JP2000503823A - Mobile link system for wireless communication device for diversity reception of selected uplink signal - Google Patents

Abstract

(57) Abstract: A mobile link system (10) for a wireless communication device comprises a first mobile link assembly (16), a second mobile link assembly (18) and a satellite feeder link assembly located in a satellite (12). (20) and a ground feeder link assembly (22) located at the ground station (14). The first and second mobile link assemblies (16 and 18) cooperate to transmit downlink signals to mobile stations in both the central band (24a) and the edge band (24b) of the coverage (24). The first mobile link assembly (16) receives uplink signals from both the center band (24a) and the edge band (24b) of the coverage (24), while the second mobile link assembly (18) receives , Receive uplink signals only from mobile stations within the edge band (24b). In this way, the first mobile link assembly (16) and the second mobile link assembly (18) provide diversity reception of edge uplink signals transmitted from mobile stations located within the edge band (24b).

Description

Description: FIELD OF THE INVENTION The present invention relates to a mobile link system for a wireless communication device, and more particularly to a mobile link system for a wireless communication device transmitted from a mobile station. The present invention relates to a mobile link system that performs diversity reception of an uplink signal. BACKGROUND OF THE INVENTION A mobile link system for a wireless communication device functions to create a communication link between a base station and a mobile station located within a range covered by the base station. To create a communication link, the mobile link system comprises one or more mobile link assemblies, each transmitting a downlink signal to a mobile station located within the coverage area or a mobile station located within the coverage area. Receiving an uplink signal from the mobile station. In the prior art, mobile link systems typically include two or more assemblies for receiving uplink signals from mobile stations and another mobile link assembly for transmitting downlink signals to mobile stations within coverage. It was equipped. Using two or more mobile link assemblies to receive uplink signals is known as diversity reception. A mobile link system using diversity reception combines uplink signals received at different mobile link assemblies to generate a diversity uplink signal. Because diversity uplink signals are formed by combining uplink signals, diversity uplink signals tend to more closely correspond to uplink signals transmitted by mobile stations. A classic example of diversity reception for coverage in the prior art has been by using an additional mobile link assembly to receive uplink signals. The addition of mobile link assemblies to base stations adds cost, complicates the mobile link system, and increases its weight and power requirements. These problems caused by the use of additional mobile link systems for diversity reception are exacerbated when the base station and its associated mobile station are satellite-based. Weight, complexity, and power requirements are critical factors for the satellite as well as for the additional mobile link assembly, and other components used for diversity reception also have a negative impact on these factors. There is a need for a mobile link system that allows diversity reception and minimizes the above problems. SUMMARY OF THE INVENTION For a wireless communication system including a first mobile link assembly located within a satellite, a second mobile link assembly, a satellite feeder link assembly and a feeder link assembly located at a ground station. Mobile link system. The first and second mobile link assemblies together provide transmission of mobile downlink signals and reception of mobile uplink signals for the first and second bands of coverage. In a preferred embodiment, the first band is a center band and the second band is an edge band. The first mobile link assembly includes a band 1 uplink signal transmitted from a mobile station located in a first band of a coverage area and a band 2 uplink signal transmitted from a mobile station located in a second band of a coverage area. And outputs the received band 1 uplink signal and the received band 2 uplink signal to the satellite feeder link assembly. The second mobile link assembly receives a mobile uplink signal transmitted from a mobile station within coverage and outputs the received band 2 uplink signal and the received band 1 uplink signal to a satellite feeder link assembly. . The second mobile link assembly transmits the mobile downlink signal to at least the first band and the second band of the coverage. The satellite feeder link assembly transmits a feeder link downlink signal corresponding to the received mobile uplink signal to carry the received mobile uplink signal to the terrestrial feeder link assembly. The ground feeder link assembly is connected to the mobile link system and couples the mobile link system to a communication network. The terrestrial feeder link assembly combines the feeder link downlink signals to combine the band 2 uplink signals received by the first and second mobile link assemblies to generate a diversity combined signal. Equipped with a vessel. Accordingly, the mobile link system provided for the purpose of the present invention comprises first and second mobile link assemblies, which together cover the first and second bands of coverage and for the second band. Only provide diversity reception. It is also an object of the present invention to combine the received band 2 uplink signals at a terrestrial feeder link assembly. It is a further object of the present invention to minimize the components required for a satellite and to minimize the weight and complexity of the satellite. Various other objects, features and advantages of the present invention will become apparent from the following detailed description and the accompanying drawings. In the drawings, the same components are denoted by the same reference numerals. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a mobile link system and its associated coverage according to the present invention. FIG. 2 is a block diagram showing the entire mobile link system according to the present invention. FIG. 3 is a block diagram of the first and second moving link assemblies according to the first embodiment of the present invention. FIG. 4 is a schematic diagram of a representative spot beam of coverage by the second moving link assembly according to the first embodiment of the present invention. FIG. 5 is a block diagram of a ground station according to the present invention. FIG. 6 is a block diagram of the first and second moving link assemblies according to the second embodiment of the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the drawings, a mobile link system according to the present invention is shown generally at 10. The mobile link system 10 serves to create a communication link between a base station and mobile stations located within the coverage of the base station. The base station is connected to a public switched telephone network (PSTN) or other communication network, and mobile stations within coverage are connected to other communication devices in the communication network. In the preferred embodiment described below, the base station and its mobile link system use satellites. The mobile link system according to the present invention can also be applied to a terrestrial base station. In FIG. 1, a mobile link system 10 links mobile stations within coverage 24 to a communication network 15 based on satellites 12 and ground stations 14. Coverage 24 for mobile link system 19 includes a central band 24a and an edge band 24b. The edge zone 24b is located along the periphery of the coverage area 24, and the center zone 24a is located at the center of the coverage area 24. FIG. 1 shows a situation where the first mobile station 26 is located in the central band 24a and the second mobile station 28 is located in the edge band 24b. The center band 24a and the edge band 24b are determined based on the relative length of the communication link provided in the coverage area 24. The mobile link between a mobile station in the central band 24a and the mobile link system 10 is generally stronger than the mobile link between the mobile station in the edge band 24b and the mobile link system 10. The communication links for mobile stations in the central band 24a are generally stronger mainly because of the relatively short distance between the mobile stations in the central band 24 and the satellites 12, and also in the central band 24a. This is because the effect of shadowing on the mobile station is relatively small. The mobile link system 10 includes a first mobile link assembly 16, a second mobile link assembly 18 and a satellite feeder link assembly 20 located within the satellite and a terrestrial feeder link assembly 22 located within the ground station 14. including. The first mobile link assembly 16 and the second mobile link assembly 18 operate together to transmit mobile downlink signals from the satellite 12 and to move up from mobile stations within the central band 24a and the edge band 24b of the coverage 24. Receive a link signal. In the description and in the claims, mobile downlink signals transmitted to central band 24a are referred to as central downlink signals, and mobile downlink signals transmitted to edge band 24b are referred to as edge downlink signals. Similarly, mobile uplink signals transmitted by mobile stations from central band 24a are referred to as central uplink signals, and mobile uplink signals transmitted from edge band 24b are referred to as edge uplink signals. The satellite feeder link assembly 20 and the terrestrial feeder link assembly 22 operate to form a feeder link between the satellite 12 and the ground station 14. The formation of the feeder link by the feeder link assemblies 20 and 22 allows the mobile stations within the coverage area 24 to connect to the communication network 15. For example, ground station 14 is connected to a public switched telephone network (PSTN) so that mobile stations within coverage 24 can communicate with telephones and other communication devices in a communication network connected to the PSTN. . The first mobile link assembly 16 and the second mobile link assembly 18 of the mobile link system 10 work together to transmit downlink signals to mobile stations located within the central band 24a and the edge band 24b, and to transmit uplink signals therefrom. Receive a link signal. Also, the first mobile link assembly 16 and the second mobile link assembly 18 provide diversity reception of edge uplink signals transmitted from mobile stations located in the edge band 24b. Diversity reception is not provided for central uplink signals transmitted from mobile stations located in central band 24a. More specifically, second mobile link assembly 18 transmits downlink signals to both central band 24a and edge band 24b, and receives uplink signals from edge region 24b. The first mobile link assembly 16 receives uplink signals from both the center band 24a and the edge band 24b. Accordingly, uplink signals transmitted by mobile stations within edge band 24b will be received by both first mobile link assembly 16 and second mobile link assembly. As described in detail below, the edge uplink signals received by the first mobile link assembly 16 and the second mobile link assembly 18 are combined to provide diversity reception for the uplink signals transmitted from the edge band 24b. provide. Diversity reception is provided for the edge uplink signal and not for the center uplink signal because the edge uplink signal is generally weaker than the center uplink signal. Edge uplink signals are generally weaker primarily because the distance between the edge band 24b and the satellite 12 is longer, and the shadowing of mobile stations within the edge band 24b is larger. Because. Providing diversity reception for the edge uplink signal can prevent the quality of the communication link of the mobile station within the edge band 24b from being generally degraded. FIG. 2 is a more detailed block diagram of the mobile link system 10. The first mobile link assembly 16 receives center and edge uplink signals and includes a receiving antenna 30 and a primary receiver 32. Receive antenna 30 converts both the center and edge uplink signals to an antenna input connected to primary receiver 32. Primary receiver 32 processes the antenna input from receive antenna 30 and outputs the received edge uplink signal and the received central uplink signal to feeder link assembly 20. The primary receiver 32 converts the antenna input to generate a received uplink signal. The second