JP2017011578A - Satellite communication system, small earth station and power consumption reduction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a satellite communication system, a small earth station and a power consumption reduction method, capable of suppressing battery power consumption while securing a band.SOLUTION: The satellite communication system includes a transmitter unit and an operation mode control unit. After a channel to be used for communication between each of a plurality of small earth stations which perform communication using a satellite is established, the transmitter unit transmits, to an opposite small earth station which performs communication using the line, information related to an operation mode associated with the small earth station, among a plurality of operation modes to reduce power consumption. Based on the information related to the operation mode transmitted from another small earth station, the operation mode control unit sets the operation mode of the self-device to be the operation mode indicated by the information, so as to control the operation of a function unit, provided in the self-device, according to the set operation mode.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to a satellite communication system, a small earth station, and a power consumption reduction method.

  In the satellite communication system, communication is performed between a plurality of satellite portable VSAT (Very Small Aperture Terminal) stations (hereinafter referred to as “small earth stations”) installed on the ground via an artificial satellite. Therefore, the satellite communication system is a relatively economical system when performing communication between long distances or between mountainous areas. In addition, the satellite communication system is used in a disaster prevention system of a local government or a backup line of a company as a communication system that is strong against a disaster such as an earthquake because the relay station is not on the ground.

  Since the small earth station is an effective means for communication at the disaster site, it may be used at the disaster site. When the small earth station is used in a place where a stable power supply is not expected, such as a disaster site, the small earth station operates only with a battery provided in its own device. In such a case, if the supply from the battery is exhausted, communication between small earth stations cannot be performed. Normally, line connection between small earth stations in a satellite communication system, bandwidth allocation, and the like are performed by a control station that manages the satellite communication system.

  The operating time differs between a small earth station operating on a battery and a small earth station with a stable power supply. For this reason, if the control station uniformly allocates the bandwidth to all the small earth stations that have requested the line, the communication time of the small earth station operating on the battery is shortened depending on the remaining amount of the battery. In addition, including such a case, if the band allocated to all the small earth stations is limited, the operation limit of the small earth station that has a secured power source and requires a band becomes large. In order to prevent such a problem, it is only necessary to dynamically change the band allocated in accordance with the operation status of each small earth station in the control station, but there is a possibility that control and processing of the control station may become complicated. .

Japanese Patent Laid-Open No. 06-13955 Japanese Patent No. 5428695 JP 2013-201501 A JP-A-10-150396 JP 2009-89052 A JP 2014-72560 A

  The problem to be solved by the present invention is to provide a satellite communication system, a small earth station, and a power consumption reduction method capable of suppressing the power consumption of a battery while securing a band.

  The satellite communication system according to the embodiment includes a transmission unit and an operation mode control unit. The transmitter is configured such that, after a line used for communication between a plurality of small earth stations performing communication via a satellite is established, power consumption is reduced with respect to the opposing small earth station performing the communication using the line. Information on the operation mode corresponding to the small-sized earth station among a plurality of operation modes for reducing. The operation mode control unit sets the operation mode of the own device to the operation mode indicated by the information based on the information regarding the operation mode transmitted from another small earth station, and the own device according to the set operation mode. Controls the operation of the functional units included in the.

1 is a system configuration diagram of a satellite communication system 100 according to a first embodiment. 1 is a schematic block diagram showing a functional configuration of a small earth station 10 in a first embodiment. The figure which shows the specific example of the operation mode table in 1st Embodiment. The figure which shows the specific example of the mode information table according to small earth station. 4 is a sequence diagram showing an operation for changing an operation mode in the satellite communication system 100. FIG. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10-1 in 1st Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10-2 in 1st Embodiment. The schematic block diagram showing the function structure of the small earth station 10a in 2nd Embodiment. The internal block diagram of the power amplification part 104a. The figure which shows the specific example of the operation mode table in 2nd Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10a-1 in 2nd Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10a-2 in 2nd Embodiment. The schematic block diagram showing the functional composition of small earth station 10b in a 3rd embodiment. The internal block diagram of the power amplification part 104b. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10b-1 in 3rd Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10b-2 in 3rd Embodiment. The schematic block diagram showing the functional structure of the small earth station 10c in 4th Embodiment. The figure which shows the specific example of the operation mode table in 4th Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10c-1 in 4th Embodiment. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10c-2 in 4th Embodiment. The system block diagram of the satellite communication system 100d in 5th Embodiment. The schematic block diagram showing the functional composition of small earth station 10d in a 5th embodiment. The figure which shows the specific example of the bandwidth request list classified by destination. The flowchart which shows the flow of the setting process of the operation mode of the small earth station 10d-1 in 5th Embodiment. The schematic block diagram showing the functional structure of the interface part 108 among the functional structures of the small earth station 10e in 6th Embodiment. The schematic block diagram showing the function structure of the setting terminal 40f in 7th Embodiment. The flowchart which shows the flow of the setting process for setting the operation mode of each small earth station.

Hereinafter, a satellite communication system, a small earth station, and a power consumption reduction method of an embodiment will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a system configuration diagram of a satellite communication system 100 according to the first embodiment.
The satellite communication system 100 includes a plurality of small earth stations 10-1 to 10-2, a satellite 20, a control station 30, and a setting terminal 40. The small earth station 10-1 is connected to the intra-station network 50-1. The small earth station 10-2 is connected to the intra-station network 50-2. Each of the small earth station 10-1, the small earth station 10-2, and the control station 30 communicate with each other via the satellite 20. A setting terminal 40 is connected to the intra-station network 50-1.
The satellite communication system 100 constitutes a subsystem 60 including a plurality of small earth stations 10, an intra-station network 50 to which each of the plurality of small earth stations 10 is connected, and a setting terminal 40. A plurality of subsystems 60 exist in the satellite communication system 100. In the following description, the small earth stations 10-1 and 10-2 will be referred to as the small earth station 10 unless otherwise distinguished. In the following description, the intra-station networks 50-1 and 50-2 will be referred to as the intra-station network 50 unless otherwise distinguished.

  The small earth station 10 is a device that uses a parabona antenna with a very small diameter among base stations that receive radio waves used in satellite communications on the ground. The small earth station 10 may be a stationary earth station or a portable earth station. The small earth station 10 communicates with other small earth stations 10 and the control station 30 via the satellite 20. The small earth station 10 communicates with the setting terminal 40. Based on the request for changing the operation mode of the small earth station 10 (hereinafter referred to as “operation mode change request”) output from the setting terminal 40, the small earth station 10 performs an operation mode change instruction (hereinafter referred to as “operation mode change request”). , “Operation mode change instruction”) is transmitted to the opposing small earth station 10. In the operation mode change request, identification information (hereinafter referred to as “mode ID”) for identifying an operation mode to be set in the small earth station 10 and destination information (for example, a MAC address) of the opposing small earth station 10 ) And Based on the operation mode change instruction, the small earth station 10 sets its own operation mode to the operation mode included in the operation mode change instruction. The operation mode is a mode for reducing power consumption.

The satellite 20 relays communication between the small earth stations 10. The satellite 20 relays communication between the small earth station 10 and the control station 30.
The control station 30 establishes a line between the small earth stations 10 by performing bandwidth allocation and channel allocation in response to a request from the small earth station 10.
The setting terminal 40 is configured using an information processing apparatus such as a personal computer. The setting terminal 40 transmits an operation mode change request to the small earth station 10-1 according to a user operation.
The intra-station network 50 may be a network configured in any way. The intra-office network 50 is, for example, an intra-office IP (Internet Protocol) network or a telephone exchange network.

FIG. 2 is a schematic block diagram showing a functional configuration of the small earth station 10 in the first embodiment. The small earth stations 10-1 and 10-2 have the same configuration and will be described as the small earth station 10.
The small earth station 10 includes an antenna 101, a low noise amplification unit 102, a frequency conversion unit 103, a power amplification unit 104, a combining / distributing unit 105, and a modem unit 106 (106-1 to 106-N: N is an integer of 4 or more), A line control unit 107, an interface unit 108 (108-1 to 108- (N-1)), an operation mode interface unit 109, an operation mode control unit 110, and a battery 111 are provided.

The antenna 101 (transmission unit) transmits and receives signals. For example, the antenna 101 transmits an operation mode change instruction to the opposing small earth station 10 via the satellite 20. The antenna 101 receives an operation mode change instruction transmitted from another small earth station 10 via the satellite 20.
The low noise amplification unit 102 amplifies a signal received via the antenna 101.
The frequency conversion unit 103 down-converts the amplified signal. The frequency conversion unit 103 up-converts the signal output from the combining / distributing unit 105.
The power amplifying unit 104 amplifies the power of the up-converted signal.

The combining / distributing unit 105 combines or distributes signals.
The modem unit 106 demodulates the signal output from the combining / distributing unit 105. The modem unit 106 modulates data to be transmitted input via the interface unit 108. The modem unit 106-1 demodulates the signal transmitted from the control station 30. The modem unit 106-2 demodulates a signal for simultaneous command that notifies an emergency situation. Modulators / demodulators 106-3 to 106-N demodulate signals for general lines. Here, the signal for the general line is a signal transmitted from another small earth station 10 or a signal transmitted from a device in the intra-station network 50.
The line control unit 107 establishes a control line with the control station 30.

