Onboard controller for multistate windows

What is claimed is: 1. An insulated glass unit assembly comprising: a. a first transparent substrate comprising an electrochromic device thereon; b. a second transparent substrate; c. a sealing separator between the first and second transparent substrates, the sealing separator comprising a separator and a primary seal between the separator and each of the first and second transparent substrates; d. an onboard controller disposed on one of the first or second transparent substrates and configured to provide optical switching control of the electrochromic device; and e. electrical wiring connecting the onboard controller with the electrochromic device on the first transparent substrate, wherein the electrical wiring passes through the sealing separator, wherein the onboard controller comprises a memory or RFID tag programmed with data on the characteristics of the electrochromic device or the insulated glass unit assembly. 2. The insulated glass unit assembly of claim 1 , wherein the onboard controller is mounted on the first transparent substrate. 3. The insulated glass unit assembly of claim 1 , wherein the onboard controller is not in the viewable area of the insulated glass unit assembly. 4. The insulated glass unit assembly of claim 1 , wherein the onboard controller comprises a user interface configured to allow an end user to control the electrochromic device functions. 5. The insulated glass unit assembly of claim 1 , provided in a network of insulated glass unit assemblies configured in a daisy chain format. 6. The insulated glass unit assembly of claim 1 , provided in a network of insulated glass unit assemblies configured in a linear bus topology. 7. The insulated glass unit assembly of claim 6 , wherein the linear bus topology is a CAN linear bus topology. 8. The insulated glass unit assembly of claim 1 , wherein the onboard controller comprises a wireless communication interface. 9. The insulated glass unit assembly of claim 8 , wherein the wireless communication interface is a Bluetooth or Zigbee interface. 10. The insulated glass unit assembly of claim 1 , wherein the onboard controller comprises one or more sensors. 11. The insulated glass unit assembly of claim 10 , wherein the one or more sensors comprises an optical sensor. 12. The insulated glass unit assembly of claim 1 , wherein the onboard controller has a wireless powering capability. 13. The insulated glass unit assembly of claim 1 , wherein the onboard controller comprises a redundant power driver circuit. 14. The insulated glass unit assembly of claim 1 , wherein the onboard controller comprises a chip, a card or a board, each including a logic circuit. 15. The insulated glass unit assembly of claim 14 , wherein the onboard controller comprises a field programmable gate array. 16. The insulated glass unit assembly of claim 1 , wherein the onboard controller is not in a single enclosure. 17. The insulated glass unit assembly of claim 3 , wherein the onboard controller is between the first and second transparent substrates within a secondary seal of the insulated glass unit assembly. 18. The insulated glass unit assembly of claim 17 , wherein the onboard controller does not extend beyond the perimeter of the first and second transparent substrates. 19. The insulated glass unit assembly of claim 1 , wherein the memory or RFID tag stores drive configuration parameters for driving tint state transitions on the electrochromic device, wherein the drive configuration parameters comprise one or more parameters selected from the group consisting of: a voltage to be applied to the electrochromic device during an optical transition of the electrochromic device, a rate of change of voltage to be applied to the electrochromic device during the optical transition of the electrochromic device, and a current limit corresponding to a current applied to the electrochromic device during the optical transition of the electrochromic device.