JPH04243343A - Packet communication method - Google Patents

Abstract

PURPOSE:To obtain an optimum transmission data packet length and to improve the communication efficiency by discriminating a state of a signal propagation path based on a magnitude of a demodulation error vector and applying optimum processing of a transmission data packet length of a MODEM. CONSTITUTION:A data packet length decision device 14 of the system makes a transmission data 15 to a proper packet length, and a modulator 11 sends the result to a signal propagation path as a modulation transmission signal 16. A demodulator 12 demodulates a modulation reception signal 17 received from the signal propagation path into a reception data 18. In this case, based on the demodulation data demodulated by the demodulator 12, a demodulation error vector output device 13 gives a demodulation error vector representing the state of the signal propagation path to the device 14. The device 14 estimates the state of the signal propagation path from the inputted demodulation error vector and sets the data packet length to a packet length optimum to the state of the signal propagation path. A modulator side uses the optimized packet length and sends the packet data to an opposite modulator, then efficient communication is implemented.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a packet communication method used in a communication system that uses a wired circuit to perform packet communication including an error correction protocol using a broadly defined phase modulation method.

0002

[Prior Art] In a communication system that uses a wired circuit to perform packet communication including an error correction protocol using a phase modulation method in a broad sense, optimization of the data packet length is carried out in accordance with the state of the signal propagation path. When the state of the propagation path is good, the packet length is made longer, and when the state is bad, the packet length is made shorter.

However, in the conventional technology, the state of the signal propagation path is determined based on the result of communication between the near-side modem and the opposite-side modem. In other words, when an error is detected on the demodulation side of the remote modem, the remote modem issues a retransmission request to the front modem, and by observing the frequency, it is possible to determine the signal propagation on the remote modem. The road condition is determined. Similarly, by observing the frequency of retransmission requests from the remote modem to the near modem,
The state of the signal propagation path on the side of the front modem is determined.

This will be explained using a block diagram of a system using the conventional technology shown in FIG. FIG. 6 is a block diagram showing the configuration of one modulation/demodulation device. In Figure 6, 6
1 is a modulator, and 62 is a demodulator. Reference numeral 63 denotes a retransmission request number counting device for counting the number of retransmission requests from the other party's modem device, and 64 a data packet that determines the packet length of transmission data from the count value of the number of retransmission requests, which is the output of the retransmission request number counting device 63. It is a long-determining device. 6
5 is transmission data from the data terminal, 66 is a modulated transmission signal, 67 is a modulated reception signal, and 68 is reception data to the data terminal.

[0005] Basically, this system converts transmission data 65 into an appropriate packet length and sends it to a signal propagation path as a modulated transmission signal 66 in a modulation device 61. Further, the modulated reception signal 67 received from the signal propagation path is returned to reception data 68 by the demodulator 62 . At this time, a retransmission request counting device 63 detects a retransmission request from the other party's modulation/demodulation device included in the data string demodulated by the demodulation device 62, and counts the number of retransmission requests. The data packet length determining device 64 estimates the state of the signal propagation path based on the count value output from the retransmission request frequency counting device 63 and determines the packet length of the transmission data 65.

The estimation of the signal propagation state performed by the data packet length determining device 64 determines that the higher the frequency of retransmission requests, the worse the condition of the signal propagation path, and the lower the frequency, the better the condition of the signal propagation path. This is a method to do so.

[0007]

In the conventional example, since the optimum packet length is not known at the initial stage of data communication, a constant data length must always be transmitted regardless of the state of the signal propagation path. Further, optimization of the packet length of the transmission data is not performed for the front modem until a retransmission request is received from the opposite side modem, and for the opposite side modem until a retransmission request is received from the front side modem. Moreover, this retransmission request is executed as a result of detecting an error on the demodulation side of the modem of the other party, so repeated trial and error is required until the packet length is optimized, resulting in unnecessary There are problems such as the need to retransmit data packets, which is a factor that degrades communication efficiency.

[0008] An object of the present invention is to provide a packet communication method that can improve communication efficiency.

[0009]

[Means for Solving the Problems] The packet communication system of the present invention is a packet communication system that performs packet communication including an error correction protocol by converting a digital signal into an analog signal using a phase modulation method in a broad sense. The packet communication method described in 1 determines the state of a signal propagation path from the magnitude of a demodulation error vector output from a demodulation error vector output device provided on the demodulation side of a modulation/demodulation device, and determines the state of the signal propagation path. Based on this, the data packet length determining device performs optimization processing on the packet length of the transmission data of the modulation/demodulation device.

[0010] Furthermore, the packet communication system according to the second aspect of the invention transmits the magnitude of the demodulation error vector outputted from the demodulation error vector output device provided on the demodulation side of the modulation/demodulation device, or information corresponding thereto, to the signal propagation path. The transmission side of the modem on the other side is notified as status information, and the data packet length determining device performs optimization processing on the packet length of the transmission data of the modem on the other side based on the status information of the signal propagation path.

[0011]

[Operation] The phase modulated signal passing through the signal propagation path becomes a signal containing errors due to various characteristics of the signal propagation path. On the demodulating side, the received signal containing this error is converted to another demodulated data point (actual demodulated data point) that deviates from the ideal demodulated data point.
Move to. A vector connecting this ideal demodulated data point and the actual demodulated data point is a demodulation error vector observed on the demodulation side. The magnitude of this demodulation error vector is
It very well reflects the state of the signal propagation path and the error state on the demodulation side of the modulation/demodulation device.

Therefore, in the invention as claimed in claim 1, the state of the signal propagation path is determined from the magnitude of the demodulation error vector outputted from the demodulation error vector output device, and the data is Since the packet length determination device optimizes the packet length of the transmission data of the modulation/demodulation device, the packet length of the transmission data is optimized from the initial stage of communication, making it possible to avoid unnecessary retransmission of data and improve communication. Efficiency can be improved.

[0013] Furthermore, in the invention as claimed in claim 2, the magnitude of the demodulation error vector outputted from the demodulation error vector output device or information corresponding thereto is transmitted to the transmission side of the modulation/demodulation device of the other party as state information of the signal propagation path. The data packet length determination device optimizes the packet length of the transmission data of the other party's modem device based on the state information of the signal propagation path, so the packet length of the transmission data can be optimized from the initial stage of communication. Therefore, unnecessary data retransmission can be avoided and communication efficiency can be improved.

[0014]

[Example] As an example of this invention, CCITT V
．． Embodiments of the invention according to claims 1 and 2 will be described using the H.22bis standard as an example. FIG. 1 is a block diagram showing the configuration of one modulation/demodulation device in a system according to a first embodiment of the invention. In FIG. 1, 11 is a modulation device, and 12 is a demodulation device. 13 is a demodulation error vector output device, and 14 is a data packet length determination device. 15 is transmission data from the data terminal, 16 is a modulated transmission signal, 17 is a modulated reception signal, and 18 is reception data to the data terminal.

FIG. 3 shows CCITT V. In this figure, 31 is an ideal demodulation data point, 32 is a demodulation data point containing errors due to the influence of various characteristics of the actual signal propagation path, and 33 is a diagram showing the demodulation error vector in the case of 22bis. The arrow indicates the demodulation error vector in this case. FIG. 4 is a diagram showing a communication procedure including an error correction protocol. In FIG. 4, 41 indicates the sequence of the calling modem and 42 indicates the sequence of the called modem. Reference numeral 43 indicates a protocol period for mutual connection of the modulation and demodulation devices, 44 indicates a mutual negotiation period of an error correction protocol after the connection of mutual modulation and demodulation devices is completed, and 45 indicates a data communication execution period.

This system basically follows the communication procedure shown in FIG. 4, and modulates the transmission data 15 into an appropriate packet length and sends it out to the signal propagation path as a modulated transmission signal 16 in the modulation device 11. Also, the modulated reception signal 1 received from the signal propagation path
7 is returned to received data 18 by the demodulator 12. At this time, based on the demodulated data demodulated by the demodulator 12, the demodulation error vector output device 13 provides the data packet length determination device 14 with a demodulation error vector indicating the state of the signal propagation path. The data packet length determination device 14 infers the state of the signal propagation path from the input demodulation error vector and sets the data packet length to the optimal packet length for the state of the signal propagation path. On the modulation side, using this optimized packet length, the packet data is transmitted to the modulation/demodulation device on the other side. As a result, an optimal packet length can be obtained from the initial stage of data communication, and efficient communication can be performed.

FIG. 2 shows a second diagram corresponding to the invention as claimed in claim 2.
FIG. 2 is a block diagram showing the configuration of one modulation/demodulation device in the system of the embodiment. In FIG. 2, 21 is a modulator, and 22 is a demodulator. 23 is a demodulation error vector output device, 24 is a demodulation error vector information output device, 25
26 is a demodulation error vector information detection device that detects demodulation error vector information from the modem on the other side, and 26 is the output of the demodulation error vector information detection device 25. The packet length of the transmission data is determined from the demodulation error vector information from the modem on the other side. This is a data packet length determination device that determines the length of a data packet.

Reference numeral 27 denotes a switch, during which the demodulation error vector information is exchanged by the demodulation error vector information output device 24.
During data communication, the data packet length determining device 26 side is closed. 28 is transmission data from the data terminal, 29 is a modulated transmission signal, 210 is a modulated reception signal, and 211 is reception data to the data terminal. FIG. 5 is a diagram showing a communication procedure including an error correction protocol including a communication procedure for notifying the other party of the size of the demodulation error vector or information corresponding thereto. In FIG. 5, 51 indicates the sequence of the modem on the calling side, and 52 indicates the sequence on the modem on the called side. 53 is a protocol period for connecting mutual modulation and demodulation devices, 54 is a mutual negotiation period for an error correction protocol after receiving the completion of connection between mutual modulation and demodulation devices, 55 is a mutual exchange period of demodulation error vector information, and 56 is a period for mutual exchange of demodulation error vector information. This is the data communication execution period.

