Hand held weight units of light weight manufactured as a solid unit, a shell unit with core insert combinations or modular units with interlocking ends. Shell units with core inserts and modular interlocking units allow for the changing of held weight by inserting or removing inserts or by locking or unlocking of modular weight unit sets creating varying held weight. The weight units are primarily used with upper body exercises during aerobic exercises in the home, outdoors, or in a gym setting such as walking or running to vary the intensity of workout during use.

Various embodiments of the disclosure relate to an electronic device for controlling a predefined function based on a response time of an external electronic device on a user input, and a method thereof. The electronic device includes: a memory configured to store one or more applications; a communication module comprising communication circuitry configured to communicate with an external electronic device; and a processor, wherein the processor is configured to control the electronic device to: receive an input; generate first control data for controlling at least one application among the one or more applications using a first recognition method based at least on the input; transmit at least part of the input to the external electronic device through the communication module, wherein the external electronic device is configured to generate second control data for controlling the at least one application using a second recognition method based at least on the input; identify a time that passes until the second control data is received after the at least part of the input is transmitted to the external electronic device; control the at least one application using the first control data based on the passing time satisfying a first predefined condition; and control the at least one application using the second control data based on the passing time satisfying a second predefined condition.

A computer-implemented method for use in conjunction with a computing device with a touch screen display comprises: detecting one or more finger contacts with the touch screen display, applying one or more heuristics to the one or more finger contacts to determine a command for the device, and processing the command. The one or more heuristics comprise: a heuristic for determining that the one or more finger contacts correspond to a one-dimensional vertical screen scrolling command, a heuristic for determining that the one or more finger contacts correspond to a two-dimensional screen translation command, and a heuristic for determining that the one or more finger contacts correspond to a command to transition from displaying a respective item in a set of items to displaying a next item in the set of items.

A computer-implemented method for use in conjunction with a computing device with a touch screen display comprises: detecting one or more finger contacts with the touch screen display, applying one or more heuristics to the one or more finger contacts to determine a command for the device, and processing the command. The one or more heuristics comprise: a heuristic for determining that the one or more finger contacts correspond to a one-dimensional vertical screen scrolling command, a heuristic for determining that the one or more finger contacts correspond to a two-dimensional screen translation command, and a heuristic for determining that the one or more finger contacts correspond to a command to transition from displaying a respective item in a set of items to displaying a next item in the set of items.

The present disclosure generally relates to health-related user interfaces. In some embodiments, user interfaces for managing health-related data are described. In some embodiments, user interfaces for viewing health data are described. In some embodiments, user interfaces related to sharing health data are described.

A system for manufacturing underwear customized for a customer may generate a 3D body shape of a customer by 3D scanning; calculate, from the 3D body shape, unique body measurement information for each customer, needed for manufacturing customized underwear, and register the information; and then, if a customized purchase request for underwear is received from the customer, generate, for the target underwear requested for purchase, a design that fits the body shape of the customer on the basis of the registered body measurement information for each customer; and thereby maximize customer satisfaction and reduce an inventory.

A programmable smart button includes a housing, at least one interactive surface, a controller, and a programmable display adjustable by a user interfacing with a user device such as a smart phone. The display may include a module identifier indicator that identifies a module being controlled by the smart button as well as function indicator associated with an interactive surface of the smart button. The controller is in communication with the display and is configured to set the information in the indicators shown by the display and to determine the function(s) of the interactive surface(s). The display may be a low power display, such as a bistable display, having negligible effect on the battery life of the smart button.

The present disclosure generally relates to digital identification credential user interfaces.

An electronic device is provided. The electronic device includes a display, a camera, and a processor. The processor displays a first image obtained through the camera, displays, in response to the first image being enlarged in one magnification in a designated first magnification range, the enlarged first image as a second image, displays, in a designated area of the display, a guide map including a first guide box indicating a location of the second image and having a size which varies in response to a magnification change in the first magnification range, and when the first image or the second image is enlarged to a third image in response to the first or second image being enlarged by one magnification in a designated second magnification range greater than the first magnification range, changes the first guide box to a second guide box having a fixed size.

A computer-implemented method of detecting and quantifying a spinal curve is disclosed herein. The method comprises obtaining an infrared radiometer camera, positioning the infrared radiometer camera for receiving thermal data for a spine of a subject, the camera being horizontally spaced about ½ meters to about 3 meters from the spine, scanning at least a portion of the spine with the infrared radiometer camera to obtain the thermal data, analyzing the thermal data using machine learning software which uses a classification algorithm to determine the presence of the spinal curve, and calculating a first Cobb angle for the curve of the subject's spine. Corresponding systems and additional methods also are disclosed.