KR102282454B1 - Surveillance system - Google Patents

Abstract

A monitoring system in which a network camera communicates with a client device through a gateway is disclosed. As the gateway periodically transmits a beacon signal to the network camera according to the first cycle, the network camera determines whether an event occurs whenever it receives a beacon signal. The gateway periodically transmits a beacon signal to the network camera by a second period longer than the first period while the image data from the network camera is received.

Description

Surveillance system

The present invention relates to a monitoring system, and more particularly, to a monitoring system in which a network camera communicates with a client device through a gateway.

In a general surveillance system, a network camera communicates with a client device through a gateway. When an event occurs, the network camera captures and compresses an image, and transmits a still image or moving image of the compression result to the client device. Since most wireless network cameras use battery power, it is important to reduce power consumption to prolong battery life.

In a network camera, the higher the compression rate of the image to be transmitted, the shorter the total transmission time of the image data, the longer the battery life, but the worse the image quality. The lower the compression rate of the image to be transmitted, the longer the total transmission time of the image data, the shorter the battery life, but the better the image quality.

The problem of the background art is the content that the inventor possessed for the derivation of the present invention or acquired during the derivation of the present invention, and it cannot be said that the content is known to the general public before the filing of the present invention.

Japanese Laid-Open Patent Publication No. 2013-179689 (Applicant: NEC Co., Ltd., title of invention: video encoding apparatus, video decoding apparatus, video encoding method, video decoding method and program)

An embodiment of the present invention is to provide a monitoring system that allows the network camera to reduce the total transmission time of image data without relatively increasing the image compression rate, and thus the battery life of the network camera can be relatively extended. do.

In the monitoring system of one aspect of the present invention, a network camera communicates with a client device through a gateway.

As the gateway periodically transmits a beacon signal to the network camera according to a first cycle, the network camera determines whether an event has occurred whenever it receives the beacon signal.

The gateway periodically transmits the beacon signal to the network camera by a second period longer than the first period while the image data from the network camera is being received.

Preferably, the first period in the network camera includes a beacon standby period and an inactivity period. In addition, the phase of the first period in the network camera is ahead of the phase of the first period in the gateway by the beacon waiting period.

Preferably, the second period in the network camera includes a beacon waiting period and an image transmission period. In addition, the phase of the second period in the network camera is ahead of the phase of the second period in the gateway by the beacon waiting period.

Preferably, the beacon waiting period in the first period has a length of time equal to the beacon waiting period in the second period.

Preferably, when it is determined that an event has occurred, the network camera transmits an event generation signal to the gateway and then transmits image data to the gateway.

Preferably, the gateway periodically transmits the beacon signal to the network camera according to the second period from the time of reception of the event occurrence signal to the end of reception of the image data.

According to the monitoring system of the embodiment of the present invention, the gateway periodically sends the beacon signal to the network camera by a second period longer than the first period while the video data from the network camera is being received. send.

That is, the network camera periodically receives the beacon signal according to the relatively long second period while transmitting the image data to the gateway. Here, the second period in the network camera includes a beacon waiting period and an image transmission period.

Accordingly, the network camera may periodically transmit image data to the gateway by applying a relatively long image transmission period. That is, since a relatively large amount of image data may be transmitted for a predetermined time, the total transmission time of the image data may be relatively short.

Accordingly, according to the monitoring system of the present embodiment, the network camera can reduce the total transmission time of image data without relatively increasing the image compression rate, and thus the battery life of the network camera can be relatively extended.

1 is a diagram showing a monitoring system according to an embodiment of the present invention.
FIG. 2 is a diagram for explaining a communication process between the network camera of FIG. 1 and a gateway.
3 is a timing diagram illustrating a communication process between a network camera and a gateway in a period in which no event occurs.
4 is a timing diagram illustrating a communication process between a network camera and a gateway when an event occurs.
FIG. 5 is a diagram showing in detail the structure of image data in step S206 of FIG. 2 .

The following description and accompanying drawings are for understanding the operation according to the present invention, and parts that can be easily implemented by those skilled in the art may be omitted.

In addition, the specification and drawings are not provided for the purpose of limiting the present invention, and the scope of the present invention should be defined by the claims. The terms used in this specification should be interpreted with meanings and concepts consistent with the technical idea of the present invention so that the present invention can be most appropriately expressed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a monitoring system of an embodiment of the present invention.

Referring to FIG. 1 , a network camera 101 communicates with a client device 103 through a gateway 102 . When an event occurs, the network camera 101 captures and compresses an image, and transmits a still image or moving image of the compression result to the client device 103 . Since most wireless network cameras use battery power, it is important to reduce power consumption to prolong battery life.

