RU2007136021A - SENDING DEVICE, RECEIVING DEVICE, MOBILE COMMUNICATION SYSTEM AND TRANSMISSION METHOD - Google Patents

Abstract

1. A transmitting device for use in a communication system using a single-carrier method and in a communication system using a multi-carrier method, comprising: a switching module that switches radio communication methods; a signal generation module in the frequency domain, which allocates radio resources for a sequence of elementary signals with a spread spectrum, over which one of the following transformations is performed: fast Fourier transform and serial-parallel conversion, in accordance with the applied radio communication method, for generating a signal in the frequency domain; and a transmission signal generating unit, performing inverse fast Fourier transform of the signal in the frequency domain to generate the transmission signal. ! 2. The transmitting device according to claim 1, characterized in that the switching module switches the radio communication methods in accordance with information about the applied radio communication method. ! 3. The transmitting device according to claim 1, characterized in that the switching module transmits a channel state measurement signal using a predetermined frequency band, the allocation of which is requested when switching to a single-carrier radio communication method. ! 4. The transmitting device according to claim 1, characterized in that it further comprises a control signal generating module, which, when switched to a single-carrier radio communication method, transmits information of at least one of the following parameters: the requested frequency bandwidth for the data channel, amount of data transmitted, data transfer rate. ! 5. The transmitting device according to claim 4, characterized in that

Claims (99)

1. A transmitting device for use in a communication system using a single-carrier method and in a communication system using a multi-carrier method, comprising: a switching module that switches radio communication methods; a signal generation module in the frequency domain, which allocates radio resources for a sequence of elementary signals with a spread spectrum, over which one of the following transformations is performed: fast Fourier transform and serial-parallel conversion, in accordance with the applied radio communication method, for generating a signal in the frequency domain; and a transmission signal generating unit, performing inverse fast Fourier transform of the signal in the frequency domain to generate the transmission signal. 2. The transmitting device according to claim 1, characterized in that the switching module switches the radio communication methods in accordance with information about the applied radio communication method. 3. The transmitting device according to claim 1, characterized in that the switching module transmits a channel state measurement signal using a predetermined frequency band, the allocation of which is requested when switching to a single-carrier radio communication method. 4. The transmitting device according to claim 1, characterized in that it further comprises a control signal generating module, which, when switched to a single-carrier radio communication method, transmits information of at least one of the following parameters: the requested frequency bandwidth for the data channel, amount of data transmitted, data transfer rate. 5. The transmitting device according to claim 4, characterized in that the control signal generation module transmits information about the requested maximum control signal bandwidth. 6. The transmitting device according to claim 5, characterized in that the control signal generating module transmits a control signal in accordance with the frequency bandwidth and the center frequency allocated based on information about the requested maximum frequency bandwidth of the control signal. 7. The transmitting device according to claim 6, characterized in that the control signal generating module transmits the control signal by a frequency hopping method. 8. The transmitting device according to claim 7, characterized in that the control signal generating module transmits a control signal in each allocated frequency band by a frequency hopping method. 9. The transmitting device according to claim 1, characterized in that the signal generation module in the frequency domain repeats a predetermined number of times a spread spectrum elementary waveform to which a fast Fourier transform is applied, and shifts each elementary sequence repeated a certain number of times, with the formation of a predetermined structure of elementary signals. 10. The transmitting device according to claim 1, characterized in that the signal generation module in the frequency domain allocates radio resources depending on the type of physical channel. 11. The transmitting device according to claim 10, characterized in that the signal generation module in the frequency domain, when allocating the frequency block to the physical channel, allocates radio resources in the time scale of the duration of the transmission interval of the frequency block. 12. The transmitting device of claim 10, characterized in that the signal generation module in the frequency domain allocates radio resources so that at least a portion of the allocated frequency band is a channel with competition in the case of the need to transmit a signal. 13. The transmitting device of claim 10, characterized in that the signal generation module in the frequency domain allocates radio resources in accordance with the planning result, if the transmitted signal is assigned to a multiplexed control channel. 14. The transmitting device according to claim 10, characterized in that the signal generation module in the frequency domain allocates radio resources in accordance with the planning result, if the transmitted signal is assigned to a multiplexed data channel. 15. The transmitting device according to 14, characterized in that the module for generating signals in the frequency domain allocates radio resources in accordance with the result of planning in the time domain in a frequency division multiplexed access method. 16. The transmitting device according to clause 15, wherein the signal generation module in the frequency domain allocates a plurality of frequency blocks in accordance with the data transfer rate. 17. The transmitting device according to 14, characterized in that the signal generation module in the frequency domain allocates radio resources in accordance with the result of the planning in the time domain and the frequency domain. 18. The transmitting device according to 17, characterized in that the signal generation module in the frequency domain groups the frequency blocks for allocation. 