Abstract: Systems and methods for providing network connectivity and remote monitoring, optimization, and control of pool/spa equipment are provided. “Internet-of-Things” (IoT) functionality is provided for pool and spa equipment in a flexible and cost-effective manner. Network connectivity and remote monitoring/control of pool and spa equipment is provided by various components such as a network communication and local control subsystem installed in pool/spa equipment, and other components. Also disclosed are various control processes (“pool logic”) which can be embodied as software code installed in any of the various embodiments of the present disclosure.

Abstract: The pressure-type flow controller includes a main body provided with a fluid passage, a control valve for pressure control fixed in a horizontal position to the main body, an on/off valve fixed in a vertical position to the main body on the downstream side of the control valve for pressure control, an orifice provided in the fluid passage on the upstream side of the on/off valve, and a pressure sensor fixed to the main body for detecting the internal pressure of the fluid passage between the control valve for pressure control and the orifice. The fluid passage includes a first passage portion in a horizontal position connected to the control valve for pressure control, a second passage portion in a vertical position connecting the first passage portion to the orifice, and a third passage portion in a horizontal position connecting the second passage portion to the pressure sensor.

Abstract: Systems and methods for providing network connectivity and remote monitoring, optimization, and control of pool/spa equipment are provided. “Internet-of-Things” (IoT) functionality is provided for pool and spa equipment in a flexible and cost-effective manner. Network connectivity and remote monitoring/control of pool and spa equipment is provided by various components such as a network communication and local control subsystem installed in pool/spa equipment, and other components. Also disclosed are various control processes (“pool logic”) which can be embodied as software code installed in any of the various embodiments of the present disclosure.

Abstract: A water flow sensor and associated distributed water management system that analyzes water flow in toilets to identify leaks or other failures. A water flow sensor is disclosed that includes: a housing that contains a power source and an event processing system; a sensor that provides water flow data to the event processing system, the sensor having an inlet adapted to receive an inflow of water from a fill tube and an outlet that expels an outflow of water; a probe that activates the event processing system in response to a detected water flow event; and a support structure for seating the housing onto an overflow tube, wherein the support structure includes an assembly to receive the outflow of water and redirect the outflow into the overflow tube.

Abstract: A gas pressure regulator includes a body having respective inlet and outlet ports and an interior chamber defining a gas flow path. A hollow piston is moved in relation to a valve seat to create a junction through which gas is directed along the flow path to the outlet port. The piston engages a valve seat, thereby defining relative open and closed positions based on the position of the piston and the pressure of the gas, the piston being axially biased by a spring. The valve seat is attached to an adjustment member having at least one externally accessible feature to enable the axial position of the valve seat to be varied relative to the spring biased piston. In one version, the gas pressure regulator can include a heater assembly extending into the flow path adjacent the outlet port, enabling ported gas to be heated before introduction, e.g., into an engine.

Abstract: A field pressure test control system is adapted to be coupled to high pressure tubing through which fluid is pumped to a wellhead. When the system is coupled to the tubing and an isolation valve is open, the tubing is in fluid communication with a fluid line via at least the isolation valve. A sensor detects pressure in the fluid line during pressure testing of the high pressure tubing, and a relief valve is opened to permit fluid flow through the relief valve and thus lower pressure in the high pressure tubing. A pressure testing method includes closing the wellhead, and pumping fluid into the high pressure tubing and the fluid line. A fluid pressure in the fluid line is detected, and a relief valve is remotely opened to lower the fluid pressure. In several exemplary embodiments, the pressure testing is completed before a hydraulic fracturing operation begins.

Abstract: Systems and methods for providing network connectivity and remote monitoring, optimization, and control of pool/spa equipment are provided. “Internet-of-Things” (IoT) functionality is provided for pool and spa equipment in a flexible and cost-effective manner. Network connectivity and remote monitoring/control of pool and spa equipment is provided by various components such as a network communication and local control subsystem installed in pool/spa equipment, and other components. Also disclosed are various control processes (“pool logic”) which can be embodied as software code installed in any of the various embodiments of the present disclosure.

