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Amartya Sen’s Peasant Economies: A Review with Examples

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1. Introduction

Amartya Kumar Sen is the most important and prolific living philosopher-economist. At present, he is Thomas W. Lamont University Professor and Professor of Economics and Philosophy, Harvard University. He was born in Santiniketan (India) and studied at Calcutta and at Cambridge. He has influential contributions to economic science in the fields of social choice theory, welfare economics, feminist economics, political philosophy, feminist philosophy, identity theory and the theory of justice. He was awarded the Nobel Prize in Economic Sciences in1998 [1] .

In this study, we have discussed peasant economies on the basis of Sen’s published paper “Peasants and Dualism with or without Surplus Labor” [2] . In 1966, most of the peasants were very poor and some of them were landless. They used old technologies and traditional seeds for cultivation. Some laborers worked on the field only for a poor meal. They worked some cases in agriculture with little or no wages. On the other hand, in 2016, most of the peasants are solvent and use modern technologies. They are using new variety of seeds, insecticides and manure and finding proper irrigation facilities. As a result, they find maximum harvest.

In this article, we explore elementary mathematical techniques in some details with displaying diagram where necessary. We have chosen this article of Sen for mathematical review because we have observed that we can do some work on it which will be beneficial for the modern peasants. We stress application of mathematics in the Sen’s paper so that readers can realize it easily. Although Sen’s paper was published in 1966, we thought its usefulness would remain same to some (but very few) peasant seven 50 years later in 2016. We consider here some explicit functions with the stated properties, such as the derivative being positive by Sen. In this review paper, we set two examples to examine various aspects, such as points of equilibrium clearly and in some details.

The objective of the study is to represent mathematical analysis of Sen’s paper mentioned above. Although the paper was published in 1966, we thought its importance would remain present to few farmers even in 2016. We hope detailed mathematical analysis will be helpful to the readers those who want to work on peasant family. Main objective of this review paper is to help the peasants of Bangladesh those who are in backward and may be benefited from this study.

2. Literature Review

Amartya Kumar Sen has given peasants economies in his published paper in 1966, where he discusses the economic equilibrium of a peasant family, the effect of surplus labor and withdrawal of labor, dual equilibrium between peasant and capitalist, and efficiency of resource allocation in peasant agriculture [2] . Sen [3] has discussed that food security is based in turn on access to resources, production technologies, environmental and market conditions, non-market food transfers and accumulated food reserves. Dale W. Jorgenson has enlightened the surplus agricultural labor and the development of a dual economyfocusing on the relationship between the degrees of industrialization and the level of economic development [4] . A survey was conducted by Jagdish N. Bhagwati and Sukhamoy Chakravarty on: 1) planning theory and techniques; 2) agriculture, and; 3) foreign trade of Indian economy [5] . Mark R. Rosenzweighas shown that to capture the essential features of rural agriculture and to maintain tractability, a labor market composed of two types of labor, male and female, and three agricultural households; a landless household and two households with different size plots, small and large, of quality standardized land producing a homogeneous agricultural commodity [6] . Abhijit V. Banerjee and Andrew F. Newman has examined the interactions among different institutional arrangements in a general equilibrium model of a modernizing economy [7] . Scale efficiency of Indian farmers is studied by Atanu Sengupta and Subrata Kundu [8] . Haradhan Kumar Mohajan has discussed food, agriculture, nutrition and economic development of Bangladesh [9] [10] .

Michael P. Todaro and Stephen C. Smith have revealed that the agricultural progress and rural development in developing nations and expressed the progressive improvement in rural levels through increases in small-farm incomes, output and productivity, along with genuine food security [11] . Paul Spicker, Sonia Alvarez Leguizamón and David Gordon analyzed the female-male wage ratio, and female labor-force participation rate in agriculture. They also discussed about lowland small and medium farm owners and cultivators [12] . Zipporah G. Glass worked on Amartya Sen’s model of entitlement and food security which focuses from supply and demand economics towards a household unit of analysis and effect [13] . Mausumi Mahapatro examined the nexus between land, migration and rural differentiation within the context of two villages in rural Bangladesh [14] . M. N. Baiphethi and P. T. Jacobs highlighted that poor households of South Africa access their food from the market, subsistence production and transfers from public programmes [15] . Sophia Murphy has exposed that agriculture had historically not been a global matter, though food has been traded across borders for thousands of years [16] .

