2. Markets for Standing Timber Insurance Worldwide

Standing timber insurance markets exist in a few countries such as Denmark, France, Germany, Japan, Portugal, New Zealand, and Sweden. Worldwide, only approximately 0.5% of commercial forestland is insured (Cottle, Reference Cottle2007; Food and Agricultural Organization of the United Nations, 2001). According to the United Nations Environment Programme Finance Initiative (UNEP FI) Climate Change Working Group and Insurance Working Group (2008), most standing timber insurance markets exist only where there are mature insurance markets. In some such countries, standing timber insurance is common. In Scandinavia, standing timber has been insured against fire and wind losses on a national scale by mutual insurance,Footnote ⁴ with high insured values and relatively low volatility of loss (Cottle, Reference Cottle2007). In Denmark and Sweden, standing timber insurance is widespread where 68% and 90% of NIPF landowners, respectively, have insurance against fire and wind damage (e.g., Angstr < tex − math/> m, Reference Angström and van Nao1982; Brunette and Couture, Reference Brunette and Couture2008). In most other European countries, however, standing timber insurance is not common even in countries where such insurance products exist. In Germany and France, for example, only 2% and 5% of the private forest owners, respectively, are insured against windstorm losses (Brunette and Couture, Reference Brunette and Couture2008; UNEP FI Climate Change Working Group and Insurance Working Group, 2008). In the Southeast Asian market, except for Japan, standing timber insurance is in its infancy, most of which is sold to oil palm companies that recognize their cash flows depend on their oil palm plantations. In Japan, where natural disasters related to tsunamis and typhoons happen frequently, the standing timber insurance market is relatively mature. A three-part standing timber insurance system consisting of a government-run standing timber insurance component, a private standing timber insurance component, and mutual relief funds for forest damage exists as countermeasures against future risks (Matsushita et al., Reference Matsushita, Yoshida, Imanaga and Ishii1995). The total insurance premium paid in Japan was approximately 2,742 million yen (US$30 million) in 2006, with an insured value of approximately 475,648 million yen (US$5.074 billion) and 386,978 hectares (Statistics Bureau, Ministry of Internal Affairs and Communications, 2008).

In the United States, early efforts to provide standing timber insurance never received serious consideration from either the forestry profession or insurance underwriters (Averill and Frost, Reference Averill and Frost1933). The Phoenix Assurance Company, established in 1912, was the earliest insurance company to solicit standing timber insurance. Yet this first venture lasted only 2 years and was not successful. The current standing timber insurance market is characterized by a lack of demand, limited supply, and little competition. So far as we know, only two insurance companies in the U.S. South are providing such insurance products, and their customers account for only a very small percentage of NIPF landowners. The likely reasons for the lack of a substantial standing timber insurance market are complicated, involving both supply-side and demand-side issues. On the supply side, high exposure to catastrophic losses and accumulation of risk, inadequate forest loss data to set proper pricing levels, insufficient risk management practices, and lack of loss assessment techniques and experts may restrict private insurance firms’ ability and willingness to provide standing timber insurance widely. On the demand side, although increased catastrophe risk poses difficult challenges for property owners looking for efficient ways to mitigate their exposure to risks, reasons for the lack of a standing timber insurance market are unclear. Anecdotal reasons cited by landowners include high premiums, cash flow problems over the rotation, tradition, and unfamiliarity with payment mechanisms.

3. Standing Timber Insurance Literature

Historically, the literature on standing timber insurance focused on forest fire insurance and supply-side issues. Brown (Reference Brown1926) as well as Kaul (Reference Kaul1928) reviewed the history of forest fire insurance in America in the early 1900s. Kaul discussed advantages of forest fire insurance for both the insurer and insured, whereas Brown examined lessons behind early development of standing timber insurance. Both pointed out that the high rates offered by small companies, such as Globe and Rutgers Fire Insurance Company and Timber Lands Mutual Fire Insurance Company of Portsmouth, were not attractive to large timberland owners. Brown (Reference Brown1928) primarily discussed forest fire actuary from the perspective of insurance companies. Shepard (Reference Shepard1939) further discussed factors affecting successful implementation of forest fire insurance in the Pacific Coast region. He noted that hazard factors pertaining to standing timber insurance fall into two distinct categories, causative hazardsFootnote ⁵ and contributive hazards,Footnote ⁶ and the misunderstanding that the introduction of insurance would decrease protection programs results from not considering the difference between the two hazard factors. Considering both demand and supply, William (Reference William1949) pointed out the underwriting problems and that the effective demand for forest fire insurance across the United States was unknown or minimal. He suggested that high rates, absence of sales promotions, and the undeveloped state of forest enterprises were the most important factors responsible for the lack of demand for forest fire insurance. Moreover, the conditions under which standing timber can be insured at reasonable cost were first noted by Wright (Reference Wright1950) and Shepard (Reference Shepard1950). They agreed that forest fire insurance could be organized on a mutual basis and discussed values that should be taken into account when considering insurance of standing timber. There is sparse literature on this topic after the 1950s in the United States. The standing timber insurance market was almost nonexistent during this period.

