2.1. Data Source

The data used in this study are from the database of the Ministry of Agriculture and Hydro-Agricultural Development (MAAH) of Burkina Faso. They come from the results of the Permanent Agricultural Survey (EPA) conducted in 2019. The EPA is a production survey for agricultural data which main purpose is to estimate annual production volumes. It provides decision-makers with forecasts of grain harvests by state and postharvest estimates of agricultural production by commodity and state. All the information used in the analysis comes from a single database. The survey aims to collect detailed information on the socioeconomic characteristics of households, farm characteristics, farming techniques used, food, and nutritional security. It also provides estimates for key food and nutrition security indicators. The survey covers farm households in all 45 provinces of Burkina Faso. The sampling procedure is a two-stage, stratified procedure. In the first stage, primary units (villages) are drawn with probability proportional to the number of farm households and without replacement. In the second stage, secondary units (households) are selected by simple random drawing without replacement. Each household in the same primary unit has the same probability of appearing in the sample. The survey included a nationally representative sample of approximately 5,304 farm households, representing three households in each of the 1768 villages. Credibility is measured by the 95% confidence level.

The sample selected concerns heads of households engaged in agriculture. Similarly, the southwestern region was removed from the database due to numerous missing data. This restriction yields 4,398 agricultural households distributed in 1,466 villages, i.e., three agricultural households per village.

2.2. The Bivariate Probit Model as a Method for Analyzing the Determinants of Agricultural Technology Adoption

To consider the possible interdependence in the adoption of agricultural practices, two types are distinguished: short-term agricultural practices (Zaï, half-moons, and stone cords) and long-term practices (agroforestry). This interrelationship between technology adoption decisions accounts for multiple resource problems by adopting practices that provide the greatest economic benefits to farmers. The analysis is based on the fact that the decision to adopt short-term cropping practices may not be an independent decision, but rather an interdependent one; the two common decisions may be correlated.

Unlike the univariate probit model, the bivariate probit model allows the joint estimation of the probabilities of two events, taking into account the possible relationship between the error terms of the two estimated equations (Greene, Reference Greene1996). The correlation between the adoption of agricultural practices indicates either complementarity (positive correlation) or substitutability (negative correlation). Treating separately the decision to adopt agricultural practices would lead to biased estimates because the univariate probit model ignores the correlation between disturbances in the underlying stochastic utility function associated with short- and long-term practices (Greene, Reference Greene1996). The two dichotomous response variables, Y ₁ and Y ₂, are coded 1 if the farmer adopts at least a short- and/or long-term agricultural technology and 0 if he adopts none of the practices. The bivariate probit model is specified as follows:

(1) $$\{ Y_1^* = {a_1}{\rm{D}}{{\rm{P}}_1} + {X_1}{\beta _1} + {\varepsilon _1}$$

(2) $$\{ \;Y_2^* = {a_2}{\rm{D}}{{\rm{P}}_2} + {X_2}{\beta _2} + {\varepsilon _2}$$

The two errors are assumed to be independent of the explanatory variables X ₁ and X ₂. The observed dichotomous results are specified as follows:

(3) $${Y_1} = \left\{ {\matrix{ {1{\rm{ }}} & {siY_1^* > 0} \cr {0,} & {otherwise} \cr } } \right.$$

(4) $${Y_2} = \left\{ {\matrix{ {1{\rm{ }}} & {siY_2^* > 0} \cr {0,} & {otherwise} \cr } } \right.$$

Where y ₁* and y ₂* represent the unobserved utilities associated with the adoption of the short- and long-term agricultural practices, respectively; DP₁ and DP₂ represent the permanent property rights in each of the equations; X ₁ and X ₂ are vectors of potential explanatory variables that influence the decision to adopt a particular technology (control variables); a ₁; a ₂; β₁ and β₂ are vectors of the associated parameters to be estimated. In this model, the stochastic errors, ϵ₁ and ϵ₂ are assumed to be normally distributed with:

