Surgical instrument with magnetic sensing

What is claimed is: 1 . A sensor array to detect a position of a magnetic element, the sensor array comprising: a printed circuit board, wherein the printed circuit board is configured to rotate about a rotation axis and relative to the magnetic element; and a plurality of sensors disposed circumferentially about the rotation axis and coupled to the printed circuit board, the plurality of sensors being configured to rotate with the printed circuit board about the rotation axis and relative to the magnetic element, wherein at least one sensor of the plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to change between an open state and a closed state in response to a change in the position of the magnetic element relative to the rotation axis. 2 . The sensor array of claim 1 , wherein each of the plurality of sensors are equidistantly spaced apart. 3 . The sensor array of claim 1 , wherein the printed circuit board defines a circular profile. 4 . The sensor array of claim 1 , further comprising a second plurality of sensors disposed circumferentially about the rotation axis and coupled to the printed circuit board. 5 . The sensor array of claim 4 , wherein the plurality of sensors is disposed on a first surface of the printed circuit board and the second plurality of sensors are disposed on an opposite second surface of the printed circuit board. 6 . The sensor array of claim 5 , wherein the sensors of the second plurality of sensors are interposed between the sensors of the plurality of sensors. 7 . The sensor array of claim 1 , wherein the printed circuit board comprises a plurality of elongated slats disposed circumferentially about the rotation axis and configured to rotate about the rotation axis and relative to the magnetic element, and each of the sensors are coupled to a respective elongated slat of the plurality of elongated slats. 8 . The sensor array of claim 7 , further comprising a second plurality of sensors coupled to a respective elongated slat of the plurality of elongated slats, wherein each of the sensors of the second plurality of sensors are laterally spaced apart along the rotation axis from the respective sensors of the plurality of sensors and at least one sensor of the second plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to change between an open state and a closed state in response to a change in the position of a second magnetic element relative to the rotation axis. 9 . A surgical instrument comprising: an instrument shaft; a tool drive adapter comprising: a housing disposed around a portion of the instrument shaft, wherein the instrument shaft is rotatably coupled to the tool drive adapter such that the instrument shaft is rotatable about a rotation axis relative to the housing; and an actuator coupled to the housing, wherein actuation of an actuator controls a function of the surgical instrument; and a sensor array disposed within the instrument shaft, the sensor array comprising: a printed circuit board fixedly coupled to an interior of the instrument shaft such that the printed circuit board is configured to rotate with the instrument shaft about the rotation axis and relative to the actuator of the tool drive adapter; and a plurality of sensors disposed circumferentially about the rotation axis and fixedly coupled to the printed circuit board such that the plurality of sensors is configured to rotate with the printed circuit board about the rotation axis and relative to the actuator of the tool drive adapter, wherein at least one sensor of the plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to provide a signal corresponding to actuation of the actuator. 10 . The surgical instrument of claim 9 , wherein the plurality of sensors comprises a plurality of reed switches. 11 . The surgical instrument of claim 9 , further comprising a second plurality of sensors disposed circumferentially about the rotation axis. 12 . The surgical instrument of claim 9 , wherein the plurality of sensors are disposed on a first surface of the printed circuit board and a second plurality of sensors are disposed on an opposite second surface of the printed circuit board. 13 . The surgical instrument of claim 12 , wherein the sensors of the second plurality of sensors are interposed between the sensors of the plurality of sensors. 14 . The surgical instrument of claim 9 , wherein the tool drive adapter comprises a second actuator coupled to the housing and actuation of the second actuator controls a second function of the surgical instrument, and at least one sensor of a second plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to provide a signal corresponding to actuation of the second actuator. 15 . The surgical instrument of claim 9 , wherein the instrument shaft comprises a laparoscopic instrument. 16 . The surgical instrument of claim 9 , wherein the housing is configured to attach to a robotic surgical system. 17 . A surgical instrument comprising: an instrument shaft; a tool drive adapter comprising: a housing disposed around a portion of the instrument shaft, wherein the instrument shaft is rotatable about a rotation axis relative to the housing; and an actuator coupled to the housing, wherein actuation of an actuator controls a function of the surgical instrument; and a sensor array disposed within the instrument shaft, the sensor array comprising: a plurality of elongated printed circuit boards disposed circumferentially about the rotation axis and fixedly coupled to an interior of the instrument shaft such that the plurality of elongated printed circuit boards is configured to rotate with the instrument shaft about the rotation axis and relative to the actuator of the tool drive adapter; and a plurality of sensors, wherein each sensor of the plurality of sensors is fixedly coupled to a respective elongated printed circuit board of the plurality of elongated printed circuit boards such that the sensor is configured to rotate with the respective elongated printed circuit board about the rotation axis and relative to the actuator of the tool drive adapter, wherein at least one sensor of the plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to provide a signal corresponding to actuation of the actuator. 18 . The surgical instrument of claim 17 , wherein the sensor array further comprises a backplane coupled to the plurality of elongated printed circuit boards. 19 . The surgical instrument of claim 17 , wherein the tool drive adapter comprises a second actuator coupled to the housing and actuation of the second actuator controls a second function of the surgical instrument, and the sensor array further comprising a second plurality of sensors coupled to a respective elongated printed circuit board of the plurality of printed elongated circuit boards, wherein each of the sensors of the second plurality of sensors are laterally spaced apart along the rotation axis from the respective sensor of the plurality of sensors and at least one sensor of the second plurality of sensors disposed at a selected circumferential position relative to the rotation axis is configured to provide a signal corresponding to actuation of the second actuator. 20 . The surg