Hicksian demand function

The Hicksian demand function, also known as the compensated demand function, represents the quantity of a good that a consumer demands at given prices while holding utility constant, isolating the pure substitution effect of price changes without income effects.^[1] This function is derived from the consumer's expenditure minimization problem, where the goal is to achieve a target utility level u at the lowest possible cost given prices p.^[2] Named after British economist John R. Hicks, the concept was introduced in his influential 1939 book Value and Capital, which advanced the analysis of consumer behavior and general equilibrium theory.^[3] Mathematically, the Hicksian demand for good i, denoted h_i(p, u), is the solution to \min_x p \cdot x subject to u(x) \geq u, and it equals the partial derivative of the expenditure function e(p, u) with respect to price p_i: h_i(p, u) = \frac{\partial e(p, u)}{\partial p_i}. This duality with the expenditure function underscores its role in welfare economics and cost analysis.^[4] Key properties of the Hicksian demand function include homogeneity of degree zero in prices, meaning h(\lambda p, u) = h(p, u) for \lambda > 0, which reflects that proportional price changes do not alter quantities demanded at fixed utility.^[2] It also exhibits a negative own-price effect, \frac{\partial h_i}{\partial p_i} < 0, due to the concavity of the utility function and diminishing marginal rates of substitution, ensuring that higher prices lead to reduced demand along the same indifference curve.^[1] Cross-price effects are symmetric, \frac{\partial h_i}{\partial p_j} = \frac{\partial h_j}{\partial p_i}, implying that the impact of a price change on one good's demand equals the reciprocal effect.^[4] In contrast to the Marshallian (uncompensated) demand function x(p, w), which holds nominal income w fixed and incorporates both substitution and income effects, the Hicksian function adjusts income to maintain utility, allowing clear separation of effects via the Slutsky equation: \frac{\partial x_i}{\partial p_j} = \frac{\partial h_i}{\partial p_j} - x_j \frac{\partial x_i}{\partial w}.^[5] This decomposition is fundamental for empirical demand estimation, policy analysis, and measuring welfare changes such as compensating variation in response to price shocks.

Fundamentals

Definition

The Hicksian demand function, denoted as h(p, \bar{u}), is defined as the solution to the consumer's expenditure minimization problem, where the consumer seeks the bundle of goods that achieves a target utility level at the lowest possible cost given prices.^[2] Formally, for a utility function u(x) representing preferences over the consumption bundle x = (x_1, \dots, x_n) \in \mathbb{R}^n_+, and a price vector p = (p_1, \dots, p_n) > 0, the Hicksian demand is given by

h(p, \bar{u}) = \arg\min_{x \geq 0} \, p \cdot x \quad \text{subject to} \quad u(x) \geq \bar{u},

where \bar{u} is the fixed target utility level.^[2] Under the standard assumption of convex preferences, which ensures that the upper contour set \{x \mid u(x) \geq \bar{u}\} is convex, the solution is unique if preferences are strictly convex.^[6] This optimization problem identifies the cost-minimizing bundle x^* = h(p, \bar{u}) that delivers at least the utility \bar{u}, reflecting compensated demand where the consumer's purchasing power is adjusted to maintain utility constant.^[1] The associated indirect expenditure function, which gives the minimum cost to achieve utility \bar{u} at prices p, is then

e(p, \bar{u}) = p \cdot h(p, \bar{u}).

By Shephard's lemma, the Hicksian demand for good i satisfies h_i(p, \bar{u}) = \frac{\partial e(p, \bar{u})}{\partial p_i}.^[2] This value function encapsulates the expenditure required and serves as the dual to the utility maximization problem underlying Marshallian demand.^[2]

