JP2004120266A - Satellite communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a satellite communication system in which combining work is executed efficiently. <P>SOLUTION: When there are a plurality of satellites, there are a plurality of outdoor devices 1, and each outdoor device 1 is connected to each satellite via a satellite line. A unit test of each outdoor device 1 is executed beforehand since the frequency and the transmission power level are different in each satellite. As a result of the test, a frequency and a transmission power level for every outdoor device 1 are made as a set frequency and a set level. Correction data 3 to make the set frequency and the set level to correspond to each other are stored in a storage part 4 of an indoor device 2. The indoor device 2 corrects (adjusts) a level to be transmitted to each outdoor device 1 on the basis of the correction data 3. Thus, it is sufficient only to acquire all of the set frequencies and the set levels by combining the indoor device 2 and each outdoor device 1. Accordingly, the transmission power level is corrected (adjusted) without executing the combining work. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a satellite communication system, and more particularly, to a satellite communication system for controlling transmission power.
[0002]
[Prior art]
Techniques for controlling transmission power for performing satellite communication are known (for example, see Patent Literature 1, Patent Literature 2, Patent Literature 3, Patent Literature 4, Patent Literature 5, and Patent Literature 6).
[0003]
A satellite communication system that controls transmission power includes an outdoor device (Out Door Unit) and an indoor device (In Door Unit). When there are a plurality of satellites, there are a plurality of outdoor units (ODUs), and each ODU is connected to each satellite via a satellite line. An indoor unit (IDU) is connected (combined) with each ODU via a communication line, and transmits and receives power to and from each ODU.
[0004]
Each ODU converts the level of the transmission power from the IDU into a frequency, amplifies it with a fixed gain, and transmits (outputs) it to each satellite. This gain is determined by the frequency when transmitting to the satellite. Conventionally, in order to obtain a stable output at all frequencies, the IDU and each ODU are combined, the frequency is grasped, and the transmission power level is corrected (adjusted).
[0005]
However, since each satellite has a different frequency and transmission power level, in the conventional satellite communication system, a combination operation (IDU) for acquiring all data (frequency and transmission power level) by combining an IDU and each ODU. To combine the ODU with each ODU via a communication line).
[0006]
In the conventional satellite communication system, some communication means is required between the IDU and each ODU in order to efficiently perform the combination work. This means that, as in the case of the Ku band, the transmission band is as high as 500 MHz, the channel step in which the frequency is set is 2.5 KHz, and when the level to be set is fine (in many cases), the number of combined steps is enormous. Therefore, the operation cost for performing the combination operation and acquiring all data (frequency and transmission power level) increases.
[0007]
Further, in the conventional satellite communication system, an increase in hardware configuration is required to efficiently perform the combination work. The hardware configuration is, for example, an output level correction circuit for correcting the level of transmission power when the ODU transmits (outputs) power to the IDU, and the transmission level of the transmission power when the IDU transmits (outputs) power to the ODU. A set value notifying function for notifying set values such as a level and the above-described frequency is provided. As described above, in the conventional satellite communication system, the cost of an apparatus for producing an ODU and an IDU increases.
[0008]
[Patent Document 1]
JP-A-6-268535
[Patent Document 2]
JP-A-4-351221
[Patent Document 3]
JP-A-5-284071
[Patent Document 4]
JP-A-5-252806
[Patent Document 5]
JP 2000-183798 A
[Patent Document 6]
JP-A-2-170628
[0009]
[Problems to be solved by the invention]
An object of the present invention is to provide a satellite communication system capable of correcting (adjusting) the level of transmission power without performing combination work.
Another object of the present invention is to provide a satellite communication system capable of reducing work costs.
Still another object of the present invention is to provide a satellite communication system capable of reducing the cost of the device.
[0010]
[Means for Solving the Problems]
The means for solving the problem will be described below using the numbers and symbols used in [Embodiments of the Invention]. These numbers and symbols are added to clarify the correspondence between the description of [Claims] and the description of [Embodiments of the Invention]. It should not be used to interpret the technical scope of the described invention.
