"Recently, it has been shown that synthesis of some circuits is quite difficult for conventional methods. In this paper we present a method of minimization of multi-level logic networks which can solve these difficult circuit instances. The synthesis problem is transformed on the search problem. A search algorithm called Cartesian genetic programming (CGP) is applied to synthesize various difficult circuits. Conventional circuit synthesis usually fails for these difficult circuits; specific synthesis processes must be employed to obtain satisfactory results. We have found that CGP is able to implicitly discover new efficient circuit structures. Thus, it is able to optimize circuits universally, regardless their structure. The circuit optimization by CGP has been found especially efficient when applied to circuits already optimized by a conventional synthesis. The total runtime is reduced, while the result quality is improved further more."@en . "Piscataway" . . "IEEE" . "[C063DB887B48]" . . "On Logic Synthesis of Conventionally Hard to Synthesize Circuits Using Genetic Programming" . . "Fi\u0161er, Petr" . "RIV/68407700:21240/10:00167768" . "RIV/68407700:21240/10:00167768!RIV14-MSM-21240___" . . "On Logic Synthesis of Conventionally Hard to Synthesize Circuits Using Genetic Programming"@en . . "4"^^ . "Schmidt, Jan" . . . "21240" . "6"^^ . . "Va\u0161\u00ED\u010Dek, Z." . "Proc. of the 13th IEEE Symposium on Design and Diagnostics of Electronic Circuits and Systems" . . "2"^^ . . "2010-04-14+02:00"^^ . . "Recently, it has been shown that synthesis of some circuits is quite difficult for conventional methods. In this paper we present a method of minimization of multi-level logic networks which can solve these difficult circuit instances. The synthesis problem is transformed on the search problem. A search algorithm called Cartesian genetic programming (CGP) is applied to synthesize various difficult circuits. Conventional circuit synthesis usually fails for these difficult circuits; specific synthesis processes must be employed to obtain satisfactory results. We have found that CGP is able to implicitly discover new efficient circuit structures. Thus, it is able to optimize circuits universally, regardless their structure. The circuit optimization by CGP has been found especially efficient when applied to circuits already optimized by a conventional synthesis. The total runtime is reduced, while the result quality is improved further more." . "Sekanina, L." . "P(GA102/09/1668), Z(MSM6840770014)" . "logic synthesis; multi-level network; genetic programming"@en . "On Logic Synthesis of Conventionally Hard to Synthesize Circuits Using Genetic Programming"@en . . . "978-1-4244-6613-9" . "On Logic Synthesis of Conventionally Hard to Synthesize Circuits Using Genetic Programming" . "Vienna" . . . . "10.1109/DDECS.2010.5491755" . "276742" . . . .