Difference between revisions of "Exercise 2.6Z: PN Generator of Length 3"
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===Solution=== | ===Solution=== | ||
{{ML-Kopf}} | {{ML-Kopf}} | ||
− | [[File:EN_Sto_Z_2_6b.png|right|frame|PN | + | [[File:EN_Sto_Z_2_6b.png|right|frame|PN generator with octal identifier $15$]] |
'''(1)''' It is an M-sequence with $L= 3$. It follows that $P= 2^L - 1 \hspace{0.15cm}\underline{= 7}$. | '''(1)''' It is an M-sequence with $L= 3$. It follows that $P= 2^L - 1 \hspace{0.15cm}\underline{= 7}$. | ||
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− | The result is entered in the first row of the above table (marked in red): | + | The result is entered in the first row of the above table (marked in red): |
*At the clock time $\nu = 7$ results in the same memory usage as at the time $\nu = 0$. | *At the clock time $\nu = 7$ results in the same memory usage as at the time $\nu = 0$. | ||
− | *From this follows $ {P = 7}$ and the sequence is from $\nu = 1$ corresponding to <u>solution 3</u> : | + | *From this follows $ {P = 7}$ and the sequence is from $\nu = 1$ corresponding to <u>solution 3</u>: |
:$$\langle z_\nu \rangle = 1 \ 1 \ 0 \ 0 \ 1 \ 1 \ 0 \ 0 \ 1 \ 0 \ 1 \ 1 \text{...}$$ | :$$\langle z_\nu \rangle = 1 \ 1 \ 0 \ 0 \ 1 \ 1 \ 0 \ 0 \ 1 \ 0 \ 1 \ 1 \text{...}$$ | ||
− | *In contrast, proposal 1 describes the M sequence of the PN generator with length $L=4$ and identifier $(31)$ ⇒ period length is $P= 15$. | + | *In contrast, proposal 1 describes the M sequence of the PN generator with length $L=4$ and identifier $(31)$ ⇒ period length is $P= 15$. |
− | *In proposal 2, the period length $P= 4$ is too short. | + | *In proposal 2, the period length $P= 4$ is too short. |
− | *Finally, the last proposal would have the desired period length $P= 7$, but from the modulo 2 addition of $S_2= 0$ and $S_3= 1$ $($ | + | *Finally, the last proposal would have the desired period length $P= 7$, but from the modulo 2 addition of $S_2= 0$ and $S_3= 1$ $($for $\nu = 0)$ it necessarily follows at the next time $(\nu = 1)$: $S_1= 1$. This property is not exhibited by sequence 4. |
'''(3)''' Correct are <u>solutions 2, 3, and 4</u>: | '''(3)''' Correct are <u>solutions 2, 3, and 4</u>: | ||
− | *The maximum number of consecutive ones is $L$ (namely if there is a one in all $L$ memory cells). | + | *The maximum number of consecutive "ones" is $L$ (namely if there is a "one" in all $L$ memory cells). |
− | *On the other hand, it is not possible that all memory cells are filled with zeros. Therefore, there is always one more than zeros. | + | *On the other hand, it is not possible that all memory cells are filled with "zeros". Therefore, there is always one more "one" than "zeros". |
− | *The period length of the last sequence is $P = 2$. On the other hand, for an M-sequence $P= 2^L - 1.$ For no value of $L$ | + | *The period length of the last sequence is $P = 2$. On the other hand, for an M-sequence $P= 2^L - 1.$ For no value of $L$: $P = 2$ is possible. |
− | [[File: EN_Sto_Z_2_6d.png|right|frame|PN | + | [[File: EN_Sto_Z_2_6d.png|right|frame|PN generator with octal identifier $13$]] |
− | '''(4)''' In the adjacent table the emergence of the PN | + | '''(4)''' In the adjacent table the emergence of the PN sequence at the reciprocal polynomial $G_{\rm R}(D)$ is entered. It can be seen that the <u>proposed solution 2</u> applies: |
− | It can be seen that the <u>proposed solution 2</u> applies: | + | *Also for the reciprocal arrangement, the period length $P = 7$ must hold, so that proposition 1 $($with $P = 15)$ is eliminated. |
− | *Also for the reciprocal arrangement, the period length $P = 7$ must hold, so that proposition 1 $($with $P = 15)$ is eliminated. | + | *Proposal 3 is just a version of the output sequence of $(15)$ shifted by two clocks. |
− | *Proposal 3 is just a version of the | + | *In contrast, in the (correct) second proposal, the inverse of ... $ 1 \ 1 \ 0 \ 0 \ 1 \ 0 \ 1$ ... – thus the sequence ... $ 1 \ 0 \ 1 \ 0 \ 0 \ 1 \ 1$ ... – are included, albeit with a phase shift. |
− | *In contrast, in the (correct) second proposal, the inverse of ... $ 1 \ 1 \ 0 \ 1 \ 0 \ 1$ ... – thus the sequence ... $ 1 \ 0 \ 1 \ 0 \ 0 \ 1 \ 1$ ... – are included, albeit with a phase shift. | ||
Latest revision as of 18:19, 28 December 2021
The adjacent sketch shows a PN generator of length $L = 3$ with generator polynomial
- $$G( D) = D^{\rm 3} + D^{\rm 2} + \rm 1$$
and thus the octal identifier $(g_3 \ g_2 \ g_1 \ g_0)$ = $(1 \ 1 \ 0 \ 1)_{\rm bin} = (15)_{\rm oct}$.
