1

Combining Adaptive Coding and Modulation with Hierarchical Modulation in Satcom Systems arXiv:1112.4944v1 [cs.NI] 21 Dec 2011

Hugo M´eric∗† , J´erˆome Lacan†∗ , Fabrice Arnal‡ , Guy Lesthievent§ and Marie-Laure Boucheret†∗ ∗ T´ eSA, † Universit´ e ‡ Thales

Toulouse, France

de Toulouse, Toulouse, France

Alenia Space, Toulouse, France

§ CNES,

Toulouse, France

Email: [email protected], [email protected], [email protected], [email protected], [email protected]

Abstract We investigate the design of a broadcast system in order to maximise the throughput. This task is usually challenging due to the channel variability. Forty years ago, Cover introduced and compared two schemes: time sharing and superposition coding. Even if the second scheme was proved to be optimal for some channels, modern satellite communications systems such as DVB-SH and DVB-S2 mainly rely on time sharing strategy to optimize the throughput. They consider hierarchical modulation, a practical implementation of superposition coding, but only for unequal error protection or backward compatibility purposes. We propose in this article to combine time sharing and hierarchical modulation together and show how this scheme can improve the performance in terms of available rate. We introduce the hierarchical 16-APSK to boost the performance of the DVB-S2 standard. We also evaluate various strategies to group the receivers in pairs when using hierarchical modulation. Finally, we show in a realistic use case based on DVB-S2 that the combined scheme can provide throughput gains greater than 10% compared to the best time sharing strategy. Index Terms Broadcast Channel, Hierarchical Modulation, Digital Video Broadcasting.

I. I NTRODUCTION In most broadcast applications, the signal-to-noise ratio (SNR) experienced by each receiver can be quite different. For instance, in satellite communications the channel quality decreases with the presence of clouds in Ku or Ka The material in this paper has been submitted in part at ICC 2011. It is available online at http://arxiv.org/abs/1111.2425.

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band, or with shadowing effects of the environment in lower bands. The first solution for broadcasting is to design the system for the worst-case reception, but this leads to poor performance as many receivers do not exploit their full potential. Then, two other schemes have been proposed in [1] and [2]: time division multiplexing with variable coding and modulation, and superposition coding. Time division multiplexing, or time sharing, allocates to each user a fraction of time where it can use the full channel with any modulation and error protection level. This functionality, called variable coding and modulation (VCM) [3], is the most used in practice in standards today. If a return channel is available, VCM may be combined with adaptive coding and modulation (ACM) to optimize the transmission parameters [3]. In superposition coding, the available energy is shared to several service flows which are sent simultaneously in the same band. This scheme was introduced by Cover in [1] in order to improve the transmission rate from a single source to several receivers. When communicating with two receivers, the principle is to superimpose information for the user with the best SNR. This superposition can be done directly at the forward error correction (FEC) level or at the modulation level as shown in Figure 1 with a 16-QAM modulation. Hierarchical modulation is a practical implementation of superposition coding. Although hierarchical modulation has been introduced to improve the throughput, it is currently often used to provide unequal protection. The idea is to merge two different streams at the modulation level. The high priority (HP) stream is used to select the quadrant, and the low priority (LP) stream selects the position inside the quadrant. The HP stream is dedicated to users with poor channel quality, unlike the LP stream which requires a large SNR to be decoded. In [4], SVC encoded video [5] is protected using hierarchical modulation. The base layer of the video is transmitted in the HP stream, while the enhanced layer is carried by the LP stream. Another usage is backward compatibility [6], [7]. The DVB-S2 standard [3], [8] is called upon to replace DVB-S, but many DVB-S receivers are already installed. Thus the hierarchical modulation helps to the migration by allowing the DVB-S receivers to operate. In [9], the authors propose to provide local content with hierarchical modulation. The principle is to carry locale information that is of interest to a particular geographic area in the LP stream, while the HP stream transmits global content. Finally, other works improve the performance of relay communication system [10] or OFDMA-based networks [11]. Our work focuses on using hierarchical modulation in modern broadcast systems to increase the transmission rate. For instance, even if the LDPC codes of DVB-S2 approach Shannon limit for the AWGN channel with one receiver [12], the throughput can be greatly increased for the broadcast case. Indeed, Cover presents the set of achievable rates for the Gaussian broadcast channel with two receivers in [1]. This set clearly dominates the time sharing achievable rate. This article investigates the performance, in terms of throughput, of a satellite broadcast system where time sharing and hierarchical modulation are combined. We show on an example modeling a satellite broadcast area that the gain can be significant. The way of grouping receivers in pairs is also investigated as it greatly affects the performance. The paper is organized as follows. Section II presents the hierarchical modulation. We introduce the hierarchical 16-APSK in order to boost the performance of the DVB-S2 standard. In Section III, the achievable rates are computed for the time sharing used alone or combined with hierarchical modulation. We study on a use case the performance of each scheme in Section IV. We also propose a grouping strategy when using hierarchical modulation December 22, 2011

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and discuss its performance. Finally, Section V concludes the paper by summarizing the results. Q

HP

Encoder

00

0100

0101

0001

0000

0110

0111

0011

0010

I

Hierarchical 16−QAM LP

Encoder 11

1110

1111

1100

1101

1011

1010

1001

1000

2dl 2dh

Fig. 1: Hierarchical modulation using a 16-QAM

II. H IERARCHICAL M ODULATION This part introduces the hierarchical 16-QAM and 16-APSK. First, the hierarchical 16-QAM, considered in the DVB-SH standard [13],[14], is presented. It gives us some insight on how to introduce the hierarchical 16-APSK. Then the hierarchical 16-APSK is presented in order to improve the performance of DVB-S2. As mentioned before, hierarchical modulations merge several streams in a same symbol. The available energy is shared between each stream. In our study, two streams are considered. When hierarchical modulation is used to unequal protection purpose, these flows are called HP and LP streams. However, unequal protection is not the goal of our work, so we will now refer to high energy (HE) and low energy (LE) streams for the stream containing the most and the least energy respectively. As each stream does not use the same energy, hierarchical modulations are based on non-uniform constellations where the symbols are not uniformly distributed in the space. The geometry of non-uniform constellations is described using the constellation parameter(s). A. Hierarchical 16-QAM The constellation parameter α is defined by dh /dl , where 2dh is the minimum distance between two constellation points carrying different HE bits and 2dl is the minimum distance between any constellation point (see Figure 1). Typically, we have α ≥ 1, where α = 1 corresponds to the uniform 16-QAM, but it is also possible to have α ≤ 1 [15]. When α grows, the constellation points in each quadrant become farer to the I and Q axes. Thus it is easier to decode the HE stream. However, in the same quadrant, the points get closer and the LE stream requires a better channel quality to be decoded. The hierarchical 16-QAM is the superposition of two QPSK modulations, one with parameter dh + dl (carrying the HE stream) and the other with parameter dl (carrying the LE stream). The energy ratio between the two streams is Ehe = (1 + α)2 , Ele December 22, 2011

(1)

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4

where Ehe and Ele correspond to the energy allocated to the HE and LE streams respectively [9]. The DVB-SH standard recommends two values for α: 2 and 4. In fact, it also considers α = 1 but only for the VCM mode. The values 2 and 4 are defined in order to provide unequal protection. From an energy point of view, this amounts to give 90% (α = 2) or 96% (α = 4) of the available energy to the HE stream. In [16], the authors improve the overall throughput of a simple broadcast channel by adding α = 1, α = 0.8 and α = 0.5. This provides a better repartion of the energy: the HE stream contains 80%, 76% and 69% of the total power. B. Hierarchical 16-APSK The DVB-S2 standard also introduces hierarchical modulation with the hierarchical 8-PSK. The constellation parameter θP SK , which is the half angle between two points in one quadrant, is defined by the service operator according to the desired performance. However, this modulation does not offer a good spectrum efficiency. As the 16-APSK is already defined in DVB-S2, we propose the hierarchical 16-APSK, shown in Figure 2, in order to boost the performance of the system. Two parameters impact on the constellation geometry: γ = R2 /R1 and θ.

2θ

R1

R2

Fig. 2: 16-APSK modulation

The hierarchical 16-APSK is not a new concept. For instance, this modulation is presented to upgrade an existing digital broadcast system in [17]. However, the design of the modulation is not addressed. In [18], the authors investigate the design of APSK modulations for satellite broadband communication, but the hierarchical case is not treated. In our study, we use an energy argument to choose the parameters γ and θ. The hierarchical modulation shares the available energy between the HE and LE streams. We consider the energy of the HE stream. It is given by the energy of a QPSK modulation, where the constellation points are located at the barycenter of the four points in each quadrant. Using the polar coordinates, the barycenter in the upper right quadrant is R1 eiπ/4 + R2 eiπ/4 + R2 ei(π/4+θ) + R2 ei(π/4−θ) R1 + R2 + 2R2 cos(θ) = eiπ/4 . 4 4

(2)

Moreover, the symbol energy is expressed as Es

= =

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4R12 + 12R22 16 1 + 3γ 2 2 R1 . 4

(3) DRAFT

5

Then combining (2) and (3), the distance of the barycenter to the origin is dB

= = =

R1 + R2 + 2R2 cos(θ) 4 1 + γ(1 + 2 cos(θ)) R1 4 √ 1 + γ(1 + 2 cos(θ)) 2 Es p . 4 1 + 3γ 2

(4)

Finally, the energy of the HE stream is given by Ehe

= Eqpsk = d2B 2

=

(1 + γ(1 + 2 cos θ)) Es . 4(1 + 3γ 2 ) | {z }

(5)

