JP2009271731A - Sensing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sensing system in which a sensor is installed at any place apart from an optical fiber and many additional sensors are mounted over a wide range of area. <P>SOLUTION: A monitoring apparatus 12 includes a laser light source 121 which drives a plurality of radio-light conversion nodes and emits steady light in the radio-light conversion node 13 (n), and a light signal receiver 122 which receives the returned light signal. A plurality of sensor nodes 14 (m) respectively include a plurality of sensor interfaces 142 and a radio transmission circuit 141 which transmits detection data from a sensor Sk by radio to the corresponding radio-light conversion node, the sensor being connected to the sensor interface. The plurality of radio-light conversion nodes 13 (n) respectively include a photoelectronic transducer 131 which converts a part of steady light to power, a wireless receiver circuit 132 which receives the detection data from the sensor by radio, and a light modulator 133 which modulates other part of the steady light to generate a signal light in which the detection data is embedded. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a sensing system in which a large number of sensors can be installed in a wide area using optical fibers and radio.

Conventionally, for example, a sensor using a radio to quickly detect a collapse or collapse of a predetermined mountain / hill region, detect the concentration of CO2 in the atmosphere in a predetermined region, detect temperature and humidity, etc. The network is widely studied.
For example, a collapse monitoring system using a wireless communication terminal, an optical fiber, or the like shown in Patent Document 1 is known. As shown in FIG. 5, in the sensing system (collapse monitoring system) 8, wireless communication terminals 861 to 864, 871 to 874, and 881 to 884 to which strain sensors are connected are arranged in each mountain / hill region. The wireless communication terminals 861 to 863 transfer detection data to the wireless communication terminal 864 by an ad hoc method, and the receiver 86 can receive the detection data from the wireless communication terminals 861 to 864. Similarly, the receiver 87 can receive detection data from the wireless communication terminals 871 to 874. The receiver 88 can receive detection data from the wireless communication terminals 881 to 884.

The receivers 86, 87, and 88 send detection data from each wireless communication terminal to the base station 83 via the optical fiber 82. The base station 83 includes an optical switch 831. By switching the optical switch 831, the detection data from the receivers 86, 87, 88 are sequentially received.
The base station 83 sends the received detection data to the observation center 85 via the public network 84.

  On the other hand, the inventor has proposed a sensing technique shown in Patent Document 2. In this technique, as shown in FIG. 6, the sensing system 9 includes a host device (monitoring device) 93 connected via an optical fiber 92, a plurality of sensor nodes 911, 912,. Terminal devices) 911, 912,... In FIG. 6, sensors S1 and S2 are connected to the sensor node 911, and sensors S3, S4 and S5 are connected to the sensor node 912.

  The host device 93 includes a laser light source 931, an optical signal receiver 932, and an optical circulator 933, and steady light that functions as power and signals is emitted from the laser light source 931. Each of the sensor nodes 911, 912,... Is provided with a photoelectric converter 94, and the photoelectric converter 94 converts part of the steady light transmitted from the host device 93 into driving power.

Detection data from the sensors S1, S2, S3, S4, S5,... Are input to the sensor nodes 911, 912,. The optical modulator 95 mounted on the sensor nodes 911, 912,... Modulates the steady light received via the optical fiber 92 based on the detection data, and the signal light passes through the optical fiber 92 and the optical circulator 933. It is transmitted to the optical signal receiver 932.
2007-018126 2007-335987

  In the sensing system 8 of Patent Document 1, since the wireless communication terminal transmits and receives data by the ad hoc method, there is a problem that system control becomes troublesome. Further, since the communication range is extremely narrow (for example, about 500 m with the receiver 81 as the center), it is not easy to expand the sensing area. In Patent Document 1, a signal from a sensor is selected by an optical switch 831 without giving an identification code (ID) to the sensor. For this reason, the number of receivers (86, 87, 88 in FIG. 5) is limited, and expansion is not easy.