The interface unit 108 is a communication interface with other devices. For example, the interface unit 108-1 transmits a simultaneous command to devices in the intra-station network 50-1. In addition, for example, the interface units 108-2 to 108-(N−1) perform signal transmission / reception with devices in the intra-station network 50-1.
The operation mode interface unit 109 acquires the operation mode change instruction received by the antenna 101 via the interface unit 108. The operation mode interface unit 109 receives the operation mode change request output from the setting terminal 40 and outputs it to the operation mode control unit 110.

The operation mode control unit 110 controls the operation of each functional unit according to the operation mode of the own device. Specifically, the operation mode control unit 110 controls the operation of the modem unit 106 according to the operation mode. The operation mode control unit 110 stores an operation mode table and a small earth station mode information table. The operation mode table is composed of records (hereinafter referred to as “operation mode records”) representing information related to operation modes. The mode information table for each small earth station is configured by a record (hereinafter, referred to as “mode information record for each small earth station”) representing information regarding an operation mode to be operated for each small earth station 10.
The battery 111 supplies the stored electric power to each functional unit included in the small earth station 10.

FIG. 3 is a diagram illustrating a specific example of the operation mode table in the first embodiment.
The operation mode table has a plurality of operation mode records 51. The operation mode record 51 has a mode ID, a communication speed in a band per channel, the number of modulation / demodulation unit operations, and each value of the modulation / demodulation unit to be operated. The value of the mode ID represents identification information for identifying an operation mode to be set by the small earth station 10. The value of the communication speed in the band per channel represents the communication speed in the band per channel required when the small earth station 10 sets the operation mode identified by the mode ID of the same operation mode record 51. The value of the number of modulation / demodulation unit operations represents the number of modulation / demodulation units to be operated when the small earth station 10 is set to the operation mode identified by the mode ID of the same operation mode record 51. The value of the modem unit to be operated represents the modem unit to be operated when the small earth station 10 is set to the operation mode identified by the mode ID of the same operation mode record 51.

  In the example shown in FIG. 3, a plurality of mode IDs are registered in the operation mode table. These mode IDs are “1”, “2”, and “3”. In FIG. 3, the operation mode record 51 registered at the top of the operation mode table has a mode ID value of “1”, a communication speed value in a band per channel of “32 kbps (bit per second)”, and modulation / demodulation. The value of the number of partial operations is “2”, and the value of the modulation / demodulation unit to be operated is “any one of the third to n-th modulation / demodulation units and the first modulation / demodulation unit” (n is an integer of 4 or more). In other words, the modulation / demodulation that is operated when the operation mode is set when the operation mode identified by the mode ID “1” is set to the small earth station 10 and the communication speed in the band per channel is “32 kbps”. It is shown that the number of units is “2”, and two modulation / demodulation units to be operated are “one of the third to n-th modulation / demodulation units and the first modulation / demodulation unit”.

  In FIG. 3, the operation mode record 51 registered in the second row of the operation mode table has a mode ID value of “2”, a communication speed value in a band per channel of “32 kbps”, and a modem operation. The value of the number is “3”, and the value of the modulation / demodulation unit to be operated is “any one of the third to n-th modulation / demodulation units, the first modulation / demodulation unit, and the second modulation / demodulation unit”. That is, the modulation / demodulation that is operated when the operation mode is set when the operation mode identified by the mode ID “2” is set to the small earth station 10 and the communication speed in the band per channel is “32 kbps”. The number of parts is “3”, and the modulation / demodulation unit to be operated is represented as “one of the third to n-th modulation / demodulation units, the first modulation / demodulation unit, and the second modulation / demodulation unit”. Yes.

  In FIG. 3, the operation mode record 51 registered in the third row of the operation mode table has a mode ID value “3”, a communication speed value in a band per channel “8 Mbps”, and a modem operation. The value of the number is “4 to n”, and the value of the modulation / demodulation unit to be operated is “two or more of the third to n-th modulation / demodulation units, the first modulation / demodulation unit, and the second modulation / demodulation unit”. That is, the modulation / demodulation that is operated when the operation mode is set when the operation mode identified by the mode ID “3” is set to the small earth station 10 and the communication speed in the bandwidth per channel is “8 Mbps”. The number of units is “4 to n”, and the number of modulation / demodulation units to be operated is 4 to n units of “two or more of the third to nth modulation / demodulation units, the first modulation / demodulation unit, and the second modulation / demodulation unit”. It is expressed that there is.

  As described above, the small earth station 10 in which the operation mode identified by the mode ID “1” is set includes any one of the third to n-th modulation / demodulation units and the two modulation / demodulation units 106 in total. To work. At this time, the small earth station 10 stops other modulation / demodulation units. More specifically, the small earth station 10 in which the operation mode identified by the mode ID “1” is set is any one of the modems 106-3 to 106-N used for communication for general lines. Then, the modem unit 106-1 used for communication with the control station 30 is operated.

  The small earth station 10 in which the operation mode identified by the mode ID “2” is set has three modulation / demodulation units in total, including any one of the third to n-th modulation / demodulation units, the first modulation / demodulation unit, and the second modulation / demodulation unit. 106 is operated. At this time, the small earth station 10 stops other modulation / demodulation units. More specifically, the small earth station 10 in which the operation mode identified by the mode ID “2” is set is any one of the modems 106-3 to 106-N used for general line communication. The modulation / demodulation unit 106-2 used for simultaneous command communication and the modulation / demodulation unit 106-1 used for communication with the control station 30 are operated.

The small earth station 10 in which the operation mode identified by the mode ID “3” is set has a total of four of any two or more of the third to n-th modem units, the first modem unit, and the second modem unit. The modem unit 106 is operated. More specifically, the small earth station 10 in which the operation mode identified by the mode ID “3” is set is any two of the modulation / demodulation units 106-3 to 106-N used for general line communication. As described above, the modem unit 106-2 used for simultaneous command communication and the modem unit 106-1 used for communication with the control station 30 are operated.
As described above, the small earth station 10 controls the operation of the modem unit 106 according to the operation mode of its own device. Of the above-mentioned mode IDs, the mode ID “1” has the lowest power consumption, and the mode ID “3” has the highest power consumption.

FIG. 4 is a diagram showing a specific example of the mode information table for each small earth station.
The small earth station mode information table includes a plurality of small earth station mode information records 52. The small earth station mode information record 52 has values of mode ID and small earth station ID. The value of the mode ID represents identification information for identifying an operation mode to be set by the small earth station 10. The value of the small earth station ID represents identification information for identifying the small earth station 10 that sets the operation mode identified by the mode ID of the same small earth station mode information record 52. For example, the value of the small earth station ID may be the MAC address of the small earth station 10 or any information that can identify the small earth station 10.

  In the example shown in FIG. 4, one mode ID is registered in the mode information table for each small earth station. This mode ID is “1”. In FIG. 4, the mode information record 52 for each small earth station registered at the top of the mode information table for each small earth station has a mode ID value “1” and a small earth station ID value “aaa”. . That is, the identification information of the small earth station 10 that sets the operation mode identified by the mode ID “1” is “aaa”.

FIG. 5 is a sequence diagram showing an operation for changing the operation mode in the satellite communication system 100. In FIG. 5, the case where there are two small earth stations 10 (small earth station 10-1 and small earth station 10-2) will be described as an example.
The setting terminal 40 transmits an operation mode change request to the small earth station 10-1 according to the user's operation (step S101). This operation mode change request includes the mode ID and the destination information of the small earth station 10-2. The small earth station 10-1 requests the control station 30 for a line corresponding to the band corresponding to the operation mode set by the small earth station 10-2 (step S102). Specifically, the small earth station 10-1 refers to the stored small earth station mode information table, and from the small earth station mode information record 52 corresponding to the destination information included in the operation mode change request. Get the value of mode ID. Next, the small earth station 10-1 refers to the operation mode table and acquires each value of the communication speed and the number of modulation / demodulation unit operations in the band per channel from the operation mode record 51 corresponding to the acquired mode ID. Then, the small earth station 10-1 generates a line request including the communication speed and the number of modem operations in the band per channel. This line request includes destination information of the small earth station 10-2 with which the small earth station 10-1 communicates.
The control station 30 assigns ch to the small earth station 10-1 and the small earth station 10-2 in response to a request from the small earth station 10-1 (step S103 and step S104). Then, the control station 30 establishes a line for the requested bandwidth (step S105).

When the line is established, the small earth station 10-1 transmits an operation mode change instruction to the small earth station 10-2 via the satellite 20 using the established line (step S106). The operation mode change instruction includes a mode ID.
The small earth station 10-2 receives the operation mode change instruction transmitted from the small earth station 10-1. The small earth station 10-2 transmits, via the satellite 20, a response to whether or not the received operation mode change instruction is accepted (hereinafter referred to as “mode change availability response”) to the small earth station 10-1 (step S107). . Specifically, the small earth station 10-2 determines whether or not the own apparatus can operate in the operation mode identified by the mode ID included in the operation mode change instruction. When the own apparatus is operable in the operation mode identified by the mode ID included in the operation mode change instruction, the satellite 20 sends a mode change availability response (OK) indicating that the small earth station 10-2 is operable. Is transmitted to the small earth station 10-1.
On the other hand, when the self-device cannot operate in the operation mode identified by the mode ID included in the operation mode change instruction, a mode change enable / disable response (NG) indicating that the small earth station 10-2 cannot operate. Is transmitted to the small earth station 10-1 via the satellite 20. In FIG. 5, a case where the small earth station 10-2 is operable will be described as an example.