ρhe

Equation (5) introduces ρhe the ratio between the energy of the HE stream Ehe and the symbol energy Es . We are now interested to determine the set of (γ, θ) pairs solution of (6), where ρhe ≥ 0.5 is known, γ ≥ 1 and θ ≥ 0. ρhe =

(1 + γ(1 + 2 cos θ)) 4(1 + 3γ 2 )

2

(6)

The resolution of (6) is given in Appendix A. The solution set is Sρhe = {(γ, arccos (f (γ, ρhe ))) |1 ≤ γ ≤ γlim } ,

(7)

where ! 4ρhe (1 + 3γ 2 ) − 1 −1 γ

(8)

+∞, if ρhe ≤ 0.75 √ = 3+4 3ρhe (1−ρhe ) , if ρhe > 0.75. 3(4ρhe −3)

(9)

1 f (γ, ρhe ) = 2

p

and γlim

Appendix A also presents two examples of the Sρhe set. When ρhe increases, the points in one quadrant tend to get closer. It implies the HE stream is easier to decode, but on the other hand the LE stream requires a better SNR to be decoded. As for the hierarchical 16-QAM, several values of ρhe have to be selected. The results presented in Section IV show that choosing ρhe = 0.75, 0.8, 0.85 and 0.9 allows to have good performance. However, once the parameter ρhe is set, we still have to decide which (γ, θ) couple to keep in the Sρhe set. We keep one (γ, θ) pair per ρhe value. This pair minimizes the average decoding threshold for the HE stream over all the coding rates in the DVB-S2 standard. Appendix B gives all the decoding thresholds and explains their computation. III. T IME S HARING AND H IERARCHICAL M ODULATION ACHIEVABLE R ATES This part introduces the rates achievable by the two following schemes: time sharing with or without hierarchical modulation, referred as hierarchical modulation and classical time sharing respectively. We first consider the case of one source communicating with two receivers. Then we study the general case with n receivers. December 22, 2011

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A. Achievable rates: case with two receivers 1) Classical time sharing: We consider one source communicating with two receivers, each one with a particular SNR. Given this SNR, we suppose receiver i (i = 1, 2) has a rate Ri , which corresponds to the best rate it can afford. This rate depends on the modulations and coding rates available in the system. For the DVB-S2 standard, readers can refer to [8]. With a time sharing strategy, the average rate results from the fraction of time ti allocated to each receiver. In our study, we are interested to offer the same rate to everyone, but our work can be easily adapted to another rate policy. To offer the same rate to the two users, we need to solve t1 R1 = t2 R2

(10)

t1 + t2 = 1. By solving (10), the fraction of time allocated to each user is t 1 = R 2 R1 +R2 t 2 =

(11)

R1 R1 +R2 .

The constraint t1 + t2 = 1 is verified and we remark that increasing Ri reduces ti , which is a consequence of our rate policy. Finally, the rate offered to each receiver is Rts =

R1 R2 . R1 + R2

(12)

2) Hierarchical modulation time sharing: The first step is to compute the rates offered by all the possible modulations, including hierarchical ones. When the hierarchical modulation is used, we suppose the receiver experiencing the best SNR decodes the LE stream. Thus we obtain a set of operating points. Moreover, when two sets of rates (R1 , R2 ) and R˜1 , R˜2 are available, the time sharing strategy allows any rate pair τ R1 + (1 − τ )R˜1 , τ R2 + (1 − τ )R˜2 , (13) where 0 ≤ τ ≤ 1 is the fraction of time allocated to (R1 , R2 ). The achievable rates set finally corresponds to the convex hull of all the operating points. As we are interested to offer the same rate to the users, we calculate the intersection of the convex hull with the curve y = x. We note Rhm and Rts the rates offered to both receivers by the hierarchical modulation and classical time sharing strategy respectively. Figure 3 presents one example of achievable rates set where one receiver experiences a SNR of 7 dB and the other 10 dB. We also represent Rhm and Rts in order to visualize the gain. For the classical time sharing strategy, the rates obtained in Figure 3 come from the 8-PSK 2/3 for the user with a SNR of 7 dB and the 16-APSK 3/4 for the other user. As said before, it is the best that each receiver can afford. For the hierarchical modulation, the operating points are computed using the standard [8] or Appendix B. Remark that the hierarchical 16-APSK gives better results than the hierarchical 8-PSK. Moreover, when ρhe increases, the rate of the user with the worst SNR increases, while the rate of the other user decreases. This can be explained as more energy is dedicated to the HE stream and then its performance improves. On the other hand, the LE stream is allocated less energy and its

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2 Time sharing 1.8

8−PSK (θ=30°)

User 1 rate

(Rhm, Rhm) 1.6

8−PSK (θ=20°) 16−APSK (ρhe=0.75)

1.4

16−APSK (ρhe=0.8) 16−APSK (ρhe=0.85)

1.2

16−APSK (ρhe=0.9)

1 (Rts, Rts) 0.8 0.6 0.4 0.2 0 0

0.5

1

1.5 User 2 rate

2

2.5

3

Fig. 3: Achievable rates set: SN R1 = 7 dB - SN R2 = 10 dB

performance decreases. Finally, the interest of using hierarchical modulation is obvious as the gain between Rhm and Rts is about 11%. We now use the same method to evaluate the gain between Rhm and Rts for all (SN R1 , SN R2 ) pairs where 4 dB ≤ SN Ri ≤ 12 dB, i = 1, 2. Figure 4 presents the results. Note that the gain provided by the hierarchical modulation is significative in several cases and can achieve up to 20%. In general, the gains are more important when the SNR difference between the two receivers is large. This observation will be used in the next part when we will group a set of users in pairs.

25

Gain in percent

20 15 10 5 0 12 12

10 10

8 Es/No user 2 (dB)

8

6

6 4

4

Es/No user 1 (dB)

Fig. 4: Rate gain

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B. Achievable rates: case with n receivers 1) Classical time sharing: We now consider a broadcast system with n receivers. We suppose receiver i has a rate Ri , which corresponds to the best rate it can afford as mentioned above. With our rate policy, (10) becomes ∀i, j, ti Ri = tj Rj (14) P ti = 1. i The resolution of (14) leads to a fraction of time allocated to user i of Q =i Rk k6Q . ti = P n R k j=1 k6=j With this time allocation, the average rate offered to each receiver is −1 Q n X R 1 k k . Q = Rts = P n R j R j=1 j=1

k6=j

(15)

(16)

k

2) Hierarchical modulation with time sharing: For the case with n receivers, the first step is to group the users in pairs in order to use hierarchical modulation. A lot of possibilities are available and the next section presents a grouping strategy which generally obtains good results. Once the pairs have been chosen, for each pair we compute the achievable rate as described previously. Finally, we need to equalize the rate between each user. This is done by time sharing using (15). For instance, consider a DVB-S2 system where a user u1 with a SNR of 7 dB is in pair with a user u2 with a SNR of 10 dB. The rate for each receiver is obtained using the hierarchical 16-APSK (ρhe = 0.8) a fraction of time a1 and the 16-APSK a fraction of time a2 as shown in Figure 3. When equalizing the rates between all the users, (15) gives the same fraction of time t to users u1 and u2 . Then, the pair of users has to share a global fraction of time 2t. It follows that the broadcast system allocates to u1 and u2 the hierarchical 16-APSK (ρhe = 0.8) for a time proportion 2t × a1 and the 16-APSK for 2t × a2 . IV. A PPLICATION TO BROADCAST CHANNEL An important insight of the previous section is that the gain of hierarchical modulation depends on the way to group users in pairs. For instance, consider a set of four users u1 , u2 , u3 , u4 with respective SNR 4, 4, 12 and 12 dB. Then, according to Figure 4, the choice of pairs (u1 , u2 ) and (u3 , u4 ) leads to no gain while the choice (u1 , u3 ) and (u2 , u4 ) allows a gain of about 20%. In this section, we first present different grouping strategies of a set of users when the hierarchical modulation time sharing is considered. Then we introduce a broadcast channel where the performance of hierarchical modulation and classical time sharing are evaluated. The impact of the grouping strategy is also discussed. A. Grouping strategy We consider a set of receivers, where the distribution of the SNR values is known. The possible SNR values are SN Ri with 1 ≤ i ≤ m and for all i ≤ j, SN Ri ≤ SN Rj . Moreover, exactly ni receivers experience a channel Pm quality of SN Ri . We also define i=1 ni = 2N the total number of receivers and ∆i,j = |SN Ri − SN Rj |. December 22, 2011

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Definition 1: For any grouping, the average SNR difference per receivers in pairs is defined as ∆=

N 1 X ∆ik ,jk , N

(17)

k=1

where the (ik , jk ) couple represents a pair of receivers. When communicating with two receivers, we have already mentioned that the gain is more important when the SNR difference between the two users is large. From this observation, we are looking to group the users in pairs in order to maximise the average SNR difference. The following theorem presents a strategy to compute this maximum. Theorem 1: From any set of receivers, the iterative procedure that picks the two receivers with the largest SNR difference, group them and repeat this operation allows to reach the maximum average SNR difference. Proof: First, we compute an upper bound for the average SNR difference. In (17), for all k, we have (assuming ik ≤ jk ) ∆ik ,jk =

jX k −1

∆m,m+1 .

(18)

m=ik

Thus, ∆ can be expressed in the following form ∆=

m−1 1 X ai ∆i,i+1 , N i=1

(19)

where ai ∈ N for all i. We now search to bound ai . The term ∆i,i+1 in (19) only appears when we group a user Pi with a SNR less or equal to SN Ri and a user with a SNR greater or equal to SN Ri+1 . There is exactly k=1 nk Pm receivers with SN R ≤ SN Ri and k=i+1 nk receivers with SN R ≥ SN Ri+1 , so ai is bounded by ai ≤ min(

i X

k=1

nk ,

m X

nk ).

