In recent years, the technique of Precision Agriculture (PA) has been highly focused. It was applied not only to the filed production but also to the greenhouses. Many research results about greenhouses and the sensing systems have been reported that current sensing systems in the greenhouses use a limited number of sensors to represent the information of the entire region. However, such sensing systems could cause information errors, even worse in non-uniform environments. The cost will be increased if more sensors are used to measure the non-uniform environments. A quantum-sensing flying robot has been developed in this study to realize the site specific crop management in greenhouses, which consists of a quadcopter and a light-weight quantum sensing module. The performances of the flying robot and quantum sensor carried by the flying robot were also evaluated. The results of customized quantum sensor made in this study being calibrated by commercial quantum sensor gave Rc2 value of 0.9967, SEC of 26.87μmole/m2/s, and RSEC of 6.67%. The comparison between flying robot with quantum sensing and static sensing system shows that the error mainly cause by spatial difference, and the standard error is 62.15μmole/m2/s with the relative standard error of 6.25%. The conclusions show that the flying robot with quantum sensing can used to sense the light spatial information in the greenhouses and show the non-uniform light distribution. On the comparison with the dynamic sensing system using moving carriers, the flying robot seems a better option in view of the construction cost and difficulty. Therefore, the flying robot with quantum sensing is feasible to apply to light spatial information sensing in greenhouses.