JP4112397B2 - Multi-carrier wireless communication system and multi-carrier modulation circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multicarrier radio communication system and a multicarrier modulation circuit, and more particularly to an orthogonal frequency division multiplex (OFDM) radio communication system and a modulation circuit.
[0002]
[Prior art]
The multicarrier modulation scheme is a scheme for transmitting information using a plurality of subcarriers. For each subcarrier, the input data signal is modulated using a QPSK (Quadrature phase shift keying) method or the like. Among the multicarrier modulation methods, the orthogonal multicarrier modulation method in which the frequencies of the subcarriers are orthogonal is also called orthogonal frequency division multiplexing, and is widely applied in wireless communication systems in which multipath propagation is a problem. .
[0003]
FIG. 10 is a block diagram showing a configuration of a conventional multicarrier modulation circuit (see, for example, Non-Patent Document 1). FIG. 11 is a diagram showing a packet format of a packet signal transmitted using a conventional multicarrier modulation circuit. Hereinafter, the operation of the conventional multicarrier modulation circuit will be described with reference to FIGS.
[0004]
The data generation circuit 401 generates transmission data S240. Subcarrier modulation circuit 402 performs subcarrier modulation on transmission data S240. The serial-to-parallel conversion circuit 403 divides the subcarrier-modulated serial data signal S240 in correspondence with the subcarrier, and converts it into a parallel signal for each subcarrier.
[0005]
On the other hand, the short preamble signal generation circuit 407 and the long preamble signal generation circuit 408 respectively generate a short preamble signal S210 and a long preamble signal S220 defined in the IEEE802.11a standard, which is a wireless LAN standard. Further, the control signal generation circuit 409 generates a control signal S230 indicating control information such as a packet length of the data signal S240.
[0006]
The transmission order control circuit 404 is supplied with a data signal S240 converted into a signal for each subcarrier, a short preamble signal S210, a long preamble signal S220, and a control signal S230. The transmission order control circuit 404 is shown in FIG. As shown, the short preamble signal S210, the long preamble signal S220, the control signal S230, and the data signal S240 are output in this order. An inverse fast Fourier transform (IFFT) circuit 405 converts the output signal in the frequency domain output from the transmission order control circuit 404 into a multi-carrier signal in the time domain. The parallel-serial conversion circuit 406 arranges parallel multicarrier signals in the order of output in the time axis direction, and outputs a serial transmission signal.
[0007]
[Non-Patent Document 1]
Richard van Nee, Ramjee Prasad, “OFDM for wireless multimedia communications”, Artech house publishers, 2000
[0008]
[Problems to be solved by the invention]
At present, wireless communication systems in the microwave band are remarkably widespread because they are easy to realize non-line-of-sight communication and easily diffract radio waves. In wireless communication in the microwave band, it is desired to construct a higher speed system. However, when a new system is constructed in this microwave band, the usable frequency band is very limited, and therefore it is preferable to use the frequency band used in the existing system. At this time, if all the existing systems are replaced with the new system, a cost burden is imposed on the user who has used the existing system. Therefore, it is desirable that the existing system and the new system coexist in the same frequency band.
[0009]
In the following, we consider the impact of the new system on the existing system when the existing system and the new system coexist in the same frequency band. Here, a wireless LAN system compliant with the IEEE802.11a standard of the wireless LAN is an existing system, and a wireless LAN system whose transmission speed is improved based on the IEEE802.11a standard is a new system.
[0010]
In the IEEE802.11a standard, the CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance) method is used as the access method, and carrier sense is performed to determine whether signals from other stations exist before transmission. Yes. In order to determine whether transmission is possible based on the result of the carrier sense, it is necessary to determine whether the received signal is a signal from the own system or a simple interference signal. Therefore, in the IEEE802.11a standard, the signal from the own system and the interference signal are identified based on the received signal level and the preamble signal. When it is determined that an interference signal has arrived, the carrier sense level that is a threshold for signal detection is raised. Under this, if the new system does not have the same preamble signal as the existing system, when the signal from the new system arrives at the receiver of the existing system, the receiver of the existing system determines that an interference signal has arrived. , Raise career sense level. As a result, the existing system cannot detect a signal coming from a long distance, and the cell radius becomes small. In addition, the throughput per cell is reduced.
[0011]
In addition, if the symbol rate of the new system is increased over the existing system to increase the transmission speed, the signal bandwidth per subcarrier becomes thicker, and the receiver of the existing system demodulates the signal of the new system. Can not do it. For this reason, the receiver of the existing system determines that the signal of the new system is an interference signal, and raises the carrier sense level. As a result, similar to the above, there is a negative effect associated with raising the carrier sense level.
[0012]
Furthermore, in the IEEE802.11a standard, random access control is performed based on the CSMA / CA method. In order to perform this control, the receiver of each station needs to recognize the time length of a packet transmitted from another station. The time length of the packet is described as control information in the control unit of one OFDM symbol transmitted following the long preamble signal. Therefore, if the new system does not have a control signal that can be demodulated by the existing system, the existing system cannot recognize the packet length of the transmission packet from the new system. As a result, each station in the existing system cannot normally perform random access control, and the packet transmission period is postponed more than necessary, resulting in a decrease in throughput.
[0013]
The present invention has been made in view of the above-described circumstances, and it is possible to suppress the adverse effects on the existing system due to the overlapping use while overlappingly using the frequency band used in the existing multicarrier wireless communication system. An object is to provide a multicarrier radio communication system and a multicarrier modulation circuit.
[0014]
[Means for Solving the Problems]
A first invention for solving the above-described problems and achieving the object is a multi-carrier radio communication system that uses the frequency band of an existing multi-carrier radio communication system in an overlapping manner. The frequency bandwidth and center frequency of each subcarrier is the same as that of the existing multicarrier radio communication system, and corresponds to the communication channel of the existing multicarrier radio communication system in which the frequency band overlaps with the data signal to be transmitted. In the frequency band, prior to the transmitted data signal, the same signal as the preamble signal used for recognition of the existing system in the existing multicarrier wireless communication system is transmitted. .
[0015]
Further, according to a second invention, in the first invention, prior to the data signal to be transmitted, the same control signal used in the existing multicarrier radio communication system and the control signal The same signal as the preamble signal for enabling demodulation of the signal is transmitted.
[0016]
The third invention is a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means is converted into a parallel signal corresponding to each subcarrier. Serial-parallel conversion means, preamble signal generation means for generating a preamble signal, preamble signal arrangement means for arranging the preamble signal generated by the preamble signal generation means in the frequency direction, the preamble signal arrangement means, and the serial-parallel conversion A transmission order control means for outputting the output signals from the means arranged in the order, a signal conversion means for converting a frequency domain signal output from the transmission order control means into a time domain signal, and an output from the signal conversion means Parallel / serial conversion means for converting the parallel signal to be converted into a serial transmission signal Is a multi-carrier modulation circuit characterized and.
[0017]
According to a fourth aspect of the present invention, subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means is converted into a parallel signal corresponding to each subcarrier. Serial / parallel conversion means, first signal conversion means for converting a frequency domain signal output from the serial / parallel conversion means into a time domain signal, and parallel signals output from the first signal conversion means in series First parallel-serial conversion means for converting to a signal; preamble signal generation means for generating a preamble signal; preamble signal arrangement means for arranging the preamble signal generated by the preamble signal generation means in the frequency direction; and the preamble signal Second signal converting means for converting a frequency domain signal output from the arranging means into a time domain signal; A second parallel-serial conversion unit that converts a parallel signal output from the second signal conversion unit into a serial signal; a preamble signal output from the second parallel-serial conversion unit; and the first parallel-serial conversion unit And a switching unit that outputs the data signals to be output in the order.
[0018]
Further, a fifth invention is the above-mentioned fourth invention, further comprising storage means for storing a preamble signal output from the second parallel-serial conversion means, wherein the switching means is the second parallel The preamble signal output from the serial conversion means is read from the storage means.
