We show that AC^1 has no more power than arithmetic circuits of polynomial size and degree n^{O(log log n)} (improving the trivial bound of n^{O(log n)}). Connections are drawn between TC^1 and arithmetic circuits of polynomial size and degree.
Then we consider non-commutative computation, and show that some depth reduction is possible over the algebra (Sigma^*, max, concat), thus establishing that OptLOGCFL is in AC^1. This is the first depth-reduction result for arithmetic circuits over a noncommutative semiring, and it complements the lower bounds of Kosaraju and Nisan showing that depth reduction cannot be done in the general noncommutative setting.
We define new notions called ``short-left-paths'' and ``short-right-paths'' and we show that these notions provide a characterization of the classes of arithmetic circuits for which optimal depth-reduction is possible. This class also can be characterized using the AuxPDA model.
Finally, we characterize the languages generated by efficient circuits
over the (union, concat) semiring in terms of simple one-way machines,
and we investigate and extend earlier lower bounds on non-commutative
circuits.
Paper Available at:
ftp://dimacs.rutgers.edu/pub/dimacs/TechnicalReports/TechReports/1996/96-03.ps.gz
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