BACKHAUL DIMENSIONING INPUT

One result of the dimensioning of the access network is the required capacity by the backhaul network. A typical backhaul network consists of point-to-point or point-to-multipoint radio links or even fiber rings in recent networks. In most cases the information rate that is originated to and from the backhaul network should be calculated to evaluate an existing infrastructure or consider the cost to deploy a backhaul network along with WiMAX.

The total committed information rate of a WiMAX PoP is linear to the number of sectors and average sector throughput, which mainly depends on channel bandwidth and deployment scenario. Considering trisector cells, and average throughput of 9 Mbps (5 MHz channel bandwidth), the total TDD committed rate is 27 Mbps. To estimate the FDD equivalent, which is directed to and from the backhaul network, the total rate is multiplied by the DL/(DL + UL) ratio. Hence the traffic that should be reserved in the backhaul network for a PoP with 2/3 DL WiMAX traffic is 18 Mbps. For a dual layer cell or 10 MHz channel bandwidth the backhaul rate per PoP would be doubled, around 36 Mbps. It is acceptable to include a 5 percent margin as in practice it is common to observe small deviations in sector throughput. During the deployment and the operation the exact backhaul traffic can be monitored through the management system and design adjustments can be made accordingly.

In certain occasions the network designers are requested to propose a backhaul system along with the WiMAX network. Although this is not in the scope of this chapter, however there are some interesting observations that can be highlighted. Clearly the multipoint systems are more cost effective than point-to-point radio systems when the WiMAX PoP number is high, the PoP are quite close to each other and when their backhaul rate is such that more than 3–4 WiMAX PoP per multipoint sector can be served (around 10–12 per site). This indicates that the WiMAX site backhaul traffic should be from 15 to 25 Mbps, which mainly refers to trisector cells with 5 MHz channel. For higher bandwidth systems, such as dual layer cells or with 10 MHz bandwidth per site the point-to-point solution may offer the higher required capacity. Again in a dense urban environment where sites are usually deployed with separation of 0.3–0.7 km the use of fiber (if available) could be a better solution. Concluding, the best backhaul system strategy can be determined by evaluating the number of WiMAX PoP, their backhaul rate, and finally the PoP positioning. Note that although the WiMAX network dimensioning is done in such way to optimize the access network, this does not suggest that the backhaul network is also optimized and a separate study may be necessary.

JOINT DIMENSIONING

The number of PoP and sectors were estimated according to the requirements of a dimensioning project. The final step is to combine these results into the optimum BS configuration. Clearly the estimated PoP and sectors are the absolute minimum according the needs of coverage and capacity, respectively. At this stage joint consideration may suggest that more PoP or sectors may be necessary. There are three possible conditions:

• Balanced network: The number of PoP approaches 1/x of the number of sectors, which means that in each PoP roughly x sectors will be deployed. The number of sectors for blanket coverage should be 3 < x < 6, where x = 3 for Mobile WiMAX. This condition ensures both the integrity of the footprint and satisfies the capacity requirement.
• Coverage-limited network: The number of PoP is quite higher than 1/3 of sectors. The network is coverage limited and in this case the number of sectors should be increased until the previous condition is met. The fact that the original business plan leads to a coverage-limited network should be stated in the dimensioning study. CapEX is driven by coverage performance indicators, while the additional sectors will further increase the air-interface capacity. Operators may want to revise the size of the service area, or exploit the additional capacity.
• Capacity-limited network: The number of PoP is quite lower than 1/3 of sectors, which indicates either additional PoP or higher sectorization (sectors/PoP). Increasing the number of PoP will trigger additional CapEX and OpEX in terms of site acquisition and preparation. Therefore, if a higher sectorization scheme is possible, such as when the terminals are fixed-outdoor, fixed-indoor, or nomadic where handover is not necessary, it should be preferred as a cost-optimum solution. When the network needs to accommodate mobile terminals and provide handover capability, the sectors should be 3 < x < 4 and more PoP may be needed. An alternative approach would be to deploy a dual layer cell where 6 sectors of 120° are used, however each pair of sectors (i.e., 1 and 4) is assigned the same azimuth. For a dual layer cell at least 6 channels are necessary for the frequency reuse of 1.3.3.

The selected number of sectors per PoP defines the BS configuration in terms of frequency reuse/channel assignment, and antenna beamwidth/azimuth/tilt, while other air-interface parameters are not related to dimensioning. Capacity or coverage dimensioning should be revised based on the above-mentioned conditions, for coverage or capacity limited cases, respectively. A comparison between initial requirement and actual achievement should be included in the dimensioning study.

CAPACITY DIMENSIONING - 4G

Further to providing adequate radio coverage to customers, the next equally important objective is to ensure sufficient air-interface capacity (throughput) to offer a wide range of services. Given a business plan, the network capacity is driven by the potential subscriber number and the committed rates for data and VoIP services, as discussed in services dimensioning. The purpose of capacity dimensioning is to translate the capacity into number of sectors, which then have to be distributed for the estimated number of PoP. The missing parameter is average operating sector throughput, which finally determines how many subscribers can be served in a sector. Defining the average sector throughput is quite complex as it involves interpretation of a wide range of parameters such as

• Accurate equipment specifications: PHY modes and SINR thresholds, advanced antenna system impact, interference mitigation mechanisms, scheduling intelligence, and terminal types.
• Deployment considerations: Available spectrum, reuse factor and channel assignment method, coverage type(s), propagation environment, and site suitability.
• Designer capabilities: Very good knowledge of the IEEE 802.16e standard, formal training or academic expertise in planning methodologies and their impact on practical networks, past deployment experience.

