A ruggedized mobile computing device is enclosed by a multi-layer housing providing protection of the device and its individual components (e.g., processors, sensors, touchscreens, peripheral devices and ports) from wear and tear, impact shock, and extreme weather conditions. The mobile device may be rechargeable via a resonant charging receiver connectable to a companion resonant charging transmitter housed in a vehicle cradle or mount, to which the mobile device can be removably mounted for hands-free use or use in a motor vehicle. The mobile device may incorporate scanners, cameras, sensors, and other peripheral devices, and further connect to additional external scanners, sensors, or input devices through its peripheral ports.

Techniques for optimizing wearable device settings using machine learning are described. A mobile device may receive, from a wearable device (such as a wristwatch), sensor data corresponding to a reaction of a user wearing the wearable device to an output modality produced by the wearable device. The mobile device may solicit user feedback for the output modality produced by the wearable device. The mobile device may receive, via a sensor set, user feedback data corresponding to a user feedback for the output modality. The mobile device may upload the sensor data and the user feedback data to a cloud-based application. The mobile device may receive a knowledge package, including a classification algorithm trained using the sensor data and the user feedback data, from the cloud-based application. Finally, the mobile device may send the knowledge package to the wearable device.

Devices, systems, and methods for detecting molecules of interest within a collected sample are described herein. In certain embodiments, self-contained sample analysis systems are disclosed, which include a reusable reader component, a disposable cartridge component, and a disposable sample collection component. In some embodiments, the reader component communicates with a remote computing device for the digital transmission of test protocols and test results. In various disclosed embodiments, the systems, components, and methods are configured to identify the presence, absence, and/or quantity of particular nucleic acids, proteins, or other analytes of interest, for example, in order to test for the presence of one or more pathogens or contaminants in a sample.

There is provided an information processing device including: a sensor configured to detect that the information processing device is worn on a part of a human body; a processing unit configured to process information; and a communication unit configured to communicate with another device. The processing unit transmits a signal to the another device on the basis of a detection signal detected by the sensor. The processing unit performs a process according to an instruction transmitted from the another device in accordance with the signal.

The present invention relates to the control and operation of cellular telephones and other portable electronic devices, and particularly to improvements in the functionality of those devices for use in conjunction with a variety of sports and recreational activities.

Techniques and mechanisms for exchanging information between a mobile device and another device which is to serve as an accessory to the mobile device. In an embodiment, the accessory device and the mobile device are coupled to one another via an audio connector of the mobile device. The mobile device receives via the audio connector encoded signals which represent, in a first frequency range, information generated by a sensor of the accessory device. The first frequency range is within an audible frequency range and outside of a telephony frequency range of the mobile device. In another embodiment, the encoded signals are provided to telephony logic of the host device during a telecommunication exchange between the host device and a remote device. Due to its representation in the first frequency range, some sensor information is prevented from being represented as an audio signal in the telecommunication exchange.

The present disclosure describes devices, systems, and methods that can be used to collect sensor data from, for instance, a sensor device that has been embedded in an article of apparel. The sensor device can be used, for instance, to monitor the athletic activity of an individual wearing the apparel into which the electronic device has been embedded. Embodiments of the sensor device include a memory, a wireless interface, and one or more processor. With these elements, the sensor device may receive instructions indicating what sensor data to collect, collect the sensor data, store the sensor data, and transmit the stored sensor data to the remote device upon completion of the activity.

One illustrative system disclosed herein includes an enclosure configured to define a boundary of a chamber, the chamber including a material, and a flexible layer coupled overtop of the chamber and configured to enclose the chamber. The illustrative system also includes a first actuation device configured to receive a first haptic signal and responsively output a first haptic effect by changing a characteristic of the material to deform the flexible layer. The illustrative system also includes a second actuation device configured to receive a second haptic signal and responsively output a second haptic effect by applying an electrical signal to the flexible layer. The illustrative system further includes a processor in communication with the first actuation device and the second actuation device. The processor is configured to transmit the first haptic signal to the first actuation device and the second haptic signal to the second actuation device.

An accessory device application executes on an accessory device of limited resources. The accessory device application includes an accessory device stub application and an interface definition. When a user interacts with the accessory device application, display changes are generated in response, in accordance with the interface definition, and are sent to a companion extension at an associated companion device. The companion extension receives the changes, and generates updated display values for the accessory device display. The updated display values are sent from the companion device daemon to the daemon of the accessory device, which displays the updated display values at the accessory device display. The functionality and operation of the accessory device application permit an accessory device of limited resources to leverage data processing and computational power of the companion device, to provide a more involving user experience at the accessory device.

A control system including a detection device and a control host is provided. The detection device is configured to detect a biometric characteristic to accordingly identify a user ID, and output an ID signal according to the user ID. The control host is configured to receive the ID signal to accordingly perform an individualized control associated with the user ID.