(5) $$\left\{ {\matrix{ {{\varepsilon _1} = {\eta _t} + {\mu _1}} \cr {{\varepsilon _2} = {\eta _t} + {\mu _2}} \cr } \quad } \right.{\mkern 1mu} {\rm{where}}\left( {\matrix{ {{\varepsilon _1}} \cr {{\varepsilon _2}} \cr } } \right) = {\rm{var}}\left( {0,\Sigma } \right){\rm{with}}{\mkern 1mu} \Sigma = \left[ {\matrix{ 1 & {{\rho _{1,2}}} \cr {{\rho _{2,1}}} & 1 \cr } } \right]$$

The errors in these two equations consist of a part (ηi) that is common to both and a part that is unique to each equation (μ _1i and μ _2i ) ; μ _1i and μ _2i are assumed to be zero mean, independent of the explanatory variables, and normally distributed. The related ϵ _1i and ϵ _2i have a bivariate normal distribution that hides several simultaneous choices and can be derived from the joint distribution of y ₁ and y ₂ on condition of X ₁ and X ₂. These joint probabilities can be identified as follows:

(6) $$Pr\left(Y_{1}=1, Y_{2}=1|X_{1}, X_{2}\right)=\Pr \left(\varepsilon _{1}\gt -X_{1}\beta _{1}, \varepsilon _{2}\gt -X_{2}\beta _{2}\right)=\varphi _{2}\left(X_{1}\beta _{1},X_{2}\beta _{2}, \rho \right)$$

(7) $$Pr\left(Y_{1}=1, Y_{2}=0|X_{1}, X_{2}\right)=\Pr \left(\varepsilon _{1}\gt -X_{1}\beta _{1}, \varepsilon _{2}\lt -X_{2}\beta _{2}\right)=\varphi _{2}\left(X_{1}\beta _{1},-X_{2}\beta _{2},-\rho \right)$$

(8) $$Pr\left(Y_{1}=0, Y_{2}=1|X_{1}, X_{2}\right)=\Pr \left(\varepsilon _{1}\lt -X_{1}\beta _{1}, \varepsilon _{2}\gt -X_{2}\beta _{2}\right)=\varphi _{2}\left(-X_{1}\beta _{1},X_{2}\beta _{2},-\rho \right)$$

(9) $$Pr\left(Y_{1}=0, Y_{2}=0|X_{1}, X_{2}\right)=\Pr \left(\varepsilon _{1}\lt -X_{1}\beta _{1}, \varepsilon _{2}\lt -X_{2}\beta _{2}\right)=\varphi _{2}\left(-X_{1}\beta _{1},-X_{2}\beta _{2}, \rho \right)$$

Where Pr denotes the probability and ϕ2 represents the bivariate standard normal cumulative distribution function. Using the maximum likelihood method, the log-likelihood function of the bivariate probit model is given by

$$lnL\left(\beta _{1},\beta _{2},\rho \right)=\sum Y_{1}Y_{2}ln\varphi _{2}\left(X_{1}\beta _{1},X_{2}\beta _{2},\rho \right)+\sum Y_{1}\left(1-Y_{2}\right)ln\varphi _{2}\left(X_{1}\beta _{1},-X_{2}\beta _{2},-\rho \right)$$

(10) $$+\sum \left(1-Y_{1}\right)Y_{2}ln\varphi _{2}\left(-X_{1}\beta _{1},X_{2}\beta _{2},-\rho \right)+\sum \left(1-Y_{1}\right)\left(1-Y_{2}\right)ln\varphi _{2}\left(-X_{1}\beta _{1},-X_{2}\beta _{2},\rho \right)$$

The correlation coefficient Rho (ρ) is interpreted as the correlation between the adoption decisions of a short-term pratique and a long-term pratique. If ρ = 0, then the errors are independent and the two decisions are uncorrelated. If ρ ≠ 0, then the errors and the decisions are correlated and the probability of adopting a short-term technology depends on the probability of adopting a long-term technology. The coefficient ρ allows analyzing the dependence or synergistic relationship between the adoption of agricultural practices as a function of the technical complexity of each process. When rho is positive and significantly different from zero, there is a complementary relationship between short-term and long-term agricultural practices. When rho is negative, there is a relationship of substitutability. The specified model is presented as a system of equations:

