2.1. Farm Gate Feedstock Costs

The facility requires feedstock for processing. Call the quantity of feedstock arriving at the facility Q. Feedstock production, Q, is the product of growing region area, L, and per-unit land productivity, y, that is $Q = y{\rm{\;}}L$ . The facility feedstock processing capacity is $\bar Q$ .

2.1.2. Allowable Age-Yield Functions

Recall, $f\left( a \right)$ —the age-yield function—is the yield per-unit land of a-year-old plants. We impose the following conditions on the age-yield function to ensure an analytical solution

(1) $$f\left( a \right)\ {\rm{is\;continuous}}$$

(2) $$f\left( 0 \right) = 0$$

(3) $$f\left( a \right)\ {\rm{monotonically\;increases\;to\;a\ maximum}},{\rm{then\;monotonically\;decreases}}$$

(4) $$\mathop {{\rm{lim}}}\limits_{a \to \infty } a{\rm{\;}}f\left( a \right) = 0$$

Assumption (1) aids analysis of the supply chain optimization problem. Although continuity can only ever be an approximation of an empirical age-yield function, we consider it to be a reasonable assumption, and that it is a worthwhile price to pay to facilitate analysis. Assumption (2) requires that plants are non-yielding when they are planted. This is a reasonable assumption when considering the entire life cycle of a plant. However, it may be possible for the manager to buy young plants that are yielding when he takes possession of them. We exclude this possibility. Assumption (3) is similar to a standard assumption in the perennial crop theory literature (Mitra, Ray, and Roy, Reference Mitra, Ray and Roy1991), but it is a little stronger, since it excludes the possibility that plants may have a maturity phase where they produce their maximum yield for several years in a row. Assumption (3), however, allows the age-yield function to become arbitrarily close to this case. Assumption (4) requires the age-yield function approach zero “fast enough” as the age of the plant approaches infinity. In particular, the assumption requires that the age-yield function approach zero faster than ${1 \over x}$ . However, this assumption imposes an important modeling restriction. The age-yield function cannot approach a positive constant, which may be an attractive assumption if the plant has a long period of relatively constant yield toward the end of its life.

2.1.3. Feedstock Production from an n-region

Assuming a uniform distribution of age, the yield of feedstock per unit of land for a region with maximum age n is

(5) $$y\left( n \right) = {1 \over n} \int \nolimits_0^n f\left( a \right)\,\,da$$

This is referred to as the n-region yield function to distinguish it from, $f\left( a \right)$ , the age-yield function, or, if unambiguous, simply the yield function. There is a trade-off between marginal and average yield inherent in this function. Since $f\left( a \right)$ is non-negative, the integral term is increasing in n. But an increase in n also increases the number of age classes that the yield must be averaged across. Whether y is increasing or decreasing in n depends on the contribution of the marginal plant relative to the average at that n, which is shown by the derivative of y with respect to n.

(6) $${{dy} \over {dn}}{\rm{\;\;}} = {\rm{\;\;}}{1 \over n}\left( {f\left( n \right) - {1 \over n}\mathop \int \nolimits_0^n f\left( a \right){\rm{\;\;}}da} \right){\rm{\;\;}} = {\rm{\;\;}}{1 \over n}( {\underbrace {f\left( n \right)}_{\matrix{ {{\rm{Yield\;of}}} \cr {{\rm{additional}}} \cr {{n} \hbox- {\rm{plant}}} \cr } } - \underbrace {y\left( n \right)}_{\matrix{ {{\rm{yield\;of}}} \cr {{n} \hbox- {\rm{region}}} \cr } }})$$

The terms in the parentheses are multiplied by ${1 \over n}$ because the contribution of any single plant is diluted with an increase in the number of ages in the n-region. Let the maximum age of the uniform distribution that maximizes yield be ${n_{MSY}}$ . Figure 1 shows an example of the n-region yield and age-yield functions.

