fundamental law of active management
TRANSCRIPT
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PORTFOLIO CONSTRAINTS AND THE
FUNDAMENTAL LAW OF ACTIVE MANAGEMENT
November 2001
Forthcoming in theFinancial Analysts Journal
Roger Clarke
Harindra de Silva
Steven Thorley
Roger Clarke, Ph.D., is Chairman of Analytic Investors, Hanrindra de Silva, Ph.D., CFA, isPresident of Analytic Investors, and Steven Thorley, Ph.D., CFA, is Associate Professor ofFinance at the Marriott School, Brigham Young University.
Please send comments and correspondence to Steven Thorley, 666 Tanner Building, BrighamYoung University, Provo, UT, 84602. Email: [email protected] Phone: 801-378-6065
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Portfolio Constraints and the Fundamental Law of Active Management
Author Digest
The expected value added in an actively managed portfolio is dependent on both the
managers forecasting skill and the ability to take appropriate positions in securities that reflect
those forecasts. The fundamental law of active management articulated by Grinold gives the
maximum expected value added for an actively managed portfolio based on the forecasting
ability of the manager and the breadth of application. However, the fundamental law does not
address the impact of portfolio constraints on potential value added. Constraints like no short
sales and security concentration limits impede the transfer of information into optimal portfolio
positions and decrease the expected value added.
We generalize the fundamental law of active management to include a transfer coefficient
as well as an information coefficient. The information coefficient measures the strength of the
return forecasting process, or signal, while the transfer coefficient measures the degree to which
the signal is transferred into active portfolio weights. The transfer coefficient turns out to be a
simple scaling factor in the generalized fundamental law, and is an intuitive way to measure the
extent to which constraints reduce the expected value of the investors forecasting ability. In the
absence of any constraints, a well-constructed portfolio has a transfer coefficient of one, and the
original form of the fundamental law applies. However, in practice, managers often work under
constraints that produce transfer coefficient values that range from 0.3 to 0.8. The transfer
coefficient suggests why performance in practice is only a fraction (0.3 to 0.8) of what is
predicted by the original form of the fundamental law.
Measuring and illustrating the impact of portfolio constraints on active weights taken
using the transfer coefficient allows an investment manager to assess strategic tradeoffs in
constructing portfolios. For example, increasing the tracking error in a long-only portfolio
typically reduces the transfer coefficient because the long-only constraint becomes binding for
more securities, and thus impedes the transfer of information into desirable portfolio positions.
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Another strategic perspective is that the long-only constraint leads to an unintended small-cap
bias in actively managed portfolios, motivating market-cap neutrality constraints. However, the
combination of long-only and market-cap neutrality constraints results in active management that
is concentrated in the large-cap sector. In addition to the long-only constraint case study, we
employ the generalized fundamental law and transfer coefficient framework to illustrate the
impact of turnover constraints, and portfolios under multiple constraints.
In addition to its ex-ante role, the transfer coefficient is also a critical parameter in
reconciling realized performance with the realized success of return forecasting. We derive a
decomposition of ex-postactive management performance, based on the transfer coefficient and
the realized information coefficient. The ex-post performance decomposition indicates that only
a fraction (the transfer coefficient squared) of the variation in realized performance, or tracking
error, is attributable to variation in realized information coefficients. For example, if there are no
portfolio constraints and the transfer coefficient is 1.0, then variation in realized performance is
wholly attributable to the success of the return-prediction process. However, if the transfer
coefficient is 0.3, then only 9 percent of performance variation is attributable to the success of
the signal, with the remaining 91 percent is attributable to constraint induced noise. Managers
with low transfer coefficients will experience frequent periods when the signal works but
performance is poor, and periods when performance is good even though the return forecasting
process fails.
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Portfolio Constraints and the Fundamental Law of Active Management
Mini-abstract: The fundamental law is generalized to include an information transfer coefficient
that reflects portfolio constraints.
Abstract
Active portfolio management is typically conducted within constraints that do not allow
managers to fully exploit their ability to forecast returns. Constraints on short positions and
turnover, for example, are fairly common and materially restrictive. Other constraints, such as
market-cap and value/growth neutrality with respect to the benchmark, or economic sector
constraints, can further restrict an active portfolios composition. We derive ex-ante and ex-post
correlation relationships that facilitate constrained portfolio performance analysis. The ex-ante
relationship is a generalized version of Grinolds (1989) fundamental law of active management,
and provides an important strategic perspective on the potential for active management to add
value. The ex-post correlation relationships represent a practical decomposition of performance
into the success of the return prediction process and the noise associated with portfolio
constraints. We verify the accuracy of these relationships with a Monte-Carlo simulation and
illustrate their application with equity portfolio examples based on the S&P 500 benchmark.
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Portfolio Constraints and the Fundamental Law of Active Management
Most portfolio managers appreciate the fact that value-added is ultimately dependent on
their ability to correctly forecast security returns. Managers work hard to create valuable
information about future returns, but may not pay as much attention to limitations in the portfolio
construction process. Constraints such as no short sales, industry limitations, and restrictions on
investment style and turnover, all limit a managers ability to transfer valuable information into
portfolio positions. In this paper, we introduce a conceptual framework and diagnostic tools that
measure the impact of constraints on value-added. The conceptual framework provides an
important strategic perspective on where and how managers have the potential to add value. The
diagnostic tools measure the degree to which realized performance is attributable to return
forecasts versus the noise induced by portfolio constraints.
Figure 1 characterizes a triangle of relationships between forecasted and realized residual
security returns, and active security weights. The realized residual return, ri, refers to the portion
of the total security return that is uncorrelated to the benchmark portfolio return. We focus on
residual security returns and risks throughout this paper. Forecasted residual security returns, i,
are the portfolio managers forecast of rifor each of the i= 1 toNsecurities in the portfolio. The
active weight, wi, is the difference between the weight of security i in the actively managed
portfolio and its weight in the benchmark portfolio. Thus, a positive active weight indicates that
the security is over-weighted in the managed portfolio, and a negative active weight indicates
that it is under-weighted, compared to the benchmark. Active security weights, wi, which sum
to zero (rather than one) are a compact way to describe a managed portfolios positions
compared to the benchmark. Note that in addition to activeweights, the word activeis also used
to convey the difference between the actively managed and benchmark portfolio returns, as
explained below.
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ForecastedResidual Returns
i
ActiveWeights
wi
RealizedResidual Returns
ri
Signal Quality
(Information Coefficient)
Portfolio Construction
(Transfer Coefficient)
Value Added
(Performance Coefficient)
Figure 1: The Correlation Triangle
The base of the triangle in Figure 1 represents the value added through active
management. Value added is measured by the difference between the return on the actively
managed and benchmark portfolios, adjusting for the managed portfolios beta with respect to
the benchmark, a difference commonly referred to as the active return, RA. As shown in the
technical appendix, RAis algebraically equivalent to the sum of the products of active weights,
wi, and residual returns, ri, for the i = 1 toNstocks in the portfolio;
==
N
i
iiA rwR1
. (1)
Equation 1 indicates that value is added when positive active-weight securities have positive
residual returns, and negative active-weight securities have negative residual returns. In other
words, performance in any given period is related to the cross-sectional correlation between the
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active security weights and realized residual returns - the security data in the bottom two corners
of the correlation triangle.