mobile link assembly 18 receives the edge uplink signal and transmits both center and edge downlink signals. The second mobile link assembly includes a transmit / receive antenna 36, a duplexer assembly 38, a secondary receiver 40, and a mobile link transmitter 42. To receive the edge uplink signal, transmit / receive antenna 36 converts the mobile uplink signal to an antenna input, which is sent to duplexer assembly 38. Duplexer assembly 38 sends the antenna input to secondary assembly 40. Secondary receiver 40 processes the antenna input and outputs a received edge uplink signal. Secondary receiver 40 does not output a central uplink signal. The received edge uplink signal is output to feeder link assembly 20. To transmit the mobile downlink signal from the second mobile link assembly 18, the mobile link transmitter 42 outputs the center and edge downlink signals to the transmit / receive antenna 36 via the direct path 42a and the duplexer path 42b. The transmitting / receiving antenna 36 outputs the center and edge downlink signals to the center band 24a and the edge band 24b. The mobile downlink signal transmitted by mobile link assembly 18 corresponds to the feeder link uplink signal received at satellite feeder link assembly 20. A satellite feeder link assembly 20 and a terrestrial feeder link assembly 22 communicatively link the satellite 12 with the ground station 14. The satellite feeder link assembly 20 carries the mobile uplink signal transmitted by the mobile station and received by the satellite 12 to the ground station and transmitted by the terrestrial feeder link assembly 22 and the communication signals from the communication network 22. To receive. Satellite feeder link assembly 20 transmits a feeder link down signal to ground station 14 to carry the mobile uplink signal to the ground station, which corresponds to the mobile uplink signal. Communication network signals received at satellite feeder link assembly 20 are carried by second mobile link assembly 18 to selected mobile stations within coverage 24. Satellite feeder link assembly 20 generates a feeder link down signal by channelizing the center and edge uplink signals output by mobile link assemblies 16 and 18. Thus, the feeder link downlink signal corresponds to the received central uplink signal and the received edge uplink signal. Satellite feeder link assembly 20 receives feeder link uplink signals transmitted from terrestrial feeder link assembly 22 to receive communication network signals from ground station 14. The feeder link uplink signal is used to carry communication network signals from communication devices in the communication network to satellite 12. Satellite feeder link assembly 34 channels the received feeder link uplink signal and outputs the channelized feeder link uplink signal to mobile link transmitter 42. The mobile link transmitter 42 carries the communication network signal to the mobile station by processing the channelized feeder link uplink signal and outputting a corresponding mobile downlink signal. Satellite feeder and link assemblies are known in the prior art. The ground feeder link assembly 22 of the ground station 14 receives the feeder link downlink signal and outputs a feeder link uplink signal. The feeder link downlink signal is used to carry the mobile uplink signal received on satellite 12 to ground station 14. The feeder link uplink signal is used to carry communication network signals from the communication network to satellite 12. The ground feeder link assembly 22 includes a feeder link antenna 44, a duplexer 46, a transmitter 48, and a controller / switch 51. Feeder link antenna 44 converts the feeder link downlink signal to an antenna input. The duplexer 46 then sends the antenna input from the feeder link antenna 44 to the receiver 50. Receiver 50 includes a combiner 52 that selectively combines the feeder link downlink signals. More specifically, combiner 52 combines feeder link downlink signals corresponding to the edge uplink signals received from both first mobile link assembly 16 and second mobile link assembly 18 by: Generate a diversity signal. The diversity combining signal corresponds to the edge uplink signal transmitted from the mobile station in the edge band 24b. Received feeder link downlink signals corresponding to the diversity combining signal and the central uplink signal are output from the receiver 50 to the controller / switch 51. The controller / switch 51 controls the output of the outgoing signal, which corresponds to the mobile uplink signal, the communication network. The terrestrial feeder link assembly 22 transmits a feeder link uplink signal corresponding to a communication network signal transmitted from a communication device in the communication network 15 connected to the ground station 14. This communication network signal is for mobile stations within the coverage area 24. To transmit a feeder link uplink signal, the controller / switch first receives a communication network signal from a communication network. Next, the controller / switch 51 sends the communication network signal to the feeder link transmitter 48. The feeder link transmitter 48 transmits a feeder link uplink signal corresponding to the input communication network signal to the feeder link antenna 44. The feeder link antenna 44 transmits the feeder link uplink signal to the satellite 12 feeder link assembly 20. FIG. 3 shows a first preferred embodiment of the mobile link system 10 located within the satellite 12. In this first embodiment, the mobile link antenna 36 of the second mobile link assembly is a reflector antenna. The transmit / receive antenna 36 of the first mobile link assembly includes a transmit / receive feed array 56 and a transmit feed array 58. The transmission / reception feed array 56 includes transmission / reception feed elements Fi (i = 1, 2,... M), and the transmission feed array 58 includes transmission transmission elements Fi (i = m + 1, m + 2,. Has. The transmission / reception feed element Fi is disposed on the antenna 36, converts only the edge uplink signal into an antenna input signal, and transmits only the edge downlink signal. More specifically, the transmit / receive feed element Fi is located at the focal point of the edge uplink signal reflected by the transmit / receive antenna 36, and the downlink signal transmitted by the transmit / receive feed element Fi is reflected toward the edge band 24b. Are