Attachment 24 Unit Value Indexes for Exports - New Developments Using Administrative Trade Data

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Attachment 24 Unit Value Indexes for Exports - New Developments Using Administrative Trade Data

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Journal of Official Statistics, Vol. 38, No. 1, 2022, pp. 83–106, http://dx.doi.org/10.2478/JOS-2022-0005

Unit Value Indexes for Exports – New Developments Using
Administrative Trade Data
Don Fast1, Susan E. Fleck1, and Dominic A. Smith1

U.S. import and export price indexes replaced unit value indexes forty years ago, given quality
concerns of mismeasurement due to unit value bias. The administrative trade data underlying
the unit values have greatly improved since that time. The transaction records are now more
detailed, available electronically, and compiled monthly with little delay. The data are used by
academic researchers to calculate price measures, and unit value indexes based on trade data
are used by other national statistical offices (NSOs). The U.S. Bureau of Labor Statistics is
now evaluating whether replacing price indexes with unit value indexes for homogeneous
products calculated from administrative trade data could expand the number of published
official import and export price indexes. Using export transactions, the research calculates
detailed unit value indexes from 200 þ million trade records from 2012– 2017 for 123 export
product categories. Results show that 27 of the 123 unit value indexes are homogeneous and
closely comparable to published official price indexes. This article presents the concepts and
methods considered to calculate and evaluate the unit value indexes and to select the product
categories that are homogeneous. Compared to official price indexes, export unit value
indexes for the 27 5-digit BEA (U.S. Bureau of Economic Analysis) end-use product
categories would deflate real exports of these goods by 13 percentage points less over the
period. Incorporating these 27 indexes into the top-level XPI would increase the value of real
exports of all merchandise goods by 2.6 percentage points at the end of 2017.
Key words: Unit values; trade; large data sets.

1.

Introduction

The U.S. Bureau of Labor Statistics (BLS) official Import and Export Price Indexes
(MXPI) measure price changes of U.S. imports and exports of goods and a limited number
of services. Other national statistics that calculate trade and output depend on the quality
and detail of MXPI to adjust current-dollar measures to constant dollars (Cerritos 2015;
Moulton 2018). Over time, the number of publishable detailed MXPI has declined as
budget-related sample size reductions shrink the number of items in the market basket and
the number of prices that support index quality. Nearly half of the import and export price
1

U.S. Bureau of Labor Statistics, 2 Massachusetts Ave., NE, Rm. 3955 Washington, DC 20212, U.S.A. Emails:
fast.don@bls.gov, fleck.susan@bls.gov and smith.dominic@bls.gov
Acknowledgments: We recognize and thank these BLS staff for their research and data support for this paper:
Brett Edgerton, Matthew Fisher, Michael Havlin, Laurence Lang, Christina Qiu, Daryl Slusher. Additional
support was received from Antonio Caraballo, Ara Khatchadourian, Aric Schneider, and Praveenkumar
Yerramareddy. Use of the export trade data are subject to Agreement No. 2067-2018-001, Memorandum of
Understanding (MOU) between the U.S. Census Bureau and the Bureau of Labor Statistics (BLS). The BLS has
received prior approval from the U.S. Census Bureau, which affirms that the research results do not present
disclosure risks and approve the publication of the results. All results have been reviewed to ensure that no
confidential information is disclosed.

q Statistics Sweden

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indexes comprising detailed BEA end-use product categories for merchandise goods did
not meet publication criteria in 2020. Furthermore, data collection has become more
difficult as business respondents are less willing to participate in the voluntary business
survey. Challenges to collecting data from sampled businesses are compounded by social
distancing recommendations based on public health guidelines.
The BLS is considering an alternative data source to calculate monthly import and
export price changes and is piloting the approach with export transactions. The data source
is the official administrative trade data set collected by the U.S. Customs and Border
Protection agency that are cleaned and edited by the U.S. Census Bureau for statistical
purposes. This data set comprises nearly all importers’ and exporters’ self-reported
detailed shipment records by the international Harmonized System (HS) product
classification for the United States.
Unit values have been and are used in both import and export price indexes for the most
homogeneous products in which the law of one-price holds, such as commodities traded on
a worldwide exchange. For example, the U.S. import price index for crude petroleum is
currently calculated using unit values derived from the U.S. Department of Energy (DOE)
petroleum transaction import records. The DOE administrative data source is more
reliable than survey data in the face of low company response rates and the price volatility
of this heavily traded product.
However, using unit values, in general, has been criticized for quality concerns. Even
though values and quantities are available in the administrative trade data set and can be
used to calculate average prices and unit value indexes (UVIs), previous research has
shown that unit value indexes often differ significantly from the price indexes that they are
meant to approximate (Alterman 1991; Bradley 2005; Silver 2009). The source of concern
is that differences in the composition and characteristics of transactions comprising a unit
value can lead to movement within and between unit values that are unrelated to price
movements and thus can mismeasure prices. Nonetheless, other research describes how
UVIs can and even should be used in place of traditional methods when homogeneous
items can be defined and when units of measure are consistent (Balk 1998; Dalton and
Fissel 2018; Diewert and Von der Lippe 2010; Silver 2010, 2011).
This research identifies product categories where unit value indexes (UVIs) can
potentially replace price indexes for U.S. exports. The homogeneity of product categories
is ranked using a coefficient of variation test, which identifies items with less price
dispersion. We then calculate UVIs for all product categories and show that UVIs for the
more homogeneous product categories are typically consistent with the comparable
official export price index (XPI). A subset of UVIs are identified as being consistent with
official XPIs.
We compare official export price indexes against all UVIs for 123 5-digit BEA end-use
product categories. The approach identifies a fifth of the UVIs, accounting for USD407
billion in trade (2015), to be of sufficient quality to replace published or augment
otherwise unpublished price indexes, and another fourth, accounting for another USD228
billion in trade (2015), that are potentially useable but are of indeterminate quality. On the
other hand, slightly more than one half of the UVIs, accounting for USD525 billion in
trade (2015), were of poor quality showing a wide range of price variability and unit value
bias common among heterogeneous goods.

Fast et al: Unit Value Indexes for Exports – New Developments

85

We find that replacing current sources with administrative data for the 27 good UVIs
would have a moderate impact on XPI between January 2012 and December 2017. The
export indexes created with administrative data would deflate real exports by 13
percentage points less at the end of 2017, compared with current sources. Incorporating
these 27 indexes into the top-level goods XPI would increase the value of real exports by
2.6 percentage points at the end of 2017.
UVIs’ current prices and quantities potentially improves the current matched model
approach that uses a fixed-basket of weights that is known to overestimate price changes.
Moulton (2018) describes multiples biases in the MXPI-including lower-level sourcing
substitution bias and new product bias-that result from insufficient observations and
lagged weights, issues that can be mitigated using the administrative data. Price experts
describe how unit values could actually mitigate outlet and sourcing substitution bias
(Nakamura et al. 2015, 43 –45). In reviewing Alterman’s (1991) critique of unit value
indexes Nakamura et al. (2015) re-evaluate Alterman’s conclusions. They hypothesize
that the slower increase of the UVI compared to official MPI that Alterman observed for
some product categories could have been an appropriate adjustment for sourcing
substitution bias, rather than a mismeasurement of prices (Nakamura et al. 2015, 52).
Hottman and Monarch’s (2018) research validates Nakamura et al. (2015). When an allgoods import unit value index is calculated with the administrative trade data it shows a
flatter price trend than the modified Laspeyres formula used in the official import price
index, at a rate of about 2% yearly from 1998 to 2014. Reinsdorf and Yuskavage (2018)
also calculate unit values to evaluate sourcing substitution bias of MPIs. All of the research
described above supports the use of unit values to mitigate substitution bias and provides
impetus to our research to calculate UVIs to replace official import and export price
indexes in homogeneous product areas.
Conceptually the ‘unit value indexes’ in our research differ from the U.S. Census’ unit
value indexes criticized by Alterman, and the unit values are more narrowly defined,
approximating Diewert and Von der Lippe’s (2010) classifications of ‘reasonably’
homogeneous products. While traditional price collection methods in the international
price survey typically record a dozen prices per importer or exporter for a few thousand
companies, the U.S. electronic trade transaction data set contains tens of thousands of
transactions for detailed product classifications by company.
Section 2 first describes the constraints and new frontiers faced when blending
alternative data, and particularly the administrative trade data, into official statistics.
Section 3 describes the coefficient of variation test for price dispersion. Section 4 describes
the building blocks of the methodology. Section 5 describes how the quality of the UVIs
was evaluated. Section 6 describes the results and how replacing official XPI with UVIs
would affect measures of real exports. Section 7 concludes with a discussion of the steps to
operationalize the new approach and potential future work.
2.

Requirements for Integrating Alternative Data into Official Statistics

Consideration of detailed U.S. trade transaction data to measure import and export price
indexes is part of an effort by U.S. Bureau of Labor Statistics’ official price statistics
programs to actively pursue alternative data to support the following operational

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objectives-measure price change more accurately, improve BLS management of
respondent burden, expand item and geographic coverage, publish new products, and
achieve cost savings. To move forward with alternative data, the new source is expected to
meet the core measurement objective of the target population by being timely, accurate, and
representative, as well as being consistent with legal and data directives. The methodology
applied to the new data source should be comparable or complementary to the methodology
used for the official price index. Such methods would address quality change, new and
replacement products, sample representativeness, and minimum publishability standards to
ensure representativeness and protect against respondent identification. Alternative data
sources for price indexes would mitigate loss as we maintain, improve, or expand the
components of the relevant market basket. These components include replacement or
expansion of current products, introduction of new products, weights for integrating the
data into the larger market basket, or more frequent prices.
The completeness of the U.S. electronic administrative trade data set and new
constraints on data collection with social distancing in place provide opportunity and
impetus, respectively, to set up statistical production in a way that blends unit values from
the administrative trade data with the directly collected data, and is similar to other efforts
to blend data sources (Reid et al. 2017). This section describes the constraints and new
frontiers to meet these statistical obligations, and looks at how limiting price dispersion
likely improves homogeneity.
2.1.

Constraints on Using Administrative Trade Data

The alternative data proposed to replace or augment direct data collection from businesses
must meet core measurement objectives of the target population by being timely, accurate,
and representative and must use a methodology that should be comparable or
complementary to the methodology used for the official price statistics. These
requirements act as constraints or limitations on the options we have to compute unit
values from the administrative trade data. The high priority constraints described here
relate to (1) timeliness and availability of data, (2) accuracy and representativeness of
homogeneous unit values, (3) consistency of published data for data users, (4) ability to
aggregate lower level UVIs to upper level published indexes.
First, the administrative trade data must meet timeliness and availability constraints to
fit the production schedule of data processing. Sufficient data must be received at the
beginning of each month for the previous month’s data to assure timely and accurate
publication of the preliminary price indexes two weeks after month’s end. The first
publication of the preliminary price index is updated with additional data in the subsequent
three months, but the preliminary index must meet quality standards of representativeness.
Collaboration with other government agencies is ongoing to evaluate how much data can
be made available in time to meet current publication deadlines. Research includes
assessing the quality difference between preliminary and final indexes based on partial and
full month trade data, respectively. This work is ongoing and is not described in detail here.
Second, the accuracy and representativeness of unit value indexes rests on the
homogeneity of the items and their unit values. We find that there is such variability of
product categories that no one item key, or group of transaction characteristics, could

Fast et al: Unit Value Indexes for Exports – New Developments

87

define homogeneity across all product categories. Each product category has a different
mix of goods, and different patterns of trade. The need to mitigate unit value bias while
maintaining item continuity leads us to use the coefficient of variation to evaluate price
variability as a key indicator of homogeneity, or at the minimum, of heterogeneity.
The common definition of unit value bias is the compositional effect on indexes when a
unit value, or average price, is not adequately narrowly defined to represent one item or
product. The choice of index framework will be discussed in the methodology section. As
the Export and Import Price Index Manual advises, direct data collection is preferable to
unit values based on Customs data (International Monetary Fund 2009). Yet of the six
reasons to prefer price survey indexes over unit value indexes, only three pertain to the
BLS MXPI-biases due to changes in the mix of the heterogeneous items in customs
transaction records, poor quality of recorded data on quantities, and infrequent trade of
‘unique’ goods, such as ships and large machinery.” (International Monetary Fund 2009,
xiv). Of these three, the first is the issue that is addressed in our research. The second issue
of missing quantities affects only 10% of U.S. trade transactions, providing millions of
transactions with quantities and total value, compared to the 45% response rates for
exports in the international price survey reported in July 2020 (U.S. Bureau of Labor
Statistics 2020a); and the last concern regarding unique high priced products is not
adequately addressed in price surveys either, given that sampling and pricing methods
exclude infrequent trade of unique items. The compositional differences of product codes
in scanner data have been widely discussed for consumer prices, and we borrow from this
research to consider how U.S. trade transaction records could measure import and export
price changes.
The literature on scanner data informs our approach to defining homogeneous items.
There are differences in the way to bundle transactions to calculate unit values for trade
data, which Nakamura et al. (2015, 56) think bodes well for combining producer products.
Given the production- and contract-driven aspect of international trade, transactions with
shared characteristics will likely be tailored to one supplier or market and will represent
larger dollar amounts than consumer purchases. The broader homogeneity is also
discussed by Diewert and von der Lippe when they describe the tradeoff between
homogeneity and continuity. That is, the narrower the classification of the items, the more
likely prices and quantities will be zero across periods given the sporadic nature of
shipments (Diewert and Von der Lippe 2010, 20). This tradeoff is described
mathematically by Chessa (2019), who evaluates scanner data for the Dutch CPI. A
homogeneous product is defined by balancing two measures: one measure quantifies the
homogeneity of product bar codes and other attributes, while the second measure
expresses the degree to which products can be matched each month to ascertain continuity
of trade and minimize item churn (Chessa 2019).
Because there is such fluidity between all aspects that define homogeneity – price
dispersion, number of grouped characteristics to define an item, and item continuity, we
depend on a qualitative and quantitative comparison of the UVIs with the official price
indexes to evaluate whether a UVI is equivalent enough to the official price index to
replace it.
The third constraint –that the administrative trade data should assure consistency of
published data for data users –goes hand in glove with the accuracy and representativeness

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of both UVIs and the official MXPI. The official import and export price indexes are based
on a methodical and statistically sound approach to sample, interview, and collect data
from U.S. importers and exporters. As a major economic indicator, all aspects of the
survey process are scrutinized with quality performance measures on a quarterly basis.
Nearly a thousand price indexes are systemically reviewed for quality and publishability
as part of monthly publication, and variance statistics assure representativeness.
Since most of the import and export BEA end-use price indexes are used to deflate net
trade in the U.S. GDP, any major difference would need to be explained clearly as breaks
in series could affect the usefulness of the indexes. While it is expected that known upward
biases of lower level substitution should be dampened with the UVIs, any differences that
cannot be explained would reduce the likelihood of acceptance of the new indicator. The
trust of data users in the current data product limits us to refine and define homogeneity in
a way that assures as much continuity as feasible with our directly collected MXPI. It is not
ex-ante clear that unit value indexes are always worse, given that official price indexes
may be based on a small number of price quotes and are constructed using less desirable
index formulas. Matching directly collected data both gives us confidence in the quality of
the UVIs and lets us publish a consistent time series when incorporating UVIs in XPI.
Finally, for consistency of methodology, the data source must be integrated into the
directly collected survey data systemically. Direct data collection begins with elementary
level items whose prices are reported by the respondent for each sampled product the
company recently traded. So too can transaction prices be averaged for individual items,
aggregated at the classification group level and then aggregated to the upper level index.
Each transaction in the data set is a shipping record that is primarily categorized by the
10-digit HS classification and includes a few dozen other transaction characteristics. We
select a subset of these transaction characteristics, including the HS classification, as an
item key. Each unique combination of values for the selected characteristic constitutes an
item. We establish four item keys, each of which uses a different subset of characteristics
to create different items and unit values. The most broadly defined item key is for the
10-digit HS classification, which produces one item and one unit value composed of all
transactions for that product classification. To specify the other three item keys, we heed
the Export and Import Price Manual to select price-determining characteristics of export
items (International Monetary Fund 2009). These include the foreign destination, U.S.
point of origin, domestic producer (U.S. principle party of interest), and other
characteristics, like unit of measure and related vs arms-length trade. The variables and
their abbreviations used in the figures are domestic/re-export goods (F), employer ID (E),
state of origin (S), zip code of export (Z), country of destination (C), U.S. Port (D), quantity
units (Q), related trade indicator (R), and 10-digit Harmonized system classification (H).
Together these variables provide significant detail about trading relationships, but they
provide less detail about the good being traded than would be available in the XPI survey.
We use this information to define items at a level of detail that was not studied in previous
applications. This approach is consistent with the suggestion of Von der Lippe and
Mehrhoff (2010, 7) for improving unit values in German price indexes.
Final price indexes are created through multiple layers of aggregation. Items are combined
to form classification group indexes, which are similar to HS classifications. The
classification group provides continuity when HS classifications change and itself is mapped

Fast et al: Unit Value Indexes for Exports – New Developments

89

through product and industry concordances to the three different classification systems for
which the MXPI are published-product indexes based on the Harmonized System and BEA
end-use, and industry indexes based on the NAICS. Upper level indexes are aggregated from
classification group indexes using a Lowe formula, which the BLS refers to as a modified
Laspeyres formula. The trade weights used in this aggregation are updated once yearly,
lagging the index by two years. A full explanation of the different classification schemes, the
upper level index formula, and the trade weights used by the MXPI is available in the
International Price Program Handbook of Methods (U.S. Bureau of Labor Statistics 2020b).
2.2.

New Frontier of Administrative Trade Data

From constraints to frontiers, there are potential improvements to be gained from using
alternative data sources. The primary reason for revisiting unit value indexes is to reinstate
publication of detailed indexes that no longer meet quality standards due to insufficient
prices or company coverage. The administrative trade data provides much better
representativeness of trade in homogeneous goods, as well as a volume of transactions that
dwarfs in-person data collection. Furthermore, the cost savings realized when
administrative data replace direct data collection would be used to expand the currently
thin coverage of service import and export indexes.
The data source can also mitigate biases that are difficult to address with existing practices.
Access to current prices and quantities provides an opportunity to account for lower level
substitution bias as described by Moulton, which for export price indexes can be described as
producer-side product replacement bias, in which “price changes that occur at the time of
product replacements tend to be dropped,” (Nakamura and Steinsson 2012, 3278).
As Nakamura et al. (2015) show in appendix 2b solutions to export product substitution
and import sourcing substitution bias both necessarily involve averaging unit prices for
different products. They, like we, look to balance homogeneity with substitution, to define
an item that is not so broad as to have unit value bias, but not so narrow that price and
quantity changes of two similar items are not reflected in the index. We consider groupings
of items with broadly and narrowly defined item keys. We find that there is no one item key
for all product categories for which the price index best matches the official price index.
3.

First Steps to Evaluate Price Dispersion and Homogeneity – Coefficient of
Variation

Similar to the proof of concept for unit values described in Fast and Fleck (2022) we
propose using a coefficient of variation test to select homogeneous items as a first step to
evaluate UVIs and the item keys underlying them for unit value bias. The coefficient of
variation test identifies whether within-month price variation of items is small relative to
the mean price of that item, which we take as an indicator that the transactions for each
item involve relatively homogeneous goods. The coefficient of variation is defined for an
item as the standard deviation of the unit value of an item within a month divided by the
mean unit value of the item within a month multiplied by 100. We calculate the coefficient
of variation for each item’s unit value with multiple transactions within a month. A small
coefficient of variation for an item within a month suggests that the physical goods traded
in those transactions are similar. Thus, the transactions comprising the item are more

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Journal of Official Statistics

CDF

likely to represent the same product. Calculating the coefficient of variation within each
month minimizes the role of inflation in causing variation across transactions within an
item, but it also understates variation that may be due to quality changes over time.
We calculate the coefficient of variation for each item in each 5-digit BEA end-use
product category and calculate the distribution of these coefficients across items by
category on a weighted basis for each month. Then, we plot the average of these monthly
distributions. Figure 1 plots the cumulative distribution function (CDF) of the distribution
of item level coefficient of variations by product category. More homogeneous product
categories have many items with small coefficients of variation, indicating less price
variability within a month, which results in a CDF that is above the other lines.
In some cases the lines corresponding to different product categories cross indicating
that one product category has many items that have a small coefficient of variation, but
also some items that are more variable. This makes it difficult to strictly rank the product
categories according to their homogeneity. In the next section, we construct indexes for
each product category and compare them to XPI indexes as a benchmark. We find that
UVIs with CDFs that are generally above the CDF of the seasonal product category
‘vegetables, vegetable preparations, and juices’ almost always are close to the
corresponding XPI index. Thus, we will refer to any product category with a CDF
above that of ‘vegetables, vegetable preparations, and juices’ as homogeneous.

100

75

50

25

0
0

10

20

30

40
Coefficient of Variation

Fig. 1. CDF of Item Coefficient of Variation for 123 BEA end-use product categories. A lower C.V. value
indicates less price dispersion, and the steeper and more concave lines represent product categories with more
items that have less price dispersion. The dark line is the CDF for ‘vegetables, vegetable preparations, and
juices.’ CDFs are calculated for individual months and then averaged across months. The x-axis is truncated at
40 for clarity.

Fast et al: Unit Value Indexes for Exports – New Developments

91

Our results suggest that the coefficient of variation test could be used to identify indexes
with well-defined items for unit values if a published index benchmark is not available.
However, establishing precise thresholds may be challenging because the expected
amount of variation of homogeneous items may vary across settings. Gopinath and Itshoki
(2010) and Gopinath and Rigobon (2008) demonstrate that homogeneous goods
experience both more frequent and larger price changes than differentiated goods in their
analysis of the directly collected import and export price microdata. For our relative
threshold, we choose a detailed item key for vegetables, which results in a relatively flat
but concave cumulative distribution. Vegetable export prices are widely variable, even at
detailed item levels. Both supply and demand are variable, as yield, quality, and
availability depend on growing seasons and weather locally and worldwide. There is also
significant competition in the sector; 2015 – 2016 records report more than 4,000 exporters
monthly, and nearly 1,000 large regular exporters (Fast and Fleck 2019). Missing prices
are filled in by imputation, and this can also cause variability. The combination of
competition, short horizon from field to market, and imputation results in price variability,
even though many of the 161 HS product categories are of nondifferentiated products, like
light red kidney beans, or certified organic asparagus. The index encompasses nearly all
conditions of variability that indexes face. There are 36 product categories that have CDFs
that are generally above that of vegetables. We will refer to these product categories as
homogeneous. There are an additional 18 product categories with CDFs that are similar to
that of vegetables.
Our primary evidence of unit value bias comes from comparing UVIs to indexes created
using directly collected data. The different data sources are used to create indexes that are
blended using a modified Laspeyres formula to calculate overall U.S. Import and Export
Price Indexes. This approach to blending data sources is currently in place for imports of
crude petroleum and exports of grain, sourced from the Energy Information Agency and
Department of Agriculture, respectively.
4.

Computing Unit Value Indexes

This section describes our approach to constructing UVIs. The construction takes place in
three steps. First, unit values for each trade transaction are computed from value and
quantity. Second, unit values for transactions are combined to form item unit values using
a weighted geometric mean. Items are defined by shared characteristics of transactions.
Third, the price relatives of these items are aggregated to a classification group using a
Tornqvist index formula. Finally, the classification group indexes are aggregated to create
123 5-digit BEA end-use indexes using a modified Laspeyres formula. We consider four
different “item keys” which are sets of characteristics. Each set of items related to these
item keys results in different unit values and UVIs. Thus, there are four options for each 5digit BEA end-use index.
4.1.

