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Economic Implication of Grazing and Water Resource Scarcity on Households’ Welfare and Food Security in Tigrai, Ethiopia

Published online by Cambridge University Press:  15 November 2018

Abstract

In this paper, I have explored the link between grazing and water resource scarcity and per capita food consumption expenditure as a proxy for welfare and food security using distance and shadow price as a resource scarcity indicator in Northern Ethiopia based on a unique data set for 518 sample farmers. To address my objectives, I employed an IV 2SLS model for estimating welfare and probit for analyzing food security, drawing on a separable farm household model. My results confirmed the theoretical prediction that grazing and water affect households’ welfare and food security adversely, as predicted by the downward spiral hypothesis.

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Research Article
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Many studies have established that the rural poor in developing countries are heavily dependent on local natural resources for their sustenance (e.g., Narain, Gupta, and Van't Veld Reference Narain, Gupta and Van't Veld2008) and that degradation of resources hurts the poor more (Khan Reference Khan2008). The downward spiral hypothesis states that people in poverty are forced to deplete resources to survive, and this environmental depletion further impoverishes them (Ostrom et al. Reference Ostrom, Burger, Field, Norgaard and Policansky1999). Land degradation in Sub-Saharan Africa (SSA) remains a substantial problem, spurring rural poverty (Bhattacharya and Innes Reference Bhattacharya and Innes2006, Tesfa and Mekuriaw Reference Tesfa and Mekuriaw2014). It directly aggravates poverty by reducing the availability of environmental goods and services and by increasing the labor input needed to seek such goods in East Africa (Lal and Stewart Reference Lal and Stewart2010, Bezabih and Berhane Reference Bezabih and Berhane2014). World Bank (2012) reported that the cost of environmental degradation is almost 8 percent of the GDP across countries, consisting of 40 percent of the developing countries.

Livestock production depends on quantity and quality of feed and water. About 10 percent of cropland is used to produce crop residues for feeding livestock, and animals in the extensive system need more water per animal (Bezabih and Berhane Reference Bezabih and Berhane2014). Increasing scarcity of grazing and water for an animal can be a significant burden to households, because grazing and water are key factors in livestock production. Thus, the scarcity of these resources may impact agriculture by reallocating production factors such as labor from agriculture, food preparation, and leisure activities into searching for and collecting the resources. Reductions in agricultural output stemming from reduced labor input are likely to have detrimental welfare and food security consequence (Kumar and Hotchkiss Reference Kumar and Hotchkiss1988, Cooke Reference Cooke1998, Alemu, Damte, and Deribe Reference Alemu, Damte and Deribe2015). The critical shortage of water and feed for an animal has negative implications for agricultural production and food security, particularly for poor people who rely on agriculture as a source of food and spend considerable time collecting these resources (Yilma et al. Reference Yilma, Guernebleich, Sebsibe and Fombad2011, Alemu, Damte, and Deribe Reference Alemu, Damte and Deribe2015).

Poverty and resource degradation appear to go hand in hand in SSA. Resource degradation, by all accounts, is rampant in the region. In many studies of Africa, feed and water scarcity are frequently mentioned constraints for animal farming activities (Tegegne Reference Tegegne2012, Bezabih and Berhane Reference Bezabih and Berhane2014). In Ethiopia, resource depletion has contributed to the existing problem of food insecurity and is still a real threat to the agricultural farming (Bewket Reference Bewket2011). In the study area, environmental depletion has reached a critical stage, posing a major threat to agriculture production and welfare Gebreegziabher et al. Reference Gebreegziabher, Nyssen, Govaerts, Getnet, Behailu, Haile and Deckers2009). Grazing and water scarcity may be less problematic in developed countries where there are available substitutes but can have a huge impact on household welfare in Developing countries such as Ethiopia. Households with scarcity may walk longer distances to search for and collect these resources, leaving less labor for leisure and food production and preparation (Cooke, Köhlin, and Hyde Reference Cooke, Köhlin and Hyde2008, Bezabih and Berhane Reference Bezabih and Berhane2014).

The literature suggests that as a result of increasing resource scarcity, many households increase the time they spend on collecting them. Overall, the scarcity has negative implications for agricultural production and food security by diminishing households’ food supply and incomes, and hence their capacity to acquire food and nutrition (Tangka and Jabbar Reference Tangka and Jabbar2005, Cooke, Köhlin, and Hyde Reference Cooke, Köhlin and Hyde2008, Damte, Koch, and Mekonnen Reference Damte, Koch and Mekonnen2012, Alemu, Damte, and Deribe Reference Alemu, Damte and Deribe2015). Cooke (Reference Cooke1998) revealed that most of the reallocated time for searching and collecting the scarce resources comes from leisure before agricultural labor time is reduced. One early analysis conducted by Bandyopadhyay, Shyamsundar, and Baccini (Reference Bandyopadhyay, Shyamsundar and Baccini2011) also indicates that the amount of biomass negatively affected rural per capita consumption expenditure in Malawi. Grazing and water scarcity in Ethiopia can affect household welfare in different ways. Poor farmers may not have access to alternative feed resources and may increase the time spent on searching for grazing and water and straw collection, reducing time on farming activities, food preparation, leisure, or household care. Thus, under situations where markets are imperfect, increasing resource scarcity can force households to reallocate labor, thereby reducing welfare.

While the above studies estimate the effect of resource scarcity on time allocation and time reduction for farming, no study of which I am aware examines the economic effect of grazing and water scarcity on welfare, which is ultimately what policymakers seek to know (Tangka and Jabbar Reference Tangka and Jabbar2005, Cooke, Köhlin, and Hyde Reference Cooke, Köhlin and Hyde2008, Khan Reference Khan2008). In this study, I estimate the effect of grazing, water, and straw scarcity on per capita food consumption expenditure (PCFE) (welfare) and food security using distance and shadow priceFootnote 1 as a proxy for scarcity indicator of these resources by exploiting household survey from Northern Ethiopia. My analysis is organized around four questions. First, what is the effect of resource scarcity on welfare (PCFE)? Second, how does resource scarcity affect household food security? Third, does the effect worsen the top quantile? Fourth, what is the total welfare effect of the scarcity?

In line with this, I hypothesize that the scarcity has a negative effect on households’ food security and welfare (PCFE) either by affecting livestock production directly, affecting crop and off-farm income, or through direct impact on time for leisure consumption drawing on a separable farm household model. I also hypothesize that the effect of these scarce resources is not uniform across the food consumption distribution. In aggregate, the principal findings confirmed the theoretical prediction that resource scarcity affects household welfare (PCFE) and food security adversely as predicted by the downward spiral hypothesis. The estimated result from both distance and shadow price revealed that reducing time spent for searching for water, grazing, and collecting crop residue leads to an increase in welfare (PCFE) and food security.

