JP3542570B2 - Facsimile machine - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a facsimile apparatus in which a procedure signal is transmitted in full-duplex communication.
[0002]
[Prior art]
In a conventional facsimile apparatus based on the ITU-T recommendations T30, T3, T4, and T6, both the procedure signal and the image signal are transmitted by half-duplex communication .
[0003]
[Problems to be solved by the invention]
As described above, in the conventional facsimile apparatus, since the transmission of the procedure signal is half-duplex communication, a signal is transmitted from the transmitter to the receiver, and the receiver responds to the signal after the reception of the signal is completed. And transmitted a new signal.
[0004]
However, there is no facsimile apparatus that switches between full-duplex communication and half-duplex communication when the receiver is capable of full-duplex communication.
[0005]
An object of the present invention is to provide a facsimile apparatus that can smoothly switch between full-duplex communication and half-duplex communication .
[0006]
[Means for Solving the Problems]
According to the invention of the present application, in a facsimile apparatus capable of full-duplex communication and half-duplex communication of a procedural signal , first, a predetermined signal capable of full-duplex communication is transmitted at a receiver side and transmitted within a predetermined time. When a predetermined signal capable of full-duplex communication is detected from the transmitter side, the full-duplex communication of the procedure signal is started, and a predetermined signal capable of full-duplex communication is not detected from the transmitter side within a predetermined time. Since the receiver transmits a predetermined signal capable of performing half-duplex communication, it is possible to smoothly switch between full-duplex communication and half-duplex communication .
[0014]
Embodiments and Examples of the Invention
FIG. 1 is a block diagram showing a configuration of a facsimile apparatus according to an embodiment of the present invention.
[0015]
In order to use the telephone network for data communication and the like, the NCU (network control unit) 2 connects to the terminal of the line, controls connection of the telephone switching network, switches to a data communication path, performs a loop, Is performed. The NCU 2 connects the telephone line 2a to the telephone 4 when the signal level (signal line 54a) from the control circuit 54 is "0", and connects the telephone line 2a when the signal level is "1". It is connected to the facsimile machine. In a normal state, the telephone line 2a is connected to the telephone 4 side.
[0016]
The hybrid circuit 6 separates the transmission system signal and the reception system signal, sends the transmission signal from the addition circuit 24 to the telephone line 2a via the NCU 2, receives the signal from the other party via the NCU 2, and It is sent to demodulator B28 and demodulator A26 via 6a. The hybrid circuit 6 enables full-duplex communication.
[0017]
The modulator A8 is a modulator that modulates a procedure signal, modulates a procedure signal (signal line 54i) from the control circuit 54, and sends the modulated signal to the addition circuit 24 through the signal line 8a. Modulator A and demodulator A can operate simultaneously in full-duplex communication.
[0018]
The reading circuit 10 is composed of an image pickup device such as a CCD (Charge Coupled Device) and an optical system, sequentially reads image signals for one line in the main scanning direction from a transmission original, and creates a signal sequence representing white and black values. The signal is output from the signal line 10a.
[0019]
The encoding circuit 16 receives the information output to the signal line 10a, and outputs encoded (K = 8 MR encoded) data to the signal line 16a.
[0020]
The memory circuit 18 stores the encoded data output to the signal line 16a and outputs the stored encoded data to the signal line 18a under the control of the signal line 54d.
[0021]
The decoding / magnification / encoding circuit 20 is a circuit that receives the signal output to the signal line 18a, decodes the image once, scales it as needed, and encodes it. Is output to the signal line 20a.
[0022]
The modulator B22 modulates the image signal. The modulator 22 receives a signal on the signal line 20a, modulates the signal, and outputs modulated data to the signal line 22a.
[0023]
The addition circuit 24 receives the signals of the signal lines 8a and 22a and outputs the result of the addition to the signal line 24a.