Figure 1. Yield is increasing in $n$ while the yield of the marginal age class, $f\left( a \right)$ , is more productive than the average of the $n$ -region, $y\left( n \right)$ .

2.1.4. Farm Gate Feedstock Costs

Feedstock production costs are separated into age-dependent costs and age-independent costs. Age-independent costs must be incurred per-unit land, regardless of the age distribution of the plants on it. Examples include the costs of the manager’s time, the rental rate of the land, any irrigation infrastructure etc. Since this cost is fixed relative to the age of the plants, it is denoted ${C_f}$ . Alternatively, other costs depend on the age distribution of land. For example, in an n-region, only ${1 \over n}$ of the plants are replanted each year, so the average annual replanting cost is ${1 \over n}$ times the cost of replanting an entire unit of land. The age-dependent feedstock cost is denoted ${C_n}$ .

The classification of a specific production cost into age-dependent or age-independent costs can be unintuitive, especially for activities that are carried out in most but not all years. We illustrate this using a sugarcane enterprise budget prepared for growing a 6-region the South-Central region of Brazil (Teixeira, Reference Teixeira2013). In the budget, costs are divided into five categories, delivery costs, and four that account for farm gate feedstock costs: preparing the soil, planting, harvest, and maintenance of the ratoon.

The total farm gate feedstock costs for a 6 age-class operation is given by

$$\matrix{ {{\rm{Total}}\;{\rm{Farm\;Gate}}} \cr {{\rm{Feedstock\;Costs}}} \cr } = {\rm{Soil\;Prep}}. + {\rm{Planting}} + 5 \times {\rm{Harvest}} + 4 \times {\rm{Ratoon}}$$

Since the total cost is given for 6 age classes, the total cost per hectare is

$$\matrix{ {{\rm{Total\;Farm\;Gate}}} \cr {{\rm{Feedstock\;Costs}}} \cr {\left( {{\rm{Per\;Hectare}}} \right)} \cr } = {1 \over 6} \times {\rm{Soil\;Prep}}. + {1 \over 6} \times {\rm{Planting}} + {5 \over 6} \times {\rm{Harvest}} + {4 \over 6} \times {\rm{Ratoon}}$$

Assuming that these cost parameters are constant with respect to the number of age classes, we can write the total farm gate feedstock per hectare as a function of the age structure

$${\eqalign{ \matrix{ {{\rm{Farm\;gate}}} \ {{\rm{feedstock\;costs}}} \cr } \left( n \right) & = {1 \over n} \times {\rm{Soil\ Prep}}. + {1 \over n} \times {\rm{Planting}} + {{n - 1} \over n} \times {\rm{Harvest}} + {{n - 2} \over n} \times {\rm{Ratoon}} \cr & = {\rm{Harvest}} + {\rm{Ratoon}} + {1 \over n}\left( {{\rm{Soil\;Prep}}. + {\rm{Planting}} - {\rm{Harvest}} - 2 \times {\rm{Ratoon}}} \right) \cr}}$$

Hence, the age-independent costs, ${C_f}$ , will be the sum of harvest and ratoon maintenance costs, while the age-dependent costs are the soil preparation and planting costs, less the avoided harvest costs during the planting year and the ratoon maintenance costs for the planting year and the first harvest year.

2.2. Total Land, L

The other component determining total feedstock quantity is the area of land controlled by the manager, L. The choice of L determines how many units of land have perennial feedstock with average yield $y\left( n \right)$ on them. This determines total feedstock production, $Q = y\left( n \right){\rm{\;}}L$ , and total feedstock growing costs, $L\;\left( {{C_f} + {{{C_n}} \over n}} \right)$ .

2.2.1. Delivery Costs

The total area of land also affects the cost of transporting the feedstock from the farm gate to the processing facility (Wright and Brown, Reference Wright and Brown2007). Delivery costs are proportional to the quantity of feedstock multiplied by the average delivery distance.

