30 PMP Formulas to Pass the PMP Certification Exam 2024

30 PMP Formulas to Pass the PMP Certification Exam 2024

One question frequently comes to me when I talk to students preparing for the Project Management Professional (PMP) exam – How are they going to understand all the PMP formulas required for the exam?

It is something that cannot be avoided. You must become familiar with a large number of these computations and formulas in order to pass the test. To pass the PMP exam, you must have a solid understanding of the fundamental formulas used to assess project performance in addition to the project management concepts. 

In the blog post below, we will look at the basic PMP formulas, their real-world uses, and how they are reduced into easy-to-understand concepts. I will also provide helpful tips on how to remember and apply these formulas throughout the exam. If you want to pass the PMP certification exam, you must fully understand these formulas and their application in order to pass the exam.

What are PMP Formulas?

PMP formulas are integral to project management, essential for the Project Management Professional (PMP) certification. They include calculations like the beta distribution formula PMP, crucial for estimating project durations. Another key aspect is the communication channel formula PMP, which aids in determining the complexity of communication in a project. 

Additionally, the communication formula PMP is pivotal for effective information exchange. These formulas are vital for project managers to accurately plan, execute, and monitor projects, ensuring success and efficiency in their management roles. Understanding these formulas is crucial for both passing the PMP exam and excelling in practical project management scenarios.

Why must you know PMP formulas?

As a PMP formula expert, I can’t stress enough the importance of understanding PMP formulas. These formulas are not just theoretical concepts; they are practical tools that enhance project management skills. Here’s why every project manager should master them.

  • Predictive Planning and Control: PMP formulas like the CPI formula in PMP (Cost Performance Index) and earned value formulas in PMP offer predictive insights. They allow project managers to forecast project trends and outcomes, enabling proactive control. For instance, I used the CPI formula to identify budget overrun early in a project, which saved significant costs.
  • Resource Optimization: The ETC formula in PMP (Estimate to Complete) is a key formula for effective resource allocation. It helps in determining the remaining resources needed for project completion. In one of my projects, the ETC formula was instrumental in reallocating resources, ensuring the project stayed on track despite initial setbacks.
  • Performance Measurement: PMP formulas are vital for evaluating project performance. Metrics like the Schedule Performance Index (SPI) and Cost Variance (CV) clearly signfies the project’s progress relative to the plan. This quantifiable approach to performance measurement is vital for making informed decisions.
  • Risk Management: These formulas help identify and manage risks. Project managers can anticipate potential issues and take corrective actions by analyzing variances and trends through these formulas. Identifying the risks earlier using formula-based analysis has been critical to mitigate effectively.

Enhanced Communication with Stakeholders: Formulation proficiency boosts the project manager’s ability to communicate flawlessly and effectively with stakeholders. Utilizing formulas establishes transparency among team members and stakeholders. Throughout my professional experience, employing these formulas has significantly improved the openness and efficiency of conversations about project progress and stakeholder expectations.

PMP® as an exam is designed to test not just the knowledge of project managers but also their ability to apply their learning in real world contexts. To perform well in the PMP certifications exam, you will need to have a clear idea of the PMP formulas to be used to find answers or make calculations to support your thoughts. There will be plenty of questions that would require you to make calculations to get the right answer. At various stages of a project, you may be required to identify values that would aid in decision-making or will give you an idea about how well the project is progressing or if it is lagging in any area. 

Get to know more about importance of project charter. 

PMP is considered the most valued certification, and learning project management with help of courses is designed to prepare you for the certification in a short duration. Take a look and bookmark these specially curated PMP formula cheat sheet that will give you all the important PMP formulas that you will need to know to clear the PMP exam with ease. Understand the purpose of each of the formulas and when and how to use them. 