Calculating Unit Values

The administrative data contain information on the value of shipments and the associated
quantity that can be used to form unit values. We calculate the unit value for a transaction
by dividing the dollar value by the quantity. The unit value P of a transaction s for any

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given month t is the value of the transaction V divided by the quantity of units Q in the
transaction,
Ps;t ¼

V s;t
:
Qs;t

ð1Þ

The transactions, Sk ; associated with some item k, defined as a unique combination of
characteristics, are aggregated using a weighted geometric mean to form a unit value for
each item. The unit value of an item k at some month t is
2
Pk;t ¼ 4

3

1

Y V Sj[Sk V j;t
Ps;ts;t 5
:

ð2Þ

s[Sk

4.2.

Classification Group Unit Value Indexes

The items are then aggregated to the classification group using a To¨rnqvist formula. The
unit value index for classification group c is calculated by aggregating the unit value
indexes for the set of items Kc that belong to classification group c. The weights,
V
wk;t ¼ Sj[Kk;tV j;t , are created using the value of trade associated with an item in some month,
c
V k;t ¼ Ss[Sk V s;t .

Rc;t

W k;t21 þ W k;t
Y Pk;t 
2
¼
k[K c Pk;t21

ð3Þ

Equation (3) describes the month-to-month changes in the classification group UVI.
This is converted to an index level by starting the index at 100 in January of 2012 and
advancing it using Rct : Therefore, the index level for a classification group in a month is
Pc;t ¼ Pc;t1 Rc;t

ð4Þ

with Pc,0 ¼ 100.

4.3.

Forming 5-Digit BEA End Use Indexes

For this article we focus on aggregating the indexes to the 5-digit BEA end-use product
category because that is the level at which decisions about whether to use unit value
indexes for a given set of classification group indexes will be made. Eventually the
classification group unit value indexes will be used as the building blocks for HS, BEA
end-use, and NAICS based indexes. These indexes will be combined with price indexes
from directly collected data using a modified Laspeyres index formula. The weights used
to aggregate from classification group to BEA end-use product category are lagged values
for consistency with directly collected data. The weights used in the MXPI are lagged two
years due to delays in the availability of real-time weights. The formula for the unit value
index for BEA end-use product category e is

Fast et al: Unit Value Indexes for Exports – New Developments

Re;t ¼

X

V c;b
Pc;t
S
V
P
c[C e i[C e i;b c;t21

93

ð5Þ

This is converted to an index level by starting the index at 100 in January of 2012 and
advancing it using Re;t : Therefore, the index level for a product category in a month is
Pe;t ¼ Pe;t1 Re;t

ð6Þ

with Pe;0 ¼ 100:

4.4.

Missing and New Items

Our approach to missing and new items is similar to the approach used in the official
MXPI. When an item is missing, we impute a price for the item using cell mean imputation
for up to three months before discontinuing the series. For directly collected data, there are
attempts to replace discontinued items and contact respondents for missing prices,
whereas for administrative data a missing price for an item indicates that no trade
occurred. An item naturally occurs as trade transactions begin, and we pre-impute a price
in the month before the item enters using cell mean imputation.

4.5.

Possibilities for Improvement and Caveats

There are a number of ways in which unit value indexes with administrative data may
improve on the official XPI. The administrative data eliminate issues with
representativeness of trade and response rate concerns. The data also allow us to address
changes in trade in a timelier manner.
The administrative data could potentially expand the number of detailed published
indexes, because two major hurdles with directly collected data are avoided.
Representativeness of trade and nonresponse are no longer problems when transaction
records comprise the universe of trade. Administrative trade data permit detailed indexes
to be published at whatever level that trade occurs, while the directly collected data are
based on a voluntary survey. Indexes must meet quality review standards of sample
representativeness and index quality. The number of sample units is distributed across all
merchandise goods categories by their trade weight to assure representativeness for the
aggregate MXPI, but this sacrifices more detailed index representativeness. Even though
item prices are collected, detailed indexes are not representative of the trade if the trade
dollar value is below the cut-off. For product categories meeting the trade dollar cut-off,
nonresponse negatively affects publishability as measures for representativeness of
companies, number of companies, and number of items are all used as publishability
standards. Nonresponse is a nonissue for administrative data.
Using current values and quantities with administrative data allows for the
incorporation of new goods and replacement of substitutes. New and exiting goods are
accurately counted because the complete data set accounts for all current trade.
Furthermore, substitution with classification groups can be addressed because the
availability of current trade values allows us to use a superlative index formula.

94

5.

Journal of Official Statistics

Comparison of UVIs to XPI Benchmarks

After calculating UVIs for each item key and product category, we must determine which
are of sufficient quality to replace the product category’s XPI counterpart. Our first criteria
is agreement with the relevant XPI when the XPI is of sufficient quality to be used as a
benchmark. We evaluate agreement for each of the four item keys under consideration and
manually choose the best key for each product category and rate the quality of the fit. This
analysis used graphs of index levels, month-to-month changes, and statistics measuring
the quality of the fit. Then, we evaluate the performance of this “best” item key against
XPI using both the manual ratings and multiple statistics that measure the quality of fit.
Our focus in evaluating the quality of fit is on long-term agreement between the two index
levels. Finally, we discuss what we do when the official XPI may not be a reliable
benchmark.
5.1.

Identifying “Best” Item Keys and Visual Analysis

Our first step of determining which unit value indexes were potentially able to replace
official price indexes was to have research team members manually review each index.
Each member studied each of the BEA end-use product categories individually using
graphs of index levels, month-to-month changes, and statistics comparing the fit of each
index. They identified the item key that was the best fit and rated the fit of that key as either
“good”, “undecided”, or “poor”. Examples of each type of index are presented in Figures 2,
3, and 4. In each figure, we show the index levels and month-to-month changes for each
item key and the XPI benchmark. All three examples involve published XPI indexes that
are considered to be high quality. Figure 2 is an example of a “good” index. The best item
key is HECQR, a key with a medium amount of detail. The UVI tracks the XPI index very
closely. The UVI generated using just information on HS product codes, the H key, has
large spikes and performs much worse. Figure 3 shows an “undecided” index. The best
item key is H. In this case, the unit value index is less close to the XPI benchmark. There
are multiple times where the UVI increases significantly more than the XPI benchmark,
but the levels are generally close until the final year. In this case, there is some hope that
with further improvements to our methodology, such as using a different item key or
handling outliers different, a UVI could be used. Figure 4 shows a “poor” index where
there is little reason to believe a unit value index could be used for this BEA end-use
product category. The more detailed keys generally perform better, but none of the keys
performs very well.
Table 1 shows the rating of the indexes and groups the number of BEA end-use product
categories by rating and publication status of official XPI. When there was disagreement
between team members, the more common rating was used. Disagreements were relatively
rare and only involved whether an index was “good” or “undecided” or whether an index
was “undecided” or “poor”.
Manually reviewing the indexes allows us to consider multiple pieces of information
simultaneously when rating indexes, but the process is time consuming as we evaluate the
impact of alternative methodologies. Additionally, manual ratings can vary across
individuals and time. In the following subsection, we describe our approach to develop
acceptance rules based on statistical comparisons. We search for a set of acceptance

