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Computable general equilibrium

Computable general equilibrium (CGE) models are large-scale numerical frameworks that combine neoclassical economic theory with real-world data to simulate economy-wide , capturing interactions among production sectors, households, governments, and through systems of simultaneous equations solved for prices, quantities, and allocations under policy changes or external shocks. These models operationalize general concepts by calibrating parameters to a matrix or input-output tables, enabling counterfactual analyses of how disturbances propagate across interlinked markets. Pioneered by Leif Johansen's 1960 multisectoral model for the Norwegian economy, CGE approaches gained prominence in the 1970s and 1980s as computational advances allowed practical implementation of Walrasian principles, shifting from purely theoretical constructs to applied tools for . Key characteristics include behavioral equations derived from utility maximization and profit optimization, often employing (CES) functional forms for production and demand, alongside market-clearing conditions and zero-profit rules in competitive settings. CGE models have been extensively applied to quantify impacts of trade agreements, fiscal reforms, energy transitions, and regulatory interventions, such as the U.S. Environmental Protection Agency's use of them to assess environmental policy effects on output and . Notable achievements encompass global databases like GTAP for multiregional simulations, facilitating cross-country comparisons of effects. However, defining limitations persist, including heavy reliance on rather than econometric for parameters, which introduces in elasticities and possibilities, and infrequent whole-model validation against historical data, potentially overstating in dynamic or contexts. Critics argue these features can yield misleading forecasts when real economies deviate from assumptions of , homogeneous agents, or fixed technological coefficients, underscoring the need for analyses and complementary empirical methods.

Theoretical Foundations

Roots in General Equilibrium Theory

Computable general equilibrium (CGE) models derive their core theoretical structure from (GET), which analyzes economies as systems where prices simultaneously clear all markets, equating aggregate supply and demand for goods, services, and . GET originated with Léon Walras's 1874 formulation of Éléments d'économie politique pure, positing tâtonnement—a hypothetical auctioneer adjusting prices iteratively until equilibrium is achieved—but lacked rigorous proofs of existence or uniqueness. Modern GET advanced through the axiomatic framework of and in their 1954 paper "Existence of an Equilibrium for a Competitive Economy," which proved equilibrium existence under assumptions of convex preferences, convex production sets, local non-satiation, and complete markets contingent on all states of nature. This model formalized economies with multiple consumers, firms, and commodities, where equilibrium prices support Pareto-efficient allocations without excess demands. CGE models operationalize GET by representing economies as systems of nonlinear equations derived from maximization, , and market-clearing conditions, mirroring Arrow-Debreu equilibria in a static or dynamic setting. Unlike pure GET, which focuses on qualitative properties like and welfare theorems, CGE emphasizes quantitative simulation, but retains GET's neoclassical foundations: rational agents with continuous, quasi-concave functions; in some variants; and Walrasian adjustment. These roots ensure CGE captures economy-wide interactions, such as effects and general-equilibrium feedbacks, where changes in one market ripple across all others—contrasting partial-equilibrium approaches that ignore interdependencies. The Arrow-Debreu framework underpins CGE's treatment of time and uncertainty through contingent commodities, though practical models often simplify to single-period or recursive dynamics for computability. Empirical in CGE aligns input data with GET-derived benchmarks, such as reproducing a base-year where benchmark prices validate zero profits under . Critics note that while GET assumes idealized conditions rarely met in reality—e.g., no externalities or monopolies unless explicitly modeled—CGE inherits these for analytical tractability, prioritizing from policy shocks over behavioral realism. This theoretical lineage enables CGE to evaluate policies like tariffs or subsidies by tracing deviations from benchmark equilibria, grounded in first-order conditions akin to those in Arrow-Debreu.

Emergence of Computability

The theoretical foundations of general equilibrium, as formalized by and Debreu in 1954, established the existence of competitive equilibria through non-constructive fixed-point theorems, such as Brouwer's, but offered no practical method for numerical computation due to the nonlinearity and high dimensionality of the systems involved. These proofs demonstrated equilibrium under idealized assumptions but left economists without tools to simulate or approximate outcomes in applied settings, limiting the framework's utility beyond abstract analysis. The breakthrough in emerged in the mid-1960s through Herbert Scarf's of a simplicial subdivision , which provided a constructive to approximate prices and quantities by iteratively refining triangulations of the excess demand until convergence to a fixed point. Scarf's method, detailed in his 1969 paper, addressed the computational challenges of nonlinear Walrasian systems by guaranteeing approximation within specified tolerances, even for economies with multiple agents and commodities, thus bridging the gap between existence theorems and feasible numerical solutions. This , often termed Scarf's algorithm, relied on path-following techniques to trace loci, enabling the handling of gross substitutability assumptions and paving the way for applied implementations. Scarf's innovations, building on earlier numerical experiments but achieving global convergence properties absent in prior tatonnement-like processes, marked the theoretical shift to computable general equilibrium by demonstrating that equilibria could be reliably calculated on early computers, influencing subsequent and policy simulations despite computational costs that initially restricted scale. This emergence underscored the need for empirical data integration, as pure theoretical constructs proved insufficient for verification, though early applications highlighted sensitivities to functional forms and parameter choices.

Historical Development

Pioneering Models (1960s)

The pioneering computable general equilibrium (CGE) model emerged in 1960 with economist Leif Johansen's A Multi-Sectoral Study of Economic Growth, a doctoral dissertation applied to the . This model represented the first integration of with numerical computation for , distinguishing itself from prior input-output frameworks by incorporating microeconomic behaviors of agents such as households, firms, and capitalists. Johansen's framework utilized a 22-sector input-output table from 1950 , encompassing industries for production, with households maximizing additive utility functions, firms minimizing costs via Cobb-Douglas production functions that allowed capital-labor substitution alongside Leontief fixed intermediate inputs, and capitalists optimizing capital allocation across sectors. Key assumptions included price-taking behavior by agents, exogenous aggregate and stocks, Hicks-neutral technical progress, and differentiation between buyers' and sellers' prices via a trade-services ; imported inputs were treated as either perfect substitutes or non-competitive, while public expenditures and net exports remained exogenous. The model solved a of 86 equations in 132 variables through inversion, employing percentage-change formulations (e.g., as x_j = \gamma_j + \beta_j n_j + (1 - \beta_j) k_j + \epsilon_j for sector j) to approximate equilibria and simulate scenarios, such as shifts in industrial composition. This approach enabled forecasting of Norwegian economic development from the , with validations against observed outcomes demonstrating its practical utility for long-term planning. Johansen's innovation lay in bridging theoretical general equilibrium—rooted in Walrasian traditions—with empirical , eschewing fixed coefficients for behavioral elasticities and providing transparent guidelines that influenced subsequent models. Despite its static and linearized nature, which limited handling of nonlinearities, the model was adopted by authorities for evaluation, marking the inception of CGE as a tool for multisectoral analysis rather than mere descriptive accounting. During the , this work remained somewhat isolated, with broader dissemination occurring later, but it established core precedents for agent-driven equilibria in .

Institutionalization and Expansion (1970s-1980s)

In the 1970s, computational advancements, including fixed-point algorithms building on Herbert Scarf's 1966 procedure, enabled the numerical solution of nonlinear general equilibrium systems using real economic data, transitioning theoretical models into practical policy tools. These methods addressed earlier limitations in scalability, allowing economists to simulate economy-wide responses to shocks like tax changes or trade policies without relying solely on linear approximations. Leif Johansen's 1960 multi-sectoral growth model provided a foundational template, emphasizing agent behaviors coordinated by prices and solved via matrix inversion of input-output structures. In , this evolved into the MSG series, with versions like MSG-4 incorporating dynamic elements and detailed sectoral data from 22 industries, adopted by the for long-term planning simulations starting in the early 1970s. The model's institutionalization reflected its utility in causal , prioritizing empirical calibration over ad hoc adjustments, though critics noted assumptions of constant returns and limited short-run dynamics. Australian economists adapted Johansen's approach through the government-sponsored IMPACT Project initiated in 1975, yielding the model by 1977—a 100-industry framework blending Leontief production with Armington import differentiation and flexible closure rules for macroeconomic variables. supported reduction analyses in the late 1970s, influencing Industries Assistance decisions, and by the early 1980s incorporated constant returns elasticities of substitution (CRESH) functions for refined labor and capital responses. Institutionalized at Monash University's Centre of , it generated over 200 policy applications by 1987, demonstrating CGE's expansion from academic prototypes to advisory standards. In , John B. Shoven and John Whalley pioneered policy-oriented CGE applications from 1972, employing Scarf's algorithm to model in multi-sector economies, such as corporate profit tax shifts in the UK and . Their frameworks, detailed in subsequent works through the 1980s, integrated distorting taxes, international trade elasticities, and benchmark equilibria calibrated to matrices, enabling simulations of reforms like corporate cuts. This period's expansion saw CGE models scale to dozens of sectors, with rigorous sensitivity analyses to parameter variations, though reliance on long-run Walrasian clearing raised questions about applicability to disequilibrium scenarios prevalent in empirical data. By the late 1980s, such models informed advisory bodies like the International Trade Commission, marking broader institutional adoption for trade and fiscal evaluations.

