Small Earth Stations Research Articles

SATCOM Earth Station Arrays Anti-Jamming Based on MVDR Algorithm

In modern life, a large amount of information is transmitted through satellites. The anti-jamming ability of satellite communication earth stations is the basis for ensuring the smooth flow of information. In the case that multiple small earth stations cannot communicate due to jamming, the minimum variance distortionless response (MVDR) algorithm based on reflector antenna array is proposed. Firstly, the gain expression of satellite communication earth station antenna is derived, and the mathematical model of the received signal of the reflector antenna array is established. Then, the MVDR beamforming algorithm based on the reflector antenna is proposed and applied to the satellite communication earth station reflector antenna array, and the anti-jamming capability of the reflector antenna array using this algorithm is analyzed through simulation. The simulation results show that the earth station reflector antenna array using MVDR algorithm can effectively achieve array gain of the direction of the satellite signal, suppress the jamming signals, increase the output signal to interference plus noise ratio (SINR) of the reflector antenna array, and increase the output signal to jamming plus noise ratio with the increase in the number of snapshots.

Maximising Bandwdith Efficency of Statistical Multiplexer Architecture using Frame Droping Methods

<span>It is generally considered that remote and rural telephone users generate less traffic as compared<span> to urban area users. This lowers the attraction of investment in rural areas by the<span> telecommunications companies and service providers. The financial implications of wiring a<span> vast area for low telephone traffic causes most telephone service providers to ignore those<span> regions. Still, it is known that telecommunications are essential to the economic development of<span> a region and that traffic increases rapidly as soon as the service is available. A satellite–based<span> telephone network can provide efficient long distance telephone service to remote rural<span> communities at a lower cost than land-based wired networks in most cases. Mobile satellite<span> systems already provide this service, but are limited in capacity and charge high per-minute fees<span> for the satellite link. Small earth stations and GEO satellites can provide this service more<span> efficiently and at lower cost. On top of that, bandwidth efficient multiplexing with compressed<span> speech, Voice Activity Detection (VAD) and Packet discarding methods can even further reduce <span>the cost of service for the users in rural areas. In this paper, Statistical Time Division Multiplexer<span> (STDM) architecture was simulated. Two packet discarding methods, random packet discarding<span> and cyclic packet discarding are used to maximize bandwidth utilization along with VAD.<span> Results indicate that considering monologue speech source, with 80%, activity for each 6.4 kbps<span> sources, on a channel of 64 kbps, 12 users can be allowed to be multiplexed instead of 9,<span> therefore a Digital Speech Interpolation (DSI) advantage of 1.33 is achieved with 3% packet<span> loss. Furthermore, it is observed that cyclic packet discarding technique perform better than<span> random packet discarding in terms of subjective quality<br /><br class="Apple-interchange-newline" /></span></span></span></span></span></span></span></span><br /><br class="Apple-interchange-newline" /></span></span></span></span></span></span></span></span></span></span></span></span>

The Mechanism of Deliberate Jamming On the Broadcast Satellite Service.

A direct broadcast satellite is making maximum efforts to transmission the TV signal from the source to the receiving in the small home earth stations, especially the important events of a widespread public demand. The power and the nature of the television signal affected by losses resulting from the length of the path and the natural noise , thus the signal's loss part of its power at the reception, but the most influential is the possibility of deliberate jamming, thus the signal of reception has loosed completely. So we are in this research analysis of the technical side to transmit the signal from the Earth station to the satellite, which is the line upward and then receive that signal and processed by machines effector inside the satellite and re-sent as a line downward to the receiving stations. The statement of the impact of deliberate jamming on that process by attacking the line upward by the largest power after the completion of the integrated analysis the original signal using sophisticated of high technology equipment. Based on that, we can see the statement of the used method to deliberate jamming on satellite's channels and methods of prevention ,then it used the simulation program (MATLAB) according to the laws relating to communication satellites, taking into account the latitude and longitude and geographic location of ground stations, satellites, sending and receiving. The results were important and productive because they determine the ability and nature of the signal for a private reception with deferent effects.

