Difference between revisions of "Signal Representation/Direct Current Signal - Limit Case of a Periodic Signal"

Revision as of 21:27, 25 November 2022

Time signal representation

$\text{Definition:}$ A $\text{direct current (DC) signal}$ is a deterministic signal whose instantaneous values are constant for all times $t$ from $-\infty$ to $+\infty$. Such a signal is the borderline case of a $\text{harmonic oscillation}$, where the period duration $T_{0}$ has an infinitely large value.

DC signal in time domain

According to this definition a DC signal always ranges from $t = -\infty$ to $t = +\infty$. If the constant signal is only switched on at the time $t = 0$ there is no DC signal.

A direct signal can never be a carrier of information in a communication system, but message signals can possess a "direct signal part".
All statements made in the following for the direct current signal apply in the same way also to such a direct signal component.

$\text{Definition:}$ For the $\text{DC signal component}$ $A_{0}$ of any signal $x(t)$ applies:

$$A_0 = \lim_{T_{\rm M}\to\infty}\,\frac{1}{T_{\rm M} }\cdot\int^{T_{\rm M}/2}_{-T_{\rm M}/2}x(t)\,{\rm d} t. $$

The measurement duration $T_{\rm M}$ should always be selected as large as possible (infinite in borderline cases).
The given equation is only valid if $T_{\rm M}$ lies symmetrical about the time $t=0$.

Random signal with DC componentl

$\text{Example 1:}$ The graph shows a random signal $x(t)$.

The DC component $A_{0}$ is here $2\ \rm V$.
In the sense of statistics, $A_{0}$ corresponds to the linear mean.

Spectral representation

We now look at the situation in the frequency domain. From the time function it is already obvious, that it contains - spectrally speaking - only one single (physical) frequency, namely the frequency $f=0$.

This result shall now be derived mathematically. In anticipation of the chapter $\text{Fourier Transform}$ the connection between the time signal $x(t)$ and the corresponding spectrum $X(f)$ is already given here:

$$X(f)= \hspace{0.05cm}\int_{-\infty} ^{{+}\infty} x(t) \, \cdot \, { \rm e}^{-\rm j 2\pi \it ft} \,{\rm d}t.$$

The spectral function $X(f)$ is called after the French mathematician $\text{Jean Baptiste Joseph Fourier}$ the Fourier transform of $x(t)$ and the short name for this functional relation is

$$X(f)\ \bullet\!\!-\!\!\!-\!\!\circ\,\ x(t).$$

For example, if $x(t)$ describes a voltage curve, so $X(f)$ has the unit "V/Hz".

Applying the Fourier transform to the DC signal $x(t)=A_{0}$ yields the spectral function

$$X(f)= A_0 \cdot \int_{-\infty} ^{+\hspace{0.01cm}\infty}\rm e \it ^{-\rm {j 2\pi} \it ft} \,{\rm d}t$$

with the following properties:

The integral diverges for $f=0$, i.e. it returns an infinitely large value $($integration over the constant value $1)$.
For a frequency $f\ne 0$ on the other hand, the integral is zero; the corresponding proof, however, is not trivial (see next section).

$\text{Definition:}$ The searched spectral function $X(f)$ is compactly expressed by the following equation

$$X(f) = A_0 \, \cdot \, \rm \delta(\it f).$$

$\delta(f)$ is denoted as the $\text{Dirac function}$, also known as " distribution".
$\delta(f)$ is a mathematically complicated function; the derivation can be found on the next section.

DC signal and its spectral function

$\text{Example 2:}$ The graphic shows the functional connection

between an DC signal $x(t)=A_{0}$ and
its corresponding spectral function $X(f)=A_{0} \cdot \delta(f)$.

The Dirac function at frequency $f=0$ is represented by an arrow with the weight $A_{0}$.

Dirac (delta) function in frequency domain

$\text{Definition:}$ The $\text{Dirac delta function}$ ⇒ short: $\text{Dirac function}$ has the following properties:

The Dirac function is infinitely narrow, i.e. it is $\delta(f)=0$ for $f \neq 0$.
The Dirac function $\delta(f)$ is infinitely high at the frequency $f = 0$ .
The Dirac weight $($area of the Dirac function$)$ yields a finite value, namely $1$:

$$\int_\limits{-\infty} ^{+\infty} \delta( f)\,{\rm d}f =1.$$

It follows from this last property that $\delta(f)$ has the unit ${\rm Hz}^{-1} = {\rm s}$ .

The derivation of the Dirac function

$\text{Proof:}$ For the mathematical derivation of these properties we assume a dimensionless direct signal $x(t)$.

To force the convergence of the Fourier integral, the non-energy-limited signal $x(t)$ is multiplied by a bilateral declining exponential function. The graph shows the signal $x(t)=1$ and the energy-limited signal

$$x_{\varepsilon} (t) = \rm e^{\it -\varepsilon \hspace{0.05cm} \cdot \hspace{0.05cm} \vert \hspace{0.01cm} t \hspace{0.01cm}\vert}{.}$$

It applies $\varepsilon > 0$. At the limit $\varepsilon \to 0$ , $x_{\varepsilon}(t)$ passes to $x(t)=1$.