This paper builds on the existing literature in a number of respects. In this paper, I contribute to the literature by using a unique dataset to investigate how the distance to or the shadow price of water, grazing, and crop residue affects PCFE and food security. I am able to estimate causal relationships with our data because, unlike previous studies, I collected information on the entire set of consumption expenditure, along with the distance to grazing, water, and crop residue for each household. Furthermore, unlike the previous studies, I use distance and shadow price as a proxy measure of resource scarcity. This paper joins the relatively scarce empirical literature on this topic in Africa – one that is dominated by South Asian cases such as NepalFootnote 2.

Review of Background and Empirical Literature

The contribution of livestock to the world's food supply, family nutrition, income, employment, soil fertility, and transport contributes to food security and poverty reduction (Randolph et al. Reference Randolph, Schelling, Grace, Nicholson, Leroy, Cole and Ruel2007). Livestock also provides a safety net in the form of liquid assets and a strategy of food production diversification (Freeman et al. Reference Freeman, Kaitibie, Moyo and Perry2007). In Ethiopia, the agricultural sector is a cornerstone of the people's economic and social lives. Livestock contribution accounts for 40 percent of total agricultural GDP, excluding the values of draft power, manure, and transport service (Asresie and Zemedu Reference Asresie and Zemedu2015). Despite its large population size, the contribution of livestock production to agriculture is deteriorating (Ilyin Reference Ilyin2011). Livestock production in Ethiopia depends on the quantity of grazing, feed, and water (Bezabih and Berhane Reference Bezabih and Berhane2014). This sector is a key player in increasing water use and water depletion (Steinfeld et al. Reference Steinfeld, Gerber, Wassenaar, Castel and de Haan2006).

Both human and livestock suffer from its shortage. Most of the year, animals have to walk long distances in search of water. Despite that major feed resources are crop residues and natural pasture, their availability is gradually declining as a result of crop expansion, settlement, and land degradation (Yimer Reference Yimer2005, Gebremedhin Reference Gebremedhin2009). With regard to this, Hassen et al. (Reference Hassen, Ebro, Kurtu and Treydte2010) revealed that shortage of water and feed are common problems in the dry season as opposed to the wet season. The case study by Belay et al. (Reference Belay, Getachew, Azage and Hegde2013) indicated that the most important problems of livestock production perceived were feed shortage (100 percent) and water shortage (27 percent) during the dry season in Ethiopia.

Poor farmers, who are directly dependent on these local natural resources are highly affected by resource scarcity. Cooke (Reference Cooke1998) revealed that reallocation of time away from leisure occurred as environmental goods become scarcer in Nepal. Kumar and Hotchkiss (Reference Kumar and Hotchkiss1988) suggested that deforestation has adverse effects on agricultural production, food consumption and nutrition in Nepal. In addition, Tangka and Jabbar (Reference Tangka and Jabbar2005) show that feed scarcity in Kenya increases livestock traveling distances in search of feed and water that increase household’ time for collection, resulting in lower livestock and crop output, which further diminishes households’ food and nutrition security. Likewise, Cooke, Köhlin, and Hyde (Reference Cooke, Köhlin and Hyde2008) found a negative effect of resource scarcity on health, labor burden, and agriculture in Nepal. Bhattacharya and Innes (Reference Bhattacharya and Innes2006) highlighted that forest degradation spurs rural poverty in SSA. According to Bandyopadhyay, Shyamsundar, and Baccini (Reference Bandyopadhyay, Shyamsundar and Baccini2011), in Malawi, more time spent on scarce fuelwood collection was associated with negative welfare.

Dasgupta (Reference Dasgupta2007) warns that the average per capita consumption level may decline with degradation of resources. Aggrey et al. (Reference Aggrey, Wambugu, Karugia and Wanga2010) showed that deforestation and degradation were positively linked with poverty in Uganda. The findings of Khan (Reference Khan2008) in Pakistan supported that environmental degradation hurts the poor the most. Baland et al. (Reference Baland, Bardhan, Das, Mookherjee and Sarkar2010) indicate that an increase in firewood collection time lowers the living standards of households in Nepal. Aluko (Reference Aluko2004) showed that deterioration in the quality of life increases with increasing environmental degradation in Niger. Alemu, Damte, and Deribe (Reference Alemu, Damte and Deribe2015), in their analysis, show that fuelwood scarcity has a negative impact on time spent on agriculture; however, scarcity of water has no effect on time spent on agriculture in Ethiopia. Likewise, Mekonnen et al. (Reference Mekonnen, Bryan, Alemu and Ringler2017) indicated that agricultural productivity decreases with increasing time spent on collecting animal dung but increases with time spent on collecting crop residue. Boone, Glick, and Sahn (Reference Boone, Glick and Sahn2011) suggest that a long distance to a water source increases water-gathering time in Madagascar.

In spite of the recognized contributions of the existing studies, none of the above studies examine the effect of grazing and water on welfare and food security (Tangka and Jabbar Reference Tangka and Jabbar2005, Cooke, Köhlin, and Hyde Reference Cooke, Köhlin and Hyde2008). Therefore, this study makes a noteworthy contribution in pointing out the relevance of improving feed and water management for the animal.

Theoretical Model

The contribution of livestock to food and nutritional security in developing countries is significant (Swanepoel et al. Reference Swanepoel, Stroebel and Moyo2010). In a mixed crop-livestock, Ethiopia owns a significantly large livestock population, and its production mainly depends on natural resources such as grazing land, water, and crop residue (Bezabih and Berhane Reference Bezabih and Berhane2014). Ethiopian farmers usually experience a serious seasonal fluctuation in fodder and water availability for the animal. The dependence on these resources implies that scarcity can have a huge impact on household welfare (Bewket Reference Bewket2011, Bezabih and Berhane Reference Bezabih and Berhane2014). In rural farm households, in which the farmer is engaged in both crop and livestock production activity, total time endowment is divided into three main activities: farm activities, off-farm activities, and leisure. However, considering the scarcity of these resources, the total time endowment will further include a fourth activity – collecting scarce resources.

