In 1992 and
2003 I contributed to the research published on construction industry
productivity by two government inquiries. The first was the Royal Commission
into Productivity in the Building Industry in NSW (1991-1992), and the
second was the Royal Commission into the Building and Construction Industry
for the Commonwealth Government (2001-03). These posts have the relevant
parts of those publications, which are reviews of the then current data and
research.
The first
post is from a paper that covered the 1980s was originally published as Productivity
and the Australian Construction Industry by the Royal Commission into
Productivity in the Building Industry in NSW.
This second
post covers the 1990s and was an Appendix in a Discussion Paper from the Royal
Commission into the Building and Construction Industry for the Commonwealth
Government.
A third
paper in this series is a conference paper of mine from 1999 called
Recalculation of Australian Construction Productivity which looked at changes in
output per person in the special trades. The document can be downloaded from a Dropbox
file here.
*
A3.1 Measures
of productivity
Productivity
refers to the relationship between the quantity of goods and services produced
and the quantity of resources employed in producing those goods and
services. The economic definition of
productivity is the ratio of output over input, and in very general terms can
be described as the efficiency of production.
This definition focuses on the quantification of inputs and output.
Box A3.1 Measures
of productivity
Within the economic definition there are three productivity
measures used.
The commonest measure is labour productivity, which refers to the
output-to-labour ratio. This is
typically measured as output per person employed or per hour worked. Labour productivity can rise through
improvements or changes in the production process, technical knowledge,
managerial expertise, greater use of equipment or machinery, and so on.
Capital productivity is measured as output per unit of
capital. There are significant problems
involved in determining the amount of physical capital (plant and equipment,
buildings and structures) in use at any point in time because investment is
creating new assets and wear and tear is depreciating existing assets.
The wider concept that combines labour and capital productivity
measures is total factor productivity (TFP) or multi-factor productivity (MFP). This combines the labour and capital inputs
used in the production process by an industry and measures their respective
contributions to output.
In
Australia, the ABS provides indexes of output per hour worked and per person
employed by industry for the market sector.
The average increase in labour productivity in the market sector of the
Australian economy between 1991-92 and 1999-2000 was 2% a year. Over the same period labour productivity in
the construction industry increased by 1% a year, with wide variation in the
year-on-year rate. As can be seen over
the longer period 1986 to 2000 the construction industry managed to lift
productivity by only 3%. These indexes are very sensitive to differences in the
rate of change between output (measured as industry gross value added) and
input (hours worked). This difference
explains the drop in construction labour productivity in 2000-2001, where the
growth in hours worked was greater than growth in output. The public sector (administration, defence
and education) and property and business services have no estimates of output
independent of inputs and productivity therefore cannot be estimated for these
industries. The rest of the economy is known
as the market sector.
Table A3.1 Labour
productivity: indexes of gross product
per hour worked, by industry
1986
|
2000
|
2001
|
|
Agriculture,
forestry and fishing
|
66.9
|
100.0
|
99.7
|
Mining
|
44.2
|
100.0
|
107.6
|
Manufacturing
|
64.6
|
100.0
|
101.3
|
Electricity,
gas and water supply
|
35.9
|
100.0
|
98.0
|
Construction
|
96.6
|
100.0
|
85.4
|
Wholesale
trade
|
71.7
|
100.0
|
104.2
|
Retail trade
|
87.6
|
100.0
|
100.9
|
Accommodation,
cafes and restaurants
|
109.1
|
100.0
|
93.8
|
Transport
and storage
|
74.0
|
100.0
|
97.1
|
Communication
services
|
34.0
|
100.0
|
104.8
|
Finance and
insurance
|
57.0
|
100.0
|
102.0
|
Property and
business services
|
0.0
|
0.0
|
0.0
|
Government
administration and defence
|
0.0
|
0.0
|
0.0
|
Education
|
0.0
|
0.0
|
0.0
|
Health and
community services
|
83.3
|
100.0
|
96.5
|
Cultural and
recreational services
|
109.7
|
100.0
|
110.6
|
Personal and
other services
|
0.0
|
0.0
|
0.0
|
All
industries
|
80.2
|
100.0
|
100.1
|
Source: Australian
System of National Accounts, ABS, 2000-01, Cat No. 5204.0
While the
ABS does not produce industry level productivity indexes, the Productivity
Commission has produced estimates using ABS data on output, hours worked and
capital input by industry. In a
Productivity Commission research report on employment and productivity, Barnes
et al. (1999) found that MFP growth for construction between 1978-79 and
1995-96 was negative, at -0.2% a year, compared to market sector MFP growth of
1.2% a year. The Productivity Commission
released revised MFP estimates for the market sector of the economy in December
1999. The new release made significant
revisions to estimates for earlier years, due to a new ABS methodology for
estimating productivity based on an improved and more complex methodology for
deriving capital inputs. For the
construction industry the revision lifted productivity growth from negative to
positive, at 0.3% a year. This was still
well below the level of the market sector as a whole, at 1.0% a year growth.
Table A3.2 Growth in
multifactor productivity by industry sector, percent per year
Industry
|
1985-86 to
1998-99
|
Agriculture
|
2.7
|
Mining
|
1.5
|
Manufacturing
|
1.3
|
Electricity,
gas and water
|
3.0
|
Construction
|
0.3
|
Wholesale
trade
|
1.9
|
Retail trade
|
-0.1
|
Accommodation,
cafes and restaurants
|
-1.6
|
Transport
and storage
|
1.2
|
Communication
services
|
5.3
|
Finance and
insurance
|
1.8
|
Cultural and
recreational services
|
-2.1
|
Market
sector
|
1.0
|
Source: Productivity
Commission, 2000. Update of
Productivity Estimates: Industry Sector Productivity, 1998-99.
