JSOC/proj/sharp/apps/sw_functions.c - diff

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Diff for /JSOC/proj/sharp/apps/sw_functions.c between version 1.31 and 1.34

version 1.31, 2014/06/05 21:27:04

version 1.34, 2015/02/27 19:49:43

Line 246 int computeB_total(float *bx_err, float

/*===========================================*/

/* Example function 5: Derivative of B_Total SQRT( (dBt/dx)^2 + (dBt/dy)^2 ) */

int computeBtotalderivative(float *bt, int *dims, float *mean_derivative_btotal_ptr, int *mask, int *bitmask, float *derx_bt, float *dery_bt, float *bt_err, float *mean_derivative_btotal_err_ptr)

int computeBtotalderivative(float *bt, int *dims, float *mean_derivative_btotal_ptr, int *mask, int *bitmask, float *derx_bt, float *dery_bt, float *bt_err, float *mean_derivative_btotal_err_ptr, float *err_termAt, float *err_termBt)

{

int nx = dims[0];

Line 266 int computeBtotalderivative(float *bt, i

for (j = 0; j <= ny-1; j++)

{

derx_bt[j * nx + i] = (bt[j * nx + i+1] - bt[j * nx + i-1])*0.5;

err_termAt[j * nx + i] = (((bt[j * nx + (i+1)]-bt[j * nx + (i-1)])*(bt[j * nx + (i+1)]-bt[j * nx + (i-1)])) * (bt_err[j * nx + (i+1)]*bt_err[j * nx + (i+1)] + bt_err[j * nx + (i-1)]*bt_err[j * nx + (i-1)])) ;

}

Line 275 int computeBtotalderivative(float *bt, i

Line 276 int computeBtotalderivative(float *bt, i

for (j = 1; j <= ny-2; j++)

{

dery_bt[j * nx + i] = (bt[(j+1) * nx + i] - bt[(j-1) * nx + i])*0.5;

err_termBt[j * nx + i] = (((bt[(j+1) * nx + i]-bt[(j-1) * nx + i])*(bt[(j+1) * nx + i]-bt[(j-1) * nx + i])) * (bt_err[(j+1) * nx + i]*bt_err[(j+1) * nx + i] + bt_err[(j-1) * nx + i]*bt_err[(j-1) * nx + i])) ;

}

Line 304 int computeBtotalderivative(float *bt, i

Line 306 int computeBtotalderivative(float *bt, i

dery_bt[j * nx + i] = ( (3*bt[j * nx + i]) + (-4*bt[(j-1) * nx + i]) - (-bt[(j-2) * nx + i]) )*0.5;

}

// Calculate the sum only

for (i = 1; i <= nx-2; i++)

{

for (j = 1; j <= ny-2; j++)

Line 320 int computeBtotalderivative(float *bt, i

Line 322 int computeBtotalderivative(float *bt, i

if isnan(derx_bt[j * nx + i]) continue;

if isnan(dery_bt[j * nx + i]) continue;

sum += sqrt( derx_bt[j * nx + i]*derx_bt[j * nx + i] + dery_bt[j * nx + i]*dery_bt[j * nx + i] ); /* Units of Gauss */

err += (((bt[(j+1) * nx + i]-bt[(j-1) * nx + i])*(bt[(j+1) * nx + i]-bt[(j-1) * nx + i])) * (bt_err[(j+1) * nx + i]*bt_err[(j+1) * nx + i] + bt_err[(j-1) * nx + i]*bt_err[(j-1) * nx + i])) / (16.0*( derx_bt[j * nx + i]*derx_bt[j * nx + i] + dery_bt[j * nx + i]*dery_bt[j * nx + i] ))+

err += err_termBt[j * nx + i] / (16.0*( derx_bt[j * nx + i]*derx_bt[j * nx + i] + dery_bt[j * nx + i]*dery_bt[j * nx + i] ))+

(((bt[j * nx + (i+1)]-bt[j * nx + (i-1)])*(bt[j * nx + (i+1)]-bt[j * nx + (i-1)])) * (bt_err[j * nx + (i+1)]*bt_err[j * nx + (i+1)] + bt_err[j * nx + (i-1)]*bt_err[j * nx + (i-1)])) / (16.0*( derx_bt[j * nx + i]*derx_bt[j * nx + i] + dery_bt[j * nx + i]*dery_bt[j * nx + i] )) ;

err_termAt[j * nx + i] / (16.0*( derx_bt[j * nx + i]*derx_bt[j * nx + i] + dery_bt[j * nx + i]*dery_bt[j * nx + i] )) ;

count_mask++;