While the direct cross-sectional correlation orPerformance Coefficientat the base of the
triangle reflects value added, a clearer understanding of the sources and limitations of value-
added can be obtained by examining the cross-sectional correlations on the two legs. First, there
is little hope of value added if the managers forecasts of returns do not correspond to actual
realized returns. Signal quality is measured by the relationship between the forecasted residual
returns or alphas at the top of the triangle, and the realized residual returns at the right corner.
This cross-sectional correlation is commonly called the Information Coefficient, or IC.
Managers with higherIC, or ability to forecast returns, will add more value over time, but only to
the extent that those forecasts are exploited in the construction of the managed portfolio. The
second correlation, the relationship between the active weights in the left corner, and forecasted
residual returns at the top of the triangle, measures the degree to which the managers forecasts
are translated into active weights. We will refer to this cross-sectional correlation as the Transfer
Coefficient, or TC.1
The TC, or correlation between active weights and forecasted residual returns, is equal to
one in the absence of constraints in portfolio construction. However, investment managers rarely
enjoy the luxury of a completely unconstrained investment portfolio. Portfolio constraints, like
no short sales and industry or sector concentrations limit the full transfer of information into
active weights and lead to TC values much lower than one. As a result, performance is a
function of both signal quality (the right leg of the triangle) and the constraints imposed in the
portfolio construction process (the left leg of the triangle).
The Generalized Fundamental Law
In this section we formalize the conceptual framework in Figure 1 with a generalized
version of Grinolds (1989) fundamental law of active management. We first review the original
form of the fundamental law. Then we generalize the law to account for portfolio constraints.
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The fundamental law describes an ex-ante relationship between expected performance
and the assumed information coefficient in the managers forecasting process. Expected
performance is measured by the ex-ante information ratio,IR, defined as the portfolios expected
active return (i.e., return in excess of the benchmark) divided by active risk, IR E(RA)/A.
Active risk, A, is the standard deviation of active portfolio return, RA, and is also referred to as
the managed portfolios tracking error. Goodwin (1998) includes a good discussion of
information ratio calculation procedures. The technical appendix at the end of this paper
contains a proof of the original form of the fundamental law;
NICIR= . (2)
whereIC is the information coefficient andNis the breadth, or number of independent bets in
the actively managed portfolio.
As discussed in the technical appendix, Equation 2 is based on the operational
assumptions that the manager uses mean-variance optimization and an alpha forecasting process
that incorporates individual security risk estimates and an assumed IC. However, there are two
additional simplifying assumptions made for mathematical tractability. First, we assume a
diagonal covariance matrix for residual security returns, or that the benchmark portfolio return is
the only source of covariance between total security returns. Under this market model
assumption,Nis simply the number of securities in the portfolio. Second, no budget constraint
is imposed in the optimization problem, an assumption that allows the active weight for each
security to be perfectly proportional to its risk-adjusted forecasted return. The second
assumption does not appear to be a serious limitation for portfolios with a large number of
securities and typical residual risk-return parameters. In the next section, we test the materiality
of the two simplifying assumptions with data on the S&P 500. Grinold (1989) readily
acknowledges the approximate nature of the fundamental law, and presents it as a strategic tool.
Thomas (2000) provides intuitive support for the strategic perspectives that come from the
fundamental law. The important lesson of the fundamental law is that breadth of application, as
well as the quality of the signal, dictates the expected value-added from active management.
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A weakness of the traditional form of the fundamental law in Equation 2 is the
assumption that the portfolio manager can take active weights that fully exploit the return
forecasting process. This assumption is explicit in Grinolds (1989) original derivation, where
he states that the law gives us only an upper bound on the value we can add because we
presume that we can pursue our information without any limitations (pp. 33). Goodwin (1998)
also emphasizes the fact that the original fundamental law provides an upper bound on potential
information ratios. Unfortunately, portfolio managers sometimes employ the law without
acknowledging this fact, and then wonder why realized information ratios are only a fraction of
their predicted value. Indeed, a common rule of thumb is that the theoretical information ratio
suggested by the fundamental law should be cut in half in practice. While this is sometimes an
implicit admission that the true signal quality, or IC, is below the assumed value, much of the
reduction in performance is simply the result of constraints in the portfolio construction process.
Below we generalize the fundamental law to incorporate a precise measure of how constraints
impact value added.
The technical appendix shows that under the two simplifying assumptions previously
mentioned, unconstrained mean-variance portfolio optimization leads to active weights for each
security that are proportional to risk-adjusted forecasted residual returns. Specifically, the
unconstrained optimal active weight on security iis given by
2
12
*
i
i
iw = (3)
where i2is the securitys residual return variance, and is a risk-aversion parameter. Because
the risk-aversion parameter is the same for all securities (is not subscripted), a perfect cross-
sectional correlation exists between the unconstrained optimal active weights, wi*, and risk-
weighted forecasted residual returns, i/i2. The full information content of the return forecasts
is transferred into active weights, with no reduction in the potential for value-added.
In practice, active managers are often subject to constraints that cause them to deviate
from the unconstrained optimal weights in Equation 3. Searching algorithms are available that
can determine optimal weights under constraints, although the results do not generally have a
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closed-form solution. Let wibe a set of active weights based on a formal optimizer, or some
other portfolio construction process, that is subject to one or more constraints. We define the
transfer coefficient, TC, as the cross-sectional correlation coefficient between risk-adjusted
active weights and risk-adjusted forecasted residual returns for the i= 1 to N securities in the
portfolio. As explained in the technical appendix, when securities have different residual risks,
the TC and other cross-sectional correlation coefficient calculations generally require risk-
adjustment in order to correctly tie the fundamental law back to the alpha generation process.
Based on this definition for the transfer coefficient, the technical appendix presents a proof of the
generalized fundamental law;
NICTCIR (4)
or in terms of the expected active return, AA NICTCRE )( . Like the information
coefficient,IC, the transfer coefficient, TC, acts as a simple scaling factor in the determination of
value added. Equation 4 is generalized in the sense that the TCin the original version of the law
in Equation 2 is assumed to be one. In practice, values for TC rarely approach 1.0, and with
multiple constraints can be as low as 0.3. The use of the approximate equality notation in
Equation 4 is motivated by an approximation in the proof, as noted in the technical appendix.
One can think of TCas an additional adjustment to breadth,N, that reflects the reduction
in independent bets due to constraints. However, the best conceptualization of TCis motivated
by its mathematical definition; the transfer coefficient measures the degree to which the
information in individual security return forecasts is transferred into managed portfolio positions.
