A vibratory detector for detecting a vibratory signal from one or more feeders. A processor is in communication with the vibratory detector and configured for determining from at least one characteristic of the vibratory signal a possible action event, and for determining from a pattern of possible action events a likely action event. A warning device is in communication with the processor for providing an output in response to the likely action event. In an embodiment, the at least one characteristic of the vibratory signal can comprise the frequency or magnitude of the vibratory signal.

According to one embodiment, an electronic apparatus includes power transmission circuitry, and detection circuitry. The power transmission circuitry transmits power by an electromagnetic wave with a first frequency band. The detection circuitry receives a reception signal and performs carrier sense with a second frequency band different from the first frequency band. The detection circuitry includes interference avoidance circuitry that eliminates a signal having a third frequency band which is a part of the second frequency band from the reception signal.

A Faraday cage enclosure for a mobile device with a portion that aligns with a display of the mobile device simultaneously substantially attenuate EM radiation to non-damaging amplitudes and is transparent to visible light in an optical spectrum, an EMP protection circuit electrically connected between the external charging and data port and the internal charging and data port, and a passive repeater configured to EM-couple with an antenna of the mobile device and relay signals to and from the antenna of the mobile device.

A method for controlling display and related products are provided. During outputting sound through a speaker of an electronic device, if an operating frequency of the speaker for playing the obtained first audio data is within an interference range of a first MIPI operating frequency of the MIPI of the display screen, and a percentage of interfered audio in the first audio data is greater than a first threshold, the first MIPI operating frequency of the MIPI of the display screen is adjusted to a target frequency such that a percentage of audio to be interfered in the first audio data is less than a second threshold, where second threshold is less than the first threshold.

A method for controlling display and related products are provided. During outputting sound through a speaker of an electronic device, if an operating frequency of the speaker for playing the obtained first audio data is within an interference range of a first MIPI operating frequency of the MIPI of the display screen, and a percentage of interfered audio in the first audio data is greater than a first threshold, the first MIPI operating frequency of the MIPI of the display screen is adjusted to a target frequency such that a percentage of audio to be interfered in the first audio data is less than a second threshold, where second threshold is less than the first threshold.

An in-band full-duplex transceiver includes a self-interference mixer for up-converting an adjusted digital baseband signal into an up-converted self-interference cancellation signal. The adjusted digital baseband signal has a phase opposite to a phase for a leakage signal from a leakage path for the transceiver. Similarly, the adjusted digital baseband signal has a magnitude matching a magnitude for the leakage signal. Given this phasing and magnitude for the up-converted self-interference signal, it substantially cancels the leakage signal when added with a received signal contaminated by the leakage signal.

An in-band full-duplex transceiver includes a self-interference mixer for up-converting an adjusted digital baseband signal into an up-converted self-interference cancellation signal. The adjusted digital baseband signal has a phase opposite to a phase for a leakage signal from a leakage path for the transceiver. Similarly, the adjusted digital baseband signal has a magnitude matching a magnitude for the leakage signal. Given this phasing and magnitude for the up-converted self-interference signal, it substantially cancels the leakage signal when added with a received signal contaminated by the leakage signal.

In some examples, a device is arranged to include a galvanic isolation barrier between first and second voltage domains. The device includes first and second capacitors arranged across the galvanic isolation barrier. The first and second capacitors are configured to communicate differential signals between the first and second domains. The device also includes a common mode suppression circuit arranged in the second voltage domain and configured to suppress a common mode signal communicated by the first and second capacitors. The common mode suppression circuit include a first passive RLC filter circuit coupled between the first capacitor and a low-impedance node. The common mode suppression circuit also includes a second passive RLC filter circuit coupled between the second capacitor and a low-impedance node.

In some examples, a device is arranged to include a galvanic isolation barrier between first and second voltage domains. The device includes first and second capacitors arranged across the galvanic isolation barrier. The first and second capacitors are configured to communicate differential signals between the first and second domains. The device also includes a common mode suppression circuit arranged in the second voltage domain and configured to suppress a common mode signal communicated by the first and second capacitors. The common mode suppression circuit include a first passive RLC filter circuit coupled between the first capacitor and a low-impedance node. The common mode suppression circuit also includes a second passive RLC filter circuit coupled between the second capacitor and a low-impedance node.

A data processing device includes an internal volume that is electromagnetic interference (EMI) isolated. The data processing device further includes an electromagnetic radiation (EMR) suppressing vent that defines one wall of the internal volume. The data processing device further includes a wireless system. The wireless system includes a first portion that is disposed in the internal volume. The first portion receives network data units from EMI emitting devices disposed in the internal volume and a second portion of the wireless system. The second portion is disposed outside of the internal volume and obtains the network data units from the first portion using a wireless connection that utilizes a transmission path that traverses through the EMR suppressing vent.