Does the United States have a productivity slowdown or a measurement problem?
Byrne, David M. ; Fernald, John G. ; Reinsdorf, Marshall B. 等
V.B. Globalization
Standard techniques for constructing price indexes do not capture
the change in the average price paid by the buyers of a product when
they alter their purchasing patterns to buy from a different seller.
Similarly, import price deflators in the NIPA do not capture changes in
the price paid by buyers when they switch from a domestic source to an
offshore producer. As a result, when sourcing moves offshore or to a
different import-supplying country, real imports are understated and
real output is overstated. (31)
This bias was particularly significant in the late 1990s and early
2000s, when the location of many kinds of manufacturing was shifting
rapidly from the United States and other countries with high labor costs
to emerging market economies. One impetus for this was China's 2001
accession to the World Trade Organization, which coincided with the
start of a large shift in the sourcing for many manufactured goods used
in the United States to China. Another was a multilateral free trade
agreement that reduced tariffs for IT products to zero for an interval
of four years ending in 2000, which accelerated international sourcing
changes for IT products (Feenstra and others 2013).
Reinsdorf and Robert Yuskavage (forthcoming) use two approaches to
estimate the sourcing bias for imported consumer goods in the 1997-2007
period, and they find a bias in the range of 0.8 to 1 percent a year for
durable goods, including computers, and about 0.6 percent a year for
imported apparel and footwear; after 2007, the effect is small. However,
even if we assume that the bias estimate of 1 percent a year for durable
goods can be generalized to similar kinds of imported capital goods and
that the bias in the apparel index can be generalized to all textile
products, the upward bias in business TFP is only 0.1 percent a year
because the affected imports have only a small weight in GDP. This
globalization adjustment shows up as a negative contribution of 10 bp
from 1995 to 2004 for the "other" category in figure 1.
Another aspect of globalization made possible by reduced
communications costs is international trade in services over a wire. The
number of American jobs that could potentially be offshored to a country
with lower wages is large (Blinder 2009), and the offshoring of services
could lead to the same sort of upward bias in measures of productivity
that is caused by the offshoring of goods. Thus far, however, the
effects have been modest; the BEA's input/output accounts show that
the imports of business-process services such as professional,
scientific, and technical services, and computer systems services--rose
from about 2 percent of total intermediate uses of these services in
1997-98 to about 5 percent in 2010-14.
V.C. The "Sharing" Economy
Nominal GDP includes transactions from the sharing economy, such as
car rides via Uber and Lyft. (32) Nevertheless, it is unlikely that the
deflator used to compare the new services to previously existing ones
correctly measures the decline in the quality-adjusted price experienced
by many consumers. Thus, there is probably some (at this point very,
very small, but likely growing) downward bias in the growth rate of real
GDP.
It would be useful to have official statistics on the nominal
output of the various types of services included in the sharing economy.
Research indexes of price changes could then be developed to try to
calibrate the size of the bias.
VI. Conclusions
The "productivity paradox 2.0" remains alive: Despite
ongoing IT-related innovation, aggregate U.S. productivity growth slowed
markedly after about 2004. To investigate this paradox, we propose
several adjustments to IT-related hardware, software, and services. The
good news is that these adjustments would make recent growth in GDP and
investment look modestly better than recorded. The bad news is that they
would make the paradox even worse--the slowdown in labor productivity is
even larger after our durable goods adjustments, while the slowdown in
TFP is not much affected. The reason is that mismeasurement was
substantial in the 1995-2004 period, as well as more recently, and
rising import penetration for computers and communications equipment
means that domestic production (which matters for GDP) has fallen over
time.
Moreover, the slowdown was broad-based, which suggests that ongoing
innovation in IT is not substantially spilling over into other areas.
Other measurement challenges--such as digital services, globalization,
and fracking--go in the right direction but are small.
Other evidence also suggests that true underlying growth is
relatively modest. First, the U.S. productivity slowdown has been
mirrored in many parts of the world (Eichengreen, Park, and Shin 2015;
Cette, Femald, and Mojon 2016; Askenazy and others 2016). This suggests
that underlying macroeconomic factors may be driving the slow pace of
growth, given the varied sources and methods used across national
statistical systems. Chad Syverson (2016) finds that the slowdown across
countries is not correlated with IT production or use, again suggesting
that the problem is not related to the mismeasurement of IT goods or
services. Second, the decline in economic dynamism--both in the form of
fewer start-ups and in the slower reallocation of labor resources in
response to productivity shocks supports the idea that
productivity-enhancing innovations are diffusing throughout the economy
more slowly (Decker and others 2016); also, the subdued pace of
investment has slowed the adoption of new technology embodied in
capital. And third, Michael Mandel (2016) also finds little evidence of
widespread rapid innovation in an analysis of labor market metrics such
as occupational employment and help-wanted ads, although there are
tremendous occupational changes in some narrow segments ot the economy,
such as IT and the extraction of oil and natural gas.
If not mismeasurement, why did productivity growth slow? The
slowdown predated the Great Recession, which suggests that the event was
not the story--or, at least, not the whole story. Given that the 1970s
and 1980s had slow growth similar to the period after 2004, the
fast-growth 1995-2004 period looks like the anomaly. With the emergence
of the Internet, the reorganization of distribution sectors, and IT
investments beginning to pay off, many things came together in a short
period. With hindsight, this looks like a one-time upward shift in the
level of productivity rather than a permanent increase in its growth
rate. Looking forward, we could get another wave of the IT revolution.
Indeed, it is difficult to say with certainty what may yet come from
cloud computing, the Internet of things, and the radical increase in
mobility from smartphones. However, we have not yet seen those gains.
Changes in overall welfare are somewhat harder to assess.
Transformative gains related to mobile technologies and the Internet
clearly raise welfare. Most of these gains properly belong outside the
purview of market sector GDP--and proposals to incorporate them into GDP
raise concerns. Still, these innovations are valued by households. That
said, the available estimates of the welfare gains (based on the value
of leisure time) suggest that "free" digital services add the
equivalent of perhaps 0.3 percent of GDP a year to well-being; that is
small relative to the roughly 1.75 percent slowdown in labor
productivity growth in the business sector from 2004 to 2014.
Nevertheless, much is unknown. Matthew Shapiro and David Wilcox
(1996) described the area of the quality adjustment of price indexes as
house-to-house combat in national accounting. The analysis must be done
product by product, and statistical agencies are usually playing
catchup. (33) Digital services and the ensuing new modes of delivery of
other types of services are particularly challenging. For example,
research on the quality-adjusted price indexes associated with changes
in the organization of production caused by the digital economy, such as
the substitution of Uber and Lyft for traditional taxi services, would
be helpful. Satellite accounts could also help to shed light on gains
from digital services and shifting of production outside the market
boundary by presenting measures of economic activity that extend beyond
the market.
Finally, we conclude by touching on the implications for
policymakers. Slow productivity growth, if it persists, implies slow
future potential growth. The benefits in the nonmarket sector can offset
this somewhat vis-a-vis well-being, but they do not help with taxes or
the budget.
ACKNOWLEDGMENTS We thank Martin Baily, Erik Brynjolfsson, Carol
Corrado, Erwin Diewert, Jean Flemming, Robert Gordon, Peter Klenow,
James Stock, and Hal Varian for helpful comments and conversations. We
thank Travis Adams, Genevieve Denoeux, and Arthi Rabbane for excellent
research assistance. The title of this paper refers to a phrase in a
Wall Street Journal article by Timothy Aeppel (2015). The views
expressed in this paper are those of the authors and should not be
attributed to the International Monetary Fund or its managers or
executive directors, or to the Federal Reserve Bank of San Francisco,
the Federal Reserve System's Board of Governors, or the Federal
Reserve System.
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Comments and Discussion
COMMENT BY MARTIN NEIL BAILY This is a terrific paper that changed
my views on the slowdown in productivity growth. I had thought that a
significant fraction of the post-2004 growth slowdown could be explained
by measurement errors of two types: first, underestimation of the pace
of productivity in the computer and semiconductor industry; and second,
the fact that the National Income and Product Accounts do not include
the contribution of "free stuff" like Google and Facebook to
final output because they are paid for by advertising and are,
therefore, considered intermediate production. David Byrne, John
Fernald, and Marshall Reinsdorf show persuasively that neither type of
measurement error is significant enough to change our estimates of the
slowing of growth in about 2004. The authors document, along with Chad
Syverson (2016), that the productivity growth slowdown is very
large--output would be larger by about $3 trillion today if there had
been no slowdown. The errors of measurement would need to be very large
indeed to explain much of this loss of output, and the authors show that
this is not the case.
