The Black-Litterman model has gained popularity in applications in the area of quantitative equity portfolio management. Unfortunately, many recent applications of the Black-Litterman to novel aspects of quantitative portfolio management have neglected the rigor of the original Black-Litterman modelling. In this article, we critically examine some of these applications from a Bayesian perspective. We identify three reasons why these applications may create losses to investors. These three reasons are: 1) Using a prior without “anchoring” the prior to an equilibrium model; 2) Using a prior and an equilibrium model that conflict with one another; and 3) Ignoring the implications of the estimation error of the variance-covariance matrix. We also quantify the loss first analytically and also numerically based on historical data on 10 major world stock market indices. Our conservative estimate of the loss is around a 1% reduction in the annualized return of the portfolio.
The Black-Litterman model is a powerful tool in the portfolio construction process. It has gained popularity among practitioners for the past two decades, and its applications to various aspects of the portfolio construction process have been discussed in the literature. We believe, however, that some of the applications adopted by practitioners and discussed in the literature deserve more critical examination. In this paper, we will highlight the uses of the Black Litterman model that we find problematic, or at least lacking the vigor of the original formulation of the Black-Litterman model. We will present numerical examples to make our case stronger and, where appropriate, will propose alternative approaches.
Black and Litterman [1,2] saw two strengths of their approach:
1) The subjective views of the investors can be easily incorporated in the portfolio construction process.
2) The Black-Litterman mean-variance optimization does not produce unreasonable solutions, as the standard mean-variance framework does.
The first of these two comes from the feature of the model that investors’ subjective views are expressed as linear combinations of expected returns of assets, rather than as expected returns of individual assets. That is, the subjective view need not be an exact value of the expected return of an individual asset, but rather can be expressed as the expected return of two assets or more in relation to each other. This type of formulation is easier for investors to apply. The second strength comes from the model’s feature that the investors’ subjective views are combined with an equilibrium model that tilts the portfolio weights away from the market capitalization weights based on the relative uncertainty in the investor’s views. This anchors the portfolio weights towards the implied market capitalization weights, thus not allowing for extreme weights due to differences in expected returns.
Out of these two features, the first feature is less essential to the Black-Litterman model. It is relatively easy to come up with an alternative way of specifying investors’ subjective views.1 The spirit of the Black Litterman model can be retained from a variety of subjective prior specifications. The second feature, however, is much more significant. An attempt to modify this feature of the model is likely to introduce inconsistencies. The reason is that there is really only one right way to combine investors’ subjective views with a given model, and there is no other correct alternative. One may choose different views or different models, but once the views and a model are chosen, there is only one way to combine them according to Bayes’ rule.
Some applications of the Black-Litterman model by other authors have attempted to modify the second feature of the model, and, in doing so, they have lost the mathematical rigor of the original Black-Litterman model. Other applications have simply ignored the nature of the subjective view and mixed it up with the model in an inconsistent manner.
In this paper we discuss three representative (mis-) uses of the Black-Litterman model in portfolio construction. We will attempt to quantify the possible losses created by the misuse of the model and, where appropriate, propose an alternative.2 The first application we consider was discussed in Jones, Lim, and Zangari [
In this article, we take a Bayesian perspective. A Bayesian perspective allows us to quantify the losses of investors without too many complications in the analysis. We borrow the framework of Satchell and Scowcroft [
The paper is organized as follows: Section 2 discusses the use of the Black-Litterman technique without an equilibrium model, and the potential losses associated with that methodology; Section 3 discusses the use of the Black-Litterman model with data based priors that conflict with the model, and the loss associated with that methodology; Section 4 discusses the use of the BlackLitterman approach as a reverse optimization and the implication of using an estimated variance-covariance matrix; and Section 5 concludes the paper.
Jones, Lim, and Zangari (2007; henceafter JLZ) presented a way in which the Black Litterman model can be used to incorporate a factor-based view in a structured equity portfolio.
Let be an -dimensional portfolio weight vector, where the -th element is the portfolio weight of asset. Let be an -by- factor exposure matrix, where element is the exposure of stock to factor.4 Then the factor exposure of the portfolio is. A portfolio manager’s factor view can be expressed as a -dimensional vector, which is the portfolio manager’s desired value of.5 JLZ suggest the following steps for the portfolio construction:
1) Specify the factor view vector.
