JP3432702B2 - Digital signal transmission / reception processing apparatus and digital signal transmission / reception processing method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission / reception processing device for efficiently performing digital transmission / reception processing in digital communication. In particular, it relates to a framing / deframing processing method.

[0002]

2. Description of the Related Art In digital communication, transmission / reception processing is performed by using a frame composed of a bit string of a predetermined length as a processing unit. When constructing a transmission frame, digital processing such as error correction coding, scrambling, and unique word addition is required (hereinafter, these processings are called framing). On the other hand, when receiving a frame, it is necessary to cancel the digital processing as described above and extract the received information from the frame (these processing will be referred to as deframing hereinafter).

FIG. 12 shows an example of the configuration of a digital transmission / reception processing device. FIG. 12 cites “Baseband Processing for Mobile Satellite Communication Using DSP (Digital Signal Processor)”, IEICE Technical Research Report, SAT96-70, FIG. In FIG. 12, the framing / deframing processing unit 1 constructs or disassembles a frame on a line. The modulator 2 includes a framing processor 1a.
Modulate a carrier (eg, carrier wave) with the signal from. The demodulation unit 3 demodulates a digital signal from the received signal. The voice codec 4 converts voice data into a digital signal, or vice versa. The main processor 5 performs the core processing of the digital transmission / reception processing device.

In the digital transmission / reception processing device configured as shown in FIG. 12, the framing processing unit 1a receives transmission information from the voice codec 4 or the main processor 5, constructs a frame on the line, and the modulation unit 2
Pass to. On the other hand, the deframing processing unit 1b includes the demodulation unit 3b.
The digital information extracted by deframing the received frame on the line is passed to the voice codec 4 or the main processor 5. The framing / deframing processing unit 1 has, for example, a configuration as shown in FIG.

The length of a frame is determined by a trade-off that combines superiority of communication conditions such as the environment of the line, the processing capacity of the transmission / reception processing device, and the line efficiency. The longer the frame, the shorter the proportion of the overhead for performing preprocessing (for example, saving the state before performing processing, starting a processing program, etc.), and improving the line efficiency. On the other hand, increasing the frame length also causes a problem that the transmission / reception processing device is required to have the ability to perform a large amount of processing at a time. In addition, in a line environment such as wireless communication in which the probability of error in digital data in a frame is higher than in wire communication, using a long frame increases the risk of information loss. . In particular, the present invention focuses on the former problem as a problem directly related to the present invention.

When performing framing / deframing processing by software using a high-speed communication processor or a digital signal processor (hereinafter referred to as DSP), in general, a frame is divided into predetermined processing units and the framing / deframing is performed. Rather than doing framing
If some of the above processing units are combined into one, the processing overhead becomes smaller. Also, the overall load is reduced. In practice, a frame unit is often selected, which is a unit that facilitates framing / deframing processing.

14 to 17 are flowcharts showing the operation of the framing / deframing process. Figure 1
4, FIG. 15 shows a processing configuration divided into symbol units. FIG. 16 and FIG. 17 show a processing configuration grouped in frame units. Here, the symbol means the minimum unit on the time axis when transmitting the digital signal of the transmission / reception frame. For example, "Clock 1 for transmitting digital data
The "cycle" has the closest meaning (however, how many bits of data can be transmitted in one symbol depends on the modulation method). Reference numerals 71a in FIG. 14 and 71b in FIG. 15 show specific processing procedures of deframing and framing in the processing configuration divided in symbol units. Reference numerals 15a in FIG. 16 and 15b in FIG. 17 show specific processing procedures of deframing and framing in a processing configuration in which they are collectively processed in frame units. As shown in FIGS. 14 and 15, processing 71a, 71 for each symbol is performed.
In b, the process is repeated for the number of symbols included in one frame. Therefore, each time one process is performed, one
It is determined whether processing for the number of symbols in the frame is completed. That is, although it is easy to divide the processing, it is determined whether or not the processing is finished each time the processing is repeated, so that the processing amount increases. On the other hand, in the case of the frame-by-frame batch processes 15a and 15b shown in FIGS. 16 and 17, the number of processes is calculated first (the number of processes is calculated based on the number of symbols included in one frame), and then The process is repeated a predetermined number of times. A processor such as a DSP has a built-in loop counter for assisting repeated processing. Therefore, management of the number of repetitions in batch processing in frame units does not affect the processing load. on the other hand,
In the case of such batch processing, since the number of times of processing is first determined, it is difficult to divide the processing in the middle.

By the way, SCPC (Single Channel Per
Carrier) method and FDD (Frequency Division Duplex)
) System, when different frequencies are used for the uplink and the downlink, both do not necessarily have the same frame configuration. For example, FIG. 18 shows “System s
ervices and architecture of the TMI satellite mobi
le data system ”, International Mobile Satellite C
onference 1993, pp. Figure 4 of 479-484 is redrawn for easy viewing. As shown in FIG. 18, there is also a communication system that uses frames of completely different lengths on the uplink and the downlink. Further, in the case of FIG. 18, a plurality of types of lengths can be taken even with only the uplink frame. Among them are
Like the upstream burst 3, the upstream frame length is 112
0 ms, but the downlink frame length is 238
In some cases, such as ms, the frame length of the uplink is considerably longer than that of the downlink.

Now, particularly, the framing / deframing process in the case where the frame length of the uplink becomes considerably longer than that of the downlink will be considered. FIG. 19 shows a temporal flow of a conventional transmission / reception process. FIG. 19 shows a processing flow from the standpoint of a slave station or a slave unit. That is, the downlink is used as the reception line and the uplink is used as the transmission line.

