
<br><br><br><br><br>
 +
This results in the following characteristic values for the FSK system:
  
The underlying frequency deviation is&nbsp;$Δf_{\rm A} = 1/T$ &nbsp; &rArr; modulation index &nbsp;$h = 2$. The two possible frequencies are &nbsp;$f_{\rm +1} = 5/T \hspace{0.05cm},\hspace{0.2cm}f_{\rm -1} = 3/T \hspace{0.05cm}.$
+
#The underlying frequency deviation is&nbsp;$Δf_{\rm A} = 1/T$.
 +
#The modulation index is &nbsp;$h = 2$.  
 +
#The two possible frequencies are &nbsp;$f_{\rm +1} = 5/T \hspace{0.05cm},\hspace{0.2cm}f_{\rm -1} = 3/T \hspace{0.05cm}.$
  
Thus, for an FSK transmission system with bit rate &nbsp;$1 \ {\rm Mbit/s} \ \ (T = 1 \ \rm &micro; s)$&nbsp;, the following FM constant would have to be used:
+
 
 +
Thus, for an FSK transmission system with bit rate &nbsp;$1 \ {\rm Mbit/s} \ \ (T = 1 \ \rm &micro; s)$,&nbsp; the following FM constant would have to be used:
 
:$$K_{\rm FM} =  \frac{2 \pi \cdot {\rm \Delta}f_{\rm A} }{A } = \frac{2 \pi }{A \cdot T } \approx 6.28 \cdot 10^{6}\,\,{\rm V^{-1}s^{-1} }\hspace{0.05cm}.$$}}
 
:$$K_{\rm FM} =  \frac{2 \pi \cdot {\rm \Delta}f_{\rm A} }{A } = \frac{2 \pi }{A \cdot T } \approx 6.28 \cdot 10^{6}\,\,{\rm V^{-1}s^{-1} }\hspace{0.05cm}.$$}}
  
 
==Coherent demodulation of FSK==
 
==Coherent demodulation of FSK==
 
<br>
 
<br>
The diagram shows the best possible demodulator for binary FSK that operates coherently and thus requires knowledge of the phase of the FSK signal.  This is accounted for in the block diagram by assuming that the received signal  &nbsp;$r(t)$&nbsp; is equal to the transmitted signal &nbsp;$s(t)$&nbsp;  - see signal waveforms in the previous section.
+
The diagram shows the best possible demodulator for binary FSK that operates coherently.
  
 
[[File:EN_Mod_T_4_4_S3.png|right|frame| Coherent FSK demodulator]]  
 
[[File:EN_Mod_T_4_4_S3.png|right|frame| Coherent FSK demodulator]]  
  
This demodulator operates according to the following principle (see upper arrangement):
+
*It thus requires knowledge of the phase of the FSK signal. 
*We are dealing with a &nbsp;[[Digital_Signal_Transmission/Optimal_Receiver_Strategies#MAP_and_Maximum.E2.80.93Likelihood_decision_rule|maximum–likelihood receiver]]&nbsp; $\rm (ML)$&nbsp; with a&nbsp; [[Theory_of_Stochastic_Signals/Matched-Filter|Matched-Filter]] realization.&nbsp; This filter with frequency response&nbsp;$H_{\rm MF}(f)$&nbsp; an also be realized as an integrator with the assumed rectangular fundamental transmit pulse &nbsp;$g_s(t)$&nbsp;.  
+
*This is accounted for in the block diagram by assuming that the received signal  &nbsp;$r(t)$&nbsp; is equal to the transmitted signal &nbsp;$s(t)$.
*Both signals &nbsp;$b_{+1}(t)$&nbsp; and &nbsp;$b_{–1}(t)$&nbsp; before their corresponding matched–filters ergeben are obtained by phase-appropriate multiplication with the oscillations of the frequencies &nbsp;$f_{+1}$&nbsp; and &nbsp;$f_{–1}$, respectively.  
+
 
*The maximum likelihood receiver is known to decide on the branch (symbol) with the larger "metric", taking into account the downstream matched filter.   
+
 
This means:   
+
This demodulator operates according to following principle&nbsp; (see upper arrangement):
*&nbsp;$a_ν = +1$&nbsp; was probably sent if the following condition is satisfied:
+
#We are dealing with a&nbsp;[[Digital_Signal_Transmission/Optimal_Receiver_Strategies#Maximum-a-posteriori_and_maximum.E2.80.93likelihood_decision_rule|$\text{maximum–likelihood receiver}$]]&nbsp; $\rm (ML)$&nbsp; with&nbsp; [[Theory_of_Stochastic_Signals/Matched_Filter|$\text{matched filter}$]]&nbsp;  realization.&nbsp; This filter with frequency response&nbsp;$H_{\rm MF}(f)$&nbsp; can also be realized as an integrator with rectangular basic transmission pulse &nbsp;$g_s(t)$.  
:$$d_{\rm +1}(\nu \cdot T) >  d_{\rm -1}(\nu \cdot T) $$
+
#Both signals &nbsp;$b_{+1}(t)$&nbsp; and &nbsp;$b_{–1}(t)$&nbsp; before their corresponding matched filters  are obtained by phase-appropriate multiplication with the oscillations of the frequencies &nbsp;$f_{+1}$&nbsp; and &nbsp;$f_{–1}$,&nbsp; respectively.  
:$$\Rightarrow \hspace{0.3cm}
+
#The maximum-likelihood receiver is known to decide on the branch&nbsp; (for the symbol)&nbsp; with the larger&nbsp; "metric",&nbsp; taking into account the following matched filter.&nbsp;  
 +
#This means:  &nbsp;$a_ν = +1$&nbsp; was probably sent if the following condition is satisfied:
 +
::$$d_{\rm +1}(\nu \cdot T) >  d_{\rm -1}(\nu \cdot T) $$
 +
::$$\Rightarrow \hspace{0.3cm}
 
  d(\nu \cdot T) = d_{\rm +1}(\nu \cdot T) - d_{\rm -1}(\nu \cdot
 
  d(\nu \cdot T) = d_{\rm +1}(\nu \cdot T) - d_{\rm -1}(\nu \cdot
 
  T) > 0\hspace{0.05cm}.$$
 
  T) > 0\hspace{0.05cm}.$$
  
 
The upper block diagram has been drawn according to this description for better understanding.  
 
The upper block diagram has been drawn according to this description for better understanding.  
*Of course, matched filtering could instead also be moved to the right of the discrimination, as shown in the lower model .  
+
 
 +
*Of course,&nbsp; matched filtering could instead also be moved to the right of the discrimination,&nbsp; as shown in the lower model.&nbsp;
 
*Then only one filter has to be implemented.  
 
*Then only one filter has to be implemented.  
 
+
*In &nbsp;[[Aufgaben:Exercise_4.13:_FSK_Demodulation|"Exercise 4.13"]]&nbsp;, this FSK demodulator is discussed in detail.  
 
+
*On the exercise page you can also see the corresponding signal waveforms.
In &nbsp;[[Aufgaben:Exercise_4.13:_FSK_Demodulation|Exercise 4.13]]&nbsp;, this FSK demodulator is discussed in detail. On the exercise page you can also see the corresponding signal waveforms.
 
  
 
==Error probability of orthogonal FSK==
 
==Error probability of orthogonal FSK==
 
<br>
 
<br>
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Definition:}$&nbsp; One speaks of &nbsp; '''orthogonal FSK''',  
+
$\text{Definition:}$&nbsp; One speaks of&nbsp; &raquo;'''orthogonal FSK'''&laquo;,  
*if the modulation index &nbsp; $h$&nbsp; is an integer multiple of &nbsp;$0.5$&nbsp;, and thus  
+
*if the modulation index&nbsp; $h$&nbsp; is an integer multiple of &nbsp;$0.5$,&nbsp; and thus  
*the frequency deviation &nbsp;$Δf_{\rm A}$&nbsp; is an integer multiple of &nbsp;$0.25/T$.}}
+
*the frequency deviation &nbsp;$Δf_{\rm A}$&nbsp; is an integer multiple of&nbsp; $0.25/T$.}}
  
  
For the coherent demodulator, the correlation coefficient between &nbsp;$d_{+1}(T_{\rm D})$&nbsp; and &nbsp;$d_{–1}(T_{\rm D})$&nbsp; is zero at all detection times.  Thus, the magnitude &nbsp;$|d(T_{\rm D})|$ - the distance of the detection samples from the threshold - is constant.  No pulse interference occurs.
+
For the coherent demodulator,&nbsp; the correlation coefficient between &nbsp;$d_{+1}(T_{\rm D})$&nbsp; and &nbsp;$d_{–1}(T_{\rm D})$&nbsp; is zero at all detection times.&nbsp; Thus,&nbsp; the magnitude &nbsp;$|d(T_{\rm D})|$&nbsp; &ndash; the distance of the detection samples from the threshold &ndash;&nbsp; is constant.&nbsp; No intersymbol interference occurs.
  
