Methods and Apparatus for Generating Purified Minimum Risk Portfolios

FIELD OF INVENTION

The present invention relates to methods for constructing investment portfolios designed to capture a performance premium associated with low volatility and minimum volatility portfolios. More particularly, it relates to improved computer based systems, methods and software for construction of portfolios using optimization by reducing the portfolio's active sector exposures, commonly referred to as unintended bets, while preserving a strong tilt in a predetermined direction.

BACKGROUND OF THE INVENTION

In 2011, there was an explosion of exchange traded funds (ETFs) offering a wide selection of affordable “factor” exposures, including the Russell-Axioma Factor ETFs and PowerShares ETFs. The factors selected—volatility, beta and momentum, among others—are a subset of the “style risk factors” used by commercial equity fundamental factor risk models for the past three decades, so these factors are predictive of risk. Several of these factors have also been closely associated with highly successful hedge funds, so the implication is that these factors are also potential alpha signals, meaning sources of large, positive returns.

Factor ETFs come in two principal flavors: simple factor ETFs and purified factor ETFs. All factor ETFs have a strong exposure to the targeted factor. Simple factor ETFs do that and nothing more. In contrast, purified factor ETFs deliver not only the target factor exposure but also take steps to explicitly reduce the exposure of the ETF to non-target factors. This purifies the target signal and reduces unintended exposures that may inadvertently harm performance.

In addition to factor ETFs, there are also a set of ETFs based on a minimum risk portfolio. In this case, the underlying index for the ETF takes a universe of potential holdings (such as the Russell 1000 Index, for example), and an equity risk model and, using numerical optimization, constructs a portfolio that has the lowest predicted portfolio risk. The optimization may be subject to additional constraints such as being long-only or having maximum bounds on individual asset holdings. The ETF then replicates the holdings of this minimum risk portfolio. By construction, minimum risk portfolios capture a characteristic of low volatility; however, they do not use an explicit volatility factor. For purposes of this invention, portfolios such as the minimum risk portfolio are referred to as prototypical factor portfolios even though it may be difficult or ambiguous to specify what the target factor may be. An aspect of the present invention involves determining what may be good candidate target factors to use when constructing factor indexes and factor ETFs.

Non-target factor exposures are neutral when they have the same or similar exposures as an underlying benchmark. Large exposure over-weights or under-weights relative to a benchmark, normally referred to as active exposures, can either be intended or unintended. In a factor ETF or factor portfolio, the large exposure to the target factor is an intentional exposure. Any other exposures, however, are likely to be unintended.

Unintended bets in a portfolio are flaws. From the perspective of a factor risk model, unintended bets produce additional risk for the portfolio, and good portfolio managers should not unintentionally take on additional risk. Furthermore, in practice, unintended bets often reduce the return of the portfolio or add undesired risk to the portfolio. As a general rule, it is desirable to reduce the absolute magnitude of any active exposures to non-target factors.

For portfolio managers, purified ETFs or portfolios can be easier to work with since they are less likely to inadvertently alter the exposure of a composite set of holdings. A portfolio manager who buys a low volatility ETF expects that holding to make his overall exposure to volatility lower. Normally, however, the portfolio manager would not want that purchase to significantly change his overall exposure to size, value or growth. If, however, there were unintended bets in size, value, or growth, then the portfolio manager would need to do additional work to manage those exposures.

Optimization techniques are frequently used to construct a portfolio of holdings for a universe or set of potential investment opportunities or assets. For example, the stocks comprising the Russell 1000 index represent a universe of U.S. large cap stocks. The stocks comprising the Russell 2000 index represent a universe of U.S. small cap stocks.

Optimization has a long history in portfolio construction, including the construction of purified factor portfolios. Mean-variance portfolio optimization was first described by H. Markowitz, “Portfolio Selection”, Journal of Finance 7(1), pp. 77-91, 1952 which is incorporated by reference herein in its entirety. In mean-variance optimization, a portfolio is constructed that minimizes the risk of the portfolio while achieving a minimum acceptable level of return. Alternatively, the level of return is maximized subject to a maximum allowable portfolio risk. The family of portfolio solutions solving these optimization problems for different values of either minimum acceptable return or maximum allowable risk is said to form an “efficient frontier”, which is often depicted graphically on a plot of risk versus return. There are numerous, well known, variations of mean-variance portfolio optimization that are used for portfolio construction. These variations include methods based on utility functions, Sharpe ratio, and value-at-risk.

In these optimizations, the expected return or alpha signal, if present, serves as the target factor in the optimization.

Portfolio construction using optimization techniques makes use of an estimate of portfolio risk, and some approaches make use of an estimate of portfolio return. A crucial issue for these optimization techniques is how sensitive the constructed portfolios are to changes in the estimates of risk and return. Small changes in the estimates of risk and return occur when these quantities are re-estimated at different time periods. They also occur when the raw data underlying the estimates is corrected or when the estimation method itself is modified. Mean-variance optimal portfolios are known to be sensitive to small changes in the estimated asset return, variances, and covariances. See, for example, J. D. Jobson, and B. Korkei, “Putting Markowitz Theory to Work”, Journal of Portfolio Management, Vol. 7, pp. 70-74, 1981 and R. O. Michaud, “The Markowitz Optimization Enigma: Is Optimized Optimal?”, Financial Analyst Journal, 1989, Vol. 45, pp. 31-42, 1989 and Efficient Asset Management: A Practical Guide to Stock Portfolio Optimization and Asset Allocation, Harvard Business School Press, 1998, (the two Michaud publications are hence referred to collectively as “Michaud”) all of which are incorporated by reference herein in their entirety.

A number of procedures have been proposed to alleviate the sensitivity of optimized portfolios to changes or errors in the input data. The most common approach is to add constraints to the optimization problem that restrict the range of possible portfolio holdings. For example, the minimum and maximum asset allocation may be limited to, say, zero and two percent of the total portfolio value, respectively. Alternatively, the minimum and maximum exposure of the portfolio to an industry, industrial sector, or country may also be incorporated in the portfolio construction strategy.

Commercial equity factor risk models predict risk using a set of data factors that capture important characteristics of the possible investment opportunities. These factors can include industries and countries. They can also include other “style” factors such as value, growth, size, and volatility. In practice, it is common to constrain the net exposure of the portfolio to each of these style factors so that it is close to the exposure of a benchmark portfolio. Typically, the factor scores for style factors are reported as standardized scores or “Z scores” by taking the raw factor score and subtracting the aggregate score for the benchmark and then dividing this benchmark relative value by the standard deviation of the raw factor scores. Z scores report all style factors in a common dimensionless format that makes it easier to determine if a given exposure is large or small. See for example, R. Litterman, Modern Investment Management: An Equilibrium Approach, John Wiley and Sons, Inc., Hoboken, N.J., 2003 (Litterman), which is incorporated by reference herein in its entirety.