It is worth backing up a little and pointing out the strange,
paradoxical economic times that form the backdrop to this paper.
Productivity growth has been very slow since about 2004, and the
slowdown appears to be getting worse, with output per hour in the
nonfarm business sector in 2015 only 2.6 percent higher than its 2010
value, according to the Bureau of Labor Statistics (BLS). This is bad
news for living standards and economic growth. At the same time, other
signs seem to point to rapid technological change. For example, in a
survey released in June 2015 of the Fortune 500 CEOs, they named their
greatest challenges; the top challenge, listed by 70 percent of the
CEOs, was rapid technological change. And a front-page article in the
May 3, 2016, Financial Times said, "Surging investment in
artificial intelligence is giving the United States an early advantage
in the global race to dominate a new era of robotics, according to
investors and experts in an industry set to become one of the most
strategically important in the coming decades" (Waters and Inagaki
2016). Erik Brynjolfsson and Andrew McAfee (2014) are leading experts on
technology, and their 2014 book The Second Machine Age has been an
important and influential guide to changing technology. In chapter 2
they write, "Most of the innovations described in this chapter have
occurred in just the past few years. They've taken place in areas
where ... the best thinking often led to the conclusion that it
wouldn't speed up. But then digital progress became sudden after
being gradual for so long" (Brynjolfsson and McAfee 2014, p. 37).
In short, they suggest that technological change has actually speeded
up. Mismeasurement had offered one way to resolve the paradox of slow
growth and rapid technological change, and Byrne, Fernald, and Reinsdorf
have punctured this balloon.
Although I agree with the bottom fine of this paper, there are some
points of disagreement or places where I would have put a different
emphasis. Most important, a casual reader of their paper might believe
that productivity growth is being well measured overall, but that is not
the case. In important segments of the economy, there is no serious
effort to capture the impact of technological change on the quality of
output. Most notable is health care, where advances in screening and
diagnostics, surgical procedures, and medical devices are constantly
being introduced. Thanks to the research by Ernst Berndt of the
Massachusetts Institute of Technology and others, (1) there has been an
effort to capture the benefits of new drugs, but improvements in the
quality of hospital care are being missed. The authors are aware of this
problem, but their tight focus on the post-2004 slowdown means they do
not give it much attention.
Unlike health care, the high-tech industry has seen efforts made to
capture quality change in output, and the authors do an admirable job of
exploring the various price deflators covering this industry. They make
a good case that errors of measurement are not likely to explain much of
the slowdown; but as they note, much uncertainty remains. The reader is
left wishing that the BLS would do a systematic review of its price
index methodology. One of the big changes in recent years has been to
make computers and tablets much lighter and more user-friendly, and I do
not think this quality change is being captured.
The authors point out that much of the manufacturing of high-tech
equipment has moved offshore, so this sector is providing a smaller
boost to U.S. productivity. They also mention the outlet substitution
bias that has likely occurred as component production has moved
offshore. These points are certainly correct, but I wonder if changes in
industry structure mean that some U.S. productivity growth is being
missed. Much of the design work for computer chips, iPhones, and the
like is still being done in the United States, so the quality change
that accounts for most of the productivity increase in high-tech
industries is still attributable to economic activity located in the
United States and not in the countries where the products are
manufactured. One reason for this is that the United States'
marginal corporate tax rate is higher than those of other countries, so
multinational companies minimize the U.S. content of products made and
sold internationally. Even without tax distortions, in a world where
supply chains are global, it is intrinsically very difficult to
correctly account for productivity by country. This measurement problem
is not huge, but it probably has been getting worse over time.
When I ask both economists and noneconomists whether they think
that the free stuff on their phones or computers is significant enough
to shift the needle of productivity growth, I get bipolar answers. Some
people believe that all the new stuff is fantastic and is changing their
lives, while others dismiss it as trivial. The answers to my
nonscientific personal survey are somewhat age-related; older people are
usually less enthusiastic than younger people, but not always so. Some
older people and some with disabilities find that their lives have been
greatly enhanced. Byrne, Fernald, and Reinsdorf are convincing in
showing that the magnitude of uncounted free services is just not large
enough to make much of a dent in the $3 trillion hole in productivity.
They evaluate free services using a time-use framework, which is an
entirely reasonable decision given that the literature has used this
framework. But I do not find this approach to be all that compelling.
All consumption involves time, but we do not try to capture this when we
measure productivity. Automobiles, for example, require time to drive,
but the contribution of automobile production to productivity depends on
quality-adjusted output in relation to inputs. There is no need to
estimate the time spent driving.
The tricky part with Google and other similar services, as the
authors note, is that consumers do not pay for them directly, but only
through advertising. Such free services did not start with Google;
television used to be entirely paid for by advertising, and much of it
still is. Like Google, television was an intermediate goods industry.
Given the value that most consumers place on watching TV, the exclusion
of this service from final output in earlier periods meant that
productivity growth was understated. Other countries chose to pay for
television through license fees, and their TV-related industries were
then counted in final output and presumably contributed to measured
productivity growth.
[FIGURE 1 OMITTED]
If we lived in a world where the budgets of the statistical
agencies were greatly expanded, I would urge them to create satellite
accounts to estimate the value of free services. If time-use analysis
provided the best approach, then I would be a convert. Another
alternative would be to use conjoint analyses from survey data, the
approach used by market researchers to assess how consumers value
different products and product attributes.
The authors have calculated productivity growth by industry, and
they use these results in their paper, but there are some additional
lessons worth drawing from these data, and I turn now to describe them.
My figure 1 shows the Domar-weighted contribution of each of the major
private sector industries to multifactor productivity (MFP) growth in
the aggregate over the entire period from 1987 to 2013 for which
consistent data are available from the BLS. The first striking fact is
that manufacturing contributes about 40 percent of aggregate MFP growth.
This is despite the fact that manufacturing is only about 10 percent of
employment. From a productivity point of view, manufacturing still
matters. The second striking fact is that two large sectors of the
economy, construction and services, had zero or negative MFP growth
contributions from 1987 to 2013. This raises a red flag that measurement
problems may actually be quite important for estimated growth over the
whole period. Construction productivity has been a mystery for a very
long time. Nonresidential output is very hard to price and measure
accurately. On the residential side, I participated in a number of
cross-country comparisons of residential productivity in the 1990s with
the McKinsey Global Institute, and we never found a country where
productivity was higher than in the United States. (2) That is not
impossible to square with U.S. productivity that declines over time, but
it is odd.
The subindustries within services that drag down the total are
education and health care, and I discussed health care above. Having no
productivity growth in education is perhaps not surprising, given how
little the format of education has changed. The content of what is being
learned has changed a lot, however, especially in higher education. And
the industry structure and the way teaching takes place both seem poised
to change, as new technology-related tools are introduced and
competition increases. It would be a step forward if measurement methods
for this industry were able to keep up with changing educational
methods.
My next two figures both illustrate that the industries whose
productivity growth increased after 1995 were generally the industries
that showed slower growth after 2004. My figure 2 shows that the pattern
holds for the major industry sectors, and my figure 3 shows the same
result when all of BLS's subindustries are included. One
interpretation of this pattern is that a broad productivity opportunity
opened up, creating the scope for a rapid productivity increase. Some
industries had business models and market conditions that were conducive
to taking advantage of this opportunity, but other industries were less
well suited and continued along the old path. After 10 years or so, the
impact of the innovative surge was over, and the rapid growers fell back
to their prior pattern. The obvious candidate for the productivity
opportunity was the rapid improvement and dissemination of information
technology. There may also have been other contributory factors, such as
a willingness to take risks, intense competition, and strong aggregate
demand growth. (3)
[FIGURE 2 OMITTED]
The authors of this paper took on a very hard task, asking whether
measurement error can explain the 2004 slowdown in productivity growth,
and they came up with a convincing answer: It cannot. In his impressive
review of U.S. economic history, Robert Gordon (2016) concludes that the
information technology revolution was the last in a series of
productivity waves dating back to the Industrial Revolution. The authors
of this paper are less pessimistic, and I agree with them. For one
thing, it seems unlikely that the productivity wave from information
technology has run its course. Moore's law must end eventually, but
there are many new ways to take advantage of cheap processing power and
low-cost communications. The crowdsourcing of design, robots, and the
Internet of Things are three such ongoing advances. Innovations in
biotechnology and materials science are in the works. Productivity
growth in wholesale and retail trade has slowed, as brick-and-mortar
retailers deal with excess capacity because they face competition from
online retailers and slow overall consumption growth, but a competitive
shakeout of the industry will eventually result in higher productivity.
