JP3147646U - Surveillance image sending device - Google Patents

Abstract

In a monitoring image transmission apparatus having a function of acquiring and outputting an image of a monitoring area, troublesome installation, wiring, setting, and the like are eliminated.
A monitoring image sending apparatus 1 includes a control unit 11, a microphone unit 12, a speaker unit 13, a sensor unit 14, a camera unit 15, a storage unit 16, and an image / sound compression unit each connected to the control unit 11. / Extension unit 17 and communication I / F unit 18. Moreover, the power supply part 19 which supplies electric power to each part is provided. Each part is provided in a single housing.
[Selection] Figure 1

Description

  The present invention relates to a monitoring image sending apparatus having a function of acquiring and outputting an image of a monitoring area.

  A security system that monitors abnormalities (intrusion, fire, gas leaks, etc.) in monitoring areas such as homes and offices and reports when an abnormality occurs. A sensor is placed in the monitoring area and a reporting device based on the detection signal from the sensor It is configured to notify the remote monitoring device of the security company using a dedicated line or a telephone line. Also, in such a security system, there is also known an image monitoring system in which a camera is installed in a monitoring area to transmit image data when an abnormality occurs and image data before and after that to a remote monitoring device (Patent Document 1). reference).

  FIG. 5 is a block diagram of a monitoring image transmission system which is an apparatus installed in a monitoring area in such an image monitoring system. The monitoring image transmission system includes an image processing / transmission device 101, a microphone 102, a speaker 103, a sensor 104, a camera 105, and a notification device 106, each connected to the image processing / transmission device 101.

  The image processing / transmission apparatus 101 includes a control unit 111 having a CPU, ROM, and RAM (not shown), an image / audio compression / decompression unit 112, a storage unit 113, and a communication I / F (interface) unit 114. ing.

  The microphone 102, the speaker 103, the sensor 104, the camera 105, and an input / output unit (not shown) in the image processing / transmission apparatus 101 are connected by cables 121 to 124. Here, the cables 121 and 122 are signal transmission lines and power supply lines from the image processing / transmission apparatus 101 to the microphone 102 and the speaker 103, and the cables 123 and 124 are signal transmission lines. The communication I / F unit 114 and the notification device 106 are connected by a communication cable 107 such as an RS485 cable. The notification device 106 is connected to a communication network 108 such as a telephone line. The image processing / transmission apparatus 101, the sensor 104, and the camera 105 are configured to be supplied with power from the commercial AC power supply 109 via the power supply line 110.

  In the monitoring image transmission system having the above configuration, the camera 105 captures a monitoring area and transmits the image data to the image processing / transmission apparatus 101. In the image processing / transmission apparatus 101, the input image data is compressed at a predetermined compression rate by the image / sound compression / decompression unit 112 and then stored in the storage unit 113. At this time, image data to be compressed and stored is, for example, one frame per second. Similarly, the microphone 102 detects sound in the monitoring area and sends the detection signal (audio data) to the image processing / transmission apparatus 101. In the image processing / transmission apparatus 101, the input audio data is compressed by the image / audio compression / decompression unit 112 and then stored in the storage unit 113.

  When the sensor 104 detects an abnormality and sends a detection signal to the image processing / transmission device 101, the image processing / transmission device 101 outputs an alarm sound from the speaker 103 and also notifies the notification device via the communication I / F unit 114. 106 is operated to call a remote monitoring device of a security company connected to the network 108, and the image data and audio data stored in the storage unit 113 are read and transmitted.

  FIG. 6 is a diagram illustrating an example of the timing of image data stored in the storage unit 113 and image data transmitted to the remote monitoring device. In this figure, the pre-alarm, on-alarm, and post-alarm are respectively before the occurrence of an abnormality, at the time of occurrence of the abnormality, and after the occurrence of the abnormality. “Details” means that the image data has a predetermined compression rate as described above. The image data storage procedure in this figure is always performed as described above. As for the image data transmission pattern, detailed image data is transmitted when an abnormality occurs and before and after the occurrence of the abnormality.

  However, this monitoring image transmission system requires installation, wiring, and setting of the image processing / transmission apparatus 101, the microphone 102, the speaker 103, the sensor 104, and the camera 105. However, there is a problem that it takes time and effort.

In addition, since image data of a certain quality (compression rate) is transmitted regardless of the speed of the communication infrastructure (communication network 108), when a low-speed (11.4 kbps) communication infrastructure such as an analog line is used. Has a problem that it takes time to transmit image data for one sheet (in the case of a 15 KB image, the average is 10 seconds or more).
Japanese Patent Laid-Open No. 11-234655

  The present invention has been made to solve such problems, and a first object of the present invention is to install, wire, and set a monitoring image transmission apparatus having a function of acquiring and outputting an image of a monitoring area. The second purpose is to make it possible to shorten the image transmission time when using a low-speed communication infrastructure.

