3.1 Economic scenario generator

Oberoi et al. (Reference Oberoi, Pittea and Tapadar2020) propose a graphical model approach to develop an ESG suitable for use by a life insurance company or a pension scheme in the UK that invests in equities and bonds. Andrews et al. (Reference Andrews, Bonnar, Curtis, Oberoi, Pittea and Tapadar2019) extend this approach to develop an ESG for the US economy. In this section, we provide a brief outline of the graphical model methodology and the relevant parameterisation for the UK and the US ESGs, which we will use in this article.

A minimal ESG, which can be used to analyse DB scheme risks, requires data for price inflation (I), salary inflation (J), stock returns and bond returns. Following the approach of Wilkie (Reference Wilkie1986), Oberoi et al. (Reference Oberoi, Pittea and Tapadar2020) use dividend yield (Y), dividend growth (K) and Consols yield (C) to construct stock and bond returns. The dataset used by Oberoi et al. (Reference Oberoi, Pittea and Tapadar2020) consists of annual values of these economic variables from 1926 to 2017 as at the end of June each year.

Andrews et al. (Reference Andrews, Bonnar, Curtis, Oberoi, Pittea and Tapadar2019) obtain the US data from two sources. The first is Robert Shiller, who provides online data for price inflation, S&P 500 Index, S&P 500 High Dividend Index and bond yields. The second source is Emmanuel Saez, who provides online data for average wages in the US. The US data extend from 1913 to 2015.

In a graphical ESG, involving a number of economic variables, first a univariate time series model, typically an AR(1) process, is fitted to each individual economic variable. If $X_t$ denotes one of the economic variables to be modelled, with data available for times $t=0,1,2,\ldots,H$ , the following model is fitted:

(6) \begin{align} \mu_x &=\mathbb{E}\left[X_t\right], \quad \textrm{(i.e. averaging over time)};\end{align}

(7) \begin{align} Z_t&=X_t-\mu_x, \quad \textrm{for } t=0,1,2,\ldots,H;\end{align}

(8) \begin{align} Z_t&=\beta_x\,Z_{t-1}+e_{x,t}, \quad \textrm{for} \ t=1,2,\ldots,H; \textrm{ where} \ e_{x,t} \sim N\left(0,\sigma_x^2\right).\end{align}

The parameter estimates of $\mu$ , $\beta$ and $\sigma$ for the chosen economic variables in the UK and the US are given in Table 1.

Table 1.

ESG time series parameter estimates

Once the residuals, $e_{x,t}$ are obtained for each variable $X_t$ , a Gaussian graphical model is fitted to the multivariate residuals:

(9) \begin{equation}\mathbf{e_{t}}=(e_{I_{t}},e_{J_{t}},e_{Y_{t}},e_{K_{t}},e_{C_{t}}) \sim \mathcal{N}(\mathbf{0},\Sigma),\end{equation}

separately for the UK and the US data. Estimation is carried out based on maximum likelihood and the resulting partial correlations are shown in Table 2.

Table 2.

Partial correlations of residuals

Clearly, some of the partial correlations in the matrices are small. Graphical models provide a means to identify the minimum number of non-zero correlations that describe the underlying data adequately. In other words, it is a dimension reduction tool whereby correlations of all pairs of residuals need not be stipulated directly. Instead, in this approach, only the correlations between variables that are not conditionally independent are used.

Oberoi et al. (Reference Oberoi, Pittea and Tapadar2020) use a number of statistical criteria, namely AIC, BIC and simultaneous p-values, to determine the optimal graphical model for the UK data. Model E6, shown in the top panel of Figure 1, is identified by Oberoi et al. (Reference Oberoi, Pittea and Tapadar2020) as a model that satisfies certain desirable features and also possesses an intuitively appealing structure. For the purpose of this article, we use Model E6 as our ESG for the UK economy.

Figure 1

UK and US graphical models.