Here, it is considered that both the framing process and the deframing process are processed by one processor. Processing by one processor means that framing and deframing cannot be performed in parallel. Therefore, as shown in FIG. 19, only one of the processes is always performed. In FIG. 19, when the transmission / reception processing device receives the reception frame 24, the transmission / reception processing device performs deframing 21 on the reception frame 24. After that, since there is enough time to start the deframing process for the next received frame, the framing 26 for generating the transmission frame 25 is performed subsequent to the deframing 21. After the framing 26 is finished, the deframing process for the received frame is performed again. Since the framing 26 and the deframing 21 are processed in frame units, the processing time is shorter than that in symbol units. However, when deframing 21 for a reception frame 24 having a short frame length occurs at a relatively high frequency, if framing 26 for a transmission frame 25 having a long frame length is attempted, as shown in FIG.
The processing margin (the “processing margin” is the time from the end of the framing 26 to the start of the deframing processing of the next received frame) becomes very small or disappears. The same problem occurs when the length of the reception frame is longer than the length of the transmission frame and the transmission frame frequently occurs.

[0011]

Since the conventional transmission / reception processing device for digital communication operates as described above, when the lengths of the received frame and the transmitted frame are different from each other, it is possible to perform processing for a short frame which frequently occurs. There is a problem that the margin between the processing for a long frame and the processing for a long frame becomes extremely small or disappears temporarily. In the example as shown in FIG. 19, there is a problem that the framing process cannot be performed on a long frame, that is, a transmission frame.

The present invention has been made to solve the above problems, and an object of the present invention is to obtain a transmission / reception processing device for efficiently performing digital transmission / reception processing in digital communication. In particular, it is an object to obtain an efficient method for framing / deframing processing.

[0013]

A digital signal transmission / reception processing device according to the present invention includes a framing processing unit for processing a transmission frame, a deframing processing unit for processing a reception frame, the framing processing unit and the deframing processing unit. In the digital signal transmission / reception processing device for processing a signal in which the length of the transmission frame is longer than the length of the reception frame, the deframing processing unit and the framing processing unit process the signals. The present invention is characterized by including a processing unit determination unit that determines the processing unit based on the length of the received frame.

The processing unit determination unit divides the length of the transmission frame by the processing unit and calculates the number of times of framing processing performed to generate one transmission frame, and the division number calculation unit. And a repetition processing control unit for controlling the framing processing to be repeatedly performed until the number of processings calculated by the unit is satisfied.

The division number calculation unit calculates the number of framing processes so that a surplus transmission frame generated at the time of the above calculation is generated by the framing process in one processing unit. .

The processing unit determination section is characterized in that one processing unit is one reception frame length.

The processing unit determination section is characterized in that one processing unit is a plurality of reception frame lengths.

The processing unit determination unit is characterized in that one processing unit is a bit length obtained by dividing the received frame into a predetermined length.

A digital signal transmission / reception processing device according to the present invention includes a framing processing unit for processing a transmission frame, a deframing processing unit for processing a reception frame, a processor for controlling the operations of the framing processing unit and the deframing processing unit. In the digital signal transmission / reception processing device for processing a signal in which the length of the reception frame is longer than the length of the transmission frame, the processing unit for operating the deframing processing unit and the framing processing unit is a transmission frame. Is provided with a processing unit determining unit for determining the processing unit based on the length.

The processing unit determination unit divides the length of the received frame into the processing units and calculates the number of deframing processes performed to process one received frame, and the division number calculation unit. It is characterized by further comprising: a repetitive processing control section for controlling the deframing processing to be repeatedly performed until the number of processings calculated by the calculation section is satisfied.

The division number calculation unit calculates the number of times of deframing processing so that the processing of the excess received frames generated when the above calculation is performed is performed by the deframing processing of one processing unit. And

The processing unit determination unit is characterized in that one processing unit is one transmission frame length.

The processing unit determination unit is characterized in that one processing unit has a plurality of transmission frame lengths.

The processing unit determining section is characterized in that one processing unit is a bit length obtained by dividing a transmission frame into a predetermined length.

A digital signal transmission / reception processing method according to the present invention comprises a framing processing step of processing a transmission frame and a deframing processing step of processing a reception frame, and the length of the transmission frame is longer than that of the reception frame. A digital signal transmission / reception processing method for processing a long signal, comprising a processing unit determining step for determining a processing unit to be processed in the framing processing step and the deframing processing step based on a length of a received frame. To do.

In the processing unit determining step, the length of the transmission frame is divided into the processing units, and the number of times of framing processing for calculating one transmission frame is calculated, and the number of divisions is calculated. It is characterized in that it is provided with a repetitive processing control step of controlling the framing processing to be repeatedly performed until the number of processings calculated by the step is satisfied.

The division number calculation step is characterized in that the number of framing processes is calculated so that a surplus transmission frame generated when the above calculation is performed is performed by a framing process for one processing unit.

A digital signal transmission / reception processing method according to the present invention comprises a framing processing step of processing a transmission frame and a deframing processing step of processing a reception frame, and the length of the reception frame is longer than that of the transmission frame. A digital signal transmission / reception processing method for processing a long signal, comprising a processing unit determining step for determining a processing unit to be processed in the framing processing step and the deframing processing step based on the length of a transmission frame. To do.

