JPH09298519A - Data signal transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the quality in the case of data signal transmission. SOLUTION: Data signal are assigned between a 1st pilot signal PS1 and a 2nd pilot signal PS2 by a slot multiplexer circuit 15. When one slot period is 1msec and a transmission speed is less than 32kbps, burst transmission is conducted. In this case, the slot multiplexer circuit 15 assigns a data signal in the middle of each slot. For example, when the transmission speed is 16kbps or 8kbps, a data signal in 16-bit or 8-bit is assigned in the middle of each slot. In this case, even when a signal to noise ratio of the transmission line is low and the transmission quality is wrong, since noise superimposed on the 1st, 2nd pilot signals PS1, PS2 is averaged at the middle part of each slot, it is possible to conduct synchronization detection by using a highly accurate reference phase.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmitting method suitable for use in combination with a data receiving method for performing synchronous detection using an interpolated pilot signal.

[0002]

2. Description of the Related Art In the field of mobile communication, since a mobile station moves at high speed, it is necessary to ensure stable operation even in an environment with a high fading pitch. Therefore, the pilot signal indicating the reference phase of modulation is transmitted at a predetermined cycle. A space between one pilot signal and the next pilot signal is called a slot, and a data signal is arranged between them. Then, on the receiving side that receives the signal composed of each slot, based on the pilot signal at the beginning of the slot and the pilot signal at the end of the slot, the reference phase within the slot period is determined by interpolation,
Synchronous detection is performed based on the interpolated reference phase.
Such a method of adaptively obtaining the reference phase is often called synchronous detection using an interpolated pilot signal, and there are various methods, but the interpolation coefficient depends on the time from each pilot signal. Is generally determined.

When variable rate data transmission is performed, data is transmitted in bursts. In this case, a technique of arranging the data signal in one slot so as to be adjacent to the pilot signal has been developed (Gigaku Technical Report RCS95-166). This point will be specifically described with reference to FIG. 11. FIG. 11 is a diagram showing a relationship between a conventional pilot signal and a data signal. In this example, the period of 1 slot is 1 mse
c. In this case, the data signal transmission rate is 32k.
If it is bps, continuous transmission is performed, and a 32-bit data signal is arranged between pilot signals PS. On the other hand, when the data transmission rate is lower than 32 kbps, burst transmission is performed. For example, the transmission rate is 16k
If it is bps, as shown in the figure, a 16-bit data signal is arranged adjacent to the pilot signal PS arranged at the beginning of the slot.

[0004]

The transmission path S
When / N is low and the transmission quality is poor, noise is superimposed on the received pilot signal at a large level. Therefore, a large error is included in the phase measurement result by the pilot signal PS. As described above, the reference phase within the slot period is the pilot signal PS at the beginning and the end.
The interpolation coefficient is determined according to the time from, and adaptive estimation is performed. Therefore, in the vicinity of the pilot signal PS, noise is not averaged and the estimation error becomes large. Therefore, when the data signal is arranged adjacent to the pilot signal PS at the head portion, there is a problem that the influence of noise is great and the transmission quality is deteriorated.

On the other hand, when the noise is sufficiently small or the fading pitch is high, the influence of the phase change due to the fading becomes larger than the noise. In this case, it is possible to improve the transmission quality by arranging the data signal near the pilot signal PS. The present invention has been made in view of the above circumstances, and an object thereof is to improve the transmission quality by arranging a data signal at an appropriate position in a slot.

[0006]

In order to solve the above problems, according to the invention of claim 1, a reference at each timing of a modulated data signal is generated based on each pilot signal indicating a reference phase of modulation. A data signal transmitting method used in combination with a data signal receiving method for reproducing a phase and demodulating the data signal, wherein the data signal is transmitted in a burst, and the data signal is provided between the pilot signals. To configure the slots,
In the data signal transmitting method for transmitting a plurality of the slots, the data signal is arranged in a central portion of the slots.

Further, in the invention according to claim 2,
A data signal transmitting method used in combination with a data signal receiving method of reproducing a reference phase at each timing of a modulated data signal based on each pilot signal indicating a reference phase of modulation and demodulating the data signal. Yes, while transmitting the data signal in a burst,
In a data signal transmitting method of arranging the data signal between the pilot signals to form a slot and transmitting a plurality of the slots, a data signal to be transmitted within one slot period is divided into a plurality of data blocks. , The plurality of data blocks are dispersedly arranged in the slot.

