Implementation of a Transportable Radar Mode S of Monopulse Secondary Surveillance (MSSR-S) for the Peruvian Civil Aviation Surveillance-Reference-Cited by-同舟云学术

Implementation of a Transportable Radar Mode S of Monopulse Secondary Surveillance (MSSR-S) for the Peruvian Civil Aviation Surveillance

Published:2023-10-03 Issue:4 Volume:4 Page:693-708
ISSN:2673-4001
Container-title:Telecom
language:en
Short-container-title:Telecom

Author:

Vidal Luis. E.¹²³,Concha Ulises Román¹²³^ORCID,Solís Justo¹²³,Piedra José¹²³,Chávez Carlos¹²³,Cano Dominga M.¹²³,Woolcott Juan C.¹²³

Affiliation:

1. Electronics and Computing Faculty, Federico Villarreal University, Lima 15007, Peru

2. Systems Engineering and Computing Faculty, Chemistry and Chemistry Engineering Faculty, National University of San Marcos, Lima 15081, Peru

3. Industrial Processes Faculty, National University of Juliaca, Juliaca 21101, Peru

Abstract

This article describes the process of implementing a transportable radar MSSR-S for Peruvian civil aviation (ACP) to minimize the operational impact in emergencies that affects air traffic without causing structural damage and restore data from the radar in a short time. In recent years, ACP has shown constant falls in the radars, causing radar data to be lost for long periods of time and putting air safety at risk due to the lack of maintenance and overlapping radar coverage of more than three radars. The deployment of the transportable radar in Mode S of Monopulse Secondary Surveillance (MSSR-S) has allowed for work that involves the prolonged stoppage of the radar to be carried out and provided coverage to eight more radars during maintenance and modernization, covering the areas without coverage in the Peruvian air space (EAP). For the implementation, this was divided into three SPRINTs using the SCRUM methodology; the first sprint refers to the equipment and radar coverage study, the second the implementation and service test phase, and the third the operational analysis phase with the eight modernized radars. As a result of the implementation and integration with the other ACP radar systems, they were able to operate together, providing highly reliable radar data, performing a continuous analysis of radar performance through the PASS software, complying with the thresholds established by ICAO and EuroControl, and guaranteeing that the systems operate under perfect conditions and with full coverage at all time.

Publisher

MDPI AG

Subject

Electrical and Electronic Engineering,Computer Networks and Communications

Link

https://www.mdpi.com/2673-4001/4/4/31/pdf

Reference14 articles.

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