2.1. Market Revenue

Market revenue $\tilde{r}$ from cotton farming equals stochastic price $\tilde{p}$ times stochastic yield $\tilde{y}$: $\tilde{r} = \tilde{p}\tilde{y}$, where $\tilde{p} = p + {\tilde{\epsilon }^p}$, p is the mean price, ${\tilde{\epsilon }^p}$ is the random error term for price that is centered on zero, the production technology is $\tilde{y} = \alpha + \beta {x^\gamma } + \tilde{\epsilon }$, α is the yield from planting operations alone, β is the productivity scale parameter, x is the composite input,Footnote ⁸ γ is the income share parameter for the composite inputs, and $\tilde{\epsilon }$ is the random error term for farm-level yield that is centered on zero. The total cost of production is tc = wx + f, where wx is the variable cost, w is the priceϵ of the composite input, and f is the fixed cost. Profits are market revenues minus total cost:

(1) $$\begin{equation} \pi = \tilde{r} - tc = \tilde{p}\left({\alpha + \beta {x^\gamma } + \tilde{\epsilon }} \right) - wx - f. \end{equation}$$

2.2. Deep-Loss Crop Insurance Policies

Deep-loss crop insurance polices include YP and RP. YP crop insurance provides protection only against yield risk. YP indemnity payments (ypi) are

(2) $$\begin{equation} ypi = {p^F}\max \left[ {0,\eta {y^A} - \tilde{y}} \right]. \end{equation}$$

where η is the coverage level, y^A is the APH yield level, and p^F is the projected price.Footnote ⁹ The cotton farmer receives an indemnity payment when actual yield $({\tilde{y}} )$ falls below the yield guarantee (ηy^A). Indemnity payments equal the projected price times the difference between the yield guarantee and actual yield. To purchase YP insurance, farmers pay an actuarially fair premium rate ${\theta ^{YP}} = \int{y}pi{\mkern 1mu} {\mkern 1mu} d{G_{{\epsilon ^p},{\epsilon ^C}}}({\tilde{\epsilon }} )$, where ${G_{{\epsilon ^p},{\epsilon ^C}}}({\tilde{\epsilon }} )$ is the marginal cumulative density for farm-level yield randomness derived from the joint cumulative density function (CDF) $G({{{\tilde{\epsilon }}^p},\tilde{\epsilon },{{\tilde{\epsilon }}^C}} )$, which characterizes the price, farm-level yield risk, and county-level yield risk. With government subsidized premiums, net YP indemnity payments (YPp) are

(3) $$\begin{equation} Y\,Pp = ypi - \left({1 - {\sigma ^{YP}}\left(\eta \right)} \right){\theta ^{YP}}, \end{equation}$$

where government subsidies σ^YP(η) are inversely related to the coverage level. For YP, coverage levelsFootnote ¹⁰ are 55%, 60%, 65%, 70%, 75%, 80%, or 85%, with corresponding subsidy rates of 64%, 64%, 59%, 59%, 55%, 48%, or 38%.Footnote ¹¹ Given these YP coverage levels, the deductible ranges from 45% to 15%. Expected YP indemnity payments to the farmer are then calculated as

(4) $$\begin{equation} \int{Y}Pp{\mkern 1mu} {\mkern 1mu} d{G_{{\epsilon ^p},{\epsilon ^C}}}\left({\tilde{\epsilon }} \right) = {\sigma ^{YP}}\left(\eta \right){\theta ^{YP}}, \end{equation}$$

because expected indemnity payments are equal to the actuarially fair premium.