Gordon (2016) may be correct, however, in saying that the era of 3
percent annual productivity growth over multiple decades is over. Future
advances are likely to be lumpier, with surges of productivity from time
to time, not all the time.
[FIGURE 3 OMITTED]
REFERENCES FOR THE BAILY COMMENT
Brynjolfsson, Erik, and Andrew McAfee. 2014. The Second Machine
Age: Work, Progress, and Prosperity in a Time of Brilliant Technologies.
New York: W. W. Norton.
Gordon, Robert J. 2016. The Rise and Fall of American Growth: The
U.S. Standard of Living since the Civil War. Princeton University Press.
Syverson, Chad. 2016. "Challenges to Mismeasurement
Explanations for the U.S. Productivity Slowdown." Working Paper no.
21974. Cambridge, Mass.: National Bureau of Economic Research.
Waters, Richard, and Kana Inagaki. 2016. "Investment Surge
Gives U.S. the Early Lead in Rise of the Robots." Financial Times,
May 3.
(1.) For a list of Ernst Berndt's publications, many of which
relate to price measurement, see
http://mitsloan.mit.edu/faculty-and-research/faculty-directory/detail/?id=41392.
(2.) Details of the studies are available on the McKinsey Global
Institute website, at http://
www.mckinsey.com/mgi/our-research/productivity-competitiveness-and-growth.
(3.) There may also be some regression toward the mean, although
over 10-year periods that effect is likely to be muted.
COMMENT BY
ROBERT J. GORDON The slow productivity growth since 2004,
particularly since 2010, represents one of the outstanding economic
puzzles of our time. It implies slow current growth of potential real
GDP. If it continues, it implies slow future growth of potential GDP and
fewer resources to address the nation's problems, including
education, infrastructure, and the looming shortfalls in funding for
Social Security and Medicare. It would be reassuring for puzzle solving,
although disconcerting for the integrity of the nation's
statistical system, to learn that the entire post-2004 or post-2010
slowdown in productivity growth was due to well-identified errors in
measurement, and that the underlying "true" rate of
productivity growth has not decelerated at all.
THE QUESTIONS TO BE ADDRESSED This paper by David Byrne, John
Fernald, and Marshall Reinsdorf places its main emphasis on the
post-2004 productivity growth slowdown and highlights the $3 trillion in
additional business sector real GDP that would have been produced in
2015 if the productivity growth rate of 1995-2004 had continued after
2004. But the post-2004 slowdown is not the only productivity puzzle to
be explained. My figure 1 displays the five-year moving average growth
rate of quarterly utilization-adjusted total factor productivity (TFP)
growth going back to 1952. This data plot identifies four separate eras
of TFP growth--consistently rapid, at about 2.0 percent a year, through
1973; then slower and erratic, in the range of 0 to 1.5 percent, from
the early 1970s through the mid-1990s; then healthy again for a decade
between 1995 and 2004; and finally a sharp slowdown, to about 0.5
percent a year, during most of the past decade.
Average TFP growth rates over selected periods are listed in my
table 1. The first two rows contrast the 26 years from 1947 to 1973 with
the 42 years since 1973. When the postwar era is divided at 1973, the
TFP growth rate slows by more than half, from 2.10 to 0.82 percent a
year. This sharp contrast poses the first productivity puzzle: What
caused the post-
1973 slowdown? The next three rows divide up the post-1973 interval
at 1995 and 2004. The TFP growth rates for 1973-95 and for 2004-15 are
almost identical, at about 0.5 percent, in sharp contrast to the growth
rate of almost 2.0 percent achieved between 1995 and 2004. This leads to
the second puzzle: What caused TFP growth to revive? And to the third
puzzle: Why was that revival only temporary? The final two rows of my
table 1 divide the 2004-15 era in early 2010 and show that TFP growth
during the 2004-10 period was slightly faster than from 1973 to 1995,
but during the 2010-15 period was somewhat slower.
[FIGURE 1 OMITTED]
This alternation between relatively fast and relatively slow TFP
growth over the four eras of the postwar epoch places a broader
perspective on Byrne, Fernald, and Reinsdorf's topic of
mismeasurement. Techniques of measurement have been relatively constant
since 1947, and thus it is implausible to argue that the slowdown from
the first era (1947-73) to the second era (1973-95) happened because
measurement became worse by an average of 1.5 percentage points a year.
In the same way, it is implausible to argue that the revival to the
third era (1995-2004) occurred because measurement became better, at a
rate of 1.5 percent a year. Likewise, it is implausible to argue that
the slowdown to the fourth era (2004-15) occurred because measurement
once again became worse, at a rate of 1.5 percent a year, as had
occurred previously, after 1973. These alleged appearances and
disappearances of measurement errors of 1.5 percent a year in both
directions are implausible, because measurement techniques were
relatively constant across the four postwar eras.
MEASUREMENT ERRORS HAVE DIMINISHED IN IMPORTANCE IN THE MARKET
ECONOMY Byrne, Fernald, and Reinsdorf place their primary emphasis on
the measurement of the private business economy. Their main focus is on
mismeasurement in the form of biased deflators for information and
communication technology (ICT) equipment in the National Income and
Product Accounts (NIPA). They survey recent research on the prices of
ICT equipment and conclude that the NIPA deflators systematically
understate the rate of decline in the quality-adjusted prices of ICT
equipment and thus understate the rate of growth of real ICT investment
as well as real GDP and labor productivity. TFP is affected less,
because the use of improved deflators not only raises real GDP growth
but also raises the growth rate of capital input that is subtracted from
output in the calculation of TFP.
However, this price index bias does not help at all in
understanding the post-2004 productivity growth slowdown, because the
price index bias is roughly constant both before and after 2004. The
difference between the rate of change of the authors' liberal ICT
price index and the corresponding NIPA index is -5.1 percent a year
during the period 1995-2004 and an almost identical -4.5 percent in
2004-14. Both the liberal index and the NIPA index exhibit a sharp
deceleration in the rate of the price decline after 2004, which points
to a declining rate of technological improvement in ICT equipment as a
substantive reason for the productivity growth slowdown.
[FIGURE 2 OMITTED]
The constant post-2004 price index bias is not the end of the
story, however, because the relative importance of ICT equipment in the
economy has changed in two ways. First, ICT investment is a smaller
share of GDP. Comparing the two years 1999-2000 with 2014-15, the GDP
share of information processing equipment declined from 2.77 to 1.79
percent, and that of computers and peripherals fell fully by half, from
1.00 to 0.45 percent. When combined with the relatively constant pre-
and post-2004 price index corrections, the shrinking ICT shares imply
that the price index bias for GDP and labor productivity became smaller
after 2004.
The second reason why the price index bias has become less
important stems from a sharp shift of ICT investment from domestic
production to imports. My figure 2 exhibits the startling shift in
computer purchases--from 17.8 percent imported in 2002 to an average of
87.9 percent imported in 2011-13. Consider the implications of the
extreme case in which all ICT equipment is imported. An upward price
index bias for imported computers would lead to an understatement of the
growth rate of both computer investment and computer imports, netting
out to zero impact on GDP and labor productivity. The understatement of
growth in capital input, however, would lead to an overstatement of TFP
growth. Thus the shift to computer imports in the last decade has caused
true TFP growth to slow down more since 2004 than in the official NIPA
data. This tendency has been exacerbated by the fact that the price
indexes for imported computers used in the NIPA decline at a
substantially slower rate than the deflators for domestically produced
computers, whereas the observed shift of computer purchases to imports
suggest the opposite--that the true prices of imported computers have
declined faster than prices of domestic production.
These two factors, the declining share of ICT investment in GDP and
the shift to imports, together with the substantial upward bias in the
price index for imported computers, suggest that since 2004 measurement
issues have caused the poor performance of TFP growth to be even worse
in reality than in the government's statistics. Byrne, Fernald, and
Reinsdorf's treatment concludes, in the third column of their table
2, that measurement errors cause labor productivity growth to be
understated by 0.49 percentage point for the period 1995-2004 and by
0.18 point for 2004-14, for a net measurement improvement of 0.31
percentage point. Because of offsetting adjustments to output and
capital input, the effect on TFP growth is much smaller and goes in the
opposite direction, with measurement errors causing TFP growth to be
overstated by 0.08 percentage point during 1995-2004 and by a slightly
greater 0.12 percentage point during 2004-14. The conclusion is that
improved measurement causes the post-2004 slowdown in both labor
productivity and TFP growth to become even worse than in the official
data.