Maturation and Global Adoption (1990s-2000s)

During the , advancements in software tools significantly enhanced the practicality and accessibility of CGE models, with GAMS integrated with MPSGE and GEMPACK emerging as dominant platforms by the mid-decade. These systems facilitated efficient implementation and solution of complex nonlinear equations, reducing development costs and enabling model sharing among researchers and policymakers. By this period, nearly all policy-relevant CGE models relied on these tools, which supported flexible functional forms and large-scale computations previously hindered by computational limitations. Model structures matured through the integration of dynamic elements, shifting from static comparative analyses to recursive-dynamic frameworks that captured intertemporal effects such as and growth paths. This evolution, prominent from the early , allowed simulations of long-term policy impacts, including responses to shocks like reforms. Concurrently, multi-regional extensions proliferated, exemplified by the GTAP model's initial development in 1992 at , which provided a standardized global database for and analysis across 15 regions and 22 sectors in its first version. GTAP's framework linked flows to a general equilibrium system, fostering consistent cross-country comparisons. Global adoption accelerated as CGE models became staples in international policy evaluation, particularly for trade liberalization under the and agreements like in the early 1990s. The , a pioneer in CGE applications since the 1970s, expanded their use for economy-wide assessments in developing countries, informing structural adjustments and poverty analyses. By the decade's end, models incorporated environmental dimensions, simulating carbon taxes and resource management, with applications in over 50 countries via networks like PEP. In the 2000s, adoption deepened in multilateral institutions such as the IMF and for medium-term growth projections and , with dynamic variants assessing . GTAP's database updates, reaching version 6 by 2001 with expanded sectoral detail, supported over 1,000 global simulations annually. Regional models proliferated in , , and for accession impacts to the and WTO, reflecting CGE's role in evidence-based policymaking amid .

Core Features and Assumptions

Fundamental Components

Computable general equilibrium (CGE) models are built upon a framework of economic agents whose optimizing behaviors generate and supply functions, combined with market-clearing conditions that ensure all markets equilibrate simultaneously. The primary agents include representative households, which maximize derived from of subject to constraints derived from incomes and transfers, and firms in multiple sectors, which maximize profits by choosing input combinations to produce outputs given market prices. Production technologies are typically specified using constant returns-to-scale functions, such as Cobb-Douglas or (CES) aggregates that combine intermediate inputs and primary s like labor and capital, allowing for substitution elasticities calibrated from data. Behavioral equations stem from the first-order conditions of these optimization problems. For households, utility maximization yields Marshallian demand functions where consumption of good i is proportional to income shares adjusted by prices, as in c_i = \alpha_i (m - s) / p_i for Cobb-Douglas preferences, with \alpha_i as share parameters, m as income, s as savings, and p_i as price. Firms' profit maximization produces input demands, such as x_{ij} = \beta_{ij} y_j / p_i for intermediate inputs from sector i to j, where \beta_{ij} are technical coefficients and y_j is output, alongside factor demands like v_{fj} = \gamma_{fj} y_j / w_f for factor f at wage w_f. Government and rest-of-world agents may be incorporated to model tax collections, public expenditures, trade balances, and exchange rates, with their behaviors often treated as exogenous or rule-based. Equilibrium is defined by prices that clear all markets, meaning total supply equals total demand for each commodity (y_i = \sum_j x_{ij} + c_i + s_i + g_i + t_i) and factor (V_f = \sum_j v_{fj}), where g_i and t_i denote government and trade uses. Additional conditions include zero profits under perfect competition (p_j y_j = \sum_i p_i x_{ij} + \sum_f w_f v_{fj}) and income-expenditure balance for households. Markets encompass goods/services, labor, and capital (sometimes resources), with prices adjusting flexibly to achieve Walrasian equilibrium, often normalized by setting a numeraire price (e.g., to 1). The system's structure includes sets of sectors and factors, endogenous variables (prices, quantities), exogenous parameters (shares, elasticities from matrices), and a mix of behavioral and definitional equations equal in number to unknowns. rules specify , such as treating as savings-driven or as fixed, ensuring solvability as a via complementarity or fixed-point methods.

Calibration and Data Inputs

Calibration of computable general equilibrium (CGE) models involves selecting values such that the model reproduces a benchmark dataset representing an observed , typically for a base year. This process ensures the model's initial solution matches empirical quantities like levels, flows, and incomes, allowing simulations of shocks to deviate from this calibrated . Unlike full econometric , calibration often fixes certain parameters—such as input shares derived directly from data—and borrows others, like Armington elasticities of substitution, from prior studies or stylized assumptions, prioritizing computational tractability over . Primary data inputs for consist of matrices (SAMs), which tabulate intersectoral flows of goods, services, factors, and incomes across economic agents in a balanced . SAMs integrate elements from national input-output tables (capturing intermediate and final demands), supply-use tables (detailing production technologies), and satellite accounts for factors like labor and endowments. For instance, production coefficients in the model's input matrices, such as Leontief or CES functions, are inverted from these tables to yield fixed shares that sum to observed outputs; endowments are scaled from , often adjusted for using historical series. Global CGE models, like those in the GTAP , aggregate such data across regions and sectors from harmonized sources including statistics and tariff schedules. Calibration techniques typically employ nonlinear equation solvers to replicate zero-profit and market-clearing conditions in the , minimizing deviations between model-generated and observed aggregates. For dynamic extensions, baselines incorporate projected paths for , , and savings rates, calibrated via Bayesian methods or to align with macroeconomic forecasts. Critics, including econometricians, argue this approach embeds untested assumptions—such as perfect foresight or homogeneity—and underutilizes time-series data for parameter , potentially overstating model precision in . Nonetheless, remains standard due to sparse in many economies, enabling rapid replication of stylized facts like GDP composition.

Model Variants

Comparative-Static Frameworks

Comparative-static frameworks in computable general equilibrium (CGE) models analyze economic equilibria by comparing baseline conditions with post-shock outcomes, assuming full and instantaneous market adjustments without intertemporal dynamics. These models solve nonlinear systems representing producer , consumer utility maximization, zero-profit conditions, and , typically under and constant returns to scale. Unlike analytical , which rely on perturbations and linear approximations around equilibria, CGE variants handle finite shocks like tariff reductions or tax reforms by numerically resolving the full system. Calibration anchors these frameworks to empirical data, such as social accounting matrices (SAMs) from , ensuring the baseline equilibrium matches observed prices, quantities, and incomes for a reference year—often the most recent available benchmark, like 2017 global SAMs in GTAP models. Post-calibration, exogenous changes (e.g., a 10% tariff cut) alter parameters like endowments or trade elasticities, prompting iterative solution algorithms—such as nonlinear complementarity or fixed-point methods—to compute new equilibria. Armington assumptions differentiate domestic and imported goods via (CES) functions, with elasticities drawn from econometric estimates averaging 4-8 for trade substitution in many applications. Efficiency conditions in these models often manifest as matrix inequalities, where price vectors \mathbf{p} and activity levels \mathbf{z} satisfy \mathbf{p}^T \mathbf{A} \geq \rho \mathbf{p}^T \mathbf{B} for costs and \mathbf{A} \mathbf{z} \leq \rho \mathbf{B} \mathbf{z} for inputs, with \rho as a scaling factor normalizing the numéraire; equality holds at optimum under complementarity. Pioneered in works like Shoven and Whalley's 1972 tariff simulations, which computed U.S.-Canada trade equilibria under varying rates, these frameworks quantify welfare changes via equivalent variation—e.g., a 1-2% GDP gain from unilateral liberalization in calibrated U.S. models. Limitations include neglect of transition costs and capital accumulation, though they excel in tracing general equilibrium feedbacks, such as terms-of-trade effects amplifying or offsetting partial equilibrium gains by 20-50% in multi-region setups. Empirical validation against post-policy data, as in ex-post evaluations of NAFTA's 1.3% Mexican welfare boost, underscores their utility despite assumptions of foresight and flexibility.

Dynamic and Recursive Models

Recursive dynamic computable general equilibrium (CGE) models represent an extension of static frameworks by sequencing multiple single-period equilibria over discrete time horizons, enabling the simulation of paths and intertemporal . In these models, each period solves a static CGE , determining prices, quantities, and factor allocations conditional on inherited stocks and exogenous trends such as or improvements; outcomes like savings then determine , which updates for the subsequent period via accumulation equations of the form K_{t+1} = (1 - \delta)K_t + I_t, where \delta denotes the rate and I_t gross . This recursive structure links periods forward without fully solving a simultaneous intertemporal optimization, approximating perfect foresight by assuming agents form expectations based on current-period outcomes or exogenous baselines. Unlike purely static models, which capture only comparative-static adjustments without stocks, flows, or time-dependent variables, recursive dynamic variants distinguish between stocks (e.g., machinery persisting across periods) and flows (e.g., annual ), incorporating endogenous through savings-driven capital deepening while often treating labor supply as growing exogenously. typically extends static matrices with time-series data on rates (often 3-5% annually for aggregate ), savings propensities (e.g., derived from historical GDP shares), and total factor productivity trends (e.g., 1-2% per year in projections for developed economies). Solution proceeds iteratively: a without shocks establishes counterfactual , against which shocked scenarios reveal deviations in metrics like GDP trajectories or streams discounted to . These models facilitate analysis of policies with lagged or cumulative effects, such as carbon taxes influencing long-run transitions via induced turnover (e.g., replacing fossil-fuel vintages over 20-30 year horizons) or reforms spurring sustained gains through scale economies. However, the recursive approximation inherits limitations from static cores, including to closure rules for savings- balances and potential underrepresentation of forward-looking expectations if agents are modeled as myopic rather than rational. Empirical applications, such as GTAP-derived recursive , demonstrate their in projecting regional GDP under demographic shifts, with shares calibrated to match observed rates (e.g., 20-25% of GDP in emerging markets). Validation often involves hindcasting historical episodes, where model-generated paths align with actual growth within 1-2% deviations for aggregate variables.

