Split optical front end receivers

What is claimed is: 1. A system, comprising: an optical receiver including: a directional coupler configured to receive an optical signal and split the optical signal into a first signal including a first portion of the optical signal and a second signal including a second portion of the optical signal; a first signal path configured to receive the first signal and including: a first photodetector; a first transimpedance amplifier (TIA) coupled to the first photodetector; and an interpolator coupled to the first TIA; a second signal path configured to receive the second signal and including: a second photodetector; a second TIA coupled to the second photodetector; and the interpolator coupled to the second TIA, the interpolator configured to generate an output signal based on at least one of an output of the first TIA or an output of the second TIA; and an optical power sensing circuit configured to detect a power level of at least one of a signal within the first signal path, a signal within the second signal path, or the output signal from the interpolator; wherein the optical receiver is configured to select at least one of the first signal path or the second signal path to generate the output signal based on the detected power level by: enabling the first TIA and disabling the second TIA when the signal power level is within a first range of signal power levels; and enabling the second TIA and disabling the first TIA when the signal power level is within a second range of signal power levels that does not overlap with the first range of signal power levels. 2. The system of claim 1 , further comprising an amplifier coupled to an output of the interpolator and configured to generate an amplified output signal based on the output signal. 3. The system of claim 1 , wherein the directional coupler comprises a silicon nitride (SiN) polarization independent directional coupler. 4. The system of claim 3 , wherein the SiN polarization independent directional coupler comprises: a first SiN waveguide including an optical input port to receive the optical signal and a first output port optically coupled to the first photodetector in the first signal path; and a second SiN waveguide including a terminated port and a second output port optically coupled to the second photodetector in the second signal path, wherein: the first and second SiN waveguides are spaced apart to inhibit optical coupling in a first region; the first and second SiN waveguides are decreasingly spaced apart with respective slopes of the first and second SiN waveguides in a second region; the first and second SiN waveguides are substantially parallel for a distance L and spaced apart with an optical coupling gap G in a third region; the first and second SiN waveguides are increasingly spaced apart with respective slopes of the first and second SiN waveguides in a fourth region; and the first and second SiN waveguides are spaced apart to inhibit optical coupling in a fifth region. 5. The system of claim 1 , wherein the first signal including the first portion of the optical signal comprises between 75% and 90% of the optical signal. 6. The system of claim 1 , further comprising at least one of a grating coupler, a spot size converter, and a polarization splitter coupled between an optical fiber and the directional coupler. 7. The system of claim 1 , wherein: the first signal path further includes a first silicon nitride (SiN)-silicon (Si) multimode adiabatic coupler between a first output port of the directional coupler and the first photodetector of the first signal path; and the second signal path further includes a second SiN—Si multimode adiabatic coupler between a second output port of the directional coupler and the second photodetector of the second signal path. 8. The system of claim 7 , further comprising: a Si substrate; a buried oxide (BOX) layer formed above the Si substrate; a Si waveguide layer formed above the BOX layer; and a silicon nitride (SiN) waveguide layer formed above the Si waveguide layer, wherein: the directional coupler is formed in the SiN waveguide layer; each of the first and second SiN—Si multimode adiabatic couplers is formed in the Si waveguide layer and the SiN waveguide layer and includes: a multimode Si waveguide formed in the Si waveguide layer, the Si waveguide including a Si taper; and a SiN waveguide formed in the SiN waveguide layer, the SiN waveguide including a SiN taper aligned in two orthogonal directions with a portion of the multimode Si waveguide that is continuous with and excludes the Si taper, the Si taper being aligned in two orthogonal directions with a portion of the SiN waveguide that is continuous with and excludes the SiN taper. 9. An optical receiver, comprising: at least one directional coupler having at least one input configured to couple to an optical fiber; a first signal path including a first photodetector coupled to an output of the at least one directional coupler, a first transimpedance amplifier (TIA) including an input coupled to the first photodetector, and an adder coupled to an output of the first TIA; a second signal path including a second photodetector coupled to an output of the at least one directional coupler, a second TIA including an input coupled to the second photodetector, and the adder coupled to an output of the second TIA; and an optical power sensing circuit coupled to at least one of the first TIA, the second TIA, the adder, and an output of the optical receiver and configured to detect a signal power level within the first signal path, within the second signal path, at the adder, or at the output of the optical receiver, wherein the optical receiver is configured to: enable the first TIA and disable the second TIA when the signal power level is within a first range of signal power levels; and enable the second TIA and disable the first TIA when the signal power level is within a second range of signal power levels that does not overlap with the first range of signal power level. 10. The optical receiver of claim 9 , wherein the optical receiver is configured to: enable the first TIA and disable the second TIA when the signal power level is equal to or less than a threshold value, the first range of signal power levels including signal power levels including and below the threshold value; and disable the first TIA and enable the second TIA when the signal power level is greater than the threshold value, the second range of signal power levels including signal power levels above the threshold value. 11. The optical receiver of claim 9 , wherein the optical receiver is configured to: enable the first TIA and distable the second TIA when the signal power is less than a first threshold value, the first range of signal power levels including signal power levels below the first threshold value; disable the first TIA and enable the second TIA when the signal power level is greater than a second threshold value, wherein the second threshold value is greater than the first threshold value, the second rage of signal power levels including signal power levels above the second threshold value; and enable each of the first IA and the second TIA when the signal power level is between the first threshold value and the second threshold value. 12. The optical receiver of claim 9 , wherein the first signal path is configured to receive a first percentage of an input signal and the second signal path is configured to receive a second, different percentage of the input signal, wherein the first percentage comprises X percent of the input signal and the second, different percentage