Suppose that a fast-food restaurant sells salad and burger. There are two cashiers. With cashier 1, the number of seconds that it takes to complete an order of salad is uniformly distributed in {55,56,...,64,65}; and the number of seconds it takes to complete an order of burger is uniformly distributed in {111,112,...,,129,130}. With cashier 2, the number of seconds that it takes to complete an order of salad is uniformly distributed in {65,66,...,74,75}; and the number of seconds it takes to complete an order of burger is uniformly distributed in {121,122,...,,139,140}. Assume that the customers arrive at random times but has an average arrival rate of r customers per minute.

Consider two diﬀerent scenarios.

• Customers wait in one line for service and, when either of two cashiers is available, the ﬁrst customer in the line goes to the cashier and gets serviced. In this scenario, when a customer arrives at the restaurant, he either gets serviced if there is no line up, or waits at the end of the line.

• Customers wait in two lines, each for a cashier. The ﬁrst customer in a line will get serviced if and only if the cashier for his line becomes available. In this scenario, when a customer arrives at the restaurant, he joins the shorter line. In addition, we impose the condition that if a customer joins a line, he will not move to the other line or to the other cashier when the other line becomes shorter or when the other cashier becomes free.

In both scenarios considered, a cashier will only start serving the next customer when the customer he is currently serving has received his ordered food. (That is the point we call “the customer’s order is completed”.)

... Simulation

For each of the two scenarios and for several choices of r (see later description), you are to simulate the customers arriving/waiting/getting service over a period of 3 hours, namely, from time 0 to time 180 minutes, where you assume that at time 0 there is no customer waiting and both cashiers are available; The entire period of 3 hours is to be divided into time slots each of 1 second duration. At each time slot, with r/60 probability, you make one new customer arrive, and with 1 − r/60 probability you make no new customer arrive. This should give rise to an average customer arrival rate of r customers/minute, and the arrival model will be reasonably close to what is described above. In each time slot, you will make your program handle whatever necessary.

... Objectives and Deliverables

You need to write a program to investigate the following. For each of the two scenarios and for each r, you are to divide the three-hour simulated period into 10-minute periods, and for every customer arriving during period i (i ∈ {1,2,...,18}), compute the overall waiting time of the customer (namely, from the time he arrives at the restaurant to the time when his order is completed. You need to print for each i the average waiting time for the customers arriving during period i. Note that if a customer arriving in period i has not been served within the three-hour simulated period, then his waiting time is not known. So the average waiting time for customers arriving in this period cannot be computed. In that case, simply print “not available” as the average waiting time for that period.

So, this program deals with hours, minutes, and seconds.

Would it be best to make a three-dimensional array as such:

```
time[3][60][60]
```

A total of three hours, with 60 minutes within, with 60 seconds within.

Alternatively, I was thinking that I should make a "for-loop" with this structure:

```
for (time=0;t<10800;t++)
```

Every iteration of this loop will represent one second of the three hour simulation (3hx60mx60s=10800 seconds).

Am I on the right track here guys? Which method is more plausible. Are there other arrays that are critical for this program?

Help is appreciated, as always!