A factor mimicking portfolio is defined as a portfolio in which the net exposure of the portfolio to a single target factor is one and the net exposure of the portfolio to a set of non-target exposures is identically zero. See Litterman for details. By construction, factor mimicking portfolios have perfect purity. The returns of a factor mimicking portfolio can be taken to represent the return of that factor. Often, the set of non-target factors are the factors from a commercial factor risk model. Commercial risk model vendors spend considerable effort selecting the set of factors used by the model so that they represent a broad range of expected asset returns as accurately as possible. High quality factors improve risk model accuracy.

As with the asset holdings, industry, sector, and country constraint, style constraints are linear bounds on the portfolio holdings which can be readily solved using modern computer optimization software. The ease of use and intuitive simplicity of these constraints account for their popularity. Indeed, virtually all commercial portfolio optimization software allows a portfolio manager to impose these kinds of constraints. For example, Axioma sells portfolio optimization software, Axioma Portfolio™ software, with this functionality. (Axioma Portfolio is a trademark of Axioma, Inc.)

SUMMARY OF THE INVENTION

A concept used by the present invention is the decomposition of a non-target factor into one part that aligns with the target factor and a second part that is orthogonal or perpendicular to the target factor. As the overlap between the target and non-target factors increases, the magnitude of the aligned part increases.

FIG. 1 illustrates a simple example where a target factor overlaps with two non-target factors. A target factor 150 is illustrated as a horizontal vector pointing to the right. A first non-target factor 152 is illustrated by a vector pointing to the upper right side of FIG. 1. A second non-target factor 154 is shown by a vector pointing to the upper left of FIG. 1. The acute angle between the first non-target factor 152 and the target factor 150 is shown by the angle 156. The acute angle between the second non-target factor 154 and the target factor 150 is shown by the angle 158. Note that since acute angles must be between zero and ninety degrees, this angle is measured between the second target vector and the extension of the target vector extending to the left.

FIG. 2 illustrates how a first non-target factor 162 is decomposed into the sum of two different vectors, a vector 164 representing the projection of the first non-target factor onto the target factor 160 and a vector 166 representing the orthogonal projection of the first non-target factor with respect to the target factor. By construction, the aligned projection points in the same direction as the target factor while the orthogonal projection is perpendicular to the target factor.

FIG. 3 illustrates how a second non-target factor 172 is decomposed into the sum of two different vectors, a vector 174 representing the projection of the first non-target factor onto the target factor 170 and a vector 176 representing the orthogonal projection of the first non-target factor with respect to the target factor. In this example, the aligned projection points in the opposite direction as the target factor which, of course, is still aligned with the target factor while the orthogonal projection is perpendicular to the target factor.

As the number of factors considered increases, it becomes more likely for there to be overlap between factors. To be sure, factors can be mathematically constructed so that they have no overlap. However, many intuitive and commonly used factors naturally have overlap. For example, Axioma's U.S. Fundamental Factor Risk Model currently uses ten style factors and sixty eight industry factors. Historically, several of the factors have overlapped significantly.

FIG. 4 shows the historical overlap between two pairs of factors in Axioma's U.S. Fundamental Factor Risk Model for a large cap benchmark of about 1000 stocks. The overlap is measured by plotting the acute angle between two factors. The smaller the acute angle, the more overlap there is between the two factors. If the two factors are orthogonal, then the acute angle is ninety degrees. FIG. 4 plots the acute angle between the market sensitivity factor and the volatility factor 200 and the acute angle between the size factor and the volatility factor 202 from 1987 to 2012. For virtually the entire time period, the angle for market sensitivity versus volatility is smaller than the angle for size versus volatility. Where the angle for size is 50 degrees at its smallest in early 2009, the angle for market sensitivity is often less than 40 degrees.

Since smaller angles mean more overlap, this means that there is significant overlap between Axioma's market sensitivity factor and its volatility factor.

A problem addressed by the current invention occurs when there is significant overlap between a target factor and a non-target factor used to purify the target portfolio. By construction, the exposure to the target factor is large. Hence, the exposure to an overlapping non-target factor is at least as large as the overlapping, aligned part of the non-target factor. Even if the optimization attempts to minimize or constrain the overlapping non-target factor to be as neutral (e.g., close to zero) as possible, its magnitude cannot be less than that derived from the overlapping part of it. In this case, the desire to have both a large target factor exposure and a purified (e.g., neutral or small absolute) non-target exposure is antagonistic.

For example, it is well known that volatility factors, which use some measure of historic asset volatility, and beta or market sensitivity factors, which use a measure of the historical correlation between an asset's return and a benchmark's return, have significant overlap. The beta of an asset is the covariance of the asset's return with those of a benchmark divided by the variance of the benchmark's return. By construction, the beta of a benchmark is one. One expects the beta of a low volatility portfolio to be significantly less than one; typical values would be 0.6 or 0.7. In other words, a low volatility portfolio generally cannot be neutral to beta since that would require its beta to be close to 1.0.

Many common portfolio construction approaches do not necessarily have a well defined target factor. For example, there are indexes which are minimum risk portfolios. That is, for a given universe of possible asset holdings, the portfolio is the one with the lowest predicted risk by a given risk model, subject to other constraints such as long only and asset holdings. In this case, even though the final portfolio has low predicted risk, there is no explicitly “low risk factor” used to define the portfolio or how it is constructed.

Even in cases in which there is an obvious target factor, it may be that the obvious target factor is not the best alpha signal to use. In particular, if the other constraints in the portfolio construction problem greatly influence the final optimal solution, the explicit alpha signal may not align well with the constrained, optimal solution.

One aspect of the present invention recognizes that current portfolio optimization software does not automatically adjust exposure constraints according to whether or not there is significant overlap between the factor being constrained and the desired target factor tilts that are to be either maximized or minimized.

One goal of the present invention, then, is to describe a methodology that will automatically adjust any exposure constraint based on the degree of overlap between it and one or more target factors.

Another goal is to describe an improved method for constructing purified portfolios; that is, portfolios with a large target factor exposure but limited or constrained non-target exposures.

Another goal of the present invention is to provide an easy way for investors to historically simulate the performance of the automatically adjusted exposure constraints through a backtest.

Another goal of the present invention is to provide an improved method for determining a target factor for a purified portfolio construction problem in the case where either there is no obvious, explicit target factor used by the portfolio construction problem. Alternatively, in the case where such an obvious and explicit target factor exists, the present invention provides a method for determining an improved target factors that can be derived and used when altering the purification constraints of the problem.