 
If one assumes
 
If one assumes
 
*orthogonal FSK,
 
*orthogonal FSK,
*an AWGN channel&nbsp; $($captured by the quotient &nbsp;$E_{\rm B}/N_0)$, and
+
*an AWGN channel&nbsp; $($captured by the quotient &nbsp;$E_{\rm B}/N_0)$,&nbsp; and
*the coherent demodulation described here
+
*the coherent demodulation described here,
  
  
Line 130: Line 156:
 
  ) = {1}/{2}\cdot {\rm erfc}\left ( \sqrt{{E_{\rm B}}/(2 N_0 }) \hspace{0.1cm}\right ).$$
 
  ) = {1}/{2}\cdot {\rm erfc}\left ( \sqrt{{E_{\rm B}}/(2 N_0 }) \hspace{0.1cm}\right ).$$
  
This corresponds to a degradation of  &nbsp;$3 \ \rm dB$ compared to  
+
This corresponds to a degradation of  &nbsp;$3 \ \rm dB$&nbsp; compared to&nbsp;[[Modulation_Methods/Linear_Digital_Modulation#Error_probabilities_-_a_brief_overview|$\text{BSPK}$]]&nbsp; because
  &nbsp;[[Modulation_Methods/Linear_Digital_Modulation#Error_probabilities_-_a_brief_overview|BSPK]]&nbsp; because
 
 
*although the coherent FSK demodulator gives the same result with respect to the useful signal,  
 
*although the coherent FSK demodulator gives the same result with respect to the useful signal,  
 
*and the noise powers in the two branches are also exactly the same as with BPSK,
 
*and the noise powers in the two branches are also exactly the same as with BPSK,
*due to the subtraction, the total noise power is doubled.
+
*due to the subtraction,&nbsp; the total noise power is doubled.
  
  
However, while non-coherent demodulation is not possible under any circumstances in binary phase modulation (BPSK), there is also a ''non-coherent FSK demodulator'', but with a somewhat increased probability of error:
+
However,&nbsp; while non-coherent demodulation is not possible under any circumstances in binary phase modulation (BPSK),&nbsp; there is also a&nbsp; "non-coherent FSK demodulator",&nbsp; but with a somewhat increased probability of error:
 
:$$p_{\rm B} = {1}/{2} \cdot {\rm e}^{- E_{\rm B}/{(2N_0) }}\hspace{0.05cm}.$$
 
:$$p_{\rm B} = {1}/{2} \cdot {\rm e}^{- E_{\rm B}/{(2N_0) }}\hspace{0.05cm}.$$
The derivation of this equation is given in the chapter&nbsp; [[Digital_Signal_Transmission/Carrier_Frequency_Systems_with_Non-Coherent_Demodulation|Carrier Frequency Systems with Non-Coherent Demodulation]]&nbsp; of the book "Digital Signal Transmission".
+
The derivation of this equation is given in the chapter&nbsp; [[Digital_Signal_Transmission/Carrier_Frequency_Systems_with_Non-Coherent_Demodulation|"Carrier Frequency Systems with Non-Coherent Demodulation"]]&nbsp; of the book&nbsp; "Digital Signal Transmission".
  
 
==Binary FSK with Continuous Phase Matching==
 
==Binary FSK with Continuous Phase Matching==
 
<br>
 
<br>
We continue to consider the orthogonal FSK.  The graph shows the source signal &nbsp;$q(t)$&nbsp; at the top and, drawn below, the FSK signal &nbsp;$s_{\rm A}(t)$&nbsp; with frequency deviation &nbsp;$Δf_{\rm A} = 1/T$ ⇒ modulation index &nbsp;$h = 2 · Δf_{\rm A} · T = 2$. The following should be noted about the other signal waveforms:
+
We continue to consider the orthogonal FSK.&nbsp; The graph shows the source signal &nbsp;$q(t)$&nbsp; at the top and,&nbsp; drawn below,&nbsp; the FSK signal &nbsp;$s_{\rm A}(t)$&nbsp; with frequency deviation &nbsp;$Δf_{\rm A} = 1/T$ ⇒ modulation index &nbsp;$h = 2 · Δf_{\rm A} · T = 2$.&nbsp; The following should be noted about the other signal waveforms:
  
[[File:EN_Mod_T_4_4_S5.png|right|frame| Binary FSK signals with &nbsp;$h = 2$, &nbsp;$h = 1$&nbsp; and &nbsp;$h = 0.5$, partially with phase matching]]
+
[[File:EN_Mod_T_4_4_S5.png|right|frame| Binary FSK signals with &nbsp;$h = 2$, &nbsp;$h = 1$&nbsp; and &nbsp;$h = 0.5$,&nbsp; partially with phase matching]]
  
* The FSK signal&nbsp;$s_{\rm B}(t)$&nbsp; uses instantaneous frequencies &nbsp;$f_{+1} = 4.5/T$,&nbsp; $f_{–1} = 3.5/T$  &nbsp; ⇒ &nbsp; $Δf_{\rm A} ·T = 0.5$ &nbsp; ⇒  &nbsp;  $h = 1.$ This FSK is also orthogonal because of&nbsp;$h = 1$&nbsp; $($multiple of &nbsp;$0.5)$.&nbsp; However, with smaller &nbsp;$h$&nbsp;, the bandwidth efficiency is better &nbsp; ⇒  &nbsp;  the spectrum &nbsp;$S_{\rm B}(f)$&nbsp;  is narrower than &nbsp;$S_{\rm A}(f)$.
+
* The signal&nbsp;$s_{\rm B}(t)$&nbsp; uses instantaneous frequencies &nbsp;$f_{+1} = 4.5/T$, &nbsp;$f_{–1} = 3.5/T$  &nbsp; ⇒ &nbsp; $Δf_{\rm A} ·T = 0.5$ &nbsp; ⇒  &nbsp;  $h = 1$.&nbsp; This FSK is also orthogonal because of&nbsp;$h = 1$&nbsp; $($multiple of &nbsp;$0.5)$.&nbsp; However,&nbsp; with smaller &nbsp;$h$,&nbsp; the bandwidth efficiency is better &nbsp; ⇒  &nbsp;  the spectrum &nbsp;$S_{\rm B}(f)$&nbsp;  is narrower than &nbsp;$S_{\rm A}(f)$.
  
 
   
 
   
*However, in the signal&nbsp;$s_{\rm B}(t)$&nbsp;, one can detect a phase jump by &nbsp;$π$ at each symbol boundary, which again results in a broadening of the spectrum. Such phase jumps can be avoided by phase matching.  This is then referred to as '''Continuous Phase Modulation'''&nbsp; $\rm (CPM)$.
+
*However,&nbsp; in the signal&nbsp;$s_{\rm B}(t)$,&nbsp; one can see a phase jump by &nbsp;$π$&nbsp; at each symbol boundary,&nbsp; which again results in a broadening of the spectrum.&nbsp; Such phase jumps can be avoided by phase matching.&nbsp; This is then referred to as&nbsp; &raquo;'''Continuous Phase Modulation'''&laquo;&nbsp; $\rm (CPM)$.
  
 
   
 
   
*Also, for the CPM signal &nbsp;$s_{\rm C}(t)$&nbsp;, &nbsp;$f_{+1} = 4.5/T, f_{–1} = 3.5/T$&nbsp; and &nbsp;$h = 1$ hold.&nbsp;. In the range &nbsp;$0$ ... $T$&nbsp;, the coefficient &nbsp;$a_1 = +1$&nbsp; is represented by &nbsp;$\cos (2π·f_{+1}·t)$&nbsp;, and in the range &nbsp;$T$ ... $2T$&nbsp;, on the other hand, the coefficient &nbsp;$a_2 = +1$&nbsp;, which is also positive, is represented by the function &nbsp;$\ –\cos (2π·f_{+1}·t)$&nbsp; shifted by &nbsp;$π$&nbsp;.
+
*Also,&nbsp; for the CPM signal &nbsp;$s_{\rm C}(t)$,&nbsp; $f_{+1} = 4.5/T,&nbsp; f_{–1} = 3.5/T$&nbsp; and &nbsp;$h = 1$&nbsp; hold.&nbsp; In the range &nbsp;$0$ ... $T$,&nbsp; the coefficient &nbsp;$a_1 = +1$&nbsp; is represented by &nbsp;$\cos (2π·f_{+1}·t)$,&nbsp; and in the range &nbsp;$T$ ... $2T$,&nbsp; on the other hand,&nbsp; the also positive coefficient &nbsp;$a_2 = +1$&nbsp; is represented by &nbsp;$\ –\cos (2π·f_{+1}·t)$ &nbsp; &rArr; &nbsp; shifted by &nbsp;$π$.
  
 
   
 
   
*The modulation index &nbsp;$h = 0.5$&nbsp; of signal nbsp;$s_{\rm D}(t)$&nbsp; is the smallest value that allows orthogonal FSK ⇒ '''Minimum Shift Keying'''&nbsp; $\rm (MSK)$. In MSK, four different initial phases are possible at each symbol boundary, depending on the previous symbols.
+
*The modulation index &nbsp;$h = 0.5$&nbsp; of signal $s_{\rm D}(t)$&nbsp; is the smallest value that allows orthogonal FSK &nbsp; &nbsp; &raquo;'''Minimum Shift Keying'''&laquo;&nbsp; $\rm (MSK)$.&nbsp; In MSK,&nbsp; four different initial phases are possible at each symbol boundary,&nbsp; depending on the previous symbols.
 
 
  
  
The interactive applet [[Applets:Frequency_Shift_Keying_%26_Continuous_Phase_Modulation|Frequency Shift Keying & Continuous Phase Modulation (CPM)]] is available to illustrate the facts presented here.  
+
&rArr; &nbsp; The&nbsp; (German language)&nbsp; SWF applet&nbsp; [[Applets:Frequency_Shift_Keying_%26_Continuous_Phase_Modulation|"Frequency Shift Keying & Continuous Phase Modulation"]]&nbsp; illustrate the facts presented here.  
  
