In the traditional mechanical factory, the cutting of non-circular workpiece is still mainly achieved by changing the model. However, when cutting other shapes of the workpiece, the model must be redesigned, which will increase the cost. The machine used in this paper has been equipped with servo motor with connecting rod and mechanism, so that when the non-circular workpiece is turned, the model is no longer needed. In this paper, a hybrid controller is designed to make noncircular turning process smoother and more accurate. In dynamic modeling, the Lagrange method along with the Lagrange multiplier and the virtual work principle were applied to device, the equations of motion, then the dynamic equations were simplied using the D’Alembert’s principle. In the hybrid control, a controller for the automatic positioning of the slide table with a laser displacement meter being used for instantaneous detection of the feeding displacement. The NI Single-Board 9632 is used as a control platform with the embedded LabVIEW for human-machine interface design for more accurate feeds. The other controller for the spindle speed directly reads the encoder signal of the motor driver into the control platform to realize the monitoring and control of the spindle speed. From the experimental results, according to the different turning methods, the accuracy of the turning is improved after the correction. Moreover, the proposed hybrid control for turning is better than using the slide table automatic positioning controller based on the accuracy of the finished product. Concludes that the use of the hybrid control, and the calibration is completed first, and the obtained precision of the finished product is better. The research results show the feasibility of the closed loop control proposed in this paper.