JP3703599B2 - Pattern signal generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a pattern signal generating apparatus for measuring a system under test using a transmission path for transmitting a digital signal including a digital exchange as a system under test, and more particularly, to program memory in rows (or rows) and columns (or columns). ) And a pattern signal generating apparatus which is divided into a plurality of blocks to efficiently write or read the pattern.
[0002]
[Prior art]
First, the principle of the bit error measuring device will be described with reference to FIG.
[0003]
FIG. 6 is a block diagram showing the principle of the bit error measuring device. The pattern generation circuit 24 provided in the transmission unit 21 generates a desired pattern signal of either a PRBS (pseudo random pattern) signal 24a or a PRGM (programmed arbitrary pattern) signal 24b. The system under measurement 23 includes a transmission line 29 and a digital exchange 28, and transmits a pattern signal from the pattern generation circuit 24. The receiving unit 22 receives this pattern signal and detects an error in the pattern generated in the system under test 23. The configuration is as follows.
[0004]
The reference pattern generation circuit 32 receives a pseudo-random pattern signal and generates a reference pattern. The reference pattern generation circuit 32 includes nine shift registers (SR1 to SR9) and one EX-OR circuit 30. A pattern signal is input via the system 23 and the A side of the switch circuit 34. The bit error measurement circuit 38 includes an EX-OR circuit (also referred to as a coincidence circuit) 37 and a shift register 33. The EX-OR circuit 37 outputs the output of the shift register 33 and the output of the reference pattern generation circuit 32. A comparison and a mismatch are detected by comparison. The error counting circuit 35 counts the mismatch (error) output from the bit error measurement circuit 38 and the match. When the synchronization circuit 36 receives the count result of the bit error measurement circuit 38 and confirms that all the bits generated by the pattern generation circuit 24 have no errors continuously, the synchronization circuit 36 operates the switch 34 to the B side. Connecting. As a result, the reference pattern generating circuit 32 is self-running, and thereafter, the same pattern as the pattern of the pattern generating circuit 24 at that time is repeatedly generated regardless of the input pattern to the receiving unit 22. This state is called a self-running state.
[0005]
Bit errors are measured with reference to the signal output from the reference pattern generation circuit 32 in this free-running state.
[0006]
The pattern generation circuit 24 used in this bit error measuring device will be further described. The pattern generation circuit 24 includes a PRBS method 24a and a PRGM method 24b. The PRBS system 24a is an acronym for Pseudo-Random Binaly Sequence. For example, the reference pattern generation circuit 32 in the free-running state corresponds to this. In this example, nine shift registers (same as binary) are used, but if 31 are used, a pseudo random pulse pattern signal in which 1 and 0 are almost the same number of sets in a period of 2 ³¹ −1. Can be generated.
[0007]
The PRGM system 24b means that an arbitrary pattern signal is generated by the programmable memory, and an arbitrary pattern signal is generated by writing a pattern to be generated in a memory and sequentially reading the pattern.
[0008]
The reference program pattern generation circuit 25 outputs a reference pattern signal when the pattern generation circuit 24 generates a programmed arbitrary pattern signal (PRGM), and has the same configuration as the PRGM 24b. Similar to the synchronization circuit 36, the program pattern synchronization circuit 26 is for synchronizing with the pattern signal from the PRGM 24b. The program pattern synchronization circuit 26 controls the delay time of the pattern output from the reference program pattern generation circuit 25 for synchronization. So that it is controlled. The error rate is measured in the same manner as the measurement of the pseudo random pattern signal (PRBS) by switching the reference pattern by the switch 31.
[0009]
Both of these types are built in and can be switched and used as necessary.
[0010]
Next, the frame configuration of the pattern signal passing through the system under test 23 will be described with reference to FIG.
[0011]
FIG. 7 is a diagram showing a frame configuration of a pattern signal that passes through the system under test 23.
[0012]
In the figure, OH and INFO constitute a set of frames.
