Surface acoustic wave filters with extracted poles

It is claimed: 1. A bandpass filter, comprising: a plurality of series acoustic resonators connected in series between an input and an output; and a plurality of shunt acoustic resonators including a first shunt acoustic resonator, each shunt acoustic resonator connected between a ground and one of the input, the output, and a junction between two of the plurality of series acoustic resonators, wherein the first shunt acoustic resonator has a motional resonance frequency higher than an upper edge of a passband of the bandpass filter and lower than respective anti-resonance frequencies of all of the plurality of series acoustic resonators, and the first shunt acoustic resonator is not in parallel with any other shunt acoustic resonator. 2. The bandpass filter of claim 1 , wherein the first shunt acoustic resonator is connected between the ground and one of the input and the output. 3. The bandpass filter of claim 1 , wherein: a second shunt acoustic resonator from the plurality of shunt acoustic resonators has a motional resonance frequency greater than or equal to the motional resonance frequency of the first shunt acoustic resonator. 4. The bandpass filter of claim 3 , wherein the first shunt acoustic resonator is connected between the ground and one of the input and the output, and the second shunt acoustic resonator is connected between the ground and the other of the input and the output. 5. The bandpass filter of claim 3 , wherein the motional resonance frequency of the second shunt acoustic resonator is less than respective anti-resonance frequencies of all of the plurality of series acoustic resonators. 6. A method to design a bandpass filter including a plurality of series acoustic resonators connected in series between an input and an output and a plurality of shunt acoustic resonators, each shunt acoustic resonator connected between a ground and one of the input, the output, and a junction between two of the plurality of series acoustic resonators, the method comprising: designing a conventional ladder filter in which motional resonance frequencies of all of the plurality of shunt acoustic resonators are less than a lower edge of a passband of the bandpass filter and anti-resonance frequencies of all of the plurality of series acoustic resonators are greater than an upper edge of the pass band; identifying one of the plurality of shunt acoustic resonators as a first shunt resonator; and repurposing the first shunt resonator by setting its motional resonance frequency to a frequency higher than and adjacent to the upper edge of the passband, whereby a transmission zero generated by the first shunt resonator is moved from a frequency below the passband to a frequency above and adjacent to the upper edge of the passband. 7. The method of claim 6 , wherein the first shunt resonator is connected between the ground and one of the input and the output. 8. The method of claim 6 , wherein the motional resonance frequency of the first shunt resonator is set to a frequency less than respective anti-resonance frequencies of all of the plurality of series acoustic resonators. 9. The method of claim 6 , further comprising: setting a motional resonance frequency of a second shunt resonator from the plurality of shunt acoustic resonators to a frequency equal to or greater than the motional resonance frequency of the first shunt resonator. 10. The method of claim 9 , wherein the first shunt resonator is connected between the ground and one of the input and the output, and the second shunt resonator is connected between the ground and the other of the input and the output. 11. The method of claim 9 , wherein the motional resonance frequency of the second shunt resonator is less than respective anti-resonance frequencies of all of the plurality of series acoustic resonators.