Another goal of the present invention is to provide an improved method for constructing an index to use as the basis of an Exchange Traded Fund or ETF. The superior characteristics of a purified portfolio methodology could then be incorporated into the ETF, making the ETF a valuable investment option.

A more complete understanding of the present invention, as well as further features and advantages of the invention, will be apparent from the following Detailed Description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a simple example of a target factor and two non-target factors;

FIG. 2 illustrates a first non-target factor being decomposed into an aligned component and orthogonal component;

FIG. 3 illustrates a second non-target factor being decomposed into an aligned component and orthogonal component;

FIG. 4 illustrates the historical overlap of two pairs of factors in Axioma's U.S. Fundamental Factor Equity risk model from 1987 to 2012;

FIG. 5 shows a computer based system which may be suitably utilized to implement the present invention;

FIG. 6 shows performance statistics for four portfolios from a backtest using U.S. equities from Jun. 30, 2009 and Aug. 31, 2012;

FIG. 7 shows the cumulative returns for four portfolios from a backtest using U.S. equities from Jun. 30, 2009 and Aug. 31, 2012;

FIG. 8 shows the exposure to the volatility factor for three low volatility portfolios from a backtest using U.S. equities from Jun. 30, 2009 and Aug. 31, 2012;

FIG. 9 shows the exposure to the size factor for three low volatility portfolios from a backtest using U.S. equities from Jun. 30, 2009 and Aug. 31, 2012;

FIG. 10 shows the exposure to the market sensitivity factor for three low volatility portfolios from a backtest using U.S. equities from Jun. 30, 2009 and Aug. 31, 2012;

FIG. 11 shows performance statistics for four portfolios from a backtest using European equities from Apr. 30, 2004 and Aug. 31, 2012;

FIG. 12 shows the cumulative returns for four portfolios from a backtest using European equities from Apr. 30, 2004 and Aug. 31, 2012;

FIG. 13 shows the exposure to the volatility factor for three low volatility portfolios from a backtest using European equities from Apr. 30, 2004 and Aug. 31, 2012;

FIG. 14 shows the exposure to the size factor for three low volatility portfolios from a backtest using European equities from Apr. 30, 2004 and Aug. 31, 2012;

FIG. 15 shows a graphical illustration of a target factor and one non-target factor;

FIG. 16 illustrates the orthogonal non-target factor and the orthogonal alpha for the illustration of FIG. 15;

FIG. 17 illustrates the orthogonal non-target factor, the orthogonal alpha, and orthogonal holdings for the illustration of FIG. 15.

FIG. 18 illustrates the GICS Sector allocations for the Russell 1000 and a traditional minimum risk portfolio;

FIG. 19 illustrates GICS Sector allocations for the purified minimum risk portfolio;

FIG. 20 illustrates a comparison of the cumulative returns of the Russell 1000 Index, the traditional minimum risk portfolio, and the purified minimum risk portfolio;

FIG. 21 shows summary performance statistics for the Russell 1000 Index, the traditional minimum risk portfolio, and the purified minimum risk portfolio;

FIG. 22 illustrates a comparison of the cumulative returns of the TSX Composite Index, the traditional minimum risk portfolio, and the purified minimum risk portfolio;

FIG. 23 illustrates benchmark weights for a simple, eight asset example;

FIG. 24 illustrates the exposure matrix, the factor-factor-covariance matrix, the specific risk vector and a vector of predicted betas for the simple eight asset example;

FIG. 25 illustrates the traditional minimum risk portfolio for the simple, eight asset example along with the implied alpha, the implied alpha as a Z score, and the active exposures of the traditional minimum risk portfolio to the four factors;

FIG. 26 illustrates the purified minimum risk portfolio for the simple, eight asset example along with the active factor exposures and the orthogonal, implied alphas as Z scores for the four factors; and

FIG. 27 illustrates a flow chart of the steps of an embodiment of the present invention.

DETAILED DESCRIPTION

The present invention may be suitably implemented as a computer based system, in computer software which is stored in a non-transitory manner and which may suitably reside on computer readable media, such as solid state storage devices, such as RAM, ROM, or the like, magnetic storage devices such as a hard disk or solid state drive, optical storage devices, such as CD-ROM, CD-RW, DVD, Blue Ray Disc or the like, or as methods implemented by such systems and software. The present invention may be implemented on personal computers, workstations, computer servers or mobile devices such as cell phones, tablets, IPads™, IPods™ and the like.

FIG. 5 shows a block diagram of a computer system 100 which may be suitably used to implement the present invention. System 100 is implemented as a computer or mobile device 12 including one or more programmed processors, such as a personal computer, workstation, or server. One likely scenario is that the system of the invention will be implemented as a personal computer or workstation which connects to a server 28 or other computer through an Internet, local area network (LAN) or wireless connection 26. In this embodiment, both the computer or mobile device 12 and server 28 run software that when executed enables the user to input instructions and calculations on the computer or mobile device 12, send the input for conversion to output at the server 28, and then display the output on a display, such as display 22, or print the output, using a printer, such as printer 24, connected to the computer or mobile device 12. The output could also be sent electronically through the Internet, LAN, or wireless connection 26. In another embodiment of the invention, the entire software is installed and runs on the computer or mobile device 12, and the Internet connection 26 and server 28 are not needed. As shown in FIG. 5 and described in further detail below, the system 100 includes software that is run by the central processing unit of the computer or mobile device 12. The computer or mobile device 12 may suitably include a number of standard input and output devices, including a keyboard 14, a mouse 16, CD-ROM/CD-RW/DVD drive 18, disk drive or solid state drive 20, monitor 22, and printer 24. The computer or mobile device 12 also has a USB connection 21 which allows external hard drives, flash drives and other devices to be connected to the computer or mobile device 12 and used when utilizing the invention. It will be appreciated, in light of the present description of the invention, that the present invention may be practiced in any of a number of different computing environments without departing from the spirit of the invention. For example, the system 100 may be implemented in a network configuration with individual workstations connected to a server. Also, other input and output devices may be used, as desired. For example, a remote user could access the server with a desktop computer, a laptop utilizing the Internet or with a wireless handheld device such as cell phones, tablets and e-readers such as an IPad™, IPhone™, IPod™, Blackberry™, Treo™, or the like.

One embodiment of the invention has been designed for use on a stand-alone personal computer running in Windows 7. Another embodiment of the invention has been designed to run on a Linux-based server system.

According to one aspect of the invention, it is contemplated that the computer or mobile device 12 will be operated by a user in an office, business, trading floor, classroom, or home setting.

As illustrated in FIG. 5, and as described in greater detail below, the inputs 30 may suitably include a universe or set of potential investments, a factor risk model, a set of non-target factors, as well as other data needed to construct the portfolio such as an initial portfolio, a reference portfolio, a vector of market capitalizations, a portfolio optimization software, asset bounds, and the like.