More recently, Manley and Watt (Reference Manley and Watt2009) provided an excellent overview of timber insurance issues and current practices and conditions in New Zealand. Pinheiro and de Almeida Ribeiro (Reference Pinheiro and de Almeida Ribeiro2013) developed models to calculate reasonable insurance premiums for Portugal in light of the dearth of insurance companies willing to provide timber insurance. Recently, some experimental studies on standing timber insurance using small samples of landowners were conducted in Europe (i.e., Brunette, Couture, and Garcia, Reference Brunette, Couture and Garcia2014; Brunette et al., Reference Brunette, Cabantous, Couture and Stenger2013; Stenger, Reference Stenger2008). Stenger (Reference Stenger2008) conducted experimental studies to analyze landowner attitudes toward risks and ambiguity under three scenarios: buying insurance, self-insurance, and self-protection.Footnote ⁷ Brunette and Couture (Reference Brunette and Couture2008) proposed a theoretical model to investigate the influence of public compensation on purchasing standing timber insurance contracts. They concluded that direct public financial assistance programs discourage landowners from purchasing standing timber insurance, whereas public financial assistance programs that are contingent on protection activities make standing timber insurance practices more attractive to forest owners, thereby expanding the pool of potential customers and improving the market viability of timber insurance products. Brunette et al. (Reference Brunette, Cabantous, Couture and Stenger2013) conducted a series of experimental designs that tested theoretical predictions about the impact of public compensation schemes and ambiguity on insurance demand for disaster-type risks. Meanwhile, a small body of literature related to the insurance of carbon credits, which can be considered a derivative of standing timber insurance, emerged (Figueiredo, Reiner, and Herzog, Reference Figueiredo, Reiner and Herzog2005; Subak, Reference Subak2003). The insurability of carbon credits from the insurer's perspective was summarized by Wong-Leung and Dutchke (Reference Wong-Leung and Dutchke2003) (e.g., risk pooling, limited maximum possible losses, accepted insurance premium, etc.), and they also expressed concerns about the profitability and inequity (technical difficulties, adverse selection, and reinsurance) of such an insurance product. Insurance of carbon credits was also demonstrated to encourage greater forestland investment in lands subject to hurricanes (Grover, Bosch, and Prisley, Reference Grover, Bosch and Prisley2005). Brunette, Couture, and Garcia (Reference Brunette, Couture and Garcia2014) explored determinants of WTP for insurance against forest fire risk in France. Public assistance, uncertainty about natural disaster–related risks, level of expected loss, and landowner characteristics all impacted WTP. Brunette et al. (Reference Brunette, Holecy, Sedliak, Tucek and Hanewinkel2015) developed an actuarial insurance model for multiple natural hazards and applied it to silver fir stands in Slovakia. Gross insurance premiums varied as a function of stand age and size.

However, few studies have examined empirically the demand for standing timber insurance in the United States. Gan, Jarrett, and Gaither (Reference Gan, Jarrett and Gaither2014) identified factors that influence forestland owners to purchase forest fire insurance in the southern United States, but they did not consider price effects. Before further exploration of the nuances of potential timber insurance vehicles, it is essential to ascertain that the current absence of a viable standing timber insurance market is not because of landowner resistance on grounds other than price.