  On the other hand, in the sensing system 9 of Patent Document 2, the sensor can be arranged only at a distance of several meters at most of the sensor nodes 911, 912, ..., and the area where the sensor can be installed is at most the sensor nodes 911, 912, ... Stay around. For this reason, even when it is desired to expand the detection area, the area that can be expanded is limited to the periphery of the optical fiber at most, and there is a problem that it cannot be expanded to a wide area. Moreover, in order to increase the number of sensors, it is necessary to increase the number of optical fibers, resulting in a problem that the construction becomes complicated.

  An object of the present invention is to provide a sensing system in which sensors can be installed at an arbitrary location away from an optical fiber and a large number of sensors can be added in a wide area.

The gist of the sensing system of the present invention is (1) to (5).
(1)
A monitoring device, a plurality of wireless / optical conversion nodes connected to the monitoring device via an optical fiber (a connection mode is a dendritic network, a radial network, a loop network, or a combination thereof); In a sensing system comprising a plurality of sensor nodes provided corresponding to conversion nodes,
The monitoring device
A laser light source that drives the plurality of wireless / optical conversion nodes and emits steady light to the optical fiber for generating signal light in the wireless / optical conversion nodes;
An optical signal receiver for receiving signal light sent back from the plurality of wireless / optical conversion nodes;
With
The plurality of sensor nodes are respectively
At least one interface for connecting a plurality of sensors;
A wireless transmission circuit that wirelessly transmits detection data from at least one sensor connected to the at least one interface to the corresponding wireless / optical conversion node;
With
The plurality of wireless / optical conversion nodes are respectively
A photoelectric converter that converts part of the stationary light supplied via the optical fiber into electric power;
A wireless reception circuit for wirelessly receiving detection data from the sensor node;
An optical modulator that modulates the other part of the stationary light and generates the signal light in which the detection data is embedded;
Sensing system characterized by comprising

(2)
The sensor system according to (1), wherein a sensor identification code and a sensor node identification code, or further a system identification code is given to the detection data at the sensor node.

(3)
The wireless transmission circuit of the sensor node performs transmission at a predetermined frequency, and the wireless reception circuit of the wireless / optical conversion node performs reception at the predetermined frequency,
The wireless / optical conversion node includes identification code verification means for verifying that the data received at the predetermined frequency is the detection data based on the sensor identification code, the sensor node identification code, or the system identification code, The identification code verification means passes the data as the detection data to the optical modulator when the received data is the detection data, and discards the data when the received data is not the detection data. The sensing system according to (1) or (2).

(4)
The wireless transmission circuit of the sensor node performs transmission at a predetermined frequency, and the wireless reception circuit of the wireless / optical conversion node performs reception at the predetermined frequency,
The wireless / optical conversion node passes the data to the optical modulator without verifying whether the received data is the detection data.
The sensing system according to (1) or (2), wherein

(5)
The sensing system according to any one of (1) to (4), wherein the sensor node has radio wave directivity with respect to the wireless / optical conversion node.

  ADVANTAGE OF THE INVENTION According to this invention, the sensing system which can install a sensor in the arbitrary places away from the optical fiber and can add many sensors in a wide area | region can be provided. Moreover, if necessary, a sensor node can be easily added or a sensor can be added to an existing sensor node.

  In the present invention, the wireless / optical conversion node can be driven with low power by configuring the wireless / optical conversion node to have no light emitting element. In addition, each sensor node has radio wave directivity for the wireless / optical conversion node, and data transmission from the wireless transmission circuit of each sensor node to the wireless reception circuit of the wireless / optical conversion node is executed without any procedure. The power consumption can be further reduced by reducing the amount.

  In the present invention, since the wireless / optical conversion node is driven by optical power feeding from the monitoring device, a battery can be eliminated. That is, in this case, it is not necessary to replace the battery, and maintenance can be made free.

An embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is an overall explanatory view of a sensing system of the present invention. 1, a sensing system 1 includes a monitoring device 12 and a plurality of wireless / optical conversion nodes 13 (1), 13 (2),..., 13 (N) connected via an optical fiber 11. A plurality of sensor nodes 14 (1), 14 (2),..., 14 (M) can be added to the optical conversion nodes.

