A system and method for modem energy management utilizing a controller that is responsive to both a user-configurable timing system and a data activity sensor. The disclosed technology provides a configurable interface that enables a user to specify the parameters governing the modem assuming a low-power or sleep state, as well as a monitor adapted to detect the occurrence and rate of user data, video, Wi-Fi, voice and other services. The parameters a user may specify include elapsed time since the last detected data use, the rate of data being transmitted/received by the modem, the time of day and/or the day of the week. The system and method also permit a user to manually initiate the assumption of a low-power or a full-power mode by a modem.

A system and method for modem energy management utilizing a controller that is responsive to both a user-configurable timing system and a data activity sensor. The disclosed technology provides a configurable interface that enables a user to specify the parameters governing the modem assuming a low-power or sleep state, as well as a monitor adapted to detect the occurrence and rate of user data, video, Wi-Fi, voice and other services. The parameters a user may specify include elapsed time since the last detected data use, the rate of data being transmitted/received by the modem, the time of day and/or the day of the week. The system and method also permit a user to manually initiate the assumption of a low-power or a full-power mode by a modem.

An embodiment of an integrated circuit may comprise a circuit block and a power management circuit coupled to the circuit block to manage two or more power states for the circuit block and to manage a request for the circuit block to enter a requested power state of the two or more power states, set a watchdog timer in response to the request, and monitor the watchdog timer and a transition of the circuit block from a current power state to the requested power state. Other embodiments are disclosed and claimed.

A computer processor includes a branch prediction unit that includes a local branch predictor and a global branch predictor. Managing power consumption in such a computer processor includes, for each of a plurality of branch instructions: performing, by the local branch predictor, a local branch prediction; performing, by each of the global branch predictors, a global branch prediction; determining to utilize the local branch prediction over the global branch predictions as a branch prediction for the branch instruction; incrementing a value of a counter; determining whether the value of the counter exceeds a predetermined threshold; and if the value of the counter exceeds the predetermined threshold, powering down at least one of the global branch predictors and configuring the branch prediction unit to bypass the powered down global branch predictor for branch predictions of subsequent branch instructions.

A method for gracefully shutdown a virtual system is disclosed, and the method includes: gracefully shutdown configuration information configured for the virtual system is received and stored; and sequential shutting down of virtual machines is performed according to the stored gracefully shutdown configuration information when a request for shutting down the virtual system is received, so as to solve problems caused by the fact that virtual machines are shut down according completely to a reverse order of starting-up in the prior art.

Various embodiments relate to a method, controller, and machine-readable storage medium for verifying controlled devices attached to the controller including one or more of the following: selecting, using a system model that models a system of devices comprising the controlled devices attached to the controller, a grouping of the system of devices to be tested; conducting a test of the grouping to produce a test result for the grouping, wherein conducting the test comprises transmitting a communication to at least one device associated with the grouping; choosing a graphical representation of a portion of the system model from a plurality of graphical representations based on the graphical representation including a representation of the grouping; and displaying, on a user interface, the graphical representation and an indication of the test result.

Various embodiments relate to a method, controller, and machine-readable storage medium for verifying controlled devices attached to the controller including one or more of the following: selecting, using a system model that models a system of devices comprising the controlled devices attached to the controller, a grouping of the system of devices to be tested; conducting a test of the grouping to produce a test result for the grouping, wherein conducting the test comprises transmitting a communication to at least one device associated with the grouping; choosing a graphical representation of a portion of the system model from a plurality of graphical representations based on the graphical representation including a representation of the grouping; and displaying, on a user interface, the graphical representation and an indication of the test result.

A method for dynamically managing power consumption, as well as a wake-up method, is disclosed for a wireless weighing platform. The method is initialized by setting both light and deep sleep period, entering a normal operating state, and starting light sleep timing. As long as no weighing operation is detected and the light sleep period has not expired, the method seeks to detect the weighing operation. If the light sleep period expires with no weighing operation, a light sleep state is entered, by turning off a communication function and starting timing for the deep sleep period. If no weighing is when the deep sleep period has expired, the wireless weighing platform enters a deep sleep state, by turning off power supply other than that for an acceleration sensor. If the acceleration sensor detects an effective vibration while in the deep sleep state, the normal operating state is restarted.

A method for dynamically managing power consumption, as well as a wake-up method, is disclosed for a wireless weighing platform. The method is initialized by setting both light and deep sleep period, entering a normal operating state, and starting light sleep timing. As long as no weighing operation is detected and the light sleep period has not expired, the method seeks to detect the weighing operation. If the light sleep period expires with no weighing operation, a light sleep state is entered, by turning off a communication function and starting timing for the deep sleep period. If no weighing is when the deep sleep period has expired, the wireless weighing platform enters a deep sleep state, by turning off power supply other than that for an acceleration sensor. If the acceleration sensor detects an effective vibration while in the deep sleep state, the normal operating state is restarted.

Disclosed herein are methods and systems enabling automatic powering on and off of a computer of a user when the user is within a predetermined range from the computer. When there is a startup error detected during the remote powering on process of the computer, an alert is generated and automatically transmitted to an analyst computer to resolve the startup error. The disclosed systems and methods save a lot of time for the user each day as the user does not have to wait for execution of computer startup processes and the computer is ready to use when the user arrives at a location of their computer.