short term update: shared on social media hundreds of times including fund CEOs, professors, CFA, and other industry leaders. also highlighted in bloomberg, a Top News in zero hedge, and others. also bear in mind that we may be violating VAR levels again (this time for september), depending on the rest of the week, ending september 4.
If you were a looking at a simple portfolio that was a mix of 1 unit S&P 500 and 1 unit Shanghai Stock Exchange (SSE), then you might consider value-at-risk (VAR) to feel cozy with your overall portfolio risk. This measure however is not considered a coherent risk measure that satisfies all of the properties of interest: monotonicity, translation invariance, homogeneity, and subadditivity. We'll explain the first three in a future article, but only focus here on how VAR violates the last of these four properties. Subadditivity is where the risk associated with multiple holdings, in a portfolio, should not be greater than the sum of the individual holdings' risk. This construes the hallmark of diversification, and yet combined with the inappropriateness of VAR to measure market risk we see subadditivity levels violated (as opposed to more complicated conditional expected tail loss measurements). Risk events that should have only happened say one month every 1.5 years have abruptly occurred in each of the past three summer months.
If you were a looking at a simple portfolio that was a mix of 1 unit S&P 500 and 1 unit Shanghai Stock Exchange (SSE), then you might consider value-at-risk (VAR) to feel cozy with your overall portfolio risk. This measure however is not considered a coherent risk measure that satisfies all of the properties of interest: monotonicity, translation invariance, homogeneity, and subadditivity. We'll explain the first three in a future article, but only focus here on how VAR violates the last of these four properties. Subadditivity is where the risk associated with multiple holdings, in a portfolio, should not be greater than the sum of the individual holdings' risk. This construes the hallmark of diversification, and yet combined with the inappropriateness of VAR to measure market risk we see subadditivity levels violated (as opposed to more complicated conditional expected tail loss measurements). Risk events that should have only happened say one month every 1.5 years have abruptly occurred in each of the past three summer months.
VAR (invented at J.P. Morgan well before both the global financial crisis and their entertaining London Whale drubbing, where experts in Congress tested CEO Dimon about his VAR models) is an expression of the largest possible loss, contained within a specified confidence interval (e.g., 90%, 95%, 99%, etc.) We can for example explore the history of worst weekly losses in the S&P, for each month starting more than 5 years ago in January 2010 (and through May 2015). A total of 65 months, which is statistically large enough where additional data (including from the global financial crisis) wouldn't change the learnings. We can set a probability tolerance of just over 6%, and state that the probability of seeing a loss greater than this VAR should be less than or equal to ~6% (or 1 in 16 months). We can vary this level about, but this is simply a foothold to initiate our analysis.
VAR in this case, for the S&P, would come to a worst weekly loss of 6.0%. Bear in mind that the average worst weekly loss over the 65 months for the S&P was a 1.9% loss. Now we do the same exercise for the SSE, and with the same probability tolerance of ~6% we get a VAR loss of 5.3%. Here the average worst weekly loss over the 65 months for the SSE is a 2.6% loss. Note that the parametric mathematical relationship to estimate the overall VAR from blending two equally volatile stocks (or indexes) does relate to the correlation between those 2 indexes.
VAR in this case, for the S&P, would come to a worst weekly loss of 6.0%. Bear in mind that the average worst weekly loss over the 65 months for the S&P was a 1.9% loss. Now we do the same exercise for the SSE, and with the same probability tolerance of ~6% we get a VAR loss of 5.3%. Here the average worst weekly loss over the 65 months for the SSE is a 2.6% loss. Note that the parametric mathematical relationship to estimate the overall VAR from blending two equally volatile stocks (or indexes) does relate to the correlation between those 2 indexes.