[0008] Further, in the invention according to claim 3,
A data signal transmitting method used in combination with a data signal receiving method of reproducing a reference phase at each timing of a modulated data signal based on each pilot signal indicating a reference phase of modulation and demodulating the data signal. Yes, while transmitting the data signal in a burst,
In a data signal transmitting method of arranging the data signal between the pilot signals to form a slot and transmitting a plurality of the slots, the arrangement of the data signal in each of the slots is changed according to a predetermined rule. It is characterized by doing.

Further, in the invention according to claim 4,
The data signal transmitting method is characterized in that a slot in which the data signal is arranged adjacent to the pilot signal and a slot in which the data signal is arranged in a central portion are alternately transmitted.

[0010] In the invention according to claim 5,
A data signal transmitting method used in combination with a data signal receiving method of reproducing a reference phase at each timing of a modulated data signal based on each pilot signal indicating a reference phase of modulation and demodulating the data signal. Yes, while transmitting the data signal in a burst,
A slot is formed by arranging the data signal between the pilot signals, and in the data signal transmitting method of transmitting a plurality of the slots, the transmission state of the transmission path is detected,
The arrangement of the data signals to be transmitted within one slot period is adaptively changed based on the detected transmission state.

Further, in the invention according to claim 6,
In the data signal transmitting method, the transmission quality of the transmission path is detected as the transmission state, and when the detected transmission quality is high, the data signal is arranged so as to be adjacent to the pilot signal, and the detected signal is detected. When the transmission quality is low, the data signal is arranged in the central portion of the slot.

Further, in the invention according to claim 7,
A method of transmitting a data signal, wherein a fading pitch of a transmission path is detected as the transmission state, and when the detected fading pitch is high, the data signal is arranged so as to be adjacent to the pilot signal, and the detected fading pitch is detected. When the fading pitch is low, the data signal is arranged in the central portion of the slot.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION

1. First Embodiment In the first embodiment, when transmitting data in bursts,
This is a preferred embodiment when the signal-to-noise ratio of the transmission line is low and the transmission quality is poor. 1-1. Configuration of First Embodiment Hereinafter, the configuration of the first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram for explaining a first embodiment of a data transmission system using a data signal transmitting method according to the present invention. In FIG. 1, 10 is a data transmission device on the base station side, and 20 is a data transmission device on the mobile station side. Each of the data transmission devices 10 and 20 can perform transmission and reception, and can perform bidirectional simultaneous communication. In this example, it is assumed that data is transmitted from the base station to the mobile station. Therefore, in the data transmission device 10 shown in FIG. 1, the configuration related to transmission is described as a main part, and in the data transmission device 20, the configuration related to reception is described as a main part.

First, the data transmission device 10 on the base station side is
The main parts are as follows. An error detection coding circuit 11 generates an error detection code based on the user data UD and adds it to the user data UD. A 16-bit CRC code is used as the error detection code, for example. Specifically, the user data UD is divided by a predetermined generator polynomial, and the remainder is added to the user data UD. Reference numeral 12 denotes a frame multiplexing circuit, to which user data UD to which an error detection code is added, transmission rate information indicating the transmission rate of the user data UD, and a tail bit for convolutional encoding are input. . The frame multiplexing circuit 12 composes these data into a frame according to a predetermined frame format.

Reference numeral 13 is an error correction coding circuit connected to the frame multiplexing circuit 12, and performs convolutional coding on the frame-structured data signal. Reference numeral 14 is an interleave circuit, which applies bit interleave to the convolutionally encoded data signal. This makes it possible to prevent continuous errors in a burst form. Reference numeral 15 denotes a slot multiplexing circuit, which forms a slot based on the bit-interleaved data signal and pilot signal PS. In this case, pilot signal PS is arranged at the beginning and end of each slot. In the following description, when the pilot signal PS at the beginning and the pilot signal PS at the end are distinguished from each other, the former is referred to as the first.
Pilot signal PS1, the latter the second pilot signal PS
2 will be called. Reference numeral 16 is a radio circuit, which modulates the signal from the slot multiplexing circuit 15 and transmits it via the antenna 17. The modulation method is, for example,
Spread spectrum modulation, QPSK or the like may be used.