[0013]
OH (1) is referred to as Over Head 11 and includes fixed information of this frame. INFO (1) is Information (Information) 12, and this frame includes: Contains information to be communicated to the other party. The fixed information in OH (1) includes information necessary for the signal of this frame to pass through the exchange (information such as caller, callee, and billing).
[0014]
Further, the communication information in INFO (1) is, for example, encoded voice in a telephone.
[0015]
OH (2) and INFO (2) also contain information of properties similar to OH (1) and INFO (1), respectively.
[0016]
Next, the PRGM system 24b will be further described with reference to FIG.
[0017]
FIG. 8 is a block diagram showing a configuration for generating a PRGM pattern signal. As described in the pattern signal frame configuration shown in FIG. 7, the program pattern memory 39 outputs a pattern signal including the overhead 11 and the information 12 as one set, in order of the addresses of the memory, OH (1 ), INFO (1), OH (2), INFO (2)... A / R is an address terminal for writing, and D / R is a data terminal for writing. The contents written in the program pattern memory are sequentially read out by the address counter 40 and a program pattern signal is output. CLK is a clock input.
[0018]
As described above, in the PRGM system 24b of the conventional bit error measuring device, the desired pattern is stored in the memory for the required number of sets of the overhead 11 and the information 12 as one set, and these are sequentially read out. The pattern signal of FIG. 7 was generated.
[0019]
In the conventional PRGM system 24b, when changing the pattern, all the patterns written in the memory must be rewritten, and much time is required for rewriting, and a large program counter is used for writing and reading. It was necessary. Further, it was impossible to generate a PRBS pattern signal following the PRGM pattern signal.
[0020]
[Problems to be solved by the invention]
The present invention simplifies the writing of a pattern to a memory in the PRGM system, particularly writing and reading when a part thereof is changed, and can arbitrarily mix and output a PRGM pattern signal and a PRBS pattern signal. Provided is a pattern signal generator capable of performing the above.
[0022]
[Means for Solving the Problems]
A pattern signal generating apparatus according to the present invention includes a program memory 1 for storing a digital pattern signal written from the outside, and an address counter 2 for designating an address for sequentially reading the digital pattern signal written in the program memory. A pattern signal generation device comprising a pattern generation circuit 3 and a pseudo random pattern generation circuit 6 composed of a plurality of shift registers, wherein the program memory 1 has a plurality of row signals for dividing and writing the digital pattern signal. And a plurality of blocks (B ₁ , B ₂ ,..., B _N ) defined by columns, and the address counter 2 includes the plurality of blocks (B ₁ , B ₂ ,... , the block counter 4 for sequentially specifying the address of the B _N), the specified Is constituted by a bit length counter 5 which outputs an increment signal to the block counter at the count end with counts up to a predetermined bit length specified respectively for each block sequentially reading digital pattern signal of the designated block, The block counter shuts off the output of the digital pattern signal written to the block of the designated address and activates the pseudo random pattern generation circuit when the designated address becomes equal to a desired set value. And a control circuit 10 for outputting the signal.
[0023]
Furthermore, in the pattern signal generating apparatus according to the present invention, the block counter 4 is configured such that a value at the start of counting and a value at the end of counting can be set from the outside.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
The present invention partitions the memory area of the program memory into a plurality of blocks defined by a plurality of rows and a plurality of columns. Program data is written as a set of row and column. The block counter sequentially accesses the blocks of the memory, and the program data in the accessed block is sequentially read by the bit length counter. This is output as a digital pattern signal.
[0025]
The block counter can be set from the outside with the starting point number (the value at the start of counting) and the end point number (the value at the end of counting) that circulate, and the blocks within the set value Only are accessed (considered as valid data) and the other blocks are not accessed (considered as invalid data). The bit length counter is usually set to the bit length to be counted for each block, and for the block being accessed, the program data is read by the set bit length and the program is read by the set bit length and completed. In this case, an increment signal is output to the block counter.