These important conclusions of Byrne, Fernald, and Reinsdorf's
analysis combine an upward bias in the price indexes of computers with a
shrinking share of computer investment and of the domestic production
share of computer equipment. If this upward price index bias were
larger, their conclusions would be magnified. In his important
historical study of the price indexes of computers, William Nordhaus
(2007, table 10, p. 153) concludes that the price of computer power
during the 1990-2002 period decreased at an annual rate of -57.5
percent, as compared with Byrne, Fernald, and Reinsdorf's
alternative price index for computers and peripherals in their table 1,
which declines at a much slower annual rate of -27.3 percent during the
1995-2004 period. Though there are conceptual differences between
Nordhaus's performance-based measure and Byrne, Fernald, and
Reinsdorf's hedonic price indexes, Nordhaus's index has the
advantage that it includes data for both mainframe and personal
computers, whereas Byrne, Fernald, and Reinsdorf's indexes for the
1990s are based only on personal computers. Compared with mainframes,
personal computers achieve a much lower price per calculation, and thus
the transition from mainframes to personal computers that took place in
the 1980s and 1990s reduced the average price per calculation more
rapidly than the price decline for personal computers alone. (1) To the
extent that Nordhaus's (2007) approach is a better guide to the
overall price behavior of computer investment in the 1990s, there has
been an even greater tendency for official data to understate that rapid
growth of labor productivity during the 1995-2004 period and to
understate the true decline in its growth rate since 2004.
THE WELFARE EFFECTS OF FREE INTERNET CONTENT Free Internet
information was available both before and after the 2004 transition from
fast to slow productivity growth. The proportion of American households
connected to the Internet rose from 5 percent in 1995 to 56 percent in
2004, followed by a more gradual increase to 75 percent by 2013 (Gordon
2016, figure 13-4, p. 455). The mismeasurement hypothesis refers to the
difference in the welfare benefits from free Internet content available
after 2004, as compared with before 2004. An aspect of the post-2004
improvement is the transition from dial-up to broadband access; the
proportion of households with broadband increased from 3 percent in 2000
to 29 percent in 2004 and to 65 percent after 2009 (Gordon 2016, figure
13-5, p. 455). Thus, even if the same amount of time were spent on
Internet access before and after 2004, there was a quality change in the
form of much faster response times made possible by the spread of
broadband. Byrne, Fernald, and Reinsdorf recognize that download speed
is not considered a quality change in current deflators for Internet
access, but they assert that "only a small amount of extra digital
service output is missed."
Most of Byrne, Fernald, and Reinsdorf's treatment of free
digital services refers to their role in the market economy. The authors
consider alternatives to the current national accounts treatment of
advertising-supported media as an intermediate good. Even when free
Internet services and other forms of entertainment are treated as final
consumption, their role in the market economy can be no larger than
their advertising revenue. Because total advertising revenue from all
sources, including television and print media, amounts to only 1.3
percent of GDP, and because real advertising revenue has grown faster
than business sector GDP by only a small margin, the authors find the
impact of free Internet services on market GDP to be close to zero.
Intuitively, the growing advertising revenue of Google and Facebook is
largely canceled out by the decline in advertising revenue from older
forms of media, particularly print publications.
Advocates of the mismeasurement hypothesis have in mind the broader
scope of free Internet services as a source of increased consumer
welfare, going well beyond market GDP. They point to the rapid increase
in Internet usage, particularly of mobile services accessed on
smartphones and tablets, as a focus of consumers' leisure-time
activity. How important is the increase in consumer welfare resulting
from increased Internet use? More than one-third of the U.S. population
uses Facebook, and the time each day that its users devote to Facebook
reached 50 minutes in 2015 (Stewart 2016). Taken together with other
Internet services, most notably YouTube and Google, total daily time
devoted to the Internet has been estimated at two hours (Karaian 2015).
By comparison, the American Time Use Survey (ATUS) reports that in 2014
Americans on average spent 2.8 hours a day watching television. (2) A
problem with the estimation of consumer surplus is that the ATUS does
not report on Internet usage as a separate category, with the exception
of "household and personal e-mail and messages," which
accounted for a trivial 0.03 hour per day. Some mobile phone usage may
occur during the ATUS category of time devoted to "socializing and
communicating" (0.71 hour per day). Otherwise, the omission of
Internet usage could imply that multitasking is the standard mode of
behavior, with mobile phones accessed while watching television, eating
meals, riding public transit, or standing in line.
To assess the consumer welfare aspects of free Internet services,
Byrne, Fernald, and Reinsdorf develop an explicit model based on Gary
Becker's (1965) theory of the economics of time, in which total
consumption is subject to both a monetary and time budget constraint.
However, they do not provide their own estimates of the time value of
free Internet services, relying instead on a paper by Erik Brynjolfsson
and Joo Hee Oh (2014) that values the incremental consumer surplus from
free digital services as "equivalent of adding about 0.3 percentage
point per year to business sector output." Note that this addition
of 0.3 percentage point exactly cancels out the authors' estimate
in their table 2 that the post-2004 decline in business sector labor
productivity has been understated by the same 0.3 percentage point a
year.
Is this estimate too large or too small? Chad Syverson (2016)
provides a survey of different approaches to measuring the consumer
surplus of the Internet and compares the resulting surplus estimates to
the total missing annual output from the post-2004 productivity
slowdown, which he estimates, like Byrne, Fernald, and Reinsdorf, to be
about $3 trillion in 2015. Most of the literature surveyed by Syverson
provides surplus estimates of about $100 billion a year, a trivial
fraction of the missing $3 trillion. But one approach developed by
Austan Goolsbee and Peter Klenow (2006), when updated by Syverson's
numbers, yields a post-2004 incremental surplus estimate of $842
billion, almost one-third of the missing $3 trillion. This one-third
translates into 0.6 percentage point of the total post-2004 slowdown of
1.8 percentage points in the growth rate of business sector
productivity. How reasonable is this estimate?
Applying $842 billion to the 80 percent of the population with
broadband access yields an annual per capita sum of $3,300. If
incremental post-2004 Internet usage, compared with the use of the
Internet before 2004, is one hour per day, this would imply an Internet
value of $9 per hour. This compares with Syverson's (2016) estimate
of the average 2015 after-tax wage of $22. The difference between $9 and
$22 makes sense, because it reflects the fact that only half the
population is employed, and the leisure time spent on the Internet is
inframarginal. The use of one hour per day in this calculation, rather
than the two hours reported as average daily Internet use, reflects not
only the fact that some time was allocated to the Internet before 2004
but also the multitasking implied by the ATUS time allocation. Much if
not most Internet use, according to the ATUS, is not occurring during
hours of leisure that previously had zero value, but rather as
multitasking during hours that previously had value obtained from
socializing or watching television.
Therefore, Byrne, Fernald, and Reinsdorf appear to be too
dismissive of the consumer surplus contributed by free Internet
services. Their estimate, taken from Brynjolfsson and Oh's (2014)
findings, values incremental post-2004 Internet services as worth 0.3
percent of business sector output per year, just enough to offset the
authors' table 2 estimate that the decline in the growth rate of
business sector productivity has been understated by the same 0.3
percent per year. In contrast, Syverson's (2016) approach values
the consumer surplus at 0.6 percent per year, twice as much. This is
enough to offset the 0.3 percentage point measurement understatement
from the authors' table 2, as well as contributing an additional
0.3 percentage point consumer surplus bonus that provides a partial
counterweight to the overall 1.8 percentage point productivity growth
slowdown. The relatively large size of this Internet valuation naturally
leads to the question of how much consumer surplus was contributed by
inventions in the past, including the value of free Internet services
introduced in the 1995-2004 decade, such as e-mail, search engines,
Wikipedia, and the early phase of e-commerce provided by Amazon, iTunes,
and airline websites. The technique of multiplying hours of leisure by
an hourly value based on the wage rate would yield a particularly large
value of incremental consumer surplus in the early 1950s, as free
television broadcasts reached almost every home between 1950 and 1955.
History is full of examples of added consumer surplus that was not
included as an increase in GDP. During the period from 1900 to 1940, as
motor vehicles replaced horses, real GDP did not value the removal of
horse droppings and urine from city streets and rural highways. And real
GDP did not value the increase in speed and load-carrying capacity made
possible by automobiles, nor their flexibility, which gave birth to a
new industry called "personal travel." Moreover, real GDP did
not value the increase in consumer surplus as clean running water
arrived at the in-home tap and replaced the previous need to carry pails
of water into the house from nearby wells or streams. Finally, real GDP
did not value the replacement of the outhouse and the need to physically
dispose of human waste with the silent efficiency of public sewers.
