[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 $:v
S_#  
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！ ^Q!A4qOQ  

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 U8<C
4  
function z = zernfun(n,m,r,theta,nflag) `9
|Uu#x  
%ZERNFUN Zernike functions of order N and frequency M on the unit circle. }8`>n4  
%   Z = ZERNFUN(N,M,R,THETA) returns the Zernike functions of order N K4OiKYq  
%   and angular frequency M, evaluated at positions (R,THETA) on the j%81q  
%   unit circle.  N is a vector of positive integers (including 0), and LQ||7>{eX  
%   M is a vector with the same number of elements as N.  Each element `9acR>00$  
%   k of M must be a positive integer, with possible values M(k) = -N(k) !=6\70lJ  
%   to +N(k) in steps of 2.  R is a vector of numbers between 0 and 1, +Y>oNX1KN  
%   and THETA is a vector of angles.  R and THETA must have the same ?5j~"  
%   length.  The output Z is a matrix with one column for every (N,M) :_o^oi7G  
%   pair, and one row for every (R,THETA) pair. 0*AXd=)"*  
% |vxmgX)  
%   Z = ZERNFUN(N,M,R,THETA,'norm') returns the normalized Zernike ]q&NO(:kbq  
%   functions.  The normalization factor sqrt((2-delta(m,0))*(n+1)/pi), Y6(=cm  
%   with delta(m,0) the Kronecker delta, is chosen so that the integral A5sz[k  
%   of (r * [Znm(r,theta)]^2) over the unit circle (from r=0 to r=1, ^szi[Cj  
%   and theta=0 to theta=2*pi) is unity.  For the non-normalized KD--w(4  
%   polynomials, max(Znm(r=1,theta))=1 for all [n,m]. w`gT]Rn  
% Bz>5OuOVS\  
%   The Zernike functions are an orthogonal basis on the unit circle. dKa2_|k'  
%   They are used in disciplines such as astronomy, optics, and *dsI>4%m  
%   optometry to describe functions on a circular domain. ff00s+  
% &+yoPF  
%   The following table lists the first 15 Zernike functions. |ZOdfr4uW  
% Au:R]7   
%       n    m    Zernike function           Normalization ^S!;snhn  
%       -------------------------------------------------- aF>&X-2  
%       0    0    1                                 1 F#.ph?W  
%       1    1    r * cos(theta)                    2 8uA!Vrp3  
%       1   -1    r * sin(theta)                    2 T*'WS!z  
%       2   -2    r^2 * cos(2*theta)             sqrt(6) g~76c.u-  
%       2    0    (2*r^2 - 1)                    sqrt(3) z8xBq%97us  
%       2    2    r^2 * sin(2*theta)             sqrt(6) !w;/J^  
%       3   -3    r^3 * cos(3*theta)             sqrt(8) rCb#E}  
%       3   -1    (3*r^3 - 2*r) * cos(theta)     sqrt(8) A>_,tt  
%       3    1    (3*r^3 - 2*r) * sin(theta)     sqrt(8) K'f2S  
%       3    3    r^3 * sin(3*theta)             sqrt(8) YoWXHg!U  
%       4   -4    r^4 * cos(4*theta)             sqrt(10) Ns5P,[pBOZ  
%       4   -2    (4*r^4 - 3*r^2) * cos(2*theta) sqrt(10) Fe.90)  
%       4    0    6*r^4 - 6*r^2 + 1              sqrt(5) aDu[iaZ  
%       4    2    (4*r^4 - 3*r^2) * cos(2*theta) sqrt(10) "CZv5)  
%       4    4    r^4 * sin(4*theta)             sqrt(10) )g KC}_h=  
%       -------------------------------------------------- 1pjx8*!B  
% _z9~\N/@[  
%   Example 1: S27s Rxfr  
% ,RP9v*  
%       % Display the Zernike function Z(n=5,m=1) :@-.whj  
%       x = -1:0.01:1; kU.@HJ[@j  
%       [X,Y] = meshgrid(x,x); .bj:tmz  
%       [theta,r] = cart2pol(X,Y); &2I8!Ia  
%       idx = r<=1; {uJ"%  
%       z = nan(size(X)); Ty7)j]b"zl  
%       z(idx) = zernfun(5,1,r(idx),theta(idx)); l+X
\>,  
%       figure s^Xs*T@~h  
%       pcolor(x,x,z), shading interp Z$zX%w  
%       axis square, colorbar r`<x@,  
%       title('Zernike function Z_5^1(r,\theta)') 0f_A"K  
% xC}'"``s  
%   Example 2: U}
w@,6  
% $9:  @M.  