Multi-Regional and Sectoral Extensions

Multi-regional extensions of computable general equilibrium (CGE) models partition the into distinct regions or countries, linked primarily through flows, to assess international spillovers from domestic policies. These frameworks incorporate the Armington assumption, treating commodities from different origins as imperfect substitutes to rationalize observed cross-hauling in data and enable modeling of substitution elasticities between domestic production and imports from various sources. The approach facilitates quantification of gains or losses across regions, such as those from , by capturing terms-of-trade effects and resource reallocation. A canonical implementation is the Global Trade Analysis Project (GTAP) model, initiated at with its first database released in 1994 and encompassing , constant , and explicit transport margins in . Later versions, such as GTAP 11 covering reference years up to 2017, aggregate data into 141 regions and 65 sectors, drawing from global input-output tables, bilateral statistics, and protection data to calibrate equilibrium prices and quantities. This structure supports simulations of global shocks, like tariff escalations, revealing heterogeneous regional impacts; for example, analyses using GTAP have estimated that U.S.- tensions in 2018-2019 reduced global welfare by approximately 0.2-0.5% of GDP equivalents, with disproportionate effects on export-dependent sectors in affected countries. Sectoral extensions complement multi-regional setups by increasing industry disaggregation, often to dozens or hundreds of sectors, to better represent interdependencies and sector-specific factor intensities derived from matrices. Such granularity reveals nuances overlooked in aggregate models, including low-substitutability linkages in or that amplify policy transmission; empirical demonstrate that disaggregating trade-exposed sectors can raise estimated rates from unilateral policies by 10-20% compared to coarser variants. In practice, these extensions enhance precision for targeted interventions, as seen in GTAP applications disaggregating technologies to evaluate renewable transitions, where finer detail alters projected investment shifts by up to 15% across regions. However, greater disaggregation demands robust data reconciliation to avoid calibration inconsistencies, typically achieved via minimization techniques on input-output frameworks.

Solution Techniques

Nonlinear Programming Approaches

Nonlinear programming (NLP) approaches to solving computable general equilibrium (CGE) models involve reformulating the system's nonlinear equations—representing agent optimization, , and conditions—as a constrained maximization or minimization problem. The general solution emerges as the optimizer, with shadow prices interpreted as prices and dual variables capturing complementarity conditions via Kuhn-Tucker optimality. This method leverages standard solvers to handle the large-scale, nonlinear structure typical of CGE models, which arise from (CES) production and utility functions. A key variant is the net social revenue (NSR) approach, which maximizes an objective defined as total sales revenues minus production and transport costs, subject to constraints for balances (e.g., ≤ supply) and non-arbitrage conditions (e.g., delivered prices ≥ basic prices). At the optimum, the objective value equals zero, and Lagrange multipliers yield prices, ensuring between primal quantities and prices for verification. Building on Takayama and Judge's 1971 spatial framework, this method accommodates fixed-coefficient Leontief technologies without estimating elasticities, enabling detailed data integration. Further formalized by MacAulay in 1992 and Salerian and Murray in 2019, NSR has been implemented in GAMS, producing results identical to mixed complementarity problem (MCP) solutions in benchmarks like Hosoe's small open-economy model. In practice, software such as GAMS implements CGE as by appending an arbitrary objective function—often a constant or like —to a square , with no impact on the unique feasible equilibrium. Solvers like CONOPT (developed by Drud) or (Stanford) iteratively adjust variables to satisfy conditions, exploiting sparsity in economic structures for efficiency on models with hundreds of sectors. This contrasts with pure equation-solving or MCP, as naturally incorporates strict inequalities (e.g., for capacity constraints or slack variables in rationing) but requires careful scaling to avoid local optima diverging from Walrasian equilibrium. Advantages of NLP include broader solver compatibility, including open-source options, and suitability for extensions like or linking with partial models (e.g., energy systems via shared variables). However, it demands precise constraint formulation to align the mathematical program with economic primitives, as mis-specification can yield shadow prices inconsistent with no-arbitrage. Empirical applications, such as policy simulations in productivity analyses, demonstrate NSR's robustness, with solution times comparable to MCP on standard hardware for multisectoral models.

Algebraic and Iterative Methods

Algebraic methods for solving (CGE) models typically involve representing the conditions as a derived from the model's behavioral equations, often in levels or percentage-change form, and solving via matrix inversion or algebraic substitution. Leif Johansen's 1960 approach pioneered this for multisectoral models, expressing the system as B \xi = L \alpha + F, where B captures technical coefficients, \xi endogenous variables, L exogenous shifts, \alpha parameters, and F fixed elements, solved by partitioning and inverting submatrices to yield multipliers for policy simulations. This method linearizes nonlinear functional forms like (CES) around a , reducing computational demands for large systems. Software such as GEMPACK implements algebraic back-substitution to eliminate variables, minimizing the equation count before inversion, as seen in models like where substitution exploits nested structures for efficiency. While exact for linear representations, nonlinearity requires re-linearization at updated points, blending into iterative procedures for accuracy in policy shocks. Iterative methods address the nonlinearity inherent in CGE models by repeatedly approximating the fixed point of excess or supply functions until criteria are met, often without inverting the full . Gauss-Seidel and Jacobi iterations sequentially solve blocks—such as deriving prices from zero-profit conditions given quantities, then updating quantities from given prices—updating variables in place for Gauss-Seidel to accelerate over simultaneous Jacobi updates. Newton-Raphson variants, as in PROC MODEL or GAMS solvers, linearize around current iterates using the for quadratic , applied to Shoven-Whalley style models with CES functions where initial guesses from benchmark data guide 20-30 iterations to residuals below $10^{-8}. Fixed-point iterations, rooted in Brouwer's , map trial solutions through the model's primitives, with (e.g., combinations of old and new values) ensuring stability in large models like GTAP. These methods, used by Jorgenson in early applied general equilibrium work, handle sparse structures efficiently but risk non- if parameters or ordering is suboptimal, necessitating tests. In practice, algebraic and iterative approaches complement each other: Johansen-style algebra provides a baseline linear solution for small shocks, iterated for larger deviations, while pure iteration suits mixed complementarity formats without explicit . Convergence relies on properties, validated empirically in software like GEMPACK's Euler integration with Gragg extrapolation for dynamic paths, achieving accuracy comparable to at lower cost for well-behaved models. Historical applications, from Johansen's Norwegian model to Shoven and Whalley's tax analyses, demonstrate robustness, though modern implementations incorporate for intertemporal extensions.

Policy Applications

Trade Liberalization and Tariff Analysis

Computable general equilibrium models are widely applied to evaluate the economy-wide impacts of trade liberalization, such as tariff reductions or eliminations, by simulating changes in relative prices, , and welfare across sectors and regions. These models incorporate as wedges between domestic and world prices, capturing effects in and , terms-of-trade adjustments, and shifts. For instance, a on imports raises the domestic of the imported good, leading to reduced imports, expanded domestic , and potential inefficiencies from distorted incentives, which CGE simulations quantify through counterfactual equilibria. In tariff analysis, CGE frameworks typically represent tariffs via input-output structures augmented with trade margins and Armington assumptions, distinguishing domestic and imported goods by assuming imperfect substitutability. Calibration uses base-year data from matrices (SAMs) or global trade databases like GTAP, where tariff rates are derived from applied schedules such as those in the WTO's Tariff Download Facility. Simulations of unilateral or multilateral liberalization—e.g., the removal of s under the —project gains from specialization according to , with aggregate increases often measured via equivalent variation, though regional asymmetries arise due to export competitiveness. A 1997 study using a global CGE model estimated that full merchandise liberalization could boost world by 0.7-2.1% of GDP, driven primarily by manufacturing sector expansions in developing economies. Multiregional CGE models, such as the GTAP framework, extend this to bilateral tariff cuts, accounting for supply chain linkages and rules of origin in free trade agreements (FTAs). For example, analysis of the U.S.-China Phase One trade deal (2020) via CGE revealed that tariff escalations reduced U.S. GDP by 0.2-0.3% and Chinese exports by up to 7%, with retaliatory tariffs amplifying losses through higher input costs for downstream industries. Empirical validation often compares model predictions to post-policy data, as in the case of NAFTA (1994), where CGE forecasts of modest Mexican welfare gains (1-2%) aligned with observed export growth but understated labor displacement in import-competing sectors. Critics note that standard CGE assumptions, like constant and , may overstate liberalization benefits by neglecting dynamic gains from scale economies or innovation spillovers, as evidenced by ex-post studies showing larger boosts in liberalizing economies than static models predict. Nonetheless, dynamic-recursive variants incorporating have been used to assess long-term effects, such as tariff phase-outs in agreements yielding sustained GDP growth differentials of 0.5-1% annually in member states.