The transfer coefficient is not the only way to access the impact of a particular constraint. Given
a set of forecasted security returns and an optimization routine, together with an estimated
covariance matrix, a manager can calculate the expected information ratio, with and without a
given constraint, and compute the difference.2 We will perform this type of calculation later as a
numerical check of Equation 4. The value of the generalized fundamental law is that it provides
a strategic framework in which to view the impact of constraints on potential value-added. In
addition, the TCplays a critical role in the ex-post decomposition of the realized active return
developed later.
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An alternative formulation of the generalized law in Equation 4 that corresponds to the
correlation triangle in Figure 1 is also helpful. Expected value-added at the base of the triangle is
reflected in the ex-ante performance coefficient, orPC. We definePCas the expected value of
the cross-sectional correlation between risk-adjusted active weights and realized residual returns.
The technical appendix shows that PCis equal to the ex-ante information ratio, IR,divided by
the square root ofN. By making this substitution in Equation 4, the generalized fundamental law
can be expressed in correlation form as
ICTCPC . (5)
The formulation of the generalized law in Equation 5 is intuitive; the expected correlation of
active weights to realized returns (PC) is equal to the correlation of active weights to forecasted
returns (TC) times the expected correlation of forecasted returns to realized returns (IC).
However, this simple relationship is only valid ex-ante; the transfer coefficient relates expected
performance (PC) to expected signal quality (IC). Later, we show that realized or ex-post
performance is described by a more complicated structure.
Constraint Case Studies
In this section, we employ the Barra portfolio optimizer and an S&P 500 benchmark to
create several case studies in the application of the generalized fundamental law. Barra is a
leading supplier of security covariance matrix estimates as well as optimization software thatstructures portfolio weights.
3 We generate a set of forecasted returns for the 500 stocks in the
index by
iii SIC = (6)
whereICis an assumed information coefficient, iis the estimated residual return volatility for
each stock, and the Si are random numbers drawn from a standard normal distribution. The
forecasted returns in this illustration are random, but their relative magnitudes and cross-
sectional variation are consistent with actual security volatilities and the assumed quality of the
signal.4 We use an assumed ICvalue of 0.067, so that the unconstrained ex-ante information
ratio, according to the fundamental law, has a value of IR = 0.067 * 500 = 1.50. These
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expected returns are fed into the optimizer with the condition that active portfolio risk (i.e.,
tracking error) be limited to 5.0 percent.
As a baseline from which to make comparisons, the first optimization is conducted
without any constraints placed on the portfolio except the standard full-investment budget
constraint. The active weights output by the optimizer are shown in Figure 2 with the active
weights sorted from left to right based on each stocks risk-adjusted forecasted residual return.
The active weights in Figure 2 range from about +2.0 percent on the left for the stocks with the
highest forecasted risk-adjusted residual returns, to less than 2.0 percent on the right for stocks
with the lowest forecasted risk-adjusted residual returns.
Figure 2
S&P 500: Unconstrained
Transfer Coefficient= 0.98
-4%-3%
-2%-1%0%1%2%3%4%
High Risk-adjusted Forecasted Return Low
ActiveWeight
The ex-ante active risk, or tracking error of the portfolio, can be calculated and works out
to be exactly 5.0 percent, as specified to the optimizer. The expected active return, calculated by
( ) =
=N
i
iiA wRE1
(7)
is 7.9 percent. This gives an ex-ante information ratio of 7.9/5.0 = 1.58, slightly higher than the
1.50 value suggested by the original fundamental law. The discrepancy is due to the simplifying
assumptions in the derivation of the law that are not met in the actual optimization. The first and
most material cause of the discrepancy is the assumption of a diagonal covariance matrix for
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residual security returns. Specifically, the proof of the fundamental law assumes that the only
source of covariance between total security returns is the benchmark portfolio, an assumption
that is violated by the actual risk estimates in the Barra-supplied covariance matrix. Second, no
budget constraint in imposed in the derivation of the theoretical results in Equation 3 while the
optimizer forces the sum of the active weights to be zero.
The weights from the unconstrained optimization routine provide an important check on
the real-world accuracy of the generalized, as well as the original fundamental law. In theory,
the active weights in Figure 2 should monotonically decline from left to right, in perfect
correspondence with risk-adjusted expected returns. In fact, small deviations in the pattern occur
because of residual covariances among the securities. The cross-sectional correlation between
risk-adjusted weights and expected returns, the transfer coefficient (TC), is 0.98 rather than a
perfect 1.00. Small deviations from a perfect transfer of information occur because the optimizer
correctly adjusts for the fact that the residual returns of the securities have some correlation.
However, the deviations in a real-world setting are small, leading to a transfer coefficient that is
almost perfect.
In the sections that follow, we discuss several types of common constraints under
different levels of active portfolio risk. As a summary of the results, Table 1 presents the TCfor
each case. For example, the unconstrained case just discussed is shown in the first row. This is
followed by entries for: 1) the long-only constraint, 2) a long-only and market-cap neutral
constraint, 3) turnover limits, and 4) a multiple-constraint portfolio similar to what might be
found in practice. Notice that the transfer coefficient declines when either the active risk is
increased or when additional constraints are added. In either event, the transfer of information
into active positions is reduced, thus lowering the transfer coefficient and decreasing the
information ratio. However, if the decline in the transfer coefficient occurs because of a desired
increase in active risk for a given constraint, the expected active return does not necessarily
decline. The investor can be rewarded with an increase in expected active return for the
additional active risk, even though the information ratio declines. However, such is not the case
if the decline in the transfer coefficient is caused by adding additional constraints while trying to
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Case study 1: Long-only constraint
We discuss the long-only constraint as our first practical example of the generalized
fundamental law for several reasons. First, the long-only constraint is ubiquitous, so common
that it is often not properly acknowledged as a constraint. Second, the long-only constraint is
quite material. We find TC to be lowered more by the long-only constraint than by any other
single restriction, with the possible exception of tight turnover limits. Third, we can compare our
findings from the generalized fundamental law to estimated declines in IR documented in the
recent examination of long-short versus long-only portfolios in Grinold and Kahn (2000). The
relative advantages of long-short portfolios are also examined by Brush (1997) and Jacobs, Levy
and Starer (1998, 1999).
When short sales are prohibited, the manager can only reduce the weight of an
unattractive security to zero. Thus, the absolute value of the negative active weight is limited by
the securitys weight in the benchmark. This limit may not be binding for securities with large
benchmark weights, but is quite restrictive for securities that have smaller benchmark weights.
In the extreme, securities with little or no weight in the benchmark cannot receive any
measurable negative active weight, no matter how pessimistic the manager is about future
returns. When short selling is allowed, securities with large negative forecasted residual returns
can be shorted, and the short-sale proceeds used to fund long positions in the securities expected
to have the highest positive residual returns. In other words, the active weights in a long/short
portfolio are primarily determined by the risk-adjusted return forecasts, and therefore conform
more closely to the theoretical optimal active weights in Equation 3.
