1. Introduction
Satellite communication services are available to any user within the service area of the satellite communication system, regardless of the user’s location. This unique feature makes satellite communication systems attractive, especially in remote areas where ground network deployment is difficult or even impossible. In addition, satellite communication can provide various services such as television, broadcasting, telephone, and Internet services, making it indispensable to our hyperconnected society.
At present, multimedia application demand and data exchange are experiencing explosive growth [
1], and multi-beam high throughput satellite (HTS) systems have proven to be one of the most promising solutions [
2]. The antenna gain of multi-beam HTS systems is significantly higher when compared to the ones which use a single large beam to cover the entire service area. Since the first HTS was launched, the number of HTSs in geosynchronous orbit has increased year by year. The first generation of HTSs, represented by IPSTAR and AMC-15/16 satellites, employed spot beams with system throughput ranging from 2 to 5 Gbps. The second generation began to utilize narrow spot beam and frequency reuse technology with throughput ranging from 5 to 10 Gbps, represented by WildBlue-1 (35 spot beams) and Spaceway-3 (24 downlink beams) satellites. The third generation largely used narrow spot beams and frequency reuse technology, with a throughput of up to about 100 Gbps, represented by KA-SAT (82 spot beams) and ViaSat-1 (72 spot beams) satellites. The fourth generation, most of which are currently under research, use large mesh deployable antennas that are capable of forming hundreds of narrower spot beams through beamforming technology, leading to a throughput of more than 300 Gbps, even up to 1 Tbps. ViaSat-2 (more than 100 spot beams), ViaSat-3, and SES17 (about 200 spot beams) are representative satellites. It can be seen that the development of HTS has led to a significant increase in system capacity, accompanied by substantial growth in the number of beams. Currently, mainstream satellite manufacturers in Europe and the United States have nearly 100 high-throughput satellites in orbit, and major satellite operators around the world are actively promoting the deployment of HTS satellites, with more than 1000 orders for HTS satellites around the world [
3].
Figure 1 shows the difference between multi-beam and single-beam coverage. Since HTS multibeams are spatially separated in space, enabling the same frequencies to be reused, multibeam coverage is an efficient way to exploit the system bandwidth, which is a very valuable yet expensive resource in any communication system. On the one hand, the frequency reuse technology greatly improves the total bandwidth of the system and then increases the system’s capacity. Nevertheless, on the other hand, the side-lobe effect of multi-beam antennas will inevitably lead to co-channel interference between beams using the same frequency band [
4,
5], which occupies a more dominant position in the whole system interference compared with cross-polarization interference, adjacent channel interference, and other interferences. In reference [
6], the authors claim that spot beam isolation and beam-to-beam interference become increasingly important as the number of beams is increased to tessellate a given geographic area, and they have to be carefully attended to. However, this paper does not focus on the quantification of the carrier-to-interference ratio (CIR). Therefore, it is necessary to research a method for quantifying the CIR (mainly co-channel interference) in multi-beam HTS systems, and based on this, the system capacity-oriented frequency allocation method is explored with a focus on the system’s CIR optimization.
References [
7,
8,
9,
10,
11] mention the role of the CIR in the link budget and give typical values of the CIR to explain or simulate relevant problems in satellite systems, but the typical values given by them are not uniform. For example, it is mentioned in reference [
7] that when the frequency reuse factor is 1, 2, 3, or 4, the CIR is about 0 dB, 8 dB, 25 dB, or 30 dB, respectively. In particular, the range is between 14 dB and 34 dB when the frequency reuse factor is 4. In references [
8,
9], the CIR was set to 18 dB and 15 dB, respectively. In reference [
10], the value of co-frequency co-polarization interference was set to 20 dB, while the value of co-frequency cross-polarization interference and co-polarization interference of different frequencies were both set to 25 dB. In reference [
11], the CIR was set to 16 dB for the reuse factor of 4. It is worth noting that these typical values are difficult to fully fit various real-world scenarios and are not persuasive due to a lack of theoretical support.
