PLEASE SHOW WORK AND STEP BY STEP PROCESS

Q$1$: Simulating Loan Processing

ZipLoan, Inc. operates a $$B$2$B$$ website for $($relatively$)$ speedy business loans. In this problem, you will simulate ZipLoan$$s operation. For simplicity, we will assume that the ZipLoan$$s operations are a continuous, $24/7$ affair $($for a more realistic model, this assumption could be changed by using Arena$$s $$schedule$$ features and$/$or changing the number of hours per day in the replication parameters dialog box$).$ ZipLoan$$s process may be modeled as follows:

Loan applications arrive from ZipLoan$$s website in a memoryless manner, with an average time between applications of $1\mathrm{.}2$ hours.

Each loan application must be analyzed by an underwriter. The time required for underwriting is well$-$modeled by a triangular random variable with a minimum of $1$ hour, a most likely value of $3$ hours, and a maximum value of $5$ hours. You always keep $4$ underwriters on staff, and applications wait in a queue if no underwriters are available when they arrive.

Historically, your underwriters approve $43\%$ of the loan applications they analyze. The remainder are rejected.

For each loan approved by underwriters, additional work must be done to prepare a loan offer. For each loan, the time required is well$-$modeled by a triangular distribution with a minimum value of $4$ hours, a most likely value of $5$ hours, and maximum of $8$ hours. This work is performed by employees called $$regular staffers$,$ and processing a loan requires one regular staffer. You have $4$ regular staffers, and approved loans wait in queue if all regular staffers are currently busy.

After preparation, each offer is sent back to the applicant. In $75\%$ of the cases, the applicant accepts the offer, but sometimes applicants decline $($for example, because they obtained better terms from another lender$).$ The time applicants take to decide whether to accept loan offers is well$-$modeled by a triangular distribution with a minimum value of $1$ hour, a most likely value of $48$ hours, and a maximum value of $168$ hours $($one week$).$

If an offer is accepted, some additional work must be done to complete the origination of the loan; after this step, the process is complete. This process takes a single regular staffer, from the same pool of $4$ workers who prepare offers, an amount of time that is well modeled by a uniform distribution between $3$ and $4$ hours. If all regular staffers are currently busy, an offer waits in a queue until a staffer is available.

Build an Arena model corresponding to this process. Enable statistics collection for entities, resources, queues, and processes, and use hours as your base time unit. Simulate $400$ days of operation, plus a warm$-$up time of $4$ days.

Based on running your simulation, answer the following questions:

For cases in which loans approved, use the Arena output report to estimate how much time passes on average, between the customer submitting their application and receiving their loan offer. What percentage of this average is queuing time? Show your work.

From the time a customer accepts an offer, estimate how long takes, on average, for origination of the loan to be complete. Again, use the Arena output report and show your work. What percentage of this average is queuing time?

What percentage of the time are the underwriters busy?

What percentage of the time are the regular staffers busy?