%       % Display the first 10 Zernike functions D|^N9lDaQ  
%       x = -1:0.01:1; m;L3c(r.  
%       [X,Y] = meshgrid(x,x); n~tb z"&  
%       [theta,r] = cart2pol(X,Y); ukRmjHbLf  
%       idx = r<=1; tD4-Llj6  
%       z = nan(size(X)); >Psq" Xj  
%       n = [0  1  1  2  2  2  3  3  3  3]; ($W%&(:/  
%       m = [0 -1  1 -2  0  2 -3 -1  1  3]; [jrfh>v  
%       Nplot = [4 10 12 16 18 20 22 24 26 28]; MH0wpHz  
%       y = zernfun(n,m,r(idx),theta(idx)); v5U'ky:  
%       figure('Units','normalized') i'\-Y]?[  
%       for k = 1:10 .tQ(q=#  
%           z(idx) = y(:,k); S\!vDtD@  
%           subplot(4,7,Nplot(k)) VN'\c3;  
%           pcolor(x,x,z), shading interp KVUub'k  
%           set(gca,'XTick',[],'YTick',[]) <RtyW  
%           axis square YHMJ5IM@.  
%           title(['Z_{' num2str(n(k)) '}^{' num2str(m(k)) '}'])
{7;QZk(  
%       end MU\Pggs  
% 1kR. .p<"  
%   See also ZERNPOL, ZERNFUN2. AWssDbh/[  
%s^1de  
%   Paul Fricker 11/13/2006 ;zV<63tW  
3i'01z  
WWo"De@  
% Check and prepare the inputs: B<n[yiJ}  
% ----------------------------- 5(E&jKn&  
if ( ~any(size(n)==1) ) || ( ~any(size(m)==1) ) L 4Z+8*  
    error('zernfun:NMvectors','N and M must be vectors.') (U_HX2f  
end ]lqZ9rO  
rS8\Vf]F  
if length(n)~=length(m) 62y
:i  
    error('zernfun:NMlength','N and M must be the same length.') jzBW'8  
end xq=!1>  
{<-wm-]mo  
n = n(:); RDjw|V
 
m = m(:); Z:es7<#y  
if any(mod(n-m,2)) }^j8<  
    error('zernfun:NMmultiplesof2', ... e4tC[6;  
          'All N and M must differ by multiples of 2 (including 0).') sLXM$SMBh  
end zmL VFGnS  
po,Ue>n/  
if any(m>n) \7pEn  
    error('zernfun:MlessthanN', ... `H$=hr  
          'Each M must be less than or equal to its corresponding N.') z%
iPk'^  
end rm$dv%q  
aw~h03R_Z  
if any( r>1 | r<0 ) ^S?f"''y3  
    error('zernfun:Rlessthan1','All R must be between 0 and 1.') x
%HxM~&  
end Gf:dN_e6.  
