JP2003514430A - Time diversity method and apparatus for improving communication bit rate in multi-carrier system - Google Patents

Abstract

(57) [Summary] A method for increasing the effective signal-to-noise ratio (SNR) of a carrier signal having a signal-to-noise ratio that cannot completely transmit information bits of an input bit stream at a certain bit error rate during one symbol period will be described. Increasing the SNR of the carrier signal involves modulating the same information bits of the input bit stream during successive symbol periods. By modulating the same information bits of the input bit stream during successive symbol periods, a bit error rate for the carrier signal is achieved. Such a carrier signal is demodulated during successive symbol periods to obtain partial information on the information bits. Such partial information is combined to obtain complete information.

Description

Detailed Description of the Invention

[0001]

[Display of related applications]

This specification is co-pending and incorporated by reference in its entirety 199
Claim the benefit of filing date of US provisional patent application No. 60 / 164,543 filed Nov. 10, 1997, entitled "Time Diversity Method for Improving Data Rate in Multi-Carrier System", entitled "Time Diversity Method".

[0002]

FIELD OF THE INVENTION

The present invention relates to a communication system using multicarrier modulation. In particular, the present invention relates to a method and apparatus for improving transmission bit rate in a multi-carrier modulation system.

[0003]

BACKGROUND OF THE INVENTION

In conventional multi-carrier communication, a transmitter communicates over a communication channel by using multi-channel modulation or separate multi-tone transform (DMT). A DMT transmitter, such as a DMT modem, receives an input bit stream with input bits and modulates such information bits onto a carrier signal (carrier) or sub-channel located within the effective frequency band of the communication channel. Such modulation is done at the symbol transmission rate of the system. DMT transmitters typically use an Inverse Fast Fourier Transform (IFFT) to produce a phase characteristic (ie, phase) and carrier to produce a time domain signal (ie, transmitted signal) that is a continuous combination of carrier signals. Modulate the amplitude of the signal. The DMT transmitter transmits the transmission signal to the DMT receiver via the communication channel. Such a receiver demodulates the received carrier signal using a fast Fourier transform.

The number of information bits carried by each carrier signal during a single DMT symbol period is
It varies depending on the carrier signal SN ratio (SNR) and the bit error rate (BER) condition corresponding to the communication channel. Usually, DSL communication system 1x10 ^{- 7} of BER (i.e., on average, 1000 only occurs one-bit error to million times) is operating in. Since the carriers are different, the SN ratio is also different, and even the same BER can carry different numbers of bits. However, in conventional multi-carrier communication systems, if a carrier signal has a signal-to-noise ratio less than the lowest signal-to-noise ratio required to modulate a complete information bit, then the DMT
The transmitter does not use that particular carrier signal. For example, to carry at least one complete information bit with a BER of 1 × 10 ⁻⁷ , the carrier signal must be at least 11
． An uncoded signal-to-noise ratio of 34 dB is required. No carrier signal can be used with an SN ratio less than 11.34 dB, leaving many carrier signals unused in noisy multi-carrier communication systems.

Therefore, a system that can use a previously unused carrier signal even if it has a signal-to-noise ratio smaller than the lowest signal-to-noise ratio required to modulate one complete information bit at a particular BER, and A method is required.

[0006]

[Outline of the Invention]

One of the objects of the present invention is to use multi-carrier modulation by using a carrier signal having a signal-to-noise ratio (SNR) that cannot transmit one information bit at a particular bit error rate during one DMT symbol period. It is to improve the transmission bit rate of the transceiver. In one aspect, the invention features a method in a multicarrier modulation system that includes two transceivers that communicate with each other using multiple carrier signals to modulate an input bitstream. One of the carrier signals has a signal-to-noise ratio (SNR) during which one information bit of an input bitstream on the carrier signal cannot be completely transmitted at a bit error rate during a DMT symbol period. There is. To increase the effective signal-to-noise ratio of the carrier signal and achieve the particular bit error rate, the same information bits of the input bitstream are modulated during the multiple symbol periods on this carrier signal. The plurality of symbol periods may be consecutive. At least 1 bit is allocated to a carrier signal having an SN ratio that cannot completely transmit information bits at a specific bit error rate. In an embodiment, a step of determining a transmission bit rate is performed, and the step of modulating the same information bit is performed when the transmission bit rate is below a minimum transmission bit rate. In another embodiment, the step of modulating the same information bit is performed if the modulation improves the transmission bit rate by at least a predetermined threshold rate.