Andrews et al. (Reference Andrews, Bonnar, Curtis, Oberoi, Pittea and Tapadar2019) use the same approach to determine the graphical structure for the US economic data. Interestingly, for the US data, all three statistical criteria, i.e. AIC, BIC and simultaneous p-values, produce the same graphical structure, which is shown in the bottom panel of Figure 1. We use this graphical ESG to model the US economy.

We have also checked that qualitatively, all the results and conclusions of our analysis are broadly very similar, regardless of the ESG employed. Specifically we have carried out the same analysis using the well-known Wilkie model (Wilkie, Reference Wilkie1986; Wilkie, Reference Wilkie1995; Wilkie et al., Reference Wilkie, Şahin, Cairns and Kleinow2011; Wilkie & Şahin, Reference Wilkie and Şahin2016, Reference Wilkie and Şahin2017a,b,c, Reference Wilkie and Şahin2018). We find that although, as expected, there are some quantitative differences between the numbers obtained from the Wilkie model and the graphical ESG, qualitatively the results point to very similar conclusions. The results for the Wilkie model are available from the authors on request.

3.2 Stochastic mortality models

Future projections of pension scheme cash flows also depend on the mortality assumptions. Cairns et al. (Reference Cairns, David, Dowd, Coughlan, Epstein, Ong and Balevich2009) provide a quantitative comparison of eight stochastic mortality models using data from England and Wales and the US, of which Model M7 provides a good fit for both UK and US data. For the purpose of this article, we use model M7 to project forward stochastic mortality rates of the UK and the US.

The structure of model M7, which models q(t,x), the probability that an individual aged x at time t will die between times t and $t+1$ , is as follows:

(10) \begin{equation}\textrm{logit } q(t,x)= \kappa_t^{(1)}+ \kappa_t^{(2)} (x-\bar{x}) + \kappa_t^{(3)}\left[(x-\bar{x})^2- \sigma^2\right]+ \gamma_{(t-x)}^{(4)},\end{equation}

where x is the age, $\bar{x}$ is average age, $\sigma^2$ is the average of $(x-\bar{x})^2$ , $\kappa_t^{(i)}$ are the period effects and $\gamma_{t-x}^{(i)}$ is the cohort effect.

We parameterise model M7 using the UK and US data from the Human Mortality Database for both males and females from 1961 to 2014 for the ages of 30–100.

Projecting future mortality rates involves projecting the time series $\kappa_t^{(i)}$ and $\gamma_{t-x}^{(i)}$ forward. Systematic risk arises from the uncertainty involved in projecting these time series. For example, if the mortality rates improve faster than expected then future q(t,x) will be lower, which in turn will result in lower deaths. Cairns et al. (Reference Cairns, Blake, Dowd, Coughlan, Epstein and Khalaf-Allah2011) suggest possible approaches to project mortality parameters forward based on the historical estimates of these parameters. For our purpose, we project $\kappa_t^{(i)}$ linearly over time. Given that we are not interested in future cohorts (but only in existing ones), we do not project $\gamma_{t-x}^{(i)}$ forward.

We do not model idiosyncratic (or non-systematic) mortality risk, because in this article, we model large pension schemes and this risk can be diversified away by pooling.

4.1 UK pension scheme

In this section, we provide a brief overview of our modelling approach of the UK scheme. The UK scheme model is based on the USS, which is one of the largest open DB schemes operating in the UK, with more than 350 participating employers and approximately 400,000 scheme members. The approach presented is based on the actuarial valuation carried out for the scheme on 31 March 2014.

4.1.1 Membership profile

The broad membership profile for the UK scheme is shown in Table 3. To capture the overall risk characteristics and the intergenerational risk dynamics of the scheme, we need a range of model points specifically for active members. So we use an age distribution for active members, as shown in Table 4. Table 4 also provides past service and salary assumptions for each model point, which have been set so that the average past service and average salary of active members broadly match the figures from Table 3. For deferred members and pensioners, we use single model points, based on the values given in Table 3, to represent each of these membership categories. We do not use a range of model points for deferred members and pensioners, as this does not have a material impact on our results and conclusions. We also assume an equal gender split and no salary differential between genders for all membership categories.

