Load-balancing algorithms play a key role in improving the performance of distributed computing systems that consist of heterogeneous nodes with different capacities. The performance of load balancing algorithms and its convergence rate deteriorate as the number of nodes in the system, the network-diameter, the communication-overhead increase. Moreover, the load-balancing technical factors, such as the load migration rule, significantly affect the performance of rebalancing the load among nodes. Therefore, we propose an approach that improves the performance of load-balancing algorithms by considering both the load-balancing technical-factors and the structure of the network that executes the algorithm. We present the design of an overlay network, namely, Functional Small World (FSW) that facilitates efficient load-balancing in heterogeneous systems. FSW is based on two innovative ideas: 1) small world network; and 2) functional similarity. Nodes in FSW are clustered according to the similarity of their Functional Sets (FS) and organized as a small world overlay network. The FSW achieves the efficiency by reducing the number of nodes that exchange their information, deteriorating the network diameter, minimizing the communication-overhead, and decreasing the time-delay results from tasks re-migration process. We then propose an improved load-balancing algorithm that will be effectively executed within the constructed FSW, where nodes consider the capacity and calculate the average effective-load. We compare our approach with two significant diffusion methods presented in the literature, the nearest neighbor algorithm and the original neighborhood algorithm. The simulation results indicate that our approach considerably outperformed the mentioned approaches in terms of response time, throughput, communication overhead, and movements cost. Finally, we prove that the proposed approach converges to the state of fairness where the effective-load in all nodes is the same since each node receives an amount of workload proportional to its processing capacity. Therefore, we conclude that this approach has the advantage of being fair, simple and no node is privileged.