IRJET- Quality Matrices of Project Schedule

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 05 Issue: 10 | Oct 2018 www.irjet.net p-ISSN: 2395-0072
© 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 612
Quality Matrices of Project Schedule
1Prabuddha Sarkar PMP, Project Controls Engineer in Fluor Daniel India Pvt. Ltd.
2Neeraj Bansal, Senior Project Controls Engineer in Fluor Daniel India Pvt. Ltd.
-------------------------------------------------------------------------***------------------------------------------------------------------------
Abstract - Schedule slippage & cost over-run of projects
prompted many Government agencies & MNCs to develop
their schedule quality matrices guidelines. This article
discusses about various quality matrices for a project
schedule developed through critical pathmethod(CPM). The
objective of this article is to appraise the project
management/ project controls community on quality
matrices for a CPM Schedule.
Key Words: Construction Project Management, Project
Scheduling, Project Schedule Quality, DCMA-14, Project
Planning, Project Controls, Construction Engineering.
1. INTRODUCTION
Overall project schedule developed through CPM (Critical
Path Method [12]) plays a very important role in controlling
the project for its entire duration. Many researchers have
published their work to identify most important success
criteria for a project. Sound schedule management remains
one of the most critical criteria to determine project’s
outcome[9, 10].
Hence, it is essential that for project management, a project
schedule guideline has to be developed & implemented. The
US Defense agencies have pioneered in developing such
schedule guidelines. In the USA, Government & Defense
Contracts runs in billions each year. US Government
Agencies & specially US Defense agencies have developed a
range of Schedule Managementprotocolsoverthetime,such
as Naval Air Systems Command Cost Department (NAVAIR)
11-Point Schedule assessment, Scheduling best practices
developed by Dept. of Homeland Security (USA), NASA’s
Schedule Management Handbook, USGAO (US Govt
Accountability Office) Schedule Assessment Guide. [1, 2,4,5,6,7]
The project schedule is an indicator or mechanism which
answers the what/ who/ when questions of Project
Management i.e. what needs to be done, which resources
must be utilized and when the project activity is due. A
project schedule is a living document that collects all the
activities/ work, which is in the scope, needed to deliver the
project on time. A schedule is a logically linked listing of a
project's milestones, activities ordeliverables,usuallywitha
specific start and finish dates. The Project schedule to also
includes information about resource allocation, budget,
activity duration, and linkages of dependencies and
scheduled events.
This article assumes that the reader is accustomed with
standard terminologies (Mentioned in Table-1) of CPM
Project Schedule, however detailed description of each can
be found in Practice Standard for Scheduling [13] published
by Project Management Institute, USA.
2. Quality Matrices
The quality points mentioned in Table-1 help us to
objectively evaluate the quality of the Project Schedule over
the life-span of the project.
Table -1
1. Schedule Logic* 9. Invalid Dates
2. Leads* 10. Resources
3. Lags* 11. Missed Tasks
4. Relationship Types (%
Ratio)*
12. Critical Path Test
5. Hard Constraints*
13. Critical Path Length
Index (CPLI)
6. High Float
14. Baseline Execution
Index (BEI)
7. Negative Float* 15. Current Execution Index
8. High Duration*
16. Total float Consumption
Index
A brief description of the criteria & their respective
thresholds are given below. The Schedule example pictures/
Figures are taken as a screen-shot from a Project Schedule
developed in Oracle Primavera P6.
2.1 Schedule Logic:
The OverallLogics(Predecessor/Successor&interlinking)in
a CPM schedule should be checked for Missing Logic, total
number of taskswhichdoesn’thavepredecessororsuccessor
should be kept to bare minimum, preferably only the start &
finish activity of the project may havemissingpredecessoror
successor.
Fig -1: Logic Checks
Prabuddha Sarkar1, Neeraj Bansal2

