JPH04100360A - Speed selective communication processor - Google Patents

Abstract

PURPOSE:To secure communication quality by providing a function for detecting the line quality of a communication network and a function for rewriting a speed display part in a negotiation signal and converting a communication speed corresponding to the line quality. CONSTITUTION:A line quality measuring circuit 18 detects the line quality in the communication network during connecting operation and an encoding rate selecting circuit 19 calculates an encoding rate required to obtain prescribed communication quality and the communication speed in the communication network when a signal is sent at the encoding rate according to detection information on the line quality. An encoding rate variation error correcting circuit 22 sets the encoding rate on receiving the calculation results and a binary signal terminating circuit 21 changes the signal transmission speed display area in a binary control signal so that the communication speed between terminals equals the communication speed in the communication network. Consequently, the communication of high quality between the terminals becomes possible and no buffer memory is required.

Description

[Detailed Description of the Invention] [Industrial Application Field] A communication network, a communication network placed between the communication network and the terminal device, or within the terminal device in order to establish communication between terminals at a predetermined communication speed of the communication terminals. The present invention relates to a communication processing device.

Specifically, the present invention relates to a method for performing communication between terminals such as a G2 sofa simulator via a communication network such as a mobile communication network with relatively poor line quality.

[Conventional technology]

The conventional technology of GI in mobile communication will be explained using facsimile terminal-to-terminal communication as an example.

In the currently available mobile communications service, the G-SofaSimili signal transmission system converts facsimile signals, which are originally digital, into analog signals within the voice band using a built-in modem in the facsimile terminal, and transmits these signals through analog radio lines.

FIG. 7 shows how a conventional facsimile is used.

On the moving side, the handset 5 is connected to the mobile device 51 via the switch 52.
3 and a facsimile terminal 54. The fixed side is comprised of a mobile communication radio base station 55, a public telephone network 56, a handset 53 and a facsimile terminal 54 connected to these via a switch 52.

The mobile side and the fixed side perform both communication using the handset 53 and communication using the facsimile terminal 54, but the signal from the facsimile terminal 54 is also converted by the built-in modem into an analog signal that can be transmitted within the same band as the voice signal. Therefore, it is possible to transmit facsimile signals without being aware of them in the wireless section.

However, this conventional technique has the problem of unavoidable deterioration in image quality due to fading and shadowing that occur in the wireless section.

As a means to improve this deterioration in image quality, it is conceivable to transmit facsimile image signals as digital signals over a wireless section. An example of this is shown in FIG. In the figure, a facsimile modem 57 is installed at a mobile terminal 151 and a radio base station 55, demodulates the signal from the facsimile terminal 54, and transmits the facsimile signal as a digital signal over the radio section. In this case, it is possible to improve the quality of the facsimile image signal by performing error control using an error correction code or retransmission method.

[Problem to be solved by the invention]

In the conventional methods described above, as a means of achieving relatively high-quality communication between terminals via a communication network where errors are likely to occur, there are two methods: A method that uses a retransmission method (ARQ) with constraints on the number of retransmissions and buffer memory, a method that uses a hybrid FEC/ARQ method that combines Possible methods include changing the transmission speed of the wireless section without changing the speed. However, no matter which method is used, there are problems as described below.

When using ■, a feedback channel or buffer memory for retransmission control is not required, but the available F
There are restrictions on the coding rate of EC, and it is expected that sufficient error correction effects cannot be expected (in general, the lower the coding rate, the lower the communication speed between terminals and the transmission speed within the communication network.) The larger the difference, the greater the effect).

When using ■, a buffer memory is required to absorb the difference between the communication speed between terminals and the communication speed within the communication network (the product of the transmission speed within the communication network and the retransmission efficiency of the retransmission method adopted). Therefore, if this difference is large or the communication time is long, it is expected that a huge amount of buffer memory will be required.

When using ■, higher quality communication is possible compared to ■ and ■, but more buffer memory is required than ■ (however, the communication speed within the communication network depends on the transmission speed within the communication network and the retransmission efficiency. and the FEC coding rate).

Even when using method (2), the more errors are attempted to be made, the more a large amount of buffer memory is required.

In view of these conventional problems, the present invention enables high-quality communication between terminals and does not require buffer memory, or even if buffer memory is necessary, the device can be constructed with a small amount of memory. The purpose is to provide communication processing means that can realize this.

[Means to solve the problem]

According to the present invention, the above-mentioned problems can be solved by the means described in the claims.