RP crop insurance covers both price and yield risk. RP indemnity payments are

(5) $$\begin{equation} rpi = \max \left[ {0,\max \left[ {\tilde{p},{p^F}} \right]\eta {y^A} - \tilde{p}\tilde{y}} \right]. \end{equation}$$

Therefore, the cotton farmer receives indemnity payments when actual market revenues $({\tilde{p}\tilde{y}} )$ fall below the revenue guarantee $({\max [ {\tilde{p},{p^F}} ]\eta {y^A}} )$. The indemnity payments equal the difference between the guarantee and market revenues. Farmers pay an actuarially fair premium (θ^RP) to buy the RP crop insurance: ${\theta ^{RP}} = \int \!\!\! \int rpi{\mkern 1mu} {\mkern 1mu} d{G_{{\varepsilon ^C}}}({{{\tilde{\epsilon }}^p},\tilde{\varepsilon }} )$, where G _ε^C is the marginal cumulative density. The government subsidizes the premium based on the coverage level. Then, net RP indemnity payments (RPp) to farmers are

(6) $$\begin{equation} RPp = rpi - \left({1 - {\sigma ^{RP}}\left(\eta \right)} \right){\theta ^{RP}}, \end{equation}$$

where government subsidy rates σ^RP(η) are also inversely related to the coverage level. Under the 2014 Farm Bill, farmers can select a coverage levels of 50%, 55%, 60%, 65%, 70%, 75%, 80%, or 85%, with corresponding subsidy rates of 67%, 64%, 64%, 59%, 59%, 55%, 48%, or 38%. Given these coverage levels, the deductible ranges from 50% to 15%. To mitigate moral hazard, deep-loss agricultural insurance polices such as RP incentivize the farmer to choose a larger deductible by offering higher ad valorem premium subsidies for lower coverage levels. Expected RP indemnity payments to the farmer are

(7) $$\begin{equation} \int \!\!\! \int RPp{\mkern 1mu} {\mkern 1mu} d{G_{{\varepsilon ^C}}}\left({{{\tilde{\epsilon }}^p},\tilde{\varepsilon }} \right) = {\sigma ^{RP}}\left(\eta \right){\theta ^{RP}}. \end{equation}$$

Both RP and YP are coupled policies because farmers can affect both the size and frequency of payments by influencing yield through input choices, resulting in moral hazard. As in all insurance markets where moral hazard occurs, crop insurance companies shift some risk to farmers by instituting a deductible by offering only incomplete coverage (η is less than 100%).

2.3. Shallow-Loss Crop Insurance Policies

The 2014 Farm Bill offers two new policies (STAX and SCO) to cotton farmers to potentiallyFootnote ¹² cover part of the deductible of the deep-loss policies. Payments under these two policies do not depend on farm-level random yield. Therefore, STAX and SCO are decoupled from a farmer's production decisions. Although farmers cannot affect the size or frequencies of payments by influencing yield (the coupling effect), these policies can still influence input uses through the well-known wealth and insurance effects (see Luckstead and Devadoss, Reference Luckstead and Devadoss2016; Moschini and Hennessy, Reference Moschini, Hennessy, Gardner and Rausser2001).

Farmers can enroll only in STAX or in combination with a deep-loss insurance policy. STAX indemnity payments (STAXi) are

(8) $$\begin{eqnarray} STAXi &=& \min \Big[ \max \Big\{ \zeta - \frac{{\tilde{p}{{\tilde{y}}^C}}}{{\max \left[ {\tilde{p},{p^F}} \right]\max \left[ {{y^C},{y^{CO}}} \right]}},0 \Big\}, \nonumber\\ && \left({\zeta - \max \left[ {\eta ,0.70} \right]} \right) \Big] \times \nonumber\\ && \phi \max \left[ {\tilde{p},{p^F}} \right]\max \left[ {{y^C},{y^{CO}}} \right], \end{eqnarray}$$