Abstract: Techniques for monitoring surface temperature of devices are described. Generally, surface temperature of devices is monitored and controlled to prevent user discomfort and/or injury that may result from user contact with an excessively heated surface. In at least some embodiments, temperature of an external surface of the device is indirectly monitored. For instance, a temperature sensor is positioned at an internal location in a device that has a known temperature relationship to a temperature of an external surface of the device. Alternatively or additionally, a temperature of an external surface of a device may be directly detected. In at least some embodiments, when a temperature of an external surface of a device is determined to reach or exceed a threshold temperature, procedures can be implemented to reduce the temperature of the external surface and/or prevent further heating of the external surface.

Abstract: A current reference comprising: a control resistor; a tracking voltage generator including: a first, flipped gate transistor having a first size; and a second transistor having a second size; wherein the tracking voltage generator is configured to output a tracking voltage having a first temperature dependency based on a ratio of the second size to the first size, the temperature dependency thereby being substantially equal to a second temperature dependency of the control resistor; and an amplifier circuit configured to receive the tracking voltage and maintain a voltage at a first terminal of the control resistor, the voltage being substantially equal to the tracking voltage; wherein the current reference thereby is configured to maintain a reference current through the control resistor at a constant value.

Abstract: A low dropout linear regulator circuit comprises a voltage reference source module (100), an error amplifier (200), a reference voltage determining module (300), a power transmission device (400) and a feedback module (500); wherein the voltage reference source module (100) provides a reference voltage for the error amplifier (200), the reference voltage determining module (300) controls an enablement of the error amplifier (200) according to whether the voltage reference source module (100) is completely started, the error amplifier (200) controls ON/OFF of the power transmission device (400) according to the reference voltage provided by the voltage reference source module (100) and a feedback voltage provided by the feedback module (500). A chip having the above low dropout linear regulator circuit and a electronic device having the above chip are provided.

Abstract: A low dropout voltage (LDO) regulator including: a coarse loop circuit configured to receive an input voltage, generate a coarse code and adjust a coarse current according to the coarse code; a digital controller configured to receive the coarse code and generate a fine loop control signal according to the coarse code; and a fine loop circuit configured to receive the input voltage and the fine loop control signal and adjust a fine current according to the input voltage and the fine loop control signal, wherein the coarse current and the fine current adjust a level of an output voltage.

Abstract: A method for providing a voltage reference at a present operating temperature in a circuit is provided. The circuit comprises a first MOS transistor having a first threshold voltage; and a second MOS transistor having a second threshold voltage different from the first threshold voltage is provided.

Abstract: A voltage regulator which provides an output current at an output voltage at an output node, based on an input voltage at an input node is described. The voltage regulator has an output amplification stage comprising a pass transistor for deriving the output current at the output node from the input voltage at the input node; and comprising a driver stage to set a gate voltage at a gate of the pass transistor based on a drive voltage. A gain of the output amplification stage is adjustable. Furthermore, the voltage regulator comprises a differential amplification unit to determine the drive voltage in dependence of the output voltage and in dependence of a reference voltage. In addition, the voltage regulator comprises a gain control circuit to adjust the gain of the output amplification stage in dependence of the output current.

Abstract: The present disclosure relates to a method and device for limiting demand of power for a power consumption system. The method comprises computing demand limiting threshold values based on one or more predefined parameters and further determining a demand limiting mode of the power consumption system to be one of enabled and disabled based on the demand limiting threshold values, the one or more predefined parameters and a ratio which is based on benefit to a user in terms of cost and impact on the user associated with the demand limiting mode. The method further comprises identifying demand limiting strategy based on the one or more predefined parameters and the impact when the demand limiting mode is enabled. Further the method comprises executing the demand limiting strategy on one or more target equipment based on a switching sequence.

Abstract: The invention relates to a power consumption reduction device in the form of an electronic device that operates as an interface between any power supply source and consumption demand. The system, with less amperage at the input, delivers the total power required according to demand, within its established capabilities. In its internal systems, three fundamental variants can be regulated, namely: line impedance, phase angle and reactive power flow. With regard to the input power supply, in the event of any variations in the fundamental frequencies, the system simulates these frequencies as if the variations were not being produced. In addition, the system optimizes consumption, supplying each device with the power required for optimal operation, while also absorbing voltage peaks, thereby also protecting the operating life of devices or household appliances.

