KR100661189B1 - Service method and system for monitoring the vehicle based on 802.11a/g wireless lan - Google Patents

Abstract

The present invention relates to a method for in-vehicle monitoring service based on 802.11A / G wireless LAN, comprising: an 802.11A / G wireless LAN-based monitoring apparatus using a 2.4 GHz band and a 5.7 GHz band, a plurality of wireless LAN base stations, and the wireless Monitoring an inside of a vehicle in operation through a central control center connected to a LAN base station through a network, and registering a registered IP of the IP with a monitoring apparatus installed in the vehicle to the central control center; The monitoring device photographing the inside of the vehicle when the vehicle is driven; The central control center invoking the monitoring device when the vehicle interior monitoring is required; The monitoring device responsive to the central control center; The central control center requesting image data from the monitoring apparatus; The monitoring device transmitting image data photographed to the central control center using an inter access point protocol (IFP) and a real-time transfer protocol (RTP); And displaying, by the central control center, the received image data.

According to the present invention, it is possible to accurately grasp the accidents generated by monitoring the inside of the driving vehicle in real time and to minimize the damage by responding quickly.

Camera, 802.11A / G, Wireless LAN, Vehicle, Surveillance

Description

２０２．１１Ａ ／ Ｇ SERVICE METHOD AND SYSTEM FOR MONITORING THE VEHICLE BASED ON 802.11A / G WIRELESS LAN}             

1 is a conceptual diagram of a vehicle interior monitoring system according to the present invention,

2 is a block diagram of a monitoring apparatus according to the present invention,

3 is an internal block diagram of a wireless transceiver module and a plurality of WLAN base stations according to the present invention;

4 is a block diagram of a central control center according to the present invention;

5 is a flowchart illustrating an in-vehicle monitoring service according to the present invention.

* Explanation of symbols for main parts of the drawings

110: monitoring device 120: wireless LAN base station

130: network 140: central control center

210: camera 220: video server

230: wireless transmission and reception module 310: transceiver

320: signal detection unit 330: control unit

340: roaming unit 350: RF unit

410: S / W Hub 420: Operation Server

430: Database 440: Surveillance Monitor

The present invention relates to a method and system for monitoring an interior of a vehicle, and more particularly, to a service method and system for real-time monitoring of an interior of a vehicle operating under the 802.11A / G WLAN specification using a 2.4 GHz band and a 5.7 GHz band. will be.

In the current surveillance system, a number of surveillance cameras are installed in a specific place such as a bank, a parking lot, an elevator, and the like, and the situation is monitored in real time while viewing image data captured by a connected surveillance monitor.

On the other hand, as society becomes more complex and the trend of personalization is spreading, crimes such as terrorism or violence targeting an unspecified majority frequently occur. In particular, recently, an accident such as violence or arson occurs in a vehicle in operation such as a subway or a bus. Therefore, if the inside of the running vehicle can be monitored in real time, it will be possible to minimize the damage caused by the accident by accurately identifying and quickly responding to the accident.

Accordingly, the present invention has been made to solve the above problems, it is possible to monitor the inside of the vehicle in real time using a wireless LAN service under the 802.11A / G wireless LAN using the 2.4GHz band and 5.7GHz band. An object of the present invention is to provide a method and system for monitoring an internal vehicle based on 802.11A / G WLAN.

In order to achieve the above object, an internal vehicle monitoring service method based on 802.11A / G wireless LAN according to the present invention includes a plurality of 802.11A / G wireless LAN-based monitoring apparatus and a plurality of wireless LAN-based wireless LAN. Monitoring the inside of the vehicle in operation through a wireless LAN base station and a central control center connected to the wireless LAN base station through a network, and registering the own IP received by the monitoring apparatus installed in the vehicle to the central control center; The monitoring device photographing the inside of the vehicle when the vehicle is driven; The central control center invoking the monitoring device when the vehicle interior monitoring is required; The monitoring device responsive to the central control center; The central control center requesting image data from the monitoring apparatus; The monitoring device transmitting image data photographed to the central control center using an inter access point protocol (IFP) and a real-time transfer protocol (RTP); And displaying, by the central control center, the received image data.

On the other hand, in-vehicle surveillance system based on 802.11A / G wireless LAN according to the present invention, a monitoring device installed in the vehicle to shoot the inside of the vehicle and manages the image data taken; A plurality of wireless LAN base stations installed in a direction in which the vehicle proceeds and wirelessly communicating with the monitoring device in a peer-to-peer manner; And a central control center connected to the plurality of WLAN base stations via a network to control and monitor the monitoring device, and receive and display image data photographed from the monitoring device through the plurality of WLAN base stations. do.

At this time, the monitoring device, a camera for photographing the interior of the vehicle; A video server for compressing image data photographed by the camera and storing the image data in a digital format; And a wireless transmitting / receiving module for transmitting the stored image data to the WLAN base station while communicating in a wireless LAN form using the plurality of WLAN base stations using an Inter Access Point Protocol (IAPP) and a Real-Time Transfer Protocol (RTP). It is preferable.

