JP2000341365A - Code error measurement unit for transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect a code error independently of a transmission rate of each transmission line. SOLUTION: The code error measurement unit of a transmission system where a code error caused in a transmission process is measured by a loopback system, is provided with a block coding section 15 that divides test data sent from one end of the transmission system 1 to the other end via a transmission line 2 of the transmission system into a plurality of blocks, encodes the blocks, and obtains additional bits, a 2nd block coding section 16 that is provided in the other end of the transmission system, divides the test data received from one end via the one transmission line 2 into a plurality of blocks, encodes the blocks and obtains the additional bits, and a code error detection section 19 that is provided in one end of the transmission system, compares the additional bits received from the other end via the other transmission line 3 with the additional bits obtained by the 1st block coding section 15 and detects the code error produced in the transmission system 1 and the transmission lines 2, 3 producing a code error.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a code error measuring device for a transmission system for detecting a code error occurring in a transmission process of digital data transmitted in a transmission system capable of transmitting data in both directions by a loopback method. .

[0002]

2. Description of the Related Art For example, in a digital mobile communication system such as a mobile phone, a PHS or a car phone, a transmission system for connecting a base station to each mobile station transmits data and various information from the base station to the mobile station. Transmission paths for transmitting data and various information from the mobile station to the base station.

[0003] In this case, since the transmission medium is wireless, the transmission medium is in the air.

In a CATV system, a transmission system for connecting a base station (broadcasting station) to a TV terminal in each home is used for transmitting TV images and the like from the base station (broadcasting station) to a TV terminal in each home. , And a pair of transmission lines having different transmission directions from an upstream transmission line for transmitting a program distribution request or the like from a TV terminal of each home to a base station (broadcasting station).

[0005] In addition, in an information communication system, when data communication is performed between a pair of information processing devices spaced apart from each other, information is transmitted from one information processing device to the other information processing device; In some cases, different transmission paths are used for transmitting information from one information processing apparatus to one information processing apparatus.

[0006] When a new transmission system including a pair of transmission paths having different data transmission directions from each other is constructed, or when an installed transmission system is inspected and maintained, digital data transmitted through this transmission system is transmitted. It is necessary to evaluate a transmission system by detecting a code error occurring in a transmission process and statistically measuring, for example, a bit error rate.

A transmission-system code error measuring device for measuring a code error occurring in such a transmission system is configured, for example, as shown in FIG. The transmission system 1 to be measured includes a downstream transmission line 2 and an upstream transmission line 3. In FIG. 6, the transmission path is represented by a solid line in a simulated manner, but may be any of aerial propagation and wired propagation. The measuring device 4 is connected to one end of the transmission system 1, and the measuring device 5 is connected to the other end of the transmission system 1. In the measuring device 4, the test data generator 6 configured by, for example, a PN pattern generator sends digital test data a composed of, for example, a PN (pseudo-random) pattern to the transmitter 7.
The test data a is sent to the code error detection unit 8. The transmitting unit 7 transmits the input test data a to the transmission system 1 to be measured.
At the transmission rate specified in the transmission line 2 of the transmission system 1
To the measurement terminal 5 via

[0008] The receiving unit 10 of the measuring terminal 5 receives the test data a transmitted from the measuring device 4 via the downlink transmission line 2 of the transmission system 1, and temporarily writes the received test data a into the receiving buffer 11. The test data a written in the reception buffer 11 is read out by the transmission unit 12, and is transmitted through the upstream transmission line 3 of the transmission system 1 at the transmission speed specified for the transmission system 1 to be measured.
Send to

[0009] The receiving section 9 of the measuring apparatus 4 receives the test data a ₁ transmitted from the measuring terminal 5 via the upstream transmission line 3 of the transmission system 1 and sends it to the code error detecting section 8. The code error detection unit 8 compares each bit data of the test data a before transmission output from the test data generation unit 6 with each bit data of the test data a ₁ transmitted through the transmission system 1, and compares each bit data. Check if the data match. If there is mismatched bit data, it is determined that a code error has occurred in the transmission system 1 to be measured. Then, if necessary, a code error rate or the like at a predetermined time interval is calculated from the occurrence frequency.

