This article includes a list of references, related reading, or external links, but its sources remain unclear because it lacks inline citations. Please help to improve this article by introducing more precise citations. (March 2021) (Learn how and when to remove this template message)

Exponential tree

tree

Invented

1995

Invented by

Arne Andersson

Time complexity in big O notation
Operation	Average	Worst case
Search	O(min(√log n, log n/log w+ log log n, log w log log n))	O(min(√log n, log n/log w+ log log n, log w log log n))
Insert	O(min(√log n, log n/log w+ log log n, log w log log n))	O(min(√log n, log n/log w+ log log n, log w log log n))
Delete	O(min(√log n, log n/log w+ log log n, log w log log n))	O(min(√log n, log n/log w+ log log n, log w log log n))
Space complexity
Space	O(n)	O(n)

An exponential tree is a type of search tree where the number of children of its nodes decreases doubly-exponentially with increasing depth. Values are stored only in the leaf nodes. Each node contains a splitter, a value less than or equal to all values in the subtree which is used during search. Exponential trees use another data structure in inner nodes containing the splitters from children, allowing fast lookup.

Exponential trees achieve optimal asymptotic complexity on some operations. They have mainly theoretical importance.

Tree structure

An exponential tree is a rooted tree where every node contains a splitter and every leaf node contains a value. The value may be different from the splitter. An exponential tree with $n$ values is defined recursively:

The root has $\Theta (n^{1/k})$ children
The splitter of the root is the same as the splitter of the leftmost child
The splitters of all children are stored in a local data structure
The subtrees are exponential trees with $\Theta (n^{1-1/k})$ values

An additional condition is that searching for a value using the splitters must yield the correct node (i.e. the one containing the value). Therefore, if a root of a subtree contains the splitter $s$ and it's right sibling contains the splitter $s'$ , then this subtree can only contain keys in the range $[s,s')$ .

Local data structure

The tree uses a static data structure in every inner node to allow fast lookup of values. It must be possible to build this structure with $d$ values in time $O(d^{k-1})$ . The lookup time in this structure is denoted $S(d)$ .

A Fusion tree can be used as this data structure.

Operations

Search

The exponential tree can be searched in the same way as a normal search tree. In each node, the local data structure can be used to find the next child quickly.

Let $T(n)$ denote the time complexity of the search. Then it satisfies the following recurrence:

$T(n)\leq T(n^{1-1/k})+O(S(n))$

Insert

Delete

References

Andersson, Arne (October 1996). "Faster deterministic sorting and searching in linear space". Proceedings of 37th Conference on Foundations of Computer Science. pp. 135–141. doi:10.1109/SFCS.1996.548472. ISBN 0-8186-7594-2. S2CID 13603426.
Andersson, Arne; Thorup, Mikkel (2007-06-01). "Dynamic ordered sets with exponential search trees". Journal of the ACM. 54 (3): 13–es. arXiv:cs/0210006. doi:10.1145/1236457.1236460. ISSN 0004-5411. S2CID 8175703.

v t e Tree data structures
Search trees (dynamic sets/associative arrays)	2–3 2–3–4 AA (a,b) AVL B B+ B* B^x (Optimal) Binary search Dancing HTree Interval Order statistic (Left-leaning) Red–black Scapegoat Splay T Treap UB Weight-balanced
Heaps	Binary Binomial Brodal Fibonacci Leftist Pairing Skew van Emde Boas Weak
Tries	Ctrie C-trie (compressed ADT) Hash Radix Suffix Ternary search X-fast Y-fast
Spatial data partitioning trees	Ball BK BSP Cartesian Hilbert R k-d (implicit k-d) M Metric MVP Octree PH Priority R Quad R R+ R* Segment VP X
Other trees	Cover Exponential Fenwick Finger Fractal tree index Fusion Hash calendar iDistance K-ary Left-child right-sibling Link/cut Log-structured merge Merkle PQ Range SPQR Top