(20)

k=i+1

Pi Pm We now prove the proposed scheme reaches this bound, i.e., ai = min( k=1 nk , k=i+1 nk ). Let L be the PL greatest integer such as i=1 ni ≤ N . The strategy insures that all the receivers with a SNR less or equal to SN RL+1 are grouped with a receiver whose SNR is greater or equal to SN RL+1 . Thus, in the computation of the average SNR difference, we verify that P1 Pm • ∆1,2 appears n1 = min( k=2 nk ) times. k=1 nk , P2 Pm • ∆2,3 appears n1 + n2 = min( k=1 nk , k=3 nk ) times. •

...

•

PL Pm ∆L,L+1 appears n1 + n2 + ... + nL = min( k=1 nk , k=L+1 nk ) times.

The equality also holds in (20) for the terms ∆i,i+1 with i ≥ L + 1. Thus, our strategy allows to reach the previous bound, which is in fact the maximum average SNR difference. However, depending on the receivers configuration, other schemes allow to reach the maximum average SNR difference. For instance, consider the case with four receivers where the SNR values are SN R1 (user 1), SN R2 = SN R1 + 1 dB (user 2), SN R3 = SN R1 + 2 dB (user 3) and SN R4 = SN R1 + 3 dB (user 4). The previous

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strategy leads to group user 1 with user 4, and user 2 with user 3. But it is also possible to group user 1 with user 3, and user 2 with user 4. In both cases, the average SNR difference is 2 dB. Moreover, to highlight the impact of the grouping strategy, we propose to compare four grouping schemes: •

Strategy A: the scheme described in the previous theorem.

•

Strategy B: we compute the maximum average SNR difference ∆max and use it to group the receivers with a SNR difference as close as possible to ∆max . This strategy usually allows to have an average SNR difference close to ∆max , but compared to strategy A, the variance of the SNR difference by pairs is much smaller.

•

Strategy C: the receivers are grouped randomly.

•

Strategy D: we group the receivers with the closest SNR.

B. DVB-S2 channel model To evaluate the effective potential of our proposal for real systems, we present a model to estimate the SNR distribution of the receivers. For that, we considered the set of receivers located in a given spot beam of a geostationnary satellite broadcasting in the Ka band. The model takes into account two main sources of attenuation: the relative location of the terminal with respect to the center of (beam) coverage and the weather. Concerning the attenuation due to the location, the principle is to set the SNR at the center of the spot beam SN Rmax and use the radiation pattern of a parabolic antenna to model the attenuation. An approximation of the radiation pattern is !2 J1 sin(θ) πD λ G(θ) = Gmax 2 , (21) sin(θ) πD λ where J1 is the first order Bessel function, D is the antenna diameter and λ = c/f is the wavelength [19]. In our simulations, we use D = 1.5 m and f = 20 GHz. Moreover we consider a typical multispot system where the edge of each spot beam is 4 dB below the center of coverage. Assuming a uniform repartion of the population, the proportion of the receivers experiencing an attenuation between two given values is the ratio of the ring area over the disk shown in Figure 5. The ring area is computed knowing the satellite is geostationary and using (21). 000000 111111 000000 111111 000000 111111 111111 000000 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111

00000 11111 00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

1111111111111111111111111111111 0000000000000000000000000000000 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111

Fig. 5: Satellite broadcasting area

Figure 6, provided by the CNES, presents the attenuation distribution in the broadcasting satellite service (BSS) band. More precisely, it is a temporal distribution for a given location in Toulouse, France. In our work, we assume the SNR distribution for the receivers in the beam coverage at a given time is equivalent to the temporal distribution at a given location. December 22, 2011

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1 0.1

Culmulative Density Function

0.9 0.8

0.01

0.7 0.001

0.6 0.5

0.0001 −9 −8 −7 −6 −5 −4 −3 −2 −1

0.4 0.3 0.2 0.1 0 −9

−8

−7

−6 −5 −4 −3 Attenuation (in dB)

−2

−1

0

Fig. 6: Attenuation distribution (due to weather)

Finally, our model combines the two kinds of attenuation to estimate the SNR distribution. From a set of receivers, we first compute the attenuation due to the location. Then, for each receiver we draw, according to the previous distribution, the attenuation caused by the weather. C. Results Two scenarios are considered. In the first one, all the terminals have the same capacities (homogeneous case). In the second one, we consider two subsets of receivers, one with personal terminals and the other with professional terminals (heterogeneous case). Professional terminals forward the service, and not the signal, to some receivers in a local area network. We suppose the professional terminals experience 5 dB better than the personal terminals. They allow to increase the SNR diversity which is interesting when using the hierarchical modulation time sharing. Figure 7 shows a broadcast channel with two kinds of terminals (large antennas represent professional terminals). 00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

3R

R

00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

3R

R R

Fig. 7: Broadcast channel with two kinds of terminals

1) Homogeneous terminals: Figure 8 presents the results for a broadcasting area with 500 receivers. For each simulation, the SNR value of each user is drawn according to the distribution presented above. For one configuration

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(i.e., the parameter SN Rmax is set), we present the average, minimum and maximum gains over 100 simulations for the four grouping strategies. 9 8

Strategy A Strategy B Strategy C Strategy D

Gain (in percent)

7 6 5 4 3 2 1 0

13 dB

dB

dB

10

7

SNRmax

Fig. 8: Results for the homogeneous case with 500 receivers

First of all, the hierarchical modulation time sharing outperforms the classical time sharing scheme whatever the grouping strategy used. In fact, the hierarchical modulation adds some new operating points and thus can only improve the performance. Then, for each configuration, strategies A and B give the best results with a slight advantage for strategy A, which obtains more than 9% of gain for SN Rmax = 10 dB. This is consistent with the results presented in Figure 4, where the best gains are obtained when the SNR difference between the two receivers is large. Moreover, strategy D, which minimises the SNR difference, appears to be the worst scheme. The results also point out that the random strategy performs well. Thus the hierarchical modulation time sharing combined with a good grouping strategy allows to obtain intermediate gains between strategies A and D. In addition, strategies A, B and C do not require intensive computation to group the receivers and this can be done in real time which is interesting for satellite standards. We remark the better results are obtained when SN Rmax = 10 dB. In fact, the hierarchical modulation time sharing is useful only in a SNR interval. Figure 9 presents the gain of the strategy A according to SN Rmax for a large range of SN Rmax values. For low SNR values, the LE stream is often not able to decode any coding rate. This explains why there is no gain for low SNR values. An idea to tackle this phenomenon is to allocate more energy to the LE stream, but in that case, the performance of the HE stream is too deteriorated. For large SNR values, the classical time sharing uses the largest coding rate possible. For instance, consider two receivers with a SNR greater than 13.13 dB which corresponds to the decoding threshold of the 9/10 16-APSK [8]. The classical time sharing strategy allocates the same fraction of time t = 0.5 to both receivers. For the hierarchical modulation time sharing, one of the receiver decodes the HE stream, and the other the LE stream. In the best case, each stream can decode the coding rate 9/10. Each receiver use the channel all the time but the HE and LE streams

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only carry two bits. Then the hierarchical modulation time sharing can not outperform the classical scheme here. This example illustrates why the hierarchical modulation time sharing does not increase the performance for large value of SN Rmax . A solution should be to use a higher order modulation, for instance the 32-APSK. 10 9 8

Gain (in percent)

7 6 5 4 3 2 1 0 2

4

6

8

10 12 SNRmax

14

16

18

20

Fig. 9: Gain vs SN Rmax (Strategy A)

2) Heterogeneous terminals: We investigate the scenario where personal and professional terminals are used simultaneously. We consider that only one receiver is served by a personal terminal whereas there are several users behind a professional terminal (see Figure 7). As mentioned before, the professional terminals experience 5 dB better than the personal terminals. It is also important to notice that the rate dedicated to one professional terminal is proportional to the number of receivers served by this terminal. The aim is always to provide the same rate for each user. In this scenario, the performance depends on the proportion of receivers served by a professional terminal and SN Rmax . Here SN Rmax corresponds to the SNR experienced by personal terminals at the center of the spot beam (with clear sky condition). Figure 10 presents the gains according to the proportion of users served by a collective terminal. Here again, the simulations involve 500 receivers and we present the results over 100 simulations. First of all, the gains are most of the time better than in Figure 8. This is in accordance with Figure 4 as the presence of professional terminals increases the average SNR difference. Then, for a given SN Rmax , the maximum gain takes place when 50% of the receivers are served by a professional terminal, which corresponds to the maximum possible SNR diversity. This result is consistent with the work presented in [11]. Finally, compared to Figure 8, the results are worse in two cases, when SN Rmax = 10 or 13 dB and 90% of the receivers are served by a professional terminal. In these particular cases, we do not really increase the SNR diversity, but rather the average SNR. Then, the performance when SN Rmax = 10 dB and 90% of the receivers are served by professional terminals is more similar to the performance observed in Figure 10 when SN Rmax = 15 dB (we assume that a professional terminal experiences 5 dB better than a personal terminal).

