[求助]ansys分析后面型数据如何进行zernike多项式拟合？ [复制链接]

小弟不是学光学的，所以想请各位大侠指点啊！谢谢啦 .lcI"%>  
就是我用ansys计算出了镜面的面型的数据，怎样可以得到zernike多项式的系数，然后用zemax各阶得到像差！谢谢啦！ P S$6`6G  

可以用matlab编程，用zernike多项式进行波面拟合，求出zernike多项式的系数，拟合的算法有很多种，最简单的是最小二乘法，你可以查下相关资料，挺简单的

泽尼克多项式的前9项对应象差的

非常感谢啊，我手上也有zernike多项式的拟合的源程序，也不知道对不对，不怎么会有 E|Q|Nx!6[  
function z = zernfun(n,m,r,theta,nflag) zx(=ArCRr  
%ZERNFUN Zernike functions of order N and frequency M on the unit circle. '5*8'.4Sy  
%   Z = ZERNFUN(N,M,R,THETA) returns the Zernike functions of order N sXpA^pT"T  
%   and angular frequency M, evaluated at positions (R,THETA) on the <z=d5g{n  
%   unit circle.  N is a vector of positive integers (including 0), and ]<zjD%Ez  
%   M is a vector with the same number of elements as N.  Each element U)3*7D  
%   k of M must be a positive integer, with possible values M(k) = -N(k) d=6FL" .o  
%   to +N(k) in steps of 2.  R is a vector of numbers between 0 and 1,
.5'_5>tkv  
%   and THETA is a vector of angles.  R and THETA must have the same =:5o"g  
%   length.  The output Z is a matrix with one column for every (N,M) (;Ad:!9{  
%   pair, and one row for every (R,THETA) pair. Lwzk<+>w^  
% -q8R'?z[  
%   Z = ZERNFUN(N,M,R,THETA,'norm') returns the normalized Zernike JF+E.-fy$  
%   functions.  The normalization factor sqrt((2-delta(m,0))*(n+1)/pi), gXQ s)Eyv  
%   with delta(m,0) the Kronecker delta, is chosen so that the integral tr<iFT}C  
%   of (r * [Znm(r,theta)]^2) over the unit circle (from r=0 to r=1, :B(vk3;U!  
%   and theta=0 to theta=2*pi) is unity.  For the non-normalized ISbhC!59  
%   polynomials, max(Znm(r=1,theta))=1 for all [n,m]. 15/lX  
% c^?+"7oO0  
%   The Zernike functions are an orthogonal basis on the unit circle. A:?|\r  
%   They are used in disciplines such as astronomy, optics, and Q.$|TbVfds  
%   optometry to describe functions on a circular domain. nKO4o8js{{  
% -D4"uoN
.  
%   The following table lists the first 15 Zernike functions. :d!qZFln  
% soTmKqj E  
%       n    m    Zernike function           Normalization lo!.%PP|  
%       -------------------------------------------------- RAh4#8]  
%       0    0    1                                 1 N1vPY]8  
%       1    1    r * cos(theta)                    2 T08SGB]  
%       1   -1    r * sin(theta)                    2 v{T%`WuPRf  
%       2   -2    r^2 * cos(2*theta)             sqrt(6) FthrI  
%       2    0    (2*r^2 - 1)                    sqrt(3) ZliJc7lss  
%       2    2    r^2 * sin(2*theta)             sqrt(6) 5N_w(B  
%       3   -3    r^3 * cos(3*theta)             sqrt(8) z"vI
-~,YU  
%       3   -1    (3*r^3 - 2*r) * cos(theta)     sqrt(8) 65>1f  
%       3    1    (3*r^3 - 2*r) * sin(theta)     sqrt(8) 8vK$]e36  
%       3    3    r^3 * sin(3*theta)             sqrt(8) UrP jZ:K'  
%       4   -4    r^4 * cos(4*theta)             sqrt(10) T"tR*2HwSd  
%       4   -2    (4*r^4 - 3*r^2) * cos(2*theta) sqrt(10) >p[skN 
 
