Quantum observable

Over the last decade, many researchers have studied the implementation of quantum systems and the states of the quantum systems. Most of the focus has been on the quantum states strategy. Researchers have found it to be more advanced than classical strategies. Complementary quantum Observables interaction and information are the most important features that are refereed by Observables. This shows us how uniquely these features can define a packet of information in mathematical terms as a state. Also, it provides technological information that indeed captures the properties of quantum systems. In this paper, we demonstrate how to implement certain logical methods in quantum computing to obtain more accurate information than classical computing systems provide. This new methodology can make the computation more efficient. First, we examine the photons and consider the various spin states, and then we consider the direction of the spinning photons to handle more information. Next, we use the unique property of photons to behave both as a wave and a particle and exploit it by passing the photon through mirrors and beam splitters to demonstrate and achieve results that are not possible in the classical world.