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Event chain methodology

April 14, 2024

Event chain methodology is a network analysis technique that is focused on identifying and managing events and relationship between them (event chains) that affect project schedules. It is an uncertainty modeling schedule technique. Event chain methodology is an extension of quantitative project risk analysis with Monte Carlo simulations. It is the next advance beyond critical path method and critical chain project management.[1] Event chain methodology tries to mitigate the effect of motivational and cognitive biases in estimating and scheduling.[2] It improves accuracy of risk assessment and helps to generate more realistic risk adjusted project schedules.[3]

Event chain diagram

History edit

Event chain methodology is an extension of traditional Monte Carlo simulation of project schedules where uncertainties in task duration and costs are defined by statistical distribution.[4][5][6] For example, task duration can be defined by three point estimates: low, base, and high. The results of analysis is a risk adjusted project schedule, crucial tasks, and probabilities that project will be completed on time and on budget. Defining uncertainties using statistical distribution provide accurate results if there is a reliable historical data about duration and cost of similar tasks in previous projects. Another approach is to define uncertainties using risk events or risk drivers, which can be assigned to different tasks or resources.[7][8] Information about probabilities and impact of such events is easier to elicit, which improves accuracy of analysis. Risks can be recorded in the Risk register. Event chain methodology was first proposed in the period of 2002–2004.[9] It is fully or partially implemented in a number of software application.[10] Event Chain Methodology is based on six principles and has a number of outcomes.

Principles edit

Moment of risk and state of activity edit

 
Event chain diagram for one activity

Activities (tasks) are not a continuous uniform procedure. Tasks are affected by external events, which transform an activity from one state to another. One of the important properties of an event is the moment when an event occurs during the course of an activity. This moment, when an event occurs, in most cases is probabilistic and can be defined using statistical distribution. The original state is called a ground state, other states are called excited states. For example, if the team completes their job on activity, they can move to other activities. The notion of an activity's state is important because certain events can or cannot occur when activity is in certain state. It means that the state of an activity is subscribed to the events. Events can be local, affecting particular tasks or resources, or global affecting all tasks or resources.

Event chains edit

Events can be related to other events, which will create event chains. These event chains can significantly affect the course of the project. For example, requirement changes can cause an activity to be delayed. To accelerate the activity, the project manager allocates a resource from another activity, which then leads to a missed deadline. Eventually, this can lead to the failure of the project. It could be different relationship between events. One event can trigger one or multiple events.

Events can be correlated with each other without one triggering another one. In this case if one risk has occurred, another one will occur and vice versa. One event assigned in one activity can execute another activity or group of activities. In many cases it the execution of risk response plans. For example, event “structural defect is discovered” can cause one or many activities “Repair”. Events can cause other events to occur either immediately or with a delay. The delay is a property of the event subscription. The delay can be deterministic, but in most cases, it is probabilistic. Also risks can be transferred from one activity to another. To define event chains, we need to identify a "sender", the event that initiates the chain of events. The sender event can cause one or more events that effect multiple activities. These are called "receiver" events. In turn, the receiver events can also act as sender events.

Event chain diagrams edit

 
Example of event chain diagram: local and global threats and opportunities with different probabilities and impacts

Event chain diagram is a visualization that shows the relationships between events and tasks and how the events affect each other.[11][12] The simplest way to represent these chains is to depict them as arrows associated with certain tasks or time intervals on the Gantt chart. Here are a few important rules:

  • Event chains diagrams present events as arrows on the Gantt charts.
  • Arrows pointing down are threats. Arrows pointing up are opportunities.
  • Issues are shown as an arrow within a circle. Color of the issue arrow is red (dark).
  • Closed or transferred risks are shown using dashed lines. Color of arrow is white. Closed issue is shown in the circle with dashed border line.
  • Excited states are represented by elevating the associated section of the bar on the Gantt chart.
  • Colors represent the calculated impact of the risk. Higher impacts are red or darker shade. Low impacts are green or lighter shade. The size of the arrow represents probability.
  • Event chains are shown as lines connecting arrows depicting events.
  • Event chains may trigger another activity. In this case event chain line will be connected with the beginning of activity with optional arrow.
  • Event chains may trigger a group of activities. In this case this group of activities will be surrounded by the box or frame and event chain line will be connected to the corner of the box or first activity within a frame.

