Choice (Microeconomic Foundations) – SAT – Evidence – Detection Limits

Back to Choice (Microeconomic Foundations) – SAT – Evidence

The Ten Cross-Scientific Detection-Limit Invariants

1. Sensitivity vs. Noise Floor

What “sensitivity” means in this field

In microeconomic choice, the “signal” is not a physical quantity but an expression of preference, valuation, or belief inferred from observed behavior (choices, prices paid, quantities chosen, response times, stated answers). Sensitivity therefore refers to the field’s ability to detect small differences in preference strength or tradeoff structure from noisy behavioral data.

The effective signal must be strong enough to stand out against behavioral variability, reporting error, situational fluctuation, and measurement imprecision.

Sources of noise

Across microeconomic settings, noise arises from multiple, structurally unavoidable sources:

Behavioral variability: the same agent makes different choices across identical or near-identical situations due to attention, mood, fatigue, or context.
Measurement error: imprecise prices, incomes, quantities, or timing; rounding; reporting error; data-entry noise.
Contextual perturbations: framing effects, order effects, default settings, experimenter demand.
Unobserved heterogeneity: differences in preferences, constraints, or beliefs across agents that are not measured.
Stochastic decision rules: mixed strategies, random utility components, or probabilistic choice mechanisms.

These noise sources impose a baseline level of variability that cannot be eliminated, only reduced or modeled.

The detection boundary

A preference difference is detectable only if it produces behavioral regularities that exceed this noise floor. Below that threshold:

Small utility differences between options cannot be reliably inferred.
Weak preferences appear as indifference or random choice.
Subtle substitution effects are masked by choice inconsistency.
Fine-grained welfare comparisons collapse into observational equivalence.

This is why many micro models rely on revealed preference inequalities or coarse choice patterns rather than attempting to recover exact utility levels.

Empirical manifestations of the limit

This detection limit appears concretely as:

Inability to distinguish weak preferences from indifference.
Large standard errors on estimated marginal utilities or elasticities.
Flat likelihood surfaces for closely ranked alternatives.
Sensitivity of inferred preferences to small specification changes.
Requirement for large sample sizes to detect modest effects.

In experimental settings, it shows up as high variance in repeated-choice tasks; in observational data, as instability of preference estimates under alternative controls.

Consequences for inference

Because of this limit:

Utility is ordinal, not cardinal, in practice.
Fine interpersonal or intrapersonal comparisons are unreliable.
Welfare analysis depends on strong assumptions or coarse thresholds.
“True preferences” cannot be directly observed—only bounded or bracketed.
Null results often reflect insufficient sensitivity, not absence of preference.

Crucially, this is not a methodological failure but a structural detection constraint of the domain.

What lies beyond the limit

Below the sensitivity threshold lie:

Micro-fluctuations in preference intensity.
Moment-to-moment belief updates.
Latent motivations not strong enough to alter choice.
Preference components orthogonal to observed decision dimensions.

These may exist, but they do not enter evidence without amplification (stronger incentives, repeated trials, sharper contrasts, or structural assumptions).

In Choice (Microeconomic Foundations), detection is limited by the field’s ability to separate true preference signals from unavoidable behavioral and measurement noise. Only preference differences large enough to generate stable, repeatable choice patterns rise above the noise floor and become empirically observable; finer structure remains inferentially inaccessible.

2. Resolution (Spatial, Temporal, Spectral, Angular)

What “resolution” means in this field

In microeconomic choice, resolution governs the field’s ability to separate distinct decision components—preferences, constraints, beliefs, tradeoffs, and timing—rather than merely detecting that a choice occurred.

There is no physical space or wavelength here. Instead, resolution operates over decision dimensions:

Attribute resolution: separating the value of price, quality, risk, time, morality, etc.
Temporal resolution: distinguishing when preferences form, change, or are acted upon.
Option resolution: distinguishing closely ranked alternatives.
Contextual resolution: separating stable preference from situational influence.

Resolution limits determine whether choice appears coarse and categorical or fine-grained and structured.

Sources of resolution limits

Resolution in choice is constrained by:

Binary or coarse choice sets: yes/no, buy/not-buy, vote/not-vote collapse rich preference structure.
Attribute bundling: options differ along many dimensions simultaneously, preventing isolation of individual tradeoffs.
Discrete pricing and quantities: rounding and indivisibilities blur marginal differences.
Sparse temporal observation: choices observed intermittently rather than continuously.
Survey and experimental binning: Likert scales, income brackets, category labels.
Attention and cognition limits: agents themselves may not resolve fine distinctions.

