초록 ▼

An auto-focusing method includes a scanning step for scanning a pair of solid-state image sensors on which light from a subject of interest impinges as passing through a focusing lens, an A/D conversion step, a Fourier transformation step, a convolution operation step, a peak detection step for dete

An auto-focusing method includes a scanning step for scanning a pair of solid-state image sensors on which light from a subject of interest impinges as passing through a focusing lens, an A/D conversion step, a Fourier transformation step, a convolution operation step, a peak detection step for determining an amount of displacement of said lens from the results of said convolution, and a lens displacement step for displacing said lens according to the displacement amount thus determined. The present auto-focusing method is least susceptible to noises and not adversely affected by differences in contrast of the subject of interest.

대표청구항 ▼

1. A method of carrying out auto-focusing by displacing a lens along the direction of an optical axis of said lens in accordance with a correlation between outputs from a pair of solid-state image sensors, said method comprising the steps of: passing light through said lens and impinging the ligh

1. A method of carrying out auto-focusing by displacing a lens along the direction of an optical axis of said lens in accordance with a correlation between outputs from a pair of solid-state image sensors, said method comprising the steps of: passing light through said lens and impinging the light passed through said lens on both of said solid-state image sensors; scanning each of said pair of solid-state image sensors thereby producing respective outputs A(n) and B(n); converting said outputs A(n) and B(n) into digital data A'(n) and B'(n); calculating Fourier transforms F 1 (u), F 2 (u), G 1 (u) and G 2 (u) using the following equations, ##EQU## where N is the number of photoelectric elements in each of said pair of solid-state image sensors, u=0, 1, 2, . . . , M, and M is an integer which is equal to or smaller than (N/2)-1; calculating the following values F 0, G 0, F(u) and G(u) from said F 1 (u), F 2 (u), G 1 (u) and G 2 (u), ##EQU## calculating the following value f*g, using said F 0, G 0, F(u) and G(u), in a timed sequence at a predetermined time period for variable t, ##EQU## determining an amount of displacement of said lens in accordance with a value of said variable t which gives a maximum value for said f*g, whereby if said amount of displacement thus determined is outside of a predetermined range, said lens is displaced to an in-focus position according to said amount of displacement thus determined. 2. The method of claim 1 wherein said timed sequence in calculating said f*g is determined by ##EQU##t i =χTI where χ: constant, T: clock period, I: positive integer 1-I N, i: positive integer 1-I N, I N : set value whereby, f*g(t i )=L(I) is calculated sequentially for I=1, 2, . . . . 3. The method of claim 2 wherein said value of variable t giving a maximum value for f*g is determined by comparing said L(I) each other and designated as I(MAX) which is then compared with a pair of predetermined values C 1 and C 2 thereby indicating a too close condition if I(MAX) is larger than C 1, a too far condition if I(MAX) is smaller than C 2 and an in-focus condition if I(MAX) is larger than C 1 but smaller than C 2 . 4. The method of claim 3 wherein the lens is moved only when said I(MAX) is either larger than C 1 or smaller than C 2 and said amount of displacement of said lens is determined according to said I(MAX). 5. The method of claim 4 further comprising the step of displaying a focusing condition determined by said step of comparing I(MAX) with C 1 and C 2 .