JPH11234186A - Satellite-mounted receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the received signal of a second antenna from being influenced by a third received signal by providing a first omnidirectional antenna to be mounted on an earth facing side, a second non-directional antenna and a direction-controllable directional antenna to be mounted to a side opposite to the earth, a switch provided with four ports to mutually switch two circuits and two wave combiner. SOLUTION: A 'C' switch 12 is in the state of connecting a directional antenna 7 to a receiver 11a and a second non-directional antenna 6 to a receiver 11b. A received signal at a first non-directional antenna 5 is distributed into two by a branching filter (HYB) 13 through a diplexer(DIP) 8c and one output is put together with the received signal of the antenna 7 by a wave combiner 14a to be inputted to a receiving part 11a. The outer output is put together with the received signal of the antenna 6 by a wave combiner 14b to be inputted to a receiving part 11b. The received signals of the antennas 6 and 7 are inputted to the receiving parts without being put together.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an improvement in a receiver mounted on a satellite.

[0002]

2. Description of the Related Art A conventional receiver mounted on a satellite will be described with reference to FIG. In the figure, 1 is the earth, 2 is a satellite orbiting the earth 1 in a low orbit, 3 is a relay satellite in geosynchronous orbit and communicating with the satellite 2, 4 is the satellite 2,
And an earth station that communicates with the relay satellite 3. Numeral 5 is an antenna used for directly communicating with the earth station 4. This antenna has a wide beam width, so that it is not necessary to control the direction of the antenna beam B1 toward the earth station 4.
An omni-directional antenna with a small antenna gain mounted on the earth-facing surface of the satellite 2. Reference numeral 6 denotes an antenna used for communicating with the relay satellite 3, and this antenna
Since the beam width is wide, it is not necessary to control the directivity of the antenna beam B2 toward the relay satellite 3, and the omnidirectional antenna has a small antenna gain and is mounted on the anti-earth directing surface of the satellite 2. Reference numeral 7 denotes an antenna used for communicating with the relay satellite 3. Since the antenna has a narrow beam width, for example, the antenna relative to the relay satellite 3 is determined by a control device (not shown) mounted on the satellite 2. It is necessary to control the pointing of the antenna beam B3 toward the relay satellite 3 by driving the antenna by an antenna driving mechanism (not shown) based on the direction.
This is a directional antenna with a large antenna gain mounted on the anti-earth directing surface. The omnidirectional antenna 5, the omnidirectional antenna 6, and the directional antenna 7 are mainly used for communication for tracking and controlling the satellite 2. The tracking and control of the satellite 2 using the omni-directional antenna 5 includes: receiving the tracking and control signal transmitted from the earth station 4 by the omni-directional antenna 5; The tracking / control signal transmitted from the earth station 4 is received by the earth station 4.

[0003] Tracking and control of the satellite 2 using the omni-directional antenna 6 transmits a tracking and control signal of the satellite 2 from the earth station 4 to the relay satellite 3 and transmits from the relay satellite 3. Receiving the tracking / control signal of the satellite 2 by the omni-directional antenna 6;
Is transmitted from the omnidirectional antenna 6 to the relay satellite 3 and the earth station 4 receives the tracking / control signal of the satellite 2 transmitted from the relay satellite 3. . The tracking and control of the satellite 2 using the directional antenna 7 is performed by transmitting a tracking and control signal of the satellite 2 from the earth station 4 to the relay satellite 3 and transmitting the satellite from the relay satellite 3 Receiving the tracking / control signal of the satellite 2 with the directional antenna 7;
Is transmitted from the directional antenna 7 to the relay satellite 3, and the earth station 4 receives the tracking / control signal of the satellite 2 transmitted from the relay satellite 3. Since the directional antenna 7 is a directional antenna, the gain is higher than that of the omnidirectional antenna 6,
Since communication at a high data rate is possible and communication with the relay satellite 3 in geosynchronous orbit is possible, a communication area is wider than that of the earth station 4. Therefore, in tracking and control of the satellite 2 in a stationary state, tracking and control using the directional antenna 7 is performed. The omnidirectional antenna 6 can perform only low data rate communication because the antenna gain is small.
Since there is no need to perform directivity control in the direction, communication with the relay satellite 3 is ensured. Therefore, when communication using the directional antenna 7 cannot be performed for some reason,
At the time of contingency of the satellite 2, tracking and control using the omnidirectional antenna 6 are performed. In addition, tracking and control of the satellite 2 using the omnidirectional antenna 5, the omnidirectional antenna 6, and the directional antenna 7 simultaneously are not performed.