To analyze the impact of the long-only restriction, the unconstrained portfolio shown in
Figure 2 is re-optimized with the added constraint that the portfolio weight for each security
cannot be less than zero. The same set of forecasted returns are used and the tracking error target
is again set to 5.0 percent. The resulting active weights, sorted by risk-adjusted forecasted
residual returns, are shown in Figure 3. One notable impact of the long-only constraint is the
large number of small negative active weights. In fact, only 89 of the 500 stocks are held in the
managed portfolio, with the remaining 411 receiving negative active weights equal in magnitude
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to their benchmark weight. The positive active weights are concentrated on the relatively few
stocks with the highest forecasted residual returns at the far left of Figure 3. The correspondence
between forecasted returns and active weights is much weaker given the long-only constraint.
The transfer coefficient, calculated by the risk-adjusted cross-sectional correlation between
active weights and forecasted residual returns, is only 0.58. The TCvalue of 58 percent indicates
that 42 percent of the unconstrained potential value-added is lost in the portfolio construction
process, due to the long-only constraint.6
Figure 3
S&P 500: Long-Only Constraint
Transfer Coefficient= 0.58
-4%-3%-2%-1%0%1%2%3%4%
High Risk-adjusted Forecasted Return Low
ActiveWeight
The accuracy of the generalized fundamental law can be assessed by a direct calculation
of the expected active return using Equation 7; the sum of the products of active weights taken
and forecasted residual returns. The directly calculated expected active return on the long-only
portfolio is 4.2 percent, yielding an IR of 4.2/5.0 = 0.84, or 56 percent of total theoretical
unconstrained IR of 1.50. Thus, the transfer coefficient of 58 percent, together with the
information coefficient and the number of securities, provides a fairly accurate perspective on the
potential value added under constraints. The accuracy of the generalized law will vary
depending on the degree to which off-diagonal elements in the residual return covariance matrix
are non-zero, but the law appears to be a reasonably accurate description for a large portfolio of
securities like the S&P 500.
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Case study 2: Factor-Neutrality Constraints
Portfolios are often constrained to have characteristics that are similar to the benchmark
along one or more dimensions. For example, the managed portfolio may be constrained to have
the same style (value/growth) tilt as the benchmark. These constraints can be a material
restriction in the portfolio construction process, depending on the investing style and data used to
forecast returns. For example, a growth manager may favor stocks with mid-range P/Es, or
growth at a reasonable price. If the manager is benchmarked against a growth index, and
constrained to have the same growth exposure as the index, the positions dictated by the mid-
range P/E-based return forecasts will be restricted. Another common neutrality constraint
involves the market-capitalization of the securities in the managed portfolio compared to the
benchmark. Managers, or their clients, might require that the managed portfolio not be any more
sensitive on average than the benchmark to market-capitalization exposure.
Figure 4
S&P 500: Long-Only Constraint
(Market Capitalization Sorting)
-4%-3%-2%-1%0%
1%2%3%4%
Large Market Capitalization Small
ActiveWeight
We use market-cap neutralization as our example of a factor constraint because a small-
cap bias happens to be a by-product of the long-only constraint previously discussed. To
illustrate, Figure 4 displays the active weights in the long-only constrained portfolio in Figure 3,but this time sorted from left to right by market capitalization. With this sorting, the nature of
the long-only constraint is readily apparent. All the large negative active weights are associated
with the large-cap stocks on the left side of the chart. The magnitude of the negative active
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weights is very small for the small-cap stocks at the right side of the chart. However, positive
active weights are as common among the small-cap stocks as the large-cap stocks. The result is
a significant small-cap bias in the managed portfolio. The bias towards small-cap stocks is an
unintended but natural consequence of the long-only constraint. Biases in other common risk
factors, such as a value-growth tilt are often a result of data used in the return forecasting
process, rather than a by-product of portfolio constraints.
Figure 5
S&P 500: Long-Only and Market-Cap-Neutral Constraints
Transfer Coefficient= 0.47
-4%-3%
-2%-1%0%1%2%
3%4%
High Risk Adjusted Forecasted Return Low
ActiveWeigh
t
To eliminate the small-cap bias, Figure 5 contains a TCdiagram for an optimization with
long-only andmarket-cap neutrality constraints.7 The correlation between active weights and
forecasted residual returns is further reduced to TC = 0.47, or 47 percent. In other words, the
added constraint leads to an even lower correlation between active weights and forecasted
residual returns than in Figure 3, with a correspondingly lower potential for value-added. Figure
6 displays the long-only and market-cap-neutral constrained active weights sorted by market
capitalization. The small-cap bias induced by the long-only constraint has been corrected; the
positive active weights have been reduced to match the negative active weights on the small-cap
end of the graph. However, the result is a portfolio that is constrained away from having
significant active management in anything but the large-cap arena, as indicated by the amount of
ink on the left end of the TC chart. In fact, about half of the active management of the
portfolio, as measured by the absolute value of the active weights, is concentrated in the largest
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Figure 7 contains a TC diagram for a portfolio that is unconstrained (i.e., long/short),
except for a turnover limit of 50 percent. The tracking error is set a 5 percent, as in the previous
examples.
Figure 7S&P 500: Turnover Constraint
Transfer Coefficient= 0.73
-4%-3%
-2%-1%0%1%2%3%4%
High Risk-adjusted Forecasted Return Low
ActiveWeight
Active weights, or deviations from the benchmark weight, are zero for many of the stocks in the
middle section of Figure 7, because turnover cannot be wasted on securities with forecasted
residual returns that are close to zero. The result is a transfer coefficient of 73 percent. Tighter
turnover limits naturally result in lower transfer coefficients. For example, when turnover is
limited to 25 percent, the resulting TCis only 49 percent.
Case Study 4: Multiple Constraints
The various types of constraints we have examined have the combined effect of
significantly altering actual active weights taken from the unconstrained optimal weights in
Equation 3. As a final example of constrained portfolio construction, Figure 8 contains a TC
chart for a portfolio with multiple constraints, similar to what might be found in practice. The
constraints in this optimization are long-only, market-cap and dividend-yield neutrality withrespect to the benchmark, and turnover limited to 50 percent from a prior long-only portfolio
optimized to an unrelated set of forecasted returns. The benchmark is the S&P 500, and active
portfolio risk is set at 5 percent, as before. Figure 8 shows only a loose correspondence between
active weights and forecasted residual returns. There are negative active weights in some of the
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highest forecasted-return stocks, and large positive active weights in some of the lowest
forecasted-return stocks. The transfer coefficient is 31 percent. More than two thirds, or 69
percent, of the value-added predicted by the information coefficient alone, is lost in the portfolio
construction process. TCvalues as low as 30 percent may be common among long-only U.S.
equity managers. The constraint-sets have an unmeasured and perhaps under-appreciated impact
on performance.10
Figure 8
S&P 500: Multiple Constraints
Transfer Coefficient= 0.31
-4%-3%-2%-1%0%1%2%
3%4%
High Risk-adjusted Forecasted Return Low
ActiveWeight
Ex-post Correlation Diagnostics
The perspectives discussed to this point relate to the potential value-added through
portfolio management, as measured by the expected information ratio. Actual performance in
any given period will vary from its expected value in a range determined by the tracking error
and the ex post quality of information. We now turn our attention to diagnosing actual
performance, the ex-post analysis of the realized active returns.
