A periscope lens module of a mobile terminal and the mobile terminal are disclosed. The periscope lens module includes a motor housing and a lens. The lens includes an enclosure, a first lens, and a second lens. The enclosure includes a first cylinder and a second cylinder connected to the first cylinder. At least one gap penetrating a sidewall of the first cylinder is disposed on the sidewall. The first lens is fastened in the first cylinder, and the second lens is fastened in the second cylinder.

A periscope lens module of a mobile terminal and the mobile terminal are disclosed. The periscope lens module includes a motor housing and a lens. The lens includes an enclosure, a first lens, and a second lens. The enclosure includes a first cylinder and a second cylinder connected to the first cylinder. At least one gap penetrating a sidewall of the first cylinder is disposed on the sidewall. The first lens is fastened in the first cylinder, and the second lens is fastened in the second cylinder.

A head for a walk-around costume is provided that is adapted for enhanced visibility. The costume head includes an outer shell defining an interior space for receiving a head of a human performer. The outer shell includes an aperture allowing incoming light from an exterior space to enter the interior space, and an eye location for the human performer is spaced apart from the aperture when the head is received in the interior space. To provide an enlarged field of view, the costume head includes an optical viewfinder assembly disposed within the interior space of the outer shell between the aperture and the eye location. The optical viewfinder assembly is adapted for receiving the incoming light and transmitting the incoming light to the eye location to move a viewpoint of the human performer to the aperture to provide a larger field of view of the exterior space.

A head for a walk-around costume is provided that is adapted for enhanced visibility. The costume head includes an outer shell defining an interior space for receiving a head of a human performer. The outer shell includes an aperture allowing incoming light from an exterior space to enter the interior space, and an eye location for the human performer is spaced apart from the aperture when the head is received in the interior space. To provide an enlarged field of view, the costume head includes an optical viewfinder assembly disposed within the interior space of the outer shell between the aperture and the eye location. The optical viewfinder assembly is adapted for receiving the incoming light and transmitting the incoming light to the eye location to move a viewpoint of the human performer to the aperture to provide a larger field of view of the exterior space.

An optical member includes a light guide body. The light guide body has an incident surface on which an outside light is incident, a first surface having flat portions and prism portions, an incident light incident on the incident surface reaching the first surface for the first time, and a second surface arranged opposite to the flat portions. The flat portions totally reflect the incident light toward the second surface. The second surface totally reflects a reflected light reflected by the flat portion toward the first surface. The prism portion has an ejection surface to emit the incident light to outside.

Provided is a periscopic camera module, which includes a first reflective element mounted on a first base, an optical lens mounted on a second substrate, a second reflective element mounted on a third substrate, and a photosensitive chip mounted on a fourth substrate. Particularly, the first reflective element is used to reflect the incident light to make it longitudinally turned; the optical lens is used to receive the reflected light which is longitudinally turned and output an imageable light beam; the second reflective element is a second prism, which is adapted to laterally turn the imageable light beam at least once and has a reflecting surface located on a side surface of the second prism; and the photosensitive chip is adapted to receive the imageable light beam laterally turned by the second reflective element. Also provided is a corresponding electronic device. The length of the periscopic camera module according to the present application may be reduced to be suitable for mass production on a large scale, thereby facilitating to improve production efficiency and yield.

Provided is a periscopic camera module, which includes a first reflective element mounted on a first base, an optical lens mounted on a second substrate, a second reflective element mounted on a third substrate, and a photosensitive chip mounted on a fourth substrate. Particularly, the first reflective element is used to reflect the incident light to make it longitudinally turned; the optical lens is used to receive the reflected light which is longitudinally turned and output an imageable light beam; the second reflective element is a second prism, which is adapted to laterally turn the imageable light beam at least once and has a reflecting surface located on a side surface of the second prism; and the photosensitive chip is adapted to receive the imageable light beam laterally turned by the second reflective element. Also provided is a corresponding electronic device. The length of the periscopic camera module according to the present application may be reduced to be suitable for mass production on a large scale, thereby facilitating to improve production efficiency and yield.

An optical module (10) is attached in front of an optical outlet (21) of a monostatic or quasi-monostatic laser rangefinder (20), for the purpose of transversely offsetting a laser beam of primary radiation (F) emitted by the optical outlet. In this manner, the risk of damage to an optical sensor (23) of the rangefinder can be avoided.

Provided is a prism device applied to a periscope lens module, including a bearing frame, a supporting-restoring assembly, a prism, and shape memory alloy wires. The shape memory alloy wires include first to fourth shape memory alloy wires. The first shape memory alloy wire and the second shape memory alloy wire are configured to drive the supporting-restoring assembly to drive the prism to rotate about a first rotation center axis. The third shape memory alloy wire and the fourth shape memory alloy wire are used to drive the supporting-restoring assembly to drive the prism to rotate about a second rotation center axis. The first rotation center axis is perpendicular to the second rotation center axis. The solutions of the present invention enable the prism to rotate towards two central axes that are perpendicular to each other, and has high stability and a simple structure, thereby achieving miniaturization.

Provided is a prism device applied to a periscope lens module, including a bearing frame, a supporting-restoring assembly, a prism, and shape memory alloy wires. The shape memory alloy wires include first to fourth shape memory alloy wires. The first shape memory alloy wire and the second shape memory alloy wire are configured to drive the supporting-restoring assembly to drive the prism to rotate about a first rotation center axis. The third shape memory alloy wire and the fourth shape memory alloy wire are used to drive the supporting-restoring assembly to drive the prism to rotate about a second rotation center axis. The first rotation center axis is perpendicular to the second rotation center axis. The solutions of the present invention enable the prism to rotate towards two central axes that are perpendicular to each other, and has high stability and a simple structure, thereby achieving miniaturization.