19. The transmitting device according to 14, characterized in that the signal generation module in the frequency domain changes the selected frequency bandwidth in accordance with the data transmission rate when transmitting with a single carrier. 20. A receiving device comprising: a radio communication method determination module defining a radio communication method used by the transmission device; a reporting module reporting a specific radio communication method. 21. The receiving device according to claim 20, characterized in that the module for determining the radio communication method determines the radio communication method in accordance with the environment in which the receiving device is installed. 22. The receiving device according to claim 20, characterized in that the module for determining the radio communication method determines the radio communication method in accordance with the configuration of the cell. 23. The receiving device according to claim 20, characterized in that the radio communication method determining module determines a radio communication method for each transmission device. 24. The receiving device according to claim 20, characterized in that the module for determining the radio communication method determines the radio communication method in accordance with the distance between the transmitting device and the receiving device. 25. The receiving device according to claim 20, characterized in that the module for determining the radio communication method determines the radio communication method in accordance with the transmit power of the transmitting device. 26. The receiving device according to claim 20, characterized in that it further comprises a radio resource allocation determination module determining a frequency band to be allocated in accordance with a frequency band in which a channel state measurement signal is transmitted, the reporting module transmitting information about a certain frequency band. 27. The receiver of claim 26, wherein the radio resource allocation determination unit allocates a frequency band within the frequency band in which the channel state measurement signal is transmitted. 28. The receiver according to claim 27, wherein the radio resource allocation determination unit determines a transmission device to which the frequency should be allocated for each predetermined frequency allocation unit in accordance with the information of at least one of the following parameters: the receiving power of the signal measuring the channel status in the receiving device, the type of data transmitted by the transmitting device, the transmission latency, and the maximum transmit power of each mobile station. 29. The receiver according to claim 26, wherein the radio resource allocation determination unit allocates a continuous frequency band to one transmitter in accordance with reception characteristics for each transmitter if the radio communication method is defined as a single-carrier method. 30. The receiving device according to claim 20, characterized in that it further comprises a pilot signal assignment module that determines a center frequency and a transmission bandwidth of a pilot signal for each transmitter and transmits information about a center frequency and a transmission bandwidth of a pilot signal to respective transmitters devices. 31. The receiving device according to claim 30, wherein the pilot signal assignment module transmits information about a certain central frequency and a bandwidth of the pilot signal transmission to respective transmitting devices by transmitting an identifier of a frequency block. 32. The receiving device according to p. 30, characterized in that the control signal assignment module determines the transmission bandwidth in accordance with the maximum transmit power of each transmitting device and the level of loss in the transmission path between each transmitting device and the receiving device. 33. The receiving device according to p, characterized in that the control signal assignment module determines the frequency bandwidth in the form of an integer multiple of the minimum frequency bandwidth defined in the system, or the product of the minimum frequency bandwidth defined in the system by 2 ⁿ . 34. The receiver according to claim 33, wherein the pilot assignment module determines the frequency bandwidth as the maximum transmission bandwidth if the expected value of the received signal-to-noise and noise ratio when the transmitter transmits a control signal with a maximum transmit power is required the value of the received ratio of the signal to interference and noise or exceeds it. 35. The receiver according to claim 33, wherein the pilot assignment module determines the frequency bandwidth as the minimum transmission bandwidth if the expected value of the received signal to noise and noise ratio when the transmitter transmits a control signal with a minimum transmission bandwidth becomes less than the required value of the received ratio of the signal to interference and noise. 36. The receiving device according to clause 34, wherein the pilot signal assignment module calculates the expected value of the received signal to noise ratio using the average level of losses in the transmission path between the receiving device and the transmitting device and the average interference power in the receiving device. 37. The receiver of claim 30, wherein the pilot assignment module determines a center frequency and a bandwidth of the pilot signal in accordance with the total receiving power in the uplink. 38. The receiving device according to clause 37, wherein the pilot assignment module determines in advance the reference value of the deviation of the receiving power of the control signal for each transmitter and determines the center frequency and bandwidth of the transmission of the pilot signal for each transmitter so that the deviation was equal to or less than the reference value. 39. The receiving device according to clause 37, wherein the pilot assignment module allocates a control signal transmission frequency band so that the number of transmitting devices transmitting control signals in each frequency band is proportional. 40. The receiver of claim 30, wherein the pilot assignment module determines a center frequency and a transmission bandwidth of the pilot for each transmitter in accordance with the residual value of the repetition coefficient. 41. The receiving device according to p. 30, characterized in that it further comprises a module for measuring reception characteristics, measuring the reception characteristics of the control signal, and a module for determining the allocation of radio resources, allocating a frequency band within the transmission band of the control signal to each transmitting device in accordance with the information about the reception characteristic, the transmission frequency band of the control signal and the required data channel bandwidth. 42. The receiving device according to paragraph 41, wherein the radio resource allocation determination unit allocates a frequency band to each transmission device in accordance with a predetermined frequency allocation unit. 43. The receiving device according to paragraph 41, wherein the radio resource allocation determination unit uses a pre-measured reception characteristic as a reception characteristic of a frequency band in which there is no transmission of a control signal. 44. The receiving device according to paragraph 41, wherein the module for measuring reception characteristics measures the reception characteristic of the transmitted control signal using a predetermined frequency allocation unit as the unit of measurement. 45. The receiving device according to paragraph 41, wherein the module for measuring reception characteristics measures the reception characteristic of the transmitted control signal using the frequency band requested for allocation for the data channel as the unit of measurement. 46. The receiving device according to p, characterized in that the module determines the allocation of radio resources assigns the transmit power on the upward channel in accordance with the allocated bandwidth. 47. The receiving device according to p, characterized in that the module determines the allocation of radio resources assigns transmission power in accordance with the interference power in the allocated frequency band so that the ratio of the requested radio wave power to the interference power is equal to a predetermined value. 48. The receiving device according to p. 26, characterized in that the module determines the allocation of radio resources sets at least one of the following: the required quality of the data channel and the required signal quality of measuring the channel status. 49. The receiver of claim 48, wherein the radio resource allocation determination module transmits at least one of the following on a broadcast channel: a required quality of a data channel and a required quality of a signal for measuring a channel state. 50. The receiving device according to p, characterized in that the module determines the allocation of radio resources determines the transmit power in accordance with the required signal quality measurement channel status, if the data channel is not allocated. 51. The receiver of claim 48, wherein the radio resource allocation determination unit controls the transmit power of the channel state measurement signal and a portion of the time-multiplexed data in the transmission frame in accordance with the required quality of the data channel if the data channel is allocated. 52. The receiving device according to p. 26, characterized in that the module determines the allocation of radio resources assigns transmit power with the provision of essentially constant density of the transmit power. 53. The receiving device according to claim 46, characterized in that when transmitting by the transmitting device to which the frequency band is allocated, the signal in accordance with the assigned transmit power and the receiving power of the channel state measurement signal, the radio resource allocation determination unit selects the use of an instantaneous value or an average value the receiving power of the signal transmitted by the transmitting device to the receiving device, and the interference power, and determines the modulation method and the degree of error correction code in accordance with the ratio of power to certain specific reception interference power. 54. The receiver according to claim 53, wherein the radio resource allocation determination module determines a modulation and coding scheme in accordance with a reception quality of a pilot signal measured for each frequency allocation unit, and transmits a certain modulation and coding scheme to a transmitting device. 55. The receiving device according to item 53, wherein the module determines the allocation of radio resources determines the modulation and coding scheme in accordance with the reception quality of the control signal in the allocated frequency band, and transmits a certain modulation and coding scheme to the transmitting device. 56. The receiving device according to item 46, wherein after the radio resource allocation determination module allocates a frequency band to the transmitting device, the radio resource allocation determination module continues to allocate this frequency band to the same transmitting device temporarily until changes the receiving power does not exceed a predetermined threshold value, and the receiving power is the receiving power of the channel state measurement signal of this transmitting device in the allocated th frequency band. 57. A mobile communication system comprising a receiving device and a transmitting device used in a communication system using a single-carrier method and in a communication system using a multi-carrier method, comprising: a radio communication method determination module defining a radio communication method used by the transmission device; a reporting module reporting information about a particular applicable radio communication method; a switching module switching the radio communication method; a signal generation module in the frequency domain, which allocates radio resources for a sequence of elementary signals with a spread spectrum, over which one of the following transformations is carried out: fast Fourier transform and series-parallel conversion, depending on the applied radio communication method, for generating a signal in the frequency domain; and a transmission signal generating unit, performing inverse fast Fourier transform of the signal in the frequency domain to generate the transmission signal. 58. A method for controlling signal transmission, including a step in which the receiving device determines an applicable radio communication method; the step at which the receiving device reports information about a particular radio communication method; the step at which the transmitting device receives information about the radio communication method; a step in which the transmitting device switches the radio communication method in accordance with the information on the radio communication method; a step in which the transmitting device allocates radio resources for a sequence of spread spectrum chips over which one of the following transforms is performed: fast Fourier transform and series-parallel transform, to generate a signal in the frequency domain; and a step in which the transmitting device performs the inverse fast Fourier transform of the signal in the frequency domain to generate a transmission signal. 59. The method according to p, characterized in that it further includes a step in which the transmitting device transmits information to the receiving device about at least one of the following parameters: the required data channel bandwidth, the amount of data transmitted and the transmission rate data. 60. The method according to p, characterized in that it further includes a step in which the transmitting device transmits information about the required maximum transmission bandwidth of the control signal. 61. The method according to § 59, characterized in that it further includes a step in which the transmitting device transmits a control signal in accordance with the width and center frequency of the frequency band assigned in accordance with the information about the required maximum transmission bandwidth of the control signal. 62. The method according to p, characterized in that the control signal is transmitted by a frequency hopping method in a step in which the transmitting device transmits a control signal. 63. The method according to § 58, wherein the step at which the transmitting device allocates radio resources includes a step in which a sequence of spread spectrum chips to which a fast Fourier transform is applied is repeated a predetermined number of times; and a step in which each sequence of spread spectrum chips repeated a predetermined number of times is shifted to obtain a predetermined pattern of chips. 64. The method according to § 58, wherein the step at which the transmitting device allocates radio resources includes a step at which radio resources are allocated in accordance with types of physical channels. 65. The method according to item 64, wherein the step at which radio resources are allocated includes a step at which radio resources are allocated using the transmission time interval in the frequency block as a unit, if this frequency block is allocated to a physical channel. 66. The method according to clause 64, wherein the step at which radio resources are allocated includes a step at which radio resources are allocated in accordance with the planning result, if the transmitted signal is distributed to the multiplex data channel. 67. The method according to p, characterized in that the step at which allocate radio resources includes a step at which radio resources are allocated in accordance with the result of planning in the time domain when using the multiple access frequency division multiple access method. 68. The method of claim 67, wherein the step of allocating radio resources includes a step of allocating a plurality of frequency blocks in accordance with a data rate. 69. The method according to item 64, wherein the step at which allocate radio resources includes a step at which radio resources are allocated in accordance with the result of planning in the time domain and in the frequency domain. 70. The method according to item 64, wherein the step at which radio resources are allocated includes a step at which frequency blocks are grouped and allocated. 71. The method according to p, characterized in that the step at which allocate radio resources includes a step in which the width of the allocated frequency band is changed in accordance with the data transfer rate, if the transmission with a single carrier. 72. The method of claim 64, wherein the step of allocating radio resources includes a step of allocating a frequency band within a frequency band in which a channel state measurement signal is transmitted. 73. The method of claim 72, wherein the step of allocating radio resources includes the step of determining a mobile station for which a frequency is allocated in each frequency allocation unit, in accordance with at least one of the following parameters: the transmit power of the signal measuring the channel status in the transmitting device, the type of data transmitted by the mobile station, the transmission latency and the maximum transmit power of each of the mobile stations. 74. The method of claim 72, wherein the step of allocating radio resources includes a step of allocating a continuous frequency band to one mobile station in accordance with a reception characteristic of each mobile station if the radio method is defined as a method with single carrier. 75. The method according to p, characterized in that it further includes a step in which the receiving device assigns a Central frequency and bandwidth of the transmission signal of the control signal for each transmitting device in accordance with the information about the required maximum transmission bandwidth of the control signal; and a step in which the receiving device transmits information about the determined center frequency and the transmission bandwidth of the pilot signal to the corresponding transmitting device. 76. The method according to item 75, wherein the information about a specific center frequency and bandwidth of the transmission frequency is reported to the corresponding transmitting device by transmitting the identifier of the frequency block in the step at which the receiving device transmits this information. 77. The method according to item 75, wherein the transmission bandwidth is determined in accordance with the maximum transmit power of each transmitting device and the level of losses in the transmission path between each transmitting device and the receiving device in the step at which the receiving device assigns a center frequency and transmission bandwidth. 78. The method according to p, characterized in that the transmission bandwidth is determined to be an integer multiple of the minimum frequency bandwidth defined in the system, or the product of the minimum frequency bandwidth determined in the system by 2 ⁿ in the step at which the receiving device assigns the center frequency and transmission bandwidth. 79. The method according to p, characterized in that in the step in which the receiving device assigns the center frequency and transmission bandwidth, the transmission bandwidth is defined as the maximum bandwidth in which the expected value of the received signal to interference and noise ratio becomes equal to the required value of the received signal-to-noise and noise ratio or exceeds it when the transmitter transmits a control signal with a maximum transmission power. 