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Article

Availability and Fade Margin Calculations for 5G Microwave and Millimeter-Wave Anyhaul Links

Nokia Software, Cloud Core, Budapest Technology Center; H-1083, Bókay János utca 36-42, Budapest, Hungary
Submission received: 26 October 2019 / Revised: 25 November 2019 / Accepted: 28 November 2019 / Published: 2 December 2019

Abstract

:
The deployment of new radio access technologies always provides a good opportunity and timing to optimize the existing mobile front- and backhaul (commonly called “anyhaul”). The legacy systems (Long-Term Evolution (LTE), High-Speed Packet Access (HSPA), third-generation mobile (3G), second-generation mobile (2G)) already extensively utilize the transmission and transport capacities of the mobile anyhaul. With the current launch of 5G (fifth-generation mobile) and recent LTE-A (Advanced Long-Term Evolution), additional new transmission capacities are required again. Depending on the traffic and network topology, additional cell sites are built, and even more locations are connected with fiber optics. The existing microwave and millimeter-wave links are rotated toward those aggregation points that already have optical-fiber access. Due to the increased cell-site density, the average distance of the radio access links can be reduced by network and topology optimization. The reduced hop lengths combined with adaptive modulation and automatic power control bring an opportunity for capacity increase in shortened radio links. Links newly deployed for 5G find a wide spectrum in the millimetric V, E, W, and D frequency bands. This paper discusses the availability and hop-length targets of the anyhaul links that should be carefully kept by proper planning and monitoring.

1. Introduction

This invited paper is an extended version of the paper presented at the 42nd Telecommunications and Signal Processing conference [1]. The paper investigates the recommended hop length and availability of microwave and millimeter-wave (µ/mmW) radio links operating in traditional and new frequency bands. In Section 2 and Section 3, it is shown that, in addition to the preferred fiber-optical access, µ/mmW radio links continue to play an essential role in fronthaul and backhaul (commonly called “anyhaul”) deployments of future mobile networks. In Section 4, a straightforward calculation method is given for the fade margin (FM) of the links by using radio equipment parameters and system gain (SG). Then, it is explained how to determine link availability from the calculated FM and for the given hop length by taking rain and atmospheric attenuation into account. In Section 5, maximum recommended hop-length curves are plotted as a function of rain-rate intensity for the different frequency bands. The paper—as a planning guideline—focuses on real deployment scenarios. Compared to earlier research and case studies, a general approach is presented for the practical link designs [1]. With the step-by-step calculation method presented, the different antenna size, the link polarization, and the used modulation modes can be taken into account. The presented calculation method and charts provide useful help in the planning phase of newly deployed µ/mmW links. The results also help in optimization projects, when existing links are shortened by rotating toward new fiber access points. For the first time, maximum hop-lengthvs vs. rain-rate curves are plotted that belong to the pre-determined availability of the radio links. Earlier, these calculations were done using planning tools; here, the results are plotted by calculations of a simple Excel macro. The charts presented in Section 5 are illustrative examples, and the presented method can be used for any equipment and antenna combinations having different system and antenna gain values. Finally, in Section 6, an interesting conclusion is drawn; in Central/Eastern Europe, even smaller countries exhibit significant geographical variations of rainfall-rate intensities. Therefore, to maximize hop lengths for a given bit rate and SG, the local rainfall-rate statistics are recommended to be used during deployment and optimization. Finally, the calculation method is helpful in the monitoring phase of mobile anyhaul networks, when field results of the running µ/mmW links are compared to the planned parameters.
The new radio access technologies (RATs) enable diverse services and different use cases in mobile networks (NWs). On one hand, the 5G (fifth-generation mobile) broadband services may require Gbps (Gigabit/second) peak data rates or even beyond. On the other hand, several critical services, e.g., remote control, robotics, or vehicular applications, require ultra-high reliability and low latency (Figure 1) [2]. Therefore, the deployment of 5G necessitates a quick expansion of the fiber-optical transport network, as well as the µ/mmW radio links in the entire mobile front- and backhaul [1,2,3,4,5,6]. The existing mobile anyhaul networks already provide the transmission capacity for the recently deployed Long-Term Evolution (LTE-A (Advanced), LTE) evolved Node-Bs, as well as the capacity for the legacy second- and third-generation (2G/3G) base stations in most of the countries [7,8].
With the new 5G radio access points (RAPs), the density of sites is further increasing. Combined systems mesh various generations that are either legacy 2G sites, 3G Node-Bs, LTE eNode-Bs, or new 5G RAPs. The different RATs (or simply “generations”) are frequently co-located to accelerate network rollouts, and they re-use earlier site investments to benefit from the capacity of the existing front- or backhaul. Earlier RATs are continuously modernized, often “re-farmed” toward 4G and 5G, resulting in a continuous expansion and optimization of the mobile anyhaul [1,2,3,4,5,6,7,8,9]. This paper investigates how the earlier deployed and new µ/mmW links can contribute to the demands of bandwidth increase. Topology optimization, shortened radio links, adaptive modulation, and automatic transmit power control (ATPC) techniques can all contribute to extra capacity for the sites. However, for 5G, low latency and high availability requirements should also be fulfilled [2,5].