As further illustrated in FIG. 5, and as described in greater detail below, the system outputs 32 may suitably include the holdings for an optimized investment portfolio.

The output info information may appear on a display screen of the monitor 22 or may also be printed out at the printer 24. The output information may also be electronically sent to an intermediary for interpretation. For example, risk predictions for many portfolios can be aggregated for multiple portfolio or cross-portfolio risk management. Alternatively, trades based, in part, on the factor risk model predictions, may be sent to an electronic trading platform. Other devices and techniques may be used to provide outputs, as desired.

Turning to a detailed discussion of the invention and its context, suppose that there are N assets in an investment portfolio, and the weight or fraction of the available wealth invested in each asset is given by the N-dimensional column vector w. These weights may be the actual fraction of wealth invested or they may represent the difference in weights between a managed portfolio and a benchmark portfolio as described by Litterman. In this case, w=w_p−w_bwhere w_pis an N-dimensional column vector representing the fraction of wealth invested by the investor and w_bis an N-dimensional column vector representing the fraction of wealth invested in the benchmark or reference portfolio.

Suppose further that there is a target factor which is an N-dimensional column factor f and a matrix of M non-target factors given by the columns of the N×M dimensional matrix B. The target factor may be a vector of expected asset returns, which is sometimes called “alpha” and denoted with the Greek letter a. Alternatively, the target factor f may an N-dimensional column vector of factor scores. In a typical optimization problem, an optimal allocation of wealth is determined that either maximizes or minimizes the portfolio's exposure to f. That is, the product vector inner product w^Tf is either as large or as small as possible.

The overlap problem occurs when the matrix-vector product of the transpose of B and f is non-zero.

Non-Orthogonality custom-character B^Tf≠0 (1)

If f is orthogonal to each column of B, then this matrix product returns an M dimensional vector of zeros.

In existing portfolio optimization software, one is allowed to impose minimum and maximum constraints on the exposures of the final, optimized portfolio to each of the M factors. That is, in existing portfolio optimization software, the functionality exists to impose

L≦B
^T
w≦U (2)

Here, L is an M-dimensional vector of lower bounds for the exposures of the portfolio and U is an M-dimensional vector of upper bounds for the exposures. If some of the constraints are unbounded, then the corresponding elements of L and U can be represented by minus infinity and plus infinity respectively. Since constraints with infinite bounds are automatically satisfied, high quality portfolio optimization software will omit such bounds and constraints when constructing the optimal portfolio.

In the present invention, an alternative to this common type of constraint is provided. Rather than constrain the exposure of the portfolio to the original factors, the exposure of the portfolio is constrained to that part of the original factors that is orthogonal to the target factor. That is, a set of orthogonal non-target factors is first formed. For each of the M columns of B, that column is replaced with its orthogonal projection. That is,

$\begin{matrix} \begin{matrix} B_{(j)}^{'} = B_{(j)} - (\frac{f^{T} B_{(j)}}{f^{T} f}) f, & j = 1, \dots, M \end{matrix} & (3) \end{matrix}$

where B_(j)is the j-th column of the original matrix B, the orthogonal matrix of non-target factors, B′, is assembled by putting the columns together, and then equation (2) is replaced with

L≦B′
^T
w≦U (4)

The optimal portfolio returned by the optimization depends on the manner in which the original target factor and non-target factors are normalized. In the results reported below, each of the factors is a Z score.

In one embodiment of the invention, L and U are set to be a vector of zeros and the constraints are imposed as soft constraints with a linear penalty functions. The vanishing L and U drive the solution to be as neutral as possible, while the soft constraints simply penalize any deviation from perfect neutrality. In this formulation of the constraint, the user need specify the magnitude of the constraint penalty. In the approach described here, it was found that a non-zero penalty magnitude usually improves portfolio performance. The constraints (4) could also be implemented with a quadratic penalty, or imposed as hard constraints. Alternatively, the constraints could also be inserted into Axioma's Constraint Hierarchy tool, a tool that automatically softens hard constraints whenever infeasibilities are found.

Mathematicians will recognize a similarity between equation (3) and Gram-Schmidt orthogonalization. If there were more than one target factor for a portfolio, we can extend the orthogonalization process to include these different target factors. If there are K target factors, the K target factors can be processed as the first K vectors using the Gram-Schmidt method. Then, each of the M non-target factors would be modified using the formula for the (K+1)-th vector in the Gram-Schmidt method. Alternatively, one can construct a matrix P that will project any vector into the null space of a set of one or more target factors. Each constraint would then be modified by pre-multiplying by the matrix P.

In some situations, it may be practical to nearly orthogonalize the constraints, so that each constraint is nearly but not exactly orthogonal. In this case, the acute angle between the approximately orthogonalized constraints and the target factor would be close to ninety degrees but not exactly ninety degrees. One way to do that is to replace equation (3) with

$\begin{matrix} \begin{matrix} B_{(j)}^{'} = B_{(j)} - (1 - ɛ_{j}) (\frac{f^{T} B_{(j)}}{f^{T} f}) f, & j = 1, \dots, M \end{matrix} & (5) \end{matrix}$

where ε_jis a small positive constant; that is, 0<ε_j<<1.

The use of the orthogonal non-target factor constraints is next illustrated using two backtests, a backtest using U.S. equities and a backtest using European equities. In both backtests, the target factor is the volatility factor of Axioma's Fundamental Factor, Medium Horizon, Equity Risk Model. Axioma's U.S. Fundamental Factor, Medium Horizon Equity Risk Model was used for the backtest with U.S. equities, and Axioma's European Fundamental Factor, Medium Horizon Equity Risk Model was used for the backtest with European equities.

In each backtest, the exposure of the optimal portfolio to the volatility factor is minimized. The final active exposure is large and negative, indicating a low volatility exposure. Since low volatility is the target, the portfolios constructed will be less volatile than the underlying benchmarks.

In each backtest, four portfolios were constructed each month. First, a benchmark portfolio is constructed consisting of a market capitalization weighting of all assets in the investment universe. For the U.S. backtest, a large cap benchmark was constructed of approximately 1000 stocks. For the European backtest, a large cap benchmark was constructed of approximately 1500 stocks.

Second, a reference portfolio was constructed by equi-weighting the 10% of the names in the universe with the lowest volatility score.

