A data transmission and control device in a multi-node sensor network, comprising a processing control module (110). The processing control module (110) comprises an instruction processing unit, a data processing unit, at least one group of first-type interfaces (J101-J10n), at least one group of second-type interfaces (J201-J20n), one group of fifth-type interfaces (J500) and one group of sixth-type interfaces (J600). The fifth-type interfaces (J500) have communication connections with an external control device (120). The first-type interfaces (J101-J10n) respectively have communication connections with a sensor (140) so as to cooperate with the instruction processing unit to configure and query a parameter of the sensor (140), and to upgrade firmware and report feedback information of the sensor (140) and the processing control module. The second-type interfaces (J201-J20n) respectively have communication connections with the sensor (140) and the sixth-type interfaces (J600) have communication connections with an external service terminal (130) so as to cooperate with the data processing unit to acquire data of a plurality of sensors (140) and transmit the data to the external service terminal (130) for processing. The device controls the sensor (140) via a network, enables the data of the sensor (140) to be modular, and provides a uniform interface to the outside, thus forming a smart control platform for dynamic configuration, data processing and external interaction of the sensor (140).

A data transmission and control device in a multi-node sensor network, comprising a processing control module (110). The processing control module (110) comprises an instruction processing unit, a data processing unit, at least one group of first-type interfaces (J101-J10n), at least one group of second-type interfaces (J201-J20n), one group of fifth-type interfaces (J500) and one group of sixth-type interfaces (J600). The fifth-type interfaces (J500) have communication connections with an external control device (120). The first-type interfaces (J101-J10n) respectively have communication connections with a sensor (140) so as to cooperate with the instruction processing unit to configure and query a parameter of the sensor (140), and to upgrade firmware and report feedback information of the sensor (140) and the processing control module. The second-type interfaces (J201-J20n) respectively have communication connections with the sensor (140) and the sixth-type interfaces (J600) have communication connections with an external service terminal (130) so as to cooperate with the data processing unit to acquire data of a plurality of sensors (140) and transmit the data to the external service terminal (130) for processing. The device controls the sensor (140) via a network, enables the data of the sensor (140) to be modular, and provides a uniform interface to the outside, thus forming a smart control platform for dynamic configuration, data processing and external interaction of the sensor (140).

An embodiment of a semiconductor package apparatus may include technology to provide a first interface between a first storage device and a host device, and provide a second interface directly between the first storage device and a second storage device. Other embodiments are disclosed and claimed.

An embodiment of a semiconductor package apparatus may include technology to provide a first interface between a first storage device and a host device, and provide a second interface directly between the first storage device and a second storage device. Other embodiments are disclosed and claimed.

In some embodiments, a controller of an intelligent switch in a three-phase power distribution network is configured to serve as a sectionalizer. The controller preferably includes voltage restraint logic and count restraint logic to prevent opening of the switch in response to a detected fault unless the voltage and current drop below minimum threshold values. The controller preferably additionally includes inrush restraint logic that prevents detection of a fault in response to an inrush current spike that may occur, for example, on startup of an AC motor or when energizing a transformer. The controller preferably further includes close-on-fault detection logic that bypasses counting of fault/line clear events by the controller if the switch is closed on a fault.

In some embodiments, a controller of an intelligent switch in a three-phase power distribution network is configured to serve as a sectionalizer. The controller preferably includes voltage restraint logic and count restraint logic to prevent opening of the switch in response to a detected fault unless the voltage and current drop below minimum threshold values. The controller preferably additionally includes inrush restraint logic that prevents detection of a fault in response to an inrush current spike that may occur, for example, on startup of an AC motor or when energizing a transformer. The controller preferably further includes close-on-fault detection logic that bypasses counting of fault/line clear events by the controller if the switch is closed on a fault.

A multi-power distributed storage system including a first power source; a second power source electrically connected to a common bus with the first power source; a single input port inverter electrically connected to the common bus. The system including a controller configured to communicate with at least the second power source, and the single input port inverter. The second power source including a plurality of battery banks and a plurality of bi-directional DC/DC converters configured to charge and discharge the plurality of battery banks and provide DC to the single input port inverter.

A multi-power distributed storage system including a first power source; a second power source electrically connected to a common bus with the first power source; a single input port inverter electrically connected to the common bus. The system including a controller configured to communicate with at least the second power source, and the single input port inverter. The second power source including a plurality of battery banks and a plurality of bi-directional DC/DC converters configured to charge and discharge the plurality of battery banks and provide DC to the single input port inverter.

A servo driver includes: a driver, a pulse conversion module and a pulse interface. The pulse conversion module is connected between the pulse interface and the driver, and the pulse conversion module converts the type of a pulse control signal received by the pulse interface from an upper computer or a PLC and then outputs same to the driver. The type of the pulse control signal includes at least one of a clockwise and counter-clockwise pulse control type, a pulse plus direction control type and an AB-phase input control type. In an embodiment, the pulse conversion module is used to convert the type of the pulse control signal from the upper computer or the PLC, so that the driver can be compatible with an upper computer or a PLC having a different control signal type.

A servo driver includes: a driver, a pulse conversion module and a pulse interface. The pulse conversion module is connected between the pulse interface and the driver, and the pulse conversion module converts the type of a pulse control signal received by the pulse interface from an upper computer or a PLC and then outputs same to the driver. The type of the pulse control signal includes at least one of a clockwise and counter-clockwise pulse control type, a pulse plus direction control type and an AB-phase input control type. In an embodiment, the pulse conversion module is used to convert the type of the pulse control signal from the upper computer or the PLC, so that the driver can be compatible with an upper computer or a PLC having a different control signal type.