where ζ is the STAX coverage level which ranges from max[η, 0.70] to 0.90 in increments of 0.05; ${\tilde{y}^C} = {y^C} + {\tilde{\epsilon }^C}$ is the random county yield equal to the average county yield y^C plus the county random term ${\tilde{\epsilon }^C}$ centered on zero; y^CO is the 5-year olympic average county yield; and ϕ ∈ [0.8, 1.2] is the protection factor. A payment is triggered when actual county revenue $({\tilde{p}{{\tilde{y}}^C}} )$ falls below the benchmark county revenue $({\max [ {\tilde{p},{p^F}} ]\max [ {{y^C},{y^{CO}}} ]} )$ by more than the STAX coverage level ζ. However, the actual payment rate is the minimum of this shortfall or (ζ − max[η, 0.70]). Consequently, the lower bound of the payment rate depends on max[η, 0.70]. STAX indemnity payments equal the payment rate times the protection factor times the benchmark county revenue. To enroll in the STAX program, farmers pay the actuarially fair premium ${\theta ^{STAX}} = \int \!\!\! \int STAXi{\mkern 1mu} {\mkern 1mu} d{G_\epsilon }({{{\tilde{\epsilon }}^p},{{\tilde{\epsilon }}^C}} )$, where ${G_\epsilon }({{{\tilde{\epsilon }}^p},{{\tilde{\epsilon }}^C}} )$ is the marginal cumulative density. The government subsidizes the premium at a fixed rate of σ^STAX = 0.8. Net STAX indemnity payments (STAXp) are

(9) $$\begin{equation} STAXp = STAXi - \left({1 - {\sigma ^{STAX}}} \right){\theta ^{STAX}}. \end{equation}$$

Expected STAX indemnity payments are

(10) $$\begin{equation} \int \!\!\! \int STAXp{\mkern 1mu} {\mkern 1mu} d{G_\epsilon }\left({{{\tilde{\epsilon }}^p},{{\tilde{\epsilon }}^C}} \right) = {\sigma ^{STAX}}{\theta ^{STAX}}. \end{equation}$$

SCO is a shallow loss program in that it potentially covers part of the deductible portion of RP or YP policies. Furthermore, if the farmer selects RP, then SCO provides revenue protection on the RP deductible. On the other hand, if the farmer selects YP, then SCO provides yield protection on the YP deductible. Also, in contrast to STAX participation, the farmer must be enrolled in a deep-loss insurance policy to be eligible for the SCO policy. SCO indemnity payments (SCOi) are

(11) $$\begin{eqnarray} SCOi = \min \left[ {\max \left\{ {0.86 - \frac{{\tilde{p}{{\tilde{y}}^C}}}{{\max \left[ {\tilde{p},{p^F}} \right]{y^C}}},0} \right\},\left({0.86 - \eta } \right)} \right]\max \left[ {\tilde{p},{p^F}} \right]{y^A}. \nonumber\\ \end{eqnarray}$$

Farmers receive an indemnity payment if actual county revenue $({\tilde{p}{{\tilde{y}}^C}} )$ falls below the county-revenue guarantee $({{\rm max}\ [{\tilde{p},{p^F}} ]{y^C}} )$ by more than the coverage rate of 86%. The actual payment rate depends on the minimum of this shortfall or (0.86 − η), implying the lower bound of this rate depends on the deep-loss coverage rate η. The SCO indemnity payment is equal to the payment rate times the liability $({\max [ {\tilde{p},{p^F}} ]{y^A}} )$. As an example, if the farmer selects RP for their deep loss insurance with a coverage rate of η = 70%, then the farmer is left with a 30% deductible. As specified in the 2014 Farm Bill, SCO can potentially cover part of this deductible, leaving the farmer to incur a 14% deductible. In this example, if county revenue falls anywhere between 14% to 30% below the county-revenue guarantee, an SCO payment is triggered. However, if county revenue falls below 30% of the county-revenue guarantee, SCO payments are capped, but RP payments will be triggered if farm-level revenues fall below their revenue guarantee.