The processing unit determining step divides the length of the received frame by the processing unit and calculates the number of times of framing processing performed to generate one received frame, and the division number calculating step. It is characterized by comprising a repetitive processing control step of controlling the above-mentioned deframing processing to be repeated until the number of processings calculated by the step is satisfied.

The division number calculation step is characterized in that the number of deframing processes is calculated so that the excess received frames generated when the above calculation is performed are performed by the deframing process for each processing unit.

[0031]

DETAILED DESCRIPTION OF THE INVENTION

Embodiment 1. In the first embodiment, a digital communication system that transmits and receives a digital signal in which the length of a transmission frame is longer than the length of a reception frame will be described below. FIG. 1 is a block diagram showing a partial configuration of a digital signal transmission / reception processing device. The other configuration of the digital signal transmission / reception processing device shown in FIG. 1 is the same as the configuration of the conventional transmission / reception processing device shown in FIG. In the transmission / reception processing device shown in FIG. 1, the framing / deframing processing unit 100 includes a processing unit determination unit 101 in addition to the framing processing unit 1a and the deframing processing unit 1b. The framing processing unit 1a performs the same processing as the framing processing 1a shown in FIG. Further, the deframing processing unit 1b performs the same processing as the deframing processing unit 1b shown in FIG. Processing unit determination unit 101
Is for determining the processing unit subjected to the framing processing by the framing processing unit 1a and the processing unit subjected to the deframing processing by the deframing processing unit 1b.
Further, the processing unit determination unit 101 calculates the number of framing processes performed for framing one transmission frame based on the determined processing unit, and determines the number of deframing processes performed for deframing one received frame. The division number calculation unit 102 for calculating and the framing processing unit 1a, so as to repeat the framing process or the deframing process for the calculated division number.
Alternatively, the repetitive processing control unit 103 that controls the operation of the deframing processing unit 1b is provided.

FIG. 2 is a flow chart showing the deframing procedure in the first embodiment of the present invention. Figure 3
6 is a flowchart showing a procedure of a framing process according to the first embodiment of the present invention. This Embodiment 1
Will describe an example in which the length of the transmission frame is longer than the length of the reception frame. Therefore, the processing unit is determined by the processing unit determination unit 101 based on the length of the received frame. FIG. 4 is a diagram showing a timing chart of deframing and framing processing according to the first embodiment of the present invention. In particular, the processing unit determination unit 10
1 shows the timing of the framing / deframing process when one processing unit has one received frame length. In FIG. 4, the processing unit 90 is the same as the received frame length. Therefore, after the reception of the reception frame 24 is completed, the deframing processing unit 1b starts the deframing 21 for the reception frame 24. The process of the deframing 21 is performed by the procedure of the deframing process shown in FIG. The deframing process 15a of FIG.
Is a repetitive process for each frame performed on the receiving side. The deframing process 15a is the same process as the flowchart shown in FIG. Therefore, in the calculation 151 of the number of processing times, the number of symbols in one frame is calculated by the loop counter included in the main processor 5, and the unit processing 152 is repeated a predetermined number of times.

Next, the framing process will be described. In the first embodiment, the length of the transmission frame is longer than the length of the reception frame. Therefore, one processing unit is set to one reception frame. Then, one transmission frame is divided into a plurality of processing units and framing processing is performed. The transmission frame 25 shown in FIG. 4 is divided into four processing units 90 and subjected to framing processing. In this way, when performing a framing process by dividing one transmission frame into a plurality of processing units, first, the division number calculation unit 102 calculates the division number 10 as shown in FIG. For example, in FIG.
The length of the received frame shown in is 15 ms / frame. The length of the transmission frame is 55 ms / frame. The division number calculation unit 102 sets the transmission frame of 55 ms / frame to n processing units (as described above, in the first embodiment, one reception frame length is one processing unit, so one processing unit is , The reception frame length is 15 ms) and the framing process is performed n times to generate one transmission frame. If one processing unit is 15 ms, 55 ms / frame is 55 ms / frame / 15 ms = 3, and the remainder is 10 ms.

Since the remainder is generated in the above calculation, if the remainder is subjected to the framing process in the framing 22 of the first period in FIG. 4, the number of divisions is four.
Therefore, the repetitive processing control unit 103 controls the framing processing unit 1a to perform the framing processing four times in order to generate one transmission frame. Then, the number of symbols included in each of the transmission frames divided into a predetermined length is calculated as the number of times of the framing process by calculation 11 of the number of times of processing. For example, 1 symbol is 5 ms
Then, in the framing process 13 of the first cycle, 10
10 ms / 5 m for performing framing processing for ms
From s, the number of times of processing is calculated so that the unit processing 13a is performed twice. Also, the framing process 1 after the second cycle
In No. 4, since the framing processing for 15 ms is performed in each cycle, the number of times of processing is calculated so that the framing processing is performed 3 times from 15 ms / 5 ms.

As described above, the operation shown in FIG.
This is applied when the transmission frame is longer than the reception frame as shown in the example. The deframing process 15a corresponding to a short received frame is performed as a batch process in frame units. Here, similarly to the conventional example, the number of times of processing (generally, the number of symbols) is first calculated, and the unit processing is repeated by the number of times of processing. On the other hand, in the framing process for a long transmission frame, first, the division number calculation unit 102 executes the division number calculation 10. After that, the iterative processing control unit 103 controls the execution of the processing so as to execute the loop processing 12 for the calculated number of divisions, and executes the framing processings 13 and 14 for each division.

In the first embodiment, if the frame lengths for which the divided framing processing is performed are all equal, that is, if the length of the transmission frame is an integral multiple of the reception frame, the calculation by the number of processing times 11 is performed once. The processing load can be reduced. However, depending on the system, the length of the transmission frame may not be an integral multiple of the reception frame. Therefore, in the calculation 11 of the number of processes shown in FIG. 3, first, the number of processes in each division process is obtained. The number of times of processing corresponding to the remainder is set as the number of times of processing in the first cycle. That is, in the processing of the first cycle, the number of times of processing becomes a value equal to or less than the number of times of processing after the second cycle.
After the second cycle, the number of times of processing is all equal, and recalculation of the number of times of processing is unnecessary.

As can be seen by comparing the timing chart (FIG. 4) showing the deframing processing and the framing processing performed by the procedure of FIGS. 2 and 3 with the prior art of FIG. 19, the allowance 91 of the transmission / reception processing is averaged. To be done. Then, the problem of the prior art that the processing margin 91 is exhausted at a certain timing is solved. This makes it possible to obtain a digital signal transmission / reception processing device that efficiently processes digital transmission / reception signals in digital communication.

In the timing chart shown in FIG. 4, the processing unit 90 is one reception frame length. But,
It is also possible to set two reception frames as one processing unit 90. FIG. 5 is a diagram showing a timing chart of deframing / framing processing when two received frames are set as one processing unit. In FIG. 5, the processing unit 90 is 2
It consists of one received frame 24. For example, the frame length of one reception frame is 15 ms. The deframing processing 15a shown in FIG. 2 is assumed to perform processing for two received frames. 2 Number of received frames processed (number of symbols)
Is calculated in the calculation 151 of the number of processing times. One symbol is 5m
If s, the number of processing times is 15 ms / frame × 2/5 ms = 6 times. Therefore, the deframing 21a in FIG. 5 represents the deframing process six times.

The frame length of the transmission frame 25 shown in FIG. 5 is, for example, 105 ms / frame. In the division number calculation 10 shown in FIG. 3, the division number calculation unit 102 divides the transmission frame 25 into processing units. The number of divisions is 105 ms / frame / 30 ms (1 processing unit) = 3
The remaining time is 15 ms. However, since the remainder is 15 ms, the number of divisions is 4 times. Then, in the calculation 11 of the number of times of processing,
The number of times of processing (the number of symbols) is calculated for each processing unit. When one symbol is 5 ms, the number of processing times is 30 ms / 5 ms = 6 times. Moreover, since the remainder is 15 ms, the number of processing times is 15 ms / 5 ms = 3 times in the framing processing for 15 ms. Therefore, the framing process 1 of the first cycle of FIG.
In 3, the unit process 13a is repeated three times. Then, the framing process 14 on and after the second period is repeated three times.
Furthermore, the unit process 14a in each cycle is repeated 6 times. Therefore, the framing 2 of the first period shown in FIG.
In 2a, the unit process 13a is repeated three times. In the framing 23a after the second cycle, the unit process 14a is repeated 6 times in each cycle. in this way,
The transmission frame 25 is divided into four processing units and processed.

The processing unit 90 can be set to a length obtained by dividing the received frame into a predetermined Bit length. FIG. 6 is a diagram showing a timing chart of deframing / framing processing in which a received frame is divided into predetermined Bit lengths and a processing unit is determined. In FIG. 6, the reception frame 24 is, for example, 1000 bits, and the processing unit 90 divides the reception frame 24 into 500 bits. The deframing process 15a shown in FIG.
Deframing processing is performed on the received frames of Bit (1/2 received frame). For example, 1 symbol is 100 Bi
In the calculation 151 of the number of times of processing, the number of times of processing (the number of symbols) is calculated as 500 Bit / 100 Bit = 5 times. Therefore, the unit process 152 of FIG. 2 is repeated 5 times. Therefore, the deframing 21b of FIG.
Will process the received frame for 500 bits, and the unit processing is repeated 5 times here.

Further, the frame length of the transmission frame 25 of FIG. 6 is set to 1600 Bit, for example. In the division number calculation 10 shown in FIG. 3, the division number calculation unit 102 divides the transmission frame 25 into processing units. The number of divisions is 1600 bits / frame / 500 bits (1 processing unit) = 3, and the remainder is 100 bits. However, since the remainder is 100 Bit, the number of divisions is 4. Subsequently, in the calculation 11 of the number of times of processing, the number of times of processing (the number of symbols) for each processing unit is calculated.
Assuming that 1 symbol is 100 bits, calculation of the number of processing times 1
In the case of 1, the number of times of processing is calculated as 500 Bit / 100 Bit = 5 times. However, since the remainder is 100 bits, the number of times of processing is calculated as 100 bits ÷ 100 Bit = 1 time for the remainder. Therefore, in the framing process 13 in the first cycle of FIG. 3, the framing process for the remaining 100 bits is performed, and therefore the unit process 13a is performed once. That is, in the first period framing 22b of FIG.
The unit processing 13a is performed once. Further, the framing processing 14 of FIG. 3 is performed by the framing 23 after the second period of FIG.
It corresponds to b and will be repeated 3 times. Also, the second
The unit process 14a in each cycle after the cycle is repeated five times.