Small Satellite Earth Stations for Disaster Recover Operations

Small Satellite Earth Stations for Disaster Recover Operations

Multiple access communications in future-generation wireless networks

In June 1971, the first two-way wireless transmission of data packets within a computer network was achieved at the Manoa campus, University of Hawaii, Honolulu [1]. The ALOHANet was an experimental UHF radio network designed and implemented at the University of Hawaii at a time when the only other option for remote access to information resources was based upon the use of inflexible, slow, and unreliable telephone network connections. The ALOHA System Research project began in September 1968, with the purpose of defining [2] “those situations where radio communications are preferable to conventional wire communications.” The properties of the wireless medium led to the use of a new form of random access channel architecture, now known as an ALOHA channel. The commercial application of ALOHA channels in the 1970s was limited by the fact that suitable frequencies for terrestrial wireless transmission of packets were not generally available. Thus, the first two commercial uses of an ALOHA channel were in cable networks and then in satellite networks. In 1973, Metcalfe demonstrated a cable-based application of ALOHA in the “Alto ALOHA Network” [3] at the Xerox Palo Alto Research Center. This network was later developed by Metcalfe into Ethernet. In 1976, an ALOHA channel was used for the request channel in the Marisat (later Inmarsat) satellite network [4]. Over the last 30 years millions of small two-way earth stations using ALOHA channels have been implemented around the world. In the early 1980s, frequencies for mobile networks became available [5] and in 1985 frequencies suitable for what became known as WiFi were allocated [6] in the USA. ALOHA channels were used in a limited way in the 1980s in 1G mobile phones for signaling and control purposes [7]. In the 1990s, Matti Makkonen and others at Telecom Finland greatly expanded the use of ALOHA channels in order to implement SMS message texting in 2G mobile phones. In the early 2000s, additional ALOHA channels were added to 2.5G and 3G mobile phones with the widespread introduction of GPRS using a slotted ALOHA random access channel combined with a version of the Reservation ALOHA scheme first analyzed by a group at BBN [8]. It seems clear that the expanding use of smartphones and IP-based web traffic in developing 4G networks will lead to an even greater use of random access ALOHA channels in this decade. Metcalfe at Xerox [9] and Kleinrock and Tobagi at UCLA [10] added the use of Carrier Sense (CS) and Carrier Detection (CD) to an unslotted ALOHA channel to define the CSMA/CD protocol used in the original Ethernet 802.3 cable standard. The 802.11 WiFi wireless standard modified the CD part of the Ethernet standard to Collision Avoidance (CA) to define the CSMA/CA protocols adopted in 1997 for WiFi. Ironically, recent chatter on the web dealing with full duplex WiFi hints at further development of WiFi in the direction of the original ALOHA architecture. The theoretical foundations of ALOHA random access have been described in various ALOHA System technical papers [11,12]. Over the last 30 years research groups throughout the world have provided a deeper, more complete understanding of the multiple access channel, its limitations, and its possibilities. Many of these possibilities are dealt with in this Special Issue of the EURASIP Journal of Wireless Communications and Networking. This Special Issue contains 21 selected articles, covering a significant number of hot topics in Multiple Access Communications such as new cooperative MAC protocols; spectrum sharing, and channel assignment techniques for cognitive radio networks; new results on PHY layer multiple access techniques; admission control, and radio resource management for multimedia traffic in WLANs, WIMAX, and LTE networks, as well as on general topics such as multiuser detection (MUD), cross layer, and quality of service. * Correspondence: boris.bellalta@upf.edu Department of Information and Communication Technologies, Universitat Pompeu Fabra, Spain Full list of author information is available at the end of the article Abramson et al. EURASIP Journal on Wireless Communications and Networking 2012, 2012:45 http://jwcn.eurasipjournals.com/content/2012/1/45

The emergence of commercial digital satellite communications

In this article some of the factors responsible for the emergence of commercial digital satellite communication are discussed. Today most voice traffic across the Atlantic is carried by fiber optic undersea cable. Satellites remain competitive in broadcast and thin route applications. Video distribution remains strong for satellites, and in mobile applications such as maritime and military telecom requirements for voice, data, and video. In disaster situations (e.g. the earthquakes in Haiti and Chile) satellite trucks with generators and small Earth stations provide quick communications when terrestrial facilities are damaged or destroyed.