The sector throughput is usually provided as recommendation by the system vendor, however it can vary a lot depending on the deployment scenario. During dimensioning a more accurate estimation can be made through two approaches: 

(1) By extensive RF planning simulations and statistical processing that would result in a PHY mode regions map and give the average throughput. If clutter data are available this approach may provide a better view of the network performance. 

(2) By previous experience and interpretation of the above factors based on system performance observation. The former approach is time consuming, however it is much more accurate and is usually followed during actual network design. The latter is more appropriate during dimensioning.

Typically the equipment specifications include a table that matches the available PHY modes with their SINR requirement and the resulting Ethernet throughput (for different channel bandwidths) as in Table 1. The SINR values are given in the standard. The provided Ethernet rates correspond to a 60/40 DL/UL asymmetry and hence the TDD rate is the sum of DL and UL rates. The upper throughput bound can be achieved for an interference-free sector where terminals are located only in the 64QAM, 3/4 region, achieving around 10 Mbps TDD for the 5 MHz bandwidth. During practical deployments, the terminals will be scattered across the whole cell footprint, hence operating in various modes. Furthermore, interference due to frequency reuse may further downgrade the PHY mode for a particular terminal, especially if the number of channels is limited. A default assumption is to consider, as average sector throughput, the one corresponding to 16QAM, 1/2. Thereafter if the deployment conditions are favorable, as in the case of fixed-outdoor terminals or when enough spectrum is available for relaxed reuse, higher throughput should be expected. The throughput can be also enhanced by means of MIMO techniques and this should also be taken into account. It should be noted that the values in Table 2 refer to full usage of subcarrier (FUSC) permutation scheme, where all subchannels are allocated to users, hence the whole channel is exploited. In case segmentation is considered, i.e., partial usage of subcarrier (PUSC), the users in a sector utilize a specific segment (1–6 subchannels), and therefore the throughput in this case is reduced accordingly. Based on the standard, there will be regions in the DL and UL subframes for both FUSC and PUSC and in this case an average throughput condition should be expected. In most products, during the sector configuration, an RF designer can select or exclude segmentation according to deployment conditions.

Table 1: Ethernet Rates per PHY Mode (IEEE 802.16e System) 

		5 MHz Bandwidth		10 MHz Bandwidth
PHY Mode (CTC)	SINR (dB)	DL (Mbps)	UL( Mbps)	DL (Mbps)	UL (Mbps)
QPSK 1/2	2.9	1.4	0.9	2.7	1.7
QPSK 3/4	6.3	2.2	1.3	4.3	2.7
16QAM 1/2	8.6	2.8	1.7	5.8	3.6
16QAM 3/4	12.7	4.3	2.6	8.6	5.4
64QAM 1/2	16.9	5.8	3.5	11.6	7.1
64QAM 3/4	18.0	6.5	3.9	12.9	8.2

The process of selecting frequency reuse and channel allocation in sectors is very important for both capacity and coverage. In mobile WiMAX this can be done in a flexible manner, although frequency planning cannot be avoided. This is due to the possibility of nonuniform network layout, in most cases, where frequency planning may improve performance. According to mobile WiMAX terminology the reuse is denoted as 1.x.y, where x denotes the cell sectors and y the available channels. There are two main schemes under consideration: global reuse 1.x.1, where a single channel is used everywhere and cell/cluster reuse 1.x.y, where y = nx, n = 1, 2, 3. The most appropriate scheme is adopted, based on the systems’s special capabilities to reject or tolerate interference (i.e., via BF). An indicative performance of the most common  schemes for nomadic/mobile terminals (most sensitive to interference) is presented in Figure 1. It can be observed that for the 1.3.1 scheme the SINR drops well below the 3 dB threshold for the lowest modulation scheme, QPSK, hence a significant part of the cell footprint, especially among adjacent sectors, has no coverage. In the case of the 1.3.3 scheme, the interference appears closer to the cell edges and hence the coverage blanks spots are much smaller. It should be noted that in the 1.3.3 scheme the higher order PHY mode schemes extend to a larger region, hence indicating an improved sector throughput. Furthermore, when employing PUSC instead of FUSC, the 1.3.1 scheme behaves essentially as 1.3.3, while 1.3.3 as 1.3.9. It is typical for a sector to operate in 1.3.1 FUSC mode for terminals with good link quality and short link distance and in PUSC mode, which is equivalent to 1.3.3 for terminals that would otherwise achieve low SINR (due to low signal strength or interference).

Figure 1: SINR map for (FUSC) and (PUSC) schemes.

Knowing the average sector throughput as described in previous paragraphs, capacity dimensioning can be completed as follows: Initially an analysis on the customers that can be accommodated in a sector is performed. This is done by analyzing the service plan and calculating the average data and VoIP CIR per service and customer. Then a graph that shows the throughput versus the subscribers is obtained, as in Figure 2. The average sector throughput is projected in the sector total graph indicating the corresponding subscriber number. Considering a 10 Mbps throughput, each sector can accommodate around 70 customers. Moreover a graph such as in Figure 2 is quite useful also during network operation as when the throughput takes a higher value, due to special circumstances, additional subscribers can be served. The second step is to divide the number of customers per area with the customers/sector to calculate the required number of sectors.

Figure 2: Estimated sector and services throughput versus subscribers.