JPH05260123A - Communication equipment - Google Patents

Abstract

PURPOSE:To prevent improper shift-down of the transmission rate due to a burst error. CONSTITUTION:A control part 15 receives a training signal of prescribed bit data sent from a counter machine from a data decoding part 13 and monitors it for a prescribed period to detect error bits due to bit corruption and counts the number of error bits. The monitor period is divided by the bit corruption detection points, and the number of proper bits in each divided period is counted, and the sum total of squares of numbers of proper bits in respective divided periods is calculated. A transmission control part 16 discriminates whether communication is possible or not in accordance with the calculated value of the number of proper bite. When this calculated value of the number of proper bits is larger than a prescribed value, the line condition and the transmission speed are judged to be satisfactory to respond to the counter machine with a reception preparation confirmation signal through a modulating/demodulating part 12 and a line control part 11. If it is equal to or smaller than the prescribed value, the transmission speed is judged to be improper to respond to the counter machine with a training failure signal, and the change of the transmission rate is requested.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device such as a facsimile device or a data transmission device, and more particularly to a communication device capable of properly setting a transmission rate.

[0002]

2. Description of the Related Art Conventionally, a communication device such as a facsimile device has been widely used. However, in order to perform data transmission with few errors, this facsimile device performs a modem training before transmitting image information to transmit a transmission speed and a modulation method. The transmission rates are matched. Modem training is performed to set the highest possible transmission rate between communication devices, and if the training fails, the transmission rate is sequentially switched to a lower transmission rate and retried.

In a training signal TCF (Training Check Fielde) used for modem training, all bit data are predetermined to be "0". When this training signal TCF is sent from the opposite device in accordance with a predetermined transmission rate, the receiving side receiving the training signal monitors the bit data of the training signal for a predetermined period, and garbles bits in the training signal. The number of generated error bits is counted, and whether or not communication is possible at the currently training transmission rate is determined according to the number of error bits.

That is, if the number of error bits is less than a predetermined value, it is judged that the condition of the line and the transmission rate are good, and the reception preparation confirmation signal CFR (Confirmation) is transmitted so that the image information is transmitted at the trained transmission rate. t
o Receive). If the number of error bits is greater than or equal to a predetermined value, it is determined that the transmission rate is inappropriate, a training failure signal FTT (Failure to Train) is responded, and a change in the transmission rate is requested. Upon receiving the training failure signal FTT, the opposite device changes the transmission rate to a one-step lower rate and tries training again.

[0005]

However, in such a conventional communication apparatus, since it is determined whether or not communication is possible according to the number of garbled bits, garbled bits are generated on average due to normal random noise. It is effective during normal communication, but it is generated during normal communication when garbled bits (such errors are sometimes called burst errors) are caused by sporadic / transient noise, so-called impulse noise. The number of burst errors that do not occur may be added as a garbled number during training, and the transmission rate may be unduly downshifted. In this way, if the transmission rate is set to be inappropriately low, it is necessary to communicate in the state of low rate thereafter, which is disadvantageous in terms of communication time and cost.

Therefore, in the conventional communication device, as described in, for example, Japanese Patent Application Laid-Open No. 57-26961, when a connection is made at a speed lower than the maximum transmission speed of the transmitter / receiver, a predetermined communication speed is set. Various proposals have been made to set the fastest transmission speed, such as automatically returning to modem training every time a few manuscripts are sent and reviewing the transmission speed to shorten the communication time. ..

However, even if the above configuration is adopted, if a burst error occurs during training, the transmission rate is once shifted down to a low transmission rate. Therefore, the transmission rate itself is inappropriately downshifted due to the burst error. Did not prevent. Therefore, the invention according to claim 1 provides a communication device for preventing inappropriate downshifting of a transmission rate due to a burst error by determining whether or not communication is possible based on an appropriate number of bits existing in a garbled bit. The purpose is to

According to the second aspect of the present invention, whether or not communication is possible is determined based on the time between garbled bits.
An object of the present invention is to provide a communication device that prevents inappropriate downshifting of the transmission rate due to a burst error. Further, the invention according to claim 3 judges pass / fail of each period obtained by dividing the monitoring period for each unit time according to the number of garbled bits, and judges whether communication is possible based on the pass / fail ratio of each divided period. An object of the present invention is to provide a communication device that prevents inappropriate downshifting of the transmission rate due to a burst error.

