Optical transmitter module

What is claimed is: 1. An optical transmitter module comprising: (a) a housing; (b) a main substrate mounted inside the housing and provided with an interface integrated circuit, and an electrical interface electrically connected with the integrated circuit; (c) a transmitting optoelectronic component mounted on the main substrate; (d) a coupling optical element configured to couple a first optical signal from the transmitting optoelectronic component to a first light guiding structure; and (e) an optical power monitor system connected to the first light guiding structure and comprising a beam splitting optical element and a receiving optoelectronic component mounted on a sub-substrate; (f) wherein the beam splitting optical element is configured to split the first optical signal from the first light guiding structure into a transmitted optical signal and a reflected optical signal, and direct the transmitted optical signal towards an external optical interface via a second light guiding structure, and direct the reflected optical signal towards the receiving optoelectronic component configured to measure the power of the reflected optical signal, which is proportional to the first optical signal; and, wherein the beam splitting optical element comprises a first lens block, a second lens block and a beam splitter inserted between the first lens block and the second lens block. 2. The optical transmitter module as claimed in claim 1 , wherein the first optical signal monitored by the optical power monitor system is fed back to an analog-to-digital converter circuit in a main circuitry for real time monitoring and control of optical power output of the transmitting optoelectronic component. 3. The optical transmitter module as claimed in claim 1 , wherein the beam splitting optical element comprises a first lens block, a second lens block and a beam splitter inserted between the first lens block and the second lens block, and wherein the first lens block is configured to couple the first optical signal from the first light guiding structure to the beam splitter, the second lens block is configured to couple the transmitted optical signal from the beam splitter to the second light guiding structure, and the beam splitter is configured to reflect a minor portion of the first optical signal onto the receiving optoelectronic component and transmit a major portion of the first optical signal to the second lens block. 4. An optical transmitter module comprising: (a) a transmitting optoelectronic component mounted on a main substrate; (b) a coupling optical element configured to couple a first optical signal from the transmitting optoelectronic component to a first light guiding structure; and (c) an optical power monitor system connected to the first light guiding structure and comprising a beam splitting optical element and a receiving optoelectronic component mounted on a sub-substrate; (d) wherein the beam splitting optical element is configured to split the first optical signal from the first light guiding structure into a transmitted optic signal and a reflected optical signal, and direct the transmitted optical signal towards an external optical interface via a second light guiding structure, a direct the reflected optical signal towards the receiving optoelectronic component configured to measure the power of the reflected optical sign which is proportional to the first optical signal; and, wherein the beam splitting optical element comprises a first lens block, a second lens block and a beam splitter inserted between the first lens block and the second lens block. 5. The optical transmitter module as claimed in claim 4 , wherein the first optical signal monitored by the optical power monitor system is fed back to an analog-to-digital converter circuit in a main circuitry for real time monitoring and control of optical power output of the transmitting optoelectronic component. 6. The optical transmitter module as claimed in claim 4 , wherein the sub-substrate of the optical power monitor system is a printed circuit board. 7. The optical transmitter module as claimed in claim 4 , wherein the sub-substrate of the optical power monitor system is a flexible circuit board. 8. The optical transmitter module as claimed in claim 4 , wherein the sub-substrate of the optical power monitor system is the main substrate of the module, and the receiving optoelectronic component and the beam splitting optical element are mounted directly on the main substrate. 9. The optical transmitter module as claimed in claim 4 , wherein the beam splitting optical element is bonded onto the sub-substrate and defines a cavity that accommodates the receiving optoelectronic component. 10. The optical transmitter module as claimed in claim 4 , wherein the first lens block is configured to couple the first optical signal from the first light guiding structure the beam splitter, the second lens block is configured to couple the transmitted optic signal from the beam splitter to the second light guiding structure, and the beam splitter is configured to reflect a minor portion of the first optical signal onto the receiving optoelectronic component and transmit a major portion of the first optic signal to the second lens block. 11. The optical transmitter module as claimed in claim 4 , wherein the first lens block is identical to the second lens block. 12. The optical transmitter module as claimed in claim 4 , wherein the beam splitter is a glass plate with a partially reflective surface, and the glass plate is placed bet the first and second lens blocks, and the normal of the glass plate is at an inclined angle of 45 degrees with respect to an optical path between the first and second blocks. 13. The optical transmitter module as claimed in claim 12 , wherein each of the first and second lens blocks further comprises a prism wedge structure, and when the first and second lens blocks are mated to each other, the prism wedge structures define a cavity that accommodates the glass plate at the inclined angle. 14. The optical transmitter module as claimed in claim 4 , wherein each of the and second lens blocks further comprises an alignment pin hole, and the 1 splitting optical component further comprises alignment metal pins that are ins into the pin holes respectively to physically and optically align the first and se lens blocks. 15. The optical transmitter module as claimed in claim 4 , wherein each of the and second lens blocks further comprises a locating post and a locating slot, an first and second lens blocks align with each other physically and optically by m the locating posts and the locating slots. 16. The optical transmitter module as claimed in claim 15 , wherein the locating posts and the locating slots are rectangular in shape. 17. The optical transmitter module as claimed in claim 4 , wherein the main substrate is provided with an interface integrated circuit, and an electrical interface is electrically connected with the interface integrated circuit. 18. The optical transmitter module as claimed in claim 4 , wherein the main substrate is mounted inside a housing. 19. The optical transmitter module as claimed in claim 18 , wherein the housing comprises an upper housing and a lower housing.