JP2010161558A - Data communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce influence of crosstalk noise of a data communication device to improve communication quality, and to reduce manual adjustment work. <P>SOLUTION: In this data communication device using a plurality of multi-drop pair wires 1, 2 as transmission media, and including a network wherein a master modem 10 and a plurality of slave modems 11, 12, 21, 22 are formed in correspondence of 1:N, a crosstalk control section 10c and a crosstalk monitoring section 11c, 12c, 21c, 22c are mounted in the master modem 10 and the slave modems 11, 12, 21, 22, respectively, to link crosstalk noise control signals among the master modem 10 and the slave modems 11, 12, 21, 22, and the master modem 10 is provided with a processing function for reducing transmission power. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention is applied to a distribution automation system in which a plurality of multi-drop pair lines are used as a transmission medium and a communication mode from a parent device (built-in modem) to a plurality of child devices (built-in modem) is a multi-drop configuration. The present invention relates to a data communication apparatus.

  In a conventional data communication apparatus, when a data communication apparatus configured with another one-to-one counter modem is in the vicinity of a data communication apparatus configured with a one-to-one counter modem, one data communication apparatus is temporarily Stop communication and monitor crosstalk noise with other lines. When the crosstalk noise exceeding the threshold is detected by this monitor, the signal to the data communication apparatus determined to be the cause of the noise is minimized, and the different data communication apparatuses are operated with the minimum interference. Such an apparatus is disclosed in Patent Document 1, for example.

JP 2000-500948 (page 25, Fig. 1)

  Since the conventional data communication apparatus is configured as described above, when the network configuration is 1: N and communication is performed from one parent modem to N child modems, the farthest child modem is used. When transmitting with a high transmission power level from the parent modem, the transmission level of the child modem can be minimized, but the power of the signal transmitted from the parent modem at a high output Because the level cannot be adjusted, the reception attenuation level on the child modem side was set to the minimum (decrease in reception sensitivity), or the signal transmission level was adjusted manually by investigating the local environment in advance. . In addition, when it is difficult to investigate the local environment, there are many cases in which a signal transmission level that does not affect the modem is fixedly set in each modem, but there is a problem that a transmission distance is restricted.

  The present invention has been made to solve the above-described problems, and is the same even when the network configuration is 1: N and communication is performed from one parent modem to N child modems. Improve communication quality by automatically suppressing crosstalk noise generated from different multi-drop pair wires or different cables in the cable, and reduce adjustment costs by reducing manual adjustment work. It is another object of the present invention to obtain a data communication apparatus capable of noise reduction control that secures a communication distance as much as possible by gradually reducing the transmission power level from the parent modem.

  The data communication apparatus according to the present invention includes a first multi-drop pair line, a second multi-drop pair line, a pair line interface unit that transmits / receives data to / from the first and second multi-drop pair lines, and the pair. A parent modem having a modem section connected to a line interface section and having a modulation / demodulation function; and a crosstalk control section connected to the modem section and generating a signal for detecting a crosstalk influence; A pair line interface unit that is connected via a multi-drop pair line, transmits and receives data, a modem unit that is connected to the pair line interface unit and has a modulation / demodulation function, and a crosstalk monitor that is connected to the modem unit and detects a crosstalk signal And a parent modem transmits a crosstalk influence detection signal to the child modem. And a function of reducing the data transmission power level to the child modem that is affected by the crosstalk noise when receiving the crosstalk effect notification (influenced) from the child modem. It is.

  According to the present invention, communication quality is improved by automatically suppressing crosstalk noise generated from different multi-drop pair wires or different cables in the same cable, and adjustment costs are reduced by reducing manual adjustment work. Reduction can be achieved, and there is an effect that noise reduction control can be performed while ensuring the communication distance as much as possible by gradually reducing the transmission power level from the parent modem.

It is a block diagram which shows the data communication apparatus which concerns on Embodiment 1 of this invention. It is an example of a processing flow when there is no influence of the crosstalk noise in the first embodiment. It is an example of a processing flow in case there exists the influence of the crosstalk noise in Embodiment 1. FIG. It is a block diagram which shows the data communication apparatus which concerns on Embodiment 2 of this invention. It is an example of a processing flow when there is no influence of the crosstalk noise in the second embodiment. It is an example of a processing flow in case there exists the influence of the crosstalk noise in Embodiment 2. FIG. It is a block diagram which shows the data communication apparatus which concerns on Embodiment 3 of this invention. 10 is an example of a processing flow in the third embodiment. It is a block diagram which shows the data communication apparatus which concerns on Embodiment 4 of this invention. It is a block diagram which shows the data communication apparatus which concerns on Embodiment 5 of this invention. It is an example of a processing flow in case there exists the influence of the crosstalk noise in Embodiment 5.