These limits are structural, not merely data limitations.

The resolution boundary

Below the field’s effective resolution:

Close preferences collapse into apparent indifference.
Multi-attribute tradeoffs cannot be decomposed.
Gradual preference changes appear as sudden switches.
Continuous valuation is misrepresented as discrete jumps.
Timing of decision formation is conflated with timing of action.

At this boundary, distinct internal states map to identical observed choices.

Empirical manifestations of the limit

Resolution limits show up as:

Step-function demand curves instead of smooth ones.
Kinks and corner solutions dominating observed behavior.
Inability to identify marginal rates of substitution precisely.
Path dependence mistaken for preference instability.
Sensitivity of estimates to arbitrary discretization choices.

Even with large datasets, these effects persist.

Consequences for inference

Because of resolution limits:

Utility functions are recoverable only up to coarse equivalence classes.
Preference continuity is often assumed rather than observed.
Fine welfare comparisons are unreliable.
Models rely on smoothness assumptions to compensate for coarse data.
Behavioral heterogeneity is flattened into representative agents.

Resolution, not noise, sets the grain of microeconomic explanation.

What lies beyond the limit

Beyond observable resolution lie:

Micro-adjustments in preference intensity.
Rapid belief updates preceding action.
Subtle tradeoff reshaping across attributes.
Gradual learning processes masked as discrete shifts.

These may exist, but they are below the decision-resolution grain of the field.

In Choice (Microeconomic Foundations), detection is limited by the field’s ability to resolve distinct decision components from coarse, discrete, and bundled choice observations. Below this resolution, preferences, tradeoffs, and timing merge, forcing microeconomics to describe behavior at a coarser grain than agents’ internal decision processes.

3. Dynamic Range and Saturation

What “dynamic range” means in this field

In microeconomic choice, dynamic range refers to the field’s ability to simultaneously detect weak and strong preference signals within the same observational or experimental framework.

The “detector” here is the choice environment and measurement scheme: price variation, incentive magnitude, task difficulty, survey scale, or experimental payoff structure. Saturation occurs when choices become uninformative at extremes—either because differences are too small to matter or so large that behavior collapses to corners.

Sources of dynamic-range limits

Dynamic range in choice is constrained by:

Binary or corner choices: once an option is strictly dominated, all agents choose the same outcome.
Incentive saturation: very large payoffs swamp all other considerations.
Survey scale limits: Likert scales cap expressed intensity at endpoints.
Budget constraints and discreteness: indivisibilities force corner solutions.
Attention and cognitive bounds: extreme complexity or stakes collapse nuanced tradeoffs.
Ethical or categorical vetoes: moral constraints truncate the choice range entirely.

These constraints bound how much preference variation can be expressed.

The saturation boundary

At the low end of dynamic range:

Weak preferences produce random or inconsistent choices.
Small price or attribute differences generate no detectable response.
Marginal tradeoffs disappear into behavioral noise.

At the high end:

Choices become uniform (always choose A, never choose B).
Willingness-to-pay becomes unbounded or censored.
Behavioral responses clip at constraints rather than reflect true intensity.

In both cases, the detector returns little information.

Empirical manifestations of the limit

Dynamic-range limits appear as:

Flat demand at low price variation.
Corner solutions dominating observed behavior.
Top-coded or censored valuation measures.
Insensitivity of choice to further incentive increases.
Failure to recover curvature of utility at extremes.

Increasing variation often reveals one side of the range while obscuring the other.

Consequences for inference

Because of dynamic-range limits:

Utility curvature is weakly identified.
Extreme preferences are under-measured or mischaracterized.
Comparisons across contexts with different incentive scales are fragile.
Experiments face tradeoffs between detecting subtle effects and avoiding saturation.
Behavioral models rely on normalization conventions rather than absolute scale.

Dynamic range constrains what parts of the preference space are observable.

What lies beyond the limit

Beyond observable dynamic range lie:

Very weak motivations that never tip behavior.
Very strong commitments that truncate choice.
Tail behavior of valuation distributions.
Extreme risk or time preferences masked by constraints.

These regions exist but are empirically silent.

