Profit Maximization

Revenue from a cow–calf operation is received from selling steers, heifers, and culled cows. Cattle prices for steers and heifers typically vary based on weight, physical characteristics, and total weight of a lot of cattle sold (Garber et al., Reference Garber, Alwang, Norton and Bovay2022; Martinez, Boyer, and Burdine, Reference Martinez, Boyer and Burdine2021; Williams et al., Reference Williams, Raper, Devuyst, Peel, Williams, Raper, Devuyst, Peel and Mckinney2012, Reference Williams, DeVuyst, Peel and Raper2014; Zimmerman et al., Reference Zimmerman, Schroeder, Dhuyvetter, Olson, Stokka, Seeger and Grotelueschen2012) and the average weight can vary across the calving seasons (Caldwell et al., Reference Caldwell, Coffey, Jennings, Philipp, Young, Tucker and Hubbell2013; Campbell et al., Reference Campbell, Backus, Dixon, Carlisle and Waller2013). Therefore, revenue from an integrated cow–calf and stocker operation depends on calving season and the number of days stocking cattle with an uncertainty of the weight and price received. Production costs for a cow–calf operation will include pasture, feed, health, marketing, trucking, and others. Most of these production expenses do not vary significantly across calving seasons except for supplemental feed costs (Henry et al., Reference Henry, Boyer, Griffith, Larson, Smith and Lewis2016; Smith et al., Reference Smith, Caldwell, Popp, Coffey, Jennings, Savin and Rosenkrans2012).

Assuming a producer is a risk-neutral and a profit-maximizer, the producer would select the number of days to retain weaned calves to feed or graze that would maximize their annual net returns per exposed female. In this research, several scenarios are analyzed to see how the optimal length of time to stocker cattle varies across herd size and calving season. Specifically, the herd sizes were assumed to be 30, 60, and 90 cow head herds, which are calving either in the spring or fall, with a stocker period of 30-, 60-, 90-, 120-, and 150-day postweaning. The producer’s decision is expressed as

(1) \begin{equation}E\left[\pi _{ikl}\right]=p_{ikl}^{s}\times y_{ikl}^{s}\times \left({{\rm WR} \over 2}\right)+p_{ikl}^{h}\times y_{ikl}^{h}\times \left({{\rm WR} \over 2}-{\rm RR}\right)+p_{i}^{c}\times y_{i}^{c}\left({\rm RR}\right)-{\rm PC}_{il}\end{equation}

were π _ikl are the expected annual net returns per exposed female ($/head) for the ith calving season (i = spring, fall) for herd size k (k = 30, 60, 90 head) for stocker period l (l = selling at weaning, 30-day, 60-day, 90-day, 120-day, and 150-day); p _ikl ^s is the price of steer calves ($/pound); y _ikl ^s is the weight of the steer calves (pound/head); WR is the weaning rate 0 ≤ WR ≤ 1; p _ikl ^h is the price of the heifer calves ($/pound); y _ikl ^h is the weight of heifer calves (pound/head); RR is the replacement rate of the cowherd 0 ≤ RR ≤ 1; p _i ^c is the price of culled cows ($/pound); y _i ^c is the weight of cull cows (pound/head), and PC _il is the annualized variable production costs ($/head). The assumption was made that production cost could be varied in each calving season due to the differences in feed cost but calving and replacement rates would stay the same for both calving seasons (Henry et al., Reference Henry, Boyer, Griffith, Larson, Smith and Lewis2016; Smith et al., Reference Smith, Caldwell, Popp, Coffey, Jennings, Savin and Rosenkrans2012), which is further discussed in the data section.

A key component to consider in this production system is uncertainty. Specifically, the uncertainty about weaning weight, cattle prices, and feed prices. Therefore, for each calving season, herd size, and stocker length, we simulate net returns considering this uncertainty. This allows the producer to make an optimal decision going beyond profits. Therefore, a producer’s decision-making framework to select the optimal stocker period changes from profit maximization to utility maximization, defined as U(π, r) where r is the producer’s risk preference level (Hardaker et al., Reference Hardaker, Richardson, Lien. and Schumann2004).

Cattle Price

Price data were collected from the Lower Middle Tennessee Cattle Association (LMTCA) video sale spanning from 2016 to 2020, which is a bid-board auction occurring monthly. This consignment sale attracts cattle from several southeastern states. A sale catalog prior to the sale date includes cattle owner, number of head, estimated weight, sex, USDA feeder calf grades and flesh score, physical animal description, management practices, weighing conditions, shrink, and some other information. These cattle also have descriptions including information such as home raised (percent of cattle sold by the original producer), breed, percent with black hide, defects (scars, pinkeye, ringworm, horns), and if the lot has been tested for identification of being persistently infected with bovine viral diarrhea virus.

Cattle are sold through a public auction with bidders being present, on the phone, and through an online bidder platform. Table 2 illustrates average prices across months and weight classes. The seasonality of beef cattle prices and the relationship between price and weight is visible in this table. The lighter weight classes on average had the higher average sale prices. The sale months with the highest average sale prices were August and October. The range of head sold each month for each weight class ranged from 66 to 4,443.

Table 2. Tennessee price data average prices across months and weight classes from 2016 to 2020 ($/cwt) (total observation equal 1,114)

*Data does not exist.

Animal Production

These cattle production data for the spring and fall calving cowherds come from Ames Plantation Research and Education Center, located in Grand Junction, Tennessee from 1990 to 2008. Both calving herds were made up of commercial and purebred Angus cows. The commercial classified cattle were Angus-influenced that been crossbred with either Hereford or Simmental lines. Purebred Angus heifers were retained for replacements. Bulls were developed at Ames or purchased for the selection of genetic diversity.

The fall calving herd calved in the months of September through November, and the spring calving herd calved in the months of February through April. These herds grazed endophyte-infected tall fescue and received supplementation of mineral and corn silage as needed on a year-round basis. We do not have data on the amount of supplementation provided to these cows. Cows were culled from the herd if unable to re-breed or for low calf performance when compared with the total weight gained of other calves with dams of the same age. These data include spring herd consisting of 478 cows that totaled 1,534 calves born, and the fall herd totaled 474 cows with 1,727 calves born. Table 3 shows the summary statistics of the birth and weaning weights of calves in the spring and fall herds. These weaning weights were the assumed starting weight of retained weaned calves for feeding periods.

Table 3. Summary statistics of birth weights (BW) (lbs) and actual weaning weights (WW) (lbs) by calving season and calf sex at Ames Plantation, from 1990 to 2008

Calf death loss, cow death loss, calving rate, cull percentage, and culled cow weights were assumed from literature for our model. The assumed culled weaning rate was 90%, replacement rate of 10%, and cull cow average weight of 1,300 pounds for both spring-and-fall calving herds (Boyer, Griffith, and DeLong, Reference Boyer, Griffith and DeLong2020; Henry et al., Reference Henry, Boyer, Griffith, Larson, Smith and Lewis2016). For a herd size of 30 head, this equates to 27 total weaned calves, with 14 steers, 10 heifers, and 3 culled cows being sold. For a herd size of 60 head this equates to 54 total weaned calves, with 27 steers, 21 heifers, and 6 culled cows being sold. For a herd size of 90 head, this equates to 81 total weaned calves, with 41 steers, 31 heifers, and 9 culled cows being sold.

Nonfeed Production Cost

The production costs were determined from the University of Tennessee Department of Agricultural and Resource Economics Extension (2021) cow–calf and stocker budgets along with estimated feed cost rations based on cow nutritional needs and stocker growth rates. The budgets include production expenses of hay and pasture production, supplemental feed and minerals, veterinary and medication cost, labor, land, marketing as well as the expense of the bull. Feed and hay production expenses were removed from the cow–calf budget, and in the stocker budget, calf purchase cost including interest were removed from the estimate as well as pasture and hay production, and purchased feed, hay, and supplement feed cost. These feed costs were estimated separately for each animal unit by month based on forage production, which is discussed in more detail in the following sections.

Ration Development

Supplemental feed rations were developed and implemented to satisfy the nutritional requirements and demands for cow–calf production, following the National Research Council (NRC) guidelines for production phases. The NRC provides calculations containing the minimum nutrient demands for a cow based on the animal description, factors of the environment, forage and pasture quality, and feedstuffs implemented in the diet (NRC, 2000). The animal description includes factors of age, weight, body condition, calf birth weight, milk production, length of gestation, and the number of days in lactation. The feed program focuses on the appropriate balance of a cow’s dry matter intake (DMI), energy (NEm), and metabolizable protein (MP) using the feedstuffs. Stocking rates as well as availability and quality of forage were assumed based on a tall fescue forage system in the Southeast. These rations utilize hay and feedstuffs when grazing is insufficient in maintaining the nutritional demands at various times of the year. These feed ingredients were selected due to availability to producers, simplicity, and nutrient quality (Poore, Johns, and Burris, Reference Poore, Johns and Burris2002).

For spring calving, cows would need to be supplemented in the months of January, February, March, and December with average quality hay that was estimated to be 85% dry matter (DM), 52% total digestible nutrients (TDN), and 9% crude protein (CP). The amount of hay fed, on an as-fed basis, following the feeding season was 40 lb/head/day in December and January, 25 lbs/head/day in February and March. A 50:50 mixture of corn gluten feed and soybean hulls, accumulating to 90% DM, 71% TDN, and 15.6% CP, was needed. The amount needed, on an as fed basis, was 16 lb/head/day in both the months February and March. The fall-calving cows will receive supplementation from November to March. The hay fed on an as-fed basis was 25 lb/head/day for November, December, January, and February, and 40 lb/head/day in March. The amount of the 50:50 mixture fed was 16 lb/head/day from November to February.