Embodiment 1 FIG.
A first embodiment of the present invention will be described below with reference to FIG. FIG. 1 is a diagram showing the configuration of a data communication apparatus according to the present invention. In FIG. 1, a parent modem 10 includes a pair line interface unit 10a connected to the first and second multidrop pair lines 1 and 2, a modem unit 10b connected to the pair line interface unit 10a, and a modem. A crosstalk control unit 10c connected to the unit 10b. A signal transmission level control line 10d is connected between the crosstalk control unit 10c and the modem unit 10b.

  Child modems 11 and 12 are connected to the first multidrop pair line 1. Similarly, the child modems 21 and 22 are connected to the second multidrop pair line 2. Each of the child modems 11, 12, 21, and 22 includes a pair line interface unit 11a, 12a, 21a, and 22a, a modem unit 11b, 12b, 21b, and 22b, and a crosstalk monitoring unit 11c, 12c, 21c, and 22c, respectively. It has. The pair line interface units 11a and 12a are connected to the first multi-drop pair line 1, the pair line interface units 21a and 22a are connected to the second multi-drop pair line 2, and the modem unit is connected to each pair line interface unit. The crosstalk monitoring unit is connected to each modem unit.

  Here, the frequency used for communication between the pair line interface unit 10a, the pair line interface unit 11a, and the pair line interface unit 12a, and the communication between the pair line interface unit 10a, the pair line interface unit 21a, and the pair line interface unit 22a. The frequency used is the same.

  In the data communication apparatus having the above configuration, the parent modem 10 exchanges data with the child modems 11 and 12 through the first multidrop pair line 1. Similarly, the parent modem 10 exchanges data with the child modems 21 and 22 through the second multidrop pair line 2. Immediately after activation, the parent modem 10 sends a crosstalk influence detection signal from the crosstalk control unit 10c to the child modems 11, 12 and 21, 22 through the paired line interface unit 10a. After a predetermined time, when the parent modem 10 receives an affected crosstalk notification from the child modem 11, for example, the crosstalk control unit 10c passes the paired line interface unit 10a to the child modem 21 that causes the crosstalk. By automatically reducing the signal transmission level to 22 and performing data transmission, the influence of crosstalk is reduced.

  Next, the operation will be described in more detail with reference to FIGS. When the parent modem 10 is activated, the parent modem 10 performs crosstalk control processing. FIG. 2 shows processing when there is no influence of crosstalk noise, and FIG. 3 shows processing when there is influence of crosstalk noise. In the processing procedure shown below, the reference numerals (A1, A2,...) Given at the beginning of the description of the procedure are the same as those shown in FIGS.

(A1) First, whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multi-drop pair line 2 when the parent modem 10 is started has an influence on the child modem 11 and the child modem 12. The crosstalk control unit 10c generates a signal (crosstalk effect detection signal (preliminary notification)) for the purpose of notifying in advance that a signal for confirming the transmission is transmitted, and the modem unit 10b and the pair line interface The data is transmitted to the child modem 11 via the unit 10a and the first multi-drop pair line 1. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(A2) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(A3) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors for n seconds whether this power level exceeds the threshold level registered in advance by setting or the like. To do.

(A4) When a signal equal to or higher than the threshold level is not detected in the A3 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 11c. The data is transmitted to the parent modem 10 via the modem unit 11b and the pair line interface unit 11a. The crosstalk effect notification (no effect) is received by the crosstalk control unit 10c via the pair line interface unit 10a and the modem unit 10b.

(A5) The crosstalk influence detection signal (preliminary notification) of the above item A1 is generated by the crosstalk control unit 10c, via the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1. Transmit to the child modem 12. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 12c via the pair line interface unit 12a and the modem unit 12b.

(A6) The crosstalk control unit 10c generates the crosstalk influence detection signal of the above A2 term, and the slave modem 21 and the slave modem via the modem unit 10b, the pair line interface unit 10a, and the second multidrop pair line 2 To 22 address.

(A7) The child modem 12 monitors the power level of the frequency band used by the child modem 12 for communication, and monitors for n seconds whether this power level exceeds the threshold level registered in advance by setting or the like. To do.

(A8) If a signal of a threshold level or higher is not detected in the above A7 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 12c. The data is transmitted to the parent modem 10 via the modem unit 12b and the pair line interface unit 12a.

(A9) A signal for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multi-drop pair line 1 has an influence on the child modem 21 and the child modem 22 is transmitted. A signal (crosstalk effect detection signal (preliminary notification)) for generating notification in advance is generated by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the second multi-drop The data is transmitted to the child modem 21 via the pair line 2. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 21c via the pair line interface unit 21a and the modem unit 21b.

(A10) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multidrop pair line 1 has an influence on the child modem 21 and the child modem 22. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 11 and the child modem 12 via the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1.

(A11) The child modem 21 monitors the power level of the frequency band used for communication by the child modem 21 itself, and monitors for n seconds whether this power level exceeds a threshold level registered in advance by setting or the like. To do.