Abstract: Some embodiments relate to a two transistor band gap reference circuit. A first transistor includes a first source, a first drain, a first body region separating the first source from the first drain, and a first gate. The first drain and first gate are coupled to a DC supply terminal. The second transistor includes a second source, a second drain, a second body region separating the second source from the second drain, and a second gate. The second gate is coupled to the DC supply terminal, and the second drain is coupled to the first source. Body bias circuitry is configured to apply a body bias voltage to at least one of the first and second body regions. Other embodiments relate to FinFET devices.

Abstract: A voltage-current converter includes a first input stage and a second input stage with a first transistor and a second transistor driven by the first input stage and by the second input stage, respectively. First and second current generators are coupled to current lines of the first transistor and of the second transistor. At least one resistor couples the current lines of the first transistor and of the second transistor, where the ends of the aforesaid resistor are coupled to feedback terminals of the input stages so that an input voltage applied between voltage input terminals of the input stages is converted into a current on respective current output terminals of the converter. The converter includes switching circuits for coupling the first and second current generators alternately to the current line of the first transistor and to the current line of the second transistor.

Abstract: An actuator device (2) for actuating at least one foot pedal (P) of a motor vehicle has at least one actuating element (8), whereby, for applying force to the foot pedal (P), said actuating element is shifted by means of a positioning mechanism (10) between an application position and a released position. It is provided that the positioning mechanism (10) is drivable with a positioning force (SF), by means of inertial means (such as an inertial mass).

Abstract: A movement member which reciprocates includes a thick portion and a thin portion, a bearing portion formed in the thick portion is slidingly supported by the guide shaft, and a sliding portion formed in the thin portion is slidingly guided by the sliding guide portion. Power of the motor is transmitted to a pinion gear via a speed reduction gear and a speed reduction mechanism inside a gear box, and a movement reaction force is applied from the pinion gear to the rack portion. Since the rack portion is positioned on an axis Os, a force is effectively applied to the movement member by the power from the motor.

Abstract: A semiconductor device includes a first clock generating circuit including a first control circuit and a first clock gating circuit, a first channel management circuit which communicates with the first clock generating circuit according to a full handshake method, a second clock generating circuit including a second control circuit and a second clock gating circuit, and a second channel management circuit which communicates with the second clock generating circuit according to the full handshake method. The first clock gating circuit outputs a first clock, and the second clock gating circuit outputs a second clock different from the first clock.

Abstract: A clock management unit (CMU) includes a first clock control circuit controlling a first clock source, a second clock control circuit sending a first clock request to the first clock control circuit in response to an intellectual property (IP) block clock request from an IP block and controlling a second clock source, and a CMU controller. The second clock control circuit receives a clock signal from the first clock source. A power management unit (PMU) sends a PMU clock request to the CMU controller. The CMU provides the clock signal to the IP block in response to the PMU clock request.

Abstract: A semiconductor device includes a first clock control circuit for controlling a first clock source; a second clock control circuit for sending a first clock request to the first clock control circuit in response to a block clock request from an intellectual property (IP) block, and controlling a second clock source, which receives a clock signal from the first clock source, to generate a stopped clock signal, which is a clock signal turned off for a predetermined amount of time; and a driver circuit for receiving a block control signal, and outputting the block control signal to the IP block while the short stopped clock signal is output to the IP block.

Abstract: A finger-wearable computing device may comprise a processor, a ring base, and a display screen. The display screen is coupled to the ring base and coupled to the processor to display an output. The display screen includes a command area configured to receive user input from a wearer's thumb while the finger-wearable computing device is worn on a wearer's finger. The ring base may be resiliently flexible and may define an overlapping loop with a central opening that expands and contracts to the fit the wearer's finger. The display screen may be flexibly coupled to the ring base and may have a vertical axis that is canted at an angle relative to a central axis of the ring base to ergonomically position the display screen while the wearable computing device is worn on the finger of the wearer's hand.