As explained in the introduction, a key determinant of the sign and the magnitude of the
realized active portfolio return, RA, is the degree to which the manager has positive activeweights on securities that realize positive residual returns, and negative active weights on
securities that realize negative residual returns. In other words, actual performance is determined
by the relationship between active weights and realized residual returns, a cross-sectional
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correlation we refer to as the ex-post or realized performance coefficient. We will use
subscripted rho notation for realized correlations, to distinguish them from expected
correlations, denoted by capitalized acronyms. Specifically, the realized performance
coefficient, w,r, is the cross-sectional correlation between risk-adjusted active weights and
realized residual returns. On the other hand, the notation for the expected performance
coefficient is PC, which the generalized fundamental law in Equation 5 states is approximately
TC times the expected information coefficient, IC. In the technical appendix we derive the
following important decomposition of the realized performance coefficient
rcrrw TCTC ,2
,, 1 + (8)
where ,ris the realized information coefficient, and c,ris a realized cross-sectional correlation
coefficient that measures the noise associated with portfolio constraints. Note that there is no
realized correlation value associated with the transfer coefficient, TC, because TCmeasures the
relationship between forecasted risk-adjusted residual returns and active weights, both of which
are established ex-ante. As in the generalized law, we use the approximate equality notation in
the ex-ante relationship in Equation (8) because of its dependence on a zero-mean
approximation, as specified in the technical appendix.
Equation 8 has important implications. In the ideal world of a completely unconstrained
portfolio construction process, TChas an approximate value of one. When TCis one in Equation
8, realized performance, w,r, is determined solely by the actual success of the return forecasting
process, ,r. In other words, if there is a perfect transfer of forecasted residual returns into
active weights, then the realized performance coefficient is identical to the realized information
coefficient. However, Equation 8 indicates that for TC values less than one, realized
performance is only partly a function of the success of the signal. For lower values of TC,
realized performance is increasingly dependent on a second realized correlation coefficient, c,r,
the risk-adjusted cross-sectional correlation between a new variable, ci, and realized returns, ri.
As explained in the technical appendix, cifor each security is the difference between the actual
active weight taken and the expected constrained active weight, TCwi*.11
When the risk-
adjusted cross-sectional correlation between ciand realized returns, c,r, is positive, performance
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is increased because at the margin the optimization has forced higher weights than expected on
positively-rewarded securities and lower weights than expected on negatively-rewarded
securities in order to satisfy the portfolio constraints. Of course the constraint noise coefficient,
c,r, might just as easily turn out to be negative, decreasing realized performance.
We can be more specific about the sources of variation in constrained portfolio
performance. Under the maintained simplifying assumption of a diagonal residual return
covariance matrix, the variance of each of the three realized correlation coefficients in Equation
8, w,r, ,r, and c,r, is one overN, the number of observations in the cross-sectional correlation
calculations. In addition, the two right-hand side correlations, ,r and c,r, are independent. As
a result, the variance of the realized performance coefficient is decomposed into signal and noise
variances by
( ) )(1)()( ,2
,
2
, rcrrw VarTCVarTCVar + . (9)
For example, if TC = 0.80, then 64 percent of the variation in expected performance is
attributable to the success of the signal, while the remaining 36 percent is attributable to the
noise induced by portfolio constraints. For a low TC value of 0.30, only 9 percent of the
variation in performance is attributable to the success of the signal, while the remaining 81
percent is attributable to constraint-related noise. The practical implication is that heavily-
constrained portfolios will experience frequent periods when the forecasting process works, as
indicated by a positive realized information coefficient, but performance is poor. Alternatively,
the realized active portfolio return may be positive, even though the realized information
coefficient is negative. Without the perspective of Equations 8 and 9, low TCmanagers might
wonder why realized performance seems unrelated to their ability to forecast returns.
Implementation of an Ex-post Diagnostic System
The ex-post relationship in Equation 8 suggests a diagnostic system for analyzing activemanagement performance under constraints. As explained in the technical appendix, the realized
active return,RA, is related to the realized performance coefficient, w,r, by
)/(, iiArwA rStdNR . (10)
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We can think of the term A Nas a measure of portfolio aggressiveness. More active risk, A,
equates to larger absolute active weights, or a more aggressively managed portfolio. The last
term in Equation (10), Std (ri/i), is the cross-sectional standard deviation of risk-adjusted
realized residual returns, or return dispersion. Because the security returns are risk adjusted, theexpected value of the return dispersion term is 1.0. Risk-adjusted statistics are technically more
precise, although the cross-sectional correlations and standard deviations can also be calculated
without the risk adjustment.12
Equation 10 can be read, Active return equals realized performance coefficient times
portfolio aggressiveness times realized return dispersion. The sign of the realized performance
coefficient determines the sign of the active return. Portfolio aggressiveness and realized return
dispersion simply act as scaling factors. The realized performance coefficient is further
decomposed into the realized information coefficient and the constraint-noise coefficient terms
according to Equation 8. Combining Equations 8 and 10, we have
)/(1 ,2
, iiArcrA rStdNTCTCR + . (11)
which forms a diagnostic system where the realized active return is the product of the
decomposed realized performance coefficient (in square brackets) times portfolio aggressiveness
times realized return dispersion. Because of the simplifying assumptions used to derive the
generalized fundamental law, actual performance, calculated directly by Equation 1, will vary
slightly from the explained performance in Equation 11.
We verify the ex-ante and ex-post mathematical relationships derived in this paper, and
illustrate the implementation of the diagnostic system, with a Monte-Carlo simulation. In the
simulation, the forecasted residual returns and active weights from the long-only constrained
optimization shown in Figure 3 are used. The weights under the long-only constraint have a TC
of 58 percent (0.578 to be more exact). Ten thousand sets of 500 realized residual returns were
generated using individual security residual-risk estimates from Barra. The realized return sets
were generated with anICparameter value of 0.067, the same parameter value used to scale the
forecasted returns.13
Summary statistics were then compiled for the ten thousand simulated
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variation in the realized signal, as suggested by Equation 9. This is very close to the predicted
value given by TCsquared of 0.5782= 33.4 percent.
The simulation also provides observations that can be used to illustrate how an ex-post
correlation diagnostic system operates. Table 2 lists parameter values for five of the ten
thousand simulated annual periods. The first period shown is noteworthy in that the realized
information coefficient is a healthy 0.075; slightly above the managers average information
coefficient of 0.067. Given the success of the forecasting process in this period, the manager
might expect good realized performance, even acknowledging the decline in expected
performance due to constraints. Taking the expectation of active return in Equation 11,
conditional on the realized information coefficient, gives
NTCRE ArrA ,, )|( = . (12)
The conditional active return based on Equation 12 is shown in Table 2. The conditional
expected return in the first period is 4.8%, slightly higher than the average value of 4.2% because
of the slightly higher than average realized information coefficient. However, the actual active
return in this period is slightly negative at 0.4% because of an unusually large and negative
constraint noise coefficient of -0.057. The portfolio constraints precluded the investor from
taking positions in particular securities that were attractive after the fact. On the other hand, the
realized information coefficient in the third period is negative, at -0.020. Given the negative
realized information coefficient, the manager might have expected an active return of -1.3%.