Third, a traditional optimized portfolio was constructed which holds the same names as the reference portfolio but whose weights have been adjusted by optimization. The optimization objective minimizes the tracking error (e.g., active risk) between this optimized portfolio and the reference portfolio as predicted by the factor risk model. For this optimization, the portfolio is purified to non-target factors without any orthogonalization. The non-target factors are the style risk factors in the corresponding Axioma factor risk model, including the volatility factor. For each style factor, benchmark neutral exposure was imposed (maximum exposure equals minimum exposure equals zero) as a soft constraint with a linear penalty for any positive or negative deviation from neutrality. Volatility is, of course, one of the factors in the style factors. In order to keep the target factor exposure strong, the target tilt of the optimized portfolio was constrained to be at least as low (e.g., large and negative) as the reference portfolio. Low volatility Z scores are traditionally negative, so the lower or more negative the exposure, the stronger the target tilt. The minimum and maximum holdings in any individual asset are zero and two percent of the total portfolio value.

Fourth, an optimized portfolio identical to the traditional optimized portfolio was constructed; but non-target exposure constraints were imposed using the risk model style factors after they had been orthogonalized with respect to the volatility factor. Otherwise, the optimization is the same.

FIG. 6 shows the performance results 110 for the U.S. backtest, which was rebalanced monthly between Jun. 30, 2009 and Aug. 31, 2012 using a universe of approximately 1000 large cap U.S. equities.

For this set of backtests, it is seen that the best total return was obtained using the orthogonal style constraints. This case also had the highest Sharpe ratio and Information ratios. The optimized portfolios had somewhat lower turnover than the reference portfolio. By construction, the optimized portfolios can only hold at most the same names as the reference portfolio. In this case, the optimized portfolios held about half the number of names as the reference portfolio. The predicted beta for the reference and optimized portfolios were virtually identical and well below one, as one would expect from a low volatility portfolio.

FIG. 7 compares the cumulative return of all four portfolios: the return of the benchmark 204 shown as a dashed-dotted line; the return of the reference portfolio 206 shown as a thin solid line; the return of the optimized portfolio with traditional constraints 208 shown as a dashed line; and the return of the portfolio optimized with orthogonal constraints 210 shown as a thick solid line.

The three low volatility portfolios have noticeably less volatility than the benchmark. Since mid-2011, the return of the portfolio optimized with orthogonal constraints steadily outperformed the other three portfolios.

FIG. 8 shows the exposure of the three low volatility portfolios to the target factor, the volatility factor of the factor risk model: the exposure of the reference portfolio 212 shown by the thin solid line; the exposure of the traditional optimization 214 shown by the dashed line; and the exposure for the orthogonal optimization 216 shown by the thick solid line. The exposures of the optimized portfolios are at least as strongly negative as the reference portfolio, as imposed by the optimization.

FIG. 9 shows the exposure of the three low volatility portfolios to the size factor. The size factor in a factor risk model is a Z score value representing the natural logarithm of the market capitalization of all assets in the benchmark. The non-target exposure constraints in both optimizations have dramatically altered the size factor exposure. Whereas the exposure of the reference portfolio 218 is about −100% (a substantial small cap bias representing a non-pure exposure relative to volatility), the exposure of the two optimized portfolios—220 for the traditional optimization and 222 for the constrained optimization—is about −40%. In other words, both the traditional constraints and the orthogonal constraints have neutralized or purified the size exposure by roughly 60%. The substantial small cap bias embedded in the reference portfolio has been dramatically corrected by both constraints.

In FIG. 9, the size exposure of the two optimized portfolios is approximately the same. Usually, there is less than a five percent difference in their size exposures. This indicates that the overlap between size and volatility is relatively small, e.g., the acute angle between the target factor (volatility) and the non-target factor (size) is large.

FIG. 10 shows the exposure of the three low volatility portfolios to the market sensitivity factor from the factor risk model. As shown in FIG. 4, there is more overlap between the market sensitivity factor and the volatility factor than there is for the size factor and the volatility factor. In other words, the acute angle between the volatility factor and the market sensitivity factor is smaller than the acute angle between the volatility factor and the size factor. As a consequence, there is not expected to be a large difference between the reference and optimized portfolios. The market sensitivity factor exposure of the reference portfolio 224 is shown by the thin solid line, the portfolio with traditional optimization 226 is shown by the dashed line, and the portfolio with orthogonal optimization 228 is shown by the thick solid line. Usually, the three exposures are within 10% to 20% of each other. However, as expected, the portfolio with orthogonal constraints often has less exposure to market sensitivity than the other two portfolios. In this case, constraining only the orthogonal component of the factor permits a much deeper exposure to the aligned part of the factor. This difference purifies the holdings from unintended bets and enables the orthogonal constraints backtest to outperform the reference portfolio and the traditional optimization backtest.

FIG. 11 shows the performance results 120 for the European backtest, which was rebalanced monthly between Apr. 30, 2004 and Aug. 31, 2012 using a universe of approximately 1500 large cap European equities.

For this set of longer backtests, the best total return was once again obtained using the orthogonal non-target factor constraints. This case also had the highest Sharpe ratio and Information ratios. The optimized portfolios had somewhat lower turnover than the reference portfolio. The optimized portfolios hold about two fifths as many names as the reference portfolio. The predicted beta for the reference and optimized portfolios are virtually identical and well below one.

FIG. 12 compares the cumulative return of all four portfolios: the return of the benchmark 300 shown as a dashed-dotted line; the return of the reference portfolio 302 shown as a thin solid line; the return of the optimized portfolio with traditional constraints 304 shown as a dashed line; and the return of the portfolio optimized with orthogonal constraints 306 shown as a thick solid line.

FIG. 11 and FIG. 12 illustrate that the return of the portfolio optimized with orthogonal constraints steadily outperformed the other three portfolios. This return improvement illustrates that portfolios purified by imposing orthogonal non-target factor constraints can improve portfolio performance.

FIG. 13 shows the exposure of the three low volatility portfolios to the target factor, the volatility factor of the factor risk model: the exposure of the reference portfolio 308 shown by the thin solid line; the exposure of the traditional optimization 310 shown by the dashed line; and the exposure for the orthogonal optimization 312 shown by the thick solid line. The volatility exposures of all three portfolios are virtually identical.

FIG. 14 shows the exposure of the three low volatility portfolios to the size factor. The size factor in a factor risk model is a Z score value representing the natural logarithm of the market capitalization of each asset. The non-target exposure constraints in both optimizations have a dramatic effect for the size factor exposure. The size exposure of the reference portfolio 314 is generally about 75% lower (a substantial small cap bias, representing a non-pure exposure relative to volatility) than the exposure of the two optimized portfolios, the traditional optimization portfolio 316 and the constrained optimization portfolio 318.

These two backtests illustrate cases in which target factor portfolios that have been purified using orthogonalized non-target factors outperform those purified using raw non-target factors as well as the simple reference portfolio. It is anticipated that portfolio managers will prefer to be able to automatically impose orthogonalized, non-target factor constraints as a standard feature in a portfolio optimization tool.

