Remote sensing technologies efficiently obtain information such as images and lidar point clouds of land covers to assist land use management. Images provide 2-D spectral information; while lidar point clouds present 3-D spatial information of land covers. The two complementary data can be beneficial for cover identification if they are appropreately integrated. Moreover, compared with pixel-based classfication, the object-based classification features more complete shape for land cover identification. 　　Integrating multisource data of remote sensing, for example, integration of multispectral/hyperspectral image and lidar, enables different types of features and wider applications. Furthermore, the hybrid approach classification is considered more flexible than traditional ones. Given the above advantages, this study aims to combine the spectral and lidar features to creat hybrid approach and object-based classification so that to illuminate merits of each under different features and spectral resolutions. 　　The examined data included hyperspectral imagery from ITRES CASI 1500, multispectral imagery from WorldView-2, and lidar data from Optech ALTM Pegasus. Spectral features were MNF, NDVI, and texture image; Lidar features included intensity, echo ratio, and nDSM. The proposed scheme incorporated four main steps: (1) defining 9 land covers in the studied area, (2) training area selection, (3) feature assessment, and (4) establishing decision tree with Support Vector Machine (SVM) integrated. Moreover, the re-segmentation and inheriting classification were used to produce image objects. The combinations of features were: (1) classification using hyperspectral features only, (2) classification using hyperspectral and each lidar features, and (3) classification using lidar and different spectral features. 　　The classification results were revealed in both quantitative and qualitative forms. The experiment results suggested 10% to 15% improvement of overall accuracy for hyperspectral features; while for hyperspectral features with different lidar features, it was 4% to 10% increase. Moreover, integrating hyperspectral features and all lidar features resulted in 15% growth of overall accuracy. To compare each lidar feature, the improvement for intensity, echo ratio, and nDSM were 3%, 5%, and 5%, respectively. In general, intensity improves the separation of vegetation and other land covers; echo ratio identifies land covers with structural characteristics; nDSM separates land covers by different height characteristics.