%       4    0    6*r^4 - 6*r^2 + 1              sqrt(5) }+F&=-P)  
%       4    2    (4*r^4 - 3*r^2) * cos(2*theta) sqrt(10) b":3J)Y6.  
%       4    4    r^4 * sin(4*theta)             sqrt(10) +IM:jrT(  
%       -------------------------------------------------- YIc|0[ ]*|  
% ]8c%)%Vi  
%   Example 1: I_k!'zR[N  
% Vp.&X 8  
%       % Display the Zernike function Z(n=5,m=1) y-/,,,r  
%       x = -1:0.01:1; 0<n*8t?A-  
%       [X,Y] = meshgrid(x,x); PE\.JU  
%       [theta,r] = cart2pol(X,Y); gI/#7Cr  
%       idx = r<=1; /
M3UK  
%       z = nan(size(X)); U=G}@Y  
%       z(idx) = zernfun(5,1,r(idx),theta(idx)); n$03##pf  
%       figure +pefk+  
%       pcolor(x,x,z), shading interp T0Kjnzs  
%       axis square, colorbar *2
(W`m  
%       title('Zernike function Z_5^1(r,\theta)') Pcs62aE  
% &l0-0T>  
%   Example 2: Q
~y) V  
% l[P VWM  
%       % Display the first 10 Zernike functions B'kV.3t  
%       x = -1:0.01:1; A@o:mZ+XN(  
%       [X,Y] = meshgrid(x,x); c2,;t)%@E  
%       [theta,r] = cart2pol(X,Y); K*]^0  
%       idx = r<=1; \H-,^[G3  
%       z = nan(size(X)); 8do7`mN  
%       n = [0  1  1  2  2  2  3  3  3  3]; RaBq@r*(
 
%       m = [0 -1  1 -2  0  2 -3 -1  1  3]; MB:VACCr  
%       Nplot = [4 10 12 16 18 20 22 24 26 28]; VOY#Y*)g  
%       y = zernfun(n,m,r(idx),theta(idx)); `-J$7)d@  
%       figure('Units','normalized') ^G*zFqa+`  
%       for k = 1:10 v1m'p:7uGB  
%           z(idx) = y(:,k); itpljh  
%           subplot(4,7,Nplot(k)) G8Qo]E9-/  
%           pcolor(x,x,z), shading interp @8;0p  
%           set(gca,'XTick',[],'YTick',[]) "+@>!U  
%           axis square 8e:\T.)M  
%           title(['Z_{' num2str(n(k)) '}^{' num2str(m(k)) '}']) uh8+Y%V p  
%       end .R<Ke\y/  
% (0cL! N;;  
%   See also ZERNPOL, ZERNFUN2. /ad]p
dF  
1;Q>B>6  
%   Paul Fricker 11/13/2006 4P(ysTuM  
?;c&5'7ct  
(X(296<;  
% Check and prepare the inputs: L( B(x>w  
% ----------------------------- iax6o+OG|  
if ( ~any(size(n)==1) ) || ( ~any(size(m)==1) ) YM(`E9{h  
    error('zernfun:NMvectors','N and M must be vectors.') ,];4+&|8kW  
end 3SU:Xd(\o  
`Qg#`  
if length(n)~=length(m) &M5_G$5n  
    error('zernfun:NMlength','N and M must be the same length.') VZRM=;V  
end \`MX\OR  
=D"H0w <zw  
n = n(:); 4NN81~v 4  
m = m(:); 2^TJ_xG~  
if any(mod(n-m,2)) uQYBq)p|  
    error('zernfun:NMmultiplesof2', ... .0eHP  
          'All N and M must differ by multiples of 2 (including 0).') {;kH&Pp  
end F:P&hK  
I {o\d'/  
if any(m>n) 4wa8Vw`  
    error('zernfun:MlessthanN', ... F[65)"^  
          'Each M must be less than or equal to its corresponding N.') Q~L"Mr8>V  
end 51Nh"JTy  
j+E[[  
if any( r>1 | r<0 ) !:7aXT*D$  
    error('zernfun:Rlessthan1','All R must be between 0 and 1.') J6s55 v  
end -H;%1y$A-  
_1? PN8  
if ( ~any(size(r)==1) ) || ( ~any(size(theta)==1) ) x,3oa_'E  
    error('zernfun:RTHvector','R and THETA must be vectors.') S[_Hc$7U  
end JuD$CHg;#  
^&|$&7  
r = r(:); R8uiLZd  
theta = theta(:); u\]aUP e  
length_r = length(r); K
ioD/  
if length_r~=length(theta) 5X'com?T  
    error('zernfun:RTHlength', ... 7T)J{:+0!|  
          'The number of R- and THETA-values must be equal.') G#~6a%VW  
end NUclF|G  
!{L6 4qI  
% Check normalization: lYz$~/sd  
% -------------------- NyJ=^=F#  
if nargin==5 && ischar(nflag) >;ucwLi  
    isnorm = strcmpi(nflag,'norm'); ?D^l&`S  
    if ~isnorm g@ ZZcBx  
        error('zernfun:normalization','Unrecognized normalization flag.') E7*z.3
  
