SUBJECT: THE HILL ABDUCTION CASE                             FILE: UFO2709




PART 8




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   REBUTTAL:  To David Saunders and Michael Peck
              By Carl Sagan and Steven Soter

     Dr.   David  Saunders  last month claimed to  have  demonstrated  the
   statistical significance of the Hill map,  which was allegedly found on
   board  a  landed  UFO and supposedly depicted the sun  and  14   nearby
   sunlike stars.  The Hill map was said to resemble the Fish map --   the
   latter   being  an  optimal  two-dimensional  projection  of  a  three-
   dimensional model prepared by selecting 14 stars from a positional list
   of  the  46  nearest known sunlike stars.  Saunders'  argument  can  be
   expressed  by the equation SS = Dr -(SF + VP),  in which all quantities
   are  in  information bits.  SS is the statistical significance  of  the
   correlation  between  the two maps,  DR is the  degree  of  resemblance
   between them, SF is a selection factor depending on the number of stars
   chosen  and  the size of the list,  and VP is the  information  content
   provided  by a free choice in three dimensions of the vantage point for
   projecting the map. Saunders finds SS = 6 to 11 bits,  meaning that the
   correlation  is equivalent to between 6 and 11  consecutive heads in  a
   coin  toss  and  therefore probably not accidental.  The  procedure  is
   acceptable  in  principle,  but the result depends entirely on how  the
   quantities on the right-hand side of the equation were chosen.

     For the degree of resemblance between the two maps,  Saunders  claims
   that DR = 11 to 16 bits, which he admits is only a guess -- but we will
   let it stand. For the selection factor,  he at first takes SF = log2C =
   37.8 bits, where C represents the combinations of 46 things taken 14 at
   a  time.  Realizing that the size of this factor alone will cause SS to
   be  negative  and wipe out his argument,  he makes a number of  ad  hoc
   adjustments  based  essentially on his interpretation of  the  internal
   logic  of the Hill map,  and SF somehow gets reduced to only 3.9  bits.
   For the present, we will let even that stand in order to avoid becoming
   embroiled  in  a  discussion  of how an explorer  from  the  star  Zeta
   Reticuli  would  choose  to arrange his/her/its  travel  itinerary  --a
   matter  about which we can claim no particular knowledge.  However,  we
   must  bear  in mind that a truly unprejudiced examination of  the  data
   with no a priori interpretations would give SF = 37.8 bits.

     It is Saunders'  choice of the vantage point factor VP with which  we
   must take strongest issue,  for this is a matter of geometry and simple
   pattern  recognition.  Saunders assumes that free choice of the vantage
   point  for viewing a three-dimensional model of 15  stars is worth only
   VP = 3 bits.  He then reduces the information content of directionality
   to one bit by introducing the "constraint"  that the star Zeta  Tucanae
   be  occulted by Zeta Reticuli (with no special notation on the Hill map
   to mark this peculiarity). This ad hoc device is invoked to explain the
   absence of Zeta Tucanae from the Hill map,  but it reveals the circular
   reasoning involved.  After all, why bother to calculate the statistical
   significance of the supposed map correlation if one has already decided
   which points represent which stars?

     Certainly  the  selection of vantage point is worth more  than  three
   bits  (not  to mention one bit).  Probably the easiest circumstance  to
   recognize  and  remember  about  random projections  of  the  model  in
   question  are  the cases in which two stars appear  to  be  immediately
   adjacent.  By viewing the model from all possible directions, there are
   14   distinct ways in which any given star can be seen in projection as
   adjacent to some other star. This can be done for each of the 15 stars,
   giving  210   projected  configurations  --  each  of  which  would  be
   recognized  as  substantially different from the others in  information
   content.  And of course there are many additional distinct recognizable
   projections  of  the 15  stars not involving any two being  immediately
   adjacent.  (For example,  three stars nearly equidistant in a  straight
   line  are  easily  recognized,  as in Orion's belt.)  Thus for  a  very
   conservative lower bound,  the information content determined by choice
   of vantage point (that is,  by being allowed to rotate the model  about
   three  axes)  can be taken as at least equal to VP = log2(210)  =   7.7
   bits. Using the rest of Saunders' analysis, this would at best yield SS
   = zero to 4.4 bits -- not a very impressive correlation.

     There  is another way to understand the large number of bits involved
   in the choice of the vantage point. The stars in question are separated
   by  distances  of order 10  parsecs.  If the vantage point is  situated
   above  or not too far from the 15  stars,  it need only be  shifted  by
   about  0.17   parsecs  to cause a change of one  degree  in  the  angle
   subtended  by  some  pair of stars.  Now one degree is  a  very  modest
   resolution, corresponding to twice the full moon and is easily detected
   by anyone.  For three degrees of freedom,  the number of vantage points
   corresponding  to this resolution is of order (10/0.17)  cubed  ~  (60)
   cubed ~ 2 X 10  to the fifth power,  corresponding to VP = 17.6   bits.
   This  factor alone is sufficient to make SS negative,  and to wipe  out
   any validity to the supposed correlation.

     Even  if  we were to accept Saunders'  claim that SS = 6 to  11  bits
   (which  we obviously do not,  particularly in view of the proper  value
   for  SF),   it  is not at all clear that this  would  be  statistically
   significant   because   we  are  not  told  how  many  other   possible
   correlations were tried and failed before the Fish map was devised. For
   comparison,  there is the well-known correlation between the  incidence
   of  Andean  earthquakes and oppositions of the planet  Uranus.   It  is
   unlikely  in  the  extreme that there is a  physical  causal  mechanism
   operating here --  among other reasons, because there is no correlation
   with oppositions of Jupiter, Saturn or Neptune.  But to have found such
   a  correlation  the  investigator must have sought a  wide  variety  of
   correlations  of  seismic  events  in  many parts  of  the  world  with
   oppositions  and conjunctions of many astronomical objects.  If  enough
   correlations  are sought,  statistics requires that eventually one will
   be found,  valid to any level of significance that we wish.  Before  we
   can   determine   whether  a  claimed  correlation  implies  a   causal
   connection,  we must convince ourselves that the number of correlations
   sought  has  not  been  so large as to  make  the  claimed  correlation
   meaningless.

     This  point  can  be further illustrated  by  Saunders'   example  of
   flipping  coins.   Suppose we flip a coin once per second  for  several
   hours. Now let us consider three cases: two heads in a row, 10 heads in
   a row,  and 40  heads in a row.  We would,  of course,  think there  is
   nothing  extraordinary  about the first case.  Only  four  attempts  at
   flipping  two coins are required to have a reasonable expectation value
   of  two heads in a row.  Ten heads in a row,  however,  will occur only
   once in every 2 to the tenth power = 1,024  trials,  and 40  heads in a
   row  will occur only once every 2 to the fortieth ~ 10  to the  twelfth
   power trials. At a flip rate of one coin per second, a toss of 10 coins
   requires 10 seconds; 1,024 trials of 10  coins each requires just under
   three hours.  But 40 heads in a row at the same rate requires 4 X 10 to
   the thirteenth power seconds or a little over a million years. A run of
   40  consecutive heads in a few hours of coin tossing would certainly be
   strong  prima facie evidence of the ability to control the fall of  the
   coin.   Ten  heads in a row under the circumstances we  have  described
   would provide no convincing evidence at all.  It is expected by the law
   of probability. The Hill map correlation is at best claimed by Saunders
   to be in the category of 10 heads in a row, but with no clear statement
   as to the number of unsuccessful trials previously attempted.

     Michael Peck finds a high degree of correlation between the Hill  map
   and  the  Fish map,  and thereby also misses the central point  of  our
   original  criticism:   that  the  stars in the Fish  map  were  already
   preselected in order to maximize that very correlation.  Peck finds one
   chance  in  10   to  the fifteenth power that 15   random  points  will
   correlate with the Fish map as well as the Hill map does. However,  had
   he selected 15  out of a random sample of, say, 46 points in space, and
   had  he  simultaneously  selected the optimal vantage  point  in  three
   dimensions in order to maximize the resemblance, he could have achieved
   an  apparent correlation comparable to that which he claims between the
   Hill and Fish maps.  Indeed,  the statistical fallacy involved in  "the
   enumeration of favorable circumstances" leads necessarily to large, but
   spurious correlations.

     We again conclude that the Zeta Reticuli argument and the entire Hill
   story do not survive critical scrutiny.


     Dr.   Steven Soter is a research associate in astronomy and Dr.  Carl
   Sagan  is  director of the Laboratory for Planetary Studies,   both  at
   Cornell University in Ithaca, N.Y.





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