In Choice (Microeconomic Foundations), detection is limited by the finite dynamic range of choice environments. Weak preferences vanish into noise, while strong preferences saturate behavior into corners, preventing simultaneous observation of the full preference spectrum within a single design.

4. Sampling Density, Coverage, and Missingness

What “sampling density and coverage” mean in this field

In microeconomic choice, sampling density and coverage determine which agents, decisions, and contexts ever enter the data at all. Detection is constrained not by how well choices are measured, but by which choices are observed, how often, and under what conditions.

The “sample” may be survey respondents, experimental subjects, transaction records, or observational datasets. Missingness arises whenever choices occur outside the observational frame.

Sources of sampling limits

Sampling constraints in choice arise from:

Population coverage gaps: nonparticipants, informal actors, marginalized groups.
Survey nonresponse and attrition: systematic dropout correlated with preferences.
Observational sparsity: infrequent purchases or rare decisions.
Contextual under-sampling: limited price variation, missing states of the world.
Platform-mediated data: only choices made on observed platforms are visible.
Experimental selection: convenience samples, WEIRD populations, lab artifacts.

These gaps are structural, not random.

The coverage boundary

Below effective sampling coverage:

Entire preference classes are absent from data.
Certain tradeoffs are never observed.
Rare but important choices vanish.
Heterogeneity collapses into apparent homogeneity.
Behavioral patterns appear stable simply because variation is unobserved.

What is not sampled does not exist empirically.

Empirical manifestations of the limit

Sampling limits show up as:

Selection bias in estimated preferences.
Overrepresentation of frequent choosers.
Missing tails of willingness-to-pay distributions.
Failure to observe corner cases or constraint-binding behavior.
Apparent rationality or consistency driven by filtered samples.

Even perfect measurement cannot recover what was never observed.

Consequences for inference

Because of sampling limits:

Estimated preferences are conditional on observability.
External validity is fragile.
Policy conclusions may not generalize.
Welfare analysis ignores invisible populations.
Structural models fill gaps with assumptions.

Sampling defines the empirical universe of choice.

What lies beyond the limit

Beyond sampling coverage lie:

Non-market decisions.
Informal or illicit exchanges.
Low-frequency, high-impact choices.
Suppressed or constrained preferences.
Context-dependent behavior never triggered in the data.

These choices may matter most, yet remain unseen.

In Choice (Microeconomic Foundations), detection is limited by who is sampled, which decisions are observed, and under what contexts. Sparse or biased coverage creates structural absences in the data, rendering entire regions of preference space empirically invisible regardless of measurement precision.

5. Channel Access, Penetration, and Occlusion

What “channel access” means in this field

In microeconomic choice, channel access refers to whether the analyst can observe the decision process or its determinants at all, not merely how accurately choices are measured. The “channel” is the pathway from an agent’s internal state (preferences, beliefs, constraints) to observable data.

Occlusion occurs when this pathway is blocked, indirect, or deliberately hidden, so that key components of choice never reach the observer.

Sources of channel occlusion

Channel access in choice is limited by:

Internal mental states: preferences, beliefs, expectations, and motivations are not directly observable.
Private constraints: liquidity, obligations, health, or risk exposure known only to the agent.
Non-market decisions: household, moral, or informal choices leaving no transactional trace.
Aggregation at the point of observation: only final choices are seen, not deliberation.
Strategic misreporting: agents conceal or distort stated preferences.
Platform mediation: only actions taken through observed channels are visible.

These barriers are intrinsic, not technological.

The access boundary

Below effective channel access:

True preferences cannot be distinguished from constraints.
Beliefs cannot be separated from outcomes.
Inaction is ambiguous (indifference vs. inability).
Observed choice is an endpoint, not a process.
Many relevant decision margins are invisible.

The phenomenon exists, but the observation path is closed.

Empirical manifestations of the limit

Channel occlusion appears as:

Reliance on revealed preference as a proxy.
Weak identification of belief-based models.
Inability to test internal consistency of preferences.
Dependence on auxiliary assumptions about information and constraints.
Fragility of welfare analysis to unobserved factors.

Data show what was chosen, not why.

Consequences for inference

Because of channel-access limits:

Preferences are inferred indirectly.
Belief formation is modeled, not observed.
Constraint vs. preference explanations are hard to disentangle.
Counterfactual choice predictions are uncertain.
Behavioral interpretation rests on structural assumptions.

Choice models necessarily compress internal reality.

