Measuring aircraft altimetry system error using automatic dependent surveillance-broadcast data / Kalyani Bahskaran
The International Civil Aviation Organization (ICAO) introduced Reduced Vertical Separation Minima (RVSM) globally to support increasing traffic volumes on congested airspace. RVSM focused on reducing vertical separation minimum from 2000 feet to 1000 feet between flight level FL290 and FL410. Im...
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| Format: | Thesis |
| Published: |
2021
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| Online Access: | http://studentsrepo.um.edu.my/14730/1/Kalyani.pdf http://studentsrepo.um.edu.my/14730/2/Kalyani_Bahskaran.pdf http://studentsrepo.um.edu.my/14730/ |
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| Summary: | The International Civil Aviation Organization (ICAO) introduced Reduced Vertical
Separation Minima (RVSM) globally to support increasing traffic volumes on congested
airspace. RVSM focused on reducing vertical separation minimum from 2000 feet to 1000
feet between flight level FL290 and FL410. Implementation of RVSM stresses the accuracy
of aircraft avionics that report altitude and requires the Regional Monitoring Agency (RMA)
to monitor the aircraft's Height Keeping Performance (HKP) to ensure the aviation safety of
their airspace. Presently, air traffic and navigation are controlled by an air traffic controller
on the ground based on the pressure altitude value, also known as a flight level (FL) measured
with barometric altimeter. The pressure altitude was subjected to errors due to various factors
including instrument defect, obstructed airflow, presence of foreign materials into the system,
variations of temperature and humidity. Altimetry System Error (ASE) is the difference
between the actual altitude based on SI units and the pressure altitude displayed. ASE
possesses risk to the aviation industry as it is an invisible to the pilots during the flight.
According to ICAO, ASE value must be less than 245 feet to ensure the safety of the aircraft.
Currently, some of the airspace operators that implement RVSM in their airspace installs
Height Monitoring Unit (HMU) on the ground to monitor the aircraft HKP in their airspace.
However, HMU methods are disposed to drawbacks. It requires high implementation and
maintenance costs, low scalability, and the requirement to have professionals on board to
operate the equipment. Alternatively, this research aims to measure the ASE using geometric height data derived from Automatic Dependent Surveillance-Broadcast (ADS-B) message,
which is transmitted to the Air Traffic Control (ATC) in the ground. Aircrafts in different
regions has been instructed to be equipped with transponders by their authorities. Hence, the
ready availability of ADS-B data can be utilized to study the HKP of the aircrafts. This
research identifies a process to measure the ASE values using ADS-B data. Subsequently, a
computer algorithm and interfacing tool is developed. The tool enables any personal with
basic computer literacy and access to the tool and data file to process the data and asses the
HKP of the flight at ease. The algorithm reads inputs of the ADS-B data file, stores all the
required fields for processing either all or a single flight, and finally the ASE will be
calculated. ASE value is calculated by subtracting Flight Level from the Orthometric Height
of the aircraft. Orthometric height is calculated using the Geoid Height derived using the
EGM96 Geopotential Model. A scatter graph is outputted displaying the FL, Datetime, and
ASE values to visualize the ASE pattern and compliance throughout the flight duration. The
algorithms’ accuracy is evaluated against the method adopted by China RMA comparing the
Mean ASE values returned 98.84% accuracy using the same dataset. Further studies require
incorporating the algorithm into the real-time Air Traffic Controller System and can be
further improved with the Big Data Analytics approach in the future when it comes to
processing more volume and variety of data.
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