Next, the signal transmitted from the data transmission device 10 is taken into the data transmission device 20 via the antenna 21. Reference numeral 22 is a wireless circuit, which amplifies the received signal to a predetermined level. The data transmission device 20 is mainly composed of the following parts. Reference numeral 23 denotes a slot demultiplexing circuit, which separates the signals forming each slot into a data signal and a pilot signal PS. Reference numeral 24 denotes a synchronous detection circuit, which obtains a reference phase in a period from the first pilot signal PS1 to the second pilot signal PS2 by interpolation based on the first pilot signal PS1 and the second pilot signal PS2. Then, the synchronous detection circuit 24
Generates a data signal by demodulating the signal from the slot demultiplexing circuit 23 based on the reference phase obtained by interpolation.

Further, 25 is the interleave circuit 1 described above.
4 is a deinterleaving circuit having a complementary relationship with 4, and performs deinterleaving on the synchronously detected data signal. 27
Is an error correction decoding circuit for Viterbi decoding the deinterleaved data signal. A frame demultiplexing circuit 27 separates the output of the error correction decoding circuit 26 into a Viterbi-decoded data signal and transmission rate information. An error determination circuit 28 divides the Viterbi-decoded data signal by the generator polynomial used in the error detection encoding circuit 11 described above, and deletes the error detection code to generate the user data U.
Output D. In this case, if the remainder of the division is 0, it is determined that there is no error, and if the remainder is other than 0, it is determined that there is an error.

Next, the receiving section 200 provided in the data transmission device 10 has a configuration from the radio circuit 22 to the error determination circuit 28, while the data transmission device 20 is provided.
The transmission section 100 provided in the error detection coding circuit 11
To the wireless circuit 16 are provided. In this case, the transmission unit 100 and the reception unit 200 communicate using a communication frequency different from the communication frequency used between the wireless circuit 16 and the wireless circuit 22. Specifically, the transmission unit 10
The signal from 0 is received by the receiving unit 20 via the antennas 29 and 18.
Sent to 0. Thereby, bidirectional simultaneous communication can be performed between the data transmission device 10 and the data transmission device 20.

1-2. Operation of First Embodiment Next, the operation of the first embodiment will be described with reference to FIG. FIG. 2 shows an example of the slot configuration according to the first embodiment. As described above, the slot multiplexing circuit 15 includes the first
A data signal is arranged between pilot signal PS1 and second pilot signal PS2. For example, the slot period is 1
If the data signal transmission rate is 32 kbps in msec, continuous transmission is performed as shown in FIG. on the other hand,
When the transmission rate is lower than 32 kbps, burst transmission is performed. In this case, the slot multiplexing circuit 15 arranges the data signal in the center of the slot. For example, if the transmission rate is 16 kbps or 8 kbps, a 16-bit or 8-bit data signal is arranged in the center of the slot as shown in FIG.

By the way, as described above, the synchronous detection circuit 24 (see FIG. 1) of the data transmission device 20 performs interpolation based on the first pilot signal PS1 and the second pilot signal PS2, and a reference used for synchronous detection. Generate phase.
Therefore, even if the signal-to-noise ratio of the transmission line is low and the transmission quality is poor, the noise superimposed on the first and second pilot signals PS1 and PS2 is averaged in the central portion of the slot. On the other hand, the first and second pilot signals PS1 and PS
In the vicinity of 2, the degree of noise averaging is low. Therefore, in the central part of the slot, the accuracy of the reference phase can be obtained more accurately than in the vicinity of the first and second pilot signals PS1 and PS2. According to this example, even if the quality of the transmission path is poor, synchronous detection can be performed using a highly accurate reference phase, and the error rate of the data signal can be reduced.

2. Second Embodiment In the second embodiment, when transmitting data in bursts,
This is a preferred embodiment when the quality of the data signal is homogenized. The configuration of the data transmission system according to the second embodiment is the same as that of the first embodiment shown in FIG.
In the embodiment and the second embodiment, the slot multiplexing circuit 15
Behave differently. Here, the operation of the slot multiplexing circuit 15 will be described with reference to FIGS. In this example, the interleave circuit 14 performs bit interleaving across a plurality of slots.

FIG. 3 is a diagram showing a first example of the configuration of slots according to the second embodiment. The slot multiplexing circuit 15 according to the second embodiment generates the slots shown in FIG. For example, if the data signal transmission rate is 16 kbps, the number of bits of the data signal per slot is 16 bits. Slot multiplexing circuit 1 of this example
Reference numeral 5 divides a 16-bit data signal into two to generate an 8-bit data block DB. Then, the slot multiplexing circuit 15 causes the first data block DB
1 is arranged so as to be adjacent to the first pilot signal PS1, while the second data block DB2 is arranged so that its start is at the center of the slot. Even when the data signal transmission rate is 8 kbps,
A data block of 4 bits is generated, and 16 kbp
As in the case of s, the first and second data blocks DB1,
DB2 is arranged at a predetermined position shown in FIG.

