The wearable coaching apparatus includes: a vision-control meeting configured for engaging an individual ‘s encounter regarding the user’s eyes,” said vision-control assembly containing a lens frame using a translucent region about the user’s eyes and an opaque area enclosing the see-through place at least about a temporal facet, a side, and an inferior side thereof. In some embodiments, the vision-control assembly includes a lens frame and a single or two lens elements secured in the lens framework. The system comprises a wearable coaching apparatus disclosed herein for being worn by the user; one or more imaging apparatus configured for capturing images of the user wearing the wearable training devices; and at least one computing device in communication with one or more imaging devices for monitoring the consumer ‘s movement using the at least one imaging apparatus. By applying the herein-disclosed devices, methods and systems, patients can learn to properly align their own bodies in a stable position when given motion tasks during rehab.

Thus, in various embodiments, the wearable coaching device 100 may include a see-through area (such as the transparent regions 132) and a vision-blocking region (including the opaque area 134 along with the sidewall 120). The see-through region is sized and positioned to allow a user to view through the wearable training apparatus 100 within a reduced FOV region about the gaze direction 206, along with the vision-blocking region blocks the consumer ‘s undesirable FOV areas peripheral to the lower FOV region. Within this embodiment, the sidewall 120 has a suitable rearward-extension depth and also the temple pieces 110 are have an appropriate configuration like a user can utilize the wearable coaching devices 100 in a way similar to wearing a pair of regular glasses and the end 124 of this sidewall 120 comfortably in contact with the user’s head blocking the user’s side vision. Those skilled in the art will appreciate that, in an alternative embodiment, the temple pieces 110 may be integrated with or otherwise fixed to the lens frame 106 also might not be pivotable.

FIG. 11C is a schematic plan view showing a user wearing the wearable training apparatus 100 and the horizontal span of this FOV in yet some other embodiments. The fundamental transparent region 132 of each lens section 104 is located facing a central vision-area of their eye of the consumer, and may not necessarily be located in the geometrical centre of the lens part 104. In certain embodiments, the flat length 232 of their reduced FOV could possibly be about 100 to about 140 (i.e., roughly 50 to about 70 on every side). In certain embodiments, the flat length of the reduced FOV is approximately 100 to approximately 140 with about 50 to about 70 on each temporal side.

Each of the two or one lens components comprises a see-through or translucent region, and the marriage of the one or two see-through regions form a translucent region configured for limiting a user’s FOV to a reduced FOV which corresponds to a central part of the human FOV, and also an opaque area for blocking a peripheral section of the user’s FOV. In certain embodiments, the transparent material contains a lens. In certain embodiments, a training program may comprise a more wearable instruction apparatuses as explained previously, and one or more imaging devices functionally coupled to one or more computing devices through one or more suitable wired or wireless connections. Alternately, the opaque area 134 might be rendered clear by gluing, staining, painting, or otherwise coupling thereto a layer of opaque material. Contrary to the lens elements of traditional glasses which are normally entirely transparent or “see-through” for minimizing the blockage of user’s eyesight, each lens element 104 inside this embodiment includes a central aperture or translucent region 132 for “see-through”, along with a surrounding, ????? (https://Wattpad.com) substantive opaque area 134 for blocking a user’s peripheral vision. In certain embodiments, the headgear includes a helmet body with a front opening about the user’s eyes along with a protective weapon covering the front opening; and wherein the vision-control assembly is attached between the helmet body and the protective fence.