[0010]

However, as shown in FIG. 6, the test data a output from one end of the transmission system 1 is generated in the transmission system 1 in a loop-back system in which the transmission system 1 reciprocates. The following problems still need to be improved in a transmission-system code error measuring device for detecting a code error.

That is, in the transmission-side code error measuring device shown in FIG. 6, the data transmission rate Va specified for the downlink transmission line 2 constituting the transmission system 1 is expressed by the equation (1).
(Bps) and the data transmission speed Vb (bps) specified for the upstream transmission line 3 or the data transmission speed Vb of the upstream transmission line 3 is higher than the data transmission speed Va of the downstream transmission line 3 Is a major premise in error measurement.

Vb ≧ Va (1) Conversely, as shown in equation (2), when the data transmission speed Vb of the upstream transmission line 3 is lower than the data transmission speed Va of the downstream transmission line 3, Since the transmission speed of the test data is lower than the reception speed of the test data, untransmitted data is accumulated in the reception buffer 11, and the test data is not normally transmitted from the measuring terminal 5 to the measuring device 4. There is a problem that cannot be implemented.

Vb <Va (2) Especially. In the case where the W-CDMA system is adopted as a communication system between the base station and each mobile station in the mobile communication system, the transmission speed from the base station to the mobile station is lower than the transmission speed Va of the downlink transmission line 2 from the mobile station. The transmission speed Vb of the uplink transmission line 3 to the base station is lower.

Also, in the above-mentioned CATV, the transmission rate Va of the downlink transmission line 2 for transmitting TV images and the like from the base station (broadcasting station) to the TV terminal of each home is determined by the TV terminal to the base station (broadcasting station). ), The transmission speed Vb of the upstream transmission line 3 for transmitting a program distribution request or the like is lower.

As described above, in the transmission-side code error measuring device adopting the loop-back method shown in FIG. 6, the transmission speeds Va and Vb of the pair of transmission lines 2 and 3 constituting the transmission system.
Depending on the combination, there is a concern that the code error measurement for the transmission system 1 cannot be performed correctly.

The present invention has been made in view of such circumstances, and does not loop back test data received from a test data transmitting side to the transmitting side as it is, but performs block coding and compression of the test data. By looping the data back to the transmitting side, the transmission system code error can be reliably detected regardless of the combination of each transmission speed in a pair of transmission paths constituting the transmission system to be measured. It is an object to provide a measuring device.

[0017]

SUMMARY OF THE INVENTION The present invention is directed to a transmission system capable of measuring a code error generated in a transmission process of digital data transmitted through a transmission system capable of transmitting data in both directions by a loopback method. Applies to measuring devices.

In order to solve the above-mentioned problems, a transmission-system code error measuring apparatus according to the present invention is provided at one end of a transmission system, and from one end of the transmission system through one transmission path of the transmission system to the other. A first block encoding unit that divides test data transmitted to an end into a plurality of blocks and performs block encoding to obtain additional bits, and a first block encoding unit that is provided at the other end of the transmission system and has one transmission path from one end. The test data received via the second block encoding unit is divided into a plurality of blocks and is subjected to block encoding to obtain additional bits, and a second block encoding unit provided at the other end of the transmission system to acquire additional bits. Additional bit transmitting means for transmitting the added bits to one end through the other transmission path of the transmission system, and additional bits provided at one end of the transmission system and received from the other end through the other transmission path. The first block By comparing the additional bits obtained by the coding unit, and a code error detection unit for detecting a code error occurs, and a code error generated transmission path in the transmission system.

In the transmission-system code error measuring apparatus thus configured, test data transmitted from one end of the transmission system to the other end of the transmission system via one transmission path (downlink transmission path) In the second block encoding unit, the data is divided into a plurality of blocks each including a predetermined number of bit data.

A block code for error correction such as a Hamming code, a cyclic code and a BCH code is generated from each block composed of the predetermined number of bit data by the second block coding unit.

