An electric filtering device (200) for filtering Repetitive Electrical Impulse Noise (REIN) in a fixed-access telecommunications network (100), the electric filtering device comprising: a REIN filter (210), said REIN filter comprising a first electrical contact (220-1) and a second electrical contact (220-2) for connecting to a telecommunications cable (140) of the fixed-access telecommunications network; an enclosure (230) for enclosing the REIN filter; an input (250-1) and an output (250-2), formed as part of the enclosure, each for receiving a telecommunications cable (140) so as to be connected to the first and the second electrical contacts, thereby to connect the REIN filter to the fixed-access telecommunications network; a coupling formation (260) for coupling the electric filtering device to an external distribution point (130) for a telecommunications cable of the fixed-access telecommunications network.

an orthogonal frequency division multiplexed (OFDM) output signal produced by a device in response to an OFDM input signal is accessed. The OFDM input signal includes OFDM input symbols in the time domain and the OFDM output signal includes OFDM output symbols in the time domain. The OFDM output symbols are time-aligned to the OFDM input symbols and a phase of the OFDM output signal is de-rotated with respect to the OFDM input signal. A complex equalization filter is applied to the OFDM output symbols in the time domain to obtain an estimate of the OFDM input symbols A distortion signal of the OFDM output signal is determined by subtracting the estimate of the OFDM input symbols. An error vector magnitude (EVM) is determined by dividing a root mean square of the distortion, by a root mean square of the OFDM input signal.

Mitigation of satellite interference is contemplated. The mitigation may include processing satellite transmissions to remove interferences based on an amount of signal overlap, such as to facilitate mitigating interferences resulting from satellite spacing and/or ground antenna dish size.

In accordance with one embodiment, a method for a health scanning system is disclosed. The method includes receiving at least one electrical physiological data signal (PDS); suppressing a Direct Current (DC) signal component of the PDS to emphasize the Alternating Current (AC) signal component of the PDS; isolating the signal noise in the AC signal component of the PDS; and extracting a noise signature from the signal noise in the PDS. The noise signature, after calibration, can be used to uniquely identify a known user from other users.

An electronic device may include wireless circuitry with a transmit antenna that transmits signals and a receive antenna that receives reflected signals. The wireless circuitry may detect a range between the device and an external object based on the transmitted signals and the reflected signals. When the range exceeds a first threshold, the wireless circuitry may use the transmitted signals and received signals to record background noise. When the range is less than a second threshold value, the wireless circuitry may detect the range based on the reflected signals and the recorded background noise. This may allow the range to be accurately measured within an ultra-short range domain even when the device is placed in different device cases, placed on different surfaces, etc.

According to one configuration, a system includes a first wireless station in communication with a second wireless station. A phase noise predictor model such as associated with the first wireless station receives phase noise information. The phase noise information captures an estimate of: i) first phase noise associated with a first wireless station, and ii) second phase noise associated with a second wireless station. Based on the received phase noise information, the predictor produces phase noise adjustment information. The predictor applies the phase noise adjustment information to adjust (compensate) a signal of the first wireless station. Adjustment of the signal results in phase noise adjustment with respect to both the first phase noise associated with the first wireless station and the second phase noise associated with the second wireless station.

In a communication apparatus, an analog circuit includes a circuit element to be connected to a first conductor, and processes a differential signal. A communication circuit receives, via a connection circuit, a differential signal processed by the analog circuit, and generates a signal for which the potential of a second conductor is used as a reference potential based on the received differential signal. An inductor is connected between the first conductor and the second conductor. The connection circuit includes a circuit element different from a capacitor. The analog circuit (21), the connection circuit, the communication circuit, the inductor, the first conductor, and the second conductor are housed in a conductive housing box.

An electric filtering device (200) for filtering Repetitive Electrical Impulse Noise (REIN) in a fixed-access telecommunications network (100), the electric filtering device comprising: a REIN filter (210), said REIN filter comprising a first electrical contact (220-1) and a second electrical contact (220-2) for connecting to a telecommunications cable (140) of the fixed-access telecommunications network; an enclosure (230) for enclosing the REIN filter; an input (250-1) and an output (250-2), formed as part of the enclosure, each for receiving a telecommunications cable (140) so as to be connected to the first and the second electrical contacts, thereby to connect the REIN filter to the fixed-access telecommunications network; a coupling formation (260) for coupling the electric filtering device to an external distribution point (130) for a telecommunications cable of the fixed-access telecommunications network.

An electronic device may include wireless circuitry with a baseband processor, a transceiver, a front-end module, and an antenna. The transceiver may include mixer circuitry. The mixer circuitry may include switches controlled by oscillator signals. The mixer circuitry may also include oscillator phase noise cancelling capacitors controlled by inverted oscillator signals. Operated in this way, the mixer circuitry exhibits improved noise figure performance.

An electronic apparatus comprising an electronic board on which are placed an electronic subassembly and a filtering unit, the analog subassembly comprising one or more radiofrequency analog components for receiving radiofrequency components is proposed. The analog subassembly is protected by shielding placed on one side of the electronic board, the filtering unit is placed on the side of the electronic board on a signal path electrically connected to the analog subassembly, the filtering unit comprises a capacitive component placed under the shielding and connected to an analog ground, and the filtering unit further comprises a filtering component placed on the input to the filtering unit in series with the signal path on passing through the shielding or in the immediate vicinity of the shielding.