Пример #1
0
  /** Create a simple WCS given a scaler, CoordinateSystem and Projection. */
  public WCS(CoordinateSystem csys, Projection proj, Scaler scale) throws TransformationException {

    this.csys = csys;
    this.proj = proj;
    this.scale = scale;

    add(csys.getSphereDistorter());
    add(csys.getRotater());
    add(proj.getRotater());
    add(proj.getProjecter());
    add(proj.getDistorter());
    add(scale);
    setWCSScale(scale);
  }
Пример #2
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  /**
   * Write FITS WCS keywords given key values. Only relatively simple WCSs are handled here. We
   * assume we are dealing with axes 1 and 2.
   *
   * @param h The header to be updated.
   * @param s A Scaler giving the transformation between standard projection coordinates and
   *     pixel/device coordinates.
   * @param projString A three character string giving the projection used. Supported projections
   *     are: "Tan", "Sin", "Ait", "Car", "Zea".
   * @param coordString A string giving the coordinate system used. The first character gives the
   *     general frame. For most frames the remainder of the string gives the equinox of the
   *     coordinate system. E.g., J2000, B1950, Galactic, "E2000", "H2020.10375".
   */
  public void updateHeader(
      Header h, Scaler s, double[] crval, String projString, String coordString) throws Exception {

    if (proj.isFixedProjection()) {
      h.addValue("CRVAL1", toDegrees(proj.getReferencePoint()[0]), "Fixed reference center");
      h.addValue("CRVAL2", toDegrees(proj.getReferencePoint()[1]), "Fixed reference center");
    } else {
      h.addValue("CRVAL1", crval[0], "Reference longitude");
      h.addValue("CRVAL2", crval[1], "Reference latitude");
    }

    coordString = coordString.toUpperCase();
    String[] prefixes = new String[2];
    char c = coordString.charAt(0);
    if (c == 'J' || c == 'I') {
      h.addValue("RADESYS", "FK5", "Coordinate system");
      prefixes[0] = "RA--";
      prefixes[1] = "DEC-";
    } else if (c == 'B') {
      h.addValue("RADESYS", "FK4", "Coordinate system");
      prefixes[0] = "RA--";
      prefixes[1] = "DEC-";
    } else {
      prefixes[0] = c + "LON";
      prefixes[1] = c + "LAT";
    }

    if (c != 'G' && c != 'I') {
      try {
        double equinox = Double.parseDouble(coordString.substring(1));
        h.addValue("EQUINOX", equinox, "Epoch of the equinox");
      } catch (Exception e) {
        // Couldn't parse out the equinox
      }
    }
    if (c == 'I') {
      h.addValue("EQUINOX", 2000, "ICRS coordinates");
    }

    String upProj = projString.toUpperCase();

    h.addValue("CTYPE1", prefixes[0] + "-" + upProj, "Coordinates -- projection");
    h.addValue("CTYPE2", prefixes[1] + "-" + upProj, "Coordinates -- projection");

    // Note that the scaler transforms from the standard projection
    // coordinates to the pixel coordinates.
    //     P = P0 + M X  where X is the standard coordinates and P is the
    // pixel coordinates.  So the reference pixels are just the constants
    // in the scaler.
    // Remember that FITS pixels are offset by 0.5 from 0 offset pixels.

    h.addValue("CRPIX1", s.x0 + 0.5, "X reference pixel");
    h.addValue("CRPIX2", s.y0 + 0.5, "Y reference pixel");

    // Remember that the FITS values are of the form
    //    X = M(P-P0)
    // so we'll need to invert the scaler.
    //
    // Do we need a matrix?
    if (abs(s.a01) < 1.e-14 && abs(s.a10) < 1.e-14) {
      // No cross terms, so we'll just use CDELTs
      h.addValue("CDELT1", toDegrees(1 / s.a00), "X scale");
      h.addValue("CDELT2", toDegrees(1 / s.a11), "Y scale");
    } else {
      // We have cross terms.  It's simplest
      // just to use the CD matrix and not worry about
      // normalization.  First invert the matrix to get
      // the transformation in the direction that FITS uses.
      Scaler rev = s.inverse();
      h.addValue("CD1_1", toDegrees(rev.a00), "Matrix element");
      h.addValue("CD1_2", toDegrees(rev.a01), "Matrix element");
      h.addValue("CD2_1", toDegrees(rev.a10), "Matrix element");
      h.addValue("CD2_2", toDegrees(rev.a11), "Matrix element");
    }
  }
Пример #3
0
  /** Handle the NEAT special projection */
  private void doNeatWCS() throws TransformationException {

    // The NEAT transformation from the standard spherical system
    // includes:
    //   Transformation to J2000 spherical coordinates (a null operation)
    //   A tangent plane projection to the standard plane
    //   A scaler transformation to corrected pixel coordinates.
    //   A distorter to distorted pixel coordinates
    //   A scaler transformation of distorted coordinates to actual pixels

    CoordinateSystem csys = CoordinateSystem.factory("J2000");
    this.csys = csys;

    // The RA0/DEC0 pair are the actual center of the projection.

    double cv1 = toRadians(h.getDoubleValue("RA0"));
    double cv2 = toRadians(h.getDoubleValue("DEC0"));
    wcsKeys.put("CRVAL1", toDegrees(cv1));
    wcsKeys.put("CRVAL2", toDegrees(cv2));

    Projection proj = new Projection("Tan", new double[] {cv1, cv2});
    this.proj = proj;

    double cd1 = toRadians(h.getDoubleValue("CDELT1"));
    double cd2 = toRadians(h.getDoubleValue("CDELT2"));
    wcsKeys.put("CDELT1", toDegrees(cd1));
    wcsKeys.put("CDELT2", toDegrees(cd2));

    wcsScale = abs(cd1);

    double cp1 = h.getDoubleValue("CRPIX1");
    double cp2 = h.getDoubleValue("CRPIX2");

    wcsKeys.put("CPRIX1", cp1);
    wcsKeys.put("CRPIX2", cp2);

    wcsKeys.put("CTYPE1", "RA---XTN");
    wcsKeys.put("CTYPE2", "DEC--XTN");

    Scaler s1 = new Scaler(0., 0., -1 / cd1, 0, 0, -1 / cd2);

    // Note that the the A0,A1,A2, B0,B1,B2 rotation
    // is relative to the original pixel values, so
    // we need to put this in the secondary scaler.
    //
    double x0 = h.getDoubleValue("X0");
    double y0 = h.getDoubleValue("Y0");

    Distorter dis =
        new skyview.geometry.distorter.Neat(
            h.getDoubleValue("RADIAL"), h.getDoubleValue("XRADIAL"), h.getDoubleValue("YRADIAL"));

    double a0 = h.getDoubleValue("A0");
    double a1 = h.getDoubleValue("A1");
    double a2 = h.getDoubleValue("A2");
    double b0 = h.getDoubleValue("B0");
    double b1 = h.getDoubleValue("B1");
    double b2 = h.getDoubleValue("B2");

    // The reference pixel is to be computed in the distorted frame.
    double[] cpix = new double[] {cp1, cp2};
    double[] cout = new double[2];
    dis.transform(cpix, cout);
    Scaler s2 =
        new Scaler(
            cout[0] - a0 - a1 * x0 - a2 * y0,
            cout[1] - b0 - b2 * x0 - b1 * y0,
            -(1 + a1),
            -a2,
            -b2,
            -(1 + b1));

    wcsKeys.put("A0", a0);
    wcsKeys.put("A1", a1);
    wcsKeys.put("A2", a2);
    wcsKeys.put("B0", b0);
    wcsKeys.put("B1", b1);
    wcsKeys.put("B2", b2);

    this.distort = dis;
    add(csys.getSphereDistorter());
    add(csys.getRotater());
    add(proj.getRotater());
    add(proj.getProjecter());
    this.scale = s1;
    // Note that s1 is defined from the projection plane to the pixels coordinates,
    // so we don't need to invert it.
    //
    // But the second scaler, s2,  used in the NEAT correction
    // is defined in the direction from pixels to sphere, so we
    // need to take its inverse.
    this.scale = this.scale.add(s2.inverse());
    add(this.scale);
    add(dis);
  }
Пример #4
0
  /** Handle a DSS projection */
  private void doDSSWCS() throws TransformationException {