arranged as follows. The transmit / receive feed array 56 generates a secondary antenna input Usi (i = 1, 2,... M) and outputs the secondary antenna input Usi to the secondary receiver 40. Secondary antenna input Usi corresponds to an edge uplink signal, and each of the secondary antenna inputs Usi corresponds to an edge uplink signal transmitted by one mobile station in edge band 24b. Secondary receiver 40 includes a bank of receiver chains Rs i (i = 1, 2,... M). The receiver chain Rsi is The output from the link assembly 18 is output to the feeder / link assembly 20. Satellite It is transported to the ground station 14. Satellite feeder link assembly 20 receives the received air. The signal Isi (i = 1, 2,... M) is transmitted to the ground station 14. The secondary feeder link downlink signal Isi is generated by conventional processing means including channelization. The transmission feed elements Fi (i = m + 1, m + 2,... N) of the transmission / reception antenna 36 are disposed on the transmission / reception antenna 36 and transmit the central downlink signal to the central band 24a. More specifically, the transmission feed element Fi is arranged such that the signal transmitted by the transmission feed element Fi is reflected toward the central band 24a but not toward the edge band 24b. The transmission feed element Fi is not connected to the receiving component. The transmit / receive feed array 56 and the transmit feed array 58 are both connected to the mobile link transmitter 42. Mobile link transmitter 42 is coupled to feeder link assembly 20 to generate a mobile down signal corresponding to the feeder link uplink signal received at feeder link assembly 20. Mobile link transmitter 42 includes a bank of transmitter chains Txi (i = 1, 2,... M, m + 1,... N). Transmitter chains Tx1 to Tx2 transmit edge downlink signals to transmit / receive feed array 56 via path 42a and duplexer 38. Transmitter chains Tx (m + 1) through Txn transmit the central downlink signal to receive feed array 58 via path 42b. FIG. 4 schematically illustrates how the transmit / receive feed array 56, the transmit feed array 58, and the reflector 57 of the transmit / receive antenna 36 generate a representative spot beam for the coverage 24. More specifically, a state is shown in which the transmission / reception feed Fi and the reflector 57 are generating a spot beam in the edge band 24b. Each of the transmit and receive feeds Fi produces a different spot beam in the edge band 24b, and the transmit and receive feed array 56 covers the edge band 24b. Similarly, in the figure, the transmission feed Fi and the reflector 57 are shown generating a spot beam in the central band 24a. Each of the transmit feeds Fi produces a different spot beam in the central band 24a, and the transmit feed array 58 covers the central band 24a. In the first preferred embodiment of the mobile link system 10, the mobile link receiving antenna 30 of the first mobile link assembly 16 is also a reflector antenna and receives feed elements Fi (i = 1, 2,... N). Has. The receive feed element Fi is arranged on the receive antenna 32 and converts both the center and edge uplink signals into antenna inputs Upi (i = 1, 2,... N). More specifically, the receive feed element Fi of the receive feed assembly 52 is located at the focal point of both the edge uplink signal and the central uplink signal reflected by the receive antenna. (I = 1, 2,... N), which are output to the primary receiver 32. The primary antenna input Upi corresponds to an edge uplink signal transmitted by one mobile station in the edge band 24b or a central uplink signal transmitted by one mobile station in the central band 24a. The primary receiver 32 includes a bank of receiver chains Rpi (i = 1, 2,... N). Receiver chain R The assembly 16 supplies the satellite feeder and link assembly 20. Satellite Convey to 4. The satellite feeder link assembly 20 The signal Ipi (i = 1, 2,... M) is transmitted to the ground station 14. The generation of the primary feeder link downlink signal Ipi takes place via conventional processing means including channelization. In FIG. 5, the feeder link downlink signals Isi and Ipi are received by the feeder link antenna 44 of the ground station 14 and the secondary feeder link Corresponding to the edge uplink signal and the central uplink signal transmitted by the mobile station in the central band. Primary feeder link corresponding to edge uplink signal Here, the receiver 50 is a coupler having a coupler Ci (i = 1, 2,... M). Secondary feed corresponding to the particular edge uplink signal received at assembly 18 The header link inputs are combined using conventional combining processes, such as selective combining, maximum percentage equal gain combining. The combiner / bank 52 outputs the diversity combined signal Ri (i = 1, 2,... M). The diversity combining signal corresponds to mobile edge uplink signals transmitted by mobile stations within edge band 24b of coverage 24 and received by first and second mobile link assemblies 16 and 18. Receiver 50 also responds to the central uplink signal received at first mobile link assembly 16. -Output Rn from the link downlink signal R (m + 1). The receive feeder link downlink signals R (m + 1) to Rn and the diversity combining signal Ri are output from the terrestrial feeder link assembly 22 to the controller / switch 51. The controller / switch 51 processes the ground feeder link assembly output and outputs communication network information leaving the communication network 15. The outgoing communication network information corresponds to mobile uplink signals originally transmitted from mobile stations within coverage 24. FIG. 6 shows a second preferred embodiment of the mobile link system 10 located within the satellite 12. The second preferred embodiment of the mobile link system differs from the first embodiment in that the transmit / receive antenna 36 of the second mobile link assembly is a direct array antenna. In a second preferred embodiment, the second mobile link assembly 18 outputs a received edge uplink signal transmitted from a mobile station within the edge band 24b as follows. That is, the transmit / receive feed array 56 of the transmit / receive antenna 36 receives edge and center uplink signals from mobile stations in the edge band 24 and the center band 24a, and receives the secondary antenna inputs U si (i = 1, 2,. .M). This secondary antenna input Usi