Miniature high performance mems piezoelectric transducer

What is claimed is: 1 . A dipole speaker assembly comprising: a first transducer section including a frame and a first piezoelectric actuator coupled to the frame; a second transducer section including a second frame and a second piezoelectric actuator coupled to the second frame; a front volume section positioned between the first transducer section and the second transducer section to form a front cavity from which a generated acoustic pressure wave exits the front volume section towards an ear canal of a user; and a first rear volume section coupled to the first transducer section and a second rear volume section coupled to the second transducer section, from which the generated acoustic pressure wave exits the rear volume sections away from the ear canal of the user. 2 . The dipole speaker assembly of claim 1 , further comprising: a third transducer section coupled to the first rear volume section; a second front volume section coupled to the third transducer section; and a fourth transducer section coupled to the second front volume section. 3 . The dipole speaker assembly of claim 1 , wherein the acoustic pressure wave exiting the rear volume sections is configured to cancel the acoustic pressure wave exiting the front volume section in a far field. 4 . The dipole speaker assembly of claim 1 , wherein each of the piezoelectric actuators includes a first end and a second end opposite the first end, the first end being attached to the frame, wherein a length of the piezoelectric actuators corresponds to a distance between the first end and the second end, a width of the piezoelectric actuators corresponds to a distance across the second end in a dimension in-line with the ear canal, the width being larger than the length. 5 . The dipole speaker assembly of claim 1 , wherein the first transducer section includes a first pair of piezoelectric actuators and a second pair of the piezoelectric actuators. 6 . The dipole speaker assembly of claim 1 , wherein each of the piezoelectric actuators comprise a fixed end and a free end opposite the fixed end. 7 . The dipole speaker assembly of claim 1 , wherein each of the piezoelectric actuators comprises a first fixed end and a second fixed end opposite the first fixed end. 8 . The dipole speaker assembly of claim 1 , wherein the first piezoelectric actuators is a bimorph comprising a first piezoelectric layer and a second piezoelectric layer, the first piezoelectric layer configured to expand and the second piezoelectric layer configured to contract responsive to a voltage being applied to the bimorph. 9 . A headset comprising: a front portion comprising a display element; a temple section coupled to the front portion; and a speaker package located within the temple section, wherein the speaker package comprises: a first transducer section including a frame and a first piezoelectric actuator coupled to the frame; a second transducer section including a second frame and a second piezoelectric actuator coupled to the second frame; a front volume section positioned between the first transducer section and the second transducer section to form a front cavity from which a generated acoustic pressure wave exits the front volume section towards an ear canal of a user; and a first rear volume section coupled to the first transducer section and a second rear volume section coupled to the second transducer section, from which the generated acoustic pressure wave exits the rear volume sections away from the ear canal of the user. 10 . The headset of claim 9 , wherein the speaker package further comprises: a third transducer section coupled to the first rear volume section; a second front volume section coupled to the third transducer section; and a fourth transducer section coupled to the second front volume section. 11 . The headset of claim 9 , wherein the acoustic pressure wave exiting the rear volume sections is configured to cancel the acoustic pressure wave exiting the front volume section in a far field. 12 . The headset of claim 9 , wherein each of the piezoelectric actuators includes a first end and a second end opposite the first end, the first end being attached to the frame, wherein a length of the piezoelectric actuators corresponds to a distance between the first end and the second end, a width of the piezoelectric actuators corresponds to a distance across the second end in a dimension in-line with the ear canal, the width being larger than the length. 13 . The headset of claim 9 , wherein the first transducer section includes a first pair of piezoelectric actuators and a second pair of the piezoelectric actuators. 14 . The headset of claim 9 , wherein each of the piezoelectric actuators comprise a fixed end and a free end opposite the fixed end. 15 . The headset of claim 9 , wherein each of the piezoelectric actuators comprises a first fixed end and a second fixed end opposite the first fixed end. 16 . The headset of claim 9 , wherein the first piezoelectric actuator is a bimorph comprising a first piezoelectric layer and a second piezoelectric layer, the first piezoelectric layer configured to expand and the second piezoelectric layer configured to contract responsive to a voltage being applied to the bimorph. 17 . The headset of claim 9 , wherein the first piezoelectric actuator is a unimorph comprising a first piezoelectric layer and a passive structure layer. 18 . The headset of claim 9 , wherein the headset is configured to beamsteer audio content to an ear of a user using a plurality of speaker packages located within the temple section. 19 . The headset of claim 9 , wherein the speaker package forms a portion of a surface of the temple section. 20 . The headset of claim 9 , wherein the first piezoelectric actuator is offset from the second piezoelectric actuator.