Integrated coherent optical transceiver, light engine

What is claimed is: 1. An integrated coherent transceiver comprising: a substrate member; a tunable laser device comprising a laser diode chip having a gain region with a p-side electrode flipped down and mounted on the substrate member, the gain region being coupled with a wavelength tuning section formed in the substrate member to tune wavelengths of a laser light outputted from the gain region to a waveguide in the substrate member; a first power splitter coupled to the waveguide to split the laser light to a first light and a second light; a coherent receiver block comprising at least two 90° hybrid receivers coupled respectively to two outputs of a polarization beam splitter rotator in the substrate member to receive a coherent input signal from a coherent optical network and to two outputs of a second power splitter to receive two local-oscillator signals split from the first light for assisting detections of a transverse electric (TE) mode signal and a transverse magnetic (TM) mode signal in the coherent input signal; and a coherent transmitter block comprising at least a pair of in-phase/quadrature-phase modulators in the substrate member to respectively modulate two parts split from the second light to two I/Q-modulated signals in TE-mode, a polarization beam rotator combiner in the substrate member to rotate one of the two I/Q modulated signals to a TM-mode signal and combine with the other one of two I/Q modulated signals in TE-mode to generate a coherent output signal transmitted through a polarization-independent semiconductor optical amplifier to the coherent optical network. 2. The integrated coherent transceiver of claim 1 wherein the substrate member is silicon photonics substrate or a planar light circuit substrate. 3. The integrated coherent transceiver of claim 1 wherein the laser diode chip comprises multiple surface fiducials engaging with multiple counter-part substrate fiducials in a patterned surface region of the substrate member for having a first end facet of the gain region aligned to an edge stopper of an integrated coupler in the substrate member for passing a light generated in the gain region into the wavelength tuning section and a second end facet of the gain region aligned to another integrated coupler to output the laser light to the waveguide. 4. The integrated coherent transceiver of claim 3 wherein the wavelength tunable section comprises a straight waveguide section coupled to at least two micro-ring resonators wire followed by a reflector section, the straight waveguide section being directly coupled to the integrated coupler to receive a light generated in the gain region, the at least two ring resonators having slightly different radii to allow the light being tuned in an extended wavelength range of synthesized spectrum, and the reflector section being characterized with at least 90% reflectivity of the light. 5. The integrated coherent transceiver of claim 4 wherein the straight section comprises SiN material, the at least two ring resonators and the reflector section comprise Si material. 6. The integrated coherent transceiver of claim 4 wherein the wavelength tunable section further comprises at least three thin-film resistor heaters placed on the substrate member respectively and at least partially over the at least two ring resonators and the reflector section. 7. The integrated coherent transceiver of claim 6 wherein the thin-film resistor heaters placed over the at least two ring resonators are configured to tune the light in the extended wavelength range at least from 1530 nm to 1570 nm and the thin-film resistor heater placed over the reflector section is configured to tune phase of the light to match a round trip cavity lasing condition between the first end facet and the second end facet of the gain region. 8. The integrated coherent transceiver of claim 1 wherein the tunable laser device comprises two laser diode chips flip mounted on the substrate member to provide two active gain regions coupled to a wavelength tuning section and a wavelength locker with three photodiodes integrated in the substrate member. 9. The integrated coherent transceiver of claim 1 wherein the first power splitter is configured in the substrate member to split the first light and the second light with an X:Y ratio in a range from 10:90 to 50:50. 10. The integrated coherent transceiver of claim 1 wherein the second power splitter is configured to split the first light substantially equally in power. 11. The integrated coherent transceiver of claim 1 wherein the polarization beam splitter rotator comprises a rib structure waveguide formed in the substrate member configured to convert a TM-mode polarization of an incoming light from an input port to a substantial TE-like polarization, the incoming light being the coherent input light received from a coherent optical network. 12. The integrated coherent transceiver of claim 11 wherein the polarization beam splitter rotator comprises a double-taper structure waveguide configured as a 50:50 splitter following the rib structure waveguide. 13. The integrated coherent transceiver of claim 12 wherein the polarization beam splitter rotator comprises a dual-branch shaped waveguide coupled to the double-taper structure waveguide and configured to provide one branch with extra 90° phase shift to the light wave traveling thereof. 14. The integrated coherent transceiver of claim 13 wherein the polarization beam splitter rotator comprises a rectangular-shaped waveguide coupled to the dual-branch shaped waveguide and configured as a 2×2 multi-mode interferometer to output a TE-mode polarization light to a first port and a TM-mode polarization light to a second port upon receiving a coherent light inputted via the input port of the rib structure waveguide. 15. The integrated coherent transceiver of claim 1 wherein one of the at least two 90° hybrid receivers is configured as a TE 90° hybrid receiver to convert a hybrid light signal combining the TE-mode signal in the coherent input signal and a first TE-mode local-oscillator signal split from the first light from the tunable laser device to a first hybrid current signal for detecting the TE-mode signal in the coherent input signal; the another one of the at least two 90° hybrid receivers is configured as a TM* 90° hybrid receiver to convert a hybrid light signal combining a TE-mode signal rotated from the TM-mode signal in the coherent input signal and a second TE-mode local-oscillator signal split from the first light from the tunable laser device to a second hybrid current signal for detecting the TM-mode signal in the coherent input signal. 16. The integrated coherent transceiver of claim 15 wherein the coherent receiver block further comprises a trans-impedance amplifier (TIA) chip flip-mounted on the substrate member and coupled to the at least two 90° hybrid receivers to process the first hybrid current signal and the second hybrid current signal to be converted to digital signals. 17. The integrated coherent transceiver of claim 1 wherein the coherent transmitter block further comprises a driver chip flip-mounted on the substrate member and configured to provide bias power and driving signal to the at least a pair of in-phase/quadrature-phase modulators. 18. The integrated coherent transceiver of claim 1 wherein the polarization beam rotator combiner is a shaped waveguide configured in the substrate member substantially same as the polarization beam splitter rotator with a reversed optical path. 19. The integrated co