The band-pass filter has a stacked pair of film bulk acoustic resonators (FBARs) and an acoustic decoupler between the FBARs. Each of the FBARs has opposed planar electrodes and a layer of piezoelectric material between the electrodes. The acoustic decoupler has a single layer of acoustic decouplin
The band-pass filter has a stacked pair of film bulk acoustic resonators (FBARs) and an acoustic decoupler between the FBARs. Each of the FBARs has opposed planar electrodes and a layer of piezoelectric material between the electrodes. The acoustic decoupler has a single layer of acoustic decoupling material having a nominal thickness equal to an odd integral multiple of one quarter of the wavelength in the acoustic decoupling material of an acoustic wave having a frequency equal to the center frequency. The acoustic decoupling material comprises plastic. The acoustic decoupler controls the coupling of acoustic energy between the FBARs. Specifically, the acoustic decoupler couples less acoustic energy between the FBARs than would be coupled by direct contact between the FBARs. The reduced acoustic coupling gives the band-pass filter desirable in-band and out-of-band properties.
대표청구항▼
I claim: 1. A band-pass filter characterized by a center frequency, the band-pass filter comprising: a stacked pair of film bulk acoustic resonators (FBARs), each of the FBARs comprising opposed planar electrodes and a layer of piezoelectric material between the electrodes; and an acoustic decouple
I claim: 1. A band-pass filter characterized by a center frequency, the band-pass filter comprising: a stacked pair of film bulk acoustic resonators (FBARs), each of the FBARs comprising opposed planar electrodes and a layer of piezoelectric material between the electrodes; and an acoustic decoupler between the FBARs, the acoustic decoupler comprising a single layer of acoustic decoupling material having a nominal thickness equal to an odd integral multiple of one quarter of the wavelength in the acoustic decoupling material of an acoustic wave having a frequency equal to the center frequency, the acoustic decoupling material comprising plastic. 2. The band-pass filter of claim 1, in which the acoustic decoupler is structured to provide substantially critical coupling of acoustic energy between the FBARs. 3. The band-pass filter of claim 1, in which: the layer of acoustic decoupling material has a nominal thickness equal to one quarter of the wavelength in the acoustic decoupling material of an acoustic wave having a frequency equal to the center frequency. 4. The band-pass filter of claim 1, in which: the piezoelectric material has an acoustic impedance; and the acoustic decoupling material has an acoustic impedance less than the acoustic impedance of the piezoelectric material. 5. The band-pass filter of claim 1, in which: the piezoelectric material has an acoustic impedance; and the acoustic decoupling material has an acoustic impedance intermediate between the acoustic impedance of the piezoelectric material and the acoustic impedance of air. 6. The band-pass filter of claim 1, in which the acoustic decoupling material has an acoustic impedance in the range from about 2 Mrayl to about 16 Mrayl. 7. The band-pass filter of claim 1, in which the acoustic decoupling material comprises poly(para-xylylene). 8. The band-pass filter of claim 1, in which the acoustic decoupling material comprises polyimide. 9. The band-pass filter of claim 1, additionally comprising a ladder filter electrically connected in series with the stacked pair of FBARs. 10. The band-pass filter of claim 9, in which the ladder filter comprises additional FBARs. 11. A band-pass filter characterized by a center frequency, the band-pass filter comprising: a stacked pair of film bulk acoustic resonators (FBARs), each of the FBARs comprising opposed planar electrodes and a layer of piezoelectric material between the electrodes; an acoustic decoupler between the FBARs, the acoustic decoupler comprising a single layer of acoustic decoupling material having a nominal thickness equal to an odd integral multiple of one quarter of the wavelength in the acoustic decoupling material of an acoustic wave having a frequency equal to the center frequency; and an electrical connection between adjacent ones of the electrodes of the FBARs. 12. The band-pass filter of claim 11, in which the acoustic decoupling material comprises plastic. 13. The band-pass filter of claim 11, in which the acoustic decoupling material comprises poly(para-xylylene). 14. The band-pass filter of claim 11, in which the acoustic decoupling material comprises polyimide. 15. The band-pass filter of claim 11, in which the acoustic decoupler is located between the adjacent ones of the electrodes. 16. A band-pass filter, comprising: a stacked pair of film bulk acoustic resonators (FBARs), each of the FBARs comprising opposed planar electrodes and a layer of piezoelectric material between the electrodes; an acoustic decoupler between the FBARs; and a ladder filter comprising additional FBARs, the ladder filter electrically connected in series with the stacked pair of FBARs, in which: the band-pass filter additionally comprises an electrical connection between adjacent ones of the electrodes of the stacked pair of FBARs and the ladder filter; and the remaining ones of the electrodes of the stacked pair of FBARs provide the output terminals of the band-pass filter. 17. A band-pass filter characterized by a center frequency, the band-pass filter comprising: a stacked pair of film bulk acoustic resonators (FBARs), each of the FBARs comprising opposed planar electrodes and a layer of piezoelectric material between the electrodes, the piezoelectric material having an acoustic impedance; and between the FBARs, a single layer of acoustic decoupling material having a nominal thickness equal to an odd integral multiple of one quarter of the wavelength in the acoustic decoupling material of an acoustic wave having a frequency equal to the center frequency, the acoustic decoupling material comprising plastic having an acoustic impedance less than the acoustic impedance of the piezoelectric material. 18. The band-pass filter of claim 17, in which the acoustic decoupling material comprises one of polyimide and poly(para-xylylene). 19. An electrical filtering method, comprising: providing a pair of film bulk acoustic resonators (FBARs); applying an input electrical signal to one of the FBARs; coupling, by no more than one layer of acoustic decoupling material located between the FBARs, less acoustic energy between the FBARs than would be coupled by direct contact between the FBARs, the acoustic decoupling material comprising plastic; and outputting a filtered output electrical signal from the other of the FBARs. 20. An electrical filtering method, comprising: providing a pair of film bulk acoustic resonators (FBARs); applying an input electrical signal to one of the FBARs; coupling less acoustic energy between the FBARs than would be coupled by direct contact between the FBARs, the coupling establishes a first pass bandwidth; prior to the applying, filtering the input electrical signal with a second pass bandwidth narrower than the first pass bandwidth; and outputting a filtered output electrical signal from the other of the FBARs.
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