The Productivity
Commission also recalculated the capital-labour ratio in producing these
estimates, and found that construction had a ratio of 2.1 (two units of capital
to each worker) compared to a ratio of 3.5 for the market sector as a whole. Other industries with low capital intensity
(ratio under 2) were agriculture and transport.
The high capital intensity industries (ratio over 5) were mining,
manufacturing, utilities and retailing.
Recent data
at the industry level for the United
States is similar to Australia. Gullickson and Harper (1999) give estimates
of MFP by industry for the US. The table
shows the estimates of multi-factor productivity growth rates for the
industries in the US private business sector.
The two sets of multi-factor productivity estimates are based on
industry output series from the BEA and from the BLS. These trends differ by more than 0.5% for
only one industry (utilities). There are
negative multi-factor productivity trends for construction and for oil and gas.
Table A3.3 Estimates of US multi-factor
productivity trends in industries, percent per year.
Industry
|
Bureau of Labor
Statistics
|
Bureau of Economic Analysis
|
|
1963-77
|
1977-92
|
1977-92
|
|
Farms
|
0.8
|
1.8
|
1.7
|
Mining
|
-1.1
|
-1.2
|
-1.5
|
Construction
|
-0.7
|
-0.4
|
-0.9
|
Manufacturing
|
0.6
|
0.5
|
0.7
|
Transportation
|
1.9
|
0.4
|
0.2
|
Communications
|
2.4
|
0.4
|
0.9
|
Electric, Gas, and Sanitary Services
|
0.4
|
-0.3
|
-1.1
|
Wholesale Trade
|
2.6
|
2.1
|
1.0
|
Retail Trade
|
1.7
|
0.3
|
1.2
|
Finance, Insurance, Real Estate
|
0.7
|
-1.2
|
-1.3
|
Hotels and Other Lodging Places
|
1.5
|
-3.5
|
-0.1
|
Personal Services
|
2.3
|
0.7
|
0.0
|
Amusement, Recreation Services
|
-0.1
|
-0.3
|
1.7
|
Source:
Gullickson and Harper 1999: 56.
International Comparison of Productivity
Despite the
difficulties in the measurement of productivity in general, and for the
construction industry in particular, some studies have found that the level of
productivity in the Australian construction industry compares well with
overseas industries. Significantly, both
these studies are for periods (1990 and 1995-96) when residential building was
at a low point in the cycle. Because
residential building is the most labour intensive part of the industry, this
lifts the overall level of productivity by improving the output to hours worked
ratio. An OECD study by Pilat (1996)
found that Australian construction labour productivity (output per person based
on National Accounts data converted with 1990 purchasing power parities) is
above that of the US, Japan and all European nations, only Canada had higher
construction output per person.
Table A3.4 Index of construction output per person,
1990 (USA=100)
Country
|
Labour Productivity
|
United States
|
100.0
|
Japan
|
79.7
|
Germany
|
75.5
|
France
|
83.3
|
Italy
|
84.2
|
United Kingdom
|
62.0
|
Canada
|
148.2
|
Australia
|
103.0
|
Austria
|
99.4
|
Belgium
|
90.1
|
Denmark
|
65.8
|
Finland
|
94.4
|
Iceland
|
69.1
|
Luxembourg
|
61.6
|
Netherlands
|
69.9
|
Norway
|
68.5
|
Portugal
|
38.5
|
Spain
|
86.8
|
Sweden
|
75.2
|
Turkey
|
49.1
|
Source:
Pilat 1996: 21.
The McKinsey
study of Australian construction was also positive in its conclusions (Lewis et
al 1996). The study found the Australian
construction industry had made a number of positive changes since the 1980s,
including the development of more harmonious working relationships and the
introduction of multi-skilling. The
effect had been dramatic: average productivity is now close to the world’s
best, and employment performance has been just as impressive. Labour productivity, at 95% of best practice,
was only just behind the United States, and on a par with Germany’s. In addition, construction costs were low,
slightly less than those of the United States and France and far below those of
Germany, Sweden, and Japan. The main
drivers of Australia’s high productivity were intense competition in the
industry, which encouraged the widespread transfer of innovative production
processes, and improved industrial relations that increased labour flexibility
and minimized time lost through industrial disputes. Despite that, many more firms need to adopt
international best practices in construction techniques and processes. McKinsey found Australia owed its success to
greater demand for housing and infrastructure and lower prices. To raise productivity further and stimulate
growth, McKinsey recommended the industry maintain or increase the rate at
which it develops and transfers innovations, and continue to explore
opportunities to expand into overseas markets.
Table A3.5 Construction compared
internationally
Country
|
Productivity
|
Employment
|
United States
|
100
|
-0.1
|
Australia
|
95
|
-3.5
|
Germany
|
95
|
-9.9
|
France
|
85
|
-12.9
|
Japan
|
71
|
na
|
Sweden
|
67
|
-7.6
|
Note:
Productivity is value-added per hour worked, index US = 100. Employment is jobs created per thousand
working age population.
Source: Lewis et al 1996: 99.
McKinsey
concluded construction firms should seek collaborations with their large
customers, especially industrial firms, to reduce capital expenditure and
improve project economics in such fields as mining and new factory
development. Close working relationships
of this kind have the potential to boost both capital productivity and
profitability.