I start with the downward spiral hypothesis that states that people in poverty are forced to deplete resources to survive, and this environmental depletion further impoverishes them (Ostrom et al. Reference Ostrom, Burger, Field, Norgaard and Policansky1999). It is supposed that the scarcity of resource can affect household well-being either by affecting livestock production directly, affecting crop and off-farm income (via labor reallocation) or through its direct impact on time for food preparation or leisure consumption (Cooke, Köhlin, and Hyde Reference Cooke, Köhlin and Hyde2008, Alemu, Damte, and Deribe Reference Alemu, Damte and Deribe2015). To conceptualize the effect of resource scarcity on welfare and food security, I develop a theoretical model within the framework of household utility model following the work of Strauss (Reference Strauss, Singh, Squire and Strauss1986) and later Faridi and Wadood (Reference Faridi and Wadood2010), which fits in to the separable farm household model. I suppose that rural households are characterized as both producers and consumers of their food; thus, a household strictly quasi-concave utility function based on the framework of consumer demand and production theories is presented as follows:

(1)$$U_i = U\lpar C_i\comma \; C_n\comma \; C_m\comma \; L_l\semicolon \; \Gamma \rpar \comma \; $$

where U i is a utility function that is twice differentiable, increasing in its arguments and strictly quasi-concave; C i and C n are vectors of home-produced food and nonfood goods consumed by the i th household; C m is a market-purchased good consumed, L l is leisure, and Γ is the vector of household sociodemographic variables. C n, in this case represents the demand for nonfood items such as education, health, and housing. Equation 1 leads us to the generalized utility function developed by Becker (Reference Becker1991), which requires that production decision is first made to maximize profit and household maximizes utility using this maximum profit consecutively (Strauss Reference Strauss, Singh, Squire and Strauss1986). The meal production is a function of agricultural goods (Q i), off-farm income (E), fuel sources such as straw or dung (E f), and labor days the household would spend on searching for grazing land, water, and crop residue (L c), The production of household goods is also influenced by the vector of household characteristics

(2)$$C_i = C\lpar E_f\comma \; Q_i\comma \; E\comma \; L_c\semicolon \; {\rm \phi} \rpar .$$

The rural household is assumed to maximize its utility subject to farm production, income, and time constraints specified as:

(3)$$F\lpar Q_i\comma \; L\comma \; L_c\comma \; K\comma \; A\rpar = 0.$$

Equation 3 is a typical household implicit production function for food, Q i produced at home and assumed to be twice differentiable, increasing in outputs, decreasing in inputs, and strictly convex; L is the total labor input used on the farm; L c is the time spent on searching for grazing, water, and collecting crop residue; K is the fixed capital stock, A is the farm size; labor time is an important resource denoted by T, and it is allocated among crop farming activities L a, searching for and collecting scarce resource L c and leisure L l supplied by the household:

(4)$$L_a + L_c + L_l.$$

At the same time, the income constraint for the rural household is given by

(5)$$P_i\lpar Q_i-C_i\rpar -P_nC_n-P_mC_m-W\lpar L-L_a\rpar + E = 0.$$

P i is the price of price of food produced; P iQ i is a marketed surplus of produced good;P n is the price of nonfood goods; P m is the price of a market-purchased good; W is the wage rate; L a is total family labor supply for on-farm use; E is nonfarm income. Substituting the right-hand side (RHS) of equations 4 into 5 yields:

(6)$$P_i\lpar Q_i-C_i\rpar -P_nC_n-P_mC_m-W\lpar L-{\rm T} + L_c + L_l\rpar + E = 0.$$

Expanding and rearranging equation 6 produces an explicit household income and expenditure:

(7)$$P_iQ_i + \; W{\rm T} + \; E-\; WL-\; WL_c = P_iC_i + P_nC_n + P_mC_m + \; WL_l.$$

The left-hand side of equation 7 represents household's full income, which comprises the value of farm produce P iQ, the value of time endowment WT, nonfarm income E, the value of labor used for farming including the hired labor WL and value of labor spent for searching and collecting scarce resources WL c. Similarly, the right-hand side of equation 7 is the household expenditure on food and leisure. The expenditure side includes purchases of its own produce food consumed, P iC i; the value of nonfood expenditure P nC n, the value of market purchase food consumed P mC m, and purchase of leisure WL l. The optimization of equation 1 yields an income and expenditure equation within the separability assumption. At an interior solution, the household selects L c, L l, L, C i and C m to maximize equation 1 subject to equations 7 and 3, which can be best visualized as:

(8)$$\eqalign{{\rm {\cal L}} &= U\lpar C\lpar E_f\comma \; Q_i\comma \; {\rm E}\comma \; L_c\semicolon \; {\rm \phi} \rpar \comma \; C_n\comma \; C_m\comma \; L_l\semicolon \; \Gamma \rpar + \lambda \lpar P_iQ_i + \; W{\rm T} + \; E-\; WL-\; WL_c\rpar \cr &\quad- \lpar P_iC_i + P_nC_n + P_mC_m + \; WL_l\rpar + \gamma \lsqb {\rm F}\lpar Q_i\comma \; L\comma \; L_c\comma \; K\comma \; A\rpar \rsqb .} $$

Based on Strauss (Reference Strauss1983), it is possible via optimization of equation 8 yield production and consumption equations separately as discussed below. The first order conditions are:

(8a)$$\displaystyle{{d{\rm {\cal L}}} \over {dL_c}} = \displaystyle{{dU} \over {dC}}\displaystyle{{dC} \over {dL_c}}-{\rm \lambda} W + {\rm \gamma} \displaystyle{{dF} \over {dL_c}} = 0$$
(8b)$$\displaystyle{{d{\rm {\cal L}}} \over {dL_l}} = \displaystyle{{dU} \over {dL_l}}-{\rm \lambda} W = 0$$
(8c)$$\displaystyle{{d{\rm {\cal L}}} \over {dL}} = {\rm \gamma} \displaystyle{{dF} \over {dL}}-{\rm \lambda} W = 0$$
(8d)$$\displaystyle{{d{\rm {\cal L}}} \over {dC_i{\rm \; }}} = \displaystyle{{\partial U} \over {\partial C_i}}-{\rm \lambda} P_i = 0$$
(8e)$$\displaystyle{{d{\rm {\cal L}}} \over {dC_m}} = \displaystyle{{\partial U} \over {\partial C_m}}-{\rm \lambda} P_m = 0$$
(8f)$$\displaystyle{{d{\rm {\cal L}}} \over {dC_n}} = \displaystyle{{\partial U} \over {\partial C_n}}-{\rm \lambda} P_n = 0$$