[0024]
The demodulator A26 demodulates the procedure signal. The demodulator 26 receives the signal on the signal line 6a to perform demodulation, and outputs demodulated data to the signal line 26a. Modulator A and demodulator A can operate simultaneously in full-duplex communication.
[0025]
The demodulator B28 demodulates the image signal. The demodulator 28 receives the signal on the signal line 6a, performs demodulation, and outputs demodulated data to the signal line 28a.
[0026]
The decoding / encoding circuit 30 receives the demodulated data output to the signal line 28a, decodes the data once, outputs the decoded data to the signal line 30a, and performs K = 8 MR encoding again. The data is output to the signal line 30b.
[0027]
The memory circuit 32 stores the encoded data output to the signal line 30b in the memory circuit 32 in accordance with the control of the signal line 54e, and transmits the data stored in the memory circuit 32 to the signal in accordance with the control of the signal line 54e. Output to line 32a.
[0028]
The decoding circuit 34 receives the signal output to the signal line 32a, and outputs the decoded (K = 8 MR decoded) data to the signal line 34a.
[0029]
The recording circuit 36 is an LBP that inputs data output to the signal line 34a and sequentially performs recording at a constant speed line by line.
[0030]
The control circuit 54 controls the whole of the facsimile apparatus. In the first embodiment of the present invention, the control circuit 54 performs the following control. First, the facsimile apparatus of the present embodiment transmits a procedure signal by full-duplex communication and transmits an image signal by half-duplex communication, and the receiver side receives an initial identification signal until a reception command signal is received. Are sent out continuously. On the other hand, the transmitter side transmits the flag pattern until the initial identification signal is received, starts transmitting the reception command signal after receiving the initial identification signal, and thereafter receives the reception preparation confirmation signal. Until one of the initial identification signals is received, one reception command signal is transmitted.
[0031]
Further, the receiver sends out a reception preparation confirmation signal every time one reception command signal is received, and upon detecting an image signal, immediately stops sending the reception preparation confirmation signal and shifts to reception of an image signal. After the transmission of the image signal is completed, the transmitter continuously transmits the command signal after the message until the message confirmation signal is received.
[0032]
When the receiver cannot receive the next page when receiving the command signal after the message, the receiver sends a non-reception signal, and then sends a flag signal continuously to enable reception of the next page. If so, a message confirmation signal is sent. After transmitting the command signal after the message, the transmitter transmits a flag until a message acknowledgment signal is received when the reception disable signal is detected, and after receiving the message acknowledgment signal, shifts to transmitting an image signal. Here, during the procedure signal, when no valid signal is transmitted, silence is not performed, and a flag is transmitted to ensure full-duplex communication.
[0033]
FIG. 2 to FIG. 4 are explanatory diagrams showing specific example procedures of the above control.
[0034]
2 to 4, (1) indicates an error-free procedure, and (1-1) indicates phase B, that is, a pre-procedure. (1-2) represents the phase D, that is, the post-procedure, and (2) represents the error procedure.
[0035]
First, in (1-1) of (1) shown in FIG. 2, first, a signal of 2100 Hz is transmitted from the transmitter side or the receiver side for a predetermined time, the echo suppressor is disabled, and full-duplex communication is enabled. The transmission speed is also determined.
[0036]
Thereafter, both the transmitter and the receiver transmit a synchronization signal, and the receiver continuously transmits the DIS signal (1), and continues to transmit the DIS signal (2) and the DIS signal (3) until the DCS signal is received. Further, the receiver ends the reception of the DCS signal (1) when the transmission of the DIS signal (3) ends.
[0037]
On the other hand, after the transmission of the synchronization signal is completed, the transmitter continuously transmits the flag signal until receiving the DIS signal. Upon receiving the DIS signal (1), the transmitter transmits the DCS signal (1), and transmits one DCS signal each time one DIS signal is received until the CFR signal is received. Then, after transmitting the DCS signal {circle around (2)}, the transmitter terminates the reception of the CFR signal {circle around (1)}, and thus shifts to transmitting the image signal.