Environmental Regulation and Climate Interventions

Computable general equilibrium (CGE) models evaluate environmental regulations by simulating how policy-induced price distortions, such as emissions taxes or quantity constraints, alter , , , and across sectors and regions. These models incorporate environmental externalities through extensions like elasticities and factors, allowing quantification of trade-offs between reductions and economic output. For instance, the EPA's model analyzes U.S. regulations by tracing impacts from regulated sectors to upstream suppliers and downstream users, estimating effects on GDP, , and under assumptions of and rational agents. In climate policy analysis, CGE frameworks compare instruments like carbon taxes and cap-and-trade systems, often finding taxes yield lower abatement costs due to smoother price signals and revenue recycling potential. A multi-model comparison for China projected that a carbon tax of 50-100 CNY per ton CO2 could reduce emissions by 10-20% by 2030 while contracting GDP by 0.5-1.5%, with variations driven by labor mobility and substitution elasticities. Similarly, the Goulder-Hafstead E3 model simulated U.S. cap-and-trade programs equivalent to a $20-40 per ton CO2 price, forecasting 20-40% emission cuts by 2030 with GDP losses under 1% when revenues fund lump-sum rebates, though border adjustments mitigate leakage in open economies. Multi-regional variants like GTAP-E extend this to global climate interventions, capturing terms-of-trade effects and emission trading. Simulations of uniform carbon pricing across regions predict welfare losses concentrated in energy-exporting developing economies, with emission reductions of 20-50% by 2050 requiring prices of $50-100 per ton, but outcomes hinge on assumptions of Armington trade differentiation that may overestimate substitution feasibility. Empirical validation against British Columbia's 2008 carbon tax, phased to $30 CAD per ton, showed CGE estimates aligning with observed 5-15% emission drops and negligible GDP effects, supporting revenue-neutral designs that offset fiscal distortions. However, models often understate transitional frictions, such as capital stranding in fossil sectors, as critiqued in comparisons revealing GDP impacts 2-3 times higher under heterogeneous firm data than homogeneous assumptions.

Fiscal Reforms and Development Strategies

Computable general equilibrium (CGE) models evaluate fiscal reforms by simulating their effects on government budgets, sectoral production, household welfare, and macroeconomic aggregates, capturing distortions from taxes and subsidies within a calibrated economy-wide framework. These models typically incorporate fiscal instruments such as value-added taxes, taxes, and expenditures using matrices derived from data, enabling quantification of deadweight losses and revenue-neutral shifts. For instance, analyses reveal that reforming inefficient tax structures, like reducing reliance on trade taxes, can enhance efficiency by lowering the of public funds, particularly in resource-constrained economies. In developing countries, CGE applications to reforms often highlight trade-offs between mobilization and . A study across 38 African nations computed the of funds for various es, finding and levies impose higher costs than labor or es due to their distortionary impacts on factor supplies and flows, with costs exceeding 1.5 in many cases for non-labor instruments. Similarly, combined CGE-microsimulation models assessed major overhauls in contexts like , projecting distributional effects where base-broadening measures increased GDP by 1-2% over baseline scenarios while mitigating poverty rises through targeted transfers, as analyzed in 2015 evaluations. reforms, a common fiscal lever, have been modeled to show fiscal savings of up to 2-5% of GDP in low-income settings, offset by compensatory spending to protect vulnerable households from price shocks. For development strategies, CGE models simulate long-term growth paths under alternative fiscal allocations, such as boosting public investment in or . In , a 2014 World Bank CGE analysis compared growth options, finding that reallocating expenditures toward productive sectors could raise annual GDP growth by 0.5-1 percentage points over a decade, contingent on improved and foreign absorption. Historical applications in (1980) and (1978) used CGE frameworks to inform redistribution-focused strategies, projecting sectoral shifts that supported targets adopted by the . These exercises underscore CGE's role in testing causal links between fiscal multipliers and development outcomes, though results hinge on closure rules like savings propensities.

Strengths and Empirical Contributions

Policy-Relevant Insights

CGE models demonstrate that trade liberalization typically generates net gains through resource reallocation toward sectors of , with empirical simulations indicating increases of 1 to 2 percent in due to pro-competitive effects reducing markups. In multi-regional applications like the GTAP framework, full liberalization yields disproportionate benefits for developing economies, equivalent to 1.35 percent of GDP, by enhancing competitiveness and without assuming fixed outputs. These results underscore the causal link between reduced barriers and gains, though they also reveal sectoral dislocations requiring targeted compensation to mitigate short-term losses for import-competing industries. For environmental regulations, CGE analyses quantify the of externalities via instruments like carbon taxes, showing that revenue-neutral —such as rebates or reductions in labor taxes—minimizes GDP contractions, often limiting losses to under 1 percent while achieving substantial emission cuts. Models like the EPA's reveal that revenues to offset distortionary taxes can yield a "double dividend" of environmental improvements and slight enhancements, as lower marginal rates boost labor supply and without exacerbating if lump-sum distributions are prioritized. This approach highlights causal trade-offs, where unrecycled taxes impose higher growth costs, informing designs that align ecological goals with . In , CGE simulations of base-broadening reforms—replacing narrow levies with low-rate, broad-based taxes—project long-term GDP expansions by curtailing deadweight losses and incentivizing investment, with dynamic models estimating sustained growth accelerations in reforming economies. For instance, shifting from corporate-specific taxes to flat consumption taxes in developing contexts, as modeled for , elevates efficiency and revenue neutrality, fostering broader development by simulating inter-sectoral spillovers absent in partial equilibrium tools. These insights reveal how fiscal distortions propagate economy-wide, guiding reforms toward neutrality that enhance without relying on unsubstantiated multipliers. Overall, CGE frameworks provide policymakers with consistent, economy-wide projections that capture policy interactions and second-best optima, as validated by alignments with econometric estimates of responses to shocks, thereby supporting in real-world applications like World Bank growth strategies. By enforcing Walrasian —where aggregate supplies equal demands—these models expose inconsistencies in analyses, enabling robust evaluation of interventions from tariff cuts to climate pricing.

Validation Against Real-World Outcomes

Ex-post evaluations provide a key mechanism for assessing the predictive accuracy of computable general equilibrium (CGE) models by comparing pre-policy simulations to observed post-policy . Such validations are essential for building confidence in model outputs, particularly for policy applications like trade agreements, where models forecast changes in trade flows, sectoral outputs, and . Studies demonstrate that CGE models often succeed in capturing qualitative directions and relative magnitudes of effects, though absolute quantitative matches can vary due to unmodeled dynamics or parameter sensitivities. A notable case is the North American Free Trade Agreement (NAFTA), implemented on January 1, 1994. Applied general equilibrium models, including variants of the Michigan Model and others calibrated to pre-NAFTA data, were evaluated against actual outcomes in trade volumes, GDP growth, and employment shifts across U.S., Mexican, and Canadian sectors through the late 1990s and early 2000s. Timothy Kehoe's analysis found that while some models overestimated aggregate employment gains—predicting up to 200,000 additional U.S. jobs versus observed stagnation or modest declines in manufacturing—they accurately replicated relative sectoral trade expansions, such as a 15-20% rise in Mexican exports to the U.S. in transport equipment, aligning with empirical data from U.S. International Trade Commission reports. Directional welfare improvements, including efficiency gains from resource reallocation, also matched observed patterns, with model-predicted GDP boosts of 0.5-1% for Mexico corroborating post-NAFTA growth rates averaging 3-4% annually in the initial years. Similar validations appear in evaluations of the Canada-U.S. Free Trade Agreement (CUFTA), effective January 1, 1989. The Cox-Harris CGE model, run , forecasted increases of 10-15% in aggregate, with stronger effects in skill-intensive sectors; ex-post comparisons using and U.S. Census Bureau data confirmed these relative shifts, including a 25% expansion in Canadian machinery exports, though absolute volumes exceeded predictions due to complementary productivity surges not fully anticipated. In energy and environmental policy, CGE models assessing carbon pricing pilots, such as British Columbia's 2008 carbon tax, have shown reasonable alignment: simulations predicted minimal GDP impacts (under 0.5% decline) and sectoral reallocations toward less carbon-intensive activities, consistent with observed outcomes of stable growth and a 5-15% emissions drop without significant employment losses in taxed sectors. Broader empirical exercises, including stochastic CGE variants, further support validation by outperforming naive trend extrapolations in disaggregated variables like agricultural price volatility or regional output under trade shocks. For instance, models incorporating historical shocks from the replicated observed deviations in global trade elasticities, with predicted welfare losses within 10-20% of IMF and estimates. These successes underscore CGE models' utility for relative impact analysis, provided calibrations draw from robust matrices and tests account for .

