An optical rotary joint includes a first annular portion and a second annular portion configured to rotate with respect to each other. Optical receivers on a receiver face of the second annular portion receive from optical transmit beam launchers on an emitter face of the first annular portion. The transmit beam launchers transmit optical signals to the optical receivers as the second annular portion rotates with respect to the first annular portion.

An imaging system for a patient comprises an imaging probe. The imaging probe comprises: an elongate shaft for insertion into the patient and comprising a proximal end, a distal portion, and a lumen extending between the proximal end and the distal portion; a rotatable optical core comprising a proximal end and a distal end, the rotatable optical core configured to optically and mechanically connect with an interface unit; a probe connector positioned on the elongate shaft proximal end and surrounding at least a portion of the rotatable optical core and an optical assembly positioned in the elongate shaft distal portion and proximate the rotatable optical core distal end, the optical assembly configured to direct light to tissue and collect reflected light from the tissue. A shear-thinning fluid can be provided between the elongate shaft and the rotatable optical core, such as to reduce undesired rotational variations of the rotatable optical core.

An example apparatus includes an optical fiber, an actuator, and a joint mechanically coupling the actuator to the optical fiber. The joint includes a neck extending along an axis. The optical fiber is threaded through an aperture extending along the axis through the neck. The optical fiber is attached to the joint at a surface of the neck facing the axis. The joint also includes a collar extending along the axis. The actuator is mechanically attached to the joint at an inner surface of the collar facing the axis. The joint also includes a flexural element extending radially from the neck to the collar. During operation, the joint couples a force from the actuator to the optical fiber to vary an orientation of a portion of the optical fiber extending from the neck with respect to the axis.

The current disclosure is regarding an electrical slip ring assembly that transmit signals, data, and power across rotary platforms, especially for high frequency applications. The high frequency slip ring assembly with through bore may include a first stage slip ring, a second stage slip ring, a gear assembly, and an internal cable assembly. Rings may have an angled notch on a circumference to break said rings and have the same diameter. The first stage slip ring and second stage slip ring may be connected in series sequence, i.e., the stator in first stage slip ring is mechanically connected with the rotor in second stage slip ring. The internal cable assembly electrically connects the brush assembly in first stage slip ring with the ring assembly in said second stage slip ring in each channel respectively.

The current invention is regarding an electrical slip ring system for high speed applications, which require slip rings to operate at speeds more than 60,000 RPM. It consists of multiple single stage slip rings and multiple gear devices, where all the stators, except the last one, are rotational. The speed limit on the slip ring market, by using the advanced fiber brush bundles, is about 10,000 RPM without cooling, or lubricating. The basic idea is that by designing gears, we can always can make sure the relative speed between the rotor and the stator in each stage is <=10000 rpm.

An automated fiber optic rotary joint (FORJ) dynamically measures, using an angle encoder, twists in an optical fiber cable caused by movements of a mouse or other animal and automatically unwinds the optical fiber cable(s) by engaging a motor. To optimize its efficiency, the unwinding process is activated automatically only when the angle encoder reaches a predetermined threshold. In some embodiments, the optical fiber is unwound in increments of 360°. Various embodiments allow simultaneous transfer of optical signals through independent channels to and from multiple sites of a freely moving animal through a rotating interface and with minimal mechanical impact on the natural behavior of the animal. The design principle leads to a minimal variation of light transmission over rotation suitable for life science applications. A single channel FORJ device can be readily expanded to a two-, three- or more-channel device.

An optical rotary joint includes first and second hollow tubular members. At least one of the first and second hollow tubular members is rotatable about a common longitudinal axis. A ring shaped optical waveguide between the first and second hollow tubular members includes first and second axial faces oriented perpendicular to the common longitudinal axis, an inner circumferential edge facing the outer circumference of the first hollow tubular member, an outer circumferential edge facing the inner circumference of the second hollow tubular member, and a circular light scattering channel formed in the first and/or second axial faces. First optical emitters are arranged to face the outer or inner circumferential edge. Second optical emitters are arranged to face the channel. A first optical receiver is arranged to face the outer or inner circumferential edge. A second optical receiver is arranged to face the channel.

A non-rotary joint for connecting a static component to a rotatable component includes an adapter on a rotatable part. A motor is joined to rotate the rotatable part. A connector is joined to the static component. The connector can be moved by an actuator from a first position joined with the adapter to a second position positioned away from the adapter. A controller is joined to control the motor and the actuator. The controller signals the actuator to move to the second position when the motor is activated and signals the actuator to move to the first position when said motor is deactivated. In a practical embodiment, the non-rotary joint makes a connection between a static signal carrier and a cable on a winch drum.

The present invention provides an imaging probe for imaging mammalian tissues and structures using high resolution imaging, including high frequency ultrasound and optical coherence tomography. The imaging probes structures using high resolution imaging use combined high frequency ultrasound (IVUS) and optical imaging methods such as optical coherence tomography (OCT) and to accurate co-registering of images obtained from ultrasound image signals and optical image signals during scanning a region of interest.

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.