(11) \begin{align}\textit{Adoption}\left(Y_{1}\right)&=\beta _{0}+\beta _{1}\textit{Landright}+\beta _{2}\textit{Gender}+\beta _{3}Age+\beta _{4}Age^{2}+\beta _{5}\textit{Literacy}\\ &\quad+\beta _{6}\textit{Householdsize}+\beta _{7}\textit{Surface}+\beta _{8}MFO+\beta _{9}IGA+\beta _{10}\textit{Training}\\ &\quad+\beta _{11}\textit{Relief}+\beta _{12}\textit{Collman}+\beta _{13}\,\textit{Paidlabor}+\beta _{14}\textit{Credit}+\beta _{15}Seed+\varepsilon _{1}\end{align}

(12) \begin{align}\textit{Adoption}\left(Y_{2}\right)&=\mu _{0}+\mu _{1}\textit{Landright}+\mu _{2}\textit{Gender}+\mu _{3}Age+\mu _{4}Age^{2}+\mu _{5}\textit{Literacy}\\ &\quad+\mu _{6}\textit{Householdsize}+\mu _{7}\textit{Surface}+\mu _{8}MFO+\mu _{9}IGA+\mu _{10}\textit{Training}\\ &\quad+\mu _{11}\textit{Relief}+\mu _{12}\textit{collman}+\mu _{13}\,\textit{Paidlabor}+\mu _{14}\textit{Credit}+\mu _{15}Seed+\varepsilon _{2}\end{align}

Variables are described in Table 1.

Table 1. Description of model variables

In addition to the bivariate probit model, an impact analysis method is used.

2.3. PSM as a Method for Analyzing the Impact of Practices on Income and Food Insecurity

Several methods can be used to analyze the impact of agricultural technology adoption on household income and food security. The PSM method (Rubin, Reference Rubin1977; Rosenbaum and Rubin, Reference Rosenbaum and Rubin1983) is used in this study. Its basic principle is to create a comparison group by matching adopters of agricultural practices with similar nonadopters based on predicting their likelihood of participating to the intervention or program. This is called a propensity score, which is calculated using several observed characteristics. The PSM is used to estimate the average treatment effect (ATE) of short- and long-term adoption of agricultural practices on income and food insecurity. In this case, treatment households (farmers who have adopted the practices) are compared to control households (who have not adopted the practices). More specifically, the technique involves selecting for each farmer i in the user subpopulation a farmer j in the nonuser subpopulation with the same characteristics as farmer i based on pretreatment observable characteristics and then measuring the average difference in the outcome variable between users and nonusers.

The PSM method is a robust impact evaluation method that should be used when extensive data are available. The results of applying PSM are only valid if all important characteristics are observable and included. Otherwise the results may be biased. A bivariate probit model is used in which the adopters of short-term and long-term practices are explained by several preparatory characteristics. The preprocessing characteristics of the model are: the variables used must be observable; the sample size must be large; the existence of two groups of individuals and the individuals in the untreated group must be greater than those in the treated group. Then, the predictions from this estimation are used to create the propensity score, which varies from 0 to 1. Here, the Propensity Score is estimated as the probability of adopting a short-term and long-term technology using vector X as the conditional factor. The equation for the score is as follows:

(13) $$PS=P(D=1|X)$$

P (.): the probability; D: the participation indicator; X: the conditioning factor

1|X : denotes the farmer’s decision to adopt a given agricultural technology, given observable characteristics.

The ATE measures the average impact of an innovation on a sample as a whole and represents the expected impact on a randomly selected individual in the sample. It is defined as follows:

(14) $$ATE=E\left(Y_{1i}-Y_{0i}\right)=E\left(Y_{1i}\right)-E\left(Y_{0i}\right)$$

E (.) denotes the expectancy; Y _1i   represents the observed outcome for the adopting farmer i and Y _0i the observed outcome for the non-adopting farmer.

