KR102002808B1 - Data communication network - Google Patents

Abstract

The present invention relates to a data communication network. In the data communication network, one or two data cables consist of a ring type, a transmitter consists of a set of transmitters and receivers on one data cable or a transmitter on one data cable, and the other data cable consists of a separate receiver. The set of a plurality of transmitters and receivers receives a detection signal transmitted from a PC installed in a predetermined place by a remote sensing device installed in a predetermined place. In addition, since it is composed of a set so that is possible to transmit a control signal from the remote sensing device to the PC, even if one of the transmitter and receiver set fails, it does not affect the other transmitter and receiver, and is possible to transmit and receive a normal signal.

Description

DATA COMMUNICATION NETWORK

The present invention relates to a data communication network.

In the conventional data transmission network configuration, a ring optical transmission and ring transmission method

 have.

As shown in FIG. 1, a ring optical transmission network system is disclosed in Korean Patent Registration No. 10-0888945, and includes a plurality of locally distributed optical transmission devices 10 and a closed loop And a relay optical fiber 40 for connecting the optical transmission devices 10 to each other.

The ring type data transmission network system is disclosed in Korean Patent Laid-Open Publication No. 10-2004-0021030. As shown in FIG. 2, the ring type data transmission network system is composed of seven layers, And first to fourth nodes (1 to 4) including a third layer having a first layer and a second layer. Here, the third layer 5 of each of the nodes 1 to 4 checks whether the packet data is received from the neighboring node when the packet data is received. If the packet data is new data, the packet is uploaded to the upper layer and transmitted to the opposite node.

On the other hand, if the received data is duplicated data, it is discarded. The third layer is provided with a flag register for checking whether a broadcast message is duplicated or not.

The microprocessor can exchange information with the outside through peripheral devices. In general, there are two ways of exchanging information with external devices: parallel communication and serial communication.

Generally, when exchanging information with a device in a computer, a parallel communication method that can process a large amount of information at a high speed is required.

This is because a large amount of information can be processed at once to improve the performance of a computer. A typical example of this method is to increase the throughput of the microprocessor itself, which is represented by the number of data bits.

In all cases, however, parallel communication can not be used. The reason for this is the limitation of communication distance, technical difficulties in implementation, and cost. In addition, there are many cases where the application itself does not need a high communication speed.

For this reason, when a computer communicates with the outside, a serial communication method is often used.

The serial communication method is a method of transmitting / receiving data bits to and from the outside in units of one bit, so that it is easy to implement and can go far, and an existing communication line (telephone line, etc.) can be easily utilized, which is advantageous in cost reduction. Typical examples of serial communication are modem, LAN, RS232, and X.25.

However, when serial communications are divided into two types, asynchronous and synchronous. Many people know the asynchronous communication method is RS232. Actually RS232 is only one of the electrical signaling methods that interface the digital signal from the asynchronous communication controller to the outside.

In general, it is not unreasonable that RS232 is recognized as an asynchronous communication method. Typical controllers supporting the asynchronous communication method are 16C450 and 16C550 of NS. Other compatible controllers are produced by many companies but there are dozens of kinds of controllers that have asynchronous communication function although there is no difference in performance and there is no compatibility.

An asynchronous communications controller is commonly referred to as a Universal Asynchronous Receiver / Transmitter (UART). The signal from the UART usually has a TTL signal level, which is weak to noise and has a limited communication range. An interface IC that receives these TTL signals and allows them to be strong and far from noise is called LINE DRIVER / RECEIVER. RS422 and RS485 are representative examples.

In the conventional RS485 communication sensor, if one of the lightning or electric shocks is broken due to a short-circuit (usually a fault), the entire module connected to the same line becomes impossible to communicate and becomes vulnerable to security.

1. Korea Patent No. 10-0888945 2. Korean Patent Publication No. 10-2004-0021030

It is an object of the present invention to provide a data communication network which does not affect communication of other modules regardless of a failure situation do.

Another object of the present invention is to provide a data communication network capable of improving vulnerability to lightning accompanied by existing communication systems and susceptibility to noise around a substation.

It is still another object of the present invention to provide a data communication network that solves the problem of high installation cost accompanying an optical link.

Other objects of the present invention will be apparent from the following description.