It is another object of the present invention to provide a communication device which improves the accuracy of communication availability judgment by adding the number of error bits to the judgment element.

[0010]

The invention according to claim 1 is
In order to achieve the above object, a training signal of predetermined bit data sent from an opposite device is monitored for a predetermined period in accordance with a predetermined transmission rate, and an error bit causing a garbled bit in the training signal is detected. A detector,
In the communication device including an error bit counter that counts the number of detected error bits, and a determination unit that determines whether communication can be performed at a transmission rate currently being trained according to the number of error bits counted When the unit detects garbled bits, the monitoring period is divided, and an appropriate bit counter for counting the appropriate number of bits in each divided period and a sum of squares of the appropriate number of counted bits in each divided period are calculated. An arithmetic unit is provided, and whether the communication is possible or not at the transmission rate currently being trained is judged by the judging unit according to the calculated value of the appropriate number of bits.

Further, the invention according to claim 2 is characterized in that, in order to achieve the above object, the appropriate number of bits is replaced with time. In order to achieve the above-mentioned object, the invention according to claim 3 monitors a training signal of predetermined bit data sent from an opposite device in accordance with a predetermined transmission rate for a predetermined period, and in the training signal, A detection unit that detects erroneous error bits, an error bit counter that counts the number of detected error bits, and determines whether communication is possible at the transmission rate currently being trained according to the number of counted error bits. In the communication device including the determining unit, the detecting unit divides the monitoring period in each unit time to detect an error bit in each divided period, and the error bit counter detects an error bit in each divided period. Counts the number of errors and compares the counted number of error bits with a predetermined value to judge whether each bit is garbled or not. That includes a judgment unit, characterized in that to determine whether the communication by the transmission rate of the current during the training by the determining portion in accordance with the number of relative merits of quality determination has been divided period.

In order to achieve the above object, the invention according to claim 4 is characterized in that the number of error bits is added as a judgment factor of the judgment section.

[0013]

According to the present invention having the above structure, the monitoring period is divided at the time when the detection unit detects garbled bits, and the appropriate bit counter counts and counts the appropriate number of bits in each divided period. In addition, the sum of squares of the appropriate number of bits in each divided period is calculated by the calculation unit, and the judgment unit judges whether or not communication is possible at the transmission rate currently being trained according to the calculated value.

Further, in the invention having the above-mentioned structure, the monitoring period is divided at the time when the detection unit detects the garbled bit, the time between bit garbled is measured by the measurement timer, and the measured bit is measured. The sum of squares of the ghost time is calculated by the calculation unit, and the judgment unit judges whether or not communication is possible at the transmission rate currently being trained according to the calculated value.

Further, in the invention having the above-mentioned configuration, the monitoring period in the detecting section is divided into unit time units to detect an error bit in each divided period, and the error bit counter is used to detect each divided period. The number of error bits for each is counted, and the number of error bits counted is compared with a predetermined value in the determination unit to determine whether the garbled bits are good or bad for each divided period, and whether the number of divided periods is good or bad is determined. Then, the judging unit judges whether or not communication is possible at the transmission rate currently being trained.

Further, in the invention having the above-mentioned structure, the number of error bits is taken into consideration as a judgment factor of the judgment unit, and it is judged whether or not communication is possible at the transmission rate currently being trained.

[0017]

EXAMPLES The present invention will be described below based on examples.
FIG. 1 is a diagram showing a facsimile apparatus as a communication apparatus according to an embodiment of the invention described in any one of claims 1 to 4, FIG. 1A is a block diagram thereof, and FIG. 1B is training. 6 is a timing chart showing the occurrence status of garbled bits during a signal monitoring period.

First, the structure of the embodiment of claim 1 will be described. In FIG. 1A, the line control unit 1
1 secures a line necessary for communication with the opposite device. The modulation / demodulation unit 12 demodulates the TCF signal, the image information and the like received via the line control unit 11 and, at the same time, transmits the image information and the like at a predetermined transmission rate. Data decoding unit 13
Cancels the encoding of the demodulated received data and decodes it to the original data. The memory unit 14 stores the decoded reception data (mainly image information) and also the transmission data. When transmitting the transmission data, the encoding unit (not shown) encodes the transmission data and transmits it to the opposite device via the modulation / demodulation unit 12 and the line control unit 11.