30 PMP Formulas to Pass the PMP Certification Exam  

Purpose Formula Description
1. Calculate Beta Value in PERT (Program Evaluation and Review Technique) Beta = (Pessimistic + 4 Most Likely + Optimistic) / 6 This equation finds the expected value by giving weightage to the most likely Value.
2. Calculate Estimated Monetary Value (EMV) EMV = P x I This is used to identify and manage risk in projects. P is the probability of an event happening and I is the impact it can have in monetary terms.
3. Calculate Risk Priority Number (RPN) RPN = Severity x Probability x Detection RPN is a value to rank risks. It is a direct multiplication of the three values.
4. Calculate Earned Value (EV) EV = % Complete x Budget at Completion Budget at Completion is the total project value. Simply put, it is the estimated cost of all the work to be completed during the project.
5. Calculate Cost Variance (CV) CV = Earned Value – Actual Cost This measures the difference between the budgeted costs and the actual costs
6. Calculate Schedule Variance (SV) SV = Earned Value – Planned Value This checks the value of the actual work against the planned progress
7. Calculate Cost Performance Index (CPI) CPI = Earned Value / Actual Cost CPI is an indicator if the project is going as per budget
8. Calculate Schedule Performance Index (SPI) SPI = Earned Value / Planned Value The Schedule Performance Index measures how efficient the project schedule is.
9. Calculate Estimate at Completion (EAC) EAC = Budget at Completion / Cost Performance Index

EAC = Actual Cost + Bottom –up Cost to Complete

EAC = Actual Cost + (Budget at Completion – Earned Value)

EAC = Actual Cost + [(Budget at Completion – Earned Value) / (Cost performance Index x Schedule Performance Index)]

Estimate at Completion is an indicator that forecasts the actual budget that may be needed at the current stage. It can be calculated as per any of the four methods.
10. Calculate Variance at Completion Variance at Completion = Budget at Completion – Estimate at Completion It estimates additional budget required or a surplus that would be available at the completion of the project
11. Calculate Estimate to Complete (ETC) TCPI = (Budget at Completion – Earned Value) / (Estimate at Completion – Actual Cost)

TCPI = (Budget at Completion – Earned Value) / (Budget at Completion – Actual Cost)

TCPI tells the project manager the cost performance that is required to complete the project.
12. Calculate Standard Deviation  Standard Deviation (σ) = (Pessimistic – Optimistic) / 6 Standard deviation indicates how reliable the estimated values are and how likely they are to vary during the actual project
13. Calculate Communication Channels Communication Channels = n(n-1) / 2 This formula lets you understand the number of communication channels needed in a project. Here n is the number of stakeholders involved in the project
14. Calculate Cost plus Percentage of Cost Cost plus Percentage of Cost = Cost + n% I pre-decided percentage of cost is added to the actual cost
15. Calculate Cost plus Fixed Fee Cost plus Fixed Fee = Cost + n A pre-decided amount is added to the actual cost incurred
16. Calculate Cost plus Award Fee Cost plus Award Fee = Cost + n A fixed fee is added to the actual cost along with reimbursements for expenses
17. Calculate Cost plus Incentive Fee Cost plus Incentive Fee = Cost + n In addition to the cost an incentive is paid if the project is done within the budget or at a lower cost
18. Calculate Return on Investment (ROI) ROI = (Net Profit / Cost of Investment) x 100 This indicates how investment in a project is performing
19. Calculate Payback Period Payback Period = Initial Investment / Periodic Cashflow This refers to the time required to recover the funds invested in a project
20. Calculate Cost Benefit Ratio Cost Benefit Ratio = Net Present Value of Investment / Initial Investment Cost It is a number that measures the monetary benefits of a project against the cost involved in it
21. Calculate Present Value (PV) PV = Future Value / (1 + i)n This considers the time value for money and discounts from the future value. “i” represents the interest rate and n represents the time periods.
22. Calculate Future Value (FV) FV = Present Value x (1 + i)n Used to measure value at a future date. “i” represents the interest rate and n represents the time periods.
23. Calculate Target Price Target Price = Target Cost + Target Fee This is a price arrived by both the buyer and seller
24. Calculate the Point of Total Assumption PTA = [(Ceiling Price — Target Price) / Buyer’s Share Ratio] + Target Cost This is the cost above which the seller will have to bear the additional costs incurred

1. Beta Value in PERT

Formula: Beta = (Pessimistic + 4 Most Likely + Optimistic) / 6 

Beta value in PERT (Program Evaluation and Review Technique) is a weighted average taken from three values. Optimistic Value, Most Likely Value, and Pessimistic Value. Suppose a task takes 5 days to finish on average, but when things do not go according to plan it could take up to 10 days. When prioritized and everything goes according to plan it can be completed in 3 days. 

3 becomes the Optimistic Value, 5 is the Most Likely Value, and 10 is the pessimistic value. 

So, Beta value will be (3 + (4×5) + 10)/6 

= 5.5 days. 

This is also sometimes calculated without giving weightage to the most likely value 

In that case the calculation will be (3+5+10)/3 

= 6 days 

2. Expected Monetary Value (EMV)

Formula: EMV = P x I 

EMV or Expected Monetary Value is a concept in risk management. It is calculated by multiplying the probability of an event and the impact of it. 

