JPH04207721A - Power line carrier communication system - Google Patents

Abstract

PURPOSE:To eliminate the need of a special signal line for communication and to reduce the wiring cost by using a trunk line power line, and also, separating and executing a signal transmission related to the trunk line power line and a branch power line, respectively. CONSTITUTION:The system is provided with plural branch power lines 2 divided, for instance, in accordance with the respective floors of a building from a trunk line power line 1, and on the branch power line 2 side of the respective branch parts, a branch block filter 3 having high impedance against a prescribed frequency f0 (100kHz), and also, having low impedance against a prescribed frequency f1 (200kHz) is placed. Also, to the respective branch power lines 2, a branch controller 8 for modulating a communication signal and a terminal, 9 are connected.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a power line carrier communication system that performs communication using power lines.

[Prior Art] Conventionally, a power line carrier communication system that performs communication using a power line is known, and this power line carrier communication system is
For example, Utility Model Application Publication No. 57-201043 (see Figure 7)
As described in , a main power line (1) is divided into multiple branch power lines (2
), and branch power lines (2
) side, a branch block filter (3) having high impedance with respect to a predetermined frequency (f) is arranged.

Each branch power line (2) is equipped with a transmitter (4
) and a receiver (5), and a controller (7) that communicates with the terminal via a signal line (6).

Next, the operation will be explained.

When controlling a terminal placed on the first floor, a carrier wave signal of a predetermined frequency (1>) is output from a controller (7) connected to a branch power line (2) on the first floor to a signal line (6).

Then, this carrier wave signal is inputted from the signal line (6) to the receiver (5) of the terminal device via the branch power line (2) on the first floor, and the terminal device is controlled according to the input signal.

At this time, the carrier wave signal of the predetermined frequency (f) is blocked by the branch block filter (3) and does not leak to the main power line (1).

Also, when transmitting a signal to a terminal, the terminal transmits a signal (
4) outputs a carrier wave signal of a predetermined frequency (f) to the branch power line (2) on the first floor.

Then, this carrier wave signal is inputted from the branch power line (2) on the first floor to the controller (7) via the signal line (6).

At this time, the carrier wave signal of the predetermined frequency (f) is blocked by the branch block filter (3) and does not leak to the main power line (1).

[Problem to be solved by the invention] Since the conventional power line carrier communication system is configured as described above, as the number of floors of the building increases and the number of signal lines (6) increases, the length of the wiring also increases. There was an issue of increased costs.

This invention was made to solve the above-mentioned problems, and provides a power line carrier communication system that can communicate using main power lines and does not require signal lines.
The purpose is to improve the reliability of communications.

[Means for Solving the Problems] A power line carrier communication system according to the present invention transmits and receives a communication signal modulated at a predetermined frequency (f1) different from a transmission/reception frequency (f0) of a terminal device via a main power line. a controller, and a main block filter provided on the opposite side of the branch power line as seen from the main controller and provided on the main power line to block the frequency (f1), and the branch controller transmits and receives a communication signal modulated at frequency ([1)] to and from the trunk controller, while transmitting and receiving a continuous bombing signal modulated at frequency (f0) to and from the terminal via the branch power line, A block filter is provided between a terminal device, a branch controller, and a trunk controller, and is characterized by blocking frequency (f0) and passing frequency (f1).

[Operation] In the power line carrier communication system of the present invention,
A communication signal with a predetermined frequency (f1) is output from the trunk controller, and the branch block filter outputs a communication signal with a predetermined frequency (f1).
0) signal is blocked, the branch controller modulates the communication signal into a signal of a predetermined frequency (f0), the signal of the predetermined frequency (f0) modulated by the terminal is received by the branch controller, and the signal is transmitted to the main block. A filter prevents it from leaking into the power line.

[Example code] An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a system configuration diagram showing the configuration of a power line carrier communication system according to the present invention.

When a power line carrier communication system is wired inside a building, it has a main power line (1) and a plurality of branch power lines (2) that are divided corresponding to, for example, each floor of the building. The branch power line (2) side has high impedance for a predetermined frequency (f0) (for example, 100kHz) and
0 kH2), a branch block filter (3) (see FIG. 5) with low impedance is arranged.

Further, each branch power line (2) is connected to a branch controller (8) that modulates a communication signal and a terminal (9).

In addition, the main power line (1) has a main power line controller (10
) is connected to the main line block filter (11) (see FIG. 6), which has a high impedance for a predetermined frequency (f1) and prevents transmission signals from leaking to the power line.

As shown in FIG. 2, the trunk controller (1 (1)) connects the coupling circuit (12), which is composed of a variable mutual inductance, etc., connected to the trunk power line (1). ) is connected to a transmission control device (13) and a modulator (14).

Furthermore, a modulator (14), an operation monitor section (15), and an oscillator (16) that emits at a predetermined frequency (f1) are connected to the transmission control device (13), and the oscillator (16) is connected to the modulator ( 14) is also connected.

Furthermore, as shown in FIG.
2) is connected to a transmission control device (13) and a modulator (14).

The transmission control device (13) includes a modulator (14).
, a control device (17), and an oscillator (18) that emits at a predetermined frequency (f0) are connected, and the oscillator (18) is also connected to a control device (14).

Furthermore, the branch controller (8), as shown in FIG.
It has a coupling circuit (12) composed of a variable mutual inductance etc. connected to the branch power line (2), and the coupling circuit (12) includes a transmission control device (13) and a modulator (1).
4) or connected.

The transmission control device (13) includes a modulator (14).
, an oscillator (16) that emits at a predetermined frequency (f1), and an oscillator (18) that emits at a predetermined frequency (f0) are connected to the oscillator (16).

(18) is connected to the modulator (14).

Next, the operation of this embodiment will be explained.

When controlling the terminal device (9) located on the first floor, the operator issues instructions to the transmission control device (13) from the operation monitor section (15) of the trunk controller (10).

Then, the transmission control device (13) transmits the predetermined frequency (f1)
The modulator (14) operates the oscillator (16) that emits
A carrier wave signal of a predetermined frequency (fl) is output to the main power line (1).

At this time, the carrier wave signal of the predetermined frequency (f1) is blocked by the main line block filter (11) which has a high impedance H with respect to the predetermined frequency (f1), and does not leak toward the power line.

This carrier wave signal of the predetermined frequency (f1) passes through the main power line (1) and passes through a branch block filter (3) having a low impedance for the predetermined frequency (f1).

Then, the carrier wave signal of a predetermined frequency (f1) is input to the transmission control device (13) of the branch controller (8) through the branch power line (2), and the transmission control device (13) transmits the carrier wave signal of the predetermined frequency (f1). Specified frequency (f0) depending on the signal
The oscillator (18) is caused to oscillate, and the frequency of the carrier signal is modulated to a predetermined frequency (f0) by the modulator (14) and output to the branch power line (2).

At this time, the carrier wave signal of the predetermined frequency (f0) is blocked by the branch block filter (3) having a high impedance with respect to the predetermined frequency (f0), and does not leak to the main power line (1).

Then, this carrier wave signal of a predetermined frequency (f0) is manually inputted to the transmission control device (13) of the terminal device (9), and the transmission control device (13) transmits the control device (17) based on the carrier wave signal.
control.

Next, when transmitting data from the control device (17) of the terminal device (9) to the trunk controller (10), the transmission control device (13) that receives the signal from the control device (17) uses a predetermined frequency (f0 ), the frequency of this signal is modulated into a carrier signal of a predetermined frequency (f0) by a modulator (14), and the signal is output to the branch power line (2).

The carrier wave signal of a predetermined frequency (f0) is input to the transmission control device (13) of the branch controller (8) through the branch power line (2), and the transmission control device (13) transmits the carrier wave signal of the predetermined frequency (f0). The signal causes an oscillator (18) to oscillate at a predetermined frequency (f1), and the frequency of the carrier signal is modulated by a modulator (14) to a predetermined frequency (f1) and output to the branch power line (2).

At this time, the carrier wave signal of the predetermined frequency (f1) is blocked by the main line block filter (11) having a high impedance with respect to the predetermined frequency (f1), and will not leak toward the power line.

Then, this carrier wave signal of a predetermined frequency (f1) is transmitted through a branch block filter (3) having a low impedance for a predetermined frequency (fl), and is transmitted through a main power line (1).
) to the transmission control device (
13), and the data is displayed on the operation monitor section (15).

In addition, in the above-mentioned example, the explanation was given using an example in which the main power line (1) was divided into three branch power lines (2).
The present invention is not limited to the number of divisions of the branch power line (2).

In addition, the main block filter (11) is connected to a predetermined frequency (
By configuring it to have high impedance not only for f1) but also for the predetermined frequency (f0), communication reliability can be further improved.

[Effects of the Invention] As explained above, according to the present invention, since the main power line is used and signal transmission related to the main power line and the branch power line are performed separately, special signal lines for communication are not required. It is possible to reduce the wiring cost by reducing the need for wiring.

[Brief explanation of the drawing]

FIG. 1 is a system configuration diagram showing the configuration of a power line carrier communication system according to the present invention, FIG. 2 is a block diagram showing the configuration of a trunk controller according to the present invention, and FIG. 3 is a configuration diagram of a terminal device according to the present invention. FIG. 4 is a block diagram showing the configuration of the branch controller according to the present invention,
FIG. 5 is a diagram showing the attenuation characteristics of the branch block filter according to the present invention, FIG. 6 is a diagram showing the attenuation characteristics of the main block filter according to the present invention, and FIG. 7 is a diagram showing the configuration of a conventional power line carrier communication system. It is a system configuration diagram. In the figure, (1) is the main power line, (2) is the branch power line, (3) is the branch block filter, (8) is the branch controller, (9) is the terminal, (10) is the main controller, and (11) is This is a main block filter. In addition, in the figures, the same reference numerals indicate the same or corresponding parts. Agent: Patent Attorney Yoshi 1) Kenji (2 others) Power 1liil carrier communication/stem Figure 1 Trunk line controller Terminal branch controller Figure 4 fOll Frequency branch flow/ku filter damping characteristics Figure 5 Trunk line pro/ku filter attenuation characteristics Figure 6

Claims (1)

[Claims] A main power line, a branch power line branched from the main power line, a terminal device connected to the branch power line that transmits and receives a communication signal modulated at a predetermined frequency (f0), and a terminal device that transmits and receives a communication signal modulated at a predetermined frequency (f1) different from the frequency (f0). A communication signal modulated at frequency (f1) is transmitted and received between the main controller and the main controller, which transmits and receives a communication signal modulated at frequency (f0) via the main power line. A branch controller that transmits and receives communication signals to and from terminals via a branch power line, and a branch controller that is installed on the opposite side of the branch power line when viewed from the main controller, and is installed on the main power line to block frequency (f1). a trunk block filter; a branch block filter provided between the terminal device, the branch controller, and the trunk controller so as to block the frequency (f0) and pass the frequency (f1);
A power line carrier communication system comprising: