Thyristor-based optical XOR circuit

What is claimed is: 1. An optical XOR circuit comprising: a first waveguide coupler configured to receive and split a first digital optical signal into first and second output signals; a second waveguide coupler configured to receive and split a second digital optical signal into third and fourth output signals; a thyristor; and a control circuit coupled to the first and second waveguide couplers and, the thyristor, the control circuit comprising: a first phototransistor having source and gate terminals coupled to a positive voltage supply, and a drain terminal coupled to a p-type injector terminal of the thyristor, wherein the first phototransistor is configured to receive the first output signal; a second phototransistor having source and gate terminals coupled to ground, and a drain terminal coupled to the p-type injector terminal of the thyristor, wherein the second phototransistor is configured to receive the third output signal; a third phototransistor having source and gate terminals coupled to the positive voltage supply, and a drain terminal coupled to an n-type injector terminal of the thyristor, wherein the third phototransistor is configured to receive the second output signal; and a fourth phototransistor having source and gate terminals coupled to ground, and a drain terminal coupled to the n-type injector terminal of the thyristor, wherein the fourth phototransistor is configured to receive the fourth output signal, wherein the control circuit is configured to control a switching operation of the thyristor based on the first and second digital optical signals such that the thyristor produces a digital signal output that is a XOR function of the first and second digital optical signals. 2. The optical XOR circuit of claim 1 , wherein the digital signal output is a digital electrical signal output. 3. The optical XOR circuit of claim 1 , wherein the digital signal output is a digital optical signal output. 4. The optical XOR circuit of claim 1 , wherein the thyristor is defined by an epitaxial layer structure that includes a bottom n-type cathode region, an intermediate p-type region formed above the bottom n-type cathode region, an intermediate n-type region formed above the intermediate p-type region, and a top p-type anode region formed above the intermediate n-type region, wherein the thyristor includes an anode terminal electrically coupled to the top p-type anode region, the n-type injector terminal electrically coupled to the intermediate n-type region, the p-type injector terminal electrically coupled to the intermediate p-type region, and a cathode terminal electrically coupled to the bottom n-type cathode region. 5. The optical XOR circuit of claim 1 , wherein: the first phototransistor is configured as a turn-on phototransistor that supplies a hole current to the p-type injector terminal that operates the thyristor in its ON state when the first digital optical signal is in an ON state and the second digital optical signal is in an OFF state; and the fourth phototransistor is configured as a turn-on phototransistor that supplies an electron current to the n-type injector terminal that operates the thyristor in its ON state when the second digital optical signal is in an ON state and the first digital optical signal is in an OFF state. 6. The optical XOR circuit of claim 5 , wherein the second and third phototransistors are configured as turn-off phototransistors that operate the thyristor in its OFF state when the first digital optical signal is an ON state and the second digital optical signal is an ON state, wherein the third phototransistor is configured to draw an electron current from the n-type injector terminal of the thyristor, and wherein the second phototransistor is configured to draw a hole current from the p-type injector terminal of the thyristor. 7. The optical XOR circuit of claim 6 , wherein the second and third phototransistors are larger in size than the first and fourth phototransistors. 8. The optical XOR circuit of claim 1 , wherein the first and third phototransistors are p-channel HFET phototransistors, and the second and fourth phototransistors are n-channel HFET phototransistors. 9. The optical XOR circuit of claim 4 , wherein the intermediate n-type and intermediate p-type regions of the epitaxial layer structure include an n-type modulation doped quantum well (QW) structure and a p-type modulation doped QW structure, respectively. 10. The optical XOR circuit of claim 9 , wherein at least one of the second and fourth phototransistors includes an n-type QW channel formed by the n-type modulation doped QW structure. 11. The optical XOR circuit of claim 9 , wherein at least one of the first and third phototransistors includes a p-type QW channel formed by the p-type modulation doped QW structure. 12. The optical XOR circuit of claim 4 , wherein the epitaxial layer structure comprises group III-V materials. 13. The optical XOR circuit of claim 1 , wherein the first waveguide coupler includes: an input waveguide configured to receive the first digital optical signal; and an optical hybrid coupler, coupled to the input waveguide, that is configured to receive and split the first digital optical signal into the first and second output signals. 14. The optical XOR circuit of claim 1 , wherein the second waveguide coupler includes: an input waveguide configured to receive the second digital optical signal; and an optical hybrid coupler, coupled to the input waveguide, that is configured to receive and split the second digital optical signal into the third and fourth output signals.