Content uploaded by M. Rizaludin Mahmud
Author content
All content in this area was uploaded by M. Rizaludin Mahmud on Dec 31, 2017
Content may be subject to copyright.
Journal of Physics: Conference Series
PAPER • OPEN ACCESS
Installing the earth station of Ka-band satellite
frequency in Malaysia: conceptual framework for
site decision
To cite this article: M R Mahmud et al 2017 J. Phys.: Conf. Ser. 852 012040
View the article online for updates and enhancements.
Related content
A conceptual framework to analyse the
effects of environmental change on
ecosystem services
Paula Harrison, M Rounsevell, G Luck et
al.
-
Current evolution and plasma density
space distribution in the reflex discharge
with ring cathodes
A A Samokhin, G D Liziakin, A V Gavrikov
et al.
-
A Conceptual Framework for Procurement
Decision Making Model to Optimize
Supplier Selection: The Case of Malaysian
Construction Industry
Ngam Min Chuan, Sivadass Thiruchelvam,
Kamal Nasharuddin Mustapha et al.
-
This content was downloaded from IP address 161.139.222.22 on 31/12/2017 at 07:20
1
Content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence. Any further distribution
of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.
Published under licence by IOP Publishing Ltd
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
Installing the earth station of Ka-band satellite frequency in
Malaysia: conceptual framework for site decision
M R Mahmud¹,², M N M Reba¹,², S W Jaw ¹,², A Arsyad² and M A M Ibrahim²
1Department of Geoinformation, Faculty of Geoinformation& Real Estate, UniversitiTeknologi
Malaysia, 81310, Skudai, Johor Bahru, Malaysia
2Geoscience & Digital Earth Centre, Research Institute for Sustainable Environment,
Universiti Teknologi Malaysia, 81310, Skudai, Johor Bahru, Malaysia
E-mail : rizaludin@utm.my
Abstract. This paper developed a conceptual framework in determining the suitable location in
installing the earth station for Ka-band satellite communication in Malaysia. This current
evolution of high throughput satellites experienced major challenge due to Malaysian climate.
Because Ka-band frequency is highly attenuated by the rainfall; it is an enormous challenge to
define the most appropriate site for the static communication. Site diversity, a measure to
anticipate this conflict by choosing less attenuated region and geographically change the
transmission strategy on season basis require accurate spatio-temporal information on the
geographical, environmental and hydro-climatology at local scale. Prior to that request, this
study developed a conceptual framework to cater the needs. By using the digital spatial data,
acquired from site measurement and remote sensing, the proposed framework applied a
multiple criteria analysis to perform the tasks of site selection. With the advancement of high
resolution remotely sensed data, site determination can be conducted as in Malaysia;
accommodating a new, fast, and effective satellite communication. The output of this study is
one of the pioneer contributions to create a high tech-society.
1. Introduction
The evolution of broadcast satellites using Ka-band frequency instead of the existing Ku-band is an
emerging trend towards faster, cheaper, and efficient communication. This is because the new mode of
high throughput satellites using Ka-band allowed extensive frequency reuse enabled larger amount of
bandwidth support for higher transmission rates, and utilization of smaller but efficient antennas [1,2].
This advancement qualities would be strategic in addressing the growing needs of the increasing
population and economy of Malaysia (~30 million, [3]); one of the rapidly developing semi industrial-
agriculture country in Southeast Asia. However, the major drawback of this Ka-band in this region is
their strong attenuation effects from large size water droplet of rainfall from atmospheric to ground.
Scientifically, the increasing frequency of Ka-band (26 – 40 GHz) would increase the speed of
signal transmission and shortened the wavelength. The aftermath of this condition in humid tropics is
the limitation to penetrate over intense rainfall with larger water droplets [4]. Literature has shown that
the diameter of the rainfall in the tropics is relatively larger [5,6]. One of the effective strategy to
overcome this constraint is via site diversity; selecting the area with less rainfall for satellite
communication and diversifying the selection according to the local-scale wet seasons [7]. In
Malaysian context, it is wise to decide based on a fine resolution of climatology data due to its high
2
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
dynamic climatological pattern [8]. In addition, we also should consider the environmental aspect of
the sites, its logistics and strategic condition.
