Ultrasonic robotic surgical navigation

What is claimed is: 1. A method by a surgical robot system of a robot having a robot base, a robot arm coupled to the robot base, and an end-effector coupled to the robot arm, the end-effector configured to guide movement of a surgical instrument, the method comprising: receiving ultrasound (US) imaging data from an ultrasound (US) transducer coupled to the end-effector, wherein the US imaging data is of anatomical structure proximately located to the end-effector; obtaining an image volume for the patient; and tracking pose of the end-effector relative to anatomical structure captured in the image volume based on the US imaging data. 2. The method of claim 1 , wherein tracking of pose of the end-effector relative to the anatomical structure captured in the image volume based on the US imaging data, comprises: generating US images of the anatomical structure based on the US imaging data; matching the anatomical structure captured in one of the US images to the anatomical structure captured in the image volume; and determining the pose of the end-effector relative to the anatomical structure captured in the image volume based on the matching. 3. The method of claim 1 , wherein the end-effector comprises a guide tube configured to guide movement of the surgical instrument through the guide tube, the US transducer comprises an array of US transducers spaced apart along a leading edge of the guide tube, and the receiving of the US imaging data comprises receiving the US imaging data from the array of US transducers. 4. The method of claim 3 , wherein the US transducers are spaced apart to form a ring shape and are at least partially disposed within the leading edge of the guide tube, and the tracking pose of the end-effector relative to the anatomical structure captured in the image volume comprises determining pose of the end-effector relative to the leading edge of the guide tube. 5. The method of claim 1 , wherein the US transducer comprises a planar array of US transducers connected by a mounting arm to the end-effector, and the receiving of the US imaging data comprises receiving the US imaging data from the planar array of US transducers. 6. The method of claim 1 , further comprising: identifying in the US imaging data locations of discrete features which are spaced apart along the surgical instrument and sensed by the US transducer; and determining pose of the surgical instrument relative to the end-effector based on the locations of the discrete features identified in the US imaging data. 7. The method of claim 6 , wherein the surgical instrument has a shaft with the discrete features configured as indentations, protrusions, slots, and/or holes spaced apart along a surface of the surgical instrument, and the determining of the pose of the surgical instrument comprises identifying location of the indentations, protrusions, slots, and/or holes. 8. The method of claim 6 , wherein: the US transducer comprises an array of US transducers; and the determining of the pose of the surgical instrument relative to the end-effector based on the locations of the discrete features identified in the US imaging data, comprises: determining depth of the surgical instrument relative to a location on the end-effector based on counting a number of the discrete features identified in the US imaging data from individual ones of the US transducers; and determining rotation of the surgical instrument relative to the end-effector based on identifying rotation of the discrete features identified in the US imaging data between adjacent US transducers in the array. 9. The method of claim 6 , wherein the determining of the pose of the surgical instrument relative to the end-effector based on the locations of the discrete features identified in the US imaging data, comprises: matching a spatial pattern of the locations of the discrete features identified in the US imaging data to content of a template for the surgical instrument which defines a pattern of the discrete features arranged around the surface of the surgical instrument as a function of locations along a length of the surgical instrument. 10. The method of claim 1 , further comprising: identifying in the US imaging data locations of layers of materials of the surgical instrument, wherein adjacent layers of the materials have different reflectivity to ultrasound; and determining pose of the surgical instrument relative to the end-effector based on the locations of the layers of materials of the surgical instrument identified in the US imaging data. 11. The method of claim 10 , wherein the surgical instrument has a shaft with layers of materials stacked along a primary axis of the shaft, wherein adjacent layers of the materials have different reflectivity to US, and the determining of the pose of the surgical instrument relative to the end-effector comprises identifying the locations of the stacked adjacent layers of the materials. 12. The method of claim 10 , further comprising the surgical instrument having a shaft with layers of materials forming helical stripes spiraling about a primary axis of the shaft, wherein adjacent layers of the materials have different reflectivity to US, and the determining of the pose of the surgical instrument relative to the end-effector comprises identifying the locations of the helical striped adjacent layers of the materials. 13. The method of claim 10 , further comprising the surgical instrument having a shaft with layers of materials forming stripes extending parallel to a primary axis of the shaft, wherein adjacent layers of the materials have different reflectivity to US. 14. The method of claim 1 , further comprising: determining a target pose for the surgical instrument based on a surgical plan defining where a surgical procedure is to be performed using the surgical instrument on the anatomical structure captured in the image volume; and generating steering information based on the target pose for the surgical instrument and a present tracked pose of the end-effector relative to the anatomical structure captured in the image volume, the steering information indicating where the surgical instrument and/or the end-effector need to be moved. 15. The method of claim 14 , wherein the surgical robot system has at least one motor operatively connected to move the robot arm relative to the robot base, and the method further comprises: controlling movement of the at least one motor based on the steering information to guide movement of the end-effector so the surgical instrument becomes positioned with the target pose. 16. The method of claim 1 , wherein the surgical robot system has kinematic sensors connected to the robot arm and operative to output kinematic movement data indicating change in pose of the robot arm relative to the robot base, and the method further comprises: after tracking pose of the end-effector relative to the anatomical structure captured in the image volume based on the US imaging data for a period of time and responsive to determining the US transducer has ceased to output US imaging data of the anatomical structure proximately located to the end-effector, triggering continued tracking of the pose of the end-effector relative to the anatomical structure captured in the image volume based on the kinematic movement data; and responsive to determining the US transducer has resumed output of US imaging data of the anatomical structure proximately located to the end-effector, triggering continued tracking of the pose of the end-effector relative to the anatomical structure captured in the ima