4. The Correlation between Standing Timber Insurance and Agricultural Insurance

Standing timber insurance is similar to agricultural insurance in at least three dimensions: systemic risk, catastrophic risk, and adverse selection. Similar to agricultural crops, systemic risk to standing timber stems primarily from the impact of geographically extensive unfavorable events, such as wildfires, pest outbreaks, and storms, which induce significant correlation among individual landowner-level losses. Because the insured individual units are not stochastically independent, the pooled risks across landowners are not sufficiently diversified, and insurers may bear substantially higher indemnity compared with other property insurance. Like drought in crops, catastrophe risks to timber arise from events with low probability of occurrence but major and irreversible loss, such as wildfire, which can result in heavy losses for landowners. Insurers facing catastrophe risks have the intertemporal problem of matching a smooth flow of annual premium receipts to a highly variable flow of annual loss payments. Generally, insurers are not willing to cover catastrophe risks without sufficient capital markets, reinsurance markets, or government intervention to share such risks. Adverse selection arises when risks vary across the insured and the insured have asymmetric information about the risks they face. Adverse selection exists in agricultural insurance in particular because of the use of aggregate measures (mostly county levels) to estimate individual yields and rates (Coble and Knight, Reference Coble, Knight, Just and Pope2002). Similarly, forest landowners who expected potentially large losses on their standing timber would be more likely to purchase insurance against risks. Adverse selection can distort premium ratings, and mitigating it requires expanded participation to pool risks or more accurate data to classify risks. Despite the features common to both agricultural insurance and standing timber insurance, there are distinct differences between them. Timber is a long-term asset and, in that regard, is very different from annual agricultural crops. For landowners, standing timber insurance may be conceptually more similar to insurance for other real assets such as homeowners insurance than to agricultural insurance. There are other differences as well. Catastrophe risks, for example, may cause a farmer severe cash flow problems and possibly bankruptcy. In contrast, standing timber is rarely a key component of landowners’ annual income; thus, landowners are less likely to suffer cash flow problems from timber losses. Also, for many forest landowners, the incentive to own forestland is not profit motivated (e.g., recreation, bequest, and nonmarket values) (U.S. Department of Agriculture, Forest Service, Forest Inventory and Analysis, 2015). These incentive differences would result in different landowner willingness to adopt risk management strategies among agricultural and timber producers. Moreover, relatively stable prices and crop supplies are important for a stable national economy. To reduce income volatility facing farmers and to avoid crop insurance market failures, adequate government subsidies and reinsurance are provided as a result of the passage of the Federal Crop Insurance Improvement Act of 1980 and the Crop Insurance Reform Act of 1994. Premiums are subsidized, and private insurers are reimbursed for administrative costs and for parts of underwriting losses. Government subsidies decrease prohibitively expensive premiums. New reinsurance agreements between private companies and the government have resulted in companies underwriting widespread crop loss risks. Timber, on the other hand, has a much less direct influence on the stability of the national economy and so has not generated the same support for government subsidies and controls as agriculture. Timber, however, still has substantial impacts on local economies and individual landowners. Because in the event of catastrophic events the aggregate losses to timber insurers could be quite large, it is critically important to understand landowner willingness to purchase standing timber insurance in order to develop insurance products that are attractive to landowners and viable to insurance providers, particularly in light of the absence of government support or subsidies.

With government providing subsidies and significantly sharing in the underwriting risks, agricultural insurance has participation rates greater than 80% and has enrolled more than 200 million acres (Davidson, 2004). Overall, the agricultural insurance program in the United States over the past 30 years has gained the reputation of being “financially sound on a national scale, properly rated and effectively managed” (Glickman, Reference Glickman2000). Growth of agricultural insurance programs in recent decades has provided researchers with a vast database. Thus, researchers can analyze existing rather than hypothetical agricultural insurance (e.g., Coble and Knight, Reference Coble, Knight, Just and Pope2002; Coble et al., Reference Coble, Knight, Pope and Williams1996; Glauber, Reference Glauber2004; Goodwin, Reference Goodwin1993; Serra, Goodwin, and Featherstone, Reference Serra, Goodwin and Featherstone2003; Smith and Baquet, Reference Smith and Baquet1996) to evaluate those insurance programs and improve rating and risk classification methodologies. However, for standing timber insurance, both products and research are in the initial stages. Thus, it is necessary to resort to hypothetical insurance policies with relatively large sample sizes to analyze factors that influence purchase decisions of standing timber insurance in order to provide insight for the potential insurance policies.

5. Conceptual Model

To examine landowner WTP for standing timber insurance, consider landowners who face the risk of a natural disaster impacting their standing timber (e.g., tornado losses) with probability p and potential loss L. The expected utility function without standing timber insurance is shown in equation (1).