 
==MSK – Minimum Shift Keying==
 
==MSK – Minimum Shift Keying==
 
<br>
 
<br>
[[File:EN_Mod_T_4_4_S6.png | right|frame|  Blockschaltbild zur Erzeugung eines MSK–Signals]]
+
The graphic shows the block diagram for generating an MSK modulation and typical signal properties at various points of the MSK transmitter. One can recognize
 
+
[[File:EN_Mod_T_4_4_S6.png | right|frame|  Block diagram for generating a MSK signal]]
The image shows the block diagram for generating an MSK modulation and typical signal properties at various points of the MSK transmitter. One can recognize  
+
*the digital source signal at point&nbsp; '''(1)''', a sequence of Dirac pulses spaced &nbsp;$T$ apart, weighted by the coefficients &nbsp;$a_ν ∈ \{–1, +1\}$:  
+
*the digital source signal at point&nbsp; '''(1)''',&nbsp; a sequence of Dirac delta pulses spaced by &nbsp;$T$,&nbsp; weighted by the coefficients &nbsp;$a_ν ∈ \{–1, +1\}$:  
 
:$$q_\delta(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot \delta (t - \nu
 
:$$q_\delta(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot \delta (t - \nu
\cdot T)\hspace{0.05cm},$$
+
\cdot T)\hspace{0.05cm};$$
*the rectangular signal &nbsp;$q_{\rm R}(t)$&nbsp; at point&nbsp; '''(2)'''&nbsp; after convolution with the rectangular pulse&nbsp;$g(t)$&nbsp; of duration&nbsp;$T$&nbsp; and height &nbsp;$1/T$:  
+
*the rectangular signal &nbsp;$q_{\rm R}(t)$&nbsp; at point&nbsp; '''(2)'''&nbsp; after convolution with the rectangular pulse&nbsp;$g(t)$&nbsp; of duration&nbsp; $T$&nbsp; and height &nbsp;$1/T$:  
 
:$$q_{\rm R}(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (t - \nu
 
:$$q_{\rm R}(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (t - \nu
 
\cdot T)\hspace{0.05cm},$$
 
\cdot T)\hspace{0.05cm},$$
*the  &nbsp;[[Modulation_Methods/Frequency_Modulation_(FM)#Signal_characteristics_with_frequency_modulation|frequency modulator]]&nbsp;  (integrator and downstream phase modulator).  For the signal at point '''(3)'''&nbsp;:  
+
*the  &nbsp;[[Modulation_Methods/Frequency_Modulation_(FM)#Signal_characteristics_with_frequency_modulation|$\text{frequency modulator}$]]&nbsp;  (integrator and following phase modulator).&nbsp; For the signal at point '''(3)''':  
 
:$$\phi(t) =  {\pi}/{2}\cdot  \int_{0}^{t}
 
:$$\phi(t) =  {\pi}/{2}\cdot  \int_{0}^{t}
 
q_{\rm R}(\tau)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
 
q_{\rm R}(\tau)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
 
+
:The phase values at multiples of the symbol duration &nbsp;$T$&nbsp; are multiples of &nbsp;$π/2$, when taking into account the modulation index &nbsp;$h = 0.5$&nbsp; for the MSK method. The phase response is linear.   
The phase values at multiples of the symbol duration &nbsp;$T$&nbsp; are multiples of &nbsp;$π/2$, when taking into account the modulation index &nbsp;$h = 0.5$&nbsp; for the MSK method. The phase response is linear.  From this, the MSK signal at point &nbsp; '''(4)'''&nbsp; of the block diagram is given by:
+
*From this,&nbsp; the MSK signal at point&nbsp; '''(4)'''&nbsp; of the diagram is given by:
 
:$$s(t)  =  s_0 \cdot \cos (2 \pi  f_{\rm T}  \hspace{0.05cm}t +
 
:$$s(t)  =  s_0 \cdot \cos (2 \pi  f_{\rm T}  \hspace{0.05cm}t +
  \phi(t)) =  s_0 \cdot \cos (2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} )) \hspace{0.05cm}.$$
+
  \phi(t)) $$
 +
:$$\Rightarrow \hspace{0.3cm} s(t)  =  s_0 \cdot \cos (2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} )) \hspace{0.05cm}.$$
  
 
==Realizing MSK as Offset–QPSK==
 
==Realizing MSK as Offset–QPSK==
 
<br>
 
<br>
''Minimum Shift Keying''&nbsp; $\rm  (MSK)$&nbsp;can also be realized by modified implementation of [[Modulation_Methods/Quadrature_Amplitude_Modulation#Offset.E2.80.93Quadrature_amplitude_modulation|Offset–QPSK]]&nbsp; $\rm (O–QPSK)$&nbsp;.
+
"Minimum Shift Keying"&nbsp; $\rm  (MSK)$&nbsp;can also be realized by modified implementation of&nbsp; [[Modulation_Methods/Quadrature_Amplitude_Modulation#Offset.E2.80.93Quadrature_amplitude_modulation|$\text{Offset–QPSK}$]].
 +
 
 +
Compared with the conventional offset QPSK implementation (upper graph),&nbsp; the following modifications must be taken into account,&nbsp; which are highlighted in red in the lower graph:
 +
 
 +
[[File: EN_Mod_T_4_4_S7.png  | right|frame| Conventional Offset-QPSK&nbsp; ("O-QPSK")&nbsp; and Offset-QPSK in MSK mode]]
 +
 
 +
*The MSK symbol duration &nbsp;$T$&nbsp; is equal to the bit duration &nbsp;$T_{\rm B}$&nbsp; of the binary input signal,&nbsp; while in original Offset-QPSK,  &nbsp;$T = 2 \cdot T_{\rm B}$.
 +
 
 +
 +
*Instead of serial-to-parallel conversion and signal space allocation,&nbsp; the source symbols must now be recoded:
 +
:$$a_k = (–1)^{k+1} · a_{k–1} · q_k.$$
 +
 +
*All amplitude coefficients &nbsp;$a_k$&nbsp; with an even index &nbsp;$(a_0,\ a_2$, ...$)$&nbsp; are applied to the Dirac comb in the upper branch,&nbsp; while &nbsp;$a_1,\ a_3$, ...&nbsp; are transmitted in the lower branch.
 +
 
  
Compared with the conventional offset QPSK implementation (upper graph), the following modifications must be taken into account, which are highlighted in red in the lower graph:
+
*The spacing of the individual Dirac delta pulses of the&nbsp; "Dirac comb"&nbsp; is now &nbsp;$2T$&nbsp; instead of &nbsp;$T$&nbsp; and the offset in the quadrature branch is no longer &nbsp;$T/2$,&nbsp; but &nbsp;$T$.&nbsp; In both cases,&nbsp; the offset is equal to &nbsp;$T_{\rm B}$.
  
[[File: EN_Mod_T_4_4_S7.png  | right|frame| Conventional O-QPSK and O-QPSK in MSK mode]]
 
  
*The symbol duration &nbsp;$T$&nbsp; of MSK is equal to the bit duration &nbsp;$T_{\rm B}$&nbsp; of the binary input signal, while in original O-QPSK,  &nbsp;$T = 2 \cdot T_{\rm B}$&nbsp;.
+
*While in conventional Offset-QPSK implementation any basic transmission pulse &nbsp;$g_s(t)$&nbsp;is possible, e.g. a rectangular or a root-Nyquist pulse,&nbsp; there is only one suitable basic pulse for MSK implementation.&nbsp; This spans two symbol durations:
*Instead of serial-to-parallel conversion and signal space allocation, the source symbols must now be recoded:
 
:$$a_k = (–1)^{k+1} · a_{k–1} · q_k.$$ 
 
*All amplitude coefficients &nbsp;$a_k$&nbsp; with an even index &nbsp;$(a_0,\ a_2$, ...$)$&nbsp; are applied to the Dirac pulse in the upper branch, while 𝑎&nbsp;$a_1,\ a_3$, ...&nbsp; are transmitted in the lower branch.
 
*The spacing of the individual Dirac pulses is now &nbsp;$2T$&nbsp; instead of &nbsp;$T$&nbsp; and the offset in the quadrature branch is no longer &nbsp;$T/2$, but &nbsp;$T$. In both cases, the offset is equal to &nbsp;$T_{\rm B}$.
 