2. Connection Options and Topology Optimization after Site Densification

With the deployment of pico-cells and 5G introduction, the distance between neighboring sites is continuously decreasing. Meanwhile, the capacity demands of the sites are increasing. As a result, more and more locations require fiber-optical connection or microwave links with increased access transmission capacity [1,2,3,4,5,6,7,8]. The rapid network expansion inherently provides the possibility of optimization by means of topology re-planning. Thanks to the site densification, the hop lengths of the micro- and millimeter-wave access links can be reduced. A recent case study estimated significant hop-length reduction with 5G deployment [9]. The shorter links can either use higher millimeter-wave frequencies where available bandwidths are wider; alternatively, when the same hardware is re-used, the average output power can be regulated by ATPC, and elevated modulation can provide higher bit rates [9,10,11,12,13,14]. Thus, the access capacity can be increased and, with careful re-design, the possible radio interference can simultaneously be reduced. Figure 2 shows two connection scenarios: how 5G and LTE cells can be connected to the LTE and 5G cores in the early 5G deployment phase, and then to a common 5G core in the mature phase of 5G. More connection options are discussed in Reference [3].
As an example, the µ/mmW links of an urban access network are shown (dark lines) in Figure 3, as seen in the link planning tool. Line-of-sight (LoS) information for possible new radio hops is plotted with light-green lines. High sites having fiber-optical access points are considered as transmission hubs (e.g., the locations 102A and 270C in Figure 3) and are target end-points of new links deployed after site densification.
Route diversity can be achieved with short radio chains composed of a few µ/mmW hops and fiber-optical loop-back. Alternatively, the entire loop can be fiber-optic and, from the aggregation points, radio links can access the sites in star or in tree topology [8,15]. It should be mentioned also that very long radio chains of multiple hops increase the delay and, therefore, cannot be tolerated by low latency 5G services. Finally, a full mesh topology composed of μ/mmW radios, free-space optical (FSO) links, and fiber-optical cables provides the mobile anyhaul [16,17,18]. Satellite links are very rarely used in Europe due to the high associated installation and lease costs and the relatively low capacity provided. Twisted pair or coaxial cables are limited in the bandwidth distance product; therefore, metallic cables were step-by-step replaced by optical fibers. Lightweight optical fibers are already widely used for remote antenna heads as feeder lines, and there is a significant research activity of radio-over-fiber (RoF) systems to deliver combined “fiber/wireless” networks for a reduced cost, with easier installation to support 5G deployments [5,17,18,19,20,21,22,23].
The evolving networking scenario is shown in Figure 4. Due to low latency requirements, cloudification, and 5G slicing, the cloud core networks tend to be more distributed toward the edge sites. Current distributed radio access networks tend to be more centralized, and the role of fiber optics in cloud RANs (radio access networks) is increasing [17,18,19,20,21,22,23]. However, the microwave and millimeter-wave links still continue to form an essential portion of the mobile anyhaul [1,3,4,6,7,9]. Business analysts forecast an initial 50%/50% split of fiber and µ/mmW access for 5G. Later on, this split may change to 75% optical fiber and 25% radio, when new optical access points—often called PoPs (points of presence)—are added to the networks. This paper focuses on the radio links of the mobile anyhaul. The possible new mmW frequency bands, the radio link availability targets, and the outage caused by rain are discussed in later sections of the paper.

3. Higher Link Frequencies and Bit Rates

As the access links are getting shorter and the capacity demands are increasing continuously, frequencies in millimeter-wave bands are becoming more and more employed [1,4,5,6,9,11,12,13]. The millimeter-wave bands V, E, W, and D (57–66, 71–86, 92–114.25, and 130–174.8 GHz, respectively) are coming into focus because wider radio-frequency (RF) bandwidths are available and, as such, the bit rate of the connections is increased and latency is reduced [12,13,14]. The European Telecommunication Standards Institute (ETSI) discussed the possible frequency bands in Reference [24]. The channel spacing may reach GHz values, i.e., as a multiple of 250 MHz, as seen in Table 1. In the 71–86-GHz bands, the link bit rates go beyond Gbit/s. In the widest 2-GHz RF channel, the link bit rate is above 10 Gbps with equipment from the best equipment class of ETSI [14,24,25,26].
Please note that there may be deviations from the frequency allocation rules indicated in Table 1 based on local decisions of the national communication authorities. The European Conference of Postal and Telecommunications Administrations (CEPT) already allocates frequencies up to 175 GHz [27,28,29]. Actual research of fiber/wireless systems goes above 200 GHz [5,12,19,30].
Different methods are utilized to increase the overall transmission capacity of a radio link. A traditional approach is to combine two radio channels operating with different carrier frequencies. Multiple channels operating at different carrier frequencies can also be branched together. Polarization multiplexed links (often simply called “dual-polar” or “cross-polar” links) add up the two different polarizations (i.e., vertical and horizontal) to double the transmission capacity [13,14,31,32,33,34]. However, dual-polar links require special antennas, and are more sensitive to interference and rain, as discussed in later sections. The combination of cross-polarized and multi-frequency techniques is also well known and widely used. For example, by adding two radio channels (in the same frequency band) and two polarizations, the link capacity can be quadrupled. A novel and interesting approach is to aggregate parallel links operating in different frequency bands to increase capacity. A recent field trial reported an aggregated bit rate of 100 Gbps over microwaves with these techniques [35]. Dual-band antennas are available to combine traditional frequency bands with the E band [9,26].

4. Link Parameters and Availability Calculation

In addition to the climatic and meteorological factors, the availability recommendations for individual links depend on the topology and diversity methods used. Instead of “bulky” hardware-based 1 + 1 link protection, in the urban environment, route diversity is recommended [15]. The installation of additional parabolic antennas for link diversity is avoided due to the undesired visual impact. The availability targets are split into site- and link-specific targets. Overall link availability targets are usually given as “four-” or “five-nines”. Each radio access link should have, e.g., A = 99.99% availability over time, including outages due to rain and equipment failures. This 99.99% availability corresponds to an annual outage of approximately 52 min. Outages of the individual links are caused by the following:
  • propagation (intensive rain and other atmospheric conditions, such as snow, fog, oxygen, or water vapor absorption at very high frequencies);
  • link unavailability due to radio equipment failure.
With reasonable dish sizes, the link unavailability (U) should be U = 0.01% of the time or less. The link planning guidelines target individual link availability for an annual timeframe that includes the seasonal fluctuations of weather conditions. The goal is to ensure reliable links, regardless of the undesired effects of propagation phenomena and rain. Exceptions may occur, when antenna size is limited due to civil work constraints, e.g., wind load or authorities not permitting the installation of bigger diameter dishes. In the calculations, the frequently used frequency bands are investigated [24]. This paper focuses on rain intensities R < 100 mm/h that are typical in Central and Eastern Europe. For completeness, higher rain rates are also calculated, following the rain and propagation model of the International Telecommunication Union, ITU-R P recommendations [36,37,38,39].

