The Frequency Spectrum Allocated By Malaysian Communication Computer Science Essay

The Frequency Spectrum on the wholeocated By Malaysian Communication Computer Science EssayInternational rest slight Telecommunications-2000 (IMT-2000), in like manner cognize as 3G or 3rd genesis, is the generation measuring for sprightly phones and telecom assistances. This generation is to meet specifications by the International Telecommunication Union. Various applications exist, including wide- ara radio pass catcher voice phone, video calls, mobile, mobile TV cyber station irritate and others.The details spectrum for IMT-2000 shows like belowInternational nomadic Telecommunications-2000 (IMT2000)Frequency Division Duplex (FDD) focal ratio band 2110 to 2200 MHzLower band 1920 to 2010 MHzTime Division Duplex (TDD)Frequency 1915 to 1920MHzFrequency 2010 to 2025MHzFigure 1.1 Frequency spectrum IMT-2000.2 global form for mobile communications (GSM) is a second generation cubicleular telecommunications system was maiden designed in the 1980 12. Compargond with the fi rst generation, GSM is more advanced enhancements such as in security, quality, capacity, and the ability to support integrated renovations. For examples GSM services is GSM-900 and GSM-1800 in which apply in the world like Europe, the Middle East, parts of Asia and others country.The details spectrum for GSM900 and GSM1800 shows like belowGlobal placement for Mobile (GSM) in the 900 MHz BandUpper band 925 to 960 MHzLower band 880 to 915 MHzGlobal System for Mobile System in the 1800 MHz BandUpper band 1805 to 1880 MHzLower band 1710 to 1785 MHzFigure 1.2 Frequency spectrum GSM900.2 Figure 1.3 Frequency spectrum GSM1800.2Summary for run Operators Maxis, Celcom, Digi and U-MobileServiceOperatorSystem StandardFrequency Spectrum (MHz)Access CodeCommercial NameService OfferedLower BandUpper BandMaxis Mobile Sdn BhdGSM 900GSM 1800IMT-2000FDDTDD880-886,905-9151710-17351935-19502015-2020925-93,950-9601805-18302125-2140012017Maxis vocalise call, SMS, MMS, data plans service, Internat ional roaming, WAPCelcom (Malaysia) BerhadGSM 900GSM 1800IMT-2000FDDTDD888-9051735-17601950-19652020-2025933-9501830-18552140-2155013019CelcomVoice call, SMS, MMS, data plans service, International roaming, WAPDigi TelecommunicationSdn BhdGSM 900GSM 1800IMT-2000FDDTDD886-8881760-17851965-19802010-2015931-9331855-18802155-2170010016DigiVoice call, SMS, MMS, data plans service, International roaming, WAPU-Mobile Sdn BhdIMT-2000FDDTDD1920-19351915-19202110-2125018U-mobileVoice call, SMS, MMS, WAP oral sex 2The Fourth Generation (4G) engineering lavatorydidates is foreseen most likely to be between massive Term Evolution Advanced (LTE-Advanced) proposed by the trine Generation Partnership Project (3GPP) and Mobile WiMAX using 802.16m prototypeised by the Institute of Electrical and Electronics Engineers (IEEE). Distinguish the technical differences between these 2 technologies and give your opinion on the scenario and deployment of 4G in the near future. massive Term Evolution Adv anced (LTE-Advanced) proposed by the Third Generation Partnership Project (3GPP)3GPP Long Term Evolution (LTE) is new standard in neting technology tree move what was once realize GSM/EDGE and UMTS/HSxPA networking technologies. It is a project Generation Partnership Project third (3GPP), administered under one name stigmatise by one of associations in partnership, European Telecommunications Standards Institute.LTE EvolutionFigure 2.1 Mobile Technologies ChargingThe first generation of cellular systems were establish on analog standards and are introduced in 80s middle. This with quick to bring to one second generation digitals cellular standard that made expenditure of digital modulation and signal processing. The second generation as salutary led to a technology fragmentation. Once m both standard contests exist, however what remains now are two main branches referred to as GSM and CDMA branches or alternately referred as the 3GPP and 3GPP2 branches. These branches remained separate as they migrated to 3G systems focusing on more efficient voice transport as well providing data-services. LTE originated in the 3GPP standards organization, and a competing specification (EV-DO rev C) started in the 3GPP2 body as the next evolutionary step. However, the support for EV-DO Rev C has waned and it has now become clear that the 3GPP2 radio port wine evolution has efficaciously ceased, allowing a single cellular technology.Figure 2.2 LTE admits a smooth evolutionary path for operators deploying all 3GPP and non-3GPP technologies. engineering science Summary of LTEFDMA on uplinkScale able OFDM on downlink, Single CarrierVariable Spectrum Width from 3 to 20 MHzUp to 64 QAM, MIMO, Spatial Multiplexing(SM),LTE- AdvancedWill be an evolution of LTE. therefrom LTE-Advanced must be backward compatible with LTE Release 8.Requirements will meet or even exceed IMT-Advanced requirements following