In another aspect, the invention features a method of communicating with each other over a communication channel. During the symbol period, one or more information bits of the input bitstream are transmitted as one or more carrier signals at a first bit error rate. During successive symbol periods, the same information bit of the input bitstream is transmitted as one of the carrier signals at a second bit error rate. In one embodiment, the second bit error rate is higher than the first bit error rate. Further, the consecutive symbol periods may include symbol periods during which at least one information bit of the input bit stream is transmitted as one or more carrier signals at the first bit error rate. This increases the number of bits transmitted for each symbol period and improves the transmission bit rate at the first bit error rate.

Furthermore, in another aspect, the present invention is a method of demodulating a carrier signal having an SN ratio that cannot completely transmit information bits at a certain bit error rate during one symbol period. Such carriers are demodulated during multiple consecutive symbol periods to obtain some information about an information bit during each successive symbol period. A portion of the information obtained during the successive symbol periods is combined to produce a complete information bit.

In yet another aspect, the present invention receives the same information bit as a previously unused carrier signal at a second bit error rate during consecutive symbol periods. Such an unused carrier signal was not used because it could not carry bits at the first bit error rate. Also, since the second bit error rate is higher than the first bit error rate, it is possible to improve the transmission bit rate with the first bit error rate.

[0010]

DESCRIPTION OF THE INVENTION

FIG. 1 illustrates separate multitone modulation (communicating with remote transceiver 14 via communication channel 18 by using communication signal 38 having a plurality of carrier signals.
Digital Subscriber Line (DSL) communication system 2 including DMT transceiver 10
Is shown. Such a DMT transceiver 10 includes DMT transmitters 22 and D
The MT transceiver 26 is provided and the remote transceiver 14 is provided with a transmitter 30 and a receiver 34. Although described below with respect to separate multitone modulation, the principles of the present invention are not limited to these, and orthogonal multi-amplitude modulation (OQA) may be used.
M), DWMT (discrete wavelet multitone) modulation, and orthogonal frequency division multiplexing (OFDM).

Communication channel 18 provides a downstream communication path from DMT transmitter 22 to remote receiver 34, and an upstream communication path from remote transmitter 30 to DMT receiver 26. In one embodiment, the communication channel 18 is a twisted pair of telephone subscriber lines. In another embodiment, the communication channel 18 is a quad cable consisting of two pairs of fiber optic lines, twisted lines, or one of the star quad cables, the Dieselhorst-Martin quad. ) It may be a cable or the like. In the case of a wireless communication system, the transceivers 10, 14 are wireless modems and a communication channel 18
Is the air through which the transmitted signal 38 is transmitted between the transceivers 10, 14.

As shown in FIG. 1, the DMT transmitter 22 includes a quadrature amplitude modulation (QAM) encoder 42, a bit allocation table (BAT) 44, and a modulator 46. The transmitter 30 of the remote transceiver 14 comprises the same parts as the DMT transmitter 22. Although this embodiment describes the details of the DMT transmitter 22, the concept of the invention can also be applied to receivers 34, 36 with similar components to the DMT transmitter 22, in which case the reverse Perform the functions in reverse order.

