JP6178265B2 - Satellite communication apparatus and transmission power control method - Google Patents

Description

  Embodiments described herein relate generally to a satellite communication apparatus that transmits a transmission signal to a communication satellite while controlling the signal intensity based on the reception level of a signal from the communication satellite, and a transmission power control method used in the apparatus.

  In satellite communication using the Ku band (14/12 GHz), the intensity of transmitted and received radio waves is attenuated by rainfall. When rain attenuation is high, the satellite link may not be maintained. This is because the intensity of the input signal to the transponder mounted on the satellite is significantly reduced by rainfall. Therefore, there is a need for a satellite communication apparatus that stabilizes the line quality by keeping the input signal to the transponder at a constant level.

  This type of satellite communication apparatus is provided with a TPC (Transmission Power Control) function for controlling transmission power and compensating for rain attenuation in the uplink. In general, a satellite communication apparatus having a TPC function compares the reception level of a signal from a communication satellite with the reception level in a clear sky, and measures the attenuation of the received signal. The satellite communication device calculates an attenuation correction amount in the uplink based on the attenuation amount in the downlink. Then, the satellite communication device controls the power of the transmission signal to the communication satellite based on the calculated attenuation correction amount.

  By the way, the satellite communication device is often installed mainly for the purpose of quickly transmitting video and / or audio during an emergency disaster and for use as an emergency communication line. Since the facility is intended to operate in the event of a disaster, a transmission device such as a video transmission device or an audio transmission device may be individually prepared according to the function, purpose, and application. In addition, a redundant system is often prepared for the transmission system and the reception system so that the function can be maintained when a failure occurs in a part of the facility. When transmitting devices are prepared individually for functions and applications, the power required for receiving by the transponder differs for each transmitting device. Therefore, the power value (hereinafter referred to as “clear sky level”) of radio waves transmitted to the satellites in clear weather by each transmitter differs. Here, when individually preparing transmission devices for functions and uses, there is a problem that forming a redundant configuration for each transmission device causes an increase in the device scale and cost of the satellite communication device. .

JP 2010-2127768 A

  As described above, the conventional satellite communication apparatus has a problem that if a redundant configuration is established for each of the independent transmission apparatuses having different clear sky levels, the apparatus scale increases and the cost increases.

  Accordingly, an object is to provide a satellite communication device capable of suppressing an increase in device scale and cost while building a redundant configuration for each independent transmission device having a different clear sky level, and a transmission power control method used in the device. Is to provide.

  According to the embodiment, the satellite communication device includes a first transmission device, a second transmission device, a standby device, and a control device. The first transmission device outputs the first output signal at the output level set by the first control signal. The second transmission device outputs the second output signal at the output level set by the second control signal. When the first clear sky level for the first transmission device is set and the first control signal is given, the spare device has the output level set by the first control signal. When the second clear sky level for the second transmission device is set and the second control signal is given, the output set by the second control signal is output. The second output signal is output at a level. When the spare device substitutes for the first transmission device, the control device sets the first clear sky level for the spare device, and sends the first control signal to the spare device. When the spare device substitutes for the second transmitting device, the second clear sky level is set for the spare device, and the second control signal is output to the spare device. To do.

It is a block diagram which shows the function structure of the satellite communication apparatus which concerns on 1st Embodiment. It is a block diagram which shows the function structure of the control apparatus shown in FIG. It is a figure which shows the flowchart at the time of the control apparatus shown in FIG. 2 implementing a transmission system switching check process and a TPC process. It is a flowchart which shows the transmission system switching check process implemented by the TPC control part shown in FIG. It is a flowchart which shows the TPC process implemented by the TPC control part shown in FIG. It is a block diagram which shows the function structure of the satellite communication apparatus which concerns on 2nd Embodiment. It is a block diagram which shows the function structure of the control apparatus shown in FIG. It is a figure which shows the flowchart at the time of the control apparatus shown in FIG. 7 implementing a transmission system switching check process and a TPC process. It is a flowchart which shows the transmission system switching check process implemented by the TPC control part shown in FIG. It is a flowchart which shows the TPC process implemented by the TPC control part shown in FIG.

  Hereinafter, embodiments will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a functional configuration of the satellite communication apparatus according to the first embodiment. The satellite communication apparatus shown in FIG. 1 includes transmission apparatuses 11 and 12, a spare apparatus 13, a switch 14, an output solid circuit 15, a transmission / reception antenna 16, an amplifier (LNC: Low Noise Converter) 17, a distributor 18, and a beacon receiver 19. And a control device 110.

  The transmission device 11 includes a modulation unit 111, a frequency conversion unit (U / C) 112, and a power amplification unit (SSPA: Solid State Power Amplifier) 113.

  Modulator 111 modulates the signal according to a preset modulation scheme.

  The frequency converter 112 converts the frequency of the signal output from the modulator 111 into a frequency suitable for communication with a communication satellite. The frequency conversion unit 112 includes an attenuator 1121. The attenuator 1121 adjusts the attenuation amount according to a first control signal output from the control device 110 described later. Thereby, the frequency converter 112 adjusts the power level of the signal.