What lies beyond the limit

Beyond accessible channels lie:

Latent motivations and intentions.
Moral, emotional, or identity-based drivers.
Private risk perceptions.
Internal deliberation and conflict.
Suppressed or constrained desires.

These shape choice without being directly observable.

In Choice (Microeconomic Foundations), detection is limited by occlusion of the decision channel itself. Preferences, beliefs, and constraints are real but internal, reaching the observer only through indirect behavioral traces; where that channel is blocked or distorted, key determinants of choice remain empirically inaccessible.

6. Confounding, Interference, and Identifiability

What “confounding and identifiability” mean in this field

In microeconomic choice, this detection limit governs whether observed behavior can be uniquely attributed to a specific underlying cause—preferences, beliefs, constraints, or information—rather than merely detected as a behavioral outcome.

The issue is not whether choices are observed (they are), but whether the mapping from latent decision drivers to observed choice is one-to-one. Identifiability fails when multiple internal mechanisms generate indistinguishable choice patterns.

Sources of confounding and interference

Confounding in choice arises from structurally overlapping causal pathways:

Preferences vs. constraints: choosing less may reflect low utility or binding budget/liquidity limits.
Beliefs vs. tastes: actions driven by pessimistic beliefs look identical to risk aversion.
Information vs. attention: failure to choose may reflect ignorance or inattention.
Risk vs. ambiguity: distinct attitudes produce similar avoidance behavior.
Time preference vs. uncertainty: delay aversion and risk discounting interfere.
Social norms vs. intrinsic preference: conformity mimics genuine taste.
Framing vs. valuation: presentation effects confound inferred utility.

These mechanisms interfere at the point of observable action.

The identifiability boundary

Below effective identifiability:

Distinct utility functions rationalize the same choices.
Belief heterogeneity is observationally equivalent to preference heterogeneity.
Structural parameters are weakly or non-identified.
Multiple models fit the same choice data equally well.
Counterfactual predictions diverge despite identical in-sample fit.

The data detect behavior, but not its unique cause.

Empirical manifestations of the limit

Identifiability limits appear as:

Flat or ill-conditioned likelihood functions.
Sensitivity of estimates to normalization choices.
Dependence on exclusion restrictions.
Parameter tradeoffs (e.g., risk vs. discounting).
Model equivalence under revealed-preference tests.

Identification often hinges on strong auxiliary assumptions.

Consequences for inference

Because of confounding and identifiability limits:

Preferences are only partially recoverable.
Welfare analysis depends on model choice.
Behavioral interpretations are non-unique.
Policy simulations vary widely across plausible specifications.
“Explanation” exceeds what the data alone justify.

Microeconomic inference is therefore structurally underdetermined.

What lies beyond the limit

Beyond identifiability lie:

Fine distinctions between motivational drivers.
Precise decomposition of belief, taste, and constraint effects.
Individual-level causal narratives.
Robust interpersonal welfare comparisons.

These distinctions may be meaningful but are empirically inaccessible without strong structure.

In Choice (Microeconomic Foundations), detection is limited not by observing behavior, but by confounding among latent decision drivers. Multiple combinations of preferences, beliefs, and constraints can generate identical choices, imposing identifiability limits that prevent unique causal attribution from choice data alone.

7. Calibration Drift and Definition Instability

What “calibration drift and definition instability” mean in this field

In microeconomic choice, this detection limit concerns whether observed choices remain comparable across time, contexts, instruments, and datasets. The issue is not whether behavior is measured correctly at a moment, but whether measurements retain a stable meaning as environments, elicitation methods, and definitions change.

The “calibration” here includes experimental designs, survey instruments, price scales, incentive schemes, task framing, and data-generation processes. Drift occurs when these evolve, intentionally or not.

Sources of instability

Calibration drift and definition instability in choice arise from:

Survey wording changes: small phrasing shifts alter elicited preferences.
Scale drift: Likert scales, willingness-to-pay measures, or stated probabilities change interpretation across contexts.
Experimental protocol evolution: incentive sizes, instructions, or task structures differ across studies.
Contextual normalization: preferences expressed relative to changing reference points.
Platform effects: digital interfaces, defaults, and UX changes alter behavior.
Temporal adaptation: agents learn, adapt, or reinterpret tasks over time.
Data construction changes: recoding, cleaning rules, or variable definitions shift.

These changes accumulate gradually and often invisibly.

The stability boundary

Below effective stability:

Identical choices no longer imply identical preferences.
Differences across datasets reflect measurement drift rather than behavior change.
Longitudinal preference comparisons become ambiguous.
Apparent preference shifts may be artifacts of elicitation changes.
Meta-analysis collapses heterogeneous measures into false continuity.

The signal exists, but its meaning moves.

Empirical manifestations of the limit

Instability appears as:

Inconsistent preference estimates across studies.
Time trends driven by survey redesigns.
Sensitivity of results to framing or normalization choices.
Failure to replicate fine-grained preference measures.
Difficulty pooling datasets without strong harmonization.

Micro data often lack a fixed reference frame.

Consequences for inference

Because of calibration and definition instability:

Long-run preference dynamics are weakly identified.
Cross-study comparisons require heavy adjustment.
Structural parameters lack absolute interpretation.
Welfare analysis depends on arbitrary normalization.
Behavioral change is hard to separate from measurement change.

Choice data are locally valid but globally fragile.

What lies beyond the limit

Beyond stable calibration lie:

True temporal evolution of preferences.
Cross-context comparability of valuation.
Fine-grained interpersonal comparison.
Robust measurement of slow preference drift.

These are conceptually meaningful but empirically unstable.

In Choice (Microeconomic Foundations), detection is limited by calibration drift and instability of preference definitions. Measurements may be valid within a given instrument and context, but shifting elicitation methods and reference frames undermine stable comparison across time, datasets, and environments.

8. Rarity and Statistical Power

What “rarity and statistical power” mean in this field

In microeconomic choice, this detection limit concerns whether infrequent decisions or weak behavioral effects occur often enough to be empirically distinguishable from noise. The issue is not whether a choice pattern exists, but whether it appears with sufficient frequency or magnitude to be detected reliably.

Here, rarity can apply to types of agents, types of decisions, or types of contexts. Statistical power governs whether observed data can reject randomness or null models in favor of meaningful structure.

Sources of rarity and low power

Rarity in choice arises from several structural features:

Low-frequency decisions: housing moves, career changes, fertility, default, bankruptcy.
Extreme preferences: very high or very low risk tolerance, patience, altruism.
Rare contexts: crises, windfalls, sudden constraint binding.
Small marginal effects: subtle framing, information, or incentive changes.
Heterogeneous subpopulations: small groups with distinct preference structures.
Short panels: limited repeated observations per agent.

Even large datasets may contain few relevant observations.

The power boundary

Below effective statistical power:

Rare preferences are indistinguishable from noise.
Weak effects fail to reach significance.
Tail behavior is underrepresented or invisible.
Behavioral heterogeneity is flattened.
Null results cannot be interpreted as nonexistence.

Absence of evidence reflects insufficient observation, not absence of structure.

Empirical manifestations of the limit

Rarity and power limits appear as:

Wide confidence intervals on key parameters.
Failure to detect known behavioral effects outside labs.
Inconsistent replication of small effects.
Overreliance on pooled estimates masking rare behavior.
Sensitivity of results to sample expansion or restriction.

Choice data often privilege common behavior.

Consequences for inference

Because of rarity and power limits:

Subtle behavioral mechanisms are hard to validate.
Tail preferences are poorly characterized.
Policy analysis underestimates rare but consequential choices.
Welfare analysis ignores low-probability harms or gains.
Researchers risk false negatives more than false positives.

Inference is biased toward frequent, average decisions.

What lies beyond the limit

Beyond observable power lie:

Rare decision rules.
Extreme preference realizations.
Crisis-driven behavioral shifts.
Low-probability but high-impact choices.

These matter disproportionately but are empirically thin.

In Choice (Microeconomic Foundations), detection is limited by rarity of relevant decisions and insufficient statistical power. When choices or effects occur infrequently or weakly, their absence from data reflects limited observation rather than nonexistence, constraining inference about tails and subtle behavioral structure.

9. Measurement Back-Action and Disturbance

What “measurement back-action” means in this field

In microeconomic choice, measurement back-action occurs when the act of observing, eliciting, or incentivizing a choice alters the choice itself. Below a certain scale or subtlety, the measurement procedure dominates the phenomenon it seeks to detect.

The “measurement” includes surveys, experiments, incentives, framing, observation, and data collection itself. Disturbance arises because agents respond to being measured.

