JPH0795200A - Method and device for sampling transmission data - Google Patents

Abstract

PURPOSE:To prevent disable transmission by sampling data at a low frequency when traffic of a transmission line is not excellent and sampling data at a high frequency when the traffic is excellent so as to send data quantity in response to the traffic state of the transmission line. CONSTITUTION:A traffic monitor means 22 confirms a traffic of a transmission line by counting a bit number used before included in a transmission packet. A sampling generating means 18 outputs a sampling signal with a low frequency when the traffic is not excellent and a sampling signal with a high frequency when the traffic is excellent based on the result of confirmation respectively. Thus, data quantity in response to the traffic of the transmission line is sent.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for sampling transmission data, and more particularly to a method and apparatus for sampling data in a local area network (LAN).

[0002]

2. Description of the Related Art FIG. 3 is a block diagram of a conventional master station of a local area network.

In the A / D conversion means 19, analog data is converted into digital data by the sampling signal of the predetermined frequency generated by the sampling signal generation means 18, and the digital data is once stored in the transmission buffer 14 according to the instruction of the transmission buffer controller 17. Buffered. For the transmission data buffered in this way, the address D of the transmission source device is added by the control bit adding means 16.
A, the address SA of the transmission destination device is attached, and transmitted as an optical signal via the E / O conversion means (electrical signal / optical signal conversion means) 1 via the selector 21 described later.

On the other hand, the received signal obtained through the O / E conversion means (optical signal / electrical signal conversion means) 2 is input to the packet header detection means 11 and the source address DA included in the header of the received packet, The destination address SA and the used bit USD indicating whether the packet is a used packet are verified.

Here, when the used packet (USD = 1) and the transmission destination address SA is its own device, the reception buffer controller 12 is operated to receive the reception packet from the O / E conversion means 2 in the reception buffer. 15 and then D according to the sampling signal generated by the sampling frequency generating means 18 and having the same frequency as that at the time of transmission.
The signal is D / A converted by the A / A conversion means 20 and is input to, for example, a telephone as an analog signal.

The used bit USD detected by the packet header detecting means 11 is the transmission buffer controller 17
Also, the transmission buffer controller 17 receives the use bit USD and outputs a selector control signal for controlling the selector 21. That is, when the received packet is unused (USD = 0), the selector 21 puts the data from the transmission buffer 14 on the unused packet and outputs it, and when the transmitted packet is already used (U
SD = 1), the selector 21 outputs the input packet obtained from the O / E conversion means 2 as it is.

[0007]

In the above conventional structure, the frequency of the sampling signal generated by the sampling signal generating means 18 is fixed.

On the other hand, when the amount of transmission data increases, the transmission data is kept waiting in the transmission buffer 14 until an empty packet arrives. However, since the sampling frequency in the A / D conversion means 19 is constant, the transmission buffer 14 may overflow and become incapable of transmission when the amount of transmission data further increases, which is inconvenient.

The present invention has been proposed in view of the above conventional circumstances, and an object of the present invention is to provide a transmission data sampling method and apparatus capable of adjusting the transmission amount according to the traffic state of the transmission path. It is what

[0010]

To achieve the above object, the present invention employs the following means. That is, FIG.
As shown in, after analog data is sampled at a predetermined frequency and digitally converted by the A / D conversion means 19,
In the data sampling method when various control bits are added by the control bit adding means 16 and transmitted, traffic monitoring means 22 for monitoring the traffic state of the transmission path based on the state of the used bit USD obtained from the transmission data, Sampling signal generating means 18 for generating a sampling signal having a frequency corresponding to the traffic state detected by the traffic monitoring means 22 and outputting it to the A / D converting means 19, and traffic which is data corresponding to the frequency of the sampling signal. Traffic bit generation means 23 for generating the bit FB, and control bit addition means 16 for loading the traffic bit FB on the transmission data
It is configured with and.

In addition to the above, a sampling frequency discriminating means 13 for discriminating a sampling frequency at the time of transmitting the transmission data from the traffic bit FB obtained from the transmission data, and a transmission frequency recognized by the sampling frequency discriminating means 13 Sampling signal generating means 18 for operating the D / A conversion means 20 on the receiving side at the same frequency as the sampling frequency.

[0012]

The use bit US originally included in the transmission packet determines whether or not the packet being transmitted is used.
D can be represented by "1" (used) or "0" (unused). Therefore, the current traffic state of the transmission path can be known by counting how much the used bit (USD = 1) is transmitted per unit time.

The traffic monitoring means 22 confirms the traffic state of the transmission path by counting the number of used bits as described above. Based on the confirmation result of the traffic monitoring means 22, the sampling signal generating means 18 outputs a sampling signal of low frequency when the traffic condition is bad, and outputs a sampling signal of high frequency when the traffic condition is good. As a result, it is possible to transmit the data amount according to the traffic state of the transmission path.

On the other hand, the sampling frequency at the time of transmitting certain data and the sampling frequency at the time of receiving must match. Therefore, the traffic bit FB formed by the traffic bit generation means 23 is placed at a predetermined position of the transmission packet by the control bit addition means 16 and decoded by the sampling determination means 13 on the receiving side. Then, based on this decoding result, the sampling signal generating means 1
8 outputs a sampling signal having the same frequency as that at the time of transmission to drive the D / A conversion means 20 on the receiving side.