    end B_B~Y8=3`  
else _*.Wo"[%[X  
    isnorm = false; zg3q\~  
end tVf1]3(_>  
>#MGGCGL  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Ef
}rMkv  
% Compute the Zernike Polynomials -ty_<m]  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |c]Y1WwDx  
t-vH\m  
% Determine the required powers of r: &f\ng{  
% ----------------------------------- Xu1tN9:oE  
m_abs = abs(m); fy|Ae  
rpowers = []; 05<MsxB"w  
for j = 1:length(n) qX(sx2TK  
    rpowers = [rpowers m_abs(j):2:n(j)]; bB^SD] }C  
end ^c9~~m16+  
rpowers = unique(rpowers); \\qw"w9  
y3 {om^ f  
% Pre-compute the values of r raised to the required powers, hE-u9i  
% and compile them in a matrix: }tIIA"dZ  
% ----------------------------- d45JT?qg&  
if rpowers(1)==0 qYMTud[Vf  
    rpowern = arrayfun(@(p)r.^p,rpowers(2:end),'UniformOutput',false); ^[d|^fRH Q  
    rpowern = cat(2,rpowern{:}); C?FUc cI  
    rpowern = [ones(length_r,1) rpowern]; Ef;OrE""  
else |7jUf$Q\p  
    rpowern = arrayfun(@(p)r.^p,rpowers,'UniformOutput',false); !2('Cq_^  
    rpowern = cat(2,rpowern{:}); +^c;4-X 0  
end YdgaZJs  
!V=s^8nj  
% Compute the values of the polynomials: az(u=}  
% -------------------------------------- ak?XE4-N  
y = zeros(length_r,length(n)); pvJsSX  
for j = 1:length(n) /&>6#3df-  
    s = 0:(n(j)-m_abs(j))/2; \pzqUTk  
    pows = n(j):-2:m_abs(j); @x>J-Owd]J  
    for k = length(s):-1:1 'w+T vOB  
        p = (1-2*mod(s(k),2))* ... ,R j{^-k  
                   prod(2:(n(j)-s(k)))/              ... =$B:i>z<  
                   prod(2:s(k))/                     ... -Kj^ l3w  
                   prod(2:((n(j)-m_abs(j))/2-s(k)))/ ... dpO ZqhRs.  
                   prod(2:((n(j)+m_abs(j))/2-s(k))); S-"&#OfWg<  
        idx = (pows(k)==rpowers); pI>i1f=W  
        y(:,j) = y(:,j) + p*rpowern(:,idx); #:v e3gWl  
    end 0R,?$qM\  
     k,xY\r$  
    if isnorm ^/wvHu[#  
        y(:,j) = y(:,j)*sqrt((1+(m(j)~=0))*(n(j)+1)/pi); b7It8  
    end  R1YRqk  
end Q'] _3  
% END: Compute the Zernike Polynomials ?~e 8:/@  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% hsVf/%  
;}b.gpG  
% Compute the Zernike functions: 9PA\Eo|Yb  
% ------------------------------
/q4<ZS#  
idx_pos = m>0; v1yNVs\}  
idx_neg = m<0; Z-RgN
 
