Hubbry Logo
Balassa–Samuelson effectBalassa–Samuelson effectMain
Open search
Balassa–Samuelson effect
Community hub
Balassa–Samuelson effect
logo
7 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Balassa–Samuelson effect
Balassa–Samuelson effect
Balassa–Samuelson effect
View on Wikipedia
from Wikipedia

The Balassa–Samuelson effect, also known as Harrod–Balassa–Samuelson effect (Kravis and Lipsey 1983), the Ricardo–Viner–Harrod–Balassa–Samuelson–Penn–Bhagwati effect (Samuelson 1994, p. 201), or productivity biased purchasing power parity (PPP) (Officer 1976) is the tendency for consumer prices to be systematically higher in more developed countries than in less developed countries. This observation about the systematic differences in consumer prices is called the "Penn effect". The Balassa–Samuelson hypothesis is the proposition that this can be explained by the greater variation in productivity between developed and less developed countries in the traded goods' sectors which in turn affects wages and prices in the non-tradable goods sectors.

Béla Balassa and Paul Samuelson independently proposed the causal mechanism for the Penn effect in the early 1960s.

Theory

[edit]

The Balassa–Samuelson effect depends on inter-country differences in the relative productivity of the tradable and non-tradable sectors.

Empirical "Penn Effect"

[edit]

By the law of one price, entirely tradable goods cannot vary greatly in price by location because buyers can source from the lowest cost location. However, most services must be delivered locally (e.g. hairdressing), and many manufactured goods such as furniture have high transportation costs or, conversely, low value-to-weight or low value-to-bulk ratios, which makes deviations from the law of one price, known as purchasing power parity or PPP-deviations, persistent. The Penn effect is that PPP-deviations usually occur in the same direction: where incomes are high, average price levels are typically high.

Basic form of the effect

[edit]

The simplest model which generates a Balassa–Samuelson effect has two countries, two goods (one tradable, and a country-specific nontradable) and one factor of production, labor. For simplicity assume that productivity, as measured by marginal product (in terms of goods produced) of labor, in the nontradable sector is equal between countries and normalized to one.

where "nt" denotes the nontradable sector and 1 and 2 indexes the two countries.

In each country, under the assumption of competition in the labor market the wage ends up being equal to the value of the marginal product, or the sector's price times MPL. (Note that this is not necessary, just sufficient, to produce the Penn effect. What is needed is that wages are at least related to productivity.)

Where the subscript "t" denotes the tradables sector. Note that the lack of a country specific subscript on the price of tradables means that tradable goods prices are equalized between the two countries.

Suppose that country 2 is the more productive, and hence, the wealthier one. This means that

which implies that

.

So with a same (world) price for tradable goods, the price of nontradable goods will be lower in the less productive country, resulting in an overall lower price level.

Details

[edit]

A typical discussion of this argument would include the following features:

  • Workers in some countries have higher productivity than in others. This is the ultimate source of the income differential. (Also expressed as productivity growth.)
  • Certain labour-intensive jobs are less responsive to productivity innovations than others. For instance, a highly skilled Zürich burger flipper is no more productive than his Moscow counterpart (in burger/hour) but these jobs are services which must be performed locally.
  • The fixed-productivity sectors are also the ones producing non-transportable goods (for instance haircuts) – this must be the case or the labour intensive work would have been off-shored.
  • To equalize local wage levels with the (highly productive) Zürich engineers, Zürich fast food employees must be paid more than Moscow fast food employees, even though the burger production rate per employee is an international constant.
  • The CPI is made up of:
    • local goods (which in richer countries are more expensive relative to tradables), and
    • tradables, which have the same price everywhere
  • The (real) exchange rate is pegged (by the law of one price) so that tradable goods follow PPP (purchasing power parity). The assumption that PPP holds only for tradable goods is testable.
  • Since money exchange rates will vary fully with tradable goods productivity, but average productivity varies to a lesser extent, the (real goods) productivity differential is less than the productivity differential in money terms.
  • Productivity becomes income, so the real income varies less than the money income does.
  • This is equivalent to saying that the money exchange rate exaggerates the real income, or that the price level is higher in more productive, richer, economies.

Equivalent Balassa–Samuelson effect within a country

[edit]

The average asking price for a house in a prosperous city can be ten times that of an identical house in a depressed area of the same country. Therefore, the RER-deviation exists independent of what happens to the nominal exchange rate (which is always 1 for areas sharing the same currency). Looking at the price level distribution within a country gives a clearer picture of the effect, because this removes some complicating factors:

  1. The econometrics of purchasing power parity (PPP) tests are complicated by nominal exchange rate noise. (This noise would be an econometric problem, even assuming that the exchange rate volatility is a pure error term).
  2. There may be some real economy border effects between countries which limit the flow of tradables or people.
  3. Monetary effects, and exchange rate movements[note 1] can affect the real economy and complicate the picture, a problem eliminated if comparing regions that use the same currency unit.
  4. Taxes are very different in many countries, whereas in a same country taxes are usually equal or similar.

A pint of pub beer is famously more expensive in the south of England than the north, but supermarket beer prices are very similar. This may be treated as anecdotal evidence in favour of the Balassa–Samuelson hypothesis, since supermarket beer is an easily transportable, traded good. (Although pub beer is transportable, the pub itself is not.) The BS-hypothesis explanation for the price differentials is that the 'productivity' of pub employees (in pints served per hour) is more uniform than the 'productivity' (in foreign currency earned per year) of people working in the dominant tradable sector in each region of the country (financial services in the south of England, manufacturing in the north). Although the employees of southern pubs are not significantly more productive than their counterparts in the north, southern pubs must pay wages comparable to those offered by other southern firms in order to keep their staff. This results in southern pubs incurring a higher labour cost per pint served.

Empirical evidence on the Balassa–Samuelson effect

[edit]

Evidence for the Penn effect is well established in today's world (and is readily observable when traveling internationally). However, the Balassa–Samuelson (BS) hypothesis implies that countries with rapidly expanding economies should tend to have more rapidly appreciating exchange rates (for instance the Four Asian Tigers); conventional econometric tests yield mixed findings for this prediction.

