14 C.F.R. § 25.535
(b) Step loading. The resultant water load must be applied in the plane of symmetry of the float at a point three-fourths of the distance from the bow to the step and must be perpendicular to the keel. The resultant limit load is computed as follows, except that the value of L need not exceed three times the weight of the displaced water when the float is completely submerged:

where— L = limit load (lbs.); C5 = 0.0053; VS0 = seaplane stalling speed (knots) with landing flaps extended in the appropriate position and with no slipstream effect; W = seaplane design landing weight in pounds; βS = angle of dead rise at a station 3/4 of the distance from the bow to the step, but need not be less than 15 degrees; and ry = ratio of the lateral distance between the center of gravity and the plane of symmetry of the float to the radius of gyration in roll.
(f) Immersed float condition. The resultant load must be applied at the centroid of the cross section of the float at a point one-third of the distance from the bow to the step. The limit load components are as follows:

where— ρ = mass density of water (slugs/ft. 2); V = volume of float (ft. 2); Cx = coefficient of drag force, equal to 0.133; Cy = coefficient of side force, equal to 0.106; K = 0.8, except that lower values may be used if it is shown that the floats are incapable of submerging at a speed of 0.8 VS0 in normal operations; VS0 = seaplane stalling speed (knots) with landing flaps extended in the appropriate position and with no slipstream effect; and g = acceleration due to gravity (ft./sec. 2).
[Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-23, 35 FR 5673, Apr. 8, 1970; Amdt. 25-148, 87 FR 75710, Dec. 9, 2022; 88 FR 2813, Jan. 18, 2023]