Abstract: A method can include receiving time series data acquired during equipment operations at a plurality of natural resource sites; detecting operational events using the time series data; ranking the operational events; associating each of the operational events with a corresponding operational action; and outputting at least a portion of the ranked operational events, each with its corresponding operational action.

Abstract: A system includes a computing platform having processing hardware, and a system memory storing a software code. The processing hardware is configured to execute the software code to identify a file transfer protocol among multiple file transfer protocols for transferring one or more file(s), to determine, using a test data sample and the file transfer protocol, one or more parameter(s) correlated with a time required for transferring the file(s) using the file transfer protocol, and to provide, based on the parameter(s), an algorithm for transferring the file(s) using the file transfer protocol. The processing hardware is further configured to perform, using the algorithm, a file transfer simulation of the file(s) using the file transfer protocol, to provide, using the file transfer simulation, data pooling parameters for transferring the file(s), and to estimate, based on the file transfer simulation and the data pooling parameters, an elapsed time for transferring the file(s).

Abstract: A method can include receiving time series data acquired during equipment operations at a plurality of natural resource sites; detecting operational events using the time series data; ranking the operational events; associating each of the operational events with a corresponding operational action; and outputting at least a portion of the ranked operational events, each with its corresponding operational action.

Abstract: An optical apparatus (10) for routing an optical signal (12) comprises a body (14) comprising a material. A waveguide (16) is formed in the body (14) by laser modification of the material. The optical apparatus (10) further comprises a region (18) comprising a lower refractive index than the material of the body (14) and defines an interface (24) between the region (18) and the waveguide (16). The waveguide (16) and the interface (24) are aligned relative to each other for routing the optical signal (12) therebetween and reflecting the optical signal (12) at the interface (24).

Abstract: An atmospheric greenhouse gas reduction system that includes greenhouse gas reduction particles having carbon dioxide conversion material that is capable of converting carbon dioxide in atmosphere into simple carbohydrates. The greenhouse gas reduction particles have a size of up to about 1,000 nanometers.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. Each coil is driven by a coil driving signal selected based on a set of target characteristics. A coil drive circuit receives an input of a pulse width modulation (PWM) signal and outputs the coil driving signal to a corresponding coil.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. One of the feedback channels may be a voltage and/or current measurement of coil driving signals from the coils that are indicative of receiver device presences on the wireless charging system. A coil driving signal may be sampled and processed using discrete Fourier transform to determine amplitude and phase information of the signal.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. One of the feedback channels may be demodulated communication signals from the one or more receiver devices. The demodulation may be performed by a communication demodulation circuit with configurable gain. The demodulated communication signals are processed for error correction at a bit level and a packet level, which improves accuracy despite presence of multiple receiver devices and noisy conditions.

Abstract: There is disclosed a dispenser 10 for dispensing product objects, comprising: a main chamber 20 for storing product objects; and a portion dispensing mechanism for dispensing a portion comprising a plurality of project objects 40. The portion dispensing mechanism comprises a gate arrangement 36 and a collection chamber 24 which are configured for relative linear movement between a loading configuration and a dispensing configuration. In the loading configuration a plurality of product objects 40 within the main chamber 20 collect within the collection chamber 24 and the gate arrangement 36 prevents product objects 40 from being dispensed from the collection chamber 24. In the dispensing configuration the gate arrangement 36 prevents product objects within the main chamber 20 from entering the collection chamber 24 and a plurality of product objects are dispensed from the collection chamber.

Abstract: A system includes a computing platform having processing hardware, and a system memory storing a software code. The processing hardware is configured to execute the software code to identify a file transfer protocol among multiple file transfer protocols for transferring one or more file(s), to determine, using a test data sample and the file transfer protocol, one or more parameter(s) correlated with a time required for transferring the file(s) using the file transfer protocol, and to provide, based on the parameter(s), an algorithm for transferring the file(s) using the file transfer protocol. The processing hardware is further configured to perform, using the algorithm, a file transfer simulation of the file(s) using the file transfer protocol, to provide, using the file transfer simulation, data pooling parameters for transferring the file(s), and to estimate, based on the file transfer simulation and the data pooling parameters, an elapsed time for transferring the file(s).

