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Forbes, Michael A. [Author]; Ghosh, Sumanta [Author]; Saxena, Nitin [Author] ; Michael A. Forbes and Sumanta Ghosh and Nitin Saxena [Contributor]

Towards Blackbox Identity Testing of Log-Variate Circuits

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  • Media type: Text; E-Article; Electronic Conference Proceeding
  • Title: Towards Blackbox Identity Testing of Log-Variate Circuits
  • Contributor: Forbes, Michael A. [Author]; Ghosh, Sumanta [Author]; Saxena, Nitin [Author]
  • Published: Schloss Dagstuhl – Leibniz-Zentrum für Informatik, 2018
  • Language: English
  • DOI: https://doi.org/10.4230/LIPIcs.ICALP.2018.54
  • Keywords: diagonal ; cone closed ; concentration ; depth-3 ; polynomial identity testing ; hitting-set ; log-variate ; basis isolation ; derandomization
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  • Description: Derandomization of blackbox identity testing reduces to extremely special circuit models. After a line of work, it is known that focusing on circuits with constant-depth and constantly many variables is enough (Agrawal,Ghosh,Saxena, STOC'18) to get to general hitting-sets and circuit lower bounds. This inspires us to study circuits with few variables, eg. logarithmic in the size s. We give the first poly(s)-time blackbox identity test for n=O(log s) variate size-s circuits that have poly(s)-dimensional partial derivative space; eg. depth-3 diagonal circuits (or Sigma wedge Sigma^n). The former model is well-studied (Nisan,Wigderson, FOCS'95) but no poly(s2^n)-time identity test was known before us. We introduce the concept of cone-closed basis isolation and prove its usefulness in studying log-variate circuits. It subsumes the previous notions of rank-concentration studied extensively in the context of ROABP models.
  • Access State: Open Access