A body care apparatus capable of providing optimal therapeutic care for a body of a user is provided. The body care apparatus includes a wearable device worn on the body of the user so as to obtain activity data of the user, a massage chair performing a massage on each body part of the user while supporting the body of the user, a data analyzing unit inferring condition data for each body part of the user according to the activity data obtained from the wearable device, and a controller controlling an operation of the massage chair according to the condition data inferred by the data analyzing unit. The body care apparatus may infer the condition data by deep learning of an artificial intelligence algorithm or a sensor fusion.

A psychosomatic state adjustment support device includes: a storage section that stores a target psychosomatic state for each destination of a moving body; a specification section that specifies a current psychosomatic state of an occupant of the moving body; an acquisition section that acquires a destination of the moving body; a deciding section that decides a vibration pattern based on the target psychosomatic state according to the destination and the current psychosomatic state; and a control section that applies a vibration stimulation to the occupant by causing a vibration applying section provided in a seat on which the occupant is seated to vibrate based on the vibration pattern.

A chair-type massage machine includes a seat portion, a backrest portion that is reclinable rearward of the seat portion, and a forearm treatment portion that treats each of forearms of a person to be treated. The forearm treatment portion is mounted to each of both left and right side surfaces of the backrest portion.

An artificial muscle chair device includes a plurality of artificial muscles embedded in a chair. Each artificial muscle includes a housing having an electrode region and an expandable fluid region. A first electrode and a second electrode each disposed in the electrode region of the housing. The artificial muscle chair device further includes a dielectric fluid disposed within the housing. The first and second electrodes electrostatically attract, inflating the expandable fluid region with dielectric fluid and thereby applying selective pressure to an outer surface of the chair.

A system to manage the sleep and/or the well-being of a passenger/user of an aircraft includes a chair to be installed in a cabin of the aircraft and interaction devices to interact with the user. The system further includes a user terminal configured to receive data relating to characteristics of a user profile of the user, and a control/command module connected to the user terminal, interaction devices and a database storing information relating to characteristics of a flight of the aircraft. The command/control module being configured to pilot the interaction devices according to the data relating to characteristics of the user profile and characteristics of the flight of the aircraft.

A remotely controlled powered chair may include a support frame, a seat pivotally mounted on the support frame, an rotary actuator mounted between the support frame and the seat to drive the seat to move relative to the support frame, a backrest pivotally mounted on the seat, and a linear actuator mounted between the seat and the backrest to drive the backrest to move relative to the seat. Thus, the rotary actuator may be controlled by an electrically control device to drive the seat to pivot relative to the support frame reciprocally in a pendulum manner so that the seat is pivoted relative to the support frame automatically. In addition, the linear actuator may be controlled by the electrically control device to adjust the inclined angle of the backrest so as to provide a comfortable sensation to the user. A remotely controlled powered chair may include a base assembly. A chair frame is supported on the base assembly. An actuator mechanism may communicate with the base assembly and the chair frame, and is operable to actuate the chair frame between first and second positions.

The present disclosure relates to a vehicle seat comprising a seating portion and a backrest, the seat further comprising at least one vibration device. The vibration device(s) are arranged in one or more of the following authorized spaces: a first authorized space in the backrest, which is defined by predefined ranges; a second authorized space in the seating portion, which is defined by predefined ranges; these ranges being defined with respect to an orthonormal coordinate system (H, x, y, z) whose origin is the point H which is the seating reference point of the seat, for which the x axis extends horizontally from the rear to the front of the seating portion, for which the y axis extends horizontally from the right to the left of the seat, and for which the z axis extends vertically from the bottom to the top of the backrest.

A seat device is provided with: a first air bag expanding and contracting inside a seat surface skin; a holding member for holding the first air bag and movable along the inner surface of the seat surface skin; a drive device for moving the holding member so as to change the arrangement of the first airbag; and a second air bag independent of the first air bag, the second air bag expanding inside the seat surface skin so as to press the seat surface skin to separate the seat surface skin from the first air bag.

Disclosed is a massage chair capable of performing acupuncture point massage. More particularly, disclosed is a massage chair comprising: a seat 200; a back support portion 100 rotatably mounted on one side of the seat 200; a calf massage portion 400 rotatably mounted on the other side of the seat 200; and a manipulation portion 600 capable of adjusting movements of the back support portion 100 and the calf massage portion 400, in which the manipulation portion 600 includes: a shoulder height measurement module 610 for measuring the shoulder height of the user; a hip bone location prediction module 620 for predicting the hip bone location by using a preset first method with reference to the shoulder height measured by the shoulder height measurement module 610; a massage location determination module 630 for determining a plurality of massage locations based on the hip bone location predicted by the hip bone location prediction module 620; and a massage mode selection module 640 for selecting one massage mode of a plurality of previously-stored massage modes based on the plurality of massage locations determined by the massage location determination module 630, thereby massaging the plurality of massage locations determined by the massage location determination module 630 in accordance with the massage mode selected by the massage mode selection module 640.

Disclosed are a massage device providing a tinnitus treatment program and a control method therefor. According to an embodiment of the present disclosure, disclosed is a method by which a massage device provides a tinnitus treatment program. The method by which the massage device provides the tinnitus treatment program comprises the steps of: obtaining tinnitus information about a user; adjusting the magnitude of at least some of a plurality of frequency components included in a raw sound source and then flattening the raw sound source, so as to generate a first processed sound source; reducing the magnitude of at least some of a plurality of frequency components included in the first processed sound source on the basis of the obtained tinnitus information, so as to generate a tinnitus treatment sound source; and providing a tinnitus treatment program in which the generated tinnitus treatment sound source and tinnitus treatment massage are combined.