Running water, the electric washing machine and refrigerator, the
automobile, and all the other inventions of the late 19th and early 20th
centuries are linked into the GDP statistics, which means that zero
value is placed on their invention. Real GDP did not value the reduction
of infant mortality from 22 percent of new births in 1890 to about 1
percent in 1950. By some estimates, this change created more welfare
value than all the other sources of increased consumer welfare taken
together.
CONCLUSION Because newly invented products and services have always
provided consumer surplus that supplements growth in real GDP by unknown
amounts, the authors of this paper are correct to focus their main
attention on the measurement issues that arise in the private business
sector of the market economy. They convincingly demonstrate that the
post-2004 slowdown in the growth rate of labor productivity and TFP has
not been due to measurement errors. On the contrary, because the most
evident source of measurement bias is in the price indexes for ICT
equipment, the understatement of business sector output and productivity
was greater in the 1995-2004 period than in the 2004-15 period, both
because ICT investment was a greater share of GDP and because a much
greater share of ICT equipment was manufactured in the domestic economy,
whereas after 2004 there was a sharp increase in the share of such
equipment that was imported. The authors thus conclude that the
post-2004 slowdown is real. I agree with their interpretation that after
2004, productivity growth returned "back to normal," to a rate
roughly the same as that achieved between 1973 and 1995, and that the
burst of faster productivity growth between 1995 and 2004 reflected a
one-time-only conversion of the economy to a modern world whose ICT
equipment and software replaced the previous world's typewriters,
calculating machines, and file cabinets.
(1.) Nordhaus (2007, p. 155) provides an example of a 2002 IBM
supercomputer that had a price-per-performance ratio roughly 34 times
higher than a typical Dell personal computer in 2004.
(2.) See Bureau of Labor Statistics, "Table A-1: Time Spent in
Detailed Primary Activities and Percent of the Civilian Population
Engaging in Each Activity, Averages per Day by Sex, 2014 Annual
Averages" (http://www.bls.gov/tus/tables/al_2014.pdf).
REFERENCES FOR THE GORDON COMMENT
Becker, Gary S. 1965. "A Theory of the Allocation of
Time." Economic Journal 75, no. 299:493-517.
Brynjolfsson, Erik, and Joo Hee Oh. 2014. "The Attention
Economy: Measuring the Value of Free Digital Services on the
Internet." Working paper. https://www.
scribd.com/doc/314594157/1-The-Attention-Economy-Measuring-the-Value-of-Free-Goods-on-the-Internet
Byrne, David, and Eugenio Pinto. 2015. "The Recent Slowdown in
High-Tech Equipment Price Declines and Some Implications for Business
Investment and Labor Productivity." FEDS Notes. Washington: Board
of Governors of the Federal Reserve System.
Goolsbee, Austan, and Peter J. Klenow. 2006. "Valuing Consumer
Products by the Time Spent Using Them: An Application to the
Internet." American Economic Review 96, no. 2: 108-13.
Gordon, Robert J. 2016. The Rise and Fall of American Growth: The
U.S. Standard of Living since the Civil War. Princeton University Press.
Karaian, Jason. 2015. "We Now Spend More Than Eight Hours a
Day Consuming Media." Quartz, June 1.
Nordhaus, William D. 2007. "Two Centuries of Productivity
Growth in Computing." Journal of Economic History 67, no. 1:
128-59.
Stewart, James B. 2016. "Facebook Has 50 Minutes of Your Time
Each Day; It Wants More." New York Times, May 5.
Syverson, Chad. 2016. "Challenges to Mismeasurement
Explanations for the U.S. Productivity Slowdown." Working Paper no.
21974. Cambridge, Mass.: National Bureau of Economic Research.
GENERAL DISCUSSION Dan Sichel commended the paper for making a good
case that mismeasurement in the technology sector is not the right way
to understand the productivity slowdown, as the paper convincingly shows
that there has not been either (i) a big shift in shares toward the
unmeasured or quality-measured sectors, or (ii) a really big step up in
the amount of mismeasurement, what he called the "ingredients"
of the mismeasurement story. However, he expressed concern that a casual
reader might come away with the wrong impression. In particular, while
mismeasurement is not a good explanation for the productivity slowdown,
mismeasurement remains a big problem, particularly in the technology,
education, and health care sectors. For instance, Sichel cited a paper
that he coauthored with David Byrne and Stephen Oliner that convincingly
documents big measurement problems in the official price indexes for
semiconductors. (1)
In addition, Sichel noted that the present paper highlighted a
range of other potential measurement problems for the whole span of the
technology sector. Though the authors use rough calibrations, he thought
that the calibrations were sensible, and that they highlighted the need
for what Matthew Shapiro and David Wilcox called the
"house-to-house combat of price measurement." (2) That is,
rather than simply applying a plausible calibration, one should actually
go and quantify the mismeasurement. Even though mismeasurement is not an
explanation of the productivity slowdown, technology is a really
dynamic, important sector in the economy, and it remains important to
support the Bureau of Economic Analysis (BEA) and the Bureau of Labor
Statistics (BLS) in their efforts to try to do a better job at
correcting it. More broadly, one would not want the casual reader to
conclude that, because mismeasurement does not explain the productivity
slowdown, there is no need to worry about mismeasurement anymore.
Mismeasurement is still a big problem, he concluded, and it needs to be
addressed.
Martin Feldstein had three short comments. First, he believed that
one big problem was not just the recent decline observed in productivity
but also the volatility in the series. Second, he expressed interest in
further examining the long-term bias in output measurement. In a piece
written for the Wall Street Journal, Feldstein argued that, despite all
the best efforts of the BLS, the problems associated with measurement
for new and improved products means that the rate of improvement is
underestimated. (3) However, he stresses that products are only a small
part of the problem, and that the measurement of services is much more
important. Roughly 80 percent of private sector employment is in
services, and figuring out how to measure improved output in many
service sectors, he believes, is going to be hopelessly difficult. And
third, he made a point about the interpretation of these statistics.
Some mistakenly tend to treat productivity statistics as indicators of
well-being, or of consumer utility, when--as the authors correctly
emphasize--they are only about market activities. There has long been a
tension in the history of the National Income and Product Accounts and
in what the BLS does in focusing on market activities where, when people
read statistics about, say, income growth, they interpret that in terms
of the value to users, rather than just the market aspect of it.
Jason Furman agreed with Feldstein that the paper was excellent,
and that it removed whatever sliver of doubt he had that mismeasurement
was an important part of the explanation for the productivity slowdown.
He followed with two comments. First, he noted that the less weight put
on mismeasurement as the explanation for the slowdown, the more
optimistic one should be about the growth measured over the next decade,
the reason being that the methods used to measure productivity growth
are considerably more persistent than the underlying "true"
productivity growth itself. He suggested that a lack of capital
investment over the last 5 to 10 years was a big part of the
low-productivity story, and that he was optimistic that productivity
would eventually rebound. Second, he warned against discounting
measurement errors not in the form of persistent biases or incomplete
sources. As more data become available in the coming years, past
productivity numbers will likely need to be revised, and while one
should think of those revisions as being unbiased, given the recent
large disconnect between strong employment growth and weak output
growth, it could be more likely that output and productivity will be
revised up than down. If, for instance, productivity growth is presently
measured to be 0.5 percent per year, Furman believed that it was more
likely in five years the number would be revised up to 1, rather than
revised down to 0.
Robert Hall noted that an important distinction needed to be made
between productivity and consumer surplus, concepts that discussants in
the room seemed to him to be conflating. It is really important to
understand that productivity cannot be measured by consumer surplus, and
how much consumer surplus is associated with output is a totally
separate question. He urged discussants to be sure to keep the two
concepts apart. Similarly, Hall noted the important distinction between
output per hour and total factor productivity (TFP). Output per hour is
just another endogenous variable, he pointed out, whereas TFP is
fundamental. He encouraged everyone to keep an eye on what the paper
basically does on TFP, and not to confuse it with looking at output per
hour, though there is of course a close relationship between the two.
On the question of the future, Hall cited a paper that he recently
encountered by Diego Comin and Mark Gertler that stakes out the claim
that the reason productivity grew so slowly from 2010 onward was a
failure to adopt existing technology, and that as the economy returns to
normal in particular, as the things that have held back investment
subside--there will be a closing of the gap, because the creation of new
technology will have gone on at normal rates. (4) Hall added that a very
interesting fact not mentioned in the discussion at all was that
research and development spending did not decline at all during the
crisis or afterward.
