Accurate evaluation of the standard normal cumulative distribution function is fundamental in many areas of mathematics, statistics, and applied computation, yet no closed-form expression in elementary functions exists. We present a simple analytic approximation based on a logistic function with a cubic argument, designed to preserve symmetry, monotonicity, and analytic invertibility. The parameters of the approximation are obtained through numerical optimization over a wide domain, targeting both maximum absolute error and root-mean-square error. The resulting function achieves uniformly low approximation error and significantly reduces error relative to the classical logistic approximation, while remaining competitive with commonly used high-accuracy numerical methods. Unlike rational or high-degree polynomial approximations, the proposed form admits an explicit inverse, making it convenient for applications requiring analytic quantile evaluation or inverse transform sampling. Numerical error analysis and illustrative examples demonstrate that the approximation provides a practical balance between accuracy, simplicity, and analytic tractability.
Michael Arnold Frölich (Fri,) studied this question.
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