The spectral representation is obtained by applying the Fourier integral given above:

$$X_\varepsilon (f)=\int_{-\infty}^{0} {\rm e}^{\varepsilon{t} }\, {\cdot}\, {\rm e}^{-\rm j 2\pi \it ft} \,{\rm d}t \hspace{0.2cm}+ \hspace{0.2cm} \int_{0}^{+\infty} {\rm e}^{-\varepsilon t} \,{\cdot}\, { \rm e}^{-\rm j 2\pi \it ft} \,{\rm d}t.$$

After integration and combination of both parts we obtain the purely real spectral function of the energy-limited signal $x_{\varepsilon}(t)$:

$$X_\varepsilon (f)=\frac{1}{\varepsilon -\rm j \cdot 2\pi \it f} + \frac{1}{\varepsilon+\rm j \cdot 2\pi \it f} = \frac{2\varepsilon}{\varepsilon^2 + (\rm 2\pi {\it f}\hspace{0.05cm} ) \rm ^2} \, .$$

The area under the $X_\varepsilon (f)$ curve is independent of the parameter $\varepsilon$ equals $1$. The smaller $ε$ is selected, the narrower and higher the function becomes, as the following (German language) learning video shows:
"Herleitung und Visualisierung der Diracfunktion" ⇒ "Derivation and visualization of the Dirac function".

The limit for $\varepsilon \to 0$ returns the Dirac function with the weight $1$:

$$\lim_{\varepsilon \hspace{0.05cm} \to \hspace{0.05cm} 0}X_\varepsilon (f)= \delta(f).$$

Exercises for the chapter

Exercise 2.2: Direct Current Component of Signals

Exercise 2.2Z: Non–Linearities

@@ Line 10: / Line 10: @@
 {{BlaueBox|TEXT=
 $\text{Definition:}$&nbsp;
-A&nbsp; $\text{direct current (DC) signal}$ &nbsp; is a deterministic signal whose instantaneous values are constant for all times&nbsp; $t$&nbsp; from&nbsp; $-\infty$&nbsp; to&nbsp; $+\infty$.&nbsp; Such a signal is the borderline case of a&nbsp; [[ Signal_Representation/Harmonic_Oscillation|harmonic oscillation]],  where the period duration&nbsp; $T_{0}$&nbsp; has an infinitely large value.}}
+A&nbsp; $\text{direct current (DC) signal}$ &nbsp; is a deterministic signal whose instantaneous values are constant for all times&nbsp; $t$&nbsp; from&nbsp; $-\infty$&nbsp; to&nbsp; $+\infty$.&nbsp; Such a signal is the borderline case of a&nbsp; [[ Signal_Representation/Harmonic_Oscillation|$\text{harmonic oscillation}$]],  where the period duration&nbsp; $T_{0}$&nbsp; has an infinitely large value.}}
@@ Line 44: / Line 44: @@
 This result shall now be derived mathematically.&nbsp;
-In anticipation of the chapter&nbsp; [[Signal_Representation/Fourier_Transform_and_Its_Inverse#Das_erste_Fourierintegral|Fourier Transform]]&nbsp;  the connection between the time signal&nbsp; $x(t)$&nbsp; and the corresponding spectrum&nbsp; $X(f)$&nbsp; is already given here:
+In anticipation of the chapter&nbsp; [[Signal_Representation/Fourier_Transform_and_Its_Inverse#Das_erste_Fourierintegral|$\text{Fourier Transform}$]]&nbsp;  the connection between the time signal&nbsp; $x(t)$&nbsp; and the corresponding spectrum&nbsp; $X(f)$&nbsp; is already given here:
 :$$X(f)= \hspace{0.05cm}\int_{-\infty} ^{{+}\infty} x(t) \, \cdot \, { \rm e}^{-\rm j 2\pi \it ft} \,{\rm d}t.$$
 The spectral function&nbsp; $X(f)$&nbsp; is called after the French mathematician&nbsp;
-[https://en.wikipedia.org/wiki/Joseph_Fourier Jean Baptiste Joseph Fourier]&nbsp; the Fourier transform of&nbsp; $x(t)$&nbsp; and the short name for this functional relation is
+[https://en.wikipedia.org/wiki/Joseph_Fourier $\text{Jean Baptiste Joseph Fourier}$]&nbsp; the Fourier transform of&nbsp; $x(t)$&nbsp; and the short name for this functional relation is
 :$$X(f)\ \bullet\!\!-\!\!\!-\!\!\circ\,\ x(t).$$
@@ Line 116: / Line 116: @@
 :$$X_\varepsilon (f)=\frac{1}{\varepsilon -\rm  j \cdot 2\pi \it f} + \frac{1}{\varepsilon+\rm j \cdot 2\pi \it  f} = \frac{2\varepsilon}{\varepsilon^2 + (\rm 2\pi {\it f}\hspace{0.05cm} ) \rm ^2} \, .$$
-*The area under the&nbsp; $X_\varepsilon (f)$ curve is independent of the parameter&nbsp; $\varepsilon$&nbsp; equals&nbsp; $1$. The smaller&nbsp; $ε$&nbsp; is selected, the narrower and higher the function becomes, as the following (German language) learning video shows:<br> &nbsp; &nbsp; &nbsp; &nbsp;[[Herleitung und Visualisierung der Diracfunktion (Lernvideo)|Herleitung und Visualisierung der Diracfunktion]] &nbsp; &rArr; &nbsp; "Derivation and visualization of the Dirac function".
+*The area under the&nbsp; $X_\varepsilon (f)$ curve is independent of the parameter&nbsp; $\varepsilon$&nbsp; equals&nbsp; $1$. The smaller&nbsp; $ε$&nbsp; is selected, the narrower and higher the function becomes, as the following (German language) learning video shows:<br> &nbsp; &nbsp; &nbsp; &nbsp;[[Herleitung und Visualisierung der Diracfunktion (Lernvideo)|"Herleitung und Visualisierung der Diracfunktion"]] &nbsp; &rArr; &nbsp; "Derivation and visualization of the Dirac function".
 *The limit for&nbsp; $\varepsilon \to 0$&nbsp; returns the Dirac function with the weight&nbsp; $1$: