Order Code RL30711
CRS Report for Congress
Received through the CRS Web
The House Apportionment Formula
in Theory and Practice
October 10, 2000
David C. Huckabee
Specialist in American National Government
Government and Finance Division
Congressional Research Service ˜ The Library of Congress

The House Apportionment Formula in Theory and Practice
Summary
The Constitution requires that states be represented in the House in accord with
their population. It also requires that each state have at least one Representative, and
that there be no more than one Representative for every 30,000 persons.
Apportioning seats in the House of Representatives among the states in
proportion to state population as required by the Constitution appears on the surface
to be a simple task. In fact, however, the Constitution presented Congress with issues
that provoked extended and recurring debate. How may Representatives should the
House comprise? How populous should congressional districts be? What is to be
done with the practically inevitable fractional entitlement to a House seat that results
when the calculations of proportionality are made? How is fairness of apportionment
to be best preserved?
Over the years since the ratification of the Constitution the number of
Representatives has varied, but in 1941 Congress resolved the issue by fixing the size
of the House at 435 Members. How to apportion those 435 seats, however,
continued to be an issue because of disagreement over how to handle fractional
entitlements to a House seat in a way that both met constitutional and statutory
requirements and minimized unfairness.
The intuitive method of apportionment is to divide the United States population
by 435 to obtain an average number of persons represented by a Member of the
House. This is sometimes called the ideal size congressional district. Then a state’s
population is divided by the ideal size to determine the number of Representatives to
be allocated to that state. The quotient will be a whole number plus a remainder–say
14.489326. What is Congress to do with the 0.489326 fractional entitlement? Does
the state get 14 or 15 seats in the House? Does one discard the fractional
entitlement? Does one round up at the arithmetic mean of the two whole numbers?
At the geometric mean? At the harmonic mean? Congress has used or at least
considered several methods over the years–e.g., Jefferson’s discarded fractions
method, Webster’s major fractions method, the equal proportions method, smallest
divisors method, greatest divisors, the Vinton method, and the Hamilton-Vinton
method. The methodological issues have been problematic for Congress because of
the unfamiliarity and difficulty of some of the mathematical concepts used in the
process.
Every method Congress has used or considered has its advantages and
disadvantages, and none has been exempt from criticism. Under current law, however,
seats are apportioned using the equal proportions method, which is not without its
critics. Some charge that the equal proportions method is biased toward small states.
They urge that either the major fractions or the Hamilton-Vinton method be adopted
by Congress as an alternative. A strong case can be made for either equal proportions
or major fractions. Deciding between them is a policy matter based on whether
minimizing the differences in district sizes in absolute terms (through major fractions)
or proportional terms (through equal proportions) is most preferred by Congress.

Contents
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Constitutional and Statutory Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 2
The Apportionment Formula . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
The Formula In Theory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Challenges to the Current Formula . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Equal Proportions or Major Fractions: an Analysis . . . . . . . . . . . . . . . . . . 10
The Case for Major Fractions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
The Case for Equal Proportions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Appendix: 1990 Priority List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
List of Tables
Table 1. Multipliers for Determining Priority Values
for Apportioning the House by the Equal Proportions Method . . . . . . . . . . 6
Table 2. Calculating Priority Values for a Hypothetical Three
State House of 30 Seats Using the Method of Equal Proportions . . . . . . . . 6
Table 3. Priority Rankings for Assigning Thirty Seats
in a Hypothetical Three-State House Delegation . . . . . . . . . . . . . . . . . . . . 7
Table 4. Rounding Points for Assigning Seats
Using the Equal Proportions Method of Apportionment* . . . . . . . . . . . . . . 9

The House Apportionment Formula in Theory
and Practice
Introduction
One of the fundamental issues before the framers at the Constitutional
Convention in 1787 was how power was to be allocated in the Congress among the
smaller and larger states. The solution ultimately adopted, known as the Great (or
Connecticut) Compromise, resolved the controversy by creating a bicameral Congress
with states represented equally in the Senate, but in proportion to population in the
House. The Constitution provided the first apportionment of House seats: 65
Representatives were allocated to the states based on the framers’ estimates of how
seats might be apportioned after a census. House apportionments thereafter were to
be based on Article 1, section 2, as modified by the Fourteenth Amendment:
Amendment XIV, section 2. Representatives shall be apportioned among
the several States ... according to their respective numbers....
Article 1, section 2. The number of Representatives shall not exceed one
for every thirty Thousand, but each State shall have at least one
Representative....
From its beginning in 1789, Congress was faced with questions about how to
apportion the House of Representatives–questions that the Constitution did not
answer. How populous should a congressional district be on average? How many
Representatives should the House comprise? Moreover, no matter how one specified
the ideal population of a congressional district or the number of Representatives in the
House, a state’s ideal apportionment would, as a practical matter, always be either
a fraction, or a whole number and a fraction–say, 14.489326. Thus, another question
was whether that state would be apportioned 14 or 15 representatives?
Consequently, these two major issues dominated the apportionment debate: how
populous a congressional district ought to be (later re-cast as how large the House
ought to be), and how to treat fractional entitlements to Representatives.1
1 Thomas Jefferson recommended discarding the fractions. Daniel Webster and others argued
that Jefferson’s method was unconstitutional because it discriminated against small states.
Webster argued that an additional Representative should be awarded to a state if the fractional
entitlement was 0.5 or greater–a method that decreased the size of the house by 17 Members
in 1832. Congress subsequently used a “fixed ratio” method proposed by Rep. Samuel Vinton
following the census of 1850 through 1900, but this method led to the paradox that Alabama
lost a seat even though the size of the House was increased in 1880. Subsequently,
mathematician W.F. Willcox proposed the “major fractions” method, which was used
(continued...)

CRS-2
The questions of how populous a congressional district should be and how many
Representatives should constitute the House have received little attention since the
number of Representatives was last increased to 435 after the 1910 Census.2 The
problem of fractional entitlement to Representatives, however, continued to be
troublesome. Various methods were considered and some were tried, each raising
questions of fundamental fairness. The issue of fairness could not be perfectly
resolved: inevitable fractional entitlements and the requirement that each state have
at least one representative lead to inevitable disparities among the states’ average
congressional district populations. The congressional debate, which sought an
apportionment method that would minimize those disparities, continued until 1941,
when Congress enacted the “equal proportions” method–the apportionment method
still in use today.
In light of the lengthy debate on apportionment, this report has four major
purposes:
1. to summarize the constitutional and statutory requirements governing
apportionment;
2. to explain how the current apportionment formula works in theory
and in practice;
3. to summarize recent challenges to it on grounds of unfairness; and
4. to explain the reasoning underlying the choice of the equal
proportions method over its chief alternative, major fractions.
Constitutional and Statutory Requirements
The process of apportioning seats in the House is constrained both
constitutionally and statutorily. As noted previously, the Constitution defines both
the maximum and minimum size of the House. There can be no fewer than one
Representative per state, and no more than one for every 30,000 persons.3
1 (...continued)
following the census of 1910. This method, too, had its critics; and in 1921 Harvard
mathematician E.V. Huntington proposed the “equal proportions” method and developed
formulas and computational tables for all of the other known, mathematically valid
apportionment methods. A committee of the National Academy of Sciences conducted an
analysis of each of those methods–smallest divisors, harmonic mean, equal proportions, major
fractions, and greatest divisors–and recommended that Congress adopt Huntington’s equal
proportions method. For a review of this history, see U.S. Congress, House, Committee on
Post Office and Civil Service, Subcommittee on Census and Statistics, The Decennial
Population Census and Congressional Apportionment
, 91st Cong., 2nd sess. H. Rept. 91-
1314 (Washington: GPO, 1970), Appendix B, pp. 15-18.
2 Article I, Section 2 defines both the maximum and minimum size of the House, but the
actual House size is set by law. There can be no fewer than one Representative per state, and
no more than one for every 30,000 persons. Thus, the House after 1990 could have been as
small as 50 and as large as 8,301 Representatives.
3 The actual language in of Article 1, section 2 pertaining to this minimum size reads as
(continued...)

CRS-3
The 1941 apportionment act, in addition to specifying the apportionment
method, sets the House size at 435 and mandates administrative procedures for
apportionment. The President is required to transmit to Congress “a statement
showing the whole number of persons in each state” and the resulting seat allocation
within one week after the opening of the first regular session of Congress following
the census.4
The Census Bureau has been assigned the responsibility of computing the
apportionment. As matter of practice, the Director of the Bureau reports the results
of the apportionment on December 31st of the census year. Once received by
Congress, the Clerk of the House is charged with the duty of sending to the Governor
of each state a “certificate of the number of Representatives to which such state is
entitled” within 15 days of receiving notice from the President.5
The Apportionment Formula
The Formula In Theory. An intuitive way to apportion the House is through
simple rounding (a method never adopted by Congress). First, the U.S.
apportionment population6 is divided by the total number of seats in the House (e.g.,
in 1990, 249,022,783 divided by 435) to identify the “ideal” sized congressional
district (572,466 in 1990). Then, each state’s population is divided by the “ideal”
district population. In most cases this will result in a whole number and a fractional
remainder, as noted earlier. Each state will definitely receive seats equal to the whole
number, and the fractional remainders will either be rounded up or down (at the .5
“rounding point”).
There are two fundamental problems with using simple rounding for
apportionment, given a House of fixed size. First, it is possible that some state
populations might be so small that they would be “entitled” to less than half a seat.
Yet, the Constitution requires that every state must have at least one seat in the
House. Thus, a method which relies entirely on rounding will not comply with the
Constitution if there are states with very small populations. Second, even a method
that assigns each state its constitutional minimum of one seat and otherwise relies on
rounding at the .5 rounding point might require a “floating” House size because
rounding at .5 could result in either fewer or more than 435 seats. Thus, this intuitive
way to apportion fails because, by definition, it does not take into account the
3 (...continued)
follows: “The number of Representatives shall not exceed one for every thirty Thousand, but
each State shall have at least one Representative.” This clause is sometime mis-read to be a
requirement that districts can be no larger than 30,000 persons, rather than as it should be
read, as a minimum-size population requirement.
4 55 Stat. 761. (1941) Sec. 22 (a). [Codified in 2 U.S.C. 2(a).] In other words, after the 2000
Census, this report is due in January 2001.
5 Ibid., Sec. 22 (b).
6 The apportionment population is the population of the 50 states. It excludes the population
of the District of Columbia and U.S. territories and possessions.

CRS-4
constitutional requirement that every state have at least one seat in the House and the
statutory requirement that the House size be fixed at 435.
The current apportionment method (the method of equal proportions established
by the 1941 act) satisfies the constitutional and statutory requirements. Although an
equal proportions apportionment is not normally computed in the theoretical way
described below, the method can be understood as a modification of the rounding
scheme described above.
First, the “ideal” sized district is found (by dividing the apportionment population
by 435) to serve as a “trial” divisor.
Then each state’s apportionment population is divided by the “ideal” district size
to determine its number of seats. Rather than rounding up any remainder of .5 or
more, and down for less than .5, however, equal proportions rounds at the geometric
mean of any two successive numbers. A geometric mean of two numbers is the
square root of the product of the two numbers.7 If using the “ideal” sized district
population as a divisor does not yield 435 seats, the divisor is adjusted upward or
downward until rounding at the geometric mean will result in 435 seats. In 1990, the
“ideal” size district of 572,466 had to be adjusted upward to between 573,555 and
573,6438 to produce a 435-Member House. Because the divisor is adjusted so that
the total number of seats will equal 435, the problem of the “floating” House size is
solved. The constitutional requirement of at least one seat for each state is met by
assigning each state one seat automatically regardless of its population size.
The Formula in Practice: Deriving the Apportionment From a Table of
"Priority Values." Although the process of determining an apportionment through
a series of trials using divisions near the “ideal” sized district as described above
works, it is inefficient because it requires a series of calculations using different
divisors until the 435 total is reached. Accordingly, the Census Bureau determines
apportionment by computing a “priority” list of state claims to each seat in the House.
During the early twentieth century, Walter F. Willcox, a Cornell University
mathematician, discovered that if the rounding points used in an apportionment
method are divided into each state's population (the mathematical equivalent of
7 The geometric mean of 1 and 2 is the square root of 2, which is 1.4142. The geometric mean
of 2 and 3 is the square root of 6, which is 2.4495. Geometric means are computed for
determining the rounding points for the size of any state’s delegation size. Equal proportions
rounds at the geometric mean (which varies) rather than the arithmetic mean (which is always
halfway between any pair of numbers). Thus, a state which would be entitled to 10.4871
seats before rounding will be rounded down to 10 because the geometric mean of 10 and 11
is 10.4881. The rationale for choosing the geometric mean rather than the arithmetic mean as
the rounding point is discussed in the section analyzing the equal proportions and major
fractions formulas.
8 Any number in this range divided into each state’s population and rounded at the geometric
mean will produce a 435-seat House.

CRS-5
multiplying the population by the reciprocal of the rounding point), the resulting
numbers can be ranked in a priority list for assigning seats in the House.9
Such a priority list does not assume a fixed House size because it ranks each of
the states’ claims to seats in the House so that any size House can be chosen easily
without the necessity of extensive recomputations.10
The traditional method of constructing a priority list to apportion seats by the
equal proportions method involves first computing the reciprocals11 of the geometric
means between every pair of consecutive whole numbers (the “rounding points”) so
that it is possible to multiply by decimals rather than divide by fractions (the former
being a considerably easier task). For example, the reciprocal of the geometric mean
between 1 and 2 (1.41452) is 1/1.414452 or .70710678. These reciprocals are
computed for each “rounding point.” They are then used as multipliers to construct
the “priority list.” Table 1 provides a list of multipliers used to calculate the “priority
values” for each state in an equal proportions apportionment.
To construct the “priority list,” each state’s apportionment population is
multiplied by each of the multipliers. The resulting products are ranked in order to
show each state’s claim to seats in the House. For example, assume that there are
three states in the Union (California, New York, and Florida) and that the House size
is set at 30 Representatives. The first seat for each state is assigned by the
Constitution; so the remaining twenty-seven seats must be apportioned using the
equal proportions formula. The 1990 apportionment populations for these states
were 29,839,250 for California, 18,044,505 for New York, and 13,003,362 for
Florida. Table 2 (p. 6) illustrates how the priority values are computed for each state.
Once the priority values are computed, they are ranked with the highest value
first. The resulting ranking is numbered and seats are assigned until the total is
reached. By using the priority rankings instead of the rounding procedures described
above, it is possible to see how an increase or decrease in the House size will affect
the allocation of seats without the necessity of doing new calculations. Table 3 (p.
7) ranks the priority values of the three states in this example, showing how the 27
seats are assigned.
9 U.S. Congress, House Committee on Post Office and Civil Service, Subcommittee on the
Census and Statistics, The Decennial Population Census and Congressional Apportionment,
91st Cong., 2nd sess., H. Rept. 91-1814, (Washington: GPO, 1970), p. 16.
10 The 435 limit on the size of the House is a statutory requirement. The House size was first
fixed at 435 by the Apportionment Act of 1911 (37 Stat. 13). The Apportionment Act of 1929
(46 Stat. 26), as amended by the Apportionment Act of 1941 (54 Stat. 162), provided for
“automatic reapportionment” rather than requiring the Congress to pass a new apportionment
law each decade. By authority of section 9 of PL 85-508 (72 Stat. 345) and section 8 of PL
86-3 (73 Stat. 8), which admitted Alaska and Hawaii to statehood, the House size was
temporarily increased to 437 until the reapportionment resulting from the 1960 Census when
it returned to 435.
11 A reciprocal of a number is that number divided into one.

CRS-6
Table 1. Multipliers for Determining Priority Values
for Apportioning the House by the Equal Proportions Method
Size of
Size of
Size of
delegation
Multiplier*
delegation
Multiplier*
delegation
Multiplier*
1
Constitution
21
0.04879500
41
0.02469324
2
0.70710678
22
0.04652421
42
0.02409813
3
0.40824829
23
0.04445542
43
0.02353104
4
0.28867513
24
0.04256283
44
0.02299002
5
0.22360680
25
0.04082483
45
0.02247333
6
0.18257419
26
0.03922323
46
0.02197935
7
0.15430335
27
0.03774257
47
0.02150662
8
0.13363062
28
0.03636965
48
0.02105380
9
0.11785113
29
0.03509312
49
0.02061965
10
0.10540926
30
0.03390318
50
0.02020305
11
0.09534626
31
0.03279129
51
0.01980295
12
0.08703883
32
0.03175003
52
0.01941839
13
0.08006408
33
0.03077287
53
0.01904848
14
0.07412493
34
0.02985407
54
0.01869241
15
0.06900656
35
0.02898855
55
0.01834940
16
0.06454972
36
0.02817181
56
0.01801875
17
0.06063391
37
0.02739983
57
0.01769981
18
0.05716620
38
0.02666904
58
0.01739196
19
0.05407381
39
0.02597622
59
0.01709464
20
0.05129892
40
0.02531848
60
0.01680732
*Table by CRS, calculated by determining the reciprocals of the geometric means of successive
numbers: 1/ n(n -1) , where “n” is the number of seats to be allocated to the state.
Table 2. Calculating Priority Values for a Hypothetical Three
State House of 30 Seats Using the Method of Equal Proportions
State’s priority value claim to a delegation size
Size of
Calculation
State
delegation
Multiplier (M)
Population (P)
Priority value (PxM)
CA
2
0.70710678
29,839,250
21,099,536.02
CA
3
0.40824829
29,839,250
12,181,822.80
CA
4
0.28867513
29,839,250
8,613,849.51
CA
5
0.22360680
29,839,250
6,672,259.14
CA
6
0.18257419
29,839,250
5,447,876.77
CA
7
0.15430335
29,839,250
4,604,296.24
CA
8
0.13363062
29,839,250
3,987,437.51
CA
9
0.11785113
29,839,250
3,516,589.34
CA
10
0.10540926
29,839,250
3,145,333.12
CA
11
0.09534626
29,839,250
2,845,060.86
CA
12
0.08703883
29,839,250
2,597,173.35
CA
13
0.08006408
29,839,250
2,389,052.01
CA
14
0.07412493
29,839,250
2,211,832.37
CA
15
0.06900656
29,839,250
2,059,103.87
CA
16
0.06454972
29,839,250
1,926,115.31
CA
17
0.06063391
29,839,250
1,809,270.29
CA
18
0.05716620
29,839,250
1,705,796.39
NY
2
0.70710678
18,044,505
12,759,391.85
NY
3
0.40824829
18,044,505
7,366,638.32
NY
4
0.28867513
18,044,505
5,208,999.91
NY
5
0.22360680
18,044,505
4,034,873.98
NY
6
0.18257419
18,044,505
3,294,460.81
NY
7
0.15430335
18,044,505
2,784,327.57

CRS-7
State’s priority value claim to a delegation size
Size of
Calculation
State
delegation
Multiplier (M)
Population (P)
Priority value (PxM)
NY
8
0.13363062
18,044,505
2,411,298.41
NY
9
0.11785113
18,044,505
2,126,565.31
NY
10
0.10540926
18,044,505
1,902,057.84
NY
11
0.09534626
18,044,505
1,720,476.05
NY
12
0.08703883
18,044,505
1,570,572.57
FL
2
0.70710678
13,003,362
9,194,765.45
FL
3
0.40824829
13,003,362
5,308,600.31
FL
4
0.28867513
13,003,362
3,753,747.28
FL
5
0.22360680
13,003,362
2,907,640.14
FL
6
0.18257419
13,003,362
2,374,078.23
FL
7
0.15430335
13,003,362
2,006,462.32
FL
8
0.13363062
13,003,362
1,737,647.34
*The “priority values” are the product of the multiplier times the state population. These values can
be computed for any size state delegation, but only those values necessary for this example have been
computed for this table. The population figures are those from the 1990 Census. Table by CRS.
Table 3. Priority Rankings for Assigning Thirty Seats
in a Hypothetical Three-State House Delegation
State’s priority value claim to a delegation size
House
Size of
Calculation
size
State
delegation
Multiplier (M)
Population (P)
Priority value (PxM)
4
CA
2
0.70710678
29,839,250
21,099,536.02
5
NY
2
0.70710678
18,044,505
12,759,391.85
6
CA
3
0.40824829
29,839,250
12,181,822.80
7
FL
2
0.70710678
13,003,362
9,194,765.45
8
CA
4
0.28867513
29,839,250
8,613,849.51
9
NY
3
0.40824829
18,044,505
7,366,638.32
10
CA
5
0.22360680
29,839,250
6,672,259.14
11
CA
6
0.18257419
29,839,250
5,447,876.77
12
FL
3
0.40824829
13,003,362
5,308,600.31
13
NY
4
0.28867513
18,044,505
5,208,999.91
14
CA
7
0.15430335
29,839,250
4,604,296.24
15
NY
5
0.22360680
18,044,505
4,034,873.98
16
CA
8
0.13363062
29,839,250
3,987,437.51
17
FL
4
0.28867513
13,003,362
3,753,747.28
18
CA
9
0.11785113
29,839,250
3,516,589.34
19
NY
6
0.18257419
18,044,505
3,294,460.81
20
CA
10
0.10540926
29,839,250
3,145,333.12
21
FL
5
0.22360680
13,003,362
2,907,640.14
22
CA
11
0.09534626
29,839,250
2,845,060.86
23
NY
7
0.15430335
18,044,505
2,784,327.57
24
CA
12
0.08703883
29,839,250
2,597,173.35
25
NY
8
0.13363062
18,044,505
2,411,298.41
26
CA
13
0.08006408
29,839,250
2,389,052.01
27
FL
6
0.18257419
13,003,362
2,374,078.23
28
CA
14
0.07412493
29,839,250
2,211,832.37
29
NY
9
0.11785113
18,044,505
2,126,565.31
30
CA
15
0.06900656
29,839,250
2,059,103.87
*The Constitution requires that each state have least one seat. Table by CRS.

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From the example in Table 3, we see that if the United States were made up of
three states and the House size were to be set at 30 Members, California would have
15 seats, New York would have nine, and Florida would have six. Any other size
House can be determined by picking points in the priority list and observing what the
maximum size state delegation size would be for each state.
A priority listing for all 50 states based on the 1990 Census is appended to this
report. It shows priority rankings for the assignment of seats in a House ranging in
size from 51 to 500 seats.
Challenges to the Current Formula
The equal proportions rule of rounding at the geometric mean results in differing
rounding points, depending on which numbers are chosen. For example, the
geometric mean between 1 and 2 is 1.4142, and the geometric mean between 49 and
50 is 49.49747. Table 4 on the following page shows the “rounding points” for
assignments to the House using the equal proportions method for a state delegation
size of up to 60. The rounding points are listed between each delegation size because
they are the thresholds which must be passed in order for a state to be entitled to
another seat. The table illustrates that, as the delegation size of a state increases,
larger fractions are necessary to entitle the state to additional seats.
The increasingly higher rounding points necessary to obtain additional seats has
led to charges that the equal proportions formula favors small states at the expense
of large states. In a 1982 book about congressional apportionment entitled Fair
Representation
, the authors (M.L. Balinski and H.P. Young) concluded that if “the
intent is to eliminate any systematic advantage to either the small or the large, then
only one method, first proposed by Daniel Webster in 1832, will do.”12 This method,
called the Webster method in Fair Representation, is also referred to as the major
fractions method. (Major fractions uses the concept of the adjustable divisor as does
equal proportions, but rounds at the arithmetic mean [.5] rather than the geometric
mean.) Balinski and Young’s conclusion in favor of major fractions, however,
contradicts a report of the National Academy of Sciences (NAS) prepared at the
request of Speaker Longworth in 1929. The NAS concluded that “the method of
equal proportions is preferred by the committee because it satisfies ... [certain tests],
and because it occupies mathematically a neutral position with respect to emphasis on
larger and smaller states”.13
12 M.L. Balinski and H.P. Young, Fair Representation, (New Haven and London: Yale
University Press, 1982), p. 4. (An earlier major work in this field was written by Laurence
F. Schmeckebier, Congressional Apportionment. (Washington: The Brookings Institution,
1941). Daniel Webster proposed this method to overcome the large-state bias in Jefferson’s
discarded fractions method. Webster’s method was used three times, in the reapportionments
following the 1840, 1910, and 1930 Censuses.
13 “Report of the National Academy of Sciences Committee on Apportionment” in The
Decennial Population Census and Congressional Apportionment
, Appendix C, p. 21.

CRS-9
Table 4. Rounding Points for Assigning Seats
Using the Equal Proportions Method of Apportionment*
Size of
Round
Size of
Round
Size of
Round
Size of
Round
delegation
up at
delegation
up at
delegation
up at
delegation
up at
1
16
31
46
1.41421
16.49242
31.49603
46.49731
2
17
32
47
2.44949
17.49286
32.49615
47.49737
3
18
33
48
3.46410
18.49324
33.49627
48.49742
4
19
34
49
4.47214
19.49359
34.49638
49.49747
5
20
35
50
5.47723
20.49390
35.49648
50.49752
6
21
36
51
6.48074
21.49419
36.49658
51.49757
7
22
37
52
7.48331
22.49444
37.49667
52.49762
8
23
38
53
8.48528
23.49468
38.49675
53.49766
9
24
39
54
9.48683
24.49490
39.49684
54.49771
10
25
40
55
10.48809
25.49510
40.49691
55.49775
11
26
41
56
11.48913
26.49528
41.49699
56.49779
12
27
42
57
12.49000
27.49545
42.49706
57.49783
13
28
43
58
13.49074
28.49561
43.49713
58.49786
14
29
44
59
14.49138
29.49576
44.49719
59.49790
15
30
45
60
15.49193
30.49590
45.49725
60.49793
*Any number between 574,847 and 576,049 divided into each state’s 1990 apportionment population
will produce a House size of 435 if rounded at these points, which are the geometric means of each
pair of successive numbers. Table by CRS.
A bill that would have changed the apportionment method to another formula
called the “Hamilton-Vinton” method was introduced in 1981.14 The fundamental
principle of the Hamilton-Vinton method is that it ranks fractional remainders. To
reapportion the House using Hamilton-Vinton, each state’s population would be
divided by the “ideal” sized congressional district (in 1990, 249,022,783 divided by
435 or 572,466). Any state with fewer residents than the “ideal”sized district would
receive a seat because the Constitution requires each state to have at least one House
14 H.R. 1990 was introduced by Representative Floyd Fithian and was cosponsored by 10
other Members of the Indiana delegation. Hearings were held, but no further action was taken
on the measure. U.S. Congress, House Committee on Post Office and Civil Service,
Subcommittee on Census and Population, Census Activities and the Decennial Census,
hearing, 97th Cong., 1st sess., June 11, 1981, (Washington: GPO, 1981).

CRS-10
seat. The remaining states in most cases have a claim to a whole number and a
fraction of a Representative. Each such state receives the whole number of seats it
is entitled to. The fractional remainders are rank-ordered from highest to lowest until
435 seats are assigned. For the purpose of this analysis, we will concentrate on the
differences between the equal proportions and major fractions methods because the
Hamilton-Vinton method is subject to several mathematical peculiarities.15
Equal Proportions or Major Fractions: an Analysis
Each of the major competing methods–equal proportions (currently used) and
major fractions–can be supported mathematically. Choosing between them is a policy
decision, rather than a matter of conclusively proving that one approach is
mathematically better than the other. A major fractions apportionment results in a
House in which each citizen’s share of his or her Representative is as equal as possible
on an absolute basis. In the equal proportions apportionment now used, each citizen’s
share of his or her Representative is as equal as possible on a proportional basis. The
state of Indiana in 1980 would have been assigned 11 seats under the major fractions
method, and New Mexico would have received 2 seats. Under this allocation, there
would have been 2.004 Representatives per million for Indiana residents and 1.538
Representative per million in New Mexico. The absolute value16 of the difference
between these two numbers is 0.466. Under the equal proportions assignment in
1980, Indiana actually received 10 seats and New Mexico 3. With 10 seats, Indiana
got 1.821 Representatives for each million persons, and New Mexico with 3 seats
received 2.308 Representatives per million. The absolute value of the difference is
0.487. Because major fractions minimizes the absolute population differences, under
it Indiana would have received 11 seats and New Mexico 2, because the absolute
value of subtracting the population shares with an 11 and 2 assignment (0.466) is
smaller than a 10 and 3 assignment (0.487).
An equal proportions apportionment, however, results in a House where the
average sizes of all the states’ congressional districts are as equal as possible if their
differences in size are expressed proportionally–that is, as percentages. The
proportional difference between 2.004 and 1.538 (major fractions) is 30%. The
proportional difference between 2.308 and 1.821 (equal proportions) is 27%. Based
15 The Hamilton-Vinton method (used after the 1850-1900 censuses) is subject to the
“Alabama paradox” and various other population paradoxes. The Alabama paradox was so
named in 1880 when it was discovered that Alabama would have lost a seat in the House if
the size of the House had been increased from 299 to 300. Another paradox, known as the
population paradox, has been variously described, but in its modern form (with a fixed size
House) it works in this way: two states may gain population from one census to the next.
State “A,” which is gaining population at a rate faster than state “B,” may lose a seat to state
“B.” There are other paradoxes of this type. Hamilton-Vinton is subject to them, whereas
equal proportions and major fractions are not.
16 The absolute value of a number is its magnitude without regard to its sign. For example,
the absolute value of -8 is 8. The absolute value of the expression (4-2) is 2. The absolute
value of the expression (2-4) is also 2.

CRS-11
on this comparison, the method of equal proportions gives New Mexico 3 seats and
Indiana 10 because the proportional difference is smaller (27%) than if New Mexico
gets 2 seats and Indiana 10 (30%). From a policy standpoint, one can make a case
for either method by arguing that one measure of fairness is preferable to the other.
The Case for Major Fractions. It can be argued that the major fractions
minimization of absolute size differences among districts most closely reflects the
“one person, one vote” principle established by the Supreme Court in its series of
redistricting cases (Baker v. Carr, 369 U.S. 186 (1964) through Karcher v. Daggett,
462 U.S.725 (1983).17
Although the “one person, one vote” rules have not been applied by the courts
to apportioning seats among states, major fractions can reduce the range between the
smallest and largest district sizes more than equal proportions–one of the measures
which the courts have applied to within-state redistricting cases. Although this range
would have not changed in 1990, if major fractions had been used in 1980, the
smallest average district size in the country would have been 399,592 (one of
Nevada’s two districts). With equal proportions it was 393,345 (one of Montana’s
two districts). In both cases the largest district was 690,178 (South Dakota’s single
seat).18 Thus, in 1980, shifting from equal proportions to major fractions as a method
would have improved the 296,833 difference between the largest and smallest districts
by 6,247 persons. It can be argued, because the equal proportions rounding points
ascend as the number of seats increases, rather than staying at .5, that small states may
be favored in seat assignments at the expense of large states. It is possible to
demonstrate this using simulation techniques.
The House has only been reapportioned 20 times since 1790. The equal
proportions method has been used in five apportionments, and major fractions in
three. Eight apportionments do not provide enough historical information to enable
policy makers to generalize about the impact of using differing methods. Computers,
however, can enable reality to be simulated by using random numbers to test many
different hypothetical situations. These techniques (such as the “Monte Carlo”
simulation method) are a useful way of observing the behavior of systems when
experience does not provide enough information to generalize about them.
17 Major fractions best conforms to the spirit of these decisions if the population discrepancy
is measured on an absolute basis, as the courts have done in the recent past. The Court has
never applied its “one person, one vote” rule to apportioning seats–states (as opposed to
redistricting within states). Thus, no established rule of law is being violated. Arguably, no
apportionment method can meet the “one person, one vote” standard required for districts
within states unless the size of the House is increased significantly (thereby making districts
smaller).
18 Nevada had two seats with a population of 799,184. Montana was assigned two seats with
a population of 786,690. South Dakota's single seat was required by the Constitution (with
a population of 690,178). The vast majority of the districts based on the 1980 census (323
of them) fell within the range of 501,000 to 530,000).

CRS-12
Apportioning the House can be viewed as a system with four main variables: (1)
the size of the House; (2) the population of the states; (3) the number of states; and
(4) the method of apportionment. A 1984 exercise prepared for the Congressional
Research Service (CRS) involving 1,000 simulated apportionments examined the
results when two of these variables were changed–the method and the state
populations. In order to further approximate reality, the state populations used in the
apportionments were based on the Census Bureau's 1990 population projections
available at that time. Each method was tested by computing 1,000 apportionments
and tabulating the results by state. There was no discernible pattern by size of state
in the results of the major fractions apportionment. The equal proportions exercise,
however, showed that the smaller states were persistently advantaged.19
Another way of evaluating the impact of a possible change in apportionment
methods is to determine the odds of an outcome being different than the one produced
by the current method–equal proportions. If equal proportions favors small states at
the expense of large states, would switching to major fractions, a method that appears
not to be influenced by the size of a state, increase the odds of the large states gaining
additional representation? Based on the simulation model prepared for CRS, this
appears to be true. The odds of any of the 23 largest states gaining an additional seat
in any given apportionment range from a maximum of 13.4% of the time (California)
to a low of .2% of the time (Alabama). The odds of any of the 21 multi-districted
smaller states losing a seat range from a high of 17% (Montana, which then had two
seats) to a low of 0% (Colorado), if major fractions were used instead of equal
proportions.
In the aggregate, switching from equal proportions to major fractions “could be
expected to shift zero seats about 37% of the time, to shift 1 seat about 49% of the
time, 2 seats 12% of the time, and 3 seats 2% of the time (and 4 or more seats almost
never), and, these shifts will always be from smaller states to larger states.”20
The Case for Equal Proportions. Support for the equal proportions formula
primarily rests on the belief that minimizing the proportional differences among
districts is more important than minimizing the absolute differences. Laurence
Schmeckebier, a proponent of the equal proportions method, wrote in Congressional
Apportionment
in 1941, that:
19 Comparing equal proportions and major fractions using the state populations from the 19
actual censuses taken since 1790, reveals that the small states would have been favored 3.4%
of the time if equal proportions had been used for all the apportionments. Major fractions
would have also favored small states, in these cases, but only .03 % of the time. See Fair
Representation
, p. 78.
20 H.P. Young and M.L. Balinski, Evaluation of Apportionment Methods, Prepared under
a contract for the Congressional Research Service of the Library of Congress. (Contract No.
CRS84-15), Sept. 30, 1984, p. 13.

CRS-13
Mathematicians generally agree that the significant feature of a difference is its
relation to the smaller number and not its absolute quantity. Thus the increase of
50 horsepower in the output of two engines would not be of any significance if one
engine already yielded 10,000 horsepower, but it would double the efficiency of
a plant of only 50 horsepower. It has been shown ... that the relative difference
between two apportionments is always least if the method of equal proportions is
used. Moreover, the method of equal proportions is the only one that uses relative
differences, the methods of harmonic mean and major fraction being based on
absolute differences. In addition, the method of equal proportions gives the
smallest relative difference for both average population per district and individual
share in a representative. No other method takes account of both these factors.
Therefore the method of equal proportions gives the most equitable distribution of
Representatives among the states.21
An example using Massachusetts and Oklahoma 1990 populations, illustrates the
argument for proportional differences. The first step in making comparisons between
the states is to standardize the figures in some fashion. One way of doing this is to
express each state’s representation in the House as a number of Representatives per
million residents.22 The equal proportions formula assigned 10 seats to Massachusetts
and 6 to Oklahoma in 1990. When 11 seats are assigned to Massachusetts, and five
are given to Oklahoma (using major fractions), Massachusetts has 1.824
Representatives per million persons and Oklahoma has 1.583 Representatives per
million. The absolute difference between these numbers is .241 and the proportional
difference between the two states’ Representatives per million is 15.22%. When 10
seats are assigned to Massachusetts and 6 are assigned to Oklahoma (using equal
proportions), Massachusetts has 1.659 Representatives per million and Oklahoma has
1.9 Representative per million. The absolute difference between these numbers is
.243 and the proportional difference is 14.53%.
Major fractions minimizes absolute differences, so in 1990, if this if this method
had been required by law, Massachusetts and Oklahoma would have received 11 and
five seats respectively because the absolute difference (0.241 Representatives per
million) is smaller at 11 and five than it would be at 10 and 6 (0.243). Equal
proportions minimizes differences on a proportional basis, so it assigned 10 seats to
Massachusetts and six to Oklahoma because the proportional difference between a 10
and 6 allocation (14.53%) is smaller than would occur with an 11 and 5 assignment
(15.22%).
The proportional difference versus absolute difference argument could also be
cast in terms of the goal of “one person, one vote.” The courts’ use of absolute
difference measures in state redistricting cases may not necessarily be appropriate
when applied to the apportionment of seats among states. The courts already
recognize that different rules govern redistricting in state legislatures than in
21 Schmeckebier, Congressional Apportionment, p. 60.
22 Representatives per million is computed by dividing the number of Representatives assigned
to the state by the state’s population (which gives the number of Representatives per person)
and then multiplying the resulting dividend by 1,000,000.

CRS-14
congressional districting. If the “one person, one vote” standard were ever to be
applied to apportionment of seats among states–a process that differs significantly
from redistricting within states–proportional difference measures might be accepted
as most appropriate.23
If the choice between methods were judged to be a tossup with regard to which
mathematical process is fairest, are there other representational goals that equal
proportions meets which are perhaps appropriate to consider? One such goal might
be the desirability of avoiding geographically large districts, if possible. After the 1990
apportionment, five of the seven states which had only one Representative (Alaska,
Delaware, Montana, North Dakota, South Dakota, Vermont, and Wyoming) have
relatively large land areas.24 The five Representatives of the larger states served
1.27% of the U.S. population, but also represented 27% of the U.S. land area.
Arguably, an apportionment method that would potentially reduce the number
of very large districts would serve to increase representation in those states. Very
large districts limit the opportunities of constituents to see their Representatives, may
require more district based offices, and may require toll calls for telephone contact
with the Representatives’ district offices. Switching from equal proportions to major
fractions may increase the number of states represented by only one Member of
Congress. Although it is impossible to predict with any certainty, using Census
Bureau projections for 202525 as an illustration, a major fractions apportionment
would result in eight states represented by only one Member, while an equal
proportions apportionment would result in six single-district states.
23 Montana argued in Federal court in 1991 and 1992 that the equal proportions formula
violated the Constitution because it “does not achieve the greatest possible equality in number
of individuals per Representative” Department of Commerce v. Montana 503 U.S. 442
(1992). Writing for a unanimous court, Justice Stevens however, noted that absolute and
relative differences in district sizes are identical when considering deviations in district
populations within states, but they are different when comparing district populations among
states. Justice Stevens noted, however, “although “common sense” supports a test requiring
a “good faith effort to achieve precise mathematical equality” within each State ... the
constraints imposed by Article I, §2, itself make that goal illusory for the nation as a whole.”
He concluded “that Congress had ample power to enact the statutory procedure in 1941 and
to apply the method of equal proportions after the 1990 census.”
24 The total area of the U.S. is 3,618,770 square miles. The area and (rank) among all states
in area for the seven single district states in this scenario are as follows: Alaska–591,004 (1),
Delaware–2,045 (49), Montana–147,046 (4), North Dakota–70,762 (17), South
Dakota–77,116 (16), Vermont–9,614 (43), Wyoming–97,809 (9). Source: U.S. Department
of Commerce, Bureau of the Census, Statistical Abstract of the United States 1987,
(Washington: GPO, 1987), Table 316: Area of States, p. 181.
25 U.S. Census Bureau, Projections of the Total Population of States: 1995-2025, Series A,
http://www.census.gov/population/projections/stpjpop.txt, visited Aug. 11, 2000.


CRS-15
The appendix which follows is the priority listing used in reapportionment
following the 1990 Census. This listing shows where each state ranked in the priority
of seat assignments. The priority values listed beyond seat number 435 show which
states would have gained additional representations if the House size had been
increased.

CRS-16
Appendix: 1990 Priority List
Seq. State Seat
Priority
100
CA
11 2,845,059.46
51
CA
2 21,099,535.65
101
NY
7 2,784,326.89
52
NY
2 12,759,391.63
102
NC
3 2,717,965.76
53
CA
3 12,181,821.46
103
MG
4 2,692,987.92
54
TX
2 12,063,103.59
104
PA
5 2,666,445.82
55
FL
2 9,194,765.29
105
GA
3 2,657,050.63
56
CA
4 8,613,849.35
106
TX
7 2,632,384.41
57
PA
2 8,432,043.16
107
KY
2 2,615,566.01
58
IL
2 8,108,168.46
108
AZ
2 2,600,728.09
59
OH
2 7,698,501.20
109
CA
12 2,597,172.96
60
NY
3 7,366,637.51
110
IL
5 2,564,027.67
61
TX
3 6,964,635.46
111
VA
3 2,537,902.98
62
CA
5 6,672,258.17
112
SC
2 2,478,909.15
63
MG
2 6,596,446.31
113
MA
3 2,461,349.49
64
NJ
2 5,479,111.55
114
OH
5 2,434,479.52
65
CA
6 5,447,875.79
115
NY
8 2,411,297.55
66
FL
3 5,308,599.72
116
CA
13 2,389,051.45
67
NY
4 5,208,999.81
117
FL
6 2,374,077.80
68
TX
4 4,924,741.41
118
CO
2 2,339,046.96
69
PA
3 4,868,241.93
119
CN
2 2,330,389.85
70
NC
2 4,707,655.23
120
TX
8 2,279,711.53
71
IL
3 4,681,252.81
121
IN
3 2,271,586.31
72
CA
7 4,604,295.11
122
NJ
4 2,236,837.92
73
GA
2 4,602,147.13
123
OK
2 2,232,763.16
74
OH
3 4,444,731.33
124
CA
14 2,211,830.60
75
VA
2 4,395,777.31
125
PA
6 2,177,143.82
76
MA
2 4,263,182.77
126
NY
9 2,126,564.37
77
NY
5 4,034,873.39
127
MO
3 2,097,499.46
78
CA
8 3,987,436.09
128
IL
6 2,093,519.75
79
IN
2 3,934,503.28
129
MG
5 2,085,979.21
80
TX
5 3,814,687.81
130
CA
15 2,059,102.28
81
MG
3 3,808,459.70
131
OR
2 2,017,893.92
82
FL
4 3,753,747.20
132
TX
9 2,010,516.41
83
MO
2 3,632,975.98
133
FL
7 2,006,461.82
84
CA
9 3,516,587.79
134
WS
3 2,003,170.03
85
WS
2 3,469,592.60
135
TN
3 1,999,045.09
86
TN
2 3,462,447.99
136
WA
3 1,995,493.33
87
WA
2 3,456,296.16
137
OH
6 1,987,744.13
88
PA
4 3,442,367.20
138
IO
2 1,971,006.37
89
MD
2 3,393,138.09
139
MD
3 1,959,029.01
90
IL
4 3,310,145.91
140
CA
16 1,926,114.17
91
NY
6 3,294,460.21
141
NC
4 1,921,892.20
92
NJ
3 3,163,366.23
142
NY
10 1,902,056.92
93
CA
10 3,145,331.61
143
GA
4 1,878,818.69
94
OH
4 3,142,899.95
144
PA
7 1,840,022.25
95
TX
6 3,114,679.44
145
MS
2 1,828,891.35
96
MN
2 3,102,097.90
146
CA
17 1,809,270.25
97
LA
2 2,996,871.22
147
TX
10 1,798,260.48
98
FL
5 2,907,639.71
148
VA
4 1,794,568.57
99
AL
2 2,872,697.61
149
MN
3 1,790,996.89

CRS-17
150
IL
7 1,769,347.01
204
MG
8 1,246,610.75
151
KA
2 1,757,584.58
205
NY
15 1,245,188.18
152
MA
4 1,740,437.07
206
IN
5 1,244,199.02
153
FL
8 1,737,646.72
207
FL
11 1,239,821.31
154
NJ
5 1,732,646.98
208
LA
4 1,223,467.55
155
LA
3 1,730,244.24
209
UT
2 1,221,727.76
156
NY
11 1,720,475.20
210
CA
25 1,218,182.21
157
CA
18 1,705,796.31
211
NC
6 1,215,511.15
158
MG
6 1,703,194.83
212
IL
10 1,208,693.83
159
OH
7 1,679,950.30
213
NJ
7 1,195,639.89
160
AR
2 1,670,355.18
214
GA
6 1,188,269.08
161
AL
3 1,658,552.58
215
TX
15 1,177,237.47
162
TX
11 1,626,587.79
216
AL
4 1,172,773.89
163
CA
19 1,613,521.84
217
CA
26 1,170,391.58
164
IN
4 1,606,254.23
218
OR
3 1,165,031.49
165
PA
8 1,593,505.83
219
NY
16 1,164,767.10
166
NY
12 1,570,572.33
220
MO
5 1,148,847.73
167
FL
9 1,532,460.23
221
OH
10 1,147,624.27
168
IL
8 1,532,299.29
222
IO
3 1,137,960.95
169
CA
20 1,530,721.18
223
PA
11 1,136,975.93
170
KY
3 1,510,097.60
224
VA
6 1,134,984.63
171
AZ
3 1,501,530.92
225
FL
12 1,131,797.21
172
NC
5 1,488,691.10
226
CA
27 1,126,209.87
173
TX
12 1,484,865.21
227
NB
2 1,120,493.40
174
MO
4 1,483,156.23
228
TX
16 1,101,205.03
175
CA
21 1,456,006.30
229
MA
6 1,100,748.87
176
GA
5 1,455,326.51
230
MG
9 1,099,407.25
177
OH
8 1,454,879.48
231
WS
5 1,097,181.37
178
NY
13 1,444,716.30
232
TN
5 1,094,922.05
179
MG
7 1,439,462.27
233
NY
17 1,094,108.80
180
SC
3 1,431,198.73
234
IL
11 1,093,304.69
181
WS
4 1,416,455.24
235
WA
5 1,092,976.67
182
NJ
6 1,414,700.28
236
CA
28 1,085,243.01
183
TN
4 1,413,538.47
237
NM
2 1,076,060.23
184
WA
4 1,411,027.00
238
MD
5 1,073,004.34
185
PA
9 1,405,339.93
239
KY
4 1,067,800.35
186
VA
5 1,390,066.66
240
AZ
4 1,061,742.79
187
CA
22 1,388,247.47
241
MS
3 1,055,910.81
188
MD
4 1,385,242.82
242
CA
29 1,047,152.30
189
FL
10 1,370,674.05
243
FL
13 1,041,101.93
190
TX
13 1,365,877.22
244
OH
11 1,038,065.20
191
IL
9 1,351,360.84
245
PA
12 1,037,912.62
192
CO
3 1,350,449.27
246
NJ
8 1,035,454.40
193
MA
5 1,348,136.59
247
TX
17 1,034,402.59
194
CN
3 1,345,451.08
248
NY
18 1,031,535.64
195
NY
14 1,337,546.63
249
NC
7 1,027,294.36
196
CA
23 1,326,516.39
250
IN
6 1,015,884.21
197
OK
3 1,289,086.29
251
KA
3 1,014,741.83
198
OH
9 1,283,082.99
252
SC
4 1,012,010.42
199
WV
2 1,273,941.23
253
CA
30 1,011,645.28
200
CA
24 1,270,042.73
254
GA
7 1,004,270.60
201
MN
4 1,266,426.16
255
IL
12
998,046.41
202
TX
14 1,264,555.87
256
MG
10
983,339.70
203
PA
10 1,256,974.20
257
MN
5
980,969.36