[0015]

2 is a block diagram showing an embodiment of the present invention, and the same means as those in the conventional example shown in FIG. 3 are represented by the same reference numerals.

In the A / D conversion means 19, analog data is converted into digital data by the sampling signal generated by the sampling signal generation means 18, and is temporarily buffered in the transmission buffer 14 according to the instruction of the transmission buffer controller 17. As in the conventional case, the control bit adding means 16 attaches the address DA of the transmission source device and the address SA of the transmission destination device to the transmission data buffered in this way, but in the present invention, the traffic state of the transmission path is further added. FB indicating the traffic bit (which is equivalent to the sampling frequency for the A / D conversion means 19 during transmission as described later) FB is the control bit addition means 1
6 is added.

The transmission data (transmission packet) to which the control bit is added in this way is input to the E / O conversion means 1 via the selector 21 which is controlled as described later, and is transmitted to the transmission line as an optical signal. .

On the other hand, the received packet obtained through the O / E conversion means 2 on the receiving side is input to the packet header detection means 11 where the used bit USD is detected. The used bit USD detected in this way is input to the transmission buffer controller 7, and the transmission buffer controller 1
7 receives this and controls the selector 21.

That is, the received packet has been used (USD
= 1), the selector 21 is switched to the receiving side to return the received packet to the transmission path again. Further, when the received packet is empty (USD = 0), the selector 21 is switched to the transmission side, and the transmission data once stored in the transmission buffer 14 as described above is sent to the transmission line.

The used bit USD detected by the packet header detecting means 11 is inputted to the traffic monitoring means 22, where the used packet per time (USD =
1) is counted. This makes it possible to confirm the traffic state of the transmission path. In other words, the greater the number of used packets, the worse the traffic condition on the transmission line,
If the number of used packets is small, the traffic condition of the transmission path is good.

The number of used bits (USD = 1) obtained as described above is input to the transmitting side frequency selecting means 18s of the sampling signal generating means 18. In the frequency selecting means 18s, the larger the number of used bits (USD = 1) is (when the traffic condition is bad), the lower frequency is selected in the frequency selecting means 18s, and conversely, the used bit (USD = 1). The smaller the number of (in the case where the traffic condition is good), the higher the frequency is input to the A / D conversion means 19.

This makes it possible to reduce the amount of transmission data when the traffic condition is bad, and to increase the number of transmission data when the traffic condition is good. The transmission packet transmitted to the transmission path as described above is temporarily stored in the reception buffer 15 controlled by the reception side buffer controller 12 via the O / E conversion means, and is received by the reception side sampling signal D described below. / A converted.

By the way, the sampling frequency when transmitting certain data and the sampling frequency when receiving the same data must be the same. Therefore, in the traffic bit generation means 23, based on the number of used packets (USD = 1) obtained by the traffic monitoring means 22,
A traffic bit FB corresponding to the frequency of the sampling signal selected by the transmission side frequency selecting means 18s is generated.

The traffic bit FB is added to a predetermined position of the transmission packet by the control bit adding means 16 and transmitted. The traffic bit FB thus transmitted together with the transmission packet is detected by the packet header detection means 11 on the receiving side and input to the sampling determination means 13. The sampling determination means 13 decodes the traffic bit FB to recognize the sampling frequency at the time of transmission.

Based on the sampling frequency thus recognized, the receiving side frequency selecting means 18r of the sampling signal generating means 18 drives the D / A converting means 20 with the sampling signal having the same frequency as the sampling frequency at the time of transmission. become.

[0026]

As described above, according to the present invention, data is sampled at a low frequency when the traffic condition of the transmission line is bad, and data is sampled at a high frequency when the traffic condition of the transmission line is good. Therefore, it is possible to send out a data amount according to the traffic state of the transmission path, and prevent transmission failure. Furthermore, the sampling frequency at the time of transmission and the sampling frequency at the time of reception can be made the same to reduce the distortion of the waveform and the like.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a block diagram of an embodiment of the present invention.

FIG. 3 is a block diagram of a conventional example.

[Explanation of symbols]

 13 Sampling Frequency Discriminating Means 16 Control Bit Adding Means 18 Sampling Signal Generating Means 19 A / D Converting Means 20 D / A Converting Means 22 Traffic Monitoring Means 23 Traffic Bit Generating Means FB Traffic Bits USD Used Bits

Claims (2)

[Claims] 1. Analog data is sampled at a predetermined frequency and digitally converted by an A / D conversion means (19),
Traffic monitoring that monitors the traffic status of the transmission path based on the status of used bits (USD) obtained from the transmission data in the data sampling method when various control bits are added by the control bit addition means (16) and transmitted Means (22) and a sampling signal having a frequency corresponding to the traffic state detected by the traffic monitoring means (22),
Sampling signal generation means for outputting to D / D conversion means (19)
(18), a traffic bit generation means (23) for generating a traffic bit (FB) which is data corresponding to the frequency of the sampling signal, and a control bit addition means (16) for putting the traffic bit (FB) on the transmission data. ) And a transmission data sampling device comprising. 2. A sampling frequency discriminating means (13) for discriminating a sampling frequency at the time of transmitting the transmission data from a traffic bit (FB) obtained from the transmission data, and a transmission recognized by the sampling frequency discriminating means (13). Sampling signal generation means (18) for operating the D / A conversion means (20) on the receiving side at the same frequency as the sampling frequency at that time
The transmission data sampling apparatus according to claim 2, further comprising: