A computer-implemented method and a navigation system are described for guiding a visually impaired user to avoid obstructions and impediments while walking. The user may wear a plurality of subassemblies of the system. The tilt and rotation of the user's head may be monitored using one of the subassemblies worn on the user's head. Based at least in part on the tilt and rotation of the user's head, vertical and horizontal firing angles used by a distance measuring unit in each of the subassemblies may be calculated to transmit and receive laser signals to perform measurements. The user is then provided with navigation instructions and alarms based on whether an obstruction or an impediment is detected that is closer than a predetermined distance to the user while the user is walking based on the measurements.

A rollator is disclosed, including first and second upright members, each including handle portions, wheels, hinges disposed between the wheels and the handle portions, channels disposed along the upright members between the hinges and the wheels, and lateral hinges orthogonal to the hinges. First and second foldable support members having wheels are attached to the hinges. At least one lateral support member is disposed between and attached to the lateral hinges, and includes an intermediate hinge. Brake systems include brake lines communicating between brake controls and brakes. In a reversible storage configuration, the foldable support members are rotated to be at least partially disposed in the channels, and the lateral hinges and intermediate hinge rotate to collapse the lateral support member, bringing the upright members with the folded foldable support members adjacent to one another.

A human-interface device and a guiding apparatus for a visually impaired user including such human-interface device. The human-interface device includes a tactile module arranged to provide a set of haptic signals to a user, wherein the tactile module has a plurality of tactile units each arranged to provide at least a first haptic signal and operable to cooperate with one or more of other tactile units to provide different haptic signals.

A device for assisting navigation including a body defining a middle portion having a first end and a second end, a handle portion at one of the first or second ends, a holder that is removably mounted with another end of the first or second ends of the body.

The technology disclosed herein includes a navigation system for a visually impaired person to navigate a public restroom. The navigation system may include a plurality of fixtures, a plurality of installations, wherein each installation is electronically connected to a fixture, and an electronic device, the electronic device configured to receive auditory or tactile signals from each installation and produce a signal indicative of a fixture location. The plurality of fixtures may include a toilet, a urinal, a sink, a soap dispenser, and a hand drying apparatus.

An information processing device calculates an occupancy rate of a pedestrian crossing in an image obtained by capturing an image of a traveling direction of a target person, determines a crossing status of the target person for the pedestrian crossing based on the calculated occupancy rate, and generates support information for supporting the target person crossing the pedestrian crossing based on the crossing status.

A detection system 100 of the present invention includes a position detection means 121 for detecting position information representing a position of a predetermined part of a person and a position of an accessory in a specific shape held by the person, and a separation detection means 122 for detecting that the accessory is separated from the person based on the position information.

A system and method for assisting a visually impaired user including an imaging device, a processing unit for receiving images from the imaging device and converting the images into signals for use by one or more controllers, and one or more vibro-tactile devices, wherein the one or more controllers activates one or more of the vibro-tactile devices in response to said signals received from the processing unit. The system preferably includes a lanyard to be worn around the neck of the user such that a first vibro-tactile device is arranged on the right side of the user's neck, a second vibro-tactile device on a left side of the user's neck, and a third vibro-tactile device at the back portion of the user's neck. The vibro-tactile devices are activated depending on a determined position in front of the user of an object and the distance from the user to the object.

Systems and methods for automatic adjustment of a wearable device are provided. One embodiment of a method includes determining whether a navigation sensor is in a desired position and, in response to determining that the navigation sensor is not in a desired position, determining a desired modification to the navigation sensor for achieving the desired position. Some embodiments include determining a change of a repositioning device for achieving the desired modification to the navigation sensor and actuating the repositioning device to implement the change.

An improved white cane includes an elongate body having a proximal end adapted to be held by or secured to a human user and a distal tip, and a noise generator located proximate the distal tip, the noise generator being configured to generate sound within a range of frequencies audible to humans. The user is able to interpret differences in reflected sound as the white cane is moved about the user's surroundings to obtain more information about the surroundings than could be obtained using a normal white cane. Additionally, the information about the surroundings may become available to the user before that information might otherwise have been available to the user using a standard white cane.