/* Copyright 2002-2025 CS GROUP
    * Licensed to CS GROUP (CS) under one or more
    * contributor license agreements.  See the NOTICE file distributed with
    * this work for additional information regarding copyright ownership.
    * CS licenses this file to You under the Apache License, Version 2.0
    * (the "License"); you may not use this file except in compliance with
    * the License.  You may obtain a copy of the License at
    *
    *   http://www.apache.org/licenses/LICENSE-2.0
   *
   * Unless required by applicable law or agreed to in writing, software
   * distributed under the License is distributed on an "AS IS" BASIS,
   * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
   * See the License for the specific language governing permissions and
   * limitations under the License.
   */
  package org.orekit.propagation.analytical.tle;
  
  import org.hipparchus.util.FastMath;
  import org.hipparchus.util.MathUtils;
  import org.hipparchus.util.SinCos;
  import org.orekit.attitudes.AttitudeProvider;
  import org.orekit.frames.Frame;
  import org.orekit.time.AbsoluteDate;
  import org.orekit.time.DateTimeComponents;
  import org.orekit.utils.Constants;
  
  /** This class contains methods to compute propagated coordinates with the SDP4 model.
   * <p>
   * The user should not bother in this class since it is handled internally by the
   * {@link TLEPropagator}.
   * </p>
   * <p>This implementation is largely inspired from the paper and source code <a
   * href="https://www.celestrak.com/publications/AIAA/2006-6753/">Revisiting Spacetrack
   * Report #3</a> and is fully compliant with its results and tests cases.</p>
   * @author Felix R. Hoots, Ronald L. Roehrich, December 1980 (original fortran)
   * @author David A. Vallado, Paul Crawford, Richard Hujsak, T.S. Kelso (C++ translation and improvements)
   * @author Fabien Maussion (java translation)
   */
  abstract class SDP4  extends TLEPropagator {
  
      // CHECKSTYLE: stop VisibilityModifier check
  
      /** New perigee argument. */
      protected double omgadf;
  
      /** New mean motion. */
      protected double xn;
  
      /** Parameter for xl computation. */
      protected double xll;
  
      /** New eccentricity. */
      protected double em;
  
      /** New inclination. */
      protected double xinc;
  
      // CHECKSTYLE: resume VisibilityModifier check
  
      /** Constructor for a unique initial TLE.
       * @param initialTLE the TLE to propagate.
       * @param attitudeProvider provider for attitude computation
       * @param mass spacecraft mass (kg)
       * @param teme the TEME frame to use for propagation.
       */
      protected SDP4(final TLE initialTLE,
                     final AttitudeProvider attitudeProvider,
                     final double mass,
                     final Frame teme) {
          super(initialTLE, attitudeProvider, mass, teme);
      }
  
      /** Initialization proper to each propagator (SGP or SDP).
       */
      protected void sxpInitialize() {
          luniSolarTermsComputation();
      }  // End of initialization
  
      /** Propagation proper to each propagator (SGP or SDP).
       * @param tSince the offset from initial epoch (minutes)
       */
      protected void sxpPropagate(final double tSince) {
  
          // Update for secular gravity and atmospheric drag
          omgadf = tle.getPerigeeArgument() + omgdot * tSince;
          final double xnoddf = tle.getRaan() + xnodot * tSince;
          final double tSinceSq = tSince * tSince;
          xnode = xnoddf + xnodcf * tSinceSq;
          xn = xn0dp;
  
          // Update for deep-space secular effects
          xll = tle.getMeanAnomaly() + xmdot * tSince;
  
          deepSecularEffects(tSince);
  
          final double tempa = 1 - c1 * tSince;
          a   = FastMath.pow(TLEConstants.XKE / xn, TLEConstants.TWO_THIRD) * tempa * tempa;
          em -= tle.getBStar(tle.getDate().shiftedBy(tSince)) * c4 * tSince;
 
         // Update for deep-space periodic effects
         xll += xn0dp * t2cof * tSinceSq;
 
         deepPeriodicEffects(tSince);
 
         xl = xll + omgadf + xnode;
 
         // Dundee change:  Reset cosio,  sinio for new xinc:
         final SinCos scI0 = FastMath.sinCos(xinc);
         cosi0 = scI0.cos();
         sini0 = scI0.sin();
         e = em;
         i = xinc;
         omega = omgadf;
         // end of calculus, go for PV computation
     }
 
     /** Computes SPACETRACK#3 compliant earth rotation angle.
      * @param date the current date
      * @return the ERA (rad)
      */
     protected double thetaG(final AbsoluteDate date) {
 
         // Reference:  The 1992 Astronomical Almanac, page B6.
         final double omega_E = 1.00273790934;
         final double jd = date
                 .getComponents(utc)
                 .offsetFrom(DateTimeComponents.JULIAN_EPOCH) /
                 Constants.JULIAN_DAY;
 
         // Earth rotations per sidereal day (non-constant)
         final double UT = (jd + 0.5) % 1;
         final double seconds_per_day = Constants.JULIAN_DAY;
         final double jd_2000 = 2451545.0;   /* 1.5 Jan 2000 = JD 2451545. */
         final double t_cen = (jd - UT - jd_2000) / 36525.;
         double GMST = 24110.54841 +
                       t_cen * (8640184.812866 + t_cen * (0.093104 - t_cen * 6.2E-6));
         GMST = (GMST + seconds_per_day * omega_E * UT) % seconds_per_day;
         if (GMST < 0.) {
             GMST += seconds_per_day;
         }
 
         return MathUtils.TWO_PI * GMST / seconds_per_day;
 
     }
 
     /** Computes luni - solar terms from initial coordinates and epoch.
      */
     protected abstract void luniSolarTermsComputation();
 
     /** Computes secular terms from current coordinates and epoch.
      * @param t offset from initial epoch (min)
      */
     protected abstract void deepSecularEffects(double t);
 
     /** Computes periodic terms from current coordinates and epoch.
      * @param t offset from initial epoch (min)
      */
     protected abstract void deepPeriodicEffects(double t);
 
 }