Full text of Economic Impact of COVID-19 : Special Reports : Some Observations About Social Distancing Across Space and Time

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May 15, 2020

Economic Impact of COVID-19
Some Observations about Social Distancing
across Space and Time
By Marios Karabarbounis and Nicholas Trachter
Uncertainty about the risk of contracting COVID-19 and strict lockdown measures induced
workers and consumers to drastically change
their work and consumption habits. Nonessential
workers substituted working at the office with
working at home. Consumers reduced the number of shopping trips, concentrating their shopping in fewer (larger) stores and increasing their
online shopping. Although these patterns seem
indisputable, the extent of the changes remains
an open question.
One way to quantify the magnitude of these
changes is to use mobility indexes. In particular,
we use mobility indexes from anonymized cell
phone data that track individuals through space
and time. With the aim of generating research to
understand the effect of the COVID-19 pandemic,
companies that usually do not share such data,
or that typically sell it, are currently making some
or all of the data available. We use data produced
by the Maryland Transportation Institute (MTI)
at the University of Maryland.1 The data include
information on the beginning and the endpoint
of each trip taken by residents of a region, as well
as the reason for the trip. The data are available at
the county, city, state, and national levels and are
presented at a daily frequency.

May 2020 – Richmond Fed

We use two different variables as indicators of
mobility: first, the fraction of people staying at
home, defined as no trips farther than a mile
away from home; and second, the average number of miles traveled per person via all modes
of transportation (walk, bike, car, train, bus,
and plane, among others). We analyze the time
period March 2 to April 27. We choose this time
period because we want to focus strictly on the
lockdown period.
Staying at Home
The left panel of Figure 1 shows the difference
in the percent of people staying home across
U.S. states between March 2 and April 27. The
right panel presents the same differences across
counties within the Richmond Fed’s district (the
Fifth District). Both plots show substantial spatial
variation, potentially related to differences in
population density and how easy it is to shop
online and/or close to home. The highest increases in the percent of people staying at home
at the state level occurred in New Jersey and
New York, while the lowest increases occurred in
North Dakota and South Dakota. Within the Fifth
District, the highest increases in the fraction of
people staying at home occurred in the counties
surrounding major cities, particularly in Northern
Virginia.

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Figure 1: Fraction of People Staying at Home, across Space

Figure 2 shows the time series of the fraction of
people staying at home. The left panel presents it for
Manhattan, Richmond, and Washington, D.C., and
adds the U.S. time series for comparison. The right
panel presents the time series for the Fifth District
as whole, the state of New York, and the U.S. Overall,
the figure reveals that: i) the fraction of people staying home increased sharply between March 10 and
March 25 and stabilized thereafter; and ii) there are
daily movements in the fraction of people staying
home -- in particular, more people stay home on
the weekends. Also, the figure shows that the city
of Richmond experienced a lower increase in the
fraction of people staying home than Manhattan and
Washington, D.C.

Why did Richmond experience a lower increase?
It may be related to the city’s lower population
density. If the probability of infection increases
with the frequency and length of close contacts
among people, a location’s population density
should play an important role in explaining
spatial differences. At the end of the memo we
confirm the link between a location’s population
density and the decline in mobility observed in
the location. The right panel of the figure shows
the same pattern for the Fifth District as a whole
when compared with New York state. Another
interesting fact is that the Fifth District follows
closely the time series for the U.S.

Figure 2: Fraction of People Staying at Home, across Time
Regions, Normalized to 0 at Date 0
35

30

30

25

25

Percent Staying Home

Percent Staying Home

Ci�es, Normalized to 0 at Date 0
35

20
15
10
5
0
-5
3/2/20

20
15
10
5
0

3/9/20
U.S.

3/16/20

3/23/20

Manha�an

3/30/20
Richmond

4/6/20

4/13/20

4/20/20

Washington, D.C.

4/27/20

-5
3/2/20

3/9/20

3/16/20 3/23/20 3/30/20
U.S.
Fi�h District

4/6/20
4/13/20
New York

4/20/20

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4/27/20

Miles Traveled
Figure 3 shows, for the period March 2 to April 27, the
log difference in average miles traveled per person in
each state in the U.S. (left panel) and each county in
the Fifth District (right panel). This index is inversely
related to the change in the fraction of residents
staying home.
Figure 3: Miles Traveled per Person, across Space

Figure 4 shows the time series for the log difference
in miles traveled. While the average person in Richmond traveled 25 percent fewer miles on April 27
relative to March 2, the average person in New York
City and Washington, D.C., traveled approximately 60
percent fewer miles on April 27 compared to March
2. A similar pattern is observed for the Fifth District as
a whole.
Figure 4: Miles Traveled per Person, across Time
Ci�es, Normalized to 1 at Date 0

Regions, Normalized to 1 at Date 0
1.2
1.1
1

1

Miles Per Person

Miles Per Person

1.2

0.8
0.6

0.8
0.7
0.6
0.5

0.4
0.2
3/2/20

0.9

0.4
3/9/20
U.S.

3/16/20

3/23/20

Manha�an

3/30/20
Richmond

4/6/20

4/13/20

4/20/20

Washington, D.C.

4/27/20

0.3
3/2/20

3/9/20

3/16/20
U.S.

3/23/20

3/30/20

Fi�h District

4/6/20

4/13/20

4/20/20

4/27/20

New York

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Density and Miles Traveled
We suggested that regional differences in the decline
in miles traveled might result from differences in
population density across space. Here, we explicitly
test the link between the population density of a
location and the change in average miles traveled
per person. Figure 5 presents a scatter plot with the
log of population density of a location in the x-axis
(states in the left panel and counties in the right
panel) and the log difference in average miles traveled per person between March 2 and April 27 in the
y-axis. As conjectured above, the figure confirms
a strong connection between a location’s population density and the decrease in miles traveled per
person. In particular, according to the state-level
analysis, a 100 percent increase in a state’s population density decreases miles traveled by the average
person in the state by 5.5 percent.

a negative relationship between a location’s population density and the decline in distance traveled by
the location’s residents. In other words, areas with
high population density had larger declines in distance traveled.
If this is the case, why did we see more infections in
New York City than in Richmond? Population density
could also be playing a role: Walking a short distance
to buy goods does not have a lower infection probability than walking a long distance if, during the
short walk, the person bumps into a large amount of
people relative to the long walk. Under this hypothesis, the fact that New York City has a higher incidence
of COVID-19 in its population relative to Richmond
implies that New York City actually experienced a
smaller decrease, relative to its population density, in
miles traveled per person than Richmond. Why didn’t
we observe an even larger adjustment in miles trav-

Figure 5: Population Density and Miles Traveled

-0.1

0

2

4

Coun�es
6

8

10

-0.2
-0.3
-0.4
-0.5
-0.6
-0.7

y = -0.0551x - 0.1608

-0.8
-0.9
Log of Popula�on Density

What explains this link? Locations with high population density have more establishments within an
industry per square mile. This implies that residents
of high population density locations can travel fewer
miles in order to purchase the same bundle of goods
than residents of low population density locations. In
the presence of the possibility of COVID-19 infection,
locations with more establishments per square mile
allow their residents to reduce the risk of infection by
purchasing goods in nearby locations. This results in

Log Difference of Miles Traveled per Person

Log Difference of Miles Traveled per
Person

States
0

2

4

6

8

10

1
0.5
0
-0.5
-1
-1.5

y = -0.062x + 0.015
Log of Popula�on Density

eled in New York City that would make the infection
probability equalized across locations? One compelling argument is that establishments require some
minimum amount of space to operate, preventing
establishments from being as close as required to
their customers. Thus, reducing the infection rate in
New York City, through further reducing the miles
traveled by its residents, is bounded above by indivisibilities in establishments.

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Marios Karabarbounis is an economist and Nicholas
Trachter is a senior economist in the Research Department of the Federal Reserve Bank of Richmond.
Endnotes
1

M
 aryland Transportation Institute, University of Maryland
COVID-19 Impact Analysis Platform

This article may be photocopied or reprinted in its
entirety. Please credit the authors, source, and the
Federal Reserve Bank of Richmond and include the
italicized statement below.
Views expressed in this article are those of the authors
and not necessarily those of the Federal Reserve Bank
of Richmond or the Federal Reserve System.

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