The QAM encoder 42 maps the input serial data bits 54, which consist of information bits, into N parallel QAM symbols 58. Where N is
It represents the number of carrier signals generated by the modulator 46. The modulator 46 is
An Inverse Fast Fourier Transform (IFFT) is used to transform the QAM symbols 58 into a transmitted signal 38 composed of a series of DMT symbols 70. Each carrier signal of transmit signal 38 is modulated with a different QAM symbol 58. In one embodiment, pilot tone is included in transmit signal 38 during reception of transmit signal 38 to provide a reference signal for coherent demodulation of the carrier signal at remote receiver 34.

Generally, the modulator 46 has a DMT symbol of 1 (on a DMT symbol by DMT s).
ymbol basis) Modulates information bits on the carrier signal. Each DMT symbol period is approximately 250 milliseconds corresponding to a DMT symbol rate of 4 kHz. D
During the MT symbol period, the number of bits modulated onto a carrier signal is
At the signal-noise ratio (SNR) of the carrier signal.

The modulator 46 is capable of modulating several information bits on each carrier signal when the communication channel 18 is low in noise (ie, for each carrier signal has a high SN ratio). Can increase the bit rate of the system. When the condition of the communication channel 18 is bad (that is, it is noisy), the SN ratio is low, the number of information bits modulated on each carrier signal is small, and the bit rate of the system is low. For example, Table 1 below uses QAM,
In one DMT symbol period, shows the non-coding SN ratio required to modulate the information bits on a 1-8 bit carrier signal at BER of 1x10 ^-7.

Table 1: Uncoded SN ratio required on carrier during 1 symbol period when BER is 1 × 10 ^−7.

[Table 1] In a DMT system, a large number of carrier signals are usually used,
The SNR of multiple carrier signals may be low to carry all of the information bits at a particular bit error rate. For example, the SN ratio of the carrier signal is 11
If the SN ratio is less than 1.34 dB, it is not possible to transmit all the information bits on the carrier signal with a BER of 1 × 10 ⁻⁷ . In accordance with the principles of the present invention, transceivers 10, 14 take advantage of these carrier signals that would not otherwise have been used to carry information over communication channel 18. In the following, such a carrier signal is referred to as a recovered carrier signal (recovered carrier signal).
signals). As described further below, the transmitter 22 is configured with a continuous DMT.
During the symbol period, a plurality of information bits are transmitted on the reproduced carrier signal with a BER higher than the BER. Depending on the carrier signal, it is not possible to transmit all the information bits at a specific BER, but the effect of transmitting the information bits on the reproduced carrier signal is to increase the effective SN ratio of the reproduced carrier signal and
It is to realize ER.

For example, the SN ratio of the reproduced carrier signal is approximately 8.34 dB, and the SN required to modulate one information bit in one DMT symbol period to achieve a BER of 1 × 10 ^−7. If the ratio is about 11.34 dB, the modulator 46 has 1
Information bits are modulated over two consecutive DMT symbols 70. Table 2 below shows an embodiment of the SN ratio required to modulate a certain information bit with 1 × 10 ⁻⁷ BER in the DMT communication system 2. As shown in the second column, another method of transmitting one bit over consecutive DMT symbols is to transmit only a fraction of one bit on the carrier during one DMT symbol period. .

Table 2: SN ratio required on carrier signal during 1 symbol period when BER is 1 × 10 ⁻⁷

[Table 2] In another embodiment, the transmitter 22 causes one or more information bits on the recovered carrier signal to be BE below the specified BER during non-consecutive DMT symbol periods.
Send with R. For example, the transmitter 22 may transmit during a separated DMT symbol period (eg,
The same information bits can be sent on the recovered carrier signal during the first and third DMT symbol periods). Another example includes transmitting the same information bit every DMT symbol period every three, four, five, and so on. Thus, if the receiver 34 is aware of which DMT symbol period the transmitter 22 is using to transmit the information bit, then it is the case when a non-contiguous DMT symbol period is used. Also, the transmitter 22 is capable of transmitting all the information bits on the reproduced carrier signal.

