Methods are described for generating a user interface displaying at least a useful image, wherein the useful image has been created in some embodiments by means of: determining, over a period of time, a first set of a first amount of values of a gait attribute, and obtaining, using the first set and leveraging a matrix factorization, a second set of a second amount of values representing colors.

Methods are described for generating a user interface displaying at least a useful image, wherein the useful image has been created in some embodiments by means of: determining, over a period of time, a first set of a first amount of values of a gait attribute, and obtaining, using the first set and leveraging a matrix factorization, a second set of a second amount of values representing colors.

Aspects of the disclosure relate to processing remotely captured sensor data. A computing platform having at least one processor, a communication interface, and memory may receive, via the communication interface, from a user computing device, sensor data captured by the user computing device using one or more sensors built into the user computing device. Subsequently, the computing platform may analyze the sensor data received from the user computing device by executing one or more data processing modules. Then, the computing platform may generate trip record data based on analyzing the sensor data received from the user computing device and may store the trip record data in a trip record database. In addition, the computing platform may generate user record data based on analyzing the sensor data received from the user computing device and may store the user record data in a user record database.

Aspects of the disclosure relate to processing remotely captured sensor data. A computing platform having at least one processor, a communication interface, and memory may receive, via the communication interface, from a user computing device, sensor data captured by the user computing device using one or more sensors built into the user computing device. Subsequently, the computing platform may analyze the sensor data received from the user computing device by executing one or more data processing modules. Then, the computing platform may generate trip record data based on analyzing the sensor data received from the user computing device and may store the trip record data in a trip record database. In addition, the computing platform may generate user record data based on analyzing the sensor data received from the user computing device and may store the user record data in a user record database.

An equipment rental system comprising a kiosk, the kiosk comprising a user interface configured to receive user input and provide outputs to a user, a processor configured to receive the user input from the user interface, generate user output and control a locker system; and a locker system configured to store the equipment and allow access to the equipment under control of the processor, the processor configured to: receive log in and credential information form a user via the user interface, present the user a choice of equipment, receive a selection of equipment through the user interface, gather payment information from the user through the user interface, wherein the payment information corresponds to a period of use for the selected equipment, and control the locker system to make the selected equipment available to the user.

An equipment rental system comprising a kiosk, the kiosk comprising a user interface configured to receive user input and provide outputs to a user, a processor configured to receive the user input from the user interface, generate user output and control a locker system; and a locker system configured to store the equipment and allow access to the equipment under control of the processor, the processor configured to: receive log in and credential information form a user via the user interface, present the user a choice of equipment, receive a selection of equipment through the user interface, gather payment information from the user through the user interface, wherein the payment information corresponds to a period of use for the selected equipment, and control the locker system to make the selected equipment available to the user.

An affixable device can include a locking mechanism, a force-limiting mechanism, and a sensing mechanism. The locking mechanism can include an engagement component configured to disable the locking mechanism. The force-limiting mechanism can be configured to limit a locking force of the locking mechanism. The sensing mechanism can be coupled to the engagement component, and can be configured to determine that the force-limiting mechanism has limited the locking force of the locking mechanism. In response to determining the force-limiting mechanism limiting the locking force, the sensing mechanism can cause the engagement component to disable the locking mechanism.

An affixable device can include a locking mechanism, a force-limiting mechanism, and a sensing mechanism. The locking mechanism can include an engagement component configured to disable the locking mechanism. The force-limiting mechanism can be configured to limit a locking force of the locking mechanism. The sensing mechanism can be coupled to the engagement component, and can be configured to determine that the force-limiting mechanism has limited the locking force of the locking mechanism. In response to determining the force-limiting mechanism limiting the locking force, the sensing mechanism can cause the engagement component to disable the locking mechanism.

A device includes one or more processors configured to execute instructions to obtain, at a first audio output device, first spatial audio data and a first reference time associated, and to cause the first reference time and data representing at least a portion of the first spatial audio data to be transmitted from the first audio output device. The instructions further cause the one or more processors to receive, at the first audio output device from a second audio output device, second spatial audio data and a second reference time. The instructions further cause the one or more processors to, based on the first reference time and the second reference time, time-align the first spatial audio data and the second spatial audio data to generate combined audio data representing a three-dimensional (3D) sound field and to generate audio output based on the combined audio data.

A device includes one or more processors configured to execute instructions to obtain, at a first audio output device, first spatial audio data and a first reference time associated, and to cause the first reference time and data representing at least a portion of the first spatial audio data to be transmitted from the first audio output device. The instructions further cause the one or more processors to receive, at the first audio output device from a second audio output device, second spatial audio data and a second reference time. The instructions further cause the one or more processors to, based on the first reference time and the second reference time, time-align the first spatial audio data and the second spatial audio data to generate combined audio data representing a three-dimensional (3D) sound field and to generate audio output based on the combined audio data.