An optical rotary junction module for an OCT system according to the present invention includes an OCT connection part having a screw thread formed on an outer peripheral surface thereof, the OCT connection part being connected to an OCT system configured to produce light, a connecting/fixing part having a screw thread formed on an inner peripheral surface thereof and screw-coupled to and engaging with the screw thread formed on the outer peripheral surface of the OCT connection part, a first housing having a screw thread formed on an inner peripheral surface of one end thereof and a screw thread formed on an inner peripheral surface of the other end thereof, the first housing having one end screw-coupled to the connecting/fixing part, a second housing screw-coupled to the screw thread formed on the inner peripheral surface of the other end of the first housing, a hollow motor inserted into the second housing and configured to generate rotational power, and an adapter configured to be coupled to an imaging catheter configured to be inserted into a blood vessel of a human body and transmit light received from the OCT system. The optical rotary junction module has the effects of reducing noise generated during high-speed rotation, and preventing failure caused by abrasion or the like. Moreover, the module may be structurally simplified and reduced in size, and the product cost per unit thereof may be lowered by minimizing the components.

An inventive rotatable optical short-range transceiver has: a support which is rotatable around a rotation axis, an optical receiver which is arranged at the support on the rotation axis to receive an optical reception signal from a first direction, an optical transmitter which is arranged at the support to be adjacent to the optical receiver to emit an optical transmission signal in a second direction, and an optical transmission/reception unit which is configured to allow interruption-free rotatable optical data communication, wherein the optical transmission/reception unit is arranged at the support above the optical receiver and extends over the optical receiver and the optical transmitter, and wherein the optical transmission/reception unit has a support structure for mounting at the support, which is implemented integrally with the optical transmission/reception unit.

A fiber optics rotary joint (FORJ) connects a system console to a probe having a rotatable core, and transfers rotational motion to the probe core. The FORJ comprises a stationary optical fiber in optical communication with a rotatable optical fiber, a motor having a hollow shaft, and a fiber connector attached to a distal end of the hollow shaft. The motor is configured to rotate the rotatable optical fiber relative to the stationary optical fiber. The rotatable fiber is attached to the proximal end of the hallow shaft and connected to the fiber connector. The distal end of the stationary optical fiber is directly opposed to and aligned with the proximal end of the rotatable optical fiber such that optical axes of the stationary and rotatable optical fibers are substantially collinear with the rotational axis of the motor. The fiber connector transfers optical power and torque to the probe core.

An electronic device may have a display, a display cover layer, and a sheet-packed coherent fiber bundle. The coherent fiber bundle may have an input surface that receives an image from the display and a corresponding output surface to which the image is transported. The coherent fiber bundle may be placed between the display and the display cover layer and mounted to a housing. The coherent fiber bundle may have fiber cores with bends that help conceal the housing from view and make the display appear borderless. The coherent fiber bundle has filaments formed from elongated strands of binder in which multiple fiber cores are embedded. Sheets of filaments are stacked and fused together to form the coherent fiber bundle. By aligning and fusing the sheets with respect to each other the filaments are packed with a desired density and uniformity.

A surgical instrument includes a body, a shaft assembly extending distally from and rotatably coupled to the body, an end effector extending distally from the shaft assembly, a fiber optic cable, and a rotary coupling assembly. The end effector may rotate with the shaft assembly relative to the body. The end effector includes a sensor assembly. The fiber optic cable extends proximally from the sensor assembly, along the shaft assembly, and into the body. The fiber optic cable includes a distal portion that rotates with the end effector, a proximal portion associated with the body, and a coiled portion interposed between the distal portion and the proximal portion. The rotary coupling assembly includes a handle-side body and a shaft-side body. The rotary coupling assembly can radially expand and contract the coiled portion of the fiber optic cable in response to relative rotation between the handle-side body and the shaft-side body.

An arm module includes a housing with a first connection side controllably rotatable relative to a second connection side, about an axis of rotation. The first connection side has a rotatable first connection device. The second connection side has a second connection device fixed to the housing, with a rotation-compatible data transmission device for transmitting data signals along at least one transmission path between the first and second connection sides. The transmission path includes at least one wireless transmission sub-path for wireless transmission of data signals, and at least one wire-guided transmission sub-path for wire-guided transmission of data signals. The rotation-compatible data transmission device includes at least one first wireless transmission unit and at least one second wireless transmission unit, interconnected via the transmission path and arranged to wirelessly transmit and receive data signals along the wireless transmission sub-path. An industrial robot can have a plurality of such arm modules.

An infinite rotation joint that allows members of a suspension arm assembly at the infinite rotation joint to have unlimited rotation relative to one another. The infinite rotation joint is configured to pass at least an optical signal therethrough. At least two portions of the infinite rotation joint are separable and can automatically form a unit when adjacent arms are connected together such that the infinite rotation joint can be separated into the at least two portions. The at least two portions are configured to be automatically connected to allow the optical signal to pass therethrough once the at least two portions are engaged.

A data transmission system used between counter rotating bodies and the design method of the system consisting of a data acquisition unit, one-to-N1 branching unit, N1 launching units, N2 all-in-one combiner, N2 receiving units and data processing equipment. N1 launching units and one-to-N1 branching unit are set on one counter rotating body; N2 all-in-one combiner and N2 receiving units are set on the other counter rotating body; one of the launching units and one of the receiving units are arranged on the closed movement path of the rotating body, and the maximum interval between two adjacent units of the other one is the closed movement path divided by its number and then deducted by the working range of the former one. One pair or several pairs of N1 launching units and N2 receiving units, of which the working range coincides with each other, have data transmission.

An optical connector includes: a receptacle assembly to be coupled to a substrate; a cover coupled to the receptacle assembly; a photoelectric element array coupled to the receptacle assembly; and a plug assembly inserted into a reception groove formed at the receptacle assembly, so as to be movably coupled to the receptacle assembly, wherein the cover includes a support member for supporting the plug assembly connected to the photoelectric element array by pressing the plug assembly.

A data transmission apparatus is applied to a LiDAR. The data transmission apparatus includes a first optical module, a second optical module, and a coupling optical system. The coupling optical system is arranged between the first optical module and the second optical module. The first optical module is communicatively connected to a LiDAR front-end apparatus, and the second optical module is communicatively connected to an upper application apparatus. The first optical module is configured to receive a first digital signal output by the LiDAR front-end apparatus and convert the first digital signal into an optical signal. The coupling optical system is configured to transmit the optical signal output by the first optical module to the second optical module. The second optical module is configured to convert the optical signal into the first digital signal and output the first digital signal to the upper application apparatus for processing.