Your search keyword '"fiber splitter"' showing total 4 results

1. Performance Comparison of Power Divider and Fiber Splitter in the Fiber-Based Frequency Transmission System of Solar Radio Observation

Author

Yuqing Liu, Daopeng Ren, Fabao Yan, Zhao Wu, Zhen Dong, and Yao Chen

Subjects

Synthetic aperture heliograph, fiber-based time and frequency synchronization, power divider, fiber splitter, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Time-frequency synchronization plays an important role in the construction of solar radio telescopes (such as heliograph and interferometry). In the development of a synchronization system, time-frequency signal is divided and transmitted to each antenna in an array, therefore, the performance of the signal splitting devices determines the quantity of the data. To address this situation, we designed a frequency transmitting system, and conducted a test to compare the phase difference among outputs (10 MHz - 1.4 GHz), and the deterioration of the frequency stability (10 MHz - 1GHz) brought by different splitting devices (fiber splitter and power divider). The following results had been obtained: 1) Phase difference introduced by both fiber splitter and power divider can be restricted in a range of ±4°, and the fiber splitter is rather stable, which indicate that a better imaging effect of heliograph can be achieved when using fiber splitters. 2) Frequency stability deterioration get better (worse) with increasing temperature for fiber splitter (power divider) in the testing frequency range for a short-time sampling (100 ms), and for a long-time sampling (10 min), the frequency stability of different devices is determined by both temperature and signal frequency. By estimating the SNR, the performance of optical splitter is found to be slightly better than power splitter. This article provides a basis for the selection and compensation of frequency transfer system components for integrated aperture heliograph, and provide a feasible solution of the construction of low-cost radioheliograph.

Published

2021

2. Discrete liquid level fiber sensor.

Author

Noor, Muhammad Yusof Mohd, Abdullah, Ahmad Sharmi, Azmi, Asrul Izam, Ibrahim, Mohd Haniff, Salim, Mohd Rashidi, and Kassim, Norazan

Subjects

*FIBERS, *DETECTORS, *LIGHT sources, *HEIGHT measurement

Abstract

A novel simple fiber sensor to sense liquid level is presented. The operation principle is based on the relative Fresnel reflective intensity. The sensor consists of a fiber splitter with the configuration of one input to multiple fiber outputs, i.e. 1×4, 1×8 and 1×12 arrangements that act as a discrete liquid level. A broadband source (BBS) is used as the light source supply. The total reflected power intensity is measured using a power meter. Experimental results show that the power intensity decreases as the level of liquid is increased. The sensor has a simple configuration, low cost, and it can be customized for a wide height measurement range spanning from a few centimeters up to a hundred meters. [ABSTRACT FROM AUTHOR]

Published

2019

3. Performance Comparison of Power Divider and Fiber Splitter in the Fiber-Based Frequency Transmission System of Solar Radio Observation

Author

Liu Yuqing, Daopeng Ren, Fabao Yan, Yao Chen, Dong Zhen, and Zhao Wu

Subjects

010504 meteorology & atmospheric sciences, General Computer Science, 01 natural sciences, Signal, Synchronization (alternating current), fiber splitter, Optics, 0103 physical sciences, Fiber optic splitter, General Materials Science, 010303 astronomy & astrophysics, Heliograph, power divider, 0105 earth and related environmental sciences, Physics, fiber-based time and frequency synchronization, business.industry, General Engineering, Synthetic aperture heliograph, Interferometry, Splitter, Power dividers and directional couplers, lcsh:Electrical engineering. Electronics. Nuclear engineering, Antenna (radio), business, lcsh:TK1-9971

Abstract

Time-frequency synchronization plays an important role in the construction of solar radio telescopes (such as heliograph and interferometry). In the development of a synchronization system, time-frequency signal is divided and transmitted to each antenna in an array, therefore, the performance of the signal splitting devices determines the quantity of the data. To address this situation, we designed a frequency transmitting system, and conducted a test to compare the phase difference among outputs (10 MHz - 1.4 GHz), and the deterioration of the frequency stability (10 MHz - 1GHz) brought by different splitting devices (fiber splitter and power divider). The following results had been obtained: 1) Phase difference introduced by both fiber splitter and power divider can be restricted in a range of ±4°, and the fiber splitter is rather stable, which indicate that a better imaging effect of heliograph can be achieved when using fiber splitters. 2) Frequency stability deterioration get better (worse) with increasing temperature for fiber splitter (power divider) in the testing frequency range for a short-time sampling (100 ms), and for a long-time sampling (10 min), the frequency stability of different devices is determined by both temperature and signal frequency. By estimating the SNR, the performance of optical splitter is found to be slightly better than power splitter. This article provides a basis for the selection and compensation of frequency transfer system components for integrated aperture heliograph, and provide a feasible solution of the construction of low-cost radioheliograph.

Published

2021

4. Discrete liquid level fiber sensor

Author

Norazan Mohd. Kassim, Muhammad Yusof Mohd Noor, Ahmad Sharmi Abdullah, Mohd Haniff Ibrahim, Asrul Izam Azmi, and Mohd Rashidi Salim

Subjects

Materials science, business.industry, 010401 analytical chemistry, 020206 networking & telecommunications, 02 engineering and technology, Sense (electronics), Fresnel equations, 01 natural sciences, Fresnel reflection, 0104 chemical sciences, environmental applications, fiber splitter, Optics, Electricity meter, Splitter, Broadband, reflected power, 0202 electrical engineering, electronic engineering, information engineering, Range (statistics), liquid level sensor, Fiber, Electrical and Electronic Engineering, business, Intensity (heat transfer)

Abstract

A novel simple fiber sensor to sense liquid level is presented. The operation principle is based on the relative Fresnel reflective intensity. The sensor consists of a fiber splitter with the configuration of one input to multiple fiber outputs, i.e. 1×4, 1×8 and 1×12 arrangements that act as a discrete liquid level. A broadband source (BBS) is used as the light source supply. The total reflected power intensity is measured using a power meter. Experimental results show that the power intensity decreases as the level of liquid is increased. The sensor has a simple configuration, low cost, and it can be customized for a wide height measurement range spanning from a few centimeters up to a hundred meters.

Published

2019