Contact lenses that have an ion-impermeable portion and an ion-permeable portion that are able to move on the eye without binding to the eye are described. The contact lenses exhibit an average ionoflux transmittance of at least 1.34×10.sup.−4 mm/min. One or more electronic components can be included in the contact lenses. Methods of making the contact lenses are also described.

An electronic case for electronic spectacles may include a base comprising a cavity formed therein. A first spectacle retention device may be located within the cavity. The first spectacle retention device may be configured to retain spectacles. An electrical control system may be included. An electrical connector may be configured to couple the electrical control system in electronic communication with the spectacles.

The present disclosure relates generally to eye-tracking systems and methods that provide a user the ability to efficiently activate the system and select and dismiss virtual objects within an augmented reality (“AR”) and/or virtual reality (“VR”) environment. A user may activate the user interface by glancing beyond an activation threshold positioned close enough to the edge of the field of view to reliably infer an intent to activate the virtual controls. Subsequently, the user interacts with virtual tools, first virtual “peek” windows and secondary virtual windows to obtain content or virtual control across a variety of granular levels. Subsequently, the user may glance away at virtual content or to other predefined areas within their eye's range of motion to dismiss the tool and/or deactivate the system.

According to some exemplary embodiments of the present disclosure, provided is a lens for providing varifocal focus. The lens for providing the varifocal focus may include: a liquid crystal layer that is variably oriented according to a voltage to have a variable refractive index; a first lens-shaped optical unit including a first optical layer having one side in contact with one side of the liquid crystal layer and a second optical layer having one side in contact with the other side of the liquid crystal layer; and a second lens-shaped optical unit made of a polymer series, having a fixed refractive index, and including a third optical layer having one side in contact with an outer surface of the first optical layer and a fourth optical layer having one side in contact with an outer surface of the second optical layer.

A lens including a flexible refractive optic having a fixed refractive index, an electro-active element embedded within the flexible refractive optic, wherein the electro-active element has an alterable refractive index, and a controller electrically connected to the electro-active element wherein when power is applied thereto the refractive index of the electro-active element is altered.

An optical device (3) comprising a light transmitting electrode layer (2) provided onto a light transmitting carrier (15), wherein a conductive layer (6) is provided on the first electrode layer (2), the conductive layer establishing a connecting area (4), the conductive layer having a thickness being significantly larger than the thickness of the electrode layer (2), and wherein the electrode layer (2) and carrier (15) show a perforation in the connecting area, the perforation being at least partially filled with a conductive material (7) which is further connected to a conductive element (1) thereby establishing an electrical connection between the electrode layer (2) and the conductive element (1) via the conductive layer (6) and the conductive material.

A multifunctional eyeglass device includes a control module, a lens group, a power supply module, a storage module, a communication module, and a frame. The lens group includes a first lens module and a second lens module, the first lens module includes a first liquid crystal lens unit and a first display unit, and the second lens module includes a second liquid crystal lens unit and a second display unit. The control module is electrically connected to the first and second lens module of the lens group, the power supply module, the storage module, and the communication module. The first and second liquid crystal lens units are adjusted in focal length according to at least one power source. The control module receives data via the communication module, and the data is displayed by the first and second display unit.

An electronic case for electronic spectacles may include a base comprising a cavity formed therein. A first spectacle retention device may be located within the cavity. The first spectacle retention device may be configured to retain spectacles. An electrical control system may be included. An electrical connector may be configured to couple the electrical control system in electronic communication with the spectacles.

Techniques and mechanisms for exchanging encrypted communications wirelessly with an accommodation-capable eye-mountable device (EMD). In an embodiment, a controller of the EMD is configured to encrypt data to be sent from the EMD to an auxiliary device or to decrypt data received by the EMD from the auxiliary device. Cryptographic operations to securely exchange the communications are based on a key value and a vector determined at the EMD. In another embodiment, the auxiliary device operates as a master, and the EMD operates as a slave, at least with respect to enablement of a functionality of the EMD to change an association of a cryptographic key value with a vector.

An electro-active lens with stacked, rotated cylindrical electro-active lens elements can provide cylinder power along more axes than there are cylindrical electro-active lens elements. For instance, six stacked cylindrical electro-active lens elements, each aligned with a different lens meridian, can produce cylinder power along fifteen unique meridians when actuated up to three at a time. If these fifteen meridians are spaced at 12° increments, then the lens stack can provide cylinder power that is aligned well to correct astigmatism along any axis. Each cylindrical electro-active lens element in the stack can include a liquid crystal layer that is actuated by linear electrodes that are parallel to each other and orthogonal to both the cylindrical electro-active lens element's cylinder axis and optical axis. The electro-active lens can also include a spherical lens element that provides spherical power in addition to any net spherical power produced by the stacked cylindrical electro-active lens elements.