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Fractional Cascading and Its Applications

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Title: Fractional Cascading and Its Applications


1
Fractional Cascading and Its Applications
  • G. S. Lueker. A data structure for orthogonal
    range queries. In Proc. 19th annu. IEEE Sympos.
    Found. Comput. Sci., pages 28-34, 1978.
  • D. E. Willard. Predicate-oriented database search
    algorithms. Ph.D. thesis, Aiken Comput. Lab.,
    Harvard Univ., Cambridge, MA, 1978, Report
    TR-20-78.
  • B. Chazelle, L. J. Guibas Fractional Cascading
    I. A Data Structuring Technique. Algorithmica
    1(2) 133-162 (1986)
  • B. Chazelle, L. J. Guibas Fractional Cascading
    II. Applications. Algorithmica 1(2) 163-191
    (1986)

Slides by Dror Aiger
2
What is Fractional Cascading?
  • A technique to speed up a sequence of binary
    searches for the same value in a sequence of
    related data structures.
  • The first binary search in the sequence takes a
    logarithmic time, but successive searches in the
    sequence are faster.

3
A simple example
  • Let A1 and A2 be two sorted arrays of real
    numbers.
  • Problem report all numbers of A1 and A2 in the
    range y,y.
  • Solution binary search for first number y in
    A1, traverse until number is y. Same for A2.
  • Query time O(k) two binary searches.
  • What if numbers in A2 are a subset of A1?

4
Adding pointers
  • We add pointers from the entries in A1 to the
    entries in A2 (in the preprocess stage).
  • Binary search for first number y in A1.
  • Store pointer from that number to array A2.
  • Traverse A1 until number is y.
  • Traverse A2 from pointer until number is y.
  • Query time one binary search on A1, plus
    reporting k numbers.

5
Adding pointers - example
6
Application in Range Searching
  • In the plane the query time of range trees is
    O(log2(n)k).
  • Can we do better?
  • Yes, we can obtain O(log(n)k) query time with
    fractional cascading.

7
A reminder a range tree
8
A reminder Canonical sets
  • We store the points in the set P in a balanced
    binary tree T, using the xcoordinates as keys.
  • Each node v of T is associated with a canonical
    set P(v), which is the set of all the points in P
    that are stored in the sub tree rooted at v

9
The idea
  • When processing a query xxxy,y, we search
    some trees with the same keys.
  • For each such tree we spend O(log(n)) time in
    standard range tree.
  • P(lc(v)) and P(rc(v)) are subsets of P(v).
  • We will keep pointers between nodes of T(v) and
    nodes of lc(v) and rc(v) that keep the same key,
    or the next smallest key.
  • After performing a search in T(v) this will allow
    to perform a search in lc(v) and rc(v) in O(1)
    time.

10
The data structure
  • Each canonical subset P(v) is stored in an array
    A(v).
  • Each entry of A(v) stores two pointers
  • A pointer into A(lc(v)) and a pointer into
    A(rc(v)).
  • Let A(v)i stores a point p - we store a pointer
    from A(v)i to the entry of A(lc(v)) such that
    the y-coordinate of the point stored there is the
    smallest one larger than or equal to py.

11
Layered range tree example
12
Query
  • We search with x and x in the main tree T to
    determine O(log(n)) nodes whose canonical subsets
    together contain the points with x-coordinate in
    xx.
  • Let the path splits at v we find the entry in
    A(v) whose y-coordinate is the smallest one
    larger than or equal to y (O(log(n) with binary
    search).
  • While we search further with x and x in the main
    tree we keep track of the entry in the associated
    arrays.
  • They can be maintained in constant time by
    following the pointers.
  • If v is one of the O(log(n)) nodes we selected,
    we have to report the points stored in A(v) whose
    y-coordinate is in yy and this is done in
    O(1kv) by walking through the array, where kv is
    the number of points reported at v.
  • The total time now becomes O(log(n)k)

13
Consequences
  • By induction, it also improves by a factor of
    O(log(n)) the results in d gt 2.
  • Range trees with fractional cascading in d 2
    yield query time O(k logd-1(n)).
  • Space usage O(n logd-1n).
  • Preprocessing time O(n logd-1(n)).
  • In d 2, the query time and preprocessing time
    are optimal, but space usage is not.

14
Another application
  • Intersecting a polygonal path with a line
  • CG86 Bernard Chazelle, Leonidas J. Guibas
    Fractional Cascading II. Applications.
    Algorithmica 1(2) 163-191 (1986)

15
Intersecting a polygonal path with a line
  • We are given a polygonal path P and we wish to
    preprocess it into a data structure so that given
    any query line l, we can quickly report all the
    intersections of P and l.
  • The idea is based on recursive application of the
    following
  • A straight line l intersects a polygonal line P
    if and only if it intersects the convex hull of
    P.
  • The convex hulls is computed (recursively) in the
    preprocess stage.
  • In each step we compute the CH of the first and
    second halves of the current polyline (F(P) and
    S(P)) This takes O(n log(n)) time and space.
  • We have a balanced binary tree T

16
Query
  • The query is simple

17
Intersecting a polygonal path with a line
  • This still gives O(log2n) query time since we
    need logarithmic time for each convex hull and we
    have at least log(n) such operations
  • We need some tools to be able to use fractional
    cascading
  • Slope Sequence of convex polygon C is a (unique)
    circular permutation of the edges of C such that
    the slopes are non decreasing (it is well known
    that it exists).
  • Finding intersection can be done in constant time
    in this sequence if we know the positions of the
    slopes of l.
  • We view each node x, of T as containing the slope
    sequence of the convex polygon associated with x
    and apply fractional cascading to these
    structures.
  • Any time we need to decide whether to descent to
    a subtree, we look up the slopes of l in that
    subtree roots sequence and find the answer in
    constant time (we still have the logarithmic time
    for the root of T).

18
Intersecting a polygonal path with a line
  • We thus get O(log n size of the subtree of T
    actually visited) query time.
  • This can be shown CG86 to be O((k1)log(n/(k1))
    ) where k is the number of intersections.
  • The size and preprocessing time of the structure
    is O(nlog(n))
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