[0011]
The satellite communication system according to the present invention (first embodiment) includes an indoor device (2) and an outdoor device (1). The indoor device (2) and the outdoor device (1) are connected (combined) via a communication line (10). The indoor device (2) includes a modulation unit (7), a storage unit (4), a selection unit (11), a calculation unit (12), and a level control unit (8). The modulator (7) modulates a transmission power level for transmitting transmission data to the outdoor device (1). The storage unit (4) stores a plurality of correction data (3) for associating the set frequency with the set level. The selecting unit (11) selects one of the plurality of correction data (3) from the frequency information indicating the frequency from the outside by referring to the storage unit (4). The calculation unit (12) calculates an adjustment value for adjusting the level modulated by the modulation unit (7) to the set level of the correction data (3) selected by the selection unit (11). The level control unit (8) adjusts the level modulated by the modulation unit (7) based on the adjustment value and transmits the adjusted level to the outdoor device (1). The outdoor device (1) has an antenna (9), converts a level from the level control unit (8) into a frequency, and transmits the frequency to the satellite (20) via the antenna (9).
In the satellite communication system of the present invention (first embodiment), when there are a plurality of satellites (20), there are a plurality of outdoor devices (1), and each of the outdoor devices (1) is connected via a satellite line (30). Connected to each satellite (20). Before the combination of the indoor device (2) and the outdoor device (1), the indoor device (2) and the outdoor device (1) are used before the combination of the indoor device (2) and the outdoor device (1) because the frequency and the transmission power level are different for each satellite (20). Before installation, a unit test of each outdoor device (1) is performed in advance, and as a result of the test, the frequency and transmission power level of each outdoor device (1) are obtained. The acquired frequency and transmission power level for each outdoor device (1) are set as a set frequency and a set level, respectively, and correction data (3) (frequency-transmission power level characteristic) that associates the set frequency with the set level is obtained. It is stored in the storage unit (4) of the indoor device (2). Thus, the storage unit (4) stores a plurality of correction data (3) {the correction data (3) for each outdoor device (1) is stored}.
[0012]
In the satellite communication system of the present invention (first embodiment), the indoor unit (2) can correct (adjust) the level transmitted (output) to each outdoor unit (1) based on the correction data (3). it can. For this reason, in the satellite communication system of the present invention (first embodiment), all data ｛frequency (set frequency) and transmission power level (set level) are obtained by combining the indoor device (2) and each outdoor device (1). ) There is no need to perform a combination work to obtain ①. Therefore, in the satellite communication system of the present invention (first embodiment), it is only necessary to acquire the set frequency and the set level in the unit test of each outdoor device (1), and the transmission power level can be reduced without performing the combination work. It can be corrected (adjusted).
Further, in the satellite communication system of the present invention (first embodiment), all data ｛frequency (set frequency) and transmission power level (set level) are obtained by combining the indoor device (2) and each outdoor device (1). Since it is not necessary to obtain 、 and it is only necessary to obtain the set frequency and the set level in the unit test of each outdoor device (1), the operation cost can be reduced.
In the satellite communication system of the present invention (first embodiment), the correction data (3) is stored in the storage unit (4) of the indoor device (2), and the indoor device (2) is based on the correction data (3). In addition, since the level transmitted (output) to each outdoor device (1) is corrected (adjusted), the conventional hardware configuration (output level correction circuit, setting value notification function, etc.) becomes unnecessary. For this reason, in the satellite communication system of the present invention (first embodiment), it is possible to reduce the device cost for manufacturing the outdoor device (1) and the indoor device (2).
[0013]
The satellite communication system of the present invention (second embodiment) includes an indoor device (2), an outdoor device (1), and a storage device (4). The indoor device (2) and the outdoor device (1) are connected (combined) via a communication line (10). The storage device (4) is connected to the indoor device (2). The storage device (4) stores a plurality of correction data (3) for associating the set frequency with the set level. The indoor device (2) includes a modulator (7), a selector (11), a calculator (12), and a level controller (8). The modulator (7) modulates a transmission power level for transmitting transmission data to the outdoor device (1). The selecting unit (11) selects one of the plurality of correction data (3) from the frequency information representing the frequency from the outside with reference to the storage device (4). The calculation unit (12) calculates an adjustment value for adjusting the level modulated by the modulation unit (7) to the set level of the correction data (3) selected by the selection unit (11). The level control unit (8) adjusts the level modulated by the modulation unit (7) based on the adjustment value and transmits the adjusted level to the outdoor device (1). The outdoor device (1) has an antenna (9), converts a level from the level control unit (8) into a frequency, and transmits the frequency to the satellite (20) via the antenna (9).