Rations were also formulated for stocker calves born in the spring and retained past weaning. We targeted a 1.7 lb/day gain for weaned calves in developing these rations, which is a common ADG found in stocker production studies in this region (Crawford et al., Reference Crawford, Forwood, Belyea and Garner1989; Wang et al., Reference Wang, Dorfman, McKissick and Turner2001; Johnson et al., Reference Johnson, Busdieker-Jesse, McClain and Lancaster2019). The literature suggests that there is a time post-weaning when calves can lose weight or not grow (Lynch, McGee, and Earley, Reference Lynch, McGee and Earley2019). Thus, it is assumed that for the first 20 days post-weaning that the ADG of the cattle is zero and after the first 20 days, cattle are assumed to gain 1.7 lb/day.

For the spring-born stockers, these cattle were fed 8 lb/head/day of hay and 12 lb/head/day of the 50:50 mixture in January. During February and March, stockers were given 9 lb/head/day of hay and 13 lb/head/day of 50:50 mixture. Supplementation resumes in October with 10 lb/head/day and 11 lb/head/day in November of 50:50 mixture. In December, these stocker cattle are fed 8 lb/head/day of hay and 11 lb/head/day 50:50 mixture fed. Fall stocker calves were supplemented with the 50:50 mixture from June to November. Hay is not required for fall stocker calves as pasture is a sufficient forage source during these months. The amounts needed for the 50:50 mixture is 10 lb/head/day in June, 11 lb/head/day in July and August, 12 lb/head/day in September, 13 lb/head/day in October and November.

Feed and Hay Costs

Hay and feed prices were used to develop ration costs. The US average hay price was $129/ton from 2016 to 2020 (USDA National Agricultural Statistics Service (NASS), 2021). However, hay prices are regional-specific, and the US hay prices do not always accurately reflect the regional hay price. That said, the seasonal changes in hay prices at the national level would be like a regional market in most years. Therefore, a seasonally adjusted, regional hay price was determined by developing a seasonal index created by using national hay prices. US monthly hay prices were collected from 2016 to 2020. An index was developed using January as a base month to show price fluctuation across months. This monthly price index was applied to a regional price of hay to build in a seasonal hay price to a local average market price. Due to limited reported transactions in the region, we selected an average price of $45/ton based on producer practice and conservations with Extension personnel.

USDA Agricultural Marketing Service (AMS) (2021) was the source for prices of corn gluten feed, and soybean hulls, from the Memphis, Tennessee reporting location. Table 4 shows monthly average feedstuff prices over the past 5 years (2016–2020) for corn gluten feed, soybean hulls, and hay. Most agricultural crops, such as those utilized for feedstuffs, have seasonality in their prices. Seasonality of feedstuffs is driven by supply and demand including price of substitutes, complements, number of producers, expectations, and any other factor that affects crop productivity like weather (Griffith, Reference Griffith2013).

Table 4. Monthly average feedstuff prices ($/ton) over the past 5 years (2016–2020) for corn gluten feed, soybean hulls, and hay (n = 60 for each price)

^a Hay Purchased at $45/ton.

The total costs are found by combining the production cost with the feed cost. Table 5 illustrates both the cost of production and feed cost by segment as the stocker length and feed cost increase over time with purchasing feed as needed.

Table 5. Cost of production varied by stocker period length

Price Response Function

A hedonic pricing model was first estimated to determine price as a function of monthly, cattle weight, and lot weight impact prices. The estimated prices were used to simulate net returns shown in equation (1). All cattle are sold in groups, identified as lots, we estimate the model using the lot as the observation for the monthly sale, which accounts for seasonal price changes. The model is written as

(2) \begin{align}&{\rm Price}_{clm}=\beta _{0}+\beta _{1}\log \ \left(W_{clm}\right)+\beta _{2}\log \ \left(H_{clm}\right)+{\beta _{3}}{\rm HR}_{clm}+\beta _{4}{\rm MB}_{clm}++\beta _{5}S_{clm} \\ & \quad \quad \quad \quad +\sum _{m=1}^{m=11}\gamma _{m}{\rm SM}_{m}+\delta _{1}\log \ ( {\rm CP}_{tm})+v_{t}+u_{c}+\varepsilon _{clm}\end{align}

where Price _clm is the average price per cwt for cattle sold in lot c in year l during sale month m; W _clm is the average weight per head (pound/head); H _clm is the variable of the number of head sold in the lot; HR _klm is a binary variable for lots that were described as home raised; MB _clm is a binary variable for the lot being described as majority black hided; S _clm is a binary variable for sex of the cattle with the variable equal one if the lots were heifers; SM _m are a set of binary variable for the months the cattle are sold; CP _m is the nearby corn futures prices at the time of the sale; β′s, γ′s, and δ′s are parameters to be estimated; v _t ∼ N(0, σ _v ²) is the year random effect; u _c ∼ N(0, σ _u ²) is the sale lot random effect; and ϵ _ilm ∼ N(0, σ _ϵ ²) is the random error term. We assume independence on all four random variables.Footnote ¹