3. Methodology of the Study

In this study we have used the secondary data and analyze on previous published papers. This is a review paper and discusses the mathematical analysis of Sen’s paper “Peasants and Dualism with or without Surplus Labor”. In this work we introduce two examples and try to give mathematical framework which (we think) Sen has not provided in detail. We have used techniques of the optimization of differential calculus. We also discussed the geometrical interpretation of mathematical results. In addition we have displayed diagrams where appropriate.

4. Highlights on the Simplest Model

Here we have discussed basic assumptions of Sen’s economic equilibrium of peasant model. Suppose a community of identical peasant families each with working members and total members. Each of the families has some stock of land and capital. The output of the family Q is only function of labor L, i.e., , which is twice differentiable always and diminishing with marginal productivity of labor. Hence the derivative of yields;

(1)

is the marginal productivity of labor. From our common sense,

and. (2)

For the maximization output, for and vanishes (Figure 1), i.e.,

. (3)

On the other hand approaches zero asymptotically, while approaches (Figure 2), i.e.,

. (4)

The total income (output) of the family, Q, is shared equally among all the members of the family, but the total labor L, is shared equally among all the working members. Let q is the individual income of any member and l is the amount of labor of any working member as,

. (5)

Again, every member of the family has a personal utility function (i.e., is the same for all members), which is a function of individual income q and every working member has a personal disutility function (i.e., is the same for all working members), which is a function of individual labor l. The “disutility” is roughly speaking, the “difficulty” or “inconvenience” of putting in labor of amount l. The function U and V satisfy the following properties:

(6)

Figure 1. The function represents the curve of maximization output.

Figure 2. The function represents the asymptotic curve of output.

. (7)

From (6) we see that the marginal utility from income is positive and non-increasing. From (7) we observe that the marginal disutility from labor is non-negative and non-decreasing [2] .

Each person’s notion of family welfare W in a suitable sense is given by the net utility from income and effort of all members taken together attaching the same weight to everyone’s happiness. Let a subscript i represents the i^{th} individual, then the family welfare W is given by;

. (8)

If it is assumed that all the functions and are the same, then we have,

(9)

Each individual could equally well regard W as a function of Q and L, since, , (by (5)). Fur-

ther, since, Q is a function of L, we can conclude that W is also a function of L;

, (say). (10)

Assume welfare is maximized by, then we can write;

(11)

provided that. Now we can write,

(12)

since

, , and. (13)

From (11) and (12) we get;

(say). (14)

Sen defined x as the “real cost of labor” which indicates that labor is applied up to the point where its marginal product equals the real cost of labor.

5. Illustrative Examples

In the light of above discussion we consider two explicit examples as follows.

5.1. Example A

We make an ad hoc assumptions about the form of the functions, , and show that for suitable values of the parameters occurring in these functions, they satisfy the conditions stated above. We then proceed to calculate the maximization point etc.

We assume, and to be given by the following expressions:

(15a)

(15b)

(15c)

where, , , a, k and b are positive constants. Note that, , and. First and second order partial derivatives of (15a, b, c) give;

(16a)

(16b)

(16c)

Also the conditions (2), (6) and (7) are all satisfied if all the constants are positive. Again, (15a) and (16a) give;

(17)

From (10) we get (15a, b, c) for the welfare function W as;

(18)

Now we get,

(19)

which is the same as the explicit form as (11). Now from (19) we get;

. (20)

Now we define a new variable X in terms of L and choose the constants a and k as;

(21)

Using (21), Equation (20) becomes the quadratic equation for X as;

. (22)

Solution of (22) becomes;

(23)

For the relevant solution we should consider only positive sign of (23), then we get,

. (24)

where. (25)

For real solution we get from (21);

and the constants, , and must satisfy the following inequality;

(25a)

Inequality (25a) is free of, it has a wider meaning than simply facilitating the derivation of an exact and explicit solution which is not clear at this stage. The solution can be studied in detail by taking specific, reasonable sets of numerical values of the constants occurring in the solution.

5.2. Example B

Here we made ad hoc assumptions about the form of the function, and show that these satisfy the relevant conditions, and then proceed via the corresponding welfare function, to obtain the value of L which maximizes this function at and. We consider the functions, , be as follows:

(26a)

(26b)

, (26c)

since and. Throughout this example we confine ourselves to the interval or. Here (26b) is same as (15b) of example A. From (26c) we get;

(27)

We observe that if l tends to, the three functions, and tend to infinity. Hence it is reasonable that it is difficult for an individual to reach the amount of labor given by. For this reason we confine the values of l are confined to the interval and also those of L are to the interval and.