In addition, some researchers take the actual measured values of the CIR as the input to conduct their research. For example, in reference [
12], the authors obtained the CIR geographical maps in dB for the KaSat coverage and came to the conclusion that the CIR increases when the beamwidth is narrower. This method may facilitate the accuracy of the research, but it is hard to obtain the data and inconvenient for theoretical research and model demonstration.
Furthermore, there are considerable efforts in the literature [
13,
14] devoted to developing the interference model and frequency reuse solutions in HTS, and a relatively concise calculation method was proposed for the calculation of the CIR. That is, the equivalent isotropically radiated power (EIRP) or on-board antenna gain value of the useful signal relative to the target user divided by the sum of the EIRP or on-board antenna gain value of interference signals relative to the target user. The calculation of the CIR is closer to the definition but is not conducive to the actual calculation, and the uplink and downlink are also not fully discussed. Similar to references [
13,
14], reference [
15] provides an expression of co-channel interference power, which equals the sum of the power level of interference inside the target beam coming from all interfering beams of the target beam. However, this expression is conceptual and cannot indicate how we can derive the power level of interference. Reference [
16] focused on the overall system design and introduced two software tools for system evaluation and analysis. In detail, the beam-drawing software developed by the University of Surrey can accomplish the gridding calculation of the CIR in the beam coverage area, and the calculation formula of the user link CIR is also known. However, the scenarios with multi-carriers in one beam related to the band plan and the influence of different frequency allocation schemes on the system CIR are not included in reference [
16]. In summary, this has become a trend in CIR evaluation, from being computable to accurate and widely used. The difficulties lie in the in-depth analysis of the co-channel interference mechanism in multi-beam satellite systems and the derivation of closed-form expressions of the CIR that are compatible with various application scenarios. The application scenarios include not only geostationary orbit satellites but also non-geostationary orbit (NGSO) satellites, especially direct-to-satellite IoT (DtS-IoT) applications. In reference [
17], the authors address massive MIMO in NGSO systems, which can substantially enhance spectral efficiency while bringing about inter-beam interference due to frequency reuse and the non-zero side lobes. In addition, the authors also emphasize the interference issue in waveform design, multiple access design, the co-existence of NGSO systems with other satellite systems and terrestrial networks, the emerging NGSO constellations, the inter-satellite links, and so on. Consequently, as the authors indicate, the interference quantification/management/cancellation should be paid more attention. In reference [
18], the authors discuss the uplink transmission in the DtS-IoT whilst disregarding interference from other sources and focusing on the impact of terrestrial network interference on a satellite uplink transmission. As mentioned in this reference, it is quite possible to utilize shared frequency bands in areas where the terrestrial interference level is low enough. However, the terrestrial deployment over populated regions could drastically increase the uplink channel interference, which has to be addressed well. In reference [
19], the authors focus on the random-access protocol based on Aloha for the MAC layer in DtS-IoT networks and introduce an intelligent traffic load distribution strategy with low implementation complexity, wherein the interference issue is addressed by applying successive interference cancellation (SIC) at the receiver for removing all copies once one of the messages is successfully decoded. The authors of [
19] propose another traffic load distribution strategy based on successive convex approximation (SCA) in reference [
20] and subsequently handle the interference between users in the same way. In reference [
21], considering the intermittent link availability between the end devices and the gateways, the authors propose a scheduling algorithm to ensure reliable communication and avoid packet drops/collisions. As discussed in [
21], the communication between the end devices and the gateways is based on a spread spectrum modulation at the physical layer, and the importance of the interference issue lies in affecting the selection of the spreading factor, which suffers from a trade-off between the resulting bit rate, the transmission range, and the energy required to transmit. In reference [
22], the authors focused on designing sparse constellations for the DtS-IoT with as few in-orbit DtS-IoT satellites as possible while guaranteeing the services. As mentioned, users’ access to the radio channel is scheduled with a trade-off between mitigating interference and signaling traffic, which is consistent with the above references.
