Powered screwdriver including clutch setting sensor

What is claimed is: 1 . A rotary power tool comprising: a gear case; an output shaft extending from the gear case; a drive mechanism configured to provide torque to the output shaft, causing the output shaft to rotate; a clutch mechanism between the output shaft and the drive mechanism, the clutch mechanism configured to limit the amount of torque provided by the output shaft, the clutch mechanism including a compression spring positioned around the output shaft; a clutch adjustment assembly having a collar disposed circumferentially around the gear case and rotatable to adjust a length of the compression spring; an inductive sensor disposed within the collar and proximate the compression spring such that a voltage is induced in the inductive sensor in response to relative movement between the compression spring and a magnetic field emitted by the inductive sensor; and an electronic control unit configured to receive an output signal from the inductive sensor indicative of the change in inductance in the inductive sensor and to determine a parameter of the clutch mechanism based on the output signal, wherein the compression spring is disposed adjacent and offset from the inductive sensor. 2 . The rotary power tool of claim 1 , wherein the electronic control unit is configured to correlate the output signal of the inductive sensor with the length of the compression spring. 3 . The rotary power tool of claim 1 , wherein the clutch mechanism is adjustable via the clutch adjustment assembly between a first torque setting, a second torque setting, and a plurality of discrete torque settings between the first torque setting and the second torque setting. 4 . The rotary power tool of claim 1 , wherein the collar is disposed circumferentially around a neck portion of the gear case and a nut is threadably coupled to the neck portion of the gear case, wherein the nut co-rotates with the collar to adjust the length of the compression spring. 5 . The rotary power tool of claim 1 , further comprising a motor operably coupled to the drive mechanism and a motor sensor that detects an amount of current drawn by the motor, wherein the electronic control unit is configured to identify a clutching event based on feedback from the motor sensor, and wherein the electronic control unit is configured to deactivate the motor when the clutching event occurs. 6 . The rotary power tool of claim 1 , further comprising a switch that is interfaced with the clutch mechanism, wherein the electronic control unit is configured to identify a clutching event based on feedback from the switch, and wherein the electronic control unit is configured to deactivate the motor when the clutching event occurs. 7 . A rotary power tool comprising: a gear case; an output shaft extending from the gear case; a drive mechanism configured to provide torque to the output shaft, causing the output shaft to rotate; a clutch mechanism between the output shaft and the drive mechanism, the clutch mechanism configured to limit the amount of torque provided by the output shaft, the clutch mechanism including a compression spring; a clutch adjustment assembly configured to adjust a length of the compression spring; and a lockout feature adjustable between a lockout state, in which adjustment of the length of the compression spring by the clutch adjustment assembly is prevented, and a release state, in which adjustment of the length of the compression spring by the clutch adjustment assembly is permitted. 8 . The rotary power tool of claim 7 , wherein the clutch adjustment assembly includes a collar disposed circumferentially around a neck portion of the gear case and a nut threadably coupled to the neck portion of the gear case, wherein the nut co-rotates with the collar to adjust the length of the compression spring. 9 . The rotary power tool of claim 8 , wherein the lockout feature mechanically interferes with the collar to inhibit rotational movement of the collar relative to the gear case. 10 . The rotary power tool of claim 7 , further comprising an electronic control unit configured to receive an output signal from a sensor indicative of the length of the compression spring, wherein the electronic control unit is configured to determine a torque setting of the clutch mechanism based on the output signal. 11 . The rotary power tool of claim 10 , wherein the lockout feature sends another output signal to the electronic control unit to alert a user when the torque setting of the clutch mechanism is adjusted by the clutch adjustment assembly. 12 . The rotary power tool of claim 10 , further comprising a user interface, wherein the electronic control unit sends a signal causing the user interface to display the discrete torque setting based on the determined torque setting of the clutch mechanism. 13 . The rotary power tool of claim 10 , further comprising a motor operably coupled to the drive mechanism and a motor sensor that detects an amount of current drawn by the motor, wherein the electronic control unit is configured to identify a clutching event based on feedback from the motor sensor, and wherein the electronic control unit is configured to deactivate the motor when the clutching event occurs. 14 . A rotary power tool comprising: a gear case; an output shaft extending from the gear case; a drive mechanism configured to provide torque to the output shaft, causing the output shaft to rotate; a clutch mechanism configured to limit the amount of torque provided by the output shaft, the clutch mechanism including a first plate, a second plate, and a compression spring disposed between the first and second plates, wherein the first plate moves and momentarily changes a length of the compression spring in response to a clutching event; a clutch adjustment assembly configured to change the length of the compression spring by moving the second plate relative to the compression spring; an inductive sensor proximate the compression spring such that a voltage is induced in the inductive sensor in response to a change in the length of the compression spring relative to a magnetic field emitted by the inductive sensor, wherein the compression spring is disposed circumferentially around the inductive sensor. 15 . The rotary power tool of claim 14 , further comprising an electronic control unit configured to receive an output signal from the inductive sensor indicative of the change in inductance in the inductive sensor and to determine a parameter of the clutch mechanism based on the output signal. 16 . The rotary power tool of claim 15 , further comprising a user interface, wherein the electronic control unit sends a signal causing the user interface to display the discrete torque setting based on the determined torque setting of the clutch mechanism. 17 . The rotary power tool of claim 14 , wherein the clutch mechanism is adjustable via the clutch adjustment assembly between a first torque setting, a second torque setting, and at least one discrete torque setting between the first torque setting and the second torque setting. 18 . The rotary power tool of claim 14 , wherein the clutch adjustment assembly includes a collar disposed circumferentially around a neck portion of the gear case and a nut threadably coupled to the neck portion of the gear case, wherein the nut co-rotates with the collar to move the second plate and adjust the length of the compression spring. 19 . The rotary power tool of claim 14 , wherein the clutch mechanism further inc