Let’s say that we have estimated the probability of an event to be 1/3rd or 0.33. If that event occurs it would cost, you $6000. In this instance EMV would be calculated as 

6000 * 1/3 = $2000 

 This value will help you assess and compare the magnitude of risks and prepare for them. 

3. Risk Priority Number

Formula: RPN = Severity x Probability x Detection 

Risk Priority Number or RPN is a value that will help you rank the risks of tasks. This is calculated by multiplying three values. 

Severity – denoting the severity of the risk. 

Probability – denotes how likely the severity would be. 

Detection – represents the ease with which it can be detected. 

The rankings are done in a reverse order. For example, if there are 50 risks the one with the highest risk will be ranked 50. The one with the highest likelihood of happening will get the highest numerical value and under detection the highest number would go to the risk that is hardest to detect. The value is usually represented on a scale of 0 to 1. With a risk that has a high severity, high probability, and low chance of getting detected will have values close to 0.9 and the lower risk tasks will have values closer to 0.1.  

By multiplying the three values you get the RPN. The RPN can be used to decide which task requires more focus and control from the perspective of project success or risk mitigation. The higher the value of RPN the more attention it should be given.  

4. Earned Value

Formula: EV = % Complete x Budget at Completion 

Earned Value estimates the amount of work done in terms of monetary value. 

It is calculated by multiplying the percentage of work completed and the project value represented by budget at completion. 

If the Budget at completion is $50,000 and 60% of the project is done, then the calculation can be made in the following way. 

50,000 x 60/100 

=$30,000 

5. Cost Variance

Formula: CV = Earned Value – Actual Cost 

Cost Variance measures the difference between actual cost and budgeted cost. This provides a good indicator of how your project is proceeding in terms of meeting the budget. If the actual costs are higher than the earned value, then it is a case for concern. 

If Actual cost incurred is $400 and the Earned Value in $450 the Cost Variance will be 

Earned Value – Actual Cost 

450 – 400 

= $50 

6. Schedule Variance 

Formula: SV = Earned Value – Planned Value 

This is a simple calculation where the earned value is subtracted from the planned value. This value measures the actual progress against the scheduled progress. 

Let’s say your project is worth $20,000 and scheduled to be completed in 4 months. 

At the end of two months your earned value (EV) should be at $10,000, which is also the planned or estimated value at the start of the project. If your earned value and planned value are same, then there is no schedule variance. If it is let’s say at $7,500 then you would calculate Schedule Variance as 

Earned Value – Planned Value  

7500 – 10000  

= -2500 

This shows that you have a negative Schedule Variance which means that the project is running behind schedule. You can also express SV as a percentage. In the above case it would be –25% 

7. Cost Performance Index (CPI) 

Formula CPI = Earned Value / Actual Cost 

The Cost Performance Index measures the cost efficiency of the project in utilizing the funds invested in it.  It is calculated through dividing earned value by actual cost. A higher CPI means that you are exceeding your budget. 

A CPI of greater than 1 shows a greater cost efficiency. If the Earned value is calculated at $15,000 and the Actual cost incurred is $10,000 then we would calculate CPI as 

Earned Value /Actual Cost 

=15000/10000 = 1.5 

This denotes a high cost-efficiency in the project. 

8. Schedule Performance Index (SPI) 

SPI PMP Formula:  

SPI = Earned Value/Planned value 

The Schedule Performance Index measures how well the project schedule is holding up against the original project plan. If the SPI is at 1, it means you are on schedule, if it is more than 1 it means you are ahead of schedule, and an SPI value that is under 1 means you are behind schedule.   

Let’s imagine you have an earned value of $7,500 and a planned value of $10,000 

In this case your SPI would be calculated as 

Earned Value / Planned Value 

7500/10000 = 0.75 

This denotes that your project is running behind schedule. 

9. Estimate at Completion (EAC)

EAC PMP Formula 

EAC = Budget at Completion / Cost Performance Index 

EAC = Actual Cost + Bottom –up Cost to Complete 

EAC = Actual Cost + (Budget at Completion – Earned Value) 

EAC = Actual Cost + [(Budget at Completion – Earned Value) / (Cost performance Index x Schedule Performance Index)]   

Estimate at Completion is the revised estimate of the budget needed for completing the project. This may change from the original budget through additional costs or a change in prices or other unforeseen variables.  