The average delivery distance is increasing in the area of land around the facility. In the case of a facility surrounded by a circular delivery region with radius ${r_{max}}$ , following Overend (Reference Overend1982), the distance from the facility to the furthest field is given by

$$L = \pi r_{max}^2\;\; \Rightarrow \;\;{r_{max}} = \sqrt {{L \over \pi }} $$

The area-weighed average delivery (transportation) distance is ${r_{av}} = {2 \over 3}{r_{max}}$ (Stone, Reference Stone1991). We express delivery costs as ${C_D}{\rm{\;}}y\left( n \right){L^{1.5}}$ . Bringing another unit of land into the growing region increases both the quantity of feedstock produced and the average distance all feedstock must be transported (delivery costs can equivalently be expressed as ${C_D}{\rm{\;}}Q{L^{0.5}}$ ). The increase in feedstock quantity is linear (holding yield constant), and the increase in average delivery distance is proportional to ${L^{0.5}}$ , making the delivery cost function a convex function of growing region area (see online supplementary appendix B.1 for full derivation).

We make a distinction between the area of land planted (growing region) and the total area of the delivery region. To allow for the possibility that some land in the delivery region is used for other purposes, we allow the planted area to be a linear function of total growing region area, $L = d \times A$ where A is the total delivery region area, and d ( $0 \lt d \le 1$ ) is a density parameter. This facilitates calibrating the model.

2.3. Objective Function

Recall the manager’s objective is to minimize the cost of feedstock acquisition, given by:

$$\matrix{ {{\rm{Feedstock}}} \ {{\rm{costs}}} \cr } = \matrix{ {{\rm{Farm\;gate}}} \cr {{\rm{feedstock\;costs}}} \cr } {\rm{\;\;}} + {\rm{\;\;}}\matrix{ {{\rm{Feedstock}}} \cr {{\rm{delivery\;costs}}} \cr } $$

Using the notation and formulas developed in the previous section, we can rewrite the feedstock cost function mathematically

(7) $$C\left( {n,L} \right) = \left( {{C_f} + {{{C_n}} \over n}} \right)L + {C_D}\;y\left( n \right)\;{L^{1.5}}$$

where n is maximum age, L is area of the growing region, ${C_f}$ is the age-independent cost per unit of land, ${C_n}$ is the age-dependent cost per unit of land, and ${C_D}$ is the delivery cost parameter.

3.1. First-Order Conditions

The three first-order conditions for the cost minimization problem are

(10) $${{\partial {\cal L}} \over {\partial n}} = {\rm{\;\;}}{{ - {C_n}{\rm{\;}}L} \over {{n^2}}} + {C_D}{\rm{\;}}y{\rm{'}}\left( n \right){\rm{\;}}{L^{1.5}} - \lambda {\rm{\;}}y{\rm{'}}\left( n \right){\rm{\;}}L = 0$$

(11) $${{\partial {\cal L}} \over {\partial L}} = {\rm{\;\;}}\left( {{C_f} + {{{C_n}} \over n}} \right) + 1.5{\rm{\;}}{C_D}{\rm{\;}}y\left( n \right){\rm{\;}}{L^{0.5}} - \lambda {\rm{\;}}y\left( n \right) = 0$$

(12) $${{\partial {\cal L}} \over {\partial \lambda }} = {\rm{\;\bar Q}} - y\left( n \right){\rm{\;}}L = 0$$

Equations (10)–(12) state that the marginal change in the Lagrangian function with respect to each of the choice variables is necessarily zero at the optimum.