}

Line 338 int computeBtotalderivative(float *bt, i

Line 340 int computeBtotalderivative(float *bt, i

/*===========================================*/

/* Example function 6: Derivative of Bh SQRT( (dBh/dx)^2 + (dBh/dy)^2 ) */

int computeBhderivative(float *bh, float *bh_err, int *dims, float *mean_derivative_bh_ptr, float *mean_derivative_bh_err_ptr, int *mask, int *bitmask, float *derx_bh, float *dery_bh)

int computeBhderivative(float *bh, float *bh_err, int *dims, float *mean_derivative_bh_ptr, float *mean_derivative_bh_err_ptr, int *mask, int *bitmask, float *derx_bh, float *dery_bh, float *err_termAh, float *err_termBh)

{

int nx = dims[0];

Line 358 int computeBhderivative(float *bh, float

Line 360 int computeBhderivative(float *bh, float

for (j = 0; j <= ny-1; j++)

{

derx_bh[j * nx + i] = (bh[j * nx + i+1] - bh[j * nx + i-1])*0.5;

err_termAh[j * nx + i] = (((bh[j * nx + (i+1)]-bh[j * nx + (i-1)])*(bh[j * nx + (i+1)]-bh[j * nx + (i-1)])) * (bh_err[j * nx + (i+1)]*bh_err[j * nx + (i+1)] + bh_err[j * nx + (i-1)]*bh_err[j * nx + (i-1)]));

}

Line 367 int computeBhderivative(float *bh, float

Line 370 int computeBhderivative(float *bh, float

for (j = 1; j <= ny-2; j++)

{

dery_bh[j * nx + i] = (bh[(j+1) * nx + i] - bh[(j-1) * nx + i])*0.5;

err_termBh[j * nx + i] = (((bh[ (j+1) * nx + i]-bh[(j-1) * nx + i])*(bh[(j+1) * nx + i]-bh[(j-1) * nx + i])) * (bh_err[(j+1) * nx + i]*bh_err[(j+1) * nx + i] + bh_err[(j-1) * nx + i]*bh_err[(j-1) * nx + i]));

}

Line 412 int computeBhderivative(float *bh, float

Line 416 int computeBhderivative(float *bh, float

if isnan(derx_bh[j * nx + i]) continue;

if isnan(dery_bh[j * nx + i]) continue;

sum += sqrt( derx_bh[j * nx + i]*derx_bh[j * nx + i] + dery_bh[j * nx + i]*dery_bh[j * nx + i] ); /* Units of Gauss */

err += (((bh[(j+1) * nx + i]-bh[(j-1) * nx + i])*(bh[(j+1) * nx + i]-bh[(j-1) * nx + i])) * (bh_err[(j+1) * nx + i]*bh_err[(j+1) * nx + i] + bh_err[(j-1) * nx + i]*bh_err[(j-1) * nx + i])) / (16.0*( derx_bh[j * nx + i]*derx_bh[j * nx + i] + dery_bh[j * nx + i]*dery_bh[j * nx + i] ))+

err += err_termBh[j * nx + i] / (16.0*( derx_bh[j * nx + i]*derx_bh[j * nx + i] + dery_bh[j * nx + i]*dery_bh[j * nx + i] ))+

(((bh[j * nx + (i+1)]-bh[j * nx + (i-1)])*(bh[j * nx + (i+1)]-bh[j * nx + (i-1)])) * (bh_err[j * nx + (i+1)]*bh_err[j * nx + (i+1)] + bh_err[j * nx + (i-1)]*bh_err[j * nx + (i-1)])) / (16.0*( derx_bh[j * nx + i]*derx_bh[j * nx + i] + dery_bh[j * nx + i]*dery_bh[j * nx + i] )) ;

err_termAh[j * nx + i] / (16.0*( derx_bh[j * nx + i]*derx_bh[j * nx + i] + dery_bh[j * nx + i]*dery_bh[j * nx + i] )) ;

count_mask++;

}

Line 429 int computeBhderivative(float *bh, float

Line 433 int computeBhderivative(float *bh, float

/*===========================================*/

/* Example function 7: Derivative of B_vertical SQRT( (dBz/dx)^2 + (dBz/dy)^2 ) */

int computeBzderivative(float *bz, float *bz_err, int *dims, float *mean_derivative_bz_ptr, float *mean_derivative_bz_err_ptr, int *mask, int *bitmask, float *derx_bz, float *dery_bz)

int computeBzderivative(float *bz, float *bz_err, int *dims, float *mean_derivative_bz_ptr, float *mean_derivative_bz_err_ptr, int *mask, int *bitmask, float *derx_bz, float *dery_bz, float *err_termA, float *err_termB)

