Design and Planning of WiMAX Networks (MobileMAN)

Transcription

1 Design and Planning of WiMAX Networks (MobileMAN) Fernando J. Velez Pedro Sebastião , it - instituto de telecomunicações. Todos os direitos reservados.

2 Outline Part I What is WiMAX Services, applications, and service quality Practical Point-to-multipoint, PTM, deployments Experimental results for coverage and throughput Cellular Planning: coverage/capacity, motivation to the usefulness of GIS tools Design and deployment of pre-wimax PTP links Conclusions 2

3 What is WiMAX? WiMAX is a IEEE broadband wireless standard for IEEE Wireless Metropolitan Area Networks (WMAN) (fully IP) There are two standards for IEEE IEEE , which defines WMAN technology for fixed access IEEE e, includes mobility, handover, subchannelisation and enhanced QoS classes There will be m Advanced air interface Convergence with LTE (in ITU) 3

4 Channel bandwidth and data rate (IEEE ) Bandwidth Data rate [Mbps] [MHz] QPSK 16-QAM 64-QAM

5 Modulation and codification schemes of 3.5GHz Alvarion equipment (3.5 MHz bandwidth) Modulation & Net PHY Bit Rate Sensitivity [dbm] coding [Mbps] BPSK 1/ BPSK 3/ QPSK 1/ QPSK 3/ QAM 16 1/ QAM 16 3/ QAM 64 2/ QAM 64 3/

6 Service quality and flows Unsolicited Grant services Ex: VoIP without silence suppression Real Time Polling Service Ex: Streaming audio and video, MPEG encoded Non-real-time Polling service Ex: FTP Best-effort service Ex: Web browsing, data transfer Extended real-time polling service Ex: VoIP with silence supression 6

7 Services and Applications 7

8 Path to Wireless Broadband Internet [Shakouri, WiMAX World USA 06] GPP: WCDMA WCDMA R.99 HSDPA R5 HSUPA R6 LTE SAE 3GPP2: CDMA2000 1xEVDO Rev 0 1xEVDO Rev A EVDO Rev B Phase II WiMAX: /HiperMAN WiMAX ETSI HiperMAN OFDM Mobile WiMAX e-2005 SISO/OFDMA Mobile WiMAX SIMO/MIMO Mobile WiMAX AAS 8 Mobile WiMAX will be available before LTE, Phase II, and 4G Source: WiMAX Forum

9 Introduction dates [Shakouri, WiMAX World USA 06] 28 WF Certified Products by: Alvarion Airspan Axxcelera Aperto Proxim Redline Siemens Sequence SR Telecom Selex Telsima Wavesat Customer premise WiMAX Certified Devices for Fixed Services Portable WiMAX Certified Devices for Portable Services 2007 WiMAX handsets and entertainment devices 2008/9 9

10 Point-to-multi-point, PTM, cell at 3.5 GHz The BS was installed at FCS CPEs 10

11 Micro-cellular LoS Dimensioning 11 a UBI, main building b UBI, Faculty of Engineering c UBI, Faculty of Social Sciences d City Council e Police Station g Health Centre f Hospital

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13 The area under study - Health Science Faculty, FCS 13

14 Detailed measurements of SNR in DL Frequency license bands: MHz MHz 14 Throughput max = 230 kb/s = 1840 kb/s (per SU) 16-QAM with several coding rates; however it increased to ~ 6 Mb/s after QoS classes were configured

15 Modulation and coding schemes 15

16 LoS Discovery with Geographic Information Systems 16

17 SNR trend curve for measured locations around FCS Meas ured and c omputed (S UI model) C /N (d ) C /N Type A C /N Type B C /N Type C Measured C /N Log. (Measured C /N) f = 3.5 GHz b rf = 3.5 MHz G e = G r = 17 dbi P e-max = -2 dbw 17

18 Is the SUI model always suitable? Meas ured and c omputed (modified F riis ) C /N g = (km ) C /N L (gama=2) C /N L (gama=3) C /N L (gama=4) Measured L og. (Measured) 18

19 Cellular Planning 19 Over the region of Beira Interior, with an area of 550km 2, the number of cells necessary to cover the area under study is 14 and 24cells, approximately, for coverage distances R=4 and R=3km, respectively

20 Pedro Sebastião will give the details on planning tools 2005, it - instituto de telecomunicações. Todos os direitos reservados.

21 PTP pre-wimax Link B100 The point-to-point, PTP, WiMAX link was installed to connect the Health Science Faculty, FCS, of our University to Reitoria The length of this WiMAX link is meters f = 5.4 GHz (Pre-WiMAX); EIRP max = 30dBm Alvarion BreezeNET B 21

22 Altitude [m] i Altitude [m] i PTP links with relays FCS Hospital Amato Lusitano FCS - Gardunha Link Gardunha - Castelo Branco Link d [Km] Altitude Feixe Elipsóide (+) Elipsóide (-) d [Km] Altitude Feixe Elipsóide (+) Elipsóide (-) 22

23 Design of Point-to-point Radio Links In IEEE standard the bit error ratio due to selective fading is zero if there is LoS When fading is considered, the minimum carrier-to-noise ratio, C/N min, is given in db by where m u is the link margin for uniform fading, in db, and selective fading is negligible The probability P that the received power p is less or equal to p 0, in the worst month, may be estimated by using an expression of the form where F is the deep fade occurrence factor (Morita) 23