(1)$$\begin{equation} {E_0}\left( u \right) = pu\left( {y - L,m} \right) + \left( {1 - p} \right)u\left( {y,m} \right), \end{equation}$$

where u(.) is the utility function, y is income, and m is a vector of demographic characteristics and forest features. It is assumed that a landowner compares expected utility with and without standing timber insurance. With standing timber insurance, the expected utility function is shown in equation (2), in which all losses would be covered by insurance once the disaster happens:

(2)$$\begin{equation} {E_1}\left( u \right) = pu\left( {y - c + i,m} \right) + \left( {1 - p} \right)u\left( {y - c,m} \right), \end{equation}$$

where c is the cost of insurance, and i is indemnity. Following Hanemann (Reference Hanemann, Loomis and Kanninen1991), the compensating variation or maximum WTP for the insurance, represented as WTP, is as follows:

(3)$$\begin{eqnarray} pu\left( {y \,{-}\, {\rm{WTP}} \,{+}\, i,m} \right) \,{+}\, \left( {1 \,{-}\, p} \right)u\left( {y \,{-}\, {\rm{WTP}},m} \right) &=& pu\left( {y \,{-}\, L,m} \right)\nonumber\\ && \,{+}\, \left( {1 \,{-}\, p} \right)u\left( {y,m} \right). \end{eqnarray}$$

The expected utility with or without standing timber insurance should be equal, and the landowner would buy such an insurance product only if the WTP is greater than or equal to the cost of insurance. The value of standing timber insurance in the view of the landowner is equivalently stated in equation (4), which is the dual problem to equation (3):

(4)$$\begin{equation} {\rm{WTP}} = f\left( {p,y,m,L,{E_0}\left( u \right)} \right) - f\left( {p,y,m,L,i,{E_0}\left( u \right)} \right), \end{equation}$$

where f is the expenditure function. If E ₁(u) > E ₀(u), then WTP will be positive. That is, landowners who derive positive utility from the protection against loss of standing timber insurance will be willing to pay a premium. This WTP estimate can be compared with premium rates currently available.

Equation (4) provides the rationale for our empirical model. It is easy to see from equation (4) that WTP is driven by landowners’ utility function, the probability and magnitude of the potential loss, income, and other characteristics. We designed a survey that provided the necessary data to proxy these variables in our empirical model.

6. Survey Design and Data

6.2. Empirical Setting

Obviously, WTP for standing timber insurance is a function of not only product-specific attributes but also landowner characteristics such as risk perception, risk aversion, and the ability to manage risk with other mechanisms. Factors included in the analyses were landowners’ level of risk perception, degree of risk aversion, importance of risk management as an alternative to standing timber insurance, participation in liability insurance for forestland, loss experience, and impact of governmental programs. Additional factors included forestland characteristics, such as ownership size and species, and demographic factors, such as age, land tenure, and income (a copy of the survey is available upon request). These variables are described subsequently.