  The small earth station 10-1 receives the mode change availability response transmitted from the small earth station 10-2. Since the small earth station 10-1 indicates that the mode change availability response is operable, the small earth station 10-1 transmits an operation mode change execution instruction to the small earth station 10-2 via the satellite 20 (step S108). The operation mode change execution instruction is an instruction for causing another small earth station 10 facing the small earth station 10 to set the operation mode.

  The small earth station 10-2 receives the operation mode change execution instruction transmitted from the small earth station 10-1. The small earth station 10-2 sets the operation mode identified by the mode ID included in the operation mode change instruction received in the process of step S106 as the operation mode of its own device. When the setting of the operation mode is completed, the small earth station 10-2 generates an instruction indicating that the setting of the operation mode is completed (hereinafter referred to as “operation mode change end instruction”), and the generated operation mode change end instruction is generated. Is transmitted to the small earth station 10-1 via the satellite 20 (step S109).

  Further, after transmitting the operation mode change execution instruction to the small earth station 10-2, the small earth station 10-1 changes the operation mode same as the operation mode changed by the small earth station 10-2 to its own operation mode. Set to. Thereafter, the small earth station 10-1 receives the operation mode change end instruction transmitted from the small earth station 10-2. The small earth station 10-1 operates between the small earth stations 10 after confirming that the setting of the operation mode of the own device has been completed and that the operation mode change end instruction has been received from the small earth station 10-2. A notification (hereinafter referred to as “operation mode change end notification”) indicating that the mode setting has been completed is generated. Then, the small earth station 10-1 transmits the generated operation mode change end notification to the setting terminal 40 (step S110). Note that after the operation mode is set, communication of each small earth station 10 is performed in the set operation mode.

  Thereafter, communication is performed between the small earth station 10-1 and the small earth station 10-2 (step S111). When communication is completed between the small earth station 10-1 and the small earth station 10-2, the small earth station 10-1 transmits a line open instruction to the small earth station 10-2 via the satellite 20 (step). S112). When the small earth station 10-2 receives an instruction to open a line from the small earth station 10-1, the small earth station 10-2 notifies the fact that the line used for communication with the small earth station 10-1 is to be released via the satellite 20. 30 (step S113). Further, the small earth station 10-1 transmits to the control station 30 via the satellite 20 that the line used for communication with the small earth station 10-2 is opened (step S114). Thereafter, the control station 30 opens the line used for communication between the small earth station 10-1 and the small earth station 10-2. Note that the process of step S111 is not necessarily executed.

  FIG. 6 is a flowchart showing the flow of processing for setting the operation mode of the small earth station 10-1 in the first embodiment. The process of FIG. 6 is started after an operation mode change request is received from the setting terminal 40. Also, description will be made assuming that the destination information included in the operation mode change request indicates the small earth station 10-2. In FIG. 6, communication between the small earth station 10-1 and the small earth station 10-2 will be described, and description of communication between the small earth station 10-1 and the control station 30 will be omitted.

  The operation mode interface unit 109 of the small earth station 10-1 outputs the received operation mode change request to the operation mode control unit 110. The received operation mode change instruction is sent to the operation mode control unit via the low noise amplification unit 102, the frequency conversion unit 103, the combining / distributing unit 105, the modem unit 106-1, the line control unit 107, and the operation mode interface unit 109. 110 is output. When the line is established based on the operation mode change request, the operation mode control unit 110 generates an operation mode change instruction (step S201). Then, the operation mode control unit 110 transmits the generated operation mode change instruction to the small earth station 10-2 (step S202). Specifically, the operation mode control unit 110 sends the generated operation mode change instruction to the operation mode interface unit 109, the interface unit 108, the modem unit 106, the combining / distributing unit 105, the power amplifying unit 104, the antenna 101, and the satellite 20. To the small earth station 10-2.

  The operation mode control unit 110 determines whether or not a mode change availability response indicating that the operation mode can be set is received from the small earth station 10 to which the operation mode change request is transmitted in the process of step S202 (step S203). ). When the mode change availability response indicating that the operation mode can be set is received (step S203—YES), the operation mode control unit 110 transmits an operation mode change execution instruction to the small earth station 10-2 (step S204). ). Thereafter, the operation mode control unit 110 sets the operation mode of the device itself to the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202 (step S205).

The antenna 101 receives an operation mode change end instruction from the small earth station 10-2 (step S206). The operation mode control unit 110 transmits an operation mode change end notification to the small earth station 10-2 (step S207).
In the process of step S203, when a mode change availability response indicating that the operation mode cannot be set is received (NO in step S203), the operation mode control unit 110 sends a different operation mode change instruction to the small earth station. 10-2 (step S208). Here, the different operation mode change instruction is an instruction including a mode ID different from the mode ID included in the operation mode change instruction transmitted in the process of step S202. For example, the different operation mode change instruction includes a mode ID of an operation mode having a smaller number of modem operations than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202. At this time, if there is no operation mode in which the number of modulation / demodulation unit operations is smaller than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202, the small earth station 10-1 is the small earth station. The station 10-2 may terminate the process because communication is impossible.

FIG. 7 is a flowchart showing a flow of processing for setting the operation mode of the small earth station 10-2 in the first embodiment. 7 is started after the small earth station 10-2 receives the operation mode change instruction.
The operation mode control unit 110 confirms the stored operation mode table (step S301). Specifically, the operation mode control unit 110 confirms the operation mode record 51 corresponding to the mode ID included in the operation mode change instruction among the operation mode records 51 registered in the operation mode table. Then, as a result of the confirmation, the operation mode control unit 110 determines whether or not the own device can operate in the operation mode identified by the mode ID.

  When the operation is possible, the operation mode control unit 110 generates a mode change availability response indicating that the operation mode can be set. On the other hand, when the operation is impossible, the operation mode control unit 110 generates a mode change availability response indicating that the operation mode cannot be set. Then, the operation mode control unit 110 transmits the generated mode change availability response to the small earth station 10-1 (step S302). Specifically, the operation mode control unit 110 sends the generated mode change availability response to the operation mode interface unit 109, the interface unit 108, the modem unit 106, the combining / distributing unit 105, the power amplification unit 104, the antenna 101, and the satellite 20. To the small earth station 10-1. In FIG. 7, an example will be described in which the small earth station 10-2 transmits a mode change availability response indicating that the operation mode can be set.

  The antenna 101 receives the operation mode change execution instruction transmitted from the small earth station 10-1 (step S303). The received operation mode change execution instruction is output to the operation mode control unit 110 via the low noise amplification unit 102, the frequency conversion unit 103, the synthesis / distribution unit 105, the modulation / demodulation unit 106, the interface unit 108, and the operation mode interface unit 109. The The operation mode control unit 110 refers to the stored operation mode table and sets the operation mode indicated by the mode ID included in the operation mode change instruction to the operation mode of the own device (step S304). Specifically, the operation mode control unit 110 controls the operation of the modem unit 106 of its own device so that the operation mode indicated by the mode ID is obtained.

  For example, when the mode ID is “1”, the operation mode control unit 110 includes any one of the third to n-th modulation / demodulation units (modem / demodulation units 106-3 to 106-N) and the first modulation / demodulation unit (modem / demodulation unit 106- 1) and the other modems 106 are stopped. More specifically, when the modem unit 106 is separated as a module, the operation mode control unit 110 turns off and stops the power for each module. Also, when the modem unit 106 is configured on the same base or in an IC such as an FPGA (Field-Programmable Gate Array), the modem unit 106 is powered off and stopped for each block, or for operation. Stop supplying the clock. In this way, the operation mode control unit 110 sets the operation mode of the own device. When the setting of the operation mode is completed, the operation mode control unit 110 generates an instruction (hereinafter referred to as “operation mode change end instruction”) indicating that the setting of the operation mode has been completed. Then, the operation mode control unit 110 transmits the generated operation mode change end instruction to the small earth station 10-1 (step S305).

According to the satellite communication system 100 configured as described above, the power consumption of the battery can be suppressed while securing the band. Hereinafter, this effect will be described in detail.
In response to a request from the setting terminal 40, the small earth station 10 requests the control station 30 for a band to be used for communication with the other small earth station 10 facing the small earth station 10. Then, when the small earth station 10 can secure the band, the small earth station 10 notifies the other small earth station 10 that is opposed to the operation mode that the other small earth station 10 sets. Depending on the operation mode, the operation of the modem unit 106 is limited. Therefore, the small earth station 10 operating with the battery operating in such an operation mode does not have to operate the modem unit 106 that is not used. For this reason, it is possible to suppress the power consumption of the battery while securing the bandwidth. As a result, the operating time of the small earth station 10 can be extended.

The small earth station 10 that has notified the other small earth stations 10 of the operation mode also operates in the same operation mode as the other small earth stations 10. Therefore, the power consumption of the battery can be suppressed in the entire system.
Further, depending on the operation mode, the operation of the modem unit 106 is not limited. Furthermore, the communication speed in the band to be used is also faster than in the operation mode that suppresses power consumption. Therefore, there is no possibility that the operation of the small earth station 10 that has a secured power source and requires a band is limited. Therefore, it becomes possible to respond flexibly according to the situation.