As described above, in the first embodiment, in the digital signal transmission / reception processing device for processing a signal in which the length of the transmission frame is longer than the length of the reception frame, the digital processing unit of reception is one of them. Alternatively, a digital signal characterized by executing a processing unit with a plurality of frames or with a bit length obtained by dividing the frame into predetermined units and dividing the digital processing unit of transmission into digital processing units of reception. The transmission / reception processing device has been described. Further, the digital signal transmission / reception processing device has been described in which the unit of the transmission process is divided so as to be equal to the unit of the reception process, and the transmission process which is the remainder of the division is executed in the unit of one reception process.

In the digital signal transmission / reception processing device having the above-mentioned characteristics, the digital processing unit for reception is one or a plurality of frames, or the processing unit is a bit length obtained by dividing the frame into predetermined units. By dividing the digital processing unit of transmission into the digital processing unit of reception and executing the same, the digital processing of transmission that requires a long processing time is dispersed, and the processing margin temporarily becomes extremely small. Alternatively, the problem of disappearance can be solved. Further, by performing the transmission process that is the remainder of division in one reception process unit, the digital process of transmission that requires a long processing time is dispersed, and the processing margin temporarily becomes extremely small or disappears. The problem can be solved. Further, the number of processes for calculating the number of processes for each division unit is only one, and the processing load can be further reduced.

Embodiment 2. In the first embodiment,
An example in which the framing process is divided when the length of the transmission frame is longer than the length of the reception frame has been described. In the second embodiment, a transmission / reception processing device when the length of a received frame is longer than the length of a transmitted frame will be described. The frame configuration of “length of received frame> length of transmitted frame” is a problem related to transmission / reception processing of a reference station or base station of wireless communication, for example. The configuration of the device according to the second embodiment of the present invention is the same as that of FIG. FIG. 7 is a flowchart showing the procedure of the deframing process according to the second embodiment of the present invention. FIG. 8 is a flowchart showing the procedure of the framing process according to the second embodiment of the present invention. FIG. 7 shows the first embodiment described above.
The same procedure as in FIG. Further, FIG. 8 shows the same procedure as in FIG. 2 of the first embodiment. In the second embodiment, an example in which the length of the received frame is longer than the length of the transmitted frame will be described. Therefore, as shown in FIG. 7, calculation of the number of divisions occurs in the deframing process. In FIG. 7, reference numeral 30 is a process of calculating the number of divisions for dividing the received frame into processing units. Reference numeral 31 is a process for calculating the number of times of processing for each division unit. Reference numeral 32 denotes a deframing processing by the deframing processing unit 1b, which is performed by the iterative processing control unit 103 for the number of divisions calculated by the division number calculation 30. Three
Reference numeral 3 denotes a deframing process in which when the number of divisions is calculated by the calculation 30 of the number of divisions, if a surplus occurs, the received frame for the surplus is used as the first cycle. A deframing process 34 repeats the process for the number of divisions calculated in the calculation 30 of the number of divisions. When a surplus occurs in the calculation 30 of the number of divisions, the deframing process for the surplus is
It was supposed to be performed in the first cycle. Therefore, the deframing process for the processing unit is repeatedly performed in the deframing process 34 after the second cycle. 15b in FIG. 8 is 1
This is framing processing in processing units.

In a digital signal transmission / reception processing device for processing a signal in which the length of the reception frame is longer than the length of the transmission frame, for example, the length of one transmission frame is used as the processing unit and one processing unit is used. Process one transmission frame. FIG. 8 shows a procedure of framing a transmission frame of one processing unit. In FIG. 8, similarly to the conventional example, the number of times of processing (generally, the number of symbols) is first calculated, and the unit processing 154 is repeated by the number of times of processing. For example, in the timing chart shown in FIG. 9, one transmission frame 28 is one processing unit 90. Therefore, the framing 41 processes one transmission frame 28. For example, the length of the transmission frame is 15 ms,
The processing unit is 15 ms. Also, one symbol is 5 ms
And The calculation 153 of the number of processing times in FIG. 8 is calculated as 15 ms / frame / 5 ms = 3 times. As a result, the unit process 154 is repeated three times. Therefore,
In the framing 41 of FIG. 9, the unit process 154 is repeated three times to process one transmission frame.

On the other hand, in the deframing processing for a long received frame, first, the division number calculation unit 102 calculates the division number for dividing the reception frame into processing units by the division number calculation 30 of FIG. Then, the number of processing times calculation 31 is performed to calculate the number of symbols for each processing unit. Then, the deframing process 32 for the calculated number of divisions is executed. For example, in the timing chart shown in FIG. 9, one processing unit is set to 15 ms for one transmission frame. Therefore, the received frame 127
If the length is 55 ms, the number of divisions is 55 ms / frame ÷ 15 ms (1 processing unit) = 3 times.
The remaining time is 10 ms. However, the remainder occurs for 10 ms. Since the received frame for 10 ms is subjected to deframing processing in one processing unit, the number of divisions is four. Therefore, in the deframing processing of FIG. 7, the remaining 10 ms of deframing processing is performed by the deframing processing 33 of the first cycle, and the deframing processing of 15 ms is performed 3 times by the deframing processing 34 of the second and subsequent cycles. Will be done once. The reception frame 27 in FIG. 9 is processed by the deframing 42 in the first cycle and the deframing 43 in the second cycle and thereafter. Also, one symbol is 5m
If s, the number of times of processing (number of symbols) in the first cycle is 10 ms / 5 ms = 2 times. Then, the number of unit processing in each processing unit after the second cycle is 15 ms / 5 ms = 3 times.