*While in conventional O-QPSK implementation any fundamental pulse &nbsp;$g_s(t)$&nbsp;is possible, for example a rectangular or root Nyquist pulse, there is only one suitable fundamental pulse for MSK implementation. This spans two symbol durations:
 
 
:$$g_{\rm MSK}(t) = \left\{ \begin{array}{l} s_0 \cdot \cos \big ({\pi/2  \cdot  t}/T \big )  \\
 
:$$g_{\rm MSK}(t) = \left\{ \begin{array}{l} s_0 \cdot \cos \big ({\pi/2  \cdot  t}/T \big )  \\
 
  0 \\  \end{array} \right.\quad
 
  0 \\  \end{array} \right.\quad
\begin{array}{*{5}c}{\rm{f\ddot{u}r}}
+
\begin{array}{*{5}c} {\rm{for}}  
\\{\rm{f\ddot{u}r}}  \\ \end{array}\begin{array}{*{10}c}
+
\\ \\ \end{array}\begin{array}{*{10}c}
 
-T \le t \le +T \hspace{0.05cm},  \\
 
-T \le t \le +T \hspace{0.05cm},  \\
{\rm sonst}\hspace{0.05cm}.  \\
+
{\rm otherwise}\hspace{0.05cm}.  \\
 
\end{array}$$
 
\end{array}$$
 
<br clear=all>
 
<br clear=all>
{{GraueBox|TEXT=$\text{Example 2:}$&nbsp;   
+
{{GraueBox|TEXT=$\text{Example 2:}$&nbsp; The graph shows  
 
[[File:P_ID1734__Mod_T_4_4_S7b_neu.png |right|frame|  Signal waveforms of O–QPSK in MSK mode]]
 
[[File:P_ID1734__Mod_T_4_4_S7b_neu.png |right|frame|  Signal waveforms of O–QPSK in MSK mode]]
  
*The graph shows the binary bipolar source signal &nbsp;$q(t)$ at the top,
+
*the binary bipolar source signal &nbsp;$q(t)$&nbsp; at the top,
*in the middle, we see the equivalent TP signals &nbsp;$s_{\rm I}(t)$&nbsp; and &nbsp;$s_{\rm Q}(t)$&nbsp; in the &nbsp;$\rm I$ and &nbsp;$\rm Q$ branches, respectively,
+
*in the middle,&nbsp; the equivalent low-pass signals &nbsp;$s_{\rm I}(t)$&nbsp; and &nbsp;$s_{\rm Q}(t)$&nbsp; in the &nbsp;$\rm I$ and &nbsp;$\rm Q$ branches, resp.,
*and below, the phase response &nbsp;$ϕ(t)$&nbsp; of the total MSK transmitted signal &nbsp;$s(t)$.  
+
*below,&nbsp; the phase response &nbsp;$ϕ(t)$&nbsp; of the total MSK transmitted signal &nbsp;$s(t)$.  
  
  
The recoding &nbsp;$a_k = (–1)^{k+1} · a_{k–1} · q_k$&nbsp; is already taken into account, as well as the MSK fundamental pulse:
+
The recoding &nbsp;$a_k = (–1)^{k+1} · a_{k–1} · q_k$&nbsp; is already taken into account,&nbsp; as well as the MSK basic pulse:
 
:$$g_{\rm MSK}(t) = \left\{ \begin{array} {l} s_0 \cdot \cos ({\pi  \cdot t}/{2  \cdot T})  \\
 
:$$g_{\rm MSK}(t) = \left\{ \begin{array} {l} s_0 \cdot \cos ({\pi  \cdot t}/{2  \cdot T})  \\
 
  0 \\  \end{array} \right.\quad
 
  0 \\  \end{array} \right.\quad
\begin{array}{*{5}c}{\rm{f\ddot{u}r} }
+
\begin{array}{*{5}c}{\rm{for} }
\\{\rm{f\ddot{u}r} } \\ \end{array}\begin{array}{*{10}c}
+
\\  \\ \end{array}\begin{array}{*{10}c}
 
-T \le t \le +T \hspace{0.05cm},  \\
 
-T \le t \le +T \hspace{0.05cm},  \\
{\rm sonst}\hspace{0.05cm}.  \\
+
{\rm otherwise}\hspace{0.05cm}.  \\
 
\end{array}$$
 
\end{array}$$
 
   
 
   
From the comparison of the top and bottom diagrams, one can see:
+
From the comparison of the top and the bottom diagrams,&nbsp; one can see:
*The MSK phase response &nbsp;$ϕ(t)$&nbsp; is step-wise linear and increases or decreases by &nbsp;$90^\circ \ (π/2)$ within each symbol duration, depending on whether &nbsp;$q_k = +1$&nbsp; or &nbsp;$q_k = -1$&nbsp; currently holds.
+
#The MSK phase response &nbsp;$ϕ(t)$&nbsp; is step-wise linear and increases or decreases by &nbsp;$90^\circ \ (π/2)$ within each symbol duration,&nbsp; depending on whether &nbsp;$q_k = +1$&nbsp; or &nbsp;$q_k = -1$&nbsp; currently holds.
*The transmitted signal &nbsp;$s(t)$&nbsp; contains the two frequencies &nbsp;$f_{\rm T} ± 1/(4T)$ in sections.  It has basically the same shape as the signal &nbsp;$s_{\rm D}(t)$&nbsp; in the section [[Modulation_Methods/Nonlinear_Digital_Modulation#Binary_FSK_with_Continuous_Phase_Matching|Binary FSK with Continuous Phase Matching]].
+
#The associated transmitted signal &nbsp;$s(t)$&nbsp; contains the two frequencies &nbsp;$f_{\rm T} ± 1/(4T)$ in sections.  It has basically the same shape as the signal &nbsp;$s_{\rm D}(t)$&nbsp; in the section [[Modulation_Methods/Nonlinear_Digital_Modulation#Binary_FSK_with_Continuous_Phase_Matching|"Binary FSK with CPM"]].
  
  
You can represent this form of MSK realization with the interactive applet: [[Applets:QPSK_und_Offset-QPSK_(Applet)|Quaternary Phase Shift Keying und Offset-QPSK]]&nbsp;  
+
&rArr; &nbsp; You can represent this MSK realization form with the SWF applet&nbsp; [[Applets:QPSK_und_Offset-QPSK_(Applet)|"Quaternary Phase Shift Keying and Offset-QPSK"]]&nbsp; using the following settings: &nbsp; "Offset–QPSK" &nbsp;&ndash;&nbsp;  "MSK allocation" &nbsp;&ndash;&nbsp;  "cosine pulse". }}  
using the following settings::
 
*Offset–QPSK,
 
*MSK allocation,
 
*cosine impulse. }}  
 
  
  
Line 235: Line 263:
 
==General Description of Continuous Phase Modulation==
 
==General Description of Continuous Phase Modulation==
 
<br>
 
<br>
We will further assume that the source is characterized by the amplitude coefficients  &nbsp;$a_ν$&nbsp;.&nbsp; These can be binary as well as &nbsp;$M$–levelled.  However, they should always be considered bipolar, for example &nbsp; $a_ν\in \{+1, -1\}$.
+
We will further assume that the source is characterized by the amplitude coefficients  &nbsp;$a_ν$.&nbsp;  
 +
#These can be binary as well as &nbsp;$M$–levelled.   
 +
#However,&nbsp; they should always be considered bipolar,&nbsp; e.g. &nbsp; $a_ν\in \{+1, -1\}$.
 +
 
  
*The&nbsp; '''phase function''' &nbsp;$ϕ(t)$&nbsp; in&nbsp; ''Continuous Phase Modulation''&nbsp; $\rm (CPM)$&nbsp; can be generally represented in the following form ( &nbsp;$(h$&nbsp; denotes the modulation index$)$:  
+
The&nbsp; &raquo;'''phase function'''&laquo; &nbsp;$ϕ(t)$&nbsp; in&nbsp; "Continuous Phase Modulation"&nbsp; $\rm (CPM)$&nbsp; can be generally represented in the following form &nbsp; $(h$&nbsp; denotes the modulation index$)$:  
 
:$$\phi(t) =  {\pi}\cdot h  \cdot\int_{-\infty}^{t}
 
:$$\phi(t) =  {\pi}\cdot h  \cdot\int_{-\infty}^{t}
 
\sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (\tau - \nu \cdot
 
\sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (\tau - \nu \cdot
 
T)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
 
T)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
*In this representation, &nbsp;$g(t)$&nbsp; denotes the&nbsp; '''frequency pulse''', which must satisfy the following condition:
+
*In this representation, &nbsp;$g(t)$&nbsp; denotes the&nbsp; &raquo;'''frequency pulse'''&laquo;,&nbsp; which must satisfy the following condition:
 
:$$\int_{-\infty}^{+\infty} g (t)\hspace{0.1cm} {\rm d}t = 1 \hspace{0.05cm}.$$
 
:$$\int_{-\infty}^{+\infty} g (t)\hspace{0.1cm} {\rm d}t = 1 \hspace{0.05cm}.$$
*But the following relationship also holds with the &nbsp; '''phase pulse''' &nbsp; $g_ϕ(t)$&nbsp;:
+
*But the following relationship also holds with the &nbsp; &raquo;'''phase pulse'''&laquo; &nbsp; $g_ϕ(t)$:
 
:$$\phi(t) =  {\pi}\cdot h  \cdot
 
:$$\phi(t) =  {\pi}\cdot h  \cdot
 
\sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_\phi (t - \nu
 
\sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_\phi (t - \nu
\cdot T),\hspace{0.2cm}{\rm wobei}\hspace{0.2cm}g_\phi(t) =
+
\cdot T),\hspace{0.2cm}{\rm where}\hspace{0.2cm}g_\phi(t) =
 
\int_{-\infty}^{t} g (\tau )\hspace{0.1cm} {\rm
 
\int_{-\infty}^{t} g (\tau )\hspace{0.1cm} {\rm
 
d}\tau\hspace{0.05cm}.$$
 
d}\tau\hspace{0.05cm}.$$
 +
 +
Many CPM variants can be realized by appropriately choosing the pulses  &nbsp;$g(t)$&nbsp; and &nbsp;$g_ϕ(t)$&nbsp;. Some of them are shown on the right.
  