4.1. System Gain Calculation

The International Telecommunication Union (ITU) defines system gain as follows [1,40,41]:
S G ( B E R ) [ dB ] = P TX [ dBm ] P RXth ( B E R ) [ dBm ] .
The system gain appropriately characterizes the transmitter and the receiver modules of the digital µW or mmW radio link. Thus, SG helps to determine the maximum distance that the equipment can connect with a given, pre-defined availability. PTX is the “nominal” transmit power at the output of the transceiver module (point C/C’ in Figure 5). The reference points are according to the definition of ETSI (as provided in Reference [24]). For simplicity, neither feeder lines nor additional branching are indicated in the figure (for multi-channel or dual-polar links). When there is no feeder or additional branching network, then the transceiver can be directly connected to the transmitting antenna, as plotted in Figure 5. In this case (C′ = D′), the output power PTX can be measured at the connection point of the antenna (D/D’ in Figure 5).
“Nominal” refers to the fact that, in a wide frequency band and at changing ambient temperatures, variation of a few dB of the output power may occur and is tolerated [24,42]. The calculations focus on the output power level that is guaranteed at any frequency and temperature within the operational range of the outdoor unit (ODU). PRXth is the receiver sensitivity threshold, i.e., the input power at the receiver that is required for demodulation. Again, if there is no feeder and branching network, then this input power level can be measured directly at the antenna connection point (point D in Figure 5). In a digital link, the sensitivity threshold of the receiver is defined for a given modulation mode and bit error rate (BER) [41,43]. In the case of transceivers capable of adaptive modulation, each modulation mode and the corresponding bit rate has its own set of BER thresholds [10]. In this paper, we use the threshold values belonging to BER = 10−6. Please note that BER = 10−3 thresholds are also often used. From a system design point of view, any gain due to error correction coding (e.g., FEC, forward error correction) is already considered in the given thresholds.
It is important to mention that an alternative system gain definition also includes the gains of the transmit (TX) and receive (RX) antennas (please see Reference [33]).
S G a ( B E R ) [ dB ] = P TX [ dBm ] + G TXa [ dBi ] + G RXa [ dBi ] P RXth ( B E R ) [ dBm ] ,
where GTXa and GRXa stand for the transmit and receive antenna gains, respectively. As indicated with the “dBi” unit, at microwave and at millimeter-wave frequencies—by definition—the antenna gains are compared to the gain of the isotropic antenna. To distinguish between the two alternative definitions of system gain, in Equation (2), we note SGa to indicate that both TX and RX antenna gains are added already. The two system gain definitions are illustrated in Figure 6, where only the µ/mmW parts are indicated. The payload and modulator/demodulator blocks shown in Figure 5 are not repeated in Figure 6.
Using the alternative system gain definition SGa is convenient when the transceiver has either an integrated antenna built together with the ODU (Figure 7a) or a flip-mount antenna directly attached to the ODU (Figure 7b). For dual-polarization and multi-channel links, additional signal combiners and/or feeder waveguides are required (Figure 7c,d) that introduce additional losses into the entire system.
A microwave or millimeter-wave link is operational, as long as the system gain is higher than the sum of link losses minus the sum of link gains in a hop.
L i n k   l o s s e s [ dB ] L i n k   g a i n s [ dB ] < S G [ dB ] .
When designing µ/mmW links, the network planners should use the SG values carefully, i.e., they must remember which definition is used by the equipment manufacturers when the parameters are specified. The calculation of a complete link is presented in the next section.

