European and Japanese investors: Consider not fully hedging your USD exposure
Global Fixed Income Insights
European and Japanese investors: Consider not fully hedging your USD exposure
julio 12, 2019
Europe- and Japan-based investors typically hedge all foreign currency exposure back to their local currencies, but is this the best practice? We have computed several FX hedge ratios and find that fully hedging USD exposures may be suboptimal. We estimate an optimal FX hedge ratio of around 66% for euro-based investors and 80% for Japan-based investors. When allowing for monthly rebalancing of the hedges, we find that the optimal FX hedge ratios are, on average, very close to the static ones, but are volatile and change drastically during episodes of heightened risk aversion.
As an example of this common practice, an asset manager residing in the euro area with exposure to the USD-denominated JPMorgan EMBIG Index (a benchmark comprising hard-currency-denominated sovereign and quasi-sovereign debt), may offset the USD exposure by entering a matching long EURUSD (eurodollar) position through a derivative (usually, an FX forward or swap).
However, this practice can be expensive, particularly in the current environment where euro and Japanese yields are significantly below U.S. yields. That is, these hedges incur negative carry because being long EUR (or JPY) vs. the USD is equivalent to borrowing in USD at a given rate, and investing the proceeds at a much lower EUR (or JPY) rate. Furthermore, given the typical underperformance of the EUR vs. the USD during spikes in global risk aversion, the cost of fully hedging USD exposure back to EUR could be even higher. The opposite may occur for Japanese investors: JPY tends to rally in risk-off scenarios and the optimal response would be to over-hedge.1 Therefore, 100% FX hedge ratios are not necessarily the optimal way to manage the USD exposure.
In this paper, we look at several FX hedging strategies proposed by finance literature with the goal of calculating an optimal FX hedge ratio of an underlying USD position. We will examine both static hedging strategies, where the FX hedge ratio remains constant throughout the investment horizon, and more realistic dynamic hedging strategies, where the hedge ratio is rebalanced frequently. All the metrics considered in our sample suggest that euro- and Japan-based investors should consider only partially hedging their USD exposure.
Moreover, dynamic FX hedge ratios are, on average, similar to the static ones. However, they are volatile and exhibit sudden spikes during periods of heightened risk aversion, leading to FX hedge ratios that can materially deviate from the static ones.
The results presented here are illustrative and do not imply investors should follow the recommendations, as the truly optimal hedge ratio will be a function of the underlying USD exposure, current market conditions, and individual investors’ views about expected returns of both the underlying and hedging assets. However, we believe the computed FX hedge ratios are similar enough to provide managers with a useful framework on how to manage FX risks.
Two frameworks to calculate optimal FX hedge ratios
There are many criteria that may guide the search for the optimal FX hedging ratio.2 The general approach is to pick the FX hedge so that it optimizes a certain objective. Typically, the investor chooses an FX hedge ratio that minimizes the volatility of the hedged portfolio return.3 Such a risk minimization framework may provide useful results, particularly when the expected return of the FX futures contract is zero, that is, when the positive interest rates differential exactly offsets the expected FX depreciation implied by the forwards.
However, when investors’ views about the currency differ from those implied by the market, the risk minimization framework is not flexible enough.
Therefore, we also study a risk-adjusted maximization framework to reflect the risk-return trade-off in hedging FX exposure. The appendix provides definitions for the specific criteria we consider when implementing both approaches.
Static and dynamic FX hedge ratios
The metrics we considered are typically calculated under the assumption that the FX hedge ratio will remain unchanged throughout the entire investment horizon, regardless of possible changes in market conditions.
However, the volatilities and correlations among asset returns vary: an FX hedge ratio that fails to adjust to changing market environments is likely to underperform. Therefore, we also calculate an FX hedge ratio alternative4 that can be adjusted every month, and depends on estimates of volatilities and correlations of asset returns at the time of each rebalancing.
Euro- and Japan-based investors: you may be better off partially hedging your USD exposure
Both static and dynamic FX hedge ratios are computed for hypothetical euro- and Japan-based investors holding a single USD exposure, represented by the JPMorgan EMBIG benchmark index. The data for the analysis consists of unhedged EUR and JPY monthly EMBIG returns, and returns for 1-month EURUSD and USDJPY FX forwards, spanning the period January 1999-May 2019, for a total of 248 observations. All the data is available in Bloomberg.
Optimal FX hedging ratios for EURbased investors are typically in the 60%-80% area though there is some variation depending on the optimality criterion (see left side of Display 1). All these metrics imply lower FX hedge ratios than the usual practice of fully hedging one’s FX exposure.
When we consider mean-risk hedge ratios, that is, those that attempt to strike an optimal balance between risk and expected return, the results for the eurobased investors are in line with intuition: they tend to prescribe slightly lower FX hedge ratios than those obtained from a pure risk-minimization framework. This is because mean-risk hedge ratios take into account the expected return of the long one-month EURUSD forward contract, which we estimated as slightly negative, at 6 basis points per month.5 That is, there is a cost to hedging the USD exposure because the appreciation of the EUR vs. the USD during the sample period did not compensate for the negative EUR-USD rate differential.
