Design of fiber optical sensor for atmospheric electric field measurement

1. H.V. Baghdasaryan, A.V. Daryan*, T.M. Knyazyan Design of fiber optical sensor for atmospheric electric field measurement Fiber Optics Communication Laboratory, State Engineering University of Armenia,105 Terian str., Yerevan 0009, Armenia *A.Alikhanyan National Laboratory, Cosmic Ray Division, 2 Alikhanyan brothers str., Yerevan 0036, Armenia E-mail: hovik@seua.am TEPA-2015,  October 5-9, Byurakan, Armenia

2. Atmospheric Electric Circuit An equivalent diagram of the atmospheric electric circuit The atmospheric electric circuit http://incompliancemag.com/article/charges-are-forever-2/ TEPA-2015,  October 5-9, Byurakan, Armenia

3. Atmospheric Electric field detection TEPA-2015,  October 5-9, Byurakan, Armenia

4. The atmospheric electric field In a clean sky day the atmosphere is home of a  electric field with intensity of 100 V/m, produced of a superficial  negative discharge.  When a storm is approaching  discharges are distributed as shown in picture: the clouds base is strongly negative, so, given its closeness to the ground  of 2-3 Km. It is forming an electric field of about 1000 V/m with a potential difference  between clouds and ground of 2 – 3 millions Volts.  http://www.vlf.it/nrs/nrs.htm TEPA-2015,  October 5-9, Byurakan, Armenia

5. Different antenna configurations for electric field measurements in the atmosphere (a) Disc antenna. (b) Whip antenna. (c) Whip antenna with radioactive probe. (d) Long wire antenna. http://a-tech.net/ElectricFieldMill/ TEPA-2015,  October 5-9, Byurakan, Armenia

6. Electric field measurement by field mill http://a-tech.net/ElectricFieldMill/ http://tikalon.com/blog/blog.php?article=2013/electric_Kelvin TEPA-2015,  October 5-9, Byurakan, Armenia

7. Probe influence on electric field distribution TEPA-2015,  October 5-9, Byurakan, Armenia

8. Conventional antenna measurement systems Optical Fiber Electric Field Sensor for Antenna Measurement Hiroyoshi Togo†, Shoji Mochizuki, and Naoya Kukutsu NTT Technical Review 2004 TEPA-2015,  October 5-9, Byurakan, Armenia

9. Application of electro-optic crystal as sensing element Electric field or discharge impulse can be precisely measured by the highly sensitive optical interference through Mach-Zehnder interferometer fabricated on a LiNbO3 electro-optical crystal substrate wafer. TEPA-2015,  October 5-9, Byurakan, Armenia

10. Integrated Mach-Zehnder interferometer Periodic relation of transmitted power and voltage difference in a Mach--Zehnder modulator, with UÏ€ being the voltage difference between zero transmission and full power transmission. Lightwave, March 7, 2014. TEPA-2015,  October 5-9, Byurakan, Armenia

11. New antenna measurement systems Optical Fiber Electric Field Sensor for Antenna Measurement Hiroyoshi Togo†, Shoji Mochizuki, and Naoya Kukutsu NTT Technical Review 2004 TEPA-2015,  October 5-9, Byurakan, Armenia

12. Basic principle of electric-field measurement using Pockels effect. Optical Fiber Electric Field Sensor for Antenna Measurement Hiroyoshi Togo†, Shoji Mochizuki, and Naoya Kukutsu NTT Technical Review 2004 TEPA-2015,  October 5-9, Byurakan, Armenia

13. Fiber based full optical electric field sensor S. M. Chandani, “Fiber-Based Probe for Electrooptic Sampling,” IEEE Photon. Technol. Lett. 18(12), 1290–1292 (2006). TEPA-2015,  October 5-9, Byurakan, Armenia

14. Fiber based full optical electric field sensor Schematic of fiber-edge probe structure based on Fabry-Perot micro-resonator Block diagram of system configuration is shown. All the optical components are connected by optical fibers. S. Wakana, E. Yamazaki, S. Mitani, H. Park, M. Iwanami, S. Hoshino, M. Kishi, and M. Tsuchiya, “Fiber-Edge Electrooptic/Magnetooptic Probe for Spectral-Domain Analysis of Electromagnetic Field,” IEEE Trans. Microw. Theory Tech. 48(12), 2611–2616 (2000). TEPA-2015,  October 5-9, Byurakan, Armenia

15. Electro-optic sensing Gires-Tournois structure For LiNbO3 At TEPA-2015,  October 5-9, Byurakan, Armenia