Sharp analytical bounds for the average treatment effect in discrete IV models must use exponentially many terms; polynomial approximations cannot be sharp, with optimal code provided.
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Causal inference often uses an instrument variable to bound the effect of a treatment on an outcome. Some methods solve this with slow optimization programs. Others try quick analytical formulas based on probability rules. This work shows that those quick formulas cannot give the tightest possible bounds unless they include an exponentially growing number of separate linear pieces when the outcome can take many different values. The authors also give ready-to-use computer code that computes the tightest analytical bounds without unnecessary extra work.
Core claim
any sharp analytical bound for the average treatment effect must be expressible as a maximum (minimum) over a collection of linear terms whose cardinality grows exponentially in the number of values taken by the outcome
Load-bearing premise
The instrumental variable model is discrete with finite support for all variables, and the target is the average treatment effect under standard IV assumptions.
read the original abstract
Bounding causal effects analytically, rather than numerically, is appealing for its interpretability and conceptual clarity. Existing sharp methods rely on optimization-based approaches such as the Balke-Pearl framework, whose computational complexity grows rapidly. An alternative line of work derives bounds heuristically using probability laws and generic inequalities, and some recent papers have claimed or conjectured that this approach can yield sharp analytical bounds with substantially lower complexity. In this paper, we show that this perceived advantage is illusory. In particular, in a discrete instrumental variable setting, we show that any sharp analytical bound for the average treatment effect must be expressible as a maximum (minimum) over a collection of linear terms whose cardinality grows exponentially in the number of values taken by the outcome. In parallel, we show that the number of instrumental variable inequalities itself also grows exponentially. Consequently, bounds and inequalities expressed using only polynomially many such terms cannot be sharp. As a constructive complement, the paper is accompanied by codes implemented in python and R to derive sharp analytical bounds and sharp inequalities with optimal efficiency, matching the lower bounds proven in this paper. These codes are available online.
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The claim rests on the assumption of finite discrete support for all variables in the IV model and standard causal assumptions (instrument relevance, exclusion restriction). No free parameters or invented entities are introduced.
axioms (2)
domain assumptionAll variables have finite discrete support Required for the exponential cardinality result to hold in the discrete IV setting.
domain assumptionStandard instrumental variable assumptions hold (relevance, exclusion, no unmeasured confounding) Implicit in the causal IV model used throughout the abstract.
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