JPH01286635A - Moving body satellite communicating system - Google Patents

Abstract

PURPOSE:To reduce energy consumption by making a frequency band used as a control line necessarily minimum, and effectively using the frequency band in the control line in the moving body satellite communicating system using the multi-beam communicating satellite mounted with a multi-terminal electronic amplifier. CONSTITUTION:The input circuit of a multi-terminal electronic amplifier 5 is equipped with a distributor 6 to distribute received signals from a base station 1, filters 7a-7e to select frequencies, and frequency converters 8a-8e. In a movable link, the frequency band used as the control line is shared between plural spot beams, the signal of the downward control line is made into a burst signal, and the control line is allotted by time-division to the plural beams according to the traffic quantities between the plural beams. The upward control line is constituted so that a random access may be commonly executed not at every beam but at every plural beams, and the frequency band used as the control line is suppressed to the necessarily minimum.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a satellite relay system mounted on a communication satellite for communication between one or a small number of base stations and a large number of mobile stations moving on land or on the sea. Used in mobile wireless communication systems that relay connections between devices.

In particular, the satellite is equipped with a multi-terminal power amplifier that receives the received signal from the base station as input, and the multiple outputs of this multi-terminal power amplifier are transmitted as multiple spot beams, each directed to a different zone on Earth. Regarding the method.

The present invention relates to two-way communication performed between a base station and a mobile station via a satellite relay device mounted on a communication satellite, in which transmission is performed from the satellite relay device to the mobile station under control from the base station. It concerns the control line frequency of the control signal and the use of that control line.

[Conventional technology]

FIG. 3 is a diagram showing a general system configuration example of the mobile satellite communication system of the present invention. This communication method uses one base station
, a large number of mobile stations 2 , and a satellite relay device 3 that is mounted on a satellite and relays radio signals transmitted between the base station 1 and the mobile stations 2 . a multi-terminal power amplifier 5 which inputs a received signal from the multi-terminal power amplifier 5, and means for forming a plurality of spot beams directed to different zones on the earth by connecting a plurality of outputs of the multi-terminal power amplifier 5, respectively. It is a method.

The input circuit of the multi-terminal power amplifier 5 includes a distributor 6 that distributes the received signal from the base station 1, and filter filters 1es and frequency converters 8a to 8e that select frequencies.

Furthermore, in FIG. 3, the satellite relay device 3 is equipped with antenna couplers 4 and 9a to 9e in addition to the system for transmitting and relaying downlink signals from the base station 1 to the mobile station 2 as described above. Regarding the system of uplink signals transmitted from to the wireless base station 1, amplifiers 101 to 10e and frequency converters 111 to 11
A relay system including e1 filters 12a to 11e1 and a combiner 13 is provided. This upstream signal relay system is a known random access system. The multi-terminal power amplifier 5 has the property that signals input to each input terminal are output only to the corresponding output terminals. Although the multi-terminal power amplifier 5 has many other features, it is disclosed in Japanese Patent Application No. 59-200959 (Japanese Unexamined Patent Publication No. 61-7-7 filed by the present applicant).
8213 Publication) and the paper "Multi-terminal power combining type multi-beam transmission system" (Transactions of the Institute of Electronics and Communication Engineers (B), J6
9-B.

k2 PF206-212.1986), detailed explanation here will be omitted.

The signal from the wireless base station 1 passes through the distributor 6 in the communication satellite and is input to filters 7a to 7e, and after determining the input terminal to the multi-terminal power amplifier 5 according to the input frequency band, frequency conversion is performed. Frequency conversion is performed by the devices 8a to 8e so that the frequency bands on the mobile links are the same. The outputs of the frequency converters 8a to 8e are input to the multiterminal power amplifier 5.

FIG. 4 shows the frequency arrangement of the feeder link transmitted from the antenna of the radio base station 1. Figure 5 shows satellite relay device 4.
transmitted from the transmitting antenna.

The frequency allocation of mobile links is shown. The frequencies F1 to Fs (bandwidth is F) of the feeder links are frequency converted on the satellite, and the frequencies usable by each beam of the mobile link become the same frequency band with a bandwidth F.

