Two-part optical coupling subassembly for monitoring optical output power in optical transceiver

What is claimed is: 1. A two-part optical coupling subassembly comprising: a main lens formed with a cavity, the main lens comprising: a first surface formed with a first collimating lens for collimating light from a vertical-cavity surface-emitting laser; a second surface oriented at an angle with respect to the first surface for reflecting collimated light from the first collimating lens to an optical fiber; a third surface formed in the cavity and inclined at an off-vertical angle from a central vertical plane of the cavity; a fourth surface formed in the cavity and oppositely inclined at the off-vertical angle from the central vertical plane such that the third and fourth surfaces are symmetric with respect to the central vertical plane; and a fifth surface facing the optical fiber; a beam router embedded in the cavity, the beam router comprising: a first beam router surface lying on the third surface of the main lens; a second beam router surface lying on the fourth surface of the main lens; and a partially reflective coating provided on one of the first and second beam router surfaces; and a transparent adhesive provided between the third surface and the first beam router surface, and between the fourth surface and the second beam router surface; wherein collimated light reflected from the second surface of the main lens passes through a first interface defined by the third surface, the first beam router surface and the transparent adhesive in between, enters into the beam router, passes through a second interface defined by the second beam router surface, the fourth surface of the main lens and the transparent adhesive in between, re-enters the main lens and propagates to the fifth surface of the main lens where the light exits and directs to the optical fiber; and wherein a portion of the collimated light is reflected by the partially reflective coating, decoupled from light transmitting towards the optical fiber, and directed to a light detector to monitor optical output power; whereby the oppositely inclined first and second interfaces provide self-correction of output beam angle in case of misalignment of the beam router and the main lens; wherein the partially reflective coating is provided on the second beam router surface, and the beam router further comprises: (i) a third beam router surface provided at an opposite side of the first beam router surface; and a fourth beam router surface provided at an opposite side of the second beam router surface; wherein the collimated light is partially reflected by the partially reflective coating to the third beam router surface and in turn reflected by the third beam router surface to the fourth beam router surface, and in turn reflected by the fourth beam router surface through the first interface, out of the main lens, and to the light detector, which is located underneath the main lens; or (ii) a third beam router surface formed on an upper, top side of the beam router; and wherein the collimated light reflected from the second surface passes through the first interface and enters into the beam router, and the light is partially reflected by the partially reflective coating and decoupled from light transmitting towards the optical fiber, and the decoupled light passes through the beam router and propagates to the third beam router surface where the light exits the beam router and directs to the light detector, which is located above the beam router. 2. The two-part optical coupling subassembly as claimed in claim 1 , wherein the partially reflective coating is provided on the first beam router surface; and wherein the collimated light reflected from the second surface of the main lens is partially reflected from the partially reflective coating and decoupled from light transmitting towards the optical fiber, and the decoupled light re-enters the main lens and propagates to the first surface of the main lens where the light exits and directs to the light detector, which is located underneath the main lens. 3. The two-part optical coupling subassembly as claimed in claim 1 , wherein the off-vertical angle is between 30 to 60 degrees. 4. The two-part optical coupling subassembly as claimed in claim 3 , wherein the off-vertical angle is 45 degrees. 5. The two-part optical coupling subassembly as claimed in claim 1 , wherein the fifth surface is formed with a lens to focus light to the optical fiber. 6. The two-part optical coupling subassembly as claimed in claim 1 , wherein an optical coating is provided on one or more of the lens surfaces and the beam router surfaces to increase or decrease light transmission. 7. The two-part optical coupling subassembly as claimed in claim 1 , wherein the partially reflective coating comprises at least one layer of dielectric film with a refractive index ranging from 1.3 to 2.3 to provide a reflectivity of 0.01 to 0.95 in the optical coupling subassembly. 8. An optical coupling subassembly comprising: a main lens formed with a cavity, the main lens comprising two surfaces formed in the cavity and oppositely inclined at an off-vertical angle from a central vertical plane of the cavity such that the two surfaces are symmetric with respect to the central vertical plane; a beam router embedded in the cavity, the beam router comprising a first beam router surface lying on one of the two surfaces; a second beam router surface lying on another one of the two surfaces; and a partially reflective coating provided on one of the first and second beam router surfaces; and a transparent adhesive provided between one of the two surfaces and the first beam router surface, and between another one of the two surfaces and the second beam router surface; wherein the main lens thither comprises: a first surface formed with a first collimating lens for collimating light from a vertical-cavity surface-emitting laser; a second surface oriented at an respect to the first surface for reflecting collimated light from the first collimating lens to an optical fiber; a third surface, being one of the two surfaces formed in the cavity and inclined at the off-vertical angle from the central vertical plane of the cavity; a fourth surface, being another one of the two surfaces formed in the cavity and oppositely inclined at the off-vertical angle from the central vertical plane such that the third and fourth surfaces are symmetric with respect to the central vertical plane; and a fifth surface facing the optical fiber; wherein collimated light reflected from the second surface passes through a first interface defined by the third surface, the first beam router surface and the transparent adhesive in between, enters into the beam router, passes through a second interface defined by the second beam router surface, the fourth surface and the transparent adhesive in between, re-enters the main lens and propagates to the fifth surface where the light exits the main lens and directs to the optical fiber; and wherein a portion of the collimated light is reflected by the partially reflective coating, decoupled from light transmitting towards the optical fiber, and directed to a light detector to monitor optical output power; whereby the oppositely inclined first and second interfaces provide self-correction of output beam angle in case of misalignment of the beam router and the main lens; wherein the partially reflective coating is provided on the second beam router surface, and the beam router further comprises: (i) a third beam router surface provided at an opposite side of the first beam router surface; and a fourth beam router surface provided at an opposite side of the second beam router surface; wherein the collimated light is partially reflected by the partially reflective