In total, since it was (re)discovered in 1964, according to Tica and Druzic (2006)[1] the HBS theory "has been tested 60 times in 98 countries in time series or panel analyses and in 142 countries in cross-country analyses. In these analyzed estimates, country specific HBS coefficients have been estimated 166 times in total, and at least once for 65 different countries". Many papers have been published since then. Bahmani-Oskooee and Abm (2005) & Egert, Halpern and McDonald (2006) also provide quite interesting surveys of empirical evidence on BS effect.

Over time, the testing of the HBS model has evolved quite dramatically. Panel data and time series techniques have crowded out old cross-section tests, demand side and terms of trade variables have emerged as explanatory variables, new econometric methodologies have replaced old ones, and recent improvements with endogenous tradability have provided direction for future researchers.

The sector approach combined with panel data analysis and/or cointegration has become a benchmark for empirical tests. Consensus has been reached on the testing of internal and external HBS effects (vis a vis a numeraire country) with a strong reservation against the purchasing power parity assumption in the tradable sector.

The vast majority of the evidence supports the HBS model. A deeper analysis of the empirical evidence shows that the strength of the results is strongly influenced by the nature of the tests and set of countries analyzed. Almost all cross-section tests confirm the model, while panel data results confirm the model for the majority of countries included in the tests. Although some negative results have been returned, there has been strong support for the predictions of a cointegration between relative productivity and relative prices within a country and between countries, while the interpretation of evidence for cointegration between real exchange rate and relative productivity has been much more controversial.

Therefore, most of the contemporary authors (e.g.: Egert, Halpern and McDonald (2006); Drine & Rault (2002)) analyze main BS assumptions separately:

  1. The differential of productivities between the traded and non-traded sector and relative prices are positively correlated.
  2. The purchasing power parity assumption is verified for tradable goods.
  3. The RER and relative prices of non-tradable goods are positively correlated.
  4. As a consequence of 1, 2, & 3, there is a long-run relationship between productivity differentials and the RER.

Refinements to the econometric techniques and debate about alternative models are continuing in the International economics community. For instance:

"A possible explanation of the BS empirical rejection may simply be that there are additional long-run real exchange determinants that have to be considered." Drine & Rault conclude.

The next section lists some of the alternative proposals to an explanation of the Penn effect, but there are significant econometric problems with testing the BS-hypothesis, and the lack of strong evidence for it between modern economies may not refute it, or even imply that it produces a small effect. For instance, other effects of exchange rate movements might mask the long-term BS-hypothesis mechanism (making it harder to detect if it exists). Exchange rate movements are believed by some to affect productivity; if this is true then regressing RER movements on differential productivity growth will be 'polluted' by a totally different relationship between the variables1.

Alternative, and additional causes of the Penn effect

[edit]

Most professional economists accept that the Balassa–Samuelson effect model has some merit. However other sources of the Penn effect RER/GDP relationship have been proposed:

Distribution sector

[edit]

In a 2001 International Monetary Fund working paper Macdonald & Ricci accept that relative productivity changes produce PPP-deviations, but argue that this is not confined to tradables versus non-tradable sectors. Quoting the abstract:

An increase in the productivity and competitiveness of the distribution sector with respect to foreign countries leads to an appreciation of the real exchange rate, similarly to what a relative increase in the domestic productivity of tradables does.

Differences in endowment of labor relative to capital

[edit]

The Bhagwati–Kravis–Lipsey view provides a somewhat different explanation from the Balassa–Samuelson theory. This view states that price levels for nontradables are lower in poorer countries because of differences in endowment of labor and capital, not because of lower levels of productivity. Poor countries have more labor relative to capital, so marginal productivity of labor is greater in rich countries than in poor countries. Nontradables tend to be labor-intensive; therefore, because labor is less expensive in poor countries and is used mostly for nontradables, nontradables are cheaper in poor countries. Wages are high in rich countries, so nontradables are relatively more expensive.[2]

Dutch disease

[edit]
Further information: Dutch disease

Capital inflows (say to the Netherlands) may stimulate currency appreciation through demand for money. As the RER appreciates, the competitiveness of the traded-goods sectors falls (in terms of the international price of traded goods).

In this model, there has been no change in real economy productivities, but money price productivity in traded goods has been exogenously lowered through currency appreciation. Since capital inflow is associated with high-income states (e.g. Monaco) this could explain part of the RER/Income correlation.

Yves Bourdet and Hans Falck have studied the effect of Cape Verde remittances on the traded-goods sector.[3] They find that, as local incomes have risen with a doubling of remittances from abroad, the Cape Verde RER has appreciated 14% (during the 1990s). The export sector of the Cape Verde economy suffered a similar fall in productivity during the same period, which was caused entirely by capital flows and not by the BS-effect.[note 2]

Services are a 'superior good'

[edit]

Rudi Dornbusch (1998) and others say that income rises can change the ratio of demand for goods and services (tradable and non-tradable sectors). This is because services tend to be superior goods, which are consumed proportionately more heavily at higher incomes.

A shift in preferences at the microeconomic level, caused by an income effect can change the make-up of the consumer price index to include proportionately more expenditure on services. This alone may shift the consumer price index, and might make the non-traded sector look relatively less productive than it had been when demand was lower; if service quality (rather than quantity) follows diminishing returns to labour input, a general demand for a higher service quality automatically produces a reduction in per-capita productivity.

A typical labour market pattern is that high-GDP countries have a higher ratio of service-sector to traded-goods-sector employment than low-GDP countries. If the traded/non-traded consumption ratio is also correlated with the price level, the Penn effect would still be observed with labour productivity rising equally fast (in identical technologies) between countries.

Protectionism

[edit]

Lipsey and Swedenborg (1996) show a strong correlation between the barriers to free trade and the domestic price level. If wealthy countries feel more able to protect their native producers than developing nations (e.g. with tariffs on agricultural imports) we should expect to see a correlation between rising GDP and rising prices (for goods in protected industries - especially food).