Satellite rural communications: telephony and narrowband networks

AbstractRural communications are important for large and developing countries, and telecommunications systems have been implemented depending upon the available technology at the time. Rural users do not generate the same amount of revenue as urban users do, thus lowering incentives for rural telecommunications investment with service to those regions delayed as long as possible. Voice and data communications are essential to the economic development of a region, and it has been shown that traffic increases rapidly as soon as the service is available. Satellite‐based digital networks provide efficient long‐distance service to rural communities at lower cost than similar land‐based wired networks with acceptable quality. Small earth stations along with Wireless Local Loops can provide both local and long‐distance service efficiently and at low cost, offering digital multimedia services on a global scale. This paper focuses on the description of different narrowband technologies used to service rural communities, namely basic telephone and low‐bit‐rate data (<64 kbps) applications through the use of satellite and terrestrial wireless systems. A basic network economic planning description is presented, and important parameters such as satellite network size, topology and multiple access are identified in order to improve the process of effective and cost‐efficient rural communications network design. Copyright © 2005 John Wiley & Sons, Ltd.

Aperiodic array consisting of subarrays for use in small mobile Earth stations

A simple yet practical method of designing an aperiodic array consisting of subarrays is shown. By properly controlling the excitation phase of each subarray, the designed aperiodic array has the capability to track a geostationary satellite within some limited angles. Starting with an initial position of the subarrays, their optimum positions in terms of the side lobe performance can be obtained by a newly developed algorithm which uses the steepest descent method together with an appropriately defined cost function. An example of an aperiodic array consisting of 16 subarrays in the 14 GHz band is shown. It can track a geostationary satellite at the maximum of 2/spl deg/ off its mechanical boresight (the direction perpendicular to the surface of the array). Although it is nearly square with the maximum dimension of only 47/spl lambda/ (wavelength), its calculated side lobe patterns satisfy most of the requirements specified in the International Telecommunication Union (ITU) recommendations, which must be met by all earth stations with antennas of larger than 50/spl lambda/ in diameter.

Design optimization of a TDMA burst modem for small earth stations in a channel containing two nonlinear devices

AbstractThe conventional TDMA satellite communication system generally involves operations in which a sufficient amount of back‐off is provided by using a large‐scale high‐power amplifier (HPA) in the earth station. However, if the HPA in the earth station can be operated at the saturation point, the earth station can be downsized and rendered into a low‐power consumption station, with considerable benefits in terms of earth station installation and economy of operation. The authors have proposed a system combining an optimized transmission system and error‐correction code, using burst modem filters and other devices, in a transmission system including two nonlinear devices of an earth station HPA and a satellite traveling‐wave tube amplifier (TWTA), and have confirmed by computer simulations and experiments that it is feasible to operate the earth station HPA at its saturation point. The authors have also demonstrated that adequate performance characteristics can be attained in terms of burst‐to‐burst interference and cycle‐skipping characteristics in the carrier recovery system. © 2004 Wiley Periodicals, Inc. Electron Comm Jpn Pt 1, 87(8): 47–62, 2004; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/ecja.10149

Internet access using VSATs

This article presents a simplified and integrated analysis of the key design issues in the use of Ku band satellite capacity and small earth stations for high-speed low-latency Internet access. These design issues involve a variety of interconnected technical and economic choices affected by the cost of the earth stations and that of the satellite capacity required to support a single user or small groups of users. The article analyzes the performance of VSATs for Internet access under a variety of multiple access architectures: SCPC/DAMA, CDMA, ALOHA, MAMA and SAMA.