Abstract: A housing includes a metal base and a non-conductive member. The metal base has an internal surface and a plurality of gap. The non-conductive member covers at least a portion of the internal surface of the metal base, and the non-conductive member is formed on the bottom of the at least one gap. The metal base is spaced by the gaps to form a plurality of metal sheets and at least one main body. Each gap is completely filled with one dielectric member. The metal sheets and the at least one main body are all bonded with the dielectric member and are electrically isolated with each other.

Abstract: An electronic device may have a metal housing. The metal housing may have an upper housing in which a component such as a display is mounted and a lower housing in which a component such as a keyboard is mounted. Hinges may be used to mount the upper housing to the lower housing for rotation about a rotational axis. A slot-shaped opening may separate the upper and lower housing. Flexible printed circuits with ground traces may bisect the slot-shaped opening to form three electrically isolated slots each of which is aligned with a respective cavity antenna. The antennas may have antenna grounds formed from portions of the metal housing and other conductive structures. Resonating elements for the antennas may be supported by an elongated ventilation port structure along the rear edge of the lower housing.

Abstract: Watercraft can be adapted with devices and systems for displaying watercraft operational data, and for receiving user input to control the watercraft. Some devices described herein are configured to releasably mount a computing device to the helm of the watercraft in a convenient, user-friendly manner. The helm-mounted computing device can be configured to display a variety of watercraft-related data, and to receive user input. Moreover, the mounting devices described herein allow the computing device to be readily removed from the helm area so the computing device can be transported for use away from the watercraft.

Abstract: An example electronic display device comprises a flexible display panel, a support panel supporting the flexible display panel, a guide about which the support panel turns and an actuator to apply a local stimulus to selected portions of the support panel that are in proximity with the guide to facilitate changing the selected portions of the support panel from a rigid planar shape to a bent shape about the guide as the support panel and the display panel are moved about the guide and such that the support panel returns to the rigid planar shape once moved away from the guide.

Abstract: A portable electronic device and a protection case thereof are provided. The portable electronic device includes a memory; a display; and a processor configured to acquire, from a flexible element included in a protection case of the portable electronic device, a characteristic value of the flexible element, the characteristic value changing according to bending of the flexible element through movement of the protection case, and determine a state of the protection case, based in the acquired characteristic value.

Abstract: This application relates to an insert nut for a housing of a computing device. The insert nut can include a threaded interior surface for receiving a screw, and a ribbed exterior surface for receiving an adhesive between ribs of the ribbed exterior surface. At least one of the ribs can include at least one notch that allows for an adhesive to flow between ribs. When the insert nut is pressed into an adhesive filled cavity, the adhesive can flow over the notch and between the ribs of the insert nut. Thereafter, the adhesive can be cured in order to secure the insert nut to the housing. This arrangement allows for screws to be secured into the insert nut rather than directly into the housing, thereby reducing cracks that can otherwise form in the housing.

Abstract: An electronic device bracket including a first supporting member, a second supporting member, and at least one pivoting member is provided. The second supporting member is disposed beside the first supporting member. The at least one pivoting member is disposed at a side of the first and the second supporting members, and two ends of the at least one pivoting member are pivoted to the first and the second supporting members. Here the first supporting member is adapted to move between a first position and a second position relative to the second supporting member, so as to adjust a length of the electronic device bracket.

Abstract: A serial pump includes a pump body, a first impeller and a second impeller. A first rotor chamber, a second rotor chamber and a connecting channel are formed in the pump body. The first rotor chamber has a first outlet opening, the second rotor chamber has a second inlet opening, and the connecting channel is communicated between the first outlet opening and the second inlet opening. The first impeller is pivotally arranged in the first rotor chamber, and an outer periphery of the first impeller is arranged corresponding to the first outlet opening. The second impeller is pivotally arranged in the second rotor chamber, and a center of the second impeller is arranged corresponding to the second inlet opening. Accordingly, the first impeller and the second impeller are serially arranged.