By using event chain diagrams to visualize events and event chains, the modeling and analysis of risks and uncertainties can be significantly simplified.

 
Example of event chain diagram with critical event chain and activity triggered by event

Another tool that can be used to simplify the definition of events is a state table. Columns in the state table represent events; rows represent the states of an activity. Information for each event in each state includes four properties of event subscription: probability, moment of event, excited state, and impact of the event.

Monte Carlo simulation edit

Once events and event chains are defined, quantitative analysis using Monte Carlo simulation can be performed to quantify the cumulative effect of the events.[13] Probabilities and impacts of risks assigned to activities are used as input data for Monte Carlo simulation of the project schedule.[14] In most projects it is necessary to supplement the event based variance with uncertainties as distributions related to duration, start time, cost, and other parameters.

In Event chain methodology, risk can not only affect schedule and cost, but also other parameters such as safety, security, performance, technology, quality, and other objectives. In other words, one event can belong to different categories.[15] The result of the analysis would show risk exposure for different categories as well as integrated project risk score for all categories. This integrated project risk score is calculated based on relative weights for each risk category.

Critical event chains edit

Monte Carlo simulation provides the capability, through sensitivity analysis, to identify single or chains of events. These chains of events can be identified by analyzing the correlations between the main project parameters, such as project duration or cost, and the event chains. These are called “critical events” or “critical chains of events”. By identifying critical events or critical chains of events, we can identify strategies to minimize their negative effects: Avoid, Transfer, Mitigate, or Accept. Event and event chain ranking is performed for all risk categories (schedule-related and non-schedule) as part of one process. Integrated risk probability, impact and score can be calculated using weights for each risk category.

Project control with event and event chains edit

Monitoring the activity's progress ensures that updated information is used to perform the analysis. During the course of the project, the probability and time of the events can be recalculated based on actual data. The main reason for performance tracking is forecasting an activity's duration and cost if an activity is partially completed and certain events are assigned to the activity. Event chain methodology reduces the risk probability and impact automatically based on the percent of work completed. Advanced analysis can be performed using a Bayesian approach. It is possible to monitor the chance that a project will meet a specific deadline. This chance is constantly updated as a result of the Monte Carlo analysis. Critical events and event chains can be different at the various phases of the project

Phenomena edit

Repeated activities edit

 
Repeated Activity

Sometimes events can cause the start of an activity that has already been completed. This is a very common scenario for real life projects; sometimes a previous activity must be repeated based on the results of a succeeding activity. Event chain methodology simplifies modeling of these scenarios. The original project schedule does not need to be updated, all that is required is to define the event and assign it to an activity that points to the previous activity. In addition, a limit to the number of times an activity can be repeated must be defined.

Event chains and risk response edit

 
Mitigation plan

If an event or event chain occurs during the course of a project, it may require some risk response effort.

Risk response plans execution are triggered by events, which occur if an activity is in an excited state. Risk response events may attempt to transform the activity from the excited state to the ground state. Response plans are an activity or group of activities (small schedule) that augment the project schedule if a certain event occurs. The solution is to assign the response plan to an event or event chain. The same response plan can be used for one or more events.

Resource allocation based on events edit

One potential event is the reassignment of a resource from one activity to another, which can occur under certain conditions. For example, if an activity requires more resources to complete it within a fixed period, this will trigger an event to reallocate the resource from another activity. Reallocation of resources can also occur when activity duration reaches a certain deadline or the cost exceeds a certain value. Events can be used to model different situations with resources, e.g. temporary leave, illness, vacations, etc.