24 PTP antennas characteristics GHz 28 dbi, 4.5o, detached, flat, 2 x2 5, GHz 21 dbi, 10.5 horizontal x 10.5 vertical, flat. 24

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26 Link Covilhã (FCS) - Gardunha FCS Gardunha 26

27 Link Gardunha - Castelo Branco Gardunha Castelo Branco Antenas Hospital Amato Lusitano 27

28 Conclusions WiMAX cellular Planning aspects and PTP links design and tools were covered in this presentation Coverage, interference, and capacity issues are crucial in planning Field trials are being conducted for the PTM cell in Covilhã with Alvarion equipment, by using the license given by ANACOM at 3.5 GHz Practical deployments of PTP links were also presented LoS dimensioning issues were addressed From a planning exercise in the district of Covilhã one concluded that there is a strong need of using sectorial antennas to guarantee an adequate coverage and interference mitigation Results are promising and will provide experimental feedback to the planning process 28

29 Thank you! CEBIT Hannover 29

30 Design and Planning of WiMAX Networks (MobileMAN) Part II Planning Tools for Wireless Networks WLAN (Wi-Fi) and WMAN (WiMAX) António Rodrigues, Fernando Velez, and Pedro Sebastião 2005, it - instituto de telecomunicações. Todos os direitos reservados.

31 Outline Motivation and Scope Tools for wireless network planning Propagation models (indoor/outdoor) Examples of planning Wi-Fi and WiMAX networks Main conclusions Future work 2

32 Motivation and Scope Develop a tool for technical and economical planning of indoor/outdoor wireless networks. Provide to the wireless network designers an user friendly and efficient planning tool to optimize and simplify a given network Addressing: Coverage (considering that all points in a given area should be covered) Capacity (considering the number of users and the corresponding applications) 3

33 Planning Tools: Inputs/Outputs Input Output Plant Number of terminals Applications Obstacle Types and Location Covered Areas Definition Define location and number of BS f(pr [mw]) Define location and number of BS f(data rate [Mbps]) Economic Plan f(manufacturer) 4

34 Planning Tools: Manual versus Automatic Planning What do the tools allow for? Manual Planning The user select the BS locations The application computes coverage and interference figures Automatic Planning The application computes the BS location and the corresponding coverage/capacity and interference figures 5

35 Indoor Propagation Model * Path-loss Attenuation Sum of partition attenuaction factors for a path (AP PC) PL( d )[db] d PL( d 0 )[db] 10nSF log FAF[dB] PAF[dB] d0 Distance between AP and terminal Average Attenuation at reference distance Exponent value for the same floor Floor attenuation factor (12.9 db) same floor Partition attenuation factor for a given obstruction *[Rappaport 2002] 6

36 outdoor propagation model * Path-loss Attenuation lognormal-distributed random variable typical values (8.2 to 10.6 db) ( m 0, ) S S PL d A 10 log d 10 X f X h S d 0 A 4 d 20 log 0 a b h c h 6.0 log X f f 2000 X h b b Correction factors for frequency log hm 20, for terrain types A and B 20.0 log hm 20, for terrain type C Another option is the modified Friis propagation model Correction factors for TS (receiver) antenna height above the ground. d0=100 m, hb is the BS height above ground, in meters (10 < hb < 80 m), a, b, and c are parameters which are chosen according to three environments. *[SUI model] 7

37 Example 1: Indoor Wi-Fi Planning IEEE802.11g 8

38 Example 2: Outdoor Wi-Fi Planning IEEE a/g (Parque das Nações) 9

39 Example 3: Outdoor Wi-Fi Planning IEEE802.11b (Parque das Nações) 10

40 WiMAX Planning: Some Simulation Conditions Frequency Band width transmitter power (Rural) 3.5 GHz 3.5 MHz 34 dbm User urban density [users/ km 2 ] 10 User rural density [users/ km 2 ] 0.1 Total number of users 172 Transmitter power (Urbana) transmitter gain (BS) Receiver gain (CPE) Height of transmitter tower Height of CPE s 15 dbm 20 dbi 18 dbi 30 m 1 m Users of class 1 [%] 40 Users of class 2 [%] 50 Users of class 3 [%] 10 Users of class 1 RT [%] 80 Users of class 2 RT [%] 20 Users of class 3 RT [%] 40 12

41 Example 4: LoS and NLoS WiMAX Planning (Base Station Location) LoS: Line of Sight NLoS: Non Line of Sight 13

42 Example 5: WiMAX Planning (Base Station Location Considering Users Distribution) Urban area Rural area 14

43 Example 6: WiMAX Planning (Omnidirectional versus Sectorial Antennas) Type of Antenna Covered area [%] Area with Interference [%] Non-covered area [%] Omni directional Sectorial

44 Main Conclusions The planning tools were built to develop network planning for Wi-Fi (indoor and outdoor) and WiMAX thinking about efficiency and user friendliness for students and network designers Coverage, capacity, and techno-economical issues are crucial in planning The planning tool support several analysis, including, population density, LOS, power, interference, etc. The result analysis allows us to see how the several parameters could influence the network planning 16

45 Future Work Address mobile users (IEEE802.16e) and power control (under development) Validation of propagation models with experimental data Algorithm optimization (automatic planning mode) 17

46 18 Thank you!!!