slV+2b  
z = y; 'AX/?Srd  
if any(idx_pos) V`V Z[  
    z(:,idx_pos) = y(:,idx_pos).*sin(theta*m(idx_pos)');
sXm/+I^  
end ?|8H|LBIr  
if any(idx_neg) }fW@8ji\  
    z(:,idx_neg) = y(:,idx_neg).*cos(theta*m(idx_neg)'); V:rq}F}  
end yz}Agc4.I  
zg!;g`Z@S  
% EOF zernfun

function z = zernfun2(p,r,theta,nflag) `s (A&=g\  
%ZERNFUN2 Single-index Zernike functions on the unit circle. |:SBkM,  
%   Z = ZERNFUN2(P,R,THETA) returns the Pth Zernike functions evaluated JPQ[JD^]  
%   at positions (R,THETA) on the unit circle.  P is a vector of positive <o^_il$W  
%   integers between 0 and 35, R is a vector of numbers between 0 and 1, xmxfXW  
%   and THETA is a vector of angles.  R and THETA must have the same D.H$4[u;j  
%   length.  The output Z is a matrix with one column for every P-value, Y,OS
QBgk  
%   and one row for every (R,THETA) pair. `y; s1nL  
% `#&pB0.y  
%   Z = ZERNFUN2(P,R,THETA,'norm') returns the normalized Zernike E%\jR  
%   functions, defined such that the integral of (r * [Zp(r,theta)]^2) i$HaE)qZ  
%   over the unit circle (from r=0 to r=1, and theta=0 to theta=2*pi) L-\-wXg%  
%   is unity.  For the non-normalized polynomials, max(Zp(r=1,theta))=1 JnCp'`  
%   for all p. $Scb8<  
% "$KU+?  
%   NOTE: ZERNFUN2 returns the same output as ZERNFUN, for the first 36 \TSt  
%   Zernike functions (order N<=7).  In some disciplines it is +2!J3{[J  
%   traditional to label the first 36 functions using a single mode w?6"`Mo  
%   number P instead of separate numbers for the order N and azimuthal ,.tv#j|A  
%   frequency M. z5PFppSQ  
% n*G[ZW*Uc  
%   Example: [H-,zY  
% h% BA,C  
%       % Display the first 16 Zernike functions @e#eAJhU  
%       x = -1:0.01:1; W8j)2nKD  
%       [X,Y] = meshgrid(x,x); DQM\Y{y|3  
%       [theta,r] = cart2pol(X,Y); jZu">Eh,  
%       idx = r<=1; 5inmFT?9Z  
%       p = 0:15; 0UeDM*  
%       z = nan(size(X)); @EH:4~  
%       y = zernfun2(p,r(idx),theta(idx)); s0"S;{_#  
%       figure('Units','normalized') de
Srs:.  
%       for k = 1:length(p) 3+_? /}<  
%           z(idx) = y(:,k);
6Clxe Lk  
%           subplot(4,4,k) Mi&,64<  
%           pcolor(x,x,z), shading interp %m]9";  
%           set(gca,'XTick',[],'YTick',[]) K0RY2Hiw  
%           axis square Cdl#LVqs  
%           title(['Z_{' num2str(p(k)) '}']) 9\RSJGx6  
%       end kD:O$8[J8  
% p
OQ'k>!  
%   See also ZERNPOL, ZERNFUN. U.<';fKnT  
Yz;Hu$/  
%   Paul Fricker 11/13/2006 l-4T Tg  
'"LrGvkZ  
j(mbUB*  
% Check and prepare the inputs: @ROMHMd}  
% ----------------------------- 1lZl10M:f  
if min(size(p))~=1 mh;<lW\K/Z  
    error('zernfun2:Pvector','Input P must be vector.') ;rWgt!l  
end 4VINu9\V  
Iih~W&  
if any(p)>35 @'`!2[2'?  
    error('zernfun2:P36', ... }N^.4HOS8  
          ['ZERNFUN2 only computes the first 36 Zernike functions ' ... mY?^]3-_  
           '(P = 0 to 35).']) =zBcfFii`w  
end 8<ZxE(v  
An cmSi  
% Get the order and frequency corresonding to the function number: rLO1Sv  
% ---------------------------------------------------------------- 3RG*:9  
p = p(:); VE5w!of  
n = ceil((-3+sqrt(9+8*p))/2); tr0P;}=  
m = 2*p - n.*(n+2); ?_q e 2R.  
X[b=25Ct  
% Pass the inputs to the function ZERNFUN: E>f+E8?  
% ---------------------------------------- ;n_|t/=  
switch nargin 9lE[oAC  
    case 3 =?>f[J5  
        z = zernfun(n,m,r,theta); x>vC;E${"  
    case 4 9,\b$?9  
        z = zernfun(n,m,r,theta,nflag); f<WP<!N%  
    otherwise R=P=?U.  
        error('zernfun2:nargin','Incorrect number of inputs.') tcyami6D4  
end 5Z/xY&  
7K3S\oPej  
% EOF zernfun2

function z = zernpol(n,m,r,nflag) !gA<9h  
%ZERNPOL Radial Zernike polynomials of order N and frequency M. 0o~? ]C  
%   Z = ZERNPOL(N,M,R) returns the radial Zernike polynomials of Z18T<e  
%   order N and frequency M, evaluated at R.  N is a vector of 0nUcUdIf+  
%   positive integers (including 0), and M is a vector with the l&l&
eOE  
%   same number of elements as N.  Each element k of M must be a rOd<nP^`\  
%   positive integer, with possible values M(k) = 0,2,4,...,N(k) ?145^ w  
%   for N(k) even, and M(k) = 1,3,5,...,N(k) for N(k) odd.  R is 94 58.!3  
%   a vector of numbers between 0 and 1.  The output Z is a matrix Bfe#,  
%   with one column for every (N,M) pair, and one row for every ~t7?5b?*\  
%   element in R. Zp@j*P  
% vYQ0e:P  
%   Z = ZERNPOL(N,M,R,'norm') returns the normalized Zernike poly- Qgx9JJ>  
%   nomials.  The normalization factor Nnm = sqrt(2*(n+1)) is .vsrZ_y?  
%   chosen so that the integral of (r * [Znm(r)]^2) from r=0 to =K'X:UM  
%   r=1 is unity.  For the non-normalized polynomials, Znm(r=1)=1 ZDEz&{3U;  
%   for all [n,m]. jMv qKJ(<  
% " &2Kvsz  
%   The radial Zernike polynomials are the radial portion of the y%%D="  
%   Zernike functions, which are an orthogonal basis on the unit <QbD ;(%  
%   circle.  The series representation of the radial Zernike 2noKy}q  
%   polynomials is A|>~/OW=@  
% hG~4i:p <  
%          (n-m)/2 \]R
PxM:_>  
%            __ | a001_Wv  
%    m      \       s                                          n-2s YaiogA  
%   Z(r) =  /__ (-1)  [(n-s)!/(s!((n-m)/2-s)!((n+m)/2-s)!)] * r ]DVZeI03@  
%    n      s=0 'J\nvNm  
% |a9d]^  
%   The following table shows the first 12 polynomials. fA"N5qQI(  
% $yxwB/O(  
%       n    m    Zernike polynomial    Normalization }e$^v*16  
%       --------------------------------------------- FW* k O  
%       0    0    1                        sqrt(2) /}+VH_N1  
%       1    1    r                           2 nE.w  
%       2    0    2*r^2 - 1                sqrt(6) UrtA]pc3L  
%       2    2    r^2                      sqrt(6) zq]I"0Bi.  
%       3    1    3*r^3 - 2*r              sqrt(8) [7x,&  
%       3    3    r^3                      sqrt(8) Y%<y`]I  
%       4    0    6*r^4 - 6*r^2 + 1        sqrt(10) )F_vWbg  
%       4    2    4*r^4 - 3*r^2            sqrt(10) y!_*CYZ~m  
%       4    4    r^4                      sqrt(10) zT$-%  
%       5    1    10*r^5 - 12*r^3 + 3*r    sqrt(12) 8<V6W F`e  
%       5    3    5*r^5 - 4*r^3            sqrt(12) 38ac~1HjE  
%       5    5    r^5                      sqrt(12) {A!1s;  
%       --------------------------------------------- |2RoDW  
% -Q3jK)1  
%   Example: Y9V%eFY5E  
% B=dF\.&Z  
%       % Display three example Zernike radial polynomials
TA;r  
%       r = 0:0.01:1; ',Y`XP"Q  
%       n = [3 2 5]; O3ij/8f  
%       m = [1 2 1]; _:dt8+T#  
%       z = zernpol(n,m,r); RRSkXDU}  
%       figure X}jWNN  
%       plot(r,z) HC1jN8WDY  
%       grid on \ a}6NIo  
%       legend('Z_3^1(r)','Z_2^2(r)','Z_5^1(r)','Location','NorthWest') LPuc&8lGWf  
% w3,DsEXu  
%   See also ZERNFUN, ZERNFUN2. '7BJ.  
72Zp%a=  
% A note on the algorithm. 'v|R' wi\  
% ------------------------ j&
6O1  
% The radial Zernike polynomials are computed using the series YdgDMd-1  
% representation shown in the Help section above. For many special p7SX,kpt>  
% functions, direct evaluation using the series representation can ^7b[spqE  
% produce poor numerical results (floating point errors), because 5&Y%N(  
% the summation often involves computing small differences between h>0R!Rl8  
% large successive terms in the series. (In such cases, the functions Y9}5&#  
% are often evaluated using alternative methods such as recurrence Evjvaa^  
% relations: see the Legendre functions, for example). For the Zernike 1#nR$  
% polynomials, however, this problem does not arise, because the IZ9L ;"}  
% polynomials are evaluated over the finite domain r = (0,1), and `vbd7i  
% because the coefficients for a given polynomial are generally all sY|by\-c  
% of similar magnitude. 8]G  
% yT3q~#:  
% ZERNPOL has been written using a vectorized implementation: multiple *yx5G-#?  
% Zernike polynomials can be computed (i.e., multiple sets of [N,M] JXT%@w>I  
% values can be passed as inputs) for a vector of points R.  To achieve RC[mpR;2  
% this vectorization most efficiently, the algorithm in ZERNPOL :A,g:B  
% involves pre-determining all the powers p of R that are required to yM_ta '^$  
% compute the outputs, and then compiling the {R^p} into a single %R|_o<(#MJ  
% matrix.  This avoids any redundant computation of the R^p, and v@xbur\L  
% minimizes the sizes of certain intermediate variables. _1>Xk_  
% +, IMN)?;z  
%   Paul Fricker 11/13/2006 3bWYRW  
-'!
K("  
3y#U|&]{  
% Check and prepare the inputs: yW=I*f  
% ----------------------------- !
sTOo  
if ( ~any(size(n)==1) ) || ( ~any(size(m)==1) ) vk:k~  
    error('zernpol:NMvectors','N and M must be vectors.') CIt%7 \c  
end ?cyBF*o  
\OzPDN  
if length(n)~=length(m) s%cfJe_k  
    error('zernpol:NMlength','N and M must be the same length.') 4J~ZZ  
end \]:}lVtxS  

