JPH11234230A - Transmission station equipment for multicarrier communication system, transmission station equipment and multicarrier communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain improvement in transmission quality without increasing the number of antenna elements. SOLUTION: A serial/parallel converter 12 converts the data of high bit rate to plural pieces of data of low bit rate. A signal allocator 16 respectively allocates the carrier of high reception power value selected out of plural carriers to the respective plural pieces of data of low bit rate. A multicarrier modulator 18 modulates the respective allocated carriers with the respective plural pieces of data of low bit rate and simultaneously transmits them together with the carriers, which are not modulated and selected with the respective plural pieces of data of low bit rate, as multicarrier signals. A multicarrier demodulator 22 receives the multicarrier signals and demodulates the plural pieces of data of low bit rate and a parallel/serial converter 28 converts the plural pieces of demodulated data of low bit rate into the data of high bit rate. A reception power measuring instrument 24 measures the reception power value of respective carriers contained in the multicarrier signal and a selected data transmitter 30 outputs carrier information showing the carrier selected based on the reception power value of the carrier measured by the reception power measuring instrument 24.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmitting station device, a receiving station device, and a multicarrier communication system for a multicarrier communication system, and more particularly, to a multicarrier communication suitable for digital radio communication such as an automobile telephone and a portable telephone. The present invention relates to a system transmitting station device, a receiving station device, and a multicarrier communication system.

[0002]

2. Description of the Related Art In multi-carrier transmission, high bit rate data is parallelized to a plurality of low bit rate data, modulated using a plurality of carriers having different frequencies, and simultaneously transmitted, that is, communicated. It is a method. An advantage of multicarrier transmission is that deterioration of transmission quality due to frequency selective fading due to frequency characteristics of a propagation path can be reduced.

This advantage will be described with reference to FIG. FIG.
In the case of so-called single-carrier transmission in which data is transmitted using one carrier, as shown in (a), waveform distortion occurs due to frequency-selective fading, and transmission quality deteriorates over the entire data to be transmitted.

On the other hand, in multi-carrier transmission as shown in FIG. 1 (b), the reception level of a carrier included in a frequency band where the reception level decreases due to the frequency characteristic of the propagation path decreases, but the other level decreases. Since the reception level of the carrier included in the band does not decrease, it is possible to avoid deterioration of transmission quality over the entire data to be transmitted.

As a device for further improving the transmission quality in the multi-carrier transmission system, a mobile communication device using a diversity reception technique in combination has been proposed (Japanese Patent Laid-Open No. Hei 9-1997).
No. 172427). In this mobile communication device, a plurality of antennas are installed in a base station device, the received power of a multicarrier signal transmitted from the mobile station is measured for each carrier by each antenna of the base station, and the received power is highest for each carrier. Is selected or the received signals obtained by each antenna are combined such that the received signal is maximized. Accordingly, when the signal received by antenna 1 is as shown in FIG. 2A and the signal received by antenna 2 is as shown in FIG. 2B due to frequency selective fading, Since the signals are combined as shown in FIG. 2C, the influence of carriers whose transmission quality is degraded due to frequency selective fading can be reduced, so that the transmission quality of the entire multicarrier signal is improved.

[0006]

In the above-mentioned conventional mobile communication device, it is necessary that the correlation between signals received by a plurality of antenna elements of the base station be low in order to obtain a diversity effect. However, a received signal having a low correlation is not always obtained due to the mutual positional relationship between the antenna elements, and the transmission quality expected by this conventional technology may not be obtained in some cases. In addition, in order to further improve the transmission quality expected in this conventional technique, it is necessary to increase the number of antenna elements arranged so as to be able to receive a signal having a low correlation, and to install the antenna in a limited space. In such a base station, it is difficult to cope.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and a transmitting station, a receiving station, and a multicarrier communication system for a multicarrier communication system capable of improving transmission quality without increasing the number of antenna elements. The purpose is to provide.

[0008]

To achieve the above object, a transmitting station apparatus for a multi-carrier communication system according to claim 1 converts high bit rate data into a plurality of parallel low bit rate data. A serial-to-parallel converter, a signal allocator that allocates each of a plurality of low-bit-rate data to a carrier having a large reception power value selected from a plurality of carriers having different frequencies, and A multi-carrier modulator that simultaneously transmits as a multi-carrier signal with a carrier that has not been selected by modulation with each of the low bit rate data,
It is comprised including.