In the satellite communication system of the present invention (second embodiment), when there are a plurality of satellites (20), there are a plurality of outdoor devices (1), and each of the outdoor devices (1) is connected via a satellite line (30). Connected to each satellite (20). Before the combination of the indoor device (2) and the outdoor device (1), the indoor device (2) and the outdoor device (1) are used before the combination of the indoor device (2) and the outdoor device (1) because the frequency and the transmission power level are different depending on each satellite (20). Before installation, a unit test of each outdoor device (1) is performed in advance, and as a result of the test, the frequency and transmission power level of each outdoor device (1) are obtained. The acquired frequency and transmission power level for each outdoor device (1) are set as a set frequency and a set level, respectively, and correction data (3) (frequency-transmission power level characteristic) that associates the set frequency with the set level is obtained. It is stored in the storage device (4). Thus, the storage device (4) stores a plurality of correction data (3) {the correction data (3) for each outdoor device (1) is stored}.
[0014]
In the satellite communication system of the present invention (second embodiment), the indoor device (2) can correct (adjust) the level to be transmitted (output) to each outdoor device (1) based on the correction data (3). it can. For this reason, in the satellite communication system of the present invention (the second embodiment), all data 装置 frequency (set frequency) and transmission power level (set level) are obtained by combining the indoor device (2) and each outdoor device (1). ) There is no need to perform a combination work to obtain ①. Therefore, in the satellite communication system of the present invention (the second embodiment), it is only necessary to acquire the set frequency and the set level in the unit test of each outdoor device (1), and the transmission power level can be reduced without performing the combination work. It can be corrected (adjusted).
Further, in the satellite communication system of the present invention (the second embodiment), the indoor device (2) and each outdoor device (1) are combined to obtain all data ｛frequency (set frequency) and transmission power level (set level). Since it is not necessary to obtain 、 and it is only necessary to obtain the set frequency and the set level in the unit test of each outdoor device (1), the operation cost can be reduced.
Further, in the satellite communication system of the present invention (second embodiment), the correction data (3) is stored in the storage device (4), and the indoor device (2) uses the outdoor device (1) based on the correction data (3). ) To correct (adjust) the level to be transmitted (output), the conventional hardware configuration (output level correction circuit, setting value notification function, etc.) becomes unnecessary. For this reason, in the satellite communication system of the present invention (second embodiment), it is possible to reduce the device cost for manufacturing the outdoor device (1) and the indoor device (2).
[0015]
The indoor apparatus (2) for satellite communication of the present invention (first embodiment) is connected (combined) to an outdoor apparatus (1) via a communication line (10). The outdoor apparatus (1) converts a transmission power level into a frequency and transmits the frequency to a satellite (20) via an antenna (9). The indoor device (2) includes a modulator (7), a storage (4), a selector (11), a calculator (12), and a level controller (8). The modulator (7) modulates a level for transmitting transmission data to the outdoor device (1). The storage unit (4) stores a plurality of correction data (3) for associating the set frequency with the set level. The selecting unit (11) selects one of the plurality of correction data (3) from the frequency information indicating the frequency from the outside by referring to the storage unit (4). The calculation unit (12) calculates an adjustment value for adjusting the level modulated by the modulation unit (7) to the set level of the correction data (3) selected by the selection unit (11). The level control unit (8) adjusts the level modulated by the modulation unit (7) based on the adjustment value and transmits the adjusted level to the outdoor device (1).
