/** * Returns a denominator for filtering the wide-field, OTF band 0 with no attenuation. * * @param wParam Wiener filter parameter */ public Vec2d.Real getWidefieldDenominator(double wParam) { Vec2d.Real ret = Vec2d.createReal(sp, 2); addWienerDenominator(ret, 0, 0, false); final int w = ret.vectorWidth(), h = ret.vectorHeight(); for (int y = 0; y < h; y++) for (int x = 0; x < w; x++) ret.set(x, y, 1 / (ret.get(x, y) + (float) (wParam * wParam))); return ret; }
/** * Returns a copy of a per-band, per-direction Wiener denominator. This is used mostly for * filtering intermediate results. * * @param d Direction * @param b Band * @param wParam Wiener filter parameter */ public Vec2d.Real getIntermediateDenominator(int d, int b, double wParam) { // get the otf Vec2d.Real ret = Vec2d.createReal(sp, 2); addWienerDenominator(ret, d, b, sp.otf().isAttenuate()); // add the wiener parameter final int w = ret.vectorWidth(), h = ret.vectorHeight(); for (int y = 0; y < h; y++) for (int x = 0; x < w; x++) ret.set(x, y, 1 / (ret.get(x, y) + (float) (wParam * wParam))); return ret; }
/** * Returns reciproc Wiener denominator. 'Reciproc' means the vector can directly be multiplied to * spectrum. * * @param wParam Wiener filter parameter */ public Vec2d.Real getDenominator(double wParam) { Vec2d.Real ret = wDenom.duplicate(); final int w = ret.vectorWidth(), h = ret.vectorHeight(); for (int y = 0; y < h; y++) for (int x = 0; x < w; x++) ret.set(x, y, 1 / (ret.get(x, y) + (float) (wParam * wParam))); return ret; }
/** * Add OTF^2, for band and direction, to a vector. * * @param d Direction * @param b Band * @param useAtt Include attenuation */ public void addWienerDenominator( final Vec2d.Real vec, final int d, final int b, final boolean useAtt) { // parameters final int w = vec.vectorWidth(), h = vec.vectorHeight(); final SimParam.Dir dir = sp.dir(d); final double cyclMicron = sp.pxlSizeCyclesMicron(); // loop the vector x,y new SimpleMT.PFor(0, h) { public void at(int y) { for (int x = 0; x < w; x++) { // wrap to coordinates: x in [-w,w], y in [-h, h] double xh = (x < w / 2) ? (x) : (x - w); double yh = (y < h / 2) ? (-y) : (h - y); // from these, calculate distance to +-(kx,ky), convert to cycl/microns double rad1 = MTool.fhypot(xh - dir.px(b), yh - dir.py(b)) * cyclMicron; double rad2 = MTool.fhypot(xh + dir.px(b), yh + dir.py(b)) * cyclMicron; // get OTF, at that distance, for that band, un-attenuated float otfVal1 = sp.otf().getOtfVal(b, rad1, false).absSq(); float otfVal2 = sp.otf().getOtfVal(b, rad2, false).absSq(); // if attenuate, do so if (useAtt) { otfVal1 *= sp.otf().getAttVal(b, rad1); otfVal2 *= sp.otf().getAttVal(b, rad2); } // store for Wiener denominator vec.set(x, y, vec.get(x, y) + otfVal1 + otfVal2); } } }; }