Matrix-addressed heat image forming device

What is claimed is: 1. A heat image forming device useful in printing with an image forming device having a rotatable reimageable latent imaging roll, comprising: a heating array disposed as a layer of the rotatable reimageable latent imaging roll proximate an outer surface of the latent imaging roll, the heating array including a pixelated array of controllable heating elements spread about the layer with each heating element corresponding to a respective pixel of the pixelated array, wherein a fluid is deposited over the rotatable reimageable latent imaging roll; driving circuitry communicatively connected to the heating array for selectively temporarily heating the heating elements in a patterned image to an elevated temperature; the selectively temporarily heated heating elements configured to heat portions of the rotatable reimageable latent imaging roll outer surface proximate the heating array as a heated patterned image when the selected heating elements are at the elevated temperature, the heated patterned image configured to modify the deposited fluid over the rotatable reimageable latent imaging roll to produce a latent image of fluid on the rotatable reimageable latent imaging roll surface based on the patterned image. 2. The device of claim 1 , each controllable heating element including a thin film transistor, the thin film transistors each having a semiconductor layer, a gate electrode, a source electrode, a drain electrode and a gate dielectric layer, the semiconductor layer having a current channel defined by a spatial gap between the source electrode and gate electrode, and an overlapping distance of the drain and source electrodes in the semiconductor layer. 3. The device of claim 2 , the driving circuitry including a plurality of conductive lines including gate address lines, current supply data lines, and current return lines, with each one of the gate electrodes electronically coupled to one of the gate lines, each one of the source or drain electrodes electronically connected to one of the data lines, and each of the other one of the source or drain electrodes electronically connected to one of the current return lines, each heating circuit having a current supplied via a connecting current supply data line in the current channel that is controlled by a voltage applied to the gate electrode via a connecting gate address line. 4. The device of claim 3 , wherein the current return lines form a current return mesh layer offset from the gate electrode by the second dielectric layer and opposite the source and drain electrodes, with different ones of the current return lines running parallel to both the gate address lines and the current supply lines, and the current channel is closer to the outer surface than the current return mesh layer. 5. The device of claim 3 , further comprising gate line drivers coupled to the gate address lines and data line drivers coupled to the current supply data lines, the gate address lines being orthogonal to the current supply data lines, with adjacent pairs of gate address lines and data lines defining a respective one of the heating elements, and the controllable heating elements being selectively switched via active matrix addressing. 6. The device of claim 5 , wherein the gate line drivers and data line drivers are positioned on a side of the pixelated array of controllable heating elements opposite the outer surface of the rotatable reimageable latent imaging roll, with the gate line drivers and data line drivers spatially separated from the pixelated array of controllable heating elements by a dielectric layer therebetween. 7. The device of claim 3 , wherein the rotatable reimageable latent imaging roll has a longitudinal axis and a cylinder circumference, the gate address lines extend across the latent imaging roll parallel to the longitudinal axis and the current supply data lines extend along the cylinder circumference. 8. The device of claim 1 , the heating array further including an insulating layer over the pixelated array of controllable heating elements adjacent the outer surface of the rotatable reimageable latent imaging roll. 9. The device of claim 8 , wherein the rotatable reimageable latent imaging roll is further configured to receive an ink image thereon for transfer of said ink image to a print substrate based on the heated patterned image. 10. The device of claim 1 , wherein the rotatable reimageable latent imaging roll has a cylinder circumference, each heating element being pixel sized with a width and a length, the heating array having the heating elements extending from a first side of the heating array along the cylinder circumference to a second side of the heating array opposite the first side leaving a gap between the first side and the second side smaller than the width or length of a heating element resulting in a seamless heating array around the rotatable reimageable latent imaging roll. 11. The device of claim 1 , wherein the rotatable reimageable latent imaging roll has a cylinder circumference, each heating element being pixel sized with a width and a length, the heating array having the heating elements extending from a first side of the heating array along the cylinder circumference to a second side of the heating array opposite the first side and in contact with the first side when disposed as the layer of the rotatable reimageable latent imaging roll. 12. The device of claim 1 , wherein the rotatable reimageable latent imaging roll is a first rotatable reimageable latent imaging roll having a cylinder circumference, each heating element being pixel sized with a width and a length, the heating array having the heating elements extending from a first side of the heating array along the cylinder circumference to a second side of the heating array opposite the first side leaving a gap between the first side and the second side larger than the width or length of a heating element, and further comprising a second rotatable reimageable latent imaging roll having a second heating array disposed as an outer layer thereof proximate an outer surface of the second rotatable reimageable latent imaging roll, the second heating array including a second pixelated array of second controllable heating elements spread about the outer layer with each heating element corresponding to a respective second pixel of the second pixelated array; the second rotatable reimageable latent imaging roll further having second driving circuitry communicatively connected to the second heating array for selectively temporarily heating the second heating elements in image-wise fashion to the elevated temperature, wherein portions of the second rotatable reimageable imaging member outer surface proximate the second heating array are heated by the second heating elements when the selected second heating elements are at the elevated temperature, the second rotatable reimageable latent imaging roll located adjacent the first rotatable reimageable latent imaging roll and operable in combination with the first rotatable reimageable latent imaging roll to create a seamless heated image output onto a substrate in contact with both the first rotatable reimageable latent imaging roll and the second rotatable reimageable latent imaging roll. 13. The device of claim 1 , further comprising a fountain solution applicator configured to deposit fountain solution as the fluid over a surface of the rotatable reimageable latent imaging roll, and the latent image is formed by the fountain solution remaining over unheated heating elements of the heating array. 14. The device of claim 1 , wherein the rotatable reimageable late