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fvn_integ/dqk61_2d_outer.f90
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! fvn comment : ! Modified version of the dqk61 quadpack routine from http://www.netlib.org/quadpack ! ! + The external 'f' function is a 2 parameters function f(x,y). The routine ! takes two more parameters 'g' and 'h' which are two external functions : ! g represent the lower bound of the integral for y parameter ! h represent the higher bound of the integral for y parameter ! The routine compute the double integral of function f with x between a and b ! and y between g(x) and h(x) subroutine dqk61_2d_outer(f,a,b,g,h,result,abserr,resabs, & resasc,epsabs,epsrel,key,limit) !***begin prologue dqk61 !***date written 800101 (yymmdd) !***revision date 830518 (yymmdd) !***category no. h2a1a2 !***keywords 61-point gauss-kronrod rules !***author piessens,robert,appl. math. & progr. div. - k.u.leuven ! de doncker,elise,appl. math. & progr. div. - k.u.leuven !***purpose to compute i = integral of f over (a,b) with error ! estimate ! j = integral of dabs(f) over (a,b) !***description ! ! integration rule ! standard fortran subroutine ! double precision version ! ! ! parameters ! on entry ! f - double precision ! function subprogram defining the integrand ! function f(x). the actual name for f needs to be ! declared e x t e r n a l in the calling program. ! ! a - double precision ! lower limit of integration ! ! b - double precision ! upper limit of integration ! ! on return ! result - double precision ! approximation to the integral i ! result is computed by applying the 61-point ! kronrod rule (resk) obtained by optimal addition of ! abscissae to the 30-point gauss rule (resg). ! ! abserr - double precision ! estimate of the modulus of the absolute error, ! which should equal or exceed dabs(i-result) ! ! resabs - double precision ! approximation to the integral j ! ! resasc - double precision ! approximation to the integral of dabs(f-i/(b-a)) ! ! !***references (none) !***routines called d1mach !***end prologue dqk61 ! double precision a,dabsc,abserr,b,centr,dabs,dhlgth,dmax1,dmin1, & epmach,fc,fsum,fval1,fval2,fv1,fv2,hlgth,resabs,resasc, & resg,resk,reskh,result,uflow,wg,wgk,xgk integer j,jtw,jtwm1 double precision,external :: f,g,h double precision :: eval_res double precision :: epsabs,epsrel,eval_abserr integer :: limit,key,eval_ier ! dimension fv1(30),fv2(30),xgk(31),wgk(31),wg(15) ! ! the abscissae and weights are given for the ! interval (-1,1). because of symmetry only the positive ! abscissae and their corresponding weights are given. ! ! xgk - abscissae of the 61-point kronrod rule ! xgk(2), xgk(4) ... abscissae of the 30-point ! gauss rule ! xgk(1), xgk(3) ... optimally added abscissae ! to the 30-point gauss rule ! ! wgk - weights of the 61-point kronrod rule ! ! wg - weigths of the 30-point gauss rule ! ! ! gauss quadrature weights and kronron quadrature abscissae and weights ! as evaluated with 80 decimal digit arithmetic by l. w. fullerton, ! bell labs, nov. 1981. ! data wg ( 1) / 0.007968192496166605615465883474674d0 / data wg ( 2) / 0.018466468311090959142302131912047d0 / data wg ( 3) / 0.028784707883323369349719179611292d0 / data wg ( 4) / 0.038799192569627049596801936446348d0 / data wg ( 5) / 