Introduction

• General
  • What is risk?
  • 6 questions to define the project
  • The key areas of concern
  • What should risk analysis provide?
  • 3 Ways to view risk management
  • General comments on risk assessment
  • Accountability
  • General comments on planning
  • What are the core process steps to assess a risk?
  • Simple process outline
  • What are the basic overall process steps?
  • Stakeholders
  • Success measures
  • Why carry out Risk Assessment?
• Project Life Cycle
  • Project Life Cycle
  • Project Life Cycle - concept
  • Project Life Cycle - plan
  • Project Life Cycle - execute
  • Project Life Cycle - termination
  • Project Life Cycle - general points

• Terminology
  • Clarification of terms
  • Basic statistical terms

The Risk Management process

• General
• Define
  • Define the project
  • Define the project management process
• Identify the risks and responses
• Organise - prioritise risks and responses
• Ownership - risks, responsibilities and contractors
• Estimation
  • Size the risks
  • Simple estimating of risk
  • Cumulative probability graph
  • Simple estimating of risk - more detail
  • Simple estimation problems
  • Obtaining the estimates
  • Breakdown of variables
• Evaluation
  • Estimates
  • Independent correlation
  • Cumulative probability graph
  • Positive correlation
  • Cumulative probability graph
  • Negative correlation
  • Conditional correlation
  • Cumulative probability graph
  • Cumulative probability graph 2
• Planning
  • Ways to modify plans
  • Plans and strategies
  • Types of plans
  • Dependencies - 4 basic types
  • Dependencies - 4 basic types
    part 2
  • Manage - plans and strategies

Risk issues

• General
  • Identify risk issues
  • Other issues
  • The contractor
  • Other aspects
  • Risk combination
• Assessment of risk
  • Common methods of assessing risk
  • Common methods of assessing risk 2
  • Issue based
  • Checklists
  • Qualitative method
  • Quantitative method
  • Quantitative method part 2
  • Quantitative method part 3
  • Quantitative method part 4

Modelling

• Cost models
  • Simple cost model
  • Cost model
  • Cost model part 2
• Monte Carlo model
  • Monte Carlo simulation
  • Monte Carlo simulation 2
  • Monte Carlo simulation - output
  • Monte Carlo distribution
  • Monte Carlo risk distribution
  • How do we carry out the simulations?
  • Probability density function - PDF
  • PDF - Simplified version

Events

• Uncertain
  • Uncertain events
  • Uncertain events part 2
  • Uncertain events part 3
  • Uncertain events part 4
• Corellated
  • Risk of exceeding the target cost
  • Correlated events
  • Correlated events part 2
  • Correlated events part 3
• 3 point model
  • 2 pathways
  • Simple probability estimation
  • Collecting task information
  • Documentation
  • Task probability
  • Monte Carlo risk distribution
  • Multiple variables

Networks and branching

• Network
  • Simple network
  • Simple network - no lag
  • Simple network - with lag
• Branching
  • Simple branching
  • Complex branching
  • Complex branching part 2
  • Multiple branching
  • Multiple branching part 2
  • Multiple probability branching
  • Multiple probability branching
    part 2
  • Nodes and branching networks
  • Branching networks
• Production example
  • Production example
  • Production example part 2
  • Risk of exceeding target duration

Other

• Business forecast
  • Business forecast
  • Business schedule risk
  • Business revenue and profit risk
  • Business revenue and profit risk 2
  • Business profit simulation
• Other areas to consider when reviewing risk
• Markov chain
• General points to consider
• Task information
  • Risk assessment of a task
  • Risk assessment of a task part 2
• Human relations
  • Negatives
  • Benefits

Uncertain events part 4

We have seen that in terms of uncertainty we can have:

Uncertainty in the value of an activity

This is the 3 point estimate [see Probability density function - Simplified version] of the value of a single activity which is represented in a model by the triangular PDF.

Uncertainty in an event

Normally, we are considering a single event. However, when an event can lead to more than one pathway we need to designate a likelihood for each [see Uncertain events part 2].

Correlated events.

We have seen [see Monte Carlo simulation output] that we can examine a number of activities over their 3 point ranges by employing random numbers to generate possible values for each activity. We would then aggregate all the individual values to get one possible total cost from many possibilities.

Using this technique we know that some activities will be near their MAXIMUM and others will be near their MINIMUM. The model reflects what we would expect in practice. This is good because a high in one area and a low in another, averaging over many activities, ought to reduce the RISK overall. There are swings and roundabouts. You gain on some activities and lose on others.

We have seen from the PDF curves [see Cost model part 2] that the likelihood of carrying out a project for the MINIMUM or MAXIMUM costs is very small compared to a value somewhere in between.

When looking at these activities we are assuming that they function independently and that there is no common theme between them.
However, many activities appear linked in that if one particular activity cost (or duration) is HIGH (or LOW) then a subsequent activity will also be HIGH (or LOW).

These events are known as CORRELATED events. See earlier examples [see full positive correlation], [see full negative correlation], [see independent correlation] and [see conditional correlation].

This might show itself in overestimating (or underestimating) the power needed for a heating and ventilation system. This could have a knock on effect in terms of pipe sizing, quantity, equipment and the site size for boilers etc.

The project manager needs to be aware of these correlated activities and make allowance for them in the model. If you don’t a HIGH might be cancelled out by a LOW in the model, where it should have been a HIGH as well, so generating a false total in the model.

Correlation makes extreme values more likely.