[0019]
In a sixth aspect based on any one of the third to fifth aspects, the preamble signal is used for recognizing an existing system in an existing multicarrier wireless communication system (hereinafter referred to as an existing system). The preamble signal arrangement means arranges the preamble signal in a frequency band corresponding to a communication channel of the existing system in which a frequency band overlaps with the data signal. And
[0020]
  A multicarrier radio communication system according to the present invention includes a multiband including a frequency band corresponding to one or more communication channels of an existing multicarrier radio communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. In a carrier radio communication system, in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal, the frequency bandwidth and center of each subcarrier Prior to the transmitted data signal in a frequency band that is the same as the existing system and overlaps a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. The preamble used for recognition of the existing system in the existing system A first preamble signal identical to the signal, a first control signal identical to the control signal used in the existing system, and a preamble signal used to enable demodulation of the first control signal; The same second preamble signal is transmitted, and the transmitted data signal is transmitted in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. In advance, a second control signal used for communication control of the multicarrier wireless communication system and a third preamble signal for enabling demodulation of the second control signal are transmitted.
  The multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier Serial-parallel conversion means for converting into a parallel signal corresponding to the carrier and outputting as a signal in the frequency domain, and a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system First preamble signal generation means for generating and the transmission in the frequency domain signal In the existing system, first preamble signal arrangement means for arranging the first preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of a power data signal First control signal generating means for generating a first control signal identical to the control signal being used, and second control for generating a second control signal used for communication control of the multicarrier wireless communication system The first control signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain, Frequency corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain Control signal arrangement means for arranging the second control signals in frequency bands that do not overlap with each other, and a second preamble that is the same as the preamble signal used to enable demodulation of the control signals in the existing system Second preamble signal generating means for generating a signal, third preamble signal generating means for generating a third preamble signal for enabling demodulation of the second preamble signal, and the transmission in the frequency domain signal The second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted, and the data signal to be transmitted in the signal in the frequency domain A frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band Second preamble signal arranging means for arranging the third preamble signal respectively, the first preamble signal arranging means, the second preamble signal arranging means, the control signal arranging means, and the serial / parallel conversion A transmission order control means for outputting the output signals from the means arranged in the order, a signal conversion means for converting a frequency domain signal output from the transmission order control means into a time domain signal, and an output from the signal conversion means Parallel-serial conversion means for converting the parallel signal to be converted into a serial transmission signal.
[0021]
  The multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier A serial / parallel converter that converts the parallel signal corresponding to the carrier and outputs the signal as a frequency domain signal, and a first signal converter that converts the frequency domain signal output from the serial / parallel converter to a time domain signal. And a first parallel / serial conversion for converting the parallel signal output from the first signal conversion means into a serial first transmission signal. Means, a first preamble signal generating means for generating a first preamble signal identical to a preamble signal used for recognition of the existing system in the existing system, and the transmission in the frequency domain signal A first preamble signal arrangement means for arranging the first preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal; and used in the existing system First control signal generating means for generating a first control signal identical to the control signal being transmitted, and a second control signal for generating a second control signal used for communication control of the multicarrier wireless communication system Generating means and a frequency domain signal of the existing system in the frequency band of the data signal to be transmitted The first control signal in a frequency band that overlaps the frequency band corresponding to the communication channel described above is transferred to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain. Control signal placement means for placing the second control signal in a frequency band that does not overlap with a corresponding frequency band, and the same preamble signal used for enabling demodulation of the control signal in the existing system Second preamble signal generating means for generating a second preamble signal; third preamble signal generating means for generating a third preamble signal for enabling demodulation of the second control signal; Frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal The frequency band that does not overlap the frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal in the frequency band that overlaps with the second preamble signal Output signals from the second preamble signal arranging means, the first preamble signal arranging means, the second preamble signal arranging means, and the control signal arranging means for arranging the third preamble signal respectively. Transmission order control means for arranging and outputting in this order, second signal conversion means for converting a frequency domain signal output from the transmission order control means into a time domain signal, and output from the second signal conversion means Second parallel / serial conversion means for converting the parallel signal to be converted into a serial second transmission signal, and output from the second parallel / serial conversion means A first transmission signal outputted from the second transmission signal and the first parallel to serial conversion means and having a switching means for outputting side by side in the order in which.
[0022]
  The multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier A serial-to-parallel converter that converts the signal into a parallel signal corresponding to the carrier and outputs the signal as a frequency domain signal, and a first control signal generator that generates a first control signal identical to the control signal used in the existing system Means for generating a second control signal used for communication control of the multicarrier wireless communication system Control signal generating means, and the first control signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal to be transmitted in a frequency domain signal, A control signal for arranging the second control signal in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain An arrangement means, a first transmission order control means for outputting the output signals from the control signal arrangement means and the serial-parallel conversion means in the order, and a frequency domain output from the first transmission order control means. First signal conversion means for converting a signal into a signal in the time domain, and a parallel signal output from the first signal conversion means as a first transmission signal in series First parallel / serial conversion means for converting, first preamble signal generation means for generating a first preamble signal identical to a preamble signal used for recognition of the existing system in the existing system, and a frequency A first preamble signal arrangement that arranges the first preamble signal in a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal to be transmitted in a signal in a region Means, a second preamble signal generating means for generating a second preamble signal identical to a preamble signal used for demodulating the control signal in the existing system, and the second preamble signal Third preamble signal generation for generating a third preamble signal for enabling demodulation And the second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal. The second preamble signal in which the third preamble signal is arranged in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted An arrangement unit, a second transmission order control unit that outputs the output signals from the first preamble signal arrangement unit and the second preamble signal arrangement unit in the order, and the second transmission order control unit. Second signal conversion means for converting an output frequency domain signal into a time domain signal, and the second signal conversion means Second parallel / serial conversion means for converting the parallel signal output from the second parallel / serial conversion means, and storage means for storing the second transmission signal output from the second parallel / serial conversion means; Switching means for reading the second transmission signal from the storage means and sending out the second transmission signal prior to sending out the first transmission signal received from the first parallel-serial conversion means. It is characterized by that.