This explanation is similar to the BS-effect, since an industry needing protection must be measurably less productive in the world market of the commodity it produces. However, this reasoning is slightly different from the pure BS-hypothesis, because the goods being produced are 'traded-goods', even though protectionist measures mean that they are more expensive on the domestic market than the international market, so they will not be "traded" internationally[note 3]

Trade theory implications

[edit]

The supply-side economists (and others) have argued that raising international competitiveness through policies that promote traded goods sectors' productivity (at the expense of other sectors) will increase a nation's GDP, and increase its standard of living, when compared with treating the sectors equally.[citation needed] The Balassa–Samuelson effect might be one reason to oppose this trade theory, because it predicts that: a GDP gain in traded goods does not lead to as much of an improvement in the living standard as an equal GDP increase in the non-traded sector. (This is due to the effect's prediction that the CPI will increase by more in the former case.)

History

[edit]

The Balassa–Samuelson effect model was developed independently in 1964 by Béla Balassa and Paul Samuelson. The effect had previously been hypothesized in the first edition of Roy Forbes Harrod's International Economics (1939, pp. 71–77), but this portion was not included in subsequent editions.

Partly because empirical findings have been mixed, and partly to differentiate the model from its conclusion, modern papers tend to refer to the Balassa–Samuelson hypothesis, rather than the Balassa–Samuelson effect. (See for instance: "A panel data analysis of the Balassa-Samuelson hypothesis", referred to above.)

See also

[edit]

Notes

[edit]

References

[edit]

Further reading

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Balassa–Samuelson effect

View on Grokipedia
from Grokipedia
The Balassa–Samuelson effect is an economic phenomenon describing how countries with higher in tradable goods sectors experience real appreciation and elevated overall price levels compared to less productive economies, primarily due to pressures spilling over from tradables to non-tradable sectors. This effect challenges the absolute version of (PPP) by showing that PPP holds better for tradable goods but deviations arise from sectoral differences, leading to systematically higher consumer prices in more developed nations. The theory was independently developed in 1964 by economists Béla Balassa and Paul A. Samuelson in response to empirical observations of the "Penn effect," where price levels correlate positively with per capita income across countries. Balassa's analysis in The Purchasing-Power Parity Doctrine: A Reappraisal critiqued traditional PPP assumptions by incorporating productivity biases, arguing that faster growth in (tradables) raises wages economy-wide, inflating non-tradable prices like services without corresponding international . Samuelson, in Theoretical Notes on Trade Problems, formalized a similar continuum-of-goods model, demonstrating how relative in exportables drives real appreciation under . These foundational works established the effect as a key explanation for long-run real movements, influencing subsequent research on economic convergence and . At its core, the mechanism operates through sectoral linkages: productivity gains in tradables (e.g., ) boost wages to maintain labor market equilibrium, but since non-tradables (e.g., , healthcare) cannot be easily imported, their relative prices rise, contributing to overall and real appreciation. In catching-up economies, such as those in during the 1990s and 2000s, this effect explained 0.2 to 2.0 percentage points of annual differentials against advanced economies like the area, though its impact on () remained modest at around 10-30% of the total. Under fixed s, it pressures policymakers to tighten to curb , potentially at the cost of growth; under floating rates, it manifests as nominal appreciation, aiding competitiveness but complicating export sectors. Empirical evidence supports the effect's role in cross-country price variations, with strong correlations (e.g., 0.89 across European countries) between relative in tradables and real exchange rates, though time-series tests among high-income nations show weaker links, suggesting extensions like unit labor costs or distribution sector influences may be needed for fuller explanation. has notable implications for monetary union criteria, such as the EU's inflation threshold, where productivity-driven appreciations in transition economies could temporarily elevate inflation without signaling overheating. Despite revisions highlighting nonlinearities (e.g., weaker effects in very low-income countries), it remains a cornerstone for understanding global imbalances and .

Theoretical Foundations

Penn Effect

The Penn Effect describes the empirical tendency for nominal price levels to rise systematically with GDP per capita in cross-country comparisons, such that richer countries exhibit higher overall prices relative to a common benchmark like the . This pattern implies that real income differences, when measured at market exchange rates, understate the economic distance between high- and low-income nations compared to PPP-adjusted figures. The observation traces its roots to early 20th-century discussions of by , who in 1911 proposed that exchange rates should equalize price levels across countries under absolute PPP, but empirical data later revealed persistent deviations. It was formally documented in the 1960s through the University of Pennsylvania's International Comparison Program, led by economists Irving B. Kravis, Robert Summers, and , with key advancements in the 1970s and 1980s by Kravis, , and Robert Summers, who analyzed price and output data from over 100 countries. Their cross-sectional analyses produced characteristic scatterplots, plotting the logarithm of national price levels against the logarithm of real GDP , which consistently displayed an upward-sloping trend line with an elasticity often estimated around 0.3 to 0.5, confirming the positive association. This effect challenges absolute PPP by showing that exchange rate adjustments fail to fully equalize price levels, as evidenced in post-World War II data where high-income countries like the maintained price levels approximately 2-3 times higher than those in low-income nations such as (with India's price level around 30-35 relative to the U.S. at 100 in the 1950s-1970s). However, it is consistent with relative PPP over the long run, as changes in relative price levels tend to align with inflation differentials and productivity growth differences across countries. The Balassa–Samuelson effect provides a prominent theoretical explanation for this price-income correlation through sector-specific productivity dynamics.

Core Mechanism

The Balassa–Samuelson effect arises from the division of an economy into tradable sectors, such as and , where goods can be easily exported or imported, and non-tradable sectors, such as services, , and retail, where goods and services cannot be traded internationally. The holds for tradable goods due to international , ensuring that their prices tend to equalize across countries when expressed in a common . In contrast, prices for non-tradables are determined domestically and can diverge significantly between countries. The core mechanism begins with faster productivity growth in the tradable sector compared to the non-tradable sector, which is a common pattern in developing and developed economies alike. This advantage in tradables raises marginal labor and, consequently, wages in that sector to maintain profit levels. Due to labor mobility across sectors, workers shift toward the higher-wage tradable sector, but overall labor market pressures equalize wages economy-wide. In the non-tradable sector, where growth lags behind, the higher wages increase production costs without a corresponding gain, leading to relative in non-tradable prices. This process results in an overall rise in the domestic , contributing to real appreciation. International plays a crucial role in constraining tradable prices to align globally, as differences would prompt flows that eliminate them. However, non-tradable prices remain untethered from such forces and reflect local cost structures, particularly levels driven by tradable . Thus, countries experiencing rapid productivity gains in tradables see their non-tradable prices rise relative to those in less productive economies, amplifying cross-country differences. A classic illustration is the cost of a haircut or housing construction, which is markedly higher in wealthy nations like than in poorer ones like , despite similar labor inputs, because Swiss wages—boosted by advanced —elevate service costs without productivity catching up in these non-tradable activities. This mechanism provides the theoretical foundation for the observed Penn Effect, where richer countries exhibit higher overall price levels.

