Lead edge offset correction for intermediate transfer drum imaging

What is claimed is: 1. An intermediate transfer drum (ITD) printing apparatus for registering and printing an image on top of another image already printed on a substrate and wherein the ITD includes a print roll and a transfer roll interfaced to form a transfer nip for applying the image to the substrate, and wherein the print roll has a radius, from an axis of rotation to a surface of the print roll, that is variable which introduces a device offset of the print roll, said apparatus comprising: a print head positioned over the print roll; a processor operatively connected to the print head, said print head transferring the image, when commanded by said processor, to the print roll at an imaging point; a substrate transport operatively connected to the processor and driven in a process direction towards the transfer nip; a first sensor for detecting a registration mark present on the image already printed on the substrate to alert said processor of the approach of the substrate towards the ITD; a second sensor, operatively connected to said processor, for detecting a plurality of discrete angular positions that correspond to rotation of said print roll, said processor using said plurality of discrete angular positions and predetermined data of the print roll to continuously update the device offset of the print roll; a third sensor, operatively, connected to said processor, which measures a distance traveled by the substrate between said first sensor and the print roll; and wherein when said first sensor alerts said processor of the detection of said registration mark, said processor begins counting down the most current device offset until the device offset is completed at which time said processor commands said print head to transfer the image to said print roll at said imaging point such that the image is subsequently transferred, at the transfer nip, to the substrate upon the another image in a registered position. 2. The ITD printing apparatus of claim 1 wherein said second and third sensors comprise an encoder disk and encoder index detector, said encoder disk coaxially-mounted on the print roll. 3. The ITD printing apparatus of claim 1 wherein said second sensor comprises an index detector on the print roll, and the third sensor comprises an encoder disk coaxially-mounted on the transfer roll and wherein rotation of the transfer roll is configured.to match the surface speed of the print roll in the transfer nip. 4. The ITD printing apparatus of claim 1 wherein said second sensor comprises an index detector on the print roll and the second sensor comprises an encoder disk coaxially-mounted on a follower roll, upstream of said ITD, and wherein rotation of the follower roll is configured to freely rotate with the substrate such that the roll surface speed matches the substrate speed. 5. The ITD printing apparatus of claim 1 wherein said processor counts down said most current device offset by using whole values of encoder tics until a fractional increment of encoder tics remains. 6. The ITD printing apparatus of claim 5 further comprising said processor uses velocity-based calculated distance increments to operate on said fractional increment of encoder tics to complete the count down and transfer the image to the imaging point on the print roll. 7. The ITD printing apparatus of claim 1 wherein said predetermined data comprises a look-up table that associates encoder lines of revolution, in correspondence with an index position, with roll segments. 8. A method for controlling an intermediate transfer drum (ITD) printing apparatus to register and print an image on top of another image already printed on a substrate and wherein the ITD includes a print roll and a transfer roll interfaced to form a transfer nip for applying the image to the substrate, the print roll having a variable radius which introduces a device offset of the print roll, said method comprising: positioning a print head over the print roll; operatively connecting a processor to the print head such that, when commanded by said processor, said print head transferring the image to the print roll at an imaging point; operatively connecting a substrate transport to the processor and wherein the substrate transport is driven in a process direction towards the transfer nip; detecting, using a first sensor, a registration mark present on the image already printed on the substrate to alert said processor of the approach of the substrate towards the ITD; operatively connecting a second sensor to said processor for detecting a plurality of discrete angular positions that correspond to rotation of said print roll and wherein said processor uses said plurality of discrete angular positions and predetermined data of the print roll to continuously update the device offset of the print roll; and alerting said processor, by said first sensor, of the detection of said registration mark; and counting down the most current device offset, by said processor, until the device offset is completed at which time said processor commands said print head to transfer the image to said print roll at said imaging point such that the image is subsequently transferred, at the transfer nip, to the substrate upon the another image in a registered position. 9. The method of claim 8 wherein said step of operatively connecting said second sensor comprises co-axially mounting an encoder disk on the print roll. 10. The method of claim 8 wherein said step of operatively connecting said second sensor comprises coaxially-mounting said encoder disk on the transfer roll and wherein rotation of the transfer roll is configured to match a surface velocity of the print roll in the transfer nip. 11. The method of claim 8 wherein said step of operatively connecting said second sensor comprises coaxially-mounting said encoder disk on a follower roll, upstream of said ITD, and wherein rotation of the follower roll is configured to match a surface velocity of the print roll in the transfer nip. 12. The method of claim 8 wherein said step of counting down the most current device offset comprises said processor counting down said most current device offset by using whole values of encoder tics until a fractional increment of encoder tics remains. 13. The method of claim 12 wherein said step of counting the most current device offset comprises said processor using velocity-based calculated distance increments to operate on said fractional increment of encoder tics to complete the count down and transfer the image to the imaging point on the print roll. 14. The method of claim 8 wherein said predetermined data comprises a look-up table that associates encoder lines of revolution, in correspondence with an encoder index, with roll segments.