As the gateway 102 periodically transmits a beacon signal to the network camera 101 according to the first cycle, the network camera 101 determines whether an event occurs every time it receives a beacon signal. .

The gateway 102 periodically transmits a beacon signal to the network camera 101 with a second period longer than the first period while the image data from the network camera 101 is being received.

FIG. 2 is a diagram for explaining a communication process between the network camera 101 and the gateway 102 of FIG. 1 . This will be described with reference to FIG. 2 as follows.

The network camera 101 waits for a beacon signal during a beacon waiting period of a predetermined time (step S201).

At the end of the beacon waiting period, the gateway 102 transmits the beacon signal of the first period to the network camera 101 (step S202).

The network camera 101 that has received the beacon signal determines whether an event has occurred (step S203).

If it is determined that no event has occurred, the network camera 101 performs a sleep mode to reduce power consumption during an inactivity period of a predetermined time (step S204). Power consumption of the network camera 101 may be reduced by such a sleep mode. When the dormant period ends, the step S201 and the subsequent step S203 are performed again.

If it is determined that the event has occurred, steps S205 to S209 are performed.

In step S205, the network camera 101 transmits an event occurrence signal to the gateway 102 (step S205). Next, the network camera 101 transmits the image data to the gateway 102 during a certain image transmission period (step S206).

Next, the network camera 101 waits for a beacon signal during a beacon waiting period of a predetermined time (step S207).

At the end of the beacon standby period, the gateway 102 transmits a beacon signal of a second period longer than the first period to the network camera 101 (step S208).

Next, the network camera 101 determines whether or not all of the video data has been transmitted (step S209). Here, steps S206 and S207 are repeatedly performed until all of the image data is transmitted. When all the image data has been transmitted, the network camera 101 performs the above step S204 and subsequent steps again.

The communication process of FIG. 2 will be described in more detail with reference to FIGS. 3 and 4 .

FIG. 3 shows a communication process between the network camera ( 101 in FIG. 2 ) and the gateway ( 102 in FIG. 2 ) in a period in which no event occurs. Here, the period in which the event does not occur is the period in which steps S201 to S204 of FIG. 2 are performed.

In FIG. 3, reference numeral Mgw denotes an operation timing diagram of the gateway 102, Mca denotes an operation timing diagram of the network camera 101, T1 denotes the first period, T1b denotes a beacon standby period, and T1s. denotes an inactivity cycle, respectively.

In this embodiment, the first period T1 is 250 milliseconds (ms), the beacon waiting period T1b is 5 milliseconds (ms), and the sleep period T1s is 245 milliseconds (ms). .

The timing diagram of FIG. 3 will be described with reference to FIGS. 2 and 3 as follows.

The first period T1 in the network camera 101 includes a beacon standby period T1b and an inactivity period T1s. The phase of the first period T1 in the network camera 101 is ahead of the phase of the first period T1 in the gateway 102 by the beacon waiting period T1b. For example, the start time t1 of the first period T1 in the network camera 101 is ahead of the start time t2 of the first period T1 in the gateway 102 by the beacon waiting period T1b.

In the beacon waiting period T1b of time t1 to t2, the network camera 101 waits for a beacon signal (step S201).

When the beacon signal from the gateway 102 is received at time t2 (step S202), the network camera 101 determines whether an event has occurred (step S203).

If it is determined that the event has not occurred at time t2, the network camera 101 performs a sleep mode to reduce power consumption during an inactivity period of time t2 to time t3 (step S204). Power consumption of the network camera 101 may be reduced by such a sleep mode.

The first period T1 of t1 to t3 as described above is repeatedly applied until an event occurs even at a time thereafter.

4 shows a communication process between the network camera 101 and the gateway 102 when an event occurs. Here, the communication process when an event occurs corresponds to steps S205 to S209 of FIG. 2 . In FIG. 4 , reference numeral T2 denotes the second period, T2b denotes a beacon standby period, and T2t denotes an image transmission period, respectively. In FIG. 4, the same reference numerals as those of FIG. 3 indicate objects having the same function.

In the present embodiment, the second period T2 is 400 milliseconds (ms), the beacon waiting period T1b is 5 milliseconds (ms), and the sleep period T1s is 395 milliseconds (ms). .

The timing diagram of FIG. 4 will be described with reference to FIGS. 2 and 4 as follows.

