Tofig M. Mansurov, Azerbaijan Technical University, Baku, Azerbaijan
Chingiz P. Aliyev, Ministry of Defense Industry, Baku, Azerbaijan

DOI: 10.36724/2664-066X-2020-6-6-10-16

SYNCHROINFO JOURNAL. Volume 6, Number 6 (2020). P. 10-16.


The results of many years of research on the subject of intellectual counteraction to cyberattacks are presented. Cloud solutions for the synthesis of the monitoring cluster of cyberattacks are based on the latest achievements with the use of neuron-fuzzy formalism. The main features of the synthesis of protection functions are determined and the features of the implementation of the security system of the object of risk in cyberspace are analyzed. Methodological approaches to solving the system problem of determining all ways of penetration of the attack on the object of risk and the formation of variants of their coatings are proposed. The peculiarities of applicability of the branch and boundary method for solving this problem are discussed. Analysis of structural construction of existing three-dimensional accelerometers is carried out, in which due to the opposite direction of sensitivity vectors and direction of measured inertial force, they allow to measure only linear inertia and accelerations varying in relatively small limits. On the other hand, due to the presence of elements in them that create electromagnetic fields, their construction is somewhat complicated. In addition, in known accel-erometers, due to the absence of a measurement object position sensor and an electronic control circuit, the func-tionality of the accelerometer is limited, Due to lack of integrator for acceleration integration, speed measurement is not provided, Due to rigid attachment of piezoelectric sensing elements through their bases, during measurement they generate interference signals, The amplitude of which exceeds the amplitude of the useful signal, which does not ensure reliability of the measured acceleration or speed and due to the presence of sensitive piezoelectric ele-ments, Having higher rigidity and requiring relatively large mechanical forces for generation of signals during mo-tion of acceleration and speed measurement object in automatic mode, which reduces sensitivity of accelerometer.
Invention proposes new design and control scheme of three-dimensional piezoelectric accelerometer for measure-ment of dynamic parameters of moving objects in automatic mode. Wherein providing the position sensor of the moving measurement object with a three-axis signal detection unit to determine a direction of motion with meas-urement of acceleration or linear velocity when the measurement object moves along the coordinate axis; With the help of differential operational amplifiers through pulse generators and integrators, Speed measurement is provided by damping piezoelectric elements when the measurement object moves along one of the coordinate axes; Across the other two axes, the generated interference signals by amplitude are significantly reduced by their redemption; Having a piezoelectric element in the structure in the form of two-layer flat plates with an excitation section and a sensor section; Which generates signals at fast-changing acceleration and speed of moving object, amplitude of signal and sensitivity increases in 4-5 due to generation of signal by sensitive elements in vibration excitation mode created in accelerometer. Mathematical basis for accelerometer control circuits, mathematical model of its functioning is developed, applica-tion of which increases sensitivity of measurement of linear accelerations and speeds of moving objects and expands functional capabilities.

Keywords: accelerometer, piezoelectric element, sensitivity vector, inertial force, linear acceleration, velocity, vibration measurement.


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