6.2.1. Risk Perception and Risk Aversion

Expected utility theory implies that WTP for insurance depends primarily on a combination of the individual's level of risk perception and the individual's degree of risk aversion (Pennings et al., Reference Pennings, Wansink and Meulenberg2002). Risk perceptions reflect a landowner's belief about the probability of certain hazards actually occurring, whereas risk aversion reflects a landowner's willingness to accept, or comfort with, risk. Landowners perceiving greater levels of insurable risk and being more risk averse are expected to have greater demand for standing timber insurance. Risk perception and risk aversion were measured using a Likert-scaling procedure because of the simplicity of measurement.Footnote ⁸ Such self-assessed strength of rating scales are reliable and valid and thus are most commonly used (e.g., Pennings and Garcia, Reference Pennings and Garcia2001; Pennings and Smidts, Reference Glickman2000). For measures of risk perception, respondents were asked to rate their concern for three types of risk on a 5-point scale ranging from 1 (not concerned) to 5 (extremely concerned). Those types of risk were (1) risks because of physical natural disasters such as fire, hurricanes, tornadoes, ice storms, drought, or flood; (2) risks because of biological natural disasters such as insects, disease, or animal damage; and (3) risks because of liability associated with timberland ownership such as hunting-related liability, liability for personal injury to those on your land, liability for escaped control burns, and so forth. These three questions reflected landowners’ risk perception associated with forest management/investments as related to natural disasters and liability, respectively. For risk aversion measurements, respondents were asked to rate their level of agreement for the following five statements on a Likert scale of 1 (strongly disagree) to 5 (strongly agree): (1) In the conduct of business, I prefer certainty to uncertainty; (2) I am willing to accept the risks of timber ownership, including fire, hurricanes, tornadoes, ice storms, insect and disease, timber theft, and liability; (3) I am willing to take higher financial risks in order to realize higher than average returns; (4) I am reluctant to adopt new ways of doing things until I see them working for others; and (5) I am more concerned about large losses to my forest investment than about missing a substantial gain. Note that answers to questions (2) and (3) had to be coded in reverse for the analysis, so that a 1 (strongly disagree) on items (2) and (3) is associated with risk aversion and a 5 (strongly agree) is associated with risk seeking. The average overall scores for both the risk perception and risk aversion questions are used instead of using the specific score of each question, with higher scores indicating more risk perception and more risk aversion. The use of a composite score is supported by prior studies that combined a set of response-scale questions into a single indicator of risk attitudes and perception (e.g., Pennings and Garcia, Reference Pennings and Garcia2001; Pennings, Wansink, and Meulenberg, Reference Pennings, Wansink and Meulenberg2002; Sherrick et al., Reference Sherrick, Barry, Ellinger and Schnitkey2004; Smidts, Reference Smidts1997). For the analysis, the average overall scores for risk perception and risk aversion measurements are further reduced to two dummy variables, with “1” indicating that the perceived risk was high or that the respondent was highly risk averse and “0” indicating the perceived risk was low or that the respondent was not risk averse.

6.2.2. Risk Management Alternatives

NIPF landowners have several timber management practices available that are likely to mitigate the risk of natural disasters. Landowners’ opinions about the effectiveness of these alternative risk management strategies may influence their demand for standing timber insurance. Landowners who engage in timber management practices that mitigate their susceptibility to natural disasters may be less likely to purchase standing timber insurance because their risk has been reduced by their actions; conversely, their willingness to engage in risk management activities may indicate a willingness to engage in all types of risk management, including buying insurance. In the survey, risk management activities involved two instruments: (1) thinning to reduce the susceptibility to forest insects and diseases and (2) control burning to reduce the amount of fuels available in case of a wildfire. The landowners were asked to rate the effectiveness of these risk management strategies on a Likert scale of 1 (not effective) to 5 (extremely effective). Although there are more timber management options available that landowners may use to mitigate risk, we only include these two as general indicators of the effect of such timber management practices on WTP. The benefits of control burning and thinning are generally well known and thus serve as good proxies for alternative risk management strategies in general. Practices to reduce damage from ice storms or loss from timber theft, for example, are less commonly applied and thus less suitable as proxies.

6.2.3. Liability Insurance

Liability coverage is protection against injury or damage claims made by third parties against the forest ownership and is not related to standing timber insurance (i.e., hunting insurance or timberland insurance).Footnote ⁹ Having liability insurance may be correlated with demand for standing timber insurance. Some landowners may be concerned about financial losses in general and not specifically concerned about the cause. If such landowners own liability insurance, it may indicate a willingness to purchase insurance that would include standing timber insurance if it were available. In contrast, purchasing liability insurance for forestland may negatively impact the probability of purchasing standing timber insurance by reducing the funds available for other forestry-related insurance.

6.2.4. Loss Experience

Previous experience with significant timber losses may also affect landowner willingness to purchase timber insurance. Landowners were asked whether they had experienced losses of more than 5% of their total timber value in the past 10 years because of natural disasters. Such past losses clearly demonstrate that forest investments are risky and losses can be significant, thereby increasing the probability of purchasing insurance. The gambler's fallacy, however, suggests that some who have experienced losses in the past may believe that they are thus less likely to suffer losses in the future. Such individuals would be less likely to purchase insurance.

6.2.5. Perceived Public Programs

The impact of public programs on NIPF landowner decisions to purchase an insurance product for windstorm coverage and other natural events was analyzed by Brunette and Couture (Reference Brunette and Couture2008). They concluded that providing public financial assistance to NIPF landowners after natural disasters may reduce their incentive to purchase insurance. Therefore, effects of public programs on NIPF landowner willingness to purchase standing timber insurance are also explored. One question related to public programs is considered: whether landowners themselves or other landowners they personally know have ever received financial or technical assistance from public agencies after timber losses in the past. However, we need to point out that although some landowners claimed to be aware of government financial aid programs, in fact, no such financial programs exist. We actually test whether the illusory expectation of governmental financial aid influences landowner insurance behavior.