It is worth noting that more and more studies are being carried out to deal with co-channel interference. For example, satellite communication coding optimization design based on large frequency multiplexing factor and precoding technology can obviously eliminate the co-channel interference [
23], which is especially suitable for full frequency multiplexing in the future. In addition, new communication schemes, such as the coded-beam high-throughput satellite system [
24], are being investigated to avoid spectrum reuses and co-channel interference. However, the quantification of the CIR in current high-throughput satellite systems is still of great significance.
Aimed at the problem of dominant co-channel interference in multi-beam systems, this paper proposes a quantification method of the CIR for user uplink and downlink in multi-beam HTS systems, and the closed-form expressions are given. Furthermore, the influencing factors and selection strategies of the CIR are expounded. Finally, the feasibility of the proposed quantification method is verified through simulation.
The contribution of this paper is two-fold: first, a quantification method of the CIR for user uplink and downlink in multi-beam HTS systems is proposed; second, through numerical simulation, the effects of the frequency plan and PSD on the CIR are presented.
The remainder of the paper is organized as follows:
Section 2 shows the model of the multi-beam HTS systems. In
Section 3, a quantification method for the CIR is proposed with closed-form expressions. The influencing factors and selection strategies of the CIR are expounded in
Section 4. In
Section 5 and
Section 6, the simulation results and discussion are presented. Finally,
Section 7 concludes the paper.
2. System Model
The HTS communication system consists of a space segment that includes the satellite constellation, a ground segment including gateway (GW) stations and large ground facilities for control, network operations, and backhauling, and a user segment with the user terminals deployed on fixed and mobile platforms (e.g., airplanes and ships) [
25], as shown in
Figure 2.
The space segment adopts the bent-pipe repeater, and the repeater is divided into the forward link and the return link. The forward link is from the ground gateway to the satellite and then to the ground users. The return link is just the opposite. According to the targeted object, the repeater can also be divided into the user link and the feeder link. The user link refers to the link between the satellite and the ground users, which can be further divided into the user uplink and user downlink. The feeder link refers to the link between the satellite and the ground gateway, which can be further divided into the feeder uplink and feeder downlink. The system utilizes the Ka band or the Q/V band as the communication frequency of feeder links and the Ka or Ku band for user links.
The common model for frequency reuse in high-throughput satellite systems is as follows [
26]. The allocated bandwidth to a satellite,
, is first sliced into sub-bands, typically two or three. A guard band is necessary between the adjacent sub-bands. Then, right-hand or both right- and left-hand polarization are used with the sub-bands. Each sub-band and polarization type constitutes a color (see
Figure 3). Then, each color is assigned to a spot beam, and
Figure 4 shows the four-color reuse scheme among all the beams. Furthermore, as long as the colors do not overlap, they can be reused in separate spot beams as many times as needed/possible (subject to various constraints including the antenna size, power limitation, pointing accuracy, and the system CIR discussed in this paper).
Based on the frequency reuse scheme, the total bandwidth in the system can be calculated as follows:
where
is the number of polarization (1 or 2),
is the number of colors,
is the number of beams, and
is the guard band relative to the bandwidth of a single channel (typically 5% to 10%). For example, a 2.5 GHz allocated bandwidth can translate into 112.5 GHz total bandwidth for the satellite when allocated to 4 colors with 2 polarizations and 100 spot beams (
for a 10% guard scheme).
The common model for the link budget in such systems is as follows.
The propagation distance in free space can be obtained by:
where
is the propagation distance in free space specified in meters;
is the earth radius specified in meters;
is the minimum distance between the satellite and the Earth’s surface and the unit is also in meters;
and
are the longitudes of the satellite and the Earth station, respectively, in degrees; and
,
are the latitudes of the satellite and the Earth station, respectively, in degrees.
The propagation loss can be calculated by:
where
is the propagation loss in free space specified in decibels and
is the working wavelength specified in meters.
The effective isotropic radiated power of transmitting antennas can be calculated by:
where
is the effective isotropic radiated power specified in dBW,
is the transmitting power specified in dBW,
is the feeder loss at the transmitter and the unit is in decibels, and
is the gain of the transmitting antenna specified in dBi.
