QUANTUM SENSOR AND SYNXAPPS ARRAY

Abstract

Similar to high-definition cameras, thermometers, microphones, and seismic sensors, Quantum Sensors are metric devices capable of converting analog signal diagnostics into quantized electrical impulses for data processing capabilities. However, unlike discrete bandwidth sensors digitally renormalized into frequency or temporal bit dependent amplitudes, Quantum Sensors can organize multiple multi-dimensional wavelength frequencies into a dense volumetric wavelength of Q-bit tomography information renormalized by its integration of a desired power wavelet function. This device functions as a time invariant, vector stabilized, and dimensionally independent signal filter for data capture and processing capabilities. Additionally, the extraction of a dimensional power wavelet function reduces ambient noise to signal compression interferences in signal spectroscopy analyzers. In this device a twerk, or transformation of a renormalized and quantized volumetric field gradient, is constructed as an anamorphic power density phase distribution detected by the Q-factor of a resonant flux capacitor, inductor, and semi-resistor circuit. Similar to layered RBG filter composites, Quantum Sensors can simulate holographic representations of any captured multi-dimensional data per discrete temporal amplitude, frequency modulation, or power wavelet interval function(s) into a SynXapps array of combinatoric data permutations.

Claims

1. A Quantum Sensor component, comprising; a primary permeable semi-resistive quantum material infused with the doping of granulated conductive and photo-sensitive impurities distributed within the resistive material; and a plurality of separated dissimilar permeable semi-resistive quantum material(s) infused with the doping of varied granulated conductive and photo-sensitive impurities distributed within each resistive material; and the embedding of geometrically arranged conductive trace leads on the etched topology of a concave surface area layered with the said primary permeable semi-resistive quantum material and successive geometrically arranged conductive trace leads etched on the topology of a transparent planar surface area layered with said dissimilar plurality of permeable resistive materials; and the suspended anchoring of a pliable transparent diaphragm membrane with a center affixed conductive toroidal ring attached to a conductive trace lead, located adjacent to the said transparent planar surface; and the affixed anchoring of a semi-transparent lens, located adjacent to the said pliable transparent membrane, with etched and perforated geometric patterns; and the partial anchoring of an orthogonal inductive wire inside the said concave surface area, thru the layers of said semi-resistive quantum material(s), thru the transparent layers of said planar surface area layered with the said dissimilar layers of permeable resistive materials, and thru the center of the said toroidal ring encased in the suspension of the pliable transparent membrane, and thru the said semi-transparent lens with etched and perforated geometric patterns.

2. A method of simultaneously capturing volumetric wavelength frequencies from a multi-dimensional sensor array to detect and process photonic, thermal, audio, pressure compression, magnetic, and phonon gradients of phased multi-dimensional energy fluctuations.

3. The method of stabilizing the angular momentum and geometric vector translation of a multi-dimensional sensor array device using an inductive core affixed to a said concave surface area, with a said semi-resistive quantum material, in a convolutional capacitor flux, and charge induced by a said toroidal conductive ring capturing volumetric combinatoric wavelength frequencies.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] FIG. 1. is a top view schematic composition diagram of the Quantum Sensor, SYNXAPPS ARRAY, Single Nonlinear Anisotropic/Isotropic Inductor (SNAIL), and Synchronized Inductor and Normalized Capacitor (SINC) according to an embodiment of this application.

[0012] FIG. 2. is a side view schematic composition diagram of the Quantum Sensor, SYNXAPPS ARRAY, Single Nonlinear Anisotropic/Isotropic Inductor (SNAIL), and Synchronized Inductor and Normalized Capacitor (SINC) according to an embodiment of this application.

DETAILED DESCRIPTION OF DRAWINGS

[0013] FIG. 1 shows a non-conductive concave surface manifold 10, with conductive trace pits geometrically etched in its surface area 20. A semi-resistive quantum material 30, doped with conductive and photo-sensitive impurities, is layered over the topology of the non-conductive manifold 10, and conductive trace pits 20. A transparent non-conductive surface manifold 40, with conductive trace pits are geometrically etched in its surface area 50, and layered over the topology of the semi-resistive quantum material 30. A transparent, flexible, and non-conductive membrane 60, embedded with a conductive ring 70 with a conductive trace lead 75 connected to the conductive ring 70 and both being elevated and affixed adjacent the transparent non-conductive surface manifold 40. A semi-translucent lens, with an inscribed geometric pattern 80, is elevated and affixed adjacent the transparent, flexible, and non-conductive membrane 60. An inductor core 90, is orthogonally centered thru the semi-translucent lens 80, thru the center of the conductive ring 70, thru the flexible membrane 60, thru the transparent surface 40, thru the semi-resistive photo-sensitive material 30, and affixed to the non-conductive concave manifold 10.

[0014] FIG. 2 shows a container 110, with an affixed semi-translucent lens 120 inserted and descended below the top region of the container 110, and an orthogonally centered inductor core 100, affixed at its base 230, is inserted thru the semi-translucent lens with a perforated and geometrically etched patterned opening 130. The semi-translucent lens is etched and perforated with a geometric pattern 140. A transparent, flexible, and non-conductive membrane 160, embedded with a conductive ring 170, is affixed to a conductive lead 190, and located adjacent a translucent lens 120. A non-conductive transparent surface manifold layered with a semi-resistive quantum material 200, etched with conductive trace pits 180, is affixed and located adjacent the flexible non-conductive membrane 160. A concave non-conductive surface area layered with a semi-resistive quantum material 210 and etched with conductive leads 220, are geometrically arranged and inserted thru the concave non-conductive surface 210.