From (26a) we get;

(28)

for and at as we expect. Maximum of Q is given by; relate L with a as follows:

. (29)

Now we can express the function in Figure 3. Here we have measured the output Q in terms of money but it is not the case, because Q can be measured in some other units, such as, in kg, liter etc. (e.g., if the peasants themselves consume their own products and calculate in such units). If Q is measured in money, then q must be in money also. If is measured in some units, then must be measured in the same unit, so that must be dimensionless, that is, a pure number. Obviously must be a pure number, which

Figure 3. The function is asymptote at.

indicates that b must have dimension of inverse money. Similarly, if labor L is measured in hours, then the constant “a” has the dimension of money/hour^{2}, etc. To avoid the different form of dimension we avoid dimension in our calculations. The welfare function W is given by;

. (30)

From (30) derivative of with respect to L gives;

. (31)

For maximum welfare (i.e.,) we get from (31);

. (32)

We know that a cubic equation can be solved in radicals in terms of the coefficients. We observe that solution of (32) will be complicated, so that we cannot find exact and necessary information from it. In this situation we proceed in an indirect way. First, we introduce some preliminary remarks.

The property of a cubic equation that it has three roots, all real, or one real and two complex. In this example we are confined to find a root in the interval that must satisfy that second order derivative of welfare function will be negative, since it must maximize W.

From (30) we see that welfare function vanishes at and. It is reasonable in the present situation, since if there is no labor, there is no welfare (income). As L increases from zero, one expects welfare to rise from value zero. We can proceed if the first derivative of (31) is positive at;

. (33)

i.e.,

, (by (29),). (34)

Here the constant is a sort of measure of the utility to the individual and hence to the family, while is a measure of disutility of labor to the working members. For any fixed, the inequality (34) will not be valid if become too large, in such a situation welfare will not rise from the value zero. This happen if the potential working members have some chronic illness, so that labor becomes prohibitively difficult for large. Finally, we conclude that inequality (33) is satisfied when L increases from zero, and the welfare function also increase from zero.

Now the second derivative of gives;

. (35)

We observe that this function is negative for all values of L in our expected interval. Thus, as increases from zero at, its rate of increase diminishes and there will be a point in at

which reaches its maximum value. We assume that the is maximum at. We will also

examine if reasonable parameter values can be found that will achieve this circumstance. Now we write (32) using (25) and (29) as follows:

. (36)

Since is a root of Equation (36), putting we get;

. (37)

From (34) we get;

, by (23). (38)

Since, so that. Hence from (37) we get the strict inequality,

. (39)

But we need a more consistent value and we choose (39) for our convenience way as follows:

. (40)

Using (37) to (40) we can write (36) in a more convenience way as solvable form as follows:

. (41)

Since is a solution of (41) we get;

(42)

Solution of 2nd equation of (42) is;

. (42a)

Hence, is the only real root at which the welfare function is maximum. We can write wel-

fare function (30) as follows:

where,

(43)

Since, so that, which implies that there is no welfare if there is no labor. Derivative of (43) gives,

. (44)

For (44) becomes;

(45)

From (44) and (45) we have two properties as;

(46)

i.e., (47)

We represent (47) in Figure 4, which indicates and Figure 5, which indicates respectively. The broken lines are tangents to the curves and at, if they make angles and respectively with the positive L-axis, then clearly,

(48)

Again is positive throughout the interval and tends to infinity as is

Figure 4. The behavior of the functions and for.

Figure 5. The behavior of the functions and for.

approached from below. Since occurs with a negative sign in the expression for in (43), it is

this property of that makes negative throughout the interval, as noted earlier. Again vanishes at at which (by first two terms of (35)), so that is a maximum of (Figure 6). The above analysis has some intrinsic, wider interest, since the welfare function generally consists of a positive term representing the utility of the whole family, and a negative term incorporating the disutility of the working members. Another reason for carrying out the above analysis in some detail is to display a mildly pathological situation which nevertheless can be given a reasonable interpretation.

Let us fix the values of and choose two values of denoted by, such that;

(49)

and set as defined by (43) as above. Now we define the corresponding welfare functions as follows:

(50)

For, the welfare function begins to rise with L from the value zero at, and for, the welfare function begins to diminish from the value zero as L increase from. We have,

. (51)

Let, , then,

. (52)

The quadratic vanishes at and is given by;

(53)

with and (Figure 6). Moreover at, where vanishes, is maxi-

Figure 6. Nature of the functions, , , and are displayed. The welfare function has a positive maximum at, but decreases from the value zero at to negative values and therefore has no maximum in.

mum at, with, so that,. Since vanishes at;

and tends to infinity at these values.

Now consider the mild pathological situation. For this we consider (47) the in equation as equation,

, (by (29),). (54)

Using (54) in (32) we get;

. (55)

The solutions of (55) are;

,

. (56)

As we have seen earlier that two roots of (56) are complex, let us now choose as,. Again since at (from (35)), the point in this case is only maximum in the range

of the function. Hence no welfare is a genuine maximum at no labor (Figure 7).

6. Review on “Production for a Market”

A. K. Sen has considered the circumstance when the product Q is not directly useable by the peasants, so it is exchanged for goods directly enjoyable by the peasants. Also it may happen that part of the product Q is used while the rest is exchanged for other goods. If the whole amount C of the new product, the individual share be-

ing, we can define as a (section 5) a utility function of the same type that is, a function of c;

(57)

The price of output Q in terms of C is p per unit;

. (58)

Figure 7. Zero welfare (no welfare) is a genuine maximum at no labor (), of the welfare function.

So that the maximum of the family welfare is given by;

. (59)

Let us now consider a situation in which a part of the product Q is sold and a part is consumed. Individually, C amount of the purchased commodity and q of the self product one is enjoyed per member. Let y be the properties of output that is marketed. Sen defines a utility function with the following properties;

;, , ,;

. (60)

Again we have;

(61)

with allocation rules;

(62)

We have also used the same form of the utility function for both of the examples, A and B. Now we consider the utility function,

. (63)

Taking derivatives of (63) with respect to q we get;

(64)

Hence from (64) we have;

. (65)

We observe that (65) agrees with (60) and also agrees with examples A and B.

7. Discussion on Response to Withdrawal of Labor

Sen also discusses the problem of surplus labor and response of peasant output to withdrawal of labor. The surplus labor is defined as that part of the labor force in this peasant economy that can be removed without reducing the total amount of output produced, even when the amount of other factors is not changed [2] . Now from (13) in slightly different form we get;

(66a)

(66b)

where (66a) is an equation but not identity. Here maximization of welfare function occurs at. We as-

sume (66a) to be valid for all, , etc. Taking derivatives of both sides of (66a) with respect

to l we get;

(67)

Now if, , , then (67) gives, which violates (7), unless , which is not necessarily the case. Hence (66a) is indeed an equation. Sen envisages a situation, in which the ratio of total number of members to working members is constant, denoted by K;

. (68)

So that when one working member leaves, he provides support for K members (including himself) and so the peasant family is left with one less working member and K less consuming ones.

Taking derivatives of (14) with respect to we get;

. (69)

We have,

. (70)

(71)

Differentiating (14), , with respect to we get;

. (72)

Using (70) to (72) in (69) we get;

. (73)

Simplifying (73) we get;

. (74)

Using (14), and multiplying by we get from (74);

. (75)

This is Sen’s Equation (31) but we have derived the equation more detailed than Sen has. Sen introduces some elasticities as follows [2] .

E is the elasticity of output with respect to the number of working members, m is the absolute value of the elasticity of the marginal utility of income with respect to individual income, n is the elasticity of marginal disutility from work with respect to individual hours of work, G is the elasticity of output with respect to hours of labor, g is the absolute value of the elasticity of the marginal product of labor with respect to hours of labor. These quantities are defined by the following relations:

(76)

Also we have,. (77)

Using (5), (76) and (77) in (75) we get the response equation;

. (78)

Now we consider the example A. From (15a) we get;

. (79)

From (76), using (15a) we get;

. (80)

From (76) and (15a), (16a, b, c) we get;

(81)

Using (79) to (81) in (78) we get;

(82)

If we get from (76);

. (83)

Using (83) and (21), (82) becomes;

. (84)

In this case L be very large to satisfy (84) and marginal disutility schedule approach to the vertical position, which of course will tend to toward constancy of the change in labor hours proportional to the change in the number of working people [2] .

Now we consider a special case for and in (78) we get;

. (85)

Using (76) and (21), (85) becomes;

(86)

Equation (86) implies and. Moreover (86) represents that when some

people are withdrawn from the peasant economy, with an unchanged number of hours of work per person, the marginal physical return work will increase [2] .

8. Conclusion

In this study, we have analyzed some parts of Sen’s paper “Peasants and Dualism with or without Surplus Labor” with detail mathematical calculations. We have tried to give the physical interpretations of the mathematical results clearly (as far as possible). We hope the readers will feel comport when they study this article. We have not discussed all the portions of the paper of Sen. So that readers can take the opportunity to discuss the parts which we have not tried. In their study, they can set new examples to discuss the paper of Sen.

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

*Open Access Library Journal*,

**3**, 1-15. doi: 10.4236/oalib.1102337.

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