In the indoor device (2) of the present invention (first embodiment), when there are a plurality of satellites (20), there are a plurality of outdoor devices (1), and each outdoor device (1) has a satellite line (30). Connected to each satellite (20). Before the combination of the indoor device (2) and the outdoor device (1), the indoor device (2) and the outdoor device (1) are used before the combination of the indoor device (2) and the outdoor device (1) because the frequency and the transmission power level are different depending on each satellite (20). Before installation, a unit test of each outdoor device (1) is performed in advance, and as a result of the test, the frequency and transmission power level of each outdoor device (1) are obtained. The acquired frequency and transmission power level for each outdoor device (1) are set as a set frequency and a set level, respectively, and correction data (3) (frequency-transmission power level characteristic) that associates the set frequency with the set level is obtained. It is stored in the storage unit (4) of the indoor device (2). Thus, the storage unit (4) stores a plurality of correction data (3) {the correction data (3) for each outdoor device (1) is stored}.
[0016]
The indoor device (2) of the present invention (first embodiment) can correct (adjust) the level transmitted (output) to each outdoor device (1) based on the correction data (3). For this reason, in the satellite communication system of the present invention (first embodiment), all data ｛frequency (set frequency) and transmission power level (set level) are obtained by combining the indoor device (2) and each outdoor device (1). ) There is no need to perform a combination work to obtain ①. Therefore, in the indoor device (2) of the present invention (first embodiment), it is only necessary to obtain the set frequency and the set level in the unit test of each outdoor device (1), and the transmission power can be reduced without performing the combination work. The level can be corrected (adjusted).
Further, in the indoor device (2) of the present invention (first embodiment), the indoor device (2) and each outdoor device (1) are combined to obtain all data 全 て frequency (set frequency) and transmission power level (set). Level)｝ is not required, and it is only necessary to obtain the set frequency and the set level in the unit test of each outdoor device (1), so that the work cost can be reduced.
In the indoor device (2) of the present invention (first embodiment), the correction data (3) is stored in the storage unit (4) of the indoor device (2), and the indoor device (2) stores the correction data (3). Therefore, the level to be transmitted (output) to each outdoor device (1) is corrected (adjusted) based on the above, so that the conventional hardware configuration (output level correction circuit, setting value notification function, etc.) becomes unnecessary. For this reason, in the indoor device (2) of the present invention (first embodiment), it is possible to reduce the device cost for manufacturing the outdoor device (1) and the indoor device (2).
[0017]
The indoor device (2) for satellite communication of the present invention (second embodiment) is connected (combined) to the outdoor device (1) via a communication line (10) and connected to a storage device (4). I have. The outdoor apparatus (1) converts a transmission power level into a frequency and transmits the frequency to a satellite (20) via an antenna (9). The storage device (4) stores a plurality of correction data (3) for associating the set frequency with the set level. The indoor device (2) includes a modulator (7), a selector (11), a calculator (12), and a level controller (8). The modulator (7) modulates a level for transmitting transmission data to the outdoor device (1). The selection unit (11) selects one of the plurality of correction data (3) from the frequency information indicating the frequency from the outside with reference to the storage device (4). The calculation unit (12) calculates an adjustment value for adjusting the level modulated by the modulation unit (7) to the set level of the correction data (3) selected by the selection unit (11). The level control unit (8) adjusts the level modulated by the modulation unit (7) based on the adjustment value and transmits the adjusted level to the outdoor device (1).
In the indoor device (2) of the present invention (second embodiment), when there are a plurality of satellites (20), there are a plurality of outdoor devices (1), and each of the outdoor devices (1) has a satellite line (30). Connected to each satellite (20). Before the combination of the indoor device (2) and the outdoor device (1), the indoor device (2) and the outdoor device (1) are used before the combination of the indoor device (2) and the outdoor device (1) because the frequency and the transmission power level are different depending on each satellite (20). Before installation, a unit test of each outdoor device (1) is performed in advance, and as a result of the test, the frequency and transmission power level of each outdoor device (1) are obtained. The acquired frequency and transmission power level for each outdoor device (1) are set as a set frequency and a set level, respectively, and correction data (3) (frequency-transmission power level characteristic) that associates the set frequency with the set level is obtained. It is stored in the storage device (4). Thus, the storage device (4) stores a plurality of correction data (3) {the correction data (3) for each outdoor device (1) is stored}.