To enroll in the SCO program, farmers pay the actuarially fair premium ${\theta ^{SCO}} = \int \!\!\! \int SCOi{\mkern 1mu} {\mkern 1mu} d{G_\epsilon }({{{\tilde{\epsilon }}^p},{{\tilde{\epsilon }}^C}} )$. The government subsidizes the SCO premium at a fixed rate of σ^SCO = 0.65. Then, net SCO indemnity payments (SCOp) are

(12) $$\begin{equation} SCOp = SCOi - \left({1 - {\sigma ^{SCO}}} \right){\theta ^{SCO}}. \end{equation}$$

Expected SCO indemnity payments are

(13) $$\begin{equation} \int \!\!\! \int {\left[ {SCOp} \right]}d{G_\epsilon }\left({{{\tilde{\epsilon }}^p},{{\tilde{\epsilon }}^C}} \right) = {\sigma ^{SCO}}{\theta ^{SCO}}. \end{equation}$$

As shown by equations (8) and (11), SCO indemnity payments are similar in structure to STAX indemnity payments, but SCO is less flexible as the coverage rate is fixed at 86% (leaving farmers with a 14% deductible) and does not have the protection factor. Furthermore, the SCO liability is based on farmer's APH yield as opposed to county yields.

2.4. Optimization Problem

A risk-averse farmer maximizes the expected value of utility from farm profits by optimally choosing inputs x, individual crop insurance coverage rate η, STAX coverage rate ζ, and the protection factor ϕ:

(14) $$\begin{equation} \mathop {\max }\limits_{x,\eta ,\zeta ,\phi } \int \!\!\! \int \!\!\! \int U\left[ {\pi \left({\tilde{y},\tilde{p}} \right)} \right]dG\left({{{\tilde{\epsilon }}^p},\tilde{\epsilon },{{\tilde{\epsilon }}^C}} \right), \end{equation}$$

where profits come from one of the four following options: (a) market revenuesFootnote ¹³ minus total cost: $\pi = \tilde{r} - tc$; (b) market revenues minus total cost plus payments from deep loss (RP or YP) insurance: $\pi = \tilde{r} - tc + ({RPp{\mkern 1mu} {\mkern 1mu} {\rm{or}}{\mkern 1mu} {\mkern 1mu} YPp} )$; (c) market revenues minus total cost plus payments from deep loss (RP or YP) insurance and shallow loss: STAX $\pi = \tilde{r} - tc + ({RPp{\mkern 1mu} {\mkern 1mu} {\rm{or}}{\mkern 1mu} {\mkern 1mu} YPp + STAXp} )$; or (d) market revenues minus total cost plus payments from deep loss (RP or YP) insurance and shallow loss: SCO $\pi = \tilde{r} - tc + ({RPp{\mkern 1mu} {\mkern 1mu} {\rm{or}}{\mkern 1mu} {\mkern 1mu} YPp + SCOp} )$.

We consider the Expo-Power utility function for the analysis because it is highly flexible in characterizing the farmer's risk attitude. The Expo-Power utility function (Saha, Shumway, and Talpaz, Reference Saha, Shumway and Talpaz1994) is

(15) $$\begin{equation} U = 1 - {\rm{exp}}\left({ - \rho {\pi ^\psi }} \right), \end{equation}$$

where ρ < 0 (> 0) is decreasing (increasing) relative risk aversion coefficient, and ψ = 1 is constant, ψ < 1 is decreasing, and ψ > 1 is increasing absolute risk aversion coefficient. To compare the impact of policies on the farmer, we calculate the certainty equivalent

(16) $$\begin{equation} CE = {U^{ - 1}}\left({EU} \right) = {\left[ { - \frac{1}{\rho }{\rm{log}}\left({1 - EU} \right)} \right]^{\frac{1}{\psi }}}, \end{equation}$$

where EU is the expected utility given by equation (14). The certainty equivalent translates the expected utility into the dollar amount that a farmer would be willing to pay to eliminate all risk. A higher certainty equivalent corresponds to a higher expected utility level, implying that the farmer is better off.