Wireless sensor networks are formed by numerous sensor nodes comprising processors, communication interfaces and sensors. Due to the limited energy for the sensor nodes, a variety of energy-efficient issues of WSNs have raised in studies. Among these issues, the energy-efficient coverage issue in wireless sensor networks (WSNs) has drawn much attention in recent years. The focus of the energy-efficient coverage issue is how to sustain a full coverage and a longer network lifetime. In order to cover a set of points of interest (POIs) with known locations in a remote sensing field (i.e., achievement of full coverage), generally, the possible solution is to deploy sensor nodes remotely from an aircraft or deploy some nodes nearby the POIs in a non-deterministic manner. In the case of node deployment, therefore, it is critical to implement judicious management for these sensor nodes deployed randomly with energy efficiency designs. Hence, the long-term full coverage surveillance can be ensured. In order to meet such the energy-efficient coverage requirements described above, in Chapter 2, a coverage control using memetic algorithm (CoCMA) to find the redundant sensor nodes and inactivate them (in a sleeping mode) for a deployed WSN is presented. Only fewer necessary nodes remain inactive to cooperate to monitor whole POIs. Afterwards, the lack of coverage could be compensated, since some of the sleeping nodes would be awaked by a sink node performing a Wake-Up scheme. In Chapter 3, a hybrid framework for coverage optimization (HyFCO) to tackle the energy-efficient coverage issue is presented. First, the HyFCO allows disjoint sets with a maximal size. Every disjoint set is composed of some of sensor nodes which cooperate to cover all POIs. The HyFCO activates the disjoint set successively, and thus the energy-efficient full coverage requirement can be met. Once coverage holes which are caused by energy depletion of sensor nodes in a disjoint set are found, the HyFCO would utilize a heuristic recursive algorithm (HRA) to rapidly repair the lost coverage. Both the presented CoCMA and HyFCO are evaluated via computer simulations and/or real-world tests. The experimental results show that the proposed algorithms outperform existing approaches.