2A and 2B show the circuit configuration of the wireless / optical conversion node 13 (n) (n = 1, 2,..., N), and FIG. 3 shows the sensor node 14 (m) (m = 1). , 2,..., M).
In FIG. 1, the monitoring device 12 includes a laser light source 121, an optical signal receiver 122, and an optical circulator 123. The laser light source 121 drives a plurality of wireless / optical conversion nodes 13 (n) (see FIG. 2A) and generates stationary light BS for generating signal light in the wireless / optical conversion nodes. The optical signal receiver 122 receives, via the optical circulator 123, the signal light BDD that is returned from the wireless / optical conversion node 13 (n) after being modulated.

  As shown in FIG. 2A, the wireless / optical conversion node 13 (n) includes a photoelectric converter 131, a wireless reception circuit 132, an amplifier 134, an optical modulator 135, and a mirror 136, respectively. ing. The photoelectric converter 131 converts part of the steady light BS propagated from the laser light source 121 through the optical fiber 11 into electric power.

  The wireless reception circuit 132 of the wireless / optical conversion node 13 (n) can receive radio waves (including detection data DD) transmitted from the wireless transmission circuit 141 of the sensor node 14 (m). Specifically, only a radio wave of a specific frequency emitted from the sensor node 14 (m) is received by the channel selection filter provided in the wireless reception circuit 132. Furthermore, the specific code (identification code ID of the sensor node 14 (m)) possessed by the radio wave is identified, and only the radio signal from the sensor node is acquired.

  Normally, the sensor nodes 14 (m) are not arranged so that the plurality of wireless / optical conversion nodes 13 (n) receive the detection data DD from one sensor node 14 (m). The 13 (n) wireless reception circuits 132 can be configured to receive detection data DD having a common frequency.

  In FIG. 2A, the microprocessor is not mounted on the wireless / optical conversion node 13 (n), but a microprocessor 133 can also be mounted as shown in FIG. When the microprocessor 133 is mounted, as will be described later, the wireless / optical conversion node 13 (n) adds the identification code of the wireless / optical conversion node 13 (n) to the detection data DD. Processing and control can be performed.

  The amplifier 134 amplifies the received detection data DD and passes it to the optical modulator 135. The optical modulator 135 modulates a part of the steady light BS from the laser light source 121 with the detection data DD to generate the signal light BDD. Detection data DD is embedded in the signal light BDD. As described above, in the monitoring device 12, the optical signal receiver 122 receives the signal light BDD.

  As shown in FIG. 3, the sensor node 14 (m) includes a wireless transmission circuit 141, a sensor interface 142, a microprocessor 143, a solar battery 144, and a secondary battery 145, respectively. The wireless transmission circuit 141 wirelessly transmits detection data DD from the plurality of sensors Sk to any of the wireless / optical conversion nodes 13 (n). In the present invention, since a certain sensor node 14 (m) is a fixed point, detection data can be transmitted to a certain wireless / optical conversion node 13 (n) by a directional antenna. As a result, the power consumption of the sensor node 14 (m) and the wireless / optical conversion node 13 (n) can be greatly reduced.

  The sensor interface 142 is configured so that at least one sensor Sk can be connected, and A / D converts a signal from the sensor Sk. In FIG. 3, the sensor interface 142 to which the sensors S1 and S2 are connected is indicated by a solid line block, and the sensor interface 142 to which the sensors S1 and S2 are not connected is indicated by a broken line block.

  The microprocessor 143 controls the entire sensor node 14 (m). For example, the detection data from each sensor Sk is determined at random within a predetermined time width at a time that does not overlap with other sensors Sk. You can get it at the time. In addition, the microprocessor 143 gives an identification code ID to the signal from the sensor Sk. The energy generated by the solar cell 144 is stored in the secondary battery 145. In the present embodiment, the solar battery 144 is used as the power source and the optical power is stored in the secondary battery 145, but may be stored in the capacitor. In addition, a primary battery can be used as a power source instead of the set of the solar battery 144 and the secondary battery 145.

  In the present embodiment, the optical fiber 11 can be provided with a large number of wireless / optical conversion nodes 13 (n). Specifically, the optical fiber 11 can be laid over 20 km, and 100 or more wireless / optical conversion nodes 13 (n) can be provided at appropriate positions. In addition, a plurality (about 10) of sensor nodes 14 (m) can be connected to one wireless / optical conversion node 13 (n).