Criticisms and Limitations

Theoretical Assumptions Under Scrutiny

Computable general equilibrium (CGE) models rest on the Walrasian framework, positing that markets clear through price adjustments, agents optimize rationally, and resources allocate efficiently to achieve Pareto optimality. This assumes , where firms and households take prices as given, leading to zero economic profits and of factors. However, empirical evidence from reveals widespread , with markups averaging 1.2 to 1.5 across U.S. sectors as of 2019 data, contradicting the constant returns and infinitesimal agent assumptions inherent in standard CGE specifications. The representative agent paradigm, aggregating heterogeneous households into a single utility maximizer with fixed preferences (often Cobb-Douglas), underpins consumer behavior in CGE models but overlooks income distribution effects and varying elasticities. Calibration via social accounting matrices enforces benchmark equilibrium, yet this imposes aggregation biases, ignoring household production and behavioral deviations documented in micro-data, such as time-use surveys showing non-market activities comprising 30-40% of total output in developed economies. Rational expectations, assuming perfect foresight, further strain realism amid evidence of bounded rationality and learning from behavioral experiments, where subjects deviate from optimization in 20-50% of cases under uncertainty. Functional forms, like Armington for (imperfect between domestic and imported ) or CES production, introduce rigidity; for instance, Armington elasticities calibrated at 2-4 yield exaggerated exchange rate swings in tariff simulations, misaligning with observed pass-through rates below 0.5 in post-NAFTA data. Closure rules—specifying exogenous variables like savings rates or labor supply—remain , with choices altering outcomes by 10-20% in sensitivity tests, undermining claims of robustness. Theoretical foundations falter on , , and : the Sonnenschein-Mantel-Debreu demonstrates that aggregate excess demand lacks structure beyond Walras' , permitting in even three-good economies, as Scarf's 1960 examples illustrate chaotic price paths. Nonconvexities from increasing returns, prevalent in services (40% of GDP in OECD countries by 2020), preclude equilibrium without auxiliary assumptions, while multiple equilibria arise under distortions, complicating policy counterfactuals. Despite tractability enabling computation, these lapses—rooted in idealized Arrow-Debreu conditions—yield predictions sensitive to perturbations, as evidenced by divergent CGE results across models for the same shocks, with variance up to 50% in welfare estimates.

Empirical and Computational Shortfalls

CGE models exhibit empirical shortfalls stemming from their predominant use of over econometric , where parameters are fitted to a single base-year Social Accounting Matrix () without statistical validation for predictive power. This method introduces biases through subjective data adjustments, as seen in cases like Mozambique's 1995 SAM, where revisions totaled $295 million (11.65% of GDP), including arbitrary reallocations such as a $58 million increase to agricultural (5% of GDP). Critics argue that such practices, coupled with untested elasticities drawn from literature rather than time-series data, undermine out-of-sample reliability and impose restrictive (CES) functional forms that disproportionately shape outcomes. Forecast validation against observed data further reveals inaccuracies, with baseline projections in prominent models like GTAP showing unweighted errors of 31.9% to 34.4% for outputs over 2014–2017, and weighted errors ranging from 27.4% to 30.0%. These errors arise partly from data inconsistencies across 27 of 45 -region pairs and an inability to endogenously capture rates or structural shifts, such as rapid expansions, forcing reliance on exogenous trends that fail to align with real-world dynamics. Moreover, assumptions of , , and static equilibria misrepresent frictions like and balance-of-payments constraints, leading to overstated welfare effects in policy simulations, particularly for trade where elasticities are inflated by factors of 3–5. Computationally, CGE models demand solving vast nonlinear systems, with large-scale intertemporal variants encompassing up to 32.7 million variables straining serial solvers like GEMPACK or GAMS due to memory limits and prolonged run times exceeding one hour for complex benchmarks. Iterative methods such as Newton-Raphson often encounter failures in high-dimensional settings, exacerbated by the curse of dimensionality from numerous sectors and agents. Addressing these requires specialized techniques, including via singly bordered block-diagonal decompositions, which can reduce times to 4–5 minutes but still hinge on data-intensive preprocessing that amplifies errors in regions with incomplete inputs. Static linearizations, commonly used to approximate equilibria, further compromise accuracy by neglecting nonlinear feedbacks essential for dynamic policy assessments.

Debates Over Policy Implications

Critics of computable general equilibrium (CGE) models argue that their policy implications often favor market due to core assumptions of , constant , and , which systematically understate barriers to adjustment and distributional losses from reforms like tariff reductions. These models, rooted in Walrasian , simulate economy-wide reallocation under policy shocks but embed a bias toward gains by presupposing frictionless markets and rational optimization, leading to projections that prioritize aggregate welfare over sector-specific disruptions or exacerbation. For instance, in trade policy analyses, CGE simulations frequently yield small positive net effects from —often under 1% of GDP—while marginalizing short-term or skill mismatches that empirical post-reform data reveal as significant. Proponents counter that CGE frameworks provide a rigorous, internally consistent for counterfactual , enabling policymakers to trace causal chains from interventions like fiscal adjustments to sectoral outputs, as demonstrated in applications for structural reforms in developing economies. However, econometric critiques highlight vulnerabilities in parameter selection, such as reliance on (CES) functions with elasticities drawn from limited rather than dynamic time-series evidence, which can amplify pro-competitive outcomes and mislead on policy magnitudes. This has fueled debates over credibility, particularly in international negotiations like or TTIP, where model variants chosen by analysts—often from neoliberal-leaning institutions—produced optimistic trade gain estimates that ignored Armington assumption limitations on and real-world transport costs. Further contention arises from CGE's static structure, which fixes factor supplies and output levels in many implementations, precluding endogenous or responses critical to long-run , thus rendering implications conservative for supply-side reforms but overly deterministic for demand-driven ones. In sustainability assessments, models have been faulted for inadequately capturing effects or non-market costs, leading to understated implications for carbon where simulated offsets exceed observed empirical emissions reductions. Academic sources advancing such critiques often reflect interventionist priors prevalent in , yet validation studies show CGE predictions aligning with aggregate trade flows in select cases, like post-Uruguay Round adjustments, underscoring the tension between theoretical purity and causal . Policymakers thus over-reliance on these tools, advocating approaches integrating micro-founded to mitigate assumption-driven biases in high-stakes decisions.

Recent Advances

Incorporation of Heterogeneity and Uncertainty

Recent developments in computable general equilibrium (CGE) modeling have addressed the limitations of representative agent assumptions by incorporating firm-level heterogeneity, drawing from Melitz (2003) frameworks that differentiate firms by productivity and fixed export costs. In these extensions, firms are modeled with Pareto-distributed productivity draws, enabling simulations of trade liberalization effects that account for selection into export markets and aggregate productivity gains from reallocation toward more efficient producers. For instance, the GTAP-HET model, introduced in 2016, integrates such firm heterogeneity into the global GTAP framework, demonstrating improved accuracy in predicting trade expansion and welfare changes compared to Armington-based models, as heterogeneous firms amplify gains from through within-industry reallocation. Similarly, a parsimonious Melitz-style approach applied in 2018 CGE models uses logit probabilities for firm entry and exit, preserving computational tractability while capturing granularity in trade responses without full microsimulation. Household heterogeneity has been advanced through techniques in dynamic CGE models, which generate disaggregated outcomes—such as distributions or patterns—from aggregate representative agent results calibrated to . A 2017 method, for example, employs conditional and minimization to allocate economy-wide shocks across heterogeneous types defined by demographics or endowments, revealing distributional impacts overlooked in homogeneous setups, such as regressive effects of price hikes on low- groups in long-run scenarios. These approaches often link CGE with microsimulation models, preserving general feedbacks while incorporating empirical heterogeneity from surveys, though they require careful to avoid aggregation biases. To handle , stochastic extensions of CGE models replace deterministic equilibria with expected-value optimizations under , incorporating probabilistic shocks like fluctuations or variability via recursive dynamics or mean-variance preferences. A review from 2013 highlights early efforts in environmental CGE applications, where accounts for by solving for robust equilibria under scenario trees, outperforming deterministic baselines in hedging against downside outcomes. More recent methods, such as informed Gaussian quadrature rotations in 2022, enable efficient of multivariate shocks in multi-sector CGE frameworks, reducing computational demands while quantifying variance in impacts across structures. Bayesian techniques further address model by averaging over priors and alternative specifications, as in 2023 analyses that weight CGE variants for sectors, mitigating overconfidence in point estimates from single deterministic runs. Integrating heterogeneity with uncertainty yields hybrid models that simulate distributional risks, such as linking agent-based heterogeneity to stochastic general equilibrium for climate mitigation, where behavioral responses among diverse households under shock distributions reveal amplified regional vulnerabilities. These advances enhance policy realism but increase data demands and solution complexity, often requiring for convergence in large-scale calibrations.

Integration with Big Data and Machine Learning

Recent advances in computable general equilibrium (CGE) modeling have incorporated (ML) techniques to address computational bottlenecks, particularly in approximating nonlinear dynamics and conducting large-scale sensitivity analyses. Neural networks, for instance, serve as models to emulate the reduced forms of multi-regional CGE frameworks, enabling faster simulations without sacrificing accuracy compared to traditional linearization methods, which often fail to capture complex interactions. A 2024 study demonstrated that feedforward neural networks can approximate CGE outputs with , reducing computation time for optimization tasks over vast parameter spaces. This approach has been applied to models like DEMETRA, a single-country CGE for , where artificial neural networks reliably replicate equilibrium outcomes under varying shocks, facilitating broader . Big data integration enhances CGE calibration by incorporating granular, high-volume datasets—such as transaction-level records or firm-level metrics—to refine parameters like elasticities and substitution rates, which traditional often underrepresent. In applications, from and IoT sensors have been fused with CGE structures to model resource flows more dynamically, improving forecasts of policy impacts like carbon pricing. For disaster resilience, ML-enabled CGE models, such as those in the IN-CORE , leverage on economic interdependencies to simulate post-hazard recoveries, drawing from multiple sources including input-output tables and household surveys to quantify sectoral disruptions. These integrations mitigate assumptions of perfect foresight by using ML for uncertainty propagation, as seen in meta-models that predict outcomes across thousands of scenarios. Empirical validation of these hybrid approaches shows promise but highlights challenges in data quality and overfitting. A 2024 review of CGE literature notes that while ML surrogates accelerate simulations—e.g., from hours to seconds per run—they require extensive training data to avoid biases in underrepresented regions, underscoring the need for robust cross-validation against observed equilibria. In trade policy analysis, combining CGE with deep neural networks has yielded predictions aligning within 5-10% of historical bilateral flows, outperforming models in volatile contexts. Nonetheless, systemic limitations persist, as ML's black-box nature can obscure causal mechanisms central to CGE's general equilibrium logic, prompting calls for interpretable models.