A modification of the satellite communication system 100 in the first embodiment will be described.
In the present embodiment, the configuration is shown in which the operation mode control unit 110 controls only the modulation / demodulation unit 106 according to the operation mode of the own apparatus. However, the operation mode control unit 110 stops the modulation / demodulation unit 106 when it stops. The interface unit 108 corresponding to the above may be configured to stop together. With this configuration, it is possible to further reduce power consumption.

(Second Embodiment)
In the second embodiment, the small earth station controls the drain applied voltage in the power amplification unit according to the operation mode of its own device. Since the system configuration of the second embodiment is the same as that of the first embodiment, only the small earth station will be described.

FIG. 8 is a schematic block diagram showing a functional configuration of the small earth station 10a in the second embodiment.
The small earth station 10a includes an antenna 101, a low noise amplifying unit 102, a frequency converting unit 103, a power amplifying unit 104a, a combining / distributing unit 105, a modem unit 106 (106-1 to 106-N), a line control unit 107, and an interface unit. 108 (108-1 to 108- (N-1)), an operation mode interface unit 109, an operation mode control unit 110a, and a battery 111.

  The small earth station 10a according to the second embodiment is different in configuration from the small earth station 10 in that it includes a power amplification unit 104a and an operation mode control unit 110a instead of the power amplification unit 104 and the operation mode control unit 110. The small earth station 10a is the same as the small earth station 10 in other configurations. Therefore, description of the entire small earth station 10a is omitted, and only the power amplification unit 104a and the operation mode control unit 110a will be described.

The power amplification unit 104 a amplifies the power of the up-converted signal and transmits it to the satellite 20 via the antenna 101. FIG. 9 shows an internal configuration diagram of the power amplifying unit 104a.
FIG. 9 is an internal configuration diagram of the power amplifying unit 104a. Normally, the power amplifying unit 104a cascades the configuration shown in FIG. 9 in a plurality of stages and amplifies the up-converted signal to a predetermined power. However, in FIG. Show. As shown in FIG. 9, the power amplification unit 104 a includes a transistor 61, an input terminal 62, an output terminal 63, a drain power supply 64, and a gate power supply 65. As shown in FIG. 9, in the power amplifying unit 104a in the second embodiment, the drain power supply 64 is variable.

  The operation mode control unit 110a controls the operation of each functional unit according to the operation mode of the own device. Specifically, the operation mode control unit 110a controls the operation of the drain power supply 64 in the power amplification unit 104a according to the operation mode. The operation mode control unit 110a stores an operation mode table and a small earth station mode information table. The operation mode table is composed of operation mode records. The small earth station mode information table is composed of small earth station mode information records. The configuration of the mode information table for each small earth station in the second embodiment is the same as that of the mode information table for each small earth station shown in FIG.

FIG. 10 is a diagram illustrating a specific example of the operation mode table in the second embodiment.
The operation mode table in the second embodiment has a plurality of operation mode records 53. The operation mode record 53 has values of mode ID, communication speed and drain voltage in a band per channel. The value of the mode ID represents identification information for identifying the operation mode to be set in the small earth station 10a. The value of the communication speed in the band per channel represents the communication speed in the band per channel required when the small earth station 10a is set to the operation mode identified by the mode ID of the same operation mode record 53. The value of the drain voltage represents the voltage applied by the drain power supply 64 when the small earth station 10a is set to the operation mode identified by the mode ID of the same operation mode record 53.

  In the example shown in FIG. 10, a plurality of mode IDs are registered in the operation mode table. These mode IDs are “1”, “2”, and “3”. In FIG. 10, the operation mode record 53 registered at the top of the operation mode table has a mode ID value “1”, a communication speed value in a band per channel “32 kbps”, and a drain voltage value “ Va ″. That is, when the operation mode identified by the mode ID “1” is set in the small earth station 10a, the communication speed in the band per channel required is “32 kbps”, and the voltage applied by the drain power supply 64 is “Va”. It is expressed that.

  Also, in FIG. 10, the operation mode record 53 registered in the second row of the operation mode table has a mode ID value “2”, a communication speed value in a band per channel “64 kbps”, and a drain voltage The value is “Vb”. That is, when the operation mode identified by the mode ID “2” is set in the small earth station 10a, the communication speed in the band per channel required is “64 kbps”, and the voltage applied by the drain power supply 64 is “Vb”. It is expressed that.

  In FIG. 10, the operation mode record 53 registered in the third row of the operation mode table has a mode ID value “3”, a communication speed value in a band per channel “8 Mbps”, and a drain voltage value. The value is “Vc”. That is, when the operation mode identified by the mode ID “3” is set in the small earth station 10a, the communication speed in the band per channel required is “8 Mbps”, and the voltage applied by the drain power supply 64 is “Vc”. It is expressed that.

  Note that the relationship between the voltage values of the drain voltages Va, Vb, and Vc is Va <Vb <Vc. In the small earth station 10a, the power per unit band needs to be increased to a certain value. Therefore, it is necessary to set the maximum power of the output of the power amplification unit 104a higher as the bandwidth increases. Usually, since the maximum power of the power amplifying unit 104a is set in the maximum bandwidth, the output power may be small when the bandwidth is small. In order to secure the maximum power of the power amplifying unit 104a, it is necessary to increase the drain voltage. However, when the band is small, the drain voltage is relatively decreased, and even if the power consumption is reduced, the communication characteristics are affected. There is no. Therefore, in the second embodiment, the operation mode control unit 110a can reduce the power consumption of the power amplification unit 104a by controlling the voltage applied by the drain power supply 64 according to the operation mode as described above. In addition, the operating time when the battery 111 operates can be extended.

  FIG. 11 is a flowchart showing a flow of processing for setting the operation mode of the small earth station 10a-1 in the second embodiment. The process of FIG. 11 is started after the operation mode change request is received from the setting terminal 40. Also, description will be made assuming that the destination information included in the operation mode change request indicates the small earth station 10a-2. In FIG. 11, communication between the small earth station 10a-1 and the small earth station 10a-2 will be described, and description of communication between the small earth station 10a-1 and the control station 30 will be omitted. Also, the processing similar to that in FIG. 6 is denoted by the same reference numerals as those in FIG.

  When the process of step S204 ends, the operation mode control unit 110a sets the operation mode of the own apparatus to the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202 (step S401). ). Specifically, the operation mode control unit 110a controls the drain voltage applied to the drain terminal of the transistor 61 by the drain power supply 64 in the power amplification unit 104a of its own device so that the operation mode indicated by the mode ID is obtained. For example, when the mode ID is “1”, the operation mode control unit 110a controls the drain voltage applied by the drain power supply 64 to be Va. In this way, the operation mode control unit 110a sets the operation mode of the own device. Thereafter, the processing after step S206 is executed.

  In the process of step S203, when a mode change availability response indicating that the operation mode cannot be set is received (step S203—NO), the operation mode control unit 110a sends a different operation mode change instruction to the small earth station. 10a-2 (step S402). For example, the different operation mode change instruction includes a mode ID of an operation mode in which the voltage applied by the drain power supply 64 is lower than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202. It is. At this time, if there is no operation mode in which the voltage applied by the drain power supply 64 is lower than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202, the small earth station 10a-1 May terminate the process because the small earth station 10a-2 cannot communicate.

FIG. 12 is a flowchart showing a flow of processing for setting the operation mode of the small earth station 10a-2 in the second embodiment. The process of FIG. 12 is started after the small earth station 10a-2 receives the operation mode change instruction. Further, the processing similar to that in FIG. 7 is denoted by the same reference numerals as those in FIG. 7 in FIG.
When the process of step S303 ends, the operation mode control unit 110a refers to the stored operation mode table and sets the operation mode indicated by the mode ID included in the operation mode change instruction as the operation mode of the own device. (Step S501). Specifically, the operation mode control unit 110a controls the operation of the drain power supply 64 in the power amplification unit 104a so that the operation mode indicated by the mode ID is set. For example, when the mode ID is “1”, the operation mode control unit 110a controls the drain power supply 64 so that the voltage applied by the drain power supply 64 becomes Va.

According to the satellite communication system 100 configured as described above, the power consumption of the battery can be suppressed while securing the band. Hereinafter, this effect will be described in detail.
In response to a request from the setting terminal 40, the small earth station 10a requests the control station 30 for a band to be used for communication with the other small earth station 10a facing the small earth station 10a. Then, when the small earth station 10a can secure the band, the small earth station 10a notifies the other small earth station 10a facing the operation mode to be set in the other small earth station 10a. Depending on the operation mode, the drain applied voltage in the power amplifier 104a is limited. Therefore, the small earth station 10a operating with the battery operating in such an operation mode can suppress the power consumption of the power amplifying unit 104a. For this reason, it is possible to suppress the power consumption of the battery while securing the bandwidth. As a result, the operating time of the small earth station 10a can be extended.
The small earth station 10a that has notified the other small earth station 10a of the operation mode also operates in the same operation mode as the other small earth station 10a. Therefore, the power consumption of the battery can be suppressed in the entire system.

(Third embodiment)
In the third embodiment, the small earth station controls the gate applied voltage in the power amplification unit according to the operation mode of its own device. Since the system configuration of the third embodiment is the same as that of the first embodiment, only the small earth station will be described.

