System and method for roll alignment of a multi-nozzle extruder in three-dimensional object printers using cross-process measurements

What is claimed: 1. A method operating a three-dimensional object printer comprising: moving, with a first actuator, a multi-nozzle extruder in a first process direction within a print zone of the three-dimensional object printer; operating at least a first nozzle and a second nozzle in a plurality of nozzles in the multi-nozzle extruder to emit a first swath and a second swath, respectively, of an extrusion material onto a surface of a receiving member in the print zone during the moving of the multi-nozzle extruder in the first process direction; moving, with the first actuator, the multi-nozzle extruder in a second process direction within the print zone of the three-dimensional object printer, the second process direction being different than the first process direction; operating at least the first nozzle and the second nozzle in the plurality of nozzles in the multi-nozzle extruder to emit a third swath and a fourth swath, respectively, of the extrusion material onto the surface of the receiving member in the print zone during the moving of the multi-nozzle extruder in the second process direction; generating, with an optical sensor, scanned image data of the first swath, the second swath, the third swath, and the fourth swath; identifying, with a controller, a measured two-dimensional location of the second nozzle relative to the first nozzle with reference to a first location of the second nozzle in a first cross-process direction corresponding to a location of the second swath relative to the first swath in the scanned image data, the first cross-process direction being perpendicular to the first process direction, and a second location of the second nozzle in a second cross-process direction corresponding to a location of the fourth swath relative to the third swath in the scanned image data, the second cross-process direction being perpendicular to the second process direction; and identifying, with the controller, an angle of roll for the multi-nozzle extruder with reference to the measured two-dimensional location of the second nozzle relative to the first nozzle and a predetermined geometric arrangement of the first nozzle and the second nozzle in the multi-nozzle extruder. 2. The method of claim 1 further comprising: operating, with the controller, a second actuator operatively connected to the multi-nozzle extruder to rotate the multi-nozzle extruder by an angle corresponding to the angle of roll for the multi-nozzle extruder to reduce or eliminate the angle of roll. 3. The method of claim 2 further comprising: operating, with the controller, the second actuator operatively connected to the multi-nozzle extruder to rotate the multi-nozzle extruder in a direction opposite of the angle of roll to reduce or eliminate the angle of roll. 4. The method of claim 1 , the identifying of the angle of roll further comprising: identifying, with the controller, a plurality of two-dimensional locations for the second nozzle relative to the first nozzle that correspond to a plurality of angles of roll for the multi-nozzle extruder within a predetermined range of angles; identifying, with the controller, a plurality of errors, each error in the plurality of errors corresponding to a distance between one two-dimensional location in the plurality of locations for the second nozzle and the measured two-dimensional location of the second nozzle; and identifying the angle of roll for the multi-nozzle extruder with reference to one angle of roll in the plurality of angle of rolls that corresponds a minimum error in the plurality of errors. 5. The method of claim 4 , the identifying of the angle of roll further comprising a non-linear least-squares minimization process to identify the one angle of roll in the plurality of angle of rolls that corresponds to a minimum error in the plurality of errors. 6. The method of claim 4 , the identifying of the angle of roll further comprising a sum-of-squares minimization process to minimize a sum-of-squares of a first component of each error corresponding to the first cross-process direction and a second component of each error corresponding to the second cross-process direction. 7. The method of claim 4 , the identifying of the angle of roll further comprising a curve-fitting process to identify the one angle of roll in the plurality of angle of rolls that corresponds a minimum error in the plurality of errors. 8. The method of claim 1 , the identifying of the measured two-dimensional location of the second nozzle further comprising: identifying, with the controller, a first relative location of the first swath in the first cross-process direction corresponding to a location in a height profile in the scanned image data of a maximum height of the first swath; and identifying, with the controller, a second relative location of the second swath in the first cross-process direction corresponding to another location in the height profile in the scanned image data of a maximum height of the second swath. 9. The method of claim 1 , the moving of the multi-nozzle extruder in the second process direction further comprising: moving, with the first actuator, the multi-nozzle extruder in the second process direction at a 90° angle relative to the first process direction. 10. A three-dimensional object printer comprising: a multi-nozzle extruder including a plurality of nozzles; a first actuator configured to move the multi-nozzle extruder in a first process direction and a second process direction within a print zone of the three-dimensional object printer, the second process direction being different than the first process direction; an optical sensor; and a controller operatively connected to the multi-nozzle extruder, the first actuator, and the optical sensor, the controller being configured to: move the multi-nozzle extruder in the first process direction using the first actuator; operate at least a first nozzle and a second nozzle in the plurality of nozzles in the multi-nozzle extruder to emit a first swath and a second swath, respectively, of an extrusion material onto a surface of a receiving member in the print zone during the moving of the multi-nozzle extruder in the first process direction; move the multi-nozzle extruder in the second process direction using the first actuator; operate at least the first nozzle and the second nozzle in the plurality of nozzles in the multi-nozzle extruder to emit a third swath and a fourth swath, respectively, of the extrusion material onto the surface of the receiving member in the print zone during the moving of the multi-nozzle extruder in the second process direction; generate scanned image data of the first swath, the second swath, the third swath, and the fourth swath using the optical sensor; identify a measured two-dimensional location of the second nozzle relative to the first nozzle with reference to a first location of the second nozzle in a first cross-process direction corresponding to a location of the second swath relative to the first swath in the scanned image data, the first cross-process direction being perpendicular to the first process direction, and a second location of the second nozzle in a second cross-process direction corresponding to a location of the fourth swath relative to the third swath in the scanned image data, the second cross-process direction being perpendicular to the second process direction; and identify an angle of roll for the multi-nozzle extruder with reference to the measured two-dimensional location of the second nozzle relative to the first nozzle and a predetermined geometric arrangement of the first nozzle and the second nozzle in the multi-nozzle extruder.