4.2. Link Budget and Fading Margin Calculations

The received signal level (RSL) behind the receiving antenna is calculated as follows [31,41,43]:
P RX [ dBm ] = P TX [ dBm ] + G TXa [ dBi ] + G RXa [ dBi ] P L [ dB ] ,
where PL is the propagation loss. With outdoor units integrated with or directly mounted onto the antenna (Figure 7a,b), the waveguide and additional branching loss terms are zero in Equation (4) [31,40]. As the link is single-polarized, a polarization combiner between the ODU and the antenna (Figure 7c) is not discussed [34]. The propagation loss PL is calculated as follows:
P L [ dB ] = F S L [ dB ] + A r [ dB ] + A a [ dB ] + A mp [ dB ] + A o [ dB ] .
In clear LoS conditions, the obstacle loss Ao is zero. At high frequencies, the effect of multipath fading Amp is usually not relevant, thanks to the very short hops. Typically, in an urban environment, any alternative propagation path is blocked by buildings or other obstacles. Multipath fading is more relevant at lower frequencies (i.e., frequencies at 18 GHz or below) and where reflection from large water surfaces may happen, e.g., propagation over lake or sea. Ar and Aa are the terms of rain and atmospheric attenuation in Equation (5). The unfaded received signal level PRXu is determined by the free space loss (FSL), the transmitted power PTX, and the gain of the antennas (Figure 8).
P RXu [ dBm ] = P TX [ dBm ] + G TXa [ dBi ] + G RXa [ dBi ] F S L [ dB ] .
The free space loss is calculated as follows [1,31,40]:
F S L ( f , d ) [ dB ] = 92.44 + 20 · log ( f   [ GHz ]   ) + 20 · log ( d   [ km ]   ) ,  
where f is the frequency of the link, and d is the hop length. The constant of 92.44 dB allows the calculation in convenient GHz and km units for the frequency and distance, respectively. The fade margin (FM) is the difference between the unfaded RSL and the receiver sensitivity threshold.
F M [ dB ] = P Rxu [ dBm ] P RXth ( B E R ) [ dBm ] .
FM should compensate for all unwanted factors degrading the link availability: rain, fog, dust, snow, atmospheric attenuation, and interference. Interference degrades the sensitivity threshold PRXth of the receiver. In a sunny scenario, the link can switch to an elevated modulation mode to carry more data. Combining Equations (1), (6), and (8), we get
F M ( f ,   d ,   Ø )   [ dB ] = S G [ dB ] + G TXa [ dBi ] + G RXa [ dBi ] F S L [ dB ] .
Equation (9) simplifies to Equation (10) when the transmit and receive antennas have equal gain (i.e., same antenna type and dish size are used at both ends of the link).
F M ( f ,   d ,   Ø )   [ dB ] = S G [ dB ] + 2 G ant [ dBi ] F S L [ dB ] .
As seen, at a given frequency, a higher system gain results in a better fade margin of the link for a given d hop length and Ø antenna diameter. In mobile front- and backhaul expansion projects (simply “anyhaul” or also called “X-haul” [13,25]), the manufacturer and the type of the radio equipment are usually defined. Thus, parameters SG, PTX, and PRXth are given and cannot be selected freely. In several projects, for example, it is expected to re-use the equipment running in the field. Only few parameters remain free for the planners in practice, when the new links in the network are designed. In the planning phase, therefore, both the frequency band f and the antenna diameters should be carefully selected for a given hop length d. Lower frequencies are more “valuable” and should be reserved for long-haul links. For simultaneously reducing the undesired radio interference [43] and increasing the FM, preferably bigger dish diameters and the use of ATPC are recommended.
Radio links using adaptive modulation have different PRXth thresholds for the different modulation modes (Figure 9). The low modulation mode is active in the rainy minutes when FM compensates for the loss caused by rain. During sunny periods when the FM is available, the link can jump to elevated modulation modes; thus, more data can be transmitted [1,11,31,32,33,34]. For simplicity, Figure 9 shows quadrature amplitude modulation (QAM) only up to the 512 states [10]. State-of-the-art transceivers can use up to 4096-QAM to reach multi Gigabit/s bit rates as discussed in Section 3.
Finally, the link is operational as long as its fade margin is greater than the losses caused by the rain and by the atmospheric attenuation (obstacle losses and interference are not considered).
F M   [ dB ] > A r , 0.01 % [ dB ] + A a [ dB ] .

4.3. Rain and Atmospheric Attenuation

The rain attenuation calculation follows the methodology discussed in ITU-R P.530 [36,37,38]. The rain attenuation term A0.01% refers to the attenuation that is exceeded for 0.01% of the time and caused by intensive rainfall. This rain attenuation—exceeded in 0.01% of the time—is given as
A 0.01 % [ dB ] = γ R d eff = γ R d 1 + d / d 0 .
In Equation (12), γR is the specific attenuation (in dB/km) due to rain, and deff is the effective hop length.
d eff = d 1 + d / d 0 .
When the rain rate is R0.01% ≤ 100 mm/h, then
d 0 = 35 e 0.015 R 0.01 % .
When R0.01% > 100 mm/h, then d0 = 35 × e−1.5 (i.e., R = 100 mm/h is used for all rain rates above 100 mm/h). However, such intensive rain is not relevant in the Central and Eastern Europe region [37]. According to ITU-R P.838, the specific attenuation for vertical polarization is calculated as follows:
γ R , V = k V R α V ,
and that for horizontal polarization is calculated as follows:
γ R , H = k H R α H ,
where the constants kV, αV, kH, and αH depend on the frequency f and the polarization of the link [38]. V and H stand for vertical and horizontal polarization, respectively.
The atmospheric attenuation, Aa, is caused by the absorption of gaseous particles in the air. Compared to rain attenuation (Ar,0.01% in Equation (11)), for few-km short hops, Aa is negligibly small in most of the frequency bands used by µ/mmW links. As seen in Figure 10, up to 300 GHz, there are four remarkable attenuation peaks [39]. Water vapor causes extra attenuation in the 23 GHz band (where Asp = 0.2 dB/km) and around 180 GHz.
Other high attenuation peaks are caused by oxygen absorption in the 56–64 GHz and in the 120 GHz range [39,44,45]. As seen in Figure 11, the attenuation due to oxygen absorption is very high: about Asp = 13–15 dB/km in the 58–62-GHz band. Therefore, the 57–63 GHz links are limited to a few hundred meters, and the use of vertical polarization is recommended [44,45]. On the other hand, at 56–64 GHz, due to the very high atmospheric attenuation, the chance for interference from other links is rather small, enabling severe frequency re-use. The 30 or 50 MHz bands are allocated by CEPT in this range, as listed in Table 1.
For the frequently used bands, Table 2 summarizes the typical atmospheric attenuation values per km (at sea level). These values are used in the calculations.
For the entire link distance d, the total gaseous attenuation caused by water vapor and oxygen is calculated as follows:
A a [ dB ] = A sp [ dB / km ] · d [ km ] .
The atmospheric attenuation per km, Asp, is shown together with rain attenuation in Figure 12 up to 200 GHz [12,30,32]. As seen, between 64 GHz and 120 GHz, there is a useful frequency “window” where new mmW links can benefit from a wide spectrum with atmospheric attenuation below 1 dB/km. Also, as seen in Figure 12, rain attenuation is dominant at all frequencies, except for 60, 120, and 180 GHz, where the atmospheric attenuation peaks are visible even when the rainfall rate is above 20 mm/h.
Equation (11) has no closed-form solution. After inserting the rain and atmospheric attenuation formulas (Equations (12)–(17)) into Equation (11), the maximum hop length d can be calculated numerically for a given R0.01% rainfall rate, polarization (either V or H), and frequency f.
S G + 2 G ant > 92.44 + 20 log ( f ) + 20 log ( d ) + k V / H R α V / H d 1 + d / 35 e 0.015 R 0.01 % + A sp d ,
where f is in GHz and d is in km units. The SG, Gant, and all the attenuation terms are in dB. Index V/H shows that parameters k and α are different for the two polarizations. In Section 5, systematic calculation results are given for typical system values considered in dense access networks.