Mathematical Details

The Balassa–Samuelson effect is formalized in a two-sector open economy model distinguishing between tradable and non-tradable goods, where productivity growth in the tradable sector outpaces that in the non-tradable sector, leading to higher relative prices of non-tradables and an appreciation of the overall price level. The model assumes full employment of labor, perfect labor mobility across sectors, constant returns to scale in production, no differences in capital mobility between sectors, and balanced trade in tradables. These assumptions ensure wage equalization across sectors and law of one price holding for tradables internationally. The derivation begins with simple production functions in each sector, often specified as linear or Cobb-Douglas forms to capture labor . In the tradable sector, output YT=ATLTY_T = A_T L_T, where ATA_T is labor and LTL_T is labor input; similarly, in the non-tradable sector, YN=ANLNY_N = A_N L_N. Under and constant returns, the rate ww equals the value marginal product of labor. For tradables, whose price pTp_T is fixed internationally by the , this yields w=ATpTw = A_T p_T. For non-tradables, the price pN=w/ANp_N = w / A_N. Substituting the from the tradable sector gives the relative price pN/pT=AT/ANp_N / p_T = A_T / A_N, implying that gains in tradables raise non-tradable prices proportionally via pressures. For Cobb-Douglas production functions, YT=ATKT1αTLTαTY_T = A_T K_T^{1-\alpha_T} L_T^{\alpha_T} and YN=ANKN1αNLNαNY_N = A_N K_N^{1-\alpha_N} L_N^{\alpha_N} with 0<αT,αN<10 < \alpha_T, \alpha_N < 1, the marginal products equate under labor mobility and capital mobility within the country, leading to the same relative price relation pN/pT=(AT/AN)αN/αTp_N / p_T = (A_T / A_N)^{\alpha_N / \alpha_T}; in the benchmark case with equal labor shares (αT=αN\alpha_T = \alpha_N), this simplifies to pN/pT=AT/ANp_N / p_T = A_T / A_N. The overall domestic price level PP is a weighted geometric average, P=pT1βpNβP = p_T^{1-\beta} p_N^\beta, where β\beta is the share of non-tradables in total expenditure (typically 0.3–0.5 across economies). Thus, the relative price level between two countries is P/P=(AT/AN)βP / P^* = (A_T / A_N)^\beta, capturing how tradable productivity advantages inflate the price level. In an open economy extension, the real exchange rate qq, defined as q=log(P/P)eq = \log(P / P^*) - e where ee is the log nominal exchange rate (domestic per foreign currency), appreciates with tradable productivity differentials: q=βlog(AT/AN)q = \beta \log(A_T / A_N). This follows from the price level relation under flexible nominal exchange rates or fixed rates with price adjustments, assuming balanced trade ensures no current account imbalances from non-tradables. The formulation highlights the effect's role in explaining deviations from absolute .

Domestic Applications

The Balassa–Samuelson effect extends analogously to domestic contexts, where regional productivity differentials in tradable sectors drive higher wages and, consequently, elevated prices for non-tradables such as housing and services within a single country. In high-productivity areas like urban tech hubs, faster growth in tradable output relative to non-tradables pushes up local labor costs, which spill over to non-tradable sectors due to labor market integration and internal mobility. This mirrors the international mechanism but operates through subnational migration and factor flows rather than trade balances. For instance, in Japan, regional service prices correlate positively with productivity differences across prefectures, primarily driven by higher urban labor costs (accounting for about 80% of the variance) rather than manufacturing productivity gaps. A prominent example appears in the United States, where price levels vary significantly between high-productivity coastal regions and lower-productivity Midwest states. Cities like those in California, encompassing , exhibit non-tradable prices—such as rents and local services—up to 10% above the national average, linked to superior tradable-sector productivity in technology and finance. This disparity reflects internal migration drawing skilled labor to productive areas, elevating regional wages and non-tradable costs. Adapting the international framework for domestic settings with free internal mobility, the relative price of non-tradables approximates pNrpNnATrATn,\frac{p_N^r}{p_N^n} \approx \frac{A_T^r}{A_T^n}, assuming similar non-tradable productivity and labor shares across regions. The overall regional price level elasticity to tradable productivity is then β (the expenditure share of non-tradables, around 0.3-0.4 in U.S. estimates). Empirical subnational purchasing power parity data confirm this pattern, with a price-income elasticity of approximately 0.3 across U.S. states, underscoring how productivity-driven wage premiums sustain regional price gaps. Within the European Union, intra-country and cross-regional studies reveal similar dynamics, with higher prices in affluent areas like Germany's industrial heartlands compared to poorer regions such as those in Bulgaria, persisting even under the eurozone's common currency in shared member states. Wealthier EU regions, including Île-de-France in France or Madrid in Spain, show price levels 10–15% above national averages, attributable to tradable-sector productivity advantages that inflate non-tradable costs via wage equalization. Panel analyses across EU regions support the Balassa–Samuelson hypothesis at the subnational level, with productivity differentials explaining much of the observed price variance, though less pronounced than internationally due to integrated markets. Domestic applications face unique limitations, including policy interventions like fiscal transfers that can dampen regional divergences. In the EU, structural funds and net fiscal flows from richer to poorer regions—totaling approximately 0.3-0.4% of EU GDP annually—promote convergence by subsidizing infrastructure and labor mobility, thereby moderating productivity-wage spillovers and non-tradable price pressures that the Balassa–Samuelson mechanism would otherwise amplify. Unlike international borders, domestic barriers to goods and labor movement are minimal, which can accelerate equalization but also introduce spatial dependencies, as seen in Japan's prefectural inflation spillovers where neighboring productivity influences local prices. These factors imply that while the effect holds theoretically, its magnitude is often attenuated in unified economies with redistributive policies.

