Abstract: Embodiments of the disclosure provide systems and methods for managing a lifecycle of a software application. According to one embodiment, software application lifecycle management can comprise receiving a specification for an application. The specification can comprise an executable script defining a plurality of features for the application and a plurality of scenarios. Each scenario representing a test for one or more features of the application and each feature comprising one or more user stories. A test entity can be created for and corresponding to each scenario in the specification and each scenario can be marked with a test identifier linking the created test entity to the corresponding scenario in the script. Results of execution of one or more scenarios of the plurality of scenarios can be received and reported on a per-feature and per-scenario basis.

Abstract: Embodiments of the disclosure provide systems and methods for managing a lifecycle of a software application. According to one embodiment, software application lifecycle management can comprise receiving a specification for an application. The specification can comprise an executable script defining a plurality of features for the application and a plurality of scenarios. Each scenario representing a test for one or more features of the application and each feature comprising one or more user stories. A test entity can be created for and corresponding to each scenario in the specification and each scenario can be marked with a test identifier linking the created test entity to the corresponding scenario in the script. Results of execution of one or more scenarios of the plurality of scenarios can be received and reported on a per-feature and per-scenario basis.

Abstract: A method for evaluating user interface efficiency includes discerning user actions with the user interface occurring between each of a plurality of adjacent pairs of transaction points. Those adjacent pairs of transaction points are evaluated to identify a given one of a plurality of user flows associated with the user interface. The identified user actions occurring between each adjacent pair of transaction points are assessed to calculate an efficiency score. The efficiency score is associated with the identified user flow and is indicative of user interface efficiency.

Abstract: A content-aware digital media storage device includes a host device interface for exchanging digital information with a host device, a memory array for storing digital information received from the host device via the host interface, a peripheral module configured to communicate the digital information stored in the memory array to a receiver located remote from the digital media storage device, and a controller communicatively coupled to the host device interface, the memory array and the peripheral module and configured to interpret directory information associated with the digital information stored in the memory array so as to selectively access said digital information and communicate such accessed digital information to the peripheral module for transmission to the remote receiver. Digital images stored in the memory array may be transmitted to a remote host via a wireless network access point with which the peripheral module of the storage device is associated.

Abstract: The disclosure relates to systems and methods for managing a wireless powering system for power transfer to electrical devices, providing central management console through a communication network. The wireless powering system comprising at least one wireless power outlet with an integrated communication module and at least one management server and is further operable is further operable to provide location based services when coupled with a software application. The management system, of the current disclosure, is enabling remote health check and maintenance of all of wireless power outlets within the network. Further, the management system allows for complete monitoring of a deployment according to system administrator rights and policy management coupled with command and control functioning to determine allowed/disallowed functionality while transferring powering to an electrical device in a specific venue.

Abstract: The disclosure relates to systems and methods for managing a wireless power transfer network for power transfer to electrical devices, providing central management console in communication with cloud based network, comprising at least one wireless power outlet and at least one management server. The management system, of the current disclosure, is enabling remote health check and maintenance of all of wireless power outlets within the network. Further, the management system allows for complete monitoring of a deployment according to system administrator rights and policy management coupled with command and control functioning to determine allowed/disallowed functionality while transferring powering to an electrical device in a specific venue.

Abstract: The disclosure relates to system and methods for managing a network of power outlet devices configured to transmit power wirelessly for charging electrical devices. In particular the invention relates to a plurality of wireless power outlets controlled centrally via a wireless power modem and operable to power electrical devices using various associated power transfer protocols. Each power transfer servicing venue may be equipped with wireless power outlets supporting a protocol or technology—resonant, non-resonant, magnetic beam, inductive power transfer and the like. The current disclosure introduces a wireless power modem accessible externally via a network communication API and operable to control a plurality of wireless power outlets, each using an associated power transfer protocol via a power-transfer software application kit (SDK).

Abstract: A wireless power receiver, configured to inductively receive power from a wireless power outlet for powering a load, and to encode a signal for detection by the wireless power outlet, is provided. The wireless power receiver comprising a receiver circuit having a secondary coil connected to the load and configured to receive power from a primary coil associated with the wireless power outlet, and a resonance adjuster electrically connected to the secondary coil and configured to adjust the resonant frequency of the receiver circuit, between one of two resonant frequencies, by selectively modifying the receiver circuit. The wireless power receiver further comprises a controller configured to operate the resonance adjuster to encode the signal by adjusting the resonant frequency of the receiver circuit, wherein the signal comprises a plurality of data blocks carrying information, alternating with a plurality of power blocks each carrying a power instruction.

Abstract: Wireless power transfer between power transmitters and power receivers may be established by a digital ping phase during which the wireless power transmitter applies a power signal and waits for a valid response message from the power receiver. The response message may include an identification code and a checksum byte used by the power transmitter to validate the identification code. When a valid response is received, the power transmitter transitions to a power transfer phase.

Abstract: In a system and method for transferring power from a wireless power outlet to a wireless power receiver, an outlet transmits a first-type ping signal transferring a burst of energy to the wireless power receiver. The outlet includes a detector able to detect when the receiver activates an over voltage protection mechanism. When the OVP is activated the outlet may transmit a lower energy second-type ping signal.

