In recent years, high-power fiber lasers have been extensively investigated for various applications. Because of the high electrical-optical efficiency, compact and low cost, laser diode arrays (LDAs) have been used in many high-power fiber laser systems as the pump sources. In 2011, side-coupling schemes, using gold-embedded grating couplers, were investigated to couple the light from a high-power LDA into double-clad glass fibers in our group. A 50% coupling efficiency has been achieved from a 21-W, 976nm LD array into a 400-μm double-clad fiber. To demonstrate the main advantage of this pumping scheme, high brightness conversion efficiency, this research is focused on the gain fibers with small inner-cladding diameters. Our system is a resonantly side-pumped 1645-nm Er:YAG crystal fiber laser utilizing a gold grating coupler. Firstly, we overcome difficulties of dry-etching the high index glass substrate, N-LaSF41, by utilizing a SiO2 thin-film embedded grating structure. Based on the theoretical simulation, an optimized diffraction efficiency of 89.51% could be achieved with the grating structure. Secondly, we optimize the overall coupling efficiency for a 130 μm fiber, by choosing a proper size of the fiber-substrate interface. In addition, the glass substrate and crystal fiber are fused under high-temperature melting at 680 ℃ and low-cooling speed at 7 ℃/Hr to eliminate scattering loss. Finally, we simulated the fiber laser performance for a 1 at.% Er:YAG crystal fiber with 40-μm-core diameter. The result shows a 9-cm Er:YAG crystal fiber is long enough to achieve 7-W 1645 nm laser output with 73% slope efficiency under 10-W pumping at 1532 nm .