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Astronomicum Caesareum

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Astronomicum Caesareum The astronomy of the Emperors Recreating the astronomy of the Renaissance Produced by the Unilab Project at the California Institute of Technology – PowerPoint PPT presentation

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Title: Astronomicum Caesareum


1
Astronomicum Caesareum
The astronomy of the Emperors
  • Recreating the astronomy of the Renaissance

Produced by the Unilab Project at the California
Institute of Technology with assistance from the
Digital Media Center and the SURF
Program. www.unilab.caltech.edu
2
  • This system introduces a central aspect of
    astronomical practice during the Renaissance.
  • We will retrace the steps by which an astronomer
    found the position of a planet for a given date.
  • To do so, we will use a sophisticated scientific
    instrument - but one made out of paper and bound
    into a book. This is Peter Apians 1540
    Astronomicum Caesareum (Astronomy of the
    Emperors).

3
  • Apians volume, perhaps the most beautiful of all
    early scientific books, used the principles of
    the ancient astronomer Claudius Ptolemy. Those
    principles dated back to antiquity, and they
    remained definitive until Copernicus argued that
    the Earth orbited the Sun in his On the
    Revolutions (1543).
  • Issued just three years before Copernicuss great
    work, Apians book thus marked the pinnacle of
    more than a millennium of scientific practice.

4
  • A Renaissance astronomers main duty was to
    predict where a planet would be on any given
    date. In particular, he wanted to know its
    longitude its position on the great circle
    called the ecliptic (or Zodiac) that spanned the
    heavens and was divided into the twelve signs
    still familiar to us today.
  • This picture shows the ecliptic as portrayed by
    seventeenth-century map-maker Johann Blaeu.

5
  • Astronomers assumed that the earth was motionless
    at (or very near) the center of the cosmos.
  • They then reckoned that a planets apparent
    movements around the earth resulted from the
    combined motions of at least two circles. The
    first of these was called the deferent. The
    planet itself moved on the rim of an epicycle
    that moved around the deferents circumference.

6
  • But astronomers found they needed to use two more
    techniques.
  • First, they said that the deferent circle could
    be eccentric - that is, the earth could be
    slightly off-center.
  • Second, they invented the equant. This was a
    separate point in space, about which the
    deferents motion was regular.
  • Apians book allows us to retrace how all these
    concepts were used.

7
  • Apian simplified the astronomers task by
    building for each planet a device called an
    equatorium.
  • An equatorium was a kind of circular slide-rule
    or, if you prefer, a Renaissance computer.
  • It reproduced in physical form all the
    mathematical concepts of astronomy - the
    epicycle, the eccentric deferent, and the equant
    point.

8
  • This image shows Marss equatorium in its
    starting position. It is composed of seven
    rotating disks.
  • We will use this equatorium to discover where
    Mars was on February 23, 1500 - the birthday of
    Apians own imperial patron, the Holy Roman
    Emperor, Charles V.
  • In doing this we are reproducing the steps taken
    by Apian himself when he did this calculation in
    1540.

9
First, however, we need to take account of
precession. Precession is a very slow movement -
less than 1 per century - that all stars and
planets appear to share. (We now know that it
comes from a variation in the Earths own
rotation.) To incorporate precession into our
procedure, we use this planisphere - a movable
map of the universe.
10
Incorporating the precession for 1500 means
deciding where to place Marss line of apsides.
This is the straight line on which the equant
point, the center of Marss deferent circle, and
the Earths center all lie. We can find where
this line lies by rotating the blue disk and
looking at the positions of the pointers on its
edge.
11
Step 1 First, we rotate the disk so that the tab
on the far right (which is marked X) matches
the 1500 point on a scale beneath the disk.
12
Step 2 Now we extend a thread from the center of
the disk through the 1500 point on a small oval
scale printed on the face of the disk. This
scale is called a trepidation oval. It provides
for an extremely slow variation in the rate of
precession that medieval astronomers thought they
had observed. It is now known that trepidation
does not exist.
13
Step 3 Now we rotate the disk again so that the
second pointer, marked AUX Communis, meets the
thread.
14
Step 4 Now we read off the location of the
pointer to the top left of the disk, which is
marked with the symbol for Mars, ?. Its location
is 15 in the sign of Leo. We will need to
remember this and use it later. Marss line of
apsides will point to this location.
15
  • Now we turn to the equatorium itself.

