Theoretic analysis of a resettable guarantee on an IPA

Assume each contract priced here is written for a principal guarantee on the accumulation of an IPA with a death benefit and a reset provision. The guarantee level, or the principal of an IPA, ascends by every contribution to the IPA during the life of the contract as a proportion of the corresponding salary. Moreover, the reset provision allows the holder to lock up the market gains of the IPA in the principal so as to increase the guarantee level. The guarantee has an ultimate maturity time conditional on the individual's age and cannot be extended even if the guarantee level is reset. Early termination can occur under a holder's death or if the holder lapses before the ultimate maturity. While the death benefit is provided, where the guarantee is paid off immediately upon death, there is no payoff from the guarantee if the holder lapses from the guarantee contract. To reduce moral hazard and basis risk for the contract provider, each contract requires the asset of the IPA to be connected with a specific traded portfolio or mutual fund.

The guarantee on an IPA is priced as a claim-terminating insurance contract. The effect of the death benefit on the payoff of the guarantee is similar to one of life insurance. The reset feature is treated as an option provision of a structured insurance. The approach from Shimko (Reference Shimko1992) helps construct the appropriate equivalent security to replicate the payoff of the guarantee.

While every contract is assumed to be written at time (t) 0, the ultimate maturity time, T, is a function of the individual age at time 0, y. The value of an individual guarantee V(C, K, y, t) is a function of the accumulation of an IPA, C(y,t), and the guarantee level, K(y,t). The C(y,t) is determined from the salary history as well as the rate of return on the portfolio connected to the IPA. Valuing C(y,t) is equivalent to valuing a security with negative dividends and whose capital value grows like a market index. The dividends are not proportional to the C(y,t) itself, but fixed proportional to the worker's salary level S(y,t). While the guarantee level, K(y,t), is set at the level of the current accumulation of the IPA, C(y,t), if the reset is executed, then it also automatically ascends by new contributions. We model the stochastic differential equations for C(y,t) and S(y,t) as:

(1) $$dC(y,t) = [\pi (C,t) \cdot C(y,t) + g \cdot S(y,t)] \cdot dt + {\sigma _C}(C,t) \cdot C(y,t) \cdot d{Z_C},$$

(2) $$dS(y,t)\, = \,w(S,t) \cdot S(y,t) \cdot dt + {\sigma _S}(S,t) \cdot S(y,t) \cdot d{Z_S},$$

where π(C,t) is the instantaneous expected rate of return on the connected portfolio, g is the fixed contribution rate as a proportion of the salary, σ _C (C,t) is the standard deviation of the rate of return, and W(S,t) and σ _S (S,t) are the salary's instantaneous average growth rate and its volatility, respectively. Terms dZ _C and dZ _S are the standardized Wiener increments.

The net cash flow of the guarantee is a terminating type and equals the guarantee payoff minus the value of the guarantee at the time of payment to surrender the contract. Since there is no payoff from the guarantee for the holder's lapse, the payoff of the guarantee for this case is zero. Therefore, the net cash flow conditional on the holder's lapse, CF _l , satisfies CF _l  = −V(C, K, y, t), where the holder gets nothing, but surrenders the value of the contract. In the other case, the 100% guarantee is paid off immediately upon death or ultimate maturity, where G(y, t) = max{[K(y, t) − C(y, t)], 0}, representing the payoff of the guarantee for this case. The net cash flow conditional on death or ultimate maturity, CF _d , therefore satisfies that CF _d  = G(y, t) − V(C, K, y, t), where the holder gets the 100% guarantee payoff and surrenders the value of the contract.

While the intensity rate for individual lapse from the guarantee contract, E _l (y, t), and the intensity rate for individual death or ultimate maturity, E _d (y, t), are assumed to be deterministic conditional functions of time, the terminating rate E(y, t) = E _d (y, t) + E _l (y, t) also is a deterministic conditional function of time. The value of an individual guarantee involves a minimum value constraint, V ^min = V(C, C, y, t), which is the value of the contract if the reset is executed and the guarantee level is reset at the level of the current accumulation of the IPA. The value of an individual guarantee also must satisfy the boundary condition of being worthless at ultimate maturity, V(C, K, y, T) = 0.

Subject to the boundary condition, the guarantee is equivalent to a risky security that has an ultimate maturity value equal to 0 and dividends equal to G(y,t) E _d (y,t) × Δt, and its value could jump to zero with an intensity of E(y,t) × Δt. One may substitute the intensity-adjusted interest rate, r + E(y, t), for the risk-free interest rate in order to automatically include the terminating payment in the price of this risky security. Merton (Reference Merton1976) and Shimko (Reference Shimko1989, Reference Shimko1992) found a similar conclusion about the pricing of the terminating payment. An up-front value of the guarantee on an IPA can then be solved by numerically pricing its equivalent security.

