Semnan UniversityInternational Journal of Nonlinear Analysis and Applications2008-682212120210201New formula to calculate the number of designs in RADG cryptosystem821829493710.22075/ijnaa.2021.4937ENLaith MKadhumFaculty of Computing College of Computing and Applied Sciences, Universiti Malaysia Pahang 26600 Pekan, Pahang
Darul Makmur, Malaysia;
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University of Kufa, Najaf, IraqAhmadFirdausaFaculty of Computing College of Computing and Applied Sciences, Universiti Malaysia Pahang 26600 Pekan, Pahang
Darul MakmurMohamad FadliZolkiplibSchool of Computing, UUM College Arts Sciences, Universiti Utara Malaysia, 06010 UUM Sintok, Kedah Darul Aman,
MalaysiaLuaySaferaliaFaculty of Computing College of Computing and Applied Sciences, Universiti Malaysia Pahang 26600 Pekan, Pahang
Darul Makmur, MalaysiaMohd FaizalAb RazakaaFaculty of Computing College of Computing and Applied Sciences, Universiti Malaysia Pahang 26600 Pekan, Pahang
Darul Makmur, MalaysiaJournal Article20210324Reaction automata direct graph (RADG) is a new technique that uses the automata direct graph method to represent a certain design for encryption and decryption. Jump states are available in the RADG design that enables the encipher to generate different ciphertexts each time from the same plaintext and wherein not a single ciphertext is related to a certain plaintext. This study created a matrix representation for RADG designs that allows the calculation of the number of cases ($F_{Q}$)mathematically possible for any design of the set $Q$. $F_{Q}$ is an important part of the function $\mathrm{F}(\mathrm{n}, \mathrm{m}, \lambda)$ that calculates the total number of cases of a certain design for the values $Q, R, \sum, \psi, J$ and $T$. This paper produces a mathematical equation to calculate $F_{Q}$.https://ijnaa.semnan.ac.ir/article_4937_b6e64e5cff8598689fde19555e463fac.pdf