[0018]
The indoor device (2) of the present invention (second embodiment) can correct (adjust) the level transmitted (output) to each outdoor device (1) based on the correction data (3). For this reason, in the indoor device (2) of the present invention (the second embodiment), by combining the indoor device (2) and each outdoor device (1), all data ｛frequency (set frequency) and transmission power level ( There is no need to perform combination work to obtain (setting level)｝. Therefore, in the indoor device (2) of the present invention (the second embodiment), it is only necessary to acquire the set frequency and the set level in the unit test of each outdoor device (1). Work (1) in combination with the outdoor device (1) can be performed efficiently.
Further, in the indoor device (2) of the present invention (the second embodiment), by combining the indoor device (2) and each outdoor device (1), all data 全 て frequency (set frequency), transmission power level (set) Level)｝ is not required, and it is only necessary to obtain the set frequency and the set level in the unit test of each outdoor device (1), so that the work cost can be reduced.
Further, in the indoor device (2) of the present invention (second embodiment), the correction data (3) is stored in the storage device (4), and the indoor device (2) stores each outdoor device based on the correction data (3). Since the level transmitted (output) in (1) is corrected (adjusted), the conventional hardware configuration (output level correction circuit, setting value notification function, etc.) becomes unnecessary. For this reason, in the indoor device (2) of the present invention (second embodiment), it is possible to reduce the device cost for manufacturing the outdoor device (1) and the indoor device (2).
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of a satellite communication system according to the present invention will be described below with reference to the accompanying drawings.
[0020]
(1st Embodiment)
FIG. 1 shows a configuration of a satellite communication system according to a first embodiment of the present invention. The satellite communication system according to the first embodiment includes a plurality of outdoor devices (Out Door Unit) 1 and an indoor device (In Door Unit) 2. Hereinafter, the outdoor device 1 is referred to as ODU1, and the indoor device 2 is referred to as IDU2. When there are a plurality of satellites 20, each ODU 1 is connected to each satellite 20 via a satellite line 30. The IDU 2 is connected (combined) with each ODU 1 via the communication line 10 and transmits and receives power to and from each ODU 1. In the present invention, only the process in which the IDU 2 transmits power (transmission power) to each ODU 1 will be described, and the description of the other processes will be omitted.
[0021]
FIG. 2 shows a configuration of the IDU 2 in the satellite communication system of the first embodiment. The IDU 2 includes a correction data storage unit 4, a CPU 5, a transmission data input terminal 6, a modulation unit 7, and a level control unit 8. The modulation unit 7 is connected to the transmission data input terminal 6 and the CPU 5. The CPU 5 is connected to the correction data storage unit 4. The level control unit 8 is connected to the modulation unit 7 and the CPU 5. The CPU 5 has a selection unit 11 and a calculation unit 12.
[0022]
The level control unit 8 is connected to each ODU 1 via the communication line 10. Each ODU 1 has an antenna 9 for communicating with each satellite 20 via a satellite line 30. In a process in which the IDU 2 transmits power to each ODU 1, this antenna 9 is used as a transmission data output terminal (hereinafter, referred to as a transmission data output terminal 9).
[0023]
Each of the ODUs 1 converts the level of the transmission power from the IDU 2 into a frequency, amplifies the level with a fixed gain, and transmits (outputs) to each satellite 20 via the transmission data output terminal 9. . Since this gain is determined by the frequency at which the signal is transmitted to the satellite 20, in order to obtain a stable output at all frequencies, it is necessary to grasp the frequency and correct (adjust) the level of the transmission power from the IDU2. There is.
[0024]
Therefore, since each satellite 20 has a different frequency and transmission power level, a unit test of each ODU1 is performed in advance before the combination of the IDU2 and each ODU1, and as a result of the test, the frequency and transmission Get the power level. The acquired frequency and transmission power level for each ODU1 are set as a set frequency and a set level, respectively, and correction data 3 (frequency-transmission power level characteristic) that associates the set frequency with the set level is stored in a correction data storage unit of the IDU2. 4 is stored. Thus, the correction data storage unit 4 stores a plurality of correction data 3 (the correction data 3 for each ODU 1 is stored).
[0025]
Next, the operation of the satellite communication system according to the first embodiment will be described with reference to FIG. Frequency information representing an external frequency is input to the CPU 5.
[0026]
In IDU2, modulation section 7 modulates the level of transmission power for transmitting the transmission data input to transmission data input terminal 6 to ODU1. The CPU 5 (selection unit 11) selects one of the plurality of correction data 3 from the frequency information indicating the frequency with reference to the correction data storage unit 4.
[0027]
The CPU 5 (calculation unit 12) calculates an adjustment value for adjusting the level modulated by the modulation unit 7 to the set level of the correction data 3 selected by the selection unit 11.
[0028]
Here, when the level modulated by the modulator 7 is lower than the set level of the correction data 3 selected by the selector 11, the calculator 12 determines that the level modulated by the modulator 7 is An adjustment value to be added to the level modulated by the modulation unit 7 is calculated so as to reach the set level of the selected correction data 3.
[0029]
When the level modulated by the modulator 7 is higher than the set level of the correction data 3 selected by the selector 11, the calculator 12 selects the level modulated by the modulator 7 by the selector 11. An adjustment value to be subtracted from the level modulated by the modulator 7 is calculated so that the level becomes the set level of the corrected data 3.
[0030]
The level control unit 8 adjusts the level modulated by the modulation unit 7 based on the adjustment value, and transmits the adjusted level to the ODU 1. As a result, the ODU 1 converts the level of the transmission power from the level control unit 8 into a frequency, transmits the frequency to the satellite 20 via the transmission data output terminal 9, and outputs a modulated wave having a stable level at the transmission data output terminal 9. Obtainable.
[0031]
In the satellite communication system according to the first embodiment, the IDU 2 can correct (adjust) the level to be transmitted (output) to each ODU 1 based on the correction data 3. For this reason, in the satellite communication system of the first embodiment, it is necessary to perform a combination work for acquiring all data {frequency (set frequency), transmission power level (set level)} by combining IDU2 and each ODU1. There is no. Therefore, in the satellite communication system of the first embodiment, it is only necessary to obtain the set frequency and the set level in the unit test of each ODU1, and the transmission power level can be corrected (adjusted) without performing the combination work. .
[0032]
Further, in the satellite communication system of the first embodiment, it is not necessary to acquire all data {frequency (set frequency) and transmission power level (set level)} by combining IDU2 and each ODU1. Since it is only necessary to acquire the set frequency and the set level in the test, the operation cost can be reduced.
[0033]
In the satellite communication system according to the first embodiment, the correction data 3 is stored in the correction data storage unit 4 of the IDU 2, and the IDU 2 corrects (adjusts) the level to be transmitted (output) to each ODU 1 based on the correction data 3. Therefore, the conventional hardware configuration (output level correction circuit, setting value notification function, etc.) is not required. For this reason, in the satellite communication system of the first embodiment, it is possible to reduce the device cost for producing the ODU1 and the IDU2.
[0034]
(2nd Embodiment)
In the first embodiment, the correction data storage unit 4 is provided in the IDU 2. However, as a satellite communication system according to the second embodiment of the present invention, the correction data storage unit 4 is provided as a storage device 4 outside the IDU 2. Is also good. In this case, as shown in FIG. 3, the satellite communication system according to the second embodiment includes an ODU1, an IDU2, and a storage device 4. ODU1 and IDU2 are connected via a communication line 10. The IDU 2 is connected to the storage device 4.
[0035]
In this case, as shown in FIG. 4, the IDU 2 includes a CPU 5, a transmission data input terminal 6, a modulation unit 7, and a level control unit 8. The modulation unit 7 is connected to the transmission data input terminal 6 and the CPU 5. The CPU 5 is connected to the storage device 4. The level control unit 8 is connected to the modulation unit 7 and the CPU 5. The CPU 5 has a selection unit 11 and a calculation unit 12. The level control unit 8 is connected to each ODU 1 via the communication line 10. Each ODU 1 has an antenna (transmission data output terminal) 9 for communicating with each satellite 20 via a satellite line 30.
[0036]
Even in this case, since the frequency and the transmission power level are different depending on each satellite 20, before the combination of the IDU2 and each ODU1 (before installing the IDU2 and each ODU1), the unit test of each ODU1 is performed in advance. Then, as a result of the test, the frequency and the transmission power level for each ODU1 are obtained. The acquired frequency and transmission power level of each ODU 1 are set as a set frequency and a set level, respectively, and correction data 3 (frequency-transmission power level characteristic) that associates the set frequency with the set level is stored in the storage device 4. Keep it. Thus, the storage device 4 stores a plurality of correction data 3 (the correction data 3 for each ODU 1 is stored).
[0037]
In the satellite communication system of the second embodiment, the correction data storage unit 4 may be replaced with the storage device 4, and the operation and effects of the second embodiment are the same as those of the first embodiment.
[0038]
【The invention's effect】
The satellite communication system of the present invention can correct (adjust) the level of the transmission power without performing the combination work.
The satellite communication system of the present invention can reduce the operation cost
The satellite communication system of the present invention can reduce the device cost.
[Brief description of the drawings]
FIG. 1 shows a configuration of a satellite communication system according to a first embodiment of the present invention.
FIG. 2 shows a configuration of an indoor unit (IDU) in the satellite communication system according to the first embodiment of the present invention.
FIG. 3 shows a configuration of a satellite communication system according to a second embodiment of the present invention.
FIG. 4 shows a configuration of an indoor unit (IDU) in a satellite communication system according to a second embodiment of the present invention.
[Explanation of symbols]
1. Outdoor equipment (Out Door Unit)
2 Indoor equipment (In Door Unit)
3 Correction data
4 Correction data storage, storage device
5 CPU
6 Transmission data input terminal
7 Modulation section
8 Level control unit
9 Transmission data output end (antenna)
10 Communication line
11 Selector
12 Calculator
20 satellites
30 satellite line

Claims (4)

Comprising an indoor device and an outdoor device connected via a communication line,
The indoor device,
A modulation unit that modulates a transmission power level for transmitting transmission data to the outdoor device,
A storage unit storing a plurality of correction data for associating the set frequency and the set level,
A selection unit that selects one of the plurality of correction data with reference to the storage unit from frequency information indicating a frequency from the outside;
A calculation unit that calculates an adjustment value for adjusting the level to the set level of the selected correction data,
A level control unit that adjusts the level based on the adjustment value and transmits the level to the outdoor device,
A satellite communication system in which the outdoor device has an antenna, converts the level from the level control unit into the frequency, and transmits the frequency to a satellite via the antenna. An indoor device and an outdoor device connected via a communication line, and a storage device connected to the indoor device,
The storage device stores a plurality of correction data for associating the set frequency and the set level,
The indoor device,
A modulation unit that modulates a transmission power level for transmitting transmission data to the outdoor device,
A selection unit that selects one of the plurality of pieces of correction data by referring to the storage device from frequency information indicating a frequency from outside;
A calculation unit that calculates an adjustment value for adjusting the level to the set level of the selected correction data,
A level control unit that adjusts the level based on the adjustment value and transmits the level to the outdoor device,
A satellite communication system in which the outdoor device has an antenna, converts the level from the level control unit into the frequency, and transmits the frequency to a satellite via the antenna. An indoor device for satellite communication, which is connected via a communication line to an outdoor device that converts the level of transmission power to a frequency and transmits it to a satellite via an antenna,
A modulation unit that modulates the level for transmitting transmission data to the outdoor device, a storage unit storing a plurality of correction data that associates a set frequency and a set level,
A selection unit that selects one of the plurality of correction data with reference to the storage unit from frequency information indicating a frequency from the outside;
A calculation unit that calculates an adjustment value for adjusting the level to the set level of the selected correction data,
A level controller for adjusting the level based on the adjustment value and transmitting the adjusted level to the outdoor apparatus. It was connected via a communication line to an outdoor device that converts the level of transmission power to a frequency and transmits it to a satellite via an antenna, and was connected to a storage device that stored a plurality of correction data for associating a set frequency with a set level. An indoor device for satellite communication,
A modulator for modulating the level for transmitting transmission data to the outdoor device, and frequency information representing a frequency from the outside, referring to the storage device and selecting one of the plurality of correction data. A selection unit to
A calculation unit that calculates an adjustment value for adjusting the level to the set level of the selected correction data,
A level controller for adjusting the level based on the adjustment value and transmitting the adjusted level to the outdoor apparatus.

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