[0026]
Further, the present invention includes a pseudo random pattern generation circuit, which operates the pseudo random pattern circuit when the block counter reaches a predetermined value, outputs a pseudo random pattern signal, and blocks the digital pattern signal. .
[0027]
This output is maintained until the bit counter counts the set bit length and the block counter is incremented.
[0028]
【Example】
An embodiment of the pattern signal generator of the present invention will be described with reference to FIGS.
[0029]
1 is a block diagram showing an embodiment of a pattern signal generator according to the present invention, FIG. 2 is a diagram showing block sections of a memory area of a program memory, FIG. 3 is a diagram showing details of a coincidence circuit, and FIG. FIG. 5 is a diagram showing a memory capacity for each block of the program memory, and FIG. 5 is a diagram showing a frame structure of a pattern signal.
[0030]
First, the configuration of an embodiment of the pattern signal generator of the present invention will be described.
[0031]
The program memory 1 has a memory area divided into a plurality of blocks, and data written in each block is accessed and read by the block counter 4 and the bit length counter 5.
[0032]
As shown in FIG. 2, the memory area of the program memory 1 is divided into 18 blocks by 9 rows and 2 columns. The first column of the first row is the first block, the second column is the second block, the first column of the second row is the third block, the second column is the fourth block, and is divided into the 18th block in order. ing. Overhead (OH) information 11 is written in the first column (hereinafter referred to as OH11) of each row, and information (INFO) information 12 is written in the second column (hereinafter referred to as INFO12). As a specific example, a memory capacity of 9 bytes is allocated to the OH 11 of each row. Each OH 11 is written with fixed information necessary for communication, for example, fixed information such as billing information. They can be further subdivided into multiple columns for each feature. In addition, a memory capacity of 261 bytes is allocated to the INFO 12 of each row. As information information put in each INFO 12, information that is a transmission target such as information obtained by encoding telephone voice is written. The pattern example of these information written in the program memory 1 is compatible with SDH (Synchronous Digital Hierarchy). In FIG. 1, A / R is a write address input terminal, and D / R is a write data input terminal.
[0033]
The address counter 2 includes a block counter 4 and a bit length counter 5. The block counter 4 is a counter for designating the addresses of the divided blocks 1 to 18 of the program memory 1. P. It is possible to set an initial value and an end value for counting addresses from U (not shown). When an address count of 3 to 14 is set, blocks 3 to 14 are sequentially output.
[0034]
The bit length counter 5 is a counter that sequentially designates addresses of information stored in the intra-block memory area designated by the block counter 4, and the count number up to the maximum bit length for each block can be set. The address of the memory area is specified by counting up to the value of the bit length, an increment command is output to the block counter 4, and the value of the block counter 4 is incremented.
[0035]
Here, the block counter 4 counts the upper digit address, the bit length counter 5 counts the lower digit address, the address of each block is specified by the upper digit address, and the information in the block is the lower digit address. It is specified by address.
[0036]
The pseudo random pattern generation circuit (PRBS) 6 includes a plurality of binary circuits provided with feedback circuits, and is the same as that conventionally used for bit error measurement of digital signals. The operation is turned on and off by an external command.
[0037]
The control circuit 10 includes a matching circuit 7, a first switch circuit 8, and a second switch circuit 9. The configuration of the coincidence circuit 7 will be described with reference to FIG. The coincidence circuit 7 includes a comparator 7a and an AND circuit 7b. One end of each of the five EX-OR circuits constituting the comparator 7a is connected to each bit of the block counter 4, and the other end is set from the outside by a CPU (not shown) or the like. In this example, 01100 is set. Now, when the input signal of the block counter 4 becomes a value indicating the twelfth block, that is, 01100, the five EX-OR circuits of the comparator 7a all match, and the AND circuit 7b outputs a match signal.