A receiving station apparatus for a multicarrier communication system according to a second aspect of the present invention receives a multicarrier signal including an unmodulated carrier and a plurality of carriers each having a different frequency modulated with low bit rate data. A multi-carrier demodulator for demodulating a plurality of low-bit-rate data, a reception power measurement device for measuring a reception power value of each carrier included in the multi-carrier signal, and a reception power measurement device. A transmitter that outputs a signal related to a received power value of the carrier, and a parallel-serial converter that converts a plurality of demodulated low-bit-rate data into serialized high-bit-rate data. .

A multi-carrier communication system according to a third aspect is a combination of the transmitting station device for the multi-carrier communication system according to the first aspect and the receiving station device for the multi-carrier communication system according to the second aspect.

According to a fourth aspect of the present invention, an encoder for attaching an error correction code is provided in the transmission station apparatus for the multicarrier communication system of the multicarrier communication system according to the third aspect, and the error correction code is provided in the reception station apparatus for the multicarrier communication system. Is provided.

According to a fifth aspect of the present invention, the signal allocator of the multicarrier communication system according to the third or fourth aspect selects and allocates a predetermined number of carriers in descending order of the received power value, or the received power value is determined in advance. In this case, carriers having a threshold value or more are selected and assigned.

The serial-parallel converter of the transmitting station apparatus for a multi-carrier communication system according to the first aspect converts high bit rate data into a plurality of parallel low bit rate data. The signal allocator allocates, to each of the plurality of low bit rate data, a carrier having a large received power value selected from a plurality of carriers having different frequencies. The signal allocator selects and allocates a carrier having a large received power value based on a signal related to the received power value of the carrier transmitted from the transmitter of the receiving station device according to claim 2. A carrier having a large received power value can be selected and assigned based on a signal related to the received power value of the carrier measured by a received power measuring device provided separately from the device and transmitted by the transmitter.

In this case, a signal indicating a predetermined number of carriers selected in descending order of the received power value is transmitted from the transmitting station apparatus as a signal related to the received power value, or the received power value is set to a predetermined threshold value. The signal indicating the carrier described above is transmitted as a signal related to the received power value, and based on the signal related to the received power value, the carrier having the larger received power value can be selected on the receiving station apparatus side.
Further, the measured reception power value itself may be transmitted from the reception station device side as a signal related to the reception power value, and a predetermined number of carriers may be selected and allocated in descending order of the reception power value by the signal allocator on the transmission station device side. Alternatively, a carrier whose received power value is equal to or greater than a predetermined threshold value may be selected and assigned.

If the number of selected carriers and the number of low bit rate data to be transmitted do not match, the number of selected carriers and the number of low bit rate data to be transmitted are matched. At least one of the number of selected carriers and the number of low bit rate data to be transmitted may be adjusted.

Then, by the multi-carrier modulator,
Each of the assigned carriers is modulated with each of the plurality of low bit rate data and transmitted simultaneously with the unselected carrier as a multi-carrier signal.

According to a second aspect of the present invention, there is provided a multicarrier demodulator for a receiving station apparatus for a multicarrier communication system, comprising a multicarrier including an unmodulated carrier and a plurality of carriers each having a different frequency modulated with low bit rate data. Receiving the signal and demodulating the plurality of low bit rate data, the parallel-to-serial converter converts the demodulated plurality of low bit rate data to serialized high bit rate data.

When demodulating with a multi-carrier demodulator, only a carrier modulated with low bit rate data may be demodulated and converted into high bit rate data with a parallel / serial converter. The demodulator may demodulate all carriers, select low bit rate data from the demodulated signal, and convert it to high bit rate data with a parallel-serial converter.

Then, the reception power measuring device measures the reception power value of each carrier included in the multi-carrier signal, and the transmitter transmits a signal related to the reception power value of the carrier measured by the reception power measurement device. Output as described above.

Note that the reception power measuring device and the transmitter may be provided near the receiving station device and separately from the receiving station device.

As described above, according to the present invention, high bit rate data is converted into a plurality of low bit rate data and transmitted using a carrier having a large received power value. Can be improved without increasing the transmission quality.

The transmitting station apparatus for a multi-carrier communication system according to the first aspect is provided with an encoder for attaching an error correction code, and the receiving station apparatus for a multi-carrier communication system according to the second aspect is provided with a decoder for an error correction code. Can be provided. The encoder can be provided before or after the serial / parallel converter, and the decoder can be provided before or after the parallel / serial converter.

With this configuration, transmission errors can be reduced by encoding and decoding error correction codes, so that transmission quality can be further improved.
Transmission efficiency can also be improved.