The left-hand side of equation (10) shows how the Lagrangian function changes with respect to an increase in the maximum age. There are three components. The first component is the change in age structure-dependent costs (e.g. average replanting costs). This is always negative since the costs are averaged over more ages as n increases. The second component is the change in delivery costs due to the increase in maximum age. This can be either positive or negative depending on the sign of marginal yield, $y{\rm{'}}\left( n \right)$ . If marginal yield is negative, then an increase in maximum age reduces delivery costs since there is less feedstock to deliver. The third term is the penalty for violating the quantity constraint. If $y{\rm{'}}\left( n \right)$ is non-zero, a change in n changes the quantity of feedstock produced (since we are holding planted area constant). If the constraint was satisfied before the change, then it will now be violated after the change. Generally, $\lambda $ represents the penalty for violating the constraint by a single unit (at the optimum it represents the change in feedstock costs due to a unit increase in processing facility capacity). So the third term is the product of the per-unit penalty and the change in total feedstock quantity due to the increase in maximum age.

The left-hand side of equation (11) shows how the Lagrangian function changes with marginal increase in the planted area. The three components have similar interpretations to the components of equation (10) except that now maximum age is being held constant. The first term is the marginal cost of growing feedstock on an additional unit of land. The second term is the marginal cost of delivery from the additional unit of land. This is an increasing function of total land due to the convexity of delivery costs. Again, the third term is the penalty for violating the capacity constraint, given the penalty per unit, $\lambda $ .

3.2. Isoquant and Isocost Curves

Figure 2 shows example isocost and isoquant curves for the constrained minimization problem presented in the previous section. The isocost and isoquant functions are presented in $\left( {n,L} \right)$ space, so both are functions of n. The figure was generated in MATLAB using the calibration for sugarcane described in Section 4. Although calibrated to the sugarcane industry in São Paulo state, Brazil, this figure displays all the qualitative features of an isocost and isoquant curve of the general constrained minimization problem, as the next sections establish.

Figure 2. Example isocost and isoquant curves for the cost minimization model. In this instance, the lower contour set for the isocost curve is non-convex.

Looking at Figure 2, two issues arise regarding using the first-order conditions to solve the constrained minimization problem. The first is that the domain of the isocost and isoquant function is unbounded to the right. The second is that the lower-cost set of the isocost curve is non-convex. The non-convexity of the lower-cost set in Figure 2 provides a counterexample to the statement “all lower-cost sets from the cost function (equation 7) are convex.” Hence, the lower-cost sets are generally non-convex. Intuitively, we see that the cost function is the sum of a linear term in L and two non-quasiconvex functions in n and L. These two issues mean that we cannot immediately invoke the usual sufficiency conditions for a convex optimization problem, which call for a bounded domain and a convex lower contour set for the objective function and guarantee that a solution to the first-order conditions is also a solution to the original optimization problem.

The first issue can be dispensed with almost immediately by noting that as n approaches infinity, yield approaches zero, requiring the growing region to increase without bound. The marginal cost savings from increasing n and reducing age-independent costs approach zero as n approaches infinity, whereas the marginal cost of expanding the growing region is always positive (and in fact increasing due to the convex delivery costs). Hence, it cannot be optimal to let n approach infinity, implying that for each parameter set there must be some upper bound beyond which the optimal n can never be found.

The second issue, a non-convex lower-cost set, is dealt with by propositions 1–2.

3.3. Comparative Statics

The signs of the comparative statics of the cost minimization model are presented in Table 1. Proofs for these signs are presented in online supplementary appendix A.1.

Table 1. Signs of comparative statics of ${n^{\rm{*}}}$ and ${L^{\rm{*}}}$

As the processing facility size increases, the optimal maximum age decreases and approaches the maximum sustainable yield age. For $n \gt {n_{MSY}}$ , a decrease in n increases the yield of the feedstock growing region. Since a fixed quantity of feedstock must be produced, higher yield allows the growing region to be marginally smaller. We have shown that it is always worthwhile to marginally boost yields as the facility size increases. The magnitude of this effect, and whether it is economically important, depends on the particular parameterization of the model.

If the second derivative of the yield function is negative at the optimum, an increase in facility capacity increases growing region area. Intuitively, the increase in feedstock required for an increase in facility capacity must come from some combination of increased land and/or increased yield. An increase in facility capacity always decreases optimal age and hence increases yield. The question becomes whether the increased yield is sufficient to provide the additional feedstock alone or must be augmented with additional land. From the proof in the appendix, we see there are 5 terms that affect the sign of ${{d{L^{\rm{*}}}} \over {d\bar Q}}$ . However, when $y{\rm{''}}\left( {{n^{\rm{*}}}} \right) \lt 0$ , a decrease in age has a diminishing increase in yield. In this case, the increase in yield can never be enough to feed the refinery alone, and additional land is always required. By definition, the second derivative of average yield will be negative at the maximum sustainable yield age. Therefore, there is a neighborhood around ${n_{MSY}}$ in which increases in facility size always increase growing region size.

The parameter ${C_f}$ represents the age-independent cost of feedstock production. An increase in ${C_f}$ increases the marginal cost of land, so the optimal choice moves away from land and toward yield through a reduction in the maximum age.

The parameter ${C_n}$ represents the age-dependent costs of feedstock production. This cost includes replanting costs, as well as the cost of maintaining plants in the years after they are planted. The total cost of replanting and maintenance is dependent on the maximum age, since ${1 \over n}$ of the region is being replanted and ${{n - 1} \over n}$ is being maintained each year. An increase in the age-dependent cost parameter always increases the attractiveness of an older region, since an older region distributes the age-dependent costs across more ages, reducing the average age-dependent costs. See appendix B for more details.

The parameter ${C_D}$ represents the costs of delivering feedstock from the field to the processing facility. It affects both costs of yield and of land, since both these variables determine the quantity of feedstock transported. Yield is only indirectly affected through total quantity. Since this analysis is focused on a cost minimization problem with respect to a fixed facility size, a change in delivery cost only directly affects the marginal cost of land, leaving the quantity of feedstock produced unchanged. Therefore, an increase in the delivery cost increases the marginal cost of land and, like the effect of ${C_f}$ , shifts the optimal choice of land and yield towards yield and away from land.

4.1. Data

The model was calibrated with productivity, cost, and facility capacity data from the São Paulo region of Brazil. Data on facility capacity were obtained from Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) who obtained facility production costs from 20 mills (mills and facility are used interchangeably in this section), with capacity ranging from 1 to 32 million tons. These mills represented over 30% of installed sugarcane processing capacity in Brazil in 2007–2008. While these mills represent only a subset of the 153 mills present in São Paulo state in 2007–2008, the range of 1 to 32 million tons covers 69.9% of the number of mills and 91.9% of processing capacity in the state (CONAB, 2008). This range better represents the most recent CONAB data from 2015/2016, when São Paulo had 160 mills. By this time, however, mill capacity had increased, with only 13% of mills smaller than 1 million tons, representing only 2.99% of processing capacity (CONAB, 2019).

Sugarcane yield data are obtained from Margarido and Santos (Reference Margarido, Santos, Santos, Borém and Caldas2012) who provide an example of planning a sugarcane production system in the Alta Mogiana region of São Paulo. These yield data are similar to those reported by CONAB (2008, 2019). These data are used to fit a piecewise linear age-yield function, which has four parameters:

(13) $$f\left( a \right) = \left( {\matrix{ 0 \hfill & {{\rm{if}}\ a \in \left[ {0,{t_1}} \right)} \hfill \cr\cr {{{{f_{max}}} \over {{t_{max}} - {t_1}}}\left( {x - {t_1}} \right)} \hfill & {{\rm{if}}\ a \in \left[ {{t_1},{t_{max}}} \right)} \hfill \cr\cr {{{ - {f_{max}}} \over {{t_T} - {t_{max}}}}\left( {x - {t_T}} \right)} \hfill & {{\rm{if}}\ a \in \left[ {{t_{max}},{t_T}} \right)} \cr\hfill \cr 0 \hfill & {{\rm{if}}\ a \in \left[ {{t_T},\infty } \right)} \hfill \cr {} \hfill & {} \hfill \cr } } \right.$$

where a is the age of the plant, ${t_1}$ is the age of initial yield, ${t_{max}}$ is the age of maximum yield, ${t_T}$ is the age of final yield, and ${f_{max}}$ is the maximum yield. The fit is shown in Figure 6 in online supplementary appendix B.1.1. Because sugarcane attains its highest yield in the first year of harvest, the piecewise linear function provides an improved fit over other functions used to fit age-yield data that cannot capture this rapid increase, for example the Hoerl function (Haworth and Vincent, Reference Haworth and Vincent1977).