The corresponding reciprocal polynomial
- $$G_{\rm R}(D) = D^{\rm 3}\cdot ( D^{\rm -3} + D^{\rm -2} + 1) = D^{\rm 3} + D^{\rm 1} + \rm 1$$
has the octal identifier $(1 \ 0 \ 1 \ 1)_{\rm bin} = (13)_{\rm oct}$.
- At start time, let the three memory cells be preallocated with the binary values $1$, $0$ and $1$ .
- Both arrangements generate an "M-sequence".
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".
Questions
Solution
(1) It is an M-sequence with $L= 3$. It follows that $P= 2^L - 1 \hspace{0.15cm}\underline{= 7}$.
(2) We denote the cells from left to right by $S_1$, $S_2$ and $S_3$. Then holds:
- $S_2(\nu) = S_1(\nu - 1)$,
- $S_3(\nu) = S_2(\nu - 1)$,
- $S_1(\nu) = S_2(\nu - 1) \ {\rm mod } \ S_3(\nu - 1)$.
The result is entered in the first row of the above table (marked in red):
- At the clock time $\nu = 7$ results in the same memory usage as at the time $\nu = 0$.
- From this follows $ {P = 7}$ and the sequence is from $\nu = 1$ corresponding to solution 3:
- $$\langle z_\nu \rangle = 1 \ 1 \ 0 \ 0 \ 1 \ 1 \ 0 \ 0 \ 1 \ 0 \ 1 \ 1 \text{...}$$
- In contrast, proposal 1 describes the M sequence of the PN generator with length $L=4$ and identifier $(31)$ ⇒ period length is $P= 15$.
- In proposal 2, the period length $P= 4$ is too short.
- Finally, the last proposal would have the desired period length $P= 7$, but from the modulo 2 addition of $S_2= 0$ and $S_3= 1$ $($for $\nu = 0)$ it necessarily follows at the next time $(\nu = 1)$: $S_1= 1$. This property is not exhibited by sequence 4.
(3) Correct are solutions 2, 3, and 4:
- The maximum number of consecutive "ones" is $L$ (namely if there is a "one" in all $L$ memory cells).
- On the other hand, it is not possible that all memory cells are filled with "zeros". Therefore, there is always one more "one" than "zeros".
- The period length of the last sequence is $P = 2$. On the other hand, for an M-sequence $P= 2^L - 1.$ For no value of $L$: $P = 2$ is possible.
(4) In the adjacent table the emergence of the PN sequence at the reciprocal polynomial $G_{\rm R}(D)$ is entered. It can be seen that the proposed solution 2 applies:
- Also for the reciprocal arrangement, the period length $P = 7$ must hold, so that proposition 1 $($with $P = 15)$ is eliminated.
- Proposal 3 is just a version of the output sequence of $(15)$ shifted by two clocks.
- In contrast, in the (correct) second proposal, the inverse of ... $ 1 \ 1 \ 0 \ 0 \ 1 \ 0 \ 1$ ... – thus the sequence ... $ 1 \ 0 \ 1 \ 0 \ 0 \ 1 \ 1$ ... – are included, albeit with a phase shift.