David Romer echoed Furman and Feldstein in stating how terrific the
paper was, and added that it crushed any sliver of hope he had that
mismeasurement could explain the productivity slowdown. However, he
thought the paper conceded too much on one point, which concerned the
question of whether we can "rescue" some of the slowdown--not
of productivity growth, but in the growth of consumer welfare--by
appealing to the consumer surplus created by new technologies. For
growth, the relevant question is not whether the recent innovations have
increased consumer surplus but whether they are contributing more to
consumer surplus than earlier innovations. Since--as discussant Robert
Gordon is fond of pointing out--the amount of surplus created by earlier
innovations was enormous, he was skeptical that bringing in consumer
surplus would eliminate any noticeable part of the growth slowdown. He
suggested that in discussing consumer surplus, the authors not just
address how much recent innovations have contributed to consumer surplus
but also at least mention that what is relevant for growth is changes in
those contributions over time.
Justin Wolfers made three points, jokingly claiming that one point
he did not believe, one was not true, and one was for introductory
economics, so it may be true. The first point, which he did not believe,
concerned the question of whether or not any of this really mattered.
That is, what would economists do differently if productivity growth was
measured appropriately? In terms of cyclical policy, productivity growth
is already understood to be sufficiently noisy, and one does not
typically look to the productivity numbers to figure out whether the
latest slowdown was due to a productivity shock. In terms of long-run
policy, whether productivity growth in the past decade was 0.05 percent,
1.5 percent, or 2.5 percent, one would still want to pick up any policy
that would add another 1 or 2 points to that. According to Wolfers, most
of the things an economist might want to advocate policymakers do would
probably not change even if a better job was done at measuring
productivity.
The second point Wolfers made related to consumer surplus and
economists' apparent obsession with free stuff. There is a view
that free services such as Facebook have significantly added to growth
and consumer surplus, more so than goods and services that are not free.
He pointed out that goods and services do not necessarily have to be
free to generate a lot of consumer surplus. As a humorous example, he
suggested that the introduction of the discount furniture store IKEA to
the United States--which made "Scandinavian clean lines and bright
colors" more affordable--arguably generated more of a consumer
surplus than Facebook.
Last, Wolfers appealed to introductory economics to make the case
to the authors that the idea of creating some sort of "national
consumer surplus accounts ' would be bad, and that the authors were
right to resist. The diamond--water paradox," an idea often taught
in introductory economics, is the apparent contradiction that, although
water is on the whole more useful than diamonds in terms of survival,
diamonds command a higher price in the market. Suppose six glasses of
water are sufficient to sustain life and that the seventh and eighth
only serve to ensure "healthy glowing skin." Pricing out the
consumer surplus from the first six glasses, one might pay $200,000 for
the first six glasses, because otherwise he would be dead. By that
logic, the increment to consumer surplus from free services such as
Facebook relative to the increment to consumer surplus from the fact
that water exists is going to be very small. Rather than try to measure
consumer surplus, one could simply measure well-being, and have a
"well-being count." The simple way to do that, Wolfers pointed
out, is by asking people how happy they are, and it turns out we already
know how to do that.
John Haltiwanger spoke next about the micro productivity evidence
for the ideas presented in the paper. The productivity slowdown in the
high-tech sector, he noted, seems to be supported by the micro evidence.
Likewise, the surge in retail trade productivity over the 1990s is
evident in both the macro and micro evidence. What is puzzling,
Haltiwanger pointed out, is the apparent collapse in retail trade
productivity that the authors report around 2004; according to the micro
data, there does not seem to have been this collapse. Haltiwanger
suggested two findings from the micro data that raise questions about
the macro evidence. First, the restructuring from single-unit
establishment firms toward large national chains continues unabated over
this period. Second, the productivity gap between single-unit
establishment firms and large national chains is just as big as it ever
was. The bottom line is that the micro dynamics still suggest that
retail trade productivity ought to be doing quite well from these
reallocation dynamics. According to the macro data, however, apparently
it is not.
Melissa Kearney wondered if it was worth taking seriously the idea
that the ways in which people use some free digital services might
actually increase the labor supply. Many of the discussants had pointed
to technology as being a substitute for leisure time, but perhaps access
to technology also frees up time for additional work. For example, an
individual might use her smart phone for home production--such as family
shopping or scheduling--late at night, freeing up time for work during
the day. She cited a paper by Lisa Dettling that found that exogenously
determined high-speed home Internet access led to an increase in labor
force participation for married women. (5) Kearney wondered if the
authors had considered anything like this in their analysis.
Jonathan Pingle commended the authors for contributing to what is
really important work suggesting a noticeable deceleration in structural
productivity growth. However, adding on the implications of Bruce
Fallick and others' cohort component model for aggregate labor
supply--presented at the Fall 2014 Brookings Papers meeting (6)--and the
normal business sector GDP gap, one struggles to talk about potential
output growth of 1.5 percent in the United States now, and certainly a
deceleration of over 2 percentage points. With many firms, businesses,
and policymakers continuing to plan based on backward-looking
expectations, that is potentially a big problem.
Joe Beaulieu found, countering Wolfers, that the idea of thinking
about consumer surplus is a somewhat interesting but sideline
conversation to TFP. He suggested that many of the free digital goods
and services talked about essentially take the form of advertising. If
there is a huge productivity increase in the advertising industry, that
is an intermediate good, which probably means that prices for
advertising services have fallen considerably. Therefore, he concluded
that productivity properly measured for the rest of the sectors in the
economy must be even worse than originally thought. This also raises a
second interesting question, which is how one should think about
advertising and the implications for the economy. A lot of the
advertising industry may involve rent-seeking behavior, which then has
interesting implications not only for how one thinks about the economy
and what is going on now versus a few years ago but also for how one
might actually measure some of these things.
Alan Auerbach raised the question of how the production of
multinationals is measured in the U.S. accounts, given that tax-induced
profit shifting leads them to understate U.S. profits for tax purposes.
Marshall Reinsdorf noted that much of the production could really be
taking place in the United States, but that it gets reported overseas.
He remarked that a recent paper by the BEA found that roughly 1 percent
of GDP is explained by the fact that multinational corporations do most
of their production based on where their labor and physical capital are
located. He suggested that one might think of this estimate as an upper
bound.
David Byrne noted that in addition to failing to reject the
hypothesis that there is a productivity slowdown, in order to square the
difference between the perspectives of Silicon Valley--that there is in
fact a productivity slowdown in the technology sector--with what is
actually observed, one should return to a Fortune 500 survey that
discussant Martin Baily brought up during his remarks. In that survey,
many of the companies said that their most important problem at the
moment was adapting to new technology. One way to interpret this is that
there is a technical frontier that has moved outward, and that these
companies have not figured out what to do with it yet, as it is
something that requires a tremendous amount of intangible investment.
But another way to look at this situation is that it appears to be
somewhat harder now to move from the back to the frontier perhaps than
it once was, a finding supported by the work of Haltiwanger and others.
This is potentially a different way of looking at the results of the
paper.
Sichel had earlier cited a paper coauthored with Byrne and Stephen
Oliner, which documented big measurement problems in the official price
indexes for semiconductors, and noted that the tenors of that paper and
the present paper seemed to be a little different. The right way to
think about the Sichel-Byrne-Oliner paper, according to Byrne, from a
GDP perspective is that microprocessors (MPUs) and semiconductors act as
intermediate goods, so they are only going to show up to the extent that
their production affects net trade. As it happens for MPUs--which are
one of the most important individual goods that the United States
trades--they are big in exports, but they are also big in imports. So,
if one makes the price index for MPUs fall faster to a first
approximation, it has no effect on GDP--not only because MPUs are
intermediate goods but also because of the global value chain. The chips
may be fabricated in the United States, tested in Costa Rica, and sent
back to the United States to be used in data centers, and the
transaction price is captured going both ways. The better way to think
about the Sichel-Byrne-Oliner paper and the MPUs, according to Byrne, is
to look at the MPU price index as a barometer of what is going on in the
frontier of the information technology (IT) sector. The huge slowdown
observed in the price index for recent years is very alarming, he noted;
what the authors find in the present paper is that, for a number of
reasons, that MPU price index is just not that accurate.