The control unit 15 is for controlling the facsimile apparatus and includes a detection unit, an error bit counter, an appropriate bit counter, and a calculation unit, which are characteristic components of the present invention. The detection unit receives the training signal of the predetermined bit data sent from the opposite device according to the predetermined transmission rate from the data decoding unit 13, monitors the training signal for a predetermined period (t ₂ shown in FIG. 1B), and performs the training. Detects error bits that cause garbled bits in the signal.
The error bit counter counts the number of error bits detected by the detection unit. The proper bit counter is
When the detection unit detects garbled bits, the monitoring period is divided, and the appropriate number of bits in each divided period is counted. The computing unit computes the sum of squares of the proper number of bits in each divided period counted by the proper bit counter.

The transmission control unit 16 is for controlling the line control unit 11 and the modulation / demodulation unit 12 to execute communication at a predetermined transmission rate, and includes a judgment unit which is a characteristic component of the present invention. The determination unit determines whether the communication is currently performed at the transmission rate according to the error bit number counted by the error bit counter or the calculated value of the proper bit number calculated by the calculation unit according to the present invention. Judge whether or not. That is, in the present invention, if the calculated value of the appropriate number of bits is equal to or more than a predetermined value, it is determined that the condition of the line and the transmission rate are good, and the image information is transmitted at the trained transmission rate.
A reception preparation confirmation signal CFR (Confirmation to Receive) is sent to the opposite device via the modulation / demodulation unit 12 and the line control unit 11. On the other hand, if the calculated value of the proper number of bits is less than or equal to the predetermined value, it is determined that the transmission speed is inappropriate, a training failure signal FTT (Failure to Train) is responded, and the opposite device is requested to change the transmission rate. .. Upon receiving the training failure signal FTT, the opposite device changes the transmission rate to a one-stage lower rate and executes training again.

Next, the operation will be described. FIG. 2 is a diagram showing a training signal TCF in the facsimile apparatus. FIG. 2A shows its communication flow and FIG. 2B shows its bit data. FIG. 2A shows a general G3 facsimile communication procedure. In order to determine a modem rate suitable for the current line state, image information data P
The training signal TCF is sent before transmitting IX. As shown in FIG. 2B, this training signal TCF continuously transmits data “0” for a maximum of t ₀ = 1.5 seconds. As described above, according to the conventional technique, the training signal TCF is monitored on the receiving side, and whether the CFR or the FTT is transmitted depending on the size of the number of garbled bits in which the data of “0” is changed to “1” is determined. Had decided.

For the monitoring period for garbled bits, for example, the preceding and following t ₁ and t ₃ seconds in t ₀ seconds are ignored, and the central portion t ₂ seconds is set as the period. Then, when the total number of data for t ₂ seconds is 100, for example, and the total number of garbled bits is 30 or more, FTT is returned, and training is performed again at a modem rate below that. However, with only the total number of garbled bits, as shown in or of FIG. 1B, when garbled bits are intensively generated due to a single noise, etc. There is a possibility that shift down may occur due to bit garbled portions. Also, comparing with the figure, it is clear that the line status shown in is good when viewed as a whole except for the bit garbled (A section) that is intensively generated by a sporadic noise. Since the total number of garbled bits is the same, the same judgment is made regarding the quality of training.
In addition, in FIG. 1B, a garbled bit (determined as an error) is shown by a bar line portion.

Therefore, in the present embodiment, the sum of squares of the proper number of bits (the number of consecutive data) existing continuously in the garbled bits is calculated, and CFR or FT is calculated according to the magnitude of the calculated value.
It is determined which of T is to be responded. First, the control unit 15 determines the number of consecutive “0” data until bit garbling occurs.
Counting by the appropriate bit counter of
Accumulate in. Let Z ₀ be the number of continuous data at this time,
After that, when the garbled bits occur, the monitoring period t
Divide ₂ into "0" after garbled bits occur within each divided period
The number of consecutive data Z ₁ , Z ₂ , ...
Accumulate in.

Monitoring period t₂When the
Continuation number, that is, proper bit number₀, Z ₁, Z₂,… Squared
CFR / FTT is judged by the sum of the above. For example,
When the total number of bits in the training monitoring period is 100
In addition, there is no garbled bit in FIG.
Number of continuous data Z₀Is Z₀= 100. Also, FIG.
In (b), the first garbled bit is the 6th bit
One bit of "0" data is generated between each occurrence.
Assuming that there are₀= 5, Z₁~₉= 1,
Z_Ten= 76.

Further, in FIG. 1B, if it is assumed that the first bit garbled occurs at the 10th bit and 9 bits of "0" data continuously exist in each bit garbled, Z ₀ ~ ₈ = 9, and Z ₉ = 10. Also,
In FIG. 1 (b), the first bit garble occurs at the 6th bit, and 1 bit of "0" data is provided between the 1st to the 5th bit garments, and the 5th and 6th bit garbles are present. If it is assumed that "0" data is continuous for 9 bits and that "0" data is continuously present for 19 bits in each of the 6th to 8th bit garbled, Z
_{0 = 5, Z 1 ~ 4} = 1, Z 5 = 9, Z 6 ~ 8 = 19, Z
₉ = 20.

Further, in FIG. 1 (b) (if no part A), the assumption of the figure, Z ₀ ~Z ₄ = 19
Becomes Here, the number of continuous data Z _x (x = 0, 1, 2,
...) is counted by the appropriate bit counter of the control unit 15 and accumulated in the memory unit 14. When the monitoring period t ₂ ends, the continuous data number Z _x accumulated in the memory unit 14
Is read by the control unit 15, and the sum of squares (calculation value N) is calculated by the calculation unit. The determination unit of the transmission control unit 16 determines which of CFR / FTT is to be responded by the calculated value N.

An example of calculation in FIG. 1 (b) is shown below. No error (x = 0 of Z _x ) N ₁ = ΣZ _x ² = Z ₀ × Z ₀ = 100 × 100 = 1000
0 Number of errors 10 (x = 0 to 10 of Z _x ) N ₂ = ΣZ _x ² = 25 + 1 + 1 + 1 + 1 + 1 + 1 + 1 + 1 + 5776 = 5810 Number of errors 9 (Z _x X = 0 to 9) N ₃ = ΣZ _x ² = 81 + 81 + 81 + 81 + 81 + 81 + 81 + 81 + 81 + 100 = 829 Number of errors 9 (Z _x x = 0 to 9) N ₄ = ΣZ _x ² = 25 + 1 + 1 + 1 + 1 + 361 + 361 + 361 + 400 = 1512 Number of errors 4 ( _x of x x = 0 to 4) N ₅ = ΣZ _x ² = 361 + 361 + 361 + 361 + 400 = 1844 As described above, the calculated values N _{1 to} N ₅ are the data monitoring time t
Calculated from the total number of bits of data in ₂ according to the variation in bit garbled.
Even if the number of garbled bits is the same or many, different values are calculated for each. For this reason, the determination unit of the transmission control unit 16 responds with the training failure signal FTT only when it determines the calculated value N ₃ that is less than the threshold value of, for example, about “1000”. On the other hand, in other cases, the reception preparation confirmation signal CFR is returned.

As described above, in this embodiment, the proper number of bits existing in the garbled bits, that is, the number of consecutive data Z
Whether the main communication is possible or not based on the transmission rate currently being trained is determined based on the total value N of the squares of _x , so that the modem rate is prevented from being inappropriately downshifted due to a single noise during modem training. Therefore, it is possible to perform transmission at a higher modem rate, reduce the communication charge, and enable more communication.

The invention according to claim 2 will be described below based on embodiments. First, regarding the embodiment described in claim 2,
The configuration will be described. In the above-described embodiment, the sum total value N of the squares thereof is calculated based on the proper number of bits existing in the garbled bits, that is, the number of continuous data Z _x, and based on this N, whether the main communication is possible or not at the transmission rate currently being trained Although it is determined, in the present embodiment, the continuous data number Z _x is replaced with the garbled time.