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14

16 14

Strategy A Strategy B Strategy C Strategy D

Gain (in percent)

12 10 8 6 4 2 0

0%

0%

,9

dB

0%

,7

dB

13

0%

,5

0%

,2

dB

13

13

0%

,1

dB

13

dB

13

0%

,9

dB

0%

,7

dB

10

0%

,5

0%

,2

dB

10

10

,1

dB

10

%

%

90

%

70

%

50

%

20

10

dB

10

B,

B,

7d

B,

7d

7d

B,

B,

7d

7d

SNRmax, proportion of receivers served by a professional terminal

Fig. 10: Results for the heterogeneous case with 500 receivers

V. C ONCLUSION In this paper, we use time sharing and hierarchical modulation together to increase the throughput of a broadcast channel. We first propose the hierarchical 16-APSK to generalise the use of hierarchical modulation for the DVB-S2 standard. To the best of our knowledge, the hierarchical 16-APSK has not been extensively studied. Here we choose the constellation parameters according to an energy argument. Then we present how to compute the achievable rates for our scheme. We introduce several strategies to group the users in pairs. We propose two scenarios including homogeneous and non-homogeneous terminals and show that a gain of roughly 15% can be achieved (in the best case) by the strategy grouping the receivers with the greatest SNR difference. In this paper, we study the case where all the receivers get the same rate. Future works will extend our work to any rate policy. We also expect to study the gain of using hierarchical modulation in other standards (e.g., terrestrial standards). ACKNOWLEDGMENT The authors wish to thank Caroline Amiot-Bazile for sharing the SNR distributions presented in Section IV. A PPENDIX A R ESOLUTION OF THE ENERGY EQUATION Consider the equation 2

ρhe =

(1 + γ(1 + 2 cos θ)) , 4(1 + 3γ 2 )

(22)

where ρhe ≥ 0.5 is known, γ ≥ 1 and θ ≥ 0. From (22), it follows ! p 4ρhe (1 + 3γ 2 ) − 1 1 cos θ = −1 2 γ = December 22, 2011

f (γ, ρhe ).

(23) DRAFT

15

We are now looking when −1 ≤ f (γ, ρhe ) ≤ 1 in order to use the arccos function. The function f (γ, ρhe ) is an increasing function of γ when ρhe is set. Moreover, f (γ, ρhe ) −−−−−→ γ→+∞

1 p (2 3ρhe − 1). 2

(24)

The right term is an increasing function in ρhe and equals 1 for ρhe = 0.75. Thus, for all ρhe ≤ 0.75, the solution is Sρhe = {(γ, arccos (f (γ, ρhe ))) |γ ≥ 1} .

(25)

When ρhe > 0.75, γ stay bounded. To determine the limit value γlim , we have to solve the equation, ! p p 4ρhe (1 + 3γ 2 ) − 1 1 4ρhe (1 + 3γ 2 ) − 1 = 3γ −1 =1 ⇔ 2 γ ⇔ (12ρhe − 9)γ 2 − 6γ + (4ρhe − 1) = 0. It is a quadratic equation with discriminant ∆ = 192ρhe (1 − ρhe ). The solutions are p 6 ± 192ρhe (1 − ρhe ) s1,2 = . 2(12ρhe − 9)

(26)

(27)

We keep the positive solution, γlim

p 3 + 4 3ρhe (1 − ρhe ) = . 3(4ρhe − 3)

(28)

Finally, the solution of (22) for γ > 0.75 is, Sρhe = {(γ, arccos (f (γ, ρhe ))) |1 ≤ γ ≤ γlim } .

(29)

Figure 11 presents two examples of Sρhe with different values of ρhe .

40

30

35 25 30

θ in degree

θ in degree

20 25 20 15

15

10 10 5 5 0 1

2

3

4

5

6

7

8

9

10

0 1

γ

1.5

2

2.5

3

γ

(a) ρhe = 0.8

(b) ρhe = 0.9

Fig. 11: Example of Sρhe

December 22, 2011

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16

A PPENDIX B H IERARCHICAL 16-APSK PERFORMANCE We develop in this section the method used to choose the (γ, θ) pair for the hierarchical 16-APSK once the parameter ρhe has been set. We decide to keep only one (γ, θ) pair per ρhe value, as the simulations to obtain the performance are time consuming. For a given ρhe , the decoding thresholds for all the coding rates in function of γ are estimated using the method described in [20]. This allows to obtain a fast approximation of all the decoding thresholds. For instance, Figure 12 presents the curves obtained for ρhe = 0.8, where the crosses correspond to the minimum of each curve. Note that the mathematical resolution of (22) allows large value of γ. In our work, we

20

30

15

25 Decoding threshold (dB)

Decoding threshold (dB)

decide to upper bound γ by min(5, γlim ).

10

5

0

−5 1

20

15

10

1.5

2

2.5

3 γ

3.5

4

4.5

5 1

5

(a) Estimated HE stream decoding thresholds, ρhe = 0.8

1.5

2

2.5

3 γ

3.5

4

4.5

5

(b) Estimated LE stream decoding thresholds, ρhe = 0.8

Fig. 12: Estimated performance of the hierarchical 16-APSK

Then we choose to adopt the (γ, θ) pair that minimizes the average decoding threshold for the HE stream over all the coding rates. Figure 12 shows that this solution does not penalize too much the LE stream. With the estimated performance, we pick the (γ, θ) pair according to the previous criteria. Table I present the adopted pairs. TABLE I: Adopted (γ, θ) values ρhe

0.75

0.8

0.85

0.9

γ

2.8

2.3

1.9

1.6

θ

31.5

28.4

25.1

20.9

Finally, the performance is evaluated with simulations using the Coded Modulation Library [21] that already implements the DVB-S2 LDPC. The LDPC codewords are 64 800 bits long (normal FEC frame) and the iterative decoding stops after 50 iterations if no valid codeword has been decoded. Moreover, in our simulations, we wait until 10 decoding failures before computing the BER. If the BER is less than 10−4 , then we stop the simulation.

December 22, 2011

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17

Our stopping criterion is less restrictive than in [3] (i.e, a Packet Error Rate of 10−7 ) because simulations are time consuming. However, our simulations are sufficient to detect the waterfall region of the LDPC and then the performance of the code. Figure 13 presents all the BER curves.

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

0.01

0.001

1

0.01

0.0001

1e−05

1e−05

1e−06 0

2

4

6 8 Es/No (dB)

10

12

14

3

(a) HE stream performance, ρhe = 0.75 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

0.01

0.001

4

5

6

7 8 9 Es/No (dB)

10

11

12

13

(b) LE stream performance, ρhe = 0.75 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01 Bit Error Rate

−2

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

1e−06 0

2

4 6 Es/No (dB)

8

10

12

4

(c) HE stream performance, ρhe = 0.8 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

6

8

10 Es/No (dB)

12

14

16

(d) LE stream performance, ρhe = 0.8 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01 Bit Error Rate

−2

Bit Error Rate

0.001

0.0001

1e−06

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

1e−06 −2

0

2 4 Es/No (dB)

6

8

10

4

(e) HE stream performance, ρhe = 0.85 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

8

10 Es/No (dB)

12

14

16

1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

6

(f) LE stream performance, ρhe = 0.85

Bit Error Rate

−4

Bit Error Rate

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

1

1e−06 −4

−2

0

2 4 Es/No (dB)

6

8

10

(g) HE stream performance, ρhe = 0.9

6

8

10

12 Es/No (dB)

14

16

18

(h) LE stream performance, ρhe = 0.90

Fig. 13: Performance of the hierarchical 16-APSK

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R EFERENCES [1] T. M. Cover, “Broadcast channels,” IEEE Transactions on Information Theory, vol. IT-18, pp. 2–14, January 1972. [2] P. P. Bergmans and T. M. Cover, “Cooperative broadcasting,” IEEE Transactions on Information Theory, vol. IT-20, pp. 317–324, May 1974. [3] A. Morello and U. Reimers, “DVB-S2, the second generation standard for satellite broadcasting and unicasting,” International Journal of Satellite Communications and Networking, vol. 22, no. 3, pp. 249–268, 2004. [Online]. Available: http://dx.doi.org/10.1002/sat.788 [4] C. Hellge, S. Mirta, T. Schierl, and T. Wiegand, “Mobile TV with SVC and hierarchical modulation for DVB-H broadcast services,” Broadband Multimedia Systems and Broadcasting, 2009. [5] H. Schwarz, D. Marpe, and T. Wiegand, “Overview of the scalable video coding extension of the H.264/AVC standard,” Circuits and Systems for Video Technology, IEEE Transactions on, vol. 17, no. 9, pp. 1103 –1120, sept. 2007. [6] E. Chen, J. L. Koslov, V. Mignone, and J. Santoru, “DVB-S2 backward-compatible modes: a bridge between the present and the future,” International Journal of Satellite Communications and Networking, vol. 22, no. 3, pp. 341–365, 2004. [Online]. Available: http://dx.doi.org/10.1002/sat.794 [7] H. Jiang and P. Wilford, “A hierarchical modulation for upgrading digital broadcast systems,” Broadcasting, IEEE Transactions on, vol. 51, no. 2, pp. 223 – 229, june 2005. [8] ETSI EN 302 307, “Digital Video Broadcasting (DVB); Second generation framing structure, channel coding and modulation systems for Broadcasting, Interactive Services, News Gathering and other broadband satellite applications (DVB-S2).” [9] H. Jiang, P. Wilford, and S. Wilkus, “Providing local content in a hybrid single frequency network using hierarchical modulation,” Broadcasting, IEEE Transactions on, vol. 56, no. 4, pp. 532 –540, dec. 2010. [10] C. Hausl and J. Hagenauer, “Relay communication with hierarchical modulation,” Communications Letters, IEEE, vol. 11, no. 1, pp. 64 –66, jan. 2007. [11] A. Jdidi, T. Chahed, S.-E. Elayoubi, and H. Besbes, “On hierarchical modulation to increase flow-level capacity in OFDMA-based networks,” in Communications (ICC), 2010 IEEE International Conference on, may 2010, pp. 1 –6. [12] M. Eroz, F.-W. Sun, and L.-N. Lee, “DVB-S2 low density parity check codes with near shannon limit performance,” International Journal of Satellite Communications and Networking, vol. 22, no. 3, pp. 269–279, 2004. [Online]. Available: http://dx.doi.org/10.1002/sat.787 [13] ETSI, “Digital video broadcasting (DVB); DVB-SH implementation guidelines issue 2,” December 2008. [14] ——, “Framing Structure, channel coding and modulation for Satellite Services to Handheld devices (SH) below 3 GHz, EN 302 583.” [15] H. M´eric, J. Lacan, C. Amiot-Bazile, F. Arnal, M. Boucheret, Z. Faraj, and G. Lesthievent, “Making hierarchical modulation more flexible,” to appear in AIAA International Communications Satellite System Conference (ICSSC 2011). [Online]. Available: http://hugo.meric.perso.sfr.fr/publis/icssc.pdf [16] H. M´eric, J. Lacan, F. Arnal, G. Lesthievent, and M. Boucheret, “Improving broadcast channel rate using hierarchical modulation.” [Online]. Available: http://arxiv.org/abs/1111.2425 [17] S. H. Choi, C. S. Sin, S. U. Lee, and J. H. Kim, “Channel capacity enhancement scheme for satellite communication system,” in Information, Communications Signal Processing, 2007 6th International Conference on, dec. 2007, pp. 1 –4. [18] R. De Gaudenzi, A. Guilln i Fbregas, and A. Martinez, “Turbo-coded APSK modulations design for satellite broadband communications,” International Journal of Satellite Communications and Networking, vol. 24, no. 4, pp. 261–281, 2006. [Online]. Available: http://dx.doi.org/10.1002/sat.841 [19] H. Schrank and K. Praba, “Optimal aperture for maximum edge-of-coverage (EOC) directivity,” Antennas and Propagation Magazine, IEEE, vol. 36, no. 3, pp. 72 – 74, jun 1994. [20] H. M´eric, J. Lacan, C. Amiot-Bazile, F. Arnal, and M. Boucheret, “Generic approach for hierarchical modulation performance analysis: Application to DVB-SH,” in Wireless Telecommunications Symposium (WTS), 2011, april 2011, pp. 1 –6. [21] Coded Modulation Library. [Online]. Available: http://www.iterativesolutions.com/index.html