Maximizing the first-order condition of the LHS of equation 8 with respect to labor (L*)and output produced(Q*), the demand for inputs and output is derived in terms of all prices, the wage rate, time for searching and collecting scarce resource, fixed land, and capital as:

(9a)$$L^{^\ast} = l^{^\ast}\lpar P_i\comma \; P_m\comma \; P_n\comma \; W\comma \; L_c\comma \; K\comma \; A\rpar $$
(9b)$$Q^{^\ast} = Q^{^\ast}\lpar P_i\comma \; P_m\comma \; P_n\comma \; W\comma \; L_c\comma \; K\comma \; A\rpar $$

Substituting optimal labor, L* and optimum output Q* into LHS of equation 7 produces optimum income/full income Y* under the assumption of maximized profit π* as:

(10a)$$Y^{^\ast} = P_iQ^{^\ast} + \; W{\rm T} + \; E-\; WL^{^\ast}-\; WL_c$$
(10b)$$Y^{^\ast} = \; W{\rm T\ +} {\rm \pi} ^{^\ast}\lpar P_i\comma \; P_m\comma \; P_n\comma \; W\comma \; L_c\comma \; K\comma \; A\rpar + E$$

where π*(P i, P m, P n, W, L c, K, A) represents P iQ* − WL* − WL c.

The first order conditions of the RHS of equation 7 give consumption demand function in terms of prices, wage rate and income, and household's preferences represented by household demographic characteristics Γ. This relationship can be specified as:

(11)$$C_d = c\lpar P_i\comma \; P_m\comma \; P_n\comma \; W\comma \; L_c\comma \; Y^{^\ast}\lpar P_i\comma \; P_m\comma \; P_n\comma \; W\comma \; L_c\comma \; K\comma \; A\comma \; E\rpar \semicolon \; \Gamma \rpar .$$

The above equation states that household food consumption C d is mainly influenced by both food and nonfood prices, wages, resource scarcity and household income. Referring to household demand for food as a measure of household food security (FS), then C d is a reduced form of the utility function of equation 1, which allows the evaluation of the effects of demographic and economic variables. Food security is approximated by food consumption expenditureFootnote 3 in this case.

The effect of scarce resources on agricultural production is investigated through the production sector, and its direct impact on household's utility is explored through the consumption sector. Thus, the total effect that is the sum of the two effects can be further explained using equation 11. Because time spent for searching for grazing or water and collecting straw is one explanatory variable of agricultural output function, the total effect of this variable on per capita food expenditure is:

(12)$$\displaystyle{{dC_d} \over {dL_c}} = \displaystyle{{dC_d} \over {dY}}\displaystyle{{dY} \over {dL_c}} + \displaystyle{{dC_d} \over {dL_c}}.$$

Then, the total effect is simply calculated by taking the slope coefficient of income in the consumption regression multiplied by the coefficient of time allocation in the production estimation, plus the coefficient of time allocation in the consumption regression.

Description of the Study Area and Dataset

The study is conducted in the Tigrai region, the northern part of Ethiopia, by randomly selecting 632 sample households. In this region, feed and water deficits start in December, when the natural pastures are at their lowest quantity, and the supply of stored crop residues is starting to diminish (Sileshi, Tegegne and Tsadik Reference Sileshi, Tegegne and Tsadik2003). Likewise, Gebremedhin (Reference Gebremedhin2009) and Yimer (Reference Yimer2005) also revealed that natural grazing is diminishing over time due to the high degree of degradation, resulting in high tropical livestock unit (TLU) per km2 of grazing land. The estimated crop residues are found to be about 1,229,651 tons of dry matter per year while the region has an estimated 878,322 ha of arable land available for crop production, contributing about 45 percent of the animal feed demand. Felleke and Geda (Reference Felleke and Geda2001) also stated that 73 percent of the feed is provided from natural grazing, 14 percent from crop residues, and the remaining 13 percent from other feed sources. A recent study by Bishu (Reference Bishu2014) in Tigrai indicated that there is a livestock drinking water shortage (34 percent) and feed shortages (7 percent). There is also a livestock management labor shortage (Tegegne Reference Tegegne2012).

This study used cross-sectional data from NMBU-MUFootnote 4 Tigrai Rural Household Survey dataset collected in 2015. The data include a panel of five rounds conducted in 1997/1998, 2000/2001, 2002/2003, 2005/2006 and 2014/2015, in which the author was involved only in collecting the data for the last round. The primary data used in this paper are adapted from the last, 2014/2015, household survey. Table 1 presents the summary of basic variables of 518 farm households drawn from 632 sample farmers. The need for information regarding livestock activity restricted us to using only 518 livestock owner-farmers for this study.

Table 1. Descriptive and Summary Statistics

a It includes crop, fruit and vegetable production, and ETB refers to Ethiopian currency in which 1USD ~23 ETB during the study period.

b A household is considered food secure if it attains at least two-thirds of the average PCFE of all households and considered food insecure if it falls below that value.

c It includes income from agriculture, off-farm, business transfer and safety net.

On the welfare side, the dependent variable is PCFEFootnote 5. For each household, expenditure profile on the following seven food groups were recorded: (1) staple foods, including cereals and pulses, (2) meat, egg, and fish, (3) dairy products, (4) fruits and vegetables, (5) fats and oils, (6) sugar and honey, and (7) miscellaneous such as tea and coffee. Likewise, the dependent variable on the production side is an aggregate monetary value of all crops produced during the survey production season. An average household has produced an average agricultural output worth 41,645 ETB, and the average total income including sales from agricultural outputs is worth 49,426 ETB. Households, on average, spend approximately 13571 ETB for food with an average PCFE of 2,490 ETB in the year. I also construct the food security dependent variable by classifying households into food secure and food insecure using a food security index calculated by dividing the individual PCFE to a two-thirds average PCFE of all householdsFootnote 6. Accordingly, a household is considered food secure if it attains at least two-thirds of the average per capita food expenditure of all households and considered food insecure if it falls below that value.

The results in Table 1 showed that 48 percent of the households were food secure, while 52 percent were food insecure, given that two-thirds of the average of all households is 1660 ETB. Feleke et al. (Reference Feleke, Kilmer and Gladwin2005) documented about 40 percent incidence of food insecurity in Ethiopia. Regarding the scarcity indicator, we know that grazing land and water resources are challenging to value because they are not traded and have no market price. Their prices are a shadow price (Magnan, Larson, and Taylor Reference Magnan, Larson and Taylor2012) because shadow prices are assumed to better reflect the economic scarcity of environmental goods to a household (Cooke Reference Cooke1998). For this reason, as a proxy indicator for scarcity, first, I use walking distance in minutes for a single trip to measure grazing, water per day and crop residue per trip using an approach similar to that used by Palmer and MacGregor (Reference Palmer and MacGregor2009). On average, the households spend 1.25 h to reach a water source for animals and 1.5 h to search for communal grazing land daily, with the maximum time reaching up to 6 h/day for water site and 8 h/day for grazing land in the data. Besides, the average time spent on collecting crop residue by the households is 9.6 h per a single trip.