Let’s assume that the budget at completion is $20000 and the CPI is at 0.75. 

In this case you would calculate EAC as  

Budget at Completion / Cost Performance Index 

20000/0.75 = 26,667 

This means that you will need an extra $6,667 to complete the project at the current level of cost efficiency. 

10. Variance at Completion 

Formula: Variance at Completion = Budget at Completion – Estimate at Completion 

Variance at Completion calculates how much the project budget is accurate to the planned budget. This will help you to plan and estimate requirements more accurately. 

If the Budget at completion was $20,000 and you find that the Estimate at completion is $25,000, then you could calculate the Variance at completion by calculating: 

Budget at Completion – Estimate at Completion 

20000 – 25000 = -5000 

You will get at Variance at Completion of –5000.  Which means the project is going beyond the initial budget by $5000 

11. Estimate to Complete (ETC)

Formula: Estimate to Complete = Estimate at Completion – Actual Cost 

Estimate to Complete or ETC is a measure of how much funds will be required to complete the remaining work. This will help you by giving a dynamic value that is more accurate than your initial estimates. 

For example, if the Estimate to complete is calculated at $25,000 and the Actual Cost incurred is $10,000. In this case you can calculate the Estimate to Complete as follows. 

 Estimate at Completion – Actual Cost 

25000 – 10000 

=$15,000 

This means that you will need $15,000 at this point to successfully complete the project. 

12. To Complete Performance Index (TCPI)

Formula:  

TCPI = (Budget at Completion – Earned Value) / (Estimate at Completion – Actual Cost) 

TCPI = (Budget at Completion – Earned Value) / (Budget at Completion – Actual Cost) 

To Complete Performance Index (TCPI) gives the cost performance required to meet project goals based on the budget that is available.  If the Budget at completion is $20,000, Estimate at Completion is $25,000, Earned Value is at $10,000 and Actual Cost is at $ 12,000. In this situation we would calculate TCPI as (Budget at Completion – Earned Value) / (Estimate at Completion – Actual Cost) 

(20000-10000)/ (25000-12000) 

= 10000/13000 = 0.77 

The TCPI would be at 0.77 

13. Standard Deviation

Formula: Standard Deviation (σ) = (Pessimistic – Optimistic) / 6 

Standard Deviation expressed by the character ‘σ’ represents the degree to which the values can change within a project. Let’s imagine a task that takes 4 days to complete in the best case and 16 days to complete in the worst case. You would calculate standard deviation as 

 (Pessimistic – Optimistic) / 6  

(16-4)/6 

Standard deviation would be 2 in this case. 

14. Communication Channels

Formula: Communication Channels = n(n-1) / 2 

In a project, communication is key. This formula is used to measure the number of communication channels needed in a project. Here ‘n’ represents the number of stakeholders. If there are 12 stakeholders in the project, there will be communication channels between each stakeholder. If you are a stakeholder then you will be part of 11 communication channels. Similarly, every other stakeholder will be a part of 11 channels. This is the n-1 calculation. This number needs to be divided in two to remove the duplicate channels because your channel with a particular stakeholder and their channel with you should not be counted twice. In this scenario of 12 stakeholders the calculation will be as follows:  

= n(n-1) / 2 

12 (12-1)/2 = 66 

We have 66 Communication channels in this case. 

15. Cost plus Percentage of Cost

Formula: Cost plus Percentage of Cost = Cost + n% 

This is a type of contract that is in the sellers’ favor where the buyer agrees to pay all the costs incurred by the seller and adds a percentage of the total cost as payment. ‘n’ represents the agreed percentage that will be paid on top of the cost incurred. If n is 10% and the cost is 50. In this case the cost-plus percentage of cost will be calculated as: 

 Cost + n% 

50 + (50 x 10/100)  

=55 

In this the cost the buyer pays more when there is an increase in the cost incurred. If the cost increases to 60 the buyer will need to pay 66. 

16. Cost plus Fixed Fee

Formula: Cost plus Fixed Fee = Cost + n 

This is done in a contract where the buyer agrees to pay all the costs plus a pre-decided amount to the seller. ‘n’ stands for the fixed amount that is to be paid apart from the costs. With the cost at 50 and ‘n’ at 5 that calculation will be a simple addition. 

Cost + n 

= 50 + 5 

While the buyer pays 55, if the cost increases to 70, the buyer will pay 75. 

