There are a few obvious ways to
categorise projects. The industry a project lies within is one, and by function
is another, although categories such as these often overlap (e.g. shipbuilding
or information technology). Distinctions are made using a variety of
characteristics between hard and soft projects, major and minor projects,
public and private sector projects, routine and transformative projects, and so
on. While there is no agreed definitive list, these characteristics typically
include factors such as size or cost, familiarity and complexity, scheduled
time, outcome or product, parent organisation type or status, and the contracts
and delivery methods used. There are many factors that can be taken into
account, and categories help resolve this diversity by creating frameworks to structure
a lot of loosely connected data.
The way we see and understand an
industry typically starts with the data we get from the national accounts and
other collections done by national statistics agencies. For building and construction, government
statistics are typically collected by sector and then divided into building or
structure type, shown in a generalised form in Table 1. Projects within a
defined market are then grouped together to establish sector size and
importance, detached housing for example, or commercial developments. Because
the data on industry activity and output is presented in these classifications,
analysis of trends and forecasts of construction work are also usually found in
this format. (Informal building is included here because it is an important part
of the industry, but this sector is not included in industry statistics.)
Table 1. Building and construction
Sector
|
Type
|
Residential building
|
Detached housing, medium and high
density dwellings, alterations and additions etc.
|
Non-residential building
|
Private - Retail, commercial,
industrial, hotels etc.
|
Public and social - Education,
health, community etc.
|
|
Engineering construction
|
Bridges, ports, rail, electricity,
roads, water and sewerage, dams, telecommunications etc.
|
Informal building
|
Owner builders, DIY, cooperatives,
communes, etc. Picked up in sales of equipment, materials and components.
|
Common typologies used to categorise building and construction projects are based on the procurement system
or contract used, financing method, size, complexity or some other characteristic
of the project. Examples are Masterman’s exhaustive set of lists of
construction project and client characteristics, which can be used to
classify projects, and Flygberg et al., who argue there is a separate and
distinct set of megaprojects and the characteristics of these projects (apart
from size) make them a focus of research in their own right. Many project
management researchers identify “complexity dimensions” and/or levels of risk
for projects to create frameworks for classification. There is a very large
literature on this, and with the diversity of projects it is not surprising
there is a wide range of views on categories and typology. However, this is not
just an abstract question. The way we understand the industry is framed by the
categories we use to structure that understanding.
The question being asked here is
whether it might be possible to develop a classification system for building
and construction projects that is independent of the characteristics and factors
identified above, such as size or building type. A different set of categories
might illuminate the industry in a different sort of way. To do this requires
identifying a number of characteristics that are common to projects in general,
and construction projects in particular. There is no shortage of candidates: organization forms,
technology, environment, information density, decision making and technical or
organisational complexity could all be considered.
When looking for common
characteristics across projects there are some obvious places to start. The
first would be the main project management (PM) systems, such as PMBOK and
PRINCE. These detail PM tasks, planning methods, and control tools and
techniques. Other systems like Morris and Pinto’s APMBOK include topics such
as technology management, economics and finance, people skills, and the social
and environmental context. These PM systems are generally organised around the
competencies needed to deliver projects, but emphasise different competencies.
They help in identifying common project characteristics by eliminating the need
to include PM methods
and techniques in the search, partly because they are so comprehensively covered by
these frameworks but also because their application varies greatly across
different types of project.
The stages a project goes through is another
candidate. All projects have stages, and while there are many variations on the
details, there is broad agreement on the sequence of initiation, development,
execution and finalisation. Again, because this has been already
comprehensively covered it does not offer much opportunity for a new approach.
Stages also create a sequential structure, which is not what is being sought
here. This means we have to move the search for common characteristics to a
higher level of generality.
In his well-known Handbook of Project Management (now in
its fourth edition) Rodney Turner states “There is no agreement about how to
classify projects, but I have found it useful to classify them against three
parameters”:
- By the position of the project in the life cycle of the product produced by the facility, or in the strategic development of the parent organisation;
- By the type of industry or technology of the project or the parent organisation;
- By the size of the project.