    double plateRA =
        h.getDoubleValue("PLTRAH")
            + h.getDoubleValue("PLTRAM") / 60
            + h.getDoubleValue("PLTRAS") / 3600;
    plateRA = toRadians(15 * plateRA);
    wcsKeys.put("PLTRAH", h.getDoubleValue("PLTRAH"));
    wcsKeys.put("PLTRAM", h.getDoubleValue("PLTRAM"));
    wcsKeys.put("PLTRAS", h.getDoubleValue("PLTRAS"));

    double plateDec =
        h.getDoubleValue("PLTDECD")
            + h.getDoubleValue("PLTDECM") / 60
            + h.getDoubleValue("PLTDECS") / 3600;
    plateDec = toRadians(plateDec);

    if (h.getStringValue("PLTDECSN").substring(0, 1).equals("-")) {
      plateDec = -plateDec;
    }
    wcsKeys.put("PLTDECD", h.getDoubleValue("PLTDECD"));
    wcsKeys.put("PLTDECM", h.getDoubleValue("PLTDECM"));
    wcsKeys.put("PLTDECS", h.getDoubleValue("PLTDECS"));
    wcsKeys.put("PLTDECSN", h.getStringValue("PLTDECSN"));

    double plateScale = h.getDoubleValue("PLTSCALE");
    double xPixelSize = h.getDoubleValue("XPIXELSZ");
    double yPixelSize = h.getDoubleValue("YPIXELSZ");
    wcsKeys.put("PLTSCALE", plateScale);
    wcsKeys.put("XPIXELSZ", xPixelSize);
    wcsKeys.put("YPIXELSZ", yPixelSize);

    double[] xCoeff = new double[20];
    double[] yCoeff = new double[20];

    for (int i = 1; i <= 20; i += 1) {
      xCoeff[i - 1] = h.getDoubleValue("AMDX" + i);
      yCoeff[i - 1] = h.getDoubleValue("AMDY" + i);
      wcsKeys.put("AMDX" + i, xCoeff[i - 1]);
      wcsKeys.put("AMDY" + i, yCoeff[i - 1]);
    }

    double[] ppo = new double[6];
    for (int i = 1; i <= 6; i += 1) {
      ppo[i - 1] = h.getDoubleValue("PPO" + i);
      wcsKeys.put("PPO" + i, ppo[i - 1]);
    }

    double plateCenterX = ppo[2];
    double plateCenterY = ppo[5];

    double cdelt1 = -plateScale / 1000 * xPixelSize / 3600;
    double cdelt2 = plateScale / 1000 * yPixelSize / 3600;

    wcsScale = abs(cdelt1);

    // This gives cdelts in degrees per pixel.

    // CNPIX pixels use a have the first pixel going from 1 - 2 so they are
    // off by 0.5 from FITS (which in turn is offset by 0.5 from the internal
    // scaling, but we handle that elsewhere).
    double crpix1 = plateCenterX / xPixelSize - h.getDoubleValue("CNPIX1", 0) - 0.5;
    double crpix2 = plateCenterY / yPixelSize - h.getDoubleValue("CNPIX2", 0) - 0.5;
    wcsKeys.put("CNPIX1", h.getDoubleValue("CNPIX1", 0));
    wcsKeys.put("CNPIX2", h.getDoubleValue("CNPIX2", 0));

    Projection proj = new Projection("Tan", new double[] {plateRA, plateDec});
    this.proj = proj;
    CoordinateSystem coords = CoordinateSystem.factory("J2000");
    this.csys = coords;

    cdelt1 = toRadians(cdelt1);
    cdelt2 = toRadians(cdelt2);

    Scaler s = new Scaler(-cdelt1 * crpix1, -cdelt2 * crpix2, cdelt1, 0, 0, cdelt2);

    // Got the transformers ready.  Add them in properly.
    add(coords.getSphereDistorter());
    add(coords.getRotater());
    add(proj.getRotater());
    add(proj.getProjecter());

    this.distort =
        new skyview.geometry.distorter.DSS(
            plateRA, plateDec, xPixelSize, yPixelSize, plateScale, ppo, xCoeff, yCoeff);
    add(this.distort);

    this.scale = s.inverse();

    add(this.scale);
  }
Пример #5
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  private void extractProjection() throws TransformationException {

    Projection proj = null;
    Scaler ncpScale = null;

    String lonType = h.getStringValue("CTYPE" + lonAxis).substring(5, 8);
    String latType = h.getStringValue("CTYPE" + latAxis).substring(5, 8);
    if (!lonType.equals(latType)) {
      throw new TransformationException(
          "Inconsistent projection in FITS header: " + lonType + "," + latType);
    }

    if (lonType.equals("AIT")) {
      proj = new Projection("Ait");

    } else if (lonType.equals("CAR")) {
      proj = new Projection("Car");
      // Allow non-central latitudes for the Cartesian projection.
      try {
        double lon = h.getDoubleValue("CRVAL" + lonAxis);
        if (lon != 0) {
          proj.setReference(toRadians(lon), 0);
        }
      } catch (Exception e) {
        System.err.println("Unable to read reference longitude in Cartesian projection");
      }

    } else if (lonType.equals("CSC")) {
      proj = new Projection("Csc");

    } else if (lonType.equals("SFL") || lonType.equals("GLS")) {
      proj = new Projection("Sfl");

    } else if (lonType.equals("TOA")) {
      proj = new Projection("Toa");

    } else {

      double crval1 = h.getDoubleValue("CRVAL" + lonAxis, NaN);
      double crval2 = h.getDoubleValue("CRVAL" + latAxis, NaN);

      if (isNaN(crval1 + crval2)) {
        throw new TransformationException("Unable to find reference coordinates in FITS header");
      }

      wcsKeys.put("CRVAL1", crval1);
      wcsKeys.put("CRVAL2", crval2);

      if (lonType.equals("TAN")
          || lonType.equals("SIN")
          || lonType.equals("ZEA")
          || lonType.equals("ARC")
          || lonType.equals("STG")) {

        String type = lonType.substring(0, 1) + lonType.substring(1, 3).toLowerCase();
        proj = new Projection(type, new double[] {toRadians(crval1), toRadians(crval2)});

        double lonpole = h.getDoubleValue("LONPOLE", NaN);
        if (!isNaN(lonpole)) {
          wcsKeys.put("LONPOLE", lonpole);
        }
        //  ---- Following is probably erroneous -----
        // The WCS standard indicates that the default LONPOLE for
        // a projection is 180 when the CRVAL latitude is less than
        // the native latitude of the projection (90 degrees for the projections
        // handled here) and 0 otherwise.  This means that for a projection
        // around the pole the default lonpole is 0.  Some data (the SFD surveys)
        // seem to require that we do a rotation of 180 degrees to accommodate
        // this.  However we do not implement this unless the LONPOLE is
        // explicitly given since this seems non-intuitive to me and I suspect
        // that a user who is not careful enough to specify a LONPOLE in this
        // situation probably doesn't understand what is going on anyway.
        // ----- We now assume that our standard processing of
        // ----- zenithal projections handles lonpole of 180 and that
        // ----- this is the default for all zenithal images.
        // ----- Previously we assumed that we were using lonPole=0 at
        // ----- at the poles, but we weren't....
        //

        if (!isNaN(lonpole)) {
          double lonDefault = 180;
          if (lonpole != lonDefault) {

            Rotater r = proj.getRotater();

            Rotater lon = new Rotater("Z", toRadians(lonpole - lonDefault), 0, 0);
            if (r != null) {
              proj.setRotater(r.add(lon));
            } else {
              proj.setRotater(lon);
            }
          }
        }

      } else if (lonType.equals("NCP")) {

        // Sin projection with projection centered at pole.
        double[] xproj = new double[] {toRadians(crval1), PI / 2};
        if (crval2 < 0) {
          xproj[1] = -xproj[1];
        }

        double poleOffset = sin(xproj[1] - toRadians(crval2));
        // Have we handled South pole here?

        proj = new Projection("Sin", xproj);

        // NCP scales the Y-axis to accommodate the distortion of the SIN projection away
        // from the pole.
        ncpScale = new Scaler(0, poleOffset, 1, 0, 0, 1);
        ncpScale = ncpScale.add(new Scaler(0., 0., 1, 0, 0, 1 / sin(toRadians(crval2))));

      } else {
        throw new TransformationException("Unsupported projection type:" + lonType);
      }
    }

    this.proj = proj;
    if (ncpScale != null) {
      this.scale = ncpScale;
    }
    add(proj.getRotater());
    add(proj.getProjecter());
    add(ncpScale); // Ignored if null
  }