Delay Minimization in Sliced Multi-Cell Mobile Edge Computing (MEC) Systems

Here, we consider the problem of jointly optimizing users' offloading decisions, communication and computing resource allocation in a sliced multi-cell mobile edge computing (MEC) network. We minimize the weighted sum of the gap between the observed delay at each slice and its corresponding delay requirement, where weights set the priority of each slice. Fractional form of the objective function, discrete subchannel allocation, considered partial offloading, and the interference incorporated in the rate function, make the considered problem a complex mixed integer non-linear programming problem. Thus, we decompose the original problem into two sub-problems: (i) offloading decision-making and (ii) joint computation resource, subchannel, and power allocation. We solve the first sub-problem optimally and for the second sub-problem, leveraging on novel tools from fractional programming and Augmented Lagrangian method, we propose an efficient algorithm whose computational complexity is proved to be polynomial. Using alternating optimization, we solve these two sub-problems iteratively until convergence is obtained. Simulation results demonstrate the convergence of our proposed algorithm and its effectiveness compared to existing schemes.

Automated summary

This study focuses on optimizing users' offloading decisions, communication, and computing resource allocation in a sliced multi-cell mobile edge computing network. By decomposing the original problem into two sub-problems and leveraging novel tools, an efficient algorithm is proposed to solve this complex mixed integer non-linear programming problem. Simulation results demonstrate the convergence and effectiveness of the proposed algorithm compared to existing schemes.