For example, BCH (Bose Chaudhuri Hocquen)
ghem) code is the sum of the original block and the additional bits. BCH (20, 15) means that the total length of the BCH code is 20 bits and the bit length of the original block is 1
Indicates that it is 5 bits. Therefore, the bit length of the additional bit in this case is 5 bits. By the way, BC
H (20,15) is a shortened code of BCH (31,26). The shortened code is used to shorten the original bit length, but to perform processing as if it had not been shortened. In this case, the reduction is 11 bits.

Incidentally, BC which is a kind of error correction code is used.
In the H code, if m is a positive integer, for an un shortened code length of (2 ^m -1) bits or less,
By providing at most mt check bits, t (t bits) errors can be corrected. Therefore, in the BCH (20, 15) code having the five additional bits described above, one (one bit) error in the original block can be corrected with the five additional bits.

That is, if a 1-bit code error occurs in one of the transmission lines (downlink transmission lines) in the additional bits, the calculation of the additional bits is affected.

Accordingly, even if only a small number of additional bits are transmitted without transmitting the received test data to the transmission source of the test data via the other transmission path (uplink transmission path), one transmission path The error occurrence information on the (downlink transmission path) is transmitted to the test data transmission source at one end of the transmission system.

At one end of the transmission system, the received additional bits are compared with the additional bits output from the first block encoder. In this case, if no code error has occurred in both transmission lines forming the transmission system, the two completely match.

When a code error occurs only in the other transmission line (uplink transmission line), a mismatch occurs only in one bit. If a code error occurs in only one transmission path (downlink transmission path), a mismatch occurs in several bits.

In this case, it is assumed that only a maximum of 1-bit code error occurs in one block in the entire transmission system. That is, a code error of two or more bits does not occur in one block.

Therefore, at one end of the transmission system on the transmission side of the test data, a code error occurs in the transmission system,
In addition, a transmission path in which a code error has occurred can be detected.

In this case, only the additional bits of a significantly smaller number of bits than the number of bits of the test data transmitted on one transmission path (downlink transmission path) are transmitted to the other transmission path (uplink transmission path). , Even if the other transmission path (uplink transmission path)
Even if the transmission speed of the transmission line is lower than the transmission speed of one transmission line (downlink transmission line), at one end of the transmission system on the transmission side of the test data, the occurrence of a code error in the transmission system Can be sufficiently detected.

Therefore, regardless of the combination of each transmission rate in the pair of transmission lines constituting the transmission system to be measured, a code error in the transmission system can be reliably detected.

According to another aspect of the present invention, there is provided a transmission system for measuring a code error generated in a transmission process of digital data transmitted in a transmission system including a pair of transmission lines having different data transmission directions by a loopback method. A bit error measuring device provided at one end of a transmission system, and bit-compressing test data transmitted from the one end to one end of the transmission system through one transmission path to output compressed data.
A second data compression unit provided at the other end of the transmission system and bit-compressing test data received from one end via one transmission path and outputting compressed data;
A compression data transmission means provided at the other end of the transmission system for transmitting the compressed data output from the second data compression unit to one end via the other transmission path of the transmission system; A code error detecting unit for comparing the compressed data received from the other end through the other transmission path with the compressed data output from the first data compression unit to detect occurrence of a code error in the transmission system; It has.

In the transmission-system code error measuring apparatus thus configured, test data transmitted from one end of the transmission system to the other end of the transmission system via one transmission path (down transmission path) is: In the second data compression unit, the data is compressed and converted into compressed data. Then, the compressed data is transmitted to one end of the transmission system via the other transmission path (uplink transmission path).

At one end of the transmission system, the received compressed data is compared with the compressed data output from the first data compression unit. In this case, if no code error has occurred in both transmission lines forming the transmission system, the two completely match. If there is a bit that does not match, it can be considered that a code error has occurred in at least one of the transmission paths.

In this case, only the compressed data having a bit number significantly smaller than the bit number of the test data transmitted through one transmission path (down transmission path) is transmitted to the other transmission path (up transmission path). , Even if the other transmission path (uplink transmission path)
Even if the transmission speed of the transmission line is lower than the transmission speed of one transmission line (downlink transmission line), occurrence of a code error in the transmission system can be sufficiently detected at one end of the transmission system on the test data transmission side.

In this case, it is conceivable that a bit in which a code error has occurred may be omitted from the compressed data by data compression, but a correct code error rate can be obtained by performing statistical processing.

Therefore, regardless of the combination of the transmission speeds of the pair of transmission lines constituting the transmission system to be measured, a code error in the transmission system can be reliably detected.

[0037]

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

(First Embodiment) FIG. 1 is a block diagram showing a schematic configuration of a transmission-system code error measuring apparatus according to a first embodiment of the present invention. The same parts as those of the conventional transmission-system code error measuring device shown in FIG. Therefore, the detailed description of the overlapping part will be omitted.

The transmission system 1 to be measured comprises a downstream transmission line 2 and an upstream transmission line 3. In this embodiment, for example, the data transmission speed Va of the downlink transmission line 2 is 3
84 kbps, and the data transmission speed Vb of the upstream transmission line 3 is 128 kbps. Therefore, the transmission speed Vb of the data on the upstream transmission line 3 is set to １ ／ of the transmission speed Va of the data on the downstream transmission line 2.

A measuring device 13 is connected to one end of the transmission system 1, and a measuring device 14 is connected to the other end of the transmission system 1. In the measuring device 13, the test data generator 6 sends digital test data a composed of a PN (pseudo-random) pattern to the transmitter 7 and sends the test data a to the first block encoder 15. . The transmitting unit 7 transmits the input test data a to the measuring terminal 14 via the downlink transmission line 2 of the transmission system 1 at the transmission speed Va (= 384 kbps) specified for the transmission system 1 to be measured.

The receiving unit 10 of the measuring terminal 14
3 receives the test data a transmitted through the down transmission line 2 of the transmission system 1 from delivering as test data a ₂ received to the second block coding unit 16. The second block encoder 16 includes a block divider 17 and an additional bit calculator 18. The block dividing unit 17 divides the test data a ₁ input to a plurality of blocks b having a predetermined number of bits. In this embodiment, the number of bits in each block b is [15].

The additional bit calculation unit 18 calculates each block b
And data converted into one which is BCH code d of block code consisting of the original block b additional bits c ₁ Tokyo. In this embodiment, since the transmission speed Vb of the upstream transmission line 3 is 1/3 of the transmission speed Va of the downstream transmission line 2, the number of bits of the additional bit c1 is ₁ of the bit number 15 of each block b. / 5, which is set to [5]. Therefore, the BCH code can be described as BCH (20, 15). Further, the additional bit calculation unit 18 extracts each 5-bit configuration additional bit c ₁ from each created block code, and sends it to the transmission unit 12.

Here, the number of bits of each block b is 15
And BCH (2) in which the number of bits of the additional bit c ₁ is 5
0,15) describes a method of calculating the additional bits c ₁ of.

The block b of 15 bits is represented by a polynomial of the equation (3), where A = K ₁₅ X ¹⁹ + K ₁₄ X ¹⁸ +... + K ₁ X ⁵ (3) The polynomial of the equation (1) is Perform processing similar to division in 4),
The remainder is the 5-bit additional bit c _1.

B = X ⁵ + X ² +1 (4) The transmitting unit 12 transmits the 5-bit additional bits c ₁ sequentially output from the block encoding unit 16 to the transmission system 1 to be measured.
At the transmission rate Vb (= 128 kbps) designated to the measuring apparatus 13 via the upstream transmission line 3 of the transmission system 1.

The receiving unit 9 of the measuring device 13 receives the additional bit c ₁ transmitted from the measuring terminal 5 via the uplink transmission line 3 of the transmission system ₁ and converts the received additional bit c ₂ into a code error It is sent to the detection unit 19.

