A high-throughput optical system possesses a large field of view (FOV) and high resolution. However, it is a major challenge to design such a telescope with these two conflicting specifications. In this paper, we propose a method to design a high-throughput telescope based on the classical off-axis three-mirror anastigmat (TMA) configuration by introducing a scanning mechanism. We derive the optimum initial design for the TMA system with no primary aberrations through characteristic ray tracing. During the design process, a real exit pupil is necessitated to accommodate the scanning mirror. By gradually increasing the system’s FOV during the optimization procedure, we finally obtained a high-throughput telescope design with an F-number of 6, a FOV of
6
0
∘
×
1
.
5
∘
, and a long focal length of 876 mm. In addition, a tolerance analysis is also conducted to demonstrate the instrumentation feasibility. We believe that this kind of large rectangle FOV telescope with high resolution has broad future applications in the optical remote sensing field.
In the field of communication, liquid crystal on silicon (LCoS) wavelength selection switches (WSS) systems are of great significance but the lack of research on its optical path design makes it challenging to realize high-port-count and perfect performance with a compact structure. In this paper, the optical path design method of a compact LCoS-based 1×10 WSS system working in C-band (1529nm~1568nm) is proposed, where there exists 1 input port and 10 output ports in the same array. The distribution of optical power in the two directions is taken into account independently, boosting system compactness, lowering assembly and manufacturing costs. Finally, a high fiber-to-fiber coupling efficiency ranging from 95.07% to 99.18% is achieved, corresponding to ultra-low simulation loss of less than 0.22dB. Furthermore, a brief tolerance analysis to demonstrate the instrumentation feasibility is also conducted. Our work is pioneering in providing a more straightforward evaluation method and a more workable solution for the optical design of WSS systems.
In the field of communication, liquid crystal on silicon (LCoS) wavelength selection switches (WSS) systems are of great significance but the lack of research on its optical path design makes it challenging to realize high-port-count and perfect performance with a compact structure. In this paper, the optical path design method of a compact LCoS-based 1×10 WSS system working in C-band (1529nm~1568nm) is proposed, where there exists 1 input port and 10 output ports in the same array. The distribution of optical power in the two directions is taken into account independently, boosting system compactness, lowering assembly and manufacturing costs. Finally, a high fiber-to-fiber coupling efficiency ranging from 95.07% to 99.18% is achieved, corresponding to ultra-low simulation loss of less than 0.22dB. Furthermore, a brief tolerance analysis to demonstrate the instrumentation feasibility is also conducted. Our work is pioneering in providing a more straightforward evaluation method and a more workable solution for the optical design of WSS systems.
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