This paper presents a novel framework for graded neural networks (GNNs) built over graded vector spaces \V\wn, extending classical neural architectures by incorporating algebraic grading. Leveraging a coordinate-wise grading structure with scalar action λ⋆\x=(λqixi), defined by a tuple \w=(q0,…,qn−1), we introduce graded neurons, layers, activation functions, and loss functions that adapt to feature significance. Theoretical properties of graded spaces are established, followed by a comprehensive GNN design, addressing computational challenges like numerical stability and gradient scaling. Potential applications span machine learning and photonic systems, exemplified by high-speed laser-based implementations. This work offers a foundational step toward graded computation, unifying mathematical rigor with practical potential, with avenues for future empirical and hardware exploration.