In this way, also in the second embodiment, as in the first embodiment, the length of the received frame may not be an integral multiple of the transmitted frame, and the processing may not be equally divided.
In this case, in the deframing procedure shown in FIG.
One received frame is divided into processing units, and the processing corresponding to the remainder when divided is processed in the first cycle. That is, in the processing of the first cycle, the number of times of processing becomes a value equal to or less than the number of times of processing after the second cycle. In the deframing process after the second cycle, the number of times of processing is the same and recalculation of the number of times of processing is unnecessary. These operations are similar to the framing process in the first embodiment.

Comparing the deframing / framing processing of FIG. 9 with the conventional technique of FIG. 19, the transmission / reception processing margin 91 is averaged, and the problem of the conventional technique of eliminating the processing margin 91 at a certain timing is solved. . This makes it possible to obtain a digital signal transmission / reception processing device that efficiently processes digital transmission / reception signals in digital communication.

Further, in FIG. 9, an example in which the length of one transmission frame is one processing unit has been described. However, for example, the length of two transmission frames can be set as one processing unit 90. FIG. 10 shows a timing chart in which the length of two transmission frames is one processing unit 90. In FIG. 10, the processing unit 90 is composed of two transmission frames 28. For example, the frame length of one transmission frame is set to 15 ms. The framing processing 15b shown in FIG. 8 is assumed to perform processing for two transmission frames. The number of processing times (the number of symbols) of the two transmission frames is calculated by the processing number calculation 153. Assuming that one symbol is 5 ms, the number of times of processing is 15 ms / frame × 2/5 ms = 6 times. Therefore, the unit processing 154 in the framing processing unit 1a is repeated 6 times for each processing unit. Figure 10
The framing 41a indicates that the unit processing is performed 6 times.

Further, the frame length of the reception frame 27 of FIG. 10 is set to 105 ms / frame, for example. In the division number calculation 30 shown in FIG. 7, the division number calculation unit 102
Divides the received frame 27 into processing units. The number of divisions is 105 ms / frame / 30 ms (1 processing unit) = 3
The remaining time is 15 ms. However, since the remainder is 15 ms, the number of divisions is 4. Then, in the calculation 31 of the number of processings,
The number of times of processing (the number of symbols) is calculated for each processing unit. When one symbol is 5 ms, the number of processing times is 30 ms / 5 ms = 6 times. Since the remainder is 15 ms, 15 ms / 5 ms = 3 times in the 15 ms deframing process. Therefore, the deframing process 33 in the first cycle in FIG. 7 is the unit process 33a repeated three times. Then, the deframing process 34 after the second cycle
Is repeated three times, and the unit process 34a in each cycle is repeated.
Will be repeated 6 times. The first cycle deframing 42a in FIG. 10 corresponds to the first cycle deframing processing 33 in FIG. 7, and the unit processing 33a is repeated three times. Further, the deframing 43a after the second period in FIG. 10 is the deframing processing 3 after the second period in FIG.
4, the unit process 34a in each cycle is repeated 6 times. Thus, the received frame 27 has four
It will be processed by being divided into individual processing units.

Further, the processing unit 90 can be set to a length obtained by dividing the transmission frame into a predetermined Bit length. FIG. 11 is a diagram showing a timing chart of the deframing / framing processing in which the transmission frame is divided into predetermined Bit lengths and the processing unit is determined. In FIG. 11, one transmission frame 28 has, for example, 1000 bits, and the processing unit 90 divides one transmission frame 28 into 500 bits to form 500 bits. The framing 41b shown in FIG. 11 is a framing process for generating a transmission frame of 500 bits by the procedure of the framing process shown in FIG. For example, 1 symbol is 100 Bi
Assuming t, the number of processing times 153 is calculated as 500 Bit / 100 Bit = 5 times. Therefore, the framing 41b of FIG.
Then, the unit process 154 is repeated five times.

Further, the frame length of the reception frame 27 of FIG. 11 is set to 1600 Bit, for example. Processing unit 90
Is 500 bits, the calculation of the number of divisions is 30
The number of divisions calculated by is 1600 Bit / frame / 500 Bit (1 processing unit) = 3, and the remainder is 100 Bit. However, since the remainder is 100 Bit, the number of divisions is 4. That is, the reception frame 27 is divided into four processing units and the deframing processing is performed. In addition, in the calculation 31 of the number of times of processing, assuming that one symbol is 100 bits, the number of times of processing of 500 Bit / 100 Bit = 5 times is calculated. Also, the remaining 100 Bi
For t, the number of processing times of 100 Bit ÷ 100 Bit = 1 is obtained. Therefore, the remaining 100B
When it is attempted to be processed by the first-cycle deframing process, the deframing process 33 performs one unit process 33a. In the deframing 42b of the first cycle in FIG. 11, the received frame for 100 bits is set to 1
It is processed by the unit processing 33a for one time. Also, the second
The deframing 43b after the cycle corresponds to the deframing processing 34 after the second cycle in FIG. 7, and the unit processing 34a is repeated five times for each cycle. Further, since the number of divisions is four, the deframing 43b after the second cycle has three cycles of the second, third and fourth cycles.

As described above, in the second embodiment, in the digital signal transmission / reception processing device for processing a signal in which the length of the reception frame is longer than the length of the transmission frame, one of the transmission digital processing units is one. Alternatively, a digital signal characterized by executing a processing unit with a plurality of frames or with a bit length obtained by dividing the frame into predetermined units and dividing the reception digital processing unit into the transmission digital processing unit and executing the processing. The transmission / reception processing device has been described.