[0023]
MaThe multicarrier wireless communication system according to the present invention includes a frequency band of a data signal transmitted in a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system). A frequency band of each subcarrier in a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. And the data signal to be transmitted in a frequency band that is the same as the existing system and overlaps with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. Prior to the pre-installation, the pre-existing system used for recognition of the existing system is used. The same first preamble signal as the preamble signal, the same first control signal as the control signal used in the existing system, and the same preamble signal used for demodulating the control signal A second preamble signal is transmitted and precedes the transmitted data signal in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. A second control signal used for communication control of the multicarrier wireless communication system, and a third preamble signal for enabling demodulation of the second control signal, respectively, the first control signal, and The second preamble signal is transmitted simultaneously with the second preamble signal.The
MaThe multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier Serial-parallel conversion means for converting into a parallel signal corresponding to the carrier and outputting as a signal in the frequency domain, and a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system First preamble signal generation means for generating and transmitting the signal in the frequency domain signal In the existing system, first preamble signal arrangement means for arranging the first preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of a data signal First control signal generating means for generating a first control signal identical to the control signal being used, and second control for generating a second control signal used for communication control of the multicarrier wireless communication system The first control signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain, Frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain Control signal placement means for simultaneously placing the second control signals in frequency bands that do not overlap each other, and a second preamble that is the same as the preamble signal used to enable demodulation of the control signals in the existing system A second preamble signal generating means for generating a signal; a third preamble signal generating means for generating a third preamble signal for enabling demodulation of the second control signal; and the transmission in the frequency domain signal. The second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted, and the data signal to be transmitted in the signal in the frequency domain Previous to a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band Second preamble signal arrangement means for arranging the third preamble signals simultaneously, the first preamble signal arrangement means, the second preamble signal arrangement means, the control signal arrangement means, and the direct parallel conversion A transmission order control means for outputting the output signals from the means arranged in the order, a signal conversion means for converting a frequency domain signal output from the transmission order control means into a time domain signal, and an output from the signal conversion means Parallel-serial conversion means for converting the parallel signal to be converted into a serial transmission signal.The
  MaThe multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier A serial / parallel converter that converts the parallel signal corresponding to the carrier and outputs the signal as a frequency domain signal, and a first signal converter that converts the frequency domain signal output from the serial / parallel converter to a time domain signal. And a first parallel / serial conversion for converting the parallel signal output from the first signal converting means into a serial first transmission signal. A first preamble signal generating means for generating a first preamble signal identical to a preamble signal used for recognition of the existing system in the existing system, and the transmission in the frequency domain signal A first preamble signal arrangement means for arranging the first preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal; and used in the existing system First control signal generating means for generating a first control signal identical to the control signal being transmitted, and a second control signal for generating a second control signal used for communication control of the multicarrier wireless communication system Generating means and one of the existing systems in the frequency band of the data signal to be transmitted in the frequency domain signal The first control signal in a frequency band that overlaps the frequency band corresponding to the upper communication channel is transmitted to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain. Control signal placement means for simultaneously placing the second control signals in frequency bands that do not overlap with corresponding frequency bands, and the same preamble signal used to enable demodulation of the control signals in the existing system Second preamble signal generating means for generating the second preamble signal, third preamble signal generating means for generating a third preamble signal for enabling demodulation of the second control signal, and a frequency domain Frequency corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted A second preamble signal in which the second preamble signal is arranged in a frequency band overlapping with several bands, and the third preamble signal in the frequency band of the data signal to be transmitted in the signal in the frequency domain is arranged simultaneously. Arrangement means, first preamble signal arrangement means, second preamble signal arrangement means, transmission order control means for outputting the output signals from control signal arrangement means in the order, and transmission order control means A second signal converting means for converting a frequency domain signal output from the second signal converting means to a time domain signal, and a second signal for converting a parallel signal output from the second signal converting means into a second transmission signal in series. Parallel-serial conversion means, a second transmission signal output from the second parallel-serial conversion means, and a first output from the first parallel-serial conversion means. To the transmission signal, comprising a switching means for outputting side by the orderThe
  MaThe multicarrier modulation circuit according to the present invention includes a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system) in a frequency band of a data signal to be transmitted. A multicarrier modulation circuit applied to a multicarrier radio communication system, wherein a subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted, and a serial signal output from the subcarrier modulation means for each subcarrier A serial-to-parallel converter that converts the signal into a parallel signal corresponding to the carrier and outputs the signal as a frequency domain signal, and a first control signal generator that generates a first control signal identical to the control signal used in the existing system And a second control for generating a second control signal used for communication control of the multicarrier wireless communication system. The first control signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the signal in the frequency domain, A control signal that simultaneously arranges the second control signal in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal to be transmitted in the frequency domain signal. An arrangement means, a first transmission order control means for outputting the output signals from the control signal arrangement means and the serial-parallel conversion means in the order, and a frequency domain output from the first transmission order control means. A first signal converting means for converting the signal into a signal in the time domain, and a parallel signal output from the first signal converting means for the first transmission signal in series; First parallel-serial conversion means for converting to a first preamble signal generation means for generating a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system; A first preamble signal that arranges the first preamble signal in a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal Placing means, second preamble signal generating means for generating a second preamble signal identical to a preamble signal used for enabling demodulation of the control signal in the existing system, and the second control signal Third preamble signal generating means for generating a third preamble signal for enabling demodulation of the signal And the second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal. A second preamble signal in which the third preamble signal is simultaneously arranged in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in a frequency band of the data signal to be transmitted in the signal An arrangement unit, a second transmission order control unit that outputs the output signals from the first preamble signal arrangement unit and the second preamble signal arrangement unit in the order, and the second transmission order control unit. A second signal converting means for converting the output frequency domain signal into a time domain signal, and the second signal converting means; Second parallel / serial conversion means for converting a parallel signal output from the second parallel / serial conversion means, and storage means for storing the second transmission signal output from the second parallel / serial conversion means; Switching means for reading the second transmission signal from the storage means and sending out the second transmission signal prior to sending out the first transmission signal received from the first parallel-serial conversion means. It is characterized byThe
  MaThe multicarrier wireless communication system according to the present invention includes a frequency band of a data signal transmitted in a frequency band corresponding to one or more communication channels of an existing multicarrier wireless communication system (hereinafter referred to as an existing system). A frequency band of each subcarrier in a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. And the data signal to be transmitted in a frequency band that is the same as the existing system and overlaps with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal. Prior to the pre-installation, the pre-existing system used for recognition of the existing system is used. First preamble signal identical to the enable signal, the existing control signals used in a system identical to the first control signal, and theFirstA second preamble signal identical to the preamble signal used to make the control signal demodulatable is transmitted.The multicarrier to be transmitted prior to the transmitted data signal in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal The second control signal used for communication control of the wireless communication system and the third preamble signal for enabling demodulation of the second control signal are omitted.It is characterized by that.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Exemplary embodiments of a multicarrier wireless communication system according to the present invention will be described below in detail from the first embodiment to the second embodiment with reference to the accompanying drawings. Further, preferred embodiments of the multicarrier modulation circuit according to the present invention will be described in detail by dividing the third embodiment to the fifth embodiment.
[0025]
(First embodiment)
The multicarrier radio communication system according to the present embodiment is a multicarrier radio communication system that uses the frequency band of an existing multicarrier radio communication system in an overlapping manner, and in the overlapping frequency band, the frequency band of each subcarrier In the existing system prior to the transmitted data signal in the frequency band corresponding to the communication channel of the existing system where the width and the center frequency are the same as the existing system and the frequency band overlaps with the transmitted data signal. The same signal as the preamble signal used for recognition of the existing system is transmitted. Hereinafter, the present embodiment will be described with reference to the drawings.
[0026]
FIG. 1 is a block diagram showing an overall configuration of a multicarrier radio communication system and an existing multicarrier radio communication system according to the present embodiment. In FIG. 1, an existing multicarrier wireless communication system 2 (hereinafter referred to as an existing system) includes a transmitter 21 (hereinafter referred to as an existing transmitter) and a packet signal S2 transmitted from the existing transmitter 21. Receiver 22 (hereinafter referred to as an existing receiver). In the present embodiment, it is assumed that the existing system 2 is a wireless LAN system compliant with the IEEE802.11a standard. A multi-carrier wireless communication system 1 (hereinafter referred to as a new system) according to the present embodiment, which is a newly constructed wireless LAN system, includes a transmitter 11 (hereinafter referred to as a new transmitter) and the new transmission. A receiver 12 (hereinafter referred to as a new receiver) that receives the packet signal S1 transmitted from the receiver 11.
[0027]
FIG. 2 is a diagram showing the arrangement of communication channels in the frequency direction of the new system 1 and the existing system 2. In FIG. 2, the frequency band used by the existing system 2 is 5150 MHz to 5250 MHz, and communication channels ch1 ′ to ch4 ′ having a width of 16.6 MHz are provided by four channels via a guard band GB having a width of 3.4 MHz. ing. Here, each communication channel ch1 ′ to ch4 ′ is divided into 52 subcarriers as shown in FIG. In the new system 1, the two communication channels of the existing system 2 and the intervening guard band frequency band are combined into one communication channel, and a total of two communication channels ch1 and ch2 are provided. Further, like the existing system 2, the communication channels ch1 and ch2 of the new system 1 are divided into a plurality of subcarriers. Of the frequency bands of the communication channels ch1 and ch2 of the new system 1, in the frequency band overlapping with the frequency bands of the communication channels ch1 'to ch4' of the existing system 2, the frequency bandwidth and center frequency of each subcarrier are This is the same as the existing system 2. As described above, in the new system 1, the frequency band used in the existing system 2 is redundantly used, and the number of subcarriers included in one communication channel is increased, thereby effectively using the limited frequency band. The speed of communication will be increased.
[0028]
FIG. 3 is a diagram illustrating a packet format of the packet signal S2 transmitted from the existing transmitter 21 of the existing system 2. As shown in FIG. 3, in the existing system 2, prior to the data signal S240, a short preamble signal S210, a long preamble signal S220, and a control signal S230 are sequentially transmitted. In the present embodiment, the short preamble signal S210 is a signal used for recognition of the existing system 2 in the existing system 2. That is, this is a signal for the existing receiver 22 to recognize the packet signal S2 transmitted from the existing transmitter 21. Further, the long preamble signal S220 is a signal for synchronization processing and the like, and is a signal for enabling the control signal S230 to be demodulated. The control signal S230 is a signal indicating control information such as the packet length of the data signal S240, the transmission speed of the data signal S240, the subcarrier modulation method, and the like, and is a signal used for various communication controls in the existing receiver 22. Here, the signal indicating the packet length of the data signal S240 included in the control signal S230 is used for random access control. Note that the short preamble signal S210 and the long preamble signal S220 are defined in the IEEE802.11a standard, but their uses are not particularly defined.
[0029]
FIG. 4 is a diagram illustrating a packet format of the packet signal S1 transmitted from the new transmitter 11 of the present embodiment. In FIG. 4, the frequency bands B1 and B2 correspond to the occupied frequency bands of the communication channels ch1 ′ and ch2 ′ of the existing system 2, respectively. As shown in FIG. 4, in the new system 1, the frequency band B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the transmitted data signal S140 is prior to the data signal S140. Thus, the same signals S111 and S112 as the short preamble signal S210 of the existing system 2 are transmitted. Prior to the data signal S140, the long preamble signal S120 for the new system and the control signal S130 for the new system are transmitted after the same signals S111 and S112 as the short preamble signal.
[0030]
In such a configuration, when the packet signal S1 shown in FIG. 4 transmitted from the new transmitter 11 arrives at the new receiver 12, the new receiver 12 uses the long signal for the new system included in the packet signal S1. The data signal S140 is demodulated using the preamble signal S120 and the control signal S130 for the new system.
[0031]
Next, the case where the packet signal S1 shown in FIG. 4 transmitted from the new transmitter 11 arrives at the existing receiver 22 will be described. In the new system 1, the frequency bandwidth and the center frequency of each subcarrier are the same as those in the existing system 2 in the frequency band of the communication channels ch 1 ′ to ch 4 ′ of the existing system 2. Therefore, when receiving the packet signal S1 shown in FIG. 4, the existing receiver 22 receives subcarriers having the same frequency bandwidth and center frequency as those of the existing system 2 in the communication channels ch1 ′ and ch2 ′. It will be. Further, in the frequency bands B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the data signal S140, the same as the short preamble signal S210 of the existing system 2 prior to the data signal S140. Signals S111 and S112 are transmitted. Therefore, when receiving the packet signal S1 shown in FIG. 4, the existing receiver 22 recognizes that the packet signal S2 of the existing system 2 shown in FIG. 3 has been received in the communication channels ch1 ′ and ch2 ′. It is not judged as an interference signal. Therefore, the existing receiver 22 does not raise the carrier sense level even when the packet signal S1 from the new transmitter 11 arrives.
[0032]
As described above, in the multicarrier wireless communication system according to the present embodiment, in the overlapping frequency bands, the frequency bandwidth and center frequency of each subcarrier are the same as those of the existing system 2, and the data signal S140 and the frequency to be transmitted are the same. In the frequency bands B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 with overlapping bands, the existing system 2 is used for recognition of the existing system 2 prior to the data signal S140 to be transmitted. The same signals S111 and S112 as the preamble signal S210 are transmitted. Therefore, according to the present embodiment, when the packet signal S1 of the new transmitter 11 arrives at the existing receiver 22, the existing receiver 22 recognizes the packet signal S1 as a packet signal of the existing system 2, It is not judged as an interference signal. As a result, it is possible to avoid an adverse effect caused by the existing system 2 recognizing the packet signal S1 of the new system 1 as an interference signal. Specifically, it is possible to avoid a decrease in cell radius and a decrease in throughput per cell due to an increase in carrier sense level.
[0033]
In addition, since the frequency band used in the existing system 2 is used in an overlapping manner and the occupied frequency band of one communication channel is expanded as compared with the existing system 2, the communication speed can be increased while effectively using the limited frequency band. Can be achieved.
[0034]
(Second Embodiment)
The multi-carrier wireless communication system according to this embodiment is almost the same as the system according to the first embodiment, but in a frequency band corresponding to a communication channel of an existing system in which a frequency band overlaps with a transmitted data signal. Prior to the data signal to be transmitted, in addition to the same signal as the preamble signal used for recognition of the existing system in the existing system, the same signal as the control signal used in the existing system The same signal as the preamble signal for enabling demodulation of the control signal is transmitted. Hereinafter, the present embodiment will be described with reference to the drawings, but description of portions common to the first embodiment will be omitted.
[0035]
FIG. 5 is a block diagram showing the overall configuration of the multicarrier radio communication system and the existing system according to the present embodiment. In FIG. 5, a multicarrier wireless communication system 3 (hereinafter referred to as a new system) according to the present embodiment, which is a newly constructed wireless LAN system, is a transmitter 31 (hereinafter referred to as a new transmitter). And a receiver 32 (hereinafter referred to as a new receiver) that receives the packet signal S3 transmitted from the new transmitter 31.
[0036]
FIG. 6 is a diagram illustrating a packet format of the packet signal S3 transmitted from the new transmitter 31 in the present embodiment. As shown in FIG. 6, in the new system 3, prior to the data signal S340 in the frequency bands B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the transmitted data signal S340. The same signals S311 and S312 as the short preamble signal S210 of the existing system 2, the same signals S321 and S322 as the long preamble signal S220 of the existing system 2, and the same signals S331 and S332 as the control signal S130 of the existing system 2 Sent in order. In addition, in the frequency band B3 that does not overlap with the communication channels ch1 ′ to ch4 ′ of the existing system 2 among the frequency bands of the data signal S340, the long preamble signal S323 for the new system and the new system signal are used prior to the data signal S340. A control signal S333 is transmitted.
[0037]
In such a configuration, when the packet signal S3 shown in FIG. 6 transmitted from the new transmitter 31 arrives at the new receiver 32, the new receiver 32 is the same as the existing system 2 included in the packet signal S3. The data signal S340 is demodulated using the long preamble signals S321 and S322, the new system long preamble signal S323, the same control signals S331 and S332 as the existing system 2, and the new system control signal S333.
[0038]
Next, a case where the packet signal S3 shown in FIG. 6 transmitted from the new transmitter 31 arrives at the existing receiver 22 will be described. Prior to the data signal S340, the same signal S321 as the long preamble signal S220 of the existing system 2 in the frequency bands B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the data signal S340. , S322 and the same signals S331 and S332 as the control signal S230 are transmitted. For this reason, when receiving the packet signal S3, the existing receiver 22 performs synchronization processing using the same signals S321 and S322 as the long preamble signal S220 of the existing system 2 in the communication channels ch1 ′ and ch2 ′. Signals S331 and S332 similar to the control signal S230 of the system 2 are demodulated to obtain control information. The existing receiver 22 performs various communication controls based on this control information. Specifically, for example, the packet length of the data signal S340 is recognized, and random access control is performed based on the recognized packet length.
[0039]
The multicarrier wireless communication system 3 according to the present embodiment has the following effects in addition to the effects exhibited by the system 1 according to the first embodiment.
In this embodiment, in the existing system 2 prior to the data signal S340 to be transmitted in the frequency bands B1 and B2 corresponding to the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the data signal S340 to be transmitted. Signals S331 and S332 identical to the used control signal S230 and signals S321 and S322 identical to the preamble signal S220 for enabling demodulation of the control signal S230 are transmitted. For this reason, when the packet signal S3 transmitted from the new transmitter 31 arrives at the existing receiver 22, the existing receiver 22 can obtain the same control information as when the packet signal S2 of the existing system 2 is received. . As a result, the existing receiver 22 can perform various controls based on the control information, similarly to when the packet signal S2 of the existing system 2 is received. In particular, since the packet length of the data signal S340 can be recognized, the random access control can be performed as in the case of receiving the packet signal S2 of the existing system 2, and the random access control cannot be normally performed. It is possible to avoid a decrease in throughput caused by the above.
[0040]
Also, the signals S331 and S332 identical to the control signal S230 used in the existing system 2 and the signals S321 and S322 identical to the long preamble signal S220 for enabling demodulation of the control signal S230 are controlled for the new system. Since the signal and the control signal are used as a long preamble signal for enabling demodulation, the above effect can be obtained with high packet efficiency.
[0041]
Further, when the new receiver 32 demodulates the packet signal S2 of the existing system 2, the packet signal S2 of the existing system 2 and the packet signal S3 of the new system 3 can be demodulated by a single demodulator. The configuration of the demodulator can be simplified.
[0042]
(Third embodiment)
The multicarrier modulation circuit according to the present embodiment is a modulation circuit used in the new transmitter 31 of the multicarrier wireless communication system 3 according to the second embodiment, and the packet signal S3 transmitted from the new transmitter 31 is received. Is to be generated. Hereinafter, the present embodiment will be described with reference to the drawings.
[0043]
FIG. 7 is a block diagram showing the configuration of the multicarrier modulation circuit according to this embodiment. In FIG. 7, the multicarrier modulation circuit includes a data signal generation circuit 101, a subcarrier modulation circuit 102, a serial / parallel conversion circuit 103, a transmission order control circuit 104, an inverse fast Fourier transform circuit 105, a parallel / serial conversion circuit 106, and a short preamble signal. Generation circuit 107, long preamble signal generation circuit 108, new system long preamble signal generation circuit 109, control signal generation circuit 110, new system control signal generation circuit 111, short preamble signal arrangement circuit 112, long preamble signal arrangement circuit 113, A control signal arrangement circuit 114 is provided.
[0044]
The operation of the multicarrier modulation circuit having the above configuration will be described below. In FIG. 7, a data signal generation circuit 101 generates a baseband data signal to be transmitted. The subcarrier modulation circuit 102 performs subcarrier modulation on the baseband data signal received from the data signal generation circuit 101. The serial-to-parallel conversion circuit 103 divides the serial data signal after subcarrier modulation received from the subcarrier modulation circuit 102 in the frequency direction, and converts it into data signals for each parallel subcarrier.
[0045]
On the other hand, the short preamble signal generation circuit 107, the long preamble signal generation circuit 108, the new system long preamble signal generation circuit 109, the control signal generation circuit 110, and the new system control signal generation circuit 111 are respectively the same as the existing system. A short preamble signal, a long preamble signal identical to the existing system, a new system long preamble signal, a control signal identical to the existing system, and a new system control signal are generated.
[0046]
The short preamble signal placement circuit 112 associates the short preamble signal received from the short preamble signal generation circuit 107 with the frequency band of the communication channel of the existing system that overlaps with the communication channel used for data signal transmission. , Arrange in the frequency direction and output. In the present embodiment, as shown in FIG. 6, the short preamble signal is arranged corresponding to the frequency bands B1 and B2 of the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the communication channel ch1. That is, the short preamble signal is output twice repeatedly.
[0047]
The long preamble signal arrangement circuit 113 associates the long preamble signal received from the long preamble signal generation circuit 108 with the frequency band of the communication channel of the existing system in which the frequency band overlaps with the communication channel used for data signal transmission. , Arrange in the frequency direction and output. In the present embodiment, as shown in FIG. 6, the long preamble signal is arranged corresponding to the frequency bands B1 and B2 of the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the communication channel ch1. In addition, the long preamble signal placement circuit 113 uses the new system long preamble signal received from the new system long preamble signal generation circuit 109 to communicate with the existing system in the frequency band of the communication channel used for data signal transmission. The output is arranged in the frequency direction in correspondence with the frequency band not overlapping with the channel. In the present embodiment, as shown in FIG. 6, the new system long preamble signal is associated with the frequency band B3 that does not overlap with the communication channels ch1 ′ to ch4 ′ of the existing system 2 among the frequency bands of the communication channel ch1. Deploy. That is, the long preamble signal arrangement circuit 113 repeatedly outputs the same long preamble signal and the new system long preamble signal as in the existing system 2 in the frequency direction.
[0048]
The control signal arrangement circuit 114 corresponds the frequency of the control signal received from the control signal generation circuit 110 to the frequency band of the communication channel of the existing system whose frequency band overlaps with the communication channel used for data signal transmission. Place in and output. In the present embodiment, as shown in FIG. 6, the control signals are arranged in correspondence with the frequency bands B1 and B2 of the communication channels ch1 ′ and ch2 ′ of the existing system 2 whose frequency band overlaps with the communication channel ch1. In addition, the control signal placement circuit 114 receives the new system control signal received from the new system control signal generation circuit 111 from the communication channel of the existing system 2 in the frequency band of the communication channel used to transmit the data signal. The output is arranged in the frequency direction in correspondence with the frequency bands that do not overlap. In the present embodiment, as shown in FIG. 6, the new system control signal is arranged corresponding to the frequency band B3 that does not overlap with the communication channels ch1 ′ to ch4 ′ of the existing system 2 among the frequency bands of the communication channel ch1. To do. That is, the control signal arrangement circuit 114 repeatedly outputs the same control signal and the new system control signal as those of the existing system 2 in the frequency direction.
[0049]
Then, transmission order control circuit 104 arranges signals received from serial / parallel conversion circuit 103, short preamble signal arrangement circuit 112, long preamble signal arrangement circuit 113, and control signal arrangement circuit 114 in the order of transmission in the time direction. Specifically, as shown in FIG. 6, the signal from the short preamble signal placement circuit 112, the signal from the long preamble signal placement circuit 113, the signal from the control signal placement circuit 114, and the signal from the serial / parallel conversion circuit 103 are displayed. Output in order in the time direction. The inverse fast Fourier transform circuit 105 performs inverse fast Fourier transform on the frequency domain signal received from the transmission order control circuit 104 and converts it into a time domain signal. The parallel-serial conversion circuit 106 arranges the parallel signals received from the inverse fast Fourier transform circuit 105 in the order of output in the time axis direction, and converts them into serial signals. In this way, the multicarrier modulated packet signal S3 shown in FIG. 6 is obtained.
[0050]
According to this embodiment, the same effect as that of the second embodiment can be obtained. Furthermore, before the inverse fast Fourier transform, the same short preamble signal as the existing system 2, the same long preamble signal as the existing system 2, the new system long preamble signal, the same control signal as the existing system 2, and the new system control signal Since the data signals are arranged in the order of transmission, signal conversion from the frequency domain to the time domain can be realized with a single circuit, and an increase in circuit scale can be suppressed.
[0051]
When the new system control signal S333 is omitted in the packet format of the packet signal S3 shown in FIG. 6, the new system control signal generation circuit 111 of this embodiment is omitted.
[0052]
In the packet format of the packet signal S3 shown in FIG. 6, when the new system long preamble signal S323 is omitted, the new system long preamble signal generation circuit 109 of this embodiment is omitted.
[0053]
Further, in the present embodiment, the long preamble signal generation circuit 108, the new system long preamble signal generation circuit 109, the control signal generation circuit 110, the new system control signal generation circuit 111, the long preamble signal arrangement circuit 113, and the control signal arrangement If the circuit 114 is omitted and the data signal generation circuit 101 generates a new system long preamble signal and a new system control signal in addition to the data signal, it is used in the new transmitter 11 of the first embodiment. A multi-carrier modulation circuit can be configured.
[0054]
(Fourth embodiment)
The multicarrier modulation circuit according to the present embodiment is a modulation circuit used in the new transmitter 31 of the multicarrier wireless communication system 3 according to the second embodiment. Further, although it is almost the same as the modulation circuit according to the third embodiment, the same short preamble signal as the existing system 2, the same long preamble signal as the existing system 2, the new system long preamble signal, and the same as the existing system 2 And multi-carrier modulation of a new system control signal (hereinafter referred to as a preamble signal or the like) and multi-carrier modulation of a data signal are processed in parallel. Hereinafter, the present embodiment will be described with reference to the drawings, but description of portions common to the third embodiment will be omitted.