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Combining Adaptive Coding and Modulation with Hierarchical Modulation in Satcom Systems arXiv:1112.4944v1 [cs.NI] 21 Dec 2011

Hugo M´eric∗† , J´erˆome Lacan†∗ , Fabrice Arnal‡ , Guy Lesthievent§ and Marie-Laure Boucheret†∗ ∗ T´ eSA, † Universit´ e ‡ Thales

Toulouse, France

de Toulouse, Toulouse, France

Alenia Space, Toulouse, France

§ CNES,

Toulouse, France

Email: [email protected], [email protected], [email protected], [email protected], [email protected]

Abstract We investigate the design of a broadcast system in order to maximise the throughput. This task is usually challenging due to the channel variability. Forty years ago, Cover introduced and compared two schemes: time sharing and superposition coding. Even if the second scheme was proved to be optimal for some channels, modern satellite communications systems such as DVB-SH and DVB-S2 mainly rely on time sharing strategy to optimize the throughput. They consider hierarchical modulation, a practical implementation of superposition coding, but only for unequal error protection or backward compatibility purposes. We propose in this article to combine time sharing and hierarchical modulation together and show how this scheme can improve the performance in terms of available rate. We introduce the hierarchical 16-APSK to boost the performance of the DVB-S2 standard. We also evaluate various strategies to group the receivers in pairs when using hierarchical modulation. Finally, we show in a realistic use case based on DVB-S2 that the combined scheme can provide throughput gains greater than 10% compared to the best time sharing strategy. Index Terms Broadcast Channel, Hierarchical Modulation, Digital Video Broadcasting.

I. I NTRODUCTION In most broadcast applications, the signal-to-noise ratio (SNR) experienced by each receiver can be quite different. For instance, in satellite communications the channel quality decreases with the presence of clouds in Ku or Ka The material in this paper has been submitted in part at ICC 2011. It is available online at http://arxiv.org/abs/1111.2425.

December 22, 2011

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2

band, or with shadowing effects of the environment in lower bands. The first solution for broadcasting is to design the system for the worst-case reception, but this leads to poor performance as many receivers do not exploit their full potential. Then, two other schemes have been proposed in [1] and [2]: time division multiplexing with variable coding and modulation, and superposition coding. Time division multiplexing, or time sharing, allocates to each user a fraction of time where it can use the full channel with any modulation and error protection level. This functionality, called variable coding and modulation (VCM) [3], is the most used in practice in standards today. If a return channel is available, VCM may be combined with adaptive coding and modulation (ACM) to optimize the transmission parameters [3]. In superposition coding, the available energy is shared to several service flows which are sent simultaneously in the same band. This scheme was introduced by Cover in [1] in order to improve the transmission rate from a single source to several receivers. When communicating with two receivers, the principle is to superimpose information for the user with the best SNR. This superposition can be done directly at the forward error correction (FEC) level or at the modulation level as shown in Figure 1 with a 16-QAM modulation. Hierarchical modulation is a practical implementation of superposition coding. Although hierarchical modulation has been introduced to improve the throughput, it is currently often used to provide unequal protection. The idea is to merge two different streams at the modulation level. The high priority (HP) stream is used to select the quadrant, and the low priority (LP) stream selects the position inside the quadrant. The HP stream is dedicated to users with poor channel quality, unlike the LP stream which requires a large SNR to be decoded. In [4], SVC encoded video [5] is protected using hierarchical modulation. The base layer of the video is transmitted in the HP stream, while the enhanced layer is carried by the LP stream. Another usage is backward compatibility [6], [7]. The DVB-S2 standard [3], [8] is called upon to replace DVB-S, but many DVB-S receivers are already installed. Thus the hierarchical modulation helps to the migration by allowing the DVB-S receivers to operate. In [9], the authors propose to provide local content with hierarchical modulation. The principle is to carry locale information that is of interest to a particular geographic area in the LP stream, while the HP stream transmits global content. Finally, other works improve the performance of relay communication system [10] or OFDMA-based networks [11]. Our work focuses on using hierarchical modulation in modern broadcast systems to increase the transmission rate. For instance, even if the LDPC codes of DVB-S2 approach Shannon limit for the AWGN channel with one receiver [12], the throughput can be greatly increased for the broadcast case. Indeed, Cover presents the set of achievable rates for the Gaussian broadcast channel with two receivers in [1]. This set clearly dominates the time sharing achievable rate. This article investigates the performance, in terms of throughput, of a satellite broadcast system where time sharing and hierarchical modulation are combined. We show on an example modeling a satellite broadcast area that the gain can be significant. The way of grouping receivers in pairs is also investigated as it greatly affects the performance. The paper is organized as follows. Section II presents the hierarchical modulation. We introduce the hierarchical 16-APSK in order to boost the performance of the DVB-S2 standard. In Section III, the achievable rates are computed for the time sharing used alone or combined with hierarchical modulation. We study on a use case the performance of each scheme in Section IV. We also propose a grouping strategy when using hierarchical modulation December 22, 2011

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3

and discuss its performance. Finally, Section V concludes the paper by summarizing the results. Q

HP

Encoder

00

0100

0101

0001

0000

0110

0111

0011

0010

I

Hierarchical 16−QAM LP

Encoder 11

1110

1111

1100

1101

1011

1010

1001

1000

2dl 2dh

Fig. 1: Hierarchical modulation using a 16-QAM

II. H IERARCHICAL M ODULATION This part introduces the hierarchical 16-QAM and 16-APSK. First, the hierarchical 16-QAM, considered in the DVB-SH standard [13],[14], is presented. It gives us some insight on how to introduce the hierarchical 16-APSK. Then the hierarchical 16-APSK is presented in order to improve the performance of DVB-S2. As mentioned before, hierarchical modulations merge several streams in a same symbol. The available energy is shared between each stream. In our study, two streams are considered. When hierarchical modulation is used to unequal protection purpose, these flows are called HP and LP streams. However, unequal protection is not the goal of our work, so we will now refer to high energy (HE) and low energy (LE) streams for the stream containing the most and the least energy respectively. As each stream does not use the same energy, hierarchical modulations are based on non-uniform constellations where the symbols are not uniformly distributed in the space. The geometry of non-uniform constellations is described using the constellation parameter(s). A. Hierarchical 16-QAM The constellation parameter α is defined by dh /dl , where 2dh is the minimum distance between two constellation points carrying different HE bits and 2dl is the minimum distance between any constellation point (see Figure 1). Typically, we have α ≥ 1, where α = 1 corresponds to the uniform 16-QAM, but it is also possible to have α ≤ 1 [15]. When α grows, the constellation points in each quadrant become farer to the I and Q axes. Thus it is easier to decode the HE stream. However, in the same quadrant, the points get closer and the LE stream requires a better channel quality to be decoded. The hierarchical 16-QAM is the superposition of two QPSK modulations, one with parameter dh + dl (carrying the HE stream) and the other with parameter dl (carrying the LE stream). The energy ratio between the two streams is Ehe = (1 + α)2 , Ele December 22, 2011

(1)

DRAFT

4

where Ehe and Ele correspond to the energy allocated to the HE and LE streams respectively [9]. The DVB-SH standard recommends two values for α: 2 and 4. In fact, it also considers α = 1 but only for the VCM mode. The values 2 and 4 are defined in order to provide unequal protection. From an energy point of view, this amounts to give 90% (α = 2) or 96% (α = 4) of the available energy to the HE stream. In [16], the authors improve the overall throughput of a simple broadcast channel by adding α = 1, α = 0.8 and α = 0.5. This provides a better repartion of the energy: the HE stream contains 80%, 76% and 69% of the total power. B. Hierarchical 16-APSK The DVB-S2 standard also introduces hierarchical modulation with the hierarchical 8-PSK. The constellation parameter θP SK , which is the half angle between two points in one quadrant, is defined by the service operator according to the desired performance. However, this modulation does not offer a good spectrum efficiency. As the 16-APSK is already defined in DVB-S2, we propose the hierarchical 16-APSK, shown in Figure 2, in order to boost the performance of the system. Two parameters impact on the constellation geometry: γ = R2 /R1 and θ.

2θ

R1

R2

Fig. 2: 16-APSK modulation

The hierarchical 16-APSK is not a new concept. For instance, this modulation is presented to upgrade an existing digital broadcast system in [17]. However, the design of the modulation is not addressed. In [18], the authors investigate the design of APSK modulations for satellite broadband communication, but the hierarchical case is not treated. In our study, we use an energy argument to choose the parameters γ and θ. The hierarchical modulation shares the available energy between the HE and LE streams. We consider the energy of the HE stream. It is given by the energy of a QPSK modulation, where the constellation points are located at the barycenter of the four points in each quadrant. Using the polar coordinates, the barycenter in the upper right quadrant is R1 eiπ/4 + R2 eiπ/4 + R2 ei(π/4+θ) + R2 ei(π/4−θ) R1 + R2 + 2R2 cos(θ) = eiπ/4 . 4 4

(2)

Moreover, the symbol energy is expressed as Es

= =

December 22, 2011

4R12 + 12R22 16 1 + 3γ 2 2 R1 . 4

(3) DRAFT

5

Then combining (2) and (3), the distance of the barycenter to the origin is dB

= = =

R1 + R2 + 2R2 cos(θ) 4 1 + γ(1 + 2 cos(θ)) R1 4 √ 1 + γ(1 + 2 cos(θ)) 2 Es p . 4 1 + 3γ 2

(4)

Finally, the energy of the HE stream is given by Ehe

= Eqpsk = d2B 2

=

(1 + γ(1 + 2 cos θ)) Es . 4(1 + 3γ 2 ) | {z }

(5)

ρhe

Equation (5) introduces ρhe the ratio between the energy of the HE stream Ehe and the symbol energy Es . We are now interested to determine the set of (γ, θ) pairs solution of (6), where ρhe ≥ 0.5 is known, γ ≥ 1 and θ ≥ 0. ρhe =

(1 + γ(1 + 2 cos θ)) 4(1 + 3γ 2 )

2

(6)

The resolution of (6) is given in Appendix A. The solution set is Sρhe = {(γ, arccos (f (γ, ρhe ))) |1 ≤ γ ≤ γlim } ,

(7)

where ! 4ρhe (1 + 3γ 2 ) − 1 −1 γ

(8)

+∞, if ρhe ≤ 0.75 √ = 3+4 3ρhe (1−ρhe ) , if ρhe > 0.75. 3(4ρhe −3)

(9)

1 f (γ, ρhe ) = 2

p

and γlim

Appendix A also presents two examples of the Sρhe set. When ρhe increases, the points in one quadrant tend to get closer. It implies the HE stream is easier to decode, but on the other hand the LE stream requires a better SNR to be decoded. As for the hierarchical 16-QAM, several values of ρhe have to be selected. The results presented in Section IV show that choosing ρhe = 0.75, 0.8, 0.85 and 0.9 allows to have good performance. However, once the parameter ρhe is set, we still have to decide which (γ, θ) couple to keep in the Sρhe set. We keep one (γ, θ) pair per ρhe value. This pair minimizes the average decoding threshold for the HE stream over all the coding rates in the DVB-S2 standard. Appendix B gives all the decoding thresholds and explains their computation. III. T IME S HARING AND H IERARCHICAL M ODULATION ACHIEVABLE R ATES This part introduces the rates achievable by the two following schemes: time sharing with or without hierarchical modulation, referred as hierarchical modulation and classical time sharing respectively. We first consider the case of one source communicating with two receivers. Then we study the general case with n receivers. December 22, 2011

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A. Achievable rates: case with two receivers 1) Classical time sharing: We consider one source communicating with two receivers, each one with a particular SNR. Given this SNR, we suppose receiver i (i = 1, 2) has a rate Ri , which corresponds to the best rate it can afford. This rate depends on the modulations and coding rates available in the system. For the DVB-S2 standard, readers can refer to [8]. With a time sharing strategy, the average rate results from the fraction of time ti allocated to each receiver. In our study, we are interested to offer the same rate to everyone, but our work can be easily adapted to another rate policy. To offer the same rate to the two users, we need to solve t1 R1 = t2 R2

(10)

t1 + t2 = 1. By solving (10), the fraction of time allocated to each user is t 1 = R 2 R1 +R2 t 2 =

(11)

R1 R1 +R2 .

The constraint t1 + t2 = 1 is verified and we remark that increasing Ri reduces ti , which is a consequence of our rate policy. Finally, the rate offered to each receiver is Rts =

R1 R2 . R1 + R2

(12)

2) Hierarchical modulation time sharing: The first step is to compute the rates offered by all the possible modulations, including hierarchical ones. When the hierarchical modulation is used, we suppose the receiver experiencing the best SNR decodes the LE stream. Thus we obtain a set of operating points. Moreover, when two sets of rates (R1 , R2 ) and R˜1 , R˜2 are available, the time sharing strategy allows any rate pair τ R1 + (1 − τ )R˜1 , τ R2 + (1 − τ )R˜2 , (13) where 0 ≤ τ ≤ 1 is the fraction of time allocated to (R1 , R2 ). The achievable rates set finally corresponds to the convex hull of all the operating points. As we are interested to offer the same rate to the users, we calculate the intersection of the convex hull with the curve y = x. We note Rhm and Rts the rates offered to both receivers by the hierarchical modulation and classical time sharing strategy respectively. Figure 3 presents one example of achievable rates set where one receiver experiences a SNR of 7 dB and the other 10 dB. We also represent Rhm and Rts in order to visualize the gain. For the classical time sharing strategy, the rates obtained in Figure 3 come from the 8-PSK 2/3 for the user with a SNR of 7 dB and the 16-APSK 3/4 for the other user. As said before, it is the best that each receiver can afford. For the hierarchical modulation, the operating points are computed using the standard [8] or Appendix B. Remark that the hierarchical 16-APSK gives better results than the hierarchical 8-PSK. Moreover, when ρhe increases, the rate of the user with the worst SNR increases, while the rate of the other user decreases. This can be explained as more energy is dedicated to the HE stream and then its performance improves. On the other hand, the LE stream is allocated less energy and its

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2 Time sharing 1.8

8−PSK (θ=30°)

User 1 rate

(Rhm, Rhm) 1.6

8−PSK (θ=20°) 16−APSK (ρhe=0.75)

1.4

16−APSK (ρhe=0.8) 16−APSK (ρhe=0.85)

1.2

16−APSK (ρhe=0.9)

1 (Rts, Rts) 0.8 0.6 0.4 0.2 0 0

0.5

1

1.5 User 2 rate

2

2.5

3

Fig. 3: Achievable rates set: SN R1 = 7 dB - SN R2 = 10 dB

performance decreases. Finally, the interest of using hierarchical modulation is obvious as the gain between Rhm and Rts is about 11%. We now use the same method to evaluate the gain between Rhm and Rts for all (SN R1 , SN R2 ) pairs where 4 dB ≤ SN Ri ≤ 12 dB, i = 1, 2. Figure 4 presents the results. Note that the gain provided by the hierarchical modulation is significative in several cases and can achieve up to 20%. In general, the gains are more important when the SNR difference between the two receivers is large. This observation will be used in the next part when we will group a set of users in pairs.

25

Gain in percent

20 15 10 5 0 12 12

10 10

8 Es/No user 2 (dB)

8

6

6 4

4

Es/No user 1 (dB)

Fig. 4: Rate gain

December 22, 2011

DRAFT

8

B. Achievable rates: case with n receivers 1) Classical time sharing: We now consider a broadcast system with n receivers. We suppose receiver i has a rate Ri , which corresponds to the best rate it can afford as mentioned above. With our rate policy, (10) becomes ∀i, j, ti Ri = tj Rj (14) P ti = 1. i The resolution of (14) leads to a fraction of time allocated to user i of Q =i Rk k6Q . ti = P n R k j=1 k6=j With this time allocation, the average rate offered to each receiver is −1 Q n X R 1 k k . Q = Rts = P n R j R j=1 j=1

k6=j

(15)

(16)

k

2) Hierarchical modulation with time sharing: For the case with n receivers, the first step is to group the users in pairs in order to use hierarchical modulation. A lot of possibilities are available and the next section presents a grouping strategy which generally obtains good results. Once the pairs have been chosen, for each pair we compute the achievable rate as described previously. Finally, we need to equalize the rate between each user. This is done by time sharing using (15). For instance, consider a DVB-S2 system where a user u1 with a SNR of 7 dB is in pair with a user u2 with a SNR of 10 dB. The rate for each receiver is obtained using the hierarchical 16-APSK (ρhe = 0.8) a fraction of time a1 and the 16-APSK a fraction of time a2 as shown in Figure 3. When equalizing the rates between all the users, (15) gives the same fraction of time t to users u1 and u2 . Then, the pair of users has to share a global fraction of time 2t. It follows that the broadcast system allocates to u1 and u2 the hierarchical 16-APSK (ρhe = 0.8) for a time proportion 2t × a1 and the 16-APSK for 2t × a2 . IV. A PPLICATION TO BROADCAST CHANNEL An important insight of the previous section is that the gain of hierarchical modulation depends on the way to group users in pairs. For instance, consider a set of four users u1 , u2 , u3 , u4 with respective SNR 4, 4, 12 and 12 dB. Then, according to Figure 4, the choice of pairs (u1 , u2 ) and (u3 , u4 ) leads to no gain while the choice (u1 , u3 ) and (u2 , u4 ) allows a gain of about 20%. In this section, we first present different grouping strategies of a set of users when the hierarchical modulation time sharing is considered. Then we introduce a broadcast channel where the performance of hierarchical modulation and classical time sharing are evaluated. The impact of the grouping strategy is also discussed. A. Grouping strategy We consider a set of receivers, where the distribution of the SNR values is known. The possible SNR values are SN Ri with 1 ≤ i ≤ m and for all i ≤ j, SN Ri ≤ SN Rj . Moreover, exactly ni receivers experience a channel Pm quality of SN Ri . We also define i=1 ni = 2N the total number of receivers and ∆i,j = |SN Ri − SN Rj |. December 22, 2011

DRAFT

9

Definition 1: For any grouping, the average SNR difference per receivers in pairs is defined as ∆=

N 1 X ∆ik ,jk , N

(17)

k=1

where the (ik , jk ) couple represents a pair of receivers. When communicating with two receivers, we have already mentioned that the gain is more important when the SNR difference between the two users is large. From this observation, we are looking to group the users in pairs in order to maximise the average SNR difference. The following theorem presents a strategy to compute this maximum. Theorem 1: From any set of receivers, the iterative procedure that picks the two receivers with the largest SNR difference, group them and repeat this operation allows to reach the maximum average SNR difference. Proof: First, we compute an upper bound for the average SNR difference. In (17), for all k, we have (assuming ik ≤ jk ) ∆ik ,jk =

jX k −1

∆m,m+1 .

(18)

m=ik

Thus, ∆ can be expressed in the following form ∆=

m−1 1 X ai ∆i,i+1 , N i=1

(19)

where ai ∈ N for all i. We now search to bound ai . The term ∆i,i+1 in (19) only appears when we group a user Pi with a SNR less or equal to SN Ri and a user with a SNR greater or equal to SN Ri+1 . There is exactly k=1 nk Pm receivers with SN R ≤ SN Ri and k=i+1 nk receivers with SN R ≥ SN Ri+1 , so ai is bounded by ai ≤ min(

i X

k=1

nk ,

m X

nk ).

(20)

k=i+1

Pi Pm We now prove the proposed scheme reaches this bound, i.e., ai = min( k=1 nk , k=i+1 nk ). Let L be the PL greatest integer such as i=1 ni ≤ N . The strategy insures that all the receivers with a SNR less or equal to SN RL+1 are grouped with a receiver whose SNR is greater or equal to SN RL+1 . Thus, in the computation of the average SNR difference, we verify that P1 Pm • ∆1,2 appears n1 = min( k=2 nk ) times. k=1 nk , P2 Pm • ∆2,3 appears n1 + n2 = min( k=1 nk , k=3 nk ) times. •

...

•

PL Pm ∆L,L+1 appears n1 + n2 + ... + nL = min( k=1 nk , k=L+1 nk ) times.

The equality also holds in (20) for the terms ∆i,i+1 with i ≥ L + 1. Thus, our strategy allows to reach the previous bound, which is in fact the maximum average SNR difference. However, depending on the receivers configuration, other schemes allow to reach the maximum average SNR difference. For instance, consider the case with four receivers where the SNR values are SN R1 (user 1), SN R2 = SN R1 + 1 dB (user 2), SN R3 = SN R1 + 2 dB (user 3) and SN R4 = SN R1 + 3 dB (user 4). The previous

December 22, 2011

DRAFT

10

strategy leads to group user 1 with user 4, and user 2 with user 3. But it is also possible to group user 1 with user 3, and user 2 with user 4. In both cases, the average SNR difference is 2 dB. Moreover, to highlight the impact of the grouping strategy, we propose to compare four grouping schemes: •

Strategy A: the scheme described in the previous theorem.

•

Strategy B: we compute the maximum average SNR difference ∆max and use it to group the receivers with a SNR difference as close as possible to ∆max . This strategy usually allows to have an average SNR difference close to ∆max , but compared to strategy A, the variance of the SNR difference by pairs is much smaller.

•

Strategy C: the receivers are grouped randomly.

•

Strategy D: we group the receivers with the closest SNR.

B. DVB-S2 channel model To evaluate the effective potential of our proposal for real systems, we present a model to estimate the SNR distribution of the receivers. For that, we considered the set of receivers located in a given spot beam of a geostationnary satellite broadcasting in the Ka band. The model takes into account two main sources of attenuation: the relative location of the terminal with respect to the center of (beam) coverage and the weather. Concerning the attenuation due to the location, the principle is to set the SNR at the center of the spot beam SN Rmax and use the radiation pattern of a parabolic antenna to model the attenuation. An approximation of the radiation pattern is !2 J1 sin(θ) πD λ G(θ) = Gmax 2 , (21) sin(θ) πD λ where J1 is the first order Bessel function, D is the antenna diameter and λ = c/f is the wavelength [19]. In our simulations, we use D = 1.5 m and f = 20 GHz. Moreover we consider a typical multispot system where the edge of each spot beam is 4 dB below the center of coverage. Assuming a uniform repartion of the population, the proportion of the receivers experiencing an attenuation between two given values is the ratio of the ring area over the disk shown in Figure 5. The ring area is computed knowing the satellite is geostationary and using (21). 000000 111111 000000 111111 000000 111111 111111 000000 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111 000000 111111

00000 11111 00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

1111111111111111111111111111111 0000000000000000000000000000000 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111 0000000000000000000000000000000 1111111111111111111111111111111

Fig. 5: Satellite broadcasting area

Figure 6, provided by the CNES, presents the attenuation distribution in the broadcasting satellite service (BSS) band. More precisely, it is a temporal distribution for a given location in Toulouse, France. In our work, we assume the SNR distribution for the receivers in the beam coverage at a given time is equivalent to the temporal distribution at a given location. December 22, 2011

DRAFT

11

1 0.1

Culmulative Density Function

0.9 0.8

0.01

0.7 0.001

0.6 0.5

0.0001 −9 −8 −7 −6 −5 −4 −3 −2 −1

0.4 0.3 0.2 0.1 0 −9

−8

−7

−6 −5 −4 −3 Attenuation (in dB)

−2

−1

0

Fig. 6: Attenuation distribution (due to weather)

Finally, our model combines the two kinds of attenuation to estimate the SNR distribution. From a set of receivers, we first compute the attenuation due to the location. Then, for each receiver we draw, according to the previous distribution, the attenuation caused by the weather. C. Results Two scenarios are considered. In the first one, all the terminals have the same capacities (homogeneous case). In the second one, we consider two subsets of receivers, one with personal terminals and the other with professional terminals (heterogeneous case). Professional terminals forward the service, and not the signal, to some receivers in a local area network. We suppose the professional terminals experience 5 dB better than the personal terminals. They allow to increase the SNR diversity which is interesting when using the hierarchical modulation time sharing. Figure 7 shows a broadcast channel with two kinds of terminals (large antennas represent professional terminals). 00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

3R

R

00000 11111 11111 00000 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111 00000 11111

3R

R R

Fig. 7: Broadcast channel with two kinds of terminals

1) Homogeneous terminals: Figure 8 presents the results for a broadcasting area with 500 receivers. For each simulation, the SNR value of each user is drawn according to the distribution presented above. For one configuration

December 22, 2011

DRAFT

12

(i.e., the parameter SN Rmax is set), we present the average, minimum and maximum gains over 100 simulations for the four grouping strategies. 9 8

Strategy A Strategy B Strategy C Strategy D

Gain (in percent)

7 6 5 4 3 2 1 0

13 dB

dB

dB

10

7

SNRmax

Fig. 8: Results for the homogeneous case with 500 receivers

First of all, the hierarchical modulation time sharing outperforms the classical time sharing scheme whatever the grouping strategy used. In fact, the hierarchical modulation adds some new operating points and thus can only improve the performance. Then, for each configuration, strategies A and B give the best results with a slight advantage for strategy A, which obtains more than 9% of gain for SN Rmax = 10 dB. This is consistent with the results presented in Figure 4, where the best gains are obtained when the SNR difference between the two receivers is large. Moreover, strategy D, which minimises the SNR difference, appears to be the worst scheme. The results also point out that the random strategy performs well. Thus the hierarchical modulation time sharing combined with a good grouping strategy allows to obtain intermediate gains between strategies A and D. In addition, strategies A, B and C do not require intensive computation to group the receivers and this can be done in real time which is interesting for satellite standards. We remark the better results are obtained when SN Rmax = 10 dB. In fact, the hierarchical modulation time sharing is useful only in a SNR interval. Figure 9 presents the gain of the strategy A according to SN Rmax for a large range of SN Rmax values. For low SNR values, the LE stream is often not able to decode any coding rate. This explains why there is no gain for low SNR values. An idea to tackle this phenomenon is to allocate more energy to the LE stream, but in that case, the performance of the HE stream is too deteriorated. For large SNR values, the classical time sharing uses the largest coding rate possible. For instance, consider two receivers with a SNR greater than 13.13 dB which corresponds to the decoding threshold of the 9/10 16-APSK [8]. The classical time sharing strategy allocates the same fraction of time t = 0.5 to both receivers. For the hierarchical modulation time sharing, one of the receiver decodes the HE stream, and the other the LE stream. In the best case, each stream can decode the coding rate 9/10. Each receiver use the channel all the time but the HE and LE streams

December 22, 2011

DRAFT

13

only carry two bits. Then the hierarchical modulation time sharing can not outperform the classical scheme here. This example illustrates why the hierarchical modulation time sharing does not increase the performance for large value of SN Rmax . A solution should be to use a higher order modulation, for instance the 32-APSK. 10 9 8

Gain (in percent)

7 6 5 4 3 2 1 0 2

4

6

8

10 12 SNRmax

14

16

18

20

Fig. 9: Gain vs SN Rmax (Strategy A)

2) Heterogeneous terminals: We investigate the scenario where personal and professional terminals are used simultaneously. We consider that only one receiver is served by a personal terminal whereas there are several users behind a professional terminal (see Figure 7). As mentioned before, the professional terminals experience 5 dB better than the personal terminals. It is also important to notice that the rate dedicated to one professional terminal is proportional to the number of receivers served by this terminal. The aim is always to provide the same rate for each user. In this scenario, the performance depends on the proportion of receivers served by a professional terminal and SN Rmax . Here SN Rmax corresponds to the SNR experienced by personal terminals at the center of the spot beam (with clear sky condition). Figure 10 presents the gains according to the proportion of users served by a collective terminal. Here again, the simulations involve 500 receivers and we present the results over 100 simulations. First of all, the gains are most of the time better than in Figure 8. This is in accordance with Figure 4 as the presence of professional terminals increases the average SNR difference. Then, for a given SN Rmax , the maximum gain takes place when 50% of the receivers are served by a professional terminal, which corresponds to the maximum possible SNR diversity. This result is consistent with the work presented in [11]. Finally, compared to Figure 8, the results are worse in two cases, when SN Rmax = 10 or 13 dB and 90% of the receivers are served by a professional terminal. In these particular cases, we do not really increase the SNR diversity, but rather the average SNR. Then, the performance when SN Rmax = 10 dB and 90% of the receivers are served by professional terminals is more similar to the performance observed in Figure 10 when SN Rmax = 15 dB (we assume that a professional terminal experiences 5 dB better than a personal terminal).

December 22, 2011

DRAFT

14

16 14

Strategy A Strategy B Strategy C Strategy D

Gain (in percent)

12 10 8 6 4 2 0

0%

0%

,9

dB

0%

,7

dB

13

0%

,5

0%

,2

dB

13

13

0%

,1

dB

13

dB

13

0%

,9

dB

0%

,7

dB

10

0%

,5

0%

,2

dB

10

10

,1

dB

10

%

%

90

%

70

%

50

%

20

10

dB

10

B,

B,

7d

B,

7d

7d

B,

B,

7d

7d

SNRmax, proportion of receivers served by a professional terminal

Fig. 10: Results for the heterogeneous case with 500 receivers

V. C ONCLUSION In this paper, we use time sharing and hierarchical modulation together to increase the throughput of a broadcast channel. We first propose the hierarchical 16-APSK to generalise the use of hierarchical modulation for the DVB-S2 standard. To the best of our knowledge, the hierarchical 16-APSK has not been extensively studied. Here we choose the constellation parameters according to an energy argument. Then we present how to compute the achievable rates for our scheme. We introduce several strategies to group the users in pairs. We propose two scenarios including homogeneous and non-homogeneous terminals and show that a gain of roughly 15% can be achieved (in the best case) by the strategy grouping the receivers with the greatest SNR difference. In this paper, we study the case where all the receivers get the same rate. Future works will extend our work to any rate policy. We also expect to study the gain of using hierarchical modulation in other standards (e.g., terrestrial standards). ACKNOWLEDGMENT The authors wish to thank Caroline Amiot-Bazile for sharing the SNR distributions presented in Section IV. A PPENDIX A R ESOLUTION OF THE ENERGY EQUATION Consider the equation 2

ρhe =

(1 + γ(1 + 2 cos θ)) , 4(1 + 3γ 2 )

(22)

where ρhe ≥ 0.5 is known, γ ≥ 1 and θ ≥ 0. From (22), it follows ! p 4ρhe (1 + 3γ 2 ) − 1 1 cos θ = −1 2 γ = December 22, 2011

f (γ, ρhe ).

(23) DRAFT

15

We are now looking when −1 ≤ f (γ, ρhe ) ≤ 1 in order to use the arccos function. The function f (γ, ρhe ) is an increasing function of γ when ρhe is set. Moreover, f (γ, ρhe ) −−−−−→ γ→+∞

1 p (2 3ρhe − 1). 2

(24)

The right term is an increasing function in ρhe and equals 1 for ρhe = 0.75. Thus, for all ρhe ≤ 0.75, the solution is Sρhe = {(γ, arccos (f (γ, ρhe ))) |γ ≥ 1} .

(25)

When ρhe > 0.75, γ stay bounded. To determine the limit value γlim , we have to solve the equation, ! p p 4ρhe (1 + 3γ 2 ) − 1 1 4ρhe (1 + 3γ 2 ) − 1 = 3γ −1 =1 ⇔ 2 γ ⇔ (12ρhe − 9)γ 2 − 6γ + (4ρhe − 1) = 0. It is a quadratic equation with discriminant ∆ = 192ρhe (1 − ρhe ). The solutions are p 6 ± 192ρhe (1 − ρhe ) s1,2 = . 2(12ρhe − 9)

(26)

(27)

We keep the positive solution, γlim

p 3 + 4 3ρhe (1 − ρhe ) = . 3(4ρhe − 3)

(28)

Finally, the solution of (22) for γ > 0.75 is, Sρhe = {(γ, arccos (f (γ, ρhe ))) |1 ≤ γ ≤ γlim } .

(29)

Figure 11 presents two examples of Sρhe with different values of ρhe .

40

30

35 25 30

θ in degree

θ in degree

20 25 20 15

15

10 10 5 5 0 1

2

3

4

5

6

7

8

9

10

0 1

γ

1.5

2

2.5

3

γ

(a) ρhe = 0.8

(b) ρhe = 0.9

Fig. 11: Example of Sρhe

December 22, 2011

DRAFT

16

A PPENDIX B H IERARCHICAL 16-APSK PERFORMANCE We develop in this section the method used to choose the (γ, θ) pair for the hierarchical 16-APSK once the parameter ρhe has been set. We decide to keep only one (γ, θ) pair per ρhe value, as the simulations to obtain the performance are time consuming. For a given ρhe , the decoding thresholds for all the coding rates in function of γ are estimated using the method described in [20]. This allows to obtain a fast approximation of all the decoding thresholds. For instance, Figure 12 presents the curves obtained for ρhe = 0.8, where the crosses correspond to the minimum of each curve. Note that the mathematical resolution of (22) allows large value of γ. In our work, we

20

30

15

25 Decoding threshold (dB)

Decoding threshold (dB)

decide to upper bound γ by min(5, γlim ).

10

5

0

−5 1

20

15

10

1.5

2

2.5

3 γ

3.5

4

4.5

5 1

5

(a) Estimated HE stream decoding thresholds, ρhe = 0.8

1.5

2

2.5

3 γ

3.5

4

4.5

5

(b) Estimated LE stream decoding thresholds, ρhe = 0.8

Fig. 12: Estimated performance of the hierarchical 16-APSK

Then we choose to adopt the (γ, θ) pair that minimizes the average decoding threshold for the HE stream over all the coding rates. Figure 12 shows that this solution does not penalize too much the LE stream. With the estimated performance, we pick the (γ, θ) pair according to the previous criteria. Table I present the adopted pairs. TABLE I: Adopted (γ, θ) values ρhe

0.75

0.8

0.85

0.9

γ

2.8

2.3

1.9

1.6

θ

31.5

28.4

25.1

20.9

Finally, the performance is evaluated with simulations using the Coded Modulation Library [21] that already implements the DVB-S2 LDPC. The LDPC codewords are 64 800 bits long (normal FEC frame) and the iterative decoding stops after 50 iterations if no valid codeword has been decoded. Moreover, in our simulations, we wait until 10 decoding failures before computing the BER. If the BER is less than 10−4 , then we stop the simulation.

December 22, 2011

DRAFT

17

Our stopping criterion is less restrictive than in [3] (i.e, a Packet Error Rate of 10−7 ) because simulations are time consuming. However, our simulations are sufficient to detect the waterfall region of the LDPC and then the performance of the code. Figure 13 presents all the BER curves.

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

0.01

0.001

1

0.01

0.0001

1e−05

1e−05

1e−06 0

2

4

6 8 Es/No (dB)

10

12

14

3

(a) HE stream performance, ρhe = 0.75 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

0.01

0.001

4

5

6

7 8 9 Es/No (dB)

10

11

12

13

(b) LE stream performance, ρhe = 0.75 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01 Bit Error Rate

−2

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

1e−06 0

2

4 6 Es/No (dB)

8

10

12

4

(c) HE stream performance, ρhe = 0.8 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

6

8

10 Es/No (dB)

12

14

16

(d) LE stream performance, ρhe = 0.8 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01 Bit Error Rate

−2

Bit Error Rate

0.001

0.0001

1e−06

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

1e−06 −2

0

2 4 Es/No (dB)

6

8

10

4

(e) HE stream performance, ρhe = 0.85 1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

8

10 Es/No (dB)

12

14

16

1

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

0.01

0.001

0.0001

0.0001

1e−05

1e−05

1e−06

6

(f) LE stream performance, ρhe = 0.85

Bit Error Rate

−4

Bit Error Rate

R=1/4 R=1/3 R=2/5 R=1/2 R=3/5 R=2/3 R=3/4 R=4/5 R=5/6 R=8/9 R=9/10

0.1

Bit Error Rate

1

1e−06 −4

−2

0

2 4 Es/No (dB)

6

8

10

(g) HE stream performance, ρhe = 0.9

6

8

10

12 Es/No (dB)

14

16

18

(h) LE stream performance, ρhe = 0.90

Fig. 13: Performance of the hierarchical 16-APSK

December 22, 2011

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