# Round-Robin Scheduling with Arrival Times

So in class, my professor was going over round robin scheduling. Consider this situation:

``````Job       |    Arrival       |      Burst
A         |       0          |        3
B         |       1          |        5
C         |       3          |        4
``````

My professor wrote down the results as follows:

``````Time
1 2 3 4 5 6 7 8 9 10 11 12
A A B A B B C C B C  B  C
``````

At times `0-1`, `A` has being processed for one burst. At time `1-2`, `A` is being processed for another burst. At time `2-3` `B` is being processed for a burst, and so on and so forth.

What I'm confused about is at times `6-8`. `B` is processed again from time `5-6`. Then `C` from time `6-7`, and `C` again from time `7-8`. Shouldn't it instead be this:

``````Time
1 2 3 4 5 6 7 8 9 10 11 12
A A B A B C B C B C  B  C
``````
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It does look like it should be as you say, but how about asking your professor? It might just have been a mistake on his/her part. –  Dukeling Mar 18 '13 at 7:43

At first each and every round robin question is based on quantum.(ex-quantum = 4). It means each and every process will take same quantum time for execution. for your example if quantum=2. then it seems like

``````A        B      C       A     B       C          B

0  -  2  - A

2  -  4  - B

4  - 6   - C

6  - 7   - A

7  - 9   - B

9  - 11  - c

11 -12   - B
``````

Waiting time of process Waiting time = (starting time of final execution – previous executed cycle – arrival time)

``````A –  (6-2-0)=4

B – (11-(2+2)-1)=6

C – (9-2)-3=4

Average waiting time = (4+6+4)/3 = 14/3 = 4.66
``````
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Sorry i was not allowed to post an image so i didn't elaborate very well. –  Manjeet Kumar roy Dec 14 '13 at 7:46
Average waiting time = (4+6+4)/3 = 14/3 = 4.66 –  lucidgold Oct 31 '14 at 18:33