Empirical Evidence

Supporting Studies

The seminal empirical tests of the Balassa–Samuelson effect were conducted independently by Balassa and Samuelson in 1964. Balassa performed cross-country regressions using post-World War II data, demonstrating a positive correlation between national price levels and per capita income in manufacturing, attributing this to higher productivity growth in tradable sectors relative to non-tradables, which drives up non-tradable prices through wage equalization. Similarly, Samuelson developed a theoretical model with empirical implications, showing how productivity differentials in tradables lead to real exchange rate appreciation, consistent with observed deviations from absolute . Modern analyses using panel data have provided robust confirmation of the effect in developed economies. In a study of OECD countries from 1970 to 1985, De Gregorio, Giovannini, and Wolf provided evidence supporting the effect, linking relative productivity growth in tradables to inflation differentials between non-tradables and tradables. Recent post-2000 research has leveraged disaggregated data to test the effect at finer levels. Berka, Devereux, and Engel analyzed Eurostat price and productivity data for Eurozone countries from 1999 to 2012, finding that real exchange rate variations align closely with an amended Balassa–Samuelson framework, where tradable sector productivity gains explain significant cross-country and time-series differences in non-tradable relative prices, confirming the productivity-non-tradables link in the EU context. Quantitative assessments indicate the Balassa–Samuelson effect accounts for a substantial portion of deviations, particularly in emerging markets. Recent studies from 2020 to 2025 continue to affirm the effect's relevance, for example, in explaining long-term Euro-Dollar exchange rate equilibrium through productivity differentials.

Limitations and Debates

Empirical tests of the Balassa–Samuelson effect have revealed significant shortcomings, particularly in low-income countries such as those in Africa, where estimates of the key coefficient β—measuring the responsiveness of relative non-tradable prices to productivity differentials—are often near zero or insignificant. Panel data analyses show that the effect weakens substantially outside high-income OECD nations, with β approaching zero in subsamples of low-income countries due to limited productivity spillovers from tradables to non-tradables. This contrasts with stronger evidence in advanced economies, highlighting the effect's limited applicability in contexts of structural underdevelopment or commodity dependence. Debates surrounding the measurement of the Balassa–Samuelson effect center on challenges in defining and classifying tradable versus non-tradable sectors, which can lead to inconsistent empirical results. Arbitrary categorizations based on national accounts data often misclassify goods with partial tradability, such as agricultural products or certain services, inflating or deflating productivity differentials. Additionally, discrepancies arise between cross-sectional and time-series analyses: while cross-country regressions typically support the effect with positive β estimates, time-series data for individual countries frequently yield weaker or unstable coefficients, attributed to data quality issues and short sample periods in emerging markets. These measurement inconsistencies underscore the need for standardized aggregation methods to isolate the effect reliably. Post-2010 critiques have intensified scrutiny of the Balassa–Samuelson effect, particularly in light of external shocks that disrupt its core productivity-driven mechanism. During the , in , non-tradable productivity rose due to labor reallocation from lockdowns, leading to a negative Balassa-Samuelson effect that contributed to real exchange rate depreciation and illustrating how shocks can alter the usual mechanism. Such episodes illustrate how transient supply shocks can dominate long-run productivity trends, challenging the effect's robustness in volatile environments and prompting calls for augmented models incorporating demand and supply-side disturbances. In transition economies of post-1990s Eastern Europe, alternative interpretations highlight instances where the Balassa–Samuelson effect overpredicts real exchange rate appreciation relative to observed patterns, partly because they overlook regulated price adjustments and fiscal policies that dampened non-tradable inflation during early reforms. These discrepancies emphasize ongoing controversies over the effect's explanatory power in dynamic, institutionally evolving settings.

Alternative Explanations

Distribution Sector Role

One explanation for deviations from (PPP) that mimics the involves differences in the efficiency and size of distribution sectors across countries. In particular, larger distribution margins in poorer countries can inflate the measured prices of tradable goods at the retail level, contributing to higher overall price levels without relying on productivity differentials in tradable versus non-tradable sectors. This mechanism suggests that what appears as a non-tradables price effect may partly stem from measurement biases in how tradables prices are recorded in price indices. Ariel Burstein, Martin Eichenbaum, and Sergio Rebelo (2005) hypothesize that high domestic distribution costs in developing economies—encompassing retail, wholesale, and local transportation—account for a substantial share of retail prices for imported tradables, leading to incomplete pass-through of producer price changes to consumers. Their analysis of large devaluations in countries like Argentina shows that distribution margins can absorb up to 50% of retail prices for tradables, compared to around 16% in advanced economies like the United States, based on input-output data and firm-level margins. This disparity arises from less efficient supply chains, higher local input costs, and greater market power in fragmented distribution networks in poorer nations. For instance, during Argentina's 2002 devaluation, dock prices for imports rose by 111%, but retail prices increased by only 83%, with the gap largely attributed to sticky distribution margins. To formalize this, Burstein et al. extend standard models by incorporating distribution markups into tradables pricing: pT=pproducer×(1+μ)p_T = p_{\text{producer}} \times (1 + \mu) where pTp_T is the retail price of tradables, pproducerp_{\text{producer}} is the producer or import price, and μ\mu represents the distribution markup (e.g., calibrated to 1.0 for a 50% margin in developing countries). This structure implies biased PPP deviations, as higher μ\mu in poor countries raises observed pTp_T independently of productivity, without requiring wage equalization across sectors. Empirical calibration to Korean data during its 1997 crisis confirms that such markups explain much of the slow adjustment in retail tradables prices post-shock. This distribution channel interacts with the Balassa–Samuelson effect by amplifying price level differences in service-heavy economies, where non-tradables dominate consumption baskets. In poorer countries with large distribution sectors (often classified as services), elevated μ\mu exacerbates the relative price of non-tradables, reinforcing the Penn Effect pattern of higher overall prices in richer nations when inverted. However, unlike pure productivity-driven Balassa–Samuelson dynamics, this mechanism highlights measurement issues in tradables indices, suggesting policy focus on improving distribution efficiency to mitigate exchange rate misalignments.