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Month-to-Month Percent Change

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25

0

–25
2012

2014

Month-to-Month Percent Change

H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

160

140

120

100
2012

2014
H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

Fig. 2. Example of product category with a “good” UVI. The best key is HECQR. The product category is
“Other animal feeds, not elsewhere classified.” The top panel depicts month-to-month percent changes. The
bottom panel depicts index levels.

criteria that can be applied to our data. The goal of these criteria is to approximate the
manual review. We focus on a set of criteria that can differentiate between “good” and
“poor” indexes.
5.2.

Statistical Comparison

We considered multiple statistics to create a set of criteria to rate unit value indexes. The
criteria use information on both index levels and month-to-month changes. From the initial

Journal of Official Statistics

Month-to-Month Percent Change

96

10

5

0

–5

–10
2012

2014

Month-to-Month Percent Change

H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

120

110

100

90

80

2012

2014
H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

Fig. 3. Example of a product category with an “undecided” UVI. The best key is H. The product category is
“Fruit and fruit preparations, including fruit juices.” The top panel depicts month-tomonth percent changes. The
bottom panel depicts index levels.

set of statistics we identified three that jointly had significant predictive power for whether
an index would be classified as “good” by the manual review. We describe the three
statistics that had significant predictive power and what values of these statistics generally
indicated a good index.
Previous work has used a wide range of statistics to evaluate whether price indexes
generated with alternative data are similar to benchmark indexes, but there is significant
disagreement about which tests should be used and what the appropriate thresholds are
(Fitzgerald and Shoemaker 2013). The appropriate threshold will depend on the needs of

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Month-to-Month Percent Change

Fast et al: Unit Value Indexes for Exports – New Developments

400

300

200

100

0

2012

2014

Index Level

H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

1500

1000

500

2012

2014
H

HECQR

2016
HFESCQR

HFESZCDQR

2018
Date
XPI

Fig. 4. Example of a product category with a “poor” UVI. The best key is HFESCQR, but that is not a close
approximation to the official XPI. The product category is “Industrial inorganic chemicals.” The top panel
depicts month-to-month prercent changes. The bottom panel depicts index levels.

data users and potential benefits of replacing official indexes with alternative data. It will
also depend on whether it is most important for the UVIs and benchmark to have similar
month-to-month changes or longterm trends. Certain statistics, such as the root mean
squared error between the month-to-month changes in indexes, can indicate agreement
over the short term, but lead to large long-term differences if the monthly misses are all in
a certain direction.
We identified three statistics that together seemed to have the most predictive power.
They are the fifth largest absolute difference between index levels, the intercept of a

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Journal of Official Statistics

Table 1. Number of BEA end-use product categories receiving a rating by published status.

Rating
Good
Undecided
Poor

Published

Unpublished

Total

15
11
24

12
21
40

27
32
64

Notes: Numbers are the count of BEA end-use product categories manually assigned a rating.
Columns differentiate between product categories that are published and those that are not.

regression of index levels of the unit value index on XPI price index levels, and a t-test of
whether the month- to-month changes have the same mean. For each statistic, we suggest
an approximate cutoff value to differentiate the “good” and “poor” UVIs. These cutoff
values were chosen jointly as the values such that satisfying all three cutoffs indicated a
“good” UVI and failing one or more indicated a “poor” UVI. We experimented with
multiple combinations of statistics and with treating the “undecided” UVIs as either
“good” or “poor”. The set of three statistics proposed here and their associated cutoffs
represent the choices that consistently performed well at minimizing misclassification of
“good” and “poor” UVIs. They should be treated as guidelines to quickly evaluate the
quality of generated indexes before a more rigorous review.
The fifth largest absolute difference tests whether index values stay close to each other
over time. Using the fifth largest difference allows for temporary differences between
indexes if the indexes come back together before five months have passed. We find there
are cases where indexes have large differences for a month or two, but otherwise match
well. Therefore, we prefer the fifth largest difference over a test such as the maximum
difference. We also considered using the percentage difference accounts for differences in
index levels due to different growth rates across BEA end-use product categories, but the
% difference is not symmetric. We find that a fifth largest absolute difference of less than
22 index points is a necessary condition for a unit value index to receive a “good” rating.
The second test comes from running a regression of the index values of the unit value
index on the index value of the XPI. If the values of the two indexes were always in
agreement the estimated parameters would be an intercept of zero and a slope of one.
These tests are similar to testing for a strong positive correlation between the two series.
However, this test avoids cases where series are correlated, but diverge because in those
cases either the slope or intercept will be far from its target value. We have generally found
that an estimated intercept of less than 50 is indicative of a “good” UVI. Recall that the
indexes are 100 in their base period which helps explain the rather large cutoff. Figure 5
illustrates this test using the “good” index from Figure 2. The points are generally near the
45-degree line, but the UVI tends to exceed the XPI index level when both levels are low.
Then, when index levels have grown, the UVI is consistently less than the XPI index level.
Table 2 The third test is a paired t-test. The test checks whether the means of the monthto-month changes of the two indexes are different. The null hypothesis of this test is that
the month-to- month changes from the two indexes come from the same distribution. We
use the p-value of the paired t-test as the value we track. A large p-value indicates that the
null hypothesis cannot be rejected which is the goal of this test. We find that a p-value
greater than 0.5 is typically indicative of a “good” UVI.