[0038]
The first switch circuit 8 is connected to the B side by the coincidence signal of the coincidence circuit 7 and outputs the output of the bit length counter to the pseudo random pattern generation circuit 6 to generate a pseudo random pattern. The second switch circuit 9 is connected to the B side by the coincidence signal of the coincidence circuit 7 and outputs a pseudo random pattern. This pseudo random pattern is generated only for the bit length set in the bit length counter 5, and when the count value of the block counter 4 is changed by the increment output of the bit length counter 5, the first switch circuit 8 is connected to the A side. While the generation is stopped, the second switch circuit 9 is connected to the A side, and the program pattern generated by the program pattern generation circuit 3 is output.
[0039]
Next, the operation of this embodiment will be described. FIG. 4 shows the memory capacity of the program memory 1 in an overlapping manner from the first block to the 18th block. The configuration of the rows and columns in the memory area of the program memory 1 is as described in FIG. The odd-numbered block (OH11) in FIG. 2 has a memory capacity of 9 bytes, and overhead information can be written. The even-numbered block (INFO12) can write information information having a memory capacity of up to 256 bytes. The data written in the program memory 1 may be as small as it is within the memory capacity of each block.
[0040]
The information written in the program memory 1 is accessed in the corresponding block by the count value of the block counter 4. That is, when the count value of the block counter 4 changes from 1 to 18, the first block to the 18th block are accessed in order according to this. Each information in the memory area of the block accessed by the block counter 4 is accessed and read bit by bit by the address count value of the bit length counter 5. The address count value range or bit length range of the bit length counter 5 can be set from the outside by a CPU (not shown) or the like, and usually the same address count value as the bit length written in the block is set. However, when an address count value having a bit length shorter than the written bit length is set, the information in the subsequent memory area is not read and becomes invalid. When the pseudo random pattern (PRBS) is generated, the count value of the bit length counter 5 is set so as to read out only the necessary bits of the pseudo random pattern (PRBS) regardless of the memory contents of the program memory 1. .
[0041]
When the bit length counter 5 counts up to the set address count value and outputs an increment signal to the block counter 4, the block counter increments the address count value by one. This block counter 4 normally counts from 1 to 18 and then returns to 1. However, if the count range can be set from the outside, for example, a CPU (not shown), and the setting counter is set from 3 to 8, Since the memory of the third block to the eighth block is sequentially read and the memory areas of the first block, the second block, and the eleventh to eighteenth blocks are not accessed, the reading is not performed. In other words, information written from the third block to the eighth block is read as valid data, and information written in other blocks is not read as invalid data.
[0042]
The pattern signal read in this way will be described with reference to FIG. FIG. 5A shows a frame structure of the pattern signal when all the blocks from the first block to the 18th block are valid, and B ₁ to B ₁₈ are repeatedly read and output. FIG. 5B shows a frame structure of the pattern signal when 6 blocks from the third block to the eighth block are valid. B ₃ to B ₈ are repeatedly read and output.
[0043]
When a PRBS signal is inserted into the fourth block, if 10000 is set in the coincidence circuit 7, the control circuit 10 operates to output a PRBS signal when the block counter 4 indicates the value of the fourth block. The bit length of the PRBS to be output is determined by the bit length set externally in the bit length counter 5 at that time.
[0044]
In the above embodiment, the program memory 1 has been described with reference to FIGS. 2 and 4 in which the first column and the second column are 9 bytes and 261 bytes, respectively. In the case of SDH, the first column is 3 × N bytes, The column is often used with a capacity of 87 × M (N and M are integers) bytes. Therefore, the program memory 1 can be defined by dividing the first column into 3 × N small blocks and the second column into 87 × M small blocks. For example, if the first column is 9 bytes and the second column is 261 bytes, the first column can be subdivided into 9 small columns and the second column can be subdivided into 261 small columns. the L _0, ···, has n columns of L _n-1, L ₀ ~L until ₈ is an area of 0H11, also the present invention the up L ₉ ~L ₂₆₉ defines the area of INFO12 The configuration and operation are the same.