The first block encoder 15 has exactly the same configuration as the second block encoder 16 described above, and includes a block divider 17 and an additional bit calculator 18. Then, the first block encoding unit 15
The test data a before being transmitted to the transmission system 1 is block-encoded to calculate an additional bit c having a 5-bit configuration, and is transmitted to the code error detector 19.

The code error detector 19 compares the additional bit c output from the first block encoder 15 with the measurement terminal 14
By comparing the additional bits c ₂ received from, according to the algorithm described above, code error occurs in the transmission system 1,
And the transmission paths 2 and 3 where a code error has occurred.

More specifically, when the two match perfectly,
It is determined that no code error has occurred in both transmission paths 2 and 3 forming the transmission system 1. If it does not coincide in combination additional bit c ₂ and the received test data a for calculating a syndrome S. If the position of the code error can be identified from the syndrome S,
Whether a code error has occurred in the downstream transmission line 2 or the upstream transmission line 3
It is possible to determine whether or not a code error has occurred. If it cannot be specified, it is found that an error exceeding the error correction capability has occurred.

The code error detector 19 sends the detection result of the occurrence of a code error for each of the sequentially received additional bits c ₂ to the next error rate calculator 20. The error rate calculation unit 20 calculates a code error rate for the entire transmission system 1 or for each of the transmission paths 2 and 3.

The flow of test data in the thus configured transmission-system code error measuring device will be described with reference to FIGS. 2, 3 and 4. FIG.

As shown in FIG. 2, the data transmission speed Va of the downstream transmission line 2 is 384 kbps,
Is a transmission speed Vb of 128 kbps.

As shown in FIG. 3A, 5-bit unit data D11, D12, D13, D21, D22, D23, D3
Test data a in which 1, D32... Are output from the test data generator 6 and transmitted to the downstream transmission line 2 of the transmission system 1 via the transmitter 7 (FIG. 3B).

In this downstream transmission process, each unit data D11,
D12, D13,..., A 5-bit noise E11, E
12, E13,... Are added. If there is no noise,
Each bit of each of the noises E11, E12, E13,... Has a value of 0, and when noise occurs, the bit of the corresponding noise E is set to 1.

Then, 5-bit unit data D'11, D'12, D'1 to which noises E11, E12, E13,.
3, D'21, D'22, D'23, D'31, D'32 ... to the second block coding unit 16 is received by the receiving unit 10 of the test data a ₂ measurement terminal 14 consecutive Input (Fig. 3
(C)).

In the second block coding section 16,
Received test data a ₂ is divided every three unit data d, i.e. the block b of 15 bits long (Figure 4
(D)). Then, block coding is performed for each block b having a length of 15 bits, and additional bits D′ 1, D′ 2, D′ 3,...
(E)).

Each calculated additional bit c having a 5-bit structure
₁ is transmitted from the transmission unit 12 to the uplink transmission line 3 (FIG. 4F).

In this upstream transmission process, each additional bit D'1,
With respect to D′ 2, D′ 3, D′ 4,...
1, E'2, E'3, E'4 ... are added. Then, additional bits D "1, D" 2, D "of a 5-bit configuration to which each noise is added
3, D "4 ... is received by the receiver 9 of the measuring device 13, as the additional bit c ₂ reception, is inputted to the code error detecting unit 19 (FIG. 4 (g)).

In the first block encoder 15,
The test data a output from the test data generator 6 is divided into three unit data d, that is, a block b having a length of 15 bits.
Is divided into Then, block coding is performed for each block b having a length of 15 bits, and additional bits D1, D2, D3,... Each calculated additional bit c is input to the code error detection unit 19 (see FIG.
4 (h)).

The code error detector 19 calculates each additional bit D
1, D2, D3, D4,... And each additional bit D "1,
A bit error occurring in the transmission system 1 is detected by sequentially comparing each bit of D "2, D" 3, D "4,...

In the transmission-system code error measuring apparatus according to the first embodiment having the above-described configuration, the measuring apparatus 13 provided at one end of the transmission system 1 which is the transmission side of the test data a uses the transmission system. 1 and the transmission lines 2 and 3 in which a code error has occurred in the downstream transmission line 2 or the upstream transmission line 3 can be detected.

In this case, the upstream transmission line 3 is connected to the downstream transmission line 2
The number of bits of the test data a transmitted only additional bit c ₁ of the much smaller number of bits 5 from (bit number 15 of the block b) is transmitted to. Therefore, even if the transmission speed Vb of the upstream transmission line 3 is lower than the transmission speed Va of the downstream transmission line 2, the transmission system 1 on the transmission side of the test data a
In the measuring device 13 arranged at one end of the
And the transmission paths 2 and 3 where the code error has occurred can be sufficiently detected.

Accordingly, regardless of the combination of the transmission speeds Va and Vb of the pair of transmission lines 2 and 3 constituting the transmission system 1 to be measured, a code error in the transmission system 1 can be reliably detected.

(Second Embodiment) FIG. 5 is a block diagram showing a schematic configuration of a transmission-system code error measuring apparatus according to a second embodiment of the present invention. The same parts as those of the transmission-side code error measuring device of the first embodiment shown in FIG. Therefore, the detailed description of the overlapping part will be omitted.

In the transmission-side code error measuring device according to the second embodiment, the test data a output from the test data generator 6 is transmitted to the transmitter 7 and transmitted to the first data compressor 21. Is done. The transmitting unit 7 transmits the input test data a to the measuring terminal 14 via the downstream transmission line 2 of the transmission system 1 at the transmission speed Va specified for the transmission system 1 to be measured.

The receiving unit 10 of the measuring terminal 14
3 receives the test data a transmitted through the down transmission line 2 of the transmission system 1 from delivering as test data a ₂ received the second data compression unit 22. The second data compression unit 22 converts the input test data a ₂ into compressed data g ₁ having a bit length that is _１ ／ of the bit length of the original test data a ₂ by using a predetermined data compression method. Data compression. Second data compression unit 22 sends the compressed data g ₁ to the transmission unit 12.

As a data compression method, it is conceivable to thin out each bit data of the received test data a ₂ according to a predetermined rule for each block unit.

The transmission unit 12 transmits the compressed data g ₁ output from the second data compression unit 22 to the upstream transmission line 3 of the transmission system 1 at the transmission speed Vb specified for the transmission system 1 to be measured. And sends it out to the measuring device 13.

The receiving unit 9 of the measuring device 13 receives the compressed data g ₁ transmitted from the measuring terminal 5 via the upstream transmission line 3 of the transmission system 1 and detects a code error as the received compressed data g _2. To the unit 23.

The first data compression section 21 is adapted to perform the second data compression
Of the test data a before being transmitted to the transmission system 1 by using a predetermined data compression method to reduce the bit length of the original test data a by one.
The data is compressed into compressed data g having a bit length of / 3. The first data compression unit 21 sends the compressed data g to the code error detection unit 23.

The code error detector 23 compares the additional bit c output from the first block
By comparing the additional bits c ₂ received from judges that, if a mismatch bit is present, a code error in the transmission system 1 has occurred.

The code error output from the code error detector 23 is statistically processed to calculate the code error rate in the transmission system 1.

In the transmission-side code error measuring device of the second embodiment configured as described above, the number of bits on the upstream transmission line 3 is significantly smaller than the number of bits of the test data a transmitted on the downstream transmission line 2. only the compressed data g ₁ is transmitted. Therefore, even if the transmission speed Vb of the upstream transmission line 3 is lower than the transmission speed Va of the downstream transmission line 2, the measuring device 13 at one end of the transmission system 1 on the transmission side of the test data a will The occurrence of a code error can be sufficiently detected.

Therefore, similarly to the transmission-system code error measuring device of the first embodiment shown in FIG.
The transmission speed V of each of the downstream and upstream transmission lines 2 and 3
Regardless of the combination of a and Vb, the bit error rate of the transmission system 1 can be reliably calculated.