  The power amplification unit 113 amplifies the power of the signal output from the frequency conversion unit 112 by a preset amplification amount.

  The transmission apparatus 12 includes a modulation unit 121, a frequency conversion unit (U / C) 122, and a power amplification unit (SSPA) 123.

  Modulator 121 modulates the signal according to a preset modulation scheme. At this time, the modulation method of the modulation unit 121 may be different from the modulation method of the modulation unit 111. For example, the modulation unit 111 may be a method for modulating video, and the modulation unit 121 may be a method for modulating audio.

  The frequency conversion unit 122 converts the frequency of the signal output from the modulation unit 121 into a frequency suitable for communication with a communication satellite. Further, the frequency conversion unit 122 includes an attenuator 1221. The attenuator 1221 adjusts the attenuation amount according to a second control signal output from the control device 110 described later. Thereby, the frequency converter 122 adjusts the power level of the signal.

  The power amplification unit 123 amplifies the power of the signal output from the frequency conversion unit 122 by a preset amplification amount.

  The spare device 13 forms a redundant configuration for the transmission device 11 or the transmission device 12. The spare device 13 is connected to the modulation unit 111 or the modulation unit 121 via the switch 14. The spare device 13 includes a frequency conversion unit (U / C) 131 and a power amplification unit (SSPA) 132.

  The frequency conversion unit 131 includes an attenuator 1311. When a signal is given from the modulation unit 111 via the switcher 14, the attenuator 1311 adjusts the attenuation amount according to the first control signal output from the control device 110. When a signal is given from the modulation unit 121 via the switcher 14, the attenuator 1311 adjusts the attenuation amount according to the second control signal output from the control device 110.

  The power amplification unit 132 amplifies the power of the signal output from the frequency conversion unit 131 by a preset amplification amount.

  The switcher 14 switches the connection in synchronization with the output solid circuit 15 according to the switching instruction output from the control device 110. That is, the switcher 14 switches the output destination of the modulation unit 111 from the frequency conversion unit 112 to the frequency conversion unit 131 or switches the output destination of the modulation unit 121 from the frequency conversion unit 122 to the frequency conversion unit 131 according to the switching instruction. .

  The output solid circuit 15 includes a switch 151 and a coupler 152. The switch 151 switches the connection in synchronization with the switch 14 in accordance with a switching instruction output from the control device 110. That is, the switch 151 switches the output source of the signal output to the combiner 152 from the power amplifying unit 113 to the power amplifying unit 132 according to the switching instruction, or the output source of the signal output to the combiner 152 is the power amplifying unit. 123 is switched to the power amplifying unit 132. By the switching process of the switches 14 and 151, the standby device 13 can have a redundant configuration of the transmission device 11 or the transmission device 12.

  The combiner 152 combines the two signals output from the switch 151. The combiner 152 outputs the combined signal to the transmission / reception antenna 16.

  The transmission / reception antenna 16 transmits a signal output from the output solid circuit 15 toward the communication satellite. The transmitting / receiving antenna 16 receives a signal coming from a communication satellite. The transmitting / receiving antenna 16 outputs the received signal to the amplifier 17.

  The amplifier 17 amplifies the reception signal output from the transmission / reception antenna 16. The amplifier 17 outputs the amplified signal to the distributor 18.

  The distributor 18 distributes the signal output from the amplifier 17, outputs one distribution signal to the beacon receiver 19, and outputs the other distribution signal to a receiving device (not shown) installed in the subsequent stage.

  The beacon receiver 19 detects a beacon signal included in the distribution signal, and measures the intensity of the detected beacon signal. The beacon receiver 19 outputs the detected beacon signal and the received intensity information about the measured beacon signal intensity to the control device 110.

  FIG. 2 is a block diagram showing a functional configuration of the control device 110 shown in FIG. The control device 110 shown in FIG. 2 includes, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), a CPU (Random Access Memory), and other programs and data storage areas for the CPU to execute processing. Including. The control device 110 implements a monitoring unit 1101 and a TPC (Transmission Power Control) control unit 1102 by causing a CPU to execute a program. In addition, the control device 110 includes a monitor 1103 and a storage unit 1104.

  The monitoring unit 1101 monitors whether or not the transmission devices 11 and 12, the standby device 13, the transmission / reception antenna 16, the amplifier 17, the distributor 18, and the beacon receiver 19 included in the satellite communication device are operating normally. When it is determined that an abnormality has occurred in at least one of the transmission devices 11 and 12, the standby device 13, the transmission / reception antenna 16, the amplifier 17, the distributor 18, and the beacon receiver 19, the monitoring unit 1101 indicates that an abnormality has occurred. Displayed on the monitor 1103.

  If it is determined that an abnormality has occurred in the transmission device 11, the monitoring unit 1101 notifies the TPC control unit 1102 that the signal is switched to the output from the standby device 13. At this time, the monitoring unit 1101 outputs a switching instruction to the switch 14 so as to switch the output destination of the modulation unit 111 from the frequency conversion unit 112 to the frequency conversion unit 131, and also outputs an output source of the signal output to the combiner 152. A switching instruction is output to the switch 151 so as to switch from the power amplifying unit 113 to the power amplifying unit 132.

