Exercise 2.6: PN Generator of Length 5

PN generator of length $L = 5$

In the graphic you can see a pseudo-random generator of length $L = 5$, which can be used to generate a binary random sequence $\langle z_{\nu} \rangle$.

At the start time, let all memory cells be preallocated with "ones".
At each clock time, the content of the shift register is shifted one place to the right.
And the currently generated binary value $z_{\nu}$ $(0$ or $1)$ is entered into the first memory cell.
Hereby $z_{\nu}$ results from the modulo-2 addition between $z_{\nu-3}$ and $z_{\nu-5}$.

Hints:

The exercise belongs to the chapter Generation of Discrete Random Variables.

The topic of this chapter is illustrated with examples in the (German language) learning video:
"Erläuterung der PN-Generatoren an einem Beispiel" $\Rightarrow$ "Explanation of PN generators using an example".

Question

	$G(D) = D^5 + D^2 +1$.
	$G(D) = D^5 + D^3 +1$.
	$G(D) = D^4 + D^2 +D$.

$O_{\rm G} \ = \ $

$\ \rm (octal)$

$P\ = \ $

$O_{\rm R} \ = \ $

$\ \rm (octal)$

	It is also a sequence of maximum length.
	The output sequence of $G_{\rm R}(D)$ is the same as that of the generator polynomial $G(D)$.
	The output sequences of $G_{\rm R}(D)$ and $G(D)$ are inverses of each other.
	Both sequences show the same statistical properties.
	In $G_{\rm R}(D)$ all memory elements can be preallocated with zeros.

Solution

(1) Correct is the proposed solution 2 ⇒ $G(D) = D^5 + D^3 +1$.

The generator polynomial $G(D)$ denotes the feedback coefficients used for modulo-2 addition.
$D$ is a formal parameter indicating a delay by one clock.
$D^3$ then indicates a delay of three measures.

(2) It is $g_0 = g_3 = g_5 = 1$.

All other feedback coefficients are $0$. It follows that:

$$(g_{\rm 5}\hspace{0.1cm}g_{\rm 4}\hspace{0.1cm}g_{\rm 3}\hspace{0.1cm}g_{\rm 2}\hspace{0.1cm}g_{\rm 1}\hspace{0.1cm}g_{\rm 0})=\rm (101001)_{bin}\hspace{0.15cm} \underline{=(51)_{oct}}.$$

(3) Since the generator polynomial $G(D)$ is primitive, one obtains an "M-sequence".

Accordingly, the period is maximal:

$$P_{\rm max} = 2^{L}-1 \hspace{0.15cm}\underline {= 31}.$$

In the theory part, the table with PN generators of maximum length ("M-sequences") for degree $L=5$ lists the configuration $(51)_{\rm oct}$.

(4) The reciprocal polynomial is:

$$G_{\rm R}(D)=D^{\rm 5}\cdot(D^{\rm -5}+\D^{\rm -3}+ 1)= D^{\rm 5}+D^{\rm 2}+1.$$

Thus, the octal identifier für this configuration: $\rm (100101)_{bin}\hspace{0.15cm} \underline{=(45)_{oct}}.$

(5) The solutions 1, 3, and 4 are correct:

The output sequence of the reciprocal realization $G_{\rm R}(D)$ of a primitive polynomial $G(D)$ is also an "M-sequence".
Both sequences are inverses of each other. This means:
The output sequence of $(45)_{\rm oct}$ is equal to the output sequence of $(51)_{\rm oct}$ when read from right to left, additionally taking into account a phase ("cyclic shift").
The prerequisite is again that not all memory cells are preallocated with zeros.
Under this condition, both sequences actually have the same statistical properties.