Turning now descriptively to the drawings, in which similar reference characters denote similar elements throughout the several views, FIG. 1 is a system diagram of a spatial audio processing system 100 according to certain embodiments of the present disclosure. According to an embodiment, spatial audio processing system 100 generally comprises transducer array 102 and processing module 128; and may further optionally comprise audio output device 120, computing device 122, camera 124, and motion sensor 126. Transducer array 102 may comprise an array of transducers (e.g., microphones) being installed in an acoustic space (e.g., a conference room). In accordance with certain embodiments, transducer array 102 may comprise transducer 102a, transducer 102b, transducer 102c, and transducer 102d. Transducers 102a-d may comprise micro-electro-mechanical system (MEMS) microphones, electret microphones, contact microphones, accelerometers, hearing aid microphones, hearing aid receivers, loudspeakers, horns, vibrators, ultrasonic transmitters, and the like. Transducer array 102 may comprise as few as one transducer and up to an Nth number of transducers (e.g., 64, 128, etc.). Transducer 102a, transducer 102b, transducer 102c, and transducer 102d may be communicably engaged with processing module 128 via a wireless or wireline communications interface 130; and transducer 102a, transducer 102b, transducer 102c, and transducer 102d may be communicably engaged with each other in a networked configuration via a wireless or wireline communications interface 132. Wireless or wireline communications interface 130 may comprise one or more audio channels. Transducer array 102 may be configured to receive sound 30 emanating from a point source 42 within the acoustic space. Point source 42 may be a spherical point in space within the acoustic space; for example, a spherical point in space having a 20 cm radii. An acoustic wave front of sound 30 may be received by transducer array 102 via direct propagation 32 or indirect propagation 34 according to the sound propagation characteristics of the acoustic space. Transducer array 102 converts the acoustic energy of the arriving acoustic wavefront of sound 30 into an audio input 44, which is communicated to processing module 128 via communications interface 130. Each of transducers 102a-d may comprise a separate input channel to comprise audio input 44. In certain embodiments, transducers 102a-d may be located at physically spaced apart locations within the acoustic space and operably interfaced to comprise a spatially distributed array. In certain embodiments, transducers 102a-d may be configured as independent transducers or may alternatively be embodied as an internal microphone to an electronic device, such as a laptop or smartphone. Transducers 102a-d may comprise two or more individually spaced transducers and/or one or more distinct clusters of transducers 102a-d comprising one or more sub-arrays. The one or more sub-arrays may be located at physically spaced apart locations within the acoustic space and operably interfaced to comprise transducer array 102.