6.2.6. Forestland Features

Three variables were used to represent forestland characteristics: ownership size, forest type, and location. Ownership size is expected to be positively correlated with the likelihood of purchasing standing timber insurance, as in general, larger land holdings represent greater values at risk. Of the several forest types considered, pine plantations represent greater out-of-pocket investments, primarily in establishment costs, compared with other forest types; thus, the need to protect the investment is more obvious and likely to increase WTP for standing timber insurance. Forestland located in the coastal region of Mississippi is more frequently impacted by hurricanes, forestland located in the north is more frequently impacted by sleet and ice storms, and forestland located in the central portion of the state is affected by both of these factors but to a lesser extent. A priori, it is hard to predict in which location landowners would be more willing to buy standing timber insurance. Highway 84 and Highway 82 are major east–west highways in Mississippi and were used as boundaries for these three regions for the purpose of this survey.

6.2.7. Landowner Characteristics

Landowner demand for standing timber insurance is likely influenced by ownership characteristics, which were represented by two variables: ownership objectives and length of ownership. Landowners were asked to identify their primary objective for their forestland property from the following list: timber production, land investment, hunting, recreation, or bequest. Those interested in timber production or investment value likely have more invested in their timber and have greater expectations for timber income, and thus greater demand for standing timber insurance than landowners with other objectives for their forestland. For the analysis, answers to the ownership objective question were reduced to a dummy variable, with “1” indicating timber production and land investment and “0” indicating others. The impact of length of ownership on WTP for standing timber insurance is ambiguous. The longer landowners own forestland, the more likely they are to have experienced losses because of natural disasters. In contrast, they may become more experienced with alternative risk mitigation strategies such as thinning or control burning. A number of other socioeconomic variables (i.e., age, race, residence, education level, income, form of ownership, etc.) may influence landowner demand for standing timber insurance. Of these, only age and income were employed in the model. All variables used in the analysis, with expected signs, are presented in Table 1. The survey is available online (http://www.cfr.msstate.edu/forestry/docs/insurance_wtp.pdf).

Table 1. Definition of Variables Used in the Analysis and the Expected Sign

7. Estimation Procedures

A mail survey of Mississippi forest landowners was implemented in the fall of 2010 to generate the necessary data. Before administration of the full survey, pretests of the initial survey were conducted with NIPF landowners attending Mississippi Forestry Association meetings for question clarity and appropriateness. The pretests were also conducted to make sure the survey format was incentive compatible (i.e., respondents would act on the stated intention) and that landowners took the questions seriously. Appropriate adjustments to the survey instrument were made. To eliminate as many nonforestry holdings as possible, the sample frame was limited to landowners who owned at least 100 acres of forestland in Mississippi. This yielded a list of approximately 20,000 owners. Among them, a random sample of 2,000 landowners was selected and used in the mail survey. Following Dillman's (Reference Dillman2000) total design method, a presurvey letter announcing the upcoming study was mailed to the selected landowners 1 week before the initial mailing. A reminder card was sent to all landowners 2 weeks after the initial mailing. A second mailing was sent after a month to those who did not respond to the first mailing. A third (final) mailing was sent after another month to landowners who did not respond to the second mailing.

To analyze the responses to the aforementioned contingent valuation questions, we employed a modified version of the interval-censored model (Cameron, Reference Cameron1988; Cameron and James, Reference Cameron and James1987) that allowed for uncensored values of zero WTP for those respondents who answered “No” to the first question. We assumed that a landowner has a latent WTP*, which can be expressed as follows:

(5)$$\begin{equation} {\rm{\ WT}}{{\rm{P}}^{\rm{*}}} = x{\rm{\beta }} + {\rm{\varepsilon }}, \end{equation}$$