In general, in terminal-to-terminal communication, before communication (user data), there is negotiation to determine the communication speed between the terminals, and procedure signals for this are defined. Therefore, by changing the speed display portion of this signal, the communication speed can be changed to a speed that corresponds to the quality of the line. The present invention utilizes this principle, and can be used within a communication network or between a communication network and a terminal device.
Alternatively, the terminal device may include a function to detect a procedure signal for negotiation of communication speed between terminals, a function to detect line quality of the communication network, and a function to detect the communication speed according to the line quality of the communication network. This communication processing device has a function of converting the negotiation signal by rewriting the speed display portion.

[For production]

The above-mentioned means has the following effect on communication between terminals via a poor quality communication network. Note that the following ■, ■, ■, and ■ correspond to ■, ■, ■, and ■ used in the above-mentioned [Problem to be Solved by the Invention].

■ When achieving relatively high-quality communication using FEC for multiple communication processing devices installed at the interface point between the terminal device and the communication network, the communication speed between terminals should be adjusted depending on the line quality of the communication network. Since it is possible to control the error correction capacity of FEC (generally FEC
(determined by the coding rate of
It becomes possible to guarantee the communication quality required for communication between terminals. In other words, it becomes possible to realize communication that satisfies the specified communication quality with the minimum communication hold time.

■ When achieving relatively high-quality communication using ARQ for multiple communication processing devices installed at the interface between the terminal device and the communication network, the communication speed between terminals should be adjusted according to the quality of the communication network. Since the communication speed between terminals can be controlled, it is possible to make the communication speed between terminals smaller than the communication speed within the communication network (the product of the transmission speed within the communication network and the retransmission efficiency of the retransmission method adopted), and the buffer required for the communication processing device can be reduced. It is possible to make the memory extremely small (this can be achieved using only the buffer memory required for retransmission processing).

(2) The same effect as (2) can be obtained when hybrid FEC/ARQ is used for multiple communication processing devices installed at the interface between the terminal device and the communication network.

(2) In the method of changing the transmission speed in the wireless section according to the line quality, the communication speed between terminals and the communication speed within the communication network can be made equal, so that no non-Npha memory is required.

In all of the above methods, the difference between the communication speed between terminals and the communication speed within the communication network is minimized by controlling the communication speed between terminals using procedure signals for negotiation. They have one thing in common. This principle will be explained using FIG. 1, taking a facsimile as an example.

FIG. 1 shows the frame structure of a facsimile binary control signal having an information field (DIS, DC3°DTC). (Refer to CCITT Recommendation T, 30) In the same figure, 8 indicates the start and end of a frame, and a flag area for establishing frame synchronization, 9 is an address area for transmitting address information, and 10 is a frame control area for identifying the function of the frame. , 11 is a facsimile control 1ISI area for identifying the function of the control signal, 12 is a facsimile information area for transmitting function information etc. possessed by the terminal, 1
3 shows a frame check sequence for detecting the presence or absence of transmission errors from the address area to the facsimile information area. 14 is an area for specifying the communication speed of the facsimile terminal in the facsimile information area, and bit numbers 11 and 1
2 bits: 2400bps, 4800bps
It is possible to specify four communication speeds: , 7200bps, and 9600bps.

The outline of the process for specifying the actual communication speed between terminals is as follows.

■ When using FEC for multiple communication processing devices installed at the interface point between the terminal device and the communication network,
Since the relationship between EC coding rate and error correction capability is known, if the raw line quality in the communication network (line quality without error correction) is known, it is possible to determine the communication quality required for terminal-to-terminal communication. The FEC coding rate required to obtain the FEC is determined. This makes it possible to specify the communication speed between terminals so that it does not exceed the product of the transmission speed within the communication network and the FEC coding rate.

■,■ ARQ or hybrid FE is installed in multiple communication processing devices installed at the interface point between the terminal device and the communication network.
When using C/ARQ, if the line quality improvement effect of ARQ or hybrid FEC/ARQ on the raw line quality within the communication network and the communication speed within the communication network are determined in advance by simulation etc., the measured communication Considering the line quality within the network, it is possible to specify the communication speed between terminals to be lower than the communication speed within the communication network.