References

  1. [1]
    Computable General Equilibrium modelling: introduction - gov.scot
    Jan 6, 2016 · Provides an introduction to Computable General Equilibrium (CGE) modelling and the key features of our in-house CGE model.
  2. [2]
    Introduction to Computable General Equilibrium Models
    Computable general equilibrium (CGE) models are widely used by governmental organizations and academic institutions to analyze the economy-wide effects of ...
  3. [3]
    Computable General Equilibrium Model - ScienceDirect.com
    The first computable general equilibrium (CGE) model, developed for Norway by Leif Johansen (Johansen, 1960), was intended to be used for policy analysis and ...
  4. [4]
    CGE Modeling for Regulatory Analysis | US EPA
    SAGE is a CGE model of the United States economy developed to aid in the analysis of environmental regulations and policies.Missing: definition | Show results with:definition
  5. [5]
    Computable General Equilibrium Modeling and GTAP
    Sep 7, 2011 · An important limitation of CGE models is that very few of them are tested as a whole against historical experience-although GTAP is one such ( ...
  6. [6]
    [PDF] an introduction to the itc computable general equilibrium model
    Chapter 2 provides an introduction to CGE models and their application to policy analysis. Chapter 3 describes the various components of the ITC CGE model and ...Missing: definition | Show results with:definition
  7. [7]
    CGE Model - an overview | ScienceDirect Topics
    A CGE model is a large system of simultaneous non-linear equations – to solve it presents a considerable computational challenge.
  8. [8]
    Algorithmic foundations of computable general equilibrium theory
    One of the great achievements of mathematical economics in the 20th century was the Walrasian economic equilibrium existence proof of Arrow and Debreu [2]. It ...
  9. [9]
    https://www.worldscientific.com/doi/10.1142/9789813208179_0001
  10. [10]
    Computable General Equilibrium - an overview | ScienceDirect Topics
    The computable general equilibrium (CGE) approach to modeling an economy was made possible by Herbert Scarf's algorithm for solving complete general equilibrium ...
  11. [11]
    None
    Summary of each segment:
  12. [12]
    An Example of an Algorithm for Calculating General Equilibrium Prices
    An Example of an Algorithm for Calculating. General Equilibrium Prices. By HERBERT SCARF*. During the past several years a number of writers have been involved ...
  13. [13]
    An Example of an Algorithm for Calculating General Equilibrium Prices
    An Example of an Algorithm for Calculating General Equilibrium Prices ; Authors. Herbert E. Scarf ; Document Type. Discussion Paper ; Publication Date. 6-1-1969 ...Missing: computing | Show results with:computing
  14. [14]
    [PDF] Discussion Papers in Economics No. 12/06 Herbert Scarf
    In the early 1960s he invented a path-breaking technique for computing equilibrium prices. This method is nowadays known as Scarf's algorithm and has made ...
  15. [15]
    Distinguished Fellow Herbert Scarf's Contributions to Economics
    While working with Arrow and Karlin on inventories, Scarf was introduced to general equilibrium theory. At the time, Arrow was working with Leonid. Hurwicz and ...
  16. [16]
    Symbolic Compuation in Computable General Equilibrium Modeling
    Alongside theoretical developments of mathematical economics in the fifties and sixties, the emerging field of computable general equilibrium (CGE) modeling ...
  17. [17]
    [PDF] Johansen's Contribution to CGE Modelling - CoPS
    May 21, 2010 · Abstract. Fifty years ago the Norwegian economist, Leif Johansen, gave us what is now recognised as the first. CGE model.
  18. [18]
    Commemorating Leif Johansen (1930–1982) and his pioneering ...
    This was Johansen's doctoral thesis and recognized in retrospect not only as the first work in the computational general equilibrium (CGE) modelling literature ...
  19. [19]
    The multi-sectoral growth model MSG-4. Formal structure and ...
    ABSTRACT. In the first part of this paper a brief retrospective survey of the development of the MSG model is given, from it was first presented in.
  20. [20]
    Leif Johansen 1930-1982 - jstor
    ... models in many countries, and in Norway it was used as a basis for the so-called MSG model, which has been used by the Ministry of Finance for long term ...
  21. [21]
    [PDF] ORANI-G: A General Equilibrium Model of the Australian Economy
    ORANI is an applied general equilibrium (AGE) model of the Australian economy which was first devel- oped in the late 1970s as part of the government-sponsored ...
  22. [22]
    [PDF] Trade Policy in Australia and the Development of Computable ...
    The Model. The main model developed at the IMPACT Project in the 1970s was ORANI. Initially ORANI was designed to satisfy Rattigan's requirement for a tool that.
  23. [23]
    None
    ### Summary of CGE Models in Development Economics
  24. [24]
    [PDF] American Economic Association - UN.org.
    The model of the United States (Ballard, Full- erton, Shoven, Whalley: BFSW, forthcom- ing) incorporates all major distorting taxes as in earlier work, but ...Missing: CGE | Show results with:CGE
  25. [25]
    [PDF] How to Evaluate Computable Models of Trade - Serge Shikher
    CGE models developed further in 1970s. In the United States, John Shoven at Stanford University and John Whalley contributed trade analyses based on CGE models ...<|separator|>
  26. [26]
    [PDF] Chapter 14 Economic Analysis at the US International Trade ...
    The economics profession began to develop more complicated “computable general equilibrium” (CGE) models in the 1970s and 1980s that operationalized these ...
  27. [27]
    [PDF] Solution Software for CGE Modeling - CoPS
    By the mid-1990s, nearly all policy-important CGE models were implemented and solved using one of. GAMS, MPSGE or GEMPACK. For this reason we only discuss these ...
  28. [28]
    [PDF] Shaping Baseline Scenarios of Economic Activity with CGE Models
    In the early 1990s, the first global economic trade models were being developed to assess the economic consequences of a potential conclusion to the Uruguay.
  29. [29]
    [PDF] The GTAP Recursive Dynamic (GTAP-RD) Model: Version 1.0
    Feb 8, 2019 · First developed in 1992, the GTAP model has become the de facto standard and starting point for nearly all economy-wide analyses of global trade ...
  30. [30]
    GTAP History - About GTAP
    The timeline and history of the GTAP Data Base are also very helpful in viewing GTAP's and the Center's development over the past decades. Humble Beginnings: ...
  31. [31]
    [PDF] The Impact of Computable General Equilibrium Models on Policy
    If the estimates of job displacement had been very large, this legislation would have been much more controversial. In the event, the predictions were correct ...
  32. [32]
    Modeling the Global Economy – Forward-Looking Scenarios for ...
    Since the 1970s, the World Bank has been at the forefront of CGE modeling both as a producer and a consumer.
  33. [33]
    Chapter 24 CGE Modeling of Environmental Policy and Resource ...
    Since the beginning of the 1990s CGE modeling has also become a widely used tool for analysis of environmental policy and natural resource management issues.
  34. [34]
    [PDF] A 25-year Retrospective on GTAP and the Shaping of a New Agenda
    This article looks back at 25 years of achievements of the Global Trade Analysis. Project (GTAP) from different angles. It covers the design features of the ...
  35. [35]
    [PDF] Computable General Equilibrium Models and Their Use in Economy ...
    CGE models are the primary tool for analyzing the impacts across multiple markets of changes in one or more policy variables. These are model parameters that ...
  36. [36]
    [PDF] Introduction To Computable General Equilibrium Mo
    Computable general equilibrium models typically consist of several fundamental components: Agents: Households, firms, government, and 1. sometimes foreign ...<|separator|>
  37. [37]
    [PDF] Calibrated Models - UC Davis Economics Department
    The process called calibration has a long tradition in economics. It has found widespread use in computable general equilibrium models of public finance and.
  38. [38]
    [PDF] Computable General Equilibrium (CGE) Models
    Use historical investment data, adjusted for price inflation and depreciation, to obtain capital stocks. – Use capital-output ratios to derive rough.
  39. [39]
    [PDF] Introduction to Key Data Inputs for Global CGE Modeling - ESCWA
    GTAP label. GTAP label. Paddy rice. Forestry. Wheat. Fishing. Cereal grains nec. Textiles. Vegetables, fruit, nuts. Wearing apparel. Oil seeds.
  40. [40]
    [PDF] Calibration, Solution and Validation of the CGE Model - UN.org.
    The calibration method relies on the assumption that the economy is ... Structuralist Computable General Equilibrium Models for the Developing. World, pp.
  41. [41]
    A Dynamic Baseline Calibration Procedure for CGE models
    Mar 31, 2022 · We propose a general, Bayesian approach that can be employed to build a baseline for any recursive-dynamic CGE model.
  42. [42]
    The econometric critique of computable general equilibrium modeling
    This paper revisits the debate over whether CGE models should be constructed using calibration or econometric methods. A compelling case has been made in ...
  43. [43]
    [PDF] A Computable General Equilibrium Model of Cedar Rapids
    This report uses a comparative-static (spatial) CGE modeling approach. Comparative-static approaches compare two alternative equilibria in order to assess ...
  44. [44]
    [PDF] Computable General Equilibrium Models in Economics - IIASA PURE
    Mar 26, 1992 · The aim of this paper is to give an overview of the modeling tradition, its theoretical foundation, characteristic features and main ...
  45. [45]
    GTAP Data Bases: Other Data and Models
    Feb 20, 2025 · FTAP Model is a comparative static, computable general equilibrium model of the world economy that includes a treatment of foreign direct ...
  46. [46]
    [PDF] Appendix: Model Documentation - ERS.USDA.gov
    GTAP is a comparative static model with price-taking behavior for all economic agents and full employment of resources. Land is employed in agriculture only ...
  47. [47]
    [PDF] Global Comparatives Statics in General Equilibrium
    I show how the tools from early local comparative statics analyses can be generalized via the use of Shepard's lemma, duality, complementarity and the Karush- ...
  48. [48]
    Capital markets and computable general equilibrium models
    Observing that many computable general equilibrium (CGE) models differ in their assumption about capital mobility, this paper examines the implications for ...
  49. [49]
    [PDF] The Benefits of Linking CGE and Microsimulation Models
    Comparative-static models are by far the most common class of CGE models.9 The eco- nomy is modelled at two given points in time only: the status quo ...
  50. [50]
    [PDF] PE VS. GE: MODEL PREDICTIONS OF INDUSTRY SPECIFIC ...
    Jul 22, 2019 · We draw on industry-specific policy shocks that have been previously been simulated using computable general equilibrium Armington models. We ...Missing: criticisms | Show results with:criticisms
  51. [51]
    [PDF] Introduction to computable general equilibrium (CGE) Modelling
    The distinguishing feature of a dynamic CGE model, however, is that growth of output is possible and changes due to policy reforms can be tracked over a given ...<|separator|>
  52. [52]
    PEP Standard CGE Models - Partnership for Economic Policy
    Technically speaking, PEP 1-t is a "recursive dynamic" version of PEP 1-1 (which is a static or single-period model): it extends the analysis to multiple ...Missing: explanation | Show results with:explanation
  53. [53]
    [PDF] A generic approach to investment modelling in recursive dynamic ...
    A vexing issue in recursively dynamic CGE models is concerned with allocating investments across sectors and/or regions which is essentially a forward-looking ...Missing: explanation | Show results with:explanation
  54. [54]
    Moving from Static to Dynamic General Equilibrium Economic ... - MIT
    A detailed description of step-by-step transformation of a simple static general equilibrium model into a dynamic Ramsey model.
  55. [55]
    [PDF] Demystifying Modelling Methods for Trade Policy
    SHORT HISTORY OF CGE MODELLING ... The second major advance was the axiomatic approach adopted in the Arrow-Debreu model.Missing: connection | Show results with:connection
  56. [56]
    G-RDEM: A GTAP-Based Recursive Dynamic CGE Model for Long ...
    Jun 26, 2019 · A computable general equilibrium tool for long-term counterfactual analysis and baseline generation from given gross domestic product (GDP) and population ...Missing: explanation | Show results with:explanation
  57. [57]
    A recursive dynamic CGE approach to investigate environmental ...
    The objective is to extract EKC for G7 countries using a multi-regional CGE model and investigate the effects of some key factors affecting EKC using historical ...Missing: explanation | Show results with:explanation
  58. [58]
    Intertemporal Computable Equilibrium System (ICES) Global CGE ...
    ICES is a recursive dynamic multiregional computable general equilibrium (CGE) model for the economic assessment of climate change impacts and policies.Missing: explanation | Show results with:explanation
  59. [59]
    Estimation of Armington elasticities in a CGE economy–energy ...
    Regarding trade, most CGE models apply the Armington assumption (Armington, 1969). The assumption determines the degree of substitutability between imported ...
  60. [60]
    The advantage of avoiding the Armington assumption in multi-region ...
    This paper presents an alternative algorithm for multi-region CGE models that is based on the assumption that goods produced in different regions are perfect ...
  61. [61]
    Current GTAP Model - Global Trade Analysis Project (GTAP)
    Jun 19, 2025 · The standard GTAP Model is a multiregion, multisector, computable general equilibrium model, with perfect competition and constant returns to scale.Missing: multi- | Show results with:multi-
  62. [62]
    [PDF] The Global Trade Analysis Project (GTAP) Data Base: Version 11
    Feb 27, 2023 · GTAP 11 offers a time series of 5 reference years (2004, 2007, 2011, 2014, and 2017), distinguishes 65 sectors in each of 141 countries and 19 ...
  63. [63]