Abstract: In some implementations, a system controller of a computing device can be configured to obtain power supply unit (PSU) fan airflow direction information. The system controller is configured to retrieve t a pre-defined airflow direction of PSU fan, and to determine whether the current airflow direction of PSU fan is consistent with the retrieved pre-defined fan airflow direction. In some implementations, upon determining that the current airflow direction of PSU fan is inconsistent with the pre-defined fan airflow direction, the system controller can cause an indication device associated with the PSU to be toggled. The indication device indicates that the PSU fan has been incorrectly installed and notifies the technician that over-temperature fault can occur due to incorrect installment.

Abstract: A method includes executing an initialization routine upon startup of a processor. The method includes executing a benchmark program during the initialization routine after the startup. The method further includes comparing an amount of time for execution of the benchmark program to a reference time to determine if the processor has slowed due to thermal degradation of heat removal components for the processor.

Abstract: A device for processing data includes a processing unit configured to predict an execution time of a compute kernel on a secondary processing unit and, based on the predicted execution time, make a power management decision for the secondary processing unit.

Abstract: A power supply device includes a housing, a plug assembly, and a sliding assembly. The plug assembly includes a power jack positioned on the housing and a power plug. The sliding assembly is slidably mounted on the housing. When the sliding assembly slides to a first position, the sliding assembly is configured to block the power jack for preventing the power plug being inserted to the power jack. When the sliding assembly slides to a second position, the sliding assembly is configured to move away from the power jack for allowing the power plug being received in the power jack.

Abstract: The invention provides a method of integrating a server using alternating current power (AC server) into a server system using direct current power (DC server system) and an alternative junction device therefor. The integrating method includes: providing an AC server having a plug-in power supply unit; providing an alternative junction device for replacing the plug-in power supply unit; extracting the plug-in power supply unit from the AC server; plugging the alternative junction device into the AC server; and coupling the alternative junction device to a direct current power supply unit of a DC server system. The alternative junction device includes: a shell to be installed into a containing slot of an AC server; an output coupled to a DC input of a processor of the AC server when the shell is installed into the containing slot; and an input coupled to a DC power supply unit of a DC server system.

Abstract: A communication apparatus comprises:a power supply; a communication unit configured to operate by using power from the power supply or a communication partner;an operation unit;a control unit configured to execute software for controlling processing of each unit of the communication apparatus, wherein the control unit starts processing to stop execution of the software if an operation to the operation unit is started while the control unit is executing the software; a power supply control unit configured to control power that is supplied to the control unit, in accordance with a state of as operation with respect to the operation unit; and a disabling unit configured to disable the communication unit, based on the state of the operation with respect to the operation unit and an execution state of the software.

Abstract: A semiconductor device includes a first control circuit controlling a first child clock source to receive a clock signal from a parent clock source, a first channel management (CM) circuit transmitting a first clock request to the first control circuit in response to a second clock request received from a first IP block, a second control circuit controlling a second child clock source to receive the clock signal from the parent clock source, a second CM circuit transmitting a third clock request to the second control circuit in response to a fourth clock request received from a second IP block, and a power management unit transmitting a power control command to the first CM circuit and the second CM circuit to control a power state of the first IP block and the second IP block. The first CM circuit and the second exchange signals to maintain a master-slave relationship.

Abstract: A computing device may comprise a volatile memory and a non-volatile storage device. Upon system shutdown, contents of the volatile memory may be preserved by memory transfer operations from the volatile memory to the non-volatile storage device. During memory preservation, the computing device may enter a low-power state. The low-power state may comprise suspension of power to a core of a processor while maintaining power to the processor's uncore, and disablement of interrupt signals not related to memory transfer operations. Power delivery to the core of the processor may be periodically resumed to initiate additional memory transfer operations.

Abstract: Example implementations relate to load discovery. For example, a load discovery system can include a shared backup power supply controlled by a backup power control module, and a node coupled to the shared backup power supply, wherein the node supports a plurality of loads, and the shared backup power supply powers the plurality of loads when the node is powered off, and a baseboard management control (BMC) unit coupled to the node, the BMC unit to discover the plurality of loads.