2) Calculate the optimal tilt portfolio weight, i.e. the weight of the portfolio that is optimal given the factor view vector. That is, solve:
where is an -by- variance-covariance matrix estimate of asset returns. The solution to this problem is
where OTP is an acronym for optimal tilt portfolio.6
3) Compute the Black Litterman alpha, i.e. the expected return that produces the optimal tilt portfolio identified in the previous step. That is, solve the following equation for:
The solution to this problem is7
4) Find an optimal portfolio based on the Black Litterman alpha, , and any other constraints using a standard mean variance optimization. For example, an optimal portfolio can be found by solving the following quadratic programming problem:
where and are lower and upper bounds on asset weights.8
In the four step procedure described above, no explicit reference is made to an equilibrium model, which is an integral component of the original Black-Litterman model. In fact, there is no explicit reference to any model of stock returns.
Implicitly, though, the above procedure requires a model to produce an estimate. Even when one decides to use a historical variance-covariance matrix for, one is using a model. The implicit model is that the historical variance-covariance matrix is a good estimator of the true variance-covariance matrix.
Using a model to produce an estimate and using the estimate in calculating the Black Litterman alpha, , however, is not equivalent to “combining a subjective view with an equilibrium model” as is done in the original Black Litterman model. The problem with this approach is that the model is used only to produce an estimate of the variance-covariance matrix. This approach ignores the information in the data about the mean return.9 The consequence is that a subjective view is combined with a model, but only partially and incompletely. The incompleteness does create a problem, as will be shown in the next sub-section.
The JLZ procedure calculates the Black Litterman alpha, , based on a view and a model. The view is summarized in and the model is summarized in an estimate of. As mentioned above, however, the view and the model are not combined in an efficient way. In particular, the mean component of the model is ignored. This creates some loss, the magnitude of which we will quantify in this subsection.
We first discuss our measures of loss. In order to measure an investor’s loss, we need to develop a formal model of returns and investor views. In the subsequent text, we discuss a measure of loss based upon a formal model of returns and views.
One can quantify the loss generated in a portfolio construction process in terms of the Sharpe ratio, the information ratio, or an investor’s utility. For the purpose at hand, the most natural choice is to use the investor’s utility implicit in the Black Litterman approach, which is
where is the mean return of the portfolio and is the standard deviation of the portfolio return. In particular, we will set the value of to, as was done in the JLZ procedure.10 Given the utility function, we can calculate the highest utility one can achieve given the model and the view, and we can also calculate the utility that one actually achieves. The difference is our measure of the loss.
To compute the utility, we will use the predictive mean and variance based on the model and the view. This is justified as our primary interest is in the investor’s portfolio construction strategy, not the validity of the investor’s belief. In addition to this, the predictive mean and variance are the only mean and variance that the investor can actually calculate. It would not make sense to define the investor’s utility in terms of the quantities that are not known to the investor.11
If a portfolio construction process combines the model and the view efficiently, then by construction the loss is zero. This is true in the original Black Litterman approach. It is not possible to improve the utility given the model and the view. In the JLZ procedure, however, it is possible to improve the utility given the model and the view. It is possible to do so by adding the mean component of the model, as we will show below.
Consider the following model:
where represents the vector of stock returns, represents the matrix of factor exposures for factors and stocks, and is a vector of factor premiums, is the error vector, and is the covariance matrix of the error. We include a scalar that affects the overall volatility of the market.
While this model is not explicitly stated in the four step procedure outlined in the previous section, this is probably the most natural model for the JLZ investor, if he were forced to adopt one. (Recall that the lack of an explicit model is one weakness of the JLZ procedure.) Without a model of this kind, it would be hard to motivate a factor tilted portfolio using the JLZ procedure.12
The variables and are observable, while
and are not observable. The error variance is not known either. Before creating a portfolio for, the investor observes and and also. With these data, the investor must determine the distribution of, by estimating, , and, or by updating his belief about these quantities.
The JLZ procedure introduced to capture the investor’s belief. is the desired tilt to specific factors, which depends on the investor’s belief about factor returns. Rather than consider the prior of (i.e. distribution of possible values of), we consider the prior of factor returns. While this approach may seem like an unnecessary detour, it makes the analysis much more tractable.
We interpret in the context of the following prior of and:
That is, has a multivariate normal distribution conditional on, and has a Gamma distribution.13
By including in the variance of, we are assuming that the overall uncertainty of the factor premium is proportional to the overall market volatility.14 This is the simplest prior one can adopt, and is general enough for our purpose. Satchell and Scowcroft (2000) also use this prior when they interpret the Black Litterman model. Note also that this prior allows for the noninformative prior as a special case, as will be shown in the next section.