That is, in FIG. 1A, the control unit 1
The reference numeral 5 is provided with a measurement timer, such as a soft clock, instead of the proper bit counter, and measures the garbled time by this measurement timer. The measured value is stored in the memory unit 14 in the same manner as the continuous data number Z _x . After the end of the monitoring period t ₂ , the calculation unit of the control unit 15 calculates the sum of squared measurement values, that is, N. The determination unit of the transmission control unit 16 determines whether or not communication can be performed at the transmission rate currently being trained based on the calculated value N, as in the above embodiment. The operation and effect of this embodiment are the same as those of the above-mentioned embodiment, and will be omitted.

The invention according to claim 3 will be described below based on embodiments. First, regarding the embodiment described in claim 3,
The configuration will be described with reference to FIG. As shown in FIG. 1B, the monitoring period t ₂ is divided for each unit time T, and the detection unit of the control unit 15 detects an error bit (bit error) for each divided period T. The number of detected error bits is counted by the error bit counter of the control unit 15 for each divided period T.

Here, the control section 15 is provided with a judging section which is a characteristic constituent element of the present embodiment, and the garbled bit number counted for each divided period T by this judging section is compared with a predetermined value. Then, the quality of the garbled bits is determined for each divided period T. Next, the determination unit of the transmission control unit 16 determines whether or not the main communication is possible based on the transmission rate currently being trained, according to the quality of the determined number of divided periods.

Next, the operation will be described. In the present embodiment, the number of garbled bits during the monitoring period t ₂ of the training signal TCF is not determined throughout, but the number of garbled bits per unit time T is counted by a soft clock, and the individual unit time T is calculated. On the other hand, CFR (good) / FTT
(No) is determined. The pass / fail result is stored in the memory unit 1.
4, and when the TCF monitoring period t ₂ ends, it is finally determined which of CFR / FTT is to be returned to the opposite device according to the number of CFR / FTTs stored in the memory unit 15. ..

For example, if there are two or more garbled bits in the monitoring period per unit time T, FTT, and if less than 1, CTT.
Assuming that the quality results of FR are accumulated, the final judgment result M of FIG. 1 (b) is as follows. No error M ₁ = CFR, CFR, CFR, CFR → CFR number of errors 10 M ₂ = FTT, CFR, CFR, CFR → CFR number of errors 9 M ₃ = FTT, FTT, FTT, FTT → FTT number of errors 9 M ₄ = FTT, CFR, CFR, CFR → CFR number of errors 4 M ₅ = CFR, CFR, CFR, CFR → CFR As described above, the determination results M _{1 to} M ₅ are bit-averaged during the monitoring period per unit time T. The response of the training failure signal FTT is determined only when the number of garbled is 2 or more, and otherwise, the response of the reception preparation confirmation signal CFR is determined.

As described above, in the present embodiment, whether or not the main communication is possible at the transmission rate currently being trained is judged based on the quality of the number of pass / fail judgments per unit time T. It is possible to avoid inappropriate downshifting of the modem rate due to noise, etc., and it becomes possible to transmit at a higher modem rate,
Communication charges can be reduced and more communication can be performed.

The invention according to claim 4 will be described below based on embodiments. In the present embodiment, the conventional total number of garbled bits is added as a determination factor for the determination unit. For example, even when it is determined that the reception preparation confirmation signal CFR is to be responded according to the embodiments of claims 1 to 3, if the total number of garbled bits is equal to or larger than a predetermined value, the training failure signal FTT is switched to the response. In the embodiment of claim 3, the unit time T
As a result of the pass / fail judgment, CFR (good) and FTT
If the (failure) is the same, C
It is determined which signal, FR / FTT, responds. In this way, by considering the total number of garbled bits in the related art, a more accurate line state is grasped by the combination, and the optimum response signal is transmitted.

As described above, in the present embodiment, by adding the bit garbled number to the determination element, it is possible to improve the accuracy of determination of communication availability in training. In the above embodiment, the G3 facsimile is described as an example, but the present invention can be applied to all communication devices that perform training using predetermined data.