[0038]
The receiver sends out the CFR signal (1) when receiving the DCS signal (1), and sends out the CFR signal (2) when receiving the DCS signal (2). Then, since the image signal is detected during the transmission of the CFR signal (2), the transmission of the CFR signal (2) is interrupted halfway, and the process shifts to the reception of the image signal. Here, when neither the transmitter nor the receiver has transmitted a valid signal, a flag is transmitted.
[0039]
FIG. 5 and FIG. 6 are flowcharts showing the flow of control in the above-described pre-procedure.
[0040]
First, FIG. 5 shows a pre-procedure on the transmitter side. After transmitting a synchronization signal in S0, a flag is transmitted (S2), and DCS is transmitted each time a DIS signal is received (S4). After the transmission of the DCS in S4, a flag is transmitted until DIS and CFR are received (S6).
[0041]
When the DIS is received, the DCS is transmitted again (S4), and when the CFR is received, the flow shifts to the transmission of the image signal (S8). Then, when T _T (a fixed value timer for command retransmission) times out, the line is released (S10).
[0042]
Further, after the synchronization signal is transmitted (S0), if T1 (35 seconds) times out, the line is released (S12).
[0043]
Next, FIG. 6 shows a pre-procedure on the receiver side. In S20, after transmitting the synchronization signal, DIS is continuously transmitted (S22), and when DCS is received, CFR is transmitted (S24). Then, when the PIX is received, the process proceeds to the reception of the PIX (S26).
[0044]
Here, when the PIX has not been received and the next DCS has not been received, a flag is transmitted (S28). When the PIX is not received and the next DCS is received, the CFR is transmitted again in S24, and the line is released when the T2 timer (T2 timer of T30: 6 seconds) times out (S30).
[0045]
Further, after the synchronization signal is transmitted (S20), when the time of the T1 timer (T1 timer of T30 is 35 seconds) expires, the line is released (S32).
[0046]
Next, in (1-2) of (1) shown in FIG. 3, the transmitter transmits the synchronization signal after the transmission of the image signal is completed, and the receiver transmits the synchronization signal after the reception of the image signal is completed.
[0047]
Thereafter, if there is no mode change in the ECM procedure and there is a next page, for example, the transmitter continuously transmits the PPS-MPS signal, and outputs the PPS-MPS (1), PPS-MPS (2), and PPS-MPS (2). 3) and transmit until receiving the MCF signal from the other receiver. Here, at the end of the transmission of the PPS-MPS (3), the MCF (1) is received. Therefore, the transmission is performed up to the PPS-MPS (3), and after a wait of 75 ms ± 10 ms, the flow proceeds to the transmission of the image signal.
[0048]
On the other hand, the receiver transmits the flag pattern after the transmission of the synchronization signal is completed, and transmits one MCF signal each time one PPS-MPS signal is received. That is, MCF (1) is transmitted to PPS-MPS (1), MCF (2) is transmitted to PPS-MPS (2), and MCF (3) is transmitted to PPS-MPS (3). During the transmission of the image signal, the image signal is received. Therefore, the transmission of the MCF (3) is interrupted on the way, and the operation shifts to the reception of the image signal (the above, (1-2-1) in FIG. 3).
[0049]
Also, if there is a mode change in the ECM procedure, the transmitter sends out the PPS-EOM signal continuously until the MCF signal is received. Since the transmitter has received the MCF (1) at the time of transmitting the PPS-EOM (3), it transmits a flag, receives the DIS signal, and after receiving the DIS signal, shifts to transmitting the DCS signal. I do. Further, the receiver sends out the MCF signal every time one PPS-EOM signal is received. In other words, MCF <1> is transmitted to PPS-EOM <1>, MCF <2> is transmitted to PPS-EOM <2>, and the preamble (PPS- When the number of flags greater than the number of flags included between EOMs is detected, the transmission of the MCF is stopped, and the flow shifts to the transmission of the DIS (above, (1-2-2) in FIG. 3).