Second, following Baland et al. (Reference Baland, Bardhan, Das, Mookherjee and Sarkar2010), Cooke (Reference Cooke1998), and Alemu, Damte, and Deribe (Reference Alemu, Damte and Deribe2015), I measure the shadow price of searching for grazing and water as well as collecting crop residue for an animal as the time taken to search for grazing land and water per animal or to collect crop residue per its amount collected multiplied by the village median adjustedFootnote 7 off-farm wage. Cooke (Reference Cooke1998) and Alemu, Damte, and Deribe (Reference Alemu, Damte and Deribe2015) use the shadow price of fuelwood, leaf fodder, water, and grass to measure scarcity. In this paper, I take the wage rate at the village level, and thus there is no variation in wages for households living within the same village. In this way, I produce a household specific shadow price of searching for grazing land or water and collecting straw. Table 1 reported that the average shadow price for animal watering is about 147 ETB per day, which is equivalent to the average daily rural wage rate in the region. On average, the opportunity cost of searching grazing is 205 ETB per day, which is greater than the opportunity cost of water and straw. This is not surprising because rural farmers usually spend a huge amount of time in searching for grazing than for watering. As expected, the shadow price of collecting a residual crop is 12 ETB per trip.

Out of the total sample, 6.4 percent lives in the highland parts of the region. Nearly 39 percent of the households report that they have been severely affected by 11 different level of shocks including, drought, pests, flood, theft, illness and death, loss of job, and home damage in the last harvesting season, and 4.25 percent of households report having been affected by animal shocks one year before the harvesting season. Seventy-four percent of the households are male heads, with an average age of 57 and family size of 5.87. Because resources are scarce, high family size may put much more pressure on consumption than it contributes to production.

Nearly 32 percent of the household heads have at least one or more years of primary school education. Thus, it is hypothesized that education is negatively related to consumption value. Around 82 percent of the households are Orthodox followers, while 18 percent of the households are Muslim households in the study area. Out of the 518 households in the sample, 61 percent got assistance either from their relatives or friends and are expected to increase production and consumption (Di Falco et al. Reference Di Falco, Veronesi and Yesuf2011). More than 40 percent of household heads attend media via TV, radio and mobile phone about any development intervention. Hence, it is expected that households with information are more likely to produce more and be food secure. The expected effect on production and consumption is positive (Di Falco et al. Reference Di Falco, Veronesi and Yesuf2011). In addition, the average livestock endowment of the sample households is 4 TLU, which is expected to increase food security.

Econometric Model Specification

In order to estimate the consumption side, the researcher is forced to approximate welfare by PCFE due to limited dataFootnote 8. Assuming that the demand equation from the utility maximization of the recursive household model has a functional form of log-linear, its capability of estimating respective elasticities as its coefficient and modeling nonlinear effects makes it applicable and preferable (Oum Reference Oum1989). Oum added that the log-linear demand function resembles the demand function obtainable from a Cobb-Douglas utility function with the drawback of invariant estimated elasticities across all data points. The aggregate demand equation per household is estimated for PCFE rather than estimating single demand equations for each product consumed or for each individual member of the household. Following Adewuyi, Mafimisebi, and Awe (Reference Adewuyi, Mafimisebi and Awe2009) and Babalola and Isitor (Reference Babalola and Isitor2014), the implicit form of the OLS is given as:

(13)$$\ln C_d = {\rm \delta} + {\rm \delta} Y_i + \mathop \sum \limits_{k = 1}^K {\rm \beta} _k\ln X_i + {\rm \nu\comma \; } $$

where –lnC d is households’ PCFE; Y i is a rural farm and off-farm income; X i for k  =  1… K, includes consumption side variables and household characteristics; X 1 is aggregate monetary value of crop production; X 2 is herd size in TLU; X 3 is family size; X 4 is gender of the household head with male being equal to 1; X 5 refers to the access of information via radio, TV, and mobile in binary form; X 6 reflects the agro-ecological location of each household measured by GPS but classified as highland if it is 2500 masl and lowland if it is below that; X 7 represents market distance in minutes; X 8 and X 9 correspond to the dummy exposure of animal shock in 2013 and cumulative number of shocks from 2012–2014; X 10 = 1 if the household is reported to be orthodox; X 11 = 1 if the household gets assistance from relatives and friends, while X 12 and X 13 capture the age of house head in years and total farm income composed of farm income, off-farm income, business transfer, and safety net income. The resource scarcity is captured by the walking distance to the water source in minutes/day/trip (X 14), walking distance to the grazing source in minutes/day/trip (X 15) and walking distance to the crop residue site in minutes/trip (X 16) per year.

ν is an error term. Because farm and off-farm income are not randomly distributed among rural households, this variable is likely to be endogenous (Hoddinott et al. Reference Hoddinott, Maluccio, Behrman, Flores and Martorell2008), which could be caused by omitted variables, measurement error, simultaneity, or household unobservable. First, a reverse causality problem might exist, because PCFE at the household level might also influence labor productivity and thus farm productivity. Second, farm and off-farm income might be influenced by household unobservable, which can lead to a correlation with the error term. In the presence of endogeneity, the use of the OLS estimator biases the effect of income (Wooldridge Reference Wooldridge2009).

In order to avoid an endogeneity bias, I adopted a two-stage least square (2SLS) approach which is the most common instrumental variable estimator (Angrist and Evans Reference Angrist and Evans1998), where rural farm income is instrumented by shock exposure and average rainfall of 2003–2014. This is similar to approaches that have been used by Sarris, Savastano, and Christiaensen (Reference Sarris, Savastano and Christiaensen2006), Hidalgo et al. (Reference Hidalgo, Naidu, Nichter and Richardson2010), and (Abdulai and Huffman Reference Abdulai and Huffman2014) in different contexts.

