| 1 | ;------------------------------------------------------------ |
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| 2 | ;------------------------------------------------------------ |
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| 3 | ;------------------------------------------------------------ |
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| 4 | ;+ |
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| 5 | ; |
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| 6 | ; @file_comments |
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| 7 | ; Calculate coordinates of the intersection between 2 straight lines |
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| 8 | ; or of a succession of 2 straight lines. |
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| 9 | ; |
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| 10 | ; @categories |
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| 11 | ; Utilities |
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| 12 | ; |
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| 13 | ; @param ABC1 {in}{required}{type=3d array} |
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| 14 | ; is the first array of dimension 3, number_of_pairs_of_straight_lines, |
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| 15 | ; whose each line contain the 3 parameters a,b and c of the first linear |
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| 16 | ; equation of the type ax+by+c=0 |
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| 17 | ; |
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| 18 | ; @param ABC2 {in}{required}{type=3d array} |
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| 19 | ; is second array of dimension 3, number_of_pairs_of_straight_lines, |
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| 20 | ; whose each line contain the 3 parameters a,b and c of the second linear |
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| 21 | ; equation of the type ax+by+c=0 |
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| 22 | ; |
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| 23 | ; @keyword FLOAT |
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| 24 | ; To return the output as a array of real numbers instead of vectors of |
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| 25 | ; complex (by default) |
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| 26 | ; |
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| 27 | ; @returns |
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| 28 | ; 2 possibilities: |
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| 29 | ; 1) by default: it is a vector of complex whose each element is the coordinates |
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| 30 | ; of the intersection point of a pair of straight lines. |
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| 31 | ; 2) if FLOAT is activated, it is a array of reels of dimension 2, |
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| 32 | ; number_of_pairs_of_straight_lines whose each row is the coordinates |
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| 33 | ; of the intersection point of a pair of straight line. |
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| 34 | ; |
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| 35 | ; @restrictions |
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| 36 | ; If the 2 straight line are parallel, we return coordinates |
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| 37 | ; (!values.f_nan,!values.f_nan) |
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| 38 | ; |
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| 39 | ; @restrictions |
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| 40 | ; Beware of the precision of the machine which make |
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| 41 | ; that calculated coordinates may not exactly verify |
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| 42 | ; equations of the pair of straight lines. |
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| 43 | ; |
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| 44 | ; @examples |
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| 45 | ; IDL> abc1=linearequation(complex(1,2),[3,4]) |
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| 46 | ; IDL> abc2=linearequation(complex(1,2),[8,15]) |
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| 47 | ; IDL> print, lineintersection(abc1, abc2) |
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| 48 | ; ( 1.00000, 2.00000) |
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| 49 | ; IDL> print, lineintersection(abc1, abc2,/float) |
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| 50 | ; 1.00000 2.00000 |
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| 51 | ; |
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| 52 | ; @history Sebastien Masson (smasson\@lodyc.jussieu.fr) |
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| 53 | ; 10 juin 2000 |
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| 54 | ; |
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| 55 | ; @version $Id$ |
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| 56 | ; |
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| 57 | ;- |
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| 58 | ;------------------------------------------------------------ |
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| 59 | ;------------------------------------------------------------ |
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| 60 | ;------------------------------------------------------------ |
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| 61 | FUNCTION lineintersection, abc1, abc2, FLOAT = float |
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| 62 | ; |
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| 63 | ; |
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| 64 | compile_opt idl2, strictarrsubs |
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| 65 | ; |
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| 66 | a1 = float(reform(abc1[0, *])) |
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| 67 | b1 = float(reform(abc1[1, *])) |
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| 68 | c1 = float(reform(abc1[2, *])) |
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| 69 | a2 = float(reform(abc2[0, *])) |
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| 70 | b2 = float(reform(abc2[1, *])) |
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| 71 | c2 = float(reform(abc2[2, *])) |
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| 72 | ; |
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| 73 | determinant = a1*b2-a2*b1 |
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| 74 | nan = where(determinant EQ 0) |
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| 75 | if nan[0] NE -1 THEN determinant = !values.f_nan |
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| 76 | ; |
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| 77 | x = (b1*c2-c1*b2)/determinant |
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| 78 | y = (c1*a2-a1*c2)/determinant |
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| 79 | ; |
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| 80 | if keyword_set(float) then begin |
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| 81 | npts = n_elements(x) |
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| 82 | res = [reform(x, 1, npts, /over), reform(y, 1, npts, /over)] |
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| 83 | ENDIF ELSE res = complex(x, y) |
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| 84 | return, res |
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| 85 | end |
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