Abstract: A computer system including a chassis having a first chassis component and a backup power source.

Abstract: A mobile terminal is disclosed. The mobile terminal includes a first body including a display and a battery receiving portion that is embedded in the first body and communicates with an opening positioned at an end of the first body, a second body including an inner housing coupled to a side of a battery, and a spring assembly positioned in the first body and providing an elastic force for the battery while contacting another side of the battery coupled to the inner housing. The first body and the second body are in at least one of states including a first state in which the second body is coupled to the end of the first body, and a second state in which an entire portion of the second body is spaced apart from the end of the first body.

Abstract: Apparatuses, methods and storage medium for providing access from outside a multicore processor System on Chip (SoC) are disclosed herein. In embodiments, an SoC may include a memory to store a plurality of embedded values correspondingly associated with a plurality of architecturally identical cores. Each embedded value may indicate a default voltage for a respective one of the plurality of architecturally identical cores. In embodiments, an apparatus may include one or more processors, devices, and/or circuitry to provide access from outside the multicore processor SoC to individually configure voltages of the plurality of architecturally identical cores to values that are different than the values of the default voltages. Other embodiments may be described and/or claimed.

Abstract: A computing device may comprise a processor, a volatile memory and a non-volatile storage device. An operating system or firmware of the device may cause one or more pages of the volatile memory to be treated, by applications executing on the computing device, as non-volatile memory pages. A maximum number of pages that may be treated as non-volatile may be determined based on an amount of energy available in a battery and an amount of energy needed to transfer a page of memory to the non-volatile storage device.

Abstract: An electronic device is provided. The electronic device includes a first connector including a first pin and a second pin configured to connect with a first external electronic device, a second connector configured to connect with a second external electronic device, a connection sensing circuit configured to sense a connection or disconnection of the second external electronic device coupled to the first pin via the second connector, and a switch configured to supply power received from the first external electronic device via the second pin to the first pin if the disconnection is sensed via the connection sensing circuit.

Abstract: A power budget allocation method includes: obtaining a system setting associated with a multi-core processor system, obtaining a target power budget, and checking, by a power management controller, at least one power management table according to the system setting and the target power budget to generate a power management output for the multi-core processor system. The system setting includes a core combination setting of the multi-core processor system, and further includes a frequency setting of each processor core selected by the core combination setting.

Abstract: A system on chip (SoC) includes a plurality of intellectual property (IP) blocks and a clock management unit (CMU) configured to perform clock gating on at least one of the IP blocks. The IP blocks and the CMU interface with one another using a full handshake method. The full handshake method may include at least one of the IP blocks sending a request signal to the CMU to begin providing a clock signal or to stop providing the clock signal, and the CMU sending an acknowledgement signal to the corresponding IP block in response to receipt of the request signal.

Abstract: Aspects of the present invention include a device comprising a first sensor and a circuitry configured to detect a first user action and a second user action, the second user action being detected by the first sensor. The circuitry is further configured to designate a first mode based on the first user action and a second mode based on the second user action, the first mode and the second mode being power saving modes and the second mode is configured to save power consumed by the first sensor.

Abstract: An optical mouse device includes a light source, an image sensor array, an energy storage element, a frame buffer and a processor, wherein the image sensor array includes a plurality of sensing pixels and a plurality of self-powered pixels. In a first mode, the sensing pixels output image data to the frame buffer, and the self-powered pixels output photocurrent to the energy storage element. In a second mode, the self-powered pixels output intensity data associated with the photocurrent to the frame buffer, and the processor determines whether to leave the second mode or not according to the intensity data. The energy storage element is configured to provide energy required in illumination.

Abstract: An apparatus for throttling traffic on a bus includes an electronic client device, a host device, and a bus protocol circuit connected between the electronic client device and the host device. Data transfers between the electronic client device and the host device are controlled by the bus protocol circuit by tracking credits. The bus protocol circuit is configured to throttle traffic between the electronic client device and the host device when signaled by a throttle signal from the electronic client device.