An Internet-of-Things module is provided, comprising a first interface, via which the module can be coupled to a hybrid single pair Ethernet line for exchanging data and/or commands and for supplying voltage. The module also has a voltage regulator for converting the first voltage applied at the first interface into a second voltage for supplying the module. A controller is also provided for IP-based communication via the hybrid single pair Ethernet line. A second interface is also provided, via which the module can be coupled to a sensor and/or actuator for exchanging data, signals and/or commands and for supplying voltage.

Provided is a battery-less sensor circuit including a power generation element, a first switching element, a voltage control circuit, a first storage capacitor, a sensor circuit, and a load. The power generation element is connected to the first storage capacitor via the first switching element. A power supply terminal of the sensor circuit is connected to an input terminal of the first switching element. The voltage control circuit is configured to control a current passing through the first switching element through reception of a voltage of the input terminal of the first switching element. The load is connected to the first storage capacitor and the sensor circuit.

The present disclosure provides a wireless sensing device. In an embodiment, the wireless sensing device includes (A) a button cell. The button cell has a positive electrode and a negative electrode. The device includes (B) a first printed circuit board (IPCB) located on a top surface of the button cell. The IPCB has a first contact and a second contact electrically connected to respective positive electrode and negative electrode of the button cell. The IPCB includes (i) a processor, and (ii) a wireless communication component (WCC). Each of the (i) processor, and (ii) WCC are electrically connected to the IPCB. The device includes (C) a sensor module. The sensor module includes a second PCB (2PCB) and one or more sensor chips electrically connected to the 2PCB. (D) The device has a length from 10 mm to 30 mm, a thickness from 3 mm to 10 mm and a width from 10 mm to 30 mm.

The present disclosure provides a wireless sensing device. In an embodiment, the wireless sensing device includes (A) a button cell. The button cell has a positive electrode and a negative electrode. The device includes (B) a first printed circuit board (IPCB) located on a top surface of the button cell. The IPCB has a first contact and a second contact electrically connected to respective positive electrode and negative electrode of the button cell. The IPCB includes (i) a processor, and (ii) a wireless communication component (WCC). Each of the (i) processor, and (ii) WCC are electrically connected to the IPCB. The device includes (C) a sensor module. The sensor module includes a second PCB (2PCB) and one or more sensor chips electrically connected to the 2PCB. (D) The device has a length from 10 mm to 30 mm, a thickness from 3 mm to 10 mm and a width from 10 mm to 30 mm.

A stemming system includes a computing device and a stemming device. The computing device includes data processing hardware and memory hardware in communication with the data processing hardware. The data processing hardware includes a transmitter and a receiver. The stemming device is communicatively-coupled to the computing device. The stemming device includes a base portion and a valve-engaging portion. The valve-engaging portion includes a transducer that obtains a measurement communicated to the receiver of the computing device. The measurement includes at least one physical parameter associated with installing a tire-wheel assembly valve to a wheel throughout a process of disposing the valve within a valve hole of the wheel. The processor analyzes a data signature associated with the measurement for determining if the valve has been adequately or inadequately installed by the stemming device.

A stemming system includes a computing device and a stemming device. The computing device includes data processing hardware and memory hardware in communication with the data processing hardware. The data processing hardware includes a transmitter and a receiver. The stemming device is communicatively-coupled to the computing device. The stemming device includes a base portion and a valve-engaging portion. The valve-engaging portion includes a transducer that obtains a measurement communicated to the receiver of the computing device. The measurement includes at least one physical parameter associated with installing a tire-wheel assembly valve to a wheel throughout a process of disposing the valve within a valve hole of the wheel. The processor analyzes a data signature associated with the measurement for determining if the valve has been adequately or inadequately installed by the stemming device.

A semiconductor device with a novel structure is provided. The semiconductor device includes a sensor, an amplifier circuit to which a sensor signal of the sensor is input, a sample-and-hold circuit that retains a voltage corresponding to an output signal of an amplifier input to the sample-and-hold circuit, an analog-to-digital converter circuit to which an output signal of the sample-and-hold circuit corresponding to the voltage is input, and an interface circuit. The interface circuit has a function of switching and controlling a first control period in which the sensor signal is input to the amplifier circuit and an output signal of the amplifier circuit is retained in the sample-and-hold circuit and a second control period in which a digital signal obtained by output of the voltage retained in the sample-and-hold circuit to the analog-to-digital converter circuit is output to the interface circuit. In the first control period, the analog-to-digital converter circuit is switched to stop output of the digital signal. The first control period is longer than the second control period.

A semiconductor device with a novel structure is provided. The semiconductor device includes a sensor, an amplifier circuit to which a sensor signal of the sensor is input, a sample-and-hold circuit that retains a voltage corresponding to an output signal of an amplifier input to the sample-and-hold circuit, an analog-to-digital converter circuit to which an output signal of the sample-and-hold circuit corresponding to the voltage is input, and an interface circuit. The interface circuit has a function of switching and controlling a first control period in which the sensor signal is input to the amplifier circuit and an output signal of the amplifier circuit is retained in the sample-and-hold circuit and a second control period in which a digital signal obtained by output of the voltage retained in the sample-and-hold circuit to the analog-to-digital converter circuit is output to the interface circuit. In the first control period, the analog-to-digital converter circuit is switched to stop output of the digital signal. The first control period is longer than the second control period.

Example methods and arrangements for sensors are disclosed herein. At least one storage device or storage disk includes instructions that, when executed, cause at least one processor of a mobile electronic device to at least access notification data indicative of an event at a security perimeter of a building, the notification data corresponding to a change in a status of one or more sensors at the security perimeter; present the notification data to a user of the mobile electronic device, the notification data including image data associated with the event; generate a message based on a user input at the mobile electronic device in response to the notification data; and output the message to cause a responsive action.

According to some embodiments, system and methods are provided including receiving, via a communication interface of an event detection and classification module comprising a processor, data from one or more sensors in a system; determining an event occurred based on the received data; applying a coherency similarity process to the received data via a classification module; determining whether the event is an actual event or a mal-doer event based on an output of the classification module; transmitting the determination of the event as the actual or the mal-doer event; and modifying operation of the system based on the transmitted output. Numerous other aspects are provided.