  A plurality (1 to 10) of sensors Sk can be connected to one sensor node 14 (m). Therefore, since one wireless / optical conversion node 13 (n) can receive signals from about 50 sensors Sk on average, in the sensing system, 5,000 or more sensors Sk can be arranged. In addition, the installation range of the sensor Sk can be set to 10 km square.

In the sensing system of the present invention, since the number of sensors Sk is large, the sensor identification technique is important.
The interface 142 provided in the sensor node 14 (m) has a specification that allows a plurality of sensors to be mounted. However, the types of sensors connected to the interface 142 of a certain sensor node 14 (m) are the same. May be different.

  In this embodiment, the sensor identification code a is not included in the detection data DD output from the sensor Sk, and the microprocessor 143 of the sensor node 14 (m) assigns the sensor identification code a to the detection data DD. .

  In addition, the sensor identification code a is not included in the detection data DD output from the sensor Sk, and the sensor node 14 (m) can be configured not to add the sensor identification code a to the detection data DD. For example, when the manhole cover is detected to be opened by the plurality of sensors Sk, it is not necessary to specify the sensor as long as the manhole can be specified when the cover is opened. As described above, when a certain detection is performed by the sensor Sk, if an abnormality occurs, the sensor Sk is specified as long as the sensor node 14 (m) to which the sensor Sk detecting the abnormality is connected can be specified. Since there is no need, the sensor identification code a need not be given to the detection data DD output from the sensor Sk.

  When transmitting the detection data DD, the microprocessor 143 provided in the sensor node 14 (m) gives information (sensor node identification code b) for specifying the sensor node 14 (m) to the detection data DD. be able to. In the present embodiment, the microprocessor 143 appends the sensor identification code a and the sensor node identification code b to the detection data DD. This sensor node identification code b is the ID of the sensor node 14 (m).

  Further, even if the sensor node identification code b is not appended to the detection data DD in the sensor node 14 (m), the sensor node identification code b is imparted to the detection data DD in the wireless / optical conversion node 13 (n). Can do. That is, in the wireless / optical conversion node 13 (n) in FIG. 2B, when the microprocessor 132 receives the detection data DD from the wireless transmission circuit 141 of the sensor node 14 (m), the sensor node 14 (m ) Can be added to the detection data DD.

  Further, in the wireless / optical conversion node 13 (n) in FIG. 2B, the microprocessor 132 uses the wireless / optical conversion node identification code c for identifying the wireless / optical conversion node 13 (n) as the detection data DD. Can be added.

  When the monitoring device 12 receives the detection data DD from the wireless / optical conversion node 13 (n), the monitoring device 12 determines the wireless / optical conversion node 13 (n) from the identification codes a, b, c included in the detection data DD. ), The sensor node 14 (m) and the sensor Sk can be specified. In addition, there is a case in which it is not necessary to include the identification code a in the detection data DD when the detection purpose can be achieved by detecting an event in which any of the plurality of sensors Sk belonging to a certain sensor node 14 (m) is detected. is there. In such a case, the wireless / optical conversion node 13 (n) and the sensor node 14 (m) are specified by the identification codes b and c.

Conventionally, one sensor is generally arranged in one sensor node. At this time, it is only necessary to identify the sensor node, and since the number of sensors is small, management is easy. On the other hand, in the present invention, there are a large number of sensors in the sensor node, and it is necessary to perform sensor identification systematically.
Since identification information Z (identification codes corresponding to a, b, and c described above) for identifying the location unique to the sensor is given to the sensor, no identification information is given to nodes in the middle.

In the present invention, when detection data is transmitted, an identification code is assigned to each node. Therefore, each time a sensor node or sensor is added, it is not necessary to give the sensor identification information Z viewed from the entire system.
Sensor identification is easy when the number of sensors is small, but when the number of sensors is several thousand, it is not easy to manage with sensor-specific identification information Z. In the present invention, without specifying the sensor Sk by the unique identification information Z, the sensor Sk is specified from the identification codes a, b, and c assigned to each node, or the sensor node 14 ( m) can be specified, and the management of the sensor Sk is easy. FIG. 4 shows how the identification code of the detection data DD is changed when the identification code of the sensor Sk is written in the detection data DD. If the identification code b includes information that can also identify the wireless / optical conversion node 13 (n), the identification code c is not necessary.

  Conventionally, when adding a sensor, it is necessary to change or extend the laying path of the existing optical fiber 11, and the construction is not easy. Moreover, in urban areas, there are many cases where restrictions are imposed on the change or extension of the laying route of the optical fiber 11. On the other hand, in the sensing system 1 of the present invention, the sensor node 14 (m) and the sensor Sk can be easily added to any place without changing or extending the laying path of the optical fiber 11, and the sensor sensor Sk can be The detection data DD can be managed in the monitoring device 12.

BRIEF DESCRIPTION OF THE DRAWINGS It is whole explanatory drawing of the sensing system of this invention. (A) is a figure which shows the circuit structure of the radio | wireless / optical conversion node which does not have a microprocessor, (B) is a figure which shows the circuit structure of the radio | wireless / optical conversion node which has a microprocessor. It is a figure which shows the circuit structure of a sensor node. It is a figure which shows the detection data which the sensor ID in case sensor ID is not written in detection data, the sensor node, the radio | wireless / light conversion node, and the identification code added to this. It is explanatory drawing which shows an example of the conventional sensing system. It is explanatory drawing which shows the other example of the conventional sensing system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sensing system 11 Optical fiber 12 Monitoring apparatus 13 (n) Radio | wireless and optical conversion node 14 (m) Sensor node 121 Laser light source 122 Optical signal receiver 123 Optical circulator 131 Photoelectric converter 132 Radio reception circuit 133 Discriminator 134 Amplifier 135 Optical modulation Device 136 Mirror 141 Wireless transmission circuit 142 Interface 143 Microprocessor 144 Solar cell 145 Secondary battery Sk sensor

Claims (5)

In a sensing system comprising a monitoring device, a plurality of wireless / light conversion nodes connected to the monitoring device via optical fibers, and a plurality of sensor nodes provided corresponding to the plurality of wireless / light conversion nodes,
The monitoring device
A laser light source that drives the plurality of wireless / optical conversion nodes and emits stationary light to the optical fiber for generating signal light in the wireless / optical conversion node;
An optical signal receiver for receiving signal light sent back from the plurality of wireless / optical conversion nodes;
With
The plurality of sensor nodes are respectively
At least one interface for connecting a plurality of sensors;
A wireless transmission circuit that wirelessly transmits detection data from at least one sensor connected to the at least one interface to the corresponding wireless / optical conversion node;
With
The plurality of wireless / optical conversion nodes are respectively
A photoelectric converter that converts part of the stationary light supplied via the optical fiber into electric power;
A wireless reception circuit for wirelessly receiving detection data from the sensor node;
An optical modulator that modulates the other part of the stationary light and generates the signal light in which the detection data is embedded;
Sensing system characterized by comprising   The sensing system according to claim 1, wherein a sensor identification code and a sensor node identification code, or further a system identification code is given to the detection data at the sensor node. The wireless transmission circuit of the sensor node performs transmission at a predetermined frequency, and the wireless reception circuit of the wireless / optical conversion node performs reception at the predetermined frequency,
The wireless / optical conversion node includes identification code verification means for verifying that the data received at the predetermined frequency is the detection data based on the sensor identification code, the sensor node identification code, or the system identification code, The identification code verification means passes the data as the detection data to the optical modulator when the received data is the detection data, and discards the data when the received data is not the detection data. The sensing system according to claim 1 or 2. The wireless transmission circuit of the sensor node performs transmission at a predetermined frequency, and the wireless reception circuit of the wireless / optical conversion node performs reception at the predetermined frequency,
The wireless / optical conversion node passes the data to the optical modulator without verifying whether the received data is the detection data.
The sensing system according to claim 1 or 2, wherein   The sensing system according to any one of claims 1 to 4, wherein the sensor node has a radio wave directivity with respect to the wireless / optical conversion node.

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