Wind noise reduction by microphone placement

What is claimed is: 1. An image capture device, comprising: a housing having a top housing surface and a front housing surface; a lens snout protruding from the front housing surface; a front microphone mounted within or on the front housing surface and below the lens snout; a top microphone mounted within or on a top housing surface in a position biased toward the front housing surface; a third microphone comprising a channel with a channel volume depth that is not uniform and varies from an upper channel volume depth to a lower channel volume depth; and an audio processor comprising a memory that is configured to store instructions that when executed cause the audio processor to generate an output audio signal, wherein the top microphone is located at a position to receive direct freestream air flow when the housing is positioned in a pitched forward orientation at a pitched forward angle relative to a vertical axis, and wherein the front microphone receives turbulent air flow from the lens snout when the housing is positioned in the pitched forward orientation. 2. The image capture device of claim 1 , wherein the top microphone is located within the housing under the top housing surface. 3. The image capture device of claim 1 , wherein the audio processor is configured to execute the instructions stored in the memory to: receive a first audio signal from the front microphone; for frequency sub-bands, generate first frequency sub-band signals from the first audio signal; receive a second audio signal from the top microphone; for the frequency sub-bands, generate second frequency sub-band signals from the second audio signal; for the respective frequency sub-bands, select one of the first frequency sub-band signals or the second frequency sub-band signals having the lowest noise metric; and combine the selected sub-band signals to generate the output audio signal. 4. The image capture device of claim 1 , further comprising a drainage microphone, wherein the drainage microphone includes a channel entrance surface area to channel volume ratio that moves audio wave resonance outside of a 500 Hz to 9 kHz frequency range. 5. The image capture device of claim 2 , wherein the memory stores instructions that when executed cause the audio processor to: perform beamforming on the first frequency sub-band signals and the second frequency sub-band signals to output a stereo audio stream. 6. The image capture device of claim 1 , wherein the lens snout is of a sufficient length such that the lens snout, when in the pitched forward angle relative to the vertical axis, disrupts a direction of the freestream air flow creating turbulent air flow. 7. An image capture device, comprising: a housing having a first housing surface and a second housing surface orthogonal to the first housing surface; a protruding feature protruding from the first housing surface; a first microphone mounted within or on the first housing surface and adjacent to the protruding feature; a second microphone mounted within or on the second housing surface; a third microphone comprising a channel with a channel volume depth that is not uniform and varies from an upper channel volume depth to a lower channel volume depth; and an audio processor comprising a memory configured to store instructions that when executed cause the audio processor to: generate an output audio signal, wherein the first microphone receives direct freestream air flow when the housing is positioned in a pitched orientation with a first pitched angle; wherein the first microphone does not receive direct freestream air flow while the housing is positioned in a vertical orientation with a second pitched angle, wherein the first pitched angle is greater than the second pitched angle relative to a vertical axis; and wherein turbulent air flow from the protruding feature contacts the second microphone when the housing is positioned in the pitched orientation. 8. The image capture device of claim 7 , wherein the first pitched angle orients the housing in a pitched forward manner so that the housing is rotated away from the vertical orientation. 9. The image capture device of claim 7 , wherein the second microphone is positioned below the protruding feature. 10. The image capture device of claim 7 , wherein the first microphone is biased within the housing under the first housing surface towards the second housing surface. 11. The image capture device of claim 7 , wherein the memory stores instructions that when executed cause the audio processor to: receive a third audio signal from the third microphone; for the frequency sub-bands, generate third frequency sub-band signals from the third audio signal; for the respective frequency sub-bands, select one of the first frequency sub-band signals, the second frequency sub-band signals, or the third frequency sub-band signals having the lowest noise metric; and combine the selected sub-band signals to generate the output audio signal. 12. The image capture device of claim 7 , wherein the memory stores instructions that when executed cause the audio processor to perform beamforming on the first frequency sub-band signals and a third frequency sub-band signals to output a stereo audio stream. 13. The image capture device of claim 7 , wherein the lens snout extends outward into the direct freestream air flow such that the lens snout, when the housing is in the pitched orientation, disrupts a direction of the freestream air flow creating turbulent air flow. 14. A method comprising: receiving, by an audio processor, a first audio signal from a first microphone mounted above a protruding feature extending from a first housing surface of a housing of an image capture device, the first microphone mounted to receive direct freestream air flow when the housing is positioned in a pitched forward orientation at a pitched forward angle relative to vertical; receiving, by the audio processor, a second audio signal from a second microphone mounted below the protruding feature, wherein the second microphone receives turbulent air flow when the housing is positioned in the pitched forward orientation; generating, by the audio processor, first frequency sub-band signals from the first audio signal; generating, by the audio processor, second frequency sub-band signals from the second audio signal; selecting, by the audio processor, one of the first frequency sub-band signals or the second frequency sub-band signals having a lowest noise metric as selected sub-band signals; and combining, by the audio processor, the selected sub-band signals to generate an output audio signal; wherein the housing further comprises: a third microphone comprising a channel with a channel volume depth that is not uniform and varies from an upper channel volume depth to a lower channel volume depth. 15. The method of claim 14 , wherein the first microphone and the second microphone are positioned on separate orthogonal surfaces of the housing. 16. The method of claim 14 , wherein the second microphone is positioned on the same surface of the housing as the protruding feature. 17. The method of claim 14 , wherein the audio processor comprises memory and the method further comprises a step of storing instructions in the memory that when executed cause the audio processor to: perform beamforming on the first frequency sub-band signals and the second frequency sub-band signals to output a stereo audio stream. 18. The method of claim 14 , wherein the lowest noise metric is a lowest