Shock caused by crop theft, illness, and death of a household member is expected to affect income and output negatively, thereby reducing food expenditure (Dercon et al. Reference Dercon, Hoddinott and Woldehanna2005, Abdulai and Huffman Reference Abdulai and Huffman2014). The explanation is that farm income is expected to decrease with increasing any shock on crop or animal farming caused by a theft or illness of the household. Then its effect on consumption reaches through its effect on farm income. Our justification for using rainfall is that average shortfall of rainfall influences rural farm income without directly influencing the consumption expenditure in the village (Hidalgo et al. Reference Hidalgo, Naidu, Nichter and Richardson2010). Increasing rainfall is expected to increase farm income directly but consumption indirectly through its effect on income. With this procedure, the structural equation is specified as

(14)$$\ln C_d = {\rm \delta} + {\rm \delta} ^{iv}\hat{Y} + \mathop \sum \limits_{k = 1}^K {\rm \beta} _k\ln X_i + {\rm \varepsilon\comma \; } $$

where ln C d is PCFE, $\hat{Y}$ is the predicted values of the endogenous rural income variables, ε is an error term, and β is the parameter coefficient of the vectors of an exogenous variable, X. To obtain income (Y), the first stage regression equation is estimated by OLS based on the following specifications:

(15)$$\ln Y = {\rm \alpha} + Z^{\prime}{\rm \gamma} + X^{\prime}{\rm \beta} + {\epsilon\comma \; } $$

where lnY is total rural income of the household, γ is the parameter coefficients of the vector of the instrumental variables, and Z are assumed to correlate with income (Y) but not with the error term ε in the structural equation 14. The estimated PCFE of the household in (14) is now assumed to be unbiased. In order to estimate the effects of water and feed scarcity across the entire distribution of the dependent variables and to document the heterogeneity in the way food consumption responds to these scarcity variations, an alternative quantile regression was used following Koenker and Basset (Reference Koenker and Bassett1978).

Per Capita Food Expenditure Estimation (PCFE)

The PCFE is analyzed using the demand functions derived from maximized utility, subject to budget constraint and technology constraint of farm production, and its estimated result is presented in Tables 2 and 3, where walking distance and shadow prices are used as scarcity indicators using naive OLS and IV methods. Tables 2 and 3 compare results from naive OLS and 2SLS estimates for all variables of interest, namely water, grazing land, and crop residue distance. The potential candidate instruments used in the estimation were tested to check if they could pass the necessary requirements to be an instrument. Table 4 reports the test results for all scenarios presented in Table 2 and 3.

Table 2. IV Estimation of Log Per Capita Food Expenditure using Walking Distance

P-Values are for slopes; ***P < 0.01; **P < 0.05 and *P < 0.10  =  Significant at 1, 5, and 10% probability level respectively.

Table 3. IV Estimation of Log Per Capita Food Expenditure using Shadow Prices

P-Values are for slopes; ***P < 0.01, **P < 0.05, and *P < 0.10  =  Significant at 1, 5, and 10% probability level respectively.

Table 4. Instrumental Variables Tests

The Wu-Hausman F-test with a p-value less than 0.05 rejected the null hypothesis that OLS estimation is consistent or income is exogenous and motivates the use of instruments. Besides, the Sargan χ2—test fails to reject the null hypothesis that all instruments are uncorrelated with the error term in the structural model or all instruments are valid, and this helps to conclude that the instruments pass the over-identification requirement for all estimates. Finally, instruments were also tested if they could pass the second most important criteria that the instrument should be correlated or relevant to the endogenous variable income. To ensure the relevance of instruments, the Stock and Yogo (Reference Stock, Yogo, Andrews and Stock2005) F-test was employed and provided higher value F statistics, a great deal higher than the rule of thumb of at least greater than 10.

The first stage regression results of two-stage least square (2SLS) which are not reported here show that both instruments have a statistical relationship with income and carry the expected sign in all scenarios (Tables 2 and 3). Household income is often a major determinant of expenditure (Babalola and Isitor Reference Babalola and Isitor2014). Total income of the household, which has a positive coefficient significantly affected PCFE. Column (1, 3, and 5) of Table 2 shows the income effect by estimating the consumption model using OLS estimator. The coefficient of income suggests that a 1 percent increase in income increases PCFE by around 0.044 percent, whereas the 2SLS result display that a 1 percent increase in total income leads to 0.059 percent increase in PCFE in all estimates. Because, as the income level of the household increases, the household purchasing power increases.

It turns out that this naive ordinary estimate grossly underestimates the income effect compared to effects from the IV-2SLS estimate. This implies that estimating the model using OLS is not the correct approach, and ignoring these differences would bias the income effect. Babalola and Isitor (Reference Babalola and Isitor2014), Njimanted (Reference Njimanted2006), and Thirumarpan (Reference Thirumarpan2013) also confirm that household income is one of the key determinants of food expenditure and food security in rural areas. I also report that farm output significantly affects household food consumption. The elasticity of PCFE with respect to the gross crop value equals to 0.063 percent for IV in the water scarcity estimates. Similar effects are found in the grazing and feed estimates presented in Table 2, columns 3–6. This is in line with Sarris, Savastano, and Christiaensen (Reference Sarris, Savastano and Christiaensen2006), who found that agricultural productivity significantly affects PCFE in Ethiopia. The coefficient's sign and statistical significance show that livestock ownership is positively correlated with PCEF, suggesting that farmers with high herd size have a higher food consumption expenditure. Dercon, Hoddinott, and Woldehanna (Reference Dercon, Hoddinott and Woldehanna2005) in Ethiopia and Sarris, Savastano, and Christiaensen (Reference Sarris, Savastano and Christiaensen2006) in Tanzania found a similar result.

Another significant variable is household size, leading to 0.363 percent decrease in PCFE for 1 percent increase in the number of members of the household. This result is in line with Dercon, Hoddinott, and Woldehanna (Reference Dercon, Hoddinott and Woldehanna2005) and Bezu et al. (Reference Bezu, Kassie, Shiferaw and Ricker-Gilbert2014) in Ethiopia and Sarris et al. (Reference Sarris, Savastano and Christiaensen2006) in Tanzania. A household with a male head has a disadvantage of 13.6 percent decrement in PCFE against the findings of Dercon, Hoddinott, and Woldehanna (Reference Dercon, Hoddinott and Woldehanna2005) in Ethiopia. Individual farmers experiencing an animal shock at least once in the previous year have 39.9, 46.3 and 45.7 percent lower PCFE for the three cases taking the estimated value of IV in Table 2. In line with this, Dercon (Reference Dercon2004) found that a livestock shock negatively affects PCFE in rural Ethiopia.