It had also been mentioned that IT is less important today than it
once was, and Byrne noted that that is certainly true as a share of
investment. Nevertheless, IT is still an important portion of
production. BEA's investment deflator for IT includes things like
computers, equipment software, and other special-purpose equipment. In
the 1980s, that high-volume production used to be a much bigger share of
IT investment than it is now--about 50 percent then, compared with only
about 25 percent today. Investment and production of the low-volume,
special-purpose equipment is much more difficult to measure. All this is
not to say that mismeasurement is bigger than was found in the present
paper. Rather, it is that the confidence interval around the estimate is
much bigger than it once was. And it is not that the statistical
agencies do not know about these problems; it is that they need more
funding for measurement. He joked, "We are not supposed to be
making price indexes at the Federal Reserve Board," but that,
nevertheless, they do because despite it being well known that there are
solutions to the problems of mismeasurement, the funding just is not
there for the statistical agencies.
On the question of why more was not said about the dire labor
productivity outcomes during the past five years, John Fernald noted
that, at least when looking at TFP, it does not actually look worse; the
past five years for TFP look about the same as the years before the
Great Recession. In growth accounting, one observes that while so many
people have been newly hired, capital accumulation has not kept up. One
common theme in the room, Fernald noted, was that much is still unknown,
and the paper only touches narrowly. He conceded that the measurement of
health care, services, and new goods more broadly are all really
challenging issues.
One final point Fernald made pertained to the value of the
Internet. In terms of growth, the Internet brings no more than a few
basis points, which he admitted was probably an overstatement; the
authors' best estimate was closer to zero. Part of this, he
explained, is because the market portion of the Internet is in
advertising support. The big benefits are nonmarket, but these are still
important, and things at the border of the market are shifting in
interesting ways. Perhaps technology has increased the opportunity cost
of working for less-educated workers. There is much need to study this,
he concluded, adding that it would be great if the statistical agencies
could acquire the resources to be able to develop better satellite
accounts, and if researchers were working on ways to measure well-being.
Table 1. Utilization-Adjusted Total Factor
Productivity Growth, 1947-2015
Period TFP growth (percent)
1947:Q2-1973:Q1 2.10
1973:Q1-2015:Q4 0.82
1973:Q1-1995:Q1 0.52
1995:Q1-2004:Q1 1.99
2004:Q1-2015:Q4 0.48
2004:Q1-2010:Q1 0.73
2010:Q1-2015:Q4 0.21
Source: Federal Reserve Bank of San Francisco (http://www.frbsf.org/
economic-research/indicators-data/total-factor-productivity-tfp/).
(1.) David M. Byrne, Stephen D. Oliner, and Daniel E. Sichel,
"Is the Information Tech..jlogy Revolution Over?" Finance and
Economics Discussion Series no. 2013-36 (Washington: Board of Governors
of the Federal Reserve System, 2013).
(2.) Matthew D. Shapiro, and David W. Wilcox, "Mismeasurement
in the Consumer Price Index: An Evaluation," NBER Macroeconomics
Annual 11 (1996): 93-154.
(3.) Martin Feldstein, "The U.S. Underestimates Growth,"
Wall Street Journal, May 18, 2015.
(4.) Diego Anzoategui, Diego Comin, Mark Gertler, and Joseba
Martinez, Endogenous Technology Adoption and R&D as Sources of
Business Cycle Persistence," Working Paper no. 22005 (Cambridge,
Mass.: National Bureau of Economic Research, 2016).
(5.) Lisa J. Dettling, "Broadband in the Labor Market: The
Impact of Residential High-Speed Internet on Married Women's Labor
Force Participation," Finance and Economics Discussion Series no.
2013-065 (Washington: Board of Governors of the Federal Reserve System,
2013).
(6.) Stephanie Aaronson, Tomaz Cajner, Bruce Fallick, Felix
Galbis-Reig, Christopher Smith, and William Wascher, "Labor Force
Participation: Recent Developments and Future Prospects," Brookings
Papers on Economic Activity, Fall 2014: 197-255.
DAVID M. BYRNE
Federal Reserve Board
JOHN G. FERNALD
Federal Reserve Bank of San Francisco
MARSHALL B. REINSDORF
International Monetary Fund
(1.) Section I and the online appendix discuss data, the timing of
the bars in the chart, and the similar pattern in measures of TFP. The
online appendixes for this and all other papers in this volume may be
found at the Brookings Papers web page, www.brookings.edu/bpea, under
"Past Editions."
(2.) In independent work, Syverson (2016) suggests a similar
calculation of the missing growth.
(3.) There are also some sources of upward measurement error in
growth related to globalization that have become less important. Still,
we will usually take "mismeasured" to mean "causing GDP
growth to be understated."
(4.) Nordhaus (2006) sketches principles of national accounting for
nonmarket as well as market goods and services.
(5.) Some academic research found even larger effects--for example,
Bils and Klenow (2001)--while Schultze and Mackie (2002) argued for a
smaller number.
(6.) A separate debate is whether the productivity slowdown of the
1970s was itself due to mismeasurement. Griliches (1994) points out that
the post-1973 slowdown was concentrated in poorly measured industries.
Gordon (2016) argues instead that the post-1973 slowdown reflects the
unusual strength of the 1920-70 period rather than anything specific
that happened in the 1970s. Relatedly, Fernald (1999) estimates that
building the Interstate Highway System substantially boosted
productivity growth in the 1950s and 1960s, but then its effects ran
their course. Triplett (1999) reviews arguments that the post-1973
slowdown was illusory.
(7.) A possibly more optimistic perspective on recent developments
comes from noting that TFP growth has continued since the Great
Recession at its pre-1995 pace. This pace of TFP growth may be
normal--it was, perhaps, the 1995-2004 period that was exceptional.
Furthermore, in recent years TFP may be more relevant than labor
productivity, whose weakness since 2010 partly reflects transitory
factors associated with weak capital deepening.
(8.) "Other well-measured" includes most of manufacturing
(except computers and electronics equipment), agriculture, mining,
utilities, transportation, broadcasting, and accommodations. Nordhaus
(2002) also considers wholesale and retail trade as well measured, but
we have broken that out separately.
(9.) Value added weighting of value added TFP growth is essentially
equivalent to doing so-called Domar weighting of gross output residuals
(Domar 1961). The fixed weights are based on nominal expenditures, not
quantities. In the data, the rise in the nominal share of services
reflects both faster growth in quantities and faster growth in prices.
(10.) Our focus in this section is on the contribution of IT
capital services to productivity and its implications for TFP growth.
Parallel measurement problems exist for IT consumer durables, which we
do not discuss explicitly. However, we account for understatement of GDP
from the mismeasurement of IT through our adjustments to domestic
production, whether for the consumer or business market.
(11.) See research for communications equipment (Byrne and Corrado
2015), computers (Byrne and Pinto 2015; Byrne and Corrado 2016), and
microprocessors (Byrne, Oliner, and Sichel 2015).
(12.) With appropriate data on characteristics, hedonic regressions
are a useful tool for quality-adjusting prices, but the absence of
hedonic adjustment does not necessarily indicate that a price index is
biased. Other techniques may also account for quality improvements
(Wasshausen and Moulton 2006).
(13.) Research for the remaining category, peripherals, is sparse.
The BEA investment price index fell 12 percent a year on average in the
1990s, but 4 percent on average since then. Aizcorbe and Pho (2005)
examine scanner data for eight categories of peripherals for the years
2001-03. Although we note that the geometric mean of price indexes for
these categories falls 15 percent per year, we chose not to adjust the
peripherals index based on this short time series.
(14.) Navigational equipment and audiovisual equipment are
classified as communications equipment in the BEA investment taxonomy.
(15.) Although the sequencing of a human genome is not final
output, improvements in the tools used to conduct science are the likely
foundation of falling prices for health services in the future. Heather
and Chain (2016, p. 6) present the history of DNA sequencing equipment,
and they note that "over the years, innovations in sequencing
protocols, molecular biology and automation increased the technological
capabilities of sequencing while decreasing the cost, allowing the
reading of DNA molecules that are hundreds of base pairs in length,
massively parallelized to produce gigabases of data in one run." On
the role of high-performance computing in genetics, also see Stein
(2010).
(16.) Byrne and Corrado (2016) have added estimates of an
alternative price index for software since this paper was written. Their
price index accelerates by roughly the same amount (1.9 percent) as the
price index we employ (1.7 percent). Consequently, the contribution of
IT price mismeasurement to the productivity slowdown would not change if
we employed their index. Their price index falls 3 percentage points
faster in both periods, implying a somewhat greater contribution to
labor productivity of capital deepening and smaller contribution of TFP
both before and after 2004, but roughly the same acceleration of TFP.