is supplied to the secondary receiver 40 via the duplexer 38. The secondary receiver 40 processes the antenna input Usi in a conventional manner and outputs a receiver output signal Usi 'to the receive beamformer 64. The receive beamformer 64 comprises beam weights Bi (i = 1, 2,... M) and transforms the receiver output signal Usi '. The selection of the beam weight Bi is made such that the central uplink signal received by the transmission / reception antenna 36 is canceled after passing through the reception beamformer 64. The beam weight Bi is multiplied by the receiver output signal Usi 'to increase the reception edge. The receive beamformer 64 comprises an adder 66, which outputs the secondary receiver signal Usi 'to the feeder link assembly 20 after summing the received edge uplink signals. In this second embodiment, the second mobile link assembly 18 transmits the center and edge downlink signals to the center band 24a and the edge band 24b as follows. After the feeder link uplink signal is processed, including channelization, from the satellite feeder link assembly 20 to a transmit beamformer 70 having beam weights Bi (i = 1, 2,... N). Is output. Transmit beamforming 70 multiplies the channelized feeder link uplink signal by beam weight Bi. The beam weighting selection of the transmit beamformer 70 is selected so that a beam signal for generating a spot for the coverage 24 is generated. The beam signal passes through mobile link transmitter 42, duplexer assembly 38, and antenna 36, as shown, to generate a spot beam for coverage 24. The mobile link system 10 of the present invention includes first and second mobile link assemblies that, together, transmit a mobile downlink signal and a mobile uplink signal for both the first and second bands of coverage. , And diversity reception for the second band of the coverage range is performed. In these preferred embodiments, the second band is an edge band, but other bands within the coverage that benefit from diversity reception can be selected for the second band. Mobile link system 10 eliminates the need to provide additional mobile link assemblies for diversity reception of mobile uplink signals. Also, by performing diversity reception only in the second band, the components required for the satellite 12 and the weight of the satellite 12 can be minimized. Similarly, by locating the coupler 52 within the terrestrial feeder link assembly 22, the components required for the satellite 12 and the weight of the satellite 12 can be minimized. Accordingly, the mobile link system 10 of the present invention minimizes the complexity and weight of the satellite 12. Those skilled in the art will be able to embody the invention in other specific forms without departing from the concept or essential characteristics of the invention. Therefore, the embodiment disclosed herein is merely an example, and the present invention is not limited to this.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission Date] November 20, 1997 (November 20, 1997) [Correction contents]   Use two or more mobile link assemblies to receive uplink signals This is known as diversity reception. Transfer using diversity reception The mobile link system uses uplinks received on different mobile link assemblies. The signals are combined to generate a diversity uplink signal. Diversity Since uplink signals are formed by combining uplink signals, diversity The uplink signal is the uplink signal transmitted by the mobile station, They tend to respond more strictly. Divers for coverage in the prior art A typical example of a sit reception is to add an additional mobile link asset to receive the uplink signal. This was done by using an assembly. Mobile link assembly to base station The additional cost increases costs, complicates the mobile link system, Increase power requirements.   National Telesystem Conference NTS82, "80s system" A star system is disclosed, according to which the user can use a transceiver and a small You can access the satellite directly using the antenna.   By using an additional mobile link system for diversity reception These problems arise because base stations and their associated mobile stations are satellite-based. When it becomes larger. Weight, complexity, and power requirements add to satellites Is a critical factor for dynamic link assemblies, and diversity Other components used for reception also have a negative impact on these factors. Affect. A mobile resource that enables diversity reception and minimizes the above problems. A link system is needed. Summary of the Invention   A first mobile link assembly disposed within the satellite and a second mobile link assembly; Buri and the feeder link assembly located at the satellite feeder link assembly and ground station And a mobile link system for a wireless communication device including a wireless communication device. First And the second moving link assembly together form the first and second bands of coverage. Transmission of mobile downlink signals and reception of mobile uplink signals. Offer.                               The scope of the claims   1. A mobile link system (10) for a wireless communication device,   a) Whether the mobile station (26) is located in the first band (24a) of the coverage area (24) Band signal transmitted from the second band (2) and the second band (2 4b) and the band 2 uplink signal transmitted from the mobile station (28) located within Receiving a mobile uplink signal including the received band 1 uplink signal Mobile link assemble for outputting received band 2 uplink signal Li (16),   b) mobile stations transmitted from the mobile stations (26, 28) within the coverage area (24); Receiving the uplink signal, outputting the band 2 uplink signal and transmitting the band 1 uplink signal. No link signal is output, and the mobile downlink signal is output at least in the coverage area. A second mobile link address for transmitting to the first (24a) and second band (24b). Assembly (18),   c) received by the first (16) and second (18) mobile link assemblies. Diversity combining the received band 2 uplink signal obtained, (16) and second (18) band 2 uplink received at the mobile link assembly A combiner (52) for generating a diversity combined signal corresponding to the link signal; A mobile link system (10) comprising:   2. The second moving link assembly (18) comprises:   a) Transmission for transmitting mobile downlink signals and receiving mobile uplink signals Receive feed (56) and transmit feed for transmitting mobile downlink signals (58) a transmitting / receiving antenna having:   b) process the mobile uplink signal received at said transmit / receive feed (56) A secondary receiver (40) for performing   c) transmitting the mobile downlink signal to the transmitting / receiving feed (56) of the transmitting / receiving antenna; And outputs the mobile downlink signal to the first band (2). 