the ITU-R agenda.Should support significantly increased instant(prenomina l) peak data rates in order to reach ITU requirements. Primary focus should be on low mobility users. It is necessary a further cash advance of cell edge data rates.Mobile WiMAX using 802.16m standardised by the Institute of Electrical and Electronics Engineers (IEEE)IEEE 802.16 is a series of Wireless Broadband standards authored by the IEEE. The sure version is IEEE 802.16-2009 amended by IEEE 802.16j-2009. IEEE 802.16 is written by a working group established by IEEE Standards Board in 1999 to develop standards for the global deployment of wideband Wireless Metropolitan Area Networks. The Workgroup is a unit of the IEEE 802 LAN/MAN Standards Committee 3.WiMAX EvolutionWiMAX grow almost independently (and in parallel) for cellular standard mentioned earlier. In late 90s, IEEE started a workgroup create one air interface to show multipoint radio receiver standard broadband. Working group lever DOCSIS (data on interface specification cable service) standard heavily oddly in defi nition MACs layers. Original standard modified into 802.16d in 2004 introduce OFDM as transmission scheme. This standard intended at fixed applications and is sometimes referred to as fixed WiMAX. In 2005, 802.16d further improving to for support for mobility and provide OFDM deli very(prenominal) system scalable. This standard known as 802.16e/ mobile WiMAX. (It should be noned that products based on 802.16d and 802.16e inhering securities industry and both classified as WiMAXs products lead to a few ambiguity on specific standard which is supported-802.16d or 802.16e.) Hope, 802.16e standard expanding to 802.16m which focusing on addition to ventilate interface specifications. This evolution is shown in Figure 2.3.Figure 2.3 WiMAX EvolutionTechnology Summary of WiMAXScale able OFDM on downlink and uplinkVariable Spectrum Width from 1.25 to 10 MHzUp to 64 QAM, MIMO, Spatial Multiplexing, BeamformingMobile WiMAX deployed since 2008IEEE802.16m and Mobile WiMAX Release 2Lower latenc y through faster MAC/signalingHigher spectrum efficiency through more advanced and higher(prenominal) order MIMO solutions, including multiuser MIMO as well as lower MAC and PHY overhead.Higher peak and user data rates using wide-band carriers (including 20 MHz) and multicarrier aggregation.Enhanced coverage in high folie environments with improved preamble and control channel.Support for higher mobility through a faster feedback mechanism and link adaption.Flexible spectrum deployments (both FDD and TDD support contiguous bands)The scenario and deployment of 4G in the near future4G refers to the fourth generation of cellular wireless standards. It is a successor to 3G and 2G families of standards. The first was the move from 1981 analog (1G) to digital (2G) transmission in 1992. This was followed, in 2002, by 3G multi-media support, spread spectrum transmission and at least 200kbit/s, soon expected to be followed by 4G, which refers to all-IP packet-switched networks, mobile ultra -broadband (gigabit speed) access and multi-carrier transmission. Pre-4G technologies such as mobile WiMAX and first-release 3G Long term evolution (LTE) have been available on the market since 2006 and 2009 respectively.According to the members of the 4G working group, the root and the terminals of 4G will have almost all the standards from 2G to 4G implemented. Although legacy systems are in place to adopt existing users, the infrastructure for 4G will be only packet-based (all-IP). Some proposals suggest having an open Internet platform. Technologies considered to be early 4G let in Flash-OFDM, the 802.16e mobile version of WiMax ( as well known as WiBro in South Korea), and HC-SDMA (see iBurst).Question 8The public cellular service operator in Malaysia are subjected to mandatary standards for Quality of Service (QoS) or year of Service (GOS) by Malaysian Communication and Multimedia Commission (MCMC). List various parameters and schemes used for providing QoS/GOS in cellular network and discuss their advantages/disadvantages to the subscribers and operators. How can QoS provisioning be managed in the future 4G cellular network?There is two focuss to measure the quality of voice services, Grade of Service (GoS) and the Quality of Service (QoS). GOS can be describe as a chances of a call in a circuit group be blocked or delayed for more than a specified interval and can be expressed as a vulgar fraction/decimal fraction fraction. This is likely to happen to the busy hour when the traffic intensity is the greatest. Grade of service can viewed from the perspective of incoming versus outgoing calls, and is not necessarily personify in each direction or between different source-destination pairs.Quality of service (QOS) can also be called as voice grade or program grade which is a single circuit that is designed or conditioned to provide. Equalization for amplification over