FIG. 6 is a control signal configuration diagram according to a conventional seat line configuration method. An example of the configuration of the control signal in the downstream direction is shown in (a), and an example of the configuration of the control signal in the upstream direction is shown in (5). Figure 6(a)
The downlink control line shown in 1 is a TDM signal, and is composed of a synchronization word 14 for creating a frame, and downlink control data 15 for zone identification and call control. 6th
The upstream control signal shown in Figure (b) is the well-known pure ALOHASslotted ALOHA
It is a burst signal for performing random access such as, and is composed of a preamble 16 used for synchronization of modulators, etc., and uplink control data 17 for zone registration and call control. These control lines are provided independently for each zone, and up and down control signals within a certain beam are valid for mobile stations within the zone covered by that beam.

Therefore, in this conventional configuration, the frequency arrangement shown in FIG. 7 is used to avoid interference between adjacent zones (particularly in the downlink). FIG. 7 is a frequency allocation diagram of a mobile link according to a conventional example. The frequency bandwidth of one communication line is Δ
f, and the frequency bandwidth F of the mobile link is NXΔf (N is a positive integer). In FIG. 7, reference numeral 18. ~18s indicates a frequency band used as a control line in each zone among all frequency bands of the mobile link. Here, the frequency band of the control line required for one zone is assumed to be MXΔf. Therefore, the frequency bandwidth required for the control line is 5XMXΔf. Further, symbols 198 to 19e indicate frequency bands that can be used as communication lines in each zone.

Its bandwidth is (N-5xM)xΔf. Note that, similarly to the control line, the same frequency cannot be used simultaneously in different zones for communication lines to avoid interference.

[Problem that the invention seeks to solve]

When a multi-terminal power amplifier is used as a repeater onboard a multi-beam satellite, the power within the satellite can be freely divided between multiple beams, and all frequency bands F can be allocated to any beam. Therefore, it is possible to flexibly deal with traffic fluctuations between zones. If a conventional control line configuration method is used for such a system, it is necessary to provide a control line band MXΔf for all beams, which is required when all communication lines are concentrated on one beam, and it is necessary to provide a control line band MXΔf for all beams. The frequency band provided for the control line in the zone is wasted.

In addition, as shown in FIG. 6(a), since the downlink control line is for continuous transmission, it is not preferable to provide a control line in every zone because it wastes power within the satellite.

An object of the present invention is to eliminate these problems and provide a mobile band satellite communication system that can effectively utilize the frequency band used for the control line and the power within the satellite.

[Means for solving problems]

The main features of the present invention for achieving the above object are that, in a mobile link, the frequency band used as a control line is shared among a plurality of spot beams, and the signal of the control line in the downlink direction is a burst signal; The purpose is to time-divisionally allocate control lines to multiple beams according to the amount of traffic between the beams. In addition, the control line in the upstream direction is configured to perform random access not for each beam, but for common random access among the plurality of beams, so that the frequency band used as the control line is kept to the minimum necessary.

[Effect]

According to the present invention, the frequency band and satellite power required for the control line can be saved, so under the same conditions (frequency band, power within the satellite), mobile terminals with a larger subscriber capacity than the conventional control line configuration can A satellite communication system can be constructed.

〔Example〕

FIG. 1 is a time chart of a control line configuration according to an embodiment of the present invention. FIG. 2 is a frequency allocation diagram of a control line moving link according to an embodiment of the present invention.

Here, a case will be described in which the number of beams is five as in the description of the prior art, but the number of beams does not limit the present invention in any way.

FIG. 1(a) shows the signal configuration of the downlink control line.

Figure 1 et al.) shows the signal structure in the upstream direction. Figure 4(a)
Reference numerals 20a to 20e are signal formats of control lines time-divisionally allocated to zones A to E, and each downlink control line 20a to 20e includes one or more unit data 21. The unit data 21 is composed of a preamble 22 including a synchronization word, and downlink control unit data 23 for zone identification and call control.

In this example, a case is illustrated in which the ratio of the number of mobile stations in zones A to E is approximately 2:2:1:1:3, and the control lines 20a to 20 are assigned to zones A to E as control lines.
The number of unit data in Oe matches this. Normally, when performing mobile communication in a multi-zone configuration, location registration is performed in order to efficiently control incoming calls. Therefore, the ratio of the number of mobile stations in multiple zones can be known from the number of mobile stations whose locations have been registered.

