Direction finding system using MEMS sound sensors

What is claimed is: 1. A Direction Finding Acoustic Sensor comprising: a first sound sensor and a second sound sensor, where the first sound sensor and the second sound sensor individually comprise: a sensor body, the sensor body comprising: a left wing; a right wing, where a first sensor axis intersects the left wing and the right wing, and where a second sensor axis is perpendicular to the first sensor axis; and a bridge coupling the left wing with the right wing; a support structure connected to the sensor body, where the support structure is hollow beneath the sensor body, allowing the sensor body to vibrate upon sound excitation; and an amplitude detection device adapted to detect a displacement of the left wing, the right wing, or both the left wing and the right wing; a platform structure coupled to the first sound sensor and coupled to the second sound sensor, and the platform structure maintaining the first sound sensor and the second sound sensor in an orientation where a θ 1 is a subtended angle between an axis of symmetry and the second sensor axis of the first sound sensor and θ 2 is a subtended angle between the axis of symmetry and the second sensor axis of the second sound sensor and where −5°≦(θ 1 −θ 2 )≦5°; and a digital device in data communication with the amplitude detection device of the first sound sensor and in data communication with the amplitude detection device of the second sound sensor, and the digital device programmed to perform steps comprising: receiving a P L from the amplitude detection device of the first sound sensor, where the P L is proportional to a detected displacement of the left wing of the first sound sensor, the right wing of the first sound sensor, or both the left wing of the first sound sensor and the right wing of the first sound sensor relative to the support structure of the first sound sensor; receiving a P R from the amplitude detection device of the second sound sensor, where the P R is proportional to a detected displacement of the left wing of the second sound sensor, the right wing of the second sound sensor, or both the left wing of the second sound sensor and the right wing of the first second sensor relative to the support structure of the second sound sensor; evaluating a value of a fraction, where a numerator of the fraction comprises a difference between an α 1 multiplied by the P L and an α 2 multiplied by the P R , and where a denominator of the fraction comprises a sum of the α 1 multiplied by the P L and the α 2 multiplied by the P R , where α 1 and α 2 are non-zero real numbers; and assigning an angle θ S based on the value of the fraction. 2. The Direction Finding Acoustic Sensor of claim 1 where the digital device is further programmed to determine a direction, where the direction is based on the angle θ S . 3. The Direction Finding Acoustic Sensor of claim 2 where the axis of symmetry is parallel to a z axis and an x axis is perpendicular to the z axis, and an angle θ off is a subtended angle between the first sensor axis of the first sound sensor and the x axis, and where the digital device is programmed determine the direction such that an angle between the direction and the axis of symmetry is equal to or less than ±(90°−θ off ). 4. The Direction Finding Acoustic Sensor of claim 1 where the numerator comprises (α 1 P L −α 2 P R ) and the denominator comprises (α 1 P L +α 2 P R ). 5. The Direction Finding Acoustic Sensor of claim 4 where 0.9≦α 1 /α 2 ≦1.1. 6. The Direction Finding Acoustic Sensor of claim 1 where the axis of symmetry is parallel to a z axis and an x axis is perpendicular to the z axis, and where the first sensor axis of the first sound sensor, the first sensor axis of the second sound sensor, and the axis of symmetry are co-planer with an x-z plane comprising the x axis and the z axis. 7. The Direction Finding Acoustic Sensor of claim 6 where an angle θ off-1 is another subtended angle between the first sensor axis of the first sound sensor and the x axis, and an angle θ off-2 is an additional subtended angle between the first sensor axis of the second sound sensor and the x axis, and where −5°≦(θ off-1 −θ off-2 )≦5°. 8. The Direction Finding Acoustic Sensor of claim 7 where the second sensor axis of the first sound sensor, the second sensor axis of the second sound sensor, and the axis of symmetry are co-planer with the x-z plane comprising the x axis and the z axis. 9. The Direction Finding Acoustic Sensor of claim 1 where the amplitude detection device of the first sound sensor comprises a first plurality of comb finger capacitors coupled to the left wing of the first sound sensor or the right wing of the first sound sensor and a second plurality of comb finger capacitors coupled to the support of the first sound sensor, where the first plurality of comb finger capacitors moveably interdigitate with the second plurality of comb finger capacitors. 10. A Direction Finding Acoustic Sensor comprising: a first sound sensor and a second sound sensor, where the first sound sensor and the second sound sensor individually comprise: a sensor body, the sensor body comprising: a left wing; a right wing, where a first sensor axis intersects the left wing and the right wing, and where a second sensor axis is perpendicular to the first sensor axis; and a bridge coupling the left wing with the right wing; a support structure connected to the sensor body, where the support structure is hollow beneath the sensor body, allowing the sensor body to vibrate upon sound excitation; and an amplitude detection device adapted to detect a displacement of the left wing, the right wing, or both the left wing and the right wing; a platform structure coupled to the first sound sensor and coupled to the second sound sensor, and the platform structure maintaining the first sound sensor and the second sound sensor in an orientation where θ 1 is a subtended angle between an axis of symmetry and the second sensor axis of the first sound sensor and θ 2 is a subtended between the axis of symmetry and the second sensor axis of second sound sensor and where −5°≦(θ 1 −θ 2 )≦5°, and where the axis of symmetry is parallel to a z axis and an x axis is perpendicular to the z axis, and where the first sensor axis of the first sound sensor, the first sensor axis of the second sound sensor, and the axis of symmetry are co-planer with an x-z plane comprising the x axis and the z axis, and where an angle θ off is a subtended angle between the first sensor axis of the first sound sensor and the x axis; and a digital device in data communication with the amplitude detection device of the first sound sensor and in data communication with the amplitude detection device of the second sound sensor, and the digital device programmed to perform steps comprising: receiving a P L from the amplitude detection device of the first sound sensor, where the P L is proportional to a detected displacement of the left wing of the first sound sensor, the right wing of the first sound sensor, or both the left wing of the first sound sensor and the right wing of the first sound sensor relative to the support structure of the first sound sensor; receiving a P R from the amplitude detection device of the second sound sensor, where the P R is proportional to a detected displacement of the left wing of the second sound sensor, the right wing of the second sound sensor, or both the left wing of the second sound sensor and the right wing of the second sound sensor relative to the support structure of the second sound sensor; evaluating a value of a fraction, where a numerator of the fraction comprises a difference between an α 1 multiplied by the P