2.2 Leads:
Leads or Negative Lags between two tasks / activities means
successor activity will start before finishing predecessor
activity; such type of logical link is to be avoided. The reason
is that having leads distorts the Total Float in the CPM
schedule & cause resource conflict sometimes, which has to
be critically reviewed. Moreover negative time-line (i.e.
Leads) is not logical & should be discouraged.
Fig -2: Leads
2.3 Lags:
Although Leads are discouraged, Lags may be
accommodated with a limit,
Fig -3: Lags
2.4 Relationship Types (% Ratio):
Arguably among the four (4) relationship types, i.e. Finish to
Start (FS) (After the predecessor is finished, then the
successor will start), Start to Start (SS), Finish to Finish (FF)
& Start to Finish (SF), the FS relationship is themostlogical&
mostly used in the logical relationship of CPM schedule.
Preferably 90% of the tasks should have this FS relationship.
2.5 Hard Constraints:
In scheduling terminology, “Hard Constraints” are those
constraints, when applied to a activity (Start/ Finish)
becomes fixed on to that dateand relations to other tasksare
ignored. That means activity date (Start/ Finish) will not
move even if its predecessor pushed it out. Hard constraints
in CPMschedulesoverridelogicalrelationships;henceshould
be avoided. Following constraints are considered HARD
Constraints,
 Must-Finish-On (MFO)
 Must-Start-On (MSO)
 Start-No-Later-Than (SNLT)
 Finish-No-Later-Than (FNLT)
Preferably tasks with Hard Constraints should not be more
than 5% of total tasks. Hard Constraints to be used in few
cases i.e. to highlight contracted Mile-Stone Dates, which
cannot be moved.
2.6 High Float:
The number of incomplete (not finished) activities with a
Float greater than 44 Days (2 working months), to be less
than 5% of all incomplete activities.
High Float % = [(Total # of incompletetaskswithhighfloat)/
(Total # of incomplete tasks)*100]
Generally CPM paths with High floats evolve due to
constrained activities, which impede logical flow of the CPM
schedule, hence high floats to be avoided, and also high float
tasks should be investigated for optimization.
Fig -4: High Float
2.7 Negative Float:
In general, presence of Negative Float means, theactual (real
life) dates are not to achieve the planned Milestones/ Finish
dates. Typically Negative float is generated in a schedule
when it is artificially constrained or accelerated (using Hard
Constraints). There should not be any incomplete activity
with negative float, under normal circumstances.
2.8 High Duration:
As a rule of thumb all the activities should be broken down
into further smaller, more manageableactivities,thiswaythe
CPM schedule become more controllable and gives better
insight on the schedule’s cost & schedule performance.
Ideally, there could be only 5% of the activities which have
duration more than 44 days (2 working Months).
2.9 Invalid Dates:
As we know, the entire CPM schedule has a Data Date or
Status Date (Cut-off date on which CPM schedule has been
updated). An invalid dates means;
a)Any task/ activity could nothaveaForecastDate,whichis
prior to the status date,
b)Any task/ activity could not have an Actual (start or
finish) Date, which is after (in future) the Status Date.
There should not be any invalid dates in the CPM schedule.

Fig -5: Invalid Dates
2.10 Resources:
In a practical Schedule, all the incomplete tasks/ activities
should have resource or cost assigned, although it is not a
mandatory criterion, however rule of thumb is that the more
resourced & cost loaded the schedule, is more realistic.
Fig -6: Missing Resources in Schedule
2.11 Missed Tasks:
This metric is about how well the schedule is performing as
on the Data/ Status Date. Missed tasks are those tasks which
overshot their Baseline (BL) Finish dates, either they have
completed after BL-Finish or their Forecasted (ongoing
activities/ tasks) Finish date is after the BL-Finish. In other
words these tasks have positive FinishVariance(EarlyFinish
minus Baseline Finish).
Calculating this metric islittle tricky. To calculate, weneedto
divide the number of missed tasks, by number of Tasks with
BL-Finish dates on or before Status/ Data date. Ideally,
Missed % should be less than 5%.
Missed % = (# of tasks with actual/forecast finish date past
baseline date)/ (#of tasks with baseline finish dates on or
before status date) * 100.
2.12 Critical Path Test:
The Critical Path test checkstheintegrityoftheCPMschedule
logics. When a complete CPM Schedule prepared, the
scheduler introducesa large(Forexample400days) slip/lag
in the Schedule, if the CPM shows that Finish milestone is
impacted to similar amount of delays, then the schedule has
passed the test.
In case the Finish Milestone is not affected by similaramount
of delay (approx. 400 days), that means there are some
“Broken Logic” in the CPM schedule.
2.13 Critical Path Length Index (CPLI):
CPLI is a performance index for the CPM Schedule. A CPLI of
1.0 means the Project is just on the schedule, whereas a CPLI
less than 1.0 means the project execution is inefficient & the
project is going to end late.
Critical Path Length Index (CPLI) = (CPL+TF)/ CPL
Here, TF is Total Float, The Total Float (TF) is the variance
(days) between Forecasted & Baseline Project Finish date.
CPL is Critical Path Length of the project; basically it is
number of working days left from status date to the Project
Finish. Sometimes activities on the critical path can have
positive float and can be delayed without extending the
overall project finish date, due to the use of advanced
scheduling features (i.e. multiple calendars, etc.)[11].
It can be measured in a unique way, in the CPM Schedule’s
native file (i.e. .xer in Oracle Primavera P6, .mpp in Microsoft
Project). One has to introduce a dummy activity/ task, with
start date on the Status date, then by hit-and-trial one has to
change the task’s duration so that task’s end date should
match with the current finish date of the project (as per the
CPM, before introducing new activity). The duration is the
Critical Path Length.
Normally CPLI more than 0.95 is okay, less than 0.95 raises a
flag & need to be investigated.
2.14 Baseline Execution Index
Baseline Execution Index (BEI), signifies how efficiently the
project tasks are being completed on time, or it is a measure
of the throughput of the schedule execution.
BEI = (Total # of Tasks Complete)/ (Total # of Tasks
Completed Before Now + Total # of Tasks Missing Baseline
Finish Date).
So, if more tasks have been completed than Baseline-Plan(as
of Status date) then BEI will be more than 1.0, which meansa
higher task throughput than baseline Plan.
If BEI is less than 1.0, means task throughput is less than the
Baseline planned.
A BEI score less than 0.95 is a flag & should be investigated.
2.15 Current Execution Index (CEI):
This Index measures with how much accuracy the project
finish milestones’ are forecasted & how accurately project is
meeting those milestones/ finish dates. By measuring this
metric Project managers’ can emphasis the accuracy of the
forecasted schedule.

