{ This file is part of the Numlib package. Copyright (c) 1986-2000 by Kees van Ginneken, Wil Kortsmit and Loek van Reij of the Computational centre of the Eindhoven University of Technology FPC port Code by Marco van de Voort (marco@freepascal.org) documentation by Michael van Canneyt (Michael@freepascal.org) Interpolate and (curve) fitting. Slegpb in this unit patched parameters slightly. Units IPF and sle were not in the same revision in this numlib copy (which was a copy of the work directory of the author) . Contains two undocumented functions. If you recognize the algoritm, mail us. See the file COPYING.FPC, included in this distribution, for details about the copyright. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. **********************************************************************} { } unit ipf; {$I direct.inc} interface uses typ, mdt, dsl, sle, spe; { Determine natural cubic spline "s" for data set (x,y), output to (a,d2a) term=1 success, =2 failure calculating "s" =3 wrong input (e.g. x,y is not sorted increasing on x)} procedure ipffsn(n: ArbInt; var x, y, a, d2a: ArbFloat; var term: ArbInt); {calculate d2s from x,y, which can be used to calculate s} procedure ipfisn(n: ArbInt; var x, y, d2s: ArbFloat; var term: ArbInt); {Calculate function value for dataset (x,y), with n.c. spline d2s for x value t. Return (corrected) y value. s calculated from x,y, with e.g. ipfisn} function ipfspn(n: ArbInt; var x, y, d2s: ArbFloat; t: ArbFloat; var term: ArbInt): ArbFloat; {Calculate minimum and maximum values for the n.c. spline d2s. Does NOT take source points into account.} procedure ipfsmm( n: ArbInt; var x, y, d2s, minv, maxv: ArbFloat; var term: ArbInt); {Calculate n-degree polynomal b for dataset (x,y) with n elements using the least squares method.} procedure ipfpol(m, n: ArbInt; var x, y, b: ArbFloat; var term: ArbInt); {**** undocumented ****} function spline( n : ArbInt; x : complex; var ac : complex; var gammar: ArbFloat; u1 : ArbFloat; pf : complex): ArbFloat; {**** undocumented ****} procedure splineparameters ( n : ArbInt; var ac, alfadc : complex; var lambda, gammar, u1, kwsom, energie : ArbFloat; var pf : complex); implementation procedure ipffsn(n: ArbInt; var x, y, a, d2a: ArbFloat; var term: ArbInt); var i, j, sr, n1s, ns1, ns2: ArbInt; s, lam, lam0, lam1, lambda, ey, ca, p, q, r: ArbFloat; px, py, pd, pa, pd2a, h, z, diagb, dinv, qty, qtdinvq, c, t, tl: ^arfloat1; ub: boolean; procedure solve; {n, py, qty, h, qtdinvq, dinv, lam, t, pa, pd2a, term} var i: ArbInt; p, q, r, ca: ArbFloat; f, c: ^arfloat1; begin getmem(f, 3*ns1); getmem(c, ns1); for