[0024]

Embodiments of the present invention will be described below in detail with reference to the drawings. First, a multicarrier transmission system according to a first embodiment of the present invention will be described.

As shown in FIG. 3, the multicarrier transmission system according to the present embodiment includes a transmission station apparatus 10 for transmitting a multicarrier signal and a reception station apparatus 20 for receiving a multicarrier signal.

The transmitting station apparatus 10 converts the high-bit-rate data as a serial signal into N (natural number, 6 in this embodiment) low-bit-rate parallel data as parallel signals. A serial-parallel converter 12 for conversion is provided. The serial-parallel converter 12 has one input terminal for inputting a serial signal and N output terminals for outputting N low-bit-rate data in parallel.

The transmitting station device 10 is provided with a selection data receiver 14 having an input terminal connected to the receiving antenna and receiving the carrier information transmitted from the selection data transmitter of the receiving station device 20.

The output terminal of the serial-parallel converter 12 and the output terminal of the selected data receiver 14 have a frequency (f in the case of this embodiment).
_{1 to} f ₈ ), N carriers are selected based on received carrier information from M carriers (N being a natural number larger than N and ₈ in the present embodiment), and each of the selected carriers is N Are assigned to each of the low bit rate data. This signal allocator 16 is provided with M output terminals of the same number as the total number of carriers.

The output of the signal allocator 16 is connected to a multi-carrier modulator 18 that modulates each of the carriers allocated to each of the low bit rate data with each of the low bit rate data. Note that the unselected carriers are not modulated by the multi-carrier modulator 18 because low bit rate data is not assigned to the carriers. At the output end of the multi-carrier modulator 18,
A transmit antenna is connected and N carriers selected and modulated with low bit rate data and (M−
N) (2 in this embodiment) unmodulated carriers are transmitted simultaneously as a multicarrier signal.

The receiving station device 20 is connected to the receiving antenna and (M−
The multi-carrier demodulator 22 receives a multi-carrier signal including N) unmodulated carriers and N modulated carriers and performs demodulation processing for each carrier. The multi-carrier demodulator 22 has M output terminals.
The low bit rate data is demodulated from the carrier modulated with the low bit rate data.

The output terminal of the multi-carrier demodulator 22 is connected to a signal selector 26. The signal selector 26 includes a memory for storing carrier information indicating the carrier selected by the selected data transmitter 30 in the previous reception, and based on the previous carrier information stored in the memory, the multicarrier received this time. N selects low-bit-rate data demodulated from the signal and outputs it in parallel
Output terminals.

The signal selector 26 has the same number of N input terminals as the number of output terminals of the serial / parallel converter 12 of the transmitting station device 10, and the N low bit rate selected by the signal selector 26. It is connected to a parallel-to-serial converter 28 that converts the data into parallel-to-serial data and converts it to transmitted high bit rate data.

The receiving antenna includes the transmitting station 10.
M carriers (modulated carrier and unmodulated carrier) included in the multicarrier signal transmitted from
A reception power measuring device 24 that measures the reception power for each and outputs a reception power value is connected.

The reception power measuring device 24 selects N carriers in descending order of the reception power value based on the measurement result of the reception power by the current reception, and transmits carrier information indicating the selected N carriers from the transmission antenna. The signal is transmitted to the transmission station device 10 and is connected to a selected data transmitter 30 that stores carrier information in a memory of the signal selector 26.

Each of the transmitting station apparatus 10 and the receiving station apparatus 20 is provided with two antennas, a receiving antenna and a transmitting antenna. Each of the transmitting station apparatus 10 and the receiving station apparatus 20 has a transmission / reception switch. A single antenna may be provided and used by switching according to transmission and reception.

Next, the operation of the multicarrier transmission system according to the present embodiment will be described. In the first transmission, the transmitting station apparatus 10 transmits the M carriers simultaneously from the multicarrier modulator 18 as a multicarrier signal as shown in FIG. In this case, the high bit rate data to be transmitted is converted into N low bit rate data parallelized by the serial / parallel converter 12, and N predetermined bit data are used by the N low bit rate data. Alternatively, each of the carriers having different frequencies may be modulated and transmitted together with the remaining unmodulated carriers as a multicarrier signal as shown in FIG.

When the multi-carrier signal transmitted from the multi-carrier modulator 18 is received through a propagation path in which frequency selective fading has occurred, a signal whose frequency characteristic is distorted as shown in FIG. Becomes

The multi-carrier signal transmitted from the transmitting station device 10 is received by the receiving station device 20 and input to the received power measuring device 24. Then, the received signal power of each carrier of the multicarrier signal is measured by the received power measuring device 24, and the received power value is input to the selected data transmitter 30.