[0075]

As described above, in the transmission-side code error measuring apparatus according to the present invention, the test data received from the test data transmitting side is not subjected to the loopback to the transmitting side, but is subjected to block coding. The compressed data is looped back to the test data transmission side.

Therefore, on the test data transmission side, it is possible to sufficiently compare the data before transmission with the looped-back data. Therefore, it is possible to reliably detect a code error in the transmission system regardless of the combination of the transmission speeds in the pair of transmission lines constituting the transmission system to be measured.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a schematic configuration of a transmission-system code error measurement device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a transmission speed of each transmission line in a transmission system to be measured in a code error measurement device of the same transmission system.

FIG. 3 is a diagram showing a transition of test data and additional bits in a code error measurement device of the transmission system.

FIG. 4 is a diagram showing the transition of test data and additional bits in the bit error measurement device of the same transmission system.

FIG. 5 is a block diagram showing a schematic configuration of a transmission-system code error measurement device according to a second embodiment of the present invention;

FIG. 6 is a block diagram showing a schematic configuration of a conventional transmission-system code error measurement device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Transmission system 2 ... Downlink transmission line 3 ... Uplink transmission line 6 ... Test data generation part 7.12 ... Transmission part 9, 10 ... Reception part 13 ... Measuring device 14 ... Measuring terminal 15 ... First block coding part 16 ... Second block coding unit 17 ... Block division unit 18 ... Additional bit calculation unit 19,23 ... Code error detection unit 20 ... Error rate calculation unit 21 ... First data compression unit 22 ... Second data compression unit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Kazufumi Yuzuki, 2-10-1, Toranomon, Minato-ku, Tokyo NTT Mobile Communications Network Co., Ltd. (72) Inventor Akihiro Higashi 2-chome Toranomon, Minato-ku, Tokyo No. 10-1 NTT Mobile Communication Network Co., Ltd. (72) Inventor Shunsuke Kiyo 2-10-1 Toranomon, Minato-ku, Tokyo F-Term in NTT Mobile Communication Network Co., Ltd. (reference) 5K014 AA05 BA06 GA05 5K035 AA03 BB02 EE02 GG02 GG09

Claims (2)

[Claims] 1. A transmission-system code error measuring device for measuring a code error generated in a transmission process of digital data transmitted through a transmission system (1) capable of bidirectionally transmitting data by a loopback method. Provided at one end of the transmission system, test data transmitted from one end to the other end via one transmission path of the transmission system is divided into a plurality of blocks and block-coded,
A first block coding unit for obtaining additional bits (15)
A second block code provided at the other end of the transmission system, dividing test data received from the one end via the one transmission line into a plurality of blocks and performing block coding to obtain additional bits And an additional unit provided at the other end of the transmission system and transmitting the additional bit obtained by the second block encoding unit to the one end via the other transmission path of the transmission system. Bit transmission means (12), provided at one end of the transmission system, additional bits received from the other end via the other transmission path, and additional bits obtained by the first block encoder. By comparing
A code error measuring device for a transmission system, comprising: a code error detection unit (19) for detecting occurrence of a code error in the transmission system and a transmission path in which the code error has occurred. 2. A transmission-system code error measuring apparatus for measuring a code error generated in a transmission process of digital data transmitted through a transmission system (1) capable of bidirectionally transmitting data by a loopback method. A first data compression unit (21) that is provided at one end of a transmission system and that performs bit compression on test data transmitted from the one end to one end of the transmission system to the other end and outputs compressed data; And a second data compression unit (22) provided at the other end of the transmission system and bit-compressing test data received from the one end via the one transmission line and outputting compressed data.
Pressurized data transmission means (12) provided at the other end of the transmission system and transmitting compressed data output from the second data compression unit to the one end via the other transmission path of the transmission system; ), Provided at one end of the transmission system, comparing the compressed data received from the other end via the other transmission line with the compressed data output from the first data compression unit, A code error measuring device for a transmission system, comprising: a code error detection unit (23) for detecting occurrence of a code error in the transmission system.