Factor Endowments

In the Heckscher-Ohlin framework, differences in factor endowments—particularly the relative abundance of capital versus labor—across countries can generate variations in price levels as an alternative mechanism to productivity-driven explanations. Capital-abundant economies, typically richer nations, specialize in and export capital-intensive tradable goods, leading to higher returns on capital through trade-induced factor price equalization. This elevates overall wage levels, as labor becomes relatively scarcer, pushing up the costs of labor-intensive non-tradable goods like services and construction. Conversely, labor-abundant poorer countries maintain lower wages due to their plentiful labor supply, resulting in cheaper non-tradables despite potentially similar technologies across borders. This endowment-based approach was formalized by , who demonstrated that if non-tradables are capital-intensive and poor countries have sufficiently low capital stocks, their relative price of non-tradables will be lower than in capital-rich countries, even without productivity gaps. Empirical extensions incorporating multiple factors, such as those by Daniel Trefler, show that endowment differences account for a substantial share of international factor price variations, which in turn influence non-tradable price gaps in models extending the Balassa-Samuelson framework. A representative example illustrates this dynamic: Japan, with its high capital-to-labor ratio, exhibits elevated non-tradable prices compared to Brazil, where capital scarcity relative to labor keeps service sector costs low, even when sectoral productivities are comparable. According to World Bank price level indices based on purchasing power parity, as of 2023 Brazil's overall price level is approximately 73% of Japan's, reflecting lower costs in labor-intensive sectors driven by endowment differences. In mathematical terms, this contrasts with the standard Balassa-Samuelson model by tying the relative price of non-tradables to tradables, PN/PTP_N / P_T, to cross-country differences in factor endowments like the capital-labor ratio (K/L)(K/L), rather than solely to the productivity ratio AT/ANA_T / A_N. Specifically, in a Heckscher-Ohlin setting with trade, the equilibrium relative price emerges from the intersection of factor supply and demand curves influenced by endowment ratios: PNPT=f(KL)\frac{P_N}{P_T} = f\left( \frac{K}{L} \right) where f()f(\cdot) increases with the capital abundance, reflecting higher factor costs for non-tradables in capital-rich economies. This formulation highlights how endowment imbalances propagate through trade to affect domestic price structures, providing a production-side rival to the productivity-centric Balassa-Samuelson mechanism detailed elsewhere.

Dutch Disease Influence

The Dutch Disease offers a complementary explanation to the Balassa–Samuelson effect for real exchange rate appreciations and elevated non-tradable prices in resource-abundant economies, particularly those exhibiting Penn Effect patterns. In the seminal model by Corden and Neary (1982), a boom in a booming tradable sector—such as commodity exports like oil—generates higher incomes, which shifts labor and resources toward the booming sector and increases demand for non-tradables. This resource movement effect and spending effect elevate non-tradable prices relative to tradables, resulting in real exchange rate appreciation and potential contraction in other tradable sectors like manufacturing. Illustrative cases highlight these dynamics. During Norway's 1970s oil boom following North Sea discoveries, the real exchange rate appreciated by approximately 20%, with non-tradable prices rising significantly due to heightened demand from oil revenues. In Australia, the 2000s mining boom driven by global commodity demand caused the Australian dollar to appreciate by over 50% in real terms between 2002 and 2012, boosting wages by about 6% and contributing to higher service sector costs while pressuring non-mining exports. Unlike the Balassa–Samuelson effect, which arises from persistent productivity growth in tradables relative to non-tradables, Dutch Disease is typically transient and sector-specific, tied to exogenous resource shocks rather than broad productivity advances. Empirical analyses, including Gylfason (1999) on Nordic experiences, demonstrate that Dutch Disease can explain substantial portions of real appreciations in resource-rich economies, often 20% or more in prominent cases, thereby amplifying cross-country price level differences akin to the Penn Effect.

Non-Tradables as Superior Goods

The concept of non-tradables as superior goods offers a demand-driven perspective on price level differences across countries, emphasizing shifts in consumption patterns rather than supply-side productivity variations. In their analysis, Kravis and Lipsey (1983) highlighted an inverse application of Engel's law to services, noting that as incomes rise, the share of expenditure on non-tradables such as services increases due to their income elasticity exceeding unity, unlike the declining share for basic necessities like food. This shift occurs because higher-income households allocate a larger proportion of their budget to labor-intensive services, exerting upward pressure on non-tradable prices through heightened demand. A simplified model illustrates this dynamic, where the demand for non-tradables is given by: pNQN=Yϵp_N Q_N = Y^\epsilon with ϵ>1\epsilon > 1, pNp_N denoting the price of non-tradables, QNQ_N the quantity demanded, and YY representing . As YY grows, the right-hand side expands more than proportionally, necessitating higher pNp_N to clear the market if supply responses are limited, thereby elevating the of non-tradables without relying on productivity gaps between sectors. Cross-country evidence aligns with this framework, as the share of service consumption in GDP rises from approximately 40% in low-income countries to 70% in high-income countries, reflecting the progressive demand tilt toward non-tradables. This pattern contributes to the Penn Effect by amplifying price disparities for non-tradables in wealthier economies. Within individual economies like the , this mechanism accounts for the faster price increases in and services compared to goods, as rising incomes boost demand for these non-tradable sectors while their supply remains relatively inelastic.

Protectionism Impacts

Trade barriers, such as tariffs and non-tariff measures, distort the prices of tradable in developing economies by raising domestic costs relative to international levels, thereby creating an artificial wedge that mimics the productivity differentials central to the Balassa-Samuelson effect. In the standard Balassa-Samuelson framework, higher in tradables (A_T) relative to non-tradables drives up wages and non-tradable prices, leading to overall increases. However, protectionism elevates tradable prices directly, inflating the aggregate and contributing to deviations from (PPP) without relying solely on productivity gaps. This distortion reduces the effective in tradables by limiting specialization, , and efficient , thus weakening the pure Balassa-Samuelson mechanism. A key theoretical insight is that tariffs act as a on imports, increasing the domestic price of tradables and shifting the of non-tradables upward, which amplifies observed differences across countries. Felbermayr, Jung, and Larch (2015) demonstrate this using a multi-country Ricardian model, showing that barriers in poor countries hinder their ability to specialize in high-productivity tradable sectors, resulting in lower effective A_T and higher relative non-tradable prices compared to richer, more open economies. This suggests explains a substantial share of PPP deviations, particularly in developing nations where barriers are higher. An illustrative example is India's pre-1991 economic regime, characterized by severe under the "license raj" system, where average tariffs reached 123% on , 115% on capital goods, and 129% on consumer goods. This policy insulated domestic manufacturers from competition, leading to an inefficient industrial sector that supplied nearly all domestic demand for manufactured goods at prices significantly higher than world levels, compounded by an overvalued . The resulting elevated tradable prices contributed to broader distortions, aligning with Balassa-Samuelson-like patterns but driven primarily by policy-induced barriers rather than productivity growth. Post-liberalization reductions in tariffs helped narrow these gaps, underscoring protectionism's role in perpetuating such effects.