The selected data transmitter 30 compares the magnitude of the received power value for each carrier input from the received power measuring device 24, selects N carriers in descending order of the received power value, and selects the selected carrier. Is transmitted to the transmitting station device 10 wirelessly. Also, the selected data transmitter 3
0 stores carrier information indicating the selected carrier in the memory of the signal selector 26.

Here, since the high bit rate data is converted into N low bit rate data by the serial / parallel converter 12, and the N low bit rate data are simultaneously modulated and transmitted, The number of carriers selected by the selected data transmitter 30 needs to be the same as the number of low bit rate data. For this reason, in the present embodiment,
The total number of carriers is M, which is larger than the number of low bit rate data converted by the serial / parallel converter, and the selected data transmitter 30 has the same number of low bit rate data as the number of low bit rate data in descending order of the received power value. N carriers have been selected.

In FIG. 4C, different frequencies f _{1 to} f
₈ eight carriers, i.e. in a multi-carrier transmission carrier number 8, an example chosen six carriers from the larger received power value (frequency _{f 1, f 2, f 5} ~f 8) is shown.

On the other hand, the transmitting station apparatus 10 converts the high bit rate data to be transmitted into N low bit rate data parallelized by the serial / parallel converter 12 and transmits the selected data to the receiving station apparatus 20. The selected data receiver 14 receives the carrier information transmitted from the receiver 30 via the receiving antenna.

The carrier signal allocator 16 receives the received
Carrier information from M carriers based on
The N carriers indicated by the information are selected, and the selected N carriers are selected.
Parallelized by the parallel converter 12 for
Each of the selected N low bit rate data
You. In the example of FIG. 4C, the frequency f₁, F_Two, F
_Five~ F₈Carrier information has been selected
And transmitted to the selected data receiver 14, the carrier
In the signal allocator 16, the frequency f₁, F_Two, F_Five
~ F₈Low-bit-rate data to be transmitted to different carriers
Are assigned.

The N carriers to which the low bit rate data is assigned include the (M−N) carriers to which the low bit rate data is not assigned, that is, the unselected carriers, and the low bit rate data. , Are input to the multi-carrier modulator 18. The multi-carrier modulator 18 modulates each of the N carriers to which the low bit rate data is allocated with the allocated low bit rate data, and modulates the carrier to which the low bit rate data is not allocated. Instead, they are transmitted simultaneously as a multicarrier signal composed of M carriers including modulated carriers and unmodulated carriers.

The multi-carrier signal transmitted from the transmitting station device 10 is received by the receiving station device 20 and input to the received power measuring device 24 and the multi-carrier demodulator 22.

The multi-carrier demodulator 22 demodulates N low bit rate data from the modulated N carriers, and inputs the demodulated data to the signal selector 26. The multi-carrier demodulator 22 also performs demodulation processing on unmodulated carriers. However, since unmodulated carriers are not modulated with data, low bit rate data is not demodulated from unmodulated carriers.

The signal selector 26 selects N low-bit-rate data demodulated from the currently received multicarrier signal based on the previous carrier information stored in the memory and outputs the data in parallel.

The N pieces of low bit rate data output from the signal selector 26 are input to the parallel / serial converter 28 and converted into high bit rate data.

In the received power measuring device 24, the received signal power of each carrier of the multicarrier signal received this time is measured, and the received power value is input to the selected data transmitter 30. The selected data transmitter 30 compares the magnitudes of the received power values of the respective carriers input from the received power measuring device 24, selects N carriers in descending order of the received power value, and selects a carrier indicating the selected carrier. The information is transmitted to the transmitting station device 10 by radio. Also, the selected data transmitter 3
A value of 0 updates the carrier information stored in the memory of the signal selector 26 to carrier information indicating the currently selected carrier after N pieces of low bit rate data are selected by the previous carrier information.

By repeating the above, data transmission is performed between the transmitting station device 10 for transmitting the multicarrier signal and the receiving station device 20 for receiving the multicarrier signal.