The coefficient of religion is 14.6 percent and is statistically significant, implying that orthodox households have 0.146 percent PCFE higher than the Muslim group, referring to the IV estimate, which is opposite of the result of Oldiges (Reference Oldiges2012) in India. The negative and significant sign of network shows that individuals who got social supports have 17.2 percent less PCFE, implying that supports from relatives or friends are not adequate enough to cover food expenditure for the recipient households. A similar result was found by Sarris, Savastano, and Christiaensen (Reference Sarris, Savastano and Christiaensen2006). Other insignificant variables are proximity to market (positive), information (positive), and the age of the household head (negative) in line with Matchaya and Chilonda (Reference Matchaya and Chilonda2012) in Malawi.

The main interest of this paper is to explore how time spent for animal feed and water searching directly affects PCFE, and our result is in line with the downward spiral hypothesis (Ostrom et al. Reference Ostrom, Burger, Field, Norgaard and Policansky1999). Using the distance indicator in Table 2, time spent looking for water and grazing land has resulted in a negative sign, and it is found to be an important factor of PCFE. A 1 percent increase in minutes traveled to reach water and grazing land leads to a 0.131 and 0.088 percent decrease in PCFE, respectively, using IV. In addition, a 1 percent increase in minutes traveled to collect crop residue leads to a 0.072 percent decrease in PCFE. Likewise, my results from the shadow price (Table 3) indicate that scarcity of resources has an important impact on the food demand, with the expected result that an increase in the shadow price of water, grazing, and crop residue by 1 percent reduces PCFE by 0.053, 0.067, and 0.044 percent, respectively. This implies that the scarcity has a negative effect on households’ PCFE, either by affecting livestock production directly, affecting crop or off-farm income via labor reallocation or through its direct impact on time leisure consumption.

This result agrees with Bandyopadhyay, Shyamsundar, and Baccini (Reference Bandyopadhyay, Shyamsundar and Baccini2011), whose result revealed that the scarcity of biomass negatively affected rural PCFE in Malawi. Baland et al. (Reference Baland, Bardhan, Das, Mookherjee and Sarkar2010) also showed that an increase in firewood collection time by 1 h/day is equivalent to an income loss of about 1 percent in Nepal. Bhattacharya and Innes (Reference Bhattacharya and Innes2006) highlighted that forest degradation spurs rural poverty in SSA. This supports the argument by Chopra et al. (Reference Chopra, Singh, Gupta, Narain and Veld2007), Cooke, Köhlin, and Hyde (Reference Cooke, Köhlin and Hyde2008), Kumar and Hotchkiss (Reference Kumar and Hotchkiss1988) and Tangka and Jabbar (Reference Tangka and Jabbar2005), whose study conclude that feed and water scarcity reduces livestock, crop, and nonfarm productivity as well as access to food, resulting in less food security and low human welfare by traveling long distance with an animal in search of feed and water in less developing countries.

Estimation of food security is presented in Table 5; the model had about 38 percent prediction power, compared to 48 percent observed probability. The negative significant relationship between the shadow prices and the household food security implies that households that spend more time on searching for water, grazing, and crop residue are more likely to be food insecure than their counterparts with nearer distance. The coefficients from marginal effect indicated that increasing the shadow prices of water, grazing, and crop residue reduces the probability of food security by 0.0594, 0.0533, and 0.0418 percent, respectively, supporting the arguments forwarded by Cooke, Köhlin, and Hyde (Reference Cooke, Köhlin and Hyde2008) and Alemu, Damte, and Deribe (Reference Alemu, Damte and Deribe2015). The results further show that the probability of food security increases significantly and consistently with farm output, total income, and religion in favor of Ogundari (Reference Ogundari2017) but declines with family and herd size, supporting the results from Feleke et al. (Reference Feleke, Kilmer and Gladwin2005).

Table 5. Probit Estimation of Food Security using Walking Distance

P-Values are for slopes; ***P < 0.01; **P < 0.05and *P < 0.10  =  Significant at 1, 5 and 10% probability level respectively.

An alternative is to estimate quantile regressions on food expenditure, to capture the effects of these scarce variables across the entire distribution of the dependent of the variable. A quantile regression is a method of estimating functional relationships between variables for all portions of a distribution function (Koenker and Bassett Reference Koenker and Bassett1978). The hypothesis that the impact of feed and water scarcity strongly increases from the bottom to the top quartile is tested using this quantile regression, and results are displayed in Table 6. The elasticity values associated with a 1 percent change in distance to a grazing land on food production range from −0.0996 percent for the forth quantile to −0.171 percent of top quartile with a median value of −0.100 percent in Table 6. The effect of a 1 percent increase in distance to crop residue source brings about a 0.069 percent reduction in food expenditure only for the top category, while the effect of water is 0.064 percent at the median value. This analysis is relevant not only from the perspective of econometric correctness but also for the purposes of policy. This is an evidence that treating all quantiles as one and hence estimating only one coefficient such as in OLS would be misleading both for policy and inference.

Table 6. Effect of Water, Grazing and Feed Scarcity on Log PCFE using Quintile Regression

P-Values are for slopes; ***P < 0.01; **P < 0.05and *P < 0.10  =  Significant at 1, 5, and 10% probability level respectively.

Total Effect of Feed and Water Scarcity on Food Security

This section discusses the total effect of an animal water and feed scarcity on total welfare effect. Based on equation 12, the total effect is simply calculated by taking the slope coefficient of income in the consumption regression multiplied by the coefficient of time allocation in the production estimation, plus the coefficient of time allocation in the consumption regression that is the total effect of grazing scarcity is the slope coefficient of income (dC d/dY) in the consumption regression multiplied by the coefficient of time spent for searching grazing in the production estimation (dY/dL c) plus the coefficient of time spent for searching grazing in the consumption regression (dC d/dL c); the total effect of water scarcity is the slope coefficient of income (dC d/dY) in the consumption regression multiplied by the coefficient of time spent for searching water in the production estimation (dY/dL c) plus the coefficient of time spent for searching water in the consumption regression (dC d/dL c) and the total effect of straw scarcity is the slope coefficient of income (dC d/dY) in the consumption regression multiplied by the coefficient of time spent for collecting straw in the production estimation (dY/dL c) plus the coefficient of time spent for collecting straw in the consumption regression (dC d/dL c). However, the coefficient of time spent for searching grazing and water or for collecting straw in the production estimation (dY/dL c) is not available here; it is available upon request.