The ATE on the Treated (ATT) determines the average impact of an innovation in the subpopulation of treated individuals. Here, it represents the expected impact on a randomly selected user among farmers who adopted the agricultural practices.

(15) $$ATT=E\left(Y_{1i}-Y_{0i}|T_{i}=1\right)=E\left(Y_{1i}|T_{i}=1\right)-E\left(Y_{0i}|T_{i}=1\right)$$

Short-term and long-term agricultural practices are the treatment variables, while income and food insecurity are the outcome variables. The average total income of the household head is approximated by his or her total consumption expenditures on food (groceries, beverages, etc.) and nonfood items (health, education, inputs, etc.).

(16) $$Y_{i}=\sum y_{i,k}$$

Where Y _i is the overall average income of the farm household head and Y _{i, k} is the average income by type of good consumed. Incomes are valued in dollars for the purposes of this research.

Food consumption indicators are intended to provide quantitative or qualitative information on household diets. According to the World Food Program (WFP), the most commonly used indicator for assessing the accessibility dimension of food security is the food consumption score. This is a proxy indicator that reflects dietary diversity and the caloric value of the food consumed. The Food Consumption Score (FCS) is determined using a questionnaire consisting of eight food groups. Each food group has a specific weighting that determines the energy value of the food. This is done by multiplying the number of days a particular food group was consumed by the weight of the corresponding group. Foods are classified by food groups and the respective consumption frequencies for each of these groups are added. The FCS is calculated according to the following formula:

(17) $$SCA=\sum x_{i}a_{i}$$

With x _i the number of days of consumption for each food group and a _i the weight assigned to food group i (i = 1, …, 8). a ₁ = 3 for pulses; a ₂ = 2 for cereals and tubers; a ₃ = 1 for vegetables; a ₄ = 1 for fruits; a _{5 =} 4 for meat and fish; a ₆ = 4 for milk; a ₇ = 0.5 for sugar; a ₈ = 0.5 for oil.

2.4. Descriptive Statistics for Variables Affecting the Adoption of Agricultural Practices

Table 2 presents the descriptive statistics for the variables in the model. The statistics for the demographic variables show that, on average, 52.28% of farmers are male. In addition, 26.17% of the sampled households are literate in at least one national or French-Arabic language. Farmers’ age varies from 16 to 79 years with an average age of 49 years. The households’ size varies from 1 to 63 with an average of 11 people. The phenomenon of population growth combined with soil degradation is forcing more and more households to farm on plots averaging 0.54 hectares with a maximum area of 22.32 hectares.

Table 2. Descriptive statistics for variables

In terms of the agricultural practices studied, the adoption rate of short-term practices is 15.88%. Of the total sample, only 17.1% of households have adopted stone cords, 16.21% have adopted Zaï, and 14.34% have adopted half-moon far. Similarly, 10.7% of the sampled households have adopted the long-term agricultural technology of agroforestry.

Statistics also indicate that 61.3% of the surveyed households have permanent property rights. Of these households, 10.85% have adopted agroforestry, while 49.43% use short-term practices. In addition, more than half of the farms are collectively managed. In fact, 52.31% of farms are collective farms, and of these collective farms, 7.2% of households have adopted short-term practices and 11.2% have adopted long-term practices.

In addition, more than a quarter of the households in the sample are members of a farmers’ organization, while 35% report having received agricultural training. The statistics also show that 10.75% of the sample employ paid labor on their farms and 28.89% are members of a rural producer organization. Of the farmers who belong to producer organizations, 52.35% have adopted at least one short-term technology and 14.38% have adopted agroforestry. In addition, the statistics show that 15.54% of the sample received credit during the last agricultural year. 52.01% of the farmers who received credit adopted short-term practices and 16.13% of these beneficiaries’ practiced agroforestry. The majority of farmers use local seeds on their farms (87.77%).

The following section presents and discusses findings of the econometric estimates.