Difference between revisions of "Aufgaben:Exercise 1.3Z: Winning with Roulette?"

From LNTwww
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[[File:P_ID82__Sto_Z_1_3.gif|right|frame|Considered betting situation]]
 
[[File:P_ID82__Sto_Z_1_3.gif|right|frame|Considered betting situation]]
In roulette, a winning number  $Z$  is determined in each game by means of a ball and a roulette wheel, where we want to assume that all possible numbers  $Z \in \{0, 1, 2, \ \text{...} \ , 36 \}$  are equally probable.
+
In roulette,  a winning number  $Z$  is determined in each game by means of a ball and a roulette wheel,  where we want to assume that all possible numbers  $Z \in \{0, 1, 2, \ \text{...} \ , 36 \}$  are equally probable.
  
 
The players can now bet on a single number or on a group of numbers with chips of different value.  Some of the possibilities and the corresponding winnings will be briefly explained here on the basis of the chips bet by a player (see graph):
 
The players can now bet on a single number or on a group of numbers with chips of different value.  Some of the possibilities and the corresponding winnings will be briefly explained here on the basis of the chips bet by a player (see graph):
  
*If a player bets on a number (in the example on "0"), he would get back  $35$ times his stake as winnings.
+
*If a player bets on a number  (in the example on "0"),  he would get back  $35$ times his stake as winnings in addition to his bet.
 
 
*If a player bets on a group of numbers with three fields (in the example, the 1-euro chip for the numbers from "22" to "24"), he would receive  $ 11$ times his stake as winnings in addition to his bet.
 
 
 
*If a player bets on a group of numbers with  $ 18$  fields (for example, the 10-euro chips on "Rouge", on "Impair" and on "Passe"), he will receive the same amount back as winnings in addition to his bet.  
 
*If the number drawn does not belong to one of the squares he occupies, his bet is lost.
 
 
 
 
 
  
 +
*If a player bets on a group of numbers with three fields  (in the example,  the 1-euro chip for the numbers from  "22"  to  "24"),  he would receive  $ 11$ times his stake as winnings in addition to his bet.
  
 +
*If a player bets on a group of numbers with  $ 18$  fields  (for example,  the 10-euro chips on  "Rouge",  on  "Impair"  and on  "Passe"),  he will receive the same amount back as winnings in addition to his bet.
 +
*If the number drawn does not belong to one of the squares he occupies,  his bet is lost.
  
  
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Hints:
 
Hints:
*The exercise belongs to the chapter  [[Theory_of_Stochastic_Signals/Set_Theory_Basics|Set Theory Basics]].
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*The exercise belongs to the chapter  [[Theory_of_Stochastic_Signals/Set_Theory_Basics|Set Theory Basics]].  
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*'''Enter any losses as negative winnings'''  in the following questions.
*Enter any losses as negative winnings in the following questions.
+
*The topic of this chapter is illustrated with examples in the  (German language)  learning video
*The topic of this chapter is illustrated with examples in the  (German language)  learning video [[Mengentheoretische_Begriffe_und_Gesetzmäßigkeiten_(Lernvideo)|Mengentheoretische Begriffe und Gesetzmäßigkeiten]] $\Rightarrow$ Set Theoretical Concepts and Laws.
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:[[Mengentheoretische_Begriffe_und_Gesetzmäßigkeiten_(Lernvideo)|Mengentheoretische Begriffe und Gesetzmäßigkeiten]]   $\Rightarrow$   "Set-Theoretical Concepts and Laws".
  
  
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<quiz display=simple>
 
<quiz display=simple>
{A player simultaneously places one 1-euro chip on each of the squares „0“, „Red“ und „Black“.&nbsp; What are his average winnings per game?
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{A player simultaneously places one 1-euro chip on each of the squares&nbsp; "0",&nbsp; "Red"&nbsp; and&nbsp; "Black".&nbsp; What are his average winnings per game?
 
|type="{}"}
 
|type="{}"}
 
$G_1 \ =\ $  { -0.083--0.079 } $\ \rm Euro$
 
$G_1 \ =\ $  { -0.083--0.079 } $\ \rm Euro$
  
{How much does he win on average per game if he always places one&nbsp; $1$&nbsp; Euro chip on each of the squares "Red" and "Black"?
+
{How much does he win on average per game if he always places one&nbsp; $1$&nbsp; Euro chip on each of the squares&nbsp; "Red"&nbsp; and&nbsp; "Black"?
 
|type="{}"}
 
|type="{}"}
 
$G_2 \ =\ $ { -0.056--0.052 } $\ \rm Euro$
 
$G_2 \ =\ $ { -0.056--0.052 } $\ \rm Euro$
  
{How much does he win on average per game if he always bets&nbsp; $1$&nbsp; on "0" and&nbsp; $10$&nbsp; Euro auf on "Red"?
+
{How much does he win on average per game if he always bets&nbsp; $1$&nbsp; Euro on&nbsp; "0"&nbsp; and&nbsp; $10$&nbsp; Euro on&nbsp; "Red"?
 