5`gVziS!S  
if ( ~any(size(r)==1) ) || ( ~any(size(theta)==1) ) ;[[6[i  
    error('zernfun:RTHvector','R and THETA must be vectors.') #g0N/  
end 11kyrv  
cMnN} '  
r = r(:); C=v+e%)x@  
theta = theta(:); "Z;({a$v  
length_r = length(r); 5MKM;6cA&p  
if length_r~=length(theta) 4;r,U{uR  
    error('zernfun:RTHlength', ... "@/pQoLy  
          'The number of R- and THETA-values must be equal.') =&qH%S
6  
end ~TeOl|!lE+  
0a#v}w^*  
% Check normalization: (E&M[hH+  
% -------------------- S]~5iO_bst  
if nargin==5 && ischar(nflag) q9{)nU  
    isnorm = strcmpi(nflag,'norm'); /!A"[Tyt  
    if ~isnorm !.q9:|oc  
        error('zernfun:normalization','Unrecognized normalization flag.') j(]O$""
 
    end 4z26a  
else ^cSfkBh  
    isnorm = false; &zJ*afi)  
end IYXN}M.=  
WBkx!{\z  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% (Z[c7  
% Compute the Zernike Polynomials u%E8&T8,  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% s/s&d pT*  
-1d*zySL  
% Determine the required powers of r: c00rq ~<K  
% ----------------------------------- D %)L"5C  
m_abs = abs(m); m)"(S  
rpowers = []; B8n[ E  
for j = 1:length(n) NH}o`x/  
    rpowers = [rpowers m_abs(j):2:n(j)]; \[.qN  
end %"fO^KA.h]  
rpowers = unique(rpowers); _KxR~
k^  
)oz2V9X{  
% Pre-compute the values of r raised to the required powers, $Cfp1#  
% and compile them in a matrix: Kg"eS`-  
% ----------------------------- J'7;+.s(  
if rpowers(1)==0 VP^Yf_  
    rpowern = arrayfun(@(p)r.^p,rpowers(2:end),'UniformOutput',false); B@0#*I Rm  
    rpowern = cat(2,rpowern{:}); % XZ&(  
    rpowern = [ones(length_r,1) rpowern]; ztX$kX:_m  
else |9IOZ

>H9  
    rpowern = arrayfun(@(p)r.^p,rpowers,'UniformOutput',false); 92A9gY
  
    rpowern = cat(2,rpowern{:}); knph549  
end ~u2f`67
{  
alHA&YC{K  
% Compute the values of the polynomials: -T{2R:\{  
% -------------------------------------- j>:N0:  
y = zeros(length_r,length(n)); 
5;p
|iT  
for j = 1:length(n) |3!)  
    s = 0:(n(j)-m_abs(j))/2; Pmd[2/][  
    pows = n(j):-2:m_abs(j); j4=iHnE;  
    for k = length(s):-1:1 Ddg!1SF  
        p = (1-2*mod(s(k),2))* ... Wkjp:`(-$r  
                   prod(2:(n(j)-s(k)))/              ... aGi`(|shW  
                   prod(2:s(k))/                     ... JJ}DYv  
                   prod(2:((n(j)-m_abs(j))/2-s(k)))/ ... H)gc"aRe;Y  
                   prod(2:((n(j)+m_abs(j))/2-s(k))); Z
AN~TG<n  
        idx = (pows(k)==rpowers); %X %zK1  
        y(:,j) = y(:,j) + p*rpowern(:,idx); Cb+$|Kg/"b  
    end NW`.7'aWT  
     2gZp O9  
    if isnorm QSa#}vCp*  
        y(:,j) = y(:,j)*sqrt((1+(m(j)~=0))*(n(j)+1)/pi); Rk#'^}  
    end Y:,C_^$w;  
end GWPBP-)0  
% END: Compute the Zernike Polynomials c!7WRHJE_a  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% 1 Ga3[g  
}8aqSD<:  
% Compute the Zernike functions: zb!1o0, J  
% ------------------------------ _0'X!1"  
idx_pos = m>0; un-%p#  
idx_neg = m<0; uyB2   
&,jUaC5I  
z = y; 2z;3NUL$n  
if any(idx_pos)
7]T(=gg /  
    z(:,idx_pos) = y(:,idx_pos).*sin(theta*m(idx_pos)'); ux(~+<k  
end MkJBKS  
if any(idx_neg) =d^hiR!GN  
    z(:,idx_neg) = y(:,idx_neg).*cos(theta*m(idx_neg)'); GU2TQx{V  
end tJ>>cFx  
,-E'059  
% EOF zernfun

function z = zernfun2(p,r,theta,nflag) Er j{_i?R?  