It is easy to show that is related to the parameters in Equations (7) and (8) in the following way:
where is the variance-covariance matrix of, i.e.,
.15
Equation (7) represents the model, and Equation (8) represents the investor’s view. And together, they describe the belief system of the JLZ investor completely.
Let us be clear about our distinction between the model and the view. The model specifies the relationship among variables that we observe. The view is about the quantities that we do not observe. In particular, the view specifies the relationship among parameters of the model. The view has hyper-parameters, whose values investors choose on their own. In Equation (7), there are three parameters:. In Equation (8), there are four hyper-parameters:. The distinction between the parameters and the hyper-parameters can be made clearly: parameters are a part of the model, while hyper-parameters are a part of the view.
These concepts might be clearer if we describe them in a series of steps.
1) All the equations are known to everyone;
2) At the beginning of our portfolio formulation stage, God decides the value of the hyper-parameters . God announces this decision to every investor;
3) On day 1, God draws parameters using Equation (8). These quantities are never known to the investor;
4) On day 2, God draws data, , and also, and shows them to the investor;16
5) After observing data, the investor estimates the parameters, makes a prediction of, and creates a portfolio;
6) On day 3, God draws using Equation (7);
7) After observing, the investor calculates his portfolio return.
In this scheme, one could think of a number of different expectations and variances of the portfolio return. Let us consider three of them. First, we can think of “God’s expectation,” which is conditional on the true value of parameters, , and. Since only God knows the value of, , and, this expectation is probably not very interesting to our hypothetical investor. Second, we can think of the “predictive expectation,” which is conditional on the data as well as on the hyperparameters, but not on the true value of the parameters. That is, it is the expectation based on the investor’s best prediction given the information available. This is something rational investors can calculate. Third, we can think of “an economist’s expectation,” which is conditional only on the hyper-parameters. This is the expectation one obtains by imagining many different worlds where different parameters could have been chosen from the same hyper-parameters. To investors who live only once, this concept is not particularly interesting. Their utility does not depend on what could have happened in other worlds. This concept, however, could be interesting to economists who want to make general statements about certain decision making schemes. Note also that “an economist’s expectation” is obtained if we integrate the data out of the “predictive expectation.”17
Our analysis is based on the “predictive expectation” and similar concepts, as we are working with a utilitybased measure of loss. Predictive expectation is conditional on the value of the hyper-parameters. Thus, an analysis of predictive expectation can be influenced by the choice of hyper-parameter values. In our numerical analysis, we vary the values of the hyper-parameters to make sure that our results are robust, and that they are not peculiar to the chosen values of the hyper-parameters.
We provide the formula for the predictive mean and the predictive variance-covariance matrix of the returns here without proof.18 The predictive mean and the predictive variance-covariance matrix of returns are obtained by applying statistical operators to the model and then using the Bayesian updating formula (see Zellner [
The predictive mean of the factor premium, the predictive variance-covariance matrix of the factor premium, and the predictive variance-covariance matrix of the error are determined by the Bayesian updating formula:
The first equation simply says that the predictive mean of the factor premium is a “precision-weighted” average of the prior mean and the GLS estimator. The second and the third equation simply break down the components of the variance-covariance matrix. The predictive mean of the error precision parameter can be expressed as follows:19
Now we are ready to compare the utility of an investor who follows the JLZ procedure (the JLZ investor) to the utility of a rational investor who combines all information efficiently (the RTL investor), both having the same view and the same model. We first discuss the utility of the two investors in general form. Then we examine a special case where we can provide an analytic solution for loss.
Let us first characterize the utility of the RTL investor. As noted before, the investor would not consider to be the best estimate of the mean return, nor would he consider the Black Litterman alpha implied by the optimal tilted portfolio to be the best estimate of the mean return. Using the Black Litterman alpha would be equivalent to not using any information from the estimation about the mean return. Instead, the RTL investor would estimate the mean and the variance-covariance matrix of returns using all the information available, and then choose a portfolio based on these estimates.