[0050]
Also, in the ECM procedure, if it is the last page, the transmitter continuously transmits the PPS-EOP signal until the MCF signal is received. Since the transmitter has received the MCF (1) at the time of transmitting the PPS-EOP (3), the transmitter transmits the DCN and releases the line. Further, the receiver sends out the MCF signal every time one PPS-EOP signal is received. That is, MCF <1> is transmitted to PPS-EOP <1>, MCF <2> is transmitted to PPS-EOP <2>, and MCF <3> is transmitted to PPS-EOP <3>. Send out. Thereafter, when the DCN is received, the line is released.
[0051]
Next, a control procedure at the time of occurrence of an error shown in (2) of FIG. 4 will be described.
[0052]
In FIG. 4, since the DIS (1) transmitted by the receiver has an error on the line, the transmitter has a longer flag transmission time. The receiver continuously sends out the DIS signal until receiving the DCS signal. The transmitter sends DCS (1) to DIS (2), which is assumed to have an error on the line.
[0053]
Subsequently, the transmitter transmits DCS (2) to DIS (3), DCS (3) to DIS (4), and DCS (4) to DIS (5). Since the CFR signal has not been received at the time of transmitting and receiving the DCS {4}, the DCS is transmitted thereafter until the CFR signal is received. Here, the reception of the CFR (2) ends when the DCS (5) is transmitted, so that the operation shifts to the transmission of the image signal.
[0054]
On the other hand, the receiver receives DCS (2) at the end of transmission of DIS (5), and thus shifts to transmission of a CFR signal. CFR (1) is transmitted to DCS (2), but an error occurs on the line, and CFR (2) is transmitted to DCS (3) and CFR (3) is transmitted to DCS (4). Since the next DCS (5) has not been received at the time when the transmission of CFR (3) has been completed, the flag is transmitted, and at the time when the reception of DCS (5) has been completed, the CFR (4) is transmitted. , PIX (image signal) is detected, the transmission of CFR <4> is interrupted on the way, and the flow shifts to the reception of the image signal.
[0055]
The transmitter transmits the synchronization signal after the transmission of the image signal is completed, and the receiver transmits the synchronization signal after the reception of the image signal is completed. Thereafter, the transmitter transmits a Q (= PPS-MPS) signal until receiving the MCF signal. Here, Q (1) causes an error on the line, and then Q (2), Q (3), Q (4), and Q (5) are transmitted, and at the time of transmission of Q (5), MCF (2) is transmitted. Since it has been received, after waiting for 75 ms ± 20 ms, the processing shifts to transmission of the image signal.
[0056]
On the other hand, the receiver sends a flag after sending the synchronization signal, and sends an MCF (1) for Q (2). An MCF (3) is sent to MCF (2) and Q (4), and an MCF (4) is sent to Q (5). Since the PIX (image signal) is detected during the transmission of the MCF-4, the transmission of the MCF-4 is interrupted and the operation shifts to the reception of the image signal (hereinafter, (2-1) in FIG. 4).
[0057]
Next, (2-2) of FIG. 4 is a specific example in a case where an MCF signal cannot be returned immediately because a received image is being recorded or the like. First, the transmitter transmits a synchronization signal after the transmission of an image signal is completed, and the receiver transmits a synchronization signal after the reception of the image signal is completed. Thereafter, the transmitter continuously transmits the Q signal. When the transmitter receives the Q (3) and receives the RNR signal, the transmitter transmits a flag until the MCF is received. When the MCF is received, the image signal is transmitted. Is sent.
[0058]
On the other hand, the receiver sends a flag after the end of sending the synchronization signal, and when it receives Q (1), it cannot receive the next page, so it sends an RNR signal and the next page can be received. Send the flag up to. Then, when the reception of the next page becomes possible, the MCF is transmitted, the flag is detected until the PIX is detected, and when the PIX is detected, the flow shifts to the reception of the image signal.
