Interferometer based on a tilted MMI

What is claimed is: 1. An optical interferometer based on multi-mode interference (MMI) devices comprising: a first input port; a first output port; a second output port; a first MMI device connected to the first input port at an input face of the first MMI device; and a second MMI device connected to the first output port and the second output port at an output face of the second MMI device; wherein an output face of the first MMI device and an input face of the second MMI device are directly connected at an interface, the first MMI device includes a first and a second self-imaging points at the interface between the first MMI device and the second MMI device, a propagation axis of the second MMI device is tilted with respect to a propagation axis of the first MMI device, causing a path length difference between an upper optical path via the first self-imaging point and a lower optical path via the second self-imaging point, and a first input light beam enters the first MMI device from the first input port and is split into first and second light beams at the first and second self-imaging points, the path length difference includes a phase shift difference at one of the self-imaging points. 2. The optical interferometer of claim 1 , wherein the first and the second light beams propagate in the first and the second MMI devices via the upper optical path and the lower optical path, respectively, the first light beam and the second light beam acquire a first phase shift and a second phase shift, respectively, and the first and the second light beams are modulated by the phase shift difference between the first phase shift and the second phase shift, which is proportional to the path length difference between the upper optical path and the lower optical path, and the first and the second light beams exit the second MMI device from the first and the second output ports, respectively. 3. The optical interferometer of claim 1 , wherein the first and the second light beams propagate in the first and the second MMI devices via the upper optical path and the lower optical path, respectively, the first light beam and the second light beam acquire a first phase shift and a second phase shift, respectively, the first and the second light beams are modulated by the phase shift difference between the first phase shift and the second phase shift, which is proportional to the path length difference between the upper optical path and the lower optical path, the first light beam is discarded, and the second light beam exits the second MMI device from the second output port. 4. The optical interferometer of claim 1 , further comprising: a second input port connected to the first MMI device at the input face of the first MMI device, wherein a second input light beam enters the first MMI device from the second input port, the first and second input light beams are combined and re-split into the first and second light beams, the first and the second light beams propagate in the first and the second MMI devices via the upper optical path and the lower optical path, respectively, the first light beam and the second light beam acquire a first phase shift and a second phase shift, respectively, the first and the second light beams are modulated by the phase shift difference between the first phase shift and the second phase shift, which is proportional to the path length difference between the upper optical path and the lower optical path, and the first and the second light beams exit the second MMI device from the first and the second output ports, respectively. 5. The optical interferometer of claim 1 , further comprising: a second input port connected to the first MMI device at the input face of the first MMI device, and a third and a fourth output ports connected to the first MMI device at the output face of the first MMI device, wherein a second input light beam enters the first MMI device from the second input port, the first and second input light beams are combined and re-split into the first and second light beams that propagate to the third and fourth output ports connected to the first MMI, and also into third and fourth light beams, the third and the fourth light beams propagate in the first and the second MMI devices via the upper optical path and the lower optical path, respectively, the third light beam and the fourth light beam acquire a first phase shift and a second phase shift, respectively, the phase shift difference by which the second phase shift exceeds the first phase shift, which is proportional to the path length difference between the upper optical path and the lower optical path, is 45 degrees. 6. The optical interferometer of claim 1 , wherein a circular segment section of a MMI device is inserted between the first MMI device and the second MMI device, one side of the circular segment section is connected to the output face of the first MMI device, and the other side of the circular segment section is connected to the input face of the second MMI device, and the curvature of the circular segment section is substantially larger than the wavelength of the incoming light to avoid discontinuity between the first MMI device and the second MMI device. 7. The optical interferometer of claim 1 , wherein the curvature of the edges of the first MMI device and the second MMI device varies continuously. 8. The optical interferometer of claim 1 , wherein the second MMI device is of a non-rectangular parallelogram shape.