17. Cost plus Award Fee

Formula: Cost plus Award Fee = Cost + n 

In this method the seller does get paid for the cost incurred with the addition of a fixed fee called an award fee. This is a more dynamic type of scenario where n is calculated based on pre decided guidelines. If the Cost is 50 and ‘n’ is 8, then the Cost-plus award fee would be 

Cost + n 

50 + 8 

The buyer pays 58 in this scenario. 

18. Cost plus Incentive Fee

Formula: Cost plus Incentive Fee = Cost + n 

This is like the cost-plus award fee model; the key difference is that the incentive is paid only when the project is completed within the estimated period. In this model the magnitude of incentive will depend on the speed with which the project gets completed. This is also a scenario where ‘n’ depends on how quickly the project got completed. The incentive might be 8 if the project is finished within 8 weeks. For 8 to 10 weeks the incentive drops to 4. For more than 10 weeks there is no incentive. If the cost is 50 and the project is finished in 9 weeks, then the Cost-plus incentive fee would be. 

 Cost + n 

=50 + 4 

The buyer pays 54 in this case, if the cost remains constant and the project is completed in 11 weeks the buyer pays only 50. 

19. Return on Investment (ROI) 

Formula: ROI = (Net Profit / Cost of Investment) x 100 

Return on Investment is the measurement of the rate at which the amount invested in a project gets recovered. This is expressed as a percentage. If net profit is $2000 and the Cost of Investment is $,30,000 then we would calculate ROI as  

(Net Profit / Cost of Investment) x 100 

(2000/30000) x 100 = 6.67 

For this project you have a ROI of 6.67% 

20. Payback Period 

Formula: Payback Period = Initial Investment / Periodic Cashflow 

The Payback Period refers to the amount of time it would take to recover the investment in a project. This is again a simple calculation where if the Initial investment is $20,000 and the periodic cash flow per month is $1000, then you could calculate the Payback period as follows:  

Initial Investment / Periodic Cashflow 

20000/1000 = 20 

Payback period in this case would be 20 months 

21. Cost Benefit Ratio

Formula: Cost Benefit Ratio = Net Present Value of Investment / Initial Investment Cost 

Cost-benefit ratio is a comparison between the funds invested in the project and the value that has come out of it. This is a measure of project success in financial terms. If the initial investment was $20,000 and the Net Present Value is $25,000 then the Cost Benefit Ratio could be calculated as follows. 

Net Present Value of Investment / Initial Investment Cost 

25000/20000 = 1.25 

The Cost benefit ratio of 1.25 denotes that every dollar invested in the project is now worth 1.25 dollars. 

22. Present Value (PV)

Formula: PV = Future Value / (1 + i)n 

Present Value (PV) considers the time value of money. This is useful to calculate what a future amount of money would mean today if adjusted for time. ‘i’ represents the interest rate or the discounting rate. ‘n’ represents the number of time periods. The period used should be the same for both variables. If the interest rate is 10% and the time period is 5 years. A Future Value of $20,000 will have a Present Value as calculated below 

Future Value / (1 + i)n 

20000/ (1+ 10%) 5 

12418.43 

This means a future value of $20,000 in 5 years has a present value of $12,418 as of now.  

23. Future Value (FV)

Formula: FV = Present Value x (1 + i)n 

Future Value is an estimate of what a fixed amount of money would be valued at a given point of time in the future. ‘i’ is the interest rate and ‘n’ is the number of time periods. If Present value is $20,000, ‘i’ is 10% and time period is 5 years. Then we can calculate the Future value as  

Present Value x (1 + i)n 

20000 x (1+0.1)5 

=32210.2 

The Future Value of $20,000 in 5 years if the interest rate is at 10 percent will be $32,210 

24. Target Price 

Formula: Target Price = Target Cost + Target Fee 

This is a simple addition of estimated cost and an agreed fee that is given to the seller on top of the target cost. This is useful when calculating price per unit. If Target Cost is $100 and Target fee is $20 the Target price will be Target Cost + Target Fee 

100 + 20 

In this case we get a Target price of $120

25. Point of Total Assumption

Formula: PTA = [(Ceiling Price — Target Price) / Buyer’s Share Ratio] + Target Cost 

Point of Total Assumption is the point at which the seller has incurred costs that have stopped the project from being profitable. Any expense beyond the PTA is an additional expense incurred by the seller.  If Ceiling Price is $25, Target Price is $20, Buyer’s share ratio is 5 and Target cost is $15 then we could calculate PTA as follows  

[(Ceiling Price — Target Price) / Buyer’s Share Ratio] + Target Cost 

[[25-20)/5] +15 

With the above details we get a PT. 

26. Defects per Million Opportunities (DPMO)

DPMO = Number of Defects / Opportunities for Defects x 1,000,000

27. Risk Priority Number (RPN) 

RPN = Severity x Occurrence x Detection 

28. Scheduled Variance 

Schedule Variance (SV) = Earned Value (EV) – Planned Value (PV) 

29. Cost of Poor Quality (COPQ) 

COPQ = Prevention Costs + Appraisal Costs + Internal Failure Costs + External Failure Costs 

30. Frequency Index 

Frequency Index = Need Frequency x Audience Size 

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Using the formulas in the PMP Exam

This is not an exhaustive list of PMP formulas you will need to know as a project manager or to pass the PMP exam. These are only the most important and most used ones. It is important to understand the concepts behind the formulas to understand them better. It will also help you decide when to use each formula.  

To understand the concepts thoroughly try using the formulas in your own projects and fortify your understanding with authentic experience.  Additionally, a comprehensive course like KnowledgeHut PMP Certification online will also train you how to use these formulas in real project like situations. 

What formula question types are in the PMP exam? 

Project Management Professional (PMP) certification involves understanding various formulas crucial for project management. This article explores different types of formula questions one may encounter in the PMP exam. As a project management expert, I will provide insights and practical examples to make these concepts clear and applicable. 

Apply a Formula

In the PMP exam, candidates often encounter questions that require the application of a single formula. For instance, you might need to calculate the Earned Value (EV) of a project. Here, you simply apply the formula EV = % of completed work × Budget at Completion (BAC). For example, if 40% of a project with a BAC of $100,000 is completed, the EV is $40,000. 

Apply Two Formulas 

Some questions necessitate the use of two formulas. For example, determining the Cost Performance Index (CPI) and Schedule Performance Index (SPI). First, you calculate the CPI using CPI = EV ÷ Actual Cost (AC). Then, calculate the SPI using SPI = EV ÷ Planned Value (PV). These indicators help assess the health of the project financially and timewise. 

Invert a Formula 

Inverting a formula is another type encountered in the exam. This could involve manipulating a known formula to find a different aspect of project management. For example, if you know the CPI and need to find the AC, you rearrange the formula to AC = EV ÷ CPI.

Result Interpretation

Interpreting results from calculated formulas is a critical skill. It involves understanding what the numbers mean in the context of project performance. For instance, a CPI greater than 1 indicates a project is under budget, while less than 1 shows it’s over budget. 

Find the Correct Formula 

Identifying the right formula based on the given scenario is crucial. This requires a solid understanding of various project management concepts and their applicable formulas. For instance, knowing when to apply the PERT (Program Evaluation and Review Technique) formula versus a simple average. 

Use a Formula Based on Keywords

Recognizing keywords in questions to determine which formula to use is essential. For example, if a question mentions ‘uncertainty’ or ‘risk’, it might require the use of Standard Deviation or PERT formulas. 

How to Practice PMP Formulas?

Practicing PMP formulas is a pivotal step in preparing for the Project Management Professional (PMP) certification. As a seasoned project manager, I’ve found that the most effective way to master these formulas is through a blend of understanding, application, and repetition. 

Firstly, understanding the context of each formula is crucial. Know why and when a particular formula is used in project management. For example, the Earned Value Management (EVM) formulas like Earned Value (EV), Actual Cost (AC), and Planned Value (PV) are not just numbers; they reflect the project’s financial health and progress. 

Next, create a personalized formula sheet. List all key formulas you need to remember. Regularly review and update this sheet to reinforce your memory and keep the information fresh. 

Applying these formulas in real-life scenarios or case studies is invaluable. Calculate the Cost Performance Index (CPI) or the Schedule Performance Index (SPI) for your current projects. This real-world application makes the formulas more relatable and easier to grasp. 

Another effective method is using flashcards. Write down the formula on one side and a brief description or example on the other. This technique aids in quick recall and retention. 

Participating in study groups or online forums can also be beneficial. Engaging with peers allows you to see different perspectives and approaches to applying these formulas. 

Finally, regular practice is key. Work on sample questions and mock exams that focus on formula-based questions. This not only prepares you for the exam format but also enhances your confidence in using these formulas effectively.

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