FIG. 13 is a schematic block diagram showing a functional configuration of the small earth station 10b in the third embodiment.
The small earth station 10b includes an antenna 101, a low noise amplifying unit 102, a frequency converting unit 103, a power amplifying unit 104b, a combining / distributing unit 105, a modem unit 106 (106-1 to 106-N), a line control unit 107, and an interface unit. 108 (108-1 to 108- (N-1)), an operation mode interface unit 109, an operation mode control unit 110b, and a battery 111.

  The small earth station 10b according to the third embodiment is different in configuration from the small earth station 10 in that it includes a power amplification unit 104b and an operation mode control unit 110b instead of the power amplification unit 104 and the operation mode control unit 110. The small earth station 10b is the same as the small earth station 10 in other configurations. Therefore, the description of the entire small earth station 10b is omitted, and the power amplification unit 104b and the operation mode control unit 110b will be described.

The power amplifying unit 104 b amplifies the power of the up-converted signal and transmits it to the satellite 20 via the antenna 101. FIG. 14 shows an internal configuration diagram of the power amplifying unit 104b.
FIG. 14 is an internal configuration diagram of the power amplifying unit 104b. Normally, the power amplifying unit 104b amplifies the up-converted signal to a predetermined power by cascading the configurations shown in FIG. 14 to a predetermined power level. However, in FIG. Show. The power amplifier 104b includes a transistor 66, an input terminal 67, an output terminal 68, a drain power supply 69, and a gate power supply 70 as shown in FIG. As shown in FIG. 14, in the power amplification unit 104b according to the third embodiment, the gate power supply 70 is variable.

  The operation of each functional unit is controlled according to the operation mode of the own device. Specifically, the operation mode control unit 110b controls the operation of the gate power supply 70 in the power amplification unit 104b according to the operation mode. The operation mode control unit 110b stores an operation mode table and a small earth station mode information table. The operation mode table is composed of operation mode records. The small earth station mode information table is composed of small earth station mode information records. The configuration of the operation mode table in the third embodiment is different from the operation mode table shown in FIG. 10 only in that the drain voltage item of the operation mode table shown in FIG. 10 is changed to the gate voltage. The value of the gate voltage represents the voltage applied by the gate power supply 70 when the small earth station 10a is set to the operation mode identified by the mode ID of the same operation mode record 53. The configuration of the mode information table for each small earth station in the third embodiment is the same as that of the mode information table for each small earth station shown in FIG.

  FIG. 15 is a flowchart showing the flow of processing for setting the operation mode of the small earth station 10b-1 in the third embodiment. The process of FIG. 15 is started after the operation mode change request is received from the setting terminal 40. Also, description will be made assuming that the destination information included in the operation mode change request indicates the small earth station 10b-2. In FIG. 15, communication between the small earth station 10b-1 and the small earth station 10b-2 will be described, and description of communication between the small earth station 10b-1 and the control station 30 will be omitted. Also, the processing similar to that in FIG. 6 is denoted by the same reference numerals as those in FIG.

  When the process of step S204 ends, the operation mode control unit 110b sets the operation mode of the own apparatus to the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202 (step S601). ). Specifically, the operation mode control unit 110b controls the gate voltage applied to the gate terminal of the transistor 66 by the gate power supply 70 in the power amplification unit 104b of its own device so that the operation mode indicated by the mode ID is obtained. For example, when the mode ID is “1”, the operation mode control unit 110b controls the gate voltage applied by the gate power supply 70 to be Va. In this way, the operation mode control unit 110b sets the operation mode of the own device. Thereafter, the processing after step S206 is executed.

  In the process of step S203, when a mode change availability response indicating that the operation mode cannot be set is received (step S203—NO), the operation mode control unit 110b sends a different operation mode change instruction to the small earth station. 10b-2 (step S602). For example, the different operation mode change instruction includes the mode ID of the operation mode in which the voltage applied by the gate power supply 70 is lower than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202. It is. At this time, if there is no operation mode in which the voltage applied by the gate power supply 70 is lower than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202, the small earth station 10b-1 May terminate the process because the small earth station 10b-2 cannot communicate.

FIG. 16 is a flowchart showing the flow of processing for setting the operation mode of the small earth station 10b-2 in the third embodiment. Note that the processing in FIG. 16 is started after the small earth station 10b-2 receives the operation mode change instruction. Also, the processing similar to that in FIG. 7 is denoted by the same reference numerals as those in FIG.
When the process of step S303 ends, the operation mode control unit 110b refers to the stored operation mode table and sets the operation mode indicated by the mode ID included in the operation mode change instruction as the operation mode of the own device. (Step S701). Specifically, the operation mode control unit 110b controls the operation of the gate power supply 70 in the power amplification unit 104b so that the operation mode indicated by the mode ID is set. For example, when the mode ID is “1”, the operation mode control unit 110b controls the gate power supply 70 so that the voltage applied by the gate power supply 70 becomes Va.

According to the satellite communication system 100 configured as described above, the power consumption of the battery can be suppressed while securing the band. Hereinafter, this effect will be described in detail.
In response to a request from the setting terminal 40, the small earth station 10b requests the control station 30 for a band to be used for communication with the other small earth station 10b facing the small earth station 10b. Then, when the small earth station 10b can secure the band, the small earth station 10b notifies the other small earth station 10b facing the operation mode to be set in the other small earth station 10b. Depending on the operation mode, the gate applied voltage in the power amplifier 104b is limited. Therefore, the small earth station 10b operating with the battery operating in such an operation mode can suppress the power consumption of the power amplifier 104b. For this reason, it is possible to suppress the power consumption of the battery while securing the bandwidth. As a result, the operating time of the small earth station 10b can be extended.
The small earth station 10b that has notified the other small earth station 10b of the operation mode also operates in the same operation mode as the other small earth station 10b. Therefore, the power consumption of the battery can be suppressed in the entire system.

(Fourth embodiment)
In the fourth embodiment, the small earth station controls the operations of the modem and the power amplifying unit according to the operation mode of its own device. Since the system configuration of the fourth embodiment is the same as that of the first embodiment, only the small earth station will be described.

FIG. 17 is a schematic block diagram showing a functional configuration of the small earth station 10c in the fourth embodiment.
The small earth station 10c includes an antenna 101, a low noise amplification unit 102, a frequency conversion unit 103, a power amplification unit 104c, a combining / distributing unit 105, a modem unit 106 (106-1 to 106-N), a line control unit 107, and an interface unit. 108 (108-1 to 108- (N-1)), an operation mode interface unit 109, an operation mode control unit 110c, and a battery 111.

  The small earth station 10c according to the fourth embodiment is different in configuration from the small earth station 10 in that it includes a power amplification unit 104c and an operation mode control unit 110c instead of the power amplification unit 104 and the operation mode control unit 110. The small earth station 10c is the same as the small earth station 10 in other configurations. Therefore, the description of the entire small earth station 10c is omitted, and the power amplification unit 104c and the operation mode control unit 110c will be described.

The power amplification unit 104 c amplifies the power of the up-converted signal and transmits it to the satellite 20 via the antenna 101. The internal configuration of the power amplification unit 104c is the same as that of the second embodiment. That is, in the power amplifying unit 104c, the drain power source 64 is variable.
The operation mode control unit 110c controls the operation of each functional unit according to the operation mode of the own device. Specifically, the operation mode control unit 110c controls the operation of the drain power supply 64 in the modem unit 106 and the power amplification unit 104c according to the operation mode. The operation mode control unit 110c stores an operation mode table and a small earth station mode information table. The configuration of the mode information table for each small earth station in the fourth embodiment is the same as the mode information table for each small earth station shown in FIG.

FIG. 18 is a diagram illustrating a specific example of an operation mode table according to the fourth embodiment.
The operation mode table in the fourth embodiment has a plurality of operation mode records 54. The operation mode record 54 has values of mode ID, communication speed in a band per channel, the number of modulation / demodulation unit operations, the modulation / demodulation unit to be operated, and the drain voltage. The description of each value is omitted because it has been described above.

  In the example shown in FIG. 18, a plurality of mode IDs are registered in the operation mode table. These mode IDs are “1”, “2”, and “3”. In FIG. 18, an operation mode record 54 registered at the top of the operation mode table has a mode ID value “1”, a communication speed value in a band per channel “32 kbps”, and a value of the number of modulation / demodulation unit operations. Is “2”, the value of the modulation / demodulation unit to be operated is “any one of the third to n-th modulation / demodulation units and the first modulation / demodulation unit”, and the value of the drain voltage is “Va”. That is, the modulation / demodulation that is operated when the operation mode is set when the operation mode identified by the mode ID “1” is “32 kbps” in the bandwidth per channel required when the small earth station 10 c is set. The number of units is “2”, the modulation / demodulation units to be operated are “one of the third to n-th modulation / demodulation units and the first modulation / demodulation unit”, and the drain power supply 64 in the power amplification unit 104c is applied. The voltage to be applied is “Va”.

