Optical receiver photodiode testing using test optical terminal at different location than operational optical terminal

What is claimed is: 1. A structure, comprising: a photodiode on a substrate, the photodiode including a first optical terminal and a second, test optical terminal, the second, test optical terminal in a different location than the first optical terminal of the photodiode; an optical component in optical communication with the first optical terminal of the photodiode; and a grating coupler in optical communication with and coupled to the second, test optical terminal of the photodiode, wherein the optical component is in optical communication with the first optical terminal of the photodiode via a first optical signal path, and the grating coupler is in optical communication with the second, test optical terminal of the photodiode via a second optical signal path separate from the first optical signal path. 2. The structure of claim 1 , wherein the photodiode is one of a plurality of photodiodes on the substrate, and wherein at least some other photodiodes of the plurality of photodiodes include the optical component in optical communication with the first optical terminal thereof but are devoid of the grating coupler in optical communication with the second, test optical terminal thereof. 3. The structure of claim 1 , wherein the first optical terminal and the second, test optical terminal of the photodiode are on opposite sides of the photodiode, and the second optical signal path includes at least two turns in a horizontal plane. 4. The structure of claim 1 , wherein the first optical terminal and the second, test optical terminal of the photodiode are on opposite sides of the photodiode, and the second optical signal path extends along a side of the photodiode and includes a U-turn in a horizontal plane. 5. The structure of claim 1 , wherein the optical component includes an optical fiber operationally coupled to an edge coupler on the substrate, wherein the first optical signal path includes a first end in optical communication with the optical component and a second end in optical communication with the first optical terminal of the photodiode, and wherein the second optical signal path includes a first end in optical communication with the grating coupler and a second end in optical communication with the second, test optical terminal of the photodiode. 6. The structure of claim 5 , wherein the first optical signal path includes a first diverging waveguide at the first end thereof, and the second optical signal path includes a second diverging waveguide at the second end thereof. 7. The structure of claim 5 , wherein a first optical signal in the second end of the second optical signal path is communicated in a direction opposite to a second optical signal in the second end of the first optical signal path. 8. A designed-for-test (DFT) structure for a photonic integrated circuit (PIC), the DFT structure comprising: a plurality of photodiodes on a substrate, each photodiode having a first optical terminal and a second, test optical terminal, the second, test optical terminal in a different location than the first optical terminal of the photodiode; a different optical component in optical communication with the first optical terminal of each photodiode of the plurality of photodiodes; and a grating coupler in optical communication with and coupled to the second, test optical terminal of at least one selected photodiode of the plurality of photodiodes, wherein each different optical component is in optical communication with the first optical terminal of a respective photodiode via a first optical signal path, and the grating coupler is in optical communication with the second, test optical terminal of the at least one selected photodiode via a second optical signal path separate from the first optical signal path. 9. The DFT structure of claim 8 , wherein the plurality of photodiodes other than the at least one selected photodiode are devoid of the grating coupler in optical communication with the second, test optical terminal. 10. The DFT structure of claim 8 , wherein the first optical terminal and the second, test optical terminal of the at least one selected photodiode are on opposite sides of the at least one selected photodiode, and the second optical signal path includes at least two turns in a horizontal plane. 11. The DFT structure of claim 8 , wherein the first optical terminal and the second, test optical terminal of the at least one selected photodiode are on opposite sides of the at least one selected photodiode, and the second optical signal path extends along a side of the at least one selected photodiode and includes a U-turn in a horizontal plane. 12. The DFT structure of claim 8 , wherein the different optical components each include an optical fiber operationally coupled to an edge coupler on the substrate, wherein the first optical signal path includes a first end in optical communication with the optical component and a second end in optical communication with the first optical terminal of the photodiode, and wherein the second optical signal path includes a first end in optical communication with the grating coupler and a second end in optical communication with the second, test optical terminal of the at least one selected photodiode. 13. The DFT structure of claim 12 , wherein the first optical signal path includes a first diverging waveguide at the first end thereof, and the second optical signal path includes a second diverging waveguide at the second end thereof. 14. The DFT structure of claim 12 , wherein a first optical signal in the second end of the second optical signal path is communicated in a direction opposite to a second optical signal in the second end of the first optical signal path. 15. A method, comprising: optically communicating a test optical signal into a grating coupler in optical communication with a first, test optical terminal of a photodiode in a photonic integrated circuit (PIC), the first, test optical terminal being different than a second optical terminal of the photodiode through which an operational optical signal is optically communicated from an optical component during operation of the PIC; and determining whether the photodiode is operational based on an electrical output of the photodiode and the test optical signal, wherein the grating coupler is in optical communication with and coupled to the first, test optical terminal of the photodiode via a first optical signal path, and wherein the optical component is in optical communication with the second optical terminal of the photodiode via a second optical signal path separate from the first optical signal path. 16. The method of claim 15 , wherein the second optical terminal of the photodiode is non-operational during the optically communicating of the test optical signal into the grating coupler in optical communication with the first, test optical terminal of the photodiode. 17. The method of claim 15 , further comprising, during operation of the PIC, optically communicating the operational optical signal from the optical component to the second optical terminal of the photodiode, wherein the first, test optical terminal of the photodiode is non-operational during operation of the PIC. 18. The method of claim 17 , wherein the first, test optical terminal and the second optical terminal of the photodiode are on opposite sides of the photodiode, and wherein: optically communicating the test optical signal includes communicating the test optical signal into the first, test optical terminal in a first direction along a first optical signal p