e7O9q8b  
n = n(:); J2_~iC&;s  
m = m(:); rd
)_*{  
length_n = length(n); d O})#50f  
5YV3pFz$)  
if any(mod(n-m,2)) Bd++G'FZ  
    error('zernpol:NMmultiplesof2','All N and M must differ by multiples of 2 (including 0).') "e-RV  
end `d,v  
$ [t7&e  
if any(m<0) Wx8oTN  
    error('zernpol:Mpositive','All M must be positive.') q HU}EEv  
end Y^Y1re+}  
}EMds3<  
if any(m>n) `GpOS_;  
    error('zernpol:MlessthanN','Each M must be less than or equal to its corresponding N.') 23(j<  
end ;h"St0
 
qH=<8Iu  
if any( r>1 | r<0 ) &s{" Vc9]  
    error('zernpol:Rlessthan1','All R must be between 0 and 1.')  /N8>>g  
end ~K2.T7=  
:lfUVa{HN  
if ~any(size(r)==1) RE<s$B$[  
    error('zernpol:Rvector','R must be a vector.') kq4ii`zi8  
end u3k{s  
f, iHM  
r = r(:); W'xJh0o  
length_r = length(r); `w(~[`F t  
wCitQ0?  
if nargin==4 .7K<9K+P  
    isnorm = ischar(nflag) & strcmpi(nflag,'norm'); 6OPYq*|  
    if ~isnorm VpO+52&  
        error('zernpol:normalization','Unrecognized normalization flag.') 2uEvu  
    end 0XzrzT"&  
else h>:eu#  
    isnorm = false; k|r|*|8  
end
\UEO$~Km  
2R`dyg  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% a W9_[#z5  
% Compute the Zernike Polynomials AzZb0wW6p  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 3 q^^Os  
n85d g  
% Determine the required powers of r: x-@}x@n&[  
% ----------------------------------- v;ZIqn"  
rpowers = []; 8WP
|cF]  
for j = 1:length(n) "q]r{0  
    rpowers = [rpowers m(j):2:n(j)]; =U`9_]~1c@  
end &_o.:SL|  
rpowers = unique(rpowers); ;!9-I%e  
z#u<]] 5  
% Pre-compute the values of r raised to the required powers, 9`FPV`/  
% and compile them in a matrix: j&|>Aa${  
% ----------------------------- xV\mS+#  
if rpowers(1)==0 r^Mu`*x*  
    rpowern = arrayfun(@(p)r.^p,rpowers(2:end),'UniformOutput',false); JW2~ G!@  
    rpowern = cat(2,rpowern{:}); mM;5UPbZ  
    rpowern = [ones(length_r,1) rpowern]; T\OpPSYbl  
else +d289"  
    rpowern = arrayfun(@(p)r.^p,rpowers,'UniformOutput',false); }{SpV  
    rpowern = cat(2,rpowern{:}); nsjrzO79L8  
end Y7GHIzX  
n1Fp$9%  
% Compute the values of the polynomials: v2KK%Qy  
% -------------------------------------- ZD#{h J-  
z = zeros(length_r,length_n); I=c}6  
for j = 1:length_n RA3!k&8?#  
    s = 0:(n(j)-m(j))/2; wqE+hKs,  
    pows = n(j):-2:m(j); ;hZ^zL  
    for k = length(s):-1:1 N6<
G`
k,  
        p = (1-2*mod(s(k),2))* ... *V[6ta
'
 
                   prod(2:(n(j)-s(k)))/          ... caD|*.b  
                   prod(2:s(k))/                 ... i7jI(VvB^  
                   prod(2:((n(j)-m(j))/2-s(k)))/ ... O!ngQrI  
                   prod(2:((n(j)+m(j))/2-s(k))); @w @SOzS)  
        idx = (pows(k)==rpowers); f2,\B6+  
        z(:,j) = z(:,j) + p*rpowern(:,idx); (!:+q$#BK  
    end I%'6IpR"d  
     h7 c  
    if isnorm Jf
3xK"in  
        z(:,j) = z(:,j)*sqrt(2*(n(j)+1)); ;vp[J&=  
    end Xo/0lT  
end H+?@LPV*N  
 ?@iGECll  
% EOF zernpol

这三个文件，我不知道该怎样把我的面型节点的坐标及轴向位移用起来，还烦请指点一下啊，谢谢啦！

我也正在找啊

我也一直想了解这个多项式的应用，还没用过呢

guapiqlh:我也一直想了解这个多项式的应用，还没用过呢 (2014-03-04 11:35)  2'5
u}G9  

uG{/yJeU  
数值分析方法看一下就行了。其实就是正交多项式的应用。zernike也只不过是正交多项式的一种。 _a-At  
,@r 0-gL  
07年就写过这方面的计算程序了。