The best estimates of the mean and of the variancecovariance matrix of the returns are the predictive mean and the predictive variance-covariance matrix described above. Given the predictive mean and the predictive variance-covariance matrix of the return, the rational investor will choose the portfolio by solving the optimization problem comparable to Equation (5). Then his utility is determined as:20
where
Now let us consider the utility of the JLZ investor. The JLZ investor would follow the four steps specified in the previous section. Thus, her portfolio is the solution to Equation (5), and her utility is determined from the mean and the variance of her portfolio. That is,
where
Computation of the loss based on the above utility can be done numerically, which we explain in the next subsection. For now, we will present an analytic solution for the special case where there are no constraints in the optimization. Although, this is not a realistic way of constructing an optimal portfolio, it will help illustrate some key concepts.
Let us start with the rational investor. When there are no constraints, the solution to the optimization problem in Equation (18) is simply
Then the utility is given by
Now let us calculate the utility of the JLZ investor. When there are no constraints, the portfolio of the JLZ investor is simply the optimal tilted portfolio of Equation (2). Combining Equation (2) and Equation (9), we get
Note that we made one simplifying assumption to get the above formula. Firstly, we assumed that the JLZ investor’s covariance estimate of returns is identical to the rational investor’s covariance estimate of returns. Since we did not specify how the JLZ investor obtains, we chose the one that was the best and most advantageous to the JLZ investor. In other words, by doing this we eliminated one mistake that the JLZ investor made, i.e. using an inferior estimate of the error covariance.
Now we can express the utility of the JLZ investor in the following way:
The above formula shows that the difference in utility between the JLZ investor and the RTL investor, i.e. the loss, is quadratic in the difference between the prior mean and the posterior mean of the factor premium. This can be understood intuitively. When one ignores the mean estimates, the portfolio weights deviate from the optimal weights and the deviation is linear in the difference between the prior mean and the posterior mean. The utility, however, depends on the second moments of the portfolio returns, so the loss is quadratic in the difference between the prior mean and the posterior mean.
In order to quantify the losses from an incorrect procedure, we perform a numerical simulation.
The simulation is based on the monthly returns and other characteristics of the MSCI country indices.21 Specifically, we select the top 10 countries by market capitalization. We used the price-to-earnings ratio, 6 months momentum return, and the market capitalization of the indices as factors in our factor model. Our data set spans the 7-year period from September 2001 to August 2008. The summary statistics of the variables for each country are presented in
For the simulation, we use the Chi-square distribution for the error precision parameter. The Chi-square distribution is a special case of the Gamma distribution, and all the formulas presented above are still applicable. The model and the prior now look as follows:
and
The simulation proceeds according to the following steps.22
1) We choose a reasonable value for the hyper parameters;
2) We draw a single value of parameters and using the hyper parameters above. We use the OLS estimator for the remaining parameter;
3) We draw from the parameters determined above. For the factor exposures and, we use historical values;
4) Given the values above, we determine the portfolio of the JLZ investor and the RTL investor;
5) We calculate the loss;
6) We repeat Steps 2 to 5 a 1000 times, without changing the hyper parameters. Then we obtain a distribution of losses, which will allow us to make general statements about the JLZ investor’s decision making process;
7) We repeat the above six steps by making small perturbations to the hyper parameter values.
The outcome of the simulations is summarized in Tables 2 and 3. A figure of the actual losses in 1000 simulations is shown in
Note: Return is the monthly percentage return. Market cap is the market capitalization in hundred of billions of US dollars. P/E is the price-toearnings ratio as calculated by MSCI. Momentum is latest 6 month return.
Note: The H.P. is for Hyper-Parameter set. Sets 1 - 11 alter the value of vector and and as follows: [1 1 1 1 1; 1.1 1 1 1 1; 0.9 1 1 1 1; 1 1.1 1 1 1; 1 0.9 1 1 1; 1 1 1.1 1 1; 1 1 0.9 1 1; 1 1 1 1.1 1; 1 1 1 0.9 1; 1 1 1 1 0.9; 1 1 1 1 1.1]. Each set is separated by a semi-colon. For example, set 1 is the baseline case where is not altered. Set 2 alters by multiplying the 2nd element of by 1.1 and so on and so forth. Each row in the table within each set represents the utility for a particular investor. The first row is Rational, the second row is the JLZ, and the third row is the FFK investor.
Note: The H.P. is for Hyper-Parameter set. Sets 1 - 11 alter the value of vector and and as follows: [1 1 1 1 1; 1.1 1 1 1 1; 0.9 1 1 1 1; 1 1.1 1 1 1; 1 0.9 1 1 1; 1 1 1.1 1 1; 1 1 0.9 1 1; 1 1 1 1.1 1; 1 1 1 0.9 1; 1 1 1 1 0.9; 1 1 1 1 1.1]. Each set is separated by a semi-colon. For example, set 1 is the baseline case where is not altered. Set 2 alters by multiplying the 2nd element of by 1.1 and so on and so forth. The first row represents the utility loss to the JLZ investor and the second row represents the utility loss to the FFK investor for each hyper parameter set.
Fabozzi, Forcardi, and Kolm (2006; henceafter FFK) suggested that one could incorporate a trading strategy, possibly based on a factor model, as a prior in the Black Litterman approach. The portfolio construction process might look as follows.24
1) Estimate the factor model that represents the portfolio manager’s belief, and specify the “prior” from the estimates of the model. Suppose that the factor model can be written in the following form
Given the estimate and, the “prior” for the mean of the future return, , can be specified as:25
2) Let be the estimate of the “equilibrium return” implied by the Capital Asset Pricing Model. Assume the following “model” for:
where is the variance-covariance matrix of future returns, i.e., , and is a known constant. Note that, where is an estimate of.26 From this value of, one can get an estimate of and also get a variance-covariance matrix estimate of the estimator:
3) Combine the “prior” with the likelihood of the “model” according to Bayes rule. The posterior of the mean returns is specified by27
The posterior mean is sometimes referred to as the “Black Litterman alpha”.
4) Find the optimal portfolio from a mean variance optimization using the posterior mean and the posterior variance-covariance matrix of stock returns.28 That is, solve
where and are lower and upper bounds on asset weight.
This procedure takes care of the problem identified in the previous section. The Black Litterman alpha is derived from an equilibrium model as well as from a prior. Information on the mean returns is not discarded, removing the potential for the type of loss identified in the previous section.
This procedure, however, introduces a new type of problem. It is based on two models that are contradictory to each other. The prior is built on the belief that a factor model is the underlying data generating process, while the likelihood is based on the belief that a CAPM is the underlying data generating process. Both beliefs cannot be true at the same time. As the procedure is based on two beliefs, the procedure cannot be optimal regardless of which belief is accurate.29 In the following subsection, we will show the magnitude of the loss arising from adopting this procedure.
We will assume that the factor model in Equation (27) is the true data generating process, and we will show that using the FFK procedure creates a loss. Our argument is independent of what the true model is.
In the previous section, we already discussed the factor model in Equation (27), a prior for this model, and the resulting predictive mean and the variance. The only difference is that in Equation (27) we have instead of. We will also make one modification to the prior in this section. We will assume that the investor does not have any prior opinion. This modification not only makes the calculation much simpler, but it also makes our comparison more relevant. If we suppose that the investor who follows the FFK procedure has a certain prior opinion, then this investor is making twice as many mistakes. The first mistake is ignoring his prior opinion, and the second mistake is not using the factor model exclusively. Thus, by assuming that the investor does not have any prior opinion, we are eliminating one possible mistake that the investor could commit by following the FFK procedure.
Formally, the non-informative prior can be expressed as
This is rather intuitive as it says that the noninformative prior is just the prior distribution of the factor premium as the variance of the factor premium converges to infinity. The formula for the posterior must be modified as well. The new formulae are:30
The predictive mean and the predictive variance-covariance matrix of the returns are then:
Consider two investors. One investor, called the FFK investor, follows the FFK procedure as described in the previous subsection. The other investor, called the RTL investor, makes rational decisions based on the factor model.
The RTL investor’s portfolio can be specified as
and the RTL investor’s utility can be written as
The FFK investor’s portfolio can be specified as
and the FFK investor’s utility can be written as
As in the previous section, we calculate the loss analytically for the simplest case, i.e. the case where there are no constraints in the optimization. If there are no constraints in the optimization, the RTL investor’s portfolio weight and his utility are identical to those presented in the previous section, i.e.
The FFK investor’s portfolio weight, on the other hand, is:
For simplicity, let us assume that the FFK investor’s estimate of the variance-covariance matrix is not very different from the predictive variance-covariance matrix of the RTL investor.31 Then we could write
and
Thus, the loss is approximately quadratic in the difference between the FFK investor’s posterior mean and the RTL investor’s posterior mean.
Let us consider the difference between the FFK investor’s posterior mean and the RTL investor’s posterior mean further. Assuming that the difference between the OLS estimator and the GLS estimator is not large32, one can write
Thus, the loss depends on the difference between the multifactor model estimates and the CAPM estimates. This is a rather obvious result, considering that the very source of the problem was the use of the CAPM, which is not the correct model in our example.
We follow the procedure identical to that of the previous section to numerically calculate the magnitude of the loss.33 Tables 2 and 3 summarize the simulation results. The actual distribution of losses for the FFK investor for 1000 simulations is shown in
One may notice that the loss of the FFK investor is somewhat smaller than the loss of the JLZ investor. This is what we could have expected. The loss of the JLZ investor is a quadratic function of the error in the mean estimate, while the loss of the FFK investor is a linear function of the difference in mean estimates of the two models.
Practitioners often use the Black-Litterman approach as a tool to extract implied expected returns for a given portfolio weight vector. Step 3 of the JLZ procedure discussed in Section 2 of this paper is an example of this.
Given a portfolio weight vector, one can derive the implied expected return by assuming that the portfo-
lio weight vector is a solution to the following optimization problem:
As we have shown in Section 2, the solution is given as
where is the variance-covariance matrix of returns.
One aspect that is often ignored in the “reverse optimization” is that the validity of the implied expected return depends on the validity of the variance-covariance matrix used.34 To the extent that the variance-covariance matrix includes an error, the implied expected return also includes the error.
Let be the true variance-covariance matrix. Let be our estimate of the variance-covariance matrix. Then the error in the implied expected return is.
To have a more intuitive sense of the magnitude of the error, we focus on the implied market return, which is, where is the market capitalization weight. We present typical values of this bias in
The Black-Litterman model has been used extensively in
Note: VW represents the reverse optimization bias for value-weighted portfolio, while EV represents the reverse optimization bias for an equalweighted portfolio in percentage terms.
asset allocation and in recent years, a number of people have proposed applications of it to areas such as trading and quantitative portfolio management. Some of these methods have necessitated a transformation or adaptation of the Black-Litterman model to the specific application. Unfortunately, these transformations could be associated with unintended consequences. In this paper, we discuss three applications of the Black Litterman model that result in unnecessary costs to the investor.
The first type of application creates a portfolio out of a prior and an estimate of the variance-covariance matrix, but fails to utilize the mean estimate. Not using the mean estimate amounts to ignoring a valuable piece of information present in the data. Our conservative estimate of the loss from neglecting the mean is about a 1% reduction in expected annual returns. Although it is well known that means are not estimated as reliably as variance and covariances, ignoring the mean estimate cannot be an optimal solution. For even if the mean estimate is not extremely precise, it is still better to use this estimate than to entirely ignore it.
The second type of application creates a portfolio out of two conflicting models of security returns, e.g. the CAPM and a multi-factor model. Assuming that the multi-factor model is the true model of stock returns, we estimate the loss to an investor that chooses to combine both a CAPM model and a multi-factor model in his portfolio construction. We find the magnitude of this loss to be around a 1% reduction in expected annual returns. One might justify the use of two models if the portfolio manager has no idea regarding which model is more likely to be true. In most practical situations, it would be unlikely that the portfolio manager or analyst did not have a clear idea about which model they believed represented the behavior of stock returns. Thus, it makes it hard to justify using two contradictory models of stock returns.
The third application is the so-called reverse optimization technique. That is, practitioners often use the weights of an index and reverse optimize to obtain the implied expected returns of the market. Since the variance-covariance matrix is estimated with error, the implied expected returns of such a procedure will also be estimated with error. We quantify the magnitude of the errors associated with this technique. We found this error to be quite high, in some cases as high as 3.5% per month and much higher if the original benchmark was an equal-weighted benchmark. This brings into question how useful this reverse optimization technique really is.
No doubt the Black-Litterman model brought a new tool to aid asset allocators, portfolio managers, and traders with the construction of optimal portfolios. In particular, it provided a theoretical framework upon which an investor’s prior views about asset markets or stocks could be combined with the actual historical data in order to construct optimal investments. The main application of the Black-Litterman model has been to asset allocation across broad asset classes. Recent research has tried to integrate the Black-Litterman model in the trading framework and the quantitative equity portfolio framework. These advances are inspiring as they improve the tool set for quantitative managers, unfortunately some of the applications have side effects which we must be aware of. In this paper, we have discussed some of the potential side effects of these applications of the Black-Litterman model. Our estimates of the losses associated with these side effects are large from a portfolio management perspective. We also suggest a straightforward way to apply the Black-Litterman model without this bias in the portfolio construction process.