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Unit Value Index Level

Fast et al: Unit Value Indexes for Exports – New Developments

y = 27+0.76∙x, r2 = 0.925
130

120

110

100

100

110

120

130

140
XPI Index Level

Fig. 5. Regression of Unit Value Index Levels on XPI Index Levels. Each point represents the index levels for a
month. The 45 degree line is included as a dashed line. The solid line is a linear regression line and the equation
for the line is at the top left of the figure along with the R-squared of the regression. The product category is
“Other animal feeds, not elsewhere classified.” The UVI for this product category is plotted in Figure 2.

Table 2. Average of three main statistics by manual UVI rating and published status.

Difference
Intercept
T-Test

Good

Published
Undecided

Poor

Good

Unpublished
Undecided

Poor

8.91
34.11
0.80

23.75
124.14
0.30

172.76
2162.52
0.14

13.25
29.97
0.83

26.44
101.37
0.57

492.90
2804.93
0.21

Notes: Average of each statistic for indexes in each group. Difference is the fifth largest absolute difference.
Intercept is the intercept of a regression of the index values of the unit value index on the index value of the XPI.
T-test is the p-value from a paired t-test using the month-to-month changes of both indexes. Lower values indicate
more agreement for the difference and intercept. Higher value indicate more agreement for the t-test. Published
indicates the BEA end-use product category is published by the XPI, indicating it is a more reliable benchmark.

Table 3 presents results for additional statistics to show that these follow the same
trends with the “good” product categories performing the best. The results of these
statistics are broadly consistent with the results presented above. However, in each of these
cases, we found instances where the statistic indicated significant agreement, but the
manual review indicated the UVI was not a good match with the XPI benchmark. The
table shows that mean absolute difference in month-to-month changes between the UVIs
in published product categories that received a “good” rating and their corresponding XPI

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Journal of Official Statistics

Table 3. Average of three Main Statistics by manual UVI rating and published status.

RMSE
MAD
Sign Agreement

Good

Published
Undecided

Poor

Good

Unpublished
Undecided

Poor

3.35
2.50
67.81

15.66
4.15
58.18

36.64
12.03
48.63

4.30
3.10
55.71

5.58
3.84
48.03

60.55
25.97
44.54

Notes: Average of each statistic for indexes in each group. RMSE is the root mean-squared error between the
month-to-month % changes. MAD is the mean absolute difference between the month-to-month % changes. Sign
agreement is the percentage of months where the sign of the month-to-month changes is the same. Published
indicates the BEA end-use product category is published by the XPI, indicating it is a more reliable benchmark.

index is 2.5 percentage points. The sign of the month- to-month changes agreed 67.81% of
the time. The “undecided” indexes performed slightly worse with a difference of 4.15
percentage points, agreeing only 58.18% of the time. The “poor” indexes performed the
worst by far with a difference of 12.03 percentage points, but the sign of the change still
agreed over 48% of the time.
6.

Results

Table 4 shows that 28.7% of the share of goods export trade could be represented by good
quality unit value indexes valued at USD407 billion of 2015 trade, counting both
published and unpublished XPI indexes. If the undecided unit value indexes were to have a
better fit with different assumptions, an additional 16% of export trade could use unit value
indexes to measure price change. Of the undecided unit value indexes, 21 (representing
9% of trade) are not published. The discrepancy between unit value indexes and XPI could
be because XPI is not a good benchmark. Seven of the 21 product categories are more
homogeneous than “vegetables” so using unit value indexes for at least these product
categories may be possible. There are 64 unit value indexes that are considered poor,
representing 56.6% of the value of trade. Forty of these come from unpublished indexes,
but only two of the 40 product categories are more homogeneous than “vegetables” so it
appears likely that many of the poor fitting unit value indexes should not replace the XPI
index. Most of the remaining product categories are heterogeneous goods such as
machinery that are not suitable for UVIs.
Table 4. Manual rating by published status.

Published
Yes
No
Yes
No
Yes
No

Rating

Number of
Indexes

Trade USD
Value

Share of
Indexes

Share of
Trade USD

Good
Good
Undecided
Undecided
Poor
Poor

15
12
11
21
24
40

271
136
100
128
307
218

12.1
9.8
8.9
17.1
19.5
32.5

19.1
9.6
7.1
9.0
21.6
15.4

Notes: Published indicates whether XPI publishes a detailed index for a given product category. Rating is the
consensus rating from manual review. The trade USD value is in 2015 billions.

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Fast et al: Unit Value Indexes for Exports – New Developments

6.1.

Homogeneity Matters

CDF

Even though evaluating homogeneity was not the primary test of index comparability, the
use of the coefficient of variation is supported by the results. Figures 6, 7, and 8 show the
CDFs of the coefficient of variation for the product categories with good UVIs (Figure 6),
undecided quality UVIs (Figure 7), and poor quality UVIs (Figure 8). The product
categories with good indexes have coefficient of variation CDFs that are usually above the

100

75

50

25

0
0

10

20

30

40
Coefficient of Variation

CDF

Fig. 6. CDF of Item Coefficient of Variation for 27 BEA end-use product categories that received a “good”
rating. Lines represent the fraction of items in a product category that have a coefficient of variation below a
given number. CDFs are calculated for individual months and then averaged across months. The darker line is
the CDF for ‘vegetables, vegetable preparations, and juices.’ The x-axis is truncated at 40 for clarity.

100

75

50

25

0
0

10

20

30

40
Coefficient of Variation

Fig. 7. CDF of Item Coefficient of Variation for 32 BEA end-use product categories that received an
“undecided” rating. Lines represent the fraction of items in a product category that have a coefficient of variation
below a given number. CDFs are calculated for individual months and then averaged across months. The darker
line is the CDF for ‘vegetables, vegetable preparations, and juices.’ The x-axis is truncated at 40 for clarity.

