JP3068498B2 - Time alignment control method and device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station modulation / demodulation system, and more particularly to a time alignment control method and apparatus.

[0002]

2. Description of the Related Art FIG. 1 shows a configuration of a base station modulation / demodulation system. The switching center 101 and the voice processing device 102 communicate voice data via the multiplex transmission path 103. Further, the audio processing device 102 performs communication of audio data through the plurality of base station modems 104 and the external transmission path 105,
The base station modem 104 uses the radio section to
06.

FIG. 2 shows a configuration diagram of a base station modem.
Line interface unit 201 (hereinafter, line I / F unit)
Performs an interface between the external transmission path 105 connected between the voice processing apparatus 102 and the base station modem 104 and the internal transmission path. Timing generation circuit 202
Generates the internal transmission line clock 205 synchronized with the audio data from the audio processing device 102. In the base station modem 104, a plurality of transmission / reception cards 206 are installed,
The input / output interface of each wireless section is an amplifier 20
7 is connected. The transmission / reception card 206 has a line I /
The data of the downlink transmission path 203 in the device (hereinafter referred to as “downlink transmission path”) from the F unit 201 is received, and the mobile station 106
Send to The data received from the mobile device 106 is demodulated by the transmission / reception card 206 and then transmitted to the line I / F unit 20 using the in-apparatus uplink transmission path 204 (hereinafter, uplink transmission path).
1 is output. The line I / F unit 201 outputs audio data from the transmission / reception card 206 to the external transmission path 105,
The communication with the voice processing device 102 is performed.

FIG. 3 shows a transmission line time slot configuration.
The transmission path 301 in the base station (hereinafter referred to as a transmission path) includes serial data 501 in the transmission path synchronized with the BIT clock 407.
(Hereinafter, serial data). The serial data 501 is divided into octets, and
Of the time slots 302 (TS0 to TS31). In order for the transmission / reception card 206 to recognize the number of the time slot 302 of the transmission path 301, the BIT
A time slot reference clock 408 (hereinafter, TS reference clock) synchronized with the clock 407 is provided.

The time slot 302 is composed of 320 frames with one frame of data in octets, and includes a downlink transmission line synchronization frame 502 (hereinafter, synchronization frame) and 12-channel analysis audio data (I _{0 to} I _0).
11 ) and a TA control value frame 503 (valid only for uplink). The transmission time (T ₂ ) of 320 frames in the time slot 302 is T ₁ (one frame transmission time) × 320 frames = T ₂
(320 frame transmission time). Since the transmission / reception card 206 has audio processing capability for six channels, the two transmission / reception cards 206
01 time slots 302 are shared, and 12 channels of audio data (I _{0 to} I ₁₁ ) are communicated in a time sharing manner.
The two transmission / reception cards 206 are controlled as a first transmission / reception card 303 / a second transmission / reception card 304.

The frame structure 50 of the time slot 302
4, a synchronization frame 502 (frame 0) is prepared. The two transmission / reception cards detect the synchronization frame 502 from the data extracted from the downlink transmission line 203 and synchronize the data, thereby obtaining time slots. The inner frame configuration 504 can be recognized. Also, line I / F2
01, the second transmission / reception card 304 is connected to the upstream transmission path 204 for transferring the audio data to the audio processing apparatus 102.
Having a TA control value frame 503 for notifying the TA control values after I _11-frame is an access region.

FIG. 4 shows a block diagram of a conventional transmitting / receiving card. The time slot detection unit 404 has a function of recognizing the designation of the time slot 302 of the transmission / reception card 206 and the designation of the first transmission / reception card 303 / second transmission / reception card 304 from the mounting position data 409 in the device. The downlink transmission line data detection unit 401 recognizes the time slot configuration in the downlink transmission line 203 from the TS reference clock 408 and the BIT clock 407, and according to the mounting position information 412 from the time slot detection unit 404, , And performs serial / parallel conversion to report to the control unit 405 using the internal bus 410 as downlink audio data.

The control unit 405 receives the synchronization frame 502 from the downlink audio data from the downlink transmission line data detection unit 401.
(Frame 0). Also, TS reference clock 4
It has a frame counter 411 (counting from 0 to 319) synchronized with 08, and when the synchronization frame 502 is detected, sets the counter number of the frame counter 411 to “0”. By synchronizing the frame counter 411 with the frame number of the downlink transmission path 203, the control unit 405 specifies the frame assigned to its own card in the time slot frame configuration 504 shown in FIG. Only when the downlink transmission path 20
3 to extract audio data. Frame counter 411
Are synchronized, the control unit 405 sets the frame counter number “0”.
Sometimes, it recognizes that the data on the downlink transmission line is the synchronization frame 502, and constantly monitors the state of synchronization with the downlink transmission line 203. If there is no synchronization frame 502 at the position of the frame counter number “0”, it is recognized that synchronization has been lost, the synchronization frame 502 is searched, and resynchronization is performed. During this time,
Since the control unit 405 is not synchronized with the downlink transmission line, it is impossible to normally communicate with the downlink transmission line data, and the downlink voice is momentarily interrupted.

The voice data extracted from the downlink transmission path 203 is subjected to modulation processing in the control section 405 and transmitted to the radio section 406 in synchronization with the radio section transmission reference timing 416. The received data 415 from the wireless unit 406 is subjected to demodulation processing by the control unit 405, and is set in the uplink transmission line data output control unit 402 using the internal bus 410. The uplink transmission line data output control unit 402 inserts the uplink audio data (six channels) from the control unit 405 into the time slot 302 specified by time division.

FIG. 5 shows the relationship between the downlink transmission line and the wireless section transmission reference timing when the transmission / reception card is activated, and FIG. 6 shows the relationship between the downlink transmission path and the wireless section transmission reference timing during conventional time alignment control.

The data (A) in the downlink transmission line 601 at the time of activation
₀ & A ₁ ) indicates a frame structure 504 (320 frames) in the time slot in the designated time slot 302, A ₀ is audio data for the first transmission / reception card 303, and A ₁ is a voice data for the second transmission / reception card 304. Indicates audio data. Downlink transmission path extraction data 602 /
Reference numeral 603 denotes audio data extracted from the multiplexed data of the downlink transmission line 601 respectively.
Reference numeral 6 denotes a synchronization frame 50 with which each control unit 405 is synchronized.
2 (0 frame). Although the downlink transmission line 601 and the wireless section transmission reference timing 416 operate at the same period (T ₂ ), they are not synchronized, and thus the voice extracted in synchronization with the downlink transmission line 601 as shown in FIG. The data (A ₀ / A ₁ ) corresponds to the wireless section transmission reference timing 41.
It is transmitted in synchronization with (a) of FIG. At this time,
The maximum value of the generated delay time a is one cycle of the wireless section transmission reference timing 416 (a <T ₂ ).

Therefore, the control unit 405 of the second transmission / reception card 304 calculates the delay time a between the downlink transmission path 601 and the wireless section transmission reference timing 416, and
4 is reported to the audio processing device 102 as the TA control amount using the TA control value frame 503 on 4. Since the voice processing apparatus 102 outputs the data of the downlink transmission line in a shifted manner in accordance with the TA control amount b from the second transmission / reception card 304, the radio section transmission reference timing after the TA control 704 is as shown in FIG. Downlink channel data 7 for 416
01 is shifted from the conventional position. At this time,
Second transmission / reception card 304 requesting TA control 704
Recognizes the TA control amount b by the audio processing device 102, and therefore, the synchronization frame 502 is previously determined by the downlink transmission line synchronization timing 606, which is conventionally synchronized, and the downlink transmission line synchronization timing 702 after TA control. It becomes possible to monitor. Therefore, the data (C ₁ ) can be extracted without losing synchronization with the downlink transmission path 701 during the TA control, and the extracted data (C ₁ ) can be transmitted at the wireless section reference timing 416 (B). Which is the shortest delay time.

However, since the first transmission / reception card 303 cannot recognize in advance the TA control by the voice processing device 102, the synchronization frame 502 is continuously monitored at the position of the conventional downlink transmission line synchronization timing 606. for that reason,
Synchronization with the downlink transmission line 701 after the TA control is lost and resynchronization occurs, and the downlink audio is momentarily interrupted.

[0014]

A first problem of the prior art is that the first transmission / reception card always loses synchronization with the downlink transmission line during the time alignment control, resulting in resynchronization processing.
That is, the down voice is momentarily interrupted. The reason is that the time alignment control value reported from the transmission / reception card to the voice processing device is mapped to the second transmission / reception card portion on the downlink transmission path, so that only the second transmission / reception card can perform time alignment control. Cannot recognize the contents of the time alignment control. Therefore, at the time of the time alignment control, it is impossible to detect the downlink transmission line synchronization frame at the conventional downlink transmission line synchronization timing and the downlink transmission line synchronization frame position after TA control, so that the downlink transmission line resynchronization occurs. Because.

A second problem of the prior art is that both the first transmitting and receiving card and the second transmitting and receiving card can cope with the solution of the first problem. The reason is,
This is because if the first transmission / reception card is made of dedicated hardware, the productivity is deteriorated and an operation error at the time of installation or the like is caused.

An object of the present invention is to provide a base station modulation / demodulation system which solves the above-mentioned problems.

Another object of the present invention is to provide a time alignment control method and apparatus in such a base station modulation / demodulation system.

[0018]

According to the base station modulation / demodulation system of the present invention, two (first / second) transmission / reception cards use time slots in octet units in a downlink transmission line in a time-division manner. And modulates the voice data received from the wireless section and transmits the modulated data to a wireless section.

According to the time alignment control method of the present invention,
A base station modulation / demodulation system in which first and second transmission / reception cards use time slots in a downlink transmission path in a time- division manner, modulate audio data taken from the time slots, and transmit the modulated data to a wireless section. The audio processing that detects the difference between the timing of extracting the audio data from the downlink transmission line and the transmission timing to the wireless section, and outputs the detected value to the downlink transmission line using the time alignment control frame to output the audio data on the downlink transmission line. By reporting to the device, the audio processing device changes the frame arrangement of the downlink audio data in the time slot so that the difference between the timing of extracting the audio data from the downlink transmission line and the transmission timing to the radio section is minimized. In the time alignment control method to be performed, the voice processing device Further the in time, characterized in that it does not cause a desynchronization of the downlink transmission path of the first transceiver card.

Further, the alignment control device of the present invention includes a transmission line in the device constituted by serial data for communicating audio data with the audio processing device, a BIT clock synchronized with the serial data in the transmission line, and a serial communication device. A time slot composed of 8 bits of data, a time slot reference clock for recognizing the time slot configuration, and a time slot detecting unit for recognizing the designation of the time slot in the transmission path based on the mounting position data of the transmitting / receiving card; A downlink transmission line data detection unit that extracts data of a designated time slot from the downlink transmission line and performs serial / parallel conversion; a downlink transmission line data output control unit that inserts uplink audio data into the designated time slot of the transmission line; Control value detector for monitoring a TA control value frame in a time slot of a road A frame counter that counts a frame number based on a time slot reference clock; and a control unit that receives an output corresponding to the detected time slot as an input. The control unit has an internal bus for reading and writing data. Performs time alignment control that does not cause the downlink transmission path of the first transmission / reception card to be out of synchronization when the data arrangement in the time slot is changed.

By providing the transmission / reception card with a TA control value detection unit, the second transmission / reception card detects the information instructed in the TA control value frame on the uplink transmission line, and detects a control value different from the previous time alignment control value. When a time alignment control instruction is issued, a control value is reported to the control unit, and the time alignment control value is recognized.

In this way, the first transmission / reception card also synchronizes in advance with the conventional downlink transmission line synchronization timing position and the downlink transmission line synchronization frame position detected after the time alignment control during the time alignment control by the second transmission / reception card. When the frame is detected and the data of the downlink transmission line is changed by the audio processing device, the downlink transmission line does not lose synchronization.

[0023]

Embodiments of the present invention will now be described with reference to the drawings.

FIG. 7 shows a transmission line configuration in which two transmission / reception cards in the base station apparatus of the present invention are assigned to one time slot. The transmission path 301 in FIG.
Audio data communication is performed between the audio processing device 102 in the base station modulation / demodulation system and the plurality of transmission / reception cards 206 via the / F unit 201. Further, a time slot 302 is provided in the transmission path 301 and two transmission / reception cards 2 are provided.
06 uses one time slot 302 in a time division manner. The transmission / reception cards 206 are all composed of the same hardware, and are controlled as a first transmission / reception card 303 and a second transmission / reception card 304 in order to use the shared time slot 302 in a time-division manner.

FIG. 8 is a block diagram showing a transmission / reception card according to an embodiment of the present invention. Between the voice processing device 102 and the transmission / reception card 206, there is an upstream transmission line 204 and a downstream transmission line 203 for voice data communication in the device via a line I / F unit 201, and a reference clock for voice data transmission. A BIT clock 407 and a TS reference clock 408.

In FIG. 8, a time slot detector 40
4 designates the designation of the time slot 302 of the own card from the mounting position data 409 of the transmitting / receiving card 206, and the first
Of the transmission / reception card 303 or the second transmission / reception card 304, and the control unit 405 as the mounting position information 412.
Report to The downlink transmission path data detection unit 401 extracts audio data of the own card from the downlink transmission path 203, performs serial / parallel conversion, and reports the result to the control unit 405 using the internal bus 410. The control unit 405 performs modulation processing on the downlink audio data, and transmits the data to the wireless unit 406 in synchronization with the wireless section transmission reference timing 416. The reception data 415 from the radio unit 406 is subjected to demodulation processing by the control unit 405, and is transmitted to the uplink transmission line data output control unit 40 using the internal bus 410.
2 and inserted into the time slot 302 assigned to the own card. The TA control value detection unit 403 constantly monitors the TA control value frame 503 on the uplink transmission line 204, and reports a TA control value 413 to the control unit 405 when a TA control request by the second transmission / reception card 304 is detected. .

FIG. 3 shows a configuration of one time slot in a transmission line according to an embodiment of the present invention. As described above, the transmission path 301 is configured by the serial data 501 synchronized with the BIT clock 407, and the serial data 501 is divided into octets to form 32 time slots 302 (TS0 to TS31). I have. In order for the transmission / reception card 206 to recognize the time slot 302 of the transmission path 301, the BIT clock 4
07 has a TS reference clock 408 synchronized with it.

The time slot 302 is composed of 320 frames with data of one octet as one frame, and includes a synchronization frame 502, audio data (I _{0 to} I ₁₁ ) for 12 channels, and a TA control value frame 503 (uplink). Only valid). 3 in time slot 302
The transmission time (T ₂ ) of 20 frames is T ₁ (transmission time of one frame) × 320 frames = T ₂
(320 frame transmission time).

Since the transmission / reception card 206 has an audio processing capability for six channels, the two transmission / reception cards 206 share each time slot 302 of the transmission path 301, and time-divisionally cope with 12 channels of audio data (I0 to _{I0). 11} ) is communicated with the voice processing device 102.

Frame structure 50 of time slot 302
4, a synchronization frame 502 (frame 0) is prepared, and the two transmission / reception cards 206 are connected to the downlink transmission path 20.
By detecting and synchronizing the synchronization request frame 502 from the data extracted from No. 3, it is possible to recognize the frame configuration 504 in each time slot.

Further, in the up transmission line 204 to the audio processing unit 102 transfers the voice data, TA control value frame 503 for notifying the TA control amount b to I ₁₁ frames after an access area of the second transceiver cards 304 Having.

As one embodiment of the present invention, the operation of two transmission / reception cards sharing a time slot (TS0) will be described in detail.