i:=1 to n-1 do begin f^[3*i]:=qtdinvq^[3*i]+lam*t^[2*i]; if i > 1 then f^[3*i-1]:=qtdinvq^[3*i-1]+lam*t^[2*i-1]; if i > 2 then f^[3*i-2]:=qtdinvq^[3*i-2]; if lam=0 then c^[i]:=qty^[i] else c^[i]:=lam*qty^[i] end; slegpb(n-1, 2,{ 3,} f^[1], c^[1], pd2a^[1], ca, term); if term=2 then begin freemem(f, 3*ns1); freemem(c, ns1); exit end; p:=1/h^[1]; if lam=0 then r:=1 else r:=1/lam; q:=1/h^[2]; pa^[1]:=py^[1]-r*dinv^[1]*p*pd2a^[1]; pa^[2]:=py^[2]-r*dinv^[2]*(pd2a^[2]*q-(p+q)*pd2a^[1]); p:=q; for i:=3 to n-1 do begin q:=1/h^[i]; pa^[i]:=py^[i]-r*dinv^[i]* (p*pd2a^[i-2]-(p+q)*pd2a^[i-1]+q*pd2a^[i]); p:=q end; q:=1/h^[n]; pa^[n]:=py^[n]-r*dinv^[n]*(p*pd2a^[n-2]-(p+q)*pd2a^[n-1]); pa^[n+1]:=py^[n+1]-r*dinv^[n+1]*q*pd2a^[n-1]; if lam=0 then for i:=1 to n-1 do pd2a^[i]:=0; freemem(f, 3*ns1); freemem(c, ns1); end; {solve} function e(var c, h: ArbFloat; n:ArbInt): ArbFloat; var i:ArbInt; s:ArbFloat; pc, ph: ^arfloat1; begin ph:=@h; pc:=@c; s:=ph^[1]*pc^[1]*pc^[1]; for i:=1 to n-2 do s:=s+(pc^[i]*(pc^[i]+pc^[i+1])+pc^[i+1]*pc^[i+1])*ph^[i+1]; e:=(s+pc^[n-1]*pc^[n-1]*ph^[n])/3 end; {e} function cr(lambda: ArbFloat): ArbFloat; var s, crs: ArbFloat; i: ArbInt; begin cr:=0; lam:=lambda; solve; { n, py, qty, h, qtdinvq, dinv, lam, t, pa, pd2a, term } if term=2 then exit; crs:=ey; if lam <> 0 then begin crs:=crs+e(pd2a^[1], h^[1], n); s:=0; for i:=1 to n-1 do s:=s+pd2a^[i]*qty^[i]; crs:=crs-2*s end; s:=0; for i:=1 to n+1 do s:=s+sqr(pa^[i]-py^[i])*diagb^[i]; cr:=crs-s end; {cr} procedure roof1r(a, b, ae, re: ArbFloat; var x: ArbFloat); var fa, fb, c, fc, m, tol, w1, w2 : ArbFloat; k : ArbInt; stop : boolean; begin fa:=cr(a); if term=2 then exit; fb:=cr(b); if term=2 then exit; if abs(fb)>abs(fa) then begin c:=b; fc:=fb; x:=a; b:=a; fb:=fa; a:=c; fa:=fc end else begin c:=a; fc:=fa; x:=b end; k:=0; tol:=ae+re*spemax(abs(a), abs(b)); w1:=abs(b-a); stop:=false; while (abs(b-a)>tol) and (fb<>0) and (not stop) do begin m:=(a+b)/2; if (k>=2) or (fb=fc) then x:=m else begin x:=(b*fc-c*fb)/(fc-fb); if abs(b-x)0 then begin a:=c; fa:=fc; k:=0 end else k:=k+1; if abs(fb)>=abs(fa) then begin c:=b; fc:=fb; x:=a; b:=a; fb:=fa; a:=c; fa:=fc; k:=0 end; tol:=ae+re*spemax(abs(a), abs(b)); w2:=abs(b-a); if w2>=w1 then stop:=true; w1:=w2 end end; {roof1r} procedure NoodGreep; var I, j: ArbInt; begin i:=1; while i <= n do begin if (pd^[i] <= 0) or (px^[i+1] <= px^[i]) then begin term:=3; exit end; i:=i+1 end; if pd^[n+1] <= 0 then begin term:=3; exit end; for i:=1 to n+1 do dinv^[i]:=1/pd^[i]; for i:=1 to n do h^[i]:=px^[i+1]-px^[i]; t^[2]:=(h^[1]+h^[2])/3; for i:=2 to n-1 do begin