Journal of Official Statistics

CDF

102

100

75

50

25

0
0

10

20

30

40
Coefficient of Variation

Fig. 8. CDF of Item Coefficient of Variation for 64 BEA end-use product categories that received a “poor”
rating. Lines represent the fraction of items in a product category that have a coefficient of variation below a
given number CDFs are calculated for individual months and then averaged across months. The darker line is the
CDF for ‘vegetables, vegetable preparations, and juices.’ The x-axis is truncated at 40 for clarity.

vegetables CDF. The product categories with undecided quality UVIs are more mixed,
while the product categories with poor quality UVIs are almost always below the CDF of
vegetables.
6.2.

Impact on Gross Domestic Product

MXPI at a detailed level are used as deflators for net exports by both the US Census and
the Bureau of Economic Analysis. Net exports are a component of Gross Domestic
Product. If the administrative data actually provide more and better quality statistics with
the administrative trade data, they will contribute to improving the measure of GDP.
To simulate the impact of replacing the historic BEA end-use 5-digit export price
indexes for 2012– 2017, price indexes for each subgrouping of the “good”, “undecided”,
and “poor” price indexes are aggregated and the difference between the trade-weighted
unit value index endpoint of December 2017 is aggregated for each quality group relative
to that of the corresponding official export price indexes – first for the partial aggregation
and then to the top-level index, holding all else equal. As can be seen in Table 5, the 27 5digit BEA end-use “good” unit value indexes show a December 2017 index value of 75.62.
This compares to the estimate of the corresponding official XPIs of 83.87. The total dollar
value of these indexes is 29% of export trade. Calculating the impact on all goods’ export
prices is done by assuming that the other 71% of trade value does not change prices.
Applying official MXPI methodology, the 5-digit indexes are aggregated to an all-goods
measure, which results in a top-level aggregate unit value index of 93.00 and the official
XPI of 95.37. The price change gap in the “good” price indexes is 8.3 percentage points
over the six years. For the top-level index comparison, the price gap between the “good”
unit value indexes versus the historic official price indexes is 2.4 percentage points from
2012 to 2017. That is, if the “good” unit value indexes were to be incorporated into the all-

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Fast et al: Unit Value Indexes for Exports – New Developments

Table 5. Effect of UVIs on XPI price indexes.

Index
classification

Average of
detailed XPI
price
indexes

Average of
detailed unit
value
indexes

Constant
all-goods
official price
index

Constant
all-goods
unit value
index

% of total
trade USD
value

83.87

75.62

95.37

93.00

29

100.22

119.52

100.04

103.13

16

99.43

312.09

99.68

220.20

57

Good
(N¼ 27)
Undecided
(N¼ 32)
Poor
(N¼ 64)

Notes: Columns 2 and 3 calculate a price index by combining the BEA end-use product categories that receive a
given manual rating. Columns 4 and 5 compare the overall goods index when the UVIs with a given rating are
used instead of the XPI indexes for those product categories.

goods XPI, export prices would have risen 2.4 percentage points more. In addition, when
applied as deflators, real export prices would have fallen by 2.4 percentage points more.
The same thought experiment comparing the “undecided” unit value indexes with their
comparable 5-digit official price indexes results in a gap of 3.1 percentage points in the
other direction. This gap is only slightly larger than the 2.4 percentage point different for
the “good” indexes, but this fact is because the “undecided” indexes account for only 16%
of the value of exports, much less than the 29% for good indexes. The “poor” unit value
indexes show an extreme price gap of over 100 percentage points.
This range of price gaps and the extreme variability for the “poor” quality grouping
validates the basic tenet of minimizing price variability and maximizing substitutability
that guides this research and qualitatively affirms that the three quality bins are reasonable.
The effort to measure the impact on net trade and thus GDP will depend on the results
from the import comparison. Hypothetically, if there were a commensurate adjustment
upward to the import index prices, and thus downward impact on real goods imports, the
impact on net trade may be small, and thus have a minimal impact on GDP. The direction
of the impact is sensitive to the choice and number of indexes determined to be “good”.
The different composition of imports, with a larger share of heterogeneous products, must
be calculated before the possible impact on the real trade balance and GDP can be
measured.

7.

Conclusion

This research on a large-scale transition to using administrative data develops an
exhaustive approach to evaluate product variety, price variability, substitutability, and
index comparability for potential replacement in the official MXPI. The results show that
not all unit value indexes are the same and that unit value indexes most likely to replace
official MXPI measures are homogeneous and should closely align with the index they
replace. The ambiguity of some of the indeterminate quality indexes may lie in the fact
that there is no comparable published official XPI, or that the product variety itself is
broad.

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The test run of unit value indexes for 123 detailed product categories over six years
shows that defining homogeneity matters, and that one can develop statistical tests and
create cutoffs to evaluate differences and make judgments on the consistency, reliability,
and comparability of unit value indexes relative to the official export price indexes.
Product categories representing 43% of the value of exports could potentially be replaced
by unit value indexes if future research is able to convert all “undecided” indexes into
“good” indexes. Ongoing approaches attempt to improve the quality of these unit value
indexes, by evaluating the product variety key, the bias introduced by the new
methodology, and/or the nonresponse bias in the official price index.
Research continues to be evaluated and refined. Some efforts to estimate hedonic linear
regressions on the complete data set to develop a systematic method of identifying the best
item key combination for each strata are constrained by IT capacity. Exploring timedummy hedonic models may reduce the specification constraints of grouping data
variables and calculating indexes for items. At the margins, improvements to the quality of
the “good” set of indexes and additionally “undecided” indexes possibly can move to the
“good” category. The Tornqvist index formula helps with substitution bias at the
classification group level, but it introduces new concerns because it is a monthly-chained
index. Frequent chaining has been determined to exacerbate chain drift (Ivancic et al.
2011; De Haan and Van der Grient 2011). Thus, work is being done to measure chain drift
in the UVIs and investigate alternative aggregation methods, such as the base construction
strategy described by Statistics Finland (Nieminen and Montonen 2018).
In addition, work will be done to analyze and compare import unit value indexes with
official import price indexes and to calculate partial-month measures with low variance
compared to full-month data. These two large projects must be addressed before the
project to blend administrative data into official import and export price measures can
begin.

8.

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Received May 2020
Revised January 2021
Accepted May 2021


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