Stimulation system including a multi-electrode ear shell and method of using the same

What is claimed is: 1. A multi-electrode ear shell comprising: an inner surface, an outer surface, and an ear canal opening as a through-hole surrounded by the multi-electrode ear shell extending from the inner surface to the outer surface, the inner surface corresponding to a surface of an ear and being configured to overlap a cymba and a cavum of the ear, the multi-electrode ear shell further comprising: a first stimulation electrode comprising a header, a spring, and an electrode shaft extending from the header; a first socket to removably receive the first stimulation electrode, the first socket comprising a rear wall and sidewalls defining an interior volume to removably receive the first stimulation electrode from the inner surface, the sidewalls of the first socket continuously extending from the outer surface of the multi-electrode ear shell, the rear wall of the first socket having a through-hole, wherein the header of the first stimulation electrode is accommodated in the interior volume of the first socket, the spring is between the header and the rear wall of the first socket around the through-hole to press the header of the first stimulation electrode towards the surface of the ear, and the electrode shaft extends through the through-hole in the rear wall to be externally exposed; and a second socket to removably receive a second stimulation electrode, the second socket comprising a rear wall and sidewalls defining an interior volume to removably receive the second stimulation electrode from the inner surface, the sidewalls of the second socket continuously extending from the outer surface of the multi-electrode ear shell. 2. The multi-electrode ear shell of claim 1 , wherein: the first socket is to align the first stimulation electrode with the cymba, and the second socket is to align the second stimulation electrode with the cavum. 3. The multi-electrode ear shell of claim 2 , further comprising an attachment socket between the first socket and the second socket. 4. The multi-electrode ear shell of claim 2 , further comprising a third socket to removably receive a third stimulation electrode, the third socket being to align the third stimulation electrode with a tragus of the ear. 5. The multi-electrode ear shell of claim 4 , further comprising: a fourth socket to removably receive a fourth stimulation electrode, the fourth socket being to align the fourth stimulation electrode with a crus helix of the ear; a fifth socket to removably receive a fifth stimulation electrode, the fifth socket being to align the fifth stimulation electrode with an inferior crus of antihelix of the ear; and a sixth socket to removably receive a sixth stimulation electrode, the sixth socket being to align the sixth stimulation electrode with a stem of the antihelix of the ear. 6. The multi-electrode ear shell of claim 1 , wherein the second stimulation electrode comprises: a header to be accommodated in an interior volume of the second socket; and a spring between the header and the rear wall of the second socket to press the header of the second stimulation electrode towards the surface of the ear. 7. The multi-electrode ear shell of claim 1 , further comprising a protrusion extending into an intertragal notch of the ear. 8. The multi-electrode ear shell of claim 1 , further comprising a ridge to accommodate an inferior crus of antihelix of the ear, wherein the inner surface extends from an antitragus of the ear to a triangular fossa of the ear. 9. The multi-electrode ear shell of claim 1 , further comprising a ridge to accommodate a stem of antihelix of the ear, wherein the inner surface extends from a tragus of the ear to the stem of antihelix. 10. The multi-electrode ear shell of claim 1 , wherein the multi-electrode ear shell comprises acrylonitrile butadiene styrene. 11. A stimulation system comprising: a first multi-electrode ear shell comprising: an inner surface corresponding to a surface of a first ear, an outer surface opposite to the inner surface, and an ear canal opening as a through-hole surrounded by the first multi-electrode ear shell extending from the inner surface to the outer surface, the inner surface being configured to overlap the first ear; a first stimulation electrode comprising a header, a spring, and an electrode shaft extending from the header; a first socket to removably receive the first stimulation electrode, the first socket comprising a rear wall and sidewalls defining an interior volume to removably receive the first stimulation electrode from the inner surface, the sidewalls of the first socket continuously extending from the outer surface of the first multi-electrode ear shell, the rear wall of the first socket having a through-hole, wherein the header of the first stimulation electrode is accommodated in the interior volume of the first socket, the spring is between the header and the rear wall of the first socket around the through-hole to press the header of the first stimulation electrode towards the surface of the ear, and the electrode shaft extends through the through-hole in the rear wall to be externally exposed; a second socket to removably receive a second stimulation electrode, the second socket comprising a rear wall and sidewalls defining an interior volume to removably receive the second stimulation electrode from the inner surface, the sidewalls of the second socket continuously extending from the outer surface of the first multi-electrode ear shell; and an attachment socket at the outer surface; and a headband coupled to the first multi-electrode ear shell via the attachment socket. 12. The stimulation system of claim 11 , further comprising a stimulation circuit housed within the headband, the stimulation circuit being configured to be connected to the first stimulation electrode via the externally exposed electrode shaft. 13. The stimulation system of claim 12 , further comprising a clip electrode connected to the stimulation circuit. 14. The stimulation system of claim 12 , wherein the stimulation circuit is configured to apply stimulation at varying frequencies, programmable waveforms, stimulus intensities, rest periods, and pulse widths. 15. The stimulation system of claim 11 , wherein the first stimulation electrode comprises a connector configured to extend and retract the header of the first stimulation electrode by extending and retracting the spring. 16. The stimulation system of claim 11 , wherein the first socket and the second socket are located such that the first socket and the second socket do not concurrently receive the first stimulation electrode and the second stimulation electrode respectively. 17. The stimulation system of claim 11 , further comprising a second multi-electrode ear shell coupled to the headband via an attachment socket of the second multi-electrode ear shell, the second multi-electrode ear shell comprising: an inner surface corresponding to a surface of a second ear to overlap the second ear; a first socket to removably receive a third stimulation electrode; and a second socket to removably receive a fourth stimulation electrode. 18. The stimulation system of claim 17 , further comprising a stimulation circuit housed within the headband, the stimulation circuit being configured to apply concurrent symmetrical stimulation to the first ear and the second ear.