The invention relates to a method and system 1) for remotely commanding a medical device (2) arranged to be implanted in a human or animal body, said command system comprising at least a first (4) and a second (5) activation element for commanding said medical device, said first activation element being arranged to be triggered by proximity to an added activation element (6), said second activation element being arranged to be triggered by pressure exerted on said second activation element, the command system being arranged to activate a command of the medical device upon triggering of the first and second activation elements.

Systems, apparatuses, and methods for implementing telemetry push aggregation techniques are described. A computing system includes one or more input/output (I/O) agents interposed between functional units and a communication fabric. A given I/O agent receives a set of aggregation rules from a power management unit. The I/O agent monitors traffic from the functional units, and the I/O agent generates telemetry data from the traffic data based on the set of aggregation rules. The telemetry data is used by the power management unit to make adjustments to one or more power settings.

A computer-implemented method and system for optimizing user experience are disclosed. The method includes determining power profile of a target device; determining historical behavior of at least one user in relation to the target device; considering the historical behavioral data of the at least one user in relation to the target device based on the determined power profile of the target device; and using rules to select at least one of a plurality of approaches for establishing connection with a server in relation to a result of the considering.

System and methods for processing audio signals are disclosed. In one implementation, a system may include a wearable device. The wearable device may include a microphone having an audio sensor configured to capture the audio signals from an environment of the user; and a processor. The processor may be programmed to receive the audio signals captured by the microphone; analyze the audio signals to generate a transcription; generate a summary of the transcription; cause the summary to be displayed to the user; receive a confirmation input from the user indicating that the displayed summary is correct; and cause the displayed summary to be stored.

Methods, apparatus, systems and articles of manufacture are disclosed to reduce temperature of a networked device. An example apparatus includes, a temperature threshold monitor to identify a temperature condition associated with the device, a window information retriever to retrieve a current value of a network receive capacity parameter, and a window adjustor to reduce the temperature of the device by generating a modified network receive capacity parameter, the modified network receive capacity parameter based on a ratio of the current value of the network receive capacity parameter and a decrease factor.

A method for power-smart packet processing includes, in response to an event trigger signal, generating, by a state machine, a number of enable signals. The method further includes applying the enable signals to a number of single-level inferred clock (SLICK) gates to generate multiple clock signals with cycles of latency. The clock signals are applied to at least some of a number of groups of flops used for packet processing. The enable signals are clock-gated enable signals that start at consecutive cycles of a main clock, and stay active for at least one cycle of the main clock. The method further includes using flow-aware clock-gating technology (FACT) to distinctly identify logic and tables and continually variable traffic (CVT) to control packet rate and packet spacing.

A method and apparatus for isolating and restoring general-purpose input/output (GPIO) pads in a computer system includes identifying GPIO pads associated with the region responsive to an entry into a power-down state of a region of a circuit. The GPIO pads are isolated from one or more external circuits. Upon exit from the power-down state, each associated GPIO pad is restored to a current value.

Disclosed are a power consumption reduction circuit for Graphics Processing Units (GPUs) in a server and a server. The power consumption reduction circuit includes a frequency reduction control chip. The frequency reduction control chip, after receiving an overpower alarm signal generated by a Power Supply Unit (PSU), generates a frequency reduction control signal to a Power Break (PWRBRK) pin of each GPU so as to start a frequency reduction operation of each GPU. It can be seen that, in the present application, an underlying hardware circuit is directly used for implementation with relatively quick responses and without intervention of an operating system, whereby the whole frequency reduction operation of the GPU may be completed within 5 ms, and the PSU is prevented from triggering overpower protection within relatively short time. Therefore, loss of service data of a user caused by an exceptional power failure of the server is avoided.

Devices and methods for linear addressing are provided. A device is provided which comprises a plurality of components having assigned registers used to store data to execute a program and a power management controller, in communication with the components. The power management controller is configured to send one of a request to remove power to the components and a request to reduce power to the components when it is determined that the components are idle, execute a first process of one of removing power and reducing power to the components and entering a reduced power state when an acknowledgement of the request is received and execute a second process of restoring power to the components when one or more of the components are indicated to be active.

A data processing apparatus (14) according to an embodiment includes a data processing unit (105) and a wireless communication unit (104). The data processing unit (105) converts input data. The wireless communication unit (104) receives the data converted by the data processing unit (105) and wirelessly transmits the input data to an access point. The data processing unit (105) converts, when a remaining amount input from a battery (12) is in a first state, the input data with a first setting and outputs the converted data to the wireless communication unit (104). The data processing unit (105) converts, when the remaining amount of the battery (12) is in a second state different from the first state, the input data with a second setting and outputs the converted data to the wireless communication unit (104). A capacity per unit time of the data after conversion is different between the first setting and the second setting.