■ Even with the method of changing the transmission speed of the wireless section according to the line quality, it is possible to bring the communication speed between terminals closer to the optimal communication speed of the wireless section, and the capacity of the buffer memory can be saved. [Example] FIG. 2 and FIG. 4 are diagrams each showing an embodiment of the present invention, and show an example of the configuration of a speed selection communication processing device according to the present invention. Figure 2 shows the FEC in the communication processing device.
Configuration example (Example 1) for improving communication quality using
), and FIG. 4 shows a configuration example (Embodiment 2) in which communication quality is improved using ARQ in a communication processing device.
It shows. It should be noted that this is a configuration example in which a Gm facsimile is assumed as these communication terminals, and a wireless mobile communication network is assumed as the communication network.

GI[[Facsimile signals include a binary control signal and an image signal, and the binary control signal is a signal for negotiation between facsimile terminals. Therefore, if the mobile device and the radio base station have a facsimile terminal transmission protocol, there is no need for this signal to be transmitted over the radio section. In this embodiment, the facsimile terminal protocol (7, 30
') is terminated at a mobile device and a wireless base station, and the wireless section is assumed to transmit only image signals.

In this case, to ensure smooth communication between devices,
It is necessary for the mobile side facsimile terminal and the base station side facsimile terminal to notify each other of the timing of activation and end of transmission and the direction of image signal transmission.

For this reason, in this embodiment, a control wJ signal transmission area is provided in the wireless @ line frame during facsimile signal transmission to indicate the timing of activation of the facsimile terminal and the end of transmission and the transmission direction of the image signal. FIG. 6 shows an example of a frame structure during facsimile signal transmission over a wireless line according to the present invention. In the same figure, 15 is a frame, 1
Reference numeral 6 represents a control signal for indicating the timing of activation of the facsimile terminal and the end of transmission, and the direction of transmission of the image signal.

Hereinafter, each of Example 1 and Example 2 according to the present invention will be explained separately.

<Embodiment 1> First, a configuration example (FIG. 2) according to the present invention in a case where FEC is used in a communication processing device to improve communication quality will be described.

In FIG. 2, 1 is a mobile device, 4 is a facsimile terminal, and 5 is a mobile device.
1 is a wireless base station, 6 is a public telephone network, 18 is a line quality measurement circuit, 19 is a transmission rate and coding rate selection circuit, 20 is a control unit, 21 is a binary signal termination circuit, and 22 is a coding rate variable error correction circuit. , 23 represent a wireless section.

In the figure, the facsimile terminals 4 on the mobile device side and the wireless base station side have binary signal termination circuits 21 facing each other.
A connection operation is performed between the

The line quality measuring circuit 18 detects the line quality within the communication network during the connection operation, and based on that information, the communication speed and coding rate selection circuit 19 selects the line quality necessary to obtain the specified communication quality. The coding rate and the communication speed within the communication network (the product of the transmission speed within the communication network and the coding rate) when a signal is transmitted at the coding rate are calculated.

In response to the above results, the variable coding rate error correction circuit 22 sets the coding rate. Furthermore, the binary signal termination circuit 21 changes the signal transmission speed display area in the binary control signal so that the communication speed between terminals becomes equal to the communication speed within the communication network.

At the transmitting station, the binary signal termination circuit 2 terminates the facsimile protocol under the control section 20 and sends only the image signal to the variable coding rate error correction circuit 22.

The variable coding rate error correction circuit 22 codes the image signal at a previously set coding rate and sends it to the radio section 23.

At the receiving side station, a coding rate variable error correction circuit 22
At , the received data is decoded to extract an image signal and sent to the public telephone network 6 through the binary signal termination circuit 21 .

Next, an example of the GIII facsimile connection sequence in this embodiment will be described with reference to FIG.

Note that the figure assumes a case where the facsimile terminal on the mobile side is transmitting and the facsimile terminal on the radio base station side is receiving.

In FIG. 3, when the facsimile terminal on the radio base station side is started up after the telephone line is set up, the facsimile terminal sends out a 2100 Hz tone signal (CED) to notify the start up. At this time, the transmission line is in telephone mode and the CE
D is transmitted within the voice band.

When the facsimile terminal on the mobile side is activated at time 30, the mobile equipment detects activation of the facsimile terminal on the mobile side at time 31 from a change in the voltage between the telephone connection terminals of the facsimile terminal.

Furthermore, the uplink radio channel control signal 16 is used to notify the radio base station of the activation of the mobile facsimile terminal. When the radio base station detects activation of the mobile facsimile terminal at time 32, it notifies the radio base station of switching to facsimile relay mode using the downlink radio channel control signal 16 at time 33. At the same time, the radio base station has detected the channel quality of the uplink radio section by this point, and transmits this information to the mobile device through the data section 17 of the radio channel.