(A12) If a signal equal to or higher than the threshold level is not detected in the above A11 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 21c. The data is transmitted to the parent modem 10 via the modem unit 21b and the pair line interface unit 21a.

(A13) The crosstalk influence detection signal (preliminary notification) of the above item A9 is generated by the crosstalk control unit 10c, and is transmitted through the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2. Transmit to the modem 22. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 21c via the pair line interface unit 21a and the modem unit 21b.

(A14) The crosstalk control unit 10c generates the crosstalk effect detection signal of the above item A10, and transmits the slave modem 11 and the child via the modem unit 10b, the pair line interface unit 10a, and the first multidrop pair line 1. Transmit to the modem 12.

(A15) The child modem 22 monitors the power level of the frequency band used for communication by the child modem 22 itself, and monitors for n seconds whether this power level exceeds the threshold level registered in advance by setting or the like. To do.

(A16) If a signal equal to or higher than the threshold level is not detected in the above item A15, the crosstalk monitoring unit 22c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)), The data is transmitted to the parent modem 10 via the modem unit 22b and the pair line interface unit 22a.

  Next, when there is an influence of crosstalk noise, the processing of FIG. 3 is performed. The processing procedure is shown below. The following procedure describes an example in which crosstalk noise due to a signal on the second multidrop pair line 2 affects the child modem 11.

(B1) When the parent modem 10 is started up, it is confirmed whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. The crosstalk control unit 10c generates a signal (crosstalk effect detection signal (preliminary notification)) for the purpose of notifying in advance that a signal for transmission is transmitted, and the modem unit 10b and the pair line interface unit 10a. , And the first multi-drop pair line 1 is transmitted to the child modem 11. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(B2) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(B3) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors for n seconds whether this power level exceeds the threshold level registered in advance by setting or the like. To do.

(B4) When a signal equal to or higher than the threshold level is detected in the item B3, the crosstalk monitoring unit 11c generates a signal (crosstalk effect notification (influenced)) indicating that there is an effect of crosstalk noise, and the modem The data is transmitted to the parent modem 10 via the unit 11b and the pair line interface unit 11a. The crosstalk influence notification (influenced) is received by the crosstalk control unit 10c via the pair line interface unit 10a and the modem unit 10b.

(B5) The crosstalk control unit 10c causes the signal transmission level control line 10d to lower the power level of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 with respect to the modem unit 10b. Control through.

(B6) The crosstalk control unit 10c attenuates (downs) the power level of the signal transmitted from the modem unit 10b to the second multi-drop pair line 2. The power level to be attenuated at this time may be a value determined in advance by setting or the like, or may be an arbitrary level.

(B7) A signal for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multi-drop pair line 2 has an influence on the child modem 11 and the child modem 12 is transmitted. A signal (crosstalk effect detection signal (preliminary notification)) for generating notification in advance is generated by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the first multi-drop The data is transmitted to the child modem 11 via the pair line 1. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(B8) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(B9) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors this power level for n seconds to check whether it exceeds a threshold level registered in advance by setting or the like. To do.

(B10) When a signal above the threshold level is detected in the above B9 term, the processing of the above B4 to B6 is performed until no signal above the threshold level is detected. If no signal of the threshold level or higher is detected in the item B9, the crosstalk monitoring unit 11c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)), and the modem. The data is transmitted to the parent modem 10 via the unit 11b and the pair line interface unit 11a.

Embodiment 2. FIG.
In the first embodiment, the crosstalk control unit 10c and the crosstalk monitoring units 11c, 12c, 21c, and 22c allow the child modems 11 to 22 to cross-link from adjacent multi-drop pair lines when the parent modem 10 is activated. Although the case where talk noise is reduced has been described, in the second embodiment, as shown in FIG. 4, a device activation detection unit 111a and a crosstalk control request signal generation unit 111b are provided in the child modem 11 to detect device activation. The unit 111a and the crosstalk control request signal generation unit 111b are connected, and the crosstalk control request signal generation unit 111b and the modem unit 11b are further connected. Further, a crosstalk control request detecting unit 101a is provided in the parent modem 10 and connected to the crosstalk control unit 10c. Since other configurations are the same as those of the first embodiment, the corresponding elements are denoted by the same reference numerals and description thereof is omitted.

  As a result, the apparatus activation detection unit 111a detects activation when the child modem 11 is activated, and the apparatus activation detection unit 111a transmits an activation detection signal to the crosstalk control request signal generation unit 111b, thereby generating a crosstalk control request signal. Since the unit 111b requests the crosstalk control unit 10c to perform the crosstalk control, even if the installation conditions of the child modem suddenly change due to the addition of the child modem 11, the crosstalk can be suppressed at that timing. Thus, it becomes possible to further improve the reliability of the entire system.