In addition, each of the wireless transceiver module and the plurality of WLAN base stations, the antenna; A signal detecting unit detecting and selecting a signal when overlapping signals according to WLAN communication; Roaming unit for selecting and switching (roaming) one wireless LAN base station maintaining a signal strength of more than a reference value to maintain a continuous wireless section; And an RF unit for controlling roaming.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a conceptual diagram of an in-vehicle monitoring system according to the present invention, and includes a monitoring device 110, a plurality of wireless LAN base stations 120, and a central control center 140. The monitoring device 110 is installed in a train car, a train car, a bus, or the like to photograph the inside of the vehicle and to manage the image data photographed. The plurality of WLAN base stations 120 are installed at regular intervals in a direction in which the vehicle proceeds for wireless LAN communication with the monitoring apparatus 110 that is installed inside the vehicle and moves. For example, the trains may be installed at regular intervals along the tracks on which the trains operate, or at regular intervals along the roads on which the buses operate.

The central control center 140 is connected to a plurality of wireless LAN base station 120 by a network network 130 to control the monitoring device 110, the image data taken from the monitoring device 110 a plurality of wireless LAN base station Received via 120, stored and displayed.

Meanwhile, the monitoring apparatus 110 and the plurality of wireless LAN base stations 120 are based on the 802.11A / G wireless LAN standard using the 2.4 GHz band and the 5.7 GHz band for high-speed implementation in the form of 30 frames. In addition, high quality data can be transmitted. At this time, the monitoring device 110 and the plurality of wireless LAN base station 120 both play the role of an access point (AP) to communicate in a point-to-point wireless LAN form.

However, the monitoring device 110 and the plurality of wireless LAN base stations 120 preferably apply orthogonal frequency division multiplexing (OFDM), which is a multicarrier modulation scheme, to achieve more stable performance in an environment of multipath and mobility. .

The monitoring apparatus 110 and the plurality of wireless LAN base stations 120 support roaming services according to a mobile environment using an inter access point protocol (IAP). Referring to the principle of roaming, when the signal level received from the wireless LAN base station 120 in the monitoring device 110 installed inside the driving vehicle is less than the reference value (for example, -74.5dBm), the wireless section is not disconnected. In order to maintain, the monitoring apparatus 110 is connected to the WLAN base station 120 having a reception signal level equal to or greater than a reference value.

In reality, the WLAN base station 120 may be installed to maintain approximately 300M intervals. In addition, the specification of the monitoring device 110 and the plurality of wireless LAN base station 120, the bandwidth is 22MHz, NF 5dB, and the transmission output is 17dBm can be adjusted in 4 steps at 3dB intervals can apply a modulation scheme of 64QAM. have.

2 is a configuration diagram of a monitoring apparatus according to the present invention, and includes a plurality of cameras 210, a video server 220, and a wireless transmission / reception module 230. The camera 210 is a CCD or CMOS camera that is commonly used to be installed in various places inside the vehicle to photograph the inside of the vehicle. The video server 220 includes a plug-n-picture function to convert image data photographed by the camera 210 into a digital format and compress the data using MPEG technology (eg, 200: 1). Ratio).

The video server 220 responds to the case where the central control center 140 calls after receiving a floating or fixed IP according to the communication protocol TCP / IP (Transmission Control Protocol / Internet Protocol). Based on the structure.

The wireless transmission / reception module 230 transmits image data stored by wireless LAN-type communication using an inter-access point protocol (IAP) for roaming and a real-time transfer protocol (RTP) for real-time transmission. To send.

3 is a block diagram of a wireless transceiver module and a plurality of WLAN base stations according to the present invention, each of the transceiver 310 (antenna), the signal detector 320, the controller 330, the roaming unit 340, and It consists of an RF unit 350. The antenna 310 may be connected by an RF cable (feed line), and converts a signal received from air, that is, an electromagnetic energy form, into a voltage to be processed into digital data, or converts a signal to be transmitted, that is, a voltage form into an electromagnetic energy form, to air. Emission to the middle

At this time, in the present invention, it is preferable to apply the smart antenna technology in order to ensure the optimal reception signal in the non-line of sight (non-visibility). In addition, it is desirable to maximize the wireless transmit / receive performance and bandwidth (capacity) by using a variety of half-wavelength device array method and a high-performance DSP, and adaptive beam pattern control according to RF signal environment change.

In addition, the antenna 310 of the WLAN base station may radiate a directional beam only to a vehicle in communication to minimize signal interference of another vehicle.

The signal detector 320 detects and selects overlapping signals when signals according to WLAN communication overlap. In addition, the roaming unit 340 selects and switches (roams) one WLAN base station maintaining a signal strength above a reference value in order to maintain a continuous wireless section without interruption. In addition, the RF unit 350 controls roaming between WLAN base stations.