We ran the same calculations for a hypothetical Japanese manager with a USD exposure via the EMBIG benchmark. The minimum-variance (MV) approach recommends a Japanese investor to hedge about 88% of the USD exposure. Other risk-based measures prescribe similar FX hedge ratios, but one interesting result of these calculations is that the optimal FX hedge ratios for Japan-based investors are uniformly higher than those prescribed to the EUR-based investor. This is partly explained by the fact that the JPY forward is a better hedging asset than the EUR forward, because the JPY forward returns correlate better with the unhedged returns of the underlying, than in the EUR case.
However, when we consider risk-adjusted measures of expected returns, the optimal FX hedges for a Japan-based manager can sometimes be lower than those calculated for the euro-based manager. These results reflect the higher negative carry of long JPY positions (versus EUR longs) used to hedge the USD exposure. In other words, because JPY rates in the time sample considered were, on average, lower than their EUR equivalents, hedging with short USDJPY forwards is more expensive, thus lowering the optimal hedge ratios prescribed by mean-risk based approaches.
Dynamic hedge ratios are volatile and react significantly to spikes in risk aversion
In this section, we go beyond constant FX hedge ratios to consider frequently rebalanced hedges based on monthly estimates of return volatilities and correlations among assets. Display 2 reports these dynamic FX hedge ratios for both euro- and Japan-based managers.
Dynamic FX hedge ratios exhibit significant variation, typically fluctuating in an interval between 50% and 100%. The average EURUSD hedge ratio is about 76%, which is broadly in line with static hedges. Similarly, for Japan-based investors: the average FX hedge ratio is about 87%, very close to the constant hedges.
However, there are significant spikes in hedge ratios, most notably during the global financial crisis in the second half of 2008. Up to September 2008, a euro-based investor following a dynamic hedging strategy would have been fully hedging the USD exposure, whereas a Japanese investor would have hedged about 90% of it. In the two subsequent months, these optimal FX hedge ratios would have drastically changed: the euro-based investor would have reduced FX hedges to a net USD exposure of 121% of the underlying USD position by November, while a Japan-based investor, on the contrary, would have overhedged by increasing short USDJPY positions to 250% of the USD exposure in November 2008 (see Displays 3 and 4).
The sharply asymmetric response of the EUR and JPY FX hedges in stress scenarios reflects the fact that in riskoff environments, the USD tends to appreciate versus the EUR (because of the latter’s high beta to the VIX, a proxy for risk aversion), but typically depreciates against the JPY (as spikes in risk aversion prompt investors to unwind carry trades, which are funded by low yielding currencies, such as JPY or CHF).6 In fact, during the October-November 2008 period, the EUR depreciated by 11% against the USD, while the JPY strengthened by the same amount.
We put the theory of futures hedging to use to address the situation European and Japanese investors face when managing USD exposure. The main takeaway is that fully hedging USD exposure back to domestic currencies appears to be suboptimal, as all the risk-based approaches we examined point to optimal FX hedges around 66% for euro-based investors and 80% for Japan-based managers. Mean-risk approaches, which factor in the cost of hedging USD exposure with long EURUSD and short USDJPY positions, suggest even lower hedge ratios. Finally, to account for timevarying volatilities and correlations, we explored dynamic hedge ratios that are, on average, close to those prescribed by static methods, but that exhibit significant volatility and change suddenly in response to spikes in global risk aversion.
In this section, we introduce the specific objective functions that we used to calculate the optimal FX hedge ratios:7
1 A comprehensive study of currency responses to risk-off events can be found in De Bock and De Carvalho Filho, “The Behavior of Currencies during Risk-off Episodes,” IMF Working Paper No. 13/8, 2013.
2 For those interested in the broad issue of hedging a position (it could be equities, bonds, FX, commodities, etc.) with futures contracts, please refer to a comprehensive survey by Chen, Lee and Shrestha, “Futures Hedge Ratios: A Review,” The Quarterly Review of Economics and Finance, 43 (2003) 433-465.
3 The variance is the traditional measure of risk or volatility, but the financial literature has examined alternative metrics that are less restrictive. In particular, risk measures, such as the Gini coefficient and the semi-variance can also be considered to compute optimal FX hedge ratios. Please refer to the appendix for definitions.
4 The specific approach we consider is a multivariate GARCH method. See appendix for further details.
5 We use historical average monthly returns as proxies for expected long EURUSD one-month forward and EUR-unhedged EMBIG returns. In turn, EMBIG unhedged returns can be broken down into two components: a USD-denominated return (due to carry and duration) and an FX return (for eurozone-domiciled investors, a depreciation of the EUR against the USD is another source of positive return).
6 See reference in fn.1.
7 See reference in fn.2.
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