Aires Tech Resonator Chip Structure
The main distinction between the Aires Resonator Chip traditional microprocessors lies in its structure and manufacturing process.
The Aires Resonator Chip utilizes nanotechnology, precisely manufactured through state-of-the-art photolithography equipment and photomask etching processes.
Specifically, the Aires Resonator Chip creates nano-scale slits using photolithography equipment, with precise width specifications of 0.4 micrometers and depths of 0.8 micrometers, over 200 times smaller than the average width of a human hair. This manufacturing process results in unparalleled efficiency and effectiveness for the microprocessor.
Compared to traditional microprocessors based on the von Neumann architecture, the operation of the Aires Resonator Chi[ may differ.
Traditional microprocessors write information based on strictly defined polarization levels of storage units and require an external power source to function properly.
Furthermore, due to the nanotechnology used in the manufacturing of the Aires Resonator Chip, it may have a smaller form factor and higher integration, occupying less space for equivalent performance, which could be significant for certain specific application scenarios.
Actual photo of the Aires Resonator Chip at extreme magnification
Circular diffraction lattice
The new product lineup utilizes three different microprocessors. With the increasing complexity of circular diffraction lattices, effectiveness also improves.
- C16 Type: 83521 circular etching 16 fractal vectors
- C28 Type: 707281 circular etching 28 fractal vectors
- C32 Type: 1185921 circular etching 32 fractal vectors
The main challenge for these processors in handling signals existing in the natural world is that natural signals are analog, meaning they are continuous in time, while the processors we describe can only handle discrete data. Therefore, signals are transformed from their natural form into a discrete digital form. This transformation introduces some degree of inaccuracy to the source data. There are mathematical methods to determine the parameters of this transformation while maintaining sufficient accuracy for practical applications. However, the transformation process represents a considerable sequential execution time. Of course, it is very short for modern high-performance processors, but fundamentally not simultaneous.
The higher the frequency of processing signals, the more diverse the requirements for circuits and traditional hardware components. To some extent, these requirements define one of the barriers of existing technology.
The core of the Aires processor is fundamentally different from this because it is a dedicated analog processor that simultaneously performs forward and inverse Fourier transforms using the product's circular diffraction grating, defining the sector of the entire possible solution. Diffraction through the grating decomposes complex signals into continuous spectra. Fundamentally, the spectrum is continuous, meaning it occupies the entire frequency range entirely. This transformation does not distort the received information pulses (no information is lost); it merely represents the pulses in a new form. An ideal processor is a three-dimensional coordinated structure, but even a two-dimensional projection that achieves forward and inverse Fourier transforms is simpler and more effective than traditional signal processing circuits.