The receiver’s figure of merit can be obtained by:
where
is the receiver’s figure of merit specified in dB/K,
is the gain of the receiving antenna specified in dBi,
is the output noise temperature of the antenna specified in K,
is the feeder loss at the receiver and the unit is in decibels,
is the feeder temperature specified in K, and
is the effective input noise temperature of the receiver specified in K.
The carrier-to-noise ratio (CNR) of the uplink and downlink can be then obtained, respectively:
where
and
are the CNRs of the uplink and downlink, respectively, specified in decibels;
and
are the effective isotropic radiated power of the earth station (or the terminal) and the satellite, respectively, specified in dBW;
and
are the propagation losses in the free space of the uplink and downlink, respectively, specified in decibels;
and
are the additional losses (including atmospheric absorption, pointing error, and polarization loss) of the uplink and downlink, respectively, specified in decibels;
and
are the figures of merit of the satellite and the Earth station (or the terminal), respectively, specified in dB/K;
is the Boltzmann’s constant; and
is the receiver’s bandwidth specified in Hz.
Based on the CNR of the uplink and downlink,
and
, the total CNR of the entire link,
, for a conventional frequency translation satellite, can be approached as follows [
13].
,
, and
are all specified in decibels.
By combining the total CNR,
, and the system CIR,
, which is just our research focus in this paper, we can obtain the carrier-to-interference-plus-noise ratio
[
13]:
followed by the ratio of the signal power per bit to noise power spectrum
:
where
is the information transmission rate specified in bps.
Based on , we can derive the available highest-level modulation coding mode and then the system capacity. Through the whole derivation process, we can conclude the importance of for the system capacity budget.
3. Quantification Method of CIR
The system CIR refers to the power ratio of the carrier signal to the sum of interference signals. As for the calculation of the satellite system CIR, the CIRs of the forward uplink (i.e., feeder uplink), forward downlink (i.e., user downlink), return uplink (i.e., user uplink), and return downlink (i.e., feeder downlink) should be comprehensively considered. The details are as follows:
where
is the carrier power and
is the interference signal power,
,
,
,
,
, and
refer to the CIR of the forward uplink, forward downlink, return uplink, return downlink, the entire forward link, and return link, respectively.
In this paper, the uplink interference and downlink interference are discussed. The quantification method of user’s uplink interference and downlink interference (corresponding to return uplink and forward downlink) is expounded. Due to the same principle, feeder uplink interference and feeder downlink interference (corresponding to the forward uplink and return downlink) can be quantified in a similar way. Moreover, the number and location of the ground gateways are deterministic, making it easier to handle the feeder link. Based on the above results, the system CIR can be obtained according to Equations (11) and (12).
Next, we will discuss the quantification method of the CIR for user uplink and downlink.
3.1. User Uplink
The schematic diagram of co-channel interference in the user uplink is shown in
Figure 5. The green continuous line represents the uplink of the useful signal, intended as the one from the actual user location to the satellite. The green dotted line represents the connection between the center of the cell that targets the user and the satellite. The red continuous line represents the uplink of the
i-th interference signal; the red dotted line represents the connection between the center of the cell, where the
i-th interfering user is located, and the satellite;
represents the terminal transmitting power of the target user;
represents the terminal antenna transmitting gain of the target user;
represents the path loss of the uplink of the useful signal;
represents the deviation angle of the uplink of the useful signal from its own cell center;
represents the on-board antenna receiving gain function for the uplink of the useful signal;
represents the terminal transmitting power of the
i-th interfering user;
represents the terminal antenna transmitting gain of the
i-th interfering user;
represents the path loss of the uplink of the
i-th interfering user;
represents the deviation angle of the uplink of the
i-th interfering signal from its own cell center;
represents the on-board antenna receiving gain function for the uplink of the
i-th interfering signal; and
represents the deviation angle of the uplink of the
i-th interfering signal from the center of the cell that targets the user.
The CIR of the uplink for the target user is (without special instructions, the interference in the following section refers to the co-channel interference):
where
is the power of the
i-th interference signal received on the satellite and
is the power of the useful signal received on the satellite.