16
  • Step 5
  • First, we rotate the outer disk so that its
    pointer indicates 18331 - a value obtained from
    a separate table.
  • This sets the basic position of the deferent for
    1400.
  • We now need to move it further to take account of
    99 more completed years, plus the 53 days
    sufficient to bring us to February 23.

17
  • Step 6
  • To advance 99 years, we use a scale on the edge
    of the outer disk.
  • We find the point on this scale marked 99. Then
    we extend a thread from the Earth through this
    point.

18
  • Step 7
  • Now we rotate the outer disk until its marker
    meets this thread.
  • We have set the deferent for the end of 1499.
  • We now need to add the remaining days.

19
  • Step 8
  • This we do by using a second scale on the outer
    disk (here it is hidden beneath the next disk).
  • We find the point on this scale corresponding to
    February 23.
  • Then we extend the thread from the Earth to cross
    this point.

20
  • Step 9
  • Now we rotate the outer disk until its pointer
    meets the thread.
  • The deferent is now set for the correct date.
  • Next, we need to incorporate precession, which we
    found earlier to be 15 in the sign of Leo.

21
  • Step 10
  • To do this, we move to the second disk, and
    rotate it so that its pointer moves to 15 in Leo
    - the value we found earlier using the
    planisphere.
  • Note that the small central disk rotates in line
    with this second disk. This means that by moving
    the second disk, we are indeed setting the line
    on which the earth and the equant lie. This is
    the line of apsides.

22
  • Step 11
  • We now need to take this amount of precession
    into account in setting the actual deferent disk
    - our third disk, and the one which carries the
    epicycle.
  • We do this by tracing one of the oblique lines
    from the first disks pointer to the scale on the
    inside of the second. There we find a value of
    8 in the sign of Aquarius (or 308). We extend
    a thread from the equant through this point.

23
  • Step 12
  • This is where the center of the epicycle must go.
  • So we rotate the third disk, the deferent, until
    the center of the epicyle falls on our thread.

24
  • Step 13
  • Then we rotate the outer of the two epicycle
    disks so that its zero point marked with a
    cross, ? - also meets this line.
  • This means that the epicycle is correctly placed
    for 0 AD.
  • We are now ready to introduce the epicycles
    motion for the period between 0 AD and February
    23, 1500.

25
  • Step 14
  • First, we rotate the inner epicycle disk so that
    its pointer indicates 105 on the scale on the
    outer disk. The value of 105 is obtained from
    separate tables, and corresponds to the total
    rotation for 1400 years.
  • This sets the epicycle to its position for 1400
    AD.
  • We now need to add 99 years plus the days
    corresponding to February 23.

26
  • Step 15
  • Next, we locate the point on the scale of the
    inner epicycle disk marked 99.
  • We extend a thread from the center of the
    epicycle through this point.

27
  • Step 16
  • Now we rotate the epicycles index until it meets
    our thread.
  • The epicycle is now in position for the end of
    1499.

28
  • Step 17
  • Now we located the point on the inner scale of
    the inner epicycle disk that corresponds to
    February 23.
  • We extend the thread from the center of the
    epicycle through this point.

29
  • Step 18
  • Then we rotate the disk until the epicycles
    pointer meets our thread.
  • The pointer is now at 20 in the 8th sign (260).
  • The disks are now in place to reveal the position
    of the planet Mars on the Emperors birthday.

30
  • Step 19
  • The planet Mars is indicated by a rosette printed
    on the pointer on the inner epicycle disk.
  • To find its observed place from the Earth, we
    extend a thread from the Earth, through the
    center of this rosette, to the Zodiac scale
    printed on the page itself.

31
  • Step 20
  • This gives a reading of 54 (or 24 in the sign
    of Taurus).
  • This, then, is where Mars will appear in the
    Zodiac on Charles Vs birthday, February 23,
    1500.

32
Here you can see where Mars actually was on the
evening of February 23, 1500. The red cross marks
the position that we have just calculated using
Apians procedure. It is within a degree or so
of the actual position. (The green line is the
ecliptic.) Apians book could clearly produce a
remarkably accurate prediction.
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