Surgical robotic systems including a user console for controlling a robotic arm or a surgical robotic tool are described. The user console includes components designed to automatically adapt to anthropometric characteristics of a user. A processor of the surgical robotic system is configured to receive anthropometric inputs corresponding to the anthropometric characteristics and to generate an initial console configuration of the user console based on the inputs using a machine learning model. Actuators automatically adjust a seat, a display, or one or more pedals of the user console to the initial console configuration. The initial console configuration establishes a comfortable relative position between the user and the console components. Other embodiments are described and claimed.

A dynamic ergonomic chair with a sensor detects an adjustment to a position of a component of the chair and includes a user interface which updates a first user profile based on the detected adjustment to create a second user profile. The second user profile including a second workstation productivity measurement; the interface compares the first workstation productivity measurement of the first user profile with the second workstation productivity measurement of the second user profile, and/or medical outcomes, to determine an optimal user profile. The chair can dynamically adjust various components (e.g. armrest, recline angle, etc.) to enhance worker productivity.

A massage chair includes a back massage system and a thigh massage system with a roller mechanism configured to move a roller in a three dimensional orbital motion. The roller mechanism is driven by a single motor that can change the direction in operation. Also included is a roller motion drive element within the roller mechanism. A shaft is configured to pass through the roller motion drive element in an offset non-perpendicular angle relative to the end face thereby forming an angle between the shaft and the end face that is less than 85 degrees. The offset causes the orbital motion of the roller when rotated. The electronics of the massage chair facilitate facial recognition and a medical assessment device to detect bodily characteristics. The backrest of the massage chair can elongate to stretch the user. A plurality of airbags are also available for the twisting of the user.

Devices, systems, and methods for determining a custom ergonomic configuration of an adjustable seating device based on interpretation and analysis of a sequence of biometric measurements of a human subject. An adjustable seating device transitions one or more adjustable surfaces between a sequence of configurations while a human subject is seated in the adjustable seating device and being biometrically measured. A custom configuration is stored in memory, where the custom configuration is a configuration where the biometric measurements of the human subject correspond to a muscle-relaxed state.

A smart mattress, including a mattress body (1), and further including an airbag assembly (2) disposed on a supporting surface of the mattress body (1). The airbag assembly (2) includes multiple airbags respectively used to support multiple parts of the human body, the height of each of the airbags is adjustable. The present smart mattress has a sleep aid function; the air volumes of corresponding airbags in the airbag assembly (2) can be controlled according to a user's experience, so that the heights of the corresponding airbags are flexibly adjusted to achieve the purpose of floating support of different parts of the human body, and the supporting heights of parts of the mattress are alternately and gently changed to achieve the function of relaxing and massage before sleeping. The smart mattress further has a wake-up function and portability; the mattress body (1) can be folded for carrying with one.

A massage chair includes a back massage system and a thigh massage system with a roller mechanism configured to move a roller in a three dimensional orbital motion. The roller mechanism is driven by a single motor that can change the direction in operation. Also included is a roller motion drive element within the roller mechanism. A shaft is configured to pass through the roller motion drive element in an offset non-perpendicular angle relative to the end face thereby forming an angle between the shaft and the end face that is less than 85 degrees. The offset causes the orbital motion of the roller when rotated. The electronics of the massage chair facilitate facial recognition and a medical assessment device to detect bodily characteristics. The backrest of the massage chair can elongate to stretch the user. A plurality of airbags are also available for the twisting of the user.

Described herein are multifunctional smart beds and methods of operating thereof. Specifically, a multifunctional smart bed comprises a controller, configured to receive input from various sensors (e.g., load cells positioned in bed legs, thermometers, and/or microphones) and/or user. These inputs are analyzed and used to control various bed components to improve the sleep quality, to monitor users' health, score couple's relationship, and the like. For example, these inputs may be used to control firmness of different mattress portions, change orientations of head, torso, and/or leg sections, adjust the light, and the like. In some examples, the smart bed generates a report indicating one or more sleep duration, sleep depth profile, sleep scope, heart rate, breadth rate, environment conditions, couple's relationship, and the like. Furthermore, in some examples, a multifunctional smart bed is also configured to control external devices in the same environment, e.g., smart switches, smart thermostats.

A method for operating a vehicle seat of a motor vehicle with electric seat adjustment is provided. The method includes the steps of importing a measurement data set that is representative of an initial sitting position of a person sitting on the vehicle seat, evaluating the measurement data set in order to determine a target sitting position data set for a target sitting position, and evaluating at least the measurement data set and the target sitting position data set in order to determine a transfer data set for transferring the initial sitting position into the target sitting position at a rate of change below a perception threshold.

Disclosed is a posture correction device. According to the present invention, the posture correction device includes: a base part; and a recognizing part having a frame whose one side is coupled to the base part in such a manner as to allow one or more of a height and an angle to be adjusted, wherein the recognizing part is recognized visually and tactilely according to a user's posture.

A system is provided for marketing bedding. The system includes a plurality of air velocity displays each having a body defining a chamber and an opening that is in communication with the chamber, an air flow generator positioned within the chamber, and a sample material that covers the opening such that air flow created by the air flow generator passes through the sample material. The system includes plurality of selection modules. The selection modules each having a user interface that is in communication with one of the air velocity displays such that engaging a feature of one of the user interfaces will cause one of the air flow generators to move from an off position to an on position to create airflow. Methods of use are provided.