Since uplink power control (UPC) is often adopted in HTS systems, the differences due to terminal transmitting power, terminal antenna gain, and path loss in different uplinks will be compensated. Finally, the signal powers received by the satellite from different terminals are uniform, namely:
Substituting Equation (14) into Equation (13), we can obtain:
It can be seen that uplink interference occurs when the signal transmitted by the interfering user falls into the on-board receiving antenna for the target user. With the participation of the UPC, the CIR of the uplink is not related to the position of the target user but rather only to the positions of interfering users.
3.2. User Downlink
The schematic diagram of co-channel interference in the user downlink is shown in
Figure 6. The green continuous line represents the downlink of the useful signal. The green dotted line represents the connection between the center of the cell, where the target user is located, and the satellite. The red continuous line represents the downlink of the
i-th interference signal; the red dotted line represents the connection between the center of the cell, where the
i-th interfering user is located, and the satellite;
represents the on-board transmitting power to the target user;
represents the path loss of the downlink of the useful signal;
represents the deviation angle of the downlink of the useful signal from its own cell center;
represents the on-board antenna transmitting gain function for the downlink of the useful signal;
represents the on-board transmitting power to the
i-th interfering user;
represents the path loss of the downlink of the
i-th interfering user;
represents the deviation angle of the downlink of the
i-th interfering signal from its own cell center;
represents the on-board antenna transmitting gain function for the downlink of the
i-th interfering signal; and
represents the deviation angle of the downlink of the useful signal from the cell center of the
i-th interfering user.
The CIR of the downlink for the target user is:
where
is the power of the
i-th interference signal received by the target user and
is the power of the useful signal received by the target user.
In the downlink, due to the same propagation path of the useful signal and interference signals,
L1 can be eliminated in Equation (16) and then we have:
It can be seen that the interference mechanism in the downlink is different from that in the uplink. The downlink interference at the user’s receiver comes from beams pointed at other users. Thus, the interference occurs when these spurious signals fall into the receiving antenna of the target user. Therefore, the CIR of the downlink for the target user is not related to the positions of the interfering users but instead only to the position of the target user.
3.3. Multi-Carrier Scenarios
The above general quantification method of the CIR is based on the assumption that there is only one continuous frequency band in each beam. For very-high-throughput satellite (VHTS) communication systems, the frequency bands within each beam may not be continuous, and the two multiplexed beams do not belong to the absolute same color. The quantification method can be improved adaptively as follows.
Each sub-carrier is treated as a “beam”. It is worth noting that the possible area where users are located for each sub-carrier within the same beam is the same, that is, the entire beam area. In order to help understand this conclusion better, we illustrate the equivalent representation of an interfering beam with multi-carriers in
Figure 7.
In
Figure 7, the green line, which points to a beam with a yellow color, represents the useful signal for the target user. The transmitting power and the frequency band of the useful signal are denoted as
and
, respectively. The other beams with a yellow color are interferers naturally. As mentioned above, the interfering power is the sum of that coming from every interfering beam, i.e.,
. However, in multi-carrier scenarios, it should be emphasized that beams with the same color do not occupy the identical frequency band, although their frequency bands overlap to a certain degree. That is to say, part of the transmitting power of an interfering beam, although not all, will cause the interference in the beam where the target user is located. Taking the i-th interfering beam for example, as shown in
Figure 7, we denote the transmitting power, the total bandwidth, and the number of carriers in this beam as
,
, and
, respectively. Specifically, the frequency band of the j-th carrier (
) is denoted as
in a generic way. It is easy to conclude that:
If there are no guard bands between the frequency bands of these carriers, then . It is worth noting that there is no difference in the spatial orientation among all the carriers. Each carrier can serve a user located at any position belonging to the beam area. Therefore, a carrier can be modelled as a virtual beam, and an interfering real beam with multi-carriers can be modelled as the addition of multiple virtual beams. As a result, the interference coming from the i-th interfering beam is equal to the sum of the contribution of all the virtual beams: .
