Integrated transmitter and receiver module for LiDAR system

The invention claimed is: 1. An optical sensing system, comprising: an integrated transmitter/receiver (TX/RX) module, the integrated TX/RX module comprising: a laser emitter; one or more transmitting optics; one or more receiving reflectors; and a receiver frontend, wherein the laser emitter and the one or more transmitting optics are part of the TX in the TX/RX module, and the receiver frontend and the one or more receiving reflectors are part of the RX in the TX/RX module, and wherein: the laser emitter is configured to emit an optical signal toward the one or more optics; the one or more transmitting optics are configured to form the optical signal received from the laser emitter into a predefined shape and direct the optical signal having the predefined shape to an environment surrounding the optical sensing system; the one or more receiving reflectors are configured to direct a returned optical signal from the environment to the receiver frontend; the receiver frontend is configured to convert the returned optical signal into an electrical signal; the laser emitter, the one or more transmitting optics, the one or more receiving reflectors, and the receiver frontend are assembled in a single package; and the laser emitter, the one or more transmitting optics, and the receiver frontend are fixed to a substrate of the single package through permanent fixing, and the one or more receiving reflectors are fixed to the substrate through fluid dispensing different from the permanent fixing; and a controller coupled to the integrated TX/RX module, the controller being configured to control the integrated TX/RX module to perform a sensing operation. 2. The optical sensing system of claim 1 , wherein the one or more receiving reflectors define a light path within the integrated TX/RX module for directing the returned optical signal to one or more photosensors of the receiver frontend. 3. The optical sensing system of claim 2 , wherein the light path is defined by aligning the one or more receiving reflectors via an external reference retroreflector. 4. The optical sensing system of claim 2 , wherein the integrated TX/RX module further comprises a receiving lens disposed in the light path of the returned optical signal, the receiving lens being assembled in the single package and being aligned to focus the returned optical signal on the one or more photosensors of the receiver frontend. 5. The optical sensing system of claim 1 , wherein the receiver frontend comprises a photodetector and a readout circuit connected to each other through wire bonding. 6. The optical sensing system of claim 1 , wherein the substrate comprises a printed circuit board (PCB). 7. The optical sensing system of claim 6 , wherein the PCB is made of ceramic with a low-thermal-expansion. 8. The optical sensing system of claim 1 , wherein the single package of the integrated TX/RX module is hermetically sealed. 9. The optical sensing system of claim 1 , wherein the single package of the integrated TX/RX module comprises a plurality of laser emitters, a plurality set of transmitting optics, and a plurality of receiver frontends aligned in a three-dimensional array. 10. An optical sensing method performed by an integrated transmitter/receiver (TX/RX) module of an optical sensing system, the method comprising: emitting, by a laser emitter of the integrated TX/RX module, an optical signal toward one or more transmitting optics of the integrated TX/RX module; forming, by the one or more transmitting optics, the optical signal received from the laser emitter into a predefined shape, and directing, by the one or more transmitting optics, the optical signal having the predefined shape to an environment surrounding the optical sensing system; directing, by one or more receiving reflectors of the integrated TX/RX module, a returned optical signal from the environment to a receiver frontend of the integrated TX/RX module; and converting, by the receiver frontend, the returned optical signal into an electrical signal, wherein the laser emitter and the one or more transmitting optics are part of the TX in the TX/RX module, and the receiver frontend and the one or more receiving reflectors are part of the RX in the TX/RX module, wherein the laser emitter, the one or more transmitting optics, the one or more receiving reflectors, and the receiver frontend are assembled in a single package, and wherein the laser emitter, the one or more transmitting optics, and the receiver frontend are fixed to a substrate of the single package through permanent fixing, and the one or more receiving reflectors are fixed to the substrate through fluid dispensing different from the permanent fixing. 11. The optical sensing method of claim 10 , wherein the one or more receiving reflectors define a light path within the integrated TX/RX module for directing the returned optical signal to one or more photosensors of the receiver frontend. 12. The optical sensing method of claim 11 , comprising: focusing, by a receiving lens disposed in the light path, the returned optical signal on the one or more photosensors of the receiver frontend, wherein the receiving lens is assembled in the single package and aligned to focus the returned optical signal. 13. An integrated transmitter/receiver (TX/RX) module for an optical sensing system, the integrated TX/RX module comprising: a laser emitter; one or more transmitting optics; one or more receiving reflectors; and a receiver frontend, wherein: the laser emitter and the one or more transmitting optics are part of the TX in the TX/RX module, and the receiver frontend and the one or more receiving reflectors are part of the RX in the TX/RX module; the laser emitter is configured to emit an optical signal toward the one or more transmitting optics; the one or more transmitting optics are configured to form the optical signal received from the laser emitter into a predefined shape and direct the optical signal having the predefined shape to an environment surrounding the optical sensing system; the one or more receiving reflectors are configured to direct a returned optical signal from the environment to the receiver frontend; the receiver frontend is configured to convert the returned optical signal into an electrical signal; the laser emitter, the one or more transmitting optics, the one or more receiving reflectors, and the receiver frontend are assembled in a single package; and the laser emitter, the one or more transmitting optics, and the receiver frontend are fixed to a substrate of the single package through permanent fixing, and the one or more receiving reflectors are fixed to the substrate through fluid dispensing different from the permanent fixing. 14. The integrated TX/RX module of claim 13 , wherein the one or more receiving reflectors define a light path within the integrated TX/RX module for directing the returned optical signal to one or more photosensors of the receiver frontend. 15. The integrated TX/RX module of claim 14 , further comprising a receiving lens disposed in the light path of the returned optical signal, the receiving lens being assembled in the single package and being aligned to focus the returned optical signal on the one or more photosensors of the receiver frontend. 16. The integrated TX/RX module of claim 13 , wherein the receiver frontend comprises a photodetector and a readout circuit connected to each other through wire bonding. 17. The integrated TX/RX module of claim 13 , wherein the single package of the integrated TX/RX mo