Table 3.

UK scheme membership profile

Table 4.

UK scheme model points, past service and salary of active members

4.1.2 Benefit structure

The pension benefits are comprised of an annual pension and a cash lump sum at retirement, calculated as follows:

\begin{align*}&\textrm{Annual pension} = \textrm{Pensionable salary} \times \textrm{Pensionable service} \times \textrm{Accrual rate};\\&\textrm{Lump sum} = 3 \times \textrm{Annual pension}.\end{align*}

To capture some of the USS-specific features of the benefit structure, while keeping the model simple, we assume that all members accrue benefits on a final salary basis up to 31 March 2014; and from 1 April 2014 onward, all members move to a career revalued basis. The accrual rate for the final salary and career revalued schemes are $1/80$ and $1/75$ , respectively.

Annual pension is assumed to increase in line with price inflation, subject to a 5% limit. Members’ salaries increase in line with salary inflation in the economy. In addition to salary inflation, there is an explicit age-based promotional salary scale, based on the LG59/60 table, which is widely used for actuarial valuation of UK DB schemes. Sample values of the scale are shown in Table 5. For our analysis, future projections of price inflation and salary inflation are generated by the ESG described in section 3.1.

Table 5.

UK pension scheme assumptions

For members who withdraw from the scheme, a deferred inflation-linked pension is provided based on accrued service. Inflation indexation of salary is provided between the date the member withdraws from the scheme and the date of retirement. A sample of the withdrawal rates for the USS taken from the 2014 actuarial valuation report, which are 270% of the LG59/60 table for males and 113% of the LG59/60 table for females, is shown in Table 5.

On the death of an active member, a lump sum payment of three times the annual salary is paid at the time of death, along with a spouse’s pension of half the amount of pension the member would have received if he or she had survived until normal retirement. On the death of a deferred pensioner, a lump sum equal to the present value of the deferred lump sum payable at normal retirement is provided along with a spouse’s pension of half the amount of the deferred pension payable at normal retirement. On the death of a pensioner, a spouse’s pension of half the amount of the member’s pension is payable. All spousal pensions commence on the date of the scheme member’s death. A sample of the married proportion for the USS taken from the 2014 actuarial valuation report, which is 109% of the 2008 Office of National Statistics table for both males and female, is shown in Table 5.

4.2 Stylised US pension scheme

For our analysis, we use a hypothetical stylised US DB scheme with the same membership profile as for the UK scheme. In this section, we outline only those features, which are specific to the stylised US scheme. Other aspects of scheme membership, benefit provisions and assumptions are the same as that for the UK scheme, except monetary amounts, which are in US dollars. The other key differences in the analysis of this scheme are the economic scenario generator and mortality projections, which are specific to the US.

5.1 Base case

The top panel of Figure 2 shows the density of $V_0^{(\infty)}$ (as a percentage of $A_0$ ) for the UK scheme. The second and third panels show the sensitivity of this distribution to changes in the asset allocation and the contribution rate, which we discuss in detail in sections 5.2 and 5.3, respectively. Table 6 provides all the summary statistics.

Figure 2

Run-off results for the UK scheme using the graphical ESG. Top panel shows base case. Middle panel shows sensitivity to asset allocation strategy with higher bond allocation. Bottom panel shows sensitivity to changing contribution rates.

Table 6.

Summary statistics of the results for the UK scheme using the graphical ESG

In this section, we first focus on the base case run-off result shown in the top panel of Figure 2 and the corresponding summary statistics in Table 6. We observe:

1. 1. The distribution has a long left skew, indicating the possibility of a significant deficit, albeit with a diminishing probability.

2. 2. The median of the distribution is 24% of $A_0$ , indicating that on average the scheme has more than sufficient assets to meet all its future obligations on a run-off basis.

3. 3. The $10^{th}$ percentile of the distribution is $-36\%$ of $A_0$ , which implies that if the scheme had 36% additional assets, it would meet all its future obligations with a 90% probability. The probability of a shortfall is 27%.

4. 4. Going further into the left tail, we find that the scheme would require 148% additional assets to ensure a $99.5\%$ chance of meeting all its future obligations.

Figure 3

3-year time horizon results for the UK scheme using base case assumptions and the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the the run-off result, $V_0^{(\infty)}$ , is also shown, as a grey curve, for reference.

Continuing with the base case, but now focusing on a shorter 3-year time horizon, Figure 3 shows the density of $V_0^{(3)}$ based on a number of alternative approaches that might be taken to value the liabilitiesFootnote ⁴ , $L_3$ , at the end of year 3. In any specific valuation, the valuation actuary will use their judgement to select a particular discount rate based on the code of practice, current data (such as on bond yields and inflation expectations), and long-term expected returns. In our stochastic projections, it is necessary to select an appropriate discount rate at several points in the future, and for 10,000 different scenarios. As such, whatever approach is taken will need to be mechanistic in nature and, perhaps, somewhat arbitrary.

We outline four illustrative approaches to select the valuation discount rate assumption and present the results based on these assumptions. We utilise these approaches to be able to contrast and compare them, not necessarily that they would be implemented by a valuation actuary. In each panel of Figure 3, we also include the density of $V_0^{(\infty)}$ , as a grey curve, for reference.

1. 1. First, we assume a valuation discount rate based solely on the prevailing bond yield at the end of 3 years. In the top left panel of Figure 3, we show the density of $V_0^{(3)}$ (as a percentage of $A_0$ ), when $L_3$ is calculated using the prevailing (simulated) long-term bond yield at the end of 3 years plus a spreadFootnote ⁵ of $1.8\%$ . Clearly, this approach produces a very different distribution of $V_0^{(3)}$ , as compared to $V_0^{(\infty)}$ , with a large median loss and a large negative $10^{th}$ percentile.

   One characteristic that stands out is that the left tail of the distribution is much fatter than the one for the full run-off. The reason for the fatter left tail of $V_0^{(3)}$ , as compared to $V_0^{(\infty)}$ , is the use of a constant valuation discount rate to calculate $L_3$ . If the long-term bond yield in the third year is low, this low yield is assumed to continue as a constant, indefinitely into the future for calculating $L_3$ , which is unrealistic and is also unlikely to happen in the simulated realisations of the ESG, hence $V_0^{(\infty)}$ does not have such fat tails as $V_0^{(3)}$ in this case.

2. 2. Another approach to calculate $L_3$ could be to use the returns earned on the backing pension scheme assets, reflecting the actual asset allocation strategy. The top right panel of Figure 3 shows the result if the third year’s returns (weighted by asset allocation) are used as the discount rate for all future years. Now the distribution of $V_0^{(3)}$ has approximately the same median as $V_0^{(\infty)}$ , but has a very large dispersion (in both tails), as is expected, because any fluctuations in returns in the third year get magnified due to the use of a constant valuation discount rate to calculate $L_3$ .

3. 3. However, using returns earned only in the third year as a discount rate for all future years is also unrealistic. It would be more appropriate to use a time-varying (but deterministic) discount rate to calculate $L_3$ , where the discount rate increases (or decreases) from its value at the end of the third year to its long-term mean over a certain period of time. The bottom left and bottom right panels of Figure 3 show the result if the time period of convergence to the long-term mean is 50 years and 15 years, respectivelyFootnote ⁶ . If the convergence to the long-term mean is slow (50 years), the dispersion is still large, but smaller than before. If the convergence to long-term mean is quicker (15 years), the distributions of $V_0^{(3)}$ and $V_0^{(\infty)}$ get closer.

In Figure 4, we show the scatter plots, or joint densities, of $V_0^{(3)}$ and $V_0^{(\infty)}$ , in the form of heatmaps, for all four approaches. The heatmaps represent densities that integrate to 1, with the same colour representing the same quantile level and darker shades representing higher density values.

Figure 4

3-year time horizon results for the UK scheme using base case assumptions and the graphical ESG. Each panel shows joint density of $V_0^{(\infty)}$ and $V_0^{(3)}$ , as heatmaps, based on different discount rate approaches used in the valuation basis.

If the valuation actuary could foresee the future, the observations would all fall on the $45^{\circ}$ line. The scatter plots show how for 3-year time horizon results, using a constant long-term bond yield as the valuation discount rate almost always underestimates $V_0$ . This is a matter of concern because such underestimation of $V_0$ could lead to a misleading perception of insufficient funding levels for an otherwise healthy scheme on a run-off basis.

The estimates improve when the backing assets are used to obtain the valuation discount rate, and they improve further if the rate is adjusted over 15 years to converge to the long-run mean.

5.2 Sensitivity to higher bond allocation strategy

The middle panel of Figure 2 shows the density of $V_0^{(\infty)}$ (as a percentage of $A_0$ ), when the bond allocation of the UK pension scheme is increased from 30% to 70%. For ease of reference, the density of the base case result is also included as a grey curve in the background. We make the following observations:

1. 1. For increased bond investment, the distribution of $V_0^{(\infty)}$ has moved to the left and has greater dispersion.

2. 2. The leftward shift of the distribution indicates a greater probability of larger deficits. This is reflected in the median of $V_0^{(\infty)}$ , which becomes a deficit of 23% as compared to a surplus of 24% for the base case. The $10^{th}$ and $0.5^{th}$ percentiles have moved by even greater magnitudes (see Table 6).

3. 3. The sensitivity patterns can be explained by the fact that the expected returns from bonds are lower in the long term compared to equities. So, a higher allocation to bonds can lead to potentially lower levels of cumulative assets, which is reflected in the leftward shift and greater dispersion in the distribution.

4. 4. Moreover, fixed interest bonds are a poor match for real liabilities (the UK scheme benefits are inflation-protected). Hence, an increased allocation to nominal bonds has exacerbated the risk, producing a fatter-tailed distribution.

   Alternatively, an allocation to real return bonds, such as Index-Linked Gilts (ILGs), could provide some risk reduction benefits for this scheme’s real liabilities, at a cost of a leftward shift in the risk distribution. As our ESG does not support ILGs, we do not consider ILGs further in this report.Footnote ⁷

Figure 5 shows the sensitivity of the results to a higher bond allocation strategy based on a 3-year time horizon. The most important observation here is that as the bond allocation of the scheme increases, a valuation basis based on bonds will produce results where the distributions of $V_0^{(3)}$ starts getting closer to that of $V_0^{(\infty)}$ , as expected.

Figure 5

3-year time horizon results showing sensitivity to higher bond allocation strategy for the UK scheme using the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the run-off result, $V_0^{(\infty)}$ , is also shown, as a grey curve, for reference.

We summarise the main takeaways from the analysis so far as follows:

1. • It is natural for both pension regulators and scheme members to expect periodic assessments of the financial status of a pension scheme. For a triennial valuation, where the valuation discount rate is based only on long-term bond yields (plus an arbitrary fixed spread to allow for excess equity returns), the UK scheme appears severely underfunded. Looking at the base case results for $V_0^{(3)}$ given in Table 6, the scheme appears to have a staggering 92% chance of insufficient assets at the end of 3 years, with an average deficit of 94% of the current value of assets.

2. • However, on a run-off approach, the chance of a shortfall is only 27%, and there is an average surplus of 24% of current assets. Note that the huge apparent deficit over a 3-year horizon is an artefact of using a valuation basis that is not consistent with the actual underlying asset allocation strategy. The true financial status is actually unaffected by how the valuation actuary is required to value future liabilities.

3. • Now, if in response to a requirement to use long-term bond yield for liability valuation, the UK scheme tries to address the mismatch by changing its actual asset allocation strategy to involve greater bond investment, it is materially detrimental to the pension scheme over the long term. Note that the distribution of $V_0^{(3)}$ is broadly unaltered by the change in asset allocation as the valuation discount rate is unaffected by the change. However, as shown in Table 6, increasing the bond allocation from 30% to 70% now creates a true deficit for the scheme on a run-off basis. By increasing the bond allocation, the scheme has gone from 24% excess assets to 23% underfunded, on average. Moreover, now the chance of assets not being able to meet all future liabilities has increased from 27% to 68%.