{

int nx = dims[0];

Line 448 int computeBzderivative(float *bz, float

Line 452 int computeBzderivative(float *bz, float

{

for (j = 0; j <= ny-1; j++)

{

if isnan(bz[j * nx + i]) continue;

derx_bz[j * nx + i] = (bz[j * nx + i+1] - bz[j * nx + i-1])*0.5;

err_termA[j * nx + i] = (((bz[j * nx + (i+1)]-bz[j * nx + (i-1)])*(bz[j * nx + (i+1)]-bz[j * nx + (i-1)])) * (bz_err[j * nx + (i+1)]*bz_err[j * nx + (i+1)] + bz_err[j * nx + (i-1)]*bz_err[j * nx + (i-1)]));

}

Line 458 int computeBzderivative(float *bz, float

Line 462 int computeBzderivative(float *bz, float

{

for (j = 1; j <= ny-2; j++)

{

if isnan(bz[j * nx + i]) continue;

dery_bz[j * nx + i] = (bz[(j+1) * nx + i] - bz[(j-1) * nx + i])*0.5;

err_termB[j * nx + i] = (((bz[(j+1) * nx + i]-bz[(j-1) * nx + i])*(bz[(j+1) * nx + i]-bz[(j-1) * nx + i])) * (bz_err[(j+1) * nx + i]*bz_err[(j+1) * nx + i] + bz_err[(j-1) * nx + i]*bz_err[(j-1) * nx + i]));

}

/* consider the edges for the arrays that contribute to the variable "sum" in the computation below.

/* consider the edges */

ignore the edges for err_termA and err_term B as those arrays have been initialized to zero.

this is okay because the error term will ultimately not include the edge pixels as they are selected out by the mask and bitmask arrays.*/

i=0;

for (j = 0; j <= ny-1; j++)

{

if isnan(bz[j * nx + i]) continue;

derx_bz[j * nx + i] = ( (-3*bz[j * nx + i]) + (4*bz[j * nx + (i+1)]) - (bz[j * nx + (i+2)]) )*0.5;

}

i=nx-1;

for (j = 0; j <= ny-1; j++)

{

if isnan(bz[j * nx + i]) continue;

derx_bz[j * nx + i] = ( (3*bz[j * nx + i]) + (-4*bz[j * nx + (i-1)]) - (-bz[j * nx + (i-2)]) )*0.5;

}

j=0;

for (i = 0; i <= nx-1; i++)

{

if isnan(bz[j * nx + i]) continue;

dery_bz[j * nx + i] = ( (-3*bz[j*nx + i]) + (4*bz[(j+1) * nx + i]) - (bz[(j+2) * nx + i]) )*0.5;

}

j=ny-1;

for (i = 0; i <= nx-1; i++)

{

if isnan(bz[j * nx + i]) continue;

dery_bz[j * nx + i] = ( (3*bz[j * nx + i]) + (-4*bz[(j-1) * nx + i]) - (-bz[(j-2) * nx + i]) )*0.5;

}

Line 509 int computeBzderivative(float *bz, float

Line 510 int computeBzderivative(float *bz, float

if isnan(derx_bz[j * nx + i]) continue;

if isnan(dery_bz[j * nx + i]) continue;

sum += sqrt( derx_bz[j * nx + i]*derx_bz[j * nx + i] + dery_bz[j * nx + i]*dery_bz[j * nx + i] ); /* Units of Gauss */

err += (((bz[(j+1) * nx + i]-bz[(j-1) * nx + i])*(bz[(j+1) * nx + i]-bz[(j-1) * nx + i])) * (bz_err[(j+1) * nx + i]*bz_err[(j+1) * nx + i] + bz_err[(j-1) * nx + i]*bz_err[(j-1) * nx + i])) /

err += err_termB[j * nx + i] / (16.0*( derx_bz[j * nx + i]*derx_bz[j * nx + i] + dery_bz[j * nx + i]*dery_bz[j * nx + i] )) +

(16.0*( derx_bz[j * nx + i]*derx_bz[j * nx + i] + dery_bz[j * nx + i]*dery_bz[j * nx + i] )) +

err_termA[j * nx + i] / (16.0*( derx_bz[j * nx + i]*derx_bz[j * nx + i] + dery_bz[j * nx + i]*dery_bz[j * nx + i] )) ;

(((bz[j * nx + (i+1)]-bz[j * nx + (i-1)])*(bz[j * nx + (i+1)]-bz[j * nx + (i-1)])) * (bz_err[j * nx + (i+1)]*bz_err[j * nx + (i+1)] + bz_err[j * nx + (i-1)]*bz_err[j * nx + (i-1)])) /