We consider the Cox et al. (Reference Cox, Ingersoll and Ross1985) single factor term structure model as an example for stochastic short-term risk-free interest rate r(t).Footnote ¹ Let H(t, τ) be the risk-neutral price at time t for a pure discount bond that pays off US$1 at maturity time t + τ and has a deterministic average intensity of $\bar E \cdot dt$ to jump instantaneously to zero before time t + τ. H(t, τ) has the form:Footnote ²

(3) $$H(t,\tau ) = P(t,\tau ) \cdot {\rm exp}\,( - \bar E \cdot \tau ),$$

Where P(t, τ) = A(t, τ) exp[−B(t, τ)·r(t)],

$$A(t,\tau )\, = \,{\left[ {\displaystyle{{2\gamma \cdot {\rm exp}\,[(\alpha + \gamma )\tau /2]} \over {(\alpha + \gamma )[\exp \,(\gamma \cdot \tau ) - 1] + 2\gamma}}} \right]^{2\alpha \cdot \beta /\sigma _r^2}}, $$

$$B(t,\tau )\, = \,\displaystyle{{2[{\rm exp}\,(\gamma \cdot \tau ) - 1]} \over {(\alpha + \gamma )[{\rm exp}\,(\gamma \cdot \tau ) - 1] + 2\gamma}}, $$

and $\gamma \, = \,\sqrt {{\alpha ^2} + 2\sigma _r^2} $ . Parameter β in equation (3) is the mean-reverting drift, α is the reversion rate, and σ _r is the volatility of changes in the interest rate. The claim-terminating type of payment is automatically priced in the intensity-adjusted bond pricing equation. Since the terminating rate of the guarantee on an IPA is assumed to be a deterministic function of time, then term $\bar E$ in equation (3), applied to a guarantee valuation, should be the average terminating rate between time t and time t + τ.

Modeling the deferred funding, one can assume that the deferred proportional costs are extracted from the accumulation of the IPA. The required deferred cost rate charged for the guarantee is then determined so that the net residual value of the guarantee is zero.

Numerical approach

The value of an equivalent security of the guarantee just described in the last section will be numerically estimated by Monte Carlo simulation in a risk-neutral world. In that, paths for all variables are simulated from their risk-neutral processes and each payoff of the equivalent securities is discounted by multiplying the risk-neutral price of a risky zero-coupon-bond as shown in equation (3).

The risk-neutral stochastic difference equation for salary level (S), the accumulation of an IPA (C), and short-term risk-free interest rate (r) are set by equation (4), (5), and (6), respectively:

(4) $${S_{t + \Delta t}} = {S_t} + (w - {\lambda _S} \cdot {\sigma _S}) \cdot {S_t} \cdot \Delta t + {\rm} {\sigma _S} \cdot {S_t} \cdot \sqrt {\Delta t} \cdot {Z_S},{\rm} $$

(5) $${C_{t + \Delta t}} = {C_t} + ({r_t} \cdot {C_t} + g \cdot {S_t}) \cdot \Delta t + {\rm} {\sigma _C} \cdot {C_t} \cdot \sqrt {\Delta t} \cdot {Z_C},{\rm} $$

(6) $${\rm} {r_{t + \Delta t}}\, = \,{r_t}\, + \,\alpha \cdot (\beta - {r_t}) \cdot \Delta t + {\sigma _r} \cdot \sqrt {{r_t} \cdot \Delta t} \cdot {Z_r}{\rm,} $$

where the terms Z _S , Z_C , and Z _r are stochastic variables of a standardized trivariate normal distribution. Generating the samples Z _S , Z_C , and Z _r requires that independent samples x ₁, x ₂, and x ₃ from a univariate standardized normal distribution are obtained first. The samples Z _S , Z_C , and Z _r are then calculated one after another as follows:

$${Z_S}\, = \,{x_1}{\rm,} {Z_C}\, = \,{\rho _{SC}} \cdot {x_1} + \sqrt {1 - \rho _{SC}^{\rm 2}} \cdot {x_2}{\rm,} {\quad}{Z_r}\, = \,{\rho _{Cr}} \cdot {Z_C} + \sqrt {1 - \rho _{Cr}^{\rm 2}} \cdot {x_3},$$

where ρ _SC is the correlation between Z _S and Z _C , and ρ _Cr is the one between Z _C and Z _r . This scheme was suggested by Hull (Reference Hull1997) to avoid an impossible correlation structure where the Cholesky decomposition of the correlation matrix for Z _S , Z_C , and Z _r does not exhibit real solutions. The feasible correlations between Z _S , Z_C , and Z _r in this scheme are required to satisfy ρ _Sr  = ρ _SC ρ_Cr , where ρ _Sr is the correlation between Z _S and Z _r .

