Ultrasound lens structure cleaner architecture and method

The invention claimed is: 1. A system, comprising: a lens structure; an oscillating wave source; first, second, third and fourth conductors; a ground terminal; a transducer coupled to the lens structure, the transducer including first and second segments of a piezoelectric material, and the piezoelectric material configured to generate a strain responsive to an electrical signal, in which: the first segment is electrically coupled to the first conductor and to the second conductor, the first conductor is configured to apply a first electrical signal to the first segment, and the second conductor is configured to apply a second electrical signal to the first segment; and the second segment is electrically coupled to the third conductor and to the fourth conductor, the third conductor is configured to apply a third electrical signal to the second segment, and the fourth conductor is configured to apply a fourth electrical signal to the second segment; a first crossbar switch having a first control input, the first crossbar switch coupled: between the oscillating wave source and the first conductor; between the oscillating wave source and the second conductor; between the ground terminal and the first conductor; and between the ground terminal and the second conductor; and a second crossbar switch having a second control input, the second crossbar switch coupled: between the oscillating wave source and the third conductor; between the oscillating wave source and the fourth conductor; between the ground terminal and the third conductor; and between the ground terminal and the fourth conductor; in which: the first and second crossbar switches are configured to connect the oscillating wave source to both of the first and second segments at a same time, responsive to the first and second control inputs; or the first and second crossbar switches are configured to connect the oscillating wave source to different ones of the first and second segments at different times, responsive to the first and second control inputs. 2. The system of claim 1 , wherein the first crossbar switch is configured, responsive to the first control input, to either: connect the oscillating wave source to the first conductor while connecting the ground terminal to the second conductor; or connect the oscillating wave source to the second conductor while connecting the ground terminal to the first conductor; or have a high impedance to disconnect the first conductor from the oscillating wave source and from the ground terminal and to disconnect the second conductor from the oscillating wave source and from the ground terminal. 3. The system of claim 2 , further comprising fifth, sixth, seventh and eighth conductors, in which: the transducer includes third and fourth segments of the piezoelectric material; the third segment is electrically coupled to the fifth conductor and to the sixth conductor, the fifth conductor is configured to apply a fifth electrical signal to the third segment, and the sixth conductor is configured to apply a sixth electrical signal to the third segment; the fourth segment is electrically coupled to the seventh conductor and to the eighth conductor, the seventh conductor is configured to apply a seventh electrical signal to the fourth segment, and the eighth conductor is configured to apply an eighth electrical signal to the fourth segment; the system further comprises: a third crossbar switch having a third control input, the third crossbar switch coupled: between the oscillating wave source and the fifth conductor; between the oscillating wave source and the sixth conductor; between the ground terminal and the fifth conductor; and between the ground terminal and the sixth conductor; and a fourth crossbar switch having a fourth control input, the fourth crossbar switch coupled: between the oscillating wave source and the seventh conductor; between the oscillating wave source and the eighth conductor; between the ground terminal and the seventh conductor; and between the ground terminal and the eighth conductor; the lens structure has a center section, the first and second segments form a first pair of segments on first opposite sides of the center section, and the third and fourth segments form a second pair of segments on second opposite sides of the center section; and the crossbar switches are configured, responsive to their respective control inputs, to apply standing wave signals to the first and second pairs, including by: for the first pair of segments, connecting the oscillating wave source to the first and third conductors while connecting the ground terminal to the second and fourth conductors; and for the second pair of segments, connecting the oscillating wave source to the sixth and eighth conductors while connecting the ground terminal to the fifth and seventh conductors. 4. The system of claim 1 , wherein: the first and second crossbar switches are configured to connect the oscillating wave source to both of the first and second segments at the same time. 5. The system of claim 3 , wherein the first, second, third and fourth crossbar switches are configured to connect the oscillating wave source to: a first subset of the segments at a first time; and a second subset of the segments at a second time. 6. The system of claim 1 , wherein: the first and second crossbar switches are configured to connect the oscillating wave source to different ones of the first and second segments at the different times. 7. The system of claim 6 , wherein the first and second crossbar switches are configured to connect the oscillating wave source to achieve different oscillatory responses on the lens structure at the different times. 8. The system of claim 7 , wherein the different oscillatory responses have different mode shapes. 9. The system of claim 8 , wherein the different mode shapes include a mode ( 0 , 1 ) shape and a mode ( 1 , 1 ) shape. 10. The system of claim 8 , wherein the different mode shapes include a mode ( 0 , 1 ) shape, a mode ( 1 , 1 ) shape, and a mode ( 2 , 1 ) shape. 11. The system of claim 1 , wherein the lens structure includes a lens cover. 12. The system of claim 1 , wherein the lens structure includes a camera lens. 13. The system of claim 1 , wherein the lens structure includes a circular lens structure. 14. The system of claim 1 , wherein the first and second segments are along an annulus of the transducer. 15. A camera assembly, comprising: a camera; a lens structure adjacent the camera; an oscillating wave source; first, second, third and fourth conductors; a ground terminal; a transducer coupled to the lens structure, the transducer including first and second segments of a piezoelectric material, and the piezoelectric material configured to generate a strain responsive to an electrical signal, in which: the first segment is electrically coupled to the first conductor and to the second conductor, the first conductor is configured to apply a first electrical signal to the first segment, and the second conductor is configured to apply a second electrical signal to the first segment; and the second segment is electrically coupled to the third conductor and to the fourth conductor, the third conductor is configured to apply a third electrical signal to the second segment, and the fourth conductor is configured to apply a fourth electrical signal to the second segment; a first crossbar switch having a first control input, the first crossbar switch coupled: between the oscillating wave source and the first conductor; between the oscillating wave source an