VARoverall
= VARindex√[(1/number
of indexes) + (1-1/number of indexes)ρ]
= VARindex√[½
+ ½ρ]
The reason it seems as if the VAR for SSE is set at an easier loss level, versus that for the S&P, is a reflection of the nonparametric nature of equity returns. This turns out to be critical as we go through this article. Also keep in mind that these VAR express a fixed week period, and not any continuous range beyond that. We know the maximum-VAR was higher if we simply augment to the trading week, ending August 21, the following "Black Monday". And most also know by now, that these stock returns are not related to the normal distribution (or elliptical distributions for that matter), and now we also see these fat tails are not even related to one another. On a related topic, for more on the Student t distribution, see here, here.
The number of months where the worst weekly losses should exceed the VAR over 65 months is no more than 3 (roughly an integer <6%*65). For the S&P, the changes have been (in order of severity): -6.6%, -6.8%, and the worst weekly loss before the summer of 2015 was -7.5%.
For the SSE, the changes were: -5.3%, -6.6%, and -6.9%. The 3 months associated with the S&P above, and the 3 months associated here with the SSE, have one month in common (May 2010). The four bolded months of the six months noted (3 S&P and 3 SSE) are part of the worst 3 joint, "worst weekly losses". We show these 3 joint losses below, where again the portfolio constitutes 1 unit S&P and 1 unit SSE (for a portfolio that is 50% in both indexes you would take ½ of every loss and VAR for the purposes of comparison):
For the SSE, the changes were: -5.3%, -6.6%, and -6.9%. The 3 months associated with the S&P above, and the 3 months associated here with the SSE, have one month in common (May 2010). The four bolded months of the six months noted (3 S&P and 3 SSE) are part of the worst 3 joint, "worst weekly losses". We show these 3 joint losses below, where again the portfolio constitutes 1 unit S&P and 1 unit SSE (for a portfolio that is 50% in both indexes you would take ½ of every loss and VAR for the purposes of comparison):
-7.5% + (-2.8%) = -10.3%
(-5.2%) + -6.9% = -12.1%
-6.6% + -6.6% = -13.2% (this is May 2010)
(-5.2%) + -6.9% = -12.1%
-6.6% + -6.6% = -13.2% (this is May 2010)
Note values in () are the paired worst weekly loss for the bolded S&P or the SSE worst weekly losses.
Again the portfolio theoretical VAR should have been no greater than the sum of the two holdings' VARs. Or 11.3% (6.0%+5.3%). And empirically we see above that the portfolio VAR comes to smaller than a 10.3% loss.
Does this make everything feel good about your portfolio risk measures? Can you take comfort with the VAR model and diversification, and feel comfortable that you would only see a <10.3% loss level once out of every 16 months? It's attractive, but look at what immediately happened next over the following 3 months of the summer:
June 2015: -0.7% + -14.3% = -15.0%
July 2015: -2.2% + -12.9% = -15.1%
August 2015: -5.9% + -12.3% = -11.9%
In each of these 3 months, the S&P always stayed within VAR yet the overall losses still were always greater than the 10.3% VAR (and all were greater than the theoretical 11.3% VAR for that matter!) A 1 in 16 months event immediately happening 3 months straight is not a quirky <0.02% (6%3) probability situation. It was a case of incorrectly using VAR as the preferred nonparametric risk measure for the market we are modeling (e.g., "extreme" tail risk events). Despite how commonly it is endeared anyway by investors and dull stress testing regulators.
Does this make everything feel good about your portfolio risk measures? Can you take comfort with the VAR model and diversification, and feel comfortable that you would only see a <10.3% loss level once out of every 16 months? It's attractive, but look at what immediately happened next over the following 3 months of the summer:
June 2015: -0.7% + -14.3% = -15.0%
July 2015: -2.2% + -12.9% = -15.1%
August 2015: -5.9% + -12.3% = -11.9%
In each of these 3 months, the S&P always stayed within VAR yet the overall losses still were always greater than the 10.3% VAR (and all were greater than the theoretical 11.3% VAR for that matter!) A 1 in 16 months event immediately happening 3 months straight is not a quirky <0.02% (6%3) probability situation. It was a case of incorrectly using VAR as the preferred nonparametric risk measure for the market we are modeling (e.g., "extreme" tail risk events). Despite how commonly it is endeared anyway by investors and dull stress testing regulators.
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