  In the above paragraph 0039, the child modem 11 has been described. However, the device activation detection unit 121a and the crosstalk control request signal generation unit 121b, the device activation detection unit 211a, and the crosstalk control request signal are also used for the child modems 12, 21, and 22. By providing the generation unit 211b, the apparatus activation detection unit 221a, and the crosstalk control request signal generation unit 221b, the same effect can be obtained.

  Next, an operation when the child modem 11 is activated will be described. When the child modem 11 is activated, the child modem 11 performs a crosstalk control process. The processing when there is no influence of crosstalk noise is shown in FIG. The processing procedure is shown below.

(C1) When the slave modem 11 is activated, the device activation detection unit 111a detects activation of the child modem 11, and transmits an activation detection signal from the device activation detection unit 111a to the crosstalk control request signal generation unit 111b. Thereby, the crosstalk control request signal generation unit 111b transmits a crosstalk control request signal to the parent modem 10 via the modem unit 11b, the pair line interface unit 11a, and the first multidrop pair line 1. The crosstalk control request signal is received by the crosstalk control request detection unit 101a via the pair line interface unit 10a, the modem unit 10b, and the crosstalk control unit 10c.

(C2) The crosstalk control request detection unit 101a causes the crosstalk control unit 10c to detect the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 as the child modem 11 and the child modem. 12 is instructed to generate a signal (crosstalk effect detection signal (preliminary notification)) for the purpose of notifying in advance that a signal for confirming whether or not the signal 12 has been affected is transmitted. As a result, the crosstalk control unit 10c generates a crosstalk effect detection signal (advance notification), and is addressed to the child modem 11 via the modem unit 10b, the pair line interface unit 10a, and the first multidrop pair line 1. Send. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(C3) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(C4) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors for n seconds whether the power level does not exceed a threshold level registered in advance by setting or the like. To do.

(C5) When a signal equal to or higher than the threshold level is not detected in the C4 term, the crosstalk monitoring unit 11c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)). The data is transmitted to the parent modem 10 via the modem unit 11b and the pair line interface unit 11a. The crosstalk effect notification (no effect) is received by the crosstalk control unit 10c via the pair line interface unit 10a and the modem unit 10b.

(C6) The crosstalk influence detection signal (preliminary notification) of the above C2 term is generated by the crosstalk control unit 10c, and is transmitted through the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1. Transmit to the modem 12. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 12c via the pair line interface unit 12a and the modem unit 12b.

(C7) The crosstalk control unit 10c generates the crosstalk effect detection signal of the above C3 term, and the slave modem 21 and the slave are connected via the modem unit 10b, the pair line interface unit 10a, and the second multidrop pair line 2. Transmit to the modem 22.

(C8) The child modem 12 monitors the power level of the frequency band used for communication by the child modem 12 itself, and monitors this power level for n seconds to check whether it exceeds a threshold level registered in advance by setting or the like. To do.

(C9) If no signal of the threshold level or higher is detected in the C8 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 12c. The data is transmitted to the parent modem 10 via the modem unit 12b and the pair line interface unit 12a.

(C10) A signal for confirming whether the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multi-drop pair line 1 has an influence on the child modem 21 and the child modem 22 is transmitted. A signal (crosstalk effect detection signal (preliminary notification)) for generating notification in advance is generated by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the second multi-drop The data is transmitted to the child modem 21 via the pair line 2. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 21c via the pair line interface unit 21a and the modem unit 21b.

(C11) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multidrop pair line 1 has an influence on the child modem 21 and the child modem 22. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 11 and the child modem 12 via the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1.

(C12) The child modem 21 monitors the power level of the frequency band used for communication by the child modem 21 itself, and monitors for n seconds whether this power level does not exceed a threshold level registered in advance by setting or the like. To do.

(C13) If no signal exceeding the threshold level is detected in the above C12 term, the crosstalk monitoring section 21c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)), and the modem The data is transmitted to the parent modem 10 via the unit 21b and the pair line interface unit 21a.

(C14) The crosstalk effect detection signal (preliminary notification) of the above item C10 is generated by the crosstalk control unit 10c, and is transmitted through the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2. Transmit to the modem 22. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 22c via the pair line interface unit 22a and the modem unit 22b.

(C15) The crosstalk control unit 10c generates the crosstalk effect detection signal of the above item C11, and the slave modem 11 and the slave are connected via the modem unit 10b, the pair line interface unit 10a, and the first multidrop pair line 1. Transmit to the modem 12.

(C16) The child modem 22 monitors the power level of the frequency band used for communication by the child modem 22 itself, and monitors for n seconds whether this power level exceeds the threshold level registered in advance by setting or the like. To do.

(C17) If a signal equal to or higher than the threshold level is not detected in the C16 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 22c. The data is transmitted to the parent modem 10 via the modem unit 22b and the pair line interface unit 22a.

