Adjustable solid film camera aperture

What is claimed is: 1. An electro-optic variable aperture to control light that passes through an imaging path, the electro-optic variable aperture comprising: a first aperture stack that provides a first aperture; and a second aperture stack placed on the first aperture stack, the second aperture stack defining a second aperture that is larger than the first aperture; wherein each aperture stack includes a first transparent conductive oxide layer, a counter electrode layer, an ion conductor layer, an electro-chromic layer, and a second transparent conductive oxide layer; wherein the first transparent conductive oxide layer of the first aperture stack is deposited on a transparent substrate; wherein the first transparent conductive oxide layer of the second aperture stack is the second transparent conductive oxide layer of the first aperture stack. 2. The electro-optic variable aperture of claim 1 wherein the counter electrode layer is deposited on the first transparent conductive oxide layer, the ion conductor layer is deposited on the counter electrode layer, the electro-chromic layer is deposited on the ion conductor layer, and the second transparent conductive oxide layer is deposited on the electro-chromic layer in each aperture stack. 3. The electro-optic variable aperture of claim 1 wherein the first transparent conductive oxide layer, the counter electrode layer, the ion conductor layer, the electro-chromic layer, and the second transparent conductive oxide layer are each a solid film in each aperture stack. 4. The electro-optic variable aperture of claim 1 wherein the electro-chromic layer has an annular shape and the inside diameter of the annulus defines the aperture in each aperture stack. 5. The electro-optic variable aperture of claim 1 wherein the second transparent conductive oxide layer of the first aperture stack is deposited on the electro-chromic layer of the first aperture stack. 6. The electro-optic variable aperture of claim 5 wherein the second transparent conductive oxide layer of the second aperture stack is deposited on the electro-chromic layer of the second aperture stack. 7. The electro-optic variable aperture of claim 1 wherein a first electrical potential is applied between the first transparent conductive oxide layer and the second transparent conductive oxide layer to make the electro-chromic layer opaque, and a second electrical potential is applied between the first transparent conductive oxide layer and the second transparent conductive oxide layer to make the electro-chromic layer transparent in each aperture stack. 8. The electro-optic variable aperture of claim 7 wherein the first electrical potential and the second electrical potential have opposite polarities. 9. A portable electronic device comprising: a device housing; and an electronic camera module in the device housing, the electronic camera module having a focusing lens with an optical axis, an imaging sensor to receive focused light, and an electro-optic variable aperture to allow different amounts of focused light to reach the imaging sensor; wherein the electro-optic variable aperture includes a first aperture stack placed on a transparent substrate, the first aperture stack defining a first aperture, and a second aperture stack placed on the first aperture stack, the second aperture stack defining a second aperture that is larger than the first aperture; wherein each aperture stack includes a first transparent conductive oxide layer, a counter electrode layer, an ion conductor layer, an electro-chromic layer, and a second transparent conductive oxide layer; wherein the first transparent conductive oxide layer of the first aperture stack is deposited on the transparent substrate; wherein the first transparent conductive oxide layer of the second aperture stack is the second transparent conductive oxide layer of the first aperture stack. 10. The portable electronic device of claim 9 wherein the counter electrode layer is deposited on the first transparent conductive oxide layer, the ion conductor layer is deposited on the counter electrode layer, the electro-chromic layer is deposited on the ion conductor layer, and the second transparent conductive oxide layer is deposited on the electro-chromic layer in each aperture stack. 11. The portable electronic device of claim 9 wherein the first transparent conductive oxide layer, the counter electrode layer, the ion conductor layer, the electro-chromic layer, and the second transparent conductive oxide layer are each a solid film in each aperture stack. 12. The portable electronic device of claim 9 wherein the electro-chromic layer has an annular shape and the inside diameter of the annulus defines the aperture in each aperture stack. 13. The portable electronic device of claim 9 wherein the second transparent conductive oxide layer of the first aperture stack is deposited on the electro-chromic layer of the first aperture stack. 14. The portable electronic device of claim 13 wherein the second transparent conductive oxide layer of the second aperture stack is deposited on the electro-chromic layer of the second aperture stack. 15. The portable electronic device of claim 9 wherein a first electrical potential is applied between the first transparent conductive oxide layer and the second transparent conductive oxide layer to make the electro-chromic layer opaque, and a second electrical potential is applied between the first transparent conductive oxide layer and the second transparent conductive oxide layer to make the electro-chromic layer transparent in each aperture stack. 16. The portable electronic device of claim 15 wherein the first electrical potential and the second electrical potential have opposite polarities. 17. An electro-optic variable aperture to control light that passes through an imaging path, the electro-optic variable aperture comprising: an aperture stack including a first transparent conductive oxide layer in form of a first annulus having a first outer diameter and a first inner diameter, a second transparent conductive oxide layer in form of a second annulus and a third annulus concentric with the second annulus, the second annulus having the first outer diameter and a second inner diameter that is larger than the first inner diameter, the third annulus having a second outer diameter that is smaller than the second inner diameter and the first inner diameter, an electro-chromic layer, an ion conductor layer, and a counter electrode layer. 18. The electro-optic variable aperture of claim 17 wherein the second transparent conductive oxide layer is deposited on a transparent substrate, the electro-chromic layer is deposited on the second transparent conductive oxide layer, the ion conductor layer is deposited on the electro-chromic layer, the counter electrode layer is deposited on the ion conductor layer, and the first transparent conductive oxide layer is deposited on the counter electrode layer, wherein the electro-chromic layer electrically isolates the second annulus from the third annulus in the second transparent conductive oxide layer. 19. The electro-optic variable aperture of claim 17 wherein the first transparent conductive oxide layer is deposited on a transparent substrate, the electro-chromic layer is deposited on the first transparent conductive oxide layer, the ion conductor layer is deposited on the electro-chromic layer, the counter electrode layer is deposited on the ion conductor layer, and the second transparent conductive oxid