At time point 34, the mobile device receives the line quality of the uplink radio circuit, and determines the coding rate necessary to ensure the specified transmission quality within the communication network and the communication speed within the communication network at the coding rate. (the product of the transmission rate within the communication network and the coding rate). Furthermore, at time 35, D
The communication speed of the mobile facsimile terminal is specified using the IS signal.

At time 36, the mobile device receives the D from the facsimile terminal.
By receiving the C3 signal, it is detected that the facsimile terminal on the mobile side has started up in the transmission mode, and this is notified to the radio base station using the control signal 16 of the radio line.

When the radio base station detects that the facsimile terminal on the mobile side has activated in transmission mode based on a notification from the mobile terminal at time 37, it calculates the communication speed within the communication network from the line quality of the uplink radio link, and also calculates the communication speed between the terminals. The communication speed of the facsimile terminal on the radio base station side is specified using the DC3 signal so that the communication speed of the facsimile terminal is equal to the communication speed within the communication network. It also sets the coding rate of the error correction circuit within the radio base station.

At time point 38, when the mobile device receives an image signal from the mobile facsimile terminal, it encodes it at a previously set coding rate and transmits it to the radio base station. When the radio base station receives the encoded image signal at time 39, it decodes it at the previously set coding rate and transmits it to the radio base station facsimile terminal.

The signal after transmitting the image signal includes EOP indicating the end of transmission,
There is an MPS that indicates transportation, and subsequent operations differ depending on which signal is received, so the wireless section needs to relay this.

At time 50, when the mobile device receives an EOP signal from the mobile facsimile terminal, it notifies the wireless base station of the end of the transmission document using the wireless line control signal 16, and
The mobile device starts disconnecting from the facsimile terminal.

When the wireless base station receives the end of transmission at time 51,
Sends an EOP signal to the facsimile terminal on the wireless base station side,
Start cutting operation.

<Embodiment 2> Next, an example of a configuration according to the present invention (FIG. 4) in a case where ARQ is used in a communication processing device to improve communication quality will be described.

In FIG. 4, 1 is a mobile device, 4 is a facsimile terminal, and 5 is a mobile device.
1 is a wireless base station, 6 is a public telephone network, 18 is a line quality measurement circuit, 24 is a transmission rate selection circuit, 20 is a control unit, 2 is a binary signal termination circuit, 25 is a retransmission processing circuit, 26 is a memory, and 23 is a It represents the radio section.

In the figure, the facsimile terminals 4 on the mobile device side and the wireless base station side have binary signal termination circuits 21 facing each other.
A connection operation is performed between the

The line quality measurement circuit 18 detects the line quality within the communication network during the connection operation, and based on that information, the communication speed selection circuit 24 selects the communication speed (transmission speed within the communication network and retransmission rate) in the communication network with the line quality. The product of efficiency) is calculated.

In response to the above results, in the binary signal termination circuit 21, the communication speed between terminals is lower than the communication speed within the communication network (
, and the signal transmission speed display area in the binary control signal is changed so that the difference therebetween is minimized.

At the transmitting station, the binary control signal terminates the facsimile protocol under the control section 20, and only the image signal is sent to the retransmission processing circuit 25.

The retransmission processing circuit 25 configures the image signal as HDLC frame data and transmits it to the radio unit 23, and the data is sent to the HDLC frame until reception confirmation is received from the receiving station.
The frame is stored in memory 26 in preparation for retransmission.

In the receiving station, the retransmission processing circuit 25 extracts the image signal from the received F (DLC frame) and sends it to the binary signal termination circuit 21, and sends it to the transmitting station.
Send an acknowledgment signal. The binary signal termination circuit 21 transmits the image signal to the public telephone network 6 in accordance with the communication speed of the previously specified facsimile terminal.

In this method, the communication speed between terminals is specified to be lower than the communication speed within the communication network, but the retransmission efficiency within the communication network temporarily deteriorates due to short-term fluctuations in line quality. The communication time may be longer than the communication time between terminals. Therefore, if this phenomenon occurs just before the end of the image signal, the transmitting terminal will send a binary control signal indicating the end of the image signal, even though the transmission of the image signal within the communication network has not yet ended. .

An example of the operation in this case will be explained using the sequence diagram shown in FIG. This figure shows a case where the mobile facsimile terminal is transmitting and the fixed facsimile terminal is receiving.

