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Complex polynomials and circuit lower bounds for modular counting (1994)

Barrington, David A. Mix ; Straubing, Howard

Springer

Computational complexity 4 (1994), S. 325-338

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ISSN: 1420-8954

Keywords: Circuit complexity ; threshold circuits ; modular counting ; 68Q05 ; 68Q25 ; 68Q40

Source: Springer Online Journal Archives 1860-2000

Topics: Computer Science

Notes: Abstract We study the power of constant-depth circuits containing negation gates, unbounded fan-in AND and OR gates, and a small number of MAJORITY gates. It is easy to show that a depth 2 circuit of sizeO(n) (wheren is the number of inputs) containingO(n) MAJORITY gates can determine whether the sum of the input bits is divisible byk, for any fixedk〉1, whereas it is known that this requires exponentialsize circuits if we have no MAJORITY gates. Our main result is that a constant-depth circuit of size $$2^{n^{o(1)} } $$ containingn o(1) MAJORITY gates cannot determine if the sum of the input bits is divisible byk; moreover, such a circuit must give the wrong answer on a constant fraction of the inputs. This result was previously known only fork=2. We prove this by obtaining an approximate representation of the behavior of constant-depth circuits by multivariate complex polynomials.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01263421

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Representing Boolean functions as polynomials modulo composite numbers (1994)

Barrington, David A. Mix ; Beigel, Richard ; Rudich, Steven

Springer

Computational complexity 4 (1994), S. 367-382

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ISSN: 1420-8954

Keywords: Complexity of finite functions ; circuit complexity ; computation by polynomials ; relativized complexity ; 68Q15 ; 68Q40

Source: Springer Online Journal Archives 1860-2000

Topics: Computer Science

Notes: Abstract Define the MOD m -degree of a boolean functionF to be the smallest degree of any polynomialP, over the ring of integers modulom, such that for all 0–1 assignments $$\vec x$$ , $$F(\vec x) = 0$$ iff $$P(\vec x) = 0$$ . We obtain the unexpected result that the MOD m -degree of the OR ofN variables is $$O(\sqrt[\tau ]{N})$$ , wherer is the number of distinct prime factors ofm. This is optimal in the case of representation by symmetric polynomials. The MOD n function is 0 if the number of input ones is a multiple ofn and is one otherwise. We show that the MOD m -degree of both the MOD n and $$\neg MOD_n$$ functions isN Ω(1) exactly when there is a prime dividingn but notm. The MOD m -degree of the MOD m function is 1; we show that the MOD m -degree of $$\neg MOD_m$$ isN Ω(1) ifm is not a power of a prime,O(1) otherwise. A corollary is that there exists an oracle relative to which the MOD m P classes (such as ⊕P) have this structure: MOD m P is closed under complementation and union iffm is a prime power, and MOD n P is a subset of MOD m P iff all primes dividingn also dividem.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01263424

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