FIG. 5 shows that, when transmitting using eight carriers of frequencies f _{1 to} f ₈ , six carriers are selected and six low bit rate data A to F are transmitted by the selected carriers. In this case, multicarrier transmission from the transmitting station apparatus to the receiving station apparatus is illustrated as time elapses. At time t ₁ , frequencies f ₁ to f ₂ modulated with low bit rate data A to F from the transmitting station apparatus, respectively.
f _3, a multi-carrier signal comprising a carrier of f ₅ ~f ₇ of the carrier, and the unmodulated frequency f _4, f ₈ is transmitted. The multi-carrier signal is received and demodulated by the receiving station device, and based on the previous carrier information (frequency f _{1 to} f ₃ , f _{5 to} f ₇ ) stored in the memory,
Frequency f ₁ ~f _3, f ₅ data A~F low bit rate demodulated from carriers of ~f ₇ is selected and is converted into data of a high bit rate. At this time, the received power is measured, and the selected data transmitter selects carriers of frequencies f ₁ , f _{3 to} f ₇ in descending order of the received power value, and transmits carrier information indicating these selected carriers to the transmitting station. is the transmitting device, the frequency f ₁ modulated with respective data A~F a low bit rate at time t _2, f ₃ ~f ₇
, And a multi-carrier signal including unmodulated frequencies f ₂ and f ₈ , and thereafter the same processing is repeated until time t _n .

As described above, in the present embodiment, data is not allocated to carriers whose reception power is small and transmission quality is expected to be degraded without using all carriers in the band. Since data is allocated and transmitted only to carriers expected to have good transmission quality, the transmission quality of multi-carrier transmission can be improved.

FIG. 6 shows calculation results of a transmission efficiency calculation example when the multicarrier communication system of the above embodiment is used in a mobile communication environment. In this calculation example, in a propagation path in which frequency selective fading has occurred,
The transmission efficiency in a multi-carrier communication system in which the total number of carriers is 64, the modulation scheme is DQPSK, and the demodulation scheme is delay detection is calculated. Here, the transmission efficiency is defined as: transmission efficiency = 2 × the number of selected carriers × the packet success probability = 2 × (the total number of carriers−the number of unused carriers) × the packet success probability, and the effective number of bits per packet is Represents. One packet indicates a set of low-bit-rate data that is transmitted in parallel and transmitted at the same time. When all the data in the packet is transmitted without error, it is determined that the transmission of the packet is successful. FIG. 6 shows a change in transmission efficiency with respect to the number of unused carriers, using the average carrier power versus noise power (CNR) as a parameter. From this figure, for example, when CNR = 20 dB, the transmission efficiency is maximized when transmission is performed without using the 18th carrier in order from the lowest reception level (the number of unused carriers is 18). I understand that there is. This indicates that the transmission efficiency is improved by using the present embodiment as compared with the conventional case where transmission is performed using all carriers. CNR = 20 dB
In other CNRs, since the transmission efficiency is improved, by using the multicarrier transmission system of the present embodiment, not only the transmission quality of the multicarrier transmission can be improved, but also the transmission efficiency can be improved. It can be understood that the multicarrier transmission system of the present embodiment is effective for multicarrier transmission.

As described above, in the present embodiment, the carrier signal as the selection result obtained by the selection data transmitter of the receiving station is updated every time transmission is performed from the transmitting station to the receiving station. Therefore, transmission can be performed so as to correspond to the latest frequency characteristic of the propagation path.

Next, a multi-carrier communication system according to a second embodiment of the present invention will be described with reference to FIG. In addition,
7, the same parts as those in FIG. 3 are denoted by the same reference numerals, and the description will be omitted.

This embodiment is different from the first embodiment shown in FIG. 3 in that an encoder 32 for adding an error correction code is added before or after the serial-to-parallel converter 12 of the transmitting station apparatus 10.
This is obtained by adding a decoder 34 of an error correction code to a stage before or after the parallel-to-serial converter 28 of the receiving station device 20.

The operation of the multi-carrier communication system of the present embodiment is basically the same as that of the first embodiment. Before being input to 12 or after being converted to low bit rate data, the data is subjected to block coding or convolutional coding by an error correction code encoder 32. Also, in the receiving station device 20, before the signal is input to the parallel-to-serial converter 28,
Are output to the decoder 34 of the error correction code and decoded.

In this embodiment, since transmission errors can be reduced by encoding and decoding error correction codes, transmission quality can be further improved, and transmission efficiency can be improved as in the first embodiment. Can be improved.

In each of the above embodiments, an example has been described in which the signal selector 26 is provided between the multicarrier demodulator 22 and the parallel-to-serial converter 28 to select a signal after demodulation. The modulator 26 is a multi-carrier demodulator 26
, A carrier modulated with low bit rate data may be selected and then demodulated.

In each of the above embodiments, an example has been described in which the selected data transmitter 30 transmits the carrier information wirelessly, but the transmission may be performed by another method such as a wired method.

Further, in each of the above-described embodiments, an example has been described in which the selected data transmitter 30 selects a predetermined number of carriers in descending order of the received power value. The received power value of each carrier may be compared with a preset threshold value, and a carrier having a received power value larger than the threshold value may be selected.

In this case, the number of selected carriers is not always N. For this reason, the low bit rate data converted by the serial / parallel converter of the transmitting station device is temporarily stored in the buffer memory, and if the number of selected carriers is smaller than the number of low bit rate data, the buffer The same number of low bit rate data as the number of selected carriers is selected from the low bit rate data stored in the memory, and the selected low bit rate data is allocated to the selected carrier, modulated, and transmitted. To do. On the other hand, when the number of selected carriers is larger than the number of low bit rate data, the same number of carriers as the number of low bit rate data are selected again from the selected carriers in descending order of the received power value. Low bit rate data is allocated to the carrier and modulated and transmitted. If the number of selected carriers is larger than the number of low bit rate data,
The number of low bit rate data stored in the buffer memory may be increased, and the same number of low bit rate data as the number of selected carriers may be selected and transmitted.

In the above description, an example in which a carrier used for transmission is selected by the selected data transmitter has been described. However, the reception power value of each carrier is transmitted from the receiving station device, and the transmitting station device side described above. The carrier used for transmission may be selected in the same manner as the selection process of the selected data transmitter.

[0064]

As described above, according to the present invention,
Since high-bit-rate data is converted to a plurality of low-bit-rate data and transmitted using a carrier with a large received power value, transmission quality can be improved without increasing the number of antenna elements. The effect is obtained.

[Brief description of the drawings]

FIG. 1A is a diagram illustrating the influence of frequency selective fading on single carrier transmission, and FIG. 1B is a diagram illustrating the effect of frequency selective fading on multicarrier transmission.

FIG. 2 is a diagram illustrating a communication quality management improvement method according to the related art.

FIG. 3 is a block diagram showing a first embodiment of the present invention.

FIG. 4A is a diagram illustrating a waveform of a signal output from the multicarrier modulator according to the first embodiment;
(B) is a diagram illustrating a waveform of a signal input to the multicarrier modulator according to the first embodiment, and (c) is a diagram illustrating a carrier selection example according to the first embodiment. is there.

FIG. 5 is a flowchart showing a procedure for transmitting information from a transmitting station to a receiving station according to the first embodiment.

FIG. 6 is a diagram showing the transmission efficiency of the first embodiment.

FIG. 7 is a block diagram showing a second embodiment of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 transmitting station apparatus 12 serial-parallel converter 14 selected data receiver 16 signal allocator 18 multicarrier modulator 20 receiving station apparatus 22 multicarrier demodulator 24 received power measuring instrument 26 signal selector 28 parallel-serial converter

Claims (5)

[Claims] 1. A serial-parallel converter for converting high bit rate data into a plurality of parallel low bit rate data, and selecting from a plurality of carriers having different frequencies for each of the plurality of low bit rate data. A signal allocator that allocates each of the carriers having a large received power value, and a multicarrier that simultaneously modulates each of the allocated carriers with each of the plurality of low bit rate data and transmits the multicarrier signal together with the unselected carrier. A modulator for a multicarrier communication system, comprising: a modulator; 2. A multi-carrier demodulator for receiving a multi-carrier signal including an unmodulated carrier and a plurality of carriers each having a different frequency modulated with low bit rate data and demodulating the plurality of low bit rate data. A receiving power measuring device that measures a receiving power value of each carrier included in the multicarrier signal; and a transmitter that outputs a signal related to the receiving power value of the carrier measured by the receiving power measuring device. A parallel-to-serial converter that converts a plurality of demodulated low-bit-rate data into serialized high-bit-rate data. 3. A multicarrier communication system comprising the transmitting station device for a multicarrier communication system according to claim 1 and the receiving station device for a multicarrier communication system according to claim 2. 4. The multi-carrier communication system according to claim 3, wherein the transmitting station device for a multi-carrier communication system includes an encoder for attaching an error correction code, and the receiving station device for the multi-carrier communication system includes a decoder for an error correction code. Carrier communication system. 5. The signal allocator selects and allocates a predetermined number of carriers in descending order of the received power value, or selects and allocates a carrier whose received power value is equal to or greater than a predetermined threshold value. The multi-carrier communication system according to claim 4.