JPH03214937A - Wire data-collecting system - Google Patents

Abstract

PURPOSE:To transmit an analog measuring data without generating transmission distortion due to a transmission line by digitizing a measured data obtained at plural points and collecting the digital signals at points of cascade connection through the use of analog transmission lines. CONSTITUTION:An analog measured data is converted into a digital measured data by a digitizing circuit 4, and converted into an analog data by a MODEM 5 and a central processing unit 6 and the data is frequency-modulated at a frequency modulation circuit 7 by using an output of a carrier oscillator 8 as a carrier. On the other hand, a frequency multiplex signal inputted from a transmission terminal station equipment 21 at a preceding stage via a transmission line 22 is demultiplexed from the signal on the transmission line 22 by a demultiplex circuit 9 and the output is amplified by an amplifier circuit 10 and the resulting signal is subjected to frequency multiplex with a frequency modulation signal from the above-mentioned frequency modulation circuit 7 by a frequency multiplex circuit 11 and outputted again to the transmission line 22 by a coupling circuit 12.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a collection system for various types of measurement data in the natural world, etc., and in particular converts measurement data obtained at a plurality of points into digital signals, and converts the digital signals into analog signals. This relates to a wired data collection system that uses transmission lines to collect data at a certain point in series.

[Conventional technology]

An example of a conventional wired data collection system is shown and explained in FIGS. 4 and 5.

FIG. 4 shows a transmitting end station device, and FIG. 5 shows a receiving end station device.

4 and 5, 31.41 is an input terminal into which a frequency multiplexed signal is input, 32 is an output terminal from which a frequency multiplexed signal output is obtained, 33 is an input terminal into which measurement data is input, 45-1. 45-2...45-n are output terminals from which measurement data can be output.

Conventionally, this type of data collection system
As shown in the figure and FIG. 5, in the transmitting terminal device, the measurement data input from the input terminal 33 is amplified by the preamplifier circuit 36, and this amplified output is used as the oscillation output of the frequency modulation oscillation circuit 37 as a carrier wave. A modulation circuit 38 performs frequency modulation. Then, a frequency multiplexed signal sent from a predetermined point via a transmission line is input to an input terminal 31, the frequency multiplexed signal from the input terminal 31 is separated by a separation circuit 34, and its output is amplified by an amplifier circuit 35. After that, the output of the frequency modulation circuit 38 and the frequency multiplexing circuit 39 perform frequency multiplexing, and the coupling circuit 40 couples the signal to the transmission line.

Further, in the receiving end station device, a frequency multiplexed signal is input to an input terminal 41, the frequency multiplexed signal is separated from the transmission path by a separation circuit 42, and its output is sent to a plurality of band pass filters 43-1 . 43-2...43-n performs υ frequency separation, and each band pass filter 43-1
The signals outputted from frequency demodulation circuits 44-1 . 44-2, . . . , 44-n to output the measured data from output terminals 45-1 to 45-n, respectively.

[Problem to be solved by the invention]

In the conventional wired data acquisition system described above, the measured data is repeatedly modulated and transmitted as analog data, so as the transmission path becomes longer, the data deteriorates, and the oscillation for frequency modulation increases. The quality of data is affected by the precision of the circuit, and the frequency bandwidth of the signal modulated by the frequency modulation circuit varies depending on the measurement data, so the frequency of the oscillation circuit must be redesigned each time. There was a problem.

[Means to solve the problem]

The wired data collection system of the present invention is a system in which transmitting end station equipment located at multiple locations and receiving end office equipment located at other locations are connected in cascade through a single analog transmission path. In the transmitting terminal device, a digitization circuit converts a plurality of measurement data into digital quantities, a modem converts the digital data obtained by the digitization circuit into analog data, and controls the digitization circuit and the modem. a central processing unit for frequency modulating the output of the modem, a carrier wave oscillator, and a first separation device for separating the signal sent from the preceding point via the transmission path from the transmission path. a circuit, an amplifier circuit for amplifying the signal separated by the first separation circuit, and a frequency multiplexing circuit for frequency multiplexing the signal amplified by the amplifier circuit and the analog signal modulated by the modem; a second separation circuit that has a coupling circuit that couples the frequency-multiplexed signal from the frequency-multiplexed circuit to the transmission path, and separates the frequency-multiplexed signal from the transmission terminal device from the transmission path in the receiving terminal device; A plurality of bandpass filters for frequency-separating the frequency multiplexed signal separated by the second separation circuit, and a plurality of frequency demodulation circuits for demodulating the frequency modulated signals output from the plurality of bandpass filters, respectively. , a plurality of modems that respectively demodulate analog data demodulated by the plurality of frequency demodulation circuits into digital data, and a plurality of analog demodulation circuits that demodulate measurement data from the digital data demodulated by the plurality of modems, respectively; The apparatus includes a plurality of central processing units that respectively control the plurality of modems and the plurality of analog demodulation circuits.

