Sofia Toto scite author profile

Sofia Toto

4Publications

17Citation Statements Received

64Citation Statements Given

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Affiliations

Karlsruhe Institute of Technology

Publications

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Design and Simulation of a Wireless SAW–Pirani Sensor with Extended Range and Sensitivity

Toto

Nicolay

Morini

et al. 2019

Sensors

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Pressure is a critical parameter for a large number of industrial processes. The vacuum industry relies on accurate pressure measurement and control. A new compact wireless vacuum sensor was designed and simulated and is presented in this publication. The sensor combines the Pirani principle and Surface Acoustic Waves, and it extends the vacuum sensed range to between 10−4 Pa and 105 Pa all along a complete wireless operation. A thermal analysis was performed based on gas kinetic theory, aiming to optimize the thermal conductivity and the Knudsen regime of the device. Theoretical analysis and simulation allowed designing the structure of the sensor and its dimensions to ensure the highest sensitivity through the whole sensing range and to build a model that simulates the behavior of the sensor under vacuum. A completely new design and a model simulating the behavior of the sensor from high vacuum to atmospheric pressure were established.

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Toward a Compact Wireless Surface Acoustic Wave Pirani Microsensor with Extended Range and Sensitivity

Toto

Nicolay

Morini

et al. 2020

Heat Transfer Engineering

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A wireless vacuum sensor based on the Pirani principle and Surface Acoustic Waves (SAW) has been designed, simulated and manufactured. The sensing unit is a heat conductivity gauge based on a passive SAW temperature sensor. The required heating energy is applied to the sensor by means of inductive coupling whereas the measurement signal is sent via a ceramic antenna. The sensor is a compact polymer cube containing all the units and operating completely wireless. Simulation was used to design and optimize the behavior of the sensor in vacuum and to predict the performances of the sensor. It was followed by the manufacturing and the assembly of a prototype. This communication presents the design, the simulation results and the manufacturing steps of the prototype.

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Characterization of a Wireless Vacuum Sensor Prototype Based on the SAW-Pirani Principle

et al. 2020

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A prototype of a wireless vacuum microsensor combining the Pirani principle and surface acoustic waves (SAW) with extended range and sensitivity was designed, modelled, manufactured and characterised under different conditions. The main components of the prototype are a sensing SAW chip, a heating coil and an interrogation antenna. All the components were assembled on a 15 mm × 11 mm × 3 mm printed circuit board (PCB). The behaviour of the PCB was characterised under ambient conditions and in vacuum. The quality of the SAW interrogation signal, the frequency shift and the received current of the coil were measured for different configurations. Pressures between 0.9 and 100,000 Pa were detected with sensitivities between 2.8 GHz/Pa at 0.9 Pa and 1 Hz/Pa close to atmospheric pressure. This experiment allowed us to determine the optimal operating conditions of the sensor and the integration conditions inside a vacuum chamber in addition to obtaining a pressure-dependent signal.

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Correction: Design and Simulation of a Wireless SAW–Pirani Sensor with Extended Range and Sensitivity

Toto

Nicolay

Morini

et al. 2019

Sensors

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Sofia Toto

Design and Simulation of a Wireless SAW–Pirani Sensor with Extended Range and Sensitivity

Toward a Compact Wireless Surface Acoustic Wave Pirani Microsensor with Extended Range and Sensitivity

Characterization of a Wireless Vacuum Sensor Prototype Based on the SAW-Pirani Principle

Correction: Design and Simulation of a Wireless SAW–Pirani Sensor with Extended Range and Sensitivity

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