Bionic hearing headset

What is claimed is: 1. A headset comprising: a pair of headphones including a left headphone having a left speaker and a right headphone having a right speaker; a pair of microphone arrays including a left microphone array integrated with the left headphone and a right microphone array integrated with the right headphone, each of the pair of microphone arrays including at least a front-located microphone and a rear-located microphone for receiving external audio from an external source; and a digital signal processor configured to receive left and right microphone array signals associated with the external audio, each microphone array signal including a front microphone signal vector generated by the front-located microphone and a rear microphone signal vector generated by the rear-located microphone, the digital signal processor being further configured to: generate a pair of front and rear directional signals from each of the left and right microphone array signals; suppress diffuse sounds from the pairs of directional signals; apply parametric models of head-related transfer function (HRTF) pairs to each pair of directional signals to obtain a left front direct HRTF output signal, a left front indirect HRTF output signal, a left rear direct HRTF output signal, a left rear indirect HRTF output signal, a right front direct HRTF output signal, a right front indirect HRTF output signal, a right rear direct HRTF output signal, and a right rear indirect HRTF output signal; add the left front direct HRTF output signal, the left rear direct HRTF output signal, the right front indirect HRTF output signal and the right rear indirect HRTF output signal to generate a left headphone output signal; and add the right front direct HRTF output signal, the right rear direct HRTF output signal, the left front indirect HRTF output signal and the left rear indirect HRTF output signal to generate a right headphone output signal. 2. The headset of claim 1 , wherein the pair of headphones are further configured to playback audio content from an electronic audio source. 3. The headset of claim 1 , wherein each pair of directional signals includes front and rear pointing beam signals. 4. The headset of claim 1 , wherein the left microphone array signals include at least a left front microphone signal vector and a left rear microphone signal vector. 5. The headset of claim 4 , wherein the digital signal processor configured to generate the pair of directional signals from the left microphone array signals includes the digital signal processor being configured to: compute a left cardioid signal pair from the left front and rear microphone signal vectors; compute real-valued time-dependent and frequency-dependent masks based on the left cardioid signal pair and the left microphone array signals; and multiply the time-dependent and frequency-dependent masks by the respective left front and rear microphone signal vectors to obtain left front and rear pointing beam signals. 6. The headset of claim 1 , wherein the right microphone array signals include at least a right front microphone signal vector and a right rear microphone signal vector. 7. The headset of claim 6 , wherein the digital signal processor configured to generate the pair of directional signals from the right microphone array signals includes the digital signal processor being configured to: compute a right cardioid signal pair from the right front and rear microphone signal vectors; compute real-valued time-dependent and frequency-dependent masks based on the right cardioid signal pair and the right microphone array signals; and multiply the time-dependent and frequency-dependent masks by the respective right front and rear microphone signal vectors to obtain right front and rear pointing beam signals. 8. The headset of claim 1 , wherein the digital signal processor configured to suppress diffuse sounds from the pairs of directional signals includes the digital signal processor being configured to: apply noise reduction to the pairs of directional signals using a common mask to suppress uncorrelated signal components. 9. A method for enhancing directional sound from an audio source external to a headset, the headset including a left headphone having a left microphone array and a right headphone having a right microphone array, each of the left and right microphone arrays including at least a front-located microphone and a rear-located microphone, the method comprising: receiving a pair of microphone array signals corresponding to the external audio source, the pair of microphone array signals including a left microphone array signal and a right microphone array signal, each microphone array signal including a front microphone signal vector generated by the front-located microphone and a rear microphone signal vector generated by the rear-located microphone; generating a pair of directional signals from each of the pair of microphone array signals; suppressing diffuse signal components from the pairs of directional signals; applying parametric models of head-related transfer function (HRTF) pairs to each pair of directional signals to obtain a left front direct HRTF output signal, a left front indirect HRTF output signal, a left rear direct HRTF output signal, a left rear indirect HRTF output signal, a right front direct HRTF output signal, a right front indirect HRTF output signal, a right rear direct HRTF output signal, and a right rear indirect HRTF output signal; adding the right front direct HRTF output signal, the right rear direct HRTF output signal, the left front indirect HRTF output signal and the left rear indirect HRTF output signal to generate a left headphone output signal; and adding the right front direct HRTF output signal, the right rear direct HRTF output signal, the left front indirect HRTF output signal and the left rear indirect HRTF output signal to generate a right headphone output signal. 10. The method of claim 9 , wherein the left microphone array signals include at least a left front microphone signal vector and a left rear microphone signal vector. 11. The method of claim 10 , wherein generating the pair of directional signals from the left microphone array signals comprises: computing a left cardioid signal pair from the left front and rear microphone signal vectors; computing real-valued time-dependent and frequency-dependent masks based on the left cardioid signal pair and the left microphone array signals; and multiplying the time-dependent and frequency-dependent masks by the respective left front and rear microphone signal vectors to obtain left front and rear pointing beam signals. 12. The method of claim 9 , wherein the right microphone array signals include at least a right front microphone signal vector and a right rear microphone signal vector. 13. The method of claim 12 , wherein generating the pair of directional signals from the right microphone array signals comprises: computing a right cardioid signal pair from the right front and rear microphone signal vectors; computing real-valued time-dependent and frequency-dependent masks based on the right cardioid signal pair and the right microphone array signals; and multiplying the time-dependent and frequency-dependent masks by the respective right front and rear microphone signal vectors to obtain right front and rear pointing beam signals. 14. The method of claim 9 , wherein suppressing diffuse signal components from the pairs of directional signals comprises: applying noise reduction to the pairs of directional signals using a common mask to suppress uncorrelated signal componen