Economic Interpretation

The Hicksian demand function captures the behavioral response of consumers to changes in relative prices while keeping their utility level constant, thereby isolating the pure substitution effect from any income-induced adjustments in consumption. This conceptual framework illustrates how a consumer would reallocate their bundle of goods to maintain the same satisfaction despite price shifts, reflecting only the incentive to substitute toward relatively cheaper alternatives. By abstracting away from income variations, it provides a theoretical lens for understanding demand adjustments driven solely by price signals.^[1] In contrast to everyday consumer decisions, where price changes directly impact real income and thus overall purchasing power under a fixed budget, the Hicksian demand envisions a compensated scenario—such as through an idealized lump-sum transfer of funds—that neutralizes these income effects and preserves the original utility. This hypothetical compensation allows economists to observe unadulterated substitution behavior, unconfounded by the broader financial repercussions that real-world consumers face when prices fluctuate.^[1] John R. Hicks introduced this function in his 1939 book Value and Capital to enable a clearer analysis of how price changes affect welfare, specifically by disentangling substitution effects from income effects that could otherwise obscure the true impact on consumer well-being. Hicks aimed to refine the study of economic value and equilibrium by providing a tool that avoids the complications arising from alterations in real income when prices vary.^[7]^[8] This decomposition role establishes the Hicksian demand as a foundational element in consumer theory, offering insights into the intrinsic responsiveness of demand to relative price movements and supporting theoretical explorations of market dynamics without the overlay of income perturbations.^[9]

Derivation

Expenditure Minimization Problem

The expenditure minimization problem (EMP) is a constrained optimization task in which a consumer seeks to minimize total expenditure on goods given a fixed vector of prices \mathbf{p} = (p_1, \dots, p_n) > \mathbf{0} and a target utility level \bar{u}, subject to achieving at least that utility from a utility function u(\mathbf{x}) that is continuous, strictly increasing, and strictly quasi-concave.^[10] Formally, it is stated as:

\min_{\mathbf{x} \geq \mathbf{0}} \mathbf{p} \cdot \mathbf{x} \quad \text{subject to} \quad u(\mathbf{x}) \geq \bar{u},

where \mathbf{x} = (x_1, \dots, x_n) is the consumption bundle.^[2] The solution to this problem yields the Hicksian demand function \mathbf{h}(\mathbf{p}, \bar{u}), which specifies the cost-minimizing quantities of each good needed to attain utility \bar{u} at prices \mathbf{p}.^[5] The minimal expenditure required is given by the expenditure function e(\mathbf{p}, \bar{u}) = \mathbf{p} \cdot \mathbf{h}(\mathbf{p}, \bar{u}), which is increasing and concave in \mathbf{p}, and increasing in \bar{u}.^[10] To solve the EMP, the Lagrangian is constructed as \mathcal{L}(\mathbf{x}, \lambda) = \mathbf{p} \cdot \mathbf{x} + \lambda (\bar{u} - u(\mathbf{x})), assuming an interior solution where the constraint binds.^[2] The first-order conditions (FOCs) with respect to each x_i are \frac{\partial \mathcal{L}}{\partial x_i} = p_i - \lambda \frac{\partial u}{\partial x_i}(\mathbf{x}) = 0 for i = 1, \dots, n, along with \frac{\partial \mathcal{L}}{\partial \lambda} = \bar{u} - u(\mathbf{x}) = 0.^[11] These imply \frac{p_i}{\frac{\partial u}{\partial x_i}(\mathbf{x})} = \frac{1}{\lambda} for all i, meaning the marginal utility per dollar spent is equalized across goods at the optimum, with \lambda > 0 serving as the shadow price of utility.^[5] Applying the envelope theorem to the EMP yields Shephard's lemma, which states that the partial derivative of the expenditure function with respect to price p_i equals the Hicksian demand for good i: h_i(\mathbf{p}, \bar{u}) = \frac{\partial e(\mathbf{p}, \bar{u})}{\partial p_i}.^[11] This result, originally derived by Ronald Shephard in his analysis of cost functions, provides a direct link between the expenditure function and the Hicksian demands without resolving the full optimization problem explicitly.^[12] For solvability with a unique interior solution, the utility function u(\mathbf{x}) must be strictly quasi-concave, guaranteeing convex indifference curves and a single tangency point between the budget hyperplane and the indifference surface at utility \bar{u}.^[10] Local non-satiation ensures the constraint binds, while continuity of u supports the existence of solutions.^[2]

Duality with Utility Maximization

The duality principle in consumer theory establishes a fundamental symmetry between the expenditure minimization problem, which yields the Hicksian demand function, and the utility maximization problem, which generates the Marshallian demand. In the utility maximization framework, a consumer seeks to maximize utility u(x) subject to the budget constraint p \cdot x \leq I, where p denotes prices, x consumption quantities, and I income, resulting in the indirect utility function v(p, I) = \max \{ u(x) \mid p \cdot x \leq I \}.^[13] The dual expenditure minimization problem minimizes expenditure p \cdot x subject to achieving at least a target utility level u, yielding the expenditure function e(p, u) = \min \{ p \cdot x \mid u(x) \geq u \} and the Hicksian demand h(p, u). These value functions act as convex conjugates: v(p, I) represents the maximum utility attainable at given prices and income, while e(p, u) gives the minimum cost to reach a specified utility, ensuring that v(p, I) = \max \{ u \mid e(p, u) \leq I \} and e(p, u) = \min \{ I \mid v(p, I) \geq u \}.^[14] This duality enables the recovery of one demand function from the other. Specifically, the Hicksian demand at prices p and utility u equals the Marshallian demand at those prices and the income level I = e(p, u) required to achieve u:

h(p, u) = x(p, e(p, u)),

where x(p, I) is the Marshallian demand. This relationship holds because the expenditure function solves for the exact income needed to attain the target utility at prevailing prices, aligning the budget constraint precisely with the utility threshold in the dual problem. Conversely, the Marshallian demand can be expressed using the inverse indirect utility. This interchangeability underscores the theoretical unity between the two approaches, allowing economists to derive compensated demands from uncompensated ones under consistent preferences.^[13] Under specific preference structures, the duality manifests in forms like the Gorman polar form, which linearizes the relationship between expenditure and utility. Assuming preferences exhibit linear Engel curves—where consumption increases linearly with income—the expenditure function takes the affine form e(p, u) = a(p) + u \cdot b(p), with a(p) and b(p) as functions of prices only. This structure links Hicksian and Marshallian demands through homotheticity or separability assumptions, facilitating aggregation across consumers in demand analysis. The polar form ensures that individual demands are consistent with market-level behavior when preferences satisfy these conditions, providing a bridge for empirical estimation.^[14] The duality also carries implications for the integrability of demand functions, ensuring that observed demands are consistent with an underlying utility representation. For demands to be integrable, they must satisfy conditions derived from revealed preference theory, such as the absence of cycles in choice behavior, which guarantee the existence of a utility function generating both Marshallian and Hicksian demands. These integrability conditions, including symmetry and negative semidefiniteness in substitution effects, arise naturally from the dual frameworks and confirm that the demands stem from rational, utility-maximizing preferences rather than arbitrary behavior. Violations of integrability would imply inconsistencies between the primal and dual problems, undermining the theoretical foundations.^[15]

Relationships

With Marshallian Demand

The Marshallian demand function, also known as ordinary demand, arises from the consumer's utility maximization problem under a fixed budget constraint. It is defined as x(p, I) = \arg\max_x u(x) subject to p \cdot x \leq I, where p represents the price vector, I is nominal income, u(x) is the utility function, and x is the consumption bundle.^[16] This formulation captures how consumers allocate their limited income across goods to achieve the highest possible utility, leading to demand that varies with both prices and income levels.^[1] In contrast, the Hicksian demand function, or compensated demand, solves the expenditure minimization problem to achieve a fixed utility level u, denoted as h(p, u) = \arg\min_x p \cdot x subject to u(x) \geq u.^[17] The key difference lies in what is held constant: Hicksian demand fixes utility, eliminating income effects and isolating pure substitution responses to price changes, whereas Marshallian demand fixes income, incorporating both substitution and income effects. Graphically, this distinction is illustrated using indifference curves and budget lines. For a price decrease in one good, the Marshallian demand shifts along a new budget line tangent to a higher indifference curve, reflecting both the substitution toward the cheaper good and an income effect allowing more consumption overall. The Hicksian demand, however, adjusts the budget line parallel to the original (via compensating variation) to remain tangent to the same indifference curve, showing only the movement along that curve due to relative price changes.^[1] This separation highlights the substitution effect versus the total effect in Marshallian demand. The Hicksian demand curve traces only the substitution effect, as consumers slide along the fixed indifference curve in response to price changes without gaining or losing purchasing power in utility terms.^[17] For normal goods—where demand increases with income—the total effect in Marshallian demand exceeds the substitution effect when prices fall, causing Marshallian demand to be more elastic than Hicksian demand. Consider a consumer with two goods, where a price drop in good 1 leads to greater consumption under Marshallian demand due to the positive income effect, while Hicksian demand shows a smaller increase confined to substitution alone.^[16] Empirically, Hicksian demand is challenging to observe directly because it requires knowledge of utility levels, which are unobservable, unlike Marshallian demand derived from market data on prices and expenditures. Instead, economists infer Hicksian demands from revealed preference analysis of observed Marshallian choices, testing consistency with axioms like the Generalized Axiom of Revealed Preference (GARP) to recover bounds or estimates of compensated responses.^[18] This approach relies on nonparametric methods to ensure data rationalizability by a utility function, allowing indirect identification without assuming specific functional forms.^[19]