A description will be given of a digital signal transmission / reception processing device characterized in that the unit of the receiving process is divided into equal units for each transmitting process, and the receiving process which is the remainder of the division is executed in the unit of one transmitting process. did.

In the digital signal transmission / reception processing device having the above characteristics, the transmission digital processing unit is one or a plurality of frames, or the processing unit is a bit length obtained by dividing the frame into predetermined units. By dividing the digital processing unit for reception into digital processing units for transmission and executing the processing, the digital processing for reception that requires a long processing time is dispersed, and the processing margin temporarily becomes extremely small. Alternatively, the problem of disappearance can be solved. Further, by performing the reception processing that is the remainder of division in one transmission processing unit, the digital processing of reception that requires a long processing time is dispersed, and the processing margin temporarily becomes extremely small or disappears. The problem can be solved. Further, the number of processes for calculating the number of processes for each division unit is only one, and the processing load can be further reduced.

[0056]

As described above, the digital signal transmission / reception processing device of the present invention processes a digital processing unit for reception as one or a plurality of frames or a bit length obtained by dividing a frame into predetermined units. Run the unit,
By dividing the transmission digital processing unit into the reception digital processing unit and executing it, the transmission digital processing that requires a long processing time is dispersed, and the processing margin temporarily becomes extremely small or disappears. There is an effect that the problem can be solved.

Further, the transmission processing which is the remainder of the division is executed in one reception processing unit. As a result, the digital processing of transmission that requires a long processing time can be dispersed, and the problem that the processing margin temporarily becomes extremely small or disappears can be solved. Also, if no surplus occurs, the time required to calculate the number of processing times for each division unit is 1
Only once, there is an effect that the processing load can be further reduced.

Also, the digital processing unit of transmission is the first
One or a plurality of frames, or the processing unit is executed as a bit length obtained by dividing the frame into a predetermined unit, and the reception digital processing unit is divided into the transmission digital processing unit and executed. As a result, the digital processing of reception, which requires a long processing time, is dispersed, and the problem that the processing margin is temporarily reduced or eliminated can be solved.

The reception process which is the remainder of the division is executed in one transmission process unit. As a result, it is possible to eliminate the problem that the digital processing of reception that requires a long processing time is dispersed and the processing margin temporarily becomes extremely small or disappears. Further, if no surplus occurs, the time and labor required for calculating the number of times of processing for each division unit are only one, and the processing load can be further reduced.

Since the process unit determining step is provided, it is possible to set a predetermined process unit. For example, if the processing unit is determined based on the frame length of the received frame, it is possible to disperse the framing process that processes a transmission frame that is longer than the received frame, and it is possible to solve the problem that the processing margin is reduced. is there.

When a transmission frame is divided on the basis of the determined processing unit, if a surplus occurs, the surplus transmission frame is subjected to the framing process for each processing unit. Therefore, even when the length of the transmission frame is not a positive multiple of the length of the reception frame, the framing process can be performed by dividing the transmission frame into predetermined processing units.

Further, since the processing unit determining step is provided, it is possible to set a predetermined processing unit. For example, if the processing unit is determined based on the frame length of the transmission frame, it is possible to disperse the deframing processing that processes a reception frame that is longer than the transmission frame, and it is possible to solve the problem that the processing margin is reduced. There is.

When a received frame is divided on the basis of the determined processing unit, when a surplus occurs, the surplus received frame is deframed by one processing unit. Therefore, even if the length of the received frame is not a positive multiple of the length of the transmitted frame, the received frame can be divided into predetermined processing units to perform the deframing processing.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a digital signal transmission / reception processing device of the present invention.

FIG. 2 is a flowchart showing a procedure of a deframing process according to the first embodiment of the present invention.

FIG. 3 is a flowchart showing a procedure of framing processing according to the first embodiment of the present invention.

FIG. 4 is a timing chart showing the deframing / framing operation according to the first embodiment of the present invention.

FIG. 5 is a timing chart showing the deframing / framing operation according to the first embodiment of the present invention.

FIG. 6 is a timing chart showing a deframing / framing operation according to the first embodiment of the present invention.

FIG. 7 is a flowchart showing a procedure of a deframing process according to the second embodiment of the present invention.

FIG. 8 is a flowchart showing a procedure of framing processing according to the second embodiment of the present invention.

FIG. 9 is a timing chart showing the deframing / framing operation according to the second embodiment of the present invention.

FIG. 10: Deframing / Embodiment 2 of Embodiment 2 of the present invention
It is a timing chart figure which shows operation | movement of framing.

FIG. 11: Deframing / Embodiment 2 of Embodiment 2 of the present invention
It is a timing chart figure which shows operation | movement of framing.

FIG. 12 is a basic configuration diagram of a digital signal transmission / reception processing device according to a conventional technique.

FIG. 13 is a diagram illustrating a configuration example of framing / deframing processing.

FIG. 14 is a flowchart showing a conventional deframing process.

FIG. 15 is a flowchart showing a conventional framing process.

FIG. 16 is a flowchart showing a conventional deframing process.

FIG. 17 is a flowchart showing a conventional framing process.

FIG. 18 is a diagram showing a configuration example of a digital communication frame.

FIG. 19 is a timing chart showing a conventional framing / deframing process.