 
[[File:P_ID1735__Mod_T_4_4_S8_neu.png |right|frame|  Frequency pulse and phase pulse of some CPM variants]]  
 
[[File:P_ID1735__Mod_T_4_4_S8_neu.png |right|frame|  Frequency pulse and phase pulse of some CPM variants]]  
  
Many CPM variants can be realized by appropriately choosing the pulses  &nbsp;$g(t)$&nbsp; and &nbsp;$g_ϕ(t)$&nbsp;. Some of them are shown below.
+
#The individual graphs show the CPM frequency pulse&nbsp;$g(t)$&nbsp; above and the CPM phase pulse &nbsp;$g_ϕ(t)$&nbsp; below.
+
#The two graphs on the left describe&nbsp; "$\rm MSK$".  
*In each case, the graph shows the CPM frequency pulse&nbsp;$g(t)$&nbsp; at the top and the CPM phase pulse &nbsp;$g_ϕ(t)$ at the bottom.
+
#The&nbsp; "$\rm 1–REC$"&nbsp; designation indicates that &nbsp;$g(t)$&nbsp; spans a single symbol duration &nbsp;$(T)$&nbsp; and is rectangular in shape.  
*The two graphs on the left describe&nbsp; $\rm MSK$.  
 
*The &nbsp; $\rm 1–REC$&nbsp; designation indicates that &nbsp;$g(t)$&nbsp; spans a single symbol duration &nbsp;$(T)$&nbsp; and is rectangular in shape.  
 
  
  
 
The other CPM variants were designed with the goal of further reducing the already small bandwidth of the MSK signal:
 
The other CPM variants were designed with the goal of further reducing the already small bandwidth of the MSK signal:
*For&nbsp; $\rm 1–RC$&nbsp;, a narrower power-spectral density results just because of the "softer" raised-cosine pulse &nbsp;$g(t)$&nbsp; compared to the rectangular pulse.
+
*For&nbsp; "$\rm 1–RC$",&nbsp; a narrower power-spectral density results just because of the&nbsp; "softer"&nbsp; raised-cosine pulse &nbsp;$g(t)$&nbsp; compared to the rectangular pulse.
*&nbsp; $\rm 2–RC$&nbsp; and&nbsp; $\rm 2–REC$&nbsp;are "Partial–Response" impulses, each over &nbsp;$2T$.&nbsp; This softens the phase response.  However, it also makes demodulation more difficult, since selective pseudo-steps are introduced into the data signal.
+
*"$\rm 2–RC$"&nbsp; and&nbsp; "$\rm 2–REC$"&nbsp;are partial–response pulses,&nbsp; each over &nbsp;$2T$.&nbsp; This softens the phase response.&nbsp; However,&nbsp; it also makes demodulation more difficult,&nbsp; since selective pseudo-steps are introduced into the data signal.
  
<br><br>  
+
   
The calculation of CPM procedures in the spectral range is complicated in general. Only the special case "MSK" leads to equations which are easy to handle, as shown in &nbsp;[[Aufgaben:Exercise_4.14:_Phase_Progression_of_the_MSK|Exercise A4.14]]&nbsp;.  
+
The spectral calculation of CPM methods is complicated in general.&nbsp; Only the special case&nbsp; "MSK"&nbsp; leads to equations which are easy to handle,&nbsp; as shown in &nbsp;[[Aufgaben:Exercise_4.14:_Phase_Progression_of_the_MSK|"Exercise 4.14"]].  
  
 
{{BlaueBox|TEXT=
 
{{BlaueBox|TEXT=
$\text{Conclusion:}$&nbsp; '''Continuous Phase Modulation'''&nbsp; $\rm (CPM)$&nbsp; is not a phase modulation, but is a '''nonlinear digital frequency modulation''' $\rm (FSK)$, with the goal of
+
$\text{Conclusion:}$&nbsp; The&nbsp; &raquo;'''Continuous Phase Modulation'''&laquo;&nbsp; $\rm (CPM)$&nbsp; it is not a phase modulation,&nbsp; but is a&nbsp; &raquo;'''non-linear digital frequency modulation'''&laquo;&nbsp; $\rm (FSK)$,&nbsp; with the goal
* guaranteeing a constant magnitude envelope (dips in the envelope lead to problems even with small nonlinearities),  
+
* of guaranteeing a constant magnitude envelope&nbsp; $($dips in the envelope lead to problems even with small non-linearities$)$,&nbsp; and
*to enable a continuous phase progression (phase jumps broaden the spectrum).
+
*to enable a continuous phase progression&nbsp; $($phase jumps broaden the spectrum$)$.
  
  
For more detailed information we refer to the technical literature, for example in the recommended book &nbsp; '''[Kam04]'''<ref>Kammeyer, K.D.: ''Nachrichtenübertragung.'' Stuttgart: B.G. Teubner, 4. Auflage, 2004.</ref>. }}
+
For detailed information we refer to the technical literature,&nbsp; for example in the recommended text book &nbsp; '''[Kam04]'''<ref>Kammeyer, K.D.:&nbsp; Nachrichtenübertragung.&nbsp; Stuttgart: B.G. Teubner, 4. Auflage, 2004.</ref>. }}
  
  
 
==GMSK – Gaussian Minimum Shift Keying==
 
==GMSK – Gaussian Minimum Shift Keying==
 
<br>
 
<br>
One advantage of MSK is the low bandwidth requirement, because:  '''Bandwidth is always expensive'''.
+
One advantage of Minimum Shift Keying is the low bandwidth requirement,&nbsp; because:&nbsp;   '''Bandwidth is always expensive'''.
*A slight modification to &nbsp; '''Gaussian Minimum Shift Keying'''&nbsp; $\rm (GMSK)$&nbsp; further narrows the spectrum.  
+
*A slight modification to&nbsp; &raquo;'''Gaussian Minimum Shift Keying'''&laquo;&nbsp; $\rm (GMSK)$&nbsp; further narrows the spectrum.  
*This type of modulation is used, for example, in the [[Examples_of_Communication_Systems/General_Description_of_GSM|GSM]]&nbsp;  mobile communications standard.
+
*This type of modulation is used,&nbsp; for example,&nbsp; in the [[Examples_of_Communication_Systems/General_Description_of_GSM|$\text{GSM}$]]&nbsp;  mobile communications standard.
 +
 
 +
[[File:EN_Mod_T_4_4_S9_v3.png |right|frame|  Signal waveforms in Gaussian Minimum Shift Keying&nbsp; $\rm (GMSK)$]]
  
[[File:P_ID1748__Mod_T_4_4_S9_neu.png |right|frame|  Signal waveforms in Gaussian Minimum Shift Keying&nbsp; $\rm (GMSK)$]]
 
  
 
From the graph one can see:
 
From the graph one can see:
*the frequency pulse &nbsp;$g(t)= g_{\rm G}(t)$&nbsp; is now no longer rectangular like &nbsp;$g_{\rm R}(t)$, but has flatter edges.  
+
*the frequency pulse &nbsp;$g(t)= g_{\rm G}(t)$&nbsp; is now no longer rectangular like &nbsp;$g_{\rm R}(t)$,&nbsp; but has flatter edges.  
  
  
*This results in a smoother phase response at point &nbsp; '''(3)'''&nbsp; than in  &nbsp;[[Modulation_Methods/Nonlinear_Digital_Modulation#MSK_.E2.80.93_Minimum_Shift_Keying|MSK]], where &nbsp;$ϕ(t)$&nbsp; rises / falls linearly with each symbol.
+
*This results in a smoother phase response at point &nbsp; '''(3)'''&nbsp; than in  &nbsp;[[Modulation_Methods/Nonlinear_Digital_Modulation#MSK_.E2.80.93_Minimum_Shift_Keying|$\text{MSK}$]],&nbsp; where &nbsp;$ϕ(t)$&nbsp; rises / falls linearly within each symbol.
  
 
   
 
   
*One achieves the smoother GMSK phase transitions by using a&nbsp;[[Linear_and_Time_Invariant_Systems/Some_Low-Pass_Functions_in_Systems_Theory#Gaussian_low-pass_filter|Gaussian low-pass]].&nbsp; With the system theoretic cutoff frequency&nbsp;$f_{\rm G}$, its frequency response and impulse response are as follows:  
+
*One achieves the smoother GMSK phase transitions by using a&nbsp; [[Linear_and_Time_Invariant_Systems/Some_Low-Pass_Functions_in_Systems_Theory#Gaussian_low-pass_filter|$\text{Gaussian low-pass}$]].&nbsp; With the system-theoretic cutoff frequency&nbsp; $f_{\rm G}$,&nbsp; its frequency response and impulse response are as follows:  
 
:$$H_{\rm G}(f) = {\rm e}^{-\pi\cdot (\frac{f}{2 \cdot f_{\rm G}})^2} \hspace{0.2cm}\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ\, \hspace{0.2cm}
 
:$$H_{\rm G}(f) = {\rm e}^{-\pi\cdot (\frac{f}{2 \cdot f_{\rm G}})^2} \hspace{0.2cm}\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ\, \hspace{0.2cm}
 
  h_{\rm G}(t) = 2 f_{\rm G} \cdot {\rm e}^{-\pi\cdot (2 \cdot f_{\rm G}\cdot t)^2}\hspace{0.05cm}.$$
 
  h_{\rm G}(t) = 2 f_{\rm G} \cdot {\rm e}^{-\pi\cdot (2 \cdot f_{\rm G}\cdot t)^2}\hspace{0.05cm}.$$
*The resulting frequency pulse &nbsp;$g(t)$&nbsp; at point&nbsp; '''(2)'''&nbsp; is ibtained by convolution of&nbsp;$g_{\rm R}(t)$&nbsp; and &nbsp;$h_{\rm G}(t)$.
+
 
 +
*The resulting frequency pulse &nbsp;$g(t)$&nbsp; at point&nbsp; '''(2)'''&nbsp; is obtained by convolution of&nbsp; $g_{\rm R}(t)$ &nbsp; and &nbsp; $h_{\rm G}(t)$.
  
