Ultrasound imaging is widely used in breast screening and often performed by the radiologist in free-hand operations. However, the examining results highly depend on the skills and experiences of operators. For full examinations, the ultrasound B mode images and the corresponding scanning path should be recorded. Utilizing a robotic system to assist scan or displacement tracking based on speckle pattern analysis are two possible solutions to providing the aforementioned information. However, it is difficult to achieve body-shape fitting and complex surface screening with the existing robotic scan system since only fixed path scanning is provided. On the other hand, the unreliable quality of the speckle pattern from soft tissues, which can be affected by tissue inhomogeneities and non-uniformly distributed scatterers in humane body, increases the difficulty of analyzing. To this end, the objectives of this study focused on providing better tracking approaches by improving the existing solutions. For the first and second part of this study, we proposed a robotic ultrasound scanning system which is able to adapt the linear and anti-radial scan path to perform conformal whole breast scan. In addition, the axillary area can also be scanned by the proposed system. A frame space of 0.76 mm can be achieved by the proposed system with both linear and radial conformal scanning. The proposed approaches were investigated using a breast phantom. Results show that 75 and 210 seconds were used to scan a rectangular region of 100 mm  50 mm and a circular region with a radius of 50 mm, respectively. Besides, 3D volumetric images can be reconstructed from the acquired B-mode images and the recorded position information. The third part of this study focused on improving the tracking accuracy in hand-held scan through speckle pattern analysis. The improvements include three parts 1) manufacturing a pad phantom with homogeneous distributed scatterers, 2) introducing an SVD-based method for feature extraction, and 3) using 2-layer neural network predictors for motion prediction. With the conventional approach using the speckle decorrelation curve for estimation, the estimated errors are too large to distinguish the types of motion and amount of displacement. By comparison with the proposed approach, the accuracy of motion prediction can reach 96% with training, and the estimated errors of elevational motion and rotational scan along X/Z axes are 0.00047 mm and 0.0038°/0.0018° respectively.