a specified band of oftenness or for this case of digital data transported via ana logue circuit can be one of the quality criteria for such circuit. One of the aspects for mobile quality of service in cellular telephone circuits is the probability of abnormal termination of the call.There is a lot of factor can push the quality of service of the telecommunication network. From the customers point of view looking at this QoS can be describe as common phenomena and its judged by the user. However there is a standard metrics of QoS that can be used by the customer to measure the QoS. The coverage, accessibility and the audio frequency quality is the indicator for this quality. For coverage, strength of the signal is metrical using test equipment and this can be used to estimate the size of the cell. For accessibility its about determining the ability of the network to handle successful calls from mobile-fixed networks and from mobile-mobile networks. For audio quality it can be considers monitoring a successful for a period of time for the clarity of the communic ation channel. All these indicators are used by the telecommunications industry to judge the quality of service of the network.QoS provisioning be managed in the future 4G cellular networkNowadays, cellular network operators across the world have seen a rapid growth of mobile usage. Data usage per subscriber is increasing daily in particular and with the introduction of flat-rate tariffs and more advanced mobile devices. go provider are moving from a single-service offering in the packet-switched domain to a multi-service offering by adding Value added services (VAS) that are also provided across the mobile broadband access. One of the examples of these Services is multimedia telephony and mobile-TV. These kind services have a different performance requirement in harm of the required bit rates and packet delays or any other examples. However solving these performance issues through over-provisioning typical is uneconomical due to the comparatively high cost for transmission capac ity in cellular access networks which includes radio spectrum and backhaul from the base stations. 4G broadband wireless technologies such as IEEE 802.16e/m and Third Generation Partnership Project (3GPP) Long Term Evolution (LTE) have been designed with different QoS (Quality of Service) frameworks and means to enable delivery of the evolving Internet applications. QoS specifically for evolving Internet applications is a fundamental requirement to provide satisfactory service delivery to users and also to manage network resources.QoS refers to the probability or ability of the network to provide a desire level of service for selected traffic on the network.Service levels are defined in terms of throughput, latency (delay), jitter (delay variation) and packet demerits or loss. several(predicate) service levels are defined for different types or streams of traffic.To supply QoS, the network identifies different types or streams of traffic and processes these traffic classes differ ently to achieve (or attempt to achieve) the desire service level for each traffic class.The efficiency of any QoS scheme can be measured based on its ability to achieve the desired service levels for a typical combination of traffic classes.4G wireless communication systems feel the requirement of transparent and seamless user roaming with end-to-end connectivity. These systems also required higher data rate, higher mobility support and QoS guarantees due to rapid development of wireless and mobile networks. All this requirements is possible for the operators to increase their service portfolio and for the users to experience context-rich and individualise services.Advantages for Subscribers and OperatorsSubscribersKnow that when the call was busyUsers may call for a long time without queuingEasier for users to choose the scoop mobile phone operator. So, they know which one the operators has the best coverage.OperatorsWill know when the time is busy and how to solve the problem faster.Always to take the opportunity to improve their network coverage.Disadvantages for Subscribers and OperatorsSubscribersCannot make a call especially during the emergency call.OperatorsIncrease the cost in order to improve the network.Will increase the number of cell in order to handle the large get of subscribers.SATELLITE COMMUNICATIONQUESTION 10The Very Small Aperture Terminal, VSAT service is becoming more popular in Malaysia. Obtain information on VSAT service operator in Malaysia including examples of application, network topology, user equipments, lease procedure and services offered and their data rate. How can a VSAT system accommodate subscriber that need higher data rate services.Introductions of VSATA Very Small Aperture Terminal (VSAT) is a two-way artificial satellite ground station with a dish antenna that is littler than 3 meters (most VSAT antennas range from 75 