See also edit

References edit

  1. ^ Virine, Lev; Trumper, Michael (2007). Project Decisions: The Art and Science. Berrett-Koehler Publishers. ISBN 978-1567262179.
  2. ^ Robyn M. Dawes and Bernard Corrigan, ‘‘Linear Models in Decision Making’’ Psychological Bulletin 81, no. 2 (1974): 93–106.
  3. ^ Virine, Lev (2013). Integrated Qualitative and Quantitative Risk Analysis of Project Portfolios. In Proceedings of Enterprise Risk Management Symposium. April 22–23, 2013, Chicago, IL
  4. ^ Vose, David (2008). Risk Analysis: A Quantitative Guide (3rd ed.). Great Britain: Wiley. ISBN 978-0-470-51284-5.
  5. ^ Hillson, David (2012). Practical Risk Management: The ATOM Methodology (2nd ed.). Berrett-Koehler Publishers. ISBN 978-1567263664.
  6. ^ Hillson, David (2009). Managing Risk in Projects (Fundamentals of Project Management). Routledge. ISBN 978-0566088674.
  7. ^ Hulett, David (2009). Practical Schedule Risk Analysis. Routledge. ISBN 978-0566087905.
  8. ^ Hulett, David (2011). Integrated Cost-Schedule Risk Analysis. Routledge. ISBN 978-0566091667.
  9. ^ Virine, Lev (2013). Integrated Qualitative and Quantitative Risk Analysis of Project Portfolios. In Proceedings of 2013 Enterprise Risk Management Symposium, April 22–24, Chicago, IL
  10. ^ Virine, Lev. and Trumper, Michael. (2015). Predicting the unpredictable: how to analyze project risks using event chain methodology. PM Network, 29(9), 28–29
  11. ^ Virine, Lev & McVean, Jason. (2004). Visual Modeling of Business Problems: Workflow and Patterns, In Proceedings of 2004 Winter Simulation Conference, Washington DC.
  12. ^ Virine, Lev & Rapley, Lisa. (2003). Visualization of Probabilistic Business Models, In Proceedings of 2003 Winter Simulation Conference, New Orleans, LA.
  13. ^ Avlijas, Goran (2018). "Examining the Value of Monte Carlo Simulation for Project Time Management". Management: Journal of Sustainable Business and Management Solutions in Emerging Economies. 24: 11. doi:10.7595/management.fon.2018.0004. S2CID 67095960.
  14. ^ Williams, T. "Why Monte Carlo simulations of project networks can mislead". Project Management Journal, Vol 35. Issue 3, (2004): 53-61
  15. ^ Agarwal, Ruchi. and Virine, Lev. (2017). Monte Carlo Project Risk Analysis. In Raydugin, Y. (ed) Handbook of Research on Leveraging Risk and Uncertainties for Effective Project Management. IGI Global; 1 edition

Further reading edit

  • Arnaud Doucet, Nando de Freitas and Neil Gordon, Sequential Monte Carlo methods in Practice, 2001, ISBN 0-387-95146-6.
  • Hammond, J.S. and Keeney, R.L. and Raiffa, H., Smart Choices: A Practical Guide to Making Better Decisions (1999). Harvard Business School Press
  • D. Kahneman and A. Tversky (ed.) (1982). Judgement under Uncertainty: Heuristics and Biases. Cambridge University Press. ISBN 0-521-28414-7
  • Keeney, R.L., Value-focused thinking: A Path to Creative Decisionmaking (1992). Harvard University Press. ISBN 0-674-93197-1
  • Matheson, David, and Matheson, Jim, The Smart Organization: Creating Value through Strategic R&D (1998). Harvard Business School Press. ISBN 0-87584-765-X
  • Raiffa, Howard, Decision Analysis: Introductory Readings on Choices Under Uncertainty (1997). McGraw Hill. ISBN 0-07-052579-X
  • Robert C.P. and G. Casella. "Monte Carlo Statistical Methods" (second edition). New York: Springer-Verlag, 2004, ISBN 0-387-21239-6
  • Skinner, David, Introduction to Decision Analysis (second edition) (1999). Probabilistic. ISBN 0-9647938-3-0
  • Smith, J.Q., Decision Analysis: A Bayesian Approach (1988), Chapman and Hall. ISBN 0-412-27520-1
  • Virine, L. and Trumper M., ProjectThink: Why Good Managers Make Poor Project Choices (2013), Gower Pub Co. ISBN 978-1409454984
  • Virine, L. and Trumper M., Project Risk Analysis Made Ridiculously Simple (2017), World Scientific Publishing. ISBN 978-9814759373