  FIG. 19 is a flowchart showing a flow of processing for setting the operation mode of the small earth station 10c-1 in the fourth embodiment. The process in FIG. 19 is started after an operation mode change request is received from the setting terminal 40. Also, description will be made assuming that the destination information included in the operation mode change request indicates the small earth station 10c-2. In FIG. 15, communication between the small earth station 10 c-1 and the small earth station 10 c-2 is described, and a description of communication between the small earth station 10 c-1 and the control station 30 is omitted. Further, the processing similar to that in FIG. 6 is denoted by the same reference numerals as those in FIG.

  When the process of step S204 ends, the operation mode control unit 110c sets the operation mode of the own apparatus to the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202. In the present embodiment, since the operation mode control unit 110c controls the power amplification unit 104c and the modulation / demodulation unit 106, the operation setting in each will be described as a first operation setting and a second operation setting. First, the operation mode control unit 110c performs the first operation setting (step S801).

  Specifically, the operation mode control unit 110c controls the operation of the modem unit 106 of its own device so that the operation mode indicated by the mode ID is obtained. For example, when the mode ID is “1”, the operation mode control unit 110c includes any one of the third to n-th modulation / demodulation units (modem / demodulation units 106-3 to 106-N) and the first modulation / demodulation unit (modem / demodulation unit 106- 1) and the other modems 106 are stopped. Next, the operation mode control unit 110c performs the second operation setting (step S802). Specifically, the operation mode control unit 110 c controls the drain voltage applied to the drain terminal of the transistor 61 by the drain power supply 64 in the power amplification unit 104 c so that the operation mode indicated by the mode ID is set. For example, when the mode ID is “1”, the operation mode control unit 110 c controls the drain voltage applied by the drain power supply 64 to be Va. In this way, the operation mode control unit 110c sets the operation mode of the own device. Note that the processes of steps S801 and 802 may be performed simultaneously, or the process of step S801 may be performed after the process of step S802 is performed.

  In the process of step S203, when a mode change availability response indicating that the operation mode cannot be set is received (NO in step S203), the operation mode control unit 110c sends a different operation mode change instruction to the small earth station. 10c-2 (step S803). For example, in the different operation mode change instruction, the number of modulation / demodulation unit operations is smaller than the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202, and the voltage applied by the drain power supply 64 The mode ID of the operation mode with a small is included. At this time, there is an operation mode in which the number of modulation / demodulation unit operations is smaller than that of the operation mode identified by the mode ID included in the operation mode change instruction transmitted in the process of step S202 and the voltage applied by the drain power supply 64 is small. If there is not, the small earth station 10c-1 may end the processing because the small earth station 10c-2 cannot communicate.

FIG. 20 is a flowchart showing the flow of processing for setting the operation mode of the small earth station 10c-2 in the fourth embodiment. The process in FIG. 20 is started after the small earth station 10c-2 receives the operation mode change instruction. In addition, about the process similar to FIG. 7, the code | symbol similar to FIG. 7 is attached | subjected in FIG. 20, and description is abbreviate | omitted.
When the process of step S303 ends, the operation mode control unit 110c refers to the stored operation mode table and sets the operation mode indicated by the mode ID included in the operation mode change instruction as the operation mode of the own device. . In the present embodiment, since the operation mode control unit 110c controls the power amplification unit 104c and the modulation / demodulation unit 106, the operation setting in each will be described as a first operation setting and a second operation setting. First, the operation mode control unit 110c performs the first operation setting (step S901).
Specifically, the operation mode control unit 110c controls the operation of the modem unit 106 so that the operation mode indicated by the mode ID is obtained. Next, the operation mode control unit 110c performs the second operation setting (step S902). Specifically, the operation mode control unit 110c controls the operation of the drain power supply 64 in the power amplification unit 104c so that the operation mode indicated by the mode ID is set.

According to the satellite communication system 100 configured as described above, the power consumption of the battery can be suppressed while securing the band. Hereinafter, this effect will be described in detail.
In response to a request from the setting terminal 40, the small earth station 10c requests the control station 30 for a band to be used for communication with the other small earth station 10c facing the small earth station 10c. Then, when the small earth station 10c can secure the band, the small earth station 10c notifies the other small earth station 10c facing the operation mode to be set in the other small earth station 10c. Depending on the operation mode, the operation limitation of the modem unit 106 and the drain applied voltage in the power amplifier unit 104c are limited. Therefore, the small earth station 10c operating with the battery operating in such an operation mode can suppress the power consumption of the modulation / demodulation unit 106 not used and the power consumption of the power amplification unit 104a. For this reason, it is possible to suppress the power consumption of the battery while securing the bandwidth. As a result, the operating time of the small earth station 10c can be extended.

The small earth station 10c that has notified the other small earth station 10c of the operation mode also operates in the same operation mode as the other small earth station 10c. Therefore, the power consumption of the battery can be suppressed in the entire system.
Further, depending on the operation mode, the operation of the modem unit 106 is not limited. Furthermore, the communication speed in the band to be used is also faster than in the operation mode that suppresses power consumption. Therefore, there is no possibility that the operation of the small earth station 10c that has a secured power source and requires a band is limited. Therefore, it becomes possible to respond flexibly according to the situation.

A modification of the satellite communication system 100 in the fourth embodiment will be described.
In the fourth embodiment, the configuration in which the small earth station 10c controls the drain applied voltage in the modulation / demodulation unit 106 and the power amplification unit 104c according to the operation mode of the own device has been described. Accordingly, the gate applied voltage in the modem unit 106 and the power amplifier unit 104c may be controlled. The process for controlling the gate applied voltage is the same as that in the third embodiment, and thus the description thereof is omitted.

(Fifth embodiment)
FIG. 21 is a system configuration diagram of a satellite communication system 100d according to the fifth embodiment.
The satellite communication system 100d includes a plurality of small earth stations 10d-1 to 10d-M (M is an integer of 3 or more), a satellite 20, a control station 30, and a setting terminal 40. The small earth station 10d-1 is connected to the intra-station network 50-1. The small earth station 10d-2 is connected to the intra-station network 50-2. The small earth station 10d-M is connected to the intra-station network 50-M. Each of the small earth stations 10 d-1 to 10 -M and the control station 30 communicate with each other via the satellite 20. A setting terminal 40 is connected to the intra-station network 50-1.

  The satellite communication system 100d constitutes a subsystem 60d including a plurality of small earth stations 10d, an intra-station network 50 to which each of the plurality of small earth stations 10d is connected, and a setting terminal 40. A plurality of subsystems 60d exist in the satellite communication system 100d. In the following description, small earth stations 10d-1 to 10d-M are described as small earth stations 10d unless otherwise distinguished. In the following description, the intra-station networks 50-1 to 50-M will be referred to as the intra-station network 50 unless otherwise distinguished.

  In the case of 1 to M as in the fifth embodiment, there is a case where it is desired to increase the transmission band even if the operation time is somewhat shortened depending on the situation of the small earth station 10d facing. In this case, for the small earth stations 10d facing M different bands, the small earth station 10d-1 needs to make an appropriate bandwidth request to the control station 30 at the time of line connection. In the fifth embodiment, a configuration for realizing such a configuration will be described.

FIG. 22 is a schematic block diagram illustrating a functional configuration of the small earth station 10d according to the fifth embodiment.
The small earth station 10d includes an antenna 101, a low noise amplification unit 102, a frequency conversion unit 103, a power amplification unit 104, a combining / distributing unit 105, a modulation / demodulation unit 106 (106-1 to 106-N), a line control unit 107d, and an interface unit. 108d (108d-1 to 108d- (N-1)), an operation mode interface unit 109, an operation mode control unit 110, and a battery 111.

  The small earth station 10d in the fifth embodiment is different in configuration from the small earth station 10 in that a line control unit 107d and an interface unit 108d are provided instead of the line control unit 107 and the interface unit 108. The small earth station 10d is the same as the small earth station 10 in other configurations. Therefore, the description of the entire small earth station 10d is omitted, and only the line control unit 107d and the interface unit 108d will be described.

  The interface unit 108d is a communication interface with other devices. For example, the interface unit 108d-1 transmits a simultaneous command to devices in the intra-station network 50d-1. Further, for example, the interface units 108d-2 to 108d- (N-1) perform signal transmission / reception with devices in the intra-station network 50-1. When a message (for example, a packet) is input from the intra-station network 50, the interface unit 108d makes a line request to the line control unit 107d.

The line control unit 107d establishes a control line with the control station 30. In addition, the line control unit 107d makes a bandwidth allocation request to the control station 30 in response to a request from the interface unit 108d. The line control unit 107d includes a destination-specific bandwidth request list unit 1071d.
The band request list for each destination 1071d writes the communication speed in the band set at the time of setting the operation mode and the identification information (small earth station ID) of the small earth station 10d facing to the band request list for each destination. When the line request is received from each interface unit 108d, the line control unit 107d checks the destination-specific bandwidth request list, and for the small earth station 10d registered in the destination-specific bandwidth request list, the bandwidth by destination. The control station 30 is requested for the communication speed in the band with priority given to the contents of the request list. On the other hand, the line control unit 107d requests the control station 30 for the communication speed in the band as requested by the interface unit 108d for the small earth station 10d not registered in the destination-specific band request list.