We derived the feedstock cost parameters, ${C_f}$ and ${C_n}$ , from Teixeira (Reference Teixeira2013), and the delivery cost parameter, ${C_D}$ , from Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010). Teixeira (Reference Teixeira2013) presents an example enterprise budget for a 6-region sugarcane operation in São Paulo state. The acreage of this representative operation is not stated. Costs are divided into five categories: delivery costs, and four that account for farm gate feedstock costs: preparing the soil, planting, harvest, and maintenance of the ratoon. The total cost per hectare is

$$\eqalign{ \matrix{ {{\rm{Total\;Farm\;Gate\;Feedstock\;Costs}}} \cr } \left( \rm{Per\;Hectare} \right) & = {{1} \over 6} \times {\rm{Soil\;\;Preparation}} + {1 \over 6} \times {\rm{Planting}} \cr & + \; {5 \over 6} \times {\rm{Harvest}} + {4 \over 6} \times {\rm{Ratoon\;\;Maintenance}} \cr}$$

Assuming that these cost parameters are constant with respect to the number of ages, we can write the total farm gate feedstock per hectare as a function of the maximum age:

$$\eqalign{ \matrix{ {{\rm{Farm\;gate}}} {{\rm{\;feedstock\;costs}}}} \left(n \right) & = {1 \over n} \times {\rm{Soil\;\;Preparation}} + {1 \over n} \times {\rm{Planting}} \cr & + \; {{n - 1} \over n} \times {\rm{Harvest}} + {{n - 2} \over n} \times {\rm{Ratoon\;\;maintenance}} \cr}$$

Substituting Teixeria’s numbers (in Reals) from the example budget, the cost function becomes

(14) $$\eqalign{ \matrix{ {{\rm{Farm\;gate\;feedstock\;costs}}} \cr } \left( n \right) & = {{656.07} \over n} + {{4159.83} \over n} + {{n - 1} \over n} \times 1273.13 + {{n - 2} \over n} \times 986.54 \cr & =2259.67 + {{1569.69} \over n} \cr}$$

Hence for the simulations, we use a baseline of ${C_f} = 2259.67$ and ${C_n} = 1569.69$ .

While Teixeira (Reference Teixeira2013) does include estimates of delivery costs, he does not include the processing facility size that this example farm is feeding. We therefore turn to Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) to derive the delivery cost parameter. The total delivery cost from a growing region is given by

$$\eqalign{\matrix{ {{\rm{Total}}} \,{{\rm{Delivery\ Costs}}} \cr } & = {\rm{Average\;Cost\;Per\;Ton\;Kilometer}} \cr & \times \;{\rm{Quantity\;Transported}} \cr & \times \;{\rm{Average\;Delivery\;Distance}} \cr} $$

Let $\delta $ represent the average delivery cost per ton kilometer (i.e. the average cost to transport one ton of feedstock one kilometer). Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) report an average transport cost of R$6.7 to transport a ton of feedstock from the farm gate to the mill. The average delivery distance in this study was 22 kilometers so in this case $\delta = 0.3045$ . This distance is smaller than the São Paulo state averages reported in 2007–2008 (23.87km) and 2015–2016 (26.78km) (CONAB, 2008, 2019).