[0038]

As described above, according to the communication device of the first aspect of the present invention, the monitoring period is divided at the time when the detection unit detects the garbled bit, and the appropriate bit counter is used to divide the monitoring period. The proper number of bits is counted, the sum of squares of the proper number of bits counted in each divided period is calculated by the calculation unit, and the determination unit determines whether or not communication is possible at the transmission rate currently being trained according to the calculated value. Therefore, it is possible to avoid improperly shifting down the transmission rate due to sporadic noise during training, etc., enabling transmission at a higher transmission rate, reducing communication charges and enabling more communication. Become.

According to the communication device of the second aspect of the invention, the monitoring period is divided at the time when the detection unit detects the garbled bit, and the time between bit garbled is measured by the measurement timer and measured. The sum of squares of time between garbled bits is calculated by the calculation unit, and the judgment unit judges whether communication is possible at the transmission rate currently being trained according to the calculated value, so it is inappropriate due to sporadic noise during training. It is possible to prevent the transmission rate from being downshifted, and it is possible to perform transmission at a higher transmission rate, reduce the communication charge, and enable more communication.

According to the communication device of the third aspect of the present invention, the monitoring period in the detecting unit is divided into unit time units to detect an error bit in each divided period, and the error bit counter is used to divide each unit. The number of error bits for each period is counted, and the number of error bits counted is compared with a predetermined value in the determination unit to determine whether the garbled bits are good or bad for each divided period. According to the determination section, whether or not communication is possible at the transmission rate currently being trained is determined, so it is possible to avoid improper downshifting of the transmission rate due to sporadic noise during training, etc. Can be transmitted, the communication fee can be reduced and more communication can be performed.

Further, according to the communication device of the present invention, the number of error bits is added as a judgment factor of the judgment unit to judge whether or not communication is possible at the transmission rate currently being trained. It is possible to improve the accuracy of determining whether or not it is possible.

[Brief description of drawings]

FIG. 1 is a diagram showing a facsimile device as a communication device according to an embodiment of the invention described in any one of claims 1 to 4, FIG. 1A is a block diagram thereof, and FIG. 7 is a timing chart showing the occurrence status of garbled bits during the training signal monitoring period.

FIG. 2 is a training signal T in a facsimile machine.
It is a figure which shows CF, the figure (a) shows the communication flow, and the figure (b) shows the bit data.

[Explanation of symbols]

15 control unit (detection unit, error bit counter, proper bit counter, arithmetic unit) 16 transmission control unit (determination unit) TCF training signal CFR reception preparation confirmation signal FTT training failure signal Z _x continuous data number (proper number of bits)

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H04N 1/00 106 C 7046-5C 1/32 K 2109-5C

Claims (4)

[Claims] 1. A detection unit for monitoring a training signal of predetermined bit data sent from an opposite device according to a predetermined transmission rate for a predetermined period, and detecting an error bit in which the bit is garbled in the training signal. In the communication device, an error bit counter that counts the number of detected error bits, and a determination unit that determines whether communication can be performed at a transmission rate currently being trained according to the counted error bit number, When the detection unit detects garbled bits, the monitoring period is divided, and an appropriate bit counter that counts the appropriate number of bits in each divided period and the sum of squares of the appropriate number of bits in each counted divided period are calculated. And a calculation unit that performs training according to the calculated value of the appropriate number of bits, Communication apparatus characterized by determining the communication availability. 2. The communication device according to claim 1, wherein an appropriate number of bits is replaced with time. 3. A detection unit for monitoring a training signal of predetermined bit data sent from an opposite device in accordance with a predetermined transmission rate for a predetermined period and detecting an error bit in which the bit is garbled in the training signal. In the communication device, an error bit counter that counts the number of detected error bits, and a determination unit that determines whether communication can be performed at a transmission rate currently being trained according to the counted error bit number, The monitoring period in the detection unit is divided into unit times to detect error bits in each divided period, and the number of error bits in each divided period is counted by the error bit counter, and the counted number of error bits is determined. Equipped with a judgment unit that judges whether the bit is garbled or not in each divided period by comparing it with the value. Communication apparatus characterized by determining whether the communication by the transmission rate of the current during the training by the determining portion in accordance with the number of relative merits of. 4. The communication device according to claim 1, wherein the number of error bits is added as a determination factor of the determination unit.