4a) and a mobile resource for transmitting to the mobile station (2, 28) in the second band (24b). Link transmitter (42),   d) the secondary receiver (40), the mobile link transmitter (42), A receiving antenna (36) for receiving and transmitting the received uplink signal; From the feed (56) to the secondary receiver (40), The mobile downlink signal from the transmitter (42) is transmitted and received by the transmission / reception feed (56). A duplexer assembly (38) for sending to The mobile link system (10) according to claim 1, comprising:   3. The first moving link assembly (16) includes:   a) Receive antenna (30) for receiving band 1 and band 2 uplink signals )When,   b) Band 1 and band 2 uplinks received by said receiving antenna (30) A primary receiver (32) for processing the signal. The mobile link system (10) according to claim 1, comprising:   4. The first (16) and second (18) mobile link assemblies include a satellite (12 ), Connected to a satellite feeder link assembly (20), A star feeder link assembly (20) is provided for the first and second mobile link assemblies. (16, 18) to the ground station (14). The moving link assembly according to claim 3, wherein the moving link assembly is transported.   5. The satellite feeder link assembly (20) includes a receiver uplink. A feeder link downlink signal to carry the signal to the ground station (14). Transmitting a signal to the ground station (14). System (10).   6. The coupler (52) is disposed in the ground station (14) and received by the ground station. Combining the received feeder link downlink signal, Band 2 received by the first (16) and second mobile link assemblies (18). Generating a diversity combined signal corresponding to the uplink signal. Item 6. The mobile link system (10) according to item 5.   7. The transmitting / receiving antenna (36) of the second mobile link assembly (18) is Reflector antenna (57), and said second mobile link assembly (18) is a band 2 transmitted from the mobile station (26) in the first band (24a). Uplink signals are received and transmitted from mobile stations in the second band (24b) The mobile station according to claim 1, wherein the mobile station does not receive a band 1 uplink signal. Link system (10).   8. The transmitting and receiving antenna (36) of the second mobile link assembly (18) is A reflector antenna, and wherein said second moving link assembly (18) comprises: Band 2 uplink transmitted from the mobile station (26) in the first band (24a) A band which receives a signal and is transmitted from a mobile station (28) in said second band (24b) 3. The mobile link according to claim 2, wherein no one uplink signal is received. System (10).   9. The transmission / reception feed (56) of the transmission / reception antenna (36) includes the first transmission / reception feed (56). Receives a band 2 uplink signal transmitted from the mobile station (26) in the band (24a). The band 1 transmitted from the mobile station (28) in the second band (24b). 9. The mobile link system according to claim 8, wherein no link signal is received. (10).   10. The mobile link transmitter (42) transmits a band 1 downlink signal. A signal is transmitted to the transmission feed (58) of the transmission / reception antenna (36), and the band 2 Link signal to the transmit / receive feed (58) of the transmit / receive antenna (36). Mobile link system (10) according to claim 8, characterized in that:   11. The duplexer assembly (38) includes the transmitting / receiving antenna (36). The band 2 uplink signal from the transmit / receive feed (56) to the secondary receiver (40) and transmits a band 2 downlink signal to the transmitting / receiving antenna (36). 11) sending to the transmission / reception feed (56). Link system (10).   12. The transmitting and receiving antennas of the second mobile link assembly are direct An array antenna, wherein the transmitting and receiving antennas are band 1 and band 2 uplink signals. And the second mobile link assembly receives the received uplink signal. And outputting a received band 2 uplink signal. Item 2. The mobile link system according to item 1.   13. The transmitting / receiving antenna (36) of the second mobile link assembly (18) Is a direct array antenna, and the transmitting / receiving antenna (36) 1 and band 2 uplink signals and said second mobile link assembly (18) is a band 2 uplink received by processing the received uplink signal. The mobile link system (10) according to claim 2, wherein the mobile link system (10) outputs a link signal. ).   14． The second receiver (40) receives from the transmit / receive feed (56). The second mobile link address is multiplied by an uplink signal with a predetermined beamforming weight. Receive beamforming to output band 2 uplink signal from assembly (18) Mobile link system (1) according to claim 13, characterized in that it comprises a switch (64). 10).   15. The mobile link transmitter (42) includes the transmission / reception feed array. Via the transmission feed array (56) and the transmission / reception antenna (58) Having a transmit beamformer (70) for forming a downlink signal to be transmitted The mobile link system (14) according to claim 14, characterized in that:   16. The first band (24a) is a central band (24) of the coverage area (24). a), wherein the second band (24b) is an edge band ( Mobile link system (10) according to claim 1, characterized in that it is 24b). .   