    Resource Display: Modeling Trade Tensions: Macroeconomic and ...
    Trade economists in some institutions mainly rely on computable general equilibrium (CGE) models with considerable sectoral disaggregation, focus on input ...
  64. [64]
    Advantages of the Regional and Sectoral Disaggregation of a ...
    Nov 9, 2019 · Sectoral disaggregation would also improve the quality of the model if key industries that have low substitutability and cause supply chain ...
  65. [65]
    Estimating carbon leakage and the efficiency of border adjustments ...
    As this paper's focus is on the estimation of the value of sectoral disaggregation in calibrated general equilibrium models, I use a standard model based on ...
  66. [66]
    Disaggregating electricity generation technologies in CGE models
    This paper clarifies, expands, and illustrates the “technology bundle” approach to disaggregated modelling of the electricity sector in CGE models.
  67. [67]
    The value-added of sectoral disaggregation: Implications on
    In this paper, we elaborate on the availability of data resources and methodological issues in disaggregating energy-intensive and trade-exposed sectors.
  68. [68]
    [PDF] Solving Computable General Equilibrium Models with SAS
    This paper demon- strates two methods for solving equations. One method uses PROC MODEL which is available on the. ETS rсpackage and the other uses PROC NLP ...Missing: approaches | Show results with:approaches
  69. [69]
    [PDF] The Net Social Revenue Approach to Solving Computable General ...
    The nonlinear programming approach also increases the number of computer software packages available for both building and solving CGE models, including open ...
  70. [70]
    [PDF] A standard computable general equilibrium (CGE) model in GAMS
    Library of Congress Cataloging-in-Publication Data. Lofgren, Hans. A standard computable general equilibrium (CGE) model in GAMS / Hans. Lofgren, Rebecca Lee ...
  71. [71]
    From linking to integration of energy system models and ...
    Sep 15, 2018 · The NLP formulation of the CGE model may be used for hard-linking the separate models, in the same way as the MCP model. The CGE model does not ...
  72. [72]
    https://www.gtap.agecon.purdue.edu/resources/res_display.asp?RecordID=365
  73. [73]
    [PDF] Computable General Equilibrium Models for the Analysis of ...
    This chapter is an introduction to the subject of computable general equilibrium (CGE) modeling in environmental and resource economics.
  74. [74]
    Resource Display: GTAP-E: An Energy-Environmental Version of the ...
    GTAP-E is an extended GTAP model that incorporates energy substitution, carbon emissions, and international trading of these emissions.Missing: interventions | Show results with:interventions
  75. [75]
    Cap and Trade Versus Carbon Tax: An Analysis Based on a CGE ...
    Feb 1, 2022 · Compared to a cap-and-trade policy, a carbon tax policy yields a much lower GDP-based carbon shadow price but a higher GSPV-based price.
  76. [76]
    The general equilibrium impacts of carbon tax policy in China
    We compare 8 China CGE models with different characteristics to examine how they estimate the effects of a plausible range of carbon tax scenarios.
  77. [77]
    Goulder-Hafstead Energy-Environment-Economy (E3) CGE Model
    In Confronting the Climate Challenge: US Policy Options, the model evaluated impacts of carbon taxes, cap-and-trade programs, federal clean energy standards, ...
  78. [78]
    Resource Display: Incorporating Climate Change Feedbacks into a ...
    GTAP Resources: Resource Display. A methodology for incorporating market and non-market effects of climate change into a computable general equilibrium (CGE) ...Missing: interventions | Show results with:interventions
  79. [79]
    Comparing Applied General Equilibrium and Econometric Estimates ...
    The econometric critique of computable general equilibrium modeling: The role of functional forms. Economic Modelling 15:543–73. First citation in article.Missing: limitations criticisms
  80. [80]
    Assessing carbon tax using a CGE model with firm heterogeneity
    We evaluate the potential macroeconomic and climate impacts of carbon tax policy in Vietnam using a unique data set and simulation analysis.
  81. [81]
    [PDF] Computable General Equilibrium Models for Pol- icy Evaluation and ...
    This chapter documents contemporary Computable General Equilibrium (CGE) approaches to policy evaluation. The algebraic formulation of a canonical multiregion ...
  82. [82]
    What do CGE models have to say about fiscal reform? - ScienceDirect
    In this paper, we present computable general equilibrium (CGE) models as a tool for analyzing the impact of fiscal reforms.
  83. [83]
    [PDF] technical report energy subsidy reform in action
    A CGE model may best be used to consider the effects of a reform on (1) the fiscal balance; (2) social welfare, focusing on the most vulner- able segments of ...
  84. [84]
    Computable General-Equilibrium Modeling of Afghanistan Growth ...
    This paper develops a general equilibrium model to analyze the marginal and joint impacts that alternative macroeconomic, education, and social protection ...
  85. [85]
    Pro-Competitive Effects of Trade Reform: Results from a CGE Model ...
    Nov 1, 1989 · ... liberalization produces welfare gains of the order of 1 to 2 percent of real income. The key is the pro-competitive effect of liberalization ...
  86. [86]
    Resource Display: Modeling the Impact of Trade Liberalization on ...
    Third, developing countries gain the most from free trade, which generates welfare gains equal to 1.35 percent of GDP for developing countries and 0.78 percent ...
  87. [87]
    The impact of trade liberalisation on poverty and inequality
    In this paper we carry out a systematic review of the evidence from CGE models regarding the effect of trade liberalisation on income inequality and poverty ...
  88. [88]
    Carbon taxes, distributional implications, and revenue recycling
    Jun 7, 2025 · The carbon tax is estimated to have a limited impact on GDP, especially if carbon taxes are used to reduce other distortionary taxes. The tax ...
  89. [89]
    The Role of Revenue Recycling Schemes in Environmental Tax ...
    If the tax revenue is recycled to finance cuts in the existing labour or indirect tax rates, carbon tax would be more efficient than the sulphur-, energy- and ...
  90. [90]
    Fiscal reform: a computable general equilibrium (CGE) analysis for ...
    The low rate of 5 per cent is advisable because it will encourage the design of simple- and broad-based taxes which are easier to manage and have little or ...
  91. [91]
    [PDF] The dynamic economic effects of a US corporate income tax rate ...
    Policymakers and economists have long advocated income tax reforms that lower tax rates while broadening the base of the tax structure by eliminating tax ...
  92. [92]
    [PDF] An Evaluation of the Performance of Applied General Equilibrium ...
    Ex-post performance evaluations of applied GE models are essential if policymakers are to have confidence in the results produced by these models.
  93. [93]
    Validation in Computable General Equilibrium Modeling
    This work demonstrates that CGE models can produce forecasts at a highly disaggregated level that comfortably beat non-model-based trend forecasts. It also ...
  94. [94]
    Validating energy-oriented CGE models - ScienceDirect.com
    Despite this heavy usage; CGE models are often criticized as being insufficiently validated. Key parameters are often not econometrically estimated, and the ...
  95. [95]
    Testing the Performance of a Stochastic CGE Model with Regionally ...
    Assessing global computable general equilibrium model validity using agricultural price volatility. American Journal of Agricultural Economics, 89(2), 383 ...<|separator|>
  96. [96]
    [PDF] Download - AgEcon Search
    a set of critical comments on the use of computable general equilibrium models in addressing trade ... A CRITIQUE OF COMPUTABLE GENERAL EQUILIBRIUM. MODELS ...Missing: criticisms | Show results with:criticisms
  97. [97]
    [PDF] Still Dead After All These Years: Interpreting the Failure of General ...
    Post-general-equilibrium economics will need a new model of consumer behavior, new mathematical models of social interaction, and an analysis of the exogenous ...
  98. [98]
    How confident can we be of CGE-based assessments of Free Trade ...
    Yet these models have been widely criticized for performing poorly (Kehoe, 2002) and having weak econometric foundations (McKitrick and Ross, 1998, Jorgenson, ...
  99. [99]
    [PDF] Baseline validation with the GTAP model: an initial effort - CoPS
    May 1, 2023 · Table 3.1 in this section presents our main results showing baseline forecast errors for values of industry outputs in 2017. Errors for ...
  100. [100]
    [PDF] Solving intertemporal CGE models in parallel using a ... - Tom Kompas
    The paper introduces a direct ordering method that employs a special feature of an intertemporal Computable. General Equilibrium (CGE) model to reorder its ...<|separator|>
  101. [101]
    Neoliberalism: Myths and Reality - Monthly Review
    Once again, a powerful free-trade bias is built into the heart of the model by assumption, thereby ensuring a pro-liberalization outcome. Although this bias is ...
  102. [102]
    [PDF] Debunking the Myths of Computable General Equilibrium Models
    Computable General Equilibrium (CGE) models are probably the most utilized tool globally for development planning and macro policy analysis.
  103. [103]
    Computable general equilibrium models for trade policy analysis in ...
    This paper surveys CGE models used to quantify trade policy implications in developing countries, reviewing their structure and applications.
  104. [104]
    Full article: The Transatlantic Trade and Investment Partnership and ...
    Dec 6, 2014 · This brings us to the final way in which CGE models introduce biases. As highlighted by McKitrick (Citation1998), the degree to which both ...
  105. [105]
    The inherent dangers of using computable general equilibrium ...
    This commentary is, hence, a critique against the claim that the CGE modelling approach may have the potential to perform satisfactory and reliable SIAs, and ...
  106. [106]
    The Influence of Computable General Equilibrium Models on Policy
    ABSTRACT: This paper reviews experience with the use of computable or applied general equilibrium (CGE or AGE) models to affect public policy.Missing: implications | Show results with:implications
  107. [107]
    GTAP-HET: Introducing Firm Heterogeneity into the GTAP Model
    Jun 3, 2016 · Computable General Equilibrium (CGE) models incorporating firm heterogeneity can overcome the shortcomings of traditional Armington-based ...
  108. [108]
    A Parsimonious Approach to Incorporate Firm Heterogeneity in CGE ...
    Dec 25, 2018 · This paper proposes a parsimonious and intuitive way to incorporate Melitz-type firm heterogeneity in a CGE-model based on the conventional ...Missing: agent | Show results with:agent
  109. [109]
    Downscaling heterogeneous household outcomes in dynamic CGE ...
    Downscaling methods for dynamic computable general equilibrium models are developed and analyzed. The methods produce outcomes for a variety of different ...
  110. [110]
    On linking microsimulation and computable general equilibrium ...
    Our paper contributes by bridging the gap between the (partial equilibrium) microsimulation and the computable general equilibrium (CGE) approaches, ...<|control11|><|separator|>
  111. [111]
    Dynamic general equilibrium model with uncertainty
    Review of CGE models incorporating risk. There have been several attempts in the literature to make explicit allowance for risk and uncertainty in CGE models.
  112. [112]
    Stochastic simulation with informed rotations of Gaussian quadratures
    Mar 18, 2022 · ... CGE models with different levels of aggregation and with different covariance structures. They conclude that the selection of a particular ...
  113. [113]
    Integrating fundamental model uncertainty in policy analysis
    However, longstanding criticisms of CGE models include that they are deterministic and provide only point estimates of impacts of an exogenous shock to an ...
  114. [114]
    Identifying key sectors of sustainable development: A Bayesian ...
    Jan 6, 2024 · Most existing studies ignore the inherent model uncertainty. Furthermore, longstanding criticisms of CGE models include that they are ...
  115. [115]
    Economy-wide impacts of behavioral climate change mitigation
    Macroeconomic Computable General Equilibrium (CGE) models serve as standard tools for quantitative policy assessments in climate change mitigation (Babatunde ...
  116. [116]
    [PDF] Stochastic Control Using Dynamic CGE Models
    Traditional CGE models have ignored uncertainty ─ even when applied to fields such as environmental modeling that are replete with economic uncertainty. In.
  117. [117]
    [PDF] 1 Neural-Network approximation of reduced forms for CGE models ...
    Nov 12, 2024 · This paper describes an approach based on Neural Network (NN) theory for creating mimic tools. This approach overcomes the limitations of ...
  118. [118]
    Resource Display: Expanding capabilities for policy evaluation throu...
    This research aims to address this gap by demonstrating the reliability of ANNs in emulating CGE models, using the DEMETRA model—a single-country CGE model for ...Missing: machine | Show results with:machine
  119. [119]
    Machine learning enabled computable general equilibrium (CGE)
    A CGE model uses multiple data sources to reflect the interactions of households, firms, and relevant government entities as they contribute to economic ...Missing: applications | Show results with:applications
  120. [120]
    Prospects for energy economy modelling with big data
    Apr 1, 2019 · An example from economic modelling is the widespread use of optimisation and computable general equilibrium ... Advanced big-data/machine-learning ...
  121. [121]
    [PDF] Computable General Equilibrium (CGE) Models
    This comprehensive analysis delves into the landscape of Computable General Equilibrium. (CGE) models, examining their historical development, key components, ...
  122. [122]
    Combining large-scale sensitivity analysis in Computable General ...
    We conclude from there that machine learning techniques are able to provide robust meta-models of CGEs and can be used to predict or even optimize over the ...