Although the present invention is different than the prior art and has advantages thereover, it possesses similarities to existing techniques used for portfolio construction using optimization. U.S. Pat. No. 7,698,202 describes a technique in which a factor risk model is augmented by additional risk associated with the vector that is the projection of the asset holdings into the null space of the set of factor risk model factors. That is, the additional risk is related to the orthogonal projection of the holdings. This patent is incorporated by reference herein in its entirety. In this procedure, there is no need for a target factor. The document “Refining Portfolio Construction When Alphas and Risk Factors are Misaligned” by J. Bender, J.-H. Lee, and D. Stefek, MSCI Barra Research Insight, March 2009, available at http://www.mscibarra.com/research/articles/2009/RI_Refining_Port_Construction.pdf describes a technique in which the objective function of a portfolio optimization problem is modified by a penalty associated with the vector that is the projection of the “alpha” vector, which is the vector of expected returns or, equivalently, the target factor into the null space of the set of factor risk model factors. That is, the objective function penalty is the orthogonal projection of the target factor. This document is incorporated by reference herein in its entirety.

Like the present invention, both of these techniques describe an orthogonal projection. However, the orthogonal projection in these two techniques is different than that described in the present invention. For these two techniques, the orthogonal projection is the projection into the null space of a set of factors used by a factor risk model. Specifically, let X be the matrix of factor exposures in a factor risk model (see U.S. Pat. No. 7,698,202 and Litterman for details). Then, the projection operator used by the prior art techniques is

P
_RM
=I−X(X^TX)⁻¹X^T (6)

where I is the identity matrix and the inverse may be a pseudo-inverse if necessary. In the technique described in U.S. Pat. No. 7,698,202, the additional variance added to the predicted risk model variance is proportional to

σ_RM²=c²w^TP_RMw (7)

for some constant c. For the technique described by Bender et al., the penalty in the objective function is proportional to

U=θ
²α^TP_RMα (8)

for some constant θ, where α is the alpha vector, which is the target vector in the present invention

By contrast, the present invention, the orthogonal projection is with respect to the target vector, not a set of risk model factors. Formally, we can compute this projection as

P
_f
=I−f(f^Tf)⁻¹f^T (9)

which, because the target factor f is one dimensional, reduces to the formula given in equation (3).

FIGS. 15, 16, and 17 provide a further illustration of the difference of the present invention from the prior art. In FIG. 15, there is a single non-target factor 402 and a target factor 404, both of which are two dimensional for illustration purposes of the example. The non-target factor 402 may be a factor from a factor risk model in which case it could be termed a risk factor. The symbol b is used to indicate this factor. The target factor 404 may be the alpha signal or expected return. In mean-variance optimization, the expected return of the optimal portfolio is maximized. Alternatively, the exposure of the optimal portfolio to the target factor can be minimized, as it was in for the two backtests described herein for which the target factor was volatility. The symbol α is used to indicate this target factor.

In FIG. 16, we have the same non-target factor 406 and the same target factor 408. In addition, we show two different projections. The orthogonalized non-target factor 410, computed as b_orthog=P_jb, is perpendicular to the target factor. In this example, it points to the upper left of FIG. 16. The orthogonal alpha, computed as α_orthog=P_RMα and used in the work of Bender et al., is perpendicular to the non-target factor and points to the bottom right. As can be readily seen in FIG. 16, these two vectors are not parallel. As a result, the changes they make to the optimization are not the same, and the present invention is therefore different than the approach described by Bender et al.

In FIG. 17, we take the same example and add a set of holdings 422, denoted by w. The target factor 416 is the same; the non-target factor 414 is the same; the orthogonalized non-target factor 418 is the same; and the orthogonal alpha 420 is the same. In order to illustrate the method of U.S. Pat. No. 7,698,202, we have added the set of holdings 422. We can then compute the orthogonal holdings, w_orthog=P_RMw, which controls the additional risk imposed in U.S. Pat. No. 7,698,202. The important thing to notice is that the orthogonal alpha 420 and the orthogonal holdings 424 are parallel in this simple example. As a result, their impact on the optimal holdings is parameterized by the same vector direction. This again is a different direction than the direction considered in the present invention, the orthogonalized non-target factor 418.

For the present invention, the impact of the orthogonalized constraint is to limit exposures that are orthogonal to the target vector. In this approach, these orthogonal exposures are considered unintended bets, and are reduced and limited by the optimization. Unlike the prior art, the present invention does not limit the holdings in the direction defined by the target factor. The directions associated with the prior art can possess a non-zero component that aligns with the target factor and can therefore reduce the exposure of the optimal holdings in that direction. In fact, the paper “Do Risk Factors Eat Alphas?” by J.-H. Lee and D. Stefek, MSCI Barra Research Insight, April 2008, available at http://www.mscibarra.com/products/analytics/aegis/RI_Do_Risk_Models_Eat_Alphas_April_—08.pdf, incorporated by reference herein in its entirety, indicates that having constraints that overlap with alpha do degrade performance. The present invention explicitly ensures that the orthogonal constraints do not degrade alpha or performance.

In many optimizations, the direction of implied alpha can be different than the target factor. If we denote the asset-asset covariance matrix as Q, then the implied alpha is given by

α₁=cQw (10)

where w represents the optimal holdings and c is a non-zero constant to be determined depending on how α₁is to be normalized. The asset-asset covariance matrix can be derived from a factor risk model. The implied alpha is the expected return that would give the optimal holdings as the most simple mean-variance optimization problem. When the implied alpha and the target factor are not well aligned, this indicates that constraints imposed in the optimization problem have substantially affected the optimal solution.

U.S. patent application Ser. No. 14/025,127 assigned to the assignee of the present application and entitled “Purifying Portfolios Using Orthogonal Non-Target Factor Constraints” filed on Sep. 12, 2013 describes an invention in which portfolios are purified using the above methodology using explicitly stated target factors, and is incorporated herein. There are numerous practical situations in which there is no explicit target factor and this invention among its several aspects addresses those situations.

An application of the present invention is to apply it to the orthogonal projection of the implied non-target factor. One way to extend the present invention to consider implied alpha is to alter equation (3) to include risk-adjusted constraints

$\begin{matrix} \begin{matrix} B_{(j)}^{'} = {QB}_{(j)} - (\frac{f^{T} ({QB}_{(j)})}{f^{T} f}) f, & j = 1, \dots, M \end{matrix} & (11) \end{matrix}$

Such risk-adjusted constraint can also improve portfolio performance. Alternatively, one can formally create the null projection matrix of Qw instead off and then use that as the target factor to alter the constraints. An optimization problem that simultaneously solves for the optimal holdings with orthogonalized constraints based on Qw instead off can also improve portfolio performance.