4.4. Obstacle Losses

By careful link design and installation, any unwanted extra loss should be avoided, to preserve the highest possible fade margin for the link. Microwave and millimeter-wave links require clean line-of-sight conditions that are checked in the planning phase of the links in two ways. The first method is to use digital maps, digital terrain, and clutter models in the link planning tool. The second method—not to be forgotten—involves site visits, where the LoS of the planned link is confirmed and photographed. It is strongly recommended to always document the clean LoS in an LoS report and to insert the confirmed LoS paths into the planning tool (green lines in Figure 3). With actual high-performing digital cameras, links of 50 km or even longer can be checked. Later, trees (Figure 13b), new buildings, cranes, electric cables, or chimneys may block the link. As a rule of thumb, at least, the first Fresnel zone of the link should be clean [32,41]. However, in some urban environments, the obstacle loss cannot be avoided, e.g., when the link must operate behind window lamels or camouflage to reduce the visual impact of the antenna (Figure 13c). In such cases, the extra loss caused by the obstacle (Figure 13) should be taken into account in the link budget calculation (Equation (5)).

5. Results and Calculation Examples

Results of systematic hop-length calculations for short- and medium-haul digital µ/mmW point-to-point links are presented in this section. Solving Equation (18), the recommended maximum distances were calculated. All the links operate in ETSI-defined communication bands widely used in Europe, at frequencies of 13, 15, 18, 23, 26, 28, 32, 38, 58, and 80 GHz. Up to 38 GHz, the links in the calculations used 14 MHz channel spacing (ETSI and ITU channel raster) and 32-TCM (trellis coded modulation) for 34 Mbit/s [10,24]. The 58 GHz links used 50 MHz channel spacing. The transmitters were set to the highest output power and the links had identical antenna size on both ends. The main parameters of the calculated links are summarized in Table 3 and Table 4. In the 13–38 GHz bands, slip-mounted 60 cm- and 30 cm-diameter parabolic dishes are used (marked with ø). At 58 GHz, ø 30 cm parabolic dishes and integrated 20 cm rectangular antennas are used (marked with ). The integrated rectangular 58 GHz antenna is a grid composed of radiating waveguide elements. The low-profile antenna structure and its measurement are discussed in Reference [46]. The system and antenna gain values are illustrative examples. Naturally, the simulation can also run with different SG values and with asymmetric antenna configuration.
The graphs in Figure 14 and Figure 15 were drawn using the rain model according to ITU-R P.838 [38]. The shadowed regions show typical rainfall rates in Central and Eastern Europe, (H and K rain zones according to ITU-R P.837 [37]). The curves were calculated without any additional obstacle loss (Figure 13). Single-polarized links were calculated, and there was no polarization combiner loss calculated in the link budget. Antennas were directly connected to the transceivers, thus no waveguide losses were considered due to feeder lines. Vertical polarization is shown in Figure 14a and Figure 15a. Horizontal polarization is shown in Figure 14b and in Figure 15b. As earlier discussed in Section 4, at 58 GHz frequency, the atmospheric attenuation is very high. Therefore, horizontal polarization is not recommended, and only vertical polarization is calculated [44,45,49]. Note that 7–15 GHz links are rarely used in a dense urban environment. For the 13–18 GHz links, the minimum recommended dish diameter is 60 cm. Several communication authorities specify very strict antenna pattern requirements for the lower frequency bands to avoid interference (e.g., minimum antenna gain, maximum sidelobe, front-to-back ratio) [50]. In practice, the 30 cm dishes are not permitted in the frequency bands below 18 GHz in some countries to achieve better frequency re-use. Therefore, the calculated 13–18 GHz links with 30 cm dishes are shown only for comparison (the upper three curves in Figure 15a,b).
Finally, calculation results are shown for the E band. In the examples, the parameters of the Nokia millimeter-wave radio family are used, as given in Table 5. The “Wavence” radios can operate with several channel spacing options at 80 GHz: 62.5 MHz, 125 MHz, 250 MHz, 500 MHz, 750 MHz, 1 GHz, 1.25 GHz, 1.5 GHz, and 2 GHz. The 80 GHz radio uses adaptive modulation up to 256-QAM.
In the calculations, 1 GHz RF bandwidth was selected. Three antenna configurations and different modulation modes were compared (from binary phase-shift keying (BPSK) to 128-QAM). The ø 12-cm antenna was integrated with the ODU (see Figure 7a). The one-foot and two-foot antennas were slip-mounted. Figure 16 plots the calculation results. As seen, depending on the antenna size and modulation used, the links can operate in distances of 1–4 km with A = 99.99% availability in the K rain zone. Calculations show that the predicted behavior is very similar for horizontal and vertical polarization in the E band (Figure 16d), which needs to be experimentally verified by long-term measurements. Finally, the curves, such as that shown in Figure 16e, help to decide the minimum required modulation mode and, as such, the bit rate that a link can support in the case of intensive rain for a given hop length. The continuous monitoring of radio RSL and modulation mode is supported by Wavence radios, as illustrated in the example of Figure 16f.

