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An experimental control system for electron spectrometers using Arduino and LabVIEW interfaces.
Manish Patel1, Ahmad Sakaamini1, Matthew Harvey1
1Photon Science Institute, Department of Physics and Astronomy, Faculty of Science and Engineering, University of Manchester, Manchester M13 9PL, United Kingdom.
A low-cost, modular control system using LabVIEW and Arduino was developed for electron spectrometers. This system enables diverse experiments like electron scattering and ionization, offering a customizable solution for researchers.
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Area of Science:
- Experimental physics
- Spectroscopy
- Control systems engineering
Background:
- Electron spectrometers require precise control for various experiments.
- Existing control systems can be expensive and inflexible.
- Need for adaptable and affordable experimental setups.
Purpose of the Study:
- To describe a modular, customizable, and low-cost experimental control system for electron spectrometers.
- To demonstrate the system's capability in performing diverse measurements.
- To present results from specific electron spectroscopy experiments.
Main Methods:
- Utilized LabVIEW software for system integration and control.
- Interfaced LabVIEW with Arduino-controlled power supplies, detectors, and stepper motors.
- Developed modular Arduino-based hardware components for flexibility.
Main Results:
- Successfully implemented a functional control system for electron spectrometers.
- Demonstrated the system's versatility through electron scattering experiments.
- Showcased the system's utility in electron impact ionization studies.
Conclusions:
- The developed LabVIEW-Arduino system provides a cost-effective and adaptable solution for electron spectroscopy.
- The modular design allows for customization to various experimental needs.
- The system facilitates a range of electron-based measurements, including scattering and ionization.