(16.0*( derx_bz[j * nx + i]*derx_bz[j * nx + i] + dery_bz[j * nx + i]*dery_bz[j * nx + i] )) ;

count_mask++;

}

Line 563 int computeBzderivative(float *bz, float

Line 562 int computeBzderivative(float *bz, float

// float *noiseby, float *noisebz)

int computeJz(float *bx_err, float *by_err, float *bx, float *by, int *dims, float *jz, float *jz_err, float *jz_err_squared,

int *mask, int *bitmask, float cdelt1, double rsun_ref, double rsun_obs,float *derx, float *dery)

int *mask, int *bitmask, float cdelt1, double rsun_ref, double rsun_obs,float *derx, float *dery, float *err_term1, float *err_term2)

{

Line 582 int computeJz(float *bx_err, float *by_e

Line 581 int computeJz(float *bx_err, float *by_e

{

for (j = 0; j <= ny-1; j++)

{

if isnan(by[j * nx + i]) continue;

derx[j * nx + i] = (by[j * nx + i+1] - by[j * nx + i-1])*0.5;

err_term1[j * nx + i] = (by_err[j * nx + i+1])*(by_err[j * nx + i+1]) + (by_err[j * nx + i-1])*(by_err[j * nx + i-1]);

}

Line 591 int computeJz(float *bx_err, float *by_e

Line 590 int computeJz(float *bx_err, float *by_e

{

for (j = 1; j <= ny-2; j++)

{

if isnan(bx[j * nx + i]) continue;

dery[j * nx + i] = (bx[(j+1) * nx + i] - bx[(j-1) * nx + i])*0.5;

err_term2[j * nx + i] = (bx_err[(j+1) * nx + i])*(bx_err[(j+1) * nx + i]) + (bx_err[(j-1) * nx + i])*(bx_err[(j-1) * nx + i]);

}

Line 600 int computeJz(float *bx_err, float *by_e

Line 599 int computeJz(float *bx_err, float *by_e

i=0;

for (j = 0; j <= ny-1; j++)

{

if isnan(by[j * nx + i]) continue;

derx[j * nx + i] = ( (-3*by[j * nx + i]) + (4*by[j * nx + (i+1)]) - (by[j * nx + (i+2)]) )*0.5;

err_term1[j * nx + i] = ( (3*by_err[j * nx + i])*(3*by_err[j * nx + i]) + (4*by_err[j * nx + (i+1)])*(4*by_err[j * nx + (i+1)]) + (by_err[j * nx + (i+2)])*(by_err[j * nx + (i+2)]) );

}

i=nx-1;

for (j = 0; j <= ny-1; j++)

{

if isnan(by[j * nx + i]) continue;

derx[j * nx + i] = ( (3*by[j * nx + i]) + (-4*by[j * nx + (i-1)]) - (-by[j * nx + (i-2)]) )*0.5;

err_term1[j * nx + i] = ( (3*by_err[j * nx + i])*(3*by_err[j * nx + i]) + (4*by_err[j * nx + (i+1)])*(4*by_err[j * nx + (i+1)]) + (by_err[j * nx + (i+2)])*(by_err[j * nx + (i+2)]) );

}

j=0;

for (i = 0; i <= nx-1; i++)

{

if isnan(bx[j * nx + i]) continue;

dery[j * nx + i] = ( (-3*bx[j*nx + i]) + (4*bx[(j+1) * nx + i]) - (bx[(j+2) * nx + i]) )*0.5;

err_term2[j * nx + i] = ( (3*bx_err[j*nx + i])*(3*bx_err[j*nx + i]) + (4*bx_err[(j+1) * nx + i])*(4*bx_err[(j+1) * nx + i]) + (bx_err[(j+2) * nx + i])*(bx_err[(j+2) * nx + i]) );

}

j=ny-1;

for (i = 0; i <= nx-1; i++)

{

if isnan(bx[j * nx + i]) continue;

dery[j * nx + i] = ( (3*bx[j * nx + i]) + (-4*bx[(j-1) * nx + i]) - (-bx[(j-2) * nx + i]) )*0.5;

err_term2[j * nx + i] = ( (3*bx_err[j*nx + i])*(3*bx_err[j*nx + i]) + (4*bx_err[(j+1) * nx + i])*(4*bx_err[(j+1) * nx + i]) + (bx_err[(j+2) * nx + i])*(bx_err[(j+2) * nx + i]) );

}

for (i = 1; i <= nx-2; i++)

for (i = 0; i <= nx-1; i++)

{

for (j = 1; j <= ny-2; j++)

for (j = 0; j <= ny-1; j++)