Earth station errors in two-way time and frequency transfer

We have investigated the earth station errors in two-way time transfer. A 3.7-m earth station and a very small aperture terminal earth station were used in these experiments along with a transponder located on a mountain about 10 km away. The temperature coefficient of the receive delay for the 3.7 m NIST earth station was (-150/spl plusmn/30) ps/K, and the temperature coefficient for the transmit delay was (-50/spl plusmn/10) ps/K. The overall temperature coefficient for the earth station was (100/spl plusmn/30) ps/K. Aside from environmental errors there are apparent changes in delay due to characteristics of the modulation/demodulation scheme. Apparent delay changes due to nonlinearity effects in the earth station were as high as 10 ns. The errors due to code dependence and third code interference were sometimes as high as 3 ns.

Dual-Space Diversity over Land Mobile Satellite Channels Operating in the L and K Frequency Bands

Land mobile satellite communication systems at Ka/K band (30/20 GHz) are attracting more and more attention to researchers because of its frequency band availability and the possibility of using small earth stations and satellite antennas for the systems. However, the Ka/K-band communications also give significant challenges in the system design due to severe channel impairments expected from the satellite links. In this paper, K-band channel characteristics are studied and compared with those at L band. The channel is modeled as Rayleigh multipath fading with the line-of-sight (LOS) component following a lognormal distribution. The first and second-order statistics of the fading channel are studied. Dual-space diversity reception is investigated to combat the flat channel fading. The bit error rate performance of coherent binary phase shift keying (BPSK) with ideal bit and carrier phase synchronization over the fading channel at K band is evaluated theoretically and verified by computer simulations in the case with and without diversity reception.

Dual-offset antennas with a spherical main reflector for small earth stations

The design of dual-reflector antennas with a spherical main reflector for small earth stations is considered. An analysis of the field polarization throughout the system shows that it is possible to adjust the reflectors to obtain very low cross-polarization. The use of an elliptical main reflector projection is explored in order to enhance efficiency and lower side-lobe levels.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

An interference cancellation method for small earth stations

AbstractThis paper proposes an interference cancellation method called the in‐band power minimizing method (IPMM), and describes the use of the method in satellite communication earth stations. In this method, an interfering signal arriving from an earth station antenna is combined by a cancellation circuit with an interfering signal received by an auxiliary antenna and the two interfering signals are arranged to have equal amplitudes but opposite phase. To achieve this condition, the amplitude and phase are adjusted so that the signal power of the output signal from the cancellation circuit contained in the desired signal frequency band is to be a minimum. This method is characterized by the fact that a simple circuit can be used to detect interference rapidly and accurately even at low C/N ratios.This paper also discusses the principle of IPMM and examines the results obtained when it is applied to small earth stations. It was found that IPMM is quite effective in this application.

120/140 Mbit/s portable HDTV codec and its transmission performance in a field trial via INTELSAT satellite

This paper describes a portable HDTV digital codec and its transmission performance obtained in a transpacific field trial via an INTELSAT satellite with a transportable small earth station. This portable codec is designed for transmitting HDTV programs including 4 channels of high quality sound via a 72 MHz bandwidth transponder in an INTELSAT satellite, or via an ISDN H 4 channel in an optical fiber submarine cable. In order to realize the portable hardware for practical applications, the codec employs bit-reduction techniques whose algorithms are extremely simple from the viewpoint of hardware construction but are effective in achieving a high coding picture quality. From the results obtained in the field trial, it is concluded that an end-to-end international digital transmission of HDTV programs, wherein HDTV programs can be directly transmitted from the place of an event to a theater, is commercially viable using the codec in conjunction with the small earth station.