where x is a vector of explanatory variables, β is a conformable vector of coefficients, and ε is an independently and identically distributed normal error with mean zero and variance σ². Rather than directly observed WTP*, what is actually observed from the data is whether a respondent indicated a WTP greater than or less than the particular designated premium rate, c. For a fixed coverage and predetermined premium rate level, there are three possible outcomes: (1) The respondent replies “Yes” to the first question, which indicates that the presented premium rate is the lower bound for the distribution of the WTP, while infinity marks the upper bound. The WTP falls in the range of (c, +∞). (2) The respondent replies “No” to the first question and “Yes” to the second question, which indicates that zero is the lower bound, and the prespecified premium rate is the upper bound, for a range of (0, c). (3) The respondent replies “No” to both of the questions, which indicates that the WTP for the standing timber insurance policy is zero. Although Shaik et al. (Reference Shaik, Coble, Hudson, Miller, Hanson and Sempier2008) argued that in case (3) the lower bound of the possible distribution of WTP is negative infinity and zero is the upper bound, such a range is not adopted in this study. A negative WTP can be ruled out on theoretical grounds in that insurance is an existing and well-known market commodity readily available for purchase as opposed to nonmarket goods. This interval-censored model is also called a partial-censored model because one point of the distribution corresponding to individuals with zero WTP is not censored (Hite, Hudson, and Intarapapong, 2002). The original log-likelihood function (LLF) is given in Cameron (Reference Cameron1988) and is modified as equation (6):

(6)$$\begin{eqnarray} {\rm{LLF}} &=& \mathop \sum \limits_{i \in {I_1}} \ln {\rm{\Phi }}\left( {\frac{{{x_i}{\rm{\beta }} - {c_j}}}{{\rm{\sigma }}}} \right) + \mathop \sum \limits_{i \in {I_2}} \ln \left[{\rm{\Phi }}\left( {\frac{{{c_j} - {x_i}{\rm{\beta }}}}{{\rm{\sigma }}}} \right)\right.\nonumber\\ &&\,\left. -\, {\rm{\Phi }}\left( {\frac{{ - {x_i}{\rm{\beta }}}}{{\rm{\sigma }}}} \right)\right] + \mathop \sum \limits_{i \in {I_3}} \ln \frac{1}{{\rm{\sigma }}}\phi \left( {\frac{{ - {x_i}{\rm{\beta }}}}{\sigma }} \right), \end{eqnarray}$$

where ϕ is the probability density function and Φ is the cumulative distribution function of a normal distribution, respectively; c_j is the premium rate presented to a landowner, and x_i represents a row vector of explanatory variables for the ith respondent; and β is a vector of parameters to be estimated, and σ is the standard error. Cameron (Reference Cameron1988) showed that coefficient estimates from the interval-censored model above can be interpreted loosely as the marginal effect of x on WTP. Duffield and Patterson (Reference Duffield and Patterson1991) noted that the interval-censored formulation is simply a reparameterization of the typical logit or probit models discussed in Hanemann (Reference Hanemann1984), which makes mean WTP and confidence intervals (CIs) easily calculated. Hence, the mean WTP value is simply:

(7)$$\begin{equation} E\left( {{\rm{WTP}}} \right) = \bar x{\rm{\beta }}, \end{equation}$$

where $\bar x$ is a vector of the sample average of the independent variables, and the CI is suggested by Cameron and Quiggin (1994):

(8)$$\begin{equation} \ {\rm{C}}{{\rm{I}}_{1 - {\rm{\alpha }}}}\left[{E\left( {{\rm{WTP}}} \right)} \right] = \bar x{\rm{\hat \beta }} \pm {t_{{{\rm{\alpha }}}/{2}}}\sqrt {\bar x{\rm{\Omega }}\bar x^\prime}, \end{equation}$$

where Ω is the variance-covariance matrix of the parameter estimates. To make the results more robust, the 95% CI for the mean WTP was also estimated by Krinsky and Robb (Reference Krinsky and Robb1986) bootstrapping methods with 5,000 repeated subsamples.

The rigorous assumption of a specific normal distribution of the error term in parametric econometric models when explaining landowner purchase behavior led us to consider estimating WTP using nonparametric methods. The basic idea is that a priori there is no reason why landowner purchase decisions should necessarily follow a normal distribution. The most straightforward nonparametric model is based on the idea that the demand curve should be nonincreasing in price. In order to compare the mean WTP calculated without an error term assumption with the parametric estimate, we use the Turnbull (Reference Turnbull1976) estimator as the benchmark. One of the advantages of the Turnbull estimator over other nonparametric estimators is its ease of use. Only a table including the range of bids and the number of “Yes” and “No” responses is required. Following Haab and McConnell (Reference Haab and McConnell2002, pp. 60–112), only responses to the first question were used, which was treated as a single-bounded format. The Turnbull approach estimates WTP E(LB_WTP) as a lower-bound approximation to expected WTP.