As the time goes on, the generation for information is grown explosively. The need of high-speed transport is increasing for human. The computation power and the transports also grow exponentially to fulfill the need of the communication. However, the transport of the electronic integrated circuit meets the physical limitation for 10 GHz. This limits the improving of the transport speed. Here is a novo technology for solving these problems called silicon photonics. It integrates the photonics circuit and the electronics devices for multiplexing, photonics for communication and electronics circuit for computation. Compare to the copper, the photonics circuit provides the high-speed, low loss, and wide band channel for communication. This will push the improvement of the technology. The photonics circuit should contain the following components: the light source, low loss waveguide, high-speed modulators, the interface between fiber and the waveguide, the logic optical switch, and the photo detector. In this work, we will focus on the interface, diffraction grating coupler, between the optical fiber and the silicon waveguide. First, we will describe the theories of the grating. By applying the grating equation, we design the 1-D diffraction grating coupler as the interface. The simulation result is calculated the coupling efficiency for 40.34% at wavelength 1550 nm with 1 dB bandwidth 39 nm. Besides, we also fabricate the real device at Nano Device Laboratory (NDL) followed by the simulation model. We have successful fabricated the grating structure with the period 630 nm, 640 nm and 650 nm. The width of the grating trench is from 270 nm to 380 nm with 10 nm steps. The shallow etching for 80 to 110 nm is also completed. The coupling efficiency of the experiment result is 21.92% at wavelength 1572 with 1 dB bandwidth 23.4 nm. The experiment result is much lower than the simulation result, but we show the benchmarks which compare to the Ghent University. The number is acceptable. In the end, we fabricated the grating coupler on the real SOI wafer. Next step is reducing the error between the simulation results and the experiments. Furthermore, how to reach high efficiency and broadband grating coupler is the final goal in the future.