The Mathematical Model of Radio-measuring Frequency Transducer of Optical Radiation Based on MOS Transistor Structures with Negative Differential Resistance

et al. 2023

IAPGOS

A self-oscillating parametric humidity sensor has been developed that implements the principle of "humidity-frequency" conversion into hybrid integrated circuit based on a microelectronic transistor structure with a negative differential resistance, in which the humidity-sensitive element is a resistor of the HR202 type. For the purposes of determining parameters self-oscillating parametric humidity sensor with frequency output a mathematical model has been developed that takes into account the effect of humidity on a sensitive resistive element, which is an integral element of the device. Based on the mathematical model, analytical expressions for the transformation function and the sensitivity equation are obtained. It is shown that the main contribution to the conversion function is made by relative humidity. The computer simulation and experimental studies of a self-oscillating parametric humidity sensor with a frequency output signal contributed to obtaining the main parameters and characteristics, such as the dependence of the generation frequency on changes in relative humidity in the range from 30% to 99%, the change in sensitivity on relative humidity, the dependence of the active and reactive components of the impedance in the frequency range from 50 kHz to 2 GHz; standing wave ratio, change in logarithmic magnitude and spectra of the output signal of a parametric humidity sensor with a frequency output signal in the LTE-800 Downlink frequency range. The obtained electrical characteristics confirm the operability of the developed device. The sensitivity of the developed self-oscillating parametric humidity sensor in the range of relative humidity change from 30% to 99% has a value from 332.8 kHz/% to 130.2 kHz/%.

Section: Introductionmentioning

confidence: 99%

Self-Oscillating Parametric Humidity Sensor With Frequency Output Signal

et al. 2023

IAPGOS

“…The frequency principle of operation of pressure sensors has several advantages: high measurement accuracy; high noise immunity; the simplicity of design; no influence of measuring channels on each other; the ability to transmit measurement information over a distance without wired communication; no need to use analog-to-digital converters during the subsequent processing of information signals; the ability to create "intelligent" pressure sensors. These advantages are good reason to carry out extensive studies of the properties of tunneling resonant diodes not only as pressure sensors, but also as generators, switches, logic elements, resonant amplifiers, memory devices, and others [4][5][6]. However, regarding pressure sensors based on resonant tunnel diodes, a mathematical model that describes the analytical dependences of all elements of the equivalent circuit on pressure has not yet been fully developed.…”

Section: Introductionmentioning

confidence: 99%

Mathematical model of a frequency pressure transducer based on a resonant tunneling diode

2022

Phys. Chem. Solid St.

The paper presents the design of pressure sensor with a frequency output signal that is based on the physical processes in a resonant tunnel diode under the action of pressure. The use of devices with negative differential resistance can significantly simplify the design of pressure sensors in the entire radio frequency range. Depending on the operating modes of the sensor, an output signal can be obtained in the form of harmonic oscillations. Pressure sensor characteristics researches based on complete equivalent circuit diagram resonant tunnel diode, which takes into account its capacitive and inductive properties. A mathematical model of the pressure sensor was developed, upon which the analytical dependences of the change in the elements tunnel resonance diode from pressure have been determined, as well as conversion functions and sensor sensitivity. It is shown that the main contribution to changes in the conversion function and sensor sensitivity is made by the change in the negative differential resistance with the change in pressure. This, in turn, results in different readings of the instrument's output frequency. The sensitivity of the sensor varied from 1.15 kHz/Pa·105 to 14.16 kHz/Pa·105 in the pressure range from 50·105 Pa up to 350·105 Pa.

“…Leading specialists of the world are developing and creating transducers of physical quantities. The values of physical quantities (such as temperature, humidity, density and others) of a gas mixture (air) significantly affect the well-being of a person and the quality of technological processes in microelectronics and various industries [4][5][6][7]. In our work, the emphasis is on temperature.…”

Section: Introductionmentioning

confidence: 99%

Investigation of a radio-frequency temperature transducer with a thermosensitive resistive element based on a complex compound of heterometallic β-diketonate

IOP Conf. Ser.: Mater. Sci. Eng.

et al. 2022

The article considers a new electrical circuit of a microelectronicradio-frequency measuring temperature transducer with a thermosensitive resistive element based on a complex compound of heterometallicβ-diketonate.The main characteristics of the researched radio-frequency temperature transducer with a thermosensitive resistive element based on a complex compound of heterometallic β-diketonate are obtained: the dependences of the active and reactive components of the full impedance of the radio-frequency measuring temperature transducer, the conversion function and the sensitivity equation.