In this example, if the quality of the transmission line is poor, the accuracy of the reference phase is improved in the central portion of the slot, so that the quality of the second data block DB2 is the first data block DB1. Will be higher than. On the other hand, when the quality of the transmission line is good and the accuracy of the reference phase is dominated by the fading characteristics, the first and second pilot signals PS are compared with the central part of the slot.
1, the accuracy of the reference phase near PS2 is improved. In this case, the quality of the first data block DB1 is higher than that of the second data block DB2. That is, even if the environment of the transmission path changes, the first and second data block DBs
The transmission quality of either one of 1 and DB2 is improved.
In addition, bit interleaving is performed over a plurality of slots as described above. So, according to this example,
The transmission quality is not significantly biased, and the average quality can be guaranteed.

Next, FIG. 4 is a diagram showing a second example of the configuration of slots according to the second embodiment. The slot multiplexing circuit 15 according to the second embodiment may generate the slots shown in FIG. 4 in addition to the slots shown in FIG. In this case, assuming that the transmission rate of the data signal is 16 kbps, the slot multiplexing circuit 15 divides the 16-bit data signal into eight to generate a data block in 1-bit units, and these data blocks are equalized. Distribute in intervals.
Even when the transmission rate of the data signal is 8 kbps, a data block of 1 bit unit is generated,
Similar to the case of 16 kbps, each data block is arranged at a predetermined position shown in FIG. Even when the slots are configured as shown in FIG. 4, as in the case of FIG. 3, even if the environment of the transmission line changes, the transmission quality is not significantly biased, and the average quality can be guaranteed. .

Next, FIG. 5 is a diagram showing a third example of the configuration of slots according to the second embodiment. The slot multiplexing circuit 15 according to the second embodiment may generate the slots shown in FIG. 5 in addition to the slots shown in FIGS. In this case, the data signal transmission rate is 16 kbps or 8 k
If it is bps, the slot multiplexing circuit 15 arranges the data signal in the central portion of the slot in the first slot and arranges the data signal so as to be adjacent to the first pilot signal PS1 in the next slot. . Thereafter, these are alternately repeated to form the entire slot. Also in this case, since bit interleaving is performed over a plurality of slots, the quality of the data signal can be averaged regardless of whether the quality of the transmission path is high or low. When the transmission rate is 8 kbps, the data signal may be sequentially arranged at each position where the slot is divided into four.

3. Third Embodiment In the third embodiment, when transmitting data in bursts,
The quality of the data signal is improved by adaptively arranging the data signal in the slot according to the change in the transmission quality. 3-1. Configuration of Third Embodiment The configuration of the third embodiment is the same as the configuration of the first embodiment except that a transmission quality detection circuit is added to the data transmission device 20. However, due to the addition of the transmission quality detection circuit, the operations of the slot multiplexing circuit 15 and the slot demultiplexing circuit 23 are different between the first embodiment and the third embodiment. These points will be described with reference to FIG. FIG. 6 is a block diagram of a data transmission system according to the third embodiment.

In FIG. 6, QD is a transmission quality detection circuit, which detects the quality of the transmission path and generates a transmission quality detection signal QS indicating this level. The transmission quality detection signal QS is
It is generated based on any of the signal-to-noise ratio of the transmission path, the signal-to-interference ratio, the bit error rate, and the frequency of signal retransmission when the retransmission method is adopted, or a combination thereof. For example, the signal-to-noise ratio corresponds to the level of the received signal detected by the wireless circuit 22, and the bit error rate is detected by the error determination circuit 28. The transmission quality detection signal QS is a digital signal having a predetermined number of bits. In this way, when the transmission quality detection signal QS is generated in the data transmission device 20 operating as the reception side, this is transmitted from the transmission unit 100 via the antenna 29. In the data transmission device 10, the antenna 18
When this signal is received via, the transmission quality detection signal QS is output from the receiving section 200 to the slot multiplexing circuit 15.