 
   
 
   
*The signal &nbsp;$s(t)$&nbsp; at point&nbsp; '''(4)'''&nbsp; in GMSK now no longer has a constant section by section frequency (per symbol duration) as it does in MSK, even though this is difficult to see with the naked eye from the above graph.
+
*The GMSK transmitted signal &nbsp;$s(t)$&nbsp; at point&nbsp; '''(4)'''&nbsp; has no longer a constant frequency&nbsp;  $($section by section,&nbsp;  per symbol duration$)$&nbsp; as it does in MSK,&nbsp; even though this is difficult to see with the naked eye from the above graph.
 
<br clear=all>
 
<br clear=all>
{{GraueBox|TEXT=$\text{Example 3:}$&nbsp; In the GSM method, the 3dB cutoff frequency is specified as &nbsp;$f_{\rm 3dB} = 0.3/T$&nbsp;, where the following relationship exists between the system theoretic frequency and the 3dB cutoff frequency:
+
{{GraueBox|TEXT=$\text{Example 3:}$&nbsp; In the GSM method,&nbsp; the cutoff frequency is specified as &nbsp;$f_\text{3dB} = 0.3/T$,&nbsp; where the following relationship exists  
 +
*between the&nbsp;  "system-theoretic cutoff frequency"&nbsp; $f_\text{G}$&nbsp;
 +
*and the&nbsp;  "3dB cutoff frequency"&nbsp; $f_\text{3dB}$:
 
:$$H_{\rm G}(f= f_{\rm 3 \hspace{0.03cm}dB}) = {\rm e}^{-\pi\cdot ({f_{\rm 3 \hspace{0.03cm}{dB} } }/{2 f_{\rm G} })^2} =  
 
:$$H_{\rm G}(f= f_{\rm 3 \hspace{0.03cm}dB}) = {\rm e}^{-\pi\cdot ({f_{\rm 3 \hspace{0.03cm}{dB} } }/{2 f_{\rm G} })^2} =  
{1}/{\sqrt{2} }$$
+
{1}/{\sqrt{2} }\hspace{0.3cm} \Rightarrow\hspace{0.3cm}
:$$\Rightarrow\hspace{0.15cm}
 
 
  f_{\rm 3 dB} = f_{\rm G} \cdot \sqrt { {4}/{\pi}\cdot {\rm ln
 
  f_{\rm 3 dB} = f_{\rm G} \cdot \sqrt { {4}/{\pi}\cdot {\rm ln
 
  }\sqrt{2} }\approx {2}/{3}\cdot f_{\rm G}
 
  }\sqrt{2} }\approx {2}/{3}\cdot f_{\rm G}
 
  \hspace{0.05cm}.$$
 
  \hspace{0.05cm}.$$
From &nbsp;$f_{\rm 3dB} = 0.3/T$&nbsp;, &nbsp;$f_{\rm G} · T ≈ 0.45$ also follows. }}
+
From &nbsp;$f_{\rm 3dB} = 0.3/T$ &nbsp; &rArr; &nbsp;$f_{\rm G} ≈ 0.45/T$. }}
  
  

Latest revision as of 15:21, 17 January 2023

Properties of non-linear modulation methods


All modulation methods can be alternatively classified as:

  • amplitude, phase and frequency modulation,
  • analog and digital modulation methods,
  • linear and non-linear modulation methods.


Considering this last distinction, the following definition applies:

$\text{Definitions:}$ 

  • A  »linear modulation method«  is present if any linear combination of signals at modulator input leads to a corresponding linear combination at its output.
  • Otherwise,  it is a  »non-linear modulation«.


At the  "beginning of the present book"  it was already pointed out that the main difference between an analog and a digital modulation method is that

  • in the first one an analog source signal  $q(t)$  is present,  and
  • in the second one a digital signal.


However,  a closer look will reveal that there are a few more differences between these methods.  This will be discussed in more detail below.

Analog and digital AM, PM and FM methods

The following diagram shows some of the differences with respect to the classifications given above.

  •  $\text{Analog amplitude modulation}$  $\rm (AM)$  is a linear method. The locus curve - that is, the equivalent low-pass signal  $s_{\rm TP}(t)$  represented in the complex plane - is a straight line.
  • In that case,  the locus curve is an arc of a circle.  With a harmonic oscillation,  there is a line spectrum  $S(f)$  at multiples of the message frequency $f_{\rm N}$  around the carrier frequency  $f_{\rm T}$.
  • $\text{Digital amplitude modulation}$,  referred to as either   "Amplitude Shift Keying"  $\rm (ASK)$  or as  "On–Off–Keying"  $\rm (OOK)$,  is also linear.  In the binary case,  the locus curve consists of only two points.
  • Since  $\text{binary phase modulation}$  $($"Binary Phase Shift Keying",  $\rm BPSK)$  can be represented as  $\rm ASK$  with bipolar amplitude coefficients,  it is also linear.  The shape of the BPSK power-spectral density is essentially determined by the magnitude square spectrum  $|G_s(f)|^2$  of the basic transmission pulse.


However,  this also means:   The BPSK spectrum is continuous in $f$,  unlike the analog PM of a harmonic oscillation  (only one frequency!).   If one were to consider BPSK as analog PM with digital source signal  $q(t)$,  then an infinite number of Bessel line spectra would have to be convolved together to calculate the power-spectral density  ${\it Φ}_s(f)$  when  $Q(f)$  is represented as an infinite sum of individual frequencies.
  • Higher-level   "Phase Shift Keying",  such as  $\rm 8–PSK$,  is linear only in special cases, see [Klo01][1].  Digital frequency modulation  $($"Frequency Shift Keying",  $\rm FSK)$  is always non-linear.  This method is described below,  where we restrict our focus to the binary case  $\rm (2-FSK)$ .

FSK – Frequency Shift Keying


$\text{Now we assume:}$ 

  • the transmitted signal of the analog frequency modulation,
$$s(t) = s_0 \cdot \cos\hspace{-0.05cm}\big [\psi(t)\big ] \hspace{0.5cm} {\rm with} \hspace{0.5cm} \psi(t) = 2\pi f_{\rm T} \hspace{0.05cm}t + K_{\rm FM} \cdot \int q(t)\hspace{0.1cm} {\rm d}t,$$
  • the rectangular binary source signal with  $a_ν ∈ \{+1, –1\}$   ⇒   bipolar signaling:
$$q(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_s (t - \nu \cdot T) \hspace{0.5cm} {\rm with} \hspace{0.5cm} g_s(t) = \left\{ \begin{array}{l} A \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for} } \\{\rm{ } } \\ \end{array}\begin{array}{*{10}c} \hspace{0.05cm}0 < t < T\hspace{0.05cm}, \\ {\rm otherwise} \hspace{0.05cm}. \\ \end{array}$$


  • Summarizing the amplitude  $A$  and the modulator constant  $K_{\rm FM}$  into the  "frequency deviation" (see below for definition)
$${\rm \Delta}f_{\rm A} = \frac{A \cdot K_{\rm FM}}{2 \pi},$$
then the  »FSK transmitted signal«  in the  $ν$–th time interval is:
$$s(t) = s_0 \cdot \cos\hspace{-0.05cm}\big [2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} ) \big ]\hspace{0.05cm}.$$
  • This can be calculated with the two possible signal frequencies
$$f_{\rm +1} = f_{\rm T} +{\rm \Delta}f_{\rm A} \hspace{0.05cm}, \hspace{0.2cm}f_{\rm -1} = f_{\rm T} -{\rm \Delta}f_{\rm A}$$
and written as:
$$s(t) = \left\{ \begin{array}{l} s_0 \cdot \cos (2 \pi \cdot f_{\rm +1} \cdot t ) \\ s_0 \cdot \cos (2 \pi \cdot f_{\rm -1} \cdot t ) \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for}} \\{\rm{for}} \\ \end{array}\begin{array}{*{10}c} \hspace{0.05cm}a_{ \nu} = +1 \hspace{0.05cm}, \\ \hspace{0.05cm}a_{ \nu} = -1\hspace{0.05cm}. \\ \end{array}$$
  • Thus,  at any given time,  only one of the two frequencies  $f_{+1}$  and  $f_{–1}$  arises.  The carrier frequency  $f_{\rm T}$  itself does not occur in the signal.


$\text{Definition:}$  The  »frequency deviation«  $Δf_{\rm A}$ 

  • is defined in the same way as for analog frequency modulation, namely
  • as the maximum deviation of the instantaneous frequency  $f_{\rm A}(t)$  from the carrier frequency  $f_{\rm T}$:
$$ {\rm \Delta}f_{\rm A} =f_{\rm +1} - f_{\rm T}\hspace{0.05cm}, \hspace{0.2cm}f_{\rm -1} = f_{\rm T} -f_{\rm -1}.$$

Sometimes,  the  »total frequency deviation«  $ 2 \cdot {\rm \Delta}f_{\rm A} =f_{\rm +1} - f_{\rm -1}$  is used in the literature.


Another important descriptive quantity in this context is the  "modulation index",  which was also already defined for analog frequency modulation as  $η = Δf_{\rm A}/f_{\rm N}.$     For FSK,  a slightly different definition is required,  which is taken into account here with a different variable symbol:   $η   ⇒   h$.

$\text{Definitions:}$ 

  • For digital frequency modulation  $\rm (FSK)$,  the  »modulation index«   $h$  denotes the ratio of the total frequency deviation and the symbol rate  $1/T$:
$$h = \frac{2 \cdot {\rm \Delta}f_{\rm A} }{1/T} = 2 \cdot {\rm \Delta}f_{\rm A}\cdot T \hspace{0.05cm}.$$
  • Sometimes  $h$  is also referred to as »phase deviation« in the literature.