Next, details of the operation will be described with reference to FIG. In FIG. 5, 2 to 7 are the same as in FIG. 8 is a diplexer for demultiplexing the transmission / reception signal of the antenna,
8a is a diplexer for demultiplexing the transmission / reception signal of the directional antenna 7, 8b is a diplexer for demultiplexing the transmission / reception signal of the omnidirectional antenna 6, and 8c is a diplexer for demultiplexing the transmission / reception signal of the omnidirectional antenna 5. is there. Reference numeral 9 denotes a multiplexer for combining the reception signal of the directional antenna 7 output from the diplexer 8a with the reception signal of the omnidirectional antenna 5 output from the diplexer 8c. A combiner that combines the combined wave of the output signals of the omnidirectional antenna 5 and the directional antenna 7 and the received signal of the omnidirectional antenna 6 output from the diplexer 8b and distributes the combined signal into two. is there.
11a and 11b are a receiving section of the master transceiver and a receiving section of the slave transceiver, respectively. The receiving section 11a of the transceiver and the receiving section 11b of the transceiver are each provided with the multiplexer. Since a composite wave of the reception signals of the omnidirectional antenna 5, the omnidirectional antenna 6, and the directional antenna 7 output from the receiver 10 is input, it is always turned on, and one of the receivers 11 of the transceiver is connected. Even if the unit fails, the receiving unit 11 of another transceiver can receive a signal. Therefore, in the receiving system of the conventional onboard satellite transceiver, the received signals of the omnidirectional antenna 5, the omnidirectional antenna 6, and the directional antenna 7 are combined as in the multiplexer 10, A multiplexer that outputs signals to the main system and the slave system of the receiving unit 11 of the transceiver is used. Here, the omnidirectional antenna 5
In the tracking and control of the satellite 2 using the above, the received signal of the omnidirectional antenna 5 is separated into a transmission signal and a reception signal by the diplexer 8c. The reception signal of the omnidirectional antenna 5 output from the diplexer 8c is combined with the reception signal of the directional antenna 7 output from the diplexer 8a by the multiplexer 9, and further combined with the multiplexer 1
At 0, the signal is combined with the reception signal of the omnidirectional antenna 6 output from the diplexer 8b.

However, the omnidirectional antenna 6 and
Since the directional antenna 7 is mounted on the anti-earth directing surface of the satellite 2, it does not receive a signal from the earth station 4. Therefore, a signal input to the multiplexer 10 is a reception signal of the omnidirectional antenna 5, and a signal input to the receiver 11a of the transceiver and the receiver 11b of the transceiver is Signal of the directional antenna 5. In tracking and controlling the satellite 2 using the directional antenna 7, the received signal of the directional antenna 7 is transmitted and received by the diplexer 8a. The reception signal of the directional antenna 7 output from the diplexer 8a is combined with the reception signal of the omnidirectional antenna 5 output from the diplexer 8c by the multiplexer 9, and Diplexer 8b
Are combined with the reception signal of the omnidirectional antenna 6 output from. However, since the omni-directional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Since the antenna is a high-gain antenna and the pointing is controlled in the direction of the relay satellite 3, the reception signal of the directional antenna 7 is larger than the reception signal of the omni-directional antenna 6. Therefore, the multiplexer 1
A signal input to 0 becomes a reception signal of the directional antenna 7, and a signal input to the receiver 11a of the transceiver and the receiver 11b of the transceiver becomes a reception signal of the directional antenna 7. .

[0006]

However, in the conventional receiver mounted on a satellite, when tracking and controlling the satellite 2 using the omni-directional antenna 6, the reception of the omni-directional antenna 6 is performed. The transmission / reception signal is demultiplexed by the diplexer 8b. The received signal of the omni-directional antenna 6 output from the diplexer 8b is the reception signal of the omni-directional antenna 5 and the directional antenna 7 output from the multiplexer 9 by the multiplexer 10. The signal is combined with the combined wave and input to the receiver 11a of the transceiver and the receiver 11b of the transceiver. Since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2,
No signal is received from the relay satellite 3. However, the directional antenna 7 is similar to the omnidirectional antenna 6,
Since the antenna is mounted on the anti-earth directing surface of the satellite 2, when the antenna beam of the directional antenna 7 coincides with the direction of the relay satellite 3, a signal from the relay satellite 3 is received. If the antenna beam of the directional antenna 7 is slightly deviated from the direction of the relay satellite 3, the power of the reception signals of the omnidirectional antenna 6 and the directional antenna 7 input to the multiplexer 10 is reduced. When the signals become equal and the phase difference between the two signals becomes 180 degrees, the input signals are combined in a vector in the multiplexer 10, so that no signal is output from the multiplexer 10, and Part 11a
Therefore, no signal is input to the receiver 11b of the transceiver. This means that communication for tracking and controlling the satellite 2 is temporarily interrupted, and there is a problem that the tracking and control of the satellite 2 is affected.

[0007] This problem can be solved by controlling the beam of the directional antenna 7 so that it does not coincide with the direction of the relay satellite 3 when communicating using the omnidirectional antenna 6. The communication using the directional antenna 6 is used when the communication using the directional antenna 7 cannot be performed for some reason, or when the satellite 2 is used for contingency. In practice, it is difficult to control the beam so that it does not coincide with the direction of the relay satellite 3.

[0008] This is also solved by making the phase of the received signal of the directional antenna 7 and the phase of the received signal of the non-directional antenna 6 always coincide with each other in the multiplexer 10. However, in this case, in the multiplexer 10, it is necessary to always measure the phases of the reception signals of the directional antenna 7 and the omnidirectional antenna 6 and control the phase with a phase shifter or the like. It's complicated and unrealistic.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and a reception signal of an omni-directional antenna mounted on an anti-earth directing surface of a satellite is transmitted to an anti-earth directing surface of the satellite. Providing stable communication when using a non-directional antenna mounted on the anti-earth-facing surface of the satellite to communicate with a relay satellite by using a receiver mounted on a satellite that is not affected by the received signal of the mounted directional antenna Is what you do.

[0010]

According to a first aspect of the present invention, there is provided a receiving device for mounting on a satellite, which is used for directly communicating with an earth station, and includes a first omnidirectional antenna mounted on an earth-facing surface of a satellite; A second omni-directional antenna used to communicate with the satellite relay and mounted on the anti-earth facing surface of the satellite, and an antenna used to communicate with the relay satellite and mounted on the satellite anti-earth facing surface A directional antenna capable of directing a beam in the direction of a relay satellite, having four ports, connecting a first port to a second port, and connecting a third port to a fourth port, or A first port and a fourth port,
And two connection states for connecting the second port and the third port can be switched, and the first port is connected to the directional antenna, and the third port is connected to the second omni-directional antenna. A connected switch, a first diplexer connected to a second port of the switch and splitting the second omni-directional antenna or the transmission / reception signal of the directional antenna, and a fourth diplexer of the switch. A second diplexer connected to a port for demultiplexing a transmission / reception signal of the second omnidirectional antenna or the directional antenna, and a third diplexer for demultiplexing a transmission / reception signal of the first omnidirectional antenna A diplexer, and the second omnidirectional antenna output from the first diplexer;
Alternatively, a reception unit of a first transceiver to which a reception signal of the directional antenna is input, and the second omni-directional antenna or a reception signal of the directional antenna output from the second diplexer , A receiving section of a second transceiver, a duplexer for splitting the received signal of the first omni-directional antenna output from the third diplexer into two, and an output from the splitter. A first multiplexer that combines the received signal of the first omnidirectional antenna with the received signal of the second omnidirectional antenna or the directional antenna output from the first diplexer And receiving the received signal of the first omnidirectional antenna output from the duplexer, the second signal output from the second diplexer.
Omni-directional antenna, or a second multiplexer for combining the received signal with the directional antenna.

A receiver for on-board satellite according to a second aspect of the present invention is used for directly communicating with an earth station, and for communicating with a first omni-directional antenna mounted on the earth-facing surface of a satellite and a relay satellite. And a second omnidirectional antenna mounted on the anti-earth-facing surface of the satellite, and an antenna beam used for communicating with the relay satellite and mounted on the anti-earth-facing surface of the satellite in the direction of the relay satellite. A directional antenna capable of directivity control, a first diplexer for demultiplexing a transmission / reception signal of the directional antenna, a second diplexer for demultiplexing a transmission / reception signal of the second omnidirectional antenna, A third diplexer for demultiplexing the transmission / reception signal of the omni-directional antenna, and having four ports, connecting the first port to the second port, and connecting the third port to the fourth port;
Alternatively, two connection states for connecting the first port to the fourth port and the second port to the third port can be switched, and the first port outputs the reception signal of the directional antenna. A switch connected to an output end of the first diplexer, and a third port connected to an output end of the second diplexer from which a reception signal of the second omnidirectional antenna is output. Second
And the second omni-directional antenna or the first signal to which the reception signal of the directional antenna is input.
A receiving unit of the transceiver, and a receiving unit of the second transceiver, which is connected to a fourth port of the switch and receives a second omnidirectional antenna or a reception signal of the directional antenna, A duplexer that divides the received signal of the first omnidirectional antenna output from the third diplexer into two, and a received signal of the first omnidirectional antenna output from the duplexer. The second omnidirectional antenna output from a second port of the switch, or a first multiplexer that combines the received signal of the directional antenna, and the second multiplexer output from the duplexer. A second multiplexer for combining a reception signal of one omnidirectional antenna with a second omnidirectional antenna output from a fourth port of the switch or a reception signal of the directional antenna. It is provided.

A receiver for on-board satellite according to a third aspect of the present invention is used for directly communicating with an earth station, and for communicating with a first omni-directional antenna mounted on an earth-facing surface of a satellite and a relay satellite. And a second omnidirectional antenna mounted on the anti-earth-facing surface of the satellite, and an antenna beam used for communicating with the relay satellite and mounted on the anti-earth-facing surface of the satellite in the direction of the relay satellite. A directional antenna capable of directivity control, a first diplexer for demultiplexing a transmission / reception signal of the directional antenna, a second diplexer for demultiplexing a transmission / reception signal of the second omnidirectional antenna, A third diplexer for demultiplexing the transmission / reception signal of the omni-directional antenna, and having four ports, connecting the first port to the second port, and connecting the third port to the fourth port;
Alternatively, two connection states for connecting the first port to the fourth port and the second port to the third port can be switched, and the first port outputs the reception signal of the directional antenna. A switch connected to an output end of the first diplexer, and a third port connected to an output end of the second diplexer from which a reception signal of the second omnidirectional antenna is output. Second
And the second omni-directional antenna or the first signal to which the reception signal of the directional antenna is input.
A receiving unit of the transceiver, and a receiving unit of the second transceiver, which is connected to a fourth port of the switch and receives a second omnidirectional antenna or a reception signal of the directional antenna, A duplexer that divides the received signal of the first omnidirectional antenna output from the third diplexer into two, and a received signal of the first omnidirectional antenna output from the duplexer. A first multiplexer for combining the reception signal of the directional antenna output from the first diplexer with the reception signal of the first omnidirectional antenna output from the duplexer; And a second multiplexer for combining the received signal of the second omnidirectional antenna output from the diplexer.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 is a block diagram showing Embodiment 1 of the present invention, in which 2 is a satellite orbiting the earth in a low orbit, 3 is a relay satellite in geosynchronous orbit and communicating with the satellite 2, and 4 is The earth station communicates with the satellite 2 and the relay satellite 3. Numeral 5 is used for direct communication with the earth station 4. Since the beam width is wide, it is not necessary to control the direction of the antenna beam toward the earth station 4, and the antenna gain mounted on the earth-directing surface of the satellite 2 is small. It is an omnidirectional antenna. 6 is the relay satellite 3
Since the beam width is wide, there is no need to control the pointing of the antenna beam in the direction of the relay satellite 3,
An omnidirectional antenna with a small antenna gain mounted on the anti-earth directing surface of the satellite 2. Numeral 7 is used to communicate with the relay satellite 3, and since the beam width is narrow, it is necessary to control the pointing of the antenna beam toward the relay satellite 3, and the antenna gain mounted on the anti-earth directing surface of the satellite 2 is large. It is a directional antenna. Reference numeral 8 denotes a diplexer for separating transmission / reception signals, 8a and 8b denote transmission / reception signals of the omnidirectional antenna 6 or the directional antenna 7, and 8c denotes transmission / reception signals of the omnidirectional antenna 5. It is a diplexer that splits waves. 11a is a receiving section of the main transceiver which receives the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8a, and 11b is the omnidirectional receiver output from the diplexer 8b. Sexual antenna 6, or
It is a receiving unit of a slave transceiver that receives a reception signal of the directional antenna 7. 12 has four ports, the first
Port and the second port, and the third port and the fourth port, or the first port and the fourth port, and the second port and the third port. 2
(Circu) that can switch between two connection states
ral) switch, the first port is the directional antenna 7, the second port is the diplexer 8a, the third port
Port is connected to the omnidirectional antenna 6, and a fourth port is connected to the diplexer 8b. 13 is the omnidirectional antenna 5 output from the diplexer 8c.
Is a splitter that splits the received signal into two. 14a is a signal for combining the reception signal of the omnidirectional antenna 5 output from the duplexer 13 with the reception signal of the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8a. 14b is the duplexer 1
3 is a multiplexer that combines a reception signal of the omnidirectional antenna 5 output from the omnidirectional antenna 3 with a reception signal of the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8b.

Next, the present invention will be described in detail. In FIG. 1, the C switch 12 has a first port and a second port.
And a state in which the third port and the fourth port are connected. The reception signal of the omnidirectional antenna 5 is obtained by splitting a transmission / reception signal by the diplexer 8c, splitting the signal by the splitter 13, and splitting the signal by the multiplexer 14a.
After being combined with the reception signal of the directional antenna 7 output from the diplexer 8a, the signal is input to the receiver 11a of the transceiver, and is output from the diplexer 8b by the multiplexer 14b. After being combined with the reception signal of the directional antenna 6, the signal is input to the receiver 11b of the transceiver. Therefore, when the satellite 2 performs tracking and control using the omnidirectional antenna 5,
A composite wave of the received signals of the omni-directional antenna 5 and the directional antenna 7 is input to the receiver 11a of the transceiver, and the received signals of the omni-directional antenna 5 and the omni-directional antenna 6 The composite wave is received by the receiver 1 of the transceiver.
1b. However, since the omnidirectional antenna 6 and the directional antenna 7 are mounted on the anti-earth directing surface of the satellite 2, they do not receive signals from the earth station 4. Therefore, a signal input to the receiving unit 11a of the transceiver and the receiving unit 11b of the transceiver becomes a received signal of the omnidirectional antenna 5. The received signal of the omni-directional antenna 6 is separated into a transmission signal and a received signal of the omni-directional antenna 5 by the diplexer 8b connected via the C-switch 12, and is combined with the reception signal of the omni-directional antenna 5 by the multiplexer 14b. The combined signals are input to the receiving unit 11b of the transceiver. Therefore, the satellite 2 is connected to the omnidirectional antenna 6.
When the tracking and control are performed using, the composite wave of the omnidirectional antenna 6 and the reception signal of the omnidirectional antenna 5 is input to the receiver 11b of the transceiver.

However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11b of the transceiver becomes a reception signal of the omnidirectional antenna 6. Further, the reception signal of the directional antenna 7 is separated into a transmission signal and a reception signal by the diplexer 8a connected via the C switch 12, and is combined with the reception signal of the omnidirectional antenna 5 by the multiplexer 14a. Then, it is input to the receiving unit 11a of the transceiver.
Therefore, when the satellite 2 is performing tracking and control using the directional antenna 7, a composite wave of the reception signal of the directional antenna 7 and the reception signal of the omni-directional antenna 5 is received by the transceiver. Input to the unit 11a. However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11a of the transceiver becomes a reception signal of the directional antenna 7.

Finally, when the satellite 2 performs tracking and control using the omni-directional antenna 5, the signal received by the omni-directional antenna 5 is transmitted to the receiver 11a of the transceiver.
Is input to the receiving unit 11b of the transceiver, so that even if the receiving unit 11a of the transceiver fails, the signal is received by the omni-directional antenna 5 so that the tracking and tracking of the satellite 2 can be performed.
Control can be performed. When the satellite 2 is performing tracking and control using the omni-directional antenna 6, a signal received by the omni-directional antenna 6 is transmitted to a receiver 11 of a transceiver.
b, the receiving unit 11 of the transceiver
Even if b fails, the reception signal of the omnidirectional antenna 5 is input to the receiver 11a of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4. Thus, tracking and control of the satellite 2 can be performed. When the satellite 2 performs tracking and control using the directional antenna 7, the directional antenna 7
Even if the receiving unit 11a of the transceiver fails while the receiving signal of the transceiver is input to the receiving unit 11a of the transceiver, the omnidirectional antenna 5 and the omnidirectional antenna 6
Is received by the receiver 11b of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4, or tracking using the omni-directional antenna 6 is performed. The tracking and control of the satellite 2 can be performed by changing to the control.

Embodiment 2 FIG. FIG. 2 is a block diagram showing an embodiment of the second invention, in which 2 is a satellite orbiting the earth in a low orbit, 3 is a relay satellite in geosynchronous orbit and communicating with the satellite 2, and 4 is a satellite. An earth station that communicates with the satellite 2 and the relay satellite 3. Numeral 5 is used for direct communication with the earth station 4. Since the beam width is wide, it is not necessary to control the direction of the antenna beam toward the earth station 4, and the antenna gain mounted on the earth-directing surface of the satellite 2 is small. It is an omnidirectional antenna. Numeral 6 is used for communication with the relay satellite 3, and since the beam width is wide, it is not necessary to control the direction of the antenna beam toward the relay satellite 3, and the antenna gain mounted on the anti-earth directing surface of the satellite 2 is small. It is an omnidirectional antenna. Numeral 7 is used for communication with the relay satellite 3, and since the beam width is narrow, it is necessary to control the pointing of the antenna beam toward the relay satellite 3.
This is a directional antenna with a large antenna gain mounted on the anti-earth directing surface. Reference numeral 8 denotes a diplexer for separating transmission / reception signals, 8a denotes a diplexer for separating transmission / reception signals of the directional antenna 7, 8b denotes a diplexer for separating transmission / reception signals of the omnidirectional antenna 6, and 8c denotes the omni-directional light. This is a diplexer that separates a transmission / reception signal of the directional antenna 5. 11a is a receiving unit of the main transceiver which receives the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8a.
b denotes a receiving unit of a slave transceiver that receives a reception signal of the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8b. 12 has four ports, a first port and a second port, and
Connecting the third port to the fourth port, or connecting the first port to the fourth port, and the second port to the third port
A C switch that can switch between two connection states connecting the ports of the diplexer 8a to which a first port outputs a reception signal of the directional antenna 7.
Output terminal, the second port of the receiving unit 11 of the transceiver
a, a third port is connected to an output end of the diplexer 8b to which a reception signal of the omnidirectional antenna 6 is output, and a fourth port is connected to a reception unit 11b of the transceiver.
Reference numeral 13 denotes a duplexer that splits the reception signal of the omnidirectional antenna 5 output from the diplexer 8c into two.
14a outputs the received signal of the omnidirectional antenna 5 output from the duplexer 13 to the omnidirectional antenna 6 output from the second port of the C switch 12, or
A multiplexer 14b combines the reception signal of the directional antenna 7 with the reception signal of the omni-directional antenna 5 output from the branching filter 13.
Of the omni-directional antenna 6 or the directional antenna 7 output from a port of the multiplexor.

Next, the present invention will be described in detail. In FIG. 2, the C switch 12 has a first port and a second port.
, And the state where the third port 1 and the fourth port are connected. The received signal of the omnidirectional antenna 5 is divided into a transmission signal and a reception signal by the diplexer 8c,
After being divided into two by the splitter 13 and combined with the reception signal of the directional antenna 7 output from the second port of the C switch 12 by the multiplexer 14a, the reception unit of the transceiver 11a, and after being combined with the reception signal of the omnidirectional antenna 6 output from the fourth port of the C switch 12 by the multiplexer 14b, the reception signal is transmitted to the reception unit 11b of the transceiver. Is entered. Therefore, when the satellite 2 performs tracking and control using the omnidirectional antenna 5, the omnidirectional antenna 5
A composite wave of the reception signals of the directional antenna 7 and the directional antenna 7 is input to the receiver 11a of the transceiver, and the composite wave of the reception signals of the omnidirectional antenna 5 and the omnidirectional antenna 6 is Is input to the receiver 11b of the device. However, the omnidirectional antenna 6 and the directional antenna 7
Is mounted on the anti-earth-facing surface of the satellite 2,
No signal from the earth station 4 is received. Therefore, the receiver 11a of the transceiver and the receiver 11 of the transceiver
The signal input to b is a reception signal of the omnidirectional antenna 5. The reception signal of the omni-directional antenna 6 is divided into a transmission / reception signal by the diplexer 8b and combined with the reception signal of the omni-directional antenna 5 by the multiplexer 14b. 11b. Therefore, when the satellite 2 performs tracking and control using the omni-directional antenna 6, the composite wave of the omni-directional antenna 6 and the reception signal of the omni-directional antenna 5 is transmitted to the transceiver Is input to the receiving unit 11b.

However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11b of the transceiver becomes a reception signal of the omnidirectional antenna 6. Further, the reception signal of the directional antenna 7 is separated from the transmission / reception signal by the diplexer 8a and combined with the reception signal of the omni-directional antenna 5 by the multiplexer 14a.
is input to a. Therefore, when the satellite 2 is performing tracking and control using the directional antenna 7, a composite wave of the reception signal of the directional antenna 7 and the reception signal of the omni-directional antenna 5 is received by the transceiver. Input to the unit 11a. However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11a of the transceiver becomes a reception signal of the directional antenna 7.

Finally, when the satellite 2 performs tracking and control using the omni-directional antenna 5, the signal received by the omni-directional antenna 5 is transmitted to the receiver 11a of the transceiver.
Is input to the receiving unit 11b of the transceiver, so that even if the receiving unit 11a of the transceiver fails, the signal is received by the omni-directional antenna 5 so that the tracking and tracking of the satellite 2 can be performed.
Control can be performed. When the satellite 2 is performing tracking and control using the omni-directional antenna 6, a signal received by the omni-directional antenna 6 is transmitted to a receiver 11 of a transceiver.
b, the receiving unit 11 of the transceiver
Even if b fails, the reception signal of the omnidirectional antenna 5 is input to the receiver 11a of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4. Thus, tracking and control of the satellite 2 can be performed. When the satellite 2 performs tracking and control using the directional antenna 7, the directional antenna 7
Even if the receiving unit 11a of the transceiver fails while the receiving signal of the transceiver is input to the receiving unit 11a of the transceiver, the omnidirectional antenna 5 and the omnidirectional antenna 6
Is received by the receiver 11b of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4, or tracking using the omni-directional antenna 6 is performed. The tracking and control of the satellite 2 can be performed by changing to the control.

Embodiment 3 FIG. 3 is a block diagram showing an embodiment of the third invention, in which 2 is a satellite orbiting the earth in a low orbit, 3 is a relay satellite in geosynchronous orbit and communicating with the satellite 2, and 4 is a satellite. An earth station that communicates with the satellite 2 and the relay satellite 3. Numeral 5 is used for direct communication with the earth station 4. Since the beam width is wide, it is not necessary to control the direction of the antenna beam toward the earth station 4, and the antenna gain mounted on the earth-directing surface of the satellite 2 is small. It is an omnidirectional antenna. Numeral 6 is used for communication with the relay satellite 3, and since the beam width is wide, it is not necessary to control the direction of the antenna beam toward the relay satellite 3, and the antenna gain mounted on the anti-earth directing surface of the satellite 2 is small. It is an omnidirectional antenna. Numeral 7 is used for communication with the relay satellite 3, and since the beam width is narrow, it is necessary to control the pointing of the antenna beam toward the relay satellite 3.
This is a directional antenna with a large antenna gain mounted on the anti-earth directing surface. Reference numeral 8 denotes a diplexer for separating transmission / reception signals, 8a denotes a diplexer for separating transmission / reception signals of the directional antenna 7, 8b denotes a diplexer for separating transmission / reception signals of the omnidirectional antenna 6, and 8c denotes the omni-directional light. This is a diplexer that separates a transmission / reception signal of the directional antenna 5. 11a is a receiving unit of the main transceiver which receives the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8a.
b denotes a receiving unit of a slave transceiver that receives a reception signal of the omnidirectional antenna 6 or the directional antenna 7 output from the diplexer 8b. 12 has four ports, a first port and a second port, and
Connecting the third port to the fourth port, or connecting the first port to the fourth port, and the second port to the third port
A first switch is a C switch capable of switching between two connection states, and a first port is an output terminal of the diplexer 8a to which a reception signal of the directional antenna 7 is output, and a second port is the transceiver. Receiving section 11a,
A third port is connected to an output terminal of the diplexer 8b from which a reception signal of the omnidirectional antenna 6 is output, and a fourth port is connected to a reception unit 11b of the transceiver. 13
Is a duplexer that splits the reception signal of the omnidirectional antenna 5 output from the diplexer 8c into two. 14
a is a multiplexer that combines the reception signal of the omnidirectional antenna 5 output from the duplexer 13 with the reception signal of the directional antenna 7 output from the diplexer 8a, and 14b is the multiplexer. This is a multiplexer that combines the reception signal of the omnidirectional antenna 5 output from the demultiplexer 13 with the reception signal of the omnidirectional antenna 6 output from the diplexer 8b.

Next, the present invention will be described in detail. In FIG. 3, the C switch 12 has a first port and a second port.
And a state in which the third port and the fourth port are connected. The reception signal of the omnidirectional antenna 5 is obtained by splitting a transmission / reception signal by the diplexer 8c, splitting the signal by the splitter 13, and splitting the signal by the multiplexer 14a.
After being combined with the reception signal of the directional antenna 7 output from the diplexer 8a, the signal is input to the receiver 11a of the transceiver, and is output from the diplexer 8b by the multiplexer 14b. After being combined with the reception signal of the directional antenna 6, the signal is input to the receiver 11b of the transceiver. Therefore, when the satellite 2 performs tracking and control using the omnidirectional antenna 5,
A composite wave of the received signals of the omni-directional antenna 5 and the directional antenna 7 is input to the receiver 11a of the transceiver, and the received signals of the omni-directional antenna 5 and the omni-directional antenna 6 The composite wave is received by the receiver 1 of the transceiver.
1b. However, since the omnidirectional antenna 6 and the directional antenna 7 are mounted on the anti-earth directing surface of the satellite 2, they do not receive signals from the earth station 4. Therefore, a signal input to the receiving unit 11a of the transceiver and the receiving unit 11b of the transceiver becomes a received signal of the omnidirectional antenna 5. The reception signal of the omni-directional antenna 6 is divided into a transmission / reception signal by the diplexer 8b and combined with the reception signal of the omni-directional antenna 5 by the multiplexer 14b. 11b1. Therefore, when the satellite 2 performs tracking and control using the omnidirectional antenna 6, the omnidirectional antenna 6 and the omnidirectional antenna 5
The combined wave with the received signal of
Is input to

However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11b of the transceiver becomes a reception signal of the omnidirectional antenna 6. Further, the reception signal of the directional antenna 7 is separated from the transmission / reception signal by the diplexer 8a and combined with the reception signal of the omni-directional antenna 5 by the multiplexer 14a.
is input to a. Therefore, when the satellite 2 is performing tracking and control using the directional antenna 7, a composite wave of the reception signal of the directional antenna 7 and the reception signal of the omni-directional antenna 5 is received by the transceiver. Input to the unit 11a. However, since the omnidirectional antenna 5 is mounted on the earth-facing surface of the satellite 2, it does not receive a signal from the relay satellite 3. Therefore, a signal input to the receiver 11a of the transceiver becomes a reception signal of the directional antenna 7.

Finally, when the satellite 2 performs tracking and control using the omni-directional antenna 5, the signal received by the omni-directional antenna 5 is transmitted to the receiver 11a of the transceiver.
Is input to the receiving unit 11b of the transceiver, so that even if the receiving unit 11a of the transceiver fails, the signal is received by the omni-directional antenna 5 so that the tracking and tracking of the satellite 2 can be performed.
Control can be performed. When the satellite 2 is performing tracking and control using the omni-directional antenna 6, a signal received by the omni-directional antenna 6 is transmitted to a receiver 11 of a transceiver.
b, the receiving unit 11 of the transceiver
Even if b fails, the reception signal of the omnidirectional antenna 5 is input to the receiver 11b of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4. Thus, tracking and control of the satellite 2 can be performed. When the satellite 2 performs tracking and control using the directional antenna 7, the directional antenna 7
Even if the receiving unit 11a of the transceiver fails while the receiving signal of the transceiver is input to the receiving unit 11a of the transceiver, the omnidirectional antenna 5 and the omnidirectional antenna 6
Is received by the receiver 11b of the transceiver, so that the communication partner of the satellite 2 is changed from the relay satellite 3 to the earth station 4, or tracking using the omni-directional antenna 6 is performed. The tracking and control of the satellite 2 can be performed by changing to the control.

[0025]

According to the present invention, the signals received by the omnidirectional antenna and the directional antenna mounted on the anti-earth-facing surface of the satellite are input to the receiver of the transceiver without being synthesized. In communication with a relay satellite using an omnidirectional antenna mounted on the anti-earth directing surface, there is an effect that stable communication can be performed. Also, when communication is performed using the omnidirectional antenna mounted on the earth-facing surface of the satellite, even if one of the receivers of the transceiver fails, the omnidirectional antenna mounted on the earth-facing surface of the satellite By using as it is,
There is an effect that a signal can be received by a receiving unit of another transceiver. When communicating using the omnidirectional antenna mounted on the anti-earth facing surface of the satellite, even if one of the receivers of the transceiver fails, the omnidirectional antenna mounted on the earth facing surface of the satellite By using this, there is an effect that a signal can be received by a receiving unit of another transceiver. Further, when communication is performed using a directional antenna mounted on the earth-facing surface of the satellite, even if one of the receivers of the transceiver fails, an omnidirectional antenna mounted on the earth-facing surface of the satellite, or By using an omni-directional antenna mounted on the earth-facing surface of a satellite, there is an effect that a signal can be received by a receiver of another transceiver.

[Brief description of the drawings]

FIG. 1 is a diagram showing a first embodiment of a transmission / reception device according to the present invention.

FIG. 2 is a diagram showing a transmitting / receiving apparatus according to a second embodiment of the present invention.

FIG. 3 is a diagram showing Embodiment 3 of a transmission / reception device according to the present invention.

FIG. 4 is an explanatory diagram of a conventional technique.

FIG. 5 is a detailed explanatory diagram of a conventional technique.

[Explanation of symbols]

1 earth, 2 satellites, 3 relay satellites, 4 earth stations, 5
1st omnidirectional antenna, 6 2nd omnidirectional antenna, 7 directional antenna, 8 diplexer, 9 multiplexer, 10 multiplexer, 11 receiver of transceiver, 12 switch, 13 duplexer, 14 multiplexer.

Claims (3)

[Claims] 1. Used for communicating directly with an earth station,
A first omni-directional antenna mounted on the earth-facing surface of the satellite, and a second omni-directional antenna used for communicating with the relay satellite and mounted on the anti-earth-facing surface of the satellite; A directional antenna used for communication and capable of directing an antenna beam mounted on an anti-earth directing surface of a satellite toward a relay satellite, having four ports, a first port and a second port, and Connecting the third port and the fourth port, or the first port and the fourth port,
Also, two connection states for connecting the second port and the third port can be switched, and the first port is connected to the directional antenna, and the third port is connected to the second omni-directional antenna. And a first diplexer connected to a second port of the switch and splitting a transmission / reception signal of the second omni-directional antenna or the directional antenna, and a fourth port of the switch And a second diplexer for demultiplexing the transmission / reception signal of the second omnidirectional antenna or the directional antenna, and a third diplexer for demultiplexing the transmission / reception signal of the first omnidirectional antenna. And the second omnidirectional antenna output from the first diplexer, or a receiving unit of a first transceiver to which a reception signal of the directional antenna is input. The second omnidirectional antenna output from the second diplexer, or a receiving unit of a second transceiver to which a reception signal of the directional antenna is input, and an output from the third diplexer A duplexer that divides the received signal of the first omnidirectional antenna into two, and a received signal of the first omnidirectional antenna output from the duplexer is output from the first diplexer The second omnidirectional antenna, or a first multiplexer that combines the received signal of the directional antenna, and the received signal of the first omnidirectional antenna output from the duplexer is A receiver mounted on a satellite, comprising: a second omni-directional antenna output from a second diplexer; or a second multiplexer for combining a received signal of the directional antenna. 2. Used for communicating directly with an earth station,
A first omni-directional antenna mounted on the earth-facing surface of the satellite, and a second omni-directional antenna used for communicating with the relay satellite and mounted on the anti-earth-facing surface of the satellite; A directional antenna that is used for communication and is capable of directing an antenna beam mounted on an anti-earth directional surface of a satellite toward a relay satellite, a first diplexer that splits a transmission / reception signal of the directional antenna, A second diplexer for demultiplexing a transmission / reception signal of the second omnidirectional antenna, a third diplexer for demultiplexing a transmission / reception signal of the first omnidirectional antenna, and four ports, Port and the second port, and the third port and the fourth port, or the first port and the fourth port, and the second port and the third port. Switch between two connection states A first port is connected to an output end of the first diplexer from which a reception signal of the directional antenna is output, and a third port is connected to an output terminal of the second omni-directional antenna. Said second
A switch connected to the output end of the diplexer,
A second transceiver connected to a second port of the switch, the second omnidirectional antenna, or a receiving unit of a first transceiver to which a reception signal of the directional antenna is input; and a fourth port of the switch. The second omnidirectional antenna, or a receiving unit of a second transceiver to which a reception signal of the directional antenna is input, and the first omnidirectional output from the third diplexer A duplexer for splitting a received signal of the antenna into two, and a second duplexer for outputting a received signal of the first omnidirectional antenna output from the splitter from a second port of the switch; A directional antenna, or a first multiplexer that combines the reception signal of the directional antenna with the reception signal of the first omni-directional antenna output from the duplexer; Output from the port It said second omni-directional antenna or a second multiplexer and for Satellite receiving apparatus characterized by comprising a synthesizing the reception signal of the directional antenna. 3. Used for communicating directly with an earth station,
A first omni-directional antenna mounted on the earth-facing surface of the satellite, and a second omni-directional antenna used for communicating with the relay satellite and mounted on the anti-earth-facing surface of the satellite; A directional antenna that is used for communication and is capable of directing an antenna beam mounted on an anti-earth directional surface of a satellite toward a relay satellite, a first diplexer that splits a transmission / reception signal of the directional antenna, A second diplexer for demultiplexing a transmission / reception signal of the second omnidirectional antenna, a third diplexer for demultiplexing a transmission / reception signal of the first omnidirectional antenna, and four ports, Port and the second port, and the third port and the fourth port, or the first port and the fourth port, and the second port and the third port. Switch between two connection states A first port is connected to an output end of the first diplexer from which a reception signal of the directional antenna is output, and a third port is connected to an output terminal of the second omni-directional antenna. Said second
A switch connected to the output end of the diplexer,
A second transceiver connected to a second port of the switch, the second omnidirectional antenna, or a receiving unit of a first transceiver to which a reception signal of the directional antenna is input; and a fourth port of the switch. A second omnidirectional antenna or a receiving unit of a second transceiver to which a reception signal of the directional antenna is input, and a first omnidirectional antenna output from the third diplexer A duplexer that divides the received signal into two, and converts the received signal of the first omnidirectional antenna output from the duplexer to the received signal of the directional antenna output from the first diplexer. A first multiplexer to be combined, and a reception signal of the second omni-directional antenna output from the second diplexer to a reception signal of the first omni-directional antenna output from the splitter Combine into Satellite reception apparatus characterized by comprising a second multiplexer.