Each transmission / reception card detects the designated time slot 302 (TS0) and the designation of the first transmission / reception card 303 or the second transmission / reception card 304 from the mounting position data 409 in the device by the time slot detection unit 404,
This is reported as mounting position information 412.

The downlink transmission path data detecting section 401 recognizes the time slot configuration in the downlink transmission path 203 from the TS reference clock 408 and the BIT clock 407, and specifies the designated time slot 302 according to the mounting position information 412 from the time slot detecting section 404. After extracting the serial data 501, serial / parallel conversion is performed, and the data is reported to the control unit 405 using the internal bus 410 as downlink audio data.

The control section 405 receives the synchronization frame 502 from the downlink audio data from the downlink transmission path data detection section 401.
(Frame 0). Also, TS reference clock 4
08 and the frame counter 411 (from 0 to 319)
The counter number of the frame counter 411 is set to “0” when the synchronization frame 502 is detected. By synchronizing the frame counter 411 with the frame number of the downlink transmission path 203, the control unit 405 determines that the counter number of the frame counter 411 is the frame allocated to the own card in the time slot frame configuration 504 shown in FIG. Extract data only when specified.

After the frame counter 411 is synchronized, when the frame counter number is "0", the control unit 405 recognizes that the downlink audio data is the synchronization frame 502, and constantly monitors the state of synchronization with the downlink transmission line 203. . If there is no synchronization frame 502 at the position of the frame counter number “0”, it is recognized that synchronization has been lost, the search processing of the downlink transmission line synchronization frame 502 is performed, and resynchronization is performed. During this time, since the control unit 405 is not synchronized with the downlink transmission line 203, it cannot correctly extract the downlink transmission line data, and an instantaneous interruption of the downlink voice occurs.

The audio data extracted from the downlink transmission path 203 is subjected to modulation processing by the control section 405 and transmitted to the radio section 406 in synchronization with the radio section reference timing 416.

FIG. 5 shows the relationship between the downlink transmission path and the wireless section transmission reference timing when the transmission / reception card is activated, as described above. The data (A ₀ & A ₁ ) in the downlink transmission path 601 at the time of activation indicates the frame configuration 504 (320 frames) in the time slot in TS ₀ , where A ₀ is the audio data for the first transmission / reception card 303 and A ₁ Is the second
5 shows audio data for the transmission / reception card 304 of FIG.

The downlink transmission path extraction data 602/603 is
The audio data extracted from the multiplexed data of the downlink transmission line 601 is shown. The downlink transmission line synchronization timing 606 indicates the position of the synchronization frame 502 (0 frame) with which each control unit 405 is synchronized. As shown by the wireless section transmission data 604 of the first transmission / reception card, the first transmission / reception card 30
3 is audio data (A ₀ ) extracted from the downlink transmission path 601
Is the first wireless section transmission reference timing 41 after the extraction is completed.
It is transmitted in synchronization with 6 (a). The downlink transmission path 601 and the wireless section transmission reference timing 416 have the same cycle (T ₂ )
However, since the two are not synchronized, a delay time a occurs between the completion of the downlink transmission path data extraction and transmission to the wireless section, and the maximum value is one cycle of the wireless section transmission reference timing 416. (A <T ₂ ).

Frame structure 50 in the time slot shown in FIG.
As shown in FIG. 4, the audio processing device 1
02, a TA control frame 503 for reporting the TA control amount b
Is in the position assigned to the second transmission / reception card 304. Therefore, when the delay time a occurs, the control unit 405 of the second transmission / reception card 304 has the least delay time with respect to the wireless section transmission reference timing 416 from the relationship between the downlink transmission path extraction data 603 and the wireless section transmission reference timing 416. The data pattern of the downstream transmission path 601 is calculated, and the TA control amount b is reported using the TA control value frame 503 on the upstream transmission path 204.