In yet another embodiment, the transmitter 22 is capable of transmitting one or more bits on the regenerated carrier signal during one DMT symbol period. The BER for such an embodiment, in which multiple bits are transmitted, is higher than if only one information bit is transmitted on the reproduced carrier signal. Also, the transmitter 22 may have a continuous DM longer than required to transmit one information bit.
During the T symbol period, the same information bit is transmitted on the reproduced signal. For example, if the SN ratio is 8.34DB, to achieve a BER of 1x10 ^-7, reproduced carrier signal may carry two bits over four consecutive DMT symbols 70.

The BAT 44 interacts with a modulator 46 to identify the number of bits carried by each carrier signal. The BAT 44 in one embodiment allocates 1 bit for multiple regenerated carrier signals and identifies additional information indicating the number of DMT symbol periods required to fully carry the information bits. This allows BAT
44, 44 'carry information bits over multiple DMT symbol periods, so which carrier signal is used and the DMT symbol period required to transmit the information bits on that carrier signal. Recognize the number. In another embodiment, BAT specifies a portion of the bits because it represents the number of DMT symbol periods needed to fully carry the information bits.

FIG. 2 illustrates a DMT transceiver 1 for communicating over a communication channel 18.
0 and one embodiment of the process used by remote transceiver 14. During initialization of the transceivers 10, 14, the remote receiver determines the number of bits carried by each carrier signal (step 204). The remote receiver 34 is
An actual measurement is performed on each carrier signal to determine the SN ratio required to achieve the specific bit error rate. The number of bits that the carrier signal can carry is limited by the determined SN ratio, and it becomes possible to achieve the specific bit error.

For example, Table 1 above shows the SN ratio of the carrier signal required to carry 1 to 8 bits with a BER of 1 × 10 ⁻⁷ .

Next, the receiver 34 determines the specific BER from the measured SN ratio of the reproduced carrier signal.
Determine how many DMT symbol periods are needed to completely carry the information bits in (step 206). For example, the measured value of the SN ratio is 8.34d.
If it is B, the receiver 34, in order to fully convey the information bits in 1x10 ^-7 it is a specific rate requires two DMT symbol periods, and determines. About half of the bit information can be carried during each of the two symbol periods, and in fact, during each symbol period, the carrier signal carries either a portion of the information or a fraction of one information bit. To do. For example, if the measured SN ratio is 5.34 dB, then the receiver determines that four DMT symbols are needed to fully carry the information bits.

Next, the remote receiver 34 exchanges the number of bits assigned to each carrier signal with the transmitter 22 (step 208). For a carrier signal having an SN ratio such that one bit cannot be completely transmitted during one symbol period, the remote receiver 3
4 specifies the number 3 of DMT symbol periods required to transmit one bit completely, or whether a fraction of one information bit should be transmitted during each DMT symbol period. Can be specified.

The transmitter 22 and the receiver 34 copy the bit allocation tables 44, 44 ′ that specify the number of bits allocated to each carrier signal based on the information determined by the receiver 34 and exchanged with the transmitter 22. Are respectively generated (step 212). The BAT 44 in one embodiment allocates 1 bit for the recovered carrier signal and identifies additional information indicating the number of DMT symbol periods required to fully carry the information bits. In another embodiment, the BAT identifies a portion of one information bit carried during each DMT symbol period for the recovered carrier signal.

In some embodiments, as indicated by the phantom, the transmitter 22 has the following factors: (1) the transmission bit rate of the communication system; or (2) a regenerated carrier for carrying information bits. Based on 1 or a combination of the degree of improvement of the transmission bit rate obtained by using the signal, it is determined whether or not the reproduced carrier signal is used to carry the information bit (step 216). Regarding the first factor, the transceiver 10 compares the transmission bit rate of the DSL communication system 2 with the minimum transmission bit rate (eg, 256 kilobits per second (kb / s)). If the transmission bit rate of DSL communication system 2 is greater than or equal to the minimum transmission bit rate, transmitter 22 does not use the regenerated carrier signal to carry the information bits (step 218). Conversely, if the transmission bit rate is less than the minimum transmission bit rate, then transmitter 22 can modulate the information bits on the regenerated carrier signal. Regarding the second factor, if the transmission bit rate of the DSL communication system 2 is increased by a predetermined amount by using the reproduced carrier signal, the transmitter 22 can modulate the information bit on the reproduced carrier signal. . For example, if the increase in transmission bit rate is above a predetermined threshold (eg, 10%), then transmitter 22 uses the regenerated carrier signal to transmit the information bits.