The present invention includes a camera unit that captures a monitoring region, a sensor unit that detects abnormality in the monitoring region, an image storage unit that stores image data from the camera unit, an image output unit that outputs image data, and each of the units described above. A monitoring image sending apparatus characterized in that a power supply unit for supplying electric power to is built in a single casing.
Here, means for changing the quality (for example, compression rate) of the image data output from the image output unit may be provided in accordance with the communication speed of the communication network to which the image data is output.

  According to the present invention, troublesome installation, wiring, setting, and the like can be eliminated in a monitoring image sending apparatus having a function of acquiring and outputting an image of a monitoring area. Further, by providing means for changing the quality of the image data output from the image output unit according to the communication speed of the communication network to which the image data is output, the image transmission time when using a low-speed communication network is shortened. be able to.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram of a monitoring image transmission apparatus according to an embodiment of the present invention. The monitoring image sending device 1 includes a control unit 11 that includes a CPU 11a, a ROM 11b, and a RAM 11c, and a microphone unit 12, a speaker unit 13, a sensor unit 14, a camera unit 15, and a storage unit 16 that are connected to the control unit 11, respectively. An image / sound compression / decompression unit 17 and a communication I / F unit 18. Moreover, the power supply part 19 which supplies electric power to each part is provided. These parts are provided in a single casing.

  The communication I / F unit 18 is connected to the notification device 2 by the communication cable 3. The power supply unit 19 and the reporting device 2 are configured such that power from the commercial AC power supply 5 is supplied via the power supply line 6. The notification device 2 may be built in the monitoring image transmission device 1.

  The image monitoring apparatus 1 is installed in a predetermined monitoring area. The microphone unit 12 detects sound in the monitoring area and sends a detection signal (audio data) to the control unit 11. The speaker unit 13 outputs an alarm sound or the like based on the control of the control unit 11. The sensor unit 14 detects an abnormality in the monitoring area and sends a detection signal to the control unit 11. The camera unit 15 captures the monitoring area, generates image data, and sends the image data to the control unit 11.

  The image / audio compression / decompression unit 17 has a function of compressing image data at a predetermined compression rate, a function of expanding compressed image data, and a function of compressing audio data at a predetermined compression rate. Has a function to expand audio data. Here, the compression rate of each of the image data and the audio data is variable, and an arbitrary compression rate can be selected from a plurality of different compression rates by the user's selection.

  The storage unit 16 includes a storage device such as a hard disk and a storage medium such as a memory, and stores image data and audio data. Here, a first image storage area 16a in which image data with a relatively low compression rate (high quality) is stored, and a second image in which image data with a relatively high compression rate (low quality) are stored. The storage area 16b is illustrated.

  Based on the control of the control unit 11, the communication I / F unit 18 instructs the reporting device 2 to connect to a remote monitoring device of a security company (not shown) via the network 4 such as an analog line or an INS line. Then, the image data is output. The communication I / F unit 18 can also be directly connected to the remote monitoring device via the network 7 such as an IP network without using the notification device 2. The power supply unit 19 supplies power to each unit based on AC power supplied from the commercial AC power supply 5.

  Next, the operation of the image monitoring apparatus 1 of this embodiment will be described. The following operation control is performed by the CPU 11a executing a program stored in the ROM 11b in the control unit 11.

  The camera unit 15 captures the monitoring area and sends the image data to the control unit 11. In the control unit 11, the image data from the camera unit 15 is compressed at a predetermined compression rate (details will be described later) by the image / sound compression / decompression unit 17 and then stored in the storage unit 16. At this time, image data to be compressed and stored is, for example, one frame per second. The microphone unit 12 detects the sound in the monitoring area and sends a detection signal (audio data) to the control unit 11. In the control unit 11, the audio data from the microphone unit 12 is compressed by the image / audio compression / decompression unit 17 and then stored in the storage unit 16.

  When the sensor unit 14 detects an abnormality and sends a detection signal to the control unit 11, the control unit 11 outputs an alarm sound from the speaker unit 13 and operates the notification device 2 via the communication I / F unit 18. Then, the remote monitoring device of the security company connected to the network 4 is called, and the image data and audio data stored in the storage unit 16 are read and transmitted.

FIG. 2 is a diagram illustrating an example of a flow of storing and transmitting image data.
First, setting for saving a detailed image is performed (step S1). When image data for one screen is acquired (step S2 → S3: Yes), the image / sound compression / decompression unit 17 converts the image data into a detailed image. And then stored in the first image storage area 16a (step S4).

