Fixed size augmented reality objects

The invention claimed is: 1. A wearable, head-mounted display system comprising: a left near-eye, see-through display configured to display a left-eye augmented reality image with a left-eye display size at left-eye display coordinates; a right near-eye, see-through display configured to display a right-eye augmented reality image with a right-eye display size at right-eye display coordinates, the left-eye augmented reality image and right-eye augmented reality image collectively forming an augmented reality object perceivable at an apparent real world depth by a wearer of the head-mounted display system; and a controller to set the left-eye display coordinates relative to the right-eye display coordinates as a function of the apparent real world depth of the augmented reality object, the function maintaining an aspect of the left-eye display size and the right-eye display size throughout a non-scaling range of apparent real world depths of the augmented reality object, and the function scaling the left-eye display size and the right-eye display size with changing apparent real world depth of the augmented reality object outside the range of apparent real world depths. 2. The display system of claim 1 , wherein the augmented reality object comprises virtual user markings. 3. The display system of claim 2 , wherein maintaining the aspect of the left-eye display size and the right-eye display size comprises maintaining a line thickness of the virtual user markings throughout the non-scaling range. 4. The display system of claim 3 , further comprising scaling a line length of the virtual user markings as a function of apparent real world depth throughout the non-scaling range. 5. The display system of claim 1 , wherein the function decreases a distance between the left-eye display coordinates and the right-eye display coordinates with decreasing apparent real world depth. 6. The display system of claim 1 , wherein maintaining the aspect of the left-eye display size and the right-eye display size throughout the non-scaling range of apparent real world depths comprises changing an apparent real world size of a corresponding aspect of the augmented reality object throughout the non-scaling range of apparent real world depths, such that the augmented reality object occupies a constant proportion of the wearer's field of view. 7. The display system of claim 1 , wherein the augmented reality object comprises a user interface control element. 8. The display system of claim 1 , wherein the function decreases the left-eye display size and the right-eye display size at apparent real world depths greater than the non-scaling range, and increases the left-eye display size and the right-eye display size at apparent real world depths less than the non-scaling range. 9. The display system of claim 1 , wherein the augmented reality object is a first augmented reality object, and wherein the controller sets left-eye coordinates of a second augmented reality object relative to right-eye coordinates of the second augmented reality object as a second function of apparent real world depth of the second augmented reality object. 10. The display system of claim 9 , wherein the second function maintains an aspect of a left-eye display size and a right-eye display size of the second augmented reality object throughout a second, different non-scaling range of apparent real world depths of the second augmented reality object. 11. The display system of claim 1 , wherein the augmented reality object is a child of a parent augmented reality object, and wherein the function scales a left-eye display size and a right-eye display size of the parent augmented reality object with changing apparent real world depth of the parent augmented reality object throughout the non-scaling range of apparent real world depths of the parent augmented reality object. 12. A method for a wearable, head-mounted display system comprising: displaying, on a left near-eye, see-through display, a left-eye augmented reality image with a left-eye display size at left-eye display coordinates according to a scaling function; displaying, on a right near-eye, see-through display, a right-eye augmented reality image with a right-eye display size at right-eye display coordinates according to the scaling function, the left-eye augmented reality image and right-eye augmented reality image collectively forming an augmented reality object perceivable at an apparent real world depth by a wearer of the head-mounted display system; the scaling function setting the left-eye display coordinates relative to the right-eye display coordinates as a function of the apparent real world depth of the augmented reality object; the scaling function maintaining an aspect of the left-eye display size and the right-eye display size throughout a non-scaling range of apparent real world depths of the augmented reality object; and the scaling function scaling the left-eye display size and the right-eye display size with changing apparent real world depth of the augmented reality object outside the non-scaling range of real world depths. 13. The method of claim 12 , wherein scaling the left-eye display size and the right-eye display size with changing apparent real world depth of the augmented reality object outside the non-scaling range comprises increasing the left-eye display size and the right-eye display size with decreasing apparent real world depth and decreasing the left-eye display size and right-eye display size with increasing apparent real world depth outside the non-scaling range of real world depths. 14. The method of claim 12 , wherein maintaining an aspect of the left-eye display size and the right-eye display size throughout the non-scaling range comprises maintaining the augmented reality object as a constant proportion of a field of view of the wearer throughout the non-scaling range. 15. The method of claim 14 , wherein maintaining the augmented reality object as a constant proportion of the field of view of the wearer comprises changing a real world size of the augmented reality object relative to real world objects at a same depth of the augmented reality object as the apparent real world depth of the augmented reality object changes. 16. The method of claim 12 , wherein the augmented reality object comprises a virtual user marking, and wherein maintaining an aspect of the left-eye display size and the right-eye display size throughout a non-scaling range of apparent real world depths comprises maintaining a line thickness of the virtual user marking. 17. A wearable, head-mounted display system comprising: a left near-eye, see-through display configured to display a first left-eye augmented reality image and a second left-eye augmented reality image, the first and second left-eye augmented reality images displayed with different left-eye display sizes at different left-eye display coordinates; a right near-eye, see-through display configured to display a first right-eye augmented reality image and a second right-eye augmented reality image, the first and second right-eye augmented reality images displayed with different right-eye display sizes at different right-eye display coordinates, the first left-eye and first right-eye augmented reality images collectively forming a first augmented reality object, the second left-eye and second right-eye augmented reality images collectively forming a second augmented reality object, the first and second augmented reality objects perceivable at respective apparent real world depths by a wearer of the head-mounted disp