This lecture discusses the duality principle in linear algebra, focusing on finite sets and linear maps. The instructor begins by defining finite sets M and N, and introduces a matrix that defines a linear map from one space to another. The concept of operator norms is explained, emphasizing the relationship between the original map and its adjoint. The duality principle is established, stating that the operator norm of the adjoint equals that of the original map. The proof involves using the Cauchy-Schwarz inequality and exploring the implications of this principle in terms of inequalities for vectors in the respective spaces. The lecture further delves into the additive large sieve inequality, demonstrating how to bound sums involving these linear maps. The instructor employs a smoothing trick and the Poisson summation formula to facilitate the proof, ultimately concluding with the implications of the results in number theory. The lecture is rich in mathematical concepts and proofs, providing a comprehensive understanding of the duality principle and its applications.