Recently, the invention of hand-held light field camera induces a revolution in photography. Although the concept of light field camera had been proposed for many years, the limitation of lacking proper computation technology has prevented the light field camera from being widely used. In typical camera systems, the sensor array of a camera is on a two-dimensional plane. To adopt a two dimensional sensor array to capture four dimensional light field data in the world, the data collected represents two dimensional projection of the four dimensional light field data. As the result, the information we get is only part of the whole four dimensional data, other information is simply lost. The main part of this work is to develop the computation approach to calculate the distribution of pixel ray of four-dimensional light field of the real measurement light field data. We use the PBRT (Physical Based Rendering Tracing) software, i.e., the concept of physically based rendering system, to compute the ray tracing necessary to create light-field camera. Firstly, we will use only the simple camera for simplicity and for verifying the system performance. We then add lens system to practice the effect of this modified camera. Secondly, we will introduce the concept of four dimensional light field to the modified camera and capture the light field of virtual scene with the modified camera. With this approach, the captured light field data will be stored in the file of light field. We will then render or zoom this file of light field only, i.e., no need to re-render the entire scene to save time and computation resources. Thirdly, we replace the four dimensional light field by inserting measured real data into PBRT. However, we will capture and analyze the result of pixel ray light energy by using one piece of the measurement data firstly and then using the two measurement data of light field to replace the four dimensional light field. The measurement data used was derived from the Bessel beam data obtained from our team’s previous research results and the newly biological tissue data. Finally, we analyze the pixel ray light energy by image processing and compare the computed result with that the measured data. The result showed virtual scene rendering developed in this thesis can significantly reduce the rendering time needed. The final result clearly demonstrated that the method developed in this thesis, can effectively capture the pixel ray light energy, which can be used to recreated any photo with any specified focal point.