4. • The impact of a 3-year assessment is somewhat less severe if the valuation discount rate is based on the returns on backing assets converging to the long-term returns over an appropriate duration.

5.3 Sensitivity to contribution rates

The bottom panel of Figure 2 shows the distribution of $V_0^{(\infty)}$ (as a percentage of $A_0$ ) when the contribution rate is increased or decreased by $7.5\%$ of salary; and also if there were no future contributions. For ease of reference, the density of the base case result with a contribution rate of $22.5\%$ is also included as a grey curve in the background.

The main observation here is that increasing or decreasing contribution rates by $\pm 7.5\%$ has the effect of shifting the median of the distribution by $\pm 9\%$ (of $A_0$ ). The relative shifts in the left tail increase slightly as we move further into the tails of the distributions. However, the impacts are small compared to the impact of a higher bond allocation. In fact, the impact at the median of moving the bond allocation from 30% to 70% is more severe than eliminating all future contributions as shown in Figure 2.

Figure 6 shows the sensitivity of the results towards a higher or lower contribution rate when using a 3-year time horizon. First, the directions of the shifts in the distributions are as expected, but the magnitudes of the shifts are much smaller than for the run-off case. This is an artefact of the valuation methodology adopted, i.e. the projected unit method, to calculate $L_3$ , in which the actuarial liability is the discounted value of accrued benefits to date (i.e. ignoring future accruals based on future service and future contributions). Hence the liability calculations do not take into account future contributions. As a result, any contribution increase or decrease beyond year 3 has no impact on $L_3$ . So the shifts in the distributions in the 3-year time horizon results are solely due to the higher or lower contributions only over the time period [0,3].

Figure 6

3-year time horizon results showing sensitivity to higher and lower contribution rates for the UK scheme using the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the base case, $V_0^{(3)}$ , is also shown, as a grey curve, for reference.

The main conclusions that can be drawn from these results are as follows:

1. • The impact of changes in contribution rates is smaller compared to changes in asset allocation strategy. In particular, if a short time horizon is employed, the contribution rate change needs to be extremely large in order to have any meaningful impact on pension scheme risk.

2. • If instead of changing asset allocation strategy, a pension scheme wants to address any apparent deficit in $V_0^{(3)}$ using higher contribution rates, the scheme will have to raise the contribution rates by enormous amounts to have a material impact on the distribution of $V_0^{(3)}$ .

6.1 Base case

The top panel of Figure 7 shows the distribution, $V_0^{(\infty)}$ (as a percentage of $A_0$ ) for the stylised US scheme. The second and third panels show the sensitivity of this distribution to changes in the asset allocation and the contribution rate, which we discuss in detail in sections 6.2 and 6.3, respectively. Table 7 provides all the summary statistics.

Figure 7

Run-off results for the stylised US scheme using the graphical ESG. Top panel shows base case. Middle panel shows sensitivity to asset allocation strategy with higher bond allocation. Bottom panel shows sensitivity to changing contribution rates.

Table 7.

Summary of results for the stylised US scheme using the graphical ESG

Focusing on the base case run-off result shown in the top panel of Figure 7 and the corresponding summary statistics in Table 7, we first observe its similarity with the corresponding result for the UK scheme as can be seen in Figure 2 and Table 6. The medians of the two distributions are the same, the probability of shortfall and the $10^{th}$ percentile are also broadly similar. However, the $0.5^{th}$ percentile for the stylised US scheme is farther to the left than that for the UK scheme, indicating that the distribution for the stylised US scheme has a fatter left tail.

The similarities between the base case run-off results for the UK and the stylised US schemes are partly by design to ensure a certain level of comparability. Recall that the membership profiles of the two schemes are the same. Also, the starting asset value of the stylised US scheme is chosen specifically to produce the same median value of $V_0^{(\infty)}$ . Although the benefit structures of the two schemes are different, with the stylised US scheme being less generous with no inflation indexation of benefits, this is compensated by a lower contribution rate.

Figure 8

3-year time horizon results for the stylised US scheme using base case assumptions and the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the the run-off result, $V_0^{(\infty)}$ , is also shown, as a grey curve, for reference.

However, the fatter left tail of the distribution for the stylised US scheme is striking. This is the result of higher fixed guarantees involved in non-indexation of benefits. This feature plays a crucial role in the rest of the analysis for the stylised US scheme.

Continuing with the base case, but now focusing on a shorter 3-year time horizon, Figure 8 shows the same alternative approaches as for the UK scheme that a valuation actuary might take to value the liabilities, $L_3$ , at the end of year 3.

1. 1. First, we look at valuation discount rate based solely on the prevalent bond yield at the end of 3 years. Unlike for the UK scheme, where we added a spread to the long-term bond yield for consistency with the USS 2014 valuation, for the US scheme we do not introduce this complexity of adding a fixed spread.

   In the top left panel of Figure 8, we show $V_0^{(3)}$ (as a percentage of $A_0$ ), when $L_3$ is calculated using the prevalent long-term bond yield at the end of 3 years. Clearly, this approach produces a very different distribution of $V_0^{(3)}$ , as compared to $V_0^{(\infty)}$ , with a large median loss and a large negative $10^{th}$ percentile.

   However, it is instructive to observe that the difference between the distributions of $V_0^{(3)}$ and $V_0^{(\infty)}$ for the stylised US scheme is not as drastic as that for the UK scheme. This is due to the fact that for the UK scheme, fixed interest bonds are a poor match for real liabilities. However, for the stylised US scheme with non-indexed benefits, liabilities calculated using long-term bond yield are still poor, but less so.

2. 2. The top right panel of Figure 8 shows the result if the third year’s returns (weighted by asset allocation) are used as the discount rate for all future years. The bottom left and bottom right panels of Figure 8 show the result if the time period of convergence to long-term mean is 50 years and 15 years, respectively. Commentary on these panels is the same as for the UK scheme.

Similar to the UK scheme results, we show the scatter plots, or joint densities, of $V_0^{(3)}$ and $V_0^{(\infty)}$ for the stylised US scheme in Figure 9. Although using a constant long-term bond yield as the valuation discount rate underestimates $V_0$ , it is less prominent for the stylised US scheme than that for the UK scheme. However, the estimates do improve when returns based on backing assets, in conjunction with convergence to the long-run mean, are used to obtain the valuation discount rate.

Figure 9

3-year time horizon results for the stylised US scheme using base case assumptions and the graphical ESG. Each panel shows joint density of $V_0^{(\infty)}$ and $V_0^{(3)}$ , as heatmaps, based on different discount rate approaches used in the valuation basis.

6.2 Sensitivity to higher bond allocation strategy

The middle panel of Figure 7 shows the distribution of $V_0^{(\infty)}$ (as a percentage of $A_0$ ), when the bond allocation of the stylised US scheme is increased from 30% to 70%. For ease of reference, the density of the base case result is also included as a grey curve in the background. We make the following observations:

1. 1. Similar to the UK scheme with increased bond investment, the distribution of $V_0^{(\infty)}$ has moved to the left and has greater dispersion.

2. 2. The leftward shift of the distribution indicates a greater probability of larger deficits. This is reflected in the median of $V_0^{(\infty)}$ , which shows a deficit of 3% as compared to a surplus of 24% for the base case results.

3. 3. The leftward shift can be explained by the fact that the expected returns from bonds are lower in the long term compared to equities, leading to potentially larger losses.

4. 4. However, the leftward shift of the distribution for the stylised US scheme is less severe than that for the UK scheme. As the UK scheme benefits are fully inflation-protected, high fixed interest investment is far more detrimental for the UK scheme.