Implications and Extensions

Trade Theory Connections

The Balassa–Samuelson (BS) effect integrates with Ricardian trade theory by linking advantages in tradable sectors to patterns of specialization and adjustments across countries. In a Ricardian framework, countries specialize in producing goods where they exhibit higher , leading to elevated wages that spill over to non-tradable sectors and cause overall increases, consistent with the BS mechanism. This connection highlights how drives not only trade flows but also real dynamics, as -led specialization amplifies the of non-tradables. The BS effect can be synthesized with the Heckscher-Ohlin (H-O) model by incorporating factor proportions into the analysis of tradable productivity differentials, enabling multi-country predictions for real movements. In an H-O setting with traded and non-traded goods, differences in factor endowments (such as capital-labor ratios) determine the composition of tradable production, which interacts with BS-driven productivity growth to influence the relative supply of non-tradables and thus exchange rates. This synthesis extends the standard BS model beyond single-factor assumptions, showing how endowment variations can modulate the strength of real appreciation in capital-abundant economies. The BS effect carries implications for , as productivity gains in tradables for growing economies lead to real exchange rate appreciation, potentially eroding export competitiveness by raising the relative price of . In models where reflect the ratio of to prices, BS-induced appreciation shifts this balance, making a country's costlier on world markets and prompting adjustments in balances. This dynamic underscores the between productivity-driven growth and sustained export performance in open economies. Recent theoretical extensions embed the BS effect within frameworks featuring , where in tradable sectors alters the transmission of productivity shocks to real exchange rates. Under , firms' pricing power in differentiated goods amplifies the BS effect through markup adjustments, leading to stronger real appreciations than in competitive models, while also accounting for patterns. These developments reconcile the BS hypothesis with empirical observations of trade in similar goods across countries.

Policy and Real Exchange Rates

Central banks in catching-up economies face significant challenges when implementing nominal anchors, such as or fixed regimes, because the Balassa–Samuelson effect drives structural real appreciation that requires higher to materialize under a stable nominal rate. This tension arises as gains in tradable sectors push up wages and non-tradable prices, but strict nominal controls suppress the necessary price adjustments, often resulting in real undervaluation of the . In during the 2000s, the managed peg to the U.S. dollar exemplified this issue, where rapid growth implied a 2% annual real appreciation under the Balassa–Samuelson mechanism, yet the fixed nominal rate and sterilized interventions led to persistent undervaluation, contributing to large current account surpluses exceeding 10% of GDP by 2007. To mitigate these pressures, policymakers have pursued productivity-targeted reforms aimed at enhancing efficiency in non-tradable sectors, thereby reducing the productivity differential and moderating real appreciation. In following the 1991 liberalization, deregulation of services such as , banking, and spurred annual productivity growth in non-tradables from 4.3% in the 1980s to 9.6% by the early 2000s, narrowing the gap with tradables and supporting balanced real dynamics without excessive . These reforms, including reductions and sectoral openings, allowed non-tradable productivity to catch up, aligning with Balassa–Samuelson predictions while fostering overall economic convergence. Within the (EMU), the Balassa–Samuelson effect has amplified price pressures in peripheral countries like , where the absence of nominal adjustment channels the required real appreciation entirely through higher in non-tradables. During the , experienced persistent differentials of approximately 1.2 percentage points above the euro area average from 2000 to 2010, partly attributable to productivity catch-up in tradables, which elevated non-tradable prices without the flexibility of currency devaluation, exacerbating competitiveness losses—though the BS contribution was estimated at less than 0.5 percentage points per year. This dynamic contributed to real misalignments, as peripheral economies could not offset Balassa–Samuelson-induced appreciations through . The Balassa–Samuelson effect informs forecasts and assessments by international institutions, predicting 1-2% annual real appreciation in fast-growing economies based on differential trends. For instance, empirical estimates for transition economies indicate contributions of around 1.5% to differentials, guiding IMF evaluations of equilibrium exchange rates and convergence criteria. These projections help calibrate policy to accommodate structural appreciations without derailing stability.

Historical Development

Origins in 1964

The Balassa–Samuelson effect originated from two independent theoretical contributions published in 1964 by economists Béla Balassa and Paul A. Samuelson, each addressing longstanding issues in related to (PPP) and exchange rates. These works emerged amid growing empirical evidence challenging the absolute version of PPP, which posits that exchange rates should equalize price levels across countries when expressed in a common currency. Béla Balassa, a Hungarian-American then at , articulated his ideas in the paper "The Purchasing-Power Parity Doctrine: A Reappraisal," published in the . Motivated by discrepancies observed in post-World War II European economic data, where recovering economies exhibited varying price levels and productivity growth rates, Balassa critiqued the use of aggregate price indexes for testing PPP. He argued that such indexes fail to account for structural differences between economies, particularly in productivity across sectors. In parallel, Paul A. Samuelson, a Nobel laureate and professor at MIT, developed a similar framework in his article "Theoretical Notes on Trade Problems," appearing in The Review of Economics and Statistics. Building on his earlier explorations of PPP from the late , Samuelson extended classical trade models to incorporate productivity differentials, emphasizing how these influenced relative prices and equilibrium exchange rates in open economies. Both contributions responded to 1950s debates on PPP failures, fueled by post-war reconstruction in —often termed the "European economic miracle"—and the exchange rate challenges arising from decolonization in and , which highlighted systematic deviations from PPP predictions. Their key innovation was the first explicit theoretical link between relative productivities in tradable and non-tradable sectors and overall price levels, explaining why higher productivity growth in tradables could lead to appreciating real exchange rates and elevated domestic prices. This addressed the empirical puzzle later formalized as the Penn effect, where richer countries tend to have higher price levels.

