Contents I. Introduction
Ultrasonography has become an important medical imaging modality especially for diagnostics and interventional procedures because of its real-time feedback, portability and radiation-free nature. Ultrasound imaging, thus, has significant advantages over other techniques like Computed Tomography (CT) or Magnetic Resonance Imaging (MRI). Although ultrasound imaging systems have great capabilities, there is a strong dependence on the trained professional's (sonographer) skill. The sonographer needs to find an appropriate area on the patient to scan, thus moving the ultrasound probe within the area of interest, making subtle corrections to the probes pose, and providing safe, significant and accurate forces through the probe to maintain diagnosticable image quality and prevent patient injury. Such skilled workers are not present everywhere. Therefore, to reduce the involve-ment of experts, the Robotic Ultrasound System (RUS) is introduced. RUS is the fusion of a robotic system and an ultrasound station with its scanning probe attached to the robot end-effector as shown in Fig. 1. Robotic ultrasound scanning also improves accuracy, stability, repeatability and maneuverability in terms of ultrasound image acquisition. In recent years, a lot of research has been put into improving the autonomy of the RUS [1]–[3], [4]–[6]. But most of these mentioned systems are tele-operated and assistive with a human still required to navigate the US probe to the region of interest.
A robotic ultrasound system (RUS), which consists of a 6-DoF UR3e serial manipulator and an ultrasound probe mounted to the robot end-effector.
