Abstract: In one embodiment, a method includes: receiving, in a first circuit of a processor, an indication of an entry of the processor into a first virtual machine, the processor to execute in a virtual machine environment having a root partition and at least one virtual partition comprising the first virtual machine; allocating a first hardware feedback structure for the root partition and allocating a second hardware feedback structure for the at least one virtual partition; populating the first hardware feedback structure with first performance and efficiency information regarding a plurality of cores of the processor; populating the second hardware feedback structure with the first performance and efficiency information regarding the plurality of cores of the processor; and providing the first performance and efficiency information from the second hardware feedback structure to a virtual machine scheduler of the at least one virtual partition. Other embodiments are described and claimed.

Abstract: A reversible toy includes a body having a first surface and a second surface opposite the first surface. The body may be reversible between a first configuration and a second configuration to alternatingly present the first and second surfaces as an outer body surface defining an exterior of the body. In this regard, the other of the first and second surfaces may alternatingly define a stored body surface defining an interior cavity within the body. The reversible toy may further include an appendage attached to the body at the first surface and comprising a coupling feature. The coupling feature may be configured to couple the reversible toy to an object at the appendage.

Abstract: In one embodiment, a processor includes: at least one core; and a power controller coupled to the at least one core. The power controller may include: a workload monitor circuit to calculate a background task ratio based on a first amount of time that the at least one core executed background tasks during an active duration; and a control circuit to dynamically apply a power management policy for a background mode when the background task ratio exceeds a background mode threshold, the power management policy for the background mode to reduce power consumption of the processor. Other embodiments are described and claimed.

Abstract: In one embodiment, a processor includes: at least one core; and a power controller coupled to the at least one core. The power controller may include: a workload monitor circuit to calculate a background task ratio based on a first amount of time that the at least one core executed background tasks during an active duration; and a control circuit to dynamically apply a power management policy for a background mode when the background task ratio exceeds a background mode threshold, the power management policy for the background mode to reduce power consumption of the processor. Other embodiments are described and claimed.

Abstract: Methods and apparatus to manage power and performance of computing devices based on user presence are disclosed. An apparatus includes an engagement detector to determine an engagement of a user with a device based on at least one of image data generated by an image sensor or an application running on the device; and an operation mode selector to select one of a plurality of operation modes for the device based on a level of engagement of the user, the plurality of operation modes including (1) a first operation mode associated with the device operating at a first performance level and a first power level and (2) a second operation mode associated with the device operating at a second performance level and a second power level, the first performance level being higher than the second performance level, the first power level being higher than the second power level.

Abstract: In one embodiment, a processor includes: at least one core; and a power controller coupled to the at least one core. The power controller may include: a workload monitor circuit to calculate a background task ratio based on a first amount of time that the at least one core executed background tasks during an active duration; and a control circuit to dynamically apply a power management policy for a background mode when the background task ratio exceeds a background mode threshold, the power management policy for the background mode to reduce power consumption of the processor. Other embodiments are described and claimed.

Abstract: A reversible toy includes a body having a first surface and a second surface opposite the first surface. The body may be reversible between a first configuration and a second configuration to alternatingly present the first and second surfaces as an outer body surface defining an exterior of the body. In this regard, the other of the first and second surfaces may alternatingly define a stored body surface defining an interior cavity within the body. The reversible toy may further include an appendage attached to the body at the first surface and comprising a coupling feature. The coupling feature may be configured to couple the reversible toy to an object at the appendage.

Abstract: In one embodiment, a processor includes: at least one core; and a power controller coupled to the at least one core. The power controller may include: a workload monitor circuit to calculate a background task ratio based on a first amount of time that the at least one core executed background tasks during an active duration; and a control circuit to dynamically apply a power management policy for a background mode when the background task ratio exceeds a background mode threshold, the power management policy for the background mode to reduce power consumption of the processor. Other embodiments are described and claimed.

Abstract: In one embodiment, a processor includes: at least one core; and a power controller coupled to the at least one core. The power controller may include: a workload monitor circuit to calculate a background task ratio based on a first amount of time that the at least one core executed background tasks during an active duration; and a control circuit to dynamically apply a power management policy for a background mode when the background task ratio exceeds a background mode threshold, the power management policy for the background mode to reduce power consumption of the processor. Other embodiments are described and claimed.

Abstract: Techniques and mechanisms to dynamically prioritize communication of a data flow based on an indication of a user's interest in a particular task. In an embodiment, data flows correspond to different respective tasks that are executed with a host operating system. An output of a human interface device indicates whether, at a particular time, a user of a computer device is interested in one particular task over another task. Where greater user interest in a first task is indicated, a first packet type corresponding to the first task is assigned a relatively high priority, as compared to a second packet type which corresponds to a second task. Based on the priority, a resource of the network interface is selectively made available (or prevented from being made available) for the communication of a given packet. In another embodiment, the resource includes a queue of the network interface.

Abstract: Dynamic interrupt steering remaps the handling of interrupts away from processor units executing important workloads. During the operation of a computing system, important workload utilization rates for processor units handling interrupts are determined and those processor units with utilization rates about a threshold value are made unavailable for handling interrupts. Interrupts are dynamically remapped to processor units available for interrupt handling based on processor unit idle state and, in the case of heterogeneous computing systems, processor unit type. Processor units are capable of idle state demotion by, in response to receiving a request to enter into a deep idle state, determining if its interrupt handling rate is greater than a threshold value, and if so, placing itself into a shallower idle state than requested. This avoids the computing system from incurring the expensive idle state exit latency and power costs associated with exiting from a deep idle state.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: Methods and apparatus to manage power and performance of computing devices based on user presence are disclosed. An apparatus includes an engagement detector to determine an engagement of a user with a device based on at least one of image data generated by an image sensor or an application running on the device; and an operation mode selector to select one of a plurality of operation modes for the device based on a level of engagement of the user, the plurality of operation modes including (1) a first operation mode associated with the device operating at a first performance level and a first power level and (2) a second operation mode associated with the device operating at a second performance level and a second power level, the first performance level being higher than the second performance level, the first power level being higher than the second power level.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: A damped propshaft assembly with a hollow shaft and a tuned damper, which is received in the hollow shaft and includes a liner and a damping member. The liner's mass and stiffness are tuned to attenuate one or more of a bending mode vibration and a torsion mode vibration that occurs at a first predetermined frequency. The liner is not configured to substantially damp shell mode vibration that occurs at a frequency that is not equal to the first predetermined frequency. The damping member is coupled to the liner and is configured to primarily attenuate shell mode vibration in the hollow shaft at one or more desired frequencies. The tuned damper attenuates the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuates shell mode vibration. A method for forming a damped propshaft assembly is also provided.

Abstract: A method for forming a propshaft assembly. The method includes: providing a hollow shaft; tuning a mass and a stiffness of at least one liner to form an intermediate damper, the intermediate damper being configured to attenuate at least one of a bending moment vibration and a torsion mode vibration that occurs at a first predetermined frequency; tuning the intermediate damper to form a tuned damper, the tuned damper attenuating the at least one of the bending moment vibration and the torsion mode vibration at the first predetermined frequency and also attenuating shell mode vibration; and installing the tuned damper into the hollow shaft.