 cryptography or cryptology from Ancient Greek, Platinum, Translate, cryptos hidden, secret, and F.E. Grafian, to write, or, D.L.G.I.A., study, respectively one is the practice and study of techniques for secure communication in the presence of third parties called adversaries. To more generally, cryptography is about constructing and analyzing protocols that prevent third parties for the public from reading private messages through various aspects and information security such as data confidentiality, data integrity, authentication, and non-repudiation for our central to modern cryptography. Modern cryptography exists at the intersection of the disciplines of mathematics, computer science, electrical engineering, communication science, and physics. Applications of cryptography include electronic commerce, chip-based payment cards, digital currencies, computer passwords, and military communications. Cryptography prior to the modern age was effectively synonymous with encryption, the conversion of information from a readable state to a parent-nonsense. The originator of an encrypted message shared the decoding technique needed to recover the original information only with intended recipients, thereby precluding unwanted persons from doing the same. The cryptography literature often uses the name Alice A. for the sender, Bob B. for the intended recipient, and E.P.'s dropper for the adversary.5 since the development of rotor cipher machines in World War I and the advent of computers in World War II, the methods used to carry out cryptology have become increasingly complex and its application more widespread. Modern cryptography is heavily based on mathematical theory and computer science practice. Cryptographic algorithms are designed around computational hardness assumptions, making such algorithms hard to break in practice by any adversary. It is theoretically possible to break such a system, but it is infeasible to do so by any known practical means. These schemes are therefore termed computationally secured, theoretical advances, e.g., improvements in integer factorization algorithms, and faster computing technology require these solutions to be continually adapted. There exist information theoretically secure schemes that probably cannot be broken even with unlimited computing power. An example is the one-time pad, but these schemes are more difficult to implement than the best theoretically breakable but computationally secure mechanisms. The growth of cryptographic technology has raised a number of legal issues in the information age. Cryptography's potential for use as a tool for SPN edge and sedition has led many governments to classify it as a weapon and to limit or even prohibit its use and export.6 in some jurisdictions where the use of cryptography is legal, laws permit investigators to compel the disclosure of encryption. Keys for documents relevant to an investigation.7a cryptography also plays a major role in digital rights management and copyright infringement of digital media.9.