Sources of measurement disturbance

Back-action in choice arises from structurally unavoidable mechanisms:

Experimenter demand effects: subjects infer what is expected and adjust behavior.
Survey reactivity: answering questions changes beliefs or salience.
Incentive distortion: monetary rewards crowd out intrinsic motivation.
Framing and priming: elicitation changes how options are perceived.
Observation effects: agents behave differently when watched or recorded.
Repeated measurement: learning and adaptation alter subsequent choices.
Hypothetical bias: stated choices differ from real ones due to context.

Measurement reshapes the decision environment.

The disturbance boundary

Below effective non-disturbance:

Fine-grained preferences cannot be observed without altering them.
Subtle motivations collapse under elicitation pressure.
“Natural” choice disappears in experimental settings.
Internal deliberation is replaced by task-solving behavior.
Observed choices reflect the measurement, not the latent preference.

The signal exists, but the probe overwhelms it.

Empirical manifestations of the limit

Back-action appears as:

Differences between lab and field behavior.
Instability across elicitation methods.
Sensitivity of results to wording and incentives.
Failure of hypothetical measures to predict real choices.
Behavioral shifts after being surveyed or studied.

Measurement effects are often larger than the effects of interest.

Consequences for inference

Because of measurement back-action:

Preferences cannot be observed in a neutral state.
Structural parameters depend on elicitation design.
Welfare conclusions are context-dependent.
External validity is limited.
Causal interpretation blurs measurement and behavior.

Choice data are inseparable from their measurement context.

What lies beyond the limit

Beyond non-disturbing measurement lie:

Pre-reflective preferences.
Unarticulated motivations.
Choice behavior absent salience or incentives.
Genuine counterfactual decisions.

These cannot be accessed without reshaping them.

In Choice (Microeconomic Foundations), detection is limited by measurement back-action. The act of eliciting or observing choice alters the decision environment itself, so beyond a certain subtlety, measurement reshapes what it seeks to reveal, imposing intrinsic limits on preference observability.

10. Computational and Algorithmic Tractability

What “computational tractability” means in this field

In microeconomic choice, computational and algorithmic tractability limits whether latent preferences, beliefs, and decision rules can be recovered, estimated, or simulated within feasible computational bounds. The constraint is not empirical detection, but whether the inference problem itself is solvable with available algorithms and resources.

Here the “instrument” is the estimation and optimization machinery: likelihood evaluation, search over preference spaces, dynamic programming, equilibrium computation, and simulation-based inference.

Sources of computational intractability

Tractability limits in choice arise from structural features of decision models:

High-dimensional preference spaces: many attributes, states, or choice alternatives.
Unobserved heterogeneity: latent types explode the parameter space.
Dynamic decision problems: state spaces grow exponentially over time.
Non-convex optimization: multiple local optima impede reliable estimation.
Discrete choice combinatorics: large choice sets make exact evaluation infeasible.
Simulation-based inference: noisy likelihoods and slow convergence.
Behavioral richness: bounded rationality, learning, and heuristics complicate structure.

These limits arise even with perfect data.

The tractability boundary

Below effective tractability:

Preference recovery becomes computationally infeasible.
Exact likelihoods cannot be evaluated.
Global optima cannot be certified.
Identification exists in theory but not in practice.
Model richness must be curtailed to permit estimation.

The phenomenon exists, but cannot be computed.

Empirical manifestations of the limit

Computational limits appear as:

Simplified utility specifications adopted for feasibility.
Heavy reliance on parametric assumptions.
Approximate or local-solution methods.
Sensitivity of results to starting values or algorithms.
Inability to scale models to large datasets or choice sets.

What is estimated reflects tractability constraints as much as behavior.

Consequences for inference

Because of computational limits:

Models are chosen for solvability, not realism.
Rich preference structures are truncated.
Counterfactual analysis is restricted.
Behavioral complexity is approximated or ignored.
Theoretical identifiability exceeds practical estimability.

Inference is bounded by algorithmic reach.

What lies beyond the limit

Beyond tractability lie:

Fully heterogeneous preference distributions.
High-dimensional belief updating.
Complex dynamic strategies.
Exact recovery of individualized decision rules.

These may exist but cannot be computed at scale.

In Choice (Microeconomic Foundations), detection is limited by computational and algorithmic tractability. Even when preferences and decision rules are conceptually well-defined and empirically detectable, they may lie beyond feasible computation, forcing inference to operate within simplified, solvable representations rather than the full decision space.