Low frequency acoustic absorption and soft boundary effect with frequency-discretized active panels

What is claimed is: 1. An active sound barrier comprising: a barrier comprising a defined boundary location; at least one passive sound absorber at or near the boundary location; a microphone or sound receiving transducer providing a receiving transducer output; a frequency division module, the frequency division module comprising a filter circuit filtering a plurality of frequencies providing outputs corresponding to frequency segments of the receiving transducer output at respective ones of the frequencies, the filter circuit filtering a plurality of frequencies comprising n 2 parallel L-C circuits, the parallel L-C circuits configured to decompose an input voltage time series into n 2 predetermined frequency components, wherein n is an integer value, the n 2 pre-determined frequency components providing the outputs from the frequency selective filters to an active driving circuit; the active driving circuit output receiving the outputs at respective ones of the frequencies; and a plurality of speakers or actuators and output transducers, the plurality of speakers or actuators and output transducers receiving driving signals from the active driving circuit to provide active noise reduction at the respective ones of the frequencies, at least a subset of said one or more output transducers at the barrier, adjacent the barrier or close to the barrier, the plurality of speakers or actuators and output transducers cooperating with the passive sound absorber. 2. The active sound barrier of claim 1 , wherein the filter circuit filtering a plurality of frequencies comprising a digital FFT processing circuit configured to decompose the input voltage time series into the n 2 predetermined frequency components, the n 2 predetermined frequency components providing the outputs from the digital FFT processing circuit to the active driving circuit, wherein the active driving circuit drives at least one of the plurality of speakers or actuators and output transducers at multiple frequencies, and wherein the active driving circuit drives at least one of the plurality of speakers or actuators and output transducers at a single discrete one of the n 2 predetermined frequency components. 3. The active sound barrier of claim 1 , wherein the active driving circuit drives at least one of the plurality of speakers or actuators and output transducers at multiple frequencies. 4. The active sound barrier of claim 1 , wherein the active driving circuit drives at least one of the plurality of speakers or actuators and output transducers at a single discrete one of the n 2 predetermined frequency components. 5. The active sound barrier of claim 1 , further comprising: a passive sound-absorbing layer located at or near the defined boundary location; and at least a subset of the plurality of speakers or actuators and output transducers positioned at or near the sound-absorbing layer, wherein at least a subset of the plurality of speakers or actuators and output transducers have resonant frequencies for frequency selection at a lower frequency than a predetermined sound absorption frequency range of the sound-absorbing layer by itself. 6. The active sound barrier of claim 5 , wherein the subset of the plurality of speakers or actuators and output transducers having at least a subset of resonant frequencies up to 800 Hz. 7. The active sound barrier of claim 5 , wherein the subset of the plurality of speakers or actuators and output transducers having at least a subset of resonant frequencies up to 400 Hz. 8. Method of sound attenuation using active sound elements, the method comprising: establishing a defined boundary or barrier location as a barrier; mounting a passive sound absorbing layer at or near the boundary location; receiving a transducer output corresponding to sound occurring within an area adjacent or close to the barrier; using a single or a plurality of frequency-selective filters to provide outputs corresponding to frequency segments of the received transducer output at frequencies of respective ones of the frequency-selective filters, using, as the single or plurality of frequency-selective filters, filter circuits comprising n 2 parallel L-C circuits, the parallel L-C circuits configured to decompose an input voltage time series into n 2 predetermined frequency components, wherein n is an integer value, the n 2 pre-determined frequency components providing the outputs from the frequency-selective filters to an active driving circuit; providing outputs from the frequency-selective filters to the active driving circuit and using the active driving circuit to generate one or more active noise reduction (ANR) driving output signals; and driving one or more output transducers with the ANR driving output signals at the barrier by placing at least a subset of said one or more output transducers at the barrier, adjacent the barrier or close to the barrier, to provide ANR at the frequencies of the frequency-selective filters, the one or more output transducers cooperating with the passive sound absorbing layer. 9. The method of sound attenuation of claim 8 , further comprising: providing at least one passive sound absorber at or close to the barrier. 10. The method of sound attenuation of claim 8 , further comprising: using, as the single or plurality of frequency-selective filters, filter circuits comprising a digital FFT processing circuit configured to decompose the input voltage time series into the n 2 predetermined frequency components, wherein n is an integer value, the n 2 predetermined frequency components providing the outputs from the digital FFT processing circuit to the active driving circuit. 11. The method of claim 8 , further comprising: driving one or more of the output transducers or metamaterial resonators at multiple frequencies. 12. The method of claim 8 , further comprising: driving one or more of the output transducers at a single discrete frequency component. 13. The method of sound attenuation of claim 8 , further comprising: locating the defined boundary or barrier location at or near a sound-absorbing surface, the sound-absorbing surface having one or more optimum sound absorption frequency ranges; and positioning at least a subset of the one or more output transducers at or near the sound-absorbing surface, wherein at least a subset the frequency-selective filters provide have resonant frequencies for frequency selection at a lower frequency than the optimum sound absorption frequency range of the sound-absorbing surface. 14. The method of sound attenuation of claim 8 , further comprising: locating a sound-absorbing surface located at or near the defined boundary location, the sound-absorbing surface comprising metamaterials and having one or more optimum sound absorption frequency ranges; and positioning at least a subset of the plurality of the one or more output transducers at or near the sound-absorbing surface, wherein at least a subset the frequency-selective filters provide have resonant frequencies for frequency selection at a lower frequency than the optimum sound absorption frequency range of the sound-absorbing surface. 15. An active sound barrier comprising: a defined boundary or barrier location as a barrier; passive sound absorbing means at or near the boundary or barrier location; means to receive a transducer output corresponding to sound occurring within an area adjacent or close to the barrier; a single frequency-selective filter or a plurality of frequency-selective filters to provide outputs corresponding to frequency segments of