However, despite the poor success of the return forecasting process in this period, the active
return is a positive 3.2%. In this case the portfolio constraints precluded the investor from taking
positions in securities that were particularly unattractive after the fact (indicated by a positive
constraint noise coefficient of 0.052). The loose correspondence between signal success and
actual performance in this simulation is indicative of the mid-range TC value of 0.578. The
disparity between the success of the return forecasting process and actual portfolio performance
can be even greater and more frequent in lower TCportfolios.
The active return explained by the diagnostic system is highly correlated with the actual
active return. However, because of the simplifying assumptions that underlie the mathematics
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the diagnostic system is not exact, as shown in the last two columns of Table 2. The active
return explained by the diagnostic system is close to but is not an exact match for the actual
performance of the portfolio. While we are encouraged by the simulation results for the S&P
500, a commonly used domestic equity benchmark, we are unable to state any general bounds on
the accuracy of the diagnostic system for other benchmarks. The most critical simplifying
assumption in the mathematical derivation of the generalized law is the assumption of a diagonal
residual covariance matrix, which seems to be an acceptable approximation.
There are a number of ex-post performance diagnostic implementation issues that we do
not address in this paper. These include non-annual performance periods, the impact of
estimation error in security risk parameters, and procedures for estimating the inaccuracy of the
diagnostic system due to simplifying assumptions. However, the simulation illustrates the key
ex-post concept that the realized information coefficient by itself explains only a portion of the
actual performance when there are material portfolio constraints. Without an ex-post diagnostic
system that measures constraint-related correlations, managers may be puzzled by actual
performance that is only loosely related to their ability to predict returns.
Conclusion
We have suggested that the fundamental law of active management, an ex-ante
relationship, can be generalized to include a transfer coefficient, as well as an information
coefficient. The information coefficient (IC) measures the strength of the return forecasting
process, or signal. We introduce the transfer coefficient (TC), which measures the degree to
which the signal is transferred into active weights. The TCturns out to be a simple scaling factor
in the generalized fundamental law and is a quick way to measure the extent to which constraints
reduce the expected value of the investors forecasting ability. In the absence of any constraints,
the transfer coefficient is approximately one, and the original form of the fundamental law is
accurate. However, in practice, managers often work under constraints that produce TCvalues
that range from 0.3 to 0.8. The lower transfer coefficient suggests why average performance in
practice is only a fraction (0.3 to 0.8) of what is predicted by the original form of the
fundamental law.
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We also derived a decomposition of ex-post performance, based on the transfer
coefficient and the realized information coefficient. The ex-post performance decomposition
indicates that only a fraction (TCsquared) of the variation in realized performance, or tracking
error, is attributable to variation in realized IC. If TC= 1.0, then variation in performance is
wholly attributable to the success of the return-prediction process. However, if TC = 0.3, then
only 9 percent of performance variation is attributable to the success of the signal, with the
remaining 91 percent attributable to constraint induced noise. Low TCmanagers will experience
frequent periods when the signal works but performance is poor, and periods when performance
is good even though the return forecasting process fails.
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Table 2
Monte-Carlo Simulation and Ex-Post Correlation Diagnostics Exampl
S&P 500: Long-Only Constraint
This table lists five observations out of ten thousand in a Monte-Carlo simulation. The simulation is for the l
an S&P 500 benchmarked portfolio at the A = 5.0% active risk level (Case Study 1). The information corealized returns isIC= 0.067. The transfer coefficient in this simulation is constant at TC= 0.578. The portf
at NA = 0.05 * 500 = 1.118. The average and standard deviation summary statistics for realized values, sh
are for all ten thousand simulated periods.
Period
Transfer
Coefficient
TC
Realized
Information
Coefficient
,r
Portfolio
Aggres-
siveness
NA
Conditional
Active
Return
(note a)
Realized
Constraint
Coefficient
c,r
Explained
Performance
Coefficient
(note b)
Realized
Return
Dispersio
Std(ri/
1 0.578 0.075 1.118 4.8% -0.057 -0.003 1.02 0.578 0.136 1.118 8.8% 0.001 0.079 1.0
3 0.578 -0.020 1.118 -1.3% 0.052 0.031 0.9
4 0.578 0.046 1.118 3.0% -0.007 0.021 0.9
5 0.578 0.010 1.118 0.6% 0.011 0.015 1.0
Average 0.067 -0.002 1.0
Std. Dev. 0.044 0.045 0.0
a) The Conditional Active Return is calculated by Equation 12: ( ) NTCRE ArrA ,,| = .
b) The Explained Performance Coefficient is calculated by Equation 8: rcrrw TCTC ,2
,, 1 + .
c) The Explained Active Return is calculated by Equation 11: /(1 ,2
, iArcrA rStdNTCTCR +
d) The Realized Active Return is calculated by Equation 1: =
=N
i
iiA rwR1
.
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Technical Appendix
Framework and Notation
Given a benchmark portfolio, the total excess return (i.e., return in excess of the risk-free
rate) on any stock i can be decomposed into a systematic portion that is correlated to the
benchmark excess return, and a residual return that is not, by
iBi
total
i rRr += (A1)
whereRBis the benchmark excess return, iis the beta of stock iwith respect to the benchmark,
and riis the security residual return with mean zero and standard deviation i. The benchmark
portfolio is defined by the weights, wB,i, assigned to each of the N stocks in the investable
universe. The benchmark excess return is
=
=N
i
total
iiBB rwR1
, . (A2)
If a given stock iin the investable universe is not in the benchmark portfolio, then wB,i= 0. Like
the benchmark, the excess return on an actively managed portfolio, RP, is determined by the
weights, wP,i,on each stock;
=
=N
i
total
iiPP rwR1
, . (A3)
Define the active return as the managed portfolio excess return minus the benchmark excess
return, adjusted for the managed portfolios beta with respect to the benchmark; RARP- PRB.
The managed portfolios beta, P, is simply the weighted average beta of the stocks in the
managed portfolio; =
N
i
iiPP w1
, . With some algebra, and the fact that the beta of the
benchmark must be exactly one, it can be shown that the active return is
=
=N
i
iiA rwR
1
(A4)
where the active weight for each stock is defined as the difference between the managed
portfolio weight and benchmark weight; wi= wP,i wB,i.
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The formulation for the active return in Equation A4 (Equation 1 in the paper) is the
focus of our analysis. Note that the active weights in Equation A4 sum to zero as they are
differences in two sets of weights that each sum to one. Also, note that the stock returns, ri, in
Equation A4 are residual, not total, excess returns. Residuals are the relevant component of
security returns when performance is measured against a benchmark on a beta-adjusted basis.
Throughout this paper, we take the individual security risk-estimates (i and i) as given,
although they may in fact be estimated with error.
