A portable magnifying assembly includes an external electronic device that may display an image. A bellows has a top end, a bottom end and a peripheral wall extending therebetween. The top end is open and the bellows are substantially hollow. The bottom end may be positioned on a support surface and the bellows may be positioned in an extended position. A magnifying plate is removably positioned on the bellows thereby facilitating the magnifying plate to magnify the image displayed on the external electronic device when the bellows is positioned in the extended position.

A portable magnifying assembly includes an external electronic device that may display an image. A bellows has a top end, a bottom end and a peripheral wall extending therebetween. The top end is open and the bellows are substantially hollow. The bottom end may be positioned on a support surface and the bellows may be positioned in an extended position. A magnifying plate is removably positioned on the bellows thereby facilitating the magnifying plate to magnify the image displayed on the external electronic device when the bellows is positioned in the extended position.

A head-mounted display in accordance with an embodiment of the present technology includes a display housing and one or more displays within the display housing. The display system further includes a first lens and a second lens, each being operably associated with the one or more displays. A lateral distance between the first and second lenses is adjustable to accommodate users having different interpupillary distances. The display system still further includes a flexible membrane having a region extending between the first and second lenses. The region of the membrane extending between the first and second lenses is configured to resiliently expand as the lateral distance between the first and second lenses increases and to resiliently contract as the lateral distance between the first and second lenses decreases.

A head-mounted display in accordance with an embodiment of the present technology includes a display housing and one or more displays within the display housing. The display system further includes a first lens and a second lens, each being operably associated with the one or more displays. A lateral distance between the first and second lenses is adjustable to accommodate users having different interpupillary distances. The display system still further includes a flexible membrane having a region extending between the first and second lenses. The region of the membrane extending between the first and second lenses is configured to resiliently expand as the lateral distance between the first and second lenses increases and to resiliently contract as the lateral distance between the first and second lenses decreases.

A device for adjustably positioning an optical component includes a holding unit, which is which at least partly composed of a magnetostrictive material, and a mechanism for generating a magnetic field having a predetermined directional and amplitude distribution in the region of the holding unit. The holding unit has, in a predefined direction, an expansion which can be varied by a specific absolute value by the effect of the magnetic field.

A device for adjustably positioning an optical component includes a holding unit, which is which at least partly composed of a magnetostrictive material, and a mechanism for generating a magnetic field having a predetermined directional and amplitude distribution in the region of the holding unit. The holding unit has, in a predefined direction, an expansion which can be varied by a specific absolute value by the effect of the magnetic field.

An optical projection unit includes first and second optical element modules. The first optical element module includes a first housing unit and a first optical element received within the first housing unit and having an optically used first region defining a first optical axis. The second optical element module is located adjacent to the first optical element module and includes a second optical element which defines a second optical axis of the optical projection unit. The first housing unit has a central first housing axis and an outer wall extending in a circumferential direction about the first housing axis. The first optical axis is laterally offset and/or inclined with respect to the first housing axis. The first housing axis is substantially collinear with the second optical axis.

An optical projection unit includes first and second optical element modules. The first optical element module includes a first housing unit and a first optical element received within the first housing unit and having an optically used first region defining a first optical axis. The second optical element module is located adjacent to the first optical element module and includes a second optical element which defines a second optical axis of the optical projection unit. The first housing unit has a central first housing axis and an outer wall extending in a circumferential direction about the first housing axis. The first optical axis is laterally offset and/or inclined with respect to the first housing axis. The first housing axis is substantially collinear with the second optical axis.

There is provided a lens element which is capable of obtaining a small-sized image capturing device with excellent resolving power, and an image capturing device including the lens element. A shape of an outer profile of an image side surface (L2) is substantially rectangular.

An optical element driving mechanism is provided. The optical element driving mechanism includes a movable portion, a fixed portion, and a driving assembly. The movable portion is used to connect the optical element. The movable portion may move relative to the fixed portion. The driving assembly is used to drive the movable portion to move relative to the fixed portion.