I rewired a standard one gang electrical outlet receptacle with an 110/120 volt three position toggle switch (ON, OFF, ON). The rewiring allowed for the top outlet to be hot when the toggle was up (ON) and the bottom outlet would be OFF. Conversely, the bottom outlet would be hot when the toggle was down (ON) and the top outlet would be OFF. When the toggle switch was flipped to the middle position (OFF), both outlets would be off. Plugged a 3.5 mm plug from a set of amplified external speakers into my headphone port on the side of my television. The external speakers were plugged into the top outlet on my rewired receptacle. The bottom outlet on my rewired receptacle provided power to my BOOM BOX. Flipping my three position toggle switch up turned on my television audio while flipping the toggle switch down would Silence my television audio and turn on my BOOM BOX radio.My rewired receptacle is the origin of the Television Commercial Silencer Electrical Wall Outlet Receptacle Tap.

An ultrasonic transducer and a method for a transmitting an acoustic wave using an ultrasonic transducer comprising a membrane; two or more patterned top electrodes; a pMUT array, wherein the patterned top electrode is arranged as row pin selector and column selector in an N?N array; the pMUT array having N+N electrical contacts; a single unpatterned bottom electrode; a row and column where the electrode is at equal or opposite polarities; and a AC driving voltage is applied to top electrodes with a phase difference of zero or is applied to one electrode to transmit the ultrasonic wave.

The present disclosure provides systems and methods associated with acoustic transmitters, receivers, and antennas. Specifically, the present disclosure provides a transducer system for transmitting and receiving acoustic energy according to a determined acoustic emission/reception pattern. In various embodiments, an acoustic transducer system may include an array of sub-wavelength transducer elements each configured with an electromagnetic resonance at one of a plurality of electromagnetic frequencies. Each sub-wavelength transducer element may generate an acoustic emission in response to the electromagnetic resonance. A beam-forming controller may cause electromagnetic energy to be transmitted at select electromagnetic frequencies to cause a select subset of the sub-wavelength transducer elements to generate acoustic emissions according to a selectable acoustic transmission pattern. A common port may facilitate electromagnetic communication with each of the sub-wavelength transducer elements.

An ultrasound probe and an ultrasound imaging system include a 2D transducer array including a plurality of transducer elements organized to form a transmit aperture and a receive aperture, where the transmit aperture and the receive aperture do not overlap with each other. The probe and system include a plurality of distribution nodes and a plurality of sets of transmit switches. Each set of transmit switches includes a plurality of transmit switches and each set of transmit switches is associated with a different one of the plurality of transducer elements in the transmit aperture. Each set of transmit switches is configured to selectively connect the associated transducer element to any one of the plurality of distribution nodes when in a continuous-wave Doppler mode.

Methods and systems are provided that perform baseband beamforming of ultrasound signals. The methods and systems obtain receive signals from transducers of an ultrasound probe and demodulate the receive signals to obtain complex receive signals having in-phase (I) and quadrature (Q) components. The methods and systems apply time delay and phase correction to the complex receive signals to form delayed complex receive signals before summing the delayed complex receive signals to produce a coherent receive signal. The phase correction includes applying coarse and fine corrections where the coarse correction is calculated as a multiple of a sampling time and the fine correction is calculated as a fraction of the sampling time. The methods and systems apply the coarse and fine corrections contemporaneously by multiplying the complex receive signal by a complex carrier delayed by a multiple of the sampling time and delayed by the fraction of the sampling time.

An ultrasound probe and an ultrasound imaging system include a 2D transducer array including a plurality of transducer elements organized to form a transmit aperture and a receive aperture, where the transmit aperture and the receive aperture do not overlap with each other. The probe and system include a plurality of distribution nodes and a plurality of sets of transmit switches. Each set of transmit switches includes a plurality of transmit switches and each set of transmit switches is associated with a different one of the plurality of transducer elements in the transmit aperture. Each set of transmit switches is configured to selectively connect the associated transducer element to any one of the plurality of distribution nodes when in a continuous-wave Doppler mode.

An ultrasound probe and an ultrasound imaging system include a plurality of transducer elements arranged in an array. The plurality of transducer elements are organized to form a transmit aperture and a receive aperture. The ultrasound probe and ultrasound imaging system include a plurality of summing nodes. The ultrasound probe and ultrasound imaging system include a set of receive switches associated with each of the transducer elements in the receive aperture. Each set of receive switches is configured to selectively connect the associated transducer element to any one of the plurality of summing nodes.