A device is described for delivering a therapeutic vibration to a body. The device may include at least two motors in a housing with unbalanced masses coupled to their axles, such that vibration of the masses causes the two motors and housing to vibrate at a beat frequency 80. The motors and housing may be coupled to the body via a platform which places the motors and housings at or near a resonant structure in the body, creating a coupled oscillation between the platform and the body. The vibration may be based on the input signal, such that the system applies the vibration based on the input signal to the user, wherein the signal may be an audio or video signal. The system may be configured to measure and manipulate the flow of cerebral spinal fluid.

Disclosed in the present invention is a head-mounted electronic vision aid device and an image magnification method thereof. The head-mounted electronic vision aid device comprising a memory unit, a processing unit, an image zooming unit, and at least one ranging unit; the ranging unit being configured to obtain distance data between a target object of interest to a user and the device and/or three-dimensional profile data of the object and output the data to the processing unit; the memory unit stores a correspondence table between the distance data and the magnification of the image zooming unit; the processing unit confirms the target object of interest to the user, performs operations on the distance data and/or the three-dimensional profile data of the object, and outputs an magnification matching the distance data to the image zooming unit according to the correspondence table; and the image zooming unit can automatically adjust to the matching magnification. For visually impaired users, accurate, intuitive and rapid automatic magnification of the target objects of interest can be realized on demand. Compared with the prior art, the repeated and tedious manual adjustment is avoided, and the user experience is greatly improved.

Disclosed in the present invention is a head-mounted electronic vision aid device and an image magnification method thereof. The head-mounted electronic vision aid device comprising a memory unit, a processing unit, an image zooming unit, and at least one ranging unit; the ranging unit being configured to obtain distance data between a target object of interest to a user and the device and/or three-dimensional profile data of the object and output the data to the processing unit; the memory unit stores a correspondence table between the distance data and the magnification of the image zooming unit; the processing unit confirms the target object of interest to the user, performs operations on the distance data and/or the three-dimensional profile data of the object, and outputs an magnification matching the distance data to the image zooming unit according to the correspondence table; and the image zooming unit can automatically adjust to the matching magnification. For visually impaired users, accurate, intuitive and rapid automatic magnification of the target objects of interest can be realized on demand. Compared with the prior art, the repeated and tedious manual adjustment is avoided, and the user experience is greatly improved.

In some embodiments, a haptic device comprises first and second multi-dimensional spatial haptic devices. The first spatial haptic device includes a handle to represent a location of one object in a virtual document or space. The second spatial haptic device includes a handle to represent a location of another object in the same virtual document or space. The first and the second handles are spatially registered with respect to each other. In some embodiments, a third spatial haptic device includes a handle to represent a location of yet another object in a virtual document or space.

In some embodiments, a haptic device comprises first and second multi-dimensional spatial haptic devices. The first spatial haptic device includes a handle to represent a location of one object in a virtual document or space. The second spatial haptic device includes a handle to represent a location of another object in the same virtual document or space. The first and the second handles are spatially registered with respect to each other. In some embodiments, a third spatial haptic device includes a handle to represent a location of yet another object in a virtual document or space.

The present invention relates to a tip for use with delivery devices, particularly for use in implanting retinal implants into the retinal space of an eye. The tip includes a flexible envelope and an internal sliding member. Further, the invention relates to an inserter attachment and a delivery device including said tip.

The present invention relates to a tip for use with delivery devices, particularly for use in implanting retinal implants into the retinal space of an eye. The tip includes a flexible envelope and an internal sliding member. Further, the invention relates to an inserter attachment and a delivery device including said tip.

A device may include an image capturing component to obtain images of an environment of a user, and a light projection system. The light projection system may include a laser source and an optical imager. The device may process, in real-time, images captured by the image capturing component to derive signals for controlling the laser source, provide the signals to the laser source to enable the laser source to generate a laser beam pattern, cause the optical imager to raster scan the laser beam pattern to an absorptive element. The absorptive element may be disposed on or in the user, and positioned proximate to a region-of interest, of the user, that includes neuronal cells. The laser beam pattern may cause the absorptive element to produce acoustic energy that cause depolarization of the neuronal cells. The sensory stimulation may enable the user to visually and/or auditorily perceive the environment.

A device may include an image capturing component to obtain images of an environment of a user, and a light projection system. The light projection system may include a laser source and an optical imager. The device may process, in real-time, images captured by the image capturing component to derive signals for controlling the laser source, provide the signals to the laser source to enable the laser source to generate a laser beam pattern, cause the optical imager to raster scan the laser beam pattern to an absorptive element. The absorptive element may be disposed on or in the user, and positioned proximate to a region-of interest, of the user, that includes neuronal cells. The laser beam pattern may cause the absorptive element to produce acoustic energy that cause depolarization of the neuronal cells. The sensory stimulation may enable the user to visually and/or auditorily perceive the environment.

A device (100) for compensating for part of the visual field comprises a wearable frame (110) configured to rest upon the face of a subject. An image capture device (120) is configured to capture an image from a first region (20) of the subject's visual field the first region being identified as a region of the visual field in which the subject's vision is impaired, and relay the image to an image display unit (130). The image display unit (130) is configured to project the image onto a region of the subject's retina that corresponds to a second region of the subject's visual field, in which the subject's vision is identified as non-impaired. Associated methods are also described.