In FIG. 5, when the facsimile terminal on the radio base station side is started up after the telephone line is set up, the facsimile terminal sends out a CED indicating the start-up.

At this time, the transmission path is in telephone mode, and CHD is transmitted within the voice band.

When the facsimile terminal on the mobile side is activated at time 30, the mobile equipment detects activation of the facsimile terminal on the mobile side at time 31 from a change in the voltage between the telephone connection terminals of the facsimile terminal.

Furthermore, the control signal 16 of the uplink radio circuit is used to notify the radio base station of the activation of the mobile facsimile terminal.

When the radio base station detects activation of the mobile facsimile terminal at time 32, it notifies the radio base station of switching to facsimile relay mode using the downlink radio channel control signal 16 at time 33. At the same time, the radio base station has detected the channel quality of the uplink radio section up to this point, and transmits this information to the mobile device through the data section 17 of the radio channel.

At time point 34, the mobile device calculates the communication speed within the communication network (the product of the transmission speed within the communication network and the retransmission efficiency) based on the line quality of the uplink wireless line notified from the base station. Furthermore, at time 35, the communication speed of the mobile facsimile terminal is transmitted to the mobile facsimile terminal using the DIS signal so that the communication speed between the terminals is lower than the communication speed within the communication network and the difference is minimized. Specify.

At time 36, the mobile device receives the D from the facsimile terminal.
By receiving the C3 signal, it is detected that the facsimile terminal on the mobile side has started up in the transmission mode, and this is notified to the radio base station using the control signal 16 of the radio line.

At time point 37, when the wireless base station detects that the mobile facsimile terminal has started up in transmission mode based on a notification from the mobile device, it calculates the communication speed within the communication network from the uplink wireless channel quality measured at time point 32. At the same time, the communication speed of the facsimile terminal on the radio base station side is specified using the DIS signal so that the communication speed between the terminals is lower than the communication speed within the communication network and the difference therebetween is minimized.

At time point 38, when the mobile device receives an image signal from the mobile facsimile terminal, it converts the image signal into HDLC data.
Construct a frame and send it to the wireless base station. When the radio base station receives the HDLC frame at time 39, it extracts an image signal from it and transmits it to the facsimile terminal on the radio base station side.

At time 40, when the mobile device receives an OF from the sending facsimile terminal while transmitting an image signal due to a temporary deterioration in the line quality of the communication network, the mobile device ignores this, and at time 41, the image signal is transmitted. A pseudo flag is sent to the sending facsimile terminal until the transmission of the sending facsimile terminal is completed, and the sequence within the sending facsimile terminal is stopped.

Also, at time 42, the wireless base station inserts FILL between the image signal data and EOLO so that the data transmitted to the receiving facsimile is not interrupted.

At time point 43, when the mobile device finishes transmitting the image signal,
Stop sending pseudo flags.

At time 50, when the mobile device receives an EOP from the mobile facsimile terminal, it notifies the wireless base station that the data to be transmitted has ended using the control signal 16 of the wireless line, and begins a disconnection operation from the mobile facsimile terminal.

At time 51, upon receiving the transmission end, the wireless base station sends an EOP signal to the wireless base station facsimile terminal,
Start cutting operation.

〔Effect of the invention〕

As explained in detail above, the present invention has the following effects.

In other words, in terminal-to-terminal communication in which a communication terminal has multiple communication speeds and negotiates the communication speed with a communication partner terminal using a procedure signal, the communication network, the communication network and the terminal device, or the terminal device a function to detect a procedure signal for negotiation, a function to detect the line quality within the communication network, and a function to convert the speed display part of the negotiation signal according to the line quality of the communication network. (1) When achieving relatively high quality communication using FEC for multiple communication processing devices installed at the interface point between the terminal and the communication network, Since the communication speed between terminals can be controlled, the error correction capacity of FEC used depends on the quality of the communication network (generally determined by the FEC coding rate, and limited by the ratio of the communication speed between terminals and the transmission speed within the communication network). This makes it possible to change the communication quality required for terminal-to-terminal communication.

In other words, communication that satisfies the specified communication quality can be achieved with the minimum communication hold time.