Achieving both objectives can be materialized with the availability of the innovated climatology
products and usage of Geographical Information System (GIS). A proper conceptual framework would
be a pioneer effort in promoting this potential technology to a local scene. The design conceptual
framework should be adhered a right product, approach and results which fit the local scale
environmental and climatology characteristics. This study tends to occupy that effort by developing
the conceptual framework based on integrated satellite-improved climatology input data that operated
on GIS environment.
2. Dealing with the attenuation factors by hydro-climatology factors in Peninsular Malaysia
Peninsular Malaysia categorized as humid tropical region with perature of 26° Celcius throughout the
year and annual rainfall of 2500mm. With no dry season, the hydro-climatology is driven by monsoon
flows. The northeast monsoon (Nov.-Jan.) constitutes the heaviest rainfall especially to the east part
(200-500mm/month). The southwest and inter-monsoon period (Jul.-Oct.) resulted second heavy
rainfall which concentrated on the west region. Added the effect from high elevation areas of the
Titiwangsa fringe, the local rainfall pattern can be highly heterogeneous especially during the non-
monsoon season [9] (Figure 1).
Figure 1. Peninsular Malaysia and its seasonal rainfall variation
3
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
Due to this humid tropics and dynamic monsoon seasons; the attenuation of Ka-band frequency not
only come from rain, but also the precipitable water in the atmosphere [10]. Considering the sky-free
condition is depending on seasonality of monsoon flows, the wise option is to employ a selection with
seasonal weightage. This can only be materialized by using high resolution hydro-climatology data;
which now available to be obtained from satellites and publicly accessed.
3. High resolution of satellite hydro-climatology data & geographic computing
The advancement of remote sensor, retrieval algorithm and data sharing has significantly improved the
representation of hydro-meteorological variables at both local and global scale. The high availability
of such data especially one from microwave scanning [11,12] provides a perfect opportunities to
tropical region, where large vapors converged, cloud formed, and rainfall downpours were indicated; a
useful option to our framework.
Integration of those data with series of logical condition, programmed by geographic computing or
GIS, enabled us to precisely determine the appropriate site. Given that all the data were correctly
projected and the resolution is fine enough, successful data manipulation can be obtained. Those two
criteria is our core to this conceptual framework.
4. Conceptual framework for site selection
The developed conceptual framework emphasize the following logic in sequential manner; (a) rainfall,
precipitable water, & water vapor effects to Ka-band frequency, (b) sensitive areas which restricted for
developments, and (c) strategic and logistics factors. Figure 2 summarized the design framework.
This conceptual framework utilized spatial-based decision making, where the site would be
determine as multi-criteria analysis, followed the design condition in Table 1. A geographical
information system usage is optimized where all the queries, display, analysis and storage of large
databases, were implemented.
The pixels which fit the design condition will be given a higher score and vice versa. This method
is chosen because it is relative; so relative description is the best option. At the end of the process (a),
(b), and (c), is the map with selected pixels with different score; how suitable is the pixels for the earth
station installation.
4.1 Attenuation from rainfall, precipitable water, & water vapor
For the first conditions, the primary goal is to determine the attenuation level contributed by rainfall,
precipitable water, & water vapor. Because of the dominant effects of monsoon flows, it is best to
quantify it temporally according to the monsoon season. Regarding the attenuation model, the
utilization of the approach from International Telecommunication Union (ITU) was recommended.
The following attenuation computation procedures for rain, cloud and water vapor from [13], [14], and
[15] respectively can be utilized. This is to ensure that the attenuation was computed following the
standard operation procedures.
The input of this part should be able to represent an effective spatio-temporal dimension to
represent its corresponding subject of interest; at least ~5km grid. For rainfall, input from dense rain
gauge network should be the first priority. Substitute or support information from other apparatus,
such as precipitation radar or satellites can be considered. For precipitable water and water vapor, an
input from the atmospheric & meteorological satellites or fine climatological model is the best option.