Abstract: A system and method of braze resistance spot welding of an aluminum component to a galvanized steel component involve providing an aluminum-side electrode having a first tip defining a rounded shape, providing a galvanized steel-side electrode having a second tip defining a flat shape, depositing a braze filler material between the aluminum and galvanized steel components at a desired location for a spot weld, performing a pre-heat including providing a first current across the electrodes for a first period such that the braze filler melts and removes a portion of a zinc coating from the galvanized steel component, and after performing the pre-heat, performing a spot weld between the aluminum and galvanized steel components by providing a second current across the electrodes for a second period such that the aluminum melts and the galvanized steel does not melt, wherein the second current is greater than the first current.

Abstract: A method can include receiving time series data acquired during equipment operations at a plurality of natural resource sites; detecting operational events using the time series data; ranking the operational events; associating each of the operational events with a corresponding operational action; and outputting at least a portion of the ranked operational events, each with its corresponding operational action.

Abstract: There is disclosed a dispenser (10), such as a confectionery dispenser, for dispensing product objects such as pieces of confectionery (40). The dispenser (10) comprises a container (12) for storing product objects; and at least one dispensing arrangement (14, 16). The dispensing arrangement (14), (16) comprises an opening (18) provided in the container (12); a collection region (26) located within the container (12) and adjacent to the opening (18); a guide (32) disposed within the container (12) and adjacent to the collection region (26); and a dispensing tray (29) disposed within the container (12) and adjacent to the opening (18). The dispensing arrangement (14), (16) is configured the opening (18) and having a dispensing surface 30 accessible through such that in use in a loading orientation of the dispensing arrangement (14), (16) product objects collect in the collection region (26).

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes a plurality of coils for wireless charging the one or more receiver devices. The wireless charging system may use a machine learning algorithm to detect the one or more receiver devices and select which of the multiple coils to activate for charging the multiple coils. Based on measurements made from signal through the coils within the wireless charging system, the machine learning algorithm determines a subset of the coils to activate for charging the detected one or more receiver devices.

Abstract: A method of a method of controlling a volume of material dispensed by a constant pressure adhesive and sealant dispensing system controlled by a controller during shots includes automatically adjusting a proportional valve control setting for an orifice size of a controlled pressure regulator. An orifice size control pressure corresponding to the proportional valve control setting is applied to an orifice size control inlet of the controlled pressure regulator. A volume of the material dispensed during each shot is monitored and when the volume of material dispensed during each shot of a predetermined number of successive shots is outside a target range, the proportional valve control setting is automatically adjusted by the controller.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. Each coil is driven by a coil driving signal selected based on a set of target characteristics. A coil drive circuit receives an input of a pulse width modulation (PWM) signal and outputs the coil driving signal to a corresponding coil.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. One of the feedback channels may be a voltage and/or current measurement of coil driving signals from the coils that are indicative of receiver device presences on the wireless charging system. A coil driving signal may be sampled and processed using discrete Fourier transform to determine amplitude and phase information of the signal.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes a plurality of coils for wireless charging the one or more receiver devices. The wireless charging system may use a machine learning algorithm to detect the one or more receiver devices and select which of the multiple coils to activate for charging the multiple coils. Based on measurements made from signal through the coils within the wireless charging system, the machine learning algorithm determines a subset of the coils to activate for charging the detected one or more receiver devices.

Abstract: A wireless charging system is configured to charge one or more receiver devices simultaneously. The wireless charging system includes multiple coils that may be driven independently based on a feedback system with one or more feedback channels. One of the feedback channels may be demodulated communication signals from the one or more receiver devices. The demodulation may be performed by a communication demodulation circuit with configurable gain. The demodulated communication signals are processed for error correction at a bit level and a packet level, which improves accuracy despite presence of multiple receiver devices and noisy conditions.