As an explicit example involving implied alpha, consider the case of determining a purified minimum risk portfolio for a benchmark universe such as the Russell 1000 Index. In this case, the traditional minimum risk portfolio may be constructed using the optimization problem:

- Find w such that
- The predicted risk, (w^TQ w)^1/2, is as small as possible, where Q is the asset-asset covariance matrix derived from a risk model.
- All individual holdings are equities in the Russell 1000 Index.
- All individual asset holdings are between 0% and 2% of the total portfolio value.
- The sum of the asset holdings equals 100%.
- The turnover in the portfolio from one month to the next is limited to at most 30%.
  
  This problem is well posed and, in fact, is often used to produce minimum risk portfolios. It is sometimes also referred to as the minimum variance portfolio. Note that there is no explicit alpha for this problem.

However, once this problem is solved, there is an implied alpha for this portfolio given by

α₁=cQw (12)

where w is the solution to the minimum risk problem. The implied alpha is determined up to the constant c. This implied alpha can be used to define a target factor.

Minimum risk portfolios often take large bets in sectors. The Global Industry Classification Standard (GICS) is an industry taxonomy developed by MSCI and Standard & Poor's (S&P) for use by the global financial community. The GICS structure consists of 10 sectors, 24 industry groups, 68 industries and 154 sub-industries into which S&P has categorized all major public companies. The system is similar to ICB (Industry Classification Benchmark), a classification structure maintained by Dow Jones Indexes and FTSE Group.

GICS defines ten sectors for U.S. equities (and other investments), which are classifications of the kind of business each company engages in: Energy, Materials, Industrials, Consumer Discretionary, Consumer Staples, Health Care, Financials, Information Technology, Telecommunication Services, and Utilities. Historically, some of these sectors are much less risky or volatile than others. For example, Consumer Staples and Utilities have often had quite low risk, and these sectors are sometimes over-weighted in minimum risk portfolios.

For example, the graphs 502 and 504 in FIG. 18 show the GICS allocations for the Russell 1000 benchmark 502 and the minimum risk portfolio 504 derived using Axioma's U.S. Fundamental Factor, Short Horizon Equity Risk Model from 1995 to 2012. The minimum risk portfolios are rebalanced every month, with a maximum round trip turnover of 30% each month. As can be seen, the GICS sector allocations for the benchmark, the Russell 1000, are quite steady and all are relatively low. The Information Technology sector 506 has a brief large allocation in 2000 to 2002 as a result of the Tech-Bubble. However, otherwise, the allocations are all nominally less than 20% (although Financials 508 is approximately 22% from 2002 to 2008).

The allocations for the minimum risk portfolio are quite different, as seen in graph 504 in the bottom portion of FIG. 18. Over time, different sectors take large positions, often well over 40%. In the late 1990's, Financials 510 and Utilities 516 often had large allocations. Consumer Discretionary 514 was often large in 2004 to 2008. Since 2008, however, Consumer Staples 512 has been the dominant allocation for these minimum risk portfolios. While this allocation does give low predicted risk, it also means that minimum risk portfolio is undiversified in the sense that it would be particularly sensitive to poor performance in the Consumer Staples sector.

Such unexpected abrupt changes have happened in the past. For example, the Japanese Utility sector was greatly altered by the tsunami in March 2011.

Here, there is an apparent dilemma: low risk portfolios have traditionally had large allocations to a handful of sectors such as Utilities and Consumer Staples; however, such large allocations may well represent unintended or undesirable bets that a portfolio manager would like to reduce.

How can this be accomplished? It can be accomplished by using the present invention. In this case, there is not an obvious target factor. However, we can compute the implied alpha of the traditional minimum risk portfolio can be computed. Once this is done, we take the implied alpha and change it into a Z score so that, relative to the Russell 1000 Index weights, it has a mean, weighted score of zero and a standard deviation of one. Note that because this normalization involves a change in the original of the implied alpha vector, it also changes the orthogonal projections as well. In testing, changing implied alpha to a local Z score has proved effective.

Next, the orthogonal projection of each sector exposure vector to the normalized implied alpha, our target factor is computed. The sector exposure is one for all assets held that are in a particular sector and zero for all other assets. The orthogonal projection is taken of this vector of zeros and ones to the normalized implied alpha. This, then, is the orthogonal sector vector to which it is desired to impose a constraint that the net active (benchmark relative) exposure is as close to zero as possible. This is done by setting this as a soft constraint with a minimum and maximum exposure of zero and a linear penalty with a penalty magnitude of 0.1.

FIG. 19 shows the sector exposures 520 of the portfolio that minimizes the portfolio risk as well as the penalties from the sector purification. As can be seen, the sector exposures are much closer to those of the benchmark, as was intended. The large exposures that occur in the traditional minimum risk portfolio have been eliminated. Information Technology 522 has a small peak in 2000, and Financials 524 is larger than some of the other sector exposures, but overall the sector exposures are much closer to those of the benchmark than the original minimum risk portfolio.

This purification approach adds value. FIG. 20 shows the cumulative returns 530 of the Russell 1000 Index 532, the traditional minimum risk portfolio 534, and the purified minimum risk portfolio 536. The cumulative return of the purified minimum risk portfolio 536 is substantially larger than the cumulative return of either the traditional minimum risk portfolio 534 or the Russell 1000 benchmark 532.

Note that in this example, the portfolio has been purified only with respect to sector exposures. It may prove beneficial to purify with respect to other non-target factors such as risk style factors, industries, countries, and so forth.

FIG. 21 gives summary performance statistics 540 for the three portfolios shown in FIG. 20: the Russell 1000 benchmark, the traditional minimum risk portfolio, and the purified minimum risk portfolio. By virtually all metrics, the purified, minimum risk portfolio has superior performance. It has larger returns and less risk. Its Sharpe Ratio and Information Ratio are higher. Interestingly, the average predicted beta of the purified minimum risk portfolio is 0.76, about midway between the average predicted beta of the traditional minimum risk portfolio (0.36) and the benchmark (1.0). This result makes sense. The sector purification makes the sector allocations resemble those of the benchmark. Hence, one expects that purified minimum risk portfolio would inherit some characteristics that resembled the benchmark. However, because the portfolio is unconstrained in the direction of the implied alpha of the traditional minimum risk portfolio, the performance captures and magnifies the return properties of that implied alpha. In the case presented here, that leads to highly desirable, superior performance.

The superior performance is not limited to U.S. equities. FIG. 22 shows the cumulative returns 540 for the benchmark 542, the traditional purified minimum risk portfolio 544, and a purified minimum risk portfolio 546 constructed for the TSX Composite Index, an equity index compiled by the Toronto Stock Exchange. Once again, desirable performance in the purified minimum risk portfolio is observed. The returns are larger than those of the other two portfolios. Similar results have been obtained using equities in the Chinese CSI 300 Index.