|type="{}"}
 
|type="{}"}
 
$G_3 \ =\ $  { -0.307--0.287 } $\ \rm Euro$
 
$G_3 \ =\ $  { -0.307--0.287 } $\ \rm Euro$
  
{The player bets as shown in the picture. &nbsp; Which number&nbsp; $Z_{\rm Wunsch}$&nbsp; (''Wunsch'' being German for ''wish/desire'') should he be hoping for?&nbsp; How big would his winnings be then?
+
{The player bets as shown in the picture. &nbsp; Which number&nbsp; $Z_{\rm desire}$&nbsp; should he be hoping for?&nbsp; How big would his winnings be then?
 
|type="{}"}
 
|type="{}"}
$Z_{\rm Wunsch} \ = \ $ { 23 }
+
$Z_{\rm desire} \ = \ $ { 23 }
 
$G_4 \ =\ $ { 40 3% } $\ \rm Euro$
 
$G_4 \ =\ $ { 40 3% } $\ \rm Euro$
  

Revision as of 15:38, 25 November 2021

Considered betting situation

In roulette,  a winning number  $Z$  is determined in each game by means of a ball and a roulette wheel,  where we want to assume that all possible numbers  $Z \in \{0, 1, 2, \ \text{...} \ , 36 \}$  are equally probable.

The players can now bet on a single number or on a group of numbers with chips of different value.  Some of the possibilities and the corresponding winnings will be briefly explained here on the basis of the chips bet by a player (see graph):

  • If a player bets on a number  (in the example on "0"),  he would get back  $35$ times his stake as winnings in addition to his bet.
  • If a player bets on a group of numbers with three fields  (in the example,  the 1-euro chip for the numbers from  "22"  to  "24"),  he would receive  $ 11$ times his stake as winnings in addition to his bet.
  • If a player bets on a group of numbers with  $ 18$  fields  (for example,  the 10-euro chips on  "Rouge",  on  "Impair"  and on  "Passe"),  he will receive the same amount back as winnings in addition to his bet.
  • If the number drawn does not belong to one of the squares he occupies,  his bet is lost.



Hints:

  • The exercise belongs to the chapter  Set Theory Basics.
  • Enter any losses as negative winnings  in the following questions.
  • The topic of this chapter is illustrated with examples in the  (German language)  learning video
Mengentheoretische Begriffe und Gesetzmäßigkeiten   $\Rightarrow$   "Set-Theoretical Concepts and Laws".


Questions

1

A player simultaneously places one 1-euro chip on each of the squares  "0",  "Red"  and  "Black".  What are his average winnings per game?

$G_1 \ =\ $

$\ \rm Euro$

2

How much does he win on average per game if he always places one  $1$  Euro chip on each of the squares  "Red"  and  "Black"?

$G_2 \ =\ $

$\ \rm Euro$

3

How much does he win on average per game if he always bets  $1$  Euro on  "0"  and  $10$  Euro on  "Red"?

$G_3 \ =\ $

$\ \rm Euro$

4

The player bets as shown in the picture.   Which number  $Z_{\rm desire}$  should he be hoping for?  How big would his winnings be then?

$Z_{\rm desire} \ = \ $

$G_4 \ =\ $

$\ \rm Euro$

5

Is there a betting combination such that the average winnings are positive?

Yes   ⇒   Quit university and go to the next casino.
No   ⇒   Continue with $\rm LNTwww$.


Solution

(1)  The player loses one euro each time one of the numbers  $1$  to  $36$  is drawn.

  • He wins  $33$  euro, if  $0$  is drawn. It follows that:
$$G_1 =\rm {36}/{37}\cdot (-1\hspace{0.1cm} Euro) + {1}/{37}\cdot (33\hspace{0.1cm} Euro) \hspace{0.15cm}\underline {= - 0.081\hspace{0.1cm} Euro\hspace{0.1cm}(Loss)}.$$


(2)  The player wins and loses nothing unless the zero is drawn.  If the zero appears, he loses his bet:

$$G_2 = \rm {1}/{37}\cdot (-2\hspace{0.1cm} Euro)\hspace{0.15cm}\underline { = -0.054 \hspace{0.1cm}Euro \hspace{0.1cm}(Loss)}.$$


(3)  If "red" is drawn, he wins nine euro.

  • If zero comes, he effectively wins  $25$  euro.
  • If "black" is drawn, he loses his entire bet of  $11$  euro:
$$G_3 = \rm {18}/{37}\cdot (10 -1) + {1}/{37}\cdot (35-10) + {18}/{37}\cdot (-10-1)\hspace{0.15cm}\underline { = - 0.297\hspace{0.1cm}Euro}.$$


(4)  He gets the highest winning at  $Z_{\rm Wunsch} \; \underline{ = 23} $.  Then four of his five chips win:

$$G_4 = \rm 10\hspace{0.1cm}(Red) + 10\hspace{0.1cm}(Passe) + 10\hspace{0.1cm}(Impair) + \rm 11\hspace{0.1cm}(between \hspace{0.1cm}22\hspace{0.1cm} and \hspace{0.1cm}24) - 1 \hspace{0.1cm}(not \hspace{0.1cm}0) \hspace{0.15cm}\underline {= 40 \hspace{0.1cm}Euro}.$$
  • If, on the other hand, the zero comes, he wins only  $\rm 35 - 31 = 4 \ Euro$.


(5)  No, unfortunately not. On statistical average, the house always wins..