Method for missing ejector compensation in three-dimensional object printing

What is claimed is: 1. A method of compensating for inoperative ejectors in a three-dimensional object printer comprising: identifying image data values associated with an inoperative ejector in a plurality of ejectors, the identified image data values are within a plurality of image data values stored in memory for a three-dimensional object to be printed by the three-dimensional object printer; replacing the image data values associated with the inoperative ejector with image data values associated with an operative ejector in the plurality of ejectors that ejects a material that is different than a material ejected by the inoperative ejector; and operating the plurality of ejectors using the plurality of image data values and the image data values that replaced the image data values associated with the inoperative ejector so the operative ejector ejects drops of the material that is different than the material ejected by the inoperative ejector into the three-dimensional object at positions where the image data values associated with the inoperative ejector would have operated the inoperative ejector to eject material. 2. The method of claim 1 further comprising: moving the image data values associated with the inoperative ejector within a first layer by a first distance and moving the image data values associated with the inoperative ejector in a second layer by a second distance that is different than the first distance to attenuate an effect of the inoperative ejector on the first and the second layers. 3. The method of claim 2 wherein the first layer is adjacent to the second layer. 4. The method of claim 2 wherein the movement of the image data values associated with the inoperative ejector in the first and the second layers occurs before the image data values associated with the inoperative ejector are replaced with the image data values associated with the operative ejector. 5. The method of claim 4 wherein the image data values associated with the inoperative ejector correspond to a colored material and the image data values associated with the operative ejector correspond to a clear material. 6. The method of claim 5 further comprising: identifying image data values associated with other operative ejectors that correspond to material that is different than the colored material and different than the clear material, the identified image data values being located within predetermined volumes about the identified image data values associated with the inoperative ejector; and replacing the identified image data values associated with the other operative ejectors with image data values associated with the operative ejector that correspond to clear material. 7. The method of claim 6 further comprising: identifying a ratio between the identified image data values associated with the other operative ejectors that are located within the predetermined volumes and the identified image data values associated with the inoperative ejector; and using the identified ratio to replace the identified image data values associated with the other operative ejectors that are located within the predetermined volumes. 8. The method of claim 6 , the identification of the image data values associated with the other operative ejectors further comprising: identifying only the image data values associated with the other operative ejectors that correspond to white material. 9. The method of claim 6 further comprising: replacing the identified image data values associated with one of the other operative ejectors that correspond to white material with image data values associated with the operative ejector that correspond to the clear material. 10. The method of claim 9 further comprising: identifying image data values associated with other operative ejectors that eject a material that is different than the white material and different than the clear material, the identified image data values being located within predetermined volumes about the image data values identified with the inoperative ejector; and replacing the identified image data values associated with the other ejectors with image data values associated with the operative ejector that corresponds to the clear material. 11. The method of claim 1 , the identification and replacement of the image data values further comprising: identifying continuous tone image data values associated with the inoperative ejector; and replacing the continuous tone image data values associated with the inoperative ejector with continuous tone image data values associated with the operative ejector that correspond to the clear material. 12. The method of claim 1 , the identification and replacement of the image data values further comprising: identifying halftone image data values associated with the inoperative ejector; and replacing the halftone tone image data values associated with the inoperative ejector with halftone image data values associated with the operative ejector that correspond to the clear material. 13. The method of claim 1 further comprising: identifying image data values associated with a color formed with at least two differently colored materials, the image data values associated with one of the at least two differently colored materials are also associated with the inoperative ejector; and replacing the identified image data values associated with the other one of the at least two differently colored materials with image data values associated with an operative ejector that corresponds to white material. 14. A method of compensating for inoperative ejectors in a three-dimensional object printer comprising: identifying image data values associated with an inoperative ejector in a plurality of ejectors, the identified image data values are within a plurality of image data values stored in memory for a three-dimensional object to be printed by the three-dimensional object printer; moving the image data values associated with the inoperative ejector within a first layer by a first distance and moving the image data values associated with the inoperative ejector in a second layer by a second distance that is different than the first distance to attenuate an effect of the inoperative ejector on the first and the second layers; replacing the image data values associated with the inoperative ejector with image data values associated with an operative ejector in the plurality of ejectors that ejects a material that is different than a material ejected by the inoperative ejector after the image data values associated with the inoperative ejector in the first and the second layers have been moved; and operating the plurality of ejectors using the plurality of image data values and the image data values that replaced the image data values associated with the inoperative ejector so the operative ejector ejects drops of the material that is different than the material ejected by the inoperative ejector into the three-dimensional object at positions where the image data values associated with the inoperative ejector would have operated the inoperative ejector to eject material. 15. The method of claim 2 wherein the first layer is adjacent to the second layer. 16. The method of claim 14 wherein the image data values associated with the inoperative ejector correspond to a colored material and the image data values associated with the operative ejector correspond to a clear material. 17. The method of claim 16 further comprising: identifying image data values associated with other operative ejectors that correspond