Figure 10 shows the sensitivity of the results to a higher bond allocation strategy when using a 3-year time horizon. The most important observation here is that as the bond allocation of the scheme increases, a valuation basis based on bonds will produce results where the distributions of $V_0^{(3)}$ starts getting closer to that of $V_0^{(\infty)}$ , as expected.

Figure 10

3-year time horizon results showing sensitivity to higher bond allocation strategy for the stylised US scheme using the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the run-off result, $V_0^{(\infty)}$ , is also shown, as a grey curve, for reference.

As for the UK scheme, we provide a summary of the main takeaways from the analysis so far for the stylised US scheme:

1. • If we consider a triennial valuation, where the valuation discount rate is based only on long-term bond yields, the scheme appears severely underfunded. Looking at the results for $V_0^{(3)}$ given in Table 7, under the base case assumption, the scheme appears to have a 62% chance of insufficient assets at the end of 3 years, with an apparent median deficit of 17%. On the other hand, using the run-off basis, the chance of a deficit is only 28%, and the scheme has a true average surplus of 24% of current assets.

2. • As with the UK scheme, the apparent deficit is an artefact of using a valuation basis that is not consistent with the actual underlying asset allocation strategy. The true financial status is actually unaffected by how the valuation actuary is required to value future liabilities.

3. • However, if this valuation method is a prescribed requirement, the stylised US scheme might be obliged to address this mismatch by changing its asset allocation strategy to involve greater bond investment. This course of action is actually materially detrimental to the long-term financial health of the pension scheme.

4. • As shown in Table 7, increasing the bond allocation from 30% to 70%, now creates a true deficit for the scheme, even on a run-off basis. By increasing its bond allocation, the fund has gone from 24% excess assets to 3% underfunded. Moreover, now the chance of assets not being able to meet all future liabilities has increased from 28% to 53%.

5. • We also note that the severity of the impact of the change in the asset allocation strategy is less severe for the stylised US scheme than that for the UK scheme.

6.3 Sensitivity to contribution rates

The bottom panel of Figure 7 shows the distribution of $V_0^{(\infty)}$ (as a percentage of $A_0$ ), when the contribution rate is increased or decreased by $3.5\%$ ; and also if there were no future contributions. For ease of reference, the density of the base case result with contribution rate of $6.5\%$ is also included as a grey curve in the background.

Consistent with the results for the UK scheme, the main observation is that increasing or decreasing contribution rates by $\pm 3.5\%$ has the effect of shifting the median of the distribution by roughly $\pm 6\%$ (of $A_0$ ). The relative shifts in the left tail increase slightly as we move further into the tails of the distributions. However the impacts are small compared to the impact of a higher bond allocation. In fact, the impact at the median of moving the bond allocation from 30% to 70% has over twice the impact of eliminating all future contributions.

Figure 11 shows the sensitivity of the results towards a higher or lower contribution rate when using a 3-year time horizon. As with the UK scheme, the direction of the shifts in the distributions are as expected, and the magnitudes of the shifts are much smaller than for the run-off case.

Figure 11

3-year time horizon results showing sensitivity to higher and lower contribution rates for the stylised US scheme using the graphical ESG. Each panel shows the density of $V_0^{(3)}$ based on different discount rate approaches used in the valuation basis. In each panel, the density for the base case, $V_0^{(3)}$ , is also shown, as a grey curve, for reference.

As for the UK scheme, the main conclusion here is that the impact of changes in contribution rates is smaller compared to changes in asset allocation strategy. In particular, if a short time horizon is employed, the contribution rate change needs to be extremely large in order to have any meaningful impact on pension scheme risk. If instead of changing asset allocation strategy, a pension scheme wants to address any apparent deficit in $V_0^{(3)}$ using higher contribution rates, the scheme will have to raise the contribution rates by enormous amounts to have a material impact on the distribution of $V_0^{(3)}$ .

We have attempted to account for significant and meaningful differences between the US scheme and UK scheme, including the benefit structure, ESG and mortality rates, thereby assessing a more representative range of DB pension schemes in general. Despite these differences and the resulting variation in the surplus distributions, our two main observations are valid for both schemes.