Within each of Turner’s three
categories there are sub-categories. The two life cycle categories are new
product development and technological development. In industry sector or
technology, the three categories are organisational change, engineering and
information technology and by size, projects can be small to medium, large or
major. This is a good representative example of the functional approach to
project classification, where the type of project is primarily defined by its
role. This functional approach is often found in construction management books,
which tend to follow the format of construction statistics with their division
of the industry into sectors and project categories based on their physical
structures.
In a later typology Turner used the
level of difference between projects to get four project types ranging from the
familiar to the completely unknown. These two approaches are complementary, in
that they expand the detail of the classification system
- Runners: These are very familiar projects, done repeatedly. They almost count as batch processing. Routine processes can be used;
- Repeaters: The organisation has done projects quite similar to these in the past. The majority of elements of the project are very similar to things done in the past and there is knowledge in the organisation about how they should be managed;
- Strangers: The organisation has never done a project like this before, but there are many familiar elements;
- Aliens: The organisation has never done anything like this before. These projects are high risk.
Using familiarity as a key point of
distinction between projects seems like a useful insight, although it then
leads to questions about where a project lies on the known/unknown spectrum,
and why. One approach that tackled these issues is Shenhar and Dvir’s novelty,
technology, complexity, and pace (NTCP) “diamond” framework. This is an
interesting system of project classification, intended mainly for technology
projects. It creates cobweb diagrams of a project based on four dimensions,
defined as:
- Novelty: How intensely new are crucial aspects of the project?
- Technology: Where does the project exist on the scale from low-tech to super-high-tech?
- Complexity: How complicated are the product, the process and the project, on a scale from a simple component to an array that combines many components.
- Pace: How urgent is the work? Is the timing normal, fast, time-critical or blitz?
Project
profiles are determined by the level of each of the four dimensions, and the
combination of the four levels on each dimension gives the set of 16 characteristics
a project can be mapped against. A project has a specific profile, with associated
specific planning and execution needs. This is a flexible approach that
identifies project characteristics, and Shenhar and Dvir argue knowing these
characteristics should lead to better project management and outcomes, and they
link specific management decisions (such as design freeze point, PM structure
or the timing of reviews) to each of the four dimensions. This line of argument,
that understanding project characteristics leads to better management decisions,
underpins many project typology and classification systems.
Using
the NTCP framework gives a visual representation of a project, and can easily
be applied to building and construction. Many building projects would fit into
a small central diamond of low-tech, derivative projects with regular timing
that are component based. An engineering project like a refinery would be
represented by a larger, still symmetrical, diamond of a medium-tech, platform
with competitive timing and on-site assembly. Disaster recovery projects need
to be fast and are often low-tech, logistics centres and fabrication plants are
high-tech and so on. While helpful this framework does not, in itself, provide any great new insight
into construction projects.
To adapt all these ideas about project typologies,
and the many others in the literature not mentioned here, to the construction
industry is not straightforward. If a characteristics approach is taken to classifying projects, the question then moves to become one of definition: what are the specific
characteristics, how are they identified, and where are the boundaries between
them? Most importantly, what is the purpose of a typology or classification
system?
Flyvbjerg, B., Bruzelius, N. and
Rothengatter, W. 2003. Megaprojects and Risk:
An Anatomy of Ambition, Cambridge University Press, Cambridge.
Masterman, J.W.E. 2002. Introduction to Building Procurement Systems, 2nd ed., Spon, London.
Masterman, J.W.E. 2002. Introduction to Building Procurement Systems, 2nd ed., Spon, London.
Turner, J.R. 2014. The
Handbook of Project-Based Management, 4th ed., McGraw-Hill, New
York.
Shenhar, A. and Dvir, D. 2005. Reinventing Project Management –The Diamond
Approach to Successful Growth and Innovation, Harvard Business
School Press, Boston, MA.