17． The mobile link system (10) for the wireless communication system is connected to the mobile station (26, 28). ) To link to   a) In the first mobile link assembly (16), the first band of the coverage area (24). Band 1 uplink signal transmitted from the mobile station (26) located in (24a) And the mobile station (28) located in the second band (24b) of the coverage area (24) Receiving a mobile uplink signal including a band 2 uplink signal transmitted from the mobile terminal; Outputs the received band 1 uplink signal and the received band 2 uplink signal And   b) moving the second moving link assembly (18) within the cover area (24); Mobile uplink signals transmitted from mobile stations (26, 28) are received, and band 2 Outputting a uplink signal and not outputting a band 1 uplink signal, and Moving the downlink signal from the link assembly (18) to the coverage area (24); At least in the first (24a) and second band (24b),   c) received by the first (16) and second (18) mobile link assemblies. Diversity combining the received band 2 uplink signal obtained, (16) and second (18) band 2 uplink received at the mobile link assembly Generating a diversity composite signal corresponding to the link signal; A method characterized by the following.   18. The first (16) and second (18) mobile link assemblies comprise a satellite (1). 2) located within and connected to a satellite feeder link assembly (20); The satellite feeder link assembly (20) includes the mobile link assembly (16). , 18) to carry the received mobile uplink signal to the ground station (14). The method of claim 17, further comprising a step.   19. Carrying the received uplink signal to the ground station (14) , A feeder link downlink signal to the satellite feeder link assembly ( 20) Transmitting from 20) to the ground station (14). Method.   20. The diversity combining step includes the steps of: Link down link signals and combine the first and second mobile link assemblies ( 16, 18) Diversity matching corresponding to the band 2 uplink signal received The method according to claim 17, wherein a generated signal is generated.   21. The second mobile link assembly (18) receives a mobile uplink signal. The step of transmitting the first band (24a) by a reflector antenna (57). ) Receives the band 2 uplink signal transmitted from the mobile station (26), and The band 1 uplink signal transmitted from the mobile station (26) in the two bands (24b) is The method of claim 17, wherein no receiving is performed.   22. The second mobile link assembly (18) receives a mobile uplink signal. The step of communicating includes the step of transmitting said first band (24) by a reflector antenna (57). a) and band 1 transmitted from the mobile station (26) in the second band (24b) and Receiving a band 2 uplink signal and receiving said band 1 and band 2 uplink signals From the second mobile link assembly (18) to receive band 2 uplink 18. The method according to claim 17, wherein a clock signal is output.   23. The first band (24a) is a center band of the coverage area (24). , The second band (24b) is an edge band (2) adjacent to the central band (24). The method according to claim 17, wherein 4b).

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, S Z, UG), UA (AM, AZ, BY, KG, KZ, MD , RU, TJ, TM), AL, AM, AT, AU, AZ , BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, FI, GB, G E, HU, IL, IS, JP, KE, KG, KP, KR , KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, MW, MX, NO, NZ, P L, PT, RO, RU, SD, SE, SG, SI, SK , TJ, TM, TR, TT, UA, UG, UZ, VN (72) Inventor Molnar, Barbara, Davis             United States 27513 North Carola             Carrie, Ina, Flying Reef             Port 110 (72) Inventors Stisik, Eric             Sweden S-113 59 Stock             Kuholm, Tegnerlunden 6.1 g             Le.

Claims (1)

[Claims]   1. A mobile link system for a wireless communication device,   a) Band 1 uplink transmitted from a mobile station located in the first band of the coverage area And a band 2 transmitted from a mobile station located in the second band of the coverage area. And receiving a mobile uplink signal including the uplink signal and receiving the mobile uplink signal. A second band for outputting a band 1 uplink signal and a received band 2 uplink signal; One moving link assembly;   b) receiving a mobile uplink signal transmitted from a mobile station within the coverage area; And outputs a band 2 uplink signal and does not output a band 1 uplink signal, and Mobile downlink signals to at least the first and second bands of the coverage area. A second mobile link assembly for transmitting;   c) the received received by the first and second mobile link assemblies Diversity-combining the band 2 uplink signals obtained from the first and second mobile links. Diversity matching corresponding to band 2 uplink signals received by A combiner for generating a synthesized signal;   A mobile link system comprising:   2. The second moving link assembly   a) Transmission for transmitting mobile downlink signals and receiving mobile uplink signals Has a receive feed and a transmit feed for transmitting mobile downlink signals Transmitting and receiving antennas,   b) for processing mobile uplink signals received in said transmit and receive feeds A secondary receiver,   c) transmitting the mobile downlink signal to the transmission / reception feed and transmission To output mobile downlink signals to mobile stations within the first and second bands. A mobile link transmitter for transmitting;   d) the secondary receiver, the mobile link transmitter and the transmitting and receiving antenna Connected and receive the received uplink signal from the transmit / receive feed to the secondary A mobile downlink signal from the mobile link transmitter. Duplexer assembly for sending to sending and receiving feeds The mobile link system according to claim 1, comprising:   3. The first moving link assembly includes:   a) a receiving antenna for receiving band 1 and band 2 uplink signals;   b) band 1 and band 2 uplink signals received by the receiving antenna A primary receiver for processing and The mobile link system according to claim 1, comprising:   4. The first and second mobile link assemblies are located within a satellite and have a satellite filter. Feeder link assembly and the satellite feeder link assembly is Carry the received mobile uplink signal output from the mobile link assembly to the ground station. The mobile link assembly according to claim 3, wherein the link is transported.   5. The satellite feeder link assembly precedes the received uplink signal. Feeder link downlink signal to said ground station for transport to said ground station The mobile link system according to claim 4, wherein the transmission is performed.   6. The coupler is disposed in the ground station, and the coupler is received by the ground station. By combining the feeder link downlink signal, the first and second Diver corresponding to band 2 uplink signal received at mobile link assembly The mobile link system according to claim 5, wherein the mobile link system generates a composite signal. M   7. The transmitting and receiving antenna of the second mobile link assembly is a reflector antenna. And the second mobile link assembly is a mobile station in the first band. And receives a band 2 uplink signal transmitted from a mobile station in the second band. 2. The mobile station according to claim 1, wherein the transmitted band-1 uplink signal is not received. Mobile link system.   8. The transmitting and receiving antenna of the second mobile link assembly is a reflector antenna. And the second mobile link assembly is from a mobile station in the first band. A band 2 uplink signal to be transmitted is received and transmitted from a mobile station in the second band. 3. The mobile station according to claim 2, wherein no band 1 uplink signal is received. Dynamic link system.   9. The transmit / receive feed of the transmit / receive antenna is a mobile station within the first band. Receiving the band 2 uplink signal transmitted from the mobile station within the second band 9. The method of claim 8, wherein the received band 1 uplink signal is not received. Mobile link system.   10. The mobile link transmitter transmits and receives a band 1 downlink signal. Transmitting to the transmission feed of a transmission antenna and transmitting / receiving the band 2 downlink signal 9. The mobile communication device according to claim 8, wherein the signal is transmitted to a transmission / reception feed of an antenna. Link system.   11. The duplexer assembly includes a transmitting and receiving filter of the transmitting and receiving antenna. A band 2 uplink signal from the base station to the secondary receiver and a band 2 uplink signal. Transmitting the downlink signal to the transmission / reception feed of the transmission / reception antenna. The mobile link system according to claim 10.   12. The transmitting and receiving antennas of the second mobile link assembly are direct An array antenna, wherein the transmitting and receiving antennas are band 1 and band 2 uplink signals. And the second mobile link assembly receives the received uplink signal. And outputting a processed band-2 uplink signal. 2. The mobile link system according to 1.   13. The transmitting and receiving antennas of the second mobile link assembly are direct An array antenna, wherein the transmitting and receiving antennas are band 1 and band 2 uplinks. Receiving a signal and the second mobile link assembly is configured to receive the received uplink signal. Processing the signal and outputting a received band 2 uplink signal. The mobile link system according to claim 2.   14． The second receiver receives a received uplink signal from the transmit / receive feed. From the second mobile link assembly by multiplying 2. A receiving beamformer for outputting an uplink signal. The mobile link system according to claim 13, wherein:   15. The mobile link transmitter includes a transmitting and receiving antenna of the transmitting and receiving antenna. Downlink signal transmitted via feed array and transmit feed array 15. The method of claim 14, further comprising a transmit beamformer for forming the signal. Mobile link system.   16. The first band is a center band of the coverage area, and the second band is The transfer according to claim 1, wherein the edge band is an edge band adjacent to the center band. Dynamic link system.   17． For linking a mobile link system for a wireless communication system with a mobile station The method   a) Movement within the first band of the coverage by the first moving link assembly. A band 1 uplink signal transmitted from a station and located within a second band of the coverage Mobile uplink signal including a band 2 uplink signal transmitted from a mobile station And receives a received band 1 uplink signal and a received band 2 uplink signal. Output a lock signal,   b) transmitted from a mobile station within said coverage area in a second mobile link assembly; Receive a mobile uplink signal, and output a band 2 uplink signal to No uplink signal is output and moving down from the second moving link assembly Transmitting a link signal to at least the first and second bands of the coverage area;   c) the received received by the first and second mobile link assemblies Diversity combining of the band 2 uplink signal obtained from the first and second mobile link. Diversity matching corresponding to band 2 uplink signals received by Generating a synthesized signal; A method characterized by the following.   18. The first and second mobile link assemblies are located within a satellite, and the satellite Feeder link assembly, wherein the satellite feeder link assembly is Receiving a mobile uplink signal output from the mobile link assembly by a ground station. 18. The method of claim 17, further comprising the step of transporting to.   19. The step of carrying the received uplink signal to the ground station comprises: A downlink signal from the satellite feeder link assembly to the ground. The method of claim 17, wherein the transmission is to a superior.   20. The diversity combining step includes the steps of: feeding and linking at the ground station; Downlink signals received at the first and second mobile link assemblies. Generating a diversity combined signal corresponding to the extracted band 2 uplink signal. The method according to claim 17, characterized in that:   21. A second mobile link assembly for receiving a mobile uplink signal; The step is transmitted by a reflector antenna from a mobile station in the first band. A band that receives a band 2 uplink signal and is transmitted from a mobile station within the second band The method of claim 17, wherein one uplink signal is not received.   22. A second mobile link assembly for receiving a mobile uplink signal; The step is performed by a reflector antenna to move between the first band and the second band. Receiving band 1 and band 2 uplink signals transmitted from a mobile station, Processing the 1 and band 2 uplink signals from the second mobile link assembly The method according to claim 17, wherein a reception band 2 uplink signal is output. Law.   23. The first band is a center band of the coverage area, and the second band is The edge band adjacent to the center band, according to claim 17, characterized in that: Method.