Qualitative analysis of project risk.
Kremljak, Zvonko
Abstract: In the paper the research on decision-making in high-risk
conditions is presented. The results are important within strategic
management, research and development management and industrial
engineering. Risk assessment, risk management and qualitative project
risk analysis also represent areas for development of projects. The main
motivation is to create tools and techniques which help us to make
better decisions. One of the most important steps to make excellent
decisions regarding projects is qualitative analysis of project risk as
described.
Key words: risk, risk management, risk handling, qualitative
analyses, project risk
1. INTRODUCTION
A difficult part of the risk management process is data gathering.
Techniques provide a means for collecting risk-related data from
subject-matter experts and from people who are intimately involved with
the various aspects of the program. It relies on "expert"
judgment to identify and analyze risk events, develop alternatives and
provide "analyzed" data. It is used almost exclusively in a
support role to help develop technical data, such as probability and
consequences/impacts information, required by a primary risk assessment
technique. It can address all the functional areas that make up the
critical risk areas and processes and can be used in support of risk
handling. Expert judgment is a sound and practical way of obtaining
necessary information that is not available elsewhere or practical to
develop using engineering or scientific techniques. However,
interviewers should be aware that expert opinions may be biased because
of over-reliance on certain information and neglect of other
information; unwarranted confidence; the tendency to recall most
frequent and most recent events; a tendency to neglect rare events; and
motivation (Boyd, 2011; Holmes, 2002).
Lessons learned and historical information about the risk
associated with programs that are similar to the new system to identify
the risk associated with a new program. It is normally used to support
other primary risk assessment techniques, e.g., Product (WBS) Risk
Assessment, Process Risk Assessment, etc. The technique is based upon
the concept that "new" programs are originated or evolved from
existing programs or simply represents a new combination of existing
components or subsystems. This technique is most appropriate when
systems engineering and systems integration issues, plus software
development, are minimal. A logical extension of this premise is that
key insights can be gained concerning aspects of a current
program's risks by examining the successes, failures, problems and
solutions of similar existing or past programs. This technique addresses
all the functional areas that make up the critical risk areas and
processes (Byrd & Cothern, 2000; Grey, 1995).
The first step in this approach is to select or develop a baseline
comparison system (BCS) that closely approximates the characteristics of
the new system/equipment to as low a level as possible and uses the
processes similar to those that are needed to develop the new system.
For processes, industry-wide best practices should be used as a
baseline. Relevant BCS data are then collected, analyzed and compared
with the new system requirements. The BCS data may require adjustment to
make a valid comparison. The comparisons can be a major source of risk
assessment data and provide some indication of areas that should be
investigated further.
2. QUALITATIVE PROJECT RISK ANALYSIS
2.1 Inputs
We identify the following levels of qualitative project risk
analysis (Chinbat, 2009):
Identified risks--risks discovered during the risk identification
process are evaluated along with their potential impacts on the project.
* Project status--the uncertainty of a risk often depends on the
project's progress through its life cycle. Early in the project,
many risks have not surfaced, the design for the project is immature and
changes can occur, making it likely that more risks will be discovered.
* Project type--projects of a common or recurrent type tend to have
better understood probability of occurrence of risk events and their
consequences. Projects using state-of-the-art or first-of-its-kind
technology--or highly complex projects--tend to have more uncertainty.
* Data precision--precision describes the extent to which a risk is
known and understood. It measures the extent of data available, as well
as the reliability of data. The source of the data that was used to
identify the risk must be evaluated.
* Scales of probability and impact--these scales are to be used in
assessing the two key dimensions of risk; probability and consequences.
* Assumptions--assumptions identified during the risk
identification process are evaluated as potential risks (***, 2002).
[FIGURE 1 OMITTED]
2.2 Outputs
* Overall risk ranking for the project--risk ranking may indicate
the overall risk position of a project relative to other projects by
comparing the risk scores. It can be used to assign personnel or other
resources to projects with different risk rankings, to make a
benefit-cost analysis decision about the project or to support a
recommendation cancellation.
* List of prioritized risks--risks and conditions can be
prioritized by a number of criteria. These include rank (high, moderate
and low) or WBS level. Risks may also be grouped by those that require
an immediate response and those that can be handled at a later date.
Risks that affect cost, schedule, functionality and quality may be
assessed separately with different ratings. Significant risks should
have a description of the basis for the assessed probability and impact.
* List of risks for additional analysis and management--risks
classified as high or moderate would be prime candidates for more
analysis, including quantitative risk analysis and for risk management
action (Conrow, 2000).
[FIGURE 2 OMITTED]
3. TOOLS AND TECHNIQUES FOR QUALITATIVE PROJECT RISK ANALYSIS
* Risk probability and impact--risk probability and risk
consequences may be described in qualitative terms such as very high,
high, moderate, low and very low. Risk probability is the likelihood
that a risk will occur. Risk consequences are the effect on project
objectives if the risk event occurs. These two dimensions of risk are
applied to specific risk events, not to the overall project. Analysis of
risks using probability and consequences helps identify those risks that
should be managed aggressively (Beneplanc & Rochet, 2011; Schuyler,
2001).
* Probability/impact risk rating matrix--a matrix may be
constructed that assigns risk ratings (very low, low, moderate, high and
very high) to risks or conditions based on combining probability and
impact scales. Risks with high probability and high impact are likely to
require further analysis, including quantification and aggressive risk
management. The risk rating is accomplished using a matrix and risk
scales for each risk (Vose, 2000).
* Project assumptions testing--identified assumptions must be
tested against two criteria: assumption stability and the consequences
on the project if the assumption is false. Alternative assumptions that
may be true should be identified and their consequences on the project
objectives tested in the qualitative risk-analysis process.
* Data precision ranking--qualitative risk analysis requires
accurate and unbiased data if it is to be helpful to project management.
Data precision ranking is a technique to evaluate the degree to which
the data about risks is useful for risk management. It involves
examining extent of understanding of the risk, data available about the
risk, quality of the data, reliability and integrity of the data.
Software tools display user's risk simulation results fully
integrated with native Gantt charts (Fig. 3). New bars indicate the
range of possible values for uncertain variables, and display
sensitivity and critical index information.
[FIGURE 3 OMITTED]
4. CONCLUSION
In projects whose results are not only tangible resources but also
capabilities, qualitative risk assessment is important. Qualitative risk
analysis is a process of evaluating influence and certainty of
recognized risks. Risks are arranged according to their potential
influence on project goals. Qualitative risk analysis is one of the ways
to define importance of treatment of individual risks and managing
reaction to risk. Time aspect can rather increase the importance of
risk. So, complete developed methodology is the main contribution to the
field.
Assessing the quality of available information can also help manage
the assessment. For qualitative risk analysis one must assess the
probability and consequences of risk with established methods and tools
for qualitative analysis. Decision-making in high-risk conditions is
becoming a common area for research within strategic management,
organizational theory, research and development management and
industrial engineering.
5. REFERENCES
Beneplanc, G. & Rochet, J.-C. (20ll). Risk Management in
Turbolent Times. Cary: Oxford University Press
Boyd, R. (2011). Fatal Risk. Hoboken: John Wiley & Sons.
Byrd, D. M. & Cothern, C. R. (2000). Introduction to Risk
Analysis: A Systematic Approach to Science-Based Decision Making. ABS Consulting
Chinbat, U. (2009). Using simulation for reducing risk of a mining
optimization project. Int. Journal of Simulation Modelling, Vol. 8, No.
3, p. 166-177
Conrow, E. H. (2000). Effective risk management. AIAA (American
Institute of Aeronautics & Ast)
Grey, S. (1995). Practical risk assessment for project management.
Chicester: John Wiley & Sons
Holmes, A. (2002). Risk Management. Oxford: Capstone Publishing
***Project Management Institute. (2002). A guide to the project
management body of knowledge. Pennsylvania, Newton Square: Project
Management Institute
Schuyler, J. (2001). Risk and Decision Analysis in Projects (Cases
in project and program management series). Pennsylvania, Newton Square:
Project Management Institute
Vose, D. (2000). Risk analysis: a quantitative guide. Chicester:
John Wiley & Sons
