Tool used in probabilistic polynomial identity testing
In mathematics, the Schwartz–Zippel lemma (also called the DeMillo–Lipton–Schwartz–Zippel lemma) is a tool commonly used in probabilistic polynomial identity testing. Identity testing is the problem of determining whether a given multivariate polynomial is the
0-polynomial, the polynomial that ignores all its variables and always returns zero. The lemma states that evaluating a nonzero polynomial on inputs chosen randomly from a large-enough set is likely to find an input that produces a nonzero output.
be a non-zero polynomial of total degreed ≥ 0over an integral domain R. Let S be a finite subset of R and letr1, r2, ..., rnbe selected at random independently and uniformly from S. Then
Equivalently, the Lemma states that for any finite subset S of R, if Z(P) is the zero set of P, then
Proof. The proof is by mathematical induction on n. For n = 1, P can have at most d roots by the fundamental theorem of algebra. This gives us the base case.
Now, assume that the theorem holds for all polynomials in n − 1 variables. We can then consider P to be a polynomial in x1 by writing it as
Since P is not identically 0, there is some i such that is not identically 0. Take the largest such i. Then , since the degree of is at most d.
Now we randomly pick from S. By the induction hypothesis,
If , then is of degree i (and thus not identically zero) so
If we denote the event by A, the event by B, and the complement of B by , we have
Applications
The importance of the Schwartz–Zippel Theorem and Testing Polynomial Identities follows
from algorithms which are obtained to problems that can be reduced to the problem
of polynomial identity testing.
Zero testing
For example, is
To solve this, we can multiply it out and check that all the coefficients are 0. However, this takes exponential time. In general, a polynomial can be algebraically represented by an arithmetic formula or circuit.
Comparison of two polynomials
Given a pair of polynomials and , is
?
This problem can be solved by reducing it to the problem of polynomial identity testing. It is equivalent to checking if
Hence if we can determine that
where
then we can determine whether the two polynomials are equivalent.
Comparison of polynomials has applications for branching programs (also called binary decision diagrams). A read-once branching program can be represented by a multilinear polynomial which computes (over any field) on {0,1}-inputs the same Boolean function as the branching program, and two branching programs compute the same function if and only if the corresponding polynomials are equal. Thus, identity of Boolean functions computed by read-once branching programs can be reduced to polynomial identity testing.
Comparison of two polynomials (and therefore testing polynomial identities) also has
applications in 2D-compression, where the problem of finding the equality of two
2D-texts A and B is reduced to the problem
of comparing equality of two polynomials and .
A simple randomized algorithm developed by Manindra Agrawal and Somenath Biswas can determine probabilistically
whether is prime and uses polynomial identity testing to do so.
They propose that all prime numbers n (and only prime numbers) satisfy the following
polynomial identity:
Then iff n is prime. The proof can be found in [4]. However,
since this polynomial has degree , where may or may not be a prime,
the Schwartz–Zippel method would not work. Agrawal and Biswas use a more sophisticated technique, which divides
by a random monic polynomial of small degree.
Prime numbers are used in a number of applications such as hash table sizing, pseudorandom number
generators and in key generation for cryptography. Therefore, finding very large prime numbers
(on the order of (at least) ) becomes very important and efficient primality testing algorithms
are required.
A subset D of E is called a matching if each vertex in V is incident with at most one edge in D. A matching is perfect if each vertex in V has exactly one edge that is incident to it in D. Create a Tutte matrixA in the following way:
where
The Tutte matrix determinant (in the variables xij, ) is then defined as the determinant of this skew-symmetric matrix which coincides with the square of the pfaffian of the matrix A and is non-zero (as polynomial) if and only if a perfect matching exists.
One can then use polynomial identity testing to find whether G contains a perfect matching. There exists a deterministic black-box algorithm for graphs with polynomially bounded permanents (Grigoriev & Karpinski 1987).[5]
if the first m rows (resp. columns) are indexed with the first subset of the bipartition and the last m rows with the complementary subset. In this case the pfaffian coincides with the usual determinant of the m × m matrix X (up to sign). Here X is the Edmonds matrix.
Currently, there is no known sub-exponential time algorithm that can solve this problem deterministically. However, there are randomized polynomial algorithms whose analysis requires a bound on the probability that a non-zero polynomial will have roots at randomly selected test points.
Grigoriev, Dima; Karpinski, Marek (1987). "The matching problem for bipartite graphs with polynomially bounded permanents is in NC". Proceedings of the 28th Annual Symposium on Foundations of Computer Science (FOCS 1987), Los Angeles, California, USA, 27-29 October 1987. IEEE Computer Society. pp. 166–172. doi:10.1109/SFCS.1987.56. ISBN978-0-8186-0807-0. S2CID14476361.
Zippel, Richard (1979). "Probabilistic algorithms for sparse polynomials". In Ng, Edward W. (ed.). Symbolic and Algebraic Computation, EUROSAM '79, An International Symposiumon Symbolic and Algebraic Computation, Marseille, France, June 1979, Proceedings. Lecture Notes in Computer Science. Vol. 72. Springer. pp. 216–226. doi:10.1007/3-540-09519-5_73. ISBN978-3-540-09519-4.