We assume that portfolio optimization is based on choosing a set of active weights, wi,
that maximize the mean-variance utility function
2)( AAREU = (A5)
where E(RA) is the expected active return, A2 is the active return variance, and is a risk-
aversion parameter. Given a set of forecasts for the individual residual stock returns, i, the
expected active return for the portfolio is
=
=N
i
iiA wRE1
)( . (A6)
Under the important simplifying assumption that the residual stock returns are uncorrelated (i.e.,
the residual covariance matrix is diagonal), the active return variance is
= 222 iiA w (A7)
where i2is the residual return variance for stock i. Substituting Equations A6 and A7 into the
optimization problem in Equation A5 leads to optimal weights given by the formula
2
12
*
i
i
iw = . (A8)
The simple closed-form solution to optimal weights in Equation A8 is based on two simplifying
assumptions. First, we assume a diagonal residual return covariance matrix, or that residual
returns are perfectly uncorrelated with each other.14
Second, there is no direct budget constraint
in the formal optimization problem. Active weights sum to zero, but no such condition is
imposed in the optimization of Equation A5. The second assumption will generally not be a
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problem for portfolios with many securities and typical risk-return parameters. One security can
be adjusted to absorb the balancing weight without distorting the analysis to any great extent.
Despite these two simplifying assumptions, the optimization result in Equation A8 will prove
useful in understanding the impact of constraints.
An intuitive property of Equation A8 is that the mean-variance optimal active weight for
each stock is proportional to the stocks forecasted residual return over residual return variance.
The constant of proportionality, common to all securities, is related to the inverse of the risk-
aversion factor, . Lower values of lead to more aggressive portfolios, with proportionally
larger absolute active weights, higher expected active return, and higher active risk. We can
insert the optimal weights from Equation A8 into the definition of active return variance in
Equation A7, and solve for . Using this solution for , the optimal active weights in terms of
active portfolio risk, A, are
2
1
2
*
=
= i
iN
i
A
i
i
iw
. (A9)
We make the operational assumption that the security alphas, i, are generated from
scores, Si, that have cross-sectional zero mean and unit standard deviation. Specifically, alphas
are the product of IC, residual security volatility, and score, based on Grinolds (1994)
prescription;
iii SIC = . (A10)
We do not subscript IC, making the implicit assumption that the information coefficient is the
same for all securities.
The Fundamental Law
A proof of Grinolds (1989) fundamental law of active management follows directly from
the optimization and alpha generation mathematics. Given a cross-sectional set of scores, Si,
constructed to have zero mean and unit standard deviation, Equation A10 dictates that the ratio
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i/ihas a cross-sectional mean of zero and standard deviation ofIC. Based on the zero-mean
property, the denominator in the last term in Equation A9 is a standard deviation calculation for
i/i, but without the requisite N divisor. We employ the term zero-mean property to justify
variance and covariance calculations that are sums of squares and products.15
Making this
substitution, and then multiplying each side by i, gives the risk-adjusted optimal weights16
=
NICw A
i
i
ii
*. (A11)
Since the last term in Equation A11 is constant across stocks, and the ratio i/ihas a zero mean,
the set of risk-adjusted optimal active weights, wi*i, also has a zero mean, and cross-sectional
standard deviation
NNICStdwStd AA
i
iii
=
= )( * . (A12)
The zero-mean property of wi*iand i/iallows the expected active return in Equation
A6 to be recast in a correlation formulation as follows;
)/,()()(*
1
*
1
*
iiii
N
i i
i
ii
N
i
iiA wCovNwwRE
=
==
==
ICNStdwStdN Awiiiiw ,*
, ** )/()( == (A13)
where w*,is the correlation coefficient between risk-adjusted optimal weights and alphas; the
correlation between wi*i, and i/i. This correlation coefficient is 1.0 because the two
variables are proportional, as indicated by Equation A11. Substituting a correlation coefficient
value of w*, = 1.0, and dividing both ends of Equation A13 by active risk, A, gives the
original form of the fundamental law
NICIR= (A14)
whereIRis the information ratio of expected active return to active risk;IRE(RA)/A.
In practice, active managers are typically subject to constraints that cause them to deviate
from the unconstrained optimal active weights. Searching algorithms are available that can
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determine optimal active weights given a set of constraints and security return forecasts,
although the solutions do not generally have a simple closed-form expression. Let wibe a set
of active weights that are generated by an optimizer where the active risk is defined by Equation
A7. The covariance and correlation methodology used in Equation A13 for unconstrained
optimal active weights can be applied to actual active weights taken as follows;
)/,()()(11
iiii
N
i i
i
ii
N
i
iiA wCovNwwRE
=
==
==
2
2
)()/()( iiA
iiii wMeanN
ICTCNStdwStdTCN
== . (A15)
where Mean(wii) is the cross-sectional mean of wii. The complexity of the final result
arises from the fact that there is nothing to force the zero-mean property on wii, although the
mean is likely to be small because the active weights alone, wi, have a zero mean. In addition,
this term is squared in Equation A15. Using zero as an approximation, and dividing by active
risk, A, as before, we have the generalized fundamental law;
NICTCIR (A16)
or in terms of the expected active return AA NICTCRE )( . TC is the transfer
coefficient, calculated as the cross-sectional correlation coefficient between risk-adjusted
forecasted residual returns and active weights; i/iand wii. Note that TCcan be calculatedex-ante (i.e., before returns are realized) based on the set of weights from an optimizer. We will
continue to employ the approximation Mean(wii) = 0 in the ex-post analysis that follows, and
use the equality notation wherever the approximation Mean(wii) = 0 impacts the results.
Ex-post Correlation Coefficient Relationships
The realized active return in any time period is the sum of the product of weights and
returns, as defined in Equation A4. The realized active return can be decomposed into cross-
sectional statistics by
( ) )/()/,( ,11
iiArwii
N
i
ii
i
i
ii
N
i
iiA rStdNrwCovNr
wrwR
==
=
== (A17)
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The realized correlation coefficient between risk-adjusted weights and returns, w,r, is an
important summary measurement of performance that will be referred to as the realized
performance coefficient. The notation for the expected value of the performance coefficient is
PCE[w,r]. Note that the cross-sectional standard deviation of realized risk-adjusted returns,
Std(ri/i), has an expected value of one. Taking expectations on both ends of Equation A17, and
rearranging, indicates that the expected performance coefficient, PC, is simply the expected
information ratio, E[RA]/A, over the square root of N . With this substitution, the generalized
fundamental law in Equation A16 has the form
ICTCPC . (A18)
Given a set of actual active weights, wi, from an optimizer, and hypothetical optimal
active weights, w*i, derived analytically from expected returns, we define a new variable, bi
wi w*i, which can be thought of as the optimal weight not taken on each stock due to
constraints. Based on this definition, the cross-sectional variance of biiis
),(2)()()( **
iiiiiiiiii wwCovwVarwVarbVar +=
( )TCNNNN
AA
ww
AA 222
22
,
22
* =+
. (A19)
Note that the substitution of the transfer coefficient, TC, for the correlation w*,w in the final
result is validated by the proportional relationship between risk-adjusted optimal weights and
alphas in Equation A11.