6. Local Rainfall Rates and Experimental Verification

As seen in the global rain-rate map of Figure 17, the Central and Eastern European countries fall mainly into the rain-rate zones of 25 mm/h, 32 mm/h, and 42 mm/h, called E, H, and K zones in the ITU recommendations. In the planning phase, the rainfall rate is often approximated with one single value for medium and small countries, i.e., 42 mm/h for the entire territory of Hungary, following ITU-R P.837-1 [37].
It is worth mentioning that advanced link planning tools provide the possibility to define rain-rate polygons inside a country when more accurate data are available. Even for medium- or relatively small-size European countries, the rainfall rate may change significantly inside the country. Switzerland is shown in Figure 18a as an example, where the R0.01% rain rates vary from 26 mm/h to 46 mm/h in the different rain zones. Research activities are ongoing in several countries to determine accurate local rainfall rates, specific for the region. Fixed µ/mmW links are monitored together with meteorological data continuously. There are also remarkable long-term rain-rate measurement activities in the Czech Republic and in Hungary [12,44,52,53]. Rainfall and RSL results are stored with high accuracy and time resolution. The statistical evaluation of rain attenuation is based on the long-term data collected experimentally. Figure 18b shows significant rainfall intensity differences calculated for Hungary [53]. Long-term trial and operator network experience were also published for the 58 GHz and 73 GHz links [44,45,52,53].
A very accurate meteorological report is available, e.g., for Norway [54]. Rainfall intensities exceeded for 0.5%, 0.1%, 0.01%, and 0.001% of the time were measured over several decades. Such an accurate report is very helpful in the availability design of µ/mmW links (Figure 19).

7. Discussion

Microwave and millimeter-wave links continue to support the mobile anyhaul networks both for the legacy and the new 5G radio access points. Site densification and new fiber-optical aggregation points result in shorter hop lengths for the µ/mmW links. In the coming years, a mesh topology composed of fiber-optical, FSO, and µ/mmW radio links will be used with load sharing and route diversity techniques. In the radio hops adaptive modulation, ATPC and channel aggregation techniques support higher bit rates. New millimeter-wave frequency bands will receive emphasis thanks to the wide spectrum available. In the millimetric E and V bands, multi-Gbps links can support 5G deployments with high bit rates and low latency.
In this paper, hop-length recommendations were given for the digital µ/mmW radio links. Using the ITU recommendations for rain and atmospheric attenuation, a detailed fade margin and availability calculation method was presented. The presented calculation method takes antenna size, link frequency, polarization, and modulation mode into account. Example radio link calculations were shown with typical system gain and antenna size values. During the numerical calculations, rainfall rate statistics were considered that are typical in Central and Eastern European countries. Recommended hop length was plotted as a function of rainfall rate for the different frequency bands, link polarizations, and dish sizes. The calculated charts provide useful help in the planning, optimization and monitoring of µ/mmW links.
Finally, it was shown with rain-rate maps that, even in medium- or small-size countries, there may be significant rainfall rate differences in Europe. For more accurate availability and optimal hop-length calculations, locally collected meteorological data should be utilized in the radio link planning tools. As a result, the new links can be planned with the required availability targets, and the existing access network can be optimized to support the increased capacity demands of 5G deployments.

Funding

This research received no external funding.

Acknowledgments

The author thanks his current and former colleagues for the fruitful discussions and for the valuable support: Gábor Járó, Szabolcs Sülle, Tina Hinch, and Radu Paducel (Nokia Software and Nokia Mobile Networks), László Csurgai-Horváth, Lajos Nagy, Éva Gödör, and Tibor Berceli (BME, the Budapest University of Technology and Economics), Julianna Györösi (HIF, the Hungarian Communications Authority and TKI, the Research Institute for Telecommunications), János Ladvánszky (TKI and Ericsson), and Viktor Fehérvári (T2-Com Ltd.). All personal communications and valuable comments given by Trevor Manning, TMC Global, Australia and Lajos Hanzó, Southampton University, UK are highly appreciated. The author acknowledges ETSI, ITU, MetNo and RACOM for providing approvals and for their quick support.

Conflicts of Interest

The authors declare no conflicts of interest.

Acronyms

Aavailability
Aaatmospheric attenuation
Aoobstacle loss
Aspspecific attenuation (in dB/km)
ATPCautomatic transmit power control
BERbit error rate
BPSKbinary phase-shift keying
CEPTThe European Conference of Postal and Telecommunications Administrations
ddistance: hop length of the radio links
dBdeciBel
dBiantenna gain in dB unit, compared to the gain of the isotropic antenna
dBmpower in dB, relative to 1 mW
ENEuropean Norm
ETSIEuropean Telecommunication Standards Institute
FECforward error correction
FMfade margin
FSLfree space loss
FSOfree space optical (link)
Gantantenna gain
GRXaantenna gain of the receiver
GTXaantenna gain of the transmitter
Gbpsgigabit/second
Hhorizontal (polarization of a link)
HSPAhigh speed packet access
IDUindoor unit
ITUInternational Telecommunication Union
LoSline-of-sight
LTElong-term evolution
LTE-ALTE Advanced
Mbpsmegabit/second
mmWmillimeter-wave frequencies: 30 GHz–300 GHz
NWnetwork
ODUoutdoor unit
PLpropagation loss
PRXpower received at the input of the transceiver
PTXpower transmitted at the output of the transceiver
PRXthreceiver threshold (for BER = 10−6)
PRXuunfaded RSL at the input of the transceiver
PoPpoint of presence
QAMquadrature amplitude modulation
QPSKquadrature phase-shift keying
Rrainfall rate in mm/h
RANradio access network
RAPradio access point
RATradio access technology
RFradio frequency
RoFradio-over-fiber
RSLreceived signal level
RXreceive or receiver
SGsystem gain
SGasystem gain with TX and RX antenna gains included
TCMtrellis coded modulation
TXtransmit or transmitter
Uunavailability
Vvertical (polarization of a link)
Ødiameter
µ/mmWmicrowave and millimeter-wave
2G2nd generation mobile network, GSM
3G3rd generation mobile network, UTRAN
4G4th generation mobile network, LTE
5G5th generation mobile network

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Figure 1. Fifth-generation mobile (5G): enabler for diverse use cases and services.
Figure 1. Fifth-generation mobile (5G): enabler for diverse use cases and services.
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Figure 2. Different 5G interfaces: (a) in early 5G phase; (b) in mature 5G phase.
Figure 2. Different 5G interfaces: (a) in early 5G phase; (b) in mature 5G phase.
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Figure 3. Example of topology re-planning for new and co-located sites.
Figure 3. Example of topology re-planning for new and co-located sites.
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Figure 4. Evolving core and radio access network (RAN) toward cloudification, 5G slicing, and edge sites.
Figure 4. Evolving core and radio access network (RAN) toward cloudification, 5G slicing, and edge sites.
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Figure 5. Block diagram of the microwave and millimeter-wave (µ/mmW) transceiver (without feeder lines), according to European Telecommunication Standards Institute, ETSI EN 302 217. The reference points follow Reference [24].
Figure 5. Block diagram of the microwave and millimeter-wave (µ/mmW) transceiver (without feeder lines), according to European Telecommunication Standards Institute, ETSI EN 302 217. The reference points follow Reference [24].
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Figure 6. System gain definitions—with and without antennas [1].
Figure 6. System gain definitions—with and without antennas [1].
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Figure 7. (a) Integrated antenna assembled as part of the outdoor unit (ODU). (b) Slip-mount antenna fitted without feeder lines to the ODU. (c) Example of combining polarization; photo reproduced with permission from RACOM [34]. (d) Separated antenna with two ODUs and two feeder waveguides.
Figure 7. (a) Integrated antenna assembled as part of the outdoor unit (ODU). (b) Slip-mount antenna fitted without feeder lines to the ODU. (c) Example of combining polarization; photo reproduced with permission from RACOM [34]. (d) Separated antenna with two ODUs and two feeder waveguides.
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Figure 8. Link budget and fading margin calculation.
Figure 8. Link budget and fading margin calculation.
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Figure 9. Adaptive link modulation when ensuring guaranteed bit rate during intensive rain.
Figure 9. Adaptive link modulation when ensuring guaranteed bit rate during intensive rain.
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Figure 10. Specific attenuation due to oxygen (blue line), water vapor (orange line), and total attenuation (red line) according to International Telecommunication Union, ITU-R P.676-12. Reproduced with permission from ITU [39].
Figure 10. Specific attenuation due to oxygen (blue line), water vapor (orange line), and total attenuation (red line) according to International Telecommunication Union, ITU-R P.676-12. Reproduced with permission from ITU [39].
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Figure 11. Atmospheric attenuation at 50–70 GHz (in dB/km, red line: sea level), according to ITU-R P.676-12. Reproduced with permission from ITU [39].
Figure 11. Atmospheric attenuation at 50–70 GHz (in dB/km, red line: sea level), according to ITU-R P.676-12. Reproduced with permission from ITU [39].
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Figure 12. Combined atmospheric and rain attenuation in dB/km as a function of frequency [12]. The figure is re-printed with the permission of ETSI.
Figure 12. Combined atmospheric and rain attenuation in dB/km as a function of frequency [12]. The figure is re-printed with the permission of ETSI.
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Figure 13. (a) Ice and snow on the radome of a parabolic dish; the photo is re-printed with permission from RACOM [34]. (b) Extra attenuation due to a tree in the near field. (c) ODU installed behind a church window (polycarbonate lamels). (d) Metal cables inside the first Fresnel zone of the µW link.
Figure 13. (a) Ice and snow on the radome of a parabolic dish; the photo is re-printed with permission from RACOM [34]. (b) Extra attenuation due to a tree in the near field. (c) ODU installed behind a church window (polycarbonate lamels). (d) Metal cables inside the first Fresnel zone of the µW link.
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Figure 14. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 34 Mbit/s, 14 MHz, and ø 60 cm dishes. For the 58 GHz link, ø 30 cm dishes are used in the calculations. (b) Hops with horizontal polarization, 34 Mbit/s, 14 MHz, and ø 60 cm dishes.
Figure 14. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 34 Mbit/s, 14 MHz, and ø 60 cm dishes. For the 58 GHz link, ø 30 cm dishes are used in the calculations. (b) Hops with horizontal polarization, 34 Mbit/s, 14 MHz, and ø 60 cm dishes.
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Figure 15. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 34 Mbit/s, 14 MHz, and ø 30 cm dishes. In the 58 GHz band, 20 cm rectangular antennas are used. (b) Hops with horizontal polarization, 34 Mbit/s, 14 MHz, and ø 30 cm dishes.
Figure 15. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 34 Mbit/s, 14 MHz, and ø 30 cm dishes. In the 58 GHz band, 20 cm rectangular antennas are used. (b) Hops with horizontal polarization, 34 Mbit/s, 14 MHz, and ø 30 cm dishes.
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Figure 16. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 1 GHz channel and ø 12 cm dishes. (b) Hops with vertical polarization, 1 GHz channel and ø 39 cm dishes. (c) Hops with vertical polarization, 1 GHz channel and ø 69 cm dishes. (d) Comparison of vertical and horizontal links at the different modulation modes. (e) Comparison of hops with different dish sizes. Modulations are quadrature phase-shift keying (QPSK) and 128-QAM. (f) Example of monitoring the local and remote received signal level (RSL) and modulation modes.