(2) ARQ or hybrid FEC/A for multiple communication processing devices installed at the interface point between the terminal and the communication network
When achieving relatively high quality communication using RQ,
Since the communication speed between terminals can be controlled according to the quality of the communication network, the communication speed between terminals can be determined by the communication speed within the communication network (the product of the transmission speed within the communication network and the retransmission efficiency of the adopted retransmission method, or It becomes possible to further reduce the product of the transmission speed within the communication network, the retransmission efficiency of the ARQ employed, and the coding rate of FEC, and the buffer memory required for the communication processing device can be made extremely small (the product of the retransmission efficiency of the adopted ARQ and the coding rate of FEC). (can be realized using only buffer memory).

(3) When achieving relatively high quality communication by using a function that changes the transmission speed within the communication network according to the line quality in multiple communication processing devices installed at the interface between the terminal and the communication network, Since the communication speed between terminals can be controlled according to the communication speed within the communication network, there is no need to install a memory buffer within the communication processing device even if the communication speed is changed significantly.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a frame structure of a facsimile binary control signal, FIG. 2 is a diagram showing a multilayer configuration of the present invention, and FIG. 3 is a diagram showing an example of a cm facsimile connection sequence according to Embodiment 1 of the present invention. 4 is a diagram showing the configuration of the second embodiment of the present invention, FIG. 5 is a diagram showing an example of the G facsimile connection sequence according to the second embodiment of the present invention, and FIG. 6 is a diagram showing the configuration of the second embodiment of the present invention. Fig. 7 is a diagram showing a conventional facsimile usage pattern; Fig. 8 is a diagram showing an example of a configuration in which a facsimile signal is transmitted as a digital signal over a radio section. It is. 1...mobile device, 4...facsimile terminal, 5...
Radio base station, 6... Public telephone network, 8... Flag transmission area, 9... Address transmission area, 10... Frame control signal transmission area, 11... Facsimile control signal transmission area, 12. ...Facsimile information signal transmission area, 1
3... Frame change signal transmission area, 14... Data signal speed transmission area, 15... Frame, 16...
- Control signal, 17... Data section, 18... Line quality measurement circuit, 19... Communication speed and coding rate selection circuit, 20... Control unit, 21... Binary signal termination circuit, 22 ... coding rate variable error correction circuit, 23 ... radio section, 24 ... communication speed selection circuit, 25 ... retransmission processing circuit, 26 ... memory, 30 ... mobile side facsimile + 31...When the mobile device detects activation of the mobile device facsimile terminal and notifies the radio base station of this; 32...The radio base station starts the mobile device facsimile terminal. 33...When the wireless base station switches the relay mode to facsimile mode and notifies the mobile device of this, and at the same time notifies the mobile device of the uplink wireless channel quality, 34 ...When the mobile device detects that the relay mode has switched to facsimile mode and at the same time detects the line quality of the uplink wireless line, 35...The mobile device transmits the DIS signal to determine the communication speed of the mobile side facsimile terminal. 36...When the mobile device detects that the mobile device side facsimile terminal is the sending side facsimile terminal and notifies the radio base station of this, 37...At the radio base station. When the mobile facsimile terminal detects that it is the transmitting facsimile terminal, and when it notifies the radio base station facsimile terminal of this using the DO3 signal and specifies the communication speed of the radio base station facsimile terminal. , 38... Time point at which the mobile device constructs a wireless relay frame using the image signal transmitted from the mobile device side facsimile terminal as data and transmits it to the wireless base station, 39... Radio relay frame received at the wireless base station 40...When the EOP signal is received during image signal transmission in the mobile device, 41-...When the mobile device compares the image signal from the mobile device and sends it to the mobile device facsimile terminal. On the other hand, at the time when the pseudo flag signal is transmitted, 42... At the time when a FILL is inserted into the image signal data received at the radio base station and transmitted to the facsimile terminal on the radio base station side, 43... From the mobile device to the radio base station When the image signal transmission is completed and the transmission of the pseudo flag signal to the mobile facsimile terminal is thereby stopped, 50--...The mobile device detects the end of the image signal data transmitted from the mobile facsimile terminal. 51... The time when the radio base station detects the end of the transmission data and sends an EOP signal to the facsimile terminal on the radio base station side.

Claims (1)

[Claims] Communication for converting inter-terminal communication signals into communication network signals in inter-terminal communication in which a communication terminal has a plurality of communication speeds and negotiates the communication speed with a communication partner terminal using a procedure signal. A processing device having a function of detecting a procedure signal for the negotiation, a function of detecting line quality within the communication network, and a function of detecting a speed display part of the negotiation signal according to the line quality of the communication network. A speed selection communication processing device characterized by having a function of rewriting to a speed.