cm to 1.2 m). VSAT data rates typically range from narrowband up to 4 Mbit/s. VSATs access satel lites in geosynchronous orbit to pass along data from small remote earth stations (terminals) to other terminals (in mesh configurations) or lord earth station hubs (in star configurations).VSAT can be used for data, voice, video or internet applications 10. It is used to communicate with to link together localizations using satellite connectivity.Figure 3.1 A typical VSAT network depicting two way communications from remote terminalsthrough a VSAT satellite to a central hub.MAXIS VSATVSATs are an ideal means of communication in areas where terrestrial infrastructure is unavailable or unreliable. As such VSAT services are able to bring distant or remote business communities closer by eliminating geographical barriers and challenges that previously existed. This in turn transfers to an increase in productivity and overall cost efficiency for such communities.In addition to providing communication to remote areas, VSATs are also suitable in providing private networks in urban area s for organizations with many geographically dispersed branches that require connectivity to their Headquarters. VSAT services generally offer service reliableness and availability that is equal to or higher than terrestrial services.Below are examples of type Maxis VSAT Services that can be used depends on the complexity of the network and the communications requirementsSCPC (Single Carrier Per Channel)Satellite bandwidth is dedicated to a single source.SCPC based design provides a point-to-point technology making it the VSAT equivalent.Supports voice, data, video communications.AdvantagesSimple and reliable technologies. affordable equipment.Figure 3.2 SkyLine (SCPC) Service hub to remote configurationTDMA (Time Division Multiple Access)Is a channel access method for partd medium network.Allows several users to share the same frequency channel by dividing the signal into different time slots. In Figure 3 (d), all VSATs share satellite resource on a time-slot basis and the remote VSATs also use inroutes for communicating with the hub or TDMA channels. There could be several inroutes associated with one outroute.Several VSATs share one inroute, so it also sharing the bandwidth. Typical inroutes operate at 64 or 128 Kbit/s. Critical to all TDMA schemes is the function of clock synchronization what is performed by the TDMA hub or master earth station.The VSATs may also access the inroute on a fixed assigned TDMA mode, where in each VSAT is allocated a specific time slot or slots.Figure 3.3 Typical SkyNet (TDM/TDMA)-configuration supporting various inter energetic data applications.Summarization of Maxis VSAT Services 6ServicesService DescriptionTypical UsersSkyWayTMVSATBroadband data and Voice service.Corporations with many branches requiring Broadband Data and telephony.Corporations requiring Internet access.Corporations or communities in remotes areas without telephone connectivity, i.e. plantations, timber camps and remote villages.SkyLine VSATDedicated lea sed line for point-to-point and point-to-multipoint connectivity.Corporations requiring dedicated link for communications between its HQ and branches.SkyLine-Plus VSATDedicated leased line with Frame Relay technology for mesh connectivity.Corporations requiring dedicated links for communications between sites indoors the VSAT network.Gyro-Stabilized VSATSpecialized VSAT service for maritime and offshore oil rigs.Upstream oil and gas corporationsShipping companies.The benefit of Maxis VSAT ServicesUniform service qualityAll sites in the VSAT network receives the same high quality services, whether the location is urban or rural areas.ReachVSAT is a service that available anywhere no matter the place, whether in a remote area, forest or anywhere in the world.High relaibility availabilityVSAT networks offer high reliability as the points of bankruptcy are limited to two points means at any two locations in a communications link.This ensures minimal downtime while the service availab ility for VSAT networks.Question 11Global put System, GPS satellite is a navigation satellite that can offer services based on locations. Investigate among the service offered in Malaysia, user hardware and equipments, subscription (if any), and their limitation in term of accuracy. Identify similar service to complement GPS system particularly for mobile and handheld environment.The Global Positioning System (GPS), also known as Navstar, is a satellite based navigation system that can be used by anyone with appropriate receiving system to pinpoint location on earth. The array of GPS satellites transmits highly accurate, time coded information that permits a recipient role to calculate its tiny location in terms of the latitude and longitude on earth as well as the altitude above the sea level 10.GPS was developed by the U.S Air Force for the Department of defence reaction as a continuous global radio navigation system that all elements of the military services would use for pr ecision navigation. GPS consists of three parts the space segment, the control segment, and the user segment 10.The space segment is composed of 24 to 32 satellites in medium Earth orbit and also includes the boosters required to ensnare them into orbit 10. The space segment is the constellation of satellites orbiting above the earth. It contains transmitters which send highly accurate timing information to GPS receivers on earth. The receivers may be used on land, sea or air.Figure 4.1 GPS mapping aids are small enough to be mounted on a dashboard or stashed in a backpackers pack. They are popular with boaters too.Figure 4.2 The GPS space segmentFigure 4.2 shows the fully implemented GPS consists of 24 main operational satellites plus 3 active space satellites. The satellites are arranged in six orbits, each orbit containing 3 or 4 satellites.User hardware and equipmentsGPS satellites circle the earth in two ways a day in a very precise orbit and transmit signal information to ea rth. GPS receivers take this information and use triangulation to calculate the users exact location. Essentially, the GPS receiver compares the time a signal was transmitted by a satellite with the time it was received. The time difference tells the GPS receiver how far away the satellite is. Now, with distance measurements from a few more satellites, the receiver can determine the users localise and display it on the units electronic map 13.fA GPS receiver must be locked on to the signal of at least three satellites to calculate a 2D position (latitude and longitude) and track movement. With four or more satellites in view, the receiver can determine the users 3D position (latitude, longitude and altitude). Once the users position has been determined, the GPS unit can calculate other information, such as speed, bearing, track, aerate distance, distance to destination, sunrise and sunset time and more13.The GPS receivers are extremely accurate, thanks to their parallel multi-chan nel design. Garmins 12 parallel channel receivers are quick to lock onto satellites when first turned on and they maintain strong locks, even in dense foliage or urban settings with tall buildings. Certain atmospheric factors and other sources of error can affect the accuracy of GPS receivers. Garmin GPS receivers are accurate to within 15 meters on average 13.Newer Garmin GPS receivers with WAAS (Wide Area Augmentation System) capability can improve accuracy to less than three meters on average. No additional equipment or fees are required to take advantage of WAAS. Users can also get correct accuracy with derived function GPS (DGPS), which corrects GPS signals to within an average of three to five meters. The U.S. Coast Guard operates the most common DGPS correction service. This system consists of a network of towers that receive GPS signals and transmit a corrected signal by shine transmitters. In order to get the corrected signal, users must have a differential beacon receiv er and beacon antenna in addition to their GPS 13.GPS satellites transmit two low power radio signals, designated L1 and L2. Civilian GPS uses the L1 frequency of 1575.42 MHz in the UHF band. The signals travel by line of sight, meaning they will pass through clouds, glass and plastic but will not go through most solid objects such as buildings and mountains. A GPS signal contains three different bits of information a pseudorandom code, ephemeris data and almanac data. The pseudorandom code is simply an I.D. code that identifies which satellite is transmitting information. You can view this number on your Garmin GPS units satellite page, as it identifies which satellites its receiving 13.Ephemeris data, which is constantly transmitted by each satellite, contains important information about the status of the satellite (healthy or unhealthy), current date and time. This part of the signal is essential for determining a position. The almanac data tells the GPS receiver where each GPS satellite should be at any time throughout the day. Each satellite transmits almanac data showing the orbital information for that satellite and for every other satellite in the system 13.The service offered in Malaysia /GPS ApplicationsThe primary application of the GPS is military and related navigation. GPS is used by all services for ships, aircraft of all sort, and group troops. Civilian uses have also increased dramatically because of the availability of many low-cost portable receivers. Most cavitations applications involve navigation, which is usually marine or aviation- related. Hikers and campers and other outdoors sports enthusiasts also use GPS.Commercial applications include surveying, mapmaking and construction. Vehicle location is a growing application for trucking and delivery companies, taxi, bus and train transportation. Police, fire, ambulance