Figure 16. Recommended hop lengths as a function of rainfall intensity. (a) Hops with vertical polarization, 1 GHz channel and ø 12 cm dishes. (b) Hops with vertical polarization, 1 GHz channel and ø 39 cm dishes. (c) Hops with vertical polarization, 1 GHz channel and ø 69 cm dishes. (d) Comparison of vertical and horizontal links at the different modulation modes. (e) Comparison of hops with different dish sizes. Modulations are quadrature phase-shift keying (QPSK) and 128-QAM. (f) Example of monitoring the local and remote received signal level (RSL) and modulation modes.
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Figure 17. Global map of rain-rate zones, reproduced with permission from RACOM [51].
Figure 17. Global map of rain-rate zones, reproduced with permission from RACOM [51].
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Figure 18. R0.01% in mm/h, the rainfall intensities exceeded 0.01% of the time. (a) Rain-rate contour lines in Switzerland. (b) Rain-rate regions in Hungary as calculated in Reference [53]. The figure is reproduced with permission from László Csurgai-Horváth.
Figure 18. R0.01% in mm/h, the rainfall intensities exceeded 0.01% of the time. (a) Rain-rate contour lines in Switzerland. (b) Rain-rate regions in Hungary as calculated in Reference [53]. The figure is reproduced with permission from László Csurgai-Horváth.
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Figure 19. Rainfall maps of Norway measured over a long period. (a) Rainfall rates in mm/h, exceeded 0.001% of the time. (b) Rainfall rates in mm/h, exceeded 0.01% of the time. (c) Rainfall rates in mm/h, exceeded 0.1% of the time. Reproduced with permission from the Norwegian Meteorological Institute [54].
Figure 19. Rainfall maps of Norway measured over a long period. (a) Rainfall rates in mm/h, exceeded 0.001% of the time. (b) Rainfall rates in mm/h, exceeded 0.01% of the time. (c) Rainfall rates in mm/h, exceeded 0.1% of the time. Reproduced with permission from the Norwegian Meteorological Institute [54].
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Table 1. Channel separation and link bit rates in the different frequency bands.
Table 1. Channel separation and link bit rates in the different frequency bands.
Frequency Bands
(GHz)
Channel Separation Options 1
Minimum; …; Maximum (MHz)
Capacities 1 According to Equipment Class and Channel Separation (Mbit/s)
13, 151.75; 3.5; 7; 14; 28; 564–431
181.75; 3.5; 7; 13.75; 27.5; 55; 1104–862
23, 26, 28, 32, 38, 423.5; 7; 14; 28; 56; 1124–862
50, 52, 553.5; 7; 14; 28; 562–128
57–64, 64–66 (V band)30 or 50, multiple of 30 or 50, maximum 200028.5–3400
(unlicensed band)
71, 76, 81, 86 (E band)62.5; 125; 250; 500; 750; 1000; 1250; 1500; 1750; 200035–11200
1 For more details, see European Telecommunication Standards Institute, ETSI EN 302 217-1 [24].
Table 2. Atmospheric attenuation at different frequencies.
Table 2. Atmospheric attenuation at different frequencies.
Frequency Band (GHz)1315182328323858608090100
Asp, atmospheric attenuation (dB/km) 0.020.030.070.20.10.090.1313150.360.40.45
Table 3. Transmit power, antenna gain, and receiver threshold of the calculated 13–38 GHz links. BER—bit error rate.
Table 3. Transmit power, antenna gain, and receiver threshold of the calculated 13–38 GHz links. BER—bit error rate.
Frequency Band
(GHz)
Nominal PTX
(dBm)
Gant
ø 30 cm
(dBi) 1, 2
Gant
ø 60 cm
(dBi) 1, 3
PRXth at
BER = 10−6
(dBm)
SGa = SG + 2Gant
ø 30 cm
(dB)
ø 60 cm
(dB)
132030.935.8−74155.8165.6
151832.136.8−76158.2167.6
181834.238.7−73159.4168.4
231835.340.4−75163.6173.8
261836.641.2−73164.2173.4
281638.142.2−72164.2172.4
321638.943.7−72165.8175.4
381640.145.2−73169.2179.4
1 Antennas in the calculations are ValuLine from Andrew, a CommScope Company. 2 The physical size of the 30-cm (one foot) antenna is 39 cm (outer diameter). 3 The physical size of the 60-cm (two feet) antenna is 69 cm (outer diameter) [47,48].
Table 4. Transmit power, antenna gain, and receiver threshold of the calculated 58 GHz links.
Table 4. Transmit power, antenna gain, and receiver threshold of the calculated 58 GHz links.
Frequency Band
(GHz)
Nominal PTX
(dBm)
Gant
20 cm
(dBi)
Gant
ø 30 cm
(dBi)
PRXth at
BER = 10−6
(dBm)
SGa = SG + 2Gant
20 cm
(dB)
ø 30 cm
(dB)
5853641.5−74146157
Table 5. Transmit power, antenna gain and receiver threshold of the calculated 80 GHz links. BPSK—binary phase-shift keying; QPSK—quadrature phase-shift keying; QAM—quadrature amplitude modulation.
Table 5. Transmit power, antenna gain and receiver threshold of the calculated 80 GHz links. BPSK—binary phase-shift keying; QPSK—quadrature phase-shift keying; QAM—quadrature amplitude modulation.
Modulation ModeNominal PTX
(dBm)
Gant
ø 12 cm
(dBi)
Gant
ø 39 cm
(dBi)
Gant
ø 69 cm
(dBi)
PRXth at
BER = 10−6
(dBm)
SGa = SG + 2Gant
ø 12 cm
(dB)
ø 39 cm
(dB)
ø 69 cm
(dB)
BPSK 1/4163843.150.9−76.4168.4178.6194.2
BPSK 1/216−73.4165.4175.6191.2
BPSK16−70.4162.4172.6188.2
QPSK16−67.4159.4169.6185.2
16-QAM14−60.8150.8161.0176.6
32-QAM14−57.7147.7157.9173.5
64-QAM13.5−55.2144.7154.9170.5
128-QAM12.5−51.8140.3150.5166.1

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Hilt, A. Availability and Fade Margin Calculations for 5G Microwave and Millimeter-Wave Anyhaul Links. Appl. Sci. 2019, 9, 5240. https://doi.org/10.3390/app9235240

AMA Style

Hilt A. Availability and Fade Margin Calculations for 5G Microwave and Millimeter-Wave Anyhaul Links. Applied Sciences. 2019; 9(23):5240. https://doi.org/10.3390/app9235240

Chicago/Turabian Style

Hilt, Attila. 2019. "Availability and Fade Margin Calculations for 5G Microwave and Millimeter-Wave Anyhaul Links" Applied Sciences 9, no. 23: 5240. https://doi.org/10.3390/app9235240

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