Direct PO optimized dual-offset reflector antennas for small Earth stations and for millimeter wave atmospheric sensors

An efficient direct numerical synthesis method for dual offset reflector antennas which is directly based on the physical optics procedure for both reflectors (PO-PO-method) and where the reflector surfaces are advantageously characterized in the spatial domain by a 2D Fourier-transformation is described. The method uses an evolution-type optimization algorithm to shape both reflectors simultaneously so as to generate the desired far field with prescribed criteria. The efficiency of the design method is demonstrated for two computer-optimized dual-offset antenna designs for space applications, a very compact optimum shaped Gregorian Earth station antenna with high offset angle (70 degrees ) and small subreflector size (13 lambda ) and a shaped Cassegrain atmospheric sensor antenna for 200 GHz. The theory is verified by available measured results.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

Spread SCPC/FDMA, spread TDMA/FDMA and SSMA/FDMA transmission through A non-linear satellite channel with an earth-station off-axis emission constraint

This paper analyses and compares possible access schemes to be used in satellite networks with a large number of small earth-stations. Basically, frequency division (FDMA), time division (TDMA), and spread spectrum multiple access (SSMA) are considered. For TDMA, one single carrier originated in one particular earth-station is transmitted in each sub-band and therefore a single-channel-per-carrier system results (SCPC/FDMA). For TDMA and SSMA, it is assumed that groups of earth-stations using either of these access schemes share the full available band in FDMA. The corresponding systems are thus TDMA/FDMA and SSMA/FDMA. Moreover, for SCPC/FDMA and TDMA/FDMA individual carriers may be spread to the extent that the available bandwidth is always fully occupied. Spectral efficiencies for these three access modes (Spread SCPC/FDMA, Spread TDMA/FDMA and SSMA/FDMA) are computed and compared for transmission through a non-linear satellite channel and optimum operating points for the non-linear amplifier are also determined. Comparisons are also performed for the situation in which transmitting earth-stations are bounded to obey an off-axis emission constraint.

Two-way time transfer via communication satellites

The history of two-way satellite time transfer is provided and developments in satellite communications technology conducive to this time transfer technique are briefly reviewed. The difference between one-way and two-way satellite time transfer is explained, and the advantages and disadvantages of the two-way method are pointed out. The theory of the two-way technique using geostationary communication satellites is presented showing the high accuracy potential of the method. The advantages of the use of spread spectrum techniques are outlined. The implementation of the two-way method using communication satellites and small Earth stations using pseudonoise (PN) modems is described. Methods for signal delay calibration are dealt with. Existing links are listed and their performances are given. The future use of the two-way technique using communication satellites is discussed.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

VSAT data networks

The use of satellite channels for very small-aperture terminal (VSAT) data networks such as spread spectrum and ALOHA is reviewed. Certain basic aspects of the architecture of VSAT data networks are discussed. Although spread spectrum and ALOHA have different origins and are sometimes represented as competing technologies, they can in fact be characterized as different ways of viewing the same low-dimensional signals in a high-dimensional signal space. After a brief introduction to the architecture of VSAT networks, it is shown how a simple linear transformation of conventional ALOHA packets called spread ALOHA leads to signals identical in all respects to the most common form of spread-spectrum signals. Two practical consequences of this theoretical result are discussed. First, for the case of small earth stations it is not possible to find an Access technique with a higher throughput than spread ALOHA. Second, the use of different spreading sequences for different users in a packet network using spread spectrum is not necessary for user separation.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

Interference Limitations and Future Small Earth Stations

Hostile Interference signals are recorded at the top of the Electrical Engineering Department, of King Saud University, using a 3m antenna, which received signal levels from Arabsat. These are good extreme examples of interference associated with the wide spread location sites of future small earth stations. Techniques are discussed to nullify this multiple source interference, for applications of reflectors and phased array antennas. Phased array antennas have more flexibility in this concern, at the expense of lower efficiency and complex design development requirements. Developments of arrangements of active phased arrays are promising for future high quality and mass production.