Material deposition systems with four or more axes

What is claimed is: 1. A non-transitory computer-readable medium storing software comprising instructions executable by one or more computers, which, upon such execution, cause the one or more computers to perform operations for controlling a 3D printer to create a 3D object, the 3D printer comprising an extruder for one or more deposition materials, the extruder comprising at least one nozzle and a movable support for the nozzle, wherein the nozzle has a nozzle axis and is rotatably attached to the movable support via a connector that is actuatable relative to the movable support to change an angular orientation of the nozzle axis relative to the movable support so as to vary an angle between the nozzle axis and a deposition surface during deposition of the one or more deposition materials, the operations comprising: applying an adjustment calculated for a path of the nozzle based on the angle formed between the nozzle axis and the deposition surface being an acute angle, the adjustment for the nozzle moving toward the acute angle being different from the adjustment for the nozzle moving away from the acute angle; and causing movement of the nozzle along the path to deposit material to form the object, wherein the adjustment removes differences in thickness of the deposited material caused by variations in the angle formed between the nozzle axis and the deposition surface, wherein the adjustment is applied to a height of the nozzle above the deposition surface and is calculated based on a diameter of a tip of the nozzle and a variable acute angle between the deposition surface and the nozzle axis. 2. The medium of claim 1 , wherein applying the adjustment includes causing the path of the nozzle to become farther from the deposition surface when the nozzle is moving away from the acute angle. 3. The medium of claim 1 , wherein applying the adjustment includes causing the path of the nozzle to become closer to the deposition surface when the nozzle is moving toward the acute angle. 4. The medium of claim 1 , wherein the operations further include, based on determining that the nozzle makes contact with any portion of the 3D printer or the object, causing the angular orientation of the nozzle to change to avoid making contact. 5. The medium of claim 1 , wherein the operations further include: causing movement of the nozzle along three orthogonal axes; causing movement of the nozzle about a first axis that is transverse to the nozzle axis; and causing movement of the nozzle about a second axis that is transverse to the first axis. 6. The medium of claim 1 , wherein the operations further include: causing movement of the nozzle along three orthogonal axes; causing movement of the nozzle about a first axis that is transverse to the nozzle axis; and causing movement of the nozzle about the nozzle axis. 7. The medium of claim 1 , wherein causing movement of the nozzle along the path to deposit material to form the object includes moving the nozzle according to the adjustment such that a distance between the nozzle and the deposition surface is larger when the nozzle is moving away from the acute angle compared to when the nozzle is moving toward the acute angle. 8. The medium of claim 2 , wherein applying the adjustment includes causing the nozzle and the movable support to become farther from the deposition surface when the nozzle is moving away from the acute angle. 9. The medium of claim 3 , wherein applying the adjustment includes causing the nozzle and the movable support to become closer to the deposition surface when the nozzle is moving toward the acute angle. 10. The medium of claim 1 , wherein, based on the nozzle moving away from the acute angle, the adjustment is added to the height of the nozzle above the deposition surface, and wherein, based on the nozzle moving toward the acute angle, the adjustment is subtracted from the height of the nozzle above the deposition surface. 11. The medium of claim 1 , wherein applying the adjustment includes, based on the nozzle moving away from the acute angle, causing the path of the nozzle to become farther from the deposition surface by (D o /2)×sin Φ, where D o is an outer diameter of a tip of the nozzle and Φ is an angle between the deposition surface and a plane perpendicular to the nozzle axis. 12. The medium of claim 1 , wherein applying the adjustment includes, based on the nozzle moving toward the acute angle, causing the path of the nozzle to become closer to the deposition surface by (D i /2)×sin Φ, where D i is an inner diameter of a tip of the nozzle and Φ is an angle between the deposition surface and a plane perpendicular to the nozzle axis. 13. The medium of claim 1 , wherein the operations further include causing actuation of the connector with at least two degrees of freedom for the nozzle relative to the movable support. 14. The medium of claim 13 , wherein the operations further include causing application of heat to a feedstock material passing through a softening zone, the softening zone being positioned upstream of an actuation point of the connector and configured to increase flexibility of the feedstock material passing through the softening zone. 15. The medium of claim 1 , wherein the operations further include: causing movement of the movable support and the nozzle relative to the object being fabricated along three orthogonal axes to thereby provide three degrees of freedom relative to the object, the nozzle being rotatably attached to the movable support via the connector to rotate about a first axis that is transverse to the nozzle axis to thereby provide a fourth degree of freedom relative to the object; and causing rotation of a rotatable base during deposition to thereby provide a fifth degree of freedom between the nozzle and the object, the rotatable base being configured to support the object being fabricated. 16. The medium of claim 1 , wherein the operations further include: causing movement of the movable support and the nozzle relative to the object being fabricated along three orthogonal axes to thereby provide three degrees of freedom relative to the object, the nozzle being rotatably attached to the movable support via the connector to rotate about a first axis that is transverse to the nozzle axis to thereby provide a fourth degree of freedom relative to the object; and causing rotation of the connector and the nozzle about the nozzle axis to thereby provide a fifth degree of freedom relative to the object, the connector being rotatably connected to the movable support. 17. The medium of claim 1 , wherein the operations further include: causing movement of the nozzle relative to the object being fabricated along three orthogonal axes to thereby provide three degrees of freedom relative to the object, wherein the connector includes a multi-link coupler that is rotatably attached to the movable support to rotate about a first axis that is transverse to the nozzle axis; and causing rotation of the nozzle that is rotatably attached to the multi-link coupler about a second axis that is transverse to the first axis to thereby provide two additional degrees freedom relative to the object. 18. The medium of claim 1 , wherein the operations further include: based on the nozzle moving away from the acute angle, applying the adjustment that causes the nozzle and the movable support to become farther from the deposition surface; and based on the nozzle moving toward the acute angle, applying the adjustment that causes the nozzle and the movable support to become closer