External links edit

 
Wikimedia Commons has media related to Event chain methodology.
  • Event Chain Methodology in Details
  • Risk Management Guide for Information Technology Systems (July 2002)
  • Project Management Using Event Chain Methodology
  • Project Decisions: How to make better project decisions, analyze and manage project risks, and manage successful projects
  • Petri Nets for Project Management and Resource Leveling
  • NASA Risk Management Handbook (November 2011)

April 14, 2024
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Event chain methodology is a network analysis technique that is focused on identifying and managing events and relationship between them event chains that affect project schedules It is an uncertainty modeling schedule technique Event chain methodology is an extension of quantitative project risk analysis with Monte Carlo simulations It is the next advance beyond critical path method and critical chain project management 1 Event chain methodology tries to mitigate the effect of motivational and cognitive biases in estimating and scheduling 2 It improves accuracy of risk assessment and helps to generate more realistic risk adjusted project schedules 3 Event chain diagramContents 1 History 2 Principles 2 1 Moment of risk and state of activity 2 2 Event chains 2 3 Event chain diagrams 2 4 Monte Carlo simulation 2 5 Critical event chains 2 6 Project control with event and event chains 3 Phenomena 3 1 Repeated activities 3 2 Event chains and risk response 3 3 Resource allocation based on events 4 See also 5 References 6 Further reading 7 External linksHistory editEvent chain methodology is an extension of traditional Monte Carlo simulation of project schedules where uncertainties in task duration and costs are defined by statistical distribution 4 5 6 For example task duration can be defined by three point estimates low base and high The results of analysis is a risk adjusted project schedule crucial tasks and probabilities that project will be completed on time and on budget Defining uncertainties using statistical distribution provide accurate results if there is a reliable historical data about duration and cost of similar tasks in previous projects Another approach is to define uncertainties using risk events or risk drivers which can be assigned to different tasks or resources 7 8 Information about probabilities and impact of such events is easier to elicit which improves accuracy of analysis Risks can be recorded in the Risk register Event chain methodology was first proposed in the period of 2002 2004 9 It is fully or partially implemented in a number of software application 10 Event Chain Methodology is based on six principles and has a number of outcomes Principles editMoment of risk and state of activity edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message nbsp Event chain diagram for one activityActivities tasks are not a continuous uniform procedure Tasks are affected by external events which transform an activity from one state to another One of the important properties of an event is the moment when an event occurs during the course of an activity This moment when an event occurs in most cases is probabilistic and can be defined using statistical distribution The original state is called a ground state other states are called excited states For example if the team completes their job on activity they can move to other activities The notion of an activity s state is important because certain events can or cannot occur when activity is in certain state It means that the state of an activity is subscribed to the events Events can be local affecting particular tasks or resources or global affecting all tasks or resources Event chains edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message Events can be related to other events which will create event chains These event chains can significantly affect the course of the project For example requirement changes can cause an activity to be delayed To accelerate the activity the project manager allocates a resource from another activity which then leads to a missed deadline Eventually this can lead to the failure of the project It could be different relationship between events One event can trigger one or multiple events Events can be correlated with each other without one triggering another one In this case if one risk has occurred another one will occur and vice versa One event assigned in one activity can execute another activity or group of activities In many cases it the execution of risk response plans For example event structural defect is discovered can cause one or many activities Repair Events can cause other events to occur either immediately or with a delay The delay is a property of the event subscription The delay can be deterministic but in most cases it is probabilistic Also risks can be transferred from one activity to another To define event chains we need to identify a sender the event that initiates the chain of events The sender event can cause one or more events that effect multiple activities These are called receiver events In turn the receiver events can also act as sender events Event chain diagrams edit nbsp Example of event chain diagram local and global threats and opportunities with different probabilities and impactsEvent chain diagram is a visualization that shows the relationships between events and tasks