All the schedules are updated on a fixed timeframe, mostly
weekly/ bi-weekly & monthly. This fixed time frame is
termed as window.
CEI = (# of forecasted Tasks, actually finished in that
window) / (# of Tasks forecasted to finish in that defined
window).
Note that tasks in this formula should exclude LOE &
Summary tasks.
Using CEI ensures ownership & accountability which are
indispensable for project’s success. It is preferable to have
CEI > 0.8.
2.16 Total Float Consumption Index (TFCI):
TFCI predicts the long term scenario, if project continue to
execute in the current pace,whatwillhappenintheEnd.TFCI
identifies average rate of “Float” consumption of the project
to the remaining schedule, then forecast finish date of the
project at the current pace of work.
TFCI indicates the achievability of final completion date.
TFCI = (Project Actual Duration + Critical Path Total Float) /
Project actual duration
Note that if CPTF (Critical Path Total Float), are not being
calculated to the BL-Finish date then variance between
Forecast Finish & BL-Finish should be considered CPTF.
3. ADDITIONAL SCHEDULE CHECKS
Additional schedule checksmaybeperformedforissuessuch
as,
 Avoid allotting resource on a summary task (Most cases
not appropriate).
 Any relationship among summary tasks should not be
allowed.
 Schedulers also need to avoidunnecessarylogic used ina
schedule.
All of these quality matrices checks can be performed
manually, with use of filters/ grouping functions in the
schedulingtools(i.e.OraclePrimaveraP6/MicrosoftProject).
There are also dedicated software products commercially
available in the market (i.e. Deltek Acumen Fuse)tocalculate
these matrices. All of these quality matrices are important
contributor in the Project’s success.
4. CONCLUSIONS & RECOMMENDATIONS
Quality metrics of a CPM schedule identify certain
measurable quality parameters.
Schedule’s health checks should bea regularprocess,may be
monthly and any skewed outcome, should be investigated.
Root-cause analysis may be performed to address these
issues. All the mentioned Schedule Matrices & their
respective thresholds may be difficult to achieve at one go.
The responsible scheduler may select importantcriteria and
their thresholds as per complexity & applicability in that
Project.
We have identified around seven important criteria which
could be implemented as “Starred (*)” in Table-1.
The Quality matrices establish, a “Technical Structure” for
the schedule and ensure sound Practices of scheduling have
been followed. Such schedule helps project management in
effective execution.
ACKNOWLEDGEMENT
The authors would like to acknowledge the generous
support & guidance of Mr. Narasimham V Suri & Mrs.
Kanchan Narang.
The authors would like to thank Mr. Mukesh Gupta and Mr.
Pramod Gupta, the reviewers of this paper for their helpful
comments and suggestions to improve this paper.
We express our appreciation to Mr. Yash Kant Varshney, Mr
Wesley Brubaker & Mr. Pankaj Pande for sharing their
thoughts and wisdom with us.
REFERENCES
[1] Earned Value Management System (EVMS) Program
Analysis Pamphlet (PAP) DCMA-EA PAM 200.1 (
October 2012 ) by Defense Contractor Management
Agency, US Army.
[2] Schedule Assessment Guide By US Government
Accountability Office
[3] PMBOK® Guide and Standards. by PMI, USA
[4] NASA/SP-2010-3403, “NASA Schedule Management
Handbook,” March 2011.
[5] SCHEDULE QUALITY ASSURANCE by Texas Dept. of
Transportation
[6] Project Scheduling with Primavera , Training Manual by
State of California Department of Transportation
[7] Planning & Scheduling Excellence Guide by National
Defense Industrial Association (NDIA), USA
[8] DCMA 14-Point Schedule Assessment by Ron Winter,
PSP
[9] Analysing DelayFactorsInIndianAffectingConstruction
Projects – by Veera Vijay. Divi & Sundara Kumar. P
[10] Causes and Effects of Delays in Indian Construction
Projects – by Dinesh Kumar R
[11] Construction Delays by Theodore Trauner

[12] James E. Kelley, Jr, Morgan R. Walker, Proceeding, IRE-
AIEE-ACM '59 (Eastern) Papers presented at the
December 1-3, 1959, eastern joint IRE-AIEE-ACM
computer conference, Pages 160-173
[13] Practice Standard for Scheduling – Second Edition
(2011), PMI, USA.

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