  When it is determined that an abnormality has occurred in the transmission device 12, the monitoring unit 1101 notifies the TPC control unit 1102 that the signal is switched to the output from the standby device 13. At this time, the monitoring unit 1101 outputs a switching instruction to the switch 14 so as to switch the output destination of the modulation unit 121 from the frequency conversion unit 122 to the frequency conversion unit 131, and also outputs the output source of the signal output to the combiner 152. A switching instruction is output to the switch 151 so as to switch from the power amplifying unit 123 to the power amplifying unit 132.

  When the monitoring unit 1101 determines that an abnormality has occurred in the transmission device 11 or the transmission device 12, the monitoring unit 1101 may determine whether or not the standby device 13 is in use. A priority may be determined for the device 12 and the device may be switched to a device with a higher priority. When an abnormality occurs in the transmission device 11 or the transmission device 12 and the standby device 13 cannot be used, the monitoring unit 1101 stops signal output from the device in which the abnormality has occurred. As a result, it is possible to continue normal operation of the device and safely stop the failed device.

  The storage unit 1104 stores the first clear sky level for the transmission device 11 and the second clear sky level for the transmission device 12. The first clear sky level is stored as a combination of the reception level strength of the beacon signal in fine weather and the set value of the attenuator 1121 adjusted to transmit at an appropriate level in the transmission device 11 at that time. The second clear sky level is stored in combination with the reception level strength of the beacon signal in fine weather and the set value of the attenuator 1221 adjusted to transmit at the appropriate level in the transmission device 12 at that time. The The first and second clear sky levels serve as reference levels for performing the TPC process. In addition, the storage unit 1104 stores a set value of the attenuator 1311 of the transmission device 13 for realizing the first or second clear sky level. Note that the first clear sky level and the second clear sky level may be different values or the same value.

  When receiving the reception level information of the beacon signal from the beacon receiver 19, the TPC control unit 1102 receives the reception level obtained from the reception level information and the first clear sky level stored in the storage unit 1104. The level is compared, and the amount of change in the reception level is calculated. The TPC control unit 1102 calculates the transmission level correction amount so that the calculated change amount is corrected as the transmission level. Then, the TPC control unit 1102 calculates a setting value for the attenuator 1121 of the frequency conversion unit 112 so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated transmission level correction amount. To do. The TPC control unit 1102 outputs a first control signal to the attenuator 1121 so that the attenuation amount of the attenuator 1121 changes with the calculated set value. The TPC control unit 1102 stores the setting value for the attenuator 1121 in the storage unit 1104.

  Further, when receiving the reception level information of the beacon signal from the beacon receiver 19, the TPC control unit 1102 holds the reception level obtained from the reception level information and the second clear sky level stored in the storage unit 1104. The received level is compared, and the amount of change in the received level is calculated. The TPC control unit 1102 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC control unit 1102 sets the attenuation amount setting value for the attenuator 1221 of the frequency conversion unit 122 so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated transmission level correction amount. Is calculated. The TPC control unit 1102 outputs a second control signal to the attenuator 1221 so that the attenuation amount of the attenuator 1221 changes with the calculated set value. The TPC control unit 1102 stores the setting value for the attenuator 1221 in the storage unit 1104.

  When the TPC control unit 1102 receives a notification from the monitoring unit 1101 to switch the signal output from the transmission device 11 to the standby device 13, the TPC control unit 1102 reads the first clear sky level from the storage unit 1104. The TPC control unit 1102 sets the set value of the attenuator 1121 stored as the read first clear sky level for the attenuator 1311 of the standby device 13.

  When the reception level information of the beacon signal is received from the beacon receiver 19 after the setting to the spare device 13 is completed, the TPC control unit 1102 receives the reception level obtained from the reception level information and the first stored in the storage unit 1104. The reception level held as one clear sky level is compared, and the amount of change in the reception level is calculated. The TPC control unit 1102 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC control unit 1102 sets the attenuation amount setting value for the attenuator 1311 of the frequency conversion unit 131 so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated transmission level correction amount. Is calculated. The TPC control unit 1102 outputs a first control signal to the attenuator 1311 so as to adjust the attenuation amount of the attenuator 1311 with the calculated set value. The TPC control unit 1102 stores the setting value for the attenuator 1311 in the storage unit 1104.

  When receiving a notification from the monitoring unit 1101 that the signal output is switched from the transmission device 12 to the standby device 13, the TPC control unit 1102 reads the second clear sky level from the storage unit 1104. The TPC control unit 1102 sets the set value of the attenuator 1221 stored as the read second clear sky level for the attenuator 1311 of the standby device 13.

  When the reception level information of the beacon signal is received from the beacon receiver 19 after the setting to the spare device 13 is completed, the TPC control unit 1102 receives the reception level obtained from the reception level information and the first stored in the storage unit 1104. The reception level held as the clear sky level 2 is compared, and the amount of change in the reception level is calculated. The TPC control unit 1102 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC control unit 1102 sets the attenuation amount setting value for the attenuator 1311 of the frequency conversion unit 131 so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated transmission level correction amount. Is calculated. The TPC control unit 1102 outputs a second control signal to the attenuator 1311 so as to adjust the attenuation amount of the attenuator 1311 with the calculated set value. The TPC control unit 1102 stores the setting value for the attenuator 1311 in the storage unit 1104.

  The TPC control unit 1102 confirms whether the satellite transmission apparatus is in a state where the TPC process can be performed.

  Specifically, the frequency conversion unit 112 is not under the control of the TPC control unit 1102, the frequency conversion unit 112 cannot normally perform signal communication with the TPC control unit 1102, and the frequency conversion unit 112 is controlled. If at least one of the things that cannot be performed normally is true, the TPC control unit 1102 determines that an abnormality has occurred in the frequency conversion unit 112 and stops the TPC process for the attenuator 1121. The frequency converter 122 is not under the control of the TPC controller 1102, the frequency converter 122 cannot normally perform signal communication with the TPC controller 1102, and the frequency converter 122 cannot be controlled normally. , The TPC control unit 1102 determines that an abnormality has occurred in the frequency conversion unit 122, and stops the TPC process for the attenuator 1221. The frequency conversion unit 131 is not under the control of the TPC control unit 1102, the frequency conversion unit 131 cannot normally perform signal communication with the TPC control unit 1102, and the frequency conversion unit 131 cannot be normally controlled. , The TPC control unit 1102 determines that an abnormality has occurred in the frequency conversion unit 131, and stops the TPC processing for the attenuator 1311.

  In addition, the beacon receiver 19 cannot normally perform signal communication with the TPC control unit 1102, the reception level detection operation in the beacon receiver 19 is abnormal, and the reception level detected by the beacon receiver 19 is preset. If at least one of the above is exceeded and the reception level detected by the beacon receiver 19 is below a preset minimum value, an abnormality has occurred in the beacon receiver 19 The TPC control unit 1102 stops the TPC process for the attenuators 1121, 1221, and 1311.

  Next, the operation of the control device 110 of the satellite communication apparatus having the above configuration will be described. FIG. 3 is a diagram illustrating an example of a flowchart when the control device 110 illustrated in FIG. 2 performs the transmission system switching check process and the TPC process.

  First, the TPC control unit 1102 of the control device 110 sets the first clear sky level for the transmission device 11 based on information input from the user (step S31). The TPC control unit 1102 stores the set first clear sky level in the storage unit 1104.

  The TPC control unit 1102 sets the second clear sky level for the transmission device 12 based on information input from the user (step S32). The TPC control unit 1102 stores the set second clear sky level in the storage unit 1104.

  The TPC control unit 1102 sets an initial value for the spare device 13 (step S33). Here, the initial value is set to the first clear sky level, the second clear sky level, or a value expected to be stable.

  When the settings for the transmission apparatuses 11 and 12 and the standby apparatus 13 are completed, the TPC control unit 1102 performs a transmission system switching check process (step S34).

  When the transmission system switching check process is completed, the TPC control unit 1102 performs the TPC process (step S35). When the TPC process is completed, the TPC control unit 1102 moves the process to step S34. The TPC control unit 1102 repeats the processing of step S34 and step S35, for example, at a cycle of several ms.

  FIG. 4 is a flowchart illustrating an example of transmission system switching check processing performed by the TPC control unit 1102 illustrated in FIG.

  First, the TPC control unit 1102 determines whether transmission system switching has occurred (step S41). That is, the TPC control unit 1102 determines whether there is a notification from the monitoring unit 1101. If there is a notification from the monitoring unit 1101 (Yes in step S41), the TPC control unit 1102 determines that transmission system switching has occurred, and determines whether or not the switching is switching from the transmission device 11 to the standby device 13. Judgment is made (step S42). If there is no notification from the monitoring unit 1101 (No in step S41), the TPC control unit 1102 ends the process.

  In step S42, when the switching is switching from the transmission device 11 to the standby device 13 (Yes in step S42), the TPC control unit 1102 reads the first clear sky level from the storage unit 1104. The TPC control unit 1102 sets the set value of the attenuator 1121 stored as the read first clear sky level for the attenuator 1311 of the standby device 13 (step S43). When the switching is not switching from the transmission device 11 to the standby device 13 (No in step S42), the TPC control unit 1102 determines whether the switching is switching from the transmission device 12 to the standby device 13 (step S44). ). When the switching is switching from the transmission device 12 to the standby device 13 (Yes in step S44), the TPC control unit 1102 reads the second clear sky level from the storage unit 1104. The TPC control unit 1102 sets the set value of the attenuator 1221 stored as the read second clear sky level in the attenuator 1311 of the standby device 13 (step S45). If the switching is not switching from the transmission device 12 to the standby device 13 (No in step S44), the TPC control unit 1102 ends the process.

  FIG. 5 is a flowchart showing an example of the TPC process performed by the TPC control unit 1102 shown in FIG.

  First, the TPC control unit 1102 determines whether or not the TPC process is in the auto mode (step S51). When the TPC process is in the auto mode (Yes in step S51), the TPC control unit 1102 determines whether the TPC process can be performed (step S52). When the TPC process is not in the auto mode, that is, when the TPC process is in the off mode (No in step S51), the TPC control unit 1102 ends the process.

  In step S52, when the TPC process can be performed (Yes in step S52), the TPC control unit 1102 performs the TPC process (step S53). That is, the TPC control unit 1102 transmits a first control signal to the transmission device 11 and transmits a second control signal to the transmission device 12. When the transmission system is switched to the spare device 13, the TPC control unit 1102 outputs the control signal transmitted to the switching source to the spare device 13.

  As described above, in the first embodiment, when the signal output source is switched from the transmission device 11 or the transmission device 12 to the standby device 13, the TPC control unit 1102 sets the setting value for the switching source attenuator as the standby device. 13 is set. As a result, the TPC control unit 1102 can switch the output of the transmission signal from the transmission device 11 to the standby device 13 or can switch the output of the transmission signal from the transmission device 12 to the standby device 13.

  Therefore, according to the satellite communication device according to the first embodiment, it is possible to suppress an increase in device scale and cost while configuring a redundant configuration for each independent transmission device having a different clear sky level.

  In the first embodiment, the case where the satellite communication device includes the transmission devices 11 and 12 and the standby device 13 has been described as an example. However, it is not limited to this. The satellite communication device may include three or more transmission devices. The satellite communication device may include two or more spare devices. However, the spare device is shared by two or more transmission devices as a switching destination of the transmission device. Therefore, the maximum number of spare devices mounted in the satellite communication device is n-1 when n transmission devices are provided.

(Second Embodiment)
FIG. 6 is a block diagram illustrating a functional configuration of the satellite communication device according to the second embodiment. The satellite communication apparatus shown in FIG. 1 includes transmission apparatuses 21 and 22, a spare apparatus 23, a switch 14, an output solid circuit 15, a transmission / reception antenna 16, an amplifier (LNC) 17, a distributor 18, a beacon receiver 19, and a control apparatus 24. It comprises.

  The transmission device 21 includes a modulation unit 111, a frequency conversion unit (U / C) 211, a TPC processing unit 212, and a power amplification unit (SSPA) 113.

  The TPC processing unit 212 stores the first clear sky level for the transmission device 21. Here, the first clear sky level is the reception level strength of the beacon signal at the time of fine weather.

  The TPC processing unit 212 receives the signal frequency-converted by the frequency conversion unit 211. When receiving the reception level information output from the control device 24, the TPC processing unit 212 receives the reception level obtained from the reception level information and the reception level held as the first clear sky level set in the own device. And the amount of change in reception level is calculated. The TPC processing unit 212 calculates the transmission level correction amount of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC processing unit 212 adjusts the output level of the own apparatus so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated correction amount. The TPC processing unit 212 stores the set value of its own device and outputs it to the control device 24.

  The transmission device 22 includes a modulation unit 121, a frequency conversion unit (U / C) 221, a TPC processing unit 222, and a power amplification unit (SSPA) 123.

  The TPC processing unit 222 stores the second clear sky level for the transmission device 22. The second clear sky level is the reception level strength of the beacon signal in fine weather.

  The TPC processing unit 222 receives the signal frequency-converted by the frequency conversion unit 221. When receiving the reception level information output from the control device 24, the TPC processing unit 222 receives the reception level obtained from the reception level information and the reception level held as the second clear sky level set in the own device. And the amount of change in reception level is calculated. The TPC processing unit 222 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC processing unit 222 adjusts the output level of the own apparatus so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated correction amount. The TPC processing unit 222 stores the set value of its own device and outputs it to the control device 24.

  The spare device 23 forms a redundant configuration for the transmission device 21 or the transmission device 22. The spare device 23 is connected to the modulation unit 111 or the modulation unit 121 via the switch 14. The standby device 23 includes a frequency conversion unit (U / C) 231, a TPC processing unit 232, and a power amplification unit (SSPA) 132.

  When receiving the reception level information from the control device 24 after the first clear sky level is set from the control device 24, the TPC processing unit 232 sets the reception level obtained from the reception level information and the own device. The reception level held as the first clear sky level is compared, and the amount of change in the reception level is calculated. The TPC processing unit 232 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC processing unit 232 adjusts the output level of the own apparatus so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated correction amount.

  Further, when the reception level information is received from the control device 24 after the second clear sky level is set from the control device 24, the TPC processing unit 232 sets the reception level obtained from the reception level information and the own device. The received level held as the second clear sky level is compared, and the amount of change in the received level is calculated. The TPC processing unit 232 calculates the correction amount of the transmission level of the transmission signal so that the calculated change amount is corrected as the transmission level. Then, the TPC processing unit 232 adjusts the output level of the own apparatus so that the transmission signal is transmitted from the transmission / reception antenna 16 at a level corrected by the calculated correction amount.

  The TPC processing unit 232 stores the set value of its own device and outputs it to the control device 24.

  Each of the TPC processing unit 212, the TPC processing unit 222, and the TPC processing unit 232 independently checks whether the satellite transmission device can perform the TPC processing.

  Further, the TPC processing unit 212, the TPC processing unit 222, and the TPC processing unit 232 stop the TPC process when there is a notification from the TPC control unit 241 that an abnormality has occurred in the beacon receiver 19.

  FIG. 7 is a block diagram showing a functional configuration of the control device 24 shown in FIG. The control device 24 shown in FIG. 7 includes, for example, a CPU and a storage area for programs and data for the CPU to execute processing such as ROM and RAM. The control device 24 realizes the monitoring unit 1101 and the TPC control unit 241 by causing the CPU to execute a program. The control device 24 includes a monitor 1103 and a storage unit 242.

  The storage unit 242 stores the first clear sky level for the transmission device 21 and the second clear sky level for the transmission device 22. Here, the first clear sky level is the reception level strength of the beacon signal at the time of fine weather. The second clear sky level is the strength of the reception level of the beacon signal in fine weather. In addition, the storage unit 242 stores setting values of the TPC processing units 212, 222, and 232 for realizing the first or second clear sky level. Note that the first clear sky level and the second clear sky level may be different values or the same value.

  When receiving the reception level information of the beacon signal from the beacon receiver 19, the TPC control unit 241 outputs the reception level information to the TPC processing unit 212 and / or the TPC processing unit 222.

  When receiving a notification from the monitoring unit 1101 that the signal output is switched from the transmission device 21 to the standby device 23, the TPC control unit 241 reads the first clear sky level from the storage unit 242. The TPC control unit 241 sets the reception level strength stored as the read first clear sky level in the TPC processing unit 232 of the standby device 23.

  When receiving a notification from the monitoring unit 1101 that the signal output is switched from the transmission device 22 to the standby device 23, the TPC control unit 241 reads the second clear sky level from the storage unit 242. The TPC control unit 241 sets the reception level strength stored as the read second clear sky level in the TPC processing unit 232 of the standby device 23. After the setting to the spare device 23 is completed, the TPC control unit 241 outputs the reception level information of the beacon signal from the beacon receiver 19 to the TPC processing unit 232.

  When the TPC control unit 241 determines that an abnormality has occurred in the beacon receiver 19, the TPC control unit 241 notifies the information to the TPC processing unit 212, the TPC processing unit 222, and the TPC processing unit 232, and each processing unit stops the TPC processing. To do. Specifically, the beacon receiver 19 cannot normally perform signal communication with the TPC control unit 241, the reception level detection operation in the beacon receiver 19 is abnormal, the reception level detected by the beacon receiver 19 Is at least one of the preset maximum value and the reception level detected by the beacon receiver 19 is lower than the preset minimum value, the TPC control unit 241 It is determined that an abnormality has occurred in the receiver 19, and the information is notified to the TPC processing unit 212, the TPC processing unit 222, and the TPC processing unit 232.

  Next, the operation of the control device 24 of the satellite communication apparatus having the above configuration will be described. FIG. 8 is a diagram illustrating an example of a flowchart when the control device 24 illustrated in FIG. 7 performs the transmission system switching check process and the TPC process.

  First, the TPC control unit 241 of the control device 24 sets the first clear sky level for the transmission device 21 based on information input from the user (step S81). The TPC control unit 241 stores the set first clear sky level in the storage unit 242.

  The TPC control unit 241 sets the second clear sky level for the transmission device 22 based on information input from the user (step S82). The TPC control unit 241 stores the set second clear sky level in the storage unit 242.

  The TPC control unit 241 sets an initial value for the spare device 23 (step S83).

  When the settings for the transmission devices 21 and 22 and the standby device 23 are completed, the TPC control unit 241 performs a transmission system switching check process (step S84). When the transmission system switching check process is completed, the TPC control unit 241 performs the TPC process (step S85). When the TPC process is completed, the TPC control unit 241 shifts the process to step S84. The TPC control unit 241 repeats the processes of step S84 and step S85, for example, every several ms.

  FIG. 9 is a flowchart illustrating an example of a transmission system switching check process performed by the TPC control unit 241 illustrated in FIG.

  First, the TPC control unit 241 determines whether transmission system switching has occurred (step S91). That is, the TPC control unit 241 determines whether there is a notification from the monitoring unit 1101. When there is a notification from the monitoring unit 1101 (Yes in step S91), the TPC control unit 241 determines that transmission system switching has occurred, and determines whether or not the switching is switching from the transmission device 21 to the standby device 23. Judgment is made (step S92). If there is no notification from the monitoring unit 1101 (No in step S91), the TPC control unit 241 ends the process.

  In step S92, when the switching is switching from the transmission device 21 to the standby device 23 (Yes in step S92), the TPC control unit 241 reads the first clear sky level from the storage unit 242. The TPC control unit 241 sets the read first clear sky level for the TPC processing unit 232 of the standby device 23 (step S93). When the switching is not switching from the transmission device 21 to the spare device 23 (No in step S92), the TPC control unit 241 determines whether or not the switching is switching from the transmission device 22 to the spare device 23 (step S94). ). When the switching is switching from the transmission device 22 to the standby device 23 (Yes in step S94), the TPC control unit 241 reads the second clear sky level from the storage unit 242. The TPC control unit 241 sets the read second clear sky level for the TPC processing unit 232 of the standby device 23 (step S95). When the switching is not switching from the transmission device 22 to the standby device 23 (No in step S94), the TPC control unit 241 ends the process.

  FIG. 10 is a flowchart illustrating an example of the TPC process performed by the TPC processing units 212, 222, and 232 illustrated in FIG. Here, the processing unit 212 will be described as a representative.

  First, the TPC processing unit 212 determines whether or not the TPC processing is in the auto mode (step S101). When the TPC process is in the auto mode (Yes in step S101), the TPC processing unit 212 determines whether the TPC process can be performed (step S102). If the TPC process is not in the auto mode, that is, if the TPC process is in the off mode (No in step S101), the TPC processing unit 212 ends the process.

  In step S102, when the TPC process can be performed (Yes in step S102), the TPC processing unit 212 performs the TPC process (step S103). That is, the TPC processing unit 212 adjusts the transmission level of the transmission signal based on the reception level information output from the TPC control unit 241.

  As described above, in the second embodiment, when the signal output source is switched from the transmission device 21 or the transmission device 22 to the spare device 23, the TPC control unit 241 clears the TPC processing unit set as the switching source. The sky level is set for the spare device 23. As a result, the TPC control unit 241 can switch the output of the transmission signal from the transmission device 21 to the standby device 23, or can switch the output of the transmission signal from the transmission device 22 to the backup device 23.

  Therefore, according to the satellite communication device according to the second embodiment, it is possible to suppress an increase in device scale and cost while building a redundant configuration for each independent transmission device having a different clear sky level.

  In the second embodiment, the case where the satellite communication device includes the transmission devices 21 and 22 and the standby device 23 has been described as an example. However, it is not limited to this. The satellite communication device may include three or more transmission devices. The satellite communication device may include two or more spare devices. However, the spare device is shared by two or more transmission devices as a switching destination of the transmission device. Therefore, the maximum number of spare devices mounted in the satellite communication device is n-1 when n transmission devices are provided.

  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.

  DESCRIPTION OF SYMBOLS 11 ... Transmitter, 111 ... Modulator, 112 ... Frequency converter, 1121 ... Attenuator, 113 ... Power amplifier, 12 ... Transmitter, 121 ... Modulator, 122 ... Frequency converter, 1221 ... Attenuator, 123 ... Power amplifier , 13 ... Preliminary device, 131 ... Frequency converter, 1311 ... Attenuator, 132 ... Power amplifier, 14 ... Switch, 15 ... Output solid circuit, 151 ... Switch, 152 ... Coupler, 16 ... Transmitting and receiving antenna, 17 ... Amplifier, 18 ... Distributor, 19 ... Beacon receiver, 110 ... Control device, 1101 ... Monitoring unit, 1102 ... TPC control unit, 1103 ... Monitor, 1104 ... Storage unit, 21 ... Transmitting device, 211 ... Frequency conversion unit, 212 ... TPC processing unit, 22 ... transmitting device, 221 ... frequency converting unit, 222 ... TPC processing unit, 23 ... spare device, 231 ... frequency converting , 232 ... TPC processor, 24 ... controller, 241 ... TPC control unit, 242 ... storage unit

Claims (5)

A first modulation unit that modulates a signal in accordance with a preset first modulation method and a frequency of a signal output from the first modulation unit are converted and set based on a first clear sky level. first and the first transmission device Ru comprising a first frequency converter for attenuating the output level of the signal attenuation amount that,
A second modulation unit that modulates a signal in accordance with a second modulation method different from the first modulation method, a frequency of a signal output from the second modulation unit, and a second clear sky level a second frequency conversion section for attenuating the output level of the signal at the second attenuation and the second transmission device Ru comprising a set based on,
A storage unit for storing the first and second attenuation amounts;
A spare device comprising a third frequency conversion unit for converting the frequency of the input signal and attenuating the output level of the input signal by an attenuator capable of adjusting the attenuation amount ;
The occurrence of an abnormality in the first and second transmission devices is monitored, and when an abnormality occurs in the first transmission device, the output destination of the signal output from the first modulation unit to the spare device A monitoring unit that switches an output destination of a signal output from the second modulation unit to the spare device when an abnormality occurs in the second transmission device, and
When the output destination of the signal output from the first modulation unit is switched to the standby device, the attenuation amount of the attenuator of the standby device is set to the first attenuation amount stored in the storage unit, Control for setting the attenuation amount of the attenuator of the auxiliary device to the second attenuation amount stored in the storage unit when the output destination of the signal output from the second modulation unit is switched to the auxiliary device satellite communication apparatus comprising a part. The storage unit further stores the first and second clear sky levels,
The control unit, when the output destination of the signal output from the first modulation unit is switched to the spare device, the first attenuation amount set in the attenuator of the spare device, When the output destination of the signal that is adjusted based on the first clear sky level and is output from the second modulation unit is switched to the spare device, the first device set in the attenuator of the spare device 2. The satellite communication device according to claim 1 , wherein an attenuation amount of 2 is adjusted based on the second clear sky level, and the adjusted attenuation amount is stored in the storage unit. A first modulation unit that modulates a signal in accordance with a preset first modulation scheme, a first frequency conversion unit that converts the frequency of a signal output from the first modulation unit, reception level information, A first TPC (Transmission Power Control) processing unit that adjusts the output level of the signal output from the first frequency conversion unit by comparing the reception level for the first clear sky level. A transmission device of
A second modulation unit that modulates a signal in accordance with a second modulation method different from the first modulation method, a second frequency conversion unit that converts a frequency of a signal output from the second modulation unit, A second TPC processing unit that adjusts an output level of a signal output from the second frequency conversion unit by comparing the reception level information with a reception level for a second clear sky level; Two transmitters;
A storage unit for storing a reception level for the first clear sky level and a reception level for the second clear sky level;
A signal output from the third frequency converter by comparing the reception level information with the reception level for the set clear sky level, the third frequency converter that converts the frequency of the input signal A spare device comprising a third TPC processing unit for adjusting the output level of
The occurrence of an abnormality in the first and second transmission devices is monitored, and when an abnormality occurs in the first transmission device, the output destination of the signal output from the first modulation unit to the spare device A monitoring unit that switches an output destination of a signal output from the second modulation unit to the spare device when an abnormality occurs in the second transmission device, and
When the reception level information is output to the first and second TPC processing units and the backup device, and the output destination of the signal output from the first modulation unit is switched to the backup device, When the reception level for the first clear sky level is set in the third TPC processing unit, and the output destination of the signal output from the second modulation unit is switched to the spare device, the third And a control device for setting a reception level for the second clear sky level in the TPC processing unit . A first modulation unit that modulates a signal in accordance with a preset first modulation method and a frequency of a signal output from the first modulation unit are converted and set based on a first clear sky level. Storing the first attenuation amount set in the first transmission device including a first frequency conversion unit that attenuates the output level of the signal with the first attenuation amount,
A second modulation unit that modulates a signal in accordance with a second modulation method different from the first modulation method, a frequency of a signal output from the second modulation unit, and a second clear sky level The second attenuation amount set in the second transmission device including a second frequency conversion unit that attenuates the output level of the signal by the second attenuation amount set based on Remember,
Monitoring occurrence of anomalies in the first and second transmitters;
When an abnormality occurs in the first transmitter, the output destination of the signal output from the first modulation unit is converted to the frequency of the input signal, and the output level of the input signal is attenuated. Is switched to a spare device having a third frequency conversion unit for attenuating the frequency with an adjustable attenuator,
Set the attenuation amount of the attenuator of the preliminary device to the first attenuation amount stored in the storage unit,
When an abnormality occurs in the second transmission device, the output destination of the signal output from the second modulation unit is switched to the spare device,
A transmission power control method for setting an attenuation amount of an attenuator of the standby device to a first attenuation amount stored in the storage unit . Storing the reception level for the first clear sky level and the reception level for the second clear sky level in the storage unit;
Output reception level information
A first modulation unit that modulates a signal in accordance with a preset first modulation scheme; a first frequency conversion unit that converts a frequency of a signal output from the first modulation unit; and the reception level information, A first TPC (Transmission Power Control) processing unit that adjusts the output level of the signal output from the first frequency conversion unit by comparing the reception level with respect to the first clear sky level. Monitor the occurrence of an abnormality in the transmitter 1
A second modulation unit that modulates a signal in accordance with a second modulation method different from the first modulation method, a second frequency conversion unit that converts a frequency of a signal output from the second modulation unit, A second TPC processing unit that adjusts an output level of a signal output from the second frequency conversion unit by comparing the reception level information with a reception level for a second clear sky level; 2 to monitor the occurrence of an abnormality in the transmitter
When an abnormality occurs in the first transmission device, the output destination of the signal output from the first modulation unit, a third frequency conversion unit that converts the frequency of the input signal, reception level information, Switching to a spare device comprising a third TPC processing unit for adjusting the output level of the signal output from the third frequency conversion unit by comparing the reception level for the set clear sky level,
Outputting the reception level information to the spare device;
Set the reception level for the first clear sky level in the third TPC processing unit,
When an abnormality occurs in the second transmission device, the output destination of the signal output from the second modulation unit is switched to the spare device,
Outputting the reception level information to the spare device;
A transmission power control method for setting a reception level for the second clear sky level in the third TPC processing unit .

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