In addition, in this embodiment, the nine unit data 21 are cyclically allocated to zones A to E, but the structure of the unit data 21, the number of unit data 21, the allocation method, the allocation cycle, etc. depend on the system. Better to be optimized.

The structure of the uplink control signal shown in FIG. 1(b) is equivalent to the structure of the uplink control signal according to the conventional control line structure. This includes a preamble 16 and uplink control data 17.

FIG. 2 shows the mobile link frequency allocation in this case. Second
In the figure, symbols 25a to 25e indicate frequency bands used as control lines, which are shared by zones A to E.

Therefore, compared to the conventional method, only 115 frequency bands are required. Reference numerals 26a to 26e indicate frequency bands that can be used as communication lines in this case. As is clear from this figure, according to the present invention, the frequency band used for the control line can be saved and the band for the communication line can be increased. In this example, the bandwidth of the communication line is (N-M)XΔf.

〔Effect of the invention〕

As explained above, in the control line of a mobile satellite communication system using a multi-beam communication satellite equipped with a multi-terminal power amplifier, the frequency band used as the control line can be minimized. can be used effectively. Additionally, power consumption within the satellite can be reduced.

This makes it possible to construct a multi-beam mobile satellite communication system with a larger subscriber capacity with the same frequency allocation and the same power compared to the conventional control line configuration.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a time chart of a control line configuration according to an embodiment of the present invention. FIG. 2 is a frequency allocation diagram of a mobile link according to a control line configuration according to an embodiment of the present invention. FIG. 3 is a block diagram of a mobile satellite communication system using a multi-beam communication satellite equipped with a multi-terminal power amplifier. FIG. 4 is a frequency allocation diagram of feeder links. FIG. 5 is a frequency allocation diagram of mobile links. FIG. 6 is a side view of a control signal configuration based on a conventional control line configuration. FIG. 7 is a frequency allocation diagram of a mobile link according to a conventional control line configuration. 1... Wireless base station, 2... Mobile station, 3a to 3e...
・Spot beam from multi-beam communication satellite, 4...
・Antenna coupler, 5...Multi-terminal power amplifier, 6...
・Distributor, 7a-7e...Filter of input circuit of multi-terminal power amplifier, 8a-8e...Frequency converter, 9a-
9e...Antenna coupler, 10a-10e...Amplifier, lla-lie...Frequency converter, 12a-12
e...Upstream output circuit filter, 13...Synthesizer,
14... Synchronization word, 15... Downlink control data, 16.
...Preamble, 17...Uplink control data, 18a
~18e...Frequency band used as a control line in each zone among all frequency bands of the mobile link, 19a
~19e... Frequency band usable as a communication line in each zone, 20a~20e... Control line allocated to zones A to E in a time-sharing manner, 21...
・Unit data, 22...Preamble, 23...
- Downlink control unit data, 25a to 25e... Frequency band used as a control line, 26a to 26e... Frequency band usable as a communication line. Patent Applicant Nippon Telegraph and Telephone Corporation Agent Patent Attorney Nao Ide Takashi Feederson 7Rat number arrangement 7F14 Oral transfer p')n7@'11, *Ik! , x shoulder 5 mouth

Claims (1)

[Claims] 1. One or a small number of base stations, a large number of mobile stations, and a satellite relay device that is mounted on a satellite and relays radio signals transmitted between the base station and the mobile stations. The satellite relay device includes a multi-terminal power amplifier receiving a received signal from the base station as an input, and a plurality of outputs of the multi-terminal power amplifier connected to each other and directed to different zones on the earth. A mobile satellite communication system including means for forming spot beams, wherein a frequency common to the plurality of spot beams is used as a frequency of a control line transmitted from the satellite relay device to the mobile station under the control of the base station. A frequency is set, and the base station includes means for time-sharingly allocating this common frequency to the plurality of spot beams, and means for changing this allocation according to the traffic of each spot beam. A mobile satellite communication system characterized by: