A method and system for battery management for a mobile geofence apparatus. Location information for a vehicle, temperature information for the vehicle and battery information for the internal battery on the mobile geofence apparatus is automatically, continuously and periodically collected and sent during a connection interval in real-time to an external network server network device via a communications network for tracking the vehicle in real-time. The battery information is displayed on the mobile geofence apparatus for a viewer and is also sent to an external server network device for display to a viewer. Internal battery usage is automatically managed internally on the mobile geofence apparatus using the collected location, battery and temperature information. The internal battery on the mobile geofence apparatus is also automatically managed externally via the external server network device using the collected location, battery and temperature information.

Described herein are mechanisms and methods for blocking the propagation of signals to Integrated Circuit (IC) components that have been power gated, rather than simply suffering from leakage through signals that might not be parked in a low state. In some embodiments, switches that block the flow of current in such signals may enable turning off power to any IC component and not just to circuits on an IC component that make sole use of protocols that are friendly to power gating. This may advantageously increase power savings, by permitting more portions of a system in an idle state to be power gated, or by reducing or eliminating leakage in signals on boundaries of blocks being power gated, or both.

A data report rate adjustment method for use between a computer host and a peripheral device is provided. According to the actual workload level of the computer host and/or the amount of the input data of the peripheral device, the priority or the report rate of the data to be transmitted from the peripheral device can be dynamically adjusted or set. More especially, the unnecessary data report can be avoided. Consequently, the workload of the computer host can be effectively reduced, and the power consumption of the peripheral device can be saved.

A micro control unit (“MCU”) controls operation of a cooling fan in a compute device. The MCU is responsive to determining that a fan speed of the cooling fan is above a predetermined speed threshold to periodically determine power consumption of the cooling fan. In response to a periodic determination of power consumption exceeding a predetermined power consumption limit, the MCU reduces the fan speed of the cooling fan by a predetermined increment and continues periodically determine power consumption of the cooling fan. Upon determining that the power consumption does not exceed the predetermined power consumption limit, the MCU discontinues any prior reduction of the fan speed.

An apparatus for outputting a sound source for minimizing power consumption and an operating method thereof are disclosed. The sound source output method includes a terminal detecting step of detecting connection and a type of a terminal; a power control processing step of generating a power control signal so as to correspond to an audio transmitting method according to the detected terminal type and controlling a power supply operation to a conversion processing unit and an amplification processing unit connected to a power source unit including at least one power block based on the power control signal; an audio signal generating step of generating at least one audio signal by performing signal converting and amplifying operations based on the power supplied based on the power supply operation; and an audio outputting step of outputting a final audio signal generated using audio signals according to the audio transmitting method.

One example provides a display device comprising a display panel, a touch sensor, an ambient light sensor, a processor, and storage. The storage comprises instructions executable by the processor to monitor an ambient light signal received from the ambient light sensor, detect, in combination with a call event, a threshold change in the ambient light signal that is indicative of the display device being proximate to a body of a user, and based at least on detecting the threshold change in the ambient light signal, modify an operation of the display device.

A bus repeater includes first and second bus ports, a first termination resistor network coupled to the first bus port, a second termination resistor network coupled to the second bus port, and a power state change detection circuit coupled to the second bus port. The power state change detection circuit is configured to detect a power state change initiated by a device coupled to the first bus port. The detection of the power state change includes a determination that a voltage on the second bus port exceeds a threshold. Responsive to detection of the power state change, the power state change detection circuit is configured cause a change in a configuration of at least one of the first or second termination resistor networks.

An electronic device displaying a user interface on a display. While displaying the user interface on the display and while one or more tactile output generators of the electronic device are in a low-power state, the electronic device detects a first user interaction via the touch-sensitive surface. In response to detecting the first user interaction, the electronic device sets the one or more tactile output generators to a low-latency state. After setting the one or more tactile output generators to the low-latency state, the electronic device detects a second user interaction that is continuation of a touch input, on the touch sensitive surface, that includes the first user interaction. In response to detecting the second user interaction, the electronic device generates a tactile output that corresponds to the second user interaction.

An information handling system wirelessly interfaces with a peripheral device, such as a keyboard or mouse, through primary radios that have a communication protocol, such as Bluetooth. Secondary radios interface with their associated primary radio to provide a low power wake and sleep using wake and sleep signals sent between the secondary radios. A sleep command communicated through the primary radios is acknowledged with the secondary radios to confirm operation of the secondary radios before a subsequent wake command transmits while in the sleep state.

Embodiments of the present disclosure provide a data transmission method, apparatuses, and a smart watch device. A first BLE module of a first MCU of a smart watch receives an instruction of transmitting data which includes an instruction of transmitting the data to an AP of the smart watch or a mobile terminal. The first BLE module determines whether the AP is in a wake-up state if the instruction is to transmit the data to the AP, and transmits the data to a second BLE module of the AP through a RFCOMM interface if the AP is determined to be in the wake-up state, otherwise, buffers the to-be-transmitted data. The first BLE module synchronizes state information to the second BLE module if the instruction is to transmit the data to the mobile terminal, and transmits the data to the mobile terminal through the RFCOMM interface.