$\text{Example 1:}$  The graph below shows the FSK transmitted signal  $s(t)$  for

  • the binary source signal  $q(t)$  sketched above with amplitude values  $\pm A =\pm 1 \ \rm V$,  and
  • the carrier signal  $z(t)$  drawn below with four oscillations per symbol duration  $(f_{\rm T} · T = 4)$.
Binary FSK signals  $q(t)$,  $z(t)$  and  $s(t)$






This results in the following characteristic values for the FSK system:

  1. The underlying frequency deviation is $Δf_{\rm A} = 1/T$.
  2. The modulation index is  $h = 2$.
  3. The two possible frequencies are  $f_{\rm +1} = 5/T \hspace{0.05cm},\hspace{0.2cm}f_{\rm -1} = 3/T \hspace{0.05cm}.$


Thus, for an FSK transmission system with bit rate  $1 \ {\rm Mbit/s} \ \ (T = 1 \ \rm µ s)$,  the following FM constant would have to be used:

$$K_{\rm FM} = \frac{2 \pi \cdot {\rm \Delta}f_{\rm A} }{A } = \frac{2 \pi }{A \cdot T } \approx 6.28 \cdot 10^{6}\,\,{\rm V^{-1}s^{-1} }\hspace{0.05cm}.$$

Coherent demodulation of FSK


The diagram shows the best possible demodulator for binary FSK that operates coherently.

Coherent FSK demodulator
  • It thus requires knowledge of the phase of the FSK signal.
  • This is accounted for in the block diagram by assuming that the received signal  $r(t)$  is equal to the transmitted signal  $s(t)$.


This demodulator operates according to following principle  (see upper arrangement):

  1. We are dealing with a $\text{maximum–likelihood receiver}$  $\rm (ML)$  with  $\text{matched filter}$  realization.  This filter with frequency response $H_{\rm MF}(f)$  can also be realized as an integrator with rectangular basic transmission pulse  $g_s(t)$.
  2. Both signals  $b_{+1}(t)$  and  $b_{–1}(t)$  before their corresponding matched filters are obtained by phase-appropriate multiplication with the oscillations of the frequencies  $f_{+1}$  and  $f_{–1}$,  respectively.
  3. The maximum-likelihood receiver is known to decide on the branch  (for the symbol)  with the larger  "metric",  taking into account the following matched filter. 
  4. This means:  $a_ν = +1$  was probably sent if the following condition is satisfied:
$$d_{\rm +1}(\nu \cdot T) > d_{\rm -1}(\nu \cdot T) $$
$$\Rightarrow \hspace{0.3cm} d(\nu \cdot T) = d_{\rm +1}(\nu \cdot T) - d_{\rm -1}(\nu \cdot T) > 0\hspace{0.05cm}.$$

The upper block diagram has been drawn according to this description for better understanding.

  • Of course,  matched filtering could instead also be moved to the right of the discrimination,  as shown in the lower model. 
  • Then only one filter has to be implemented.
  • In  "Exercise 4.13" , this FSK demodulator is discussed in detail.
  • On the exercise page you can also see the corresponding signal waveforms.

Error probability of orthogonal FSK


$\text{Definition:}$  One speaks of  »orthogonal FSK«,

  • if the modulation index  $h$  is an integer multiple of  $0.5$,  and thus
  • the frequency deviation  $Δf_{\rm A}$  is an integer multiple of  $0.25/T$.


For the coherent demodulator,  the correlation coefficient between  $d_{+1}(T_{\rm D})$  and  $d_{–1}(T_{\rm D})$  is zero at all detection times.  Thus,  the magnitude  $|d(T_{\rm D})|$  – the distance of the detection samples from the threshold –  is constant.  No intersymbol interference occurs.

If one assumes

  • orthogonal FSK,
  • an AWGN channel  $($captured by the quotient  $E_{\rm B}/N_0)$,  and
  • the coherent demodulation described here,


then the bit error probability is given by:

$$p_{\rm B} = {\rm Q}\left ( \sqrt{{E_{\rm B}}/{N_0 }} \hspace{0.1cm}\right ) = {1}/{2}\cdot {\rm erfc}\left ( \sqrt{{E_{\rm B}}/(2 N_0 }) \hspace{0.1cm}\right ).$$

This corresponds to a degradation of  $3 \ \rm dB$  compared to $\text{BSPK}$  because

  • although the coherent FSK demodulator gives the same result with respect to the useful signal,
  • and the noise powers in the two branches are also exactly the same as with BPSK,
  • due to the subtraction,  the total noise power is doubled.


However,  while non-coherent demodulation is not possible under any circumstances in binary phase modulation (BPSK),  there is also a  "non-coherent FSK demodulator",  but with a somewhat increased probability of error:

$$p_{\rm B} = {1}/{2} \cdot {\rm e}^{- E_{\rm B}/{(2N_0) }}\hspace{0.05cm}.$$

The derivation of this equation is given in the chapter  "Carrier Frequency Systems with Non-Coherent Demodulation"  of the book  "Digital Signal Transmission".

Binary FSK with Continuous Phase Matching


We continue to consider the orthogonal FSK.  The graph shows the source signal  $q(t)$  at the top and,  drawn below,  the FSK signal  $s_{\rm A}(t)$  with frequency deviation  $Δf_{\rm A} = 1/T$ ⇒ modulation index  $h = 2 · Δf_{\rm A} · T = 2$.  The following should be noted about the other signal waveforms:

Binary FSK signals with  $h = 2$,  $h = 1$  and  $h = 0.5$,  partially with phase matching
  • The signal $s_{\rm B}(t)$  uses instantaneous frequencies  $f_{+1} = 4.5/T$,  $f_{–1} = 3.5/T$   ⇒   $Δf_{\rm A} ·T = 0.5$   ⇒   $h = 1$.  This FSK is also orthogonal because of $h = 1$  $($multiple of  $0.5)$.  However,  with smaller  $h$,  the bandwidth efficiency is better   ⇒   the spectrum  $S_{\rm B}(f)$  is narrower than  $S_{\rm A}(f)$.


  • However,  in the signal $s_{\rm B}(t)$,  one can see a phase jump by  $π$  at each symbol boundary,  which again results in a broadening of the spectrum.  Such phase jumps can be avoided by phase matching.  This is then referred to as  »Continuous Phase Modulation«  $\rm (CPM)$.


  • Also,  for the CPM signal  $s_{\rm C}(t)$,  $f_{+1} = 4.5/T,  f_{–1} = 3.5/T$  and  $h = 1$  hold.  In the range  $0$ ... $T$,  the coefficient  $a_1 = +1$  is represented by  $\cos (2π·f_{+1}·t)$,  and in the range  $T$ ... $2T$,  on the other hand,  the also positive coefficient  $a_2 = +1$  is represented by  $\ –\cos (2π·f_{+1}·t)$   ⇒   shifted by  $π$.


  • The modulation index  $h = 0.5$  of signal $s_{\rm D}(t)$  is the smallest value that allows orthogonal FSK   ⇒   »Minimum Shift Keying«  $\rm (MSK)$.  In MSK,  four different initial phases are possible at each symbol boundary,  depending on the previous symbols.


⇒   The  (German language)  SWF applet  "Frequency Shift Keying & Continuous Phase Modulation"  illustrate the facts presented here.

MSK – Minimum Shift Keying


The graphic shows the block diagram for generating an MSK modulation and typical signal properties at various points of the MSK transmitter. One can recognize

Block diagram for generating a MSK signal
  • the digital source signal at point  (1),  a sequence of Dirac delta pulses spaced by  $T$,  weighted by the coefficients  $a_ν ∈ \{–1, +1\}$:
$$q_\delta(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot \delta (t - \nu \cdot T)\hspace{0.05cm};$$
  • the rectangular signal  $q_{\rm R}(t)$  at point  (2)  after convolution with the rectangular pulse $g(t)$  of duration  $T$  and height  $1/T$:
$$q_{\rm R}(t) = \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (t - \nu \cdot T)\hspace{0.05cm},$$
$$\phi(t) = {\pi}/{2}\cdot \int_{0}^{t} q_{\rm R}(\tau)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
The phase values at multiples of the symbol duration  $T$  are multiples of  $π/2$, when taking into account the modulation index  $h = 0.5$  for the MSK method. The phase response is linear.
  • From this,  the MSK signal at point  (4)  of the diagram is given by:
$$s(t) = s_0 \cdot \cos (2 \pi f_{\rm T} \hspace{0.05cm}t + \phi(t)) $$
$$\Rightarrow \hspace{0.3cm} s(t) = s_0 \cdot \cos (2 \pi \cdot t \cdot (f_{\rm T}+a_{ \nu} \cdot {\rm \Delta}f_{\rm A} )) \hspace{0.05cm}.$$

Realizing MSK as Offset–QPSK


"Minimum Shift Keying"  $\rm (MSK)$ can also be realized by modified implementation of  $\text{Offset–QPSK}$.

Compared with the conventional offset QPSK implementation (upper graph),  the following modifications must be taken into account,  which are highlighted in red in the lower graph:

Conventional Offset-QPSK  ("O-QPSK")  and Offset-QPSK in MSK mode
  • The MSK symbol duration  $T$  is equal to the bit duration  $T_{\rm B}$  of the binary input signal,  while in original Offset-QPSK,  $T = 2 \cdot T_{\rm B}$.