When using the regenerated carrier signal to carry information, the transmitter 22 modulates the same information bits on the regenerated carrier signal for two or more consecutive DMT signal periods (step 226). The number of consecutive DMT symbols over which the same information bit is transmitted depends on the signal-to-noise ratio of the regenerated carrier signal and the BER at which the modulation bits are transmitted. Therefore, some of the carrier signals carry fully transmitted information bits at the first BER during one DMT symbol period, and a plurality of regenerated carrier signals are said over one or more consecutive DMT symbols 70. At the second BER, which is longer than the first BER, (1 DMT
Carry information bits (per period). By combining the information bits on the reproduced carrier signal and the information bits on the other carrier signal during one DMT symbol period,
The transmitter 22 can increase the transmission rate to the first BER.

For example, in one embodiment of BAT 44, 1 bit is set to 1 for carrier signal # 1.
Bits are carrier signals # 2 and # 3, 3 bits are carrier signals # 4 and #
5 can be assigned. The BAT 44 can also identify carrier signal # 1 as a reproduced carrier signal that carries the same information bits in two consecutive DMT symbols. Therefore, the reproduced carrier signal # 1 has two consecutive DMs.
While carrying the same information bits in the second BER over both T symbols 70, carrier signals # 2, # 3, # 4, and # 5 are new information bits during each of two consecutive DMT symbols 70. Is transported at the first BER.

In another embodiment, the reproduced carrier signals (eg carrier signals # 2, # 3,
Since # 4 and # 5 carry only the information bits on (not used), 2
Two consecutive second DMT symbol periods can be used. In another embodiment, the transmitter 22 transmits the information bits on the first BER in one DMT symbol 70, and then on the regenerated carrier signal on the second BER during two consecutive DMT symbol periods. Send the information bit of. Each of the above embodiments may have little or no use in improving the transmission rate, but
These embodiments can at least simplify the configuration of the transmitter 22 or the receiver 34.

Next, the DMT transmitter 22 transmits the transmission signal 38 to the receiver 34 (step 228). Receiver 34 demodulates such transmitted signal 38 during successive DMT symbol periods to obtain partial information of the information bits during successive DMT symbol periods (step 230). The receiver 34 then linearly combines the partial information of the information bits to produce a complete information bit (step 232).

In one embodiment, the receiver 34 uses the first DMT symbol period in a series of consecutive DMT symbol periods to determine if the same information is modulated over consecutive DMT symbol periods. For example, if the receiver 34 determines that the phase of the carrier signal is approximately 90 °, then the receiver 34 expects such information bits to have a value equal to one. Therefore, the receiver 34 does not have to wait for the next DMT symbol to obtain another piece of partial information, as it produces a complete information bit. Therefore, in such an embodiment, receiving one information bit over a plurality of DMT symbols does not delay the demodulation of such information bit. However, if the phase of the carrier signal is less than 90 °, such as 45 °, then the receiver 34 recognizes the value of the information bit and the receiver 34
It will be necessary to obtain the additional information provided by the MT symbol. For example, phase 45
° corresponds to a bit value of 1 or a value caused by noise. Even in such a case, the receiver 34 can still determine from this phase that the information bit has the value 1, and can then use error checking to determine if such a decision was incorrect. .

Since the SN ratio of one or more carrier signals is affected during the operation of the communication system 2, the communication state may be changed. In one embodiment, the receiver 34
And the transmitter 22 dynamically exchanges bit allocation information corresponding to the new communication conditions of the communication channel 18. As mentioned above, for carrier signals with signal-to-noise ratios below the minimum signal-to-noise ratio, such information exchange involves the number of DMT symbol periods needed to transmit a complete information bit. The exchange of information may occur at the boundaries of complete information bits (eg, after the second DMT symbol 70, which carries the fully transmitted information bits in two DMT symbols).

While the invention has been shown and described with reference to certain preferred embodiments, various modifications in form and detail are intended to be embraced by the spirit and scope of the invention as defined by the following claims. Those skilled in the art will appreciate that what can be done without departing from the above. For example, although the invention has been described in the present specification using DSL, various types of DSL such as ADSL, VDSL, SDSL, and HD are used.
It will be appreciated that SL, HDSL2 or SHDSL can also be used. The principle of the invention is that any combination of applications carried over a DSL system (
It goes without saying that it also applies to work from home, video conferencing, high speed internet access, video on demand, etc.

[Brief description of drawings]

The invention is specified in detail by the appended claims. Not only the advantages of the present invention described above, but further advantages of the present invention can be better understood by referring to the following description in connection with the accompanying drawings.

FIG. 1 shows separate multitone modulation (DMT) communicating with a remote transceiver.
1 is a block diagram of one embodiment of a Digital Subscriber Line (DSL) communication system that includes a transceiver.

FIG. 2 is a flow diagram of an embodiment of a process for improving transmission bit rate of a communication system.

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Claims (29)

[Claims] 1. A plurality of carrier signals for modulating an input bitstream, one of which has a signal-to-noise ratio (SN ratio) such that information bits of the input bitstream cannot be completely transmitted at a certain bit error rate. A method of increasing an effective SN ratio of the carrier signal in a multicarrier modulation system including: two transceivers that communicate with each other using a transmission signal including: To achieve the bit error rate, during the plurality of symbol periods, modulating the same information bits of the input bitstream onto the carrier signal having a signal-to-noise ratio that cannot be transmitted completely at the bit error rate. What is equipped with. 2. The method of claim 1, wherein the plurality of symbol periods are consecutive (success).
ive order). 3. The method of claim 1, further comprising the step of determining a number of symbol periods for carrying the same information bit. 4. The method of claim 1, further comprising the step of allocating at least one bit to a carrier signal having a signal-to-noise ratio that does not allow information bits to be transmitted completely at the bit error rate. thing. 5. The method of claim 1, further comprising the step of determining a transmission bit rate, wherein the step of modulating the same information bit is performed if the transmission bit rate is below a minimum transmission bit rate. The thing characterized by. 6. The method of claim 1, wherein the step of modulating the same information bit is performed when the modulation improves a transmission bit rate by at least a predetermined threshold percentage. What to do. 7. A multicarrier modulation system comprising two transceivers using a transmission signal having a plurality of carrier signals for modulating an input bitstream and communicating with each other via the communication channel via the communication channel. And transmitting at least one information bit of the input bit stream as one or more carrier signals at a first bit error rate during a symbol period, and during the symbol period, the input Transmitting the same information bit of a bitstream as one of the carrier signals at a second bit error rate. 8. The method of claim 7, wherein the second bit error rate is higher than the first bit error rate. 9. The method according to claim 7, wherein the number of bits transmitted in each symbol period is increased in the consecutive symbol periods, and the transmission is performed at the first bit error rate. A symbol period for transmitting at least one information bit of the stream as at least one carrier signal at a first bit error rate. 10. The method of claim 7, further comprising the step of identifying one or more carrier signals for transmitting the input bitstream information bits at the second bit error rate. What to do. 11. A communication bit rate at a first bit error rate in a multi-carrier modulation system comprising two transceivers communicating with each other using a transmission signal comprising a plurality of carrier signals for modulating an input bit stream. Is a method of using a carrier signal that cannot be used to carry bits at the first bit error rate in order to increase the transmission bit rate by increasing the number of bits transmitted per symbol period. To the first bit error rate, a second bit error rate that is higher than the first bit error rate for one or more carrier signals for the same information bit of the input bit stream during consecutive symbol periods. With a step of sending in, characterized by 12. The method of claim 11, further comprising the step of determining a number of symbols to carry the same information bit. 13. The method of claim 11, further comprising the step of allocating at least 1 bit to the unusable carrier signal at a second bit error rate. 14. The method of claim 11, further comprising the step of determining a transmission bit rate, wherein the step of modulating the same information bit is performed if the transmission bit rate is less than a minimum transmission bit rate. The thing characterized by. 15. The method of claim 11, wherein the step of modulating the same information bit comprises:
What is performed when the transmission bit rate is improved by at least a predetermined threshold rate by the modulation. 16. A multi-carrier modulation system comprising two transceivers using a transmission signal having a plurality of carrier signals for modulating an input bit stream and communicating with each other via the communication channel via the communication channel. And a step of receiving one or more information bits of the input bitstream as one or more carrier signals at a first bit error rate during a symbol period, and the input bitstream during consecutive symbol periods. Receiving the same information bit of as the one of the carrier signals at a second bit error rate. 17. The method of claim 16, further comprising allocating at least one bit for the one carrier signal on which the same information bit was received during successive symbol periods. Characterized by. 18. The method of claim 16, further comprising measuring a signal to noise ratio (SN ratio) for the carrier signal. 19. The method of claim 18, further comprising using the signal-to-noise ratio to determine the number of consecutive symbol periods required to fully carry the information bits at the second bit error rate. It is characterized by having steps. 20. A plurality of carrier signals for modulating an input bitstream, one of which has a signal-to-noise ratio (SN ratio) such that information bits of the input bitstream cannot be completely transmitted at a certain bit error rate. A method of increasing the effective signal-to-noise ratio of the carrier signal in a multicarrier modulation system comprising: two transceivers communicating with each other using a transmission signal comprising: Demodulating a carrier signal having a signal-to-noise ratio such that the information bit cannot be completely transmitted on the carrier signal at a certain bit error rate during a plurality of consecutive symbol periods in order to obtain a part of the information about the information bit; To generate different information bits during the consecutive symbol periods. Coupling a portion of the information that has been, further comprising a, those characterized by. 21. The method of claim 20, further comprising the step of determining a number of symbols for receiving the same information bit. 22. The method of claim 20, further comprising the step of allocating at least one bit to a carrier signal having an SN ratio that does not allow information bits to be transmitted completely at the bit error rate. thing. 23. The method of claim 20, further comprising the step of determining a received bit rate, wherein the step of demodulating the same information bit is performed if the received bit rate is below a minimum received bit rate. The thing characterized by. 24. The method of claim 20, wherein the step of demodulating the same information bit comprises:
What is performed when the received bit rate is improved by at least a predetermined threshold rate by the demodulation. 25. A communication bit rate at a first bit error rate in a multi-carrier modulation system comprising two transceivers communicating with each other using a transmission signal comprising a plurality of carrier signals for modulating an input bit stream. A method of using a carrier signal that cannot be used to carry bits at the first bit error rate in order to increase the information bit received per symbol period using a carrier signal that was previously unavailable. Of the same information bits on the previously unusable carrier signal during consecutive symbol periods in order to increase the transmission bit rate at the first bit error rate with increasing the number of With a second bit error rate higher than the error rate Shin steps, further comprising a, those characterized by. 26. The method of claim 25, further comprising the step of determining a number of symbols for receiving the same information bit. 27. The method of claim 25, further comprising the step of allocating at least 1 bit to the unusable carrier signal at a second bit error rate. 28. The method of claim 25, further comprising the step of determining a received bit rate, wherein said step of demodulating said same information bit is performed if said received bit rate is below a minimum received bit rate. Things that are characterized by. 29. The method of claim 25, wherein the step of demodulating the same information bits comprises:
The demodulation is performed when the reception bit rate is improved by at least a predetermined threshold rate.