Next, when there is an influence of stroke noise, the processing of FIG. 6 is performed. The processing procedure is shown below. In the following procedure, an example in which crosstalk noise caused by a signal on the second multi-drop pair line 2 affects the child modem 11 will be described.

(D1) When the child modem 11 is activated, the device activation detection unit 111a detects activation of the child modem 11, and transmits an activation detection signal from the device activation unit 111a to the crosstalk control request signal generation unit 111b. As a result, the crosstalk control request signal generation unit 111b transmits a crosstalk control request signal to the parent modem 10 via the modem unit 11b, the pair line interface unit 11a, and the first multi-drop pair line 1. The crosstalk control request signal is received by the crosstalk control request detection unit 101a via the pair line interface unit 10a, the modem unit 10b, and the crosstalk control unit 10c.

(D2) The crosstalk control request detection unit 101a causes the crosstalk control unit 10c to detect the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multi-drop pair line 2 as the child modem 11 and the child modem. 12 is instructed to generate a signal (crosstalk effect detection signal (preliminary notification)) for the purpose of notifying in advance that a signal for confirming whether or not the signal 12 has been affected is transmitted. As a result, the crosstalk control unit 10c generates a crosstalk effect detection signal (advance notification), and is addressed to the child modem 11 via the modem unit 10b, the pair line interface unit 10a, and the first multidrop pair line 1. Send. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(D3) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. The influence detection signal is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(D4) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors this power level for n seconds to check whether it exceeds a threshold level registered in advance by setting or the like. To do.

(D5) When a signal equal to or higher than the threshold level is detected in the item D4, the crosstalk monitoring unit 11c generates a signal (crosstalk influence signal (with influence)) indicating that there is an influence of crosstalk noise, and the modem The data is transmitted to the parent modem 10 via the unit 11b and the pair line interface unit 11a. The crosstalk influence detection signal (with an influence) is received by the crosstalk control section 10c via the pair line interface section 10a and the modem section 10b.

(D6) The crosstalk control unit 10c controls the modem unit 10b via the signal transmission level control line 10d so as to lower the power level of the signal transmitted from the modem unit 10b to the second multi-drop pair line 2. To do.

(D7) The crosstalk control unit 10c attenuates (downs) the power level of the signal transmitted from the modem unit 10b to the second multidrop pair line 2 via the pair line interface unit 10a. The power level to be attenuated at this time may be a value determined in advance by setting or the like, or may be an arbitrary level.

(D8) A signal for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multi-drop pair line 2 has an influence on the child modem 11 and the child modem 12 is transmitted. A signal (crosstalk effect detection signal (preliminary notification)) intended to be notified in advance is transmitted to the child modem 11 via the crosstalk pair line 1. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(D9) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. The influence detection signal is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(D10) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors for n seconds whether this power level does not exceed the threshold level registered in advance by setting or the like. To do.

(D11) When a signal above the threshold level is detected in the above D10 term, the processing of the above D5 to D7 is performed until a signal above the threshold level is not detected. If no signal of the threshold level or higher is detected in the D10 term, the crosstalk monitoring unit 11c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)), and the modem. The data is transmitted to the parent modem 10 via the unit 11b and the pair line interface unit 11a.

Embodiment 3 FIG.
In the first embodiment, the crosstalk control unit 10c and the crosstalk monitoring units 11c, 12c, 21c, and 22c allow the child modems 11 to 22 to crosstalk from the adjacent multidrop pair lines when the parent modem 10 is activated. Although the case of reducing noise has been described, in the third embodiment, as shown in FIG. 7, the crosstalk reduction timing generation unit 102a is connected to the crosstalk control unit 10c, and the crosstalk reduction timing generation unit 102a is connected in advance. Based on the set timing (fixed period or irregular), it is possible to perform control for reducing crosstalk. As a result, even when the influence of crosstalk occurs due to changes in the surrounding environment of the child modems 11 to 22 while the parent modem 10 is activated, the crosstalk can be suppressed with dynamic timing, and the reliability of the entire system Can be further increased.

Next, the operation will be described. When the parent modem 10 is activated, the parent modem 10 performs a crosstalk control process. When there is no influence of the crosstalk noise, the processing of FIG. 8 is performed. The processing procedure is shown below.

(E1) Check whether the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multi-drop pair line 2 does not affect the child modem 11 and the child modem 12 when the parent modem 10 is activated. The crosstalk unit 10c generates a signal (crosstalk effect detection signal (preliminary notification)) for the purpose of notifying in advance that a signal for transmission is transmitted, and the modem unit 10b, the pair line interface unit 10a, And transmitted to the child modem 11 via the first multi-drop pair line 1. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 11c via the pair line interface unit 11a and the modem unit 11b.

(E2) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the second multidrop pair line 2 has an influence on the child modem 11 and the child modem 12. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 21 and the child modem 22 via the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2.