This system basically follows the communication procedure shown in FIG. 5, converts the transmission data 28 into an appropriate packet length, and sends it to the signal propagation path as a modulated transmission signal 29 in the modulation device 21. Also, the modulated reception signal 2 received from the signal propagation path
10 is returned to received data 211 by the demodulator 22. At this time, based on the demodulated data demodulated by the demodulator 22, the demodulation error vector output device 23 provides a demodulation error vector indicating the state of the signal propagation path to the demodulation error vector information output device 24. The demodulation error vector information output device 24 creates the size of the demodulation error vector or information corresponding thereto, which allows the state of the signal propagation path to be inferred from the input demodulation error vector, and generates information corresponding to the magnitude of the demodulation error vector, which allows the state of the signal propagation path to be inferred from the input demodulation error vector. Send and notify the other party at the right time. The modem on the other end uses this information to infer the state of the signal propagation path and
Optimize the packet length of data packets to be sent. When this communication procedure is completed, the switch 27 switches to the data packet length determining device 26 side, and data communication can be performed with the optimized packet length.

In this embodiment, at the initial stage of communication as shown in period 55 in FIG.
Alternatively, by exchanging corresponding information, it is possible to obtain the optimal transmission data packet length for the conditions of each other's signal propagation paths from the initial stage of data communication, and efficient communication can be performed.

[0021]

According to the packet communication system according to claim 1, the state of the signal propagation path is determined from the magnitude of the demodulation error vector, and the transmission data of the modulation/demodulation device is adjusted based on the result of the determination of the state of the signal propagation path. Since the packet length optimization process is performed, the optimal packet length of the transmission data can be obtained from the initial stage of communication, unnecessary retransmission of data can be avoided, and communication efficiency can be improved.

Further, according to the packet communication method according to claim 2, the magnitude of the demodulation error vector or information corresponding thereto is notified to the transmission side of the modulation/demodulation device on the other side as state information of the signal propagation path, and the signal propagation Since the packet length of transmission data from the other party's modem is optimized based on the path status information, the optimal packet length of transmission data can be obtained from the initial stage of communication, and unnecessary retransmission of data can be avoided. communication efficiency can be improved.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of a first embodiment of the present invention.

FIG. 2 is a block diagram showing the configuration of a second embodiment of the invention.

FIG. 3 shows CCITT V. FIG. 2 is an explanatory diagram showing a demodulation error vector in the case of V.22bis.

FIG. 4 is a timing diagram showing a communication procedure including an error correction protocol.

FIG. 5 is a timing diagram showing a communication procedure including an error correction protocol having a communication procedure for notifying the other party of the magnitude of a demodulation error vector or information corresponding thereto.

FIG. 6 is a block diagram showing the configuration of a conventional example.

[Explanation of symbols]

11 Modulation device 12 Demodulation device 13 Demodulation error vector output device 14 Data packet length determination device 15 Transmission data 16 Modulation transmission signal 17 Modulation reception signal 18 Reception data 21 Modulation device 22 Demodulation device 23 Demodulation error vector output device 24 Demodulation error vector information output Device 25 Demodulation error vector information detection device 26 Data packet length determination device 27 Switch 28 Transmission data 29 Modulated transmission signal 210 Modulated reception signal 211 Reception data 31 Ideal demodulation data point 32 Demodulation data point 33 Demodulation error vector

Claims (2)

[Claims] Claim 1: A packet communication method that converts a digital signal into an analog signal using a broadly defined phase modulation method and performs packet communication including an error correction protocol, the method comprising: a demodulation error vector output device provided on the demodulation side of a modulation/demodulation device; The state of the signal propagation path is determined from the magnitude of the output demodulation error vector, and the packet length of the transmission data of the modulation and demodulation device is optimized by a data packet length determination device based on the determination result of the state of the signal propagation path. A packet communication method that is characterized by the following. 2. A packet communication method that converts a digital signal into an analog signal using a broadly defined phase modulation method and performs packet communication including an error correction protocol, the method comprising: a demodulation error vector output device provided on the demodulation side of a modulation/demodulation device; The size of the demodulation error vector to be output or information corresponding thereto is notified to the transmitting side of the modulation/demodulation device on the other end as signal propagation path status information, and the data packet length determination device uses the signal propagation path status information to inform A packet communication method characterized by performing optimization processing on the packet length of transmission data of the modem/demodulator of the other party.