t^[2*i]:=(h^[i]+h^[i+1])/3; t^[2*i-1]:=h^[i]/6 end; move(t^[1], tl^[1], ns2); mdtgpb(n-1, 1, 2, tl^[1], ca, term); if term=2 then exit; z^[1]:=1/(h^[1]*tl^[2]); for j:=2 to n-1 do z^[j]:=-(tl^[2*j-1]*z^[j-1])/tl^[2*j]; s:=0; for j:=1 to n-1 do s:=s+sqr(z^[j]); diagb^[1]:=s; z^[1]:=(-1/h^[1]-1/h^[2])/tl^[2]; if n>2 then z^[2]:=(1/h^[2]-tl^[3]*z^[1])/tl^[4]; for j:=3 to n-1 do z^[j]:=-tl^[2*j-1]*z^[j-1]/tl^[2*j]; s:=0; for j:=1 to n-1 do s:=s+sqr(z^[j]); diagb^[2]:=s; for i:=2 to n-2 do begin z^[i-1]:=1/(h^[i]*tl^[2*(i-1)]); z^[i]:=(-1/h^[i]-1/h^[i+1]-tl^[2*i-1]*z^[i-1])/tl^[2*i]; z^[i+1]:=(1/h^[i+1]-tl^[2*i+1]*z^[i])/tl^[2*(i+1)]; for j:=i+2 to n-1 do z^[j]:=-tl^[2*j-1]*z^[j-1]/tl^[2*j]; s:=0; for j:=i-1 to n-1 do s:=s+sqr(z^[j]); diagb^[i+1]:=s end; z^[n-2]:=1/(h^[n-1]*tl^[2*(n-2)]); z^[n-1]:=(-1/h^[n-1]-1/h^[n]-tl^[2*n-3]*z^[n-2])/tl^[2*(n-1)]; s:=0; for j:=n-2 to n-1 do s:=s+sqr(z^[j]); diagb^[n]:=s; diagb^[n+1]:=1/sqr(h^[n]*tl^[2*(n-1)]); p:=1/h^[1]; for i:=2 to n do begin q:=1/h^[i]; qty^[i-1]:=py^[i+1]*q-py^[i]*(p+q)+py^[i-1]*p; p:=q end; p:=1/h^[1]; q:=1/h^[2]; r:=1/h^[3]; qtdinvq^[3]:=dinv^[1]*p*p+dinv^[2]*(p+q)*(p+q)+dinv^[3]*q*q; if n>2 then begin qtdinvq^[6]:=dinv^[2]*q*q+dinv^[3]*(q+r)*(q+r)+dinv^[4]*r*r; qtdinvq^[5]:=-(dinv^[2]*(p+q)+dinv^[3]*(q+r))*q; p:=q; q:=r; for i:=3 to n-1 do begin r:=1/h^[i+1]; qtdinvq^[3*i]:=dinv^[i]*q*q+dinv^[i+1]*(q+r)*(q+r)+dinv^[i+2]*r*r; qtdinvq^[3*i-1]:=-(dinv^[i]*(p+q)+dinv^[i+1]*(q+r))*q; qtdinvq^[3*i-2]:=dinv^[i]*p*q; p:=q; q:=r end end; dslgpb(n-1, 1, 2, tl^[1], qty^[1], c^[1], term); if term=2 then exit; ey:=e(c^[1], h^[1], n); lam0:=0; s:=cr(lam0); if term=2 then exit; if s >= 0 then begin lambda:=0; term:=4 end else begin lam1:=1e-8; ub:=false; while (not ub) and (lam1<=1.1e8) do begin s:=cr(lam1); if term=2 then exit; if s >= 0 then ub:=true else begin lam0:=lam1; lam1:=10*lam1 end end; if not ub then begin term:=4; lambda:=lam0 end else roof1r(lam0, lam1, 0, 1e-6, lambda); if term=2 then exit end; end; begin term:=1; if n < 2 then begin term:=3; exit end; sr:=sizeof(ArbFloat); n1s:=(n+1)*sr; ns2:=2*(n-1)*sr; ns1:=(n-1)*sr; getmem(dinv, n1s); getmem(h, n*sr); getmem(t, ns2); getmem(tl, ns2); getmem(z, ns1); getmem(diagb, n1s); getmem(qtdinvq, 3*ns1); getmem(c, ns1); getmem(qty, ns1); getmem(pd, n1s); { pd:=@d; } px:=@x; py:=@y; pa:=@a; pd2a:=@d2a; { de gewichten van de punten worden op 1 gezet} for i:=1 to n+1 do pd^[i]:=1; NoodGreep; freemem(dinv, n1s); freemem(h, n*sr); freemem(t, ns2); freemem(tl, ns2); freemem(z, ns1); freemem(diagb, n1s); freemem(qtdinvq, 3*ns1); freemem(c, ns1); freemem(qty, ns1); freemem(pd, n1s); end; {ipffsn} procedure ortpol(m, n: ArbInt; var x, alfa, beta: ArbFloat); // this function used to use mark/release. var i, j, ms : ArbInt; xppn1, ppn1, ppn, p, alfaj, betaj : ArbFloat; px, pal, pbe, pn, pn1 : ^arfloat1; begin px:=@x; pal:=@alfa; pbe:=@beta; ms:=m*sizeof(ArbFloat); getmem(pn, ms); getmem(pn1, ms); xppn1:=0; ppn1:=m; for i:=1 to m do begin pn^[i]:=0; pn1^[i]:=1; xppn1:=xppn1+px^[i] end; pal^[1]:=xppn1/ppn1; pbe^[1]:=0; for j:=2 to n do begin alfaj:=pal^[j-1]; betaj:=pbe^[j-1]; ppn:=ppn1; ppn1:=0; xppn1:=0; for i:=1 to m do begin p:=(px^[i]-alfaj)*pn1^[i]-betaj*pn^[i]; pn^[i]:=pn1^[i]; pn1^[i]:=p; p:=p*p; ppn1:=ppn1+p; xppn1:=xppn1+px^[i]*p end; {i} pal^[j]:=xppn1/ppn1; pbe^[j]:=ppn1/ppn end; {j} freemem(pn); freemem(pn1); end; {ortpol} procedure ortcoe(m, n: ArbInt; var x, y, alfa, beta, a: ArbFloat); // this function used to use mark/release. var i, j, mr : ArbInt; fpn, ppn, p, alphaj, betaj : ArbFloat; px, py, pal, pbe, pa, pn, pn1 : ^arfloat1; begin mr:=m*sizeof(ArbFloat); px:=@x; py:=@y; pal:=@alfa; pbe:=@beta; pa:=@a; getmem(pn, mr); getmem(pn1, mr); fpn:=0; for i:=1 to m do begin pn^[i]:=0; pn1^[i]:=1; fpn:=fpn+py^[i] end; {i} pa^[1]:=fpn/m; for j:=1 to n do begin fpn:=0; ppn:=0; alphaj:=pal^[j]; betaj:=pbe^[j]; for i:=1 to m do begin p:=(px^[i]-alphaj)*pn1^[i]-betaj*pn^[i]; pn^[i]:=pn1^[i]; pn1^[i]:=p; fpn:=fpn+py^[i]*p; ppn:=ppn+p*p end; {i} pa^[j+1]:=fpn/ppn end; {j} freemem(pn); freemem(pn1); end; {ortcoe} procedure polcoe(n:ArbInt; var alfa, beta, a, b: ArbFloat); var k, j : ArbInt; pal, pbe : ^arfloat1; pa, pb : ^arfloat0; begin pal:=@alfa; pbe:=@beta; pa:=@a; pb:=@b; move(pa^[0], pb^[0], (n+1)*sizeof(ArbFloat)); for j:=0 to n-1 do for k:=n-j-1 downto 0 do begin pb^[k+j]:=pb^[k+j]-pal^[k+1]*pb^[k+j+1]; if k+j<>n-1 then pb^[k+j]:=pb^[k+j]-pbe^[k+2]*pb^[k+j+2] end end; {polcoe} procedure ipfpol(m, n: ArbInt; var x, y, b: ArbFloat; var term: ArbInt); var i, ns: ArbInt; fsum: ArbFloat; px, py, alfa, beta: ^arfloat1; pb, a: ^arfloat0; begin if (n<0) or (m<1) then begin term:=3; exit end; term:=1; if n = 0 then begin py:=@y; pb:=@b; fsum:=0; for i:=1 to m do fsum:=fsum+py^[i]; pb^[0]:=fsum/m end else begin if n>m-1 then begin pb:=@b; fillchar(pb^[m], (n-m+1)*sizeof(ArbFloat), 0); n:=m-1 end; ns:=n*sizeof(ArbFloat); getmem(alfa, ns); getmem(beta, ns); getmem(a, (n+1)*sizeof(ArbFloat)); ortpol(m, n, x, alfa^[1], beta^[1]); ortcoe(m, n, x, y, alfa^[1], beta^[1], a^[0]); polcoe(n, alfa^[1], beta^[1], a^[0], b); freemem(alfa, ns); freemem(beta, ns); freemem(a, (n+1)*sizeof(ArbFloat)); end end; {ipfpol} procedure ipfisn(n: ArbInt; var x, y, d2s: ArbFloat; var term: ArbInt); var s, i : ArbInt; p, q, ca : ArbFloat; px, py, h, b, t : ^arfloat0; pd2s : ^arfloat1; begin px:=@x; py:=@y; pd2s:=@d2s; term:=1; if n < 2 then begin term:=3; exit end; {n<2} s:=sizeof(ArbFloat); getmem(h, n*s); getmem(b, (n-1)*s); getmem(t, 2*(n-1)*s); for i:=0 to n-1 do h^[i]:=px^[i+1]-px^[i]; q:=1/6; p:=2*q; t^[1]:=p*(h^[0]+h^[1]); for i:=2 to n-1 do begin t^[2*i-1]:=p*(h^[i-1]+h^[i]); t^[2*i-2]:=q*h^[i-1] end; {i} p:=1/h^[0]; for i:=2 to n do begin q:=1/h^[i-1]; b^[i-2]:=py^[i]*q-py^[i-1]*(p+q)+py^[i-2]*p; p:=q end; slegpb(n-1, 1, {2,} t^[1], b^[0], pd2s^[1], ca, term); freemem(h, n*s); freemem(b, (n-1)*s); freemem(t, 2*(n-1)*s); end; {ipfisn} function ipfspn(n: ArbInt; var x, y, d2s: ArbFloat; t:ArbFloat; var term: ArbInt): ArbFloat; var px, py : ^arfloat0; pd2s : ^arfloat1; i, j, m : ArbInt; d, s3, h, dy : ArbFloat; begin i:=1; term:=1; if n<2 then begin term:=3; exit end; {n<2} px:=@x; py:=@y; pd2s:=@d2s; if t <= px^[0] then begin h:=px^[1]-px^[0]; dy:=(py^[1]-py^[0])/h-h*pd2s^[1]/6; ipfspn:=py^[0]+(t-px^[0])*dy end { t <= x[0] } else if t >= px^[n] then begin h:=px^[n]-px^[n-1]; dy:=(py^[n]-py^[n-1])/h+h*pd2s^[n-1]/6; ipfspn:=py^[n]+(t-px^[n])*dy end { t >= x[n] } else begin i:=0; j:=n; while j <> i+1 do begin m:=(i+j) div 2; if t>=px^[m] then i:=m else j:=m end; {j} h:=px^[i+1]-px^[i]; d:=t-px^[i]; if i=0 then begin s3:=pd2s^[1]/h; dy:=(py^[1]-py^[0])/h-h*pd2s^[1]/6; ipfspn:=py^[0]+d*(dy+d*d*s3/6) end else if i=n-1 then begin s3:=-pd2s^[n-1]/h; dy:=(py^[n]-py^[n-1])/h-h*pd2s^[n-1]/3; ipfspn:=py^[n-1]+d*(dy+d*(pd2s^[n-1]/2+d*s3/6)) end else begin s3:=(pd2s^[i+1]-pd2s^[i])/h; dy:=(py^[i+1]-py^[i])/h-h*(2*pd2s^[i]+pd2s^[i+1])/6; ipfspn:=py^[i]+d*(dy+d*(pd2s^[i]/2+d*s3/6)) end end { x[0] < t < x[n] } end; {ipfspn} procedure ipfsmm( n: ArbInt; var x, y, d2s, minv, maxv: ArbFloat; var term: ArbInt); var i: ArbInt; h: ArbFloat; px, py: ^arfloat0; pd2s: ^arfloat1; procedure UpdateMinMax(v: ArbFloat); begin if (0 >= v) or (v >= h) then exit; v := ipfspn(n, x, y, d2s, px^[i]+v, term); if v < minv then minv := v; if v > maxv then maxv := v; end; procedure MinMaxOnSegment; var a, b, c: ArbFloat; d: ArbFloat; begin h:=px^[i+1]-px^[i]; if i=0 then begin a:=pd2s^[1]/h/2; b:=0; c:=(py^[1]-py^[0])/h-h*pd2s^[1]/6; end else if i=n-1 then begin a:=-pd2s^[n-1]/h/2; b:=pd2s^[n-1]; c:=(py^[n]-py^[n-1])/h-h*pd2s^[n-1]/3; end else begin a:=(pd2s^[i+1]-pd2s^[i])/h/2; b:=pd2s^[i]; c:=(py^[i+1]-py^[i])/h-h*(2*pd2s^[i]+pd2s^[i+1])/6; end; if a=0 then exit; d := b*b-4*a*c; if d<0 then exit; d:=Sqrt(d); UpdateMinMax((-b+d)/(2*a)); UpdateMinMax((-b-d)/(2*a)); end; begin term:=1; if n<2 then begin term:=3; exit; end; px:=@x; py:=@y; pd2s:=@d2s; for i:=0 to n-1 do MinMaxOnSegment; end; function p(x, a, z:complex): ArbFloat; begin x.sub(a); p:=x.Inp(z) end; function e(x, y: complex): ArbFloat; const c1: ArbFloat = 0.01989436788646; var s: ArbFloat; begin x.sub(y); s := x.norm; if s=0 then e:=0 else e:=c1*s*ln(s) end; function spline( n : ArbInt; x : complex; var ac : complex; var gammar: ArbFloat; u1 : ArbFloat; pf : complex): ArbFloat; var i : ArbInt; s : ArbFloat; a : arcomp0 absolute ac; gamma : arfloat0 absolute gammar; begin s := u1 + p(x, a[n-2], pf); for i:=0 to n do s := s + gamma[i]*e(x,a[i]); spline := s end; procedure splineparameters ( n : ArbInt; var ac, alfadc : complex; var lambda, gammar, u1, kwsom, energie : ArbFloat; var pf : complex); procedure SwapC(var v, w: complex); var x: complex; begin x := v; v := w; w := x end; procedure pxpy(a, b, c: complex; var p:complex); var det: ArbFloat; begin b.sub(a); c.sub(a); det := b.xreal*c.imag-b.imag*c.xreal; b.sub(c); p.Init(b.imag/det, -b.xreal/det) end; procedure pfxpfy(a, b, c: complex; f: vector; var pf: complex); begin b.sub(a); c.sub(a); f.j := f.j-f.i; f.k := f.k-f.i; pf.init(f.j*c.imag - f.k*b.imag, -f.j*c.xreal + f.k*b.xreal); pf.scale(1/(b.xreal*c.imag - b.imag*c.xreal)) end; function InpV(n: ArbInt; var v1, v2: ArbFloat): ArbFloat; var i: ArbInt; a1: arfloat0 absolute v1; a2: arfloat0 absolute v2; s : ArbFloat; begin s := 0; for i:=0 to n-1 do s := s + a1[i]*a2[i]; InpV := s end; PROCEDURE SPDSOL( N : INTEGER; VAR AP : pointer; VAR B : ArbFloat); VAR I, J, K : INTEGER; H : ArbFloat; a : ^ar2dr absolute ap; bx : arfloat0 absolute b; BEGIN for k:=0 to n do BEGIN h := sqrt(a^[k]^[k]-InpV(k, a^[k]^[0], a^[k]^[0])); a^[k]^[k] := h; FOR I:=K+1 TO N do a^[i]^[k] := (a^[i]^[k] - InpV(k, a^[k]^[0], a^[i]^[0]))/h; BX[K] := (bx[k] - InpV(k, a^[k]^[0], bx[0]))/h END; FOR I:=N DOWNTO 0 do BEGIN H := BX[I]; FOR J:=I+1 TO N DO H := H - A^[J]^[I]*BX[J]; BX[I] := H/A^[I]^[I] END END; var i, j, i1 : ArbInt; x, h, absdet, absdetmax, s, s1, ca: ArbFloat; alfa, dv, hulp, u, v, w : vector; e22 : array[0..2] of vector; e21, b : ^arvect0; k, c : ^ar2dr; gamma : arfloat0 absolute gammar; an2, an1, an, z, vz, wz : complex; a : arcomp0 absolute ac; alfad : arcomp0 absolute alfadc; begin i1:=0; x:=a[0].xreal; for i:=1 to n do begin h:=a[i].xreal; if hx then begin i1:=i; x:=h end end; SwapC(a[n-1], a[i1]); SwapC(alfad[n-1], alfad[i1]); vz := a[n-2]; vz.sub(a[n-1]); absdetmax := -1; for i:=0 to n do begin wz := a[i]; wz.sub(a[n-2]); absdet := abs(wz.imag*vz.xreal-wz.xreal*vz.imag); if absdet>absdetmax then begin i1:=i; absdetmax:=absdet end end; SwapC(a[n], a[i1]); SwapC(alfad[n], alfad[i1]); an2 := a[n-2]; an1 := a[n-1]; an := a[n]; alfa.i := alfad[n-2].xreal; dv.i := alfad[n-2].imag; alfa.j := alfad[n-1].xreal; dv.j := alfad[n-1].imag; alfa.k := alfad[n ].xreal; dv.k := alfad[n ].imag; n := n - 3; GetMem(k, (n+1)*SizeOf(pointer)); for j:=0 to n do GetMem(k^[j], (j+1)*SizeOf(ArbFloat)); GetMem(e21, (n+1)*SizeOf(vector)); GetMem(b, (n+1)*SizeOf(vector)); pxpy(an2,an1,an,z); for i:=0 to n do b^[i].i:=1+p(a[i],an2,z); pxpy(an1,an,an2,z); for i:=0 to n do b^[i].j:=1+p(a[i],an1,z); pxpy(an,an2,an1,z); for i:=0 to n do b^[i].k:=1+p(a[i],an,z); e22[0].init(0,e(an1,an2),e(an,an2)); e22[1].init(e(an1,an2),0,e(an,an1)); e22[2].init(e(an,an2),e(an,an1),0); for j:=0 to n do e21^[j].init(e(an2,a[j]),e(an1,a[j]),e(an,a[j])); GetMem(c, (n+1)*SizeOf(pointer)); for j:=0 to n do GetMem(c^[j], (j+1)*SizeOf(ArbFloat)); for i:=0 to n do for j:=0 to i do begin if j=i then s:=0 else s:=e(a[i],a[j]); hulp.init(b^[j].Inprod(e22[0]), b^[j].Inprod(e22[1]), b^[j].Inprod(e22[2])); hulp.sub(e21^[j]); k^[i]^[j] := s+b^[i].InProd(hulp)-b^[j].Inprod(e21^[i]); if j=i then s:=1/alfad[i].imag else s:=0; hulp.init(b^[j].i/dv.i, b^[j].j/dv.j, b^[j].k/dv.k); c^[i]^[j] := k^[i]^[j] + (s + b^[i].Inprod(hulp))/lambda end; for i:=0 to n do gamma[i]:=alfad[i].xreal - b^[i].Inprod(alfa); SpdSol(n, pointer(c), gamma[0]); for j:=n downto 0 do FreeMem(c^[j], (j+1)*SizeOf(ArbFloat)); FreeMem(c, (n+1)*SizeOf(pointer)); s:=0; for j:=0 to n do s:=s+b^[j].i*gamma[j]; w.i:=s; gamma[n+1] := -s; s:=0; for j:=0 to n do s:=s+b^[j].j*gamma[j]; w.j:=s; gamma[n+2] := -s; s:=0; for j:=0 to n do s:=s+b^[j].k*gamma[j]; w.k:=s; gamma[n+3] := -s; FreeMem(b, (n+1)*SizeOf(vector)); u.init(w.i/dv.i, w.j/dv.j, w.k/dv.k); u.scale(1/lambda); u.add(alfa); s:=0; for j:=0 to n do s:=s+e21^[j].i*gamma[j]; v.i := e22[0].inprod(w)-s; s:=0; for j:=0 to n do s:=s+e21^[j].j*gamma[j]; v.j := e22[1].inprod(w)-s; s:=0; for j:=0 to n do s:=s+e21^[j].k*gamma[j]; v.k := e22[2].inprod(w)-s; FreeMem(e21, (n+1)*SizeOf(vector)); u.add(v); pfxpfy(an2, an1, an, u, pf); u1:=u.i; kwsom := 0; for j:=0 to n do kwsom:=kwsom+sqr(gamma[j])/alfad[j].imag; kwsom := kwsom+sqr(w.i)/dv.i+sqr(w.j)/dv.j+sqr(w.k)/dv.k; kwsom := kwsom/sqr(lambda); s:=0; for i:=0 to n do begin s1:=0; for j:=0 to i do s1:=s1+k^[i]^[j]*gamma[j]; for j:=i+1 to n do s1:=s1+k^[j]^[i]*gamma[j]; s := gamma[i]*s1+s end; for j:=n downto 0 do FreeMem(k^[j], (j+1)*SizeOf(ArbFloat)); FreeMem(k, (n+1)*SizeOf(pointer)); energie := s end {splineparameters}; end.