(E3) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and if this power level does not exceed the threshold level registered in advance by setting or the like, n seconds Monitor.

(E4) If a signal equal to or higher than the threshold level is not detected in the above E3 term, the crosstalk monitoring unit 11c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)). The data is transmitted to the parent modem 10 via the modem unit 11b and the pair line interface unit 11a. The crosstalk influence detection signal (no influence) is received by the crosstalk control section 10c via the pair line interface section 10a and the modem section 10b.

(E5) The crosstalk effect detection signal (preliminary notification) of the above E1 term is generated by the crosstalk control unit 10c, and is transmitted through the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1. Transmit to the modem 12. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 12c via the pair line interface unit 12a and the modem unit 12b.

(E6) The crosstalk control unit 10c generates the crosstalk effect detection signal of the above E2 term, and the slave modem 21 and the slave are connected via the modem unit 10b, the pair line interface unit 10a, and the second multidrop pair line 2. Transmit to the modem 22.

(E7) The child modem 12 monitors the power level of the frequency band used for communication by the child modem 12 itself, and monitors this power level for n seconds to check whether it exceeds a threshold level registered in advance by setting or the like. To do.

(E8) When a signal equal to or higher than the threshold level is not detected in the above E7 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 12c. The data is transmitted to the parent modem 10 via the modem unit 12b and the pair line interface unit 12a.

(E9) A signal for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multi-drop pair line 1 has an influence on the child modem 21 and the child modem 22 is transmitted. A signal (crosstalk effect detection signal (preliminary notification)) for generating notification in advance is generated by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the second multi-drop The data is transmitted to the child modem 21 via the pair line 2. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 21c via the pair line interface unit 21a and the modem unit 21b.

(E10) A signal (crosstalk for confirming whether or not the crosstalk noise of the signal transmitted from the pair line interface unit 10a to the first multidrop pair line 1 has an influence on the child modem 21 and the child modem 22. (Effect detection signal) is generated by the crosstalk control unit 10c and transmitted to the child modem 11 and the child modem 12 via the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1.

(E11) The sub-modem 21 monitors the power level of the frequency band used for communication by the sub-modem 21 itself, and monitors for n seconds whether this power level does not exceed the threshold level registered in advance by setting or the like. To do.

(E12) If a signal equal to or higher than the threshold level is not detected in the above E11 term, a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)) is generated by the crosstalk monitoring unit 21c. The data is transmitted to the parent modem 10 via the modem unit 21b and the pair line interface unit 21a.

(E13) The crosstalk effect detection signal (preliminary notification) of the above E9 term is generated by the crosstalk control unit 10c, and is transmitted through the modem unit 10b, the pair line interface unit 10a, and the second multi-drop pair line 2. Transmit to the modem 22. The crosstalk influence detection signal (preliminary notification) is received by the crosstalk monitoring unit 21c via the pair line interface unit 21a and the modem unit 21b.

(E14) The crosstalk control unit 10c generates the crosstalk effect detection signal of the above E10 term, and the slave modem 11 and the slave are connected via the modem unit 10b, the pair line interface unit 10a, and the first multidrop pair line 1. Transmit to the modem 12.

(E15) The child modem 22 monitors the power level of the frequency band used for communication by the child modem 22 itself, and monitors for n seconds whether the power level does not exceed the threshold level registered in advance by setting or the like. To do.

(E16) If a signal equal to or higher than the threshold level is not detected in the item E15, the crosstalk monitoring unit 22c generates a signal indicating that there is no influence of crosstalk noise (crosstalk influence notification (no influence)), The data is transmitted to the parent modem 10 via the modem unit 22b and the pair line interface unit 22a.

(E17) The crosstalk reduction timing generation unit 102a starts time count and counts m seconds (msec fixed period), and generates a crosstalk effect detection signal (preliminary notification) of the above E1 term. Thereafter, the above items E2 to E17 are repeated.

In addition, although the case where the timing which the crosstalk reduction timing generation part 102a produces | generates is a fixed period of m second, it demonstrated, even if the timing which the crosstalk reduction timing generation part 102a produces is irregular, there exists the same effect. Further, the case has been described where the crosstalk reduction timing generation unit 102a starts the timer count when the parent modem receives the crosstalk effect notification (no effect) from the child modem 22, but the timer count start trigger is Wherever it is, the same effect can be obtained by repeatedly performing the processing of the above E1 to E17.

Embodiment 4 FIG.
In the first embodiment, the crosstalk control unit 10c and the crosstalk monitoring units 11c, 12c, 21c, and 22c allow the child modems 11 to 22 to crosstalk from the adjacent multidrop pair lines when the parent modem 10 is activated. Although the case of reducing noise has been described, in the fourth embodiment, as shown in FIG. 9, a crosstalk occurrence location estimation unit 103a and a crosstalk occurrence location notification unit 103b are provided in the parent modem 10 to perform crosstalk control. The unit 10c and the crosstalk occurrence location estimation unit 103a are connected, and the crosstalk occurrence location estimation unit 103a and the crosstalk occurrence location notification unit 103b are connected. A network management apparatus 3 is connected to the parent modem 10.

  As a result, the crosstalk occurrence location estimation unit 103a receives the crosstalk influence notification (influenced) via the crosstalk control unit 10c, and in which section the crosstalk occurs in the crosstalk occurrence location estimation unit 103a. And the information is transmitted to a device such as the network management device 3 that manages this system via the crosstalk occurrence location notifying unit 103b. If it is detected, but the influence of crosstalk is not detected by the child modem 12, it is possible to infer problems such as a long parallel running distance with the adjacent multidrop pair line between the parent modem 10 and the vicinity of the child modem 11. , Maintenance efficiency can be improved.

Embodiment 5 FIG.
In the first embodiment, the case where the first multidrop pair line 1 and the second multidrop pair line 2 are connected to the pair line interface unit 10a in one parent modem 10 has been described. In the fifth embodiment, as shown in FIG. 10, a crosstalk control interface unit 41a and a crosstalk control arbitration unit 41b are provided in the parent modem (master) 41, and the crosstalk control unit 10c and the crosstalk control arbitration unit 41b are provided. And a crosstalk control arbitration unit 41b and a crosstalk control interface unit 41a were further connected. Further, a crosstalk control interface unit 42a is provided in the parent modem (slave) 42, and the crosstalk control unit 10c and the crosstalk control interface unit 42a are connected. An inter-modem cable 43 is connected between the parent modem (master) 41 and the parent modem (slave) 42. Since other configurations are the same as those of the first embodiment, the corresponding elements are denoted by the same reference numerals and description thereof is omitted.

  Thus, even when the signal injection location of the first multidrop pair line 1 and the signal injection location of the second multidrop pair line 2 are separated, the parent modem (master) 41 is connected via the inter-modem cable 43. And the parent modem (slave) 42 can perform crosstalk control, so that the installation location of the parent modem can be flexibly dealt with, and the efficiency of construction and maintenance can be improved.

  Next, the operation will be described. FIG. 11 shows processing when there is an influence of crosstalk noise. The processing procedure is shown below. The following procedure describes an example in which crosstalk noise due to a signal on the second multidrop pair line 2 affects the child modem 11.

(F1) The parent modem (master) 41 generates a crosstalk effect detection signal (preliminary notification) by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1 Is transmitted to the child modem 11 via. At this time, the crosstalk control arbitration unit 41b detects the crosstalk influence on the crosstalk control unit 10c in the parent modem (slave) 42 via the crosstalk control interface unit 41a, the inter-modem cable 43, and the crosstalk control interface unit 42a. Instructs to send a business signal.

(F2) The parent modem (slave) 42 generates a crosstalk influence detection signal by the crosstalk control unit 10c, and the child modem via the modem unit 10b, the pair line interface unit 10a, and the second multidrop pair line 2 21 and the child modem 22.

(F3) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors for n seconds whether this power level does not exceed the threshold level registered in advance by setting or the like. To do.

(F4) When a signal exceeding the threshold level is detected in the above F3 term, a crosstalk monitoring notice (influenced) is generated by the crosstalk monitoring unit 11c, and the parent modem (via the modem unit 11b and the paired line interface unit 11a) Master) 41. The crosstalk influence detection signal (with an influence) is received by the crosstalk control section 10c via the pair line interface section 10a and the modem section 10b.

(F5) The crosstalk control unit 10c in the parent modem (master) 41 is connected to the parent modem via the crosstalk control arbitration unit 41b, the crosstalk control interface unit 41a, the inter-modem cable 43, and the crosstalk control interface unit 42a. Signal transmission is performed so that the power level of the signal transmitted from the modem unit 10b in the parent modem (slave) 42 to the second multi-drop pair line 2 is lowered with respect to the crosstalk control unit 10c in the (slave) 42. Control is performed via the level control line 10d.

(F6) The crosstalk control unit 10c in the parent modem (slave) 42 attenuates (downs) the power level of the signal transmitted from the modem unit 10b to the second multi-drop pair line 2. The power level to be attenuated at this time may be a value determined in advance by setting or the like, or may be an arbitrary level.

(F7) When the power level attenuation is completed, the crosstalk control unit 10c in the parent modem (slave) 42 completes the parent modem via the crosstalk control interface unit 42a, the inter-modem cable 43, and the crosstalk control interface unit 41a. The crosstalk control unit 10c in the (master) 41 is notified that the power level attenuation has been completed.

(F8) The parent modem (master) 41 generates a crosstalk influence detection signal (preliminary notification) by the crosstalk control unit 10c, and the modem unit 10b, the pair line interface unit 10a, and the first multi-drop pair line 1 Is transmitted to the child modem 11 via.

(F9) The parent modem (slave) 42 generates a crosstalk influence detection signal by the crosstalk control unit 10c, and transmits the child modem via the modem unit 10b, the pair line interface unit 10a, and the second multidrop pair line 2. 21 and the child modem 22.

(F10) The child modem 11 monitors the power level of the frequency band used for communication by the child modem 11 itself, and monitors this power level for n seconds to check whether it exceeds a threshold level registered in advance by setting or the like. To do.

(F11) When a signal above the threshold level is detected in the above F10 term, the processing of the above F4 to F7 items is repeated until no signal above the threshold level is detected. Further, when a signal exceeding the threshold level is not detected in the above F9 term, a crosstalk effect notification (no effect) is generated by the crosstalk monitoring unit 11c, and the parent modem is connected via the modem unit 11b and the pair line interface unit 11a. (Master) 41.

1 first multi-drop pair wire, 2 second multi-drop pair wire,
3 Network management device, 10 Parent modem,
10a pair line interface, 10b modem section,
10c crosstalk control unit, 10d signal transmission level control line,
11, 12, 21, 22 child modem,
11a, 12a, 21a, 22a Pair line interface unit,
11b, 12b, 21b, 22b modem part,
11c, 12c, 21c, 22c Crosstalk monitoring unit,
41 Parent modem (master),
41a Crosstalk control interface unit,
41b Crosstalk control arbitration unit,
42 Parent modem (slave),
42a Crosstalk control interface unit,
43 Modem cable,
101a Crosstalk control request detection unit,
102a Crosstalk reduction timing generation unit,
103a Crosstalk occurrence location estimation unit,
103b Crosstalk occurrence location notifier,
111a Device activation detection unit,
111b crosstalk control request signal generator.

Claims (7)

First multi-drop pair wire,
Second multi-drop pair wire,
A pair line interface unit for transmitting / receiving data to / from the first and second multi-drop pair lines, a modem unit connected to the pair line interface unit and having a modulation / demodulation function, and a crosstalk effect detection signal connected to the modem unit A parent modem with a crosstalk controller that generates
Connected to the parent modem via the first or second multi-drop pair line to transmit / receive data, a modem unit connected to the pair line interface unit and having a modulation / demodulation function, and to the modem unit A child modem having a crosstalk monitoring unit for detecting a crosstalk signal,
When the parent modem sends a crosstalk influence detection signal to the child modem and receives a crosstalk influence notification (influenced) from the child modem, the parent modem is sent to the child modem that is affected by the crosstalk noise. A data communication apparatus characterized by having a function of reducing the data transmission power level. First multi-drop pair wire,
Second multi-drop pair wire,
A pair line interface unit that transmits / receives data to / from the first multi-drop pair line, a modem unit that is connected to the pair line interface unit and has a modulation / demodulation function, and a crosstalk effect detection signal that is connected to the modem unit A first parent modem with a crosstalk controller to perform,
A pair line interface unit that transmits / receives data to / from the second multi-drop pair line, a modem unit that is connected to the pair line interface unit and has a modulation / demodulation function, and a crosstalk effect detection signal that is connected to the modem unit A second parent modem with a crosstalk controller to perform,
A modem cable connecting the first parent modem and the second parent modem;
Data is transmitted / received by being connected to the first parent modem via the first multi-drop pair line or to the second parent modem via the second multi-drop pair line A paired line interface unit, a modem unit connected to the paired line interface unit and having a modulation / demodulation function, and a child modem including a crosstalk monitoring unit connected to the modem unit for detecting a crosstalk signal,
When the first parent modem sends a crosstalk influence detection signal from the first or second parent modem to the child modem and receives a crosstalk influence notification (influenced) from the child modem A data communication apparatus comprising: a crosstalk control arbitration unit for realizing, together with the second parent modem, a function of reducing a data transmission power level to a child modem affected by crosstalk noise.   The data communication device according to claim 1, wherein the child modem has a function of generating a signal that triggers reduction of crosstalk.   The said parent modem is provided with the crosstalk reduction timing production | generation part which has a function which sends the control signal for reducing crosstalk to the said child modem at a fixed period or irregular timing. Data communication equipment.   The first parent modem includes a crosstalk reduction timing generation unit having a function of sending a control signal for reducing crosstalk to the child modem at a fixed cycle or irregular timing. 2. The data communication device according to 2.   The parent modem includes a crosstalk occurrence section detection unit that estimates a section in which crosstalk has occurred based on the crosstalk effect notification received from each of the child modems and transmits the crosstalk to a network management device or the like. The data communication apparatus according to claim 1.   The first parent modem estimates a section where the crosstalk is generated based on the crosstalk influence notification received from each of the child modems, and transmits the section to a network management device or the like. The data communication apparatus according to claim 2, further comprising:

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