Meanwhile, the controller 330 integrally controls the antenna 310, the signal detector 320, the roaming unit 340, and the RF unit 350 to detect the inside of the vehicle by wireless LAN communication. Implement

4 is a block diagram of the central control center according to the present invention, which includes a S / W Hub 410, an operation server 420, a database 430, and a monitoring monitor 440. The S / W Hub 410 performs a switching function as an aggregation device between terminals. In addition, the operation server 420 monitors the inside of the vehicle in real time by controlling the monitoring device 110 installed inside the vehicle while taking charge of overall operation.

The database 430 stores a list related to the registered monitoring apparatus 110 and stores image data photographed and received from the monitoring apparatus 110. The monitoring monitor 440 displays the received image data in real time.

FIG. 5 is a flowchart illustrating an in-vehicle monitoring service according to the present invention, wherein an 802.11A / G WLAN-based monitoring apparatus 110 and a plurality of WLAN base stations 120 using a 2.4 GHz band and a 5.7 GHz band, In addition, the present invention represents a service for real-time monitoring of the inside of a vehicle in operation through the central control center 140 connected to the WLAN base station 120 through the network 130.

Referring to FIG. 5, the monitoring device 110 installed in a train carriage, a train carriage, a bus, and the like registers an IP granted from the central control center 140 to the central control center 140 (S510).

Subsequently, when the vehicle is driven, the monitoring apparatus 110 photographs the inside of the vehicle (S520). When the need arises to monitor the inside of the vehicle, the central control center 140 calls the monitoring apparatus 110 using the registered IP information (S530). Then, the monitoring device 110 responds to the central control center 140 according to the client / server base (S540).

Subsequently, the central control center 140 requests image data from the monitoring apparatus 110 (S550). Then, the monitoring device 110 uses the IAPP (Inter Access Point Protocol) for roaming and the Real-Time Transfer Protocol (RTP) for real-time transmission to control centrally through the WLAN communication with the WLAN base station 120 The image data photographed to the center 140 is transmitted (S560).

Finally, the central control center 140 stores and displays the received image data and monitors the inside of the vehicle (S570).

On the other hand, the monitoring device 110 and the wireless LAN base station 120 is preferably communicated by Orthogonal Frequency Division Multiplexing (OFDM) that can exhibit a stable performance in the environment of multipath and mobility.

As described above, in-vehicle surveillance service method and system based on 802.11A / G wireless LAN can accurately identify the accidents caused by real-time monitoring of the inside of the vehicle in operation and can quickly respond accordingly to minimize damage. .

Claims (6)

Monitoring inside the vehicle in operation through a monitoring device based on 802.11A / G WLAN using a 2.4GHz band and a 5.7GHz band, a plurality of WLAN base stations, and a central control center connected to the WLAN base station by a network. Registering, by the monitoring apparatus installed in the vehicle, its own IP assigned to the central control center; The monitoring device photographing the inside of the vehicle when the vehicle is driven; The central control center invoking the monitoring device when the vehicle interior monitoring is required; The monitoring device responsive to the central control center; The central control center requesting image data from the monitoring apparatus; The monitoring device transmitting image data photographed to the central control center using an inter access point protocol (IFP) and a real-time transfer protocol (RTP); And And displaying the received image data in the central control center. The method of claim 1, The vehicle is at least one of a train passenger car, a train car, and a bus, characterized in that the vehicle interior monitoring service based on 802.11A / G wireless LAN. The method of claim 1, The monitoring apparatus and the WLAN base station in the orthogonal frequency division multiplexing (OFDM) communication method characterized in that the inside of the vehicle monitoring service under 802.11A / G WLAN. In the system for monitoring the inside of the vehicle running under the 802.11A / G wireless LAN base using 2.4GHz band and 5.7GHz band, A monitoring device installed inside the vehicle and configured to photograph the interior of the vehicle and manage image data photographed; A plurality of wireless LAN base stations installed in a direction in which the vehicle proceeds and wirelessly communicating with the monitoring device in a peer-to-peer manner; And And a central control center connected to the plurality of WLAN base stations via a network to control and monitor the monitoring device, and to receive and display image data photographed from the monitoring device via the plurality of WLAN base stations, The monitoring device, A camera photographing the inside of the vehicle; A video server for compressing image data photographed by the camera and storing the image data in a digital format; And And a wireless transmitting / receiving module for transmitting the stored image data to the WLAN base station while communicating in a wireless LAN form using the plurality of WLAN base stations and the Inter Access Point Protocol (IAPP) and the Real-Time Transfer Protocol (RTP). In-vehicle monitoring system using the 802.11A / G wireless LAN standard. delete The method of claim 4, wherein Each of the wireless transceiver module and a plurality of WLAN base stations, antenna; A signal detecting unit detecting and selecting a signal when overlapping signals according to WLAN communication; Roaming unit for selecting and switching (roaming) one wireless LAN base station maintaining a signal strength of more than a reference value to maintain a continuous wireless section; And In-vehicle monitoring system using the 802.11A / G wireless LAN standard characterized in that it comprises an RF unit for controlling roaming.

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