According to an aspect of the present invention, there is provided a data communication network including:

When the electromotive force values of the two strands of the wire are equal to each other, zero (0) is outputted. When the electromotive force value is equal to The two wires are connected to the differential amplifier to output a predetermined deviation value that is not zero and recognizes the predetermined deviation value as a crime / A sensor cable connected to the operational amplifier for generating an electromotive force in a proportional manner and recognizing a crime prevention / disaster detection signal to generate a sensing signal for comparing the amplified signal of the differential amplifier and the operational amplifier to determine whether an alarm has occurred;

A fence sensor for sensing a height of the fence due to the loss of the fence based on a change in distance or a change in strength between the upper end of the fence and the lower floor,

When a data cable for transmitting a detection signal output from an wind speed sensor for detecting wind speed to a signal analyzer is formed in a ring shape by one or a plurality of data cables, a plurality of transmitters and receivers are constituted as a set in the data cable,

Wherein the plurality of transmitters and receiver sets are configured to be able to receive a sensing signal transmitted from a PC installed in a predetermined place and to transmit a control signal from the remote sensing device to the PC, Even if the transmitter and the receiver set of the transmitter and the receiver fail, it does not affect other transmitters and receivers, enables normal signal transmission and reception,

The data cable is connected to a control device of the sensing system to detect a failure of the data table and to stop the sensing signal transmission operation in the control device.

In an embodiment of the present invention,

The transmitter and receiver are comprised of a Troy month coil,

A transmitter and a receiver are constituted by forming a circular loop of the data cable and penetrating the Troy month coil,

And a signal having a specific frequency is used to form an on or off code in a transmitter composed of a Troy coils.

According to another aspect of the present invention, there is provided a data communication network including:

When the electromotive force values of the two strands of the wire are equal to each other, zero (0) is outputted. When the electromotive force value is equal to The two wires are connected to the differential amplifier to output a predetermined deviation value that is not zero and recognizes the predetermined deviation value as a crime / A sensor cable connected to the operational amplifier for generating an electromotive force in a proportional manner and recognizing a crime prevention / disaster detection signal to generate a sensing signal for comparing the amplified signal of the differential amplifier and the operational amplifier to determine whether an alarm has occurred;

A fence sensor for sensing a height of the fence due to the loss of the fence based on a change in distance or a change in strength between the upper end of the fence and the lower floor,

A transmission coil and a receiving coil are divided into upper and lower parts in a multiplexing board so as to transmit a detection signal output from an airflow sensor for detecting the wind speed to a signal analyzer,

The transmitting coil is connected to a receiver, the receiving coil constitutes a data cable to be connected to a transmitter,

The plurality of transmitters and receiver sets are configured as one set so that a remote sensing device installed at a predetermined place receives a sensing signal transmitted from a PC installed at a predetermined place and further transmits a control signal from the remote sensing device to the PC So that even if any one of the transmitter and the receiver set fails, it does not affect other transmitters and receivers, and normal signal transmission and reception is enabled.

In another embodiment of the present invention, the transmitter and the receiver are comprised of a Troy month coil,

A data cable is formed in a ring shape, and a transmitter and a receiver are constituted by passing through a Troy month coil, and a transmitter having a Troy month coil forms an on or off code using a signal having a specific frequency So that signal transmission can be performed.

According to the data communication network of the present invention, the communication efficiency of the individual modules can be improved without affecting the communication of other modules regardless of any failure situation.

In addition, communication efficiency can be improved by improving vulnerability to lightning accompanied by existing communication systems and improving vulnerability to noise around a substation.

In addition, it is possible to reduce the cost by solving the expensive installation cost problem accompanying the optical link.

In addition, a transmitting coil and a receiving coil are additionally provided on the multiplexing board, and these are respectively connected to the transmitter and the receiver through a data cable, thereby improving the signal-to-noise ratio and enabling long distance communication.

1 is a block diagram of a conventional ring-type optical cable transmission network.
2 is a block diagram of a conventional ring data cable transmission network;
3 is a perspective view showing an external shape of an emergency situation detection system to which the present invention is applied.
FIG. 4 is an exploded perspective view showing a configuration in which a cable passes through an emergency situation detection system to which the present invention is applied. FIG.
5 is a perspective view showing a state in which a permanent magnet of the emergency situation detection system to which the present invention is applied is separated from a sensing device.
FIG. 6 is a sectional view showing a coupling relationship of cables of an emergency situation detection system to which the present invention is applied; FIG.
7 is a diagram showing a magnetic field forming state by the emergency situation detection system to which the present invention is applied.
8 is an exemplary view of a security system using an emergency situation detection system to which the present invention is applied.
FIG. 9 to FIG. 11 are diagrams showing a layout of a cable and a permanent magnet for maximizing sensing performance of the emergency situation detection system to which the present invention is applied. FIG.
FIG. 12 is a diagram showing a connection structure of a conductor and an amplifier of the emergency situation detection system to which the present invention is applied; FIG.
13 is a block diagram of an emergency situation detection system according to another embodiment of the present invention.
FIG. 14 is a configuration diagram of a ring data communication network according to the first embodiment of the present invention; FIG.
15 is a configuration diagram of a ring data communication network according to a second embodiment of the present invention;
16 is a configuration diagram of a data communication network according to a third embodiment of the present invention;

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail.

It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

3 is a perspective view showing an external shape of the emergency situation detection system to which the present invention is applied. FIG. 4 is an exploded perspective view showing a configuration in which a cable penetrates an emergency situation detection system to which the present invention is applied. 5 is a perspective view showing a state in which the permanent magnet of the emergency situation detection system to which the present invention is applied is separated from the sensing device. 6 is a cross-sectional view showing a coupling relationship of cables of the emergency situation detection system to which the present invention is applied. 7 is a diagram showing a magnetic field formed state by the emergency situation detection system to which the present invention is applied. 8 is an exemplary view of a security system using the emergency situation detection system to which the present invention is applied. 9 to 11 are diagrams showing the arrangement of cables and permanent magnets for maximizing sensing performance of the emergency situation detection system to which the present invention is applied. FIG. 12 is a diagram illustrating a connection structure between a conductor and an amplifier of the emergency situation detection system to which the present invention is applied.

As shown in Figs. 3 to 5, the sensing device 1 of the present invention is constituted by coupling a pair of coupling feeling pieces 2a and 2b.

The coupling feeling pieces 2a and 2b each have an annular groove 4 for allowing the permanent magnet 15 to be inserted into the center of the joint surface 3, The same elliptical support hole 5 is configured to communicate with the seat groove 4 and the cable 20 can be inserted through the seat groove 4 and the support hole 5.

A packing member 50 similar to the shape of a cap is formed in the inside of the housing groove 4 so as to seal a permanent magnet to be described later from the outside, and on the outside thereof, three coupling rods 8 and 8 ' 9 and 9 ', respectively. In addition, a clip groove 10 is formed parallel to the upper and lower sides of the outer periphery of the coupling feeling piece 2a.

The coupling pieces 2a and 2b configured as described above are connected to the outside of the cable 20. The permanent magnet 15 and the cable A sensing sensor 16 for sensing an electromotive force generated due to the movement of the permanent magnet 15 due to the flow or cutting of the permanent magnet 15 is formed on one side of the coupling trace piece 2a.

6, the cable 20 is formed by laminating the shield wire 22 inside the sheath 21 and by embedding the lead wire 24 in the inner space 23 of the shield wire 22, And permanent magnets 15 are disposed around them.

7, when a change in the magnetic field due to the movement of the permanent magnet 15 affects the conductor of the cable 20 and an electromotive force and noise are induced, thereby determining whether the cable 20 is abnormal or not, (20) outside the cable (20), and also detects the electromotive force and noise induced in the cable (24) through the permanent magnet (15) Thereby constituting the sensor 16.

As shown in FIG. 8, the method system using the cable state sensing device of the present invention includes a permanent magnet 15 and a sensing sensor 16 to detect an abnormality of the cable 20, A sensing device (1) installed; An analyzer 25 for analyzing and determining the abnormality of the cable 20 and the position of the abnormality cable based on the sensing value transmitted from the sensing device 1; A remote receiving device (26) for receiving an abnormality of the cable (20) judged by the analyzing device (25); And a power source 27 for applying operating power to the sensing device 1. [

The analyzer 25 of the present invention detects the electromotive force and noise induced by the movement of the permanent magnet 15 formed inside the sensing device 1 installed at a predetermined interval in the cable 20 by the sensor 16 It is determined whether the movement of the cable 20 caused by the natural phenomenon or the movement of the third person is the intrusion of the intention. At the same time, the position of the cable 20 in which the abnormality is generated is determined, 26).

The analyzer 25 measures the electromotive force and noise induced in accordance with the movement of the cable 20, that is, the movement of the permanent magnet 15 due to natural phenomena (e.g., wind, etc.) Thereby determining whether the cable 20 is abnormal or not and comparing the sensed value from the sensing sensor 16 to determine at which point the sensor 20 is installed, When the abnormality is determined based on the sensing value, it is determined which of the cables 20 is located.

The electromotive force sensed by the sensing device 1 due to the movement of the cable 20 uses a formula such as F = qvBsin? Or F = iB sin? According to Lorenz's law.

Where θ = the amount of charge (c), v = the velocity of the moving charge (m / s), B = the magnetic field, θ = the angle between the current and the magnetic field )to be.

The permanent magnet 15 in the sensing device 1 through which the cable 20 through which the current i flows passes is waved as shown in FIG. 4, . Therefore, the flow of the magnetic field B changes according to the change of the position of the permanent magnet 15, and the angle? Formed by the magnetic field B and the current i changes. Therefore, as the frequency is formed by the sinusoidal waveform, the changed magnetic field B is induced in the conductor of the cable 20 through which the current flows, and the waveform is instantaneously distorted to generate the electromotive force.

In the present invention, when the sensing device 1 senses an output waveform generated due to the movement of the cable 20 and sends it to the analyzer 25, the analyzer 25 receives the output waveform f (t) dt is converted into decibel (dB) using a value obtained by integrating a period (t1 to t2) (for example, 100 ms) of a predetermined period T, dt. By storing the obtained noise in the database, it is possible to determine whether or not the noise is caused by the natural phenomenon.

The noise on the output waveform measures a maximum amount of data that can be generated by the natural environment like a database of the electromotive force and converts it into a database.

Therefore, the present invention detects the electromotive force and the output waveform generated by the natural phenomenon by the detection sensor 16, and determines the abnormality of the cable 20 through the analyzer 25 that analyzes these signals.

9 to 11, the cable 20 is configured such that three conductors 24a, 24b and 24c are inserted into the conductor 24 (wire), and the conductors 24a ) And the conductor 24b are connected to the differential amplifier. When the two conductors move, when the electromotive force is generated, they become zero when the waveforms are the same or when the signal strength is the same. When a deviation occurs, And performs alarm processing.

The conductor 24c is connected to the operational amplifier so that an electromotive force is generated in proportion to the intensity of movement of the conductor.

Therefore, the analyzer 25 compares and analyzes the amplified signals of the differential amplifier and the operational amplifier to determine whether or not an alarm is generated.

The crime prevention system using the emergency situation detection system constructed as described above will be described as follows.

When the cable 20 is shaken, the permanent magnet 15 moves, the magnetic field B changes, and noise is generated in the cable conductor, and electromotive force and noise are generated. The generated electromotive force value is detected by the sensor 16 .

The electromotive force and the noise sensed by the sensing sensor 16 are analyzed and transmitted to the analyzing device 25 and analyzed based on the electromotive force and noise (for example, snow, rain, wind, etc.) Is compared with the stored database to determine whether or not the cable 20 intentionally caused by the third party has occurred.

As a result of the determination by the analyzer 25, if the cable 20 is not shaken by the natural phenomenon, that is, the position of the cable 20 in which the abnormality due to the impure intention of the third party is generated, (26) to transmit the abnormality of the cable (20) to promptly take action.

13 is a block diagram of an emergency situation detection system according to another embodiment of the present invention.

As shown in FIG. 13, a plurality of sensor cables 20 are provided at a predetermined distance, for example, a fence sensor 200 for detecting a change in the height of the fence, Thereby forming the wind speed sensor 300.

For example, the fence sensor 200 may be provided with an ultrasonic sensor as an ultrasonic wave transmitting unit at the upper end of the fence and an ultrasonic wave receiving unit as an ultrasonic wave receiving unit at the lower floor, And detects the change of the height of the fence, for example, the disappearance of the fence.

Therefore, when the fence disappears, the sensor cable is shaken. Therefore, the sensor cable signal and the ultrasonic signal of the ultrasonic sensor are connected with each other to determine whether or not the intruder is detected.

For example, assume that the sensor cable is set to detect an intruder when the shaking signal is greater than 100 (reference signal), and the ultrasonic signal is less than 100 (reference signal) 100, and the ultrasonic signal is below 100, it is not detected as an intruder unconditionally, but the sensor cable is detected as being shaken due to loss of fence.

In addition, when the signal of the sensor cable shaking is 100 or more and the ultrasonic signal is 100, the sensor cable is determined to be shaken by the intruder.

When the signal of the sensor cable is less than 100 and the ultrasonic signal is 100 or more, it is judged that the sensor cable is shaken due to the disappearance of the fence.

At this time, the detection value of the wind speed sensor 300 may also be correlated with the detection value of the intruder.

When the wind speed sensor 300 is equal to or greater than 100 (reference signal), the wind speed sensor 300 is used for intruder detection in conjunction with the sensor cable signal for every predetermined value interval.

For example, if the sensor cable signal is 100 or less and the wind speed is 100 or more, it is judged that the sensor cable is shaken due to the influence of the wind. If the sensor cable signal is 100 or more and the wind speed is 100 or less, It is judged to be shaken.

In the case where the sensor cable signal, the ultrasonic sensor signal, and the signal of the wind speed sensor are all combined to determine whether or not the intruder is intruding, the sensor cable signal is 100 or less, the ultrasonic sensor signal is 100, If it is less than 100, it is judged that there is no intruder.

On the other hand, if the sensor cable signal is 100 or more, the ultrasonic sensor signal is 100, and the signal of the pen sensor is 100 or less, it is determined that the sensor cable is shaken due to the intruder.

If the sensor cable signal is 100 or more, the ultrasonic sensor signal is 100 or more, and the signal of the pen sensor is 100 or less, it is judged that the sensor cable is shaken due to the disappearance of the fence.

When the sensor cable signal is 100 or more, the ultrasonic sensor signal is also 100 or more, and the signal of the pen sensor is 100, it is judged that the sensor cable is shaken due to the disappearance of the fence or wind. In this case, The cause of the shaking of the sensor cable is judged based on the fact that the change value of the sensor signal is large.

Meanwhile, according to the present invention, a sensor cable can be installed by dividing a region that is most affected by a natural phenomenon and a region that is not affected most.

Here, for example, natural phenomena can be winds, and there will be parts of the fence that are most likely to be exposed to this wind.

Therefore, the sensor cable signal installed in these places adjusts the size of the sensor cable detection signal so that when a larger signal is input, it can be recognized as intruder detection.

Alternatively, for the fence portion which is considered to be most influenced by the natural phenomenon, the pulling of the wire is set to be larger than the other portions, so that even if a stronger wind influences, the flicker is made equal.

In this way, the control center will not need to divide and manage the parts that can be affected by natural phenomena.

14 is a configuration diagram of a ring data communication network according to the first embodiment of the present invention.

14, in the ring-type data communication network of the present invention, one data cable 500 is configured in a ring shape, and a plurality of transmitters 600 and a receiver 700 are configured on the data cable 500. That is, The transmitter 600 and the receiver 700 are both formed on one data cable 500.

The plurality of transmitters 600 and the receivers 700 are bundled together. For example, the emergency situation detecting device installed at a predetermined place receives a detection signal transmitted from a PC installed at a predetermined place, And a set such that signals can be transmitted and received with each other, such as by transmitting a control signal to the PC.

A plurality of sets of the transmitter 600 and the receiver 700 configured on the data cable 500 may be connected to one sensing device or may be connected to other electronic devices for performing a signal transmission and reception function .

Therefore, even if any one of the transmitter and the receiver set fails, there is no adverse effect on other transmitters and receivers. In particular, if only one set is normal when connected to one sensor, a normal signal Enable transmission and reception.

Assuming that the plurality of transmitter and receiver sets are respectively connected to a separate sensing device and a PC, only the sensing device and the PC connected to the failed transmitter and receiver set are connected to a normal transmitter and receiver set The sensing device and the PC are capable of normal sensing operation.

The present invention constitutes a set of a transmitter 600 and a receiver 700 constituted by a coil, for example, a Trojan coil, which is very strong against noise, etc., in a ring data cable transmission network.

The set of the transmitter 600 and the receiver 700 composed of the Troy coils constitute a structure in which the data cable 500 forms a ring of, for example, a circular ring and penetrates the Troy month coil.

In this way, a signal having a specific frequency is transmitted to the transmitter 600 constituted by the Troy coils so as to form an on or off code.

The data communication network configured as described above serves to transmit a crime prevention and disaster prevention signal sensed and transmitted by, for example, an analog sensor, an acceleration sensor, a gyro sensor, a PIR sensor, or the like installed to sense a crime prevention signal, to a signal analyzer .

As the sensor for detecting the crime prevention signal, there may be an analog sensor and a contact input sensor.

Examples of the analog sensor include a magnetic field sensor, a vibration sensor, an acceleration sensor, and a piezo sensor. The contact input sensors include a PIR sensor, an infrared sensor, and a magnetic sensor.

As described above, the data communication network transmits a signal sensed by the sensor cable 20, the fence sensor 200, and the wind speed sensor 300 to the signal analyzer to detect the emergency disaster prevention signal, . This technique is also applied to the second and third embodiments described later.

15 is a configuration diagram of a ring data communication network according to the second embodiment of the present invention.

As shown in FIG. 15, the ring data cable transmission network is composed of two data cables 500 and 550, unlike the above embodiment.

The transmitter embodiment 600 includes both the transmitter 600 and the receiver 700 in one data cable 500 but the present embodiment separately configures the transmitter configuration cable 500 and the receiver configuration cable 550.

15, when the two data cables 500 and 550 are configured to have the same shape and the transmitter 600 is configured on one data cable 500, the other data cables 550 ) Constitute a receiver (700).

In this manner, a plurality of sets of transmitters 600 and receivers 700 are configured in the ring-shaped data cables 500 and 550.

The plurality of transmitters 600 and the receivers 700 are constituted by a bundled set as in the above embodiment. For example, a sensing device installed at a predetermined place receives a sensing signal transmitted from a PC installed at a predetermined place, A control signal is transmitted from the sensing device to the PC, and so on.

A plurality of sets of transmitters 600 and 700, each of which is comprised in the data cables 500 and 550, are connected to other electronic devices for each set to perform a signal transmission / reception function.

Therefore, even if any one of the transmitter and the receiver set fails, it does not adversely affect other transmitters and receivers, and enables normal signal transmission and reception.

For example, if it is assumed that the plurality of transmitters and receiver sets are connected to a separate remote sensing device and a PC, only the remote sensing device and the PC connected to the failed transmitter and receiver set can perform normal operations, And remote monitoring devices and PCs connected to the receiver set are capable of normal monitoring operations.

Meanwhile, the present embodiment can constitute a set of a transmitter 600 and a receiver 700 constituted by a coil, for example, a Trojan coil, which is very strong against noise, etc., in the ring data communication network.

The set of the transmitter 600 and the receiver 700 constituted of the Troy coils constitute a structure in which the data cables 500 and 550 form, for example, a ring of a round shape and penetrate the Troy month coil.

In this way, a signal having a specific frequency is transmitted to the transmitter 600 constituted by the Troy coils so as to form an on or off code.

The data cable transmission network configured as described above serves to transmit a crime prevention and disaster prevention signal sensed and transmitted by, for example, an analog sensor, an acceleration sensor, a gyro sensor, or a PIR sensor installed to sense a crime prevention signal, to a signal analyzer do.

As the sensor for detecting the crime prevention signal, there may be an analog sensor and a contact input sensor.

Examples of the analog sensor include a magnetic field sensor, a vibration sensor, an acceleration sensor, and a piezo sensor. The contact input sensors include a PIR sensor, an infrared sensor, and a magnetic sensor.

As described above, the data communication network transmits a signal sensed by the sensor cable 20, the fence sensor 200, and the wind speed sensor 300 to the signal analyzer to detect the emergency disaster prevention signal, .

16 is a configuration diagram of a data communication network according to the third embodiment of the present invention.

16, in a third embodiment of the present invention, coils 910 and 920 are divided into upper and lower parts in a multiplexing board (MUX) 900, and one coil 910 is connected to a transmission coil And the other coil 920 is constituted by a receiving coil.

At this time, the transmitting coil 910 is connected to the receiver 700, and the receiving coil 920 is connected to the transmitter 600. The data cable connected to the transmitting coil 910 is connected to the receiver 700 and the receiving cable 700 is connected to the receiving coil 920 in a state where a plurality of the transmitter 600 and the receiver 700 are constituted by one set 500 The connected data cable is configured to be connected to the transmitter 600.

With such a configuration, addition of the transmitting coil 910 and the receiving coil 920 to the multiplexing board 900 can improve the signal-to-noise ratio and enable long-distance communication.

In the data communication network of the present invention, when a light emitting device is formed on a data cable and connected to a control device of a sensing system, for example, when a data table is broken, Or may stop the sensing signal transmission operation.

An embodiment of a device for implementing a data communication network has been described. The above described embodiments illustrate some of the many concrete embodiments that illustrate the principles described herein. It will thus be appreciated that those skilled in the art, using the embodiments of the present invention, may readily implement many other arrangements within the scope defined by the claims of the present invention.

500, 550: Data cable 600: Transmitter
700: receiver

Claims (4)

When the electromotive force values of the two strands of the wire are equal to each other, zero (0) is outputted. When the electromotive force value is equal to And outputs a predetermined deviation value other than zero (0), thereby recognizing the predetermined deviation value as a crime prevention / disaster prevention detection signal and performing alarm processing. The two wires are connected to the differential amplifier, and the remaining one wire is connected to the differential amplifier A sensor cable connected to the operational amplifier to generate an electromotive force in a proportional manner and to detect a crime prevention disaster detection signal and to generate a detection signal to compare the amplified signal of the differential amplifier and the operational amplifier to determine whether an alarm is generated;
The height of the fence due to the disappearance of the fence due to the change in the distance or the intensity of the ultrasonic signal detected by the ultrasonic receiver in a state where the ultrasonic sensor as the ultrasonic wave transmitting unit is installed on the upper end of the fence and the ultrasonic receiving unit A fence sensor for detecting the fence,
A data cable for transmitting a sensing signal output from an wind speed sensor for sensing a wind speed to a signal analyzer is formed in a ring shape by one or a plurality of data cables,
Wherein the plurality of transmitters and receiver sets are configured to be able to receive a sensing signal transmitted from a PC installed in a predetermined place and to transmit a control signal from the remote sensing device to the PC, Even if the transmitter and the receiver set of the transmitter and the receiver fail, it does not affect other transmitters and receivers, enables normal signal transmission and reception,
Wherein the light emitting device is formed on the data cable and connected to the control device of the sensing system to detect a failure of the data table and to stop the sensing signal transmission operation in the control device. The method according to claim 1,
Wherein the transmitter and the receiver are constructed of a Troydal coil,
A transmitter and a receiver are constituted by forming a circular loop of the data cable and penetrating the Troy month coil,
Wherein a signal having a specific frequency is used to form an on or off code in a transmitter composed of a Troy coils. When the electromotive force values of the two strands of the wire are equal to each other, zero (0) is outputted. When the electromotive force value is equal to And outputs a predetermined deviation value other than zero (0), thereby recognizing the predetermined deviation value as a crime prevention / disaster prevention detection signal and performing alarm processing. The two wires are connected to the differential amplifier, and the remaining one wire is connected to the differential amplifier A sensor cable connected to the operational amplifier to generate an electromotive force in a proportional manner and to detect a crime prevention disaster detection signal and to generate a detection signal to compare the amplified signal of the differential amplifier and the operational amplifier to determine whether an alarm is generated;
The height of the fence due to the disappearance of the fence due to the change in the distance or the intensity of the ultrasonic signal detected by the ultrasonic receiver in a state where the ultrasonic sensor as the ultrasonic wave transmitting unit is installed on the upper end of the fence and the ultrasonic receiving unit A fence sensor for detecting the fence,
A transmission coil and a receiving coil are divided into upper and lower parts in a multiplexing board so as to transmit a detection signal output from an airflow sensor for detecting the wind speed to a signal analyzer,
Wherein the transmitting coil is connected to a receiver, the receiving coil is constituted by a data cable to be connected to a transmitter, the data cable is constituted by a plurality of transmitters and receivers,
The plurality of transmitters and receiver sets are configured as one set so that a remote sensing device installed at a predetermined place receives a sensing signal transmitted from a PC installed at a predetermined place and further transmits a control signal from the remote sensing device to the PC So that even if any one of the transmitter and the receiver fails, the other transmitter and the receiver are not affected and normal signal transmission and reception are enabled. [Claim 3]
Wherein the transmitter and the receiver are constructed of a Troydal coil,
A transmitter and a receiver are constituted by forming a circular loop of the data cable and penetrating the Troy month coil,
Wherein a signal having a specific frequency is used to form an on or off code in a transmitter composed of a Troy coils.

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