FIG. 9 shows the relationship between the transmission path and the transmission timing of the radio section during the time alignment control. The TA control value detection unit 403 of the transmission / reception card 206
Constantly monitors the TA control value frame 503 in the
The TA control amount b reported from the transmission / reception card 304 to the voice processing device 102 is detected, and if the content differs from the previous monitoring content, the difference between the two is calculated and the TA control value 41 is supplied to the control unit 405.
Report as 3.

The control unit 405 uses the TA control value 413 from the TA control value detection unit 403 to
3, the monitoring of the synchronization frame 502 is started in advance at the downlink transmission line synchronization timing 606 that is currently synchronized and the downlink transmission line synchronization timing 702 that is changed by the audio processing device 102 by the TA control. I do.

As shown in the downlink transmission path 701 at the time of TA control, the audio processing apparatus 102 that has transmitted downlink data (Z ₀ & Z ₁ ) in the frame configuration 504 in the time slot of the downlink transmission path 601 from the time of activation is , The second transmitting / receiving card 3
In accordance with the TA control amount b reported as the TA control request 703 of No. 04, the frame configuration 504 in the time slot of the downlink transmission line 701 is shifted by (a) frame, and data after the synchronization frame is changed (C ₀ & C ₁ ).

The first transmission / reception card 303 has a synchronization file in advance.
Downlink transmission line synchronization timing after TA control of frame 502
Since the monitoring is performed at 702, the first transmission / reception card goes down.
As shown by the transmission path extraction data 602, the
Data (C ₀& C₁ ) Out of sync
Extraction without causing (C₀ )can do. this
Since the function also functions with the second transmission / reception card 304, the second
The second transmission / reception card 304 is also different from the first transmission / reception card.
Without performing the same control, the downlink transmission path data (C
₁ ) Can be extracted.

The audio data (C ₀ ) after TA control extracted from the downlink transmission path 701 is transmitted to the wireless section in synchronization with the wireless section transmission reference timing 416 (b).
Since the delay adjustment by the A control is performed, the delay time is minimized.

[0046]

According to the present invention, the first transmission / reception card does not lose synchronization with the downlink transmission line during the time alignment control, so that instantaneous interruption of downlink audio due to resynchronization of the downlink transmission line does not occur, so that communication quality is improved. Is improved. The reason is,
In a conventional TA control method using a TA control value frame in an uplink transmission line by a second transmission / reception card, a TA control value detection unit that monitors a TA control value frame in an uplink transmission line has a first configuration. This is because also in the transmitting / receiving card, the TA control amount requested by the second transmitting / receiving card is detected, and the control unit monitors and follows the synchronization frame in advance at the position after the TA control.

Further, according to the present invention, since the first effect is realized by common hardware, mass production of transmission / reception cards becomes possible, and there is no difference in operation, so that errors such as installation do not occur. The reason is that a TA control value inspection unit is provided to monitor the TA control value frame of the uplink transmission path,
Since the control unit recognizes the TA control value by the monitoring report,
This is because they can be controlled by common software.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a base station modulation / demodulation system.

FIG. 2 is a configuration diagram of a base station modem.

FIG. 3 is a configuration diagram of a transmission line time slot.

FIG. 4 is a block diagram of a conventional transmitting / receiving card.

FIG. 5 is a diagram illustrating a relationship between a downlink transmission path and a wireless section transmission timing at the time of activation.

FIG. 6 is a diagram illustrating a relationship between a transmission path and a wireless section transmission timing during conventional time alignment control.

FIG. 7 is a diagram illustrating a configuration of a transmission line in a base station device.

FIG. 8 is a block diagram of a transmission / reception card of the present invention.

FIG. 9 is a diagram illustrating a relationship between a transmission path and wireless section transmission timing during time alignment control.

[Explanation of symbols]

 Reference Signs List 101 switching station 102 voice processing device 103 multiplex transmission line 104 base station modem 105 external transmission line 106 mobile station 201 line interface section 202 timing generation circuit 203 in-device downstream transmission line 204 in-device upstream transmission line 205 internal transmission line clock 206 transmission / reception Card 207 amplifier 301 transmission line in base station 302 time slot 303 first transmission / reception card 304 second transmission / reception card 401 downlink transmission line data detection unit 402 uplink transmission line data output control unit 403 TA control value detection unit 404 time slot detection unit 405 Control unit 406 Wireless unit 407 BIT clock 408 TS (time slot) reference clock 409 Mounting position data 410 Internal bus 411 Frame counter 412 Mounting position information 413 TA control value 414 Wireless section Inter-transmission data 415 Wireless section reception data 416 Wireless section transmission reference timing 501 Serial data in transmission path 502 Downlink transmission path synchronization frame 503 TA control value frame 504 Time slot frame configuration 601 Downlink transmission path at start-up 602 First transmission and reception Card downlink transmission path extraction data 603 Second transmission / reception card downlink transmission path extraction data 604 First transmission / reception card wireless section transmission data 605 Second transmission / reception card wireless section transmission data 606 Downlink transmission path synchronization timing 607 Delay time 701 TA control Downlink transmission path 702 Downlink transmission path synchronization timing after TA control 703 TA control request 704 TA control 705 TA control amount

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 H04Q ⁷ /00-7/38

Claims (4)

(57) [Claims] 1. A time slot in a downlink transmission line is used by a first and second transmission / reception card in a time-division manner, and the second transmission / reception card extracts audio data from the downlink transmission line and transmission timing to a wireless section. The difference between
By using the time alignment control frame in the uplink transmission path to report the detected value to the audio processing apparatus that is outputting audio data on the downlink transmission path, the audio processing apparatus can extract the audio data from the downlink transmission path with the timing. A time alignment control method characterized by changing a frame arrangement of downlink audio data in a time slot so as to minimize a difference in transmission timing to a radio section. 2. The voice processing apparatus changes the data arrangement in a time slot by monitoring a time alignment control value designated by a time alignment control frame on an upstream transmission line in the first transmission / reception card. 3. The time alignment control method according to claim 2, wherein the synchronization of the downlink transmission path of the first transmission / reception card is not caused when the synchronization is performed. 3. A base station modulation / demodulation system in which first and second transmission / reception cards use time slots in a downlink transmission path in a time- division manner, modulate audio data taken from the time slots, and transmit the modulated data to a radio section. The second transmission / reception card detects a difference between the timing of extracting the audio data from the downlink transmission line and the transmission timing to the wireless section, and outputs the detected value to the downlink transmission line using the time alignment control frame in the uplink transmission line. Reporting to the voice processing device that is performing the processing, the voice processing device transmits the downlink voice data in the time slot so that the difference between the timing of extracting the voice data from the downlink transmission line and the transmission timing to the wireless section is minimized. In the time alignment control method for changing a frame arrangement, the audio processing device may be configured to execute a time slot A time alignment control method, wherein when the data arrangement in the first transmission / reception card is changed, the downlink transmission path of the first transmission / reception card is not out of synchronization. 4. An alignment in a base station modulation / demodulation system in which first and second transmission / reception cards use time slots in a downlink transmission path in a time- division manner, modulate audio data taken from the time slots, and transmit the modulated data to a radio section. The control device comprises a transmission line in the device configured by serial data for communicating voice data with the voice processing device, a BIT clock synchronized with the serial data in the transmission line, and eight bits of serial data. A time slot, a time slot reference clock for recognizing the time slot configuration, a time slot detecting unit for recognizing the designation of the time slot in the transmission path based on the mounting position data of the transmission / reception card, and Downlink transmission path data detection that extracts data and performs serial / parallel conversion A downlink transmission line data output control unit that inserts uplink audio data into a designated time slot of the transmission line; a TA control value detection unit that monitors a TA control value frame in a time slot of the uplink transmission line; A frame counter that counts the frame number according to, and a control unit that receives the output of the time slot detection unit as an input. The control unit has an internal bus that reads and writes data, so that the audio processing device An alignment control device, wherein when the data arrangement is changed, the downlink transmission path of the first transmission / reception card is not out of synchronization.