and forest services also use GPS. GPS based navigation systems are now widely available as accessories in cars to provide a continuous readout of current vehicle location.GPS is purpose new applications every day. For instance, it is used to keep track of fleets of trunks. A GPS receiver in each trunk transmits its position data by way of a wireless connection, such as a wireless local- area network or cell phone. Many new cell phones contain a GPs receiver that automatically reports the location of the user people makes a 999 call. Most location based services will be used for 999 calls, eventually other location services may be developed for cell phones. Not all cell phones use GPS. Some use a unique triangulation method based on the cell phone being able to be in touch with at least three call sites. Finally, GPS receivers are so gimcrack an accurate that they have led to a new hobby called geocaching. In this sport, one team up hides an item or treasure and then gives the other team coordinates to follow to find the treasure within a habituated time.Limitation in term of accuracyFactors that ca n degrade the GPS signal and thus affect accuracy include the followingIonosphere and troposphere delays The satellite signal slows as it passes through the atmosphere. The GPS system uses a built-in model that calculates an average amount of delay to part correct for this type of error.Signal multipath This occurs when the GPS signal is reflected off objects such as tall buildings or large rock surfaces before it reaches the receiver. This increases the travel time of the signal, thereby causing errors.Receiver clock errors A receivers built-in clock is not as accurate as the atomic clocks onboard the GPS satellites. Therefore, it may have very slight timing errors.Orbital errors Also known as ephemeris errors, these are inaccuracies of the satellites reported location.Number of satellites visible The more satellites a GPS receiver can see, the better the accuracy. Buildings, terrain, electronic interference, or sometimes even dense foliage can block signal reception, causing position errors or possibly no position reading at all. GPS units typically will not work indoors, underwater or underground.Satellite geometry/shading This refers to the relative position of the satellites at any given time. Ideal satellite geometry exists when the satellites are located at wide angles relative to each other. Poor geometry results when the satellites are located in a line or in a tight grouping.Similar service to complement GPS system particularly for mobile and handheld environment.GPS-enabled Cell PhonesMotorola and Blackberry were the first GPS-enable phones to proliferate the linked States. Initially, MotorolaiDEN phones were commonly used for employee tracking on the business-oriented Nextel network. Then GPS enabled Blackberry phones, once used almost exclusively by corporate and government VIPs, began to penetrate the consumer market stimulated by the demand for phones with advanced messaging capability. Next came specialty devices produced under the name s of Disney Mobile and Wherify Wireless targeting use by children and elderly. Now in 2009, a variety of GPS-enabled phones and tracking services are available, as you can see from the ads on this page.Locating People in an EmergencyStimulated by the events of 11 September 2001, the demand for enhanced 911 (e911) emergency calling capabilities pushed forward GPS tracking technology in cell phones. At the end of 2005, all cell phone carriers were required to provide the ability to trace cell phone calls to a location within 100 meters or less.Wireless NetworksYour phone may have GPS and know exactly where it is, but it cant tell anyone else where you are unless you are connected to a wireless network. Here in the United States, the wireless networks used for GPS tracking are primarily those operated by cell phone carriers. It is not likely that you as an individual will negotiate network access with a carrier. It is more likely that you will select a solution including a cell phone p rovisioned to communicate in a certain way on a specific wireless network. List below are some carriers recommended for use with GPS cell phones and services.T-Mobile / Cingular / ATT The Global System for Mobile (GSM) communications as adopted by these carriers represents the network with the largest coverage footprint. Roaming agreements between these carriers provide end users with service throughout the country. GSM is also the prominent cellular network abroad.Sprint / Nextel, not so much because of coverage, but because of their emphasis on data. Nextel has created their own data formats and communication protocols for high bandwidth mobile electronics applications. This company, who gave new meaning to the term walkie-talkie, provides the most tractability for the communication of GPS data between cell phones and location-based service pro