Even when there is an obvious target factor associated with a portfolio, it may be beneficial to use the implied alpha as the target factor for orthogonal constraints that purify the portfolio. For example, in a High Value portfolio, a reference portfolio can be constructed using the original value factor. Once that reference portfolio is constructed, its implied alpha can be computed and used as the target factor against which to orthogonally purify the portfolio. That purification can be against sectors exposures, industry exposures, style risk factor exposures, and the like. The present invention is not limited to minimum risk portfolios, but can be effectively applied to virtually any factor portfolio. Such portfolios would include High Value portfolios, High Growth portfolios, and even Low Volatility portfolios whose reference portfolio was constructed differently than using the traditional minimum risk portfolio methodology.

A simple, detailed, numerically worked out example is presented to illustrate the aspects of the invention. Consider a universe of eight assets identified as E1, E2, E3, E4, E5, E6, E7, and E8. In FIG. 23, the benchmark weights 602 for this universe are given. The sum of the eight benchmark weights is 100%.

For this universe, a factor risk model is considered with four factors: two style factors, denoted S1 and S2; and two industry factors, denoted I1 and I2. As illustrated in FIG. 24, the factor risk model is comprised of a factor exposure matrix 604, denoted X; a factor-factor covariance matrix 606 denoted as S; and a vector of asset specific risks 607. The specific variance matrix, denoted as D², is the diagonal matrix of the squares of the specific risks, 607.

The asset-asset covariance matrix Q is constructed using matrix multiplication as

Q=XSX
^T
+D
² (13)

For the benchmark 602, and the factor risk model composed of X, S, and D, a vector of predicted beta's 608 can be computed as

β=(XSX^T+D²)w_b/(w_b^TQw_b) (14)

The aggregate beta of the benchmark holdings, computed as (β^Tw_b) is one by construction.

A traditional minimum risk portfolio is then constructed for this example satisfying

- Find w_MinRisksuch that
- The predicted risk, (w_MinRisk^TQ w_MinRisk)^1/2, is as small as possible.
- All individual asset holdings are between 0% and 15%.
- The sum of the asset holdings equals 100%.
  
  The solution of the traditional minimum risk problem is illustrated in FIG. 25. The holdings in the traditional minimum risk portfolio are shown in table 610. For this particular example, three assets, E3, E4, and E8 are at the maximum 15% allocation.

The total predicted risk of the traditional minimum risk portfolio is 11.26%. The aggregate beta of this portfolio is 0.966 which is slightly less than one.

The implied alpha for the traditional minimum risk portfolio using c=1 is shown in table 612. The implied alphas are all very close: they range from 1.13 (for E4) to 1.31 (for E1, E2, E5, E6, and E7. When this vector is converted to a Z score, a vector 612 is obtained with a minimum entry of −2.341 and a maximum entry of 0.513.

The active exposures to each of the four factors are defined as the exposure of the traditional minimum risk portfolio to each factor minus the exposure of the benchmark. For this particular example, the active exposure 613 ranges from −16.58% to +1.07%. The exposure to S1 is a large, under-weight relative to the benchmark. This exposure represents the unintended exposure that arose from constructing the traditional minimum risk portfolio.

Next, a purified minimum risk portfolio is constructed that reduces the magnitude of the active exposures. In FIG. 26, the orthogonal implied alpha is computed as a Z score for each factor in table 620. These four column vectors are obtained using equation (3) where f is the implied alpha as a Z score. The vector inner product of each of these columns with the implied alpha as a Z score is zero.

The optimization problem is then solved as follows:

- Find w_PureMinRisksuch that
- The predicted risk, (w_PureMinRisk^TQ w_PureMinRisk)^1/2, is as small as possible.
- All individual asset holdings are between 0% and 15%.
- The sum of the asset holdings equals 100%.
- For each of the four factors, if the orthogonal implied alpha as a Z score is different than zero, penalize the objective function with a linear penalty proportional to 0.1 times the difference from zero.
  
  The solution to the purified minimum risk portfolio is given in FIG. 26 by table 614. In contrast with the traditional minimum risk portfolio 610, five assets reach the maximum allocation of 15%, instead of just three. The total risk of the purified minimum risk portfolio is 11.43% as opposed to the 11.26% obtained for the traditional minimum risk portfolio, as expected. Since constraints were added to the optimization problem, the value of the objective function increases. The predicted beta of the purified minimum risk portfolio is 0.991, which is slightly closer to one than that of the traditional minimum risk portfolio, indicating that this portfolio is more similar to the benchmark than the traditional minimum risk portfolio.

The active exposures of the purified minimum risk portfolio are shown in table 618. These are all small. The largest magnitude is −2.54% for S1, which is substantially smaller in magnitude than the −16.58% active S1 exposure for the traditional minimum risk portfolio.

FIG. 27 shows a flow diagram illustrating the steps of process 2700 embodying the present invention. In step 2702, an N dimensional investment universe is defined. In the simple numerical example, the investment universe are the eight assets. In step 2704, data is obtained for the investment universe including a risk model and non-target factor scores. In the simple numerical example, the risk model is defined by 604, 6060 and 607. The non-target factor scores are the columns of the exposure matrix, 604. In step 2706, a reference portfolio is obtained or constructed. In the simple numerical example, a minimum risk portfolio 610 was constructed using a traditional portfolio construction optimization strategy. In step 2708, the implied alpha of the reference portfolio is computed and linearly resealed. In the simple numerical example, these are shown in table 612. In step 2710, the projections of the non-target factors scores that are orthogonal to the linearly resealed implied alpha are determined. In the simple numerical example, these four projections are shown in table 620. Finally, in step 2712, a new investment portfolio is determined using an optimization strategy that limits the exposures of the optimal portfolio to the projections of the non-target factors scores that are orthogonal to the linearly resealed implied alpha. In the simple numerical example, this new portfolio is shown in table 614. The steps of process 2700 may be suitably carried out using the computer system 100 of FIG. 5, for example.

Another important application of the implied alpha, orthogonal purification approach described in the present invention is as a method for constructing an index to be used as the basis of an exchange traded fund (ETF). The implied alpha, orthogonally purified factor portfolio or minimum risk portfolio would be a desirable underlying index for an ETF because it possesses superior performance characteristics. In reference to the simple example illustrated above, the reference portfolio would take the place of the traditional minimum risk portfolio. The implied alpha as a Z score would then be used to purify the portfolio against unintended exposures in whatever portfolio optimization strategy was employed to construct the index.

While the present invention has been disclosed in the context of various aspects of presently preferred embodiments, it will be recognized that the invention may be suitably applied to other environments consistent with the claims which follow.

Methods and Apparatus for Generating Purified Minimum Risk Portfolios

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