and how the events affect each other 11 12 The simplest way to represent these chains is to depict them as arrows associated with certain tasks or time intervals on the Gantt chart Here are a few important rules Event chains diagrams present events as arrows on the Gantt charts Arrows pointing down are threats Arrows pointing up are opportunities Issues are shown as an arrow within a circle Color of the issue arrow is red dark Closed or transferred risks are shown using dashed lines Color of arrow is white Closed issue is shown in the circle with dashed border line Excited states are represented by elevating the associated section of the bar on the Gantt chart Colors represent the calculated impact of the risk Higher impacts are red or darker shade Low impacts are green or lighter shade The size of the arrow represents probability Event chains are shown as lines connecting arrows depicting events Event chains may trigger another activity In this case event chain line will be connected with the beginning of activity with optional arrow Event chains may trigger a group of activities In this case this group of activities will be surrounded by the box or frame and event chain line will be connected to the corner of the box or first activity within a frame By using event chain diagrams to visualize events and event chains the modeling and analysis of risks and uncertainties can be significantly simplified nbsp Example of event chain diagram with critical event chain and activity triggered by eventAnother tool that can be used to simplify the definition of events is a state table Columns in the state table represent events rows represent the states of an activity Information for each event in each state includes four properties of event subscription probability moment of event excited state and impact of the event Monte Carlo simulation edit Once events and event chains are defined quantitative analysis using Monte Carlo simulation can be performed to quantify the cumulative effect of the events 13 Probabilities and impacts of risks assigned to activities are used as input data for Monte Carlo simulation of the project schedule 14 In most projects it is necessary to supplement the event based variance with uncertainties as distributions related to duration start time cost and other parameters In Event chain methodology risk can not only affect schedule and cost but also other parameters such as safety security performance technology quality and other objectives In other words one event can belong to different categories 15 The result of the analysis would show risk exposure for different categories as well as integrated project risk score for all categories This integrated project risk score is calculated based on relative weights for each risk category Critical event chains edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message Monte Carlo simulation provides the capability through sensitivity analysis to identify single or chains of events These chains of events can be identified by analyzing the correlations between the main project parameters such as project duration or cost and the event chains These are called critical events or critical chains of events By identifying critical events or critical chains of events we can identify strategies to minimize their negative effects Avoid Transfer Mitigate or Accept Event and event chain ranking is performed for all risk categories schedule related and non schedule as part of one process Integrated risk probability impact and score can be calculated using weights for each risk category Project control with event and event chains edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message Monitoring the activity s progress ensures that updated information is used to perform the analysis During the course of the project the probability and time of the events can be recalculated based on actual data The main reason for performance tracking is forecasting an activity s duration and cost if an activity is partially completed and certain events are assigned to the activity Event chain methodology reduces the risk probability and impact automatically based on the percent of work completed Advanced analysis can be performed using a Bayesian approach It is possible to monitor the chance that a project will meet a specific deadline This chance is constantly updated as a result of the Monte Carlo analysis Critical events and event chains can be different at the various phases of the projectPhenomena editRepeated activities edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message nbsp Repeated ActivitySometimes events can cause the start of an activity that has already been completed This is a very common scenario for real life projects sometimes a previous activity must be repeated based on the results of a succeeding activity Event chain methodology simplifies modeling of these scenarios The original project schedule does not need to be updated all that is required is to define the event and assign it to an activity that points to the previous activity In addition a limit to the number of times an activity can be repeated must be defined Event chains and risk response edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message nbsp Mitigation planIf an event or event chain occurs during the course of a project it may require some risk response effort Risk response plans execution are triggered