Slutsky Equation

The Slutsky equation relates the Marshallian (uncompensated) demand function x_i(p, I) to the Hicksian (compensated) demand function h_i(p, u) by decomposing the total price effect into a substitution effect and an income effect.^[20] Specifically, it states that the partial derivative of the Marshallian demand for good i with respect to the price of good j equals the partial derivative of the Hicksian demand for good i with respect to the price of good j minus the product of the Marshallian demand for good j and the partial derivative of the Marshallian demand for good i with respect to income:

\frac{\partial x_i}{\partial p_j} = \frac{\partial h_i}{\partial p_j} - x_j \frac{\partial x_i}{\partial I}.

Here, \frac{\partial h_i}{\partial p_j} captures the pure substitution effect, holding utility constant, while -x_j \frac{\partial x_i}{\partial I} represents the income effect arising from the change in purchasing power.^[21]^[11] The derivation of the Slutsky equation relies on the duality between the indirect utility function v(p, I) and the expenditure function e(p, u), applying the envelope theorem and Shephard's lemma. Start with the identity h_i(p, u) = x_i(p, e(p, u)), which equates Hicksian demand to Marshallian demand evaluated at the expenditure needed to achieve utility u. Differentiating both sides with respect to price p_j using the chain rule yields \frac{\partial h_i}{\partial p_j} = \frac{\partial x_i}{\partial p_j} + \frac{\partial x_i}{\partial I} \frac{\partial e}{\partial p_j}. By Shephard's lemma, \frac{\partial e}{\partial p_j} = h_j(p, u) = x_j(p, I) under the duality, substituting to obtain the Slutsky equation after rearranging.^[11]^[20] In matrix form, the Slutsky matrix S has elements S_{ij} = \frac{\partial h_i}{\partial p_j} = \frac{\partial x_i}{\partial p_j} + x_j \frac{\partial x_i}{\partial I}, which is symmetric (S_{ij} = S_{ji}) due to the symmetry of the second derivatives of the expenditure function and negative semi-definite, reflecting the concavity of the expenditure function in prices.^[11]^[20] For own-price effects where i = j, the Hicksian term \frac{\partial h_i}{\partial p_i} is always negative, as it isolates the substitution effect that reduces demand when the price of good i rises, holding utility constant. The total Marshallian effect \frac{\partial x_i}{\partial p_i} can be positive or negative depending on the income effect: for normal goods, it reinforces the negative substitution effect, while for inferior goods, a sufficiently large positive income effect may lead to an upward-sloping demand curve, as in Giffen goods.^[11]^[20]

