Design of quantum gravity sensor by curvature energy and their encoding

Using fine electromagnetic signals to measurable observables of fields like curvature and torsion of a space and the corresponding value of their integrals of the action of perception of curvature through of electronic signals that detect curvature on a curved space, are designed several electronic and photonic sensors of accelerometer type to curvature based in the principle of curvature energy to different scales and interaction field considering their behavior as a non-harmonic signal, which is an effect that characterizes the curvature as a deformation of field in the corresponding resonance space and an obstruction to the displacement to the corresponding shape operator. Finally considering the quantized version of the curvature as observable of field where the space is distorted by the strong interactions between particles, and through the same concept of curvature energy, is conjectured and designed a possible sensor to detect and measure curvature of the space-time from the concept of quantum gravity interpreting their observable in this case, as light fields deformations obtained on space-time background. To the application of this measurement we use a hypothetical particle graviton modeled as dilaton which must be gauge graviton (gauge boson).