  • Instead of serial-to-parallel conversion and signal space allocation,  the source symbols must now be recoded:
$$a_k = (–1)^{k+1} · a_{k–1} · q_k.$$
  • All amplitude coefficients  $a_k$  with an even index  $(a_0,\ a_2$, ...$)$  are applied to the Dirac comb in the upper branch,  while  $a_1,\ a_3$, ...  are transmitted in the lower branch.


  • The spacing of the individual Dirac delta pulses of the  "Dirac comb"  is now  $2T$  instead of  $T$  and the offset in the quadrature branch is no longer  $T/2$,  but  $T$.  In both cases,  the offset is equal to  $T_{\rm B}$.


  • While in conventional Offset-QPSK implementation any basic transmission pulse  $g_s(t)$ is possible, e.g. a rectangular or a root-Nyquist pulse,  there is only one suitable basic pulse for MSK implementation.  This spans two symbol durations:
$$g_{\rm MSK}(t) = \left\{ \begin{array}{l} s_0 \cdot \cos \big ({\pi/2 \cdot t}/T \big ) \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c} {\rm{for}} \\ \\ \end{array}\begin{array}{*{10}c} -T \le t \le +T \hspace{0.05cm}, \\ {\rm otherwise}\hspace{0.05cm}. \\ \end{array}$$


$\text{Example 2:}$  The graph shows

Signal waveforms of O–QPSK in MSK mode
  • the binary bipolar source signal  $q(t)$  at the top,
  • in the middle,  the equivalent low-pass signals  $s_{\rm I}(t)$  and  $s_{\rm Q}(t)$  in the  $\rm I$ and  $\rm Q$ branches, resp.,
  • below,  the phase response  $ϕ(t)$  of the total MSK transmitted signal  $s(t)$.


The recoding  $a_k = (–1)^{k+1} · a_{k–1} · q_k$  is already taken into account,  as well as the MSK basic pulse:

$$g_{\rm MSK}(t) = \left\{ \begin{array} {l} s_0 \cdot \cos ({\pi \cdot t}/{2 \cdot T}) \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{for} } \\ \\ \end{array}\begin{array}{*{10}c} -T \le t \le +T \hspace{0.05cm}, \\ {\rm otherwise}\hspace{0.05cm}. \\ \end{array}$$

From the comparison of the top and the bottom diagrams,  one can see:

  1. The MSK phase response  $ϕ(t)$  is step-wise linear and increases or decreases by  $90^\circ \ (π/2)$ within each symbol duration,  depending on whether  $q_k = +1$  or  $q_k = -1$  currently holds.
  2. The associated transmitted signal  $s(t)$  contains the two frequencies  $f_{\rm T} ± 1/(4T)$ in sections. It has basically the same shape as the signal  $s_{\rm D}(t)$  in the section "Binary FSK with CPM".


⇒   You can represent this MSK realization form with the SWF applet  "Quaternary Phase Shift Keying and Offset-QPSK"  using the following settings:   "Offset–QPSK"  –  "MSK allocation"  –  "cosine pulse".


General Description of Continuous Phase Modulation


We will further assume that the source is characterized by the amplitude coefficients  $a_ν$. 

  1. These can be binary as well as  $M$–levelled.
  2. However,  they should always be considered bipolar,  e.g.   $a_ν\in \{+1, -1\}$.


The  »phase function«  $ϕ(t)$  in  "Continuous Phase Modulation"  $\rm (CPM)$  can be generally represented in the following form   $(h$  denotes the modulation index$)$:

$$\phi(t) = {\pi}\cdot h \cdot\int_{-\infty}^{t} \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g (\tau - \nu \cdot T)\hspace{0.1cm} {\rm d}\tau \hspace{0.05cm}.$$
  • In this representation,  $g(t)$  denotes the  »frequency pulse«,  which must satisfy the following condition:
$$\int_{-\infty}^{+\infty} g (t)\hspace{0.1cm} {\rm d}t = 1 \hspace{0.05cm}.$$
  • But the following relationship also holds with the   »phase pulse«   $g_ϕ(t)$:
$$\phi(t) = {\pi}\cdot h \cdot \sum_{\nu = - \infty}^{+\infty}a_{ \nu} \cdot g_\phi (t - \nu \cdot T),\hspace{0.2cm}{\rm where}\hspace{0.2cm}g_\phi(t) = \int_{-\infty}^{t} g (\tau )\hspace{0.1cm} {\rm d}\tau\hspace{0.05cm}.$$

Many CPM variants can be realized by appropriately choosing the pulses  $g(t)$  and  $g_ϕ(t)$ . Some of them are shown on the right.

Frequency pulse and phase pulse of some CPM variants
  1. The individual graphs show the CPM frequency pulse $g(t)$  above and the CPM phase pulse  $g_ϕ(t)$  below.
  2. The two graphs on the left describe  "$\rm MSK$".
  3. The  "$\rm 1–REC$"  designation indicates that  $g(t)$  spans a single symbol duration  $(T)$  and is rectangular in shape.


The other CPM variants were designed with the goal of further reducing the already small bandwidth of the MSK signal:

  • For  "$\rm 1–RC$",  a narrower power-spectral density results just because of the  "softer"  raised-cosine pulse  $g(t)$  compared to the rectangular pulse.
  • "$\rm 2–RC$"  and  "$\rm 2–REC$" are partial–response pulses,  each over  $2T$.  This softens the phase response.  However,  it also makes demodulation more difficult,  since selective pseudo-steps are introduced into the data signal.


The spectral calculation of CPM methods is complicated in general.  Only the special case  "MSK"  leads to equations which are easy to handle,  as shown in  "Exercise 4.14".

$\text{Conclusion:}$  The  »Continuous Phase Modulation«  $\rm (CPM)$  it is not a phase modulation,  but is a  »non-linear digital frequency modulation«  $\rm (FSK)$,  with the goal

  • of guaranteeing a constant magnitude envelope  $($dips in the envelope lead to problems even with small non-linearities$)$,  and
  • to enable a continuous phase progression  $($phase jumps broaden the spectrum$)$.


For detailed information we refer to the technical literature,  for example in the recommended text book   [Kam04][2].


GMSK – Gaussian Minimum Shift Keying


One advantage of Minimum Shift Keying is the low bandwidth requirement,  because:  Bandwidth is always expensive.

  • A slight modification to  »Gaussian Minimum Shift Keying«  $\rm (GMSK)$  further narrows the spectrum.
  • This type of modulation is used,  for example,  in the $\text{GSM}$  mobile communications standard.
Signal waveforms in Gaussian Minimum Shift Keying  $\rm (GMSK)$


From the graph one can see:

  • the frequency pulse  $g(t)= g_{\rm G}(t)$  is now no longer rectangular like  $g_{\rm R}(t)$,  but has flatter edges.


  • This results in a smoother phase response at point   (3)  than in  $\text{MSK}$,  where  $ϕ(t)$  rises / falls linearly within each symbol.


  • One achieves the smoother GMSK phase transitions by using a  $\text{Gaussian low-pass}$.  With the system-theoretic cutoff frequency  $f_{\rm G}$,  its frequency response and impulse response are as follows:
$$H_{\rm G}(f) = {\rm e}^{-\pi\cdot (\frac{f}{2 \cdot f_{\rm G}})^2} \hspace{0.2cm}\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ\, \hspace{0.2cm} h_{\rm G}(t) = 2 f_{\rm G} \cdot {\rm e}^{-\pi\cdot (2 \cdot f_{\rm G}\cdot t)^2}\hspace{0.05cm}.$$
  • The resulting frequency pulse  $g(t)$  at point  (2)  is obtained by convolution of  $g_{\rm R}(t)$   and   $h_{\rm G}(t)$.


  • The GMSK transmitted signal  $s(t)$  at point  (4)  has no longer a constant frequency  $($section by section,  per symbol duration$)$  as it does in MSK,  even though this is difficult to see with the naked eye from the above graph.


$\text{Example 3:}$  In the GSM method,  the cutoff frequency is specified as  $f_\text{3dB} = 0.3/T$,  where the following relationship exists

  • between the  "system-theoretic cutoff frequency"  $f_\text{G}$ 
  • and the  "3dB cutoff frequency"  $f_\text{3dB}$:
$$H_{\rm G}(f= f_{\rm 3 \hspace{0.03cm}dB}) = {\rm e}^{-\pi\cdot ({f_{\rm 3 \hspace{0.03cm}{dB} } }/{2 f_{\rm G} })^2} = {1}/{\sqrt{2} }\hspace{0.3cm} \Rightarrow\hspace{0.3cm} f_{\rm 3 dB} = f_{\rm G} \cdot \sqrt { {4}/{\pi}\cdot {\rm ln }\sqrt{2} }\approx {2}/{3}\cdot f_{\rm G} \hspace{0.05cm}.$$

From  $f_{\rm 3dB} = 0.3/T$   ⇒  $f_{\rm G} ≈ 0.45/T$.


Exercises for the chapter


Exercise 4.13: FSK Demodulation

Exercise 4.14: Phase Progression of the MSK

Exercise 4.14Z: Offset QPSK vs. MSK

Exercise 4.15: MSK Compared with BPSK and QPSK

Exercise 4.15Z: MSK Basic Pulse and MSK Spectrum

Exercise 4.16: Comparison between Binary PSK and Binary FSK

References

  1. Klostermeyer, R.:  Digitale Modulation.  Braunschweig: Vieweg, 2001.
  2. Kammeyer, K.D.:  Nachrichtenübertragung.  Stuttgart: B.G. Teubner, 4. Auflage, 2004.