A generation of optical capsules and tweezers array within a modified optical add-drop filter known as PANDA ring resonator with a new concept is proposed. By using dark and bright solitons, the orthogonal tweezers can be formed within the system and observed simultaneously at the output ports. Under the resonant condition, the optical capsules and tweezers generated by dark and bright soliton orthogonal pair where the dark-bright soliton array with different center wavelengths and propagation in to the modified add/drop filter that can be generated the optical capsule. In principle, the molecule/atom is trapped and capsule by the force generated by reverse different combinations of gradient fields and photons interaction within the PANDA ring. In application, the molecules/atoms can be secured by using the dark-bright soliton reverse different combinations (optical capsule). Whereas the dark-bright soliton can be capsule as the molecule/atom, which can be used to molecule/atom transportation increased. Simulation result obtained has shown that the amplified power 12 W of the dark-bright soliton array capsule and with wavelength center around 1.40 - 1.50 μm at drop port and throughput port can be achieved, respectively.
We propose a novel system for generating multiplexed dark-soliton pulses using multiple light sources via an optical multiplexer, whereby dark solitons with different center wavelengths can be generated. The multiplexed signals can be transmitted into the communication link and filtered by using an optical add-drop filter. By using suitable simulation parameters, we have shown that dark solitons with different center wavelengths can in fact be obtained. In application, the communication capacity can be increased by using the multiplexed dark solitons; moreover, the transmission signals can be secured by utilizing the behavior of dark solitons. A free spectrum range (FSR) 2.5 nm and an amplified power of 30 W of dark solitons with wavelength 1.60 µm can be achieved. Channel spacing of the communication signals within a wavelength router can be provided by using a suitable FSR, which can be managed by using crosstalk effect analysis.
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