In measuring total column of precipitable water and vapor, among the data that fit our objective are
from The Special Sensor Microwave Imager (SSM/I), Special Sensor Microwave Imager Sounder
(SSMI), TRMM Microwave Imager (TMI), The Advanced Microwave Scanning Radiometer (AMSR)
or from the web-host that supply integrated products from various satellites such as the operational
Microwave Integrated Retrieval System (MIRS) and the Morphed Integrated Microwave Imagery
(MIMIC) (16).
In term of frequency selection, because the effective frequency Ka-band (~26-40 GHz) in tropical
region is varies via location [17], selecting samples according to the constant interval is suggested.
4
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
After the attenuation rates for each parameter were obtained, the areas which have higher attenuation
is ranked low and vice versa. In addition, the Ka-band attenuation effects were strongly influenced by
larger water droplets, therefore, it is suggested that the weightage is assign to give emphasis in the
following orders; rain, precipitable water, and vapor.
Table 1. Summary of the input, condition and ranking system of the developed conceptual framework
Phase
Input
Condition
Ranks
1
2
3
4
5
Least
suitable
Moderately
suitable
Fairly
suitable
Suitable
Most
suitable
Phase 1 -
Attenuation
from
rainfall,
precipitable
water &
atmospheric
water vapor
Monthly maps:
Rainfall
Precipitable water
Water vapor
Attenuation model:
Attenuation co-
efficient
Viewing angle
Selective frequency
from 26-40GHz
Attenuation
rate
Maximum attenuation rate ----> Minimum
attenuation rate
Phase 2 -
Sensitive
areas
restriction
(i) Natural Protected
areas
Boolean
logic, Yes or
No
No
-
Yes
- Forest reserve
maps
(ii) Natural Sensitive
areas
Boolean
logic, Yes or
No
No
-
Yes
- Rivers, swamp,
and peatland
(iii) Private entities
Boolean
logic, Yes or
No
No
-
Yes
- Building, roads,
expressways,
railways
Phase 3 -
Strategic &
logistics
High resolution
aerial images
Non-
occupied
land
No
-
Yes
Non-
residential
areas
No
-
Yes
Appropriate
slope
No
-
Yes
Accessible
No
-
Yes
4.2 Sensitive areas restriction
The output from the attenuation rate will undergo further screening of sensitive areas. In Malaysia
context, environmental sensitive areas were divided into three broad category, (i) natural protected
areas, (ii) private entities, and (iii) natural reserve areas. Development or commercialization of these
areas were prohibited by law and also destabilizing the ecosystem.
Environmental sensitive and protected areas include forest reserve; both inland and mangrove, and
their corresponding adjacent areas (depending on context). Next, the natural reserve areas are natural
features which not gazette as protected by law but contribute major services for ecosystem; rivers,
5
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
swamp, peatland and their buffers. For private entities, accounted features are major road and
expressways, railways, power grid & transmission areas, and private land or building.
To conduct this analysis, maps of land use, transportation, utilities and sensitive areas are used.
Areas which located in this sensitive condition are excluded from the selection. A series of Boolean
logic is applied for the operation.
Figure 2. Conceptual framework
4.3 Strategic & logistics factors
The third phase of the framework is determining the strategic & logistics factors. This factor represents
the elements which associated with the logistics aspect the earth station. That includes non-occupied
land, non-residential areas, low to middle topographic slope and logistically accessible via vehicles
(~200-300m).
A high resolution images are utilized. Basic filtering started with separation between densely built
up areas and vegetated and non-developed areas. The use of vegetation indices is encouraged for fast
processing. There are wide array of data selection for this process; depending on the quality of the
desired output and cost. A low altitude and small unmanned vehicle or an aircraft with high resolution
cameras can obtain the most precise resolution (1-2 meter). Meanwhile, high resolution data from
satellite can offered between 10m – 15m accuracy results.
6
1234567890
International Conference on Space Science and Communication IOP Publishing
IOP Conf. Series: Journal of Physics: Conf. Series 852 (2017) 012040 doi :10.1088/1742-6596/852/1/012040
5. Conclusion
This paper developed a conceptual framework in precise determination of the suitable location for the
earth station of Ka-band frequency signal. The conceptual framework emphasized the Ka-band ability
to obtain effective transmission in high resolution area scale (~1km); with considering the attenuated
by water droplets from rainfall, cloud and atmospheric water vapor. The site selection then being
conducted using high resolution satellite imageries to potentially identify the non-sensitive areas,
strategic location, meets the logistics demand and targeted community. The realization of the
conceptual framework would be the pioneer step in creating fast, efficient and cheaper network from
the high throughput satellites.
References
[1] Butash, T and Evans, B 2016 IJSCN Special Issue on Ka band and high throughput satellites Int.
J. Satell. Commun. Network 34 459
[2] Gilat Satellite Network 2011 Ka-band versus Ku-band, Whatmakesthe difference in VSAT
technology? Satellite Evolution Magazine
[3] Dept of Statistics Malaysia 2017 Population Projection (Revised) Malaysia, 2010-2040 Access
online (30/01/2017) at https://www.dosm.gov.my/v1/index.
[4] Ellis S M and Vivekanandan, J 2011 Liquid water content estimates using simultaneous S and
Ka band radar measurements Radio Sci. 46 RS2021
[5] Maciel L R, Assis M S 1990 Tropical rainfall drop-size distribution Int. J. Satell. Commun. 8
181
[6] Tenorio R S, Moraes M C D S and Sauvageot H 2011 Raindrop size distribution and radar
parameters in Coastal Tropical Rain Systems of Northeastern Brazil J. App. Met. Clim. 51
1960
[7] Semire F A, Mokhtar R M, Ismail W, Mohamad N and Mandeep J S 2014 Evaluation of site
diversity rain attenuation mitigation technique in South-East Asia Acta Astronautica 96 303
[8] Wong C L, Venneker R, Uhlenbrook S, Jamil A B M and Zhou Y 2009 Variability of rainfall in
Peninsular Malaysia, Hydrol Earth Syst. Sci. Discuss. 6 5471
[9] Cheang B K 1980 Some aspects of winter monsoon and its characteristics in Malaysia.In M.M.
Service (Ed.) Research Publication Malaysian Meteorological Service
[10] Saurabh D, Maitra A and Shukla A 2013 Diurnal variation of slant path Ka-band rain
attenuation at four tropical locations in India Indian J. of Radio & Space Physics 42 34
[11] Boukabara S -A, Garrett K and Wanchun C 2010 Global coverage of total precipitable water
using a microwave variational algorithm IEEE Transactions on Geoscience and Remote
Sensing 48(10) 3608
[12] Petty G W and Li K 2013 Improved passive microwave retrievals of rain rate over land and
ocean. Part II: Validation and intercomparison J. Atmos. Oceanic Technol. 30 2509
[13] Recommendation ITU-R P 840-6 2013 Attenuation due to clouds and fog, P-Series Radiowave
Propagation
[14] Recommendation ITU-R. P. 676-3 2013 Attenuation due to atmospheric gases, P-Series,
Radiowave Propagation
[15] Recommendation ITU-R P 676-3 2013 Specific attenuation for rain for use in prediction
methods, P-Series Radiowave Propagation
[16] Wimmers A J and Velden C S 2011 Seamless advective blending of total precipitation water
retrievals from Polar-Orbiting Satellites J. Appl. Meteor. Climatol. 50 1024
[17] Dasgupta K S, Charania A, Shukla, A and Acharya R 2009 A new propagation campaign in
tropical areas: The Ka-band propagation experiment over India with the GSAT-4 satellite.
Antennas and Propagation 2009 EuCAP 2009 3rd European Conference on Antennas and
Propagation 23-27 March 2009