Subsequent Refinements

In the and , the Balassa–Samuelson effect gained prominence in open-economy through integrations that accounted for dynamic adjustments beyond static differentials. Rudiger Dornbusch's seminal 1985 analysis embedded the effect within frameworks, explaining structural deviations through the Ricardo-Harrod-Balassa-Samuelson model of differentials that affect real price levels and exchange rates. This extension provided a more comprehensive explanation for persistent non-stationarity in real exchange rates observed in empirical data. The saw significant extensions of the effect to emerging and transition economies, where structural reforms created pronounced productivity shifts. László Halpern and Charles Wyplosz's 2001 study applied the framework to post-communist countries, attributing observed real appreciations—averaging 2-3% annually in the —to rapid tradable sector growth during and market liberalization, while non-tradable sectors lagged due to institutional legacies. Their of nine Central and Eastern European economies confirmed the effect's relevance, estimating it accounted for up to 40% of differentials during early transition phases. Recent debates on further evolve the model, positing that AI-driven in non-tradables like healthcare and could induce an "inverse" effect, leading to real depreciations in AI-adopting nations by narrowing sectoral gaps. Post-2015 studies have incorporated climate-impacted sectors, recognizing environmental factors as exogenous shocks to differentials. Analyses integrating variations into the model show effects on real exchange rates in climate-vulnerable economies.

References

  1. https://www.nber.org/reporter/2014number4/real-exchange-rates-and-balassa-samuelson-effect-revisited
  2. https://www.jstor.org/stable/1829464
  3. https://www.bis.org/publ/work143.pdf
  4. https://www.nber.org/system/files/working_papers/w1912/w1912.pdf
  5. https://www.nber.org/system/files/chapters/c8437/c8437.pdf
  6. https://www.princeton.edu/~deaton/downloads/Welcome-to-the-50th-anniversary-of-the-world_World-Bank-May2018.pdf
  7. https://scholar.harvard.edu/files/kenfroot/files/perspectives_on_ppp_and_long-run_real_exchange_rates_froot_rogoff.pdf
  8. https://www.dpipe.tsukuba.ac.jp/~naito/teaching_web/international_trade_ay2013_web/balassa_samuelson.pdf
  9. http://digamo.free.fr/balassa64.pdf
  10. http://digamo.free.fr/samu1964.pdf
  11. https://www.sas.upenn.edu/~egme/pp/RIE1994.pdf
  12. https://www.nber.org/system/files/working_papers/w20228/w20228.pdf
  13. https://www.rieti.go.jp/en/publications/summary/19100014.html
  14. https://www.oecd.org/content/dam/oecd/en/publications/reports/2019/12/subnational-purchasing-power-of-parity-in-oecd-countries_f72bd17d/3d8f5f51-en.pdf
  15. https://www.econstor.eu/bitstream/10419/78030/1/528606352.pdf
  16. https://www.bruegel.org/analysis/when-will-european-union-finally-get-budget-it-needs
  17. https://mpra.ub.uni-muenchen.de/59220/1/MPRA_paper_59220.pdf
  18. https://www.ecb.europa.eu/pub/pdf/scpwps/ecbwp1029.pdf
  19. https://www.journals.uchicago.edu/doi/abs/10.1086/258965
  20. https://www.sciencedirect.com/science/article/pii/0014292194900701
  21. https://www.aeaweb.org/articles?id=10.1257/aer.20151045
  22. https://www.bbvaresearch.com/wp-content/uploads/2025/03/Equilibrium-of-the-EUR-USD-exchange-rate-A-long-term-perspective.pdf
  23. https://www.aeaweb.org/conference/2016/retrieve.php?pdfid=11597
  24. https://www.cepii.fr/PDF_PUB/wp/2019/wp2019-11.pdf
  25. https://cnrs.hal.science/hal-03101442/document
  26. https://www.bcb.gov.br/content/publicacoes/WorkingPaperSeries/WP596.pdf
  27. https://www.bis.org/publ/work270.pdf
  28. https://www.journals.uchicago.edu/doi/10.1086/431254
  29. http://www-2.rotman.utoronto.ca/~dtrefler/papers/Trefler_JPE_December_1993.pdf
  30. https://data.worldbank.org/indicator/PA.NUS.PPPC.RF?locations=JP-BR
  31. https://www.jstor.org/stable/2232670
  32. https://ageconsearch.umn.edu/record/295493/files/wp-1999-167.pdf
  33. https://www.rba.gov.au/publications/rdp/2014/pdf/rdp2014-08.pdf
  34. https://ies.princeton.edu/pdf/S52.pdf
  35. https://data.worldbank.org/indicator/NV.SRV.TOTL.ZS?locations=XD-XP
  36. https://doi.org/10.1016/j.jinteco.2015.02.003
  37. https://www.piie.com/blogs/trade-and-investment-policy-watch/2021/indias-trade-reforms-30-years-later-great-start
  38. https://www.sciencedirect.com/science/article/abs/pii/S1090944320303744
  39. https://doireann.com/wp-content/uploads/2018/02/toteffects.pdf
  40. https://onlinelibrary.wiley.com/doi/abs/10.1111/j.1467-9396.2010.00917.x
  41. https://www.ecb.europa.eu/press/key/date/2003/html/sp031114.en.html
  42. https://www.bis.org/events/conf080626/mussa.pdf
  43. https://www.elibrary.imf.org/view/journals/001/2007/268/article-A001-en.xml
  44. https://www.econstor.eu/bitstream/10419/45152/1/589760629.pdf
  45. https://www.nationalbanken.dk/media/qppplbm0/2003-mon4-inf41.pdf
  46. https://ideas.repec.org/a/kap/openec/v19y2008i5p629-650.html
  47. https://www.jstor.org/stable/1928178
  48. https://doi.org/10.2307/1928178
  49. https://doi.org/10.1086/258965
  50. https://papers.ssrn.com/sol3/papers.cfm?abstract_id=336331
  51. https://www.unece.org/fileadmin/DAM/oes/disc_papers/ECE_DP_2001-1.pdf
  52. https://cepr.org/voxeu/columns/global-impact-ai-mind-gap
  53. https://onlinelibrary.wiley.com/doi/10.1111/cwe.12597
Add your contribution
Related Hubs
User Avatar
No comments yet.