By applying the definitional relationship, wiwi*+ bi, the realized active return can be
decomposed into two correlation structures by
( ) ( ) ( ) = ==
+
=+=
N
i
N
i i
i
ii
i
i
ii
N
i
iiiiA
rb
rwrbrwR
1 1
*
1
*
)/(22,, iiArbr
rStdNTC +
(A20)
where the replacement for Std(bii) is given by Equation A19. Note that the correlation between
wi*iand ri/iis replaced by the realized information coefficient, ,r, based on the proportional
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relationship in Equation A11. Equating the final expressions in Equations A17 and A20, and
dividing out common terms, yields the correlation relationship
rbrrw TC ,,, 22 + . (A21)
Equation A21 indicates that for unconstrained portfolios with a transfer coefficient close to 1.0,
the realized performance coefficient, w,r, is largely dependent on the realized information
coefficient, ,r, or success of the return signaling process. However, for lower TC values,
realized performance is increasingly dependent on the noise associated with constraints, as
measured by the correlation coefficient b,r. Note that the expected value of the constraint noise
coefficient, b,r, is not zero.17
Also, it will be shown that the constraint noise correlation, b,r,
and realized information coefficient, ,r, in Equation A21 are not independent.
Ex-post Performance Decomposition
An alternative ex-post correlation diagnostic equation can be derived that has more
favorable statistical properties than Equation A21 using a modified definition of optimal weight
not taken. In place of bi wi - wi*, we define an alternative variable ci wi - TCwi*.
Recall that TC is equivalent to the correlation between the hypothetical risk-adjusted optimal
weights and the actual weights from the optimizer. The multiplier TC in front of wi* is a
shrinkage factor, or can be thought of as the expected value of wi, given the value of wi*.
Note that TCand consequently the ci termcan be calculated ex-ante (i.e., after the portfolio is
optimized but before returns are realized.) The cross-sectional variance of cii parallels that in
Equation A19;
),(2)()()( **2 iiiiiiiiii wwCovTCwVarwVarTCcVar +=
( )222
,
22
2 12 * TCNN
TCNN
TC AAww
AA =+
. (A22)
where again the substitution of the transfer coefficient, TCfor the correlation w*,win the final
result is validated by the proportionality between risk-adjusted optimal weights and alphas.
Using the result in Equation A22, the realized active return can be decomposed into two
correlation structures that parallel Equation A20;
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( ) ( ) ( ) = ==
+
=+=
N
i
N
i i
i
ii
i
i
ii
N
i
iiiiA
rc
rwTCrcrwTCR
1 1
*
1
*
( )[ ] )/(1 ,2, iiArcr rStdNTCTC + (A23)
Equating the final expressions in Equations A17 and A23, and dividing out common terms,
yields the correlation relationship;
rcrrw TCTC ,2
,, 1 + . (A24)
The correlation diagnostic in Equation A24 differs from Equation A21 in structure and in the
alternative measure of constraint induced noise, c,r. The expected value of the alternative
constraint noise coefficient, c,r, is zero. This can be verified by taking expectations of both
sides of Equation A24, and employing the relationship in Equation A18 and the fact that the
expected value of the realized information coefficient, ,r, is the assumed information
coefficient parameter,IC.
The two ex-ante correlation coefficients on the right-hand side of the alternative
correlation structure in Equation A24 can be shown to be approximately independent, as follows.
The realized values of cross-sectional correlation coefficients have a standard deviation of
N/1 around their means, by definition. Thus, the variance analysis of Equation A24 is
( )N
TCTCCorrelN
TCN
TCN
rcr11),(21111 2,,
22 + . (A25)
Rearranging Equation A25 indicates that 0),( ,, rcrCorrel . Similar analysis on the
correlation structure in the bi-based correlation diagnostic in Equation A21 indicates that it is not
independent since ),( ,, rbrCorrel 2/)1( TC 0.
The value of the independence property of the ci-based correlation diagnostic in Equation
A24 is variance decomposition. Because the two right-hand-side realized correlation coefficients
are approximately independent, we have
( ) )(1)()( ,2
,
2
, rcrrw VarTCVarTCVar + . (A26)
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Thus, TC2percent of the variation of the performance coefficient, w,r, is due to the success of
the signal as measured by the realized information coefficient, ,r, while the remaining 1-TC2
percent is attributable to constraint-induced noise.
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10While it may appear that constraints are always undesirable, some constraints guard against
the effect of estimation error in the forecasting process, which can then be magnified by the
optimization process. The manager may be willing to tolerate a lower transfer coefficient to
protect against sizeable underperformance if the forecasting process fails.11
An alternative and perhaps more intuitive definition of active weight not taken,
b w wi i
= * results in a different ex post correlation structure than Equation (8). However, the
definition we use in Equation (8) of the difference between actual active weight and expected
constrained active weight c w TC wi i i
= * has nicer mathematical properties. The technical
appendix discusses both results.
12A simple non-risk-weighted system can be implemented with the cross-sectional correlation
and standard deviation calculations based on wi, i, and ri, instead of the riskadjusted datawi, i/i, and ri/i. While the characterization of the realized information and transfercoefficients are incorrect when the securities have different estimated residual risks, the ex-postsystem will still add up. However, the components will not correspond exactly to theconceptual decomposition suggested by the generalized fundamental law.
13 While the realized residual returns are generated to have a 0.067 correlation with their
respective forecasted residual returns, and have magnitudes consistent with their respective
residual risks, they are cross-sectionally random within in each set (i.e., the returns simulate a
perfectly diagonal covariance matrix). Thus, while the simulation is real-world in the
generation of constrained active weights using an actual non-diagonal covariance matrix, thesimulation controls the generation of the realized residual returns to conform to assumed
statistical parameters.
14 The correlation of market model residual returns, as defined in Equation A1, cannot be
exactly zero, even in a theoretical sense. For example, if the benchmark contains only two
stocks, then the residual return on the first has to be perfectly negatively correlated to theresidual return on the second. For benchmark portfolios with a large number of stocks (e.g., 500)
the correlation matrix is populated with off-diagonal elements that are generally small but on
average tend to be slightly negative.
15 Specifically, if a variableXhas a mean of zero, then the variance of Xis 2
1
1)( i
N
i
XN
XVar =
= .
Similarly, if either X or Y has a mean of zero, then the covariance of X and Y is
==N
i
ii YXNYXCov 1
1),( . Also note that the statistical definition of the correlation coefficient
between two variables, X and Y, is based on Cov(X,Y) x,y Std(X) Std(Y). This definitionaldecomposition of covariances into correlations and standard deviations is used repeatedlythroughout the appendix.
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16
Kahn (2000) refers to these risk-adjusted weights as optimal risk allocations.
17 Taking expectations of both sides of Equation (A21), and employing the expectational
relationship in Equation A18 and E(,r) =IC, gives E(b,r) 2/)1( TCIC .