Abstract: The disclosed technology relates to antenna configurations for wireless power transmission and supplemental visual signals. In some implementations, the disclosed technology includes a wireless power transmitter with boards that have multiple antennas physically coupled to the board. In some implementations, the antennas boards are arranged in a polygonal configuration (e.g., star shape). Additionally, in some implementations, the antennas can have different polarization configurations.

Abstract: The disclosed system utilizes multiple wireless power receivers (antennas and or paths) for receiving power. The disclosed system includes a chip, such as an application specific chip (ASICs) connectable to multiple antennas and units to convert radio frequency (RF) power into direct current (DC) power. The disclosed system can also include antennas that are used to receiving power, communicate, and send a beacon signal. The disclosed system also comprises a mobile electronic device to receive wireless power using multiple antennas connected or coupled to multiple wireless power receivers.

Abstract: Various embodiments utilize page scripting and parsing to identify the target destination of a hyperlink and provide a visual indication of the destination to the user without causing redirection to the target destination. In some embodiments, hyperlink color, highlighting, or icons are used to indicate the destination. Particular colors and/or icons selected to indicate the destination can, in some embodiments, be selected based on the domain hosting the target destination. In at least some embodiments, the destination of a link is determined by the page script run by a web browser on a user's device, while in other embodiments, information is transmitted to a web request handler on the server hosting the web site to determine the destination.

Abstract: A transmitter assembly is useful in optimizing in the delivery of wireless power to a plurality of receivers. Each receiver measures its own battery need for power and transmits that measurement as a request to the transmitter. The transmitter is configured to normalize and compare battery need requests. The transmitter then allocates pulses of wireless power among the requesting receivers according to their battery need.

Abstract: Systems and methods for improvement in transmission antenna design and, more particularly, for rapid determine phase determination of incoming signals are described herein. In some embodiments, a phase detection system is described. The phase detection system includes a phase detection apparatus and a control system. The phase detection apparatus includes a phase shifting element and a phase detector element. The phase shifting element is configured to phase-shift a reference signal multiple times per detection cycle. The phase detector element is configured to compare an incoming signal to multiple phases of the phase-shifted reference signal during the detection cycle, and generate an output indicating a relative phase difference between the incoming signal and the phase-shifted reference signal for each of the multiple phases. The control system is configured to determine a relative phase of the incoming signal based, at least in part, on the outputs.

Abstract: Techniques are described herein for filtering and/or otherwise isolating or extracting components of multi-component signals. More specifically, embodiments of the present disclosure describe techniques for filtering and/or otherwise extracting a continuous wave component (or wireless power component) and a modulated data component from a multi-component signal. In some embodiments, the techniques describe systems, apparatuses and methods for filtering and/or otherwise isolating or extracting a frequency (e.g., modulated data component) from a continuous wave (e.g., wireless power component) without affecting the levels of other frequencies. The individual components or signals can be transmitted by one or more sources and received at one or more existing antennas of an electronic device simultaneously.

Abstract: A transmitter assembly is useful in optimizing in the delivery of wireless power to a plurality of receivers. Each receiver measures its own battery need for power and transmits that measurement as a request to the transmitter. The transmitter is configured to normalize and compare battery need requests. The transmitter then allocates pulses of wireless power among the requesting receivers according to their battery need.

Abstract: In retrodirective wireless power delivery environments wireless power receivers generate and send beacon signals that are received by multiple antennas of a wireless power transmission system. The beacon signals provide the charger with timing information for wireless power transfers and also indicate directionality of the incoming signal. As discussed herein, the directionality information is employed when transmitting in order to focus energy (e.g., power wave delivery) on individual wireless power receiver clients. Techniques are described herein for reducing the burden of sampling the beacon signals across the multiple antennas and determining the directionality of the incoming wave. In some embodiments, the techniques leverage previously calculated values to simplify the receiver sampling.

Abstract: Techniques for automated clock synchronization and control are discussed herein. For example, the techniques can include monitoring of transmissions for ‘known’ events and identifying timing or frequencies of such events. Deviations in the timing or frequencies of the events from expected times or frequencies may indicate that wireless power transmission system and receiver clocks are not synchronized. The deviations can be used to synchronize the clock for optimum wireless power transfer. Techniques are also described for enhancing clock control mechanisms to provide additional means for managing the adjustments of the clocks, as well as for enabling wireless power transmission systems to mimic client clock offsets for effective synchronization of events (e.g., beacon signals).

Abstract: Techniques are described for accumulating data regarding the charging environment and power delivery efficiency at various regions in the environment under various transmission conditions. In some embodiments, this data may be utilized to generate efficient and sophisticated power transmission schedules; however, this data may also be leveraged for the manipulation of the standing waves within the environment. This allows for two discrete and powerful applications: creation of null zones and conversely the generation of high power regions. These regions may also be referred to as ‘power nulls’ and ‘energy balls’ respectively.

Abstract: Techniques are described herein for load balancing wireless power receiver clients over multiple wireless power transmission systems in a wireless power delivery environment. In some embodiments, a method is described. The method includes identifying transmitter load information associated with at least two wireless power transmission systems of the multiple wireless power transmission systems, detecting a load imbalance between the at least two wireless power transmission systems based, at least in part, on the transmitter load information, and determining one or more operations for improving the load imbalance. The method further includes directing one or more of the at least two wireless power transmission systems to perform the one or more operations.

Abstract: Various techniques are described herein for efficiently transmitting and receiving wireless power and/or data signals. In one example, a transmitter includes multiple antennas, a dielectric material in proximity to the multiple antennas, and multiple scattering elements embedded in the dielectric material. One or more of the multiple scattering elements are configured to be excited by one or more signals emitted by the multiple antennas.

Abstract: Various embodiments utilize page scripting and parsing to identify the target destination of a hyperlink and provide a visual indication of the destination to the user without causing redirection to the target destination. In some embodiments, hyperlink color, highlighting, or icons are used to indicate the destination. Particular colors and/or icons selected to indicate the destination can, in some embodiments, be selected based on the domain hosting the target destination. In at least some embodiments, the destination of a link is determined by the page script run by a web browser on a user's device, while in other embodiments, information is transmitted to a web request handler on the server hosting the web site to determine the destination.

Abstract: Techniques are described herein for collecting and utilizing diagnostic information for advanced monitoring of wireless power delivery systems. Wireless power transmission systems and/or cloud processing systems accumulate significant volumes of data related to wireless devices, usage patterns, power delivery efficiency and system components. This data can be utilized to generate efficient and sophisticated power transmission schedules. Additionally, as discussed herein, the diagnostic information can be leveraged for advanced system diagnostics and health monitoring. Among other features, the diagnostic and health monitoring system can detect patterns and correlate events that lead to system errors or failures. In some embodiments, the diagnostic and health monitoring system can also provide error notification and/or automatic error correction.

Abstract: Techniques are described herein for utilizing power requirements of a device in order to schedule wireless power delivery in wireless power delivery environments. In some embodiments, the techniques can alternatively or additionally employ advanced usage based power models to schedule wireless power delivery in wireless power delivery environments. For embodiments where device usage information is utilized, various means of collecting and analyzing the usage data may be employed. Furthermore, in some embodiments, some of the usage data may be ignored in order to ensure that the usage models for the device are not polluted with abnormal or detrimental data.

Abstract: Techniques are described herein for determining which power receiver clients are within a set network and limiting power transmission to these select clients. Ignoring some power requests frees up the wireless power transmission system to preferentially supply power to wireless power receiver clients that are determined to be of higher importance.

Abstract: Techniques are described for retention of known data within a wireless power transmission system, or within a cloud-based processing system. In order to perform scheduling procedures for determining which device to power, it is necessary to collect data regarding a device, e.g., the battery type, power usage, device model, present charge level and amount of power delivered per power cycle. A wireless power receiver client typically needs to collect or infer the information from the device and then provide the information directly to the charger via a messaging protocol. In existing wireless power transmission systems, information is re-transmitted to the wireless power transmission system every time the receiver engages or reengages the system.

Abstract: Techniques are described herein for leveraging these existing components of electronic devices with wireless or internet connectivity to reduce cost, size and complexity of electronic devices while enabling wireless power transfer. The techniques described herein can also be utilized to new low cost dual-function devices that utilize one or more of the same components for both wireless connectively and wireless power transfer.

Abstract: Techniques are described herein for filtering and/or otherwise isolating or extracting components of multi-component signals. More specifically, embodiments of the present disclosure describe techniques for filtering and/or otherwise extracting a continuous wave component (or wireless power component) and a modulated data component from a multi-component signal. In some embodiments, the techniques describe systems, apparatuses and methods for filtering and/or otherwise isolating or extracting a frequency (e.g., modulated data component) from a continuous wave (e.g., wireless power component) without affecting the levels of other frequencies. The individual components or signals can be transmitted by one or more sources and received at one or more existing antennas of an electronic device simultaneously.