80. The method according to p, characterized in that in the step in which the receiving device assigns the center frequency and bandwidth of the transmission frequency, the transmission bandwidth is defined as the minimum transmission bandwidth if the expected value of the received signal to interference and noise ratio becomes less than the required value of the received ratio of the signal to interference and noise, when the transmitting device transmits a control signal with maximum transmit power. 81. The method according to p. 79, characterized in that in the step in which the receiving device assigns the center frequency and bandwidth of the transmission frequency, the expected value of the received signal to noise and noise ratio is calculated using the average interference power in the receiver and the average level of losses in the transmission path between the receiver and the transmitter. 82. The method according to item 75, wherein in the step in which the receiving device assigns the center frequency and bandwidth of the transmission frequency, determine the center frequency and bandwidth of the transmission of the control signal in accordance with the total receiving power in the uplink channel. 83. The method according to item 75, wherein in the step in which the receiving device assigns the center frequency and bandwidth of the transmission, for each transmitter, the center frequency and bandwidth of the transmission of the control signal is determined in accordance with the residual value of the repetition coefficient. 84. The method according to p, characterized in that it further includes a step at which the receiving device measures the reception characteristic of the control signal; and a step in which the receiving device allocates to each transmitting device a frequency band within the transmission band of the pilot signal in accordance with information about the reception characteristic, the transmission band of the pilot signal and the required bandwidth. 85. The method of claim 84, wherein in a step in which the receiving device allocates a frequency band, a frequency band is allocated to each transmitting device based on a predetermined frequency allocation unit. 86. The method according to p. 84, characterized in that in the step in which the receiving device allocates a frequency band, a pre-measured reception characteristic is used as a reception characteristic of a frequency band in which there is no transmission of a control signal. 87. The method according to p. 84, characterized in that in the step at which the receiving device measures the characteristic of the reception of the control signal, the characteristic of the reception of the control signal is measured using a predetermined frequency allocation unit. 88. The method according to p. 84, characterized in that in the step at which the receiving device measures the reception characteristic of the control signal, the reception characteristic of the control signal is measured using the frequency band requested for allocation for the data channel as the unit of measurement. 89. The method according to p, characterized in that it further includes a step at which the transmit power in the uplink is assigned in accordance with the allocated frequency band. 90. The method according to p. 89, characterized in that in the step at which the transmit power in the uplink is assigned, the transmit power is assigned in accordance with the interference power in the allocated frequency band so that the ratio of the power of the requested radio waves to the interference power is equal to a predetermined value. 91. The method according to item 65, wherein in the step at which the transmit power in the uplink is assigned, at least one of the following is set: the required quality of the data channel and the required quality of the signal for measuring the channel state. 92. The method according to p. 91, characterized in that in the step at which the transmit power in the upstream channel is assigned, at least one of the following is transmitted via the broadcast channel: the required quality of the data channel and the required quality of the signal for measuring the channel state. 93. The method according to p. 91, characterized in that in the step at which the transmit power in the upstream channel is assigned, the transmit power is adjusted in accordance with the required quality of the channel state measurement signal if the data channel is not allocated. 94. The method according to p. 91, characterized in that in the step at which the transmit power in the upstream channel is assigned, for the part of the channel state measurement signal and the part of the time-multiplexed data in the transmission frame, the transmit power is adjusted in accordance with the desired channel quality data if the data channel is allocated. 95. The method according to p. 89, characterized in that the step at which the transmit power in the uplink is assigned includes a step in which the transmit power is assigned with a substantially constant transmit power density. 96. The method according to p. 89, characterized in that it further includes a step on which the transmitting device to which the frequency band is allocated, transmits a signal in accordance with the assigned transmit power and the receiving power of the channel state measurement signal, wherein the receiving device uses an instantaneous value or the average value of the receiving power of the signal transmitted by the transmitting device, and the interference power is determined; and a step in which the modulation method and degree of the error correction code is determined in accordance with the ratio of the determined receiving power to the interference power. 97. The method according to p, characterized in that in the step at which the modulation method and the degree of the error correction code are determined, the modulation and coding scheme is determined in accordance with the quality of reception of the control signal measured for each frequency allocation unit. 98. The method according to p. 96, characterized in that in the step at which the modulation method and the degree of error correction code are determined, the modulation and coding scheme is determined in accordance with the quality of reception of the control signal measured in the selected frequency band. 99. The method according to item 65, wherein in the step at which radio resources are allocated, after allocating a frequency band to the transmitting device, this frequency band continues to be allocated to the same transmitting device temporarily until the received power changes exceed a predetermined threshold value, and the receiving power is the receiving power of the signal measuring the channel status of this transmitting device in the allocated frequency band.