The transmitting power of the j-th virtual beam (
) is denoted as
, and
. Furthermore, because the multi-carriers in a real beam shall share the same travelling wave tube amplifier (TWTA), the power spectral density (PSD) of them are equal, i.e., the transmitting power of each carrier, or each virtual beam, is proportional to its own bandwidth. Hence,
can be calculated by:
Furthermore, a fraction of
would create an interference in the target beam and the proportion depends on the overlapping of
and
. Thus, the weighted power,
, would be:
As described in
Section 3.2, the interfering power coming from the
j-th virtual beam would be:
To summarize, in multi-carrier scenarios, Equation (17) should turn into:
In the same way, if the target beam also includes multi-carriers, and the total transmitting power and bandwidth are denoted as
and
, respectively, Equation (22) should turn into:
5. Analysis of the CIR under Different Frequency Plans
The adjustment of the frequency plan will directly affect the degree of interference between the co-channel beams. The variation in the interference degree will cause the variation in the CIR (and hence the carrier to interference and noise ratio, CINR), which will affect the system’s capacity.
This section takes 19 beams with 4-color reuse (single polarization) as an example. Assuming two different beam-to-color mapping schemes, namely, regular mapping and irregular mapping, are adopted, we analyze the user-link CIR of each beam under them, respectively, by using the quantization method described in
Section 3 and the statistical method described in
Section 4. Furthermore, it can provide an idea for our future exploration, namely, frequency planning optimization based on CIR optimization.
The two mapping schemes, regular mapping and irregular mapping, are shown in
Figure 10a,b, respectively. For regular mapping, the cell-center points of beams with the same color (except beam 1) always form a rectangular shape. Meanwhile, for irregular mapping, these points may form a parallelogram or a hexagon, not like in regular mapping with a rectangular shape. In addition, an important difference between these two mapping schemes is that the minimum spacing between beams with the same color for regular mapping is smaller than that for the irregular one. Each color corresponds to a certain frequency band, that is, the beams with the same color shall share the same uplink/downlink frequency band, and the interferences will appear among them consequently. In this simulation, we assume a Ka-band HTS for illustrative purposes and the simulation conclusion is also applicable to the satellite systems using other frequency bands, such as Ku. Specifically, the red color represents the uplink frequency of 27,500–28,125 MHz and the downlink frequency of 17,700–18,325 MHz, as shown on beams 4/7/9/11/15/17 in
Figure 10a and beams 1/9/11/13/15/17/19 in
Figure 10b. The yellow color represents the uplink frequency of 28125-28750 MHz and the downlink frequency of 18,325–18,950 MHz, as shown on beams 2/6/12/14 in
Figure 10a and beams 2/5/12/18 in
Figure 10b, respectively. The green color represents the uplink frequency of 28,750–29,375 MHz and the downlink frequency of 18,950–19,575 MHz, as shown on beams 3/5/8/18 in
Figure 10a and beams 3/6/8/14 in
Figure 10b, respectively. The orange color represents the uplink frequency of 29,375–30,000 MHz and the downlink frequency of 19,575–20,200 MHz, as shown on beams 1/10/13/16/19 in
Figure 10a and beams 4/7/10/16 in
Figure 10b, respectively. It is worth noting that these frequency values are taken only as an example and can be replaced by other values according to the actual situation.
The −3 dB beamwidths of the 19 beams are all assumed to be 0.25°. UPC is considered for the uplink of each beam, and the output power of the downlink travelling wave tube (TWT) is 100 W. Moreover, the sub-satellite point (i.e., the intersection points of the line segment, from the satellite to the Earth’s core, and the Earth’s surface) is in beam 1. The gain function of the onboard user antenna is as follows [
13]:
where
refers to the deviation angle between the user link and antenna center,
, and
is specified in degrees.
, specified in dBi, is the antenna gain value when the deviation angle is
. Finally, 51.5 is the peak gain in dBi, and
is the −3 dB width of the beam in degree.
In the simulation, the locations of the target user and interfering users in their respective areas are randomly generated and repeated 1000 times to obtain the cumulative distribution function of user-link CIR in 19 beams under different schemes. Taking beam 1 as an example (the other beams are similar), we compare and illustrate the influence of the two schemes on the cumulative distribution function of the CIR, as shown in
Figure 11.