[Explanation of symbols]

1 framing / deframing processing section, 1a framing processing section, 1b deframing processing section, 2 modulation section, 3 demodulation section, 4 audio codec, 5 main processor, 21, 21a, 21b deframing, 22,
22a, 22b first period framing, 23, 23
a, 23b Framing after the second period, 24, 27
Received frame, 25,28 Transmitted frame, 26,4
1, 41a, 41b framing, 42, 42a, 4
2b first period deframing, 43, 43a, 43
b Deframing after the second cycle, 100 framing / deframing processing unit, 101 processing unit determination unit, 102 division number calculation unit, 103 repetition processing control unit.

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04L 29/02 H04L 12/56

Claims (18)

(57) [Claims] 1. A transmission frame length comprising: a framing processing unit for processing a transmission frame, a deframing processing unit for processing a reception frame, a processor for controlling the operations of the framing processing unit and the deframing processing unit. transmission frame but in the digital signal transmission and reception processing apparatus for processing a long signal than the length of the received frame, which Oite processing to the framing processing unit
A digital signal transmission / reception processing device, comprising: a processing unit determination unit that determines the processing unit of the above based on the length of a reception frame processed by the deframing processing unit . 2. The processing unit determination unit divides the length of a transmission frame by the processing unit to calculate the number of times of framing processing performed to generate one transmission frame, and the division unit. 2. The digital signal transmission / reception processing apparatus according to claim 1, further comprising: a repetition processing control unit that controls the framing processing to be repeatedly performed until the number of times of processing calculated by the number of times calculation unit is satisfied. 3. The division number calculation unit calculates the number of framing processes so that a surplus transmission frame generated when the calculation is performed is generated by a framing process for each processing unit. The digital signal transmission / reception processing device according to claim 2. 4. The processing unit determination unit sets one processing unit to one.
2. The digital signal transmission / reception processing device according to claim 1, wherein the reception frame length is set. 5. The digital signal transmission / reception processing device according to claim 1, wherein the processing unit determination unit sets one processing unit to a plurality of reception frame lengths. 6. The digital signal transmission / reception processing apparatus according to claim 1, wherein the processing unit determination unit sets one processing unit to a bit length obtained by dividing a received frame into a predetermined length. 7. The length of a received frame is provided with a framing processing unit for processing a transmission frame, a deframing processing unit for processing a reception frame, a processor for controlling the operation of the framing processing unit and the deframing processing unit. In the digital signal transmission / reception processing device for processing a signal longer than the length of the transmission frame, the reception frame processed by the deframing processing section is processed.
The processing unit of the arm, the digital signal transmission and reception processing apparatus characterized by comprising a processing unit determination unit that determines based on the length of the transmission <br/> signal frame the framing processing unit processes. 8. The processing unit determination unit divides the length of a received frame into the processing units, and calculates the number of times of deframing processing performed to process one received frame; 8. The digital signal transmission / reception processing device according to claim 7, further comprising: a repetitive processing control unit that controls the deframing processing to be repeatedly performed until the number of times of processing calculated by the division number calculation unit is satisfied. 9. The division number calculation unit calculates the number of times of deframing processing so that the processing of the excess received frames generated when the above calculation is performed is performed by the deframing processing of one processing unit. 9. The digital signal transmission / reception processing device according to claim 8. 10. The digital signal transmission / reception processing device according to claim 7, wherein the processing unit determination unit sets one processing unit to one transmission frame length. 11. The processing unit determination unit sets one processing unit to a plurality of transmission frame lengths.
The described digital signal transmission / reception processing device. 12. The digital signal transmission / reception processing device according to claim 7, wherein the processing unit determination unit sets one processing unit to a bit length obtained by dividing a transmission frame into a predetermined length. 13. A digital signal transmitting / receiving process, comprising a framing process step of processing a transmission frame and a deframing processing step of processing a reception frame, and processing a signal in which a transmission frame length is longer than a reception frame length. in the method, transmission frame to Oite processing to the framing processing step
The processing unit of the system is processed in the above deframing process step.
Digital signal transmission and reception processing method characterized by comprising a unit-of-processing determining step of determining based on the length of the received frame that. 14. The processing unit determining step divides the length of a transmission frame into the processing units to calculate the number of times of framing processing performed to generate one transmission frame, and the division number calculating step. 14. The digital signal transmission / reception processing method according to claim 13, further comprising a repetitive processing control step of controlling the framing processing to be repeatedly performed until the number of processings calculated by the number of times calculation step is satisfied. 15. The number of times of framing processing is calculated in the step of calculating the number of times of division so that a surplus transmission frame generated when the above calculation is performed is performed by framing processing in one processing unit. Item 15. A digital signal transmission / reception processing method according to Item 14. 16. A digital signal transmission / reception process comprising a framing process step of processing a transmission frame and a deframing processing step of processing a reception frame, and processing a signal in which the length of the reception frame is longer than the length of the transmission frame. in the method, the reception frame to be processed in the de-framing process
Digital signal transmission and reception processing method characterized by the processing unit of the over arm, equipped with a unit-of-processing determining step of determining based on the length of the transmission <br/> signal frames to be processed in the framing process. 17. The processing unit determining step divides the length of a received frame into the processing units to calculate the number of times of framing processing performed to generate one received frame, and the division number calculating step. 17. The digital signal transmission / reception processing method according to claim 16, further comprising a repetitive processing control step of controlling the deframing processing to be repeatedly performed until the number of processings calculated by the number of times calculation step is satisfied. 18. The number of divisions calculation step calculates the number of deframing processings so that a surplus received frame generated when the calculation is performed is performed by a deframing processing for each processing unit. 18. The digital signal transmission / reception processing method according to claim 17.