by events which occur if an activity is in an excited state Risk response events may attempt to transform the activity from the excited state to the ground state Response plans are an activity or group of activities small schedule that augment the project schedule if a certain event occurs The solution is to assign the response plan to an event or event chain The same response plan can be used for one or more events Resource allocation based on events edit This section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed June 2023 Learn how and when to remove this template message One potential event is the reassignment of a resource from one activity to another which can occur under certain conditions For example if an activity requires more resources to complete it within a fixed period this will trigger an event to reallocate the resource from another activity Reallocation of resources can also occur when activity duration reaches a certain deadline or the cost exceeds a certain value Events can be used to model different situations with resources e g temporary leave illness vacations etc See also editList of project management software List of project management topics Monte Carlo simulation Program Evaluation and Review Technique Project Project management Project planning Virtuous circle and vicious circle Work breakdown structureReferences edit Virine Lev Trumper Michael 2007 Project Decisions The Art and Science Berrett Koehler Publishers ISBN 978 1567262179 Robyn M Dawes and Bernard Corrigan Linear Models in Decision Making Psychological Bulletin 81 no 2 1974 93 106 Virine Lev 2013 Integrated Qualitative and Quantitative Risk Analysis of Project Portfolios In Proceedings of Enterprise Risk Management Symposium April 22 23 2013 Chicago IL Vose David 2008 Risk Analysis A Quantitative Guide 3rd ed Great Britain Wiley ISBN 978 0 470 51284 5 Hillson David 2012 Practical Risk Management The ATOM Methodology 2nd ed Berrett Koehler Publishers ISBN 978 1567263664 Hillson David 2009 Managing Risk in Projects Fundamentals of Project Management Routledge ISBN 978 0566088674 Hulett David 2009 Practical Schedule Risk Analysis Routledge ISBN 978 0566087905 Hulett David 2011 Integrated Cost Schedule Risk Analysis Routledge ISBN 978 0566091667 Virine Lev 2013 Integrated Qualitative and Quantitative Risk Analysis of Project Portfolios In Proceedings of 2013 Enterprise Risk Management Symposium April 22 24 Chicago IL Virine Lev and Trumper Michael 2015 Predicting the unpredictable how to analyze project risks using event chain methodology PM Network 29 9 28 29 Virine Lev amp McVean Jason 2004 Visual Modeling of Business Problems Workflow and Patterns In Proceedings of 2004 Winter Simulation Conference Washington DC Virine Lev amp Rapley Lisa 2003 Visualization of Probabilistic Business Models In Proceedings of 2003 Winter Simulation Conference New Orleans LA Avlijas Goran 2018 Examining the Value of Monte Carlo Simulation for Project Time Management Management Journal of Sustainable Business and Management Solutions in Emerging Economies 24 11 doi 10 7595 management fon 2018 0004 S2CID 67095960 Williams T Why Monte Carlo simulations of project networks can mislead Project Management Journal Vol 35 Issue 3 2004 53 61 Agarwal Ruchi and Virine Lev 2017 Monte Carlo Project Risk Analysis In Raydugin Y ed Handbook of Research on Leveraging Risk and Uncertainties for Effective Project Management IGI Global 1 editionFurther reading editArnaud Doucet Nando de Freitas and Neil Gordon Sequential Monte Carlo methods in Practice 2001 ISBN 0 387 95146 6 Hammond J S and Keeney R L and Raiffa H Smart Choices A Practical Guide to Making Better Decisions 1999 Harvard Business School Press D Kahneman and A Tversky ed 1982 Judgement under Uncertainty Heuristics and Biases Cambridge University Press ISBN 0 521 28414 7 Keeney R L Value focused thinking A Path to Creative Decisionmaking 1992 Harvard University Press ISBN 0 674 93197 1 Matheson David and Matheson Jim The Smart Organization Creating Value through Strategic R amp D 1998 Harvard Business School Press ISBN 0 87584 765 X Raiffa Howard Decision Analysis Introductory Readings on Choices Under Uncertainty 1997 McGraw Hill ISBN 0 07 052579 X Robert C P and G Casella Monte Carlo Statistical Methods second edition New York Springer Verlag 2004 ISBN 0 387 21239 6 Skinner David Introduction to Decision Analysis second edition 1999 Probabilistic ISBN 0 9647938 3 0 Smith J Q Decision Analysis A Bayesian Approach 1988 Chapman and Hall ISBN 0 412 27520 1 Virine L and Trumper M ProjectThink Why Good Managers Make Poor Project Choices 2013 Gower Pub Co ISBN 978 1409454984 Virine L and Trumper M Project Risk Analysis Made Ridiculously Simple 2017 World Scientific Publishing ISBN 978 9814759373External links edit nbsp Wikimedia Commons has media related to Event chain methodology Event Chain Methodology in Details Risk Management Guide for Information Technology Systems July 2002 Project Management Using Event Chain Methodology Project Decisions How to make better project decisions analyze and manage project risks and manage successful projects Petri Nets for Project Management and Resource Leveling NASA Risk Management Handbook November 2011 Retrieved from https en wikipedia org w index php title Event chain methodology amp oldid 1217003105, wikipedia, wiki, book, books, library,

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