The average mill size in Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) is 4.8 million tons. Given our assumption that the growing region produces the exact quantity required to feed the mill, this implied that the average quantity of feedstock transported was 4.8 million tons. Recall that when calculating the average delivery distance, we must make a distinction between the area of land planted with sugarcane, L, and the area of the growing region, A. Although we are assuming that the growing region is circular, it is not necessarily the case that all the land is planted with sugarcane. In fact, relaxing the link between planted area and growing region area is necessary to correctly calibrate the model to the data in Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010).

Let d be the average density of sugarcane fields in the growing region, and A be the area of the growing region, so $L = d \times A$ . The average delivery distance, ${r_{av}}$ , which is the average radius from the center to points in the circle, is given by the expression

$${r_{av}} = {2 \over 3}{r_{max}} = {2 \over 3}\sqrt {{A \over \pi }} $$

where ${r_{max}}$ is the radius of the growing region, and $\pi $ is the mathematical constant. Since the average delivery distance, ${r_{av}}$ , from Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) is 22km, the size of the growing region is A = 342 119 ha. The total quantity of feedstock production is the product of the yield, density, and growing region area. Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010) report an average yield of 75 tons per hectare, so $d = 0.187$ . The expression for total delivery costs is

(15) $$\matrix{ {\matrix{ {{\rm{Total\;Delivery\;Costs}}} \cr } } & \displaystyle{ = {{2\delta } \over 3}\sqrt {{1 \over {d \times \pi }}} \times y\left( n \right){L^{1.5}}} \cr {} \hfill & { = {C_D} \times y\left( n \right){L^{1.5}}} \hfill \cr }$$

For the d and $\delta $ derived from Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010), ${C_D} = 0.2649$ .

4.2. Simulation Results

Figure 3 shows a numerical example of the changes in cost-minimizing age and planted land area as the facility processing capacity is increased. The shape of the expansion path corresponds to the results of the comparative statics of ${n^{\rm{*}}}$ and ${L^{\rm{*}}}$ as we increase $\bar Q$ . As facility capacity increases from 1 to 36 million tons, the optimal maximum age decreases from 6.50 to 6.21, corresponding to an increase in the n-region yield from 75.76 tons per hectare to 75.92 tons per hectare. The majority of the additional feedstock is supplied from additions to planted land area.

Figure 3. Cost-minimizing age and planted land area as processing facility capacity is increased from 1 million tons to 36 million tons. With increased capacity, age approaches ${n_{MSY}}\left( { = 6.02} \right)$ .

Over the period 2009–2015, the average age of sugarcane in São Paulo was 3.76 years, which, if the ages are assumed to be distributed uniformly, implies a maximum age of 7.52 (CONAB, 2012, 2013a, 2013b, 2017a, 2017b, 2017c). Denote this maximum São Paulo age as ${n_{SP}} = 7.52$ . Figure 3 shows that as facility size increases, the cost-minimizing maximum age moves towards the maximum sustainable yield age, and away from the São Paulo maximum age. The difference between ${n^{\rm{*}}}$ and the São Paulo maximum age implies a difference in average age of between six and eight months. Conditional on the maintained assumptions of the model, what is the difference in feedstock acquisition cost between using an ${n^{\rm{*}}}$ -region and an ${n_{SP}}$ -region for a facility of a given size?

Figure 4 shows the difference in cost between the cost of choosing both n and L to minimize the cost of supplying the processing facility ( ${n^{\rm{*}}}$ -region) and the cost of fixing n at ${n_{SP}}$ and only allowing L to vary ( ${n_{SP}}$ -region). The cost difference ranges from 0.75% when supplying a one million ton facility to 0.94% for a 36 million ton facility. For the range of facilities presented in the graph, the condition for the comparative static of land with respect to refinery capacity is satisfied and the increased capacity is met with an increase in land and a decrease in optimal age toward ${n_{MSY}}$ .

Figure 4. Percentage difference in cost between using the cost-minimizing maximum age ( ${n^{\rm{*}}}$ ) and implied São Paulo maximum age ( ${n_{SP}} = 7.52$ ).