A point on any line in
Figure 11 has the following meaning. If the point coordinate is (x, y), it means that the number of CIR results lower than x in this 1000-times simulation is 1000 × y. For two comparative lines, if point A is on line 1, point B is on line 2, the horizontal coordinates of A and B are both equal to x, and the horizontal coordinates of A and B are y
1 and y
2 and y
1 < y
2, respectively, we can easily derive that the number of CIR results lower than x in this 1000-times simulation is 1000 × y
1 for line 1, while this value is 1000 × y
2 for line 2. It is evident that line 1 corresponds to a better scheme in terms of the CIR level. Hence, we can conclude that the lower line is better for the result shown in
Figure 11.
It can be seen from
Figure 11 that in 1000 simulation cases, for the user uplink of beam 1, the minimum CIR value under regular mapping is lower than 10 dB, while the minimum CIR value under irregular mapping is higher than 15 dB. Moreover, the corresponding maximum CIR values under the two schemes are similar. For the user downlink of beam 1, the minimum and maximum CIR values under regular mapping are lower than 11 dB and 24 dB, respectively, while the corresponding values under irregular mapping are higher than 15 dB and 28 dB. Specifically, with 20 dB as the reference value, the probability of meeting the reference value under regular mapping and irregular mapping is about 60% and 80%, respectively, regardless of the user uplink or downlink in beam 1. Therefore, irregular mapping is significantly better than regular mapping in terms of beam 1. In order to comprehensively consider all 19 beams, the CIR values satisfying the requirements of 100% coverage and 85% coverage are taken as the reference to compare the two schemes for all beams. The CIR of the user uplink and downlink are shown in
Table 1 and
Table 2, respectively. In order to show the comparison effect more clearly, bar charts comparing the CIR of the user uplink and downlink for all beams with the 85% coverage requirement (the other coverage requirements are similar) are formed, as shown in
Figure 12a,b, respectively.
It can be seen from
Table 1 and
Figure 12 that the CIR values of the user uplink and downlink obtained by irregular mapping are higher than those obtained by regular mapping in all of the beams, except for beam 13 and beam 19 whose values are highlighted in bold. In addition, irregular mapping can make the CIR of the user uplink or downlink more balanced for all of the beams. Specifically, as shown in
Figure 6, the variance in the user-uplink CIR in all beams obtained by regular mapping is 8.735, and the variance is 8.542 for user downlink. However, the variance in the user uplink CIR and user downlink CIR is only 1.393 and 1.805 under irregular mapping, respectively.
From the above simulation cases, it is obvious that the frequency plan has a significant impact on the CIR. In general, the larger the minimum spacing between the beams at the same frequency (maximizing the minimum spacing at the same frequency), the better the system’s CIR performance. Therefore, we can follow the above idea to explore the optimization scheme of the frequency plan based on the improvement of the CIR.
6. Analysis of the CIR under Different Power Spectral Density (PSD)
In this section, we conduct a simulation analysis of the CIR under different PSD. The number of beams, the beam layout, the −3 dB beamwidth of all the beams, and the gain function of the onboard user antenna are the same as those in
Section 4. In addition, the frequency plan adopts 4-color regular mapping, as shown in
Figure 10a. What is particular about this simulation setup is that the output power of downlink TWTs for all the beams are different. In detail, in order to cover more potential cases concerning how different PSD levels are distributed among the co-channel beams, the output power of downlink TWTs are set to 80 W, 100 W, 80 W, 60 W, 80 W, 100 W, 80 W, 80 W, 100 W, 100 W, 80 W, 100 W, 100 W, 100 W, 100 W, 100 W, 80 W, 80 W, and 100 W for beams 1~19, respectively. The PSD is obtained as a mean value for each TWT/transponder, i.e., power/bandwidth. It can be concluded that the PSD levels of all the beams are not the same due to their equal bandwidth and unequal transmit power.
