Introduction
  
     Despite the launch of two early missions HEOS 2 and
  Hawkeye into highly elliptical polar orbits, we know very
  little about the solar wind interface with the polar cusp.  In
  this paper we will use Hawkeye data to determine the shape of
  the magnetopause at high latitudes in an attempt to understand
  some of the basic physics in this region.  Our present lack of
  understanding is underscored by the stark difference between
  "vacuum" models of the magnetosphere and MHD simulations. 
  Vacuum models, such as the model of Tsyganenko (1989) of a
  dipole field in an ellipsoidal superconducting shell, have a
  polar cusp that is tilted well forward of the terminator
  except for large tilts of the dipole away from the sun.  This
  is illustrated in Figures 1a, b and c for tilt angles of 0o,
  10o and 30o.  However, many MHD models have a cusp that is
  tilted away from the sun.  Examples of such cusps are shown in
  Figure 2a, b (Wu, 1984) while Figure 2c shows a more classical
  model.  The difference between these two types of models may
  be due to the presence of plasma in the MHD models and its
  ability to diffuse across the magnetopause due to the finite
  diffusivity of the codes. An initial study of the shape of the
  magnetopause below the cusp was attempted using the lower
  latitude ISEE data by Petrinec and Russell (1995).  By
  examining the shape of the boundary as a function of the
  latitudinal distance from the cusp as measured by the sum of
  the tilt angle plus the magnetic latitude of the observation,
  they found evidence for the indentation of the cusp at high
  latitudes. This is shown in Figure 3 that compares the
  observations as plus sign, the fit to these points as a solid
  line and the model of Spreiter and Briggs [1961] as a dashed
  line. The observations are clearly consistent with the shape
  obtained from the Spreiter and Briggs model.  The Hawkeye data
  allows us to make a simple test as to which of these models is
  closest to the configuration of the terrestrial cusps.
                             Effect of Dipole Tilt
  
     While Figures 5a, b show statistically where the cusp is
  found, it provides little insight into the dependence of the
  cusp location or dipole tilt angle or even what the tilt angle
  was during this period.  Figures 6a, b, c, d break up Figures
  5a and b into IMF north and south and into three tilt angle
  ranges <-10o, -10o to 10o, >10o.  The median tilt angle is
  shown in the Figure as well as being illustrated by a tilted
  arrow.  The polar cusp will be encountered polarward of the
  below the cusp crossings and equatorward of the above the cusp
  crossings.  We see that as the dipole tilts further and
  further toward the sun the cusp location moves equatorward for
  both northward and southward IMF.  We can quantify this by
  putting limits on the cusp location for each of our dipole
  tilt ranges and comparing with the cusp position in the
  Tsyganenko (1989) vacuum model.  Figures 7a and b show this
  for northward and southward IMF separately. In this figure we
  include positions near the noon-midnight meridian (positional
  clock angles <22.5o  from noon) as well as clock angles
  further from the noon-midnight meridian (67.5o  to 22.5o )
  labled "mid" in Figure 7. Clearly the polar cusp is swept back
  from the vacuum location by the interaction for both IMF
  northward and southward but somewhat less for the southward
  orientation.  Moreover the sweep back seems to be
  substantially less than that predicted by Wu.
                                 Data Analysis
  
     We have examined time series of the magnetic field data
  at 46 second resolution for the period June 4, 1974 to June 1,
  1976.  As shown in Figures 4a and 4b we have identified the
  magnetopause through its signature in the 3 vector components
  of the field and in the angles declination D=tan-1[by/(Rxbz-
  Rzbx)] and inclination I=cos(Rxbx+Rzbz)-90o .  Where R is the
  unit vector from the center of the earth to the point of
  observation in the Dipole Meridian system, and b is the
  direction of the magnetic field in the same system.  The field
  values just inside the magnetopause tell us whether the
  spacecraft is above the cusp or below the cusp.  Below the
  cusp the field lines point away from the sun and above it
  toward the sun.  Figure 4a shows an example of measurements
  below the cusp and Figure 4b shows an example of measurements
  above the cusp.  Unless we are in the cusp itself we do not
  know where it is exactly since we can determine whether we are
  above or below the cusp we can determine where the cusp is
  statistically.  Since we expect that the direction of the IMF
  will affect the cusp location we examine only magnetopause
  crossings for which there are IMF measurements on the IMP-8
  spacecraft.  Figure 5a and b show the location of the
  magnetopause crossings for magnetopause clock angles within
  22.5o of the noon-midnight meridian for north and south IMF
  respectively.  Solid circles show measurements below the cusp
  and open circles above the cusp.  All locations have been
  normalized by the sixth root of the dynamic pressure to a
  common 2nPa pressure.
                     The 3D Shape of the Magnetopause
  
     Even though we used all the Hawkeye data available to us
  there is still not enough data to explore the funnel of the
  polar cusp.  Moreover it seems to move.  This motion is
  controlled by more than just the tilt angle of the dipole. 
  The IMF clearly plays a role as may other solar wind
  parameters.  Thus we will not be able to test the assertion of
  Petrinec and Russell (1995) that lower latitude ISEE data
  indicate the presence of a cusp.  However, we do have enough
  data to determine the zeroth order shape averaged over any
  cusp indentation.  This average shape is shown in Figures 8a
  and b for three clock angle ranges.  The noon midnight
  meridian (    22.5o), mid latitudes (22.5o   67.5o) and
  equatorial (Petrinec et al., 1991).  Perhaps surprisingly the
  equatorial cross-section is larger than the cross-section over
  the pole for Bz>0.  This may be due to the presence of hot
  plasma in the closed magnetosphere with pressure approaching
  that of the magnetic field with a near absence of plasma in
  the tail lobes above the pole cusp.  However, for Bz<0 the
    shapes are all very similar.                               Conclusions
  
     Observations with the Hawkeye spacecraft in the
  neighborhood of the polar cusp show that
  
       the polar cusp is swept back by the solar wind whether
      the IMF is northward or southward
  
        the polar cusp is not swept back as much as in the Wu
      MHD model
  
        the polar cusp location is controlled by the tilt of the
      dipole so that it moves increasingly toward the sun as
      the dipole tilts more toward the sun
        
        the noon-midnight cross-section of magnetosphere is
      smaller than the equatorial cross-section for Bz>0
  
        the magnetospheric shape is nearly cylindrically
      symmetric for Bz<0