Based on Table 7, the effects of time spent searching for water, feed, and collecting straw on PCFE are −0.142, −0.102, and −0.092 percent, respectively, using distance measure. This implies that for a 1 percent increase in minutes traveled to a water, grazing, and straw source, PCFE decreases by 0.142, 0.102, and 0.092 percent, respectively. If the median household in this data spends about 60 min daily to look for water and feed source and has PCFE 2490 ETB, decreasing traveling minutes to a water, grazing, and straw sources by 0.6 min/day will increase PCFE by 354 (2490*0.142) ETB, 254 (2490*0.102) ETB, and 229 (2490*0.092) ETB, respectively, for the median household using panel A distance value (Table 7).

Table 7. Aggregate Effect of Water and Feed Scarcity on Output, Food Expenditure, and Food Security

Conclusion and Suggestion

The scarcity of grazing and water for an animal has negative effects on a household's welfare and food security, either by affecting livestock production directly, affecting crop or off-farm income via labor reallocation, or through its direct impact on time leisure consumption. My research questions focus on the relationship between natural resources scarcity and PCFE (welfare) and food security. In this paper, I have explored these effects using distance and shadow price as resource scarcity indicators in Northern Ethiopia based on 518 sample farmers. To address the first objective of my research, I employed the IV 2SLS estimation, and the second question is addressed by estimating a probit model for food security. The descriptive result shows that about 48 percent of households were food secure. while 52 percent were food insecure given that two-thirds of the average of all households’ PCFE was 1660 ETB.

My results confirmed the theoretical prediction that resource scarcity affects households’ welfare and food security adversely as predicted by the downward spiral hypothesis (Ostrom et al. Reference Ostrom, Burger, Field, Norgaard and Policansky1999). The results in this paper provide an interesting picture of smallholders in Ethiopia and hint at several areas that could be important for improving food security and welfare in general. As expected, it appears that time spent looking for water and feed has a significant and negative effect on PCFE and food security. In aggregate, reducing time spent looking for water by 1 percent leads to an increase in PCFE by 0.131 percent and food security by 0.0594 percent. Similarly, a 1 percent decrease in time wastage for searching for grazing land increases PCFE and aggregate food security by 0.088 percent and 0.053 percent, respectively. Likewise, an increment of 0.0716 percent in PCFE and 0.0418 percent in food security is achieved by a 1 percent reduction in crop residue transporting time per tripe.

The impact of time spent searching for water and feed and collecting straw on PCFE is −0.142, −0.102 and −0.092 percent, respectively, using distance measure in Table 7. The median household in these data spends about 60 min looking for water and feed sources and has a PCFE of 2490 ETB. For the median household, decreasing traveling minutes to water, grazing and straw source by 0.6 (60/100) minutes will increase PCFE by 354 (2490*0.142) ETB, 254 (2490*0.102) ETB, and 229 (2490*0.092) ETB, respectively.

Depending on results from the quantile regression, the effect of water and feed scarcity is not uniform across the food income group, implying that its negative effect strongly increases from the bottom (poor) to the top (rich) quantile. For instance, the elasticity values associated with a 1 percent change in distance to a grazing land on food production ranges from −0.0996 percent for the fourth quantile to −0.171 percent of the top quartile with a median value of −0.100 percent. The effect of a 1 percent increase in distance to crop residue source brings about a 0.069 percent reduction in food expenditure only for the top category, while the effect of water is 0.064 percent at the median value. This analysis is relevant for the purposes of policy. If coefficients for a policy variable differ in different quantiles of the output variable, it implies that a policy change seeking to address issues of resource scarcity will have different effects on different households based on their position on the distribution of the food income variable.

In general, this study can be helpful for policymakers working to alleviate animal water and feed problems in Ethiopia to justify their actions with empirical results. The findings play a great role in the understanding of the linkage between welfare, food security, and environmental resources such as grazing and water scarcity. Three areas of policy intervention can be emerged as relevant. The first involves policies and institutions that facilitate easier access to animal water tap by advocating on emergency relief grounds. The second area of policy intervention involves the introduction of more efficient animal feed management strategies such as stall feeding and rotational grazing with the help of improved cow adoption that can improve cattle production and reduce land degradation. A policy that sought to increase household food consumption would greatly affect the highest quantile more than those who are in the lowest quantile of food production distribution.

Footnotes

This research has been sponsored by the collaborative research and capacity-building project on Climate Smart Natural Resource Management and Policy (NORHED-CLISNARP) between Mekelle University and Norwegian University of Life Sciences. The NORHED-CLISNARP project (NORHED-CLISNARP-ETH-13/2015) and this fieldwork research were funded by the Norwegian Agency for Development Cooperation (NORAD) and the Quota Scholarship programme of StatensLånekasse for Utdanning. Special thanks also go to my supervisor, Professor Stein Holden (NMBU), Norway, for his unreserved advice and my co-advisor, Dr. Mesfin Tilahun (MU), for his assistance.

1 See for a similar approach in the work of (Cooke Reference Cooke1998; Cooke et al. Reference Cooke, Köhlin and Hyde2008; Baland et al. Reference Baland, Bardhan, Das, Mookherjee and Sarkar2010)

2 For a detail review of related empirical studies, see Cooke et al. (Reference Cooke, Köhlin and Hyde2008).

4 NMBU-MU refers to Norwegian University of Life Science-Mekelle University.

5 Thirumarpan (Reference Thirumarpan2013) and Asfaw et al. (Reference Asfaw, Shiferaw, Simtowe and Lipper2012) used consumption expenditure to reflect the socioeconomic welfare of households and is a reliable indicator of food accessibility and degree of vulnerability to food insecurity.

6 The same approach is found in the work of Titus and Adetokunbo (Reference Titus and Adetokunbo2007).

7 To adjust for big variation in the wage rate among villages of the region, the wage rate is adjusted using a general informal rural labor conversion factor, 0.98.

8 Check Asfaw et al. (Reference Asfaw, Shiferaw, Simtowe and Lipper2012) and Thirumarpan (Reference Thirumarpan2013) for similar work.

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Figure 0

Table 1. Descriptive and Summary Statistics

Figure 1

Table 2. IV Estimation of Log Per Capita Food Expenditure using Walking Distance

Figure 2

Table 3. IV Estimation of Log Per Capita Food Expenditure using Shadow Prices

Figure 3

Table 4. Instrumental Variables Tests

Figure 4

Table 5. Probit Estimation of Food Security using Walking Distance

Figure 5

Table 6. Effect of Water, Grazing and Feed Scarcity on Log PCFE using Quintile Regression

Figure 6

Table 7. Aggregate Effect of Water and Feed Scarcity on Output, Food Expenditure, and Food Security