[0059]
FIGS. 7 and 8 are flowcharts showing the flow of control in the post-procedure as described above.
[0060]
First, FIG. 7 shows a post-procedure on the transmitter side. After transmitting a synchronization signal in S40, if there is a next block in S42, if there is a PPS-NULL signal, there is a next page and there is no mode change, A PPS-MPS signal, a PPS-EOM signal if there is a next page and a mode change, and a PPS-EOP signal if there is no next page are continuously transmitted.
[0061]
When the MCF signal is received, the image signal is transmitted when transmitting the PPS-NULL signal or the PPS-MPS signal, and the process proceeds to (5) in FIG. 5 when transmitting the PPS-EOM signal. When transmitting the PPS-EOP signal, the DCN signal is transmitted to open the line (S44).
[0062]
Here, when T _T times out, the line is released in S46. When receiving the RNR signal, the flag is transmitted in S48, and when the MCF is received, the process proceeds to S44. When the PPR is received, it is determined whether or not it is the fourth PPR reception. If the PPR is received, the process proceeds to S54 (at this time, the reception counter of the PPR is cleared). If not, the flow advances to S52 to retransmit the image signal of the error frame specified by the PPR signal.
[0063]
If the error retransmission of the frame is continued in S54, CTC is continuously transmitted in S56. Then, the process proceeds to S52 upon receipt of the CTR, the process proceeds to S58 and _T T time-out, the line is opened. If error retransmission of the frame is not continued in S54, EOR-Q is continuously transmitted in S60, and when ERR is received, DCN is transmitted in S62 to release the line.
[0064]
Figure 8 shows a post-procedure in the receiver, after having sent the synchronization signal at S70, sends a flag (S72), the process proceeds to S74 Upon receiving the Q signal, T _R timer (predetermined time response reception When the value timer expires, the process proceeds to S76, and the line is released.
[0065]
If the reception of one page was performed without error, but the output (recording) of one page has not been completed, and flow control is desired, an RNR signal is transmitted in S78, and then a flag is transmitted. (S80) If the recording of the next page becomes possible, the process proceeds to S74, and the MCF is transmitted. In S74, the reception status of the image signal is determined, and if there is no error frame, the MCF is transmitted, if there is an error frame, the PPR is transmitted, if the CTC signal is received, the CTR signal is transmitted, and the EOR-Q signal is received. Send out the ERR signal.
[0066]
Next, if the image signal has not been received or the reception of the Q signal has not been completed, a flag is transmitted in S82, a PPR or CTR is transmitted in S74, and if a PIX is received, the flag is retransmitted in S84. When the image information is received and the received Q is the PPS-EOM and no error is detected and the flag is detected, the process proceeds to (6) in FIG. 6, and the received Q is the PPS-MPS or PPS-NULL and the error is free. When the PIX is received, the image signal is received in S86, the received Q is PPS-EOP or EOR-Q, and after transmitting MCF or ERR and receiving DCN, the line is opened in S88.
[0067]
In addition, T2 or T _R timer when the time is over, the line is opened at S90. When the CTC signal is received, the process proceeds to S74 again, the CTR is transmitted, the PIX is not received, and when the Q signal is received, the process again proceeds to S74. When the EOR-Q is received, the process again proceeds to S74.
[0068]
Next, switching control between full-duplex communication and half-duplex communication of a procedural signal will be described with reference to FIG.
[0069]
Since the receiver can perform the full-duplex communication and the half-duplex communication of the procedure signal, the receiver first transmits a signal (200) indicating that the full-duplex communication is possible. If the transmitter side is a facsimile apparatus of a type that transmits a procedure signal by half-duplex communication as described in the conventional example, a silent or CNG signal is transmitted. Therefore, if the receiver side cannot hear a signal indicating that full-duplex communication of the procedure signal from the transmitter side is performed within a predetermined time (addition to this condition, further, the conventional procedure signal A condition that a CNG signal of a type that performs half-duplex communication may be added) may be added to a signal of a type that performs half-duplex communication of a conventional procedural signal, specifically, CED, NSF / CSI / The process proceeds to DIS transmission (201). Here, the CED may be omitted.
[0070]
Here, when receiving the NSS / TSI / DCS (202), the receiver executes the conventional half-duplex communication of the procedural signal. When the receiver cannot receive the NSS / TSI / DCS or the like, the receiver again performs the NSF / CSI / DCS. Send DIS. Here, instead of NSF / CSI / DIS, a signal indicating that full-duplex communication of the procedure signal is possible may be alternately transmitted with NSF / CSI / DIS. When the transmitter detects a signal indicating that full-duplex communication of the procedure signal is possible in response to the signal (S200) indicating that full-duplex communication of the procedure signal transmitted by the receiver is possible, Thereafter, full-duplex communication is executed.
[0071]
In the above description, half-duplex communication is performed for the image signal. However, the image signal may perform full-duplex communication similarly to the procedure signal. FIG. 10 is an explanatory diagram showing an example of a procedure in which an image signal is set to full-duplex communication.
[0072]
The receiver side receives the image signal formatted in HDLC, returns nothing if there is no error, sends out the MCF signal after sending out the last frame, and outputs the conventional T.264 signal. The communication protocol is the same as the communication protocol specified in 30. However, when an error is detected, the error frame No. And a retransmission request (300) is made.
[0073]
Upon detecting this, the transmitter may transmit the retransmission frame (302) after transmitting the final frame (301), or may transmit the retransmission frame when detecting the error frame retransmission request signal. Further, after transmitting the last frame, the transmitter transmits the Flag signal (305) and continues this until the reception good signal (MCI) (304) from the receiver is detected, thereby securing full-duplex communication. .
[0074]
After receiving the MCF from the receiver, if there is a next page, the transmitter shifts to image transmission of the next page without signal interruption.
[0075]
【The invention's effect】
According to the present invention, it is possible to smoothly switch between full-duplex communication and half-duplex communication .
[Brief description of the drawings]
FIG. 1 is a block diagram showing one embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a specific example of a procedure in the first embodiment of the present invention.
FIG. 3 is an explanatory diagram showing a specific procedure example in the first embodiment.
FIG. 4 is an explanatory diagram showing a specific example of a procedure in the first embodiment.
FIG. 5 is a flowchart showing a specific example of a procedure in the first embodiment.
FIG. 6 is a flowchart showing a specific example of a procedure in the first embodiment.
FIG. 7 is a flowchart showing a specific example of a procedure in the first embodiment.
FIG. 8 is a flowchart showing a specific example of a procedure in the first embodiment.
FIG. 9 is an explanatory diagram showing a specific example of a procedure in the second embodiment of the present invention.
FIG. 10 is an explanatory diagram showing a specific example of a procedure in the second embodiment.
[Explanation of symbols]
2 ... NCU,
4: Phone,
6 ... Hybrid circuit,
8, 22 ... modulator,
10 ... Reading circuit,
16 ... encoding circuit,
18, 32 ... memory circuit,
20: decoding / magnification / encoding circuit,
24 ... addition circuit,
26, 28 ... demodulator,
30 decoding / encoding circuit,
34 ... Decoding circuit,
36 ... Recording circuit,
54 ... Control circuit.

Claims (1)

In a facsimile machine capable of full-duplex communication and half-duplex communication of procedure signals,
First, the receiver sends out a predetermined signal capable of full-duplex communication, and if a predetermined signal capable of full-duplex communication is detected from the transmitter within a predetermined time, full-duplex communication of the procedure signal is performed. A facsimile apparatus for transmitting a predetermined signal capable of performing half-duplex communication at a receiver side when a predetermined signal capable of performing full-duplex communication is not detected from a transmitter side within a predetermined time. .

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