The locations of the target user and interfering users in their respective areas are randomly generated and repeated 1000 times to obtain the cumulative distribution function of the user link CIR in 19 beams. Taking beam 1 as an example (the other beams are similar), we illustrate the cumulative distribution function of the CIR in
Figure 13, represented by a solid line. In order to present the comparative effect concerning different or uniform PSD, we also put the previous simulation result in
Figure 13, as shown as the dotted line, which is achieved in
Section 4 when assuming all of the downlink TWTs as 100 W.
It can be seen from
Figure 13a that the CIR levels are almost the same for the user uplink of beam 1, regardless of different or uniform PSD. The reason for this is that we set the different PSD by adjusting the output power of the downlink TWTs, while keeping the output power of user terminals unchanged. In other words, only the downlink’s PSD is varied. As shown in
Figure 13b, for the user downlink of beam 1, the CIR level under different PSD is evidently lower than that under uniform PSD. The reason is as follows. The user downlink PSD of beam 1, 80 W/(20,200–19,575) MHz, suffers from a significant decrease compared to that under uniform PSD, 100 W/(20,200–19,575) MHz. Meanwhile, the user downlink PSD of beam 10/13/16/19, which shares the same frequency band as beam 1, remains unchanged. In other words, the carrier signal power of beam 1 decreases while the interference power remains constant.
In order to comprehensively conduct an analysis of all 19 beams, the CIR values satisfying the requirements of 100% coverage and 85% coverage are taken as the reference. Moreover, the CIR levels are almost the same for the user uplink regardless of different or uniform PSD, which is inferred from beam 1 to all the beams. Therefore, not paying useless attention to the user uplink, we only simulate the user downlink CIR of all the beams under both different and uniform PSD, as shown in
Table 3. In order to show the comparison effect under different and uniform PSD more clearly, bar charts illustrating the user downlink CIR of all beams with the 85% coverage requirement (the other coverage requirements are similar) are formed, as shown in
Figure 14.
It can be seen from
Table 3 and
Figure 14 that the size relation of user downlink CIR values under different PSD and uniform PSD is uncertain among the 19 beams. In particular, for co-channel beam group 1 (beams 1, 10, 13, 16, and 19), the user downlink CIR level of beam 1 under different PSD is lower than that under uniform PSD, which has been explained before; the user downlink CIR level of beams 10/13/16/19 under different PSD is higher than that under uniform PSD because their downlink PSD levels remain unchanged while the interference power coming from beam 1 decreases evidently. For co-channel beam group 2 (beams 2, 6, 12, and 14), the simulation results change very weakly under different PSD compared to uniform PSD, due to the unchanged PSD of beams 2/6/12/14. For co-channel beam group 3 (beams 3, 5, 8, and 18), the simulation results also change weakly because the carrier signal power and interference power decrease at almost the same level for any beam therein. For co-channel beam group 4 (beams 4, 7, 9, 11, 15, and 17), the situations are diverse. The user downlink CIR level of beam 4 decreases significantly under different PSD compared to uniform PSD because beam 4 suffers from a significantly downward carrier signal power while it benefits from downward interference power slightly. The user downlink CIR level of beams 9/15 experiences an increase under different PSD compared to uniform PSD due to the unchanged carrier signal power and downward interference power. The user downlink CIR level of beams 7/11/17 shows an uncertain and slight change under different PSD compared to uniform PSD. It depends on which one of the carrier signal power and interference power decreases more, although neither of them decreases significantly.
Furthermore, we can conclude the importance of the estimation of the CIR with PSD, which accords with our method very well, for satellite operators, especially in the present day’s flexible payload applications. Flexible payload architectures can support configurable power, bandwidth, and/or coverage, which provides operators with flexibilities but also challenges. For example, in order to change the in-orbit capacity of one beam according to real-time demand, the operator can reallocate the channel power among several beams. However, it will affect the PSD of beams, and then yield variation in the beam’s CIR, which can even lead to link interruption. Therefore, the operators will be overcautious during the power allocation. Our work is so meaningful in that it provides operators with prediction of beams’ CIR after power allocation and helps them to find a possible allocation scheme guaranteeing the level of beams’ CIR.