Properties and Applications

Mathematical Properties

The Hicksian demand function, derived from the expenditure minimization problem, possesses several fundamental mathematical properties that ensure its consistency with economic theory and the underlying assumptions of consumer preferences. These properties—homogeneity, symmetry, negative semi-definiteness, and monotonicity—stem from the concavity and differentiability of the expenditure function, which generates the Hicksian demands via Shephard's lemma.^[22] A key property is homogeneity of degree zero in prices. Specifically, for any scalar \lambda > 0, the Hicksian demand satisfies h(\lambda p, u) = h(p, u), where h(p, u) denotes the demand vector for prices p and utility level u. This arises because scaling all prices by \lambda proportionally scales the expenditure function e(\lambda p, u) = \lambda e(p, u), preserving the optimal bundle that achieves utility u at minimum cost.^[22]^[23] The homogeneity reflects the absence of money illusion in compensated demand choices, as relative prices remain unchanged under uniform scaling. Symmetry in the cross-price derivatives is another essential property. The Slutsky matrix for Hicksian demand, given by the Jacobian \frac{\partial h_i}{\partial p_j}, is symmetric, meaning \frac{\partial h_i}{\partial p_j} = \frac{\partial h_j}{\partial p_i} for all goods i and j. This follows from the expenditure function e(p, u) being twice continuously differentiable and concave in p, so its Hessian matrix (which equals the Slutsky matrix by Shephard's lemma) has equal mixed partial derivatives.^[22]^[24] The Slutsky matrix is also negative semi-definite, implying that for any price vector \Delta p, \Delta p^\top \left( \frac{\partial h}{\partial p} \right) \Delta p \leq 0. This property derives directly from the concavity of the expenditure function in prices, as the Hessian of a concave function must be negative semi-definite.^[22]^[24] It ensures that compensated demand curves are downward-sloping in an aggregate sense, consistent with the law of demand under utility compensation. Monotonicity properties further characterize the Hicksian demand. In particular, the own-price effect is non-positive: \frac{\partial h_i}{\partial p_i} \leq 0 for each good i, meaning that an increase in the price of good i does not increase its compensated demand. This follows from the negative semi-definiteness of the Slutsky matrix, as the diagonal elements are non-positive. Cross-price effects \frac{\partial h_i}{\partial p_j} (for i \neq j) can be positive or negative, depending on whether goods i and j are complements or substitutes in the utility function.^[24]^[23]

Role in Welfare Economics

The Hicksian demand function plays a central role in welfare economics by enabling the analysis of price changes that maintain a consumer's utility level constant, thus isolating pure substitution effects without confounding income effects. This compensated demand traces out substitution paths along an indifference curve, allowing economists to evaluate welfare impacts from price adjustments in a utility-neutral manner. For instance, when a price rises, the Hicksian demand curve reflects only the substitution away from the good, providing a more precise measure of efficiency losses compared to the Marshallian demand, which includes both substitution and income effects that can lead to biased surplus estimates.^[25] In measuring consumer surplus, the Hicksian demand facilitates exact calculations of welfare changes through the compensating variation (CV), defined as the difference in expenditure required to achieve a fixed utility level at different price vectors:

CV = e(\mathbf{p}^1, u) - e(\mathbf{p}^0, u)

where e(\mathbf{p}, u) is the expenditure function, and integration along the Hicksian demand curve yields a path-independent measure of surplus, avoiding the path-dependence issues inherent in Marshallian approximations. This exactness ensures that the area under the Hicksian demand curve precisely captures the welfare cost of a price change, such as a tax, restoring the consumer to their original utility.^[26] The Hicksian framework underpins policy applications in cost-benefit analysis, particularly for evaluating taxes and subsidies by isolating efficiency effects from distributional concerns via the Kaldor-Hicks compensation criterion, where gains from a policy must hypothetically compensate losers. In the 1940s, debates between Hicks and Slutsky's earlier contributions clarified the exactness of surplus measures under compensated demands, resolving ambiguities in applying consumer surplus to policy without assuming integrability of ordinary demands.^[27]^[28]^[29] Despite its strengths, the Hicksian demand relies on assumptions such as local non-satiation to ensure the expenditure minimization problem is well-defined and quasi-concavity of preferences for convex demand sets and uniqueness. Modern extensions integrate Hicksian demands into general equilibrium welfare analysis, where aggregate expenditure functions evaluate Pareto improvements across economies, accommodating interpersonal utility comparisons and market interactions beyond partial equilibrium settings.