Controlled switching for electrochromic devices

What is claimed is: 1. An apparatus, comprising: an electrochromic device comprising: at least two separate conductive layers, on opposite sides of an electrochromic (EC) stack; and a short of the EC stack; wherein: the electrochromic device is structured to selectively switch each of at least two separate EC regions of the EC stack to at least one of at least two different transmission levels, based at least in part upon different respective sheet resistances in corresponding at least two separate conductive layer regions of at least one of the at least two separate conductive layers and based at least in part on a respective distance of each of the at least two separate conductive layer regions from the short of the EC stack, wherein the at least two separate conductive layer regions are located relative to the short to form a specific transmission pattern. 2. The apparatus of claim 1 , wherein: the electrochromic device is structured to selectively switch each of the at least two separate EC regions of the EC stack to at least one of at least two different transmission levels to selectively switch the EC stack between at least two separate transmission patterns. 3. The apparatus of claim 1 , wherein: the at least two separate EC regions of the EC stack comprises a plurality of concentric annular regions extending outward from the short, wherein each separate EC region corresponds to a separate one of a plurality of concentric annular conductive layer regions extending outward from the short. 4. The apparatus of claim 1 , wherein: the electrochromic device comprises a selectively apodized camera aperture filter structured to switch to an apodized transmission state, based at least in part upon selectively varying voltage applied to the separate conductive layer segments, to selectively change the transmission pattern of the electrochromic device to a particular transmission pattern which approximates a Gaussian pattern. 5. The apparatus of claim 1 , wherein: the corresponding at least two separate conductive layer regions comprise at least one outer region and a particular region encompassed by the at least one outer region; and a sheet resistance of the particular region is greater than a sheet resistance of the at least one outer region. 6. The apparatus of claim 5 , wherein: the corresponding at least two separate conductive layer regions comprise at least one inner region encompassed by the particular region; and a sheet resistance of the at least one inner region is less than the sheet resistance of the particular region. 7. The apparatus of claim 6 , wherein: the particular region is structured to enable increased uniformity of current distribution to the at least one inner region from the at least one outer region, based at least in part upon the sheet resistance of the particular region being greater than the sheet resistance of the at least one outer region. 8. The apparatus of claim 1 , wherein: each conductive layer region of the at least two separate conductive layer regions having different sheet resistances comprises one or more of a particular crystal structure, a particular crystallinity level, a particular chemical composition, or a particular chemical distribution associated with a particular sheet resistance of the respective conductive layer region. 9. A method comprising: structuring an electrochromic device, which comprises an electrochromic (EC) layer located between at least two conductive layers to form an EC stack, to selectively switch to different transmission levels in separate EC stack regions, wherein the structuring comprises: adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions; and forming a short of the EC stack in a specified location. 10. The method of claim 9 , wherein: the separate EC stack regions comprise at least one annular region surrounding the short; and adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions comprises adjusting a sheet resistance of at least one annular TC region, to configure the electrochromic device to selectively switch the EC stack to at least one transmission pattern, extending away from the short. 11. The method of claim 9 , wherein: adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions comprises increasing a sheet resistance of the at least one selected conductive layer region, relative to a separate sheet resistance of a separate conductive layer region at least partially encompassing the selected conductive layer region. 12. The method of claim 9 , wherein: adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions comprises: introducing at least one chemical species into the at least one selected conductive layer region to adjust a chemical species distribution of the at least one selected conductive layer region, independently of at least one other conductive layer region of the at least one conductive layer, wherein the chemical species distribution of the at least one selected conductive layer region is associated with the sheet resistance of the at least one selected conductive layer region. 13. The method of claim 12 , wherein: introducing at least one chemical species into the at least one selected conductive layer region to adjust a chemical species distribution of the at least one selected conductive layer region comprises: implanting one or more chemical species in at least two different conductive layer regions to establish different chemical species distributions in the at least two different conductive layer regions, based at least in part upon separate set of implantation parameters associated with each of the at least two different conductive layer regions. 14. The method of claim 13 , wherein: implanting one or more chemical species in at least two different conductive layer regions to establish different chemical species distributions in the at least two different conductive layer regions comprises: implanting one or more oxidizing species in at least one conductive layer region, of at least two different conductive layer regions, to establish different oxidizing species distributions in the at least two different conductive layer regions. 15. The method of claim 9 , wherein: adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions comprises: heating the at least one selected conductive layer region to induce a chemical reaction in the at least one selected conductive layer region which adjusts the sheet resistance of the at least one selected conductive layer region, independently of at least one other conductive layer region of the at least one conductive layer. 16. The method of claim 9 , wherein: adjusting a sheet resistance of at least one selected conductive layer region corresponding to at least one of the separate EC stack regions comprises one or more of the following: depositing the at least one selected conductive layer region at one or more particular selected thicknesses associated with one or more various selected conductive layer sheet resistances; removing at least a portion of the at least one selected conductive layer region to establish one or more particular selected thicknesses associated with one or more various sel