The slot multiplexing circuit 1 in this embodiment
5 is configured to arrange the data signal at a predetermined position in the slot according to the transmission quality indicated by the transmission quality detection signal QS, and to multiplex the arrangement signal indicating the arrangement of the data signal with the data signal. The slot multiplexing circuit 15 is
When the transmission quality is higher than a predetermined upper limit value, the data signal is arranged so as to be adjacent to the first pilot signal PS1, and the data signal is arranged apart from the first pilot signal PS1 as the transmission quality deteriorates. Is lower than a predetermined lower limit value, the data signal is arranged in the central portion of the slot. On the other hand, the slot demultiplexing / demultiplexing circuit 23 detects an arrangement signal and separates the data signal and the pilot signal PS based on the arrangement of the data signal indicated by the arrangement signal.

3-2. Operation of Third Embodiment Next, the operation of the third embodiment will be described with reference to FIG. 7.
FIG. 7 is a diagram showing the relationship between the transmission quality indicated by the transmission quality detection signal QS and the arrangement of data signals according to the third embodiment. In the figure, the transmission quality is high in the first slot, decreases from the vicinity of the end of the first slot, maintains a low state for the second slot and the third slot, and increases again when the fourth slot starts. In this case, the first
The transmission quality is high in the slot and the fourth slot, and is less susceptible to noise during these periods. Therefore, the quality of the data signal depends on the fading characteristics of the transmission path. Therefore, during the first and fourth slot periods in which the transmission quality is high, the data signal is arranged adjacent to the first pilot signal PS1 as shown in the figure. On the other hand, in the second and third slot periods, the reference phase is affected by noise, so that the data signal is arranged in the central portion of the slot.

As described above, in the third embodiment, the data signal is adaptively arranged in the slot according to the transmission quality. Therefore, even if the environment of the transmission line changes, the data signal can be tracked accordingly. The arrangement of can be changed automatically. As a result, the error rate of the data signal can be significantly reduced.

4. Fourth Embodiment In a fourth embodiment, when transmitting data in bursts,
The quality of the data signal is improved by adaptively arranging the data signal in the slot according to the change of the fading characteristics. 4-1. Configuration of Fourth Embodiment The configuration of the fourth embodiment is the same as the configuration of the first embodiment except that a fading pitch detection circuit is added to the data transmission device 20. Due to the addition of the fading pitch detection circuit, in the first and fourth embodiments, the slot multiplexing circuit 15 and the slot demultiplexing circuit 23 are provided.
Behave differently. These points will be described with reference to FIG. FIG. 8 is a block diagram of a data transmission system according to the fourth embodiment.

In FIG. 8, FD is a fading pitch detection circuit, which detects the fading pitch from the level of the received signal to generate the fading detection signal FS. The fading detection signal FS is a digital signal having a predetermined number of bits. The fading detection signal FS is transmitted from the transmitter 100 via the antenna 29. In the data transmission device 10, the antenna 18
When this signal is received via, the fading detection signal FS is output from the receiving section 200 to the slot multiplexing circuit 15.

Slot multiplexing circuit 1 in this embodiment
5 is configured to arrange the data signal at a predetermined position in the slot in accordance with the fading pitch indicated by the fading detection signal FS, and to multiplex the arrangement signal indicating the arrangement of the data signal with the data signal. The slot multiplexing circuit 15 arranges the data signal so as to be adjacent to the first pilot signal PS1 when the fading pitch exceeds a predetermined upper limit value, and changes the data signal to the first pilot signal PS1 as the fading pitch decreases. When the fading pitch is below a predetermined lower limit value, the data signals are arranged in the central portion of the slot.
On the other hand, in the slot demultiplexing circuit 23, the arrangement signal is detected and the data signal and the pilot signal PS are separated based on the arrangement of the data signal indicated by the arrangement signal, as in the third embodiment.

4-2. Operation of Fourth Embodiment Next, the operation of the fourth embodiment will be described with reference to FIG.
FIG. 9 shows a fading detection signal F according to the fourth embodiment.
It is a figure which shows the relationship between the fading pitch which S directs, and the arrangement | positioning of a data signal. In the figure, the fading pitch is high in the first slot, decreases from the end of the first slot from the vicinity, maintains a low state for the second slot and the third slot, and increases again when the fourth slot starts. In this case, the quality of the data signal in the first slot and the fourth slot depends on the fading characteristics of the transmission path. Therefore, during the first and fourth slot periods, the data signal is arranged adjacent to the first pilot signal PS1 as shown in the figure. On the other hand, since the fading pitch is low in the second and third slot periods,
The error of the reference phase is dominated by the influence of noise. Therefore, in these periods, the data signal is arranged in the central portion of the slot.

As described above, in the fourth embodiment, since the data signal is adaptively arranged in the slot in accordance with the fading pitch, even if the environment of the transmission line changes, the data signal can be tracked accordingly. The arrangement of can be changed automatically. As a result, the error rate of the data signal can be significantly reduced.

5. Fifth Embodiment In the fifth embodiment, when transmitting data in bursts,
The data signal quality is improved by adaptively arranging the data signal in the slot according to the change in transmission quality and fading pitch. The configuration of the fifth embodiment is the same as the configuration of the first embodiment except that the transmission quality detection circuit QD of the third embodiment and the fading pitch detection circuit FD of the fourth embodiment are added to the data transmission device 20. Is. This point will be described with reference to FIG. FIG. 10 is a block diagram of a data transmission system according to the fifth embodiment. The slot multiplexing circuit 15 shown in FIG. 10 is provided with a table composed of a ROM therein, and a pattern for arranging data signals is stored therein.

When the transmission quality detection signal QS and the fading detection signal FS are supplied from the transmission quality detection circuit QD and the fading pitch detection circuit FD to the transmission section 100, the signals are transmitted from the data transmission device 20. It is transmitted to the transmission device 10. Then, the slot weighting circuit 15 arranges the data signal in the slot so that the quality of the data signal becomes highest based on the received transmission quality detection signal QS and the fading detection signal FS. In this case, the slot multiplexing circuit 15 searches the table using the transmission quality detection signal QS and the fading detection signal FS as read addresses, and reads the pattern in which the data signals are arranged. After this, data signals are arranged according to the pattern. Further, similarly to the above-described third and fourth embodiments, the arrangement signal that instructs the arrangement of the data signal is multiplexed with the data signal.

When the transmission quality indicated by the transmission quality detection signal QS is good and the fading pitch indicated by the fading detection signal FS is high, the slot multiplexing circuit 15 is arranged so as to be adjacent to the first pilot signal PS1. Place the data signal. When the transmission quality indicated by the transmission quality detection signal QS is poor and the fading pitch indicated by the fading detection signal FS is low, the data signal is arranged in the central portion of the slot. Further, when the transmission quality indicated by the transmission quality detection signal QS is good and the fading pitch indicated by the fading detection signal FS is low, the quality of the data signal is determined to be the highest in accordance with the degree thereof. Place the data signal at the optimum position.

As described above, in the fifth embodiment, since the data signal is arranged at the optimum position according to the transmission quality and the fading pitch, the error of the reference phase used for synchronous detection can be minimized. As a result, it is possible to significantly reduce the error rate.

6. Modifications The present invention is not limited to the above-described embodiments, and various modifications are possible, for example, as follows.

In the third to fifth embodiments described above, the data transmission devices 10 and 20 have been described as an example in which two-way simultaneous communication is possible by using two frequency bands, but the present invention is not limited to this. Not limited to
It can also be applied when simultaneous communication is not allowed. For example, when the user data UD is transmitted from the data transmission device 10 to the data transmission device 20, transmission and reception may be alternately repeated for each slot. Specifically, from a data transmission device 10 to a data transmission device 20 in a certain slot.
If the data signal is transmitted to the data transmission device 20, the data transmission device 20 that receives the data signal detects at least one of the transmission quality detection signal FS and the fading detection signal FS. Then, in the next slot, the detected signal is transmitted from the data transmission device 20 to the data transmission device 10. Then, in the next slot, the data transmission device 10 arranges the data signal based on the transmission quality detection signal QD received in the preceding slot, multiplexes the arrangement signal and the data signal, and outputs this signal. Send. Thereafter, transmission and reception are alternately repeated to transmit the data signal.

In the above embodiment, when variable rate data transmission is performed, a certain slot has a capacity of 8 kb.
Of course, the transmission rate of the data signal may be switched in units of slot, such as ps, 32 kbps in the next slot, and 16 kbps in the next slot.
In the above embodiment, the data transmission device 20 is
The end of the data signal may be determined by the coincidence of the error detection signals.

In the above third to fifth embodiments, the placement signal may be placed at a predetermined location in the slot, for example, the first pilot signal PS.
It may be arranged immediately after 1.

[0044]

As described above, according to the features of the invention of the present invention, since the data signal is arranged in the central portion of the slot, the error rate of the data signal is low when the signal-to-noise ratio of the transmission line is low. Can be reduced. Also, since the data signals are arranged adaptively according to the transmission quality and fading pitch, even if the environment of the transmission line changes, the data signals can be arranged according to this and the error rate can be reduced. It can be significantly reduced.

[Brief description of drawings]

FIG. 1 is a block diagram for explaining a first embodiment of a data transmission system using a data signal transmitting method according to the present invention.

FIG. 2 is a diagram showing another example of a configuration of slots according to the same embodiment.

FIG. 3 shows a first slot configuration according to the second embodiment.
It is a figure showing the example of.

FIG. 4 is a diagram showing a second example of the configuration of slots according to the embodiment.

FIG. 5 is a diagram showing a third example of the configuration of slots according to the embodiment.

FIG. 6 is a block diagram of a data transmission system according to a third embodiment.

FIG. 7 is a diagram showing a relationship between transmission quality indicated by a quality detection signal and an arrangement of data signals according to the same embodiment.

FIG. 8 is a block diagram of a data transmission system according to a fourth embodiment.

FIG. 9 is a diagram showing the relationship between the transmission quality and the arrangement of data signals indicated by the quality detection signal according to the embodiment.

FIG. 10 is a block diagram of a data transmission system according to a fifth embodiment.

FIG. 11 is a diagram showing a configuration of slots related to conventional data signal transmission.

[Explanation of symbols]

 PS Pilot signal 10, 20 Data transmission device 15 Slot multiplexing circuit 24 Synchronous detection circuit QD Transmission quality detection circuit QS Transmission quality detection signal FD Fading pitch detection circuit FS Fading detection signal

Claims (7)

[Claims] 1. Used in combination with a data signal reception method of reproducing a reference phase at each timing of a modulated data signal based on each pilot signal indicating a modulation reference phase and demodulating the data signal. In the data signal transmitting method, which transmits the data signal in a burst manner, arranges the data signal between the pilot signals to form a slot, and transmits a plurality of the slots, A data signal transmitting method, comprising arranging the data signal in a central portion of the slot. 2. The method is used in combination with a data signal receiving method of reproducing a reference phase at each timing of a modulated data signal on the basis of each pilot signal indicating a reference phase of modulation and demodulating the data signal. In the data signal transmitting method, which transmits the data signal in a burst manner, arranges the data signal between the pilot signals to form a slot, and transmits a plurality of the slots, A data signal transmitting method, characterized in that a data signal to be transmitted within one slot period is divided into a plurality of data blocks, and the plurality of data blocks are dispersedly arranged in the slots. 3. A data signal receiving method for demodulating the data signal by reproducing the reference phase at each timing of the modulated data signal based on each pilot signal indicating the modulation reference phase. In the data signal transmitting method, which transmits the data signal in a burst manner, arranges the data signal between the pilot signals to form a slot, and transmits a plurality of the slots, A data signal transmission method, wherein the arrangement of the data signal in each slot is varied according to a predetermined rule. 4. The data signal transmitting method according to claim 3, wherein a slot in which the data signal is arranged adjacent to the pilot signal and a slot in which the data signal is arranged in a central portion are alternately arranged. A data signal transmitting method characterized by transmitting. 5. The method is used in combination with a data signal receiving method of reproducing a reference phase at each timing of a modulated data signal based on each pilot signal indicating a reference phase of modulation and demodulating the data signal. In the data signal transmitting method, which transmits the data signal in a burst manner, arranges the data signal between the pilot signals to form a slot, and transmits a plurality of the slots, A data signal transmitting method, comprising: detecting a transmission state of a transmission line; and adaptively varying an arrangement of the data signals to be transmitted within one slot period based on the detected transmission state. 6. The data signal transmitting method according to claim 5, wherein the transmission quality of the transmission path is detected as the transmission state, and when the detected transmission quality is high, the pilot signal is adjacent to the pilot signal. A data signal transmitting method comprising arranging a data signal and arranging the data signal in a central portion of the slot when the detected transmission quality is low. 7. The data signal transmitting method according to claim 5, wherein a fading pitch of a transmission path is detected as the transmission state, and when the detected fading pitch is high, the fading pitch is set to be adjacent to the pilot signal. A data signal transmitting method comprising arranging a data signal and arranging the data signal in a central portion of the slot when the detected fading pitch is low.