The paper is to propose a numerical method to calculate highly nonlinear solitary waves. The key expression of solitary waves is first derived in the paper. Through conformal mapping the whole flow in the -plane is mapped into a semicircular region in the -plane forming a doublet that includes a source and a sink of equal strength. The complex velocity potential for the doublet in the -plane is transformed by a series using a condition of analytical function for the whole field except the doublet and iterative approximation. The deviated infinite tanh-type series for solitary waves is identified by the McCowan’s solution. The deviated infinite tanh-type series for solitary waves is tedious to expand the complex form into the real part and imaginary part so that its alternative polar form is applied for propitiously avoiding the disadvantage of series expansion. The collocation method and Newton iterative method combined by 96 terms truncated from the infinite series and vertical equal-space cutting are examined key numerical algorithms in the proposed calculation. For dwarf solitary wave to high solitary waves all calculated dynamic properties are close to those of Wu et al. (2005a) by small relative errors less than 2.5%. The resulting comparison verifies the validity of the proposed numerical calculation of highly nonlinear solitary waves.