Tool based welding technique monitoring systems with multiple tool orientations

What is claimed is: 1 . A method, comprising: determining, via processing circuitry, a first joint characteristic vector and a second joint characteristic vector based on a joint orientation and first sensor data detected during a first time period by a sensor system attached to, or integrated with, a stick electrode holder; identifying, via the processing circuitry, an active electrode slot from a plurality of electrode slots of the stick electrode holder, the active electrode slot being identified as corresponding to a first electrode slot of the plurality of electrode slots, and the active electrode slot being configured to hold a stick electrode; tracking, in real time during a second time period, via the processing circuitry, an electrode orientation of the stick electrode based on the active electrode slot and second sensor data detected by the sensor system during the second time period; identifying, via the processing circuitry, a first welding technique parameter value based on the electrode orientation during the second time period and the first or second joint characteristic vector; determining, via the processing circuity, the active electrode slot corresponds to a second electrode slot of the plurality of electrode slots in response to an input; tracking, in real time during a third time period, via the processing circuitry, the electrode orientation based on the active electrode slot and third sensor data detected by the sensor system during the third time period; and identifying, via the processing circuitry, a second welding technique parameter value based on the electrode orientation during the third time period and the first or second joint characteristic vector. 2 . The method of claim 1 , wherein the stick electrode holder is configured to hold the stick electrode in a first orientation with respect to the stick electrode holder when the stick electrode is in the first electrode slot. 3 . The method of claim 1 , wherein the input is received from a user interface, or the input is received from a sensor that detects the stick electrode is in the second electrode slot. 4 . The method of claim 2 , wherein the stick electrode holder is configured to hold the stick electrode in a second orientation with respect to the stick electrode holder when the stick electrode is in the second electrode slot, the first orientation being different from the second orientation. 5 . The method of claim 1 , further comprising: identifying, via the processing circuitry, a first electrode orientation vector relative to a sensor reference frame of the sensor system based on fourth sensor data detected by the sensor system during a fourth time period when the stick electrode is in the first electrode slot in a known orientation; associating, in memory circuitry, the first electrode orientation vector with the first electrode slot; identifying, via the processing circuitry, a second electrode orientation vector relative to the sensor reference frame of the sensor system based on fifth sensor data detected by the sensor system during a fifth time period when the stick electrode is in the second electrode slot in the known orientation; and associating, in memory circuitry, the second electrode orientation vector with the second electrode slot, wherein the electrode orientation is tracked based on an orientation of the sensor reference frame and the first electrode orientation vector when the active electrode slot corresponds to the first electrode slot, and the electrode orientation is tracked based on the orientation of the sensor reference frame and the second electrode orientation vector when the active electrode slot corresponds to the second electrode slot. 6 . The method of claim 1 , further comprising providing feedback, via a user interface, based on the first or second welding technique parameter value, the first or second welding technique parameter value comprising a work angle value or a travel angle value of the stick electrode. 7 . The method of claim 1 , wherein the sensor system comprises an inertial measurement unit comprising an accelerometer, a gyroscope, or a magnetometer, and the first or second sensor data comprises data detected by the inertial measurement unit. 8 . A method, comprising: determining, via processing circuitry, a first joint characteristic vector and a second joint characteristic vector based on a joint orientation and first sensor data detected during a first time period by a sensor system attached to, or integrated with, a stick electrode holder; identifying, via the processing circuitry, a pivotal position, from a plurality of potential pivotal positions, of an electrode holding head of the stick electrode holder, the pivotal position being identified as corresponding to a first pivotal position of the electrode hold head, the electrode holding head being pivotable relative to a handle of the electrode holder, and the electrode holding head being configured to hold a stick electrode; tracking, in real time during a second time period, via the processing circuitry, an electrode orientation of the stick electrode based on the pivotal position of the electrode holding head and second sensor data detected by the sensor system during the second time period; and identifying, via the processing circuitry, a first welding technique parameter value based on the electrode orientation during the second time period and the first or second joint characteristic vector; in response to an input, identifying, via the processing circuitry, the pivotal position of the electrode holding head of the stick electrode holder as corresponding to a second pivotal position; tracking, in real time during a third time period, via the processing circuitry, the electrode orientation based on the pivotal position of the electrode holding head and third sensor data detected by the sensor system during the third time period; and identifying, via the processing circuitry, a second welding technique parameter value based on the electrode orientation during the third time period and the first or second joint characteristic vector. 9 . The method of claim 8 , wherein the electrode holding head holds the stick electrode in a first orientation with respect to the handle when the electrode holding head is in the first pivotal position. 10 . The method of claim 8 , wherein the input is received from a user interface, or the input is received from a sensor that detects the electrode holding head is in the second pivotal position. 11 . The method of claim 9 , wherein the electrode holding head holds the stick electrode in a second orientation with respect to the handle when the electrode holding head is in the second pivotal position, the first orientation being different from the second orientation. 12 . The method of claim 8 , further comprising: identifying, via the processing circuitry, a first electrode orientation vector relative to a sensor reference frame of the sensor system based on fourth sensor data detected by the sensor system during a fourth time period when the electrode holding head is in the first pivotal position and the stick electrode is in a known orientation; associating, in memory circuitry, the first electrode orientation vector with the first pivotal position; identifying, via the processing circuitry, a second electrode orientation vector relative to the sensor reference frame of the sensor system based on fifth sensor data detected by the sensor system during a fifth time period when the electrode holding head is in the second pivotal position and the stick electrode is in the known orientation; and associating, in memory