FIG. 23 is a diagram showing a specific example of the destination-specific bandwidth request list.
The destination-specific bandwidth request list includes a plurality of records 55. The record 55 has each value of the partner station, the mode ID, the communication speed in the band per channel, the number of modulation / demodulation unit operations and the modulation / demodulation unit to be operated. The value of the partner station represents identification information for identifying the small earth station 10d. The value of the mode ID represents identification information for identifying the operation mode to be set in the small earth station 10d. The value of the communication speed in the band per channel represents the communication speed in the band per channel required when the small earth station 10d is set to the operation mode identified by the mode ID of the same record 55. The value of the number of modulation / demodulation unit operations represents the number of modulation / demodulation units to be operated when the small earth station 10d is set to the operation mode identified by the mode ID of the same record 55. The value of the modem unit to be operated represents the modem unit to be operated when the small earth station 10d is set to the operation mode identified by the mode ID of the same record 55.

FIG. 24 is a flowchart showing a flow of processing for setting an operation mode of the small earth station 10d-1 in the fifth embodiment. The process of FIG. 24 is started after the operation mode change request is received from the setting terminal 40. 24, communication between the small earth station 10d-1 and the small earth station 10d-M will be described, and description of communication between the small earth station 10d-1 and the control station 30 will be omitted. Further, the processing similar to that in FIG. 6 is denoted by the same reference numerals as those in FIG.
When the processing of step S204 is completed, the destination-specific bandwidth request list unit 1071 changes the destination-specific bandwidth request list (step S1001).
According to the satellite communication system 100d configured as described above, the power consumption of the battery can be suppressed while securing the band. Hereinafter, this effect will be described in detail.
In response to a request from the setting terminal 40, the small earth station 10d requests the control station 30 for a band to be used for communication with the other small earth station 10d facing the small earth station 10d. At this time, the small earth station 10d requests a bandwidth from the control station 30 with reference to information on the communication speed in the requested band for each small earth station 10d. Therefore, an appropriate band can be requested for each small earth station 10d. Then, when the small earth station 10d can secure the band, the small earth station 10d notifies the other small earth station 10d facing the operation mode to be set in the other small earth station 10d. Depending on the operation mode, the operation of the modem unit 106 is limited. Therefore, the small earth station 10d operating with the battery operating in such an operation mode does not need to operate the modem unit 106 that is not used. For this reason, it is possible to suppress the power consumption of the battery while securing the bandwidth. As a result, the operating time of the small earth station 10d can be extended.

In addition, the small earth station 10d that has notified the other small earth station 10d of the operation mode also operates in the same operation mode as the other small earth station 10d. Therefore, the power consumption of the battery can be suppressed in the entire system.
Further, depending on the operation mode, the operation of the modem unit 106 is not limited. Furthermore, the communication speed in the band to be used is also faster than in the operation mode that suppresses power consumption. Therefore, there is no possibility that the operation of the small earth station 10d that has a secured power source and requires a band is limited. Therefore, it becomes possible to respond flexibly according to the situation.

Hereinafter, a modification of the satellite communication system 100d in the fifth embodiment will be described.
In the present embodiment, the exchange between the small earth station 10d-1 and the small earth stations 10d-2 to 10d-M facing each other has been described. However, communication is performed between the small earth stations 10d-2 to 10d-M. It may be called. In such a case, the small-sized earth station 10d-1 to 10d-M is transmitted by the small-sized earth station 10d-1 to the small-sized earth stations 10d-2 to 10d-M every time the content is changed. The same request list by destination can be held between M. As a result, connection between the small earth stations 10d-2 to 10d-M becomes possible.

(Sixth embodiment)
In the sixth embodiment, priority is provided to processing in an interface unit in a small earth station. Specifically, it is necessary to limit the state where the communication speed in the transmission band is limited to 32 kbps to only important communication. In particular, voice communication and facsimile communication according to voice are highly urgent. The interface unit can be connected to other lines such as a voice line, an Ethernet (registered trademark) line, and RS-485. Therefore, the interface unit sets a priority among the above-described lines and operates according to the priority. Since the system configuration of the sixth embodiment is the same as that of the fifth embodiment, only the small earth station will be described.

  FIG. 25 is a schematic block diagram illustrating a functional configuration of the interface unit 108 among the functional configurations of the small earth station 10e according to the sixth embodiment. The configuration other than the interface unit 108e of the small earth station 10e is the same as that of any one of the first to fifth embodiments.

As shown in FIG. 25, the interface unit 108e includes a voice line adapter unit 1081, an Ethernet (registered trademark) adapter unit 1082, another adapter unit 1083, and a priority selection unit 1084.
The voice line adapter unit 1081 is connected to a voice line used for telephone or fax.
The Ethernet (registered trademark) adapter unit 1082 is connected to the intra-office network 50.
The other adapter unit 1083 is connected to a communication line such as RS-485.
The priority selection unit 1084 transfers a message output from each adapter unit according to the priority of each adapter unit. For example, when the transmission capacity is sufficient, the priority selection unit 1084 transfers the messages output from each adapter in order according to fairness or weighting. On the other hand, when the communication speed in the transmission band is low (for example, in the case of 32 kbps), the priority selection unit 1084 preferentially transfers the message output from the voice line adapter unit 1081, and the Ethernet (registered trademark) adapter unit 1082 and the like. The message output from the adapter unit 1083 is put on standby. When there is no longer any message output from the voice line adapter unit 1081, the priority selection unit 1084 transfers messages output from the Ethernet (registered trademark) adapter unit 1082 and the other adapter unit 1083.

According to the satellite communication system 100d in the sixth embodiment configured as described above, priority can be given to important communication even when the communication speed in the usable band is limited. Hereinafter, this effect will be described in detail.
When the communication speed in the usable band is limited, the small earth station 10e gives priority to important communication (for example, voice communication or facsimile communication according to voice), and other communication is important communication. Not done until finished. Therefore, it is possible to preferentially execute important communication at any time.

(Seventh embodiment)
In the seventh embodiment, the operation mode of each small earth station is determined at the setting terminal in order to operate the operating time of the battery 111 for a long time. Since the system configuration of the seventh embodiment is the same as that of the fifth embodiment, only the setting terminal will be described.

FIG. 26 is a schematic block diagram illustrating a functional configuration of the setting terminal 40f according to the seventh embodiment.
The setting terminal 40f includes an input unit 401, a processing unit 402, an output unit 403, and a mode setting unit 404.
The input unit 401 is configured using existing input devices such as a keyboard, a pointing device (such as a mouse and a tablet), a touch panel, and buttons. The input unit 401 is operated by the user when inputting a user instruction to the setting terminal 40f. The input unit 401 may be an interface for connecting the input device to the setting terminal 40f. In this case, the input unit 401 inputs an input signal generated in response to a user input in the input device to the setting terminal 40f. Here, the user is an operator of the satellite communication system 100d.

The processing unit 402 determines the operation mode of each small earth station 10f based on the input information.
The output unit 403 outputs data to the user of the setting terminal 40f via an output device (not shown) connected to the setting terminal 40f. For example, the output unit 403 outputs a result during processing by the processing unit 402 to the output device. The output device may be configured using, for example, a device that outputs images and characters on a screen. For example, the output device can be configured using a CRT (Cathode Ray Tube), a liquid crystal display, an organic EL (Electro-Luminescent) display, or the like. The output device may be configured using a device that prints (prints) an image or a character on a sheet. For example, the output device can be configured using an ink jet printer, a laser printer, or the like. In addition, the output device may be configured using a device that converts characters into speech and outputs the speech. In this case, the output device can be configured using a voice synthesizer and a voice output device (speaker).
The mode setting unit 404 sets the operation mode of each small earth station 10d by transmitting the determined operation mode to the small earth station 10d-1.

FIG. 27 is a flowchart showing the flow of setting processing for setting the operation mode of each small earth station 10.
First, as pre-processing, the input unit 401 determines the number of frequency channels (bandwidth) allocated from the control station 30 that can be used in the satellite communication system 100d according to the user's operation, and the small earth stations 10d-2 to 10d-M. And the power consumption in each operation mode of each small earth station 10 are input. In addition, the input unit 401 inputs the battery capacity provided in each small earth station 10, the operating time of the generator, and the necessary number of frequency channels (band).

  The processing unit 402 estimates the excess or deficiency of the number of channels (bandwidth) of the entire system from the number of usable channels (bandwidth) and the number of channels (bandwidth) necessary for each small earth station 10. A bandwidth is allocated to the small earth station 10 by apportioning the allocated bandwidth by the ratio of the required bandwidth of the earth station 10d (step S1101). Next, the output unit 403 outputs the band allocation result to the output device. The processing unit 402 determines whether or not a band allocation result acceptance OK has been input (step S1102). The operator determines whether or not the band allocation result can be accepted. Then, the operator inputs the determination result to the setting terminal 40f via the input unit 401.

When it is determined that the band allocation result is not accepted (step S1102-NO), the processing unit 402 determines whether or not an input indicating that the bandwidth allocation of the entire system can be increased from the control station 30 (step S1103). As a premise of the processing in step S1103, it is determined whether or not the bandwidth can be increased by negotiation with the control station 30 by the operator. If the bandwidth can be increased as a result of the negotiation, the operator inputs to the setting terminal 40 using the input unit 401 that the bandwidth can be increased. When it is input that it can be increased (step S1103-YES), the processing unit 402 resets the system band (step S1104). Thereafter, the processing unit 402 repeatedly executes the processes after step S1101.
On the other hand, when it is not input that the increase is possible (step S1103-NO), the processing unit 402 executes a review of the band setting of each small earth station 10 (step S1105). Thereafter, the processing unit 402 repeatedly executes the processes after step S1101.

