Coupling

Virtual-virtual coupling

Based on the experimental result, we select the dual-feedback oscillator to finish the modulating and coupling process. First, we will finish the virtual-virtual coupling. So different initial values of parameters are set to the simulation to form two e-oscillators which are of the same properties.

Then how could they adjust to each other and be strongly coupled or synchronized? We think about the dynamic equilibrium of wolf and rabbit. If the number of wolves increases rapidly, lots of rabbits would be eaten and the number would reduce. Faced with the decrease of prey, the quantity of wolves would also cut down. On the contrary, rabbits would multiply with fewer natural predators. Cycling like these, wolf and rabbit would finally reach the dynamic balance.

According to the above mechanism, we make the two e-oscillators pass the parameters and affect each other. In terms of the transfer function, with the enhancement of the light intensity, the expression of lacI will reduce, which is proportional to the other e-oscillator’s light intensity. It means that the illumination intensity of e-oscillator 2 will decrease and the corresponding lacI will increase. Then lacI will also be inversely linked to the e-oscillator 1. With the circulation and regulation, the two e-oscillator will be coupled or synchronized gradually.

To achieve the process of coupling or synchronization, we write programs in MATLAB and get the simulation result shown in video 1.

video 1. Simulation result of virtual-virtual coupling.

Mixed-reality of physics

In the second stage, LED lamp controlled by single-chip replace the fluorescence released by E.coli. Based on the virtual-virtual coupling, LED will glow following one of the e-oscillators simulated above as the physical real part, while the other e-oscillator will be the virtual part.

Through a camera, intensity of LED will be transfer to computer and affect the e-oscillator. The returned value of e-oscillator will also be passed to the physical real part by single-chip. With the interaction, the two parts will get coupled in the end. The details of connecting device are specified in our Interface Hardware part.

Reference

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