0.048402672830594052902938140422808d0 / data wg ( 6) / 0.057493156217619066481721689402056d0 / data wg ( 7) / 0.065974229882180495128128515115962d0 / data wg ( 8) / 0.073755974737705206268243850022191d0 / data wg ( 9) / 0.080755895229420215354694938460530d0 / data wg ( 10) / 0.086899787201082979802387530715126d0 / data wg ( 11) / 0.092122522237786128717632707087619d0 / data wg ( 12) / 0.096368737174644259639468626351810d0 / data wg ( 13) / 0.099593420586795267062780282103569d0 / data wg ( 14) / 0.101762389748405504596428952168554d0 / data wg ( 15) / 0.102852652893558840341285636705415d0 / ! data xgk ( 1) / 0.999484410050490637571325895705811d0 / data xgk ( 2) / 0.996893484074649540271630050918695d0 / data xgk ( 3) / 0.991630996870404594858628366109486d0 / data xgk ( 4) / 0.983668123279747209970032581605663d0 / data xgk ( 5) / 0.973116322501126268374693868423707d0 / data xgk ( 6) / 0.960021864968307512216871025581798d0 / data xgk ( 7) / 0.944374444748559979415831324037439d0 / data xgk ( 8) / 0.926200047429274325879324277080474d0 / data xgk ( 9) / 0.905573307699907798546522558925958d0 / data xgk ( 10) / 0.882560535792052681543116462530226d0 / data xgk ( 11) / 0.857205233546061098958658510658944d0 / data xgk ( 12) / 0.829565762382768397442898119732502d0 / data xgk ( 13) / 0.799727835821839083013668942322683d0 / data xgk ( 14) / 0.767777432104826194917977340974503d0 / data xgk ( 15) / 0.733790062453226804726171131369528d0 / data xgk ( 16) / 0.697850494793315796932292388026640d0 / data xgk ( 17) / 0.660061064126626961370053668149271d0 / data xgk ( 18) / 0.620526182989242861140477556431189d0 / data xgk ( 19) / 0.579345235826361691756024932172540d0 / data xgk ( 20) / 0.536624148142019899264169793311073d0 / data xgk ( 21) / 0.492480467861778574993693061207709d0 / data xgk ( 22) / 0.447033769538089176780609900322854d0 / data xgk ( 23) / 0.400401254830394392535476211542661d0 / data xgk ( 24) / 0.352704725530878113471037207089374d0 / data xgk ( 25) / 0.304073202273625077372677107199257d0 / data xgk ( 26) / 0.254636926167889846439805129817805d0 / data xgk ( 27) / 0.204525116682309891438957671002025d0 / data xgk ( 28) / 0.153869913608583546963794672743256d0 / data xgk ( 29) / 0.102806937966737030147096751318001d0 / data xgk ( 30) / 0.051471842555317695833025213166723d0 / data xgk ( 31) / 0.000000000000000000000000000000000d0 / ! data wgk ( 1) / 0.001389013698677007624551591226760d0 / data wgk ( 2) / 0.003890461127099884051267201844516d0 / data wgk ( 3) / 0.006630703915931292173319826369750d0 / data wgk ( 4) / 0.009273279659517763428441146892024d0 / data wgk ( 5) / 0.011823015253496341742232898853251d0 / data wgk ( 6) / 0.014369729507045804812451432443580d0 / data wgk ( 7) / 0.016920889189053272627572289420322d0 / data wgk ( 8) / 0.019414141193942381173408951050128d0 / data wgk ( 9) / 0.021828035821609192297167485738339d0 / data wgk ( 10) / 0.024191162078080601365686370725232d0 / data wgk ( 11) / 0.026509954882333101610601709335075d0 / data wgk ( 12) / 0.028754048765041292843978785354334d0 / data wgk ( 13) / 0.030907257562387762472884252943092d0 / data wgk ( 14) / 0.032981447057483726031814191016854d0 / data wgk ( 15) / 0.034979338028060024137499670731468d0 / data wgk ( 16) / 0.036882364651821229223911065617136d0 / data wgk ( 17) / 0.038678945624727592950348651532281d0 / data wgk ( 18) / 0.040374538951535959111995279752468d0 / data wgk ( 19) / 0.041969810215164246147147541285970d0 / data wgk ( 20) / 0.043452539701356069316831728117073d0 / data wgk ( 21) / 0.044814800133162663192355551616723d0 / data wgk ( 22) / 0.046059238271006988116271735559374d0 / data wgk ( 23) / 0.047185546569299153945261478181099d0 / data wgk ( 24) / 0.048185861757087129140779492298305d0 / data wgk ( 25) / 0.049055434555029778887528165367238d0 / data wgk ( 26) / 0.049795683427074206357811569379942d0 / data wgk ( 27) / 0.050405921402782346840893085653585d0 / data wgk ( 28) / 0.050881795898749606492297473049805d0 / data wgk ( 29) / 0.051221547849258772170656282604944d0 / data wgk ( 30) / 0.051426128537459025933862879215781d0 / data wgk ( 31) / 0.051494729429451567558340433647099d0 / ! ! list of major variables ! ----------------------- ! ! centr - mid point of the interval ! hlgth - half-length of the interval ! dabsc - abscissa ! fval* - function value ! resg - result of the 30-point gauss rule ! resk - result of the 61-point kronrod rule ! reskh - approximation to the mean value of f ! over (a,b), i.e. to i/(b-a) ! ! machine dependent constants ! --------------------------- ! ! epmach is the largest relative spacing. ! uflow is the smallest positive magnitude. ! epmach = d1mach(4) uflow = d1mach(1) ! centr = 0.5d+00*(b+a) hlgth = 0.5d+00*(b-a) dhlgth = dabs(hlgth) ! ! compute the 61-point kronrod approximation to the ! integral, and estimate the absolute error. ! !***first executable statement dqk61 resg = 0.0d+00 !fc = f(centr) call fvn_d_integ_2_inner_gk(f,centr,g(centr), & h(centr),epsabs,epsrel,key,eval_res,eval_abserr, & eval_ier,limit) fc=eval_res resk = wgk(31)*fc resabs = dabs(resk) do 10 j=1,15 jtw = j*2 dabsc = hlgth*xgk(jtw) !fval1 = f(centr-dabsc) call fvn_d_integ_2_inner_gk(f,centr-dabsc,g(centr-dabsc), & h(centr-dabsc),epsabs,epsrel,key,eval_res,eval_abserr, & eval_ier,limit) fval1=eval_res !fval2 = f(centr+dabsc) call fvn_d_integ_2_inner_gk(f,centr+dabsc,g(centr+dabsc), & h(centr+dabsc),epsabs,epsrel,key,eval_res,eval_abserr, & eval_ier,limit) fval2=eval_res fv1(jtw) = fval1 fv2(jtw) = fval2 fsum = fval1+fval2 resg = resg+wg(j)*fsum resk = resk+wgk(jtw)*fsum resabs = resabs+wgk(jtw)*(dabs(fval1)+dabs(fval2)) 10 continue do 15 j=1,15 jtwm1 = j*2-1 dabsc = hlgth*xgk(jtwm1) !fval1 = f(centr-dabsc) call fvn_d_integ_2_inner_gk(f,centr-dabsc,g(centr-dabsc), & h(centr-dabsc),epsabs,epsrel,key,eval_res,eval_abserr, & eval_ier,limit) fval1=eval_res !fval2 = f(centr+dabsc) call fvn_d_integ_2_inner_gk(f,centr+dabsc,g(centr+dabsc), & h(centr+dabsc),epsabs,epsrel,key,eval_res,eval_abserr, & eval_ier,limit) fval2=eval_res fv1(jtwm1) = fval1 fv2(jtwm1) = fval2 fsum = fval1+fval2 resk = resk+wgk(jtwm1)*fsum resabs = resabs+wgk(jtwm1)*(dabs(fval1)+dabs(fval2)) 15 continue reskh = resk*0.5d+00 resasc = wgk(31)*dabs(fc-reskh) do 20 j=1,30 resasc = resasc+wgk(j)*(dabs(fv1(j)-reskh)+dabs(fv2(j)-reskh)) 20 continue result = resk*hlgth resabs = resabs*dhlgth resasc = resasc*dhlgth abserr = dabs((resk-resg)*hlgth) if(resasc.ne.0.0d+00.and.abserr.ne.0.0d+00) & abserr = resasc*dmin1(0.1d+01,(0.2d+03*abserr/resasc)**1.5d+00) if(resabs.gt.uflow/(0.5d+02*epmach)) abserr = dmax1 & ((epmach*0.5d+02)*resabs,abserr) return end subroutine |