JPS63269659A - Data communication equipment - Google Patents

Abstract

PURPOSE:To simplify the constitution of a monitoring center and to reduce the burden of an operator, by providing plural sets of MODEMs corresponding to the modulating/ demodulating system of the MODEM of each terminal equipment at the monitoring center and selecting one whose modulating/demodulating system coincides with that of one terminal equipment with which messages are exchanged by means of a selecting means. CONSTITUTION:When data are transmitted to a monitoring center 1' from a terminal equipment 3, the data are transmitted to the center 1' by means of one circuit through the exchange of a data communication circuit. At the center 1', the data are inputted to each MODEM 7 and 11 and, after discriminating the MODEM 7 which makes an output, the MODEM 7 is selected by means of a selecting means 17 and the transmitted data are received through the selected MODEM 7. When data are transmitted from the center 1' to a prescribed terminal equipment 3, on the other hand, the MO DEM 7 of the monitoring center 1' is selected by means of the means 17, since the modulating/demodulating system of the MODEM of the terminal equipment 3 is already known and the MODEM 7 corresponds to the system, and the data to be transmitted are transmitted through the MODEM 7 after modulation. Therefore, the constitution of the monitoring center can be simplified without unifying the modulating/ demodulating system.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a data communication device that transmits and receives various data using a telephone line.

[Conventional technology]

Data communication devices are used that transmit and receive various data using telephone lines. FIG. 2 is a block diagram showing the configuration of a conventionally used data communication device. In this device, a monitoring center 1 connects a terminal device 3 to a terminal device 3 via a telephone line 2.
~3n and 4~4n are configured to exchange data. The terminal devices 3 to 3n have a transmission/reception system using the FSK modulation method, and the terminal devices 4 to 4n have a MF modulation method. Note that the FSX modulation method and the MF modulation method will be described later.

The monitoring center 1 is provided with a CPU 5 that performs predetermined control, and a memory 6 and a modem 7 are connected to the CPU 5. Modem 7 is connected to a signal terminal of network control circuit 8a.

On the other hand, the CPU 9 performs predetermined control and is connected to the memory IO and the modem 11. This modem 11 is connected to a signal terminal of the network control circuit 8b. Network control circuit 8a
, 8b are connected to one end of the telephone line 2.

The terminal devices 3 to 3n and 4 to 4n are installed in each building, monitor the equipment in the building, and send and receive equipment monitoring information to and from the monitoring center 1. The terminal devices 3 to 3n are equipped with the FSK modulation system as described above, and these are shown as terminals (3) in FIG.

Further, the terminal devices 4 to 4n are equipped with the MF modulation method as described above, and these are shown as terminals 2 in FIG. Here, the FSX modulation method and MF modulation method are shown in Figure 3 (a).
, (b) will be briefly explained.

Figure 3 (a) is a waveform diagram of the FSX modulation method, Figure 3 (b)
is a waveform diagram of the MF modulation method. In the FSK modulation method, on the transmitting side, for example, a digital signal "1" is modulated into a certain low frequency signal FL + a digital signal rOJ into a certain high frequency signal F, and the receiving side modulates these signals into a digital signal rlJ. , rOJ.

On the other hand, in the MF modulation method, on the transmitting side, a digital signal composed of multiple bits, for example rooolJ, is combined with a determined low frequency signal FLI among multiple low frequency signals and a determined low frequency signal FLI among multiple high frequency signals. In this method, the signal is transmitted as a two-frequency combination signal (Ft++FNI) with the high-frequency signal FHI, and this is demodulated into a digital signal r0001J on the receiving side. Note that the same applies to the illustrated signal wave (FLZ + FM).

For example, when transmitting data from the terminal device 3 to the monitoring center 1, the modem 7 performs modulation and demodulation using the same FSX modulation method.
The network control circuit 8a is selected for transmitting to. Therefore, data communication is transmitted from the terminal 3 to the modem 7L via the telephone line 2 including the exchange, the network control circuit 8a, and the modem 7L. The modem 7 demodulates the data signal into a digital signal, and based on the signal, the CPU 5 and memory 6 recognize the transmission location (terminal device 3) and analyze the monitoring information. Terminal device 4-4
This also applies when transmitting data from n to monitoring center 1.

Also, the modem 7 transmits data from the monitoring center 1 to the terminal device 3.
The information is transmitted from the network control circuit 8a to the terminal 3 via the telephone line 2, and necessary monitoring information can be received and necessary measures can be taken. In that case, of course, the FS on terminal 3
It is demodulated into a signal in the K modulation system.

The same applies to transmissions for terminals 4 to 4n.

[Problem that the invention seeks to solve]

In the data communication device described above, since the FSK modulation method and the MF modulation method are mixed in the terminal device, the monitoring center 1 side necessarily uses the network control circuit 8a, corresponding to each modulation method.
8b, CPU 5.9, and memory 6.10 must be separately provided. On the other hand, the operator of the monitoring center 1 has to always recognize whether the terminal uses the FSK modulation method or the MF modulation method during operation, which is extremely troublesome.

In order to avoid this kind of configuration complexity, all the modulation methods of terminal devices should be unified to the latest modulation method, that is, one FSX modulation method. There is a serious drawback in that the cost of replacing the device with a terminal device using the FSK modulation method becomes significant, and there is a gap in the monitoring system during the replacement, making it difficult to unify the modulation method.

An object of the present invention is to solve the problems of the prior art described above, to simplify the configuration of a monitoring center without unifying the modulation method, and to provide data that facilitates operator operation. To provide communication equipment.

[Means for solving problems]

In order to achieve the above object, the present invention includes a plurality of terminal devices, a monitoring center that monitors these terminal devices, and a communication line that exchanges data between the terminal devices and the monitoring center. , in a data communication device in which the modulation and demodulation devices provided in each of the terminal devices include a mixture of modulation and demodulation methods of different types, the monitoring center has a plurality of modulation and demodulation devices corresponding to each of the modulation and demodulation methods, and among these modulation and demodulation devices, a signal The present invention is characterized in that it includes a selection means for selecting a modulation/demodulation device that matches a modulation/demodulation method of a modulation/demodulation device of a terminal device that performs transmission/reception.

[Effect]

When transmitting data from a terminal device to a monitoring center, the data is transmitted to the monitoring center over one line via a data communication line exchange. The monitoring center inputs this data to each modem, recognizes the modem with the output, selects that modem using the selection means, and receives the data transmitted via the selected modem. .

On the other hand, when transmitting data from the monitoring center to a predetermined terminal device, since the modulation method of the modulation/demodulation device of the predetermined terminal device is known, the corresponding modulation/demodulation device of the monitoring center is selected by the selection means. Then, the data to be transmitted is modulated and transmitted via this modulation/demodulation device.

〔Example〕

Hereinafter, the present invention will be explained based on illustrated embodiments.

FIG. 1 is a block diagram of a data communication device according to an embodiment of the present invention. In the figure, parts that are the same as those shown in FIG. 2 are given the same reference numerals, and explanations thereof will be omitted.

12 is a network control circuit, which is a conventional network control circuit 8a, 8
Whereas b is provided as many times as there are modulation methods of the terminal device, only one is provided in this embodiment. Reference numerals 13 and 14 indicate detection circuits connected to each modem 7.11, which detect when there is an output from each modem 7.11.

15 and 16 are a CPU and memory, respectively, and have the same functions as the CPU and memory in the conventional device. However, in addition to the functions of conventional memory, the memory 16 also has the following functions:
The modulation method of each terminal device 3 to 3n and 4 to 4n is stored. In the conventional device, the number of CPUs and memories is equal to the number of modulation methods of the terminal device, but in this embodiment, only one each is provided. 17 is C
This is a switch that selects modem 7 or modem 11 based on a command signal from PU 15. A monitoring center having such a configuration is designated by the reference numeral 1'.

Next, the operation of this embodiment will be explained. The modulation method is now FS
When transmitting data from the terminal 3 to the monitoring center 1' using the K method, the terminal device 3 calls the monitoring center 1' using the telephone number of the monitoring center 1' and then starts transmission. In this way, when calling the monitoring center from the terminal device side, in the past, the network control circuit had a separate configuration for each modem, so a different number was used for calling the monitoring center depending on the modulation method. In this embodiment, a common telephone number can be used for all terminal devices. Furthermore, the telephone line does not require a line for each modulation method, but can be made into one common line, and the number of lines can be reduced.

Now, when the terminal device 3 and the monitoring center 1' are connected via a telephone line, data is then transmitted. This data is FS
It is transmitted using the X modulation method and is input to the modem 7.11 via the network control circuit 12. By the way, modem 7 is FS
Since this is an X modulation modem (modem ■) and modem 11 is an MF modulation modem (modem ■), when the above data is input, only the demodulated output is generated from modem 7, and the demodulated output is generated from modem 11. produces no output. The detection circuit 13 detects that there is an output from the modem 7,
This is output to the CPU 15. The CPU 15 is the detection circuit 1
Check the detection signal from 3 and switch 17 to modem 7 side. Thereby, data from the terminal device 3 is demodulated by the modem 7 and received by the CPU 15.

Thereafter, the CPU 15 and memory 6 perform the same processing as in the past.

On the other hand, when transmitting data from the monitoring center 1' side to the terminal device 3, by specifying the terminal device 3 in the monitoring center 1', the CPU 15 reads the modulation method of the terminal device 3 from the memory 16, and switches accordingly. 17 to the modem 7 side. Thereafter, the data is modulated using the FSK method, and the signal is transmitted and received by the terminal device 3.
It will be demodulated using the SK method.

When transmitting and receiving data between the terminal devices 4 to 4n and the monitoring center 1', the switch 17 is switched to the modem 11 side, and when receiving data at the monitoring center 1', the detection circuit 1 is switched to the modem 11 side.
It is clear from the above description that the detection signal is output from the CPU 15 from the CPU 15.

In this way, in this embodiment, a switch is provided on the monitoring center side to select the same modem as the modulation method of the other party for sending and receiving data signals, thereby reducing the number of network control circuits, CPUs, and memories. Therefore, the configuration can be simplified. Furthermore, since there is one network control circuit, the wiring between the exchange and the monitoring center can be reduced to one. Furthermore, the operator does not need to pay any consideration to the modulation method used in data exchange, and the burden on the operator can be reduced.

In addition, in the description of the above embodiment, the case where there are two types of modulation schemes was illustrated, but it is obvious that it is applicable even if there are three or more types.

〔Effect of the invention〕

As described above, in the present invention, a monitoring center is provided with a plurality of modulation/demodulation devices corresponding to the modulation/demodulation method of the modulation/demodulation device of each terminal device, and one of these modulation/demodulation devices that matches the modulation/demodulation method of the terminal device with which communication is performed is provided. Since selection is made using the selection means, the configuration of the monitoring center can be simplified without replacing the modem on the terminal side, and
The burden on the operator can be reduced.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a data communication device according to an embodiment of the present invention, FIG. 2 is a block diagram of a conventional data communication device, and FIGS. 3(a) and 3(b) are waveform diagrams explaining the modulation method. be. 1'...Monitoring center, 2...Telephone line, 3-3n. 4-4n...Terminal device, 15...CP
U, 16...Memory, 7.11...Modem, 12...Network control circuit, 13°14...
...Detection circuit, 17...Switch. Figure 2 Figure 3

Claims (1)

[Claims] A modulation/demodulation device included in each of the terminal devices, comprising a plurality of terminal devices, a monitoring center that monitors these terminal devices, and a communication line that exchanges data between the terminal devices and the monitoring center. In a data communication device in which different modulation and demodulation methods coexist, the monitoring center includes a plurality of modulation and demodulation devices corresponding to each of the modulation and demodulation methods, and a modulation and demodulation device of a terminal device that transmits and receives signals among these modulation and demodulation devices. 1. A data communication device comprising: selection means for selecting a modulation/demodulation device that matches a system.