  Next, a setting for saving a coarse image is made (step S5). When image data for one screen is acquired (step S6 → S7: Yes), the image / sound compression / decompression unit 17 coarsens the image data. After compression at a relatively low compression rate corresponding to the image, the image is stored in the second image storage area 16b (step S4). After waiting for a certain time, the process is repeated from step S1. Accordingly, detailed image data and coarse image data are alternately stored in the first image storage area 16a.

  FIG. 3 is a diagram illustrating an example of the timing of the image data stored in the storage unit 16 and the image data transmitted to the remote monitoring device. Here, FIG. 3A shows image data stored in the storage unit 16 by executing the flow of FIG. On the other hand, three patterns shown in FIGS. 3B to 3D can be selected for image data to be transmitted to the remote monitoring device.

  That is, when a high-speed infrastructure is used, detailed image data is transmitted for each of the pre-alarm, on-alarm, and post-alarm as shown in FIGS. When using a low-speed infrastructure, as shown in FIGS. 2 and 3C, coarse image data is transmitted for each of the pre-alarm, on-alarm, and post-alarm. Further, when a high-speed infrastructure is used, as shown in FIG. 3D, detailed image data may be transmitted only for the on alarm and immediately before and after that. Although not shown, even when using a low-speed infrastructure, detailed image data may be transmitted only for the on-alarm. Furthermore, when using a low-speed infrastructure, the image may be transmitted in the pattern shown in FIG. 3C, and detailed image data may be transmitted later.

  FIG. 4 is a diagram showing another example of the flow of image data storage and transmission operations. In the flow of FIG. 2, the compressed image data is stored in the storage unit 16. However, in the flow of this diagram, uncompressed image data is stored and compressed when transmitted, which is different from FIG. 2.

  When image data for one screen is acquired (step S11 → S12: Yes), the image data is stored in a predetermined storage area of the storage unit 16 (step S13). After waiting for a certain time, the process is repeated from step S11. Therefore, only uncompressed image data is stored in the storage unit 16.

  When transmitting image data to a remote monitoring device, when using a high-speed infrastructure, the image data read from the storage unit 16 is compressed by the image / audio compression / decompression unit 17 at a relatively low compression rate ( Step S15) and transmitting. This transmission pattern is the same pattern as in FIG. 3B. On the other hand, when using a low-speed infrastructure, the image data read from the storage unit 16 is compressed by the image / audio compression / decompression unit 17 at a relatively high compression rate (step S16), and then transmitted. This transmission pattern is the same pattern as in FIG. 3C.

  As described above, according to the monitoring image transmission apparatus of the present embodiment, since each unit is provided in a single housing, the microphone, the speaker, the sensor, and the camera are individually provided as in the conventional monitoring image transmission system. Installation work and wiring work are not required. Therefore, troublesomeness such as installation, wiring, and setting is eliminated. In addition, cost reduction can be realized by wire saving, resource saving, and labor saving.

  In addition, since it has a function to select and transmit image data of quality according to the speed of the communication infrastructure to be used, when using a high-speed infrastructure, it transmits detailed image data in a short time, When used, although the image quality is inferior, image data can be transmitted in a shorter time than the conventional system. Accordingly, even when the low-speed infrastructure is used, the remote monitoring device can quickly check the state of the monitoring area.

1 is a block diagram of a monitoring image transmission device according to an embodiment of the present invention. It is an example of the flow of the preservation | save and transmission operation | movement of the image data in the monitoring image transmission apparatus of embodiment of this invention. It is a figure which shows an example of the timing of the image data preserve | saved at a memory | storage part, and the image data transmitted to a remote monitoring apparatus in the monitoring image transmission apparatus of embodiment of this invention. It is another example of the flow of the preservation | save and transmission operation | movement of the image data in the monitoring image transmission apparatus of embodiment of this invention. It is a block diagram of the conventional monitoring image transmission system. In the conventional monitoring image transmission system, it is a figure which shows an example of the timing of the image data preserve | saved at a memory | storage part, and the image data transmitted to a remote monitoring apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Surveillance image transmission apparatus, 11 ... Control part, 14 ... Sensor part, 15 ... Camera part, 16 ... Memory | storage part, 17 ... Image and sound compression / decompression part, 18 ... Communication I / F part.

Claims (3)

  A camera unit that captures an image of the monitoring area, a sensor unit that detects an abnormality in the monitoring area, an image storage unit that stores image data from the camera unit, an image output unit that outputs image data, and power to each of the units And a power supply unit that is built in a single housing.   A monitoring image transmission apparatus comprising means for changing the quality of image data output from an image output unit in accordance with a communication speed of a communication network to which image data is output. The monitoring image transmission device according to claim 2,
A monitoring image sending device, wherein the quality of image data is a compression rate of image data.

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