{

// calculate jz at all points

jz[j * nx + i] = (derx[j * nx + i]-dery[j * nx + i]); // jz is in units of Gauss/pix

jz_err[j * nx + i] = 0.5*sqrt( (bx_err[(j+1) * nx + i]*bx_err[(j+1) * nx + i]) + (bx_err[(j-1) * nx + i]*bx_err[(j-1) * nx + i]) +

jz_err[j * nx + i] = 0.5*sqrt( err_term1[j * nx + i] + err_term2[j * nx + i] ) ;

(by_err[j * nx + (i+1)]*by_err[j * nx + (i+1)]) + (by_err[j * nx + (i-1)]*by_err[j * nx + (i-1)]) ) ;

jz_err_squared[j * nx + i]= (jz_err[j * nx + i]*jz_err[j * nx + i]);

count_mask++;

}

return 0;

Line 832 int computeHelicity(float *jz_err, float

Line 830 int computeHelicity(float *jz_err, float

/* Example function 12: Sum of Absolute Value per polarity */

// The Sum of the Absolute Value per polarity is defined as the following:

// fabs(sum(jz gt 0)) + fabs(sum(jz lt 0)) and the units are in Amperes.

// fabs(sum(jz gt 0)) + fabs(sum(jz lt 0)) and the units are in Amperes per arcsecond.

// The units of jz are in G/pix. In this case, we would have the following:

// Jz = (Gauss/pix)(1/CDELT1)(0.00010)(1/MUNAUGHT)(RSUN_REF/RSUN_OBS)(RSUN_REF/RSUN_OBS)(RSUN_OBS/RSUN_REF),

// = (Gauss/pix)(1/CDELT1)(0.00010)(1/MUNAUGHT)(RSUN_REF/RSUN_OBS)

Line 869 int computeSumAbsPerPolarity(float *jz_e

Line 867 int computeSumAbsPerPolarity(float *jz_e

}

*totaljzptr = fabs(sum1) + fabs(sum2); /* Units are A */

*totaljzptr = fabs(sum1) + fabs(sum2); /* Units are Amperes per arcsecond */

*totaljz_err_ptr = sqrt(err)*(1/cdelt1)*fabs((0.00010)*(1/MUNAUGHT)*(rsun_ref/rsun_obs));

//printf("SAVNCPP=%g\n",*totaljzptr);

//printf("SAVNCPP_err=%g\n",*totaljz_err_ptr);

Line 1160 int computeR(float *bz_err, float *los,

Line 1158 int computeR(float *bz_err, float *los,

for (j = 0; j < ny1; j++)

{

index = j * nx1 + i;

if isnan(pmapn[index]) continue;

if isnan(rim[index]) continue;

sum += pmapn[index]*abs(rim[index]);

}

Line 1169 int computeR(float *bz_err, float *los,

else

*Rparam = log10(sum);

//printf("R_VALUE=%f\n",*Rparam);

free_fresize(&fresboxcar);

free_fresize(&fresgauss);

Line 1201 int computeLorentz(float *bx, float *by

Line 1203 int computeLorentz(float *bx, float *by

double k_h = -1.0 * area / (4. * PI) / 1.0e20;

double k_z = area / (8. * PI) / 1.0e20;

/* Multiplier */

float vectorMulti[] = {1.,-1.,1.};

if (nx <= 0 || ny <= 0) return 1;

for (int i = 0; i < nxny; i++)

Line 1212 int computeLorentz(float *bx, float *by

Line 1211 int computeLorentz(float *bx, float *by

if isnan(bx[i]) continue;

if isnan(by[i]) continue;

if isnan(bz[i]) continue;

fx[i] = (bx[i] * vectorMulti[0]) * (bz[i] * vectorMulti[2]) * k_h;

fx[i] = bx[i] * bz[i] * k_h;

fy[i] = (by[i] * vectorMulti[1]) * (bz[i] * vectorMulti[2]) * k_h;

fy[i] = by[i] * bz[i] * k_h;

fz[i] = (bx[i] * bx[i] + by[i] * by[i] - bz[i] * bz[i]) * k_z;

bsq = bx[i] * bx[i] + by[i] * by[i] + bz[i] * bz[i];

totfx += fx[i]; totfy += fy[i]; totfz += fz[i];

Line 1228 int computeLorentz(float *bx, float *by

Line 1227 int computeLorentz(float *bx, float *by

*epsy_ptr = (totfy / k_h) / totbsq;

*epsz_ptr = (totfz / k_z) / totbsq;

//printf("TOTBSQ=%f\n",*totbsq_ptr);

return 0;

}

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Karen Tian