Exercise 1.10: BPSK Baseband Model

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Unbalanced channel frequency response

In this exercise, we consider a BPSK system with coherent demodulation, i.e.

$$s(t) \ = \ z(t) \cdot q(t),$$
$$b(t) \ = \ 2 \cdot z(t) \cdot r(t) .$$

The designations chosen here are based on the  block diagram  in the theory section.

The influence of a channel frequency response  $H_{\rm K}(f)$  can be taken into account in a simple way if it is described together with modulator and demodulator by a common baseband frequency response:

$$H_{\rm MKD}(f) = {1}/{2} \cdot \big [ H_{\rm K}(f-f_{\rm T}) + H_{\rm K}(f+f_{\rm T})\big ] .$$
  • Thus the modulator and demodulator are virtually shortened against each other, and
  • the bandpass channel  $H_{\rm K}(f)$  is transformed into the lowpass range.


The resulting transmission function  $H_{\rm MKD}(f)$  should not be confused with the lowpass transmission function  $H_{\rm K, \, TP}(f)$  as described in the chapter  Equivalent Low-Pass Signal and its Spectral Function  of the book "Signal Representation", which results from  $H_{\rm K}(f)$  by truncating the components at negative frequencies as well as a frequency shift by  $f_{\rm T}$  to the left.

For frequency responses, in contrast to spectral functions, the doubling of the components at positive frequencies must be omitted.




Notes:



Questions

1

Which statements are valid for the equivalent lowpass function  $H_{\rm K, \, TP}(f)$ ?

 $H_{\rm K, \, TP}(f=0)= 2$ holds.
 $H_{\rm K, \, TP}(f = \Delta f_{\rm K}/4) = 1$ holds.
 $H_{\rm K, \, TP}(f = –\Delta f_{\rm K}/4) = 0.75$ holds.
The corresponding time function  $h_{\rm K, \, TP}(t)$  is complex.

2

Which statements are valid for the frequency response  $H_{\rm MKD}(f)$ ?

 $H_{\rm MKD}(f=0)= 2$ holds.
 $H_{\rm MKD}(f = \Delta f_{\rm K}/4) = 1$ holds.
 $H_{\rm MKD}(f = –\Delta f_{\rm K}/4) = 0.75$ holds.
The corresponding time function  $h_{\rm MKD}(t)$  is complex.

3

Calculate the time function  $h_{\rm MKD}(t)$. Specify the value at  $t = 0$. 

$ h_{\rm MKD}(t = 0)/\Delta f_{\rm K} \ = \ $

4

Which of the following statements are true?

$h_{\rm MKD}(t)$  has equidistant zero crossings at distance  $1/\Delta f_{\rm K}$.
$h_{\rm MKD}(t)$  has equidistant zero crossings at distance  $2/\Delta f_{\rm K}$.


Solution

(1)  Statements 2, 3 and 4 are correct:

  • $H_{\rm K,TP}(f)$ results from $H_{\rm K}(f)$ by cutting off the negative frequency components and shifting $f_{\rm T}$ to the left.
  • For frequency responses – in contrast to spectra – the doubling of the components at positive frequencies is omitted. Therefore:
$$H_{\rm K,\hspace{0.04cm} TP}(f= 0) = H_{\rm K}(f= f_{\rm T})=1.$$
  • Because of the real and asymmetrical spectral functions $H_{\rm K,\hspace{0.04cm}TP}(f)$ the corresponding time function (Fourier inverse transform) $h_{\rm K,\hspace{0.04cm}TP}(t)$ is complex according to the allocation theorem.


Lowpass functions for $H_{\rm K}(f)$

(2)  Here only the third proposed solution is correct:

  • The spectral function $H_{\rm MKD}(f)$ always has an even real part and no imaginary part. Consequently $h_{\rm MKD}(t)$ is always real.
  • If $H_{\rm K}(f)$ had additionally an imaginary part odd by $f_{\rm T}$, $H_{\rm MKD}(f)$ would have an imaginary part odd by $f = 0$. Thus $h_{\rm MKD}(t)$ would still be a real function.


The diagram illustrates the differences between $H_{\rm K,\hspace{0.04cm}TP}(f)$ and $H_{\rm MKD}(f)$. The parts of $H_{\rm MKD}(f)$ in the range around $\pm 2f_{\rm T}$ need not be considered further.


(3)  $H_{\rm MKD}(f)$ is additively composed of a rectangle and a triangle, each with width $\Delta f_{\rm K}$ and height $0.5$. It follows:

$$h_{\rm MKD}(t) = \frac{\Delta f_{\rm K}}{2} \cdot {\rm si} (\pi \cdot \Delta f_{\rm K} \cdot t)+ \frac{\Delta f_{\rm K}}{4} \cdot {\rm si}^2 (\pi \cdot \frac{\Delta f_{\rm K}}{2} \cdot t)$$
$$ \Rightarrow \hspace{0.3cm}h_{\rm MKD}(t = 0) = \frac{\Delta f_{\rm K}}{2} + \frac{\Delta f_{\rm K}}{4} = 0.75 \cdot \Delta f_{\rm K}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}h_{\rm MKD}(t = 0)/{\Delta f_{\rm K}} \hspace{0.1cm}\underline {= 0.75} .$$


(4)  The second proposed solution is correct:

  • The first si function does have equidistant zero crossings at the distance $1/\Delta f_{\rm K}$.
  • But the equidistant zero crossings of the whole time function $h_{\rm MKD}$ are determined by the second term:
$$h_{\rm MKD}(t = \frac{1}{\Delta f_{\rm K}}) = \ \frac{\Delta f_{\rm K}}{2} \cdot {\rm si} (\pi )+ \frac{\Delta f_{\rm K}}{4} \cdot {\rm si}^2 (\pi/2) = \frac{\Delta f_{\rm K}}{4},$$
$$h_{\rm MKD}(t = \frac{2}{\Delta f_{\rm K}}) = \ \frac{\Delta f_{\rm K}}{2} \cdot {\rm si} (2\pi )+ \frac{\Delta f_{\rm K}}{4} \cdot {\rm si}^2 (\pi) = 0.$$