[0045]
As described in detail in the above embodiments, the program memory 1 is divided into a plurality of blocks, a pattern is stored, and this can be read and accessed in units of blocks, and can be read to a desired bit length in the block. Can do. Note that a PRBS signal can be output by designating an arbitrary block number. Further, when changing the information in the program memory 1, only the information of the block corresponding to the changed portion needs to be rewritten, and the rewriting time of the program memory 1 can be shortened.
[0047]
【The invention's effect】
The pattern signal generator of the present invention has a program memory 1 for storing a digital pattern signal written from the outside, and a program pattern having an address counter 2 for designating an address for sequentially reading the digital pattern signal written in the program memory. A pattern signal generation device comprising a generation circuit 3 and a pseudo random pattern generation circuit 6 comprising a plurality of shift registers, wherein the program memory 1 has a plurality of rows and The address counter 2 is composed of areas of a plurality of blocks (B ₁ , B ₂ ,..., B _N ) defined by columns, and the address counter 2 has the plurality of blocks (B ₁ , B ₂ ,. a block counter 4 for sequentially specifying the address of the B _N), said specified Bro Counts up to a predetermined bit length specified respectively for each click is constituted by a bit length counter 5 which outputs an increment signal to the block counter at the end of counting with sequentially reading digital pattern signal of the designated block, The block counter shuts off the output of the digital pattern signal written to the block of the designated address and activates the pseudo random pattern generation circuit when the designated address becomes equal to a desired set value. Since the control circuit 10 that outputs the signal is provided, the pseudo-random pattern can be output at an arbitrary location with an arbitrary bit length.
[0048]
In the pattern signal generator according to the present invention, the block counter 4 can set the value at the start of counting and the value at the end of counting to be set from the outside. Can be done in units.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an embodiment of the present invention.
FIG. 2 is a diagram showing a block division of a memory area of a program memory.
FIG. 3 is a diagram showing details of a coincidence circuit.
FIG. 4 is a diagram showing a memory capacity for each block of a program memory.
FIG. 5 is a diagram illustrating a frame configuration of a pattern signal.
FIG. 6 is a block diagram showing the principle of a bit error measuring device.
FIG. 7 is a diagram showing a frame configuration of a pattern signal passing through a system under measurement.
FIG. 8 is a block diagram showing a configuration for generating a PRGM pattern signal.
[Explanation of symbols]
1 Program Memory 2 Address Counter 3 Program Pattern Generation Circuit 4 Block Counter 5 Bit Length Counter 6 Pseudo Random Pattern Generation Circuit 7 Matching Circuit 8 First Switch Circuit 9 Second Switch Circuit 10 Control Circuit 11 Overhead (OH)
12 Information (INFO)

Claims (2)

Program pattern generation circuit (3) having a program memory (1) for storing a digital pattern signal written from the outside and an address counter (2) for designating an address for sequentially reading the digital pattern signal written in the program memory And a pseudo random pattern generation circuit (6) composed of a plurality of shift registers, wherein the program memory (1) has a plurality of low-level write signals for dividing and writing the digital pattern signal. And multiple blocks defined by columns (B ₁ , B ₂ ,..., B _N ) Each area,
The address counter (2) includes the plurality of blocks (B ₁ , B ₂ , ..., B _N The block counter (4) for sequentially designating addresses), and counting up to a predetermined bit length designated for each designated block, sequentially reading out the digital pattern signals in the designated block and at the end of counting And a bit length counter (5) that outputs an increment signal to the block counter, and the block counter writes the block at the designated address when the designated address becomes equal to a desired set value. And a control circuit (10) for cutting off the output of the digital pattern signal and operating the pseudo-random pattern generation circuit to output the signal. 2. The pattern signal generator according to claim 1, wherein the block counter (4) is capable of setting a value at the start of counting and a value at the end of counting from the outside .

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