A virtual reality system is described herein. The virtual reality system includes a cane controller and a computing system. The cane controller comprises a rod, a sensor, and a brake mechanism, wherein the sensor is configured to generate a signal that is indicative of position, direction of movement, and velocity of the rod, and wherein the brake mechanism is configured to apply a force to the rod. The computing system receives the signal, computes a position, direction of movement, and velocity of a virtual rod in a virtual space, and outputs a control signal to the brake mechanism based upon such computation. The brake mechanism applies the force to the rod in a direction and with a magnitude indicated in the control signal, thereby preventing the user from causing the virtual rod to penetrate a virtual barrier in the virtual space.

A virtual reality system is described herein. The virtual reality system includes a cane controller and a computing system. The cane controller comprises a rod, a sensor, and a brake mechanism, wherein the sensor is configured to generate a signal that is indicative of position, direction of movement, and velocity of the rod, and wherein the brake mechanism is configured to apply a force to the rod. The computing system receives the signal, computes a position, direction of movement, and velocity of a virtual rod in a virtual space, and outputs a control signal to the brake mechanism based upon such computation. The brake mechanism applies the force to the rod in a direction and with a magnitude indicated in the control signal, thereby preventing the user from causing the virtual rod to penetrate a virtual barrier in the virtual space.

The application describes example of enhanced capability (also referred to as smart) mobility aid devices, such as rollators, wheel-chairs, walkers, crutches, canes and the like, as well as apparatuses, systems, and processes for enhancing the capabilities of mobility aid devices.

An embodiment includes a walking stick. The walking stick includes a rod assembly, a water purification assembly, and a manual pump. The rod assembly extends from a first end to a second end that is opposite the first end along a longitudinal direction of the rod assembly. The rod assembly includes at least one rod portion. The water purification assembly is integrated with the rod assembly. The manual pump is configured to impose a pressure gradient in the water purification assembly. The manual pump includes a plunger that is physically coupled to a handle portion. Motion of the plunger relative to the water purification assembly draws water into an inlet tube that is positioned in the rod portion and through the water purification assembly. The motion of the plunger results from translation of the handle portion in substantially the longitudinal direction of the rod assembly.

An embodiment includes a walking stick. The walking stick includes a rod assembly, a water purification assembly, and a manual pump. The rod assembly extends from a first end to a second end that is opposite the first end along a longitudinal direction of the rod assembly. The rod assembly includes at least one rod portion. The water purification assembly is integrated with the rod assembly. The manual pump is configured to impose a pressure gradient in the water purification assembly. The manual pump includes a plunger that is physically coupled to a handle portion. Motion of the plunger relative to the water purification assembly draws water into an inlet tube that is positioned in the rod portion and through the water purification assembly. The motion of the plunger results from translation of the handle portion in substantially the longitudinal direction of the rod assembly.

Embodiments described herein relate generally to apparatuses and methods relating to mobility assist devices including, for example, walking canes. In some embodiments, a mobility assist device can include a wrist stabilizer and one or more exercising elements for enabling a user to perform torsion, rotation, grip, and/or other exercises.

Embodiments described herein relate generally to apparatuses and methods relating to mobility assist devices including, for example, walking canes. In some embodiments, a mobility assist device can include a wrist stabilizer and one or more exercising elements for enabling a user to perform torsion, rotation, grip, and/or other exercises.

A walking cane may be transformed into an assistive device for sit-to-stand transfers. The device has two sets of opposing handles, which are to be grasped by the user and an assister during sit-to-stand transfers. The transformation is accomplished by deploying a second set of handles by pivoting or rotating from a stored to a utility position. The assistive device form can then be reversed by the user once standing by reversing the deployment.

A walking cane may be transformed into an assistive device for sit-to-stand transfers. The device has two sets of opposing handles, which are to be grasped by the user and an assister during sit-to-stand transfers. The transformation is accomplished by deploying a second set of handles by pivoting or rotating from a stored to a utility position. The assistive device form can then be reversed by the user once standing by reversing the deployment.

A flying umbrella assembly includes a flying drone that can fly through the air. An umbrella is removably attachable to the flying drone such that the umbrella can be flown above the ground. A tracking unit is carried by a user and the tracking unit broadcasts a tracking signal to the flying drone thereby facilitating the flying drone to fly within a pre-determined distance of the tracking unit. In this way the flying drone positions the umbrella over the user regardless if the user is stationary or in motion. A personal electronic device is in wireless communication with the flying drone. The flying drone receives the sun tracking data from the personal electronic device to optimally position the umbrella for shading the user.