Abstract: Techniques for determining a status of exchange of audio messages between a source computing device and a destination computing device are described. In an example, an audio input is received from a user from a source computing device. A source audio message and a source text file are then generated based on the audio input. The source audio message is then sent to the destination computing device. A destination text file is then received from the source computing device, where the destination text file is generated based on a destination audio message received at the destination computing device, and where the destination audio message is received by the destination computing device corresponding to the source audio message. The source text file is then compared to the destination text file to determine a status of transmission of the source audio message to the destination computing device.

Abstract: An optical receiving device includes a substrate; an optical receiving chip arranged on the substrate; an optical demultiplexer arranged on the substrate and used to distinguish optical signals into optical signals with different wavelengths; an optical transmission structure optically coupled to the optical demultiplexer and providing the optical signals to the optical demultiplexer; and an optical fiber array fused with optical fibers of the optical demultiplexer, and transmitting the optical signals with different wavelengths to the optical receiving chip.

Abstract: In some examples, a controller of a wearable device causes display by the wearable device of a test image, and adjusts a color property of the displayed test image. In response to an input provided by a user responsive to the displayed test image as the color property is adjusted, the controller determines a distribution of color wavelengths for an eye of the user, and detects a color vision deficiency of the user based on the determined distribution of color wavelengths. The controller provides control information to control a display device of the wearable device to compensate for the color vision deficiency.

Abstract: Examples of establishing a communication link based on an activity on a keyboard are described. In an example, the activity may be detected on the keyboard of a computing device. Based on the detection, the computing device may send a request to an input device for establishing a wireless communication link with the computing device. Upon receiving an acceptance of the request by the input device, the computing device may establish the wireless communication link with the computing device.

Abstract: An optical communication module separating the input and output of light signals by birefringence includes first and second planar optical waveguides with a birefringent crystal connected to both. An optical fiber is adjacent to the second planar optical waveguide. An output beam from a transmitter passes through the first planar optical waveguide, the birefringent crystal, and the second planar optical waveguide in sequence, and enters into the optical fiber. An incoming beam from the optical fiber passes through the second planar optical waveguide, the birefringent crystal, and the first planar optical waveguide in sequence, and then falls onto a receiver.

Abstract: Examples of establishing a communication link based on an activity on a keyboard are described. In an example, the activity may be detected on the keyboard of a computing device. Based on the detection, the computing device may send a request to an input device for establishing a wireless communication link with the computing device. Upon receiving an acceptance of the request by the input device, the computing device may establish the wireless communication link with the computing device.

Abstract: Techniques to identify information associated with an Access Point (AP) are described. The information associated with an AP corresponding to AP Parameters (APP) is received from a user. Based on the information associated with the AP, a unique ID corresponding to the AP is generated. An AP information ID (APID) is generated by combining the unique ID with the SSID.

Abstract: An optical communication module separating the input and output of light signals by birefringence includes first and second planar optical waveguides with a birefringent crystal connected to both. An optical fiber is adjacent to the second planar optical waveguide. An output beam from a transmitter passes through the first planar optical waveguide, the birefringent crystal, and the second planar optical waveguide in sequence, and enters into the optical fiber. An incoming beam from the optical fiber passes through the second planar optical waveguide, the birefringent crystal, and the first planar optical waveguide in sequence, and then falls onto a receiver.

Abstract: A wavelet-based method for analysis of singularities improves analysis and information gathering from seismic trace data. A wavelet transform is applied to seismic trace data. The Hölder exponent is calculated for every time point of the wavelet transform for each seismic trace. Hölder exponents are then plotted versus time. These graphs are utilized in place of seismic traces themselves in creating two and three dimensional images. The graphs produced using Hölder exponents greatly improve interpretation of stratigraphic boundaries and other geological information to be readily identified. This provides for better, more accurate stratigraphic analysis. In addition, the nature of the Hölder exponents of the seismic trace are consistent with Hölder exponents calculated from acoustic impedance of the various strata.