Surgical robotics system with mode switching

What is claimed is: 1 . A surgical method, comprising: operating, by a surgical robot, in a first mode; detecting a crossing of an object from a first side of a boundary to a second side of the boundary; switching, in response to the crossing of the object from the first side of the boundary to the second side of the boundary, the surgical robot from the first mode to a second mode; and operating, by the surgical robot, in the second mode. 2 . The surgical method of claim 1 , wherein the boundary is correlated with a surgical field. 3 . The surgical method of claim 1 , wherein operating, by the surgical robot, in the second mode comprises providing automated movement of the surgical robot. 4 . The surgical method of claim 3 , further comprising stopping the automated movement in response to a sensed movement of a surgeon's hand. 5 . The surgical method of claim 1 , wherein: operating, by the surgical robot, in the first mode comprises providing automated movement of the surgical robot; and operating, by the surgical robot, in the second mode comprises enabling, by the surgical robot, manual movement of the surgical robot. 6 . The surgical method of claim 5 , wherein enabling, by the surgical robot, the manual movement of the surgical robot further comprises constraining the manual movement of the surgical robot with a haptic object. 7 . The surgical method of claim 1 , further comprising switching the surgical robot from the second mode to a third mode in response to the object entering a defined volume. 8 . The surgical method of claim 1 , wherein the boundary is curved. 9 . The surgical method of claim 1 , wherein the object is a surgical tool coupled to the surgical robot or a portion of the surgical robot. 10 . The surgical method of claim 1 , further comprising changing the operating of the surgical robot in the first mode or the second mode based on a sensed position of a hand of a surgeon. 11 . The surgical method of claim 1 , comprising tracking the object to determine the crossing using data from an optical tracking system. 12 . The surgical method of claim 1 , comprising tracking the object to determine the crossing using data from joints of the surgical robot. 13 . A surgical system, comprising: a surgical robot; and a controller comprising a processor and non-transitory computer-readable memory storing instructions that, when executed, cause the processor to perform operations comprising: operating the surgical robot in a first mode; determining a crossing of an object from a first side of a boundary to a second side of the boundary; switching, in response to the crossing of the object from the first side of the boundary to the second side of the boundary, the surgical robot from the first mode to a second mode; and operating the surgical robot in the second mode. 14 . The surgical system of claim 13 , wherein the boundary is correlated with a surgical field. 15 . The surgical system of claim 13 , wherein operating the surgical robot in the second mode comprises causing automated movement of the surgical robot. 16 . The surgical system of claim 15 , comprising a sensor configured to detect presence of a hand, wherein the operations further comprise stopping the automated movement based on data from the sensor. 17 . The surgical system of claim 13 , wherein the second mode is a haptic mode. 18 . The surgical system of claim 13 , comprising the object, wherein the object is a surgical tool coupled to the surgical robot. 19 . The surgical system of claim 13 , comprising an optical tracking system configured to provide tracking data, wherein determining the crossing of the object from the first side of the boundary to the second side of the boundary uses the tracking data. 20 . The surgical system of claim 13 , wherein: operating the surgical robot in the first mode comprises providing automated movement of the surgical robot; and operating the surgical robot the second mode comprises enabling, by the surgical robot, manual movement of the surgical robot.