Equation (4) indicates that the unconditional distribution of salary is lognormal. Following Chen (Reference Chen2006), this description of salary allows the possibility for negative wage growth and is based on the fact that negative wage growth could happen during an economic slump. In equation (4), the term w − λ _S σ_S is the risk-adjusted expected growth rate of salary, whereby λ _S and σ _S are respectively the market price of salary risk and the volatility of salary.

Equation (5) presents that the risk-neutral expected rate of return on the IPA is assumed to be the short-term risk-free interest rate, r _t . This assumption is based on a result for the equilibrium pricing theory, as the asset of the IPA is connected with a specific traded portfolio. In equation (5), the term g is the fixed contribution rate as a proportion of salary and σ _C is the volatility of the accumulation of an IPA.

Equation (6) indicates that the risk-neutral short-term risk-free interest rate is generated using the Euler scheme to discrete-time approximate the stochastic interest rate modeled in Cox et al. (Reference Cox, Ingersoll and Ross1985).Footnote ³ In that, β is the mean-reverting drift, α is the reversion rate, and ${\sigma _r}\sqrt {{r_t}} $ is the volatility of the interest rate. One problem with this scheme is that the discrete process for the interest rate could become negative with non-zero probability, which makes the computation of $\sqrt {{r_t}} $ impossible, if the size of the time step is not enough small. To handle this problem and to consider both simplicity and efficiency simultaneously, Lord et al. (Reference Lord, Koekkoek and van Dijk2010) proposed a Full Truncation fix as in equation (7):

(7) $${r_{t + \Delta t}}\, = \,{r_t} + \alpha \cdot (\beta - {r_t}^ + ) \cdot \Delta t + {\sigma _r} \cdot \sqrt {{r_t}^ + \cdot \Delta t} \cdot {Z_r}{\rm,} $$

where r _t ⁺ = max(r _t , 0). This scheme allows the process for the interest rate to go below zero while avoiding making the computation of $\sqrt {{r_t}} $ impossible. A full truncation fix to prevent the interest rate from going to become negative involves taking the maximum of the value generated from equation (6) and zero as equation (8):

(8) $${\rm} {r_{t + \Delta t}}\, = \,\max \{ [{r_t} + \alpha \cdot (\beta - {r_t}) \cdot \Delta t + {\sigma _r} \cdot \sqrt {{r_t} \cdot \Delta t} \cdot {Z_r}{\rm ], 0\}} {\rm.} $$

The fix schemes of equations (7) and (8) are not to be used before a known failure of the time stepping from the original Euler scheme as in equation (6).Footnote ⁴

When modeling the deferred funding, the risk-neutral stochastic difference equation for the accumulation of an IPA, equation (5), is reset by equation (9):

(9) $${{\rm C}_{t + \Delta t}}\, = \,{C_t} + {\rm [}{r_t} \cdot {C_t} + {\rm (}g - p{\rm )} \cdot {S_t}] \cdot \Delta t + {\rm} {\sigma _C} \cdot {C_t} \cdot \sqrt {\Delta t} \cdot {Z_C},{\rm} $$

where p is the deferred proportional cost on salary. In order to maintain the central theme as being salary-related throughout this paper, we only model the cost proportional to salary and leave the alternative of the cost proportional to the value of the IPA aside here.Footnote ⁵

Regarding the expected terminating rate, we suppose that the guarantee should ultimately mature when the individual reaches 60 years old and assume two types, 5% and no lapse, for the deterministic annual lapse intensity. Table 1 shows the female mortality rates on an annual basis based on the fourth and third experience mortality tables provided by the Life Insurance Association of R.O.C.,Footnote ⁶ which are used respectively as the low and high types of expected intensity of individual death (EIID). The ratio of the EIID of the low type to the high type is about 50%–60%. For monthly calculations, the early terminations are assumed to be uniformly distributed over the year of age. The two-type lapse and mortality purposes not only mitigate the question from the arbitrary choice of the rate, but also mainly help analyze the sensitivity of the guarantee value to early terminating intensity.

Table 1. The EIID

Note: These are the female mortality rates on an annual basis based on the fourth and third experience mortality tables provided by the Life Insurance Association of R.O.C. The former is used as the low type of EIID and the latter is used as the high type of EIID.

We assume the reset provision is ignored or used optimally at any time a new contribution is made. If resets are ignored, then the guarantee level at time t + ∆t, K _t+∆t , satisfies K _t+∆t  = K _t  + g × St × ∆t. If the resets are used optimally, then K _t+∆t  = max{C _t ,K_t } + g × S _t  × ∆t. The value of a reset feature is observed from the difference in results between the two types of reset.Footnote ⁷