Difference between revisions of "Aufgaben:Exercise 2.5Z: Flower Meadow"

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[[File:P_ID124__Sto_Z_2_5.gif|right|frame|flower meadow &ndash; another <br>example of the Poisson distribution]]
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[[File:P_ID124__Sto_Z_2_5.gif|right|frame|Flower meadow &ndash; another example of the Poisson distribution]]
 
A farmer is happy about the splendor of flowers on his land and wants to know how many dandelions are currently blooming on his meadow.  
 
A farmer is happy about the splendor of flowers on his land and wants to know how many dandelions are currently blooming on his meadow.  
*He knows that the meadow has an area of $5000$&nbsp; square meters and he also knows from the agricultural school that the number of flowers in a small area is always poisson distributed.  
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*He knows that the meadow has an area of&nbsp; $5000$&nbsp; square meters and he also knows from the agricultural school that the number of flowers in a small area is always Poisson distributed.  
*He stakes out ten squares, each with an edge length of &nbsp; $\text{25 cm}$&nbsp;, randomly distributed over the entire meadow and counts the flowers in each of these squares:
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*He stakes out ten squares,&nbsp; each with an edge length of&nbsp; $\text{25 cm}$,&nbsp; randomly distributed over the entire meadow and counts the flowers in each of these squares:
 
::$$\rm 3, \ 4, \ 1, \ 5, \ 0, \ 3, \ 2, \ 4, \ 2, \ 6.$$
 
::$$\rm 3, \ 4, \ 1, \ 5, \ 0, \ 3, \ 2, \ 4, \ 2, \ 6.$$
  
 
Consider these numerical values as random results of the discrete random variable&nbsp; $z$.
 
Consider these numerical values as random results of the discrete random variable&nbsp; $z$.
  
It is obvious that the sample size is very small at&nbsp; $10$&nbsp; but &ndash; this much is revealed &ndash; the farmer is lucky.&nbsp; First consider how you would proceed to solve this task, and then answer the following questions.
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It is obvious that the sample size&nbsp; $(10)$&nbsp; is very small but &ndash; this much is revealed &ndash; the farmer is lucky.&nbsp; First consider how you would proceed to solve this task,&nbsp; and then answer the following questions.
 
 
 
 
 
 
 
 
  
  
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<quiz display=simple>
 
<quiz display=simple>
{Find the mean of&nbsp; $z$,&nbsp; that is, the mean number of flowers counted in the ten squares.
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{Find the mean of&nbsp; $z$,&nbsp; that is,&nbsp; the mean number of flowers counted in each of the ten squares.
 
|type="{}"}
 
|type="{}"}
 
$m_z \ =$ { 3 3% }
 
$m_z \ =$ { 3 3% }
  
  
{Determine the rms of the random variable&nbsp; $z$.
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{Determine the rms value of the random variable&nbsp; $z$.
 
|type="{}"}
 
|type="{}"}
 
$\sigma_z\ = \ $ { 1.732 3% }
 
$\sigma_z\ = \ $ { 1.732 3% }
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{Which of the following statements are true?
 
{Which of the following statements are true?
 
|type="[]"}
 
|type="[]"}
+ Actually, one would have to use considerably more than ten random numbers (squares) for the moment calculation.
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+ Actually,&nbsp; one would have to use considerably more than ten random numbers&nbsp; (squares)&nbsp; for the moment calculation.
+ The random size $z$&nbsp; is in fact Poisson distributed.
+
+ The random variable&nbsp; $z$&nbsp; is in fact Poisson distributed.
- The rate&nbsp; $\lambda$&nbsp; of the Poisson distribution is equal to the rms&nbsp; $\sigma_z$.
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- The rate&nbsp; $\lambda$&nbsp; of the Poisson distribution is equal to the rms value&nbsp; $\sigma_z$.
 
+ The rate&nbsp; $\lambda$&nbsp; of the Poisson distribution is equal to the mean&nbsp; $m_z$.
 
+ The rate&nbsp; $\lambda$&nbsp; of the Poisson distribution is equal to the mean&nbsp; $m_z$.
  

Revision as of 15:17, 18 December 2021

Flower meadow – another example of the Poisson distribution

A farmer is happy about the splendor of flowers on his land and wants to know how many dandelions are currently blooming on his meadow.

  • He knows that the meadow has an area of  $5000$  square meters and he also knows from the agricultural school that the number of flowers in a small area is always Poisson distributed.
  • He stakes out ten squares,  each with an edge length of  $\text{25 cm}$,  randomly distributed over the entire meadow and counts the flowers in each of these squares:
$$\rm 3, \ 4, \ 1, \ 5, \ 0, \ 3, \ 2, \ 4, \ 2, \ 6.$$

Consider these numerical values as random results of the discrete random variable  $z$.

It is obvious that the sample size  $(10)$  is very small but – this much is revealed – the farmer is lucky.  First consider how you would proceed to solve this task,  and then answer the following questions.



Hints:




Questions

1

Find the mean of  $z$,  that is,  the mean number of flowers counted in each of the ten squares.

$m_z \ =$

2

Determine the rms value of the random variable  $z$.

$\sigma_z\ = \ $

3

Which of the following statements are true?

Actually,  one would have to use considerably more than ten random numbers  (squares)  for the moment calculation.
The random variable  $z$  is in fact Poisson distributed.
The rate  $\lambda$  of the Poisson distribution is equal to the rms value  $\sigma_z$.
The rate  $\lambda$  of the Poisson distribution is equal to the mean  $m_z$.

4

Predict the total number  $B$  of all flowers in the meadow.

$B\ = \ $

$\ \text{thousand}$

5

What is the probability of a square without any flowers?

${\rm Pr}(z = 0) \ = \ $

$\ \%$


Musterlösung

(1)  The linear mean of these ten numbers gives  $\underline{m_z = 3}$.


(2)  For the quadratic mean of the random variable  $z$  applies accordingly:

$$m_{\rm 2\it z}=\frac{1}{10}\cdot (0^2+1^2+ 2\cdot 2^2+ 2\cdot 3^2+2\cdot 4^2+ 5^2+6^2)=12.$$
  • According to Steiner's theorem, the variance is thus equal to.
$$\sigma_z^2 =12 -3^2 = 3$$
and accordingly the rms
$$\underline{\sigma_z \approx 1.732}.$$


(3)  Correct solutions 1, 2, and 4:

  • Mean and rms agree here.  This is indicative of the Poisson distribution with rate  $\lambda = 3$  (equal to the mean and equal to the variance, not equal to the rms).
  • Naturally, it is questionable to make this statement on the basis of only ten values. However, in the case of moments, a smaller sample number is less serious than, for example, in the case of probabilities.


(4)  In total, there  are $80000$  such squares, each with three flowers in the mean. 

  • This suggests a total of   $\underline{B = 240}$  thousand flowers.


(5)  According to the Poisson distribution, this probability results in $${\rm Pr}(z = 0) = \frac{3^0}{0!} \cdot{\rm e}^{-3}\hspace{0.15cm}\underline{\approx 5\%}.$$

  • However, the small sample size  $N = 10$  on which this task was based would have indicated probability  ${\rm Pr}(z = 0) = { 10\%}$  since only in a single square no single flower was counted.