  Further, when it is possible to accept the band allocation result in the process of step S1102 (step S1102-YES), the processing unit 402 calculates the operating time of each small earth station 10 (step S1106). The processing unit 402 determines whether or not OK is input as the operation time calculation result (step S1107). The operator determines whether the operating time calculation result is acceptable (OK or NG). When OK is input as the operation time calculation result (step S1107—YES), the processing unit 402 determines an operation mode to be assigned to each small earth station 10d. The mode setting unit 404 sets the operation mode for each small earth station 10d by outputting the determined operation mode to the small earth station 10d-1 (step S1108).

  In the process of step S1107, NG is input as the operation time calculation result (step S1107—NO), and the processing unit 402 determines whether or not a bandwidth setting review instruction is input (step S1109). The operator determines whether or not the bandwidth setting can be reviewed. Then, the operator inputs the determination result via the input unit 401. For example, when it is determined that the bandwidth setting can be reviewed, the operator inputs a bandwidth setting review instruction via the input unit 401. On the other hand, when the operator determines that the bandwidth setting cannot be reviewed, the operator does not input the bandwidth setting review instruction via the input unit 401.

When the bandwidth setting review instruction is input (step S1109—YES), the processing unit 402 executes the process of step S1105.
On the other hand, when the band setting review instruction is not input (step S1109-NO), the operator examines the generator fuel and storage battery distribution plan of each small earth station 10 (step S1110). The operator reviews the examination result (step S1111), and inputs the result to the input unit 401. Thereafter, the processing unit 402 executes the processing after step S1101.

According to the satellite communication system 100 configured as described above, the operation mode of each small earth station 10d can be appropriately set. Hereinafter, this effect will be described in detail.
The operator operates the setting terminal 40 to input information on each small earth station 10d. The setting terminal 40 calculates a bandwidth allocated to each small earth station 10d from the input information. Then, the setting terminal 40 asks the operator for confirmation according to the processing, and sets the operation mode of each small earth station 10d according to the operator's instruction. Thus, the setting of the operation mode of each small earth station 10d can be performed interactively between the setting terminal 40 and the operator. Therefore, the operation mode can be set according to the operator's intention. Therefore, it becomes possible to appropriately set the operation mode of each small earth station 10d.

A modification common to the first to fourth embodiments will be described.
In the satellite communication system 100 according to the first to fourth embodiments, the small earth station 10 has a one-to-one configuration (small earth station 10-1 and small earth station 10-2). The satellite communication system 100 in the fourth to fourth embodiments can be applied to a one-to-M configuration. When configured in this way, combinations of M small earth station IDs and mode IDs are registered in the mode information table for each small earth station.

A modification common to the embodiments will be described.
In each embodiment, the case where there are three mode IDs registered in the operation mode table is shown. However, the number of mode IDs registered in the operation mode table may be two or less, or four or more. Also good.

  According to at least one embodiment described above, an opposing small earth station that performs communication using a line after a line used for communication between a plurality of small earth stations that communicate via a satellite is established. 10, a transmission unit (corresponding to the antenna 101 of the embodiment) that transmits information on an operation mode corresponding to the small earth station 10 among a plurality of operation modes for reducing power consumption, and other small earth stations Based on the operation mode change instruction from 10, the operation mode of the own apparatus is set to the operation mode indicated by the operation mode change instruction, and the operation mode control for controlling the operation of the functional unit included in the own apparatus according to the set operation mode By having the unit 110, the power consumption of the battery can be suppressed while securing the band.

  A program for executing each process of the small earth station 10 (10a, 10b, 10c, 10d, 10e) and the setting terminals 40, 40f of the present invention is recorded on a computer-readable recording medium, and the recording medium The above-mentioned various processes related to the processes of the small earth station 10 (10a, 10b, 10c, 10d, 10e) and the setting terminals 40, 40f are performed by causing the computer system to read and execute the program recorded in May be. Here, the “computer system” may include an OS and hardware such as peripheral devices. Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used. The “computer-readable recording medium” means a flexible disk, a magneto-optical disk, a ROM, a writable nonvolatile memory such as a flash memory, a portable medium such as a CD-ROM, a hard disk built in a computer system, etc. This is a storage device.

  Further, the “computer-readable recording medium” means a volatile memory (for example, DRAM (Dynamic DRAM) in a computer system that becomes a server or a client when a program is transmitted through a network such as the Internet or a communication line such as a telephone line. Random Access Memory)), etc., which hold programs for a certain period of time. The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. Here, the “transmission medium” for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

10 (10-1 to 10-M), 10a, 10b, 10c, 10d (10d-1 to 10d-M), 10e ... small earth station, 20 ... satellite, 30 ... control station, 40, 40f ... setting terminal, 50 (50-1 to 50-M)... Intra-office network, 101. (106-1 to 106-N) ... modulation / demodulation unit, 107, 107d ... line control unit, 1071 ... destination-specific bandwidth request list unit, 108 (108-1 to 108- (N-1)), 108d (108d-1) 108d- (N-1)), 108e ... interface unit, 1081 ... voice line adapter unit, 1082 ... Ethernet (registered trademark) adapter unit, 1083 ... other adapter unit, 108 ... priority selection unit, 109 ... operation mode interface unit, 110 and 110a, 110b, 110c ... operation mode control unit, 111 ... Battery

Claims (15)

To reduce power consumption with respect to an opposing small earth station that performs communication using the line after a line used for communication between a plurality of small earth stations that communicate via a satellite is established. A transmission unit for transmitting information on the operation mode corresponding to the small earth station among the plurality of operation modes;
Based on the information on the operation mode transmitted from another small earth station, the operation mode of the own device is set to the operation mode indicated by the information, and the operation of the functional unit included in the own device according to the set operation mode An operation mode control unit for controlling
A satellite communication system comprising: The small earth station includes a plurality of modulation / demodulation units,
The satellite communication system according to claim 1, wherein the operation mode control unit operates a part of the modulation / demodulation unit according to the operation mode and stops the rest. The small earth station includes a power amplification unit that amplifies the power of data to be transmitted,
The satellite communication system according to claim 1, wherein the operation mode control unit lowers a drain voltage or a gate voltage in the power amplification unit according to the operation mode. The small earth station includes a plurality of modulation / demodulation units and a power amplification unit that amplifies the power of data to be transmitted,
The operation mode control unit operates a part of the modulation / demodulation unit according to the operation mode, stops the remaining modulation / demodulation units, and lowers a drain voltage or a gate voltage in the power amplification unit. Satellite communication system.   The satellite communication system according to claim 1, wherein the small earth stations performing the communication set the same operation mode. To reduce power consumption with respect to an opposing small earth station that performs communication using the line after a line used for communication between a plurality of small earth stations that communicate via a satellite is established. A transmission unit for transmitting information on the operation mode corresponding to the small earth station among the plurality of operation modes;
Based on the information about the operation mode transmitted to another small earth station, the operation mode of the own device is set to the operation mode indicated by the information, and the operation of the functional unit included in the own device is performed according to the set operation mode. An operation mode control unit to control;
A small earth station. A plurality of modulation / demodulation units;
The small earth station according to claim 6, wherein the operation mode control unit operates a part of the modulation / demodulation unit according to the operation mode and stops the rest. A power amplifying unit for amplifying the power of data to be transmitted;
The small earth station according to claim 6, wherein the operation mode control unit lowers a drain voltage or a gate voltage in the power amplification unit according to the operation mode. A power amplifying unit for amplifying the power of a plurality of modems and data to be transmitted;
The operation mode control unit operates a part of the modulation / demodulation unit according to the operation mode, stops the remaining modulation / demodulation units, and lowers a drain voltage or a gate voltage in the power amplification unit. Small earth station.   The small earth station according to claim 6, wherein the small earth stations performing the communication set the same operation mode. To reduce power consumption with respect to an opposing small earth station that performs communication using the line after a line used for communication between a plurality of small earth stations that communicate via a satellite is established. A transmission step of transmitting information on the operation mode corresponding to the small earth station among the plurality of operation modes;
Based on the information on the operation mode transmitted from another small earth station, the operation mode of the own device is set to the operation mode indicated by the information, and the operation of the functional unit included in the own device according to the set operation mode An operation mode control step for controlling
A method for reducing power consumption. The small earth station includes a plurality of modulation / demodulation units,
The power consumption reduction method according to claim 11, wherein in the operation mode control step, a part of the modulation / demodulation unit is operated according to the operation mode and the rest is stopped. The small earth station includes a power amplification unit that amplifies the power of data to be transmitted,
The power consumption reduction method according to claim 11, wherein, in the operation mode control step, a drain voltage or a gate voltage in the power amplification unit is lowered according to the operation mode. The small earth station includes a plurality of modulation / demodulation units and a power amplification unit that amplifies the power of data to be transmitted,
12. In the operation mode control step, according to the operation mode, a part of the modulation / demodulation unit is operated to stop the remaining modulation / demodulation units, and a drain voltage or a gate voltage in the power amplification unit is lowered. Power consumption reduction method.   The power consumption reduction method according to claim 11, wherein the same operation mode is set between the small earth stations performing the communication.

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