[0055]
FIG. 8 is a block diagram showing the configuration of the multicarrier modulation circuit according to the present embodiment. In FIG. 8, the multicarrier modulation circuit includes a portion 201 to 206 that performs multicarrier modulation on a data signal, a portion 207 to 217 that performs multicarrier modulation on a preamble signal and the like, and a multicarrier modulated data signal, a preamble signal, and the like. The switching circuit 218 controls the transmission order. The multi-carrier modulation part of the data signal includes a data signal generation circuit 201, a subcarrier modulation circuit 202, a serial / parallel conversion circuit 203, a first inverse fast Fourier transform circuit 205, and a first parallel / serial conversion circuit 206. Yes. On the other hand, a portion for performing multicarrier modulation of a preamble signal or the like includes a short preamble signal generation circuit 207, a long preamble signal generation circuit 208, a new system long preamble signal generation circuit 209, a control signal generation circuit 210, and a new system control signal generation circuit. 211, a short preamble signal arrangement circuit 212, a long preamble signal arrangement circuit 213, a control signal arrangement circuit 214, a transmission order control circuit 215, a second inverse fast Fourier transform circuit 216, and a second parallel / serial conversion circuit 217. Yes.
[0056]
The operation and signal flow of the multicarrier modulation circuit having the above configuration will be described below. In FIG. 8, the baseband data signal generated by the data signal generation circuit 201 is similar to the third embodiment in that a subcarrier modulation circuit 202, a serial / parallel conversion circuit 203, and a first inverse fast Fourier transform circuit 205 are used. Multicarrier modulation is performed by the first parallel-serial conversion circuit 206.
[0057]
On the other hand, the signals generated by the short preamble signal generation circuit 207, the long preamble signal generation circuit 208, the new system long preamble signal generation circuit 209, the control signal generation circuit 210, and the new system control signal generation circuit 211 are Similar to the first embodiment, the short preamble signal arrangement circuit 212, the long preamble signal arrangement circuit 213, and the control signal arrangement circuit 214 arrange and output in the frequency direction. In this embodiment, they are arranged in the frequency direction as shown in FIG.
[0058]
Transmission order control circuit 215 arranges signals received from short preamble signal arrangement circuit 212, long preamble signal arrangement circuit 213, and control signal arrangement circuit 214 in the order of transmission in the time direction. Specifically, as shown in FIG. 6, a signal from the short preamble signal arrangement circuit 212, a signal from the long preamble signal arrangement circuit 213, and a signal from the control signal arrangement circuit 214 are arranged in the time direction and output. The second inverse fast Fourier transform circuit 216 performs inverse fast Fourier transform on the frequency domain signal received from the transmission order control circuit 215 to convert it into a time domain signal. The second parallel-serial conversion circuit 217 arranges the parallel signals received from the second inverse fast Fourier transform circuit 216 in the order of output in the time axis direction, and converts them into serial signals.
[0059]
Then, as shown in FIG. 6, the switching circuit 218 outputs the preamble signal after the multicarrier modulation received from the second parallel / serial conversion circuit 217, and then received the first parallel / serial conversion circuit 206. The data signal after multicarrier modulation is output. That is, a preamble signal or the like is output prior to the data signal. In this way, the multicarrier modulated packet signal S3 shown in FIG. 6 is obtained.
[0060]
According to this embodiment, the same effect as that of the second embodiment can be obtained. Furthermore, since the multicarrier modulation of the preamble signal and the like and the multicarrier modulation of the data signal are processed in parallel, there is no restriction that the generation of the multicarrier modulated preamble signal or the like is performed before the generation of the multicarrier modulated data signal. . As a result, it is possible to generate a preamble signal or the like that has been subjected to multicarrier modulation in advance, and it is possible to reduce the time required for signal processing necessary for packet signal transmission from the local station after reception of the packet signal from another station.
[0061]
When the new system control signal S333 is omitted in the packet format of the packet signal S3 shown in FIG. 6, the new system control signal generation circuit 211 of this embodiment is omitted.
[0062]
Further, in the packet format of the packet signal S3 shown in FIG. 6, when the new system long preamble signal S323 is omitted, the new system long preamble signal generation circuit 209 of this embodiment is omitted.
[0063]
Further, in the present embodiment, the long preamble signal generation circuit 208, the new system long preamble signal generation circuit 209, the control signal generation circuit 210, the new system control signal generation circuit 211, the long preamble signal arrangement circuit 213, and the control signal arrangement circuit 214 and the transmission order control circuit 215 are omitted, and the data signal generation circuit 201 generates the new system long preamble signal and the new system control signal in addition to the data signal. A multicarrier modulation circuit used for the transmitter 11 can be configured.
[0064]
(Fifth embodiment)
The multicarrier modulation circuit according to the present embodiment is a modulation circuit used in the new transmitter 31 of the multicarrier wireless communication system 3 according to the second embodiment. Further, although it is almost the same as the modulation circuit according to the fourth embodiment, the same short preamble signal as that of the existing system 2 after multi-carrier modulation, the same long preamble signal as that of the existing system 2, and the new system long preamble signal (Hereinafter, these are referred to as preamble signals) are stored, and when transmitting the data signal, the stored preamble signal is read and output before the data signal. Hereinafter, the present embodiment will be described with reference to the drawings, but description of portions common to the fourth embodiment will be omitted.
[0065]
FIG. 9 is a block diagram showing the configuration of the multicarrier modulation circuit according to this embodiment. In FIG. 9, the multicarrier modulation circuit includes a portion for multicarrier modulation of the data signal and the control signal, a portion for multicarrier modulation of the preamble signal, a memory circuit 319 for storing the multicarrier modulated preamble signal, The switching circuit 318 controls the transmission order of the modulated data signal and the preamble signal.
[0066]
The operation of the multicarrier modulation circuit having the above configuration will be described below.
First, the operation of the part that multicarrier modulates the data signal and the control signal will be described. In FIG. 9, a data signal generation circuit 301 generates a baseband data signal to be transmitted. The subcarrier modulation circuit 302 performs subcarrier modulation on the baseband data signal. The serial / parallel conversion circuit 303 converts the serial data signal after subcarrier modulation into a data signal for each parallel subcarrier.
[0067]
On the other hand, the control signal generation circuit 310 and the new system control signal generation circuit 311 generate the same control signal and new system control signal as the existing system, respectively. As in the third embodiment, the control signal arrangement circuit 314 arranges the control signal received from the control signal generation circuit 310 and the new system control signal received from the new system control signal generation circuit 311 in the frequency direction. Output.
[0068]
Then, the first transmission order control circuit 304 arranges the signals received from the serial / parallel conversion circuit 303 and the control signal arrangement circuit 314 in the order of transmission in the time direction. Specifically, as shown in FIG. 6, the signals from the control signal arrangement circuit 314 and the signals from the serial / parallel conversion circuit 303 are arranged in the order of time and output. The first inverse fast Fourier transform circuit 305 performs inverse fast Fourier transform on the frequency domain signal received from the first transmission order control circuit 304 and converts it into a time domain signal. The first parallel / serial conversion circuit 306 arranges the parallel signals received from the first inverse fast Fourier transform circuit 305 in the order of output in the time axis direction, and converts them into serial signals. In this way, a control signal and a data signal after multicarrier modulation are obtained.
[0069]
Next, the operation of the part that multicarrier modulates the preamble signal will be described. In FIG. 9, a short preamble signal generation circuit 307, a long preamble signal generation circuit 308, and a new system long preamble signal generation circuit 309 are respectively the same short preamble signal as the existing system 2 and the same long preamble signal as the existing system 2. Generate a long preamble signal for the new system. The short preamble signal placement circuit 312 places the short preamble signal in the frequency direction and outputs the same as in the third embodiment. The long preamble signal arrangement circuit 313 arranges and outputs the long preamble signal and the new system long preamble signal in the frequency direction, as in the third embodiment.
[0070]
Then, second transmission order control circuit 315 arranges the preamble signals received from short preamble signal arrangement circuit 312 and long preamble signal arrangement circuit 313 in the order of transmission in the time direction. Specifically, as shown in FIG. 6, the signals from the short preamble signal arrangement circuit 312 and the signals from the long preamble signal arrangement circuit 313 are arranged in the order of time and output. The second inverse fast Fourier transform circuit 316 performs inverse fast Fourier transform on the frequency domain signal received from the second transmission order control circuit 315 and converts it into a time domain signal. The second parallel-serial conversion circuit 317 arranges the parallel signals received from the second inverse fast Fourier transform circuit 316 in the order of output in the time axis direction, and converts them into serial signals.
[0071]
The thus-obtained preamble signal after multicarrier modulation is stored in the memory circuit 319. Then, the switching circuit 318 reads the preamble signal after multicarrier modulation from the memory circuit 319, and outputs the preamble signal prior to the output of the data signal after multicarrier modulation received from the parallel-serial conversion circuit 306. In this way, the packet signal S3 after the multicarrier modulation shown in FIG. 6 is obtained.
[0072]
According to this embodiment, the same effect as the fourth embodiment can be obtained. Furthermore, since the multicarrier-modulated preamble signal is stored and the stored preamble signal is read and used, the number of arithmetic processes can be reduced, and the power consumption can be reduced. In addition, since it is not necessary to generate a preamble signal at the time of transmission, processing associated with control can be reduced.
[0073]
When the new system control signal S333 is omitted in the packet format of the packet signal S3 shown in FIG. 6, the new system control signal generation circuit 311 of this embodiment is omitted.
[0074]
Further, in the packet format of the packet signal S3 shown in FIG. 6, when the new system long preamble signal S323 is omitted, the new system long preamble signal generation circuit 309 of this embodiment is omitted.
[0075]
Further, in the present embodiment, the first transmission order control circuit 304, the long preamble signal generation circuit 308, the new system long preamble signal generation circuit 309, the control signal generation circuit 310, the new system control signal generation circuit 311, the long preamble The signal arrangement circuit 313, the control signal arrangement circuit 314, and the second transmission order control circuit 315 are omitted, and the data signal generation circuit 301 generates a new system long preamble signal and a new system control signal in addition to the data signal. As a result, the multicarrier modulation circuit used in the new transmitter 11 of the first embodiment can be configured.
[0076]
As mentioned above, although preferred embodiment about the multicarrier radio | wireless communications system and multicarrier modulation circuit which concern on this invention was shown, this invention is not limited to the said 1st-5th embodiment. For example, in the above embodiment, the new system 1 and the existing system 2 have the configuration shown in FIG. 1, but the configuration is not limited thereto, and other configurations may be used. Specifically, a configuration may be adopted in which a plurality of wireless communication devices including a transmitter and a receiver are provided and the plurality of wireless communication devices communicate with each other.
[0077]
In the above embodiment, the wireless LAN system compliant with the IEEE802.11a standard is the existing system 2, but the existing system 2 may be another multi-carrier wireless communication system.
[0078]
Further, in the above embodiment, the frequency band of the communication channel of the new system 1 is set as shown in FIG. 2, but may be set to other settings as long as the existing system 2 and the frequency band overlap. . For example, the four communication channels ch1 ′ to ch4 ′ of the existing system 2 can be combined into one communication channel of the new system. In addition, the number of communication channels in the new system 1 and the existing system 2 are both arbitrary, and the present invention can be applied when the frequency bands of the communication channels overlap in the new system 1 and the existing system 2. . In the above embodiment, the frequency band of each communication channel of the new system 1 completely includes the frequency band of the communication channel of the existing system 2, but the frequency bands may partially overlap. However, even if the frequency bands partially overlap, the same signal as the short preamble signal of the existing system 2 is transmitted over the entire frequency band corresponding to the communication channel of the existing system 2 related to the overlap, The entire frequency band is redundantly used. Therefore, from the viewpoint of effective use of frequency resources, it is preferable that the new system 1 overlaps and uses the frequency band used in the existing system 2 so that the communication channel frequency band does not partially overlap.
[0079]
In the above embodiment, the packet formats shown in FIGS. 4 and 6 are used as the packet formats of the packet signals S1 and S3, but other packet formats may be adopted. For example, the new system control signals S130 and S333 may be omitted in FIGS. 4 and 6, and the position and length of the new system long preamble signal S323 in the time axis direction may be changed in FIG.
[0080]
【The invention's effect】
As described above, according to the present invention, in the overlapping frequency bands, the frequency bandwidth and center frequency of each subcarrier are the same as those in the existing system, and the communication of the existing system in which the transmitted data signal and the frequency band overlap. In the frequency band corresponding to the channel, the same signal as the preamble signal used for recognition of the existing system is transmitted in the existing system prior to the data signal. For this reason, when the transmission signal of the new system arrives at the receiver of the existing system, the receiver recognizes the transmission signal as the transmission signal of the existing system. As a result, it is possible to avoid adverse effects caused by the receiver recognizing the transmission signal as an interference signal. That is, the present invention provides a multicarrier radio communication system and a multicarrier modulation circuit capable of suppressing the adverse effects on the existing system due to the redundant use while overlappingly using the frequency band used in the existing multicarrier radio communication system can do.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an overall configuration of a multicarrier radio communication system and an existing multicarrier radio communication system according to a first embodiment.
FIG. 2 is a diagram showing the arrangement of communication channels in the frequency direction in the new system 1 and the existing system 2;
3 is a diagram illustrating a packet format of a packet signal S2 transmitted from an existing transmitter 21 of the existing system 2. FIG.
FIG. 4 is a diagram illustrating a packet format of a packet signal S1 transmitted from the new transmitter 11 according to the first embodiment.
FIG. 5 is a block diagram showing an overall configuration of a multicarrier radio communication system and an existing multicarrier radio communication system according to a second embodiment.
FIG. 6 is a diagram illustrating a packet format of a packet signal S3 transmitted from the new transmitter 31 according to the second embodiment.
FIG. 7 is a block diagram showing a configuration of a multicarrier modulation circuit according to a third embodiment.
FIG. 8 is a block diagram showing a configuration of a multicarrier modulation circuit according to a fourth embodiment.
FIG. 9 is a block diagram showing a configuration of a multicarrier modulation circuit according to a fifth embodiment.
FIG. 10 is a block diagram showing a configuration of a conventional multicarrier modulation circuit.
FIG. 11 is a diagram illustrating a packet format of a packet signal transmitted using a conventional multicarrier modulation circuit.
[Explanation of symbols]
1, 3 New system
11, 31 New transmitter
12, 32 New receiver
2 Existing system
21 Existing transmitter
22 Existing receiver
ch1 'to ch4' Communication channel of existing system 2
ch1, ch2 Communication channel of new system 1
S210 Short preamble signal of existing system 2
S220 Long preamble signal of the existing system 2
S230 Control signal of existing system 2
S240 Data signal of existing system 2
S111, S112, S311, S312 The same signal as the short preamble signal of the existing system 2
S321, S322 The same signal as the long preamble signal of the existing system 2
S120, S323 Long preamble signal for new system
S331, S332 The same signal as the control signal of the existing system 2
S130, S333 New system control signal
S340 New system 1 data signal
101, 201, 301 Data signal generation circuit
102, 202, 302 Subcarrier modulation circuit
103, 203, 303 Series-parallel conversion circuit
104, 215 Transmission order control circuit
304 first transmission order control circuit
315 Second transmission order control circuit
105 Inverse Fast Fourier Transform Circuit
205, 305 First inverse fast Fourier transform circuit
106 Parallel to serial converter
206, 306 First parallel-serial conversion circuit
107, 207, 307 Short preamble signal generation circuit
108, 208, 308 Long preamble signal generation circuit
109, 209, 309 Long preamble signal generation circuit for new system
110, 210, 310 Control signal generation circuit
111, 211, 311 New system control signal generation circuit
112, 212, 312 Short preamble signal arrangement circuit
113, 213, 313 Long preamble signal arrangement circuit
114, 214, 314 Control signal arrangement circuit
216, 316 Second inverse fast Fourier transform circuit
217, 317 Second parallel-serial conversion circuit
218, 318 switching circuit
319 Memory circuit

Claims (5)

A multicarrier radio communication system including a frequency band of a data signal to be transmitted in a frequency band corresponding to one or more communication channels of an existing multicarrier radio communication system (hereinafter referred to as an existing system) ,
In the frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal the transmission, the frequency bandwidth and center frequency of each subcarrier is the already resides stem Are the same,
In a frequency band that overlaps a frequency band corresponding to one or more communication channels of the already resides stem in the frequency band of the data signal the transmission, said prior to the data signal to be transmitted, in the already resides stem The first preamble signal that is the same as the preamble signal used for recognition of the existing system, the first control signal that is the same as the control signal used in the existing system, and the first control signal A second preamble signal identical to the preamble signal used to enable demodulation is transmitted ;
Communication in the multi-carrier wireless communication system prior to the transmitted data signal in a frequency band that does not overlap with one or more communication channels of the existing system in the frequency band of the transmitted data signal A multi-carrier wireless communication system , wherein a second control signal used for control and a third preamble signal for enabling demodulation of the second control signal are transmitted . Multi-carrier modulation applied to a multi-carrier radio communication system including a frequency band of a data signal to be transmitted in a frequency band corresponding to one or more communication channels of an existing multi-carrier radio communication system (hereinafter referred to as an existing system) A circuit,
Subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted;
A serial / parallel conversion means for converting a serial signal output from the subcarrier modulation means into a parallel signal corresponding to each subcarrier , and outputting the parallel signal as a frequency domain signal ;
First preamble signal generation means for generating a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system ;
First preamble to place the first preamble signal to a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission of the signal in the frequency domain Signal placement means;
First control signal generating means for generating a first control signal identical to the control signal used in the existing system;
Second control signal generation means for generating a second control signal used for communication control of the multicarrier wireless communication system;
The first control signal in a frequency band that overlaps with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, Control signal arrangement means for arranging the second control signals in frequency bands not overlapping with frequency bands corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted;
Second preamble signal generation means for generating a second preamble signal identical to the preamble signal used to enable demodulation of the control signal in the existing system ;
Third preamble signal generation means for generating a third preamble signal for enabling demodulation of the second preamble signal ;
The second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, the third preamble signal to a frequency band not overlapping the frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission, and a second preamble signal arrangement means for arranging each ,
Before SL first preamble signal arrangement means, and said second preamble signal arrangement means, the control signal arrangement means, and transmission order control means an output signal from the serial-parallel conversion means and outputs are arranged in that order,
Signal converting means for converting a frequency domain signal output from the transmission order control means into a time domain signal;
Parallel-serial conversion means for converting a parallel signal output from the signal conversion means into a serial transmission signal;
A multi-carrier modulation circuit comprising: Multi-carrier modulation applied to a multi-carrier radio communication system including a frequency band of a data signal to be transmitted in a frequency band corresponding to one or more communication channels of an existing multi-carrier radio communication system (hereinafter referred to as an existing system) A circuit,
Subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted;
A serial / parallel conversion means for converting a serial signal output from the subcarrier modulation means into a parallel signal corresponding to each subcarrier , and outputting the parallel signal as a frequency domain signal ;
First signal conversion means for converting a frequency domain signal output from the serial / parallel conversion means into a time domain signal;
First parallel / serial conversion means for converting the parallel signal output from the first signal conversion means into a serial first transmission signal;
First preamble signal generation means for generating a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system ;
First preamble to place the first preamble signal to a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission of the signal in the frequency domain Signal placement means;
First control signal generating means for generating a first control signal identical to the control signal used in the existing system;
Second control signal generation means for generating a second control signal used for communication control of the multicarrier wireless communication system;
The first control signal in a frequency band that overlaps with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, Control signal arrangement means for arranging the second control signals in frequency bands not overlapping with frequency bands corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted;
Second preamble signal generation means for generating a second preamble signal identical to the preamble signal used to enable demodulation of the control signal in the existing system ;
Third preamble signal generation means for generating a third preamble signal for enabling demodulation of the second control signal ;
The second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, the third preamble signal to a frequency band not overlapping the frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission, and a second preamble signal arrangement means for arranging each ,
A transmission order control means for arranging and outputting the output signals from the first preamble signal arrangement means, the second preamble signal arrangement means, and the control signal arrangement means in that order;
Second signal conversion means for converting a frequency domain signal output from the transmission order control means into a time domain signal;
Second parallel / serial conversion means for converting the parallel signal output from the second signal conversion means into a serial second transmission signal;
Switching means for arranging and outputting the second transmission signal output from the second parallel-serial conversion means and the first transmission signal output from the first parallel-serial conversion means in the order;
A multi-carrier modulation circuit comprising: Multi-carrier modulation applied to a multi-carrier radio communication system including a frequency band of a data signal to be transmitted in a frequency band corresponding to one or more communication channels of an existing multi-carrier radio communication system (hereinafter referred to as an existing system) A circuit,
Subcarrier modulation means for performing subcarrier modulation on a data signal to be transmitted;
A serial / parallel conversion means for converting a serial signal output from the subcarrier modulation means into a parallel signal corresponding to each subcarrier , and outputting the parallel signal as a frequency domain signal ;
First control signal generating means for generating a first control signal identical to the control signal used in the existing system ;
Second control signal generation means for generating a second control signal used for communication control of the multicarrier wireless communication system ;
In the frequency domain signal, the first control signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, said second control signal to a frequency band not overlapping the frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission, respectively placed to control signal arrangement means,
First transmission order control means for arranging and outputting the output signals from the control signal arrangement means and the serial / parallel conversion means in the order;
First signal conversion means for converting a frequency domain signal output from the first transmission order control means into a time domain signal;
First parallel / serial conversion means for converting the parallel signal output from the first signal conversion means into a serial first transmission signal;
First preamble signal generation means for generating a first preamble signal identical to the preamble signal used for recognition of the existing system in the existing system ;
First preamble to place the first preamble signal to a frequency band that overlaps a frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission of the signal in the frequency domain Signal placement means;
Second preamble signal generation means for generating a second preamble signal identical to the preamble signal used to enable demodulation of the control signal in the existing system ;
Third preamble signal generation means for generating a third preamble signal for enabling demodulation of the second preamble signal ;
The second preamble signal in a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the data signal to be transmitted in the frequency domain signal, the third preamble signal to a frequency band not overlapping the frequency band corresponding to one or more communication channels of the existing systems in the frequency band of the data signal to be the transmission, and a second preamble signal arrangement means for arranging each ,
Second transmission order control means for arranging and outputting the output signals from the first preamble signal placement means and the second preamble signal placement means in that order;
Second signal conversion means for converting a frequency domain signal output from the second transmission order control means into a time domain signal;
Second parallel / serial conversion means for converting the parallel signal output from the second signal conversion means into a serial second transmission signal;
Storage means for storing the second transmission signal output from the second parallel-serial conversion means;
Switching means for reading the second transmission signal from the storage means and sending the second transmission signal prior to sending the first transmission signal received from the first parallel-serial conversion means;
A multi-carrier modulation circuit comprising: A multicarrier radio communication system including a frequency band of a data signal to be transmitted in a frequency band corresponding to one or more communication channels of an existing multicarrier radio communication system (hereinafter referred to as an existing system),
In a frequency band overlapping with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal, the frequency bandwidth and the center frequency of each subcarrier are the same as those of the existing system. Yes,
In the frequency band that overlaps the frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal, prior to the transmitted data signal, the existing system The first preamble signal identical to the preamble signal used for recognition, the first control signal identical to the control signal used in the existing system, and the first control signal can be demodulated A second preamble signal identical to the preamble signal used for the transmission is transmitted ,
The multicarrier radio to be transmitted prior to the transmitted data signal in a frequency band that does not overlap with a frequency band corresponding to one or more communication channels of the existing system in the frequency band of the transmitted data signal A multicarrier radio communication system , wherein a second control signal used for communication control of the communication system and a third preamble signal for enabling demodulation of the second control signal are omitted .

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