Quantum clocks are the most advanced clocks in the world.

Laser pulses can use to make the logic gate. But laser systems can also use to create ultra-fast clocks. Those systems benefit the frequency of wave motion. When the energy wave hits the sensor. It sends the impulse to the oscillation circuit.

Ultra-fast laser flashes are making it possible to create computers that are a million times faster than anything before them. But by using quantum-hybrid technology is possible to make a clock, which frequency is, even higher than any clock before that. The idea of that ultra-fast clock is to benefit the wave motion of the light or other electromagnetic radiation.

The wave motion can use to adjust clocks. The frequency of the wave motion determines how often the oscillation circuit sends the pulse to the system. The frequency of wave motion can make the same thing that crystals are making in the regular clocks. When wave motion hits the sensor. That sensor sends the signal or energy pike the oscillation circuit.

Image 2: 1 The sensor in wave motion-based oscillation circuit.

In image 2 the wave motion is adjusting the clock system. When the top of the energy wave touches the sensor it sends the impulse to the clock. The frequency of the wave motion determines the frequency of the signals that are making the clock circuit oscillate.

Image 3: The wave motion that travels over sensor pairs.

The idea is that the radiation or wave movement would affect the quantum sensors one by one. Image 3 introduces the model where wave motion just touches another sensor in the sensor pair in the wave motion travels in the oscillation unit.

The wave motion touches those sensors separately. And the sensors measure the energy level of the wave motion. That makes it possible to transmit data in the same system. The use of wave motion in the clocks and their oscillation circuit requires the elimination of disturbing effects from the system.

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