[Effect]

In the present invention, measurement data obtained at a plurality of points is converted into digital signals, and the digital signals are collected at a certain point in series using an analog transmission path.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

1 and 2 are block diagrams showing an embodiment of a wired data collection system according to the present invention, in which FIG. 1 shows a transmitting end station device, and FIG. 2 shows a receiving end station device. This is what is shown.

FIG. 3 is a block diagram showing the configuration of the Genshin-style data collection system. In order to facilitate understanding of the present invention, this will be explained first. As shown in FIG. 3, this system connects transmitting terminal equipment 21 located at multiple locations and receiving terminal equipment 23 located at other locations over a single analog transmission line 2.
2 are configured to be connected in cascade.

In FIG. 1, which is a block diagram of a transmitting terminal device, 1 is an input terminal into which a frequency multiplexed signal is input, 2 is an output terminal from which a frequency multiplexed signal output is obtained, 3-1.3-2...3
-n is an input terminal to which measurement data is input.

A digitizing circuit 5 for converting a plurality of measurement data of the natural world, etc. inputted from the 4Fi input terminals 3-1 to 3-n into digital quantities, is obtained by the digitizing circuit 4. - A modem (M) that converts digital data into analog data.
ODEM), 6 is a central processing unit that controls the digitization circuit 4 and the motem 5, T is a frequency modulation circuit for frequency modulating the output of the modem 5, 8 is a carrier wave oscillator, and 9 is a transmission path from the prefix point. 10 is an amplification circuit for amplifying the signal separated by this separation circuit 9, and 11 is a separation circuit for separating the signal sent via this amplification circuit 10 from the transmission path. Frequency multiplexing circuit for frequency multiplexing modulated analog data, 12
is a coupling circuit that couples the signals frequency-multiplexed by this frequency multiplexing circuit 11 to a transmission path.

In FIG. 2, which is a block diagram of the receiving terminal device, 13
is an input terminal into which a frequency multiplexed signal is input, 14-1-1
．． 14-1-2...14-1-n are output terminals from which measurement data can be output.

15 is a separation circuit that separates the station wave number multiplexed signal from the transmitting terminal device from the transmission path, 16-1.16-2・self・16-n
This separation circuit 15 includes a plurality of bandpass filters for frequency-separating the separated frequency multiplexed signals, 17-
1.17-2...17-n are a plurality of frequency demodulation circuits for demodulating the frequency modulated signals outputted from the band pass filters 16-1 to 16-n, respectively; 18
-1 is a modem 19 that demodulates analog data demodulated by this frequency demodulation circuit 11-1 into digital data;
20-1 is an analog harmonization circuit that modulates the digital data demodulated by this modem 18-1;
1 is a central processing unit that controls the modem 18-1 and analog demodulation circuit 19-1.

Then, the frequency demodulation circuits 1T-2 to 17-n
Each of the demodulated analog data is demodulated into digital data by a modem (not shown), and the demodulated digital data is demodulated into measurement data by an analog demodulation circuit (not shown). The analog demodulation circuits not shown in the figure are each configured to be controlled by a central processing unit (not shown).

Further, each of the analog demodulation circuits (not shown) is configured to output a plurality of measurement data similarly to the analog demodulation circuit 19-1.

Next, the operation of the embodiment shown in FIGS. 1 and 2 will be explained with reference to FIG. 3.

First, in the transmitting terminal device shown in FIG.
-1 to 3-n, a plurality of analog measurement data of the natural world etc. are converted into digital measurement data by the digitization circuit 4, and further converted into digital measurement data by the modem 5 and central processing unit 6, The frequency modulation circuit 7 modulates the frequency using the output of the oscillator 8 as a carrier wave.

On the other hand, the frequency multiplexed signal inputted to the input terminal 1 from the transmitting terminal device 21 (see FIG. 3) provided in the front via the transmission path 22 (see FIG. 3) is separated from the transmission path 22 by the separation circuit 9. , the output thereof is amplified by an amplifier circuit 10, frequency-multiplexed with the frequency modulated signal from the frequency modulation circuit 7 by a frequency multiplexing circuit 11, and outputted again to a transmission line 22 (see FIG. 3) by a coupling circuit 12.

Next, in the receiving terminal device 23 shown in FIG.
The frequency multiplexed signal inputted to the input terminal 13 in FIG. The frequency modulation signals outputted from the respective band pass filters 16-1 to 16-n are demodulated by the frequency demodulation circuits 17-1 to 17-n, and then sent to the modem 18-1... and central processing. Device 20-1
The analog demodulation circuit 19-1 converts analog data into digital measurement data, respectively.
・Each demodulates into multiple analog measurement data,
The signals are output to the output terminals 14-1, respectively.

〔Effect of the invention〕

As explained above, the present invention provides a system in which a transmitting terminal station device located at a plurality of points K and a receiving terminal station device located at another point are connected in cascade through a single analog transmission path.
Convert measurement data obtained from multiple points into digital signals,
By using an analog transmission line to collect these digital signals in series at a certain point, it is possible to secure a transmission capacity several to several tens of times higher than that of a conventional analog system on the same transmission line. Since the signal is digitized before being loaded, it has the effect of being able to transmit analog measurement data without causing transmission distortion due to the transmission path.

[Brief explanation of drawings]

1 and 2 are block diagrams showing an embodiment of a wired data collection system according to the present invention, FIG. 3 is a block diagram showing a configuration example of a wired data collection system according to the present invention, and FIGS. 4 and 5 The figure is a block diagram showing an example of a conventional edged data collection system. 4...digitization circuit, 5...modem, 6...
...Central processing unit, 1...Frequency modulation circuit, 8...
... Carrier wave oscillator, 9... Separation circuit, 10...
・Amplification circuit, 11... Frequency multiplexing circuit, 12...
・Coupling circuit, 15...Separation circuit, 16-1 to 16-
n...Band pass filter, 17-1 to 17-n.
...Frequency demodulation circuit, 18-1 ...Modem,
19-1... Analog demodulation circuit, 20-1 ・
... central processing unit, 21 ... transmitting terminal device, 22
...Transmission path, 23...Receiving terminal equipment.

Claims (1)

[Claims] A system in which transmitting terminal equipment located at multiple points and receiving end equipment located at other locations are connected in cascade through a single analog transmission path, and each transmitting end equipment transmits multiple pieces of measurement data. a digitizing circuit for converting the digital data into digital quantities, a modem for converting the digital data obtained by the digitizing circuit into analog data, a central processing unit for controlling the digitizing circuit and the modem, and the modem. a frequency modulation circuit for frequency modulating the output of the
a carrier wave oscillator; a first separation circuit that separates a signal sent from a preceding point via the transmission path from the transmission path;
an amplifier circuit for amplifying the signal separated by this first separation circuit; a frequency multiplexing circuit for frequency multiplexing the signal amplified by this amplifier circuit and the analog data modulated by the modem; and this frequency multiplexing circuit. a coupling circuit for coupling the frequency-multiplexed signal from the transmission line to the transmission line; a plurality of bandpass filters for frequency-separating the frequency multiplexed signals separated by the separation circuit; a plurality of frequency demodulation circuits for demodulating the frequency modulated signals output from the plurality of bandpass filters; a plurality of modems that respectively demodulate the analog data demodulated by the frequency demodulation circuit of the plurality of modems into digital data; a plurality of analog demodulation circuits that respectively demodulate the measurement data from the digital data demodulated by the plurality of modems; and the plurality of modems. and a plurality of central processing units that respectively control the plurality of analog demodulation circuits.