Abstract: The disclosure relates to systems and methods for controlling a wireless power transfer system based upon Inductive Charging Technology using frequency based signaling communication protocol, operable to function in modes of Standby, Digital Ping, Identification, Power Transfer and End of Charge (EOC). The power transfer system comprising at least one wireless power outlet associated with a wireless power transmitter coil and at least one electrical device associated with a wireless power receiver coil, where the wireless power receiver coil is in multi-directional communication with the wireless power transmission of a message transmitter coil. The amount of power transferred is controlled by feedback communication between the receiver and the transmitter configured to increase or NO decrease power.

Abstract: The disclosure relates to systems and methods for managing a wireless powering system for power transfer to electrical devices, providing central management console through a communication network. The wireless powering system comprising at least one wireless power outlet with an integrated communication module and at least one management server and is further operable is further operable to provide location based services when coupled with a software application. The management system, of the current disclosure, is enabling remote health check and maintenance of all of wireless power outlets within the network. Further, the management system allows for complete monitoring of a deployment according to system administrator rights and policy management coupled with command and control functioning to determine allowed/disallowed functionality while transferring powering to an electrical device in a specific venue.

Abstract: A content-aware digital media storage device includes a host device interface for exchanging digital information with a host device, a memory array for storing digital information received from the host device via the host interface, a peripheral module configured to communicate the digital information stored in the memory array to a receiver located remote from the digital media storage device, and a controller communicatively coupled to the host device interface, the memory array and the peripheral module configured to interpret directory information associated with the digital information stored in the memory array so as to selectively access said digital information and communicate such accessed digital information to the peripheral module for transmission to the remote receiver. Digital images stored in the memory array may be transmitted to a remote host via a wireless network access point with which the peripheral module of the storage device is associated.

Abstract: A method for evaluating user interface efficiency includes discerning user actions with the user interface occurring between each of a plurality of adjacent pairs of transaction points. Those adjacent pairs of transaction points are evaluated to identify a given one of a plurality of user flows associated with the user interface. The identified user actions occurring between each adjacent pair of transaction points are assessed to calculate an efficiency score. The efficiency score is associated with the identified user flow and is indicative of user interface efficiency.

Abstract: The disclosure relates to systems and methods for managing a wireless power transfer network for power transfer to electrical devices, providing central management console in communication with cloud based network, comprising at least one wireless power outlet and at least one management server. The management system, of the current disclosure, is enabling remote health check and maintenance of all of wireless power outlets within the network. Further, the management system allows for complete monitoring of a deployment according to system administrator rights and policy management coupled with command and control functioning to determine allowed/disallowed functionality while transferring powering to an electrical device in a specific venue.

Abstract: Wireless power transfer between power transmitters and power receivers may be established by a digital ping phase during which the wireless power transmitter applies a power signal and waits for a valid response message from the power receiver. The response message may include an identification code and a checksum byte used by the power transmitter to validate the identification code. When a valid response is received, the power transmitter transitions to a power transfer phase.

Abstract: A wireless power transmitter and method for providing power to a remote secondary coil of a power receiver include a primary coil, a driver, and a signal receiving circuit wherein the power transmitter is configured to switch between a standby mode and a transmission mode. In the standby mode, the power transmitter is configured to wait for an activation signal from the power receiver. In the transmission mode, the driver is operable to provide an oscillating voltage across the primary coil such that the primary coil transmits power to the remote secondary coil; and the signal receiving circuit receives feedback signals from the power receiver concurrently with uninterrupted power transfer.

Abstract: A wireless power system comprising a secondary unit and a wireless power outlet configured to provide an electric charge wirelessly to the secondary unit comprises a primary inductive coil connected to a power source via a driver configured to provide an oscillating driving voltage to the primary inductive coil. The secondary unit is configured to receive an electric charge wirelessly from the wireless power outlet, and comprises a secondary inductive coil wired to an electric load. The wireless power outlet and secondary unit are each configured to ensure compatibility with one another.

Abstract: The disclosure relates to inductive charging systems comprising at least one power access point (PAP) comprising a primary inductor connectable to a power supply, a PAP credential characterizing said PAP and a charger link comprising at least one wireless communication component; at least one device comprising a secondary inductor, a device credential characterizing said device and a device link comprising at least one wireless communication component; and a power controller comprising a communicator comprising at least one wireless communication component and a server having a database. The disclosure further relates to methods of controlling the inductive charging performed by an inductive charging system.

Abstract: A control circuit for an inductive power outlet configured to transfer power to an inductive power receiver includes a resonant circuit having a characteristic resonant peak and connected to a primary coil configured to inductively couple with a secondary coil of the inductive power receiver, a frequency driver operable to provide a driving voltage oscillating at an operating frequency higher than the characteristic resonant peak of the resonant circuit across the primary coil, a magnitude detector operable to monitor primary coil voltage, and a data demodulator operable to detect modulated peaks in primary coil voltage indicating that a communications modulator of the inductive power receiver has transitioned from a first state to a second state. The communications modulation determines a characteristic frequency of the peaks and extracts modulated data sent in communication signals from the inductive power receiver.