(17.) Though not original to them, Basu and others (2004) make this
point in the context of intangible investment. Dale Jorgenson had made
this observation to Fernald when software investment was added to the
U.S. GDP in 1999.
(18.) Note, as well, that the slower pace of aggregate TFP growth
would be distributed unevenly. Suppose the mismeasurement reflects
faster true TFP growth in domestic equipment and software goods. Then
TFP growth in the other industries must be slower than measured.
Intuitively, this happens because growth in their capital input is more
rapid than measured, but growth in their output is the same as measured.
(19.) The careful reader will note that labor productivity growth
for 1995-2004 is about 0.1 percentage point higher in column 3 than
column 2, as is capital growth. So why does TFP growth fall, even though
the labor productivity effect looks larger than the adjusted
contribution of capital (capital's share times capital growth)? The
reason is that, with intangibles, capital's share is also adjusted
upward, and so the effect on TFP involves not just the adjustment to
capital growth but also the adjustment to capital's share
multiplied by (the new) capital growth rate. This effect can be a few
tenths.
(20.) In "The GNU Manifesto," Richard Stallman (1985)
describes his vision that "in the long run, ... nobody will have to
work very hard just to make a living. People will be free to devote
themselves to activities that are fun, such as programming." (We
thank Hank Farber for pointing us to this quotation.)
(21.) This is according to the American Time Use Survey
(http://www.bls.gov/tus/tables/ al_all_years.xlsx).
(22.) As a nonprofit institution serving households,
Wikipedia's output, about $0.2 billion in 2011, is counted as
personal consumption. The $25.2 billion thus overstates the adjustment
that could be made to GDP by $0.2 billion.
(23.) The online appendix shows that the Laspeyres and Paasche
quantity indexes that are averaged to obtain the Fisher index are upper
and lower bound measures of the relative change in consumer surplus.
(24.) We thank Joo Hee Oh for sending these data. Our calculation
corresponds to Brynjolfsson and Oh's (2014) equation 14 on the
money benefits.
(25.) Another revenue source for providers of free digital services
is the valuable information that the users of these services reveal
about themselves, but this is a small revenue source compared with
advertising.
(26.) In another project we are working on (Byrne, Fernald, and
Reinsdorf ongoing work), we discuss a way to bring the extra value added
into the business sector, as opposed to being in the household sector.
Their approach requires special treatment of the advertising revenue, so
that some of the output that is currently viewed as intermediate
consumption by the ad buyers can instead be viewed as consumed by
households. This would make business sector nominal and real value added
larger, but the effect on TFP growth is still close to zero. A separate
issue is that a more explicit agreement for consumers to watch the ads
in order to receive the services would be required for the ad watching
to qualify as a barter transaction under the international guidelines of
the System of National Accounts (United Nations and others 2009, para.
3.51 and 3.53, pp. 43-44).
(27.) A well-known example--the need to distinguish between
increases in welfare and productivity gains--occurs with changes in
terms of trade. Favorable shifts in exports and imports increase the
opportunity to gain from trade, allowing real consumption to rise as the
economy moves to a different point on the production possibility
frontier.
(28.) The Census Bureau defines e-commerce as purchases made over
the Internet or other electronic network or via email. The e-commerce
shares for products that are easy to order online (such as books) are
even larger, because some products (such as gasoline and building
supplies) presumably involve little e-commerce
(https://www.census.gov/retail/mrts/www/
data/excel/tsnotadjustedsales.xls). Evans, Schmalensee, and Murray
(2016) conjecture that the Census figures underestimate e-commerce.
(29.) Schreyer, Brandt, and Zipperer (2015) discuss an alternative
approach to measuring multifactor productivity (MFP) for mining that
includes services of natural resource assets. The Australian Bureau of
Statistics publishes an experimental measure of MFP for mining that
includes services of subsoil natural resource assets in inputs. In the
tables released in December 2015, this raises the estimated growth rate
of mining MFP between 2000-01 and 2014-15 from -4 percent a year to -1
percent a year. Similarly, Zheng and Bloch (2014) find that adjusting
for inputs of natural resources, declining returns to scale, and
capacity utilization raises MFP growth for the mining industry of
Australia between 1974-75 and 2007-08 from -0.2 percent a year to 2
percent a year.
(30.) These data were downloaded at
http://www.abs.gov.aU/AUSSTATS/abs@nsf/
DetailsPage/5260.0.55.0022014-15.
(31.) This problem is examined by Houseman and others (2011) and
Mandel (2009).
(32.) Where they are in the source data is not clear. However, the
Quarterly Services Survey indicates slowing nominal growth of the local
transportation measure that includes taxis, which is where one would
expect to find the new kinds of local transportation services.
(33.) Wasshausen and Moulton (2006) discuss how statistical
agencies incorporate quality adjustments.
Table 1. Prices and Weights for Information Technology Investment (a)
Measure 1947-78 1978-95 1995-2004 2004-14
IT investment share of
business fixed investment 12.2 23.6 30.7 29.3
IT investment price indexes
National Income and
Product Accounts 0.2 -2.2 -6.1 -1.4
Conservative alternative (b) -1.8 -4.4 -9.2 -4.4
Liberal alternative (c) -3.9 -6.5 -11.2 -5.9
Share of IT investment
Computers and peripherals 13.1 22.8 20.8 14.5
Communications equipment 36.9 26.6 22.6 17.0
Other information systems
equipment 38.3 26.7 17.3 20.4
Software 11.7 23.9 39.3 48.2
Price deflators
Computers and peripherals (d)
National Income and
Product Accounts -18.1 -14.6 -19.3 -6.6
Alternative -18.1 -19.0 -27.3 -18.6
Communications equipment
National Income and
Product Accounts 1.9 1.4 -5.4 -2.7
Alternative -3.0 -2.7 -11.2 -10.3
Other information systems
equipment
National Income and
Product Accounts 2.3 2.9 -0.6 0.5
Alternative -1.7 -2.2 -8.9 -4.9
Software (d)
National Income and
Product Accounts -0.7 -1.2 -1.1 0.1
Alternative -4.8 -4.4 -2.5 -0.8
Sources: U.S. Bureau of Economic Analysis; Byrne and Corrado
(2016).
(a.) All values are expressed as percents.
(b.) Incorporates alternative computer and communications equipment
prices.
(c.) Incorporates alternative software and special-purpose
equipment prices.
(d.) Price indexes begin in 1958.
Table 2. Adjustments to Business Sector Growth Accounting (a)
(0)
Measure Published
of growth Period baseline (c)
Labor 1978-95 1.50
productivity 1995-2004 3.26
2004-14 1.44
2004-10 1.92
2010-14 0.71
Capital-to- 1978-95 2.20
hours ratio 1995-2004 3.68
2004-14 1.80
2004-10 3.14
2010-14 -0.22
Total factor 1978-95 0.53
productivity 1995-2004 1.82
2004-14 0.49
2004-10 0.44
2010-14 0.58
Annual percentage point
change relative to baseline (b)
(1) (2) (3)
Measure Conservative Liberal Liberal +
of growth Period (d) (e) intangibles (f)
Labor 1978-95 0.12 0.21 0.30
productivity 1995-2004 0.27 0.38 0.49
2004-14 0.13 0.19 0.18
2004-10 0.17 0.25 0.24
2010-14 0.06 0.11 0.10
Capital-to- 1978-95 0.27 0.52 0.66
hours ratio 1995-2004 0.54 0.89 1.02
2004-14 0.44 0.70 0.55
2004-10 0.46 0.74 0.54
2010-14 0.41 0.63 0.58
Total factor 1978-95 0.04 0.05 -0.01
productivity 1995-2004 0.09 0.09 -0.08
2004-14 -0.04 -0.07 -0.12
2004-10 0.00 -0.02 -0.12
2010-14 -0.10 -0.14 -0.12
Sources: Fernald (2014); Corrado and Jager (2015).
(a.) Averages start in 1978 because of the availability of
intangibles data.
(b.) Each column involves a separate, experimental adjustment to
selected components of capital investment. The entries show the
percentage point adjustment to business sector growth accounting
components, relative to the unadjusted estimates in column 0.
(c.) Baseline (the business sector) measured as the percent change
at an annual rate.
(d.) Alternative deflators for computers and communications.
(e.) Column 1, plus alternative deflators for specialized equipment
and software.
(f.) Column 2, plus intangibles from Corrado and Jager (2015).