These models were estimated using maximum likelihood with the MIXED procedure in SAS 9.4 (SAS Institute, 2011). The parameter estimates of logged variables are converted to nominal dollar change in the sale price of cattle by multiplying the estimated parameter value by the average predicted selling price of the cattle (Wooldridge, Reference Wooldridge2013). Heteroskedasticity is tested for with respect to all covariates utilizing the likelihood ratio test (Wooldridge, Reference Wooldridge2013). If heteroskedasticity is present, it is corrected by implementing multiplicative heteroskedasticity in the variance equation and the results are reported for the model that adjusts for the unequal variances (Wooldridge, Reference Wooldridge2013).

Simulation

The simulation was developed assuming cattle prices and feed price were stochastic. Hay prices were randomly drawn from the Gray-Richardson–Klose–Schumann (GRKS) distribution. The GRKS distribution is useful when minimal information is available about the distribution, requiring only minimum, midpoint, and maximum values as the bounds for the distribution (Richardson, Reference Richardson2006). The GRKS distribution is a two-piece normal distribution with 50% of the observations below the midpoint and 2.5% below the minimum value, while 50% of the observations are above the midpoint and 2.5% above the maximum value (Richardson, Reference Richardson2006) and frequently used in analyzing beef cattle net returns (Henry et al., Reference Henry, Boyer, Griffith, Larson, Smith and Lewis2016; McFarlane, Boyer, and Mulliniks, Reference McFarlane, Boyer and Mulliniks2018). We select a minimum of $25/ton and maximum of $60/ton with the mid-point of $45/ton. These prices were based on producer suggestions of hay prices. The corn gluten feed and soybean hull prices were assumed to be deterministic and the stochastic hay price results in the stochastic feed cost. We choose to only make hay price stochastic since it is most of the feed cost.

Calves weaning weights were randomly drawn from a truncated normal distribution with the lower and upper bound being the minimum and maximum of the data found in Table 4, respectively. These random weights feed into the price estimate to generate a random cattle price (equation 2). Finally, a truncated normal distribution was used to simulate price premiums for stocker cattle. There are several studies that suggest price premiums for preconditioned calves with a range of reports from zero to $6 per hundred weights (Garber et al., Reference Garber, Alwang, Norton and Bovay2022; Williams et al., Reference Williams, Raper, Devuyst, Peel, Williams, Raper, Devuyst, Peel and Mckinney2012, Reference Williams, DeVuyst, Peel and Raper2014; Zimmerman et al., Reference Zimmerman, Schroeder, Dhuyvetter, Olson, Stokka, Seeger and Grotelueschen2012). In this study, it is assumed producers could receive a price premium for cattle that were in a stocker phase before selling. The low and higher were selected from the literature as zero to $6/cwt (Garber et al., Reference Garber, Alwang, Norton and Bovay2022; Williams et al., Reference Williams, Raper, Devuyst, Peel, Williams, Raper, Devuyst, Peel and Mckinney2012, Reference Williams, DeVuyst, Peel and Raper2014; Zimmerman et al., Reference Zimmerman, Schroeder, Dhuyvetter, Olson, Stokka, Seeger and Grotelueschen2012).

For each herd size, stocker length, and calving season, the price will vary based on the number of calves being sold, month calves are sold, sex, stochastic weaning weight, and stochastic price premium. We assume all calves are black hided, home raised, and average corn price from these data. This is substituted into equation (1) along with the stochastic weaning weights, head sold, and stochastic production costs.

Stochastic dominance was then used to compare the distributions of net returns. In first-degree stochastic dominance, the scenario with cumulative density function (CDF) F dominates another scenario with CDF G if F(π) ≤ G(π)∀π (Chavas, Reference Chavas2004). First-degree stochastic dominance often does not find one scenario to clearly be preferred to another; therefore, second-degree stochastic dominance adds the restriction that producers are risk averse, which increases the chance of finding a preferable scenario (Chavas, Reference Chavas2004). Second-degree stochastic dominance states the scenario with CDF F dominates another scenario with CDF G if G $\int F(\pi )d\pi \leq \int G(\pi )d\pi \forall \pi$ (Chavas, Reference Chavas2004).

Simulation and Econometrics to Analyze Risk (SIMETAR©) was used to develop the distributions and perform the simulations (Richardson et al., Reference Richardson, Schumann and Feldman2008). A total of 1,000 net return simulated iterations were generated for each scenario.