%ZERNFUN2 Single-index Zernike functions on the unit circle. qwj7CIc(  
%   Z = ZERNFUN2(P,R,THETA) returns the Pth Zernike functions evaluated nf"#F@dk  
%   at positions (R,THETA) on the unit circle.  P is a vector of positive Wd)\r.pJ  
%   integers between 0 and 35, R is a vector of numbers between 0 and 1, a4~B  
%   and THETA is a vector of angles.  R and THETA must have the same y _"V=:  
%   length.  The output Z is a matrix with one column for every P-value, M NwY   
%   and one row for every (R,THETA) pair. <%uEWb)  
% JP6 Noia  
%   Z = ZERNFUN2(P,R,THETA,'norm') returns the normalized Zernike wW\@^5  
%   functions, defined such that the integral of (r * [Zp(r,theta)]^2) 54>0Dv??H  
%   over the unit circle (from r=0 to r=1, and theta=0 to theta=2*pi) } (-9d  
%   is unity.  For the non-normalized polynomials, max(Zp(r=1,theta))=1 9]IZ3 fQX  
%   for all p. \l/}` w  
% FauASu,A  
%   NOTE: ZERNFUN2 returns the same output as ZERNFUN, for the first 36 Fd<Ouyxqe  
%   Zernike functions (order N<=7).  In some disciplines it is {X(nn.GpC  
%   traditional to label the first 36 functions using a single mode i]k)wr(  
%   number P instead of separate numbers for the order N and azimuthal LS<+V+o2%  
%   frequency M. L k nK  
% oydP}X  
%   Example: ,>6a)2xh  
% Ev
m3Sm!S  
%       % Display the first 16 Zernike functions `IwZVz  
%       x = -1:0.01:1; ]YhQQH1>]  
%       [X,Y] = meshgrid(x,x); EDgtn)1  
%       [theta,r] = cart2pol(X,Y); Y"8@\73(R  
%       idx = r<=1; 2ak]&ll+h  
%       p = 0:15; }'x)e  
%       z = nan(size(X)); $aJay]F  
%       y = zernfun2(p,r(idx),theta(idx)); ff.k1%wr^  
%       figure('Units','normalized') Q34u>VkdQI  
%       for k = 1:length(p) !vu-`u~86  
%           z(idx) = y(:,k); xk>cd
gt  
%           subplot(4,4,k) dyn)KDS  
%           pcolor(x,x,z), shading interp h?n?3x!(  
%           set(gca,'XTick',[],'YTick',[]) E<3xv;v8r  
%           axis square |Vz)!M  
%           title(['Z_{' num2str(p(k)) '}']) O[MFp  
%       end }?mSMqnB  
% 3<$Ek3X  
%   See also ZERNPOL, ZERNFUN. z3S"1L7  
t.;._'  
%   Paul Fricker 11/13/2006 M]{~T7n-  
8ly)G  
06AgY0\  
% Check and prepare the inputs: sd%)g<t  
% ----------------------------- COHBjufmR  
if min(size(p))~=1 A8mc+ Bf(  
    error('zernfun2:Pvector','Input P must be vector.') ]m 3cm  
end de W1>yh^_  
u,8)M'UU  
if any(p)>35 ;AOLbmb)H4  
    error('zernfun2:P36', ... jnJ*e-AW  
          ['ZERNFUN2 only computes the first 36 Zernike functions ' ... SceHdx(]  
           '(P = 0 to 35).']) y-.{){uaD  
end (y!bvp[" m  
s;oe Qa}TB  
% Get the order and frequency corresonding to the function number: w"[T  
% ---------------------------------------------------------------- Sq,>^|v4&e  
p = p(:); s1cu5eCt  
n = ceil((-3+sqrt(9+8*p))/2); t6+W  
m = 2*p - n.*(n+2); xP_%d,  
y'^U4# (  
% Pass the inputs to the function ZERNFUN: rMIX{K)'f  
% ---------------------------------------- l@GJcCufE  
switch nargin W3UxFs]$  
    case 3
3)W_^6>bM  
        z = zernfun(n,m,r,theta); V^Z5i]zT  
    case 4 #OM'2@  
        z = zernfun(n,m,r,theta,nflag); Q+
Q"JU  
    otherwise *\'t$se+  
        error('zernfun2:nargin','Incorrect number of inputs.') z~`X4Segw  
end $6UU58>n  
n^{h@u  
% EOF zernfun2

function z = zernpol(n,m,r,nflag) IYq#|^)5+  
%ZERNPOL Radial Zernike polynomials of order N and frequency M. VS ECD;u4c  
%   Z = ZERNPOL(N,M,R) returns the radial Zernike polynomials of ,h1\PT9ULY  
%   order N and frequency M, evaluated at R.  N is a vector of p({@t=L3g  
%   positive integers (including 0), and M is a vector with the dO2?&f  
%   same number of elements as N.  Each element k of M must be a cA4?[F  
%   positive integer, with possible values M(k) = 0,2,4,...,N(k) r3' DXP  
%   for N(k) even, and M(k) = 1,3,5,...,N(k) for N(k) odd.  R is lbt8S.fx  
%   a vector of numbers between 0 and 1.  The output Z is a matrix dDl+  
%   with one column for every (N,M) pair, and one row for every h9m|f|cH  
%   element in R. ;0m J4G  
% 9Cd/SlNV2  
%   Z = ZERNPOL(N,M,R,'norm') returns the normalized Zernike poly- lq53 xT  
%   nomials.  The normalization factor Nnm = sqrt(2*(n+1)) is `.JW_F)1  
%   chosen so that the integral of (r * [Znm(r)]^2) from r=0 to fgL"\d}  
%   r=1 is unity.  For the non-normalized polynomials, Znm(r=1)=1 N}VoO0I  
%   for all [n,m]. x*F-d2D  
% /y{fDCC  
%   The radial Zernike polynomials are the radial portion of the ~cp=B>*(  
%   Zernike functions, which are an orthogonal basis on the unit ,8Q0AkG  
%   circle.  The series representation of the radial Zernike B=]L%~xL$  
%   polynomials is +pT;; 9  
% JXkx!X_{  
%          (n-m)/2 k]:`<`/I_  
%            __ qh6b;ae\x  
%    m      \       s                                          n-2s ku*k+4rz  
%   Z(r) =  /__ (-1)  [(n-s)!/(s!((n-m)/2-s)!((n+m)/2-s)!)] * r [g@qZ5I.  
%    n      s=0 Gev\bQa  
% ~.^:?yCA  
%   The following table shows the first 12 polynomials. 3O*
iv{-&  
% ZhCz]z~tj6  
%       n    m    Zernike polynomial    Normalization mz1m^p)~{  
%       --------------------------------------------- 'MYKAnZ-i  
%       0    0    1                        sqrt(2) <Tgubv+J  
%       1    1    r                           2 XN t` 4$L  
%       2    0    2*r^2 - 1                sqrt(6) -eV*I>G  
%       2    2    r^2                      sqrt(6) Ygg+=@].@  
%       3    1    3*r^3 - 2*r              sqrt(8) (T2HUmkQ6  
%       3    3    r^3                      sqrt(8) ) C~#W  
%       4    0    6*r^4 - 6*r^2 + 1        sqrt(10) 9=iMP~?xF  
%       4    2    4*r^4 - 3*r^2            sqrt(10) 7^rT-f07  
%       4    4    r^4                      sqrt(10) & ;5f/  
%       5    1    10*r^5 - 12*r^3 + 3*r    sqrt(12) Oz\J+  
%       5    3    5*r^5 - 4*r^3            sqrt(12) Y'P^]Q=}_#  
%       5    5    r^5                      sqrt(12) L=Aj+  
%       --------------------------------------------- ]g9SUFM  
% "&D0Sd@[?  
%   Example: Gl{'a
1  
% YG*<jKcX  
%       % Display three example Zernike radial polynomials n)a/pO_  
%       r = 0:0.01:1; )ZLj2H<  
%       n = [3 2 5]; GBg  
%       m = [1 2 1]; a0JMLLa [I  
%       z = zernpol(n,m,r); 34)l3UI~  
%       figure #gWok'ZcR  
%       plot(r,z) J:uFQWxZ   
%       grid on <<qzZ+u  
%       legend('Z_3^1(r)','Z_2^2(r)','Z_5^1(r)','Location','NorthWest') $Nvox<d0  
% F3!6}
u\F  
%   See also ZERNFUN, ZERNFUN2. |]q{qsy  
[W[awGf  
% A note on the algorithm. *dB3Gu{ +  
% ------------------------ En-=z`j G  
% The radial Zernike polynomials are computed using the series J Z@sk2  
% representation shown in the Help section above. For many special `3[
W~Cq  
% functions, direct evaluation using the series representation can h-Ks:pcR  
% produce poor numerical results (floating point errors), because ueW/i  
% the summation often involves computing small differences between obbg#,  
% large successive terms in the series. (In such cases, the functions |iSwG=&  
% are often evaluated using alternative methods such as recurrence :G9d,B7*  
% relations: see the Legendre functions, for example). For the Zernike {Gfsiz6  
% polynomials, however, this problem does not arise, because the L*Ffic  
% polynomials are evaluated over the finite domain r = (0,1), and #+"D?  
% because the coefficients for a given polynomial are generally all g] IPNW^n  
% of similar magnitude. )knK'H(  
% WQw11uMt@q  
% ZERNPOL has been written using a vectorized implementation: multiple 0.!vp?  
% Zernike polynomials can be computed (i.e., multiple sets of [N,M] eUa:@cA  
% values can be passed as inputs) for a vector of points R.  To achieve ~Odclrs  
% this vectorization most efficiently, the algorithm in ZERNPOL hP[/xe  
% involves pre-determining all the powers p of R that are required to ;gJAxVD<  
% compute the outputs, and then compiling the {R^p} into a single C)qG<PW.!  
% matrix.  This avoids any redundant computation of the R^p, and S9b=?? M)  
% minimizes the sizes of certain intermediate variables. OHngpe4  
% {KTZSs $n  
%   Paul Fricker 11/13/2006 A;/,</  
b4KNIP7E  
J~
@W":v  
% Check and prepare the inputs: {RsdI=%  
% ----------------------------- 7S=]@*  
if ( ~any(size(n)==1) ) || ( ~any(size(m)==1) ) Bz,Xg-k+  
    error('zernpol:NMvectors','N and M must be vectors.') )cOBP}j+  
end ,HE{&p2y  
(i<\n`h1K  
if length(n)~=length(m) tnb'\}Vn  
    error('zernpol:NMlength','N and M must be the same length.') :%fnJg(
 
end N-p||u  
KxJDAP  
n = n(:); 54]UfmT%I  
m = m(:); _!vuDv%  
length_n = length(n); "0>AefFd#  
aJs! bx>K  
if any(mod(n-m,2)) h^H)p`[Gme  
    error('zernpol:NMmultiplesof2','All N and M must differ by multiples of 2 (including 0).') '|%\QWuZ  
end ,4,./wIq  
L`w_Q2{sv  
if any(m<0) l~1l~Gx_&n  
    error('zernpol:Mpositive','All M must be positive.') Fv^>^txh  
end .q 4FGPWz  
uXGAcUx(  
if any(m>n) &xC5Mecb*  
    error('zernpol:MlessthanN','Each M must be less than or equal to its corresponding N.') -ebyW#  
end dZd]p8  
k1D|Cpnp  
if any( r>1 | r<0 ) `apC
u  
    error('zernpol:Rlessthan1','All R must be between 0 and 1.') 8X\":l:  
end R C!~eJG!  
\%W"KLP  
if ~any(size(r)==1) _4lKd`  
    error('zernpol:Rvector','R must be a vector.') /dR:\ffz2  
end m$'ZiS5  
``h*A  
r = r(:); 2tp95E`(O  
length_r = length(r); eN TKX  
>/-Bg:  
if nargin==4 c5eimA%`  
    isnorm = ischar(nflag) & strcmpi(nflag,'norm'); 2) Q/cH\g  
    if ~isnorm M"OCwBTU  
        error('zernpol:normalization','Unrecognized normalization flag.') k#5Qwxu`  
    end nG| NRp  
else Q,o"[ &Gp  
    isnorm = false; %$R]NL|  
end p"Di;3!y!  
SUoUXh^!w  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #.@D}7y5  
% Compute the Zernike Polynomials Q"GZh.m  
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% [-=y*lx%g  
u>03l(X6f  
% Determine the required powers of r: [@$t35t~  
% ----------------------------------- pc](  
rpowers = []; s%l^zA(  
for j = 1:length(n) A9y3B^\*  
    rpowers = [rpowers m(j):2:n(j)]; ~5~Cpu
2v7  
end Bh q]h  
rpowers = unique(rpowers); ~2 J!I^J  
? C6tYd  
% Pre-compute the values of r raised to the required powers, [jKhC<t}  
% and compile them in a matrix: y>JSo9[@  
% ----------------------------- 7Y1FFw|  
if rpowers(1)==0 KA9v?_@{F  
    rpowern = arrayfun(@(p)r.^p,rpowers(2:end),'UniformOutput',false); h}GzQry1  
    rpowern = cat(2,rpowern{:}); T5TAkEVl  
    rpowern = [ones(length_r,1) rpowern]; v==/tr)  
else 2Ni
{fC?  
    rpowern = arrayfun(@(p)r.^p,rpowers,'UniformOutput',false); OGnuBK
 
    rpowern = cat(2,rpowern{:}); GaOM|F'>  
end rn-CQ2{?  
r)f+j@KF  
% Compute the values of the polynomials: f]kG%JEK  
% -------------------------------------- {60U6n  
z = zeros(length_r,length_n); f;a55%3c  
for j = 1:length_n c"S{5xh0&  
    s = 0:(n(j)-m(j))/2; iq`caoi  
    pows = n(j):-2:m(j); ys}I~MK-  
    for k = length(s):-1:1 6tBe,'*  
        p = (1-2*mod(s(k),2))* ... N?mQ50o~C  
                   prod(2:(n(j)-s(k)))/          ... /G!M\teeF  
                   prod(2:s(k))/                 ... jtQ}   
                   prod(2:((n(j)-m(j))/2-s(k)))/ ... ,\ zx4*  
                   prod(2:((n(j)+m(j))/2-s(k))); 0-IL@Di`F  
        idx = (pows(k)==rpowers); I73=PfS:m  
        z(:,j) = z(:,j) + p*rpowern(:,idx); $36.*s m  
    end WKONK;U+7  
     :Mnl1;oh  
    if isnorm / #D R|  
        z(:,j) = z(:,j)*sqrt(2*(n(j)+1)); !TPKD  
    end [|APMMYK1  
end 78t:ge eX  
y3@5~4+  
% 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)  [9G=x[  

%<fs \J^k  
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。 AG><5 }  
U9jdb9 |  
07年就写过这方面的计算程序了。