The optimal maximum age is lower for larger facilities. The difference between the optimal maximum age and the fixed São Paulo maximum age, and consequently the difference in costs, increases as the capacity of the facility increases. As the processing facility’s capacity increases, the difference in cost increases at a decreasing rate. This increase is approximately log-linear, with a 1% increase in the facility capacity leading to an approximately 0.062 percentage point increase in the cost difference. To put this in perspective, consider a 10 million ton mill. The cost reduction from optimizing age, relative to the São Paulo average age, is 0.872%, or 1.137 million Reals. Increasing the capacity of the mill by 1%, to 10.1 million, will increase the cost difference by 0.062 percentage points, or 704 Reals.

4.3. Sensitivity

Table 1 provided qualitative comparative statics of ${n^{\rm{*}}}$ and ${L^{\rm{*}}}$ with respect to facility size and cost parameters. To examine the quantitative magnitude of these derivatives, as well as the effect of changes in the piecewise linear age-yield function parameters, we generated random parameter sets and solved the cost minimization problem for each set. We then used linear regression to estimate the approximate marginal effects of each parameter on total feedstock costs, optimal maximum age, and optimal area.

Simulation parameters were drawn from a uniform distribution generated by scaling draws from a Halton sequence. For cost parameters, we centered the uniform distribution on the calibrated parameter values, with a minimum parameter value of half the calibrated value, and a maximum value of 1.5 times the calibrated value. In the absence of information on plausible ranges for cost and yield parameters, the uniform distribution and bounds were chosen to create sufficient variation to estimate the marginal effects. Mill capacity ranged between 1 and 36 million tons (the range from Crago et al. (Reference Crago, Khanna, Barton, Giuliani and Amaral2010)).

Each of the four parameters of the piecewise linear age-yield function was allowed to vary independently. In the baseline calibration, the time to initial yield was 1 year after planting and maximum yield was achieved one year after initial yield. The age of final yield was 13 years, and the maximum yield was 120 ton/ha. Varying the four parameters independently allows hypothetical age yield relationships to be considered, for example what if maximum yield was reached two years after initial yield? The age of maximum yield is defined relative to the age of initial yield. If the age of initial yield increases by 1, so will the age of maximum yield. Likewise, the age of final yield is defined relative to the age of maximum yield. The parameter values used in the simulation are reported in Table 3 in online supplementary appendix B.2.

Using MATLAB, we generated 100,000 random parameter sets. For each random parameter set, the fmincon function was used to solve for the cost-minimizing values of n and L along with the associated costs for feeding the facility using the cost-minimizing age and area. Because of numerical issues or theoretical incompatibility (e.g. ${n^{\rm{*}}} \lt 0$ ), 3.9% of draws were eliminated.

The simulations allow us to construct numerical comparative statics for all parameters, using linear regression on the simulated data. The results of these regressions are shown in Table 2. Each column is a regression of either total cost, optimal age, or optimal land on the parameters and a constant. The natural logarithm of all dependent and independent variables has been taken, so estimated coefficients should be interpreted as elasticities.

Table 2. Numerical comparative statics. Log-log regression of total cost, optimal age, and optimal land on all parameters

***p<0.001; **p<0.01; *p<0.05.

The signs of the coefficients are consistent with the theoretical signs presented in Table 1, although the coefficients of ${L^{\rm{*}}}$ with respect to age-independent costs and delivery costs are not significantly different from zero. Total costs are convex with increases in facility size due to the corresponding increases in growing region area. Total costs are most sensitive to changes in the delivery cost parameter, with a 1% increase in ${C_D}$ increasing total costs by 0.75%, while total costs are least sensitive to changes in age-dependent costs.

For the age-yield function parameters, a 1% increase maximum yield decreases total costs by 0.63%. Increases in time to initial yield and time from initial yield to maximum yield increase total costs as they delay the peak of the n-region yield function. Conversely, increases in the time from maximum yield to final yield decrease total costs, since older plants become relatively more productive.