CRS-18
258
CA
31
978,467.51
312
NY
23
802,176.05
259
NY
19
975,735.07
313
MN
6
800,958.10
260
TX
18
975,244.09
314
CA
38
795,784.05
261
AR
3
964,379.92
315
TX
22
793,693.91
262
FL
14
963,872.55
316
MO
7
792,780.17
263
VA
7
959,237.03
317
IL
15
791,275.62
264
CO
4
954,911.92
318
HA
2
788,617.79
265
PA
13
954,740.67
319
FL
17
788,444.61
266
CN
4
951,377.67
320
NH
2
787,656.83
267
LA
5
947,693.77
321
NC
9
784,608.87
268
OH
12
947,619.86
322
SC
5
783,899.80
269
CA
32
947,397.10
323
CA
39
775,110.76
270
MO
6
938,030.21
324
LA
6
773,788.69
271
MA
7
930,302.53
325
PA
16
769,736.26
272
NY
20
925,663.55
326
NY
24
768,025.08
273
TX
19
922,488.60
327
GA
9
767,024.19
274
CA
33
918,239.42
328
TX
23
758,400.80
275
IL
13
918,069.09
329
WS
7
757,127.00
276
NJ
9
913,184.87
330
TN
7
755,567.92
277
OK
4
911,521.74
331
CA
40
755,484.48
278
AL
5
908,426.63
332
WA
7
754,225.48
279
FL
15
897,316.53
333
OH
15
751,296.22
280
WS
6
895,844.81
334
MG
13
746,900.30
281
TN
6
894,000.08
335
MS
4
746,641.76
282
WA
6
892,411.68
336
IN
8
743,550.98
283
CA
34
890,823.07
337
FL
18
743,352.69
284
NC
8
889,662.91
338
AL
6
741,727.21
285
MG
11
889,464.22
339
MD
7
740,443.26
286
PA
14
883,917.61
340
IL
16
740,170.70
287
NY
21
880,481.68
341
CO
5
739,671.50
288
MD
6
876,104.34
342
NJ
11
738,802.90
289
TX
20
875,149.50
343
CN
5
736,933.88
290
ME
2
872,020.33
344
CA
41
736,827.74
291
OH
13
871,683.42
345
NY
25
736,663.79
292
GA
8
869,723.76
346
WV
3
735,510.24
293
CA
35
864,996.63
347
VA
9
732,629.24
294
IN
7
858,578.81
348
TX
24
726,113.47
295
NV
2
852,878.24
349
PA
17
723,041.73
296
IL
14
849,966.34
350
CA
42
719,070.17
297
CA
36
840,625.60
351
KA
4
717,530.90
298
NY
22
839,506.30
352
ID
2
715,582.15
299
FL
16
839,362.91
353
RI
2
711,338.09
300
TX
21
832,433.24
354
MA
9
710,530.16
301
VA
8
830,723.54
355
NY
26
707,763.66
302
KY
5
827,114.49
356
OK
5
706,061.61
303
OR
4
823,801.74
357
UT
3
705,364.78
304
PA
15
822,882.53
358
FL
19
703,141.28
305
AZ
5
822,422.32
359
OH
16
702,773.39
306
CA
37
817,590.39
360
CA
43
702,148.53
307
NJ
10
816,777.34
361
NC
10
701,775.48
308
MG
12
811,966.30
362
TX
25
696,463.58
309
OH
14
807,021.57
363
IL
17
695,269.70
310
MA
8
805,665.54
364
MG
14
691,494.92
311
IO
4
804,659.98
365
MO
8
686,567.69

CRS-19
366
GA
10
686,047.27
420
NY
31
591,702.60
367
CA
44
686,005.00
421
CA
51
590,905.18
368
AR
4
681,919.64
422
OH
19
588,719.10
369
PA
18
681,690.26
423
IL
20
588,228.36
370
NY
27
681,045.92
424
IN
10
586,520.84
371
MN
7
676,933.10
425
MN
8
586,241.20
372
KY
6
675,336.13
426
PA
21
581,866.26
373
NJ
12
674,431.92
427
NC
12
579,472.22
374
AZ
6
671,504.99
428
CA
52
579,430.15
375
CA
45
670,587.24
429
TX
30
578,381.53
376
TX
26
669,140.55
430
MS
5
578,346.15
377
FL
20
667,058.37
431
WS
9
578,265.19
378
OH
17
660,141.03
432
FL
23
578,069.92
379
NY
28
656,272.29
433
TN
9
577,074.42
380
CA
46
655,847.22
434
OK
6
576,496.87
381
IN
9
655,750.27
435
WA
9
576,049.11
382
WS
8
655,691.14
Last seat assigned by law
383
IL
18
655,506.55
436
MA
11
574,847.17
384
VA
10
655,283.49
437
NJ
14
574,366.50
385
TN
8
654,340.94
438
NY
32
572,913.58
386
LA
7
653,970.76
439
KY
7
570,763.16
387
WA
8
653,178.36
440
CA
53
568,392.42
388
NB
3
646,917.11
441
MT
2
568,269.89
389
PA
19
644,814.46
442
AZ
7
567,525.26
390
TX
27
643,880.82
443
GA
12
566,485.07
391
MG
15
643,746.75
444
LA
8
566,355.23
392
CA
47
641,741.37
445
MG
17
565,640.60
393
MD
8
641,242.61
446
MD
9
565,522.77
394
SC
6
640,051.48
447
IL
21
559,516.78
395
OR
5
638,114.00
448
TX
31
559,413.02
396
MA
10
635,517.47
449
OH
20
558,507.97
397
NC
11
634,779.80
450
CA
54
557,767.31
398
FL
21
634,499.09
451
KA
5
555,796.97
399
NY
29
633,237.93
452
NY
33
555,281.24
400
CA
48
628,229.44
453
PA
22
554,787.68
401
AL
7
626,873.87
454
FL
24
553,459.80
402
IO
5
623,286.86
455
CA
55
547,532.16
403
OH
18
622,386.91
456
AL
8
542,888.63
404
NM
3
621,263.60
457
TX
32
541,649.33
405
GA
11
620,553.10
458
MO
10
541,571.83
406
TX
28
620,459.09
459
VA
12
541,082.71
407
NJ
13
620,387.08
460
SC
7
540,942.20
408
IL
19
620,047.14
461
NY
34
538,701.92
409
CA
49
615,274.87
462
CA
56
537,665.94
410
NY
30
611,765.99
463
NJ
15
534,706.13
411
PA
20
611,724.70
464
IL
22
533,478.29
412
MO
9
605,495.74
465
MG
18
533,291.06
413
FL
22
604,971.11
466
NC
13
533,036.87
414
CO
6
603,939.23
467
OH
21
531,247.06
415
CA
50
602,843.86
468
FL
25
530,860.00
416
MG
16
602,170.06
469
IN
11
530,528.06
417
CN
6
601,703.97
470
PA
23
530,117.99
418
TX
29
598,681.74
471
AR
5
528,212.62
419
VA
11
592,726.21
472
CA
57
528,148.99

CRS-20
473
TX
33
524,979.20
474
MA
12
524,761.45
475
NY
35
523,084.05
476
GA
13
521,090.43
477
OR
6
521,017.88
478
WV
4
520,084.33
479
CA
58
518,963.07
480
WS
10
517,216.08
481
MN
9
517,016.09
482
TN
10
516,151.03
483
WA
10
515,233.97
484
CO
7
510,421.77
485
CA
59
510,091.18
486
FL
26
510,033.77
487
IL
23
509,756.16
488
TX
34
509,304.61
489
IO
6
508,911.57
490
CN
7
508,532.64
491
NY
36
508,346.32
492
PA
24
507,549.32
493
OH
22
506,524.17
494
MD
10
505,818.92
495
MG
19
504,442.86
496
ME
3
503,461.12
497
CA
60
501,517.64
498
NJ
16
500,171.88
499
LA
9
499,478.32
500
UT
4
498,768.26