The second period T2 in the network camera 101 includes a beacon waiting period T2b and an image transmission period T2t. The phase of the second period T2 in the network camera 101 is ahead of the phase of the second period T2 in the gateway 102 by the beacon waiting period T1b. For example, the start time t11 of the second period T2 in the network camera 101 is earlier than the start time t12 of the second period T2 in the gateway 102 by the beacon waiting periods T1b and T2b. there is. Here, the beacon standby period T1b in the first period T1 has the same length as the beacon standby period T2b in the second period T2.

In the beacon waiting period T1b of time t9 to t10, the network camera 101 waits for a beacon signal (step S201).

When the beacon signal from the gateway 102 is received at time t10 (step S202), the network camera 101 determines whether an event has occurred (step S203).

If it is determined that no event has occurred at time t10, the network camera 101 performs a sleep mode to reduce power consumption during an inactivity period of time t10 to time t11 (step S204). Power consumption of the network camera 101 may be reduced by such a sleep mode.

Repeatedly, in the beacon waiting period T1b of time t11 to t12, the network camera 101 waits for a beacon signal (step S201).

When the beacon signal from the gateway 102 is received at time t12 (step S202), the network camera 101 determines whether an event has occurred (step S203).

If it is determined that an event has occurred at time t12, the network camera 101 transmits an event generation signal to the gateway 102 (step S205). Next, the network camera 101 transmits the image data to the gateway 102 during the image transmission period T2t of t12 to t13 (step S206).

The second period T2 of t11 to t13 as described above is repeatedly applied until all the image data is transmitted even after that time.

In summary, while the video data from the network camera 101 is being received, the gateway 102 transmits a beacon signal to the network camera 101 by a second period T2 longer than the first period T1. sent periodically to

That is, the network camera 101 periodically receives a beacon signal with a relatively long second period T2 while transmitting the image data to the gateway 102 . Here, the second period T2 in the network camera 101 includes a beacon waiting period T2b and an image transmission period T2t.

Accordingly, the network camera 101 may periodically transmit image data to the gateway 102 by applying a relatively long image transmission period T2t. That is, since a relatively large amount of image data may be transmitted for a predetermined time, the total transmission time of the image data may be relatively short.

For example, if the first period T1 is 250 milli-seconds (ms), the number of the first period in 100 seconds is 100/0.25. When the beacon waiting period (T1b, T2b) is 5 milliseconds (ms), the total beacon-waiting time (second) Tb ₁₀₀ for 100 seconds is calculated by Equation 1 below.

Accordingly, when only the first period T1 is applied as in the prior art, the total image-transmission time Tt ₁₀₀ for 100 seconds is calculated by Equation 2 below.

That is, when only the first period T1 is applied as in the prior art, the total image-transmission time Tt ₁₀₀ for 100 seconds is 98 seconds.

In contrast, when the second period T2 of 400 milliseconds (ms) is applied while the image is transmitted, the number of the second period in 100 seconds is 100/0.4. Since the beacon waiting period (T1b, T2b) is 5 milliseconds (ms), the total beacon-waiting time (second) Tb ₁₀₀ for 100 seconds is calculated by Equation 3 below.

Therefore, when the second period T2 of 400 milliseconds (ms) is applied according to the embodiment of the present invention while the image is being transmitted, the effective image-transmission time Tt ₁₀₀ for 100 seconds is the following Equation 4 is calculated by

That is, when the second period T2 of 400 milliseconds (ms) is applied while the image is being transmitted, the effective image-transmission time Tt ₁₀₀ for 100 seconds is 98.75 seconds.

Accordingly, according to the embodiment of the present invention, the effective video-transmission time Tt ₁₀₀ for 100 seconds is increased by 0.75 seconds compared to the prior art. That is, when the transmission rate of the network camera 101 is 1024 Kbps (Killo bits per second), the total amount of image-transmission in 100 seconds is increased by 0.75 X 1024 (= 768) Kbps compared to the prior art.

Therefore, according to the monitoring system of the present embodiment, the network camera 101 can reduce the total transmission time of image data without relatively increasing the image compression rate, and thus the battery life of the network camera 101 is relatively extended. can be

FIG. 5 shows the structure of the image data in step S206 of FIG. 2 in detail. This will be described with reference to FIG. 5 as follows.

In the case of this embodiment, the image data in step S206 includes at least one multi-data packet (MDP). The multi-data packet MDP includes a series of 23 data packets DP1 to DP23. As such a multi-data packet (MDP) is transmitted to the gateway 102 , an acknowledgment procedure from the gateway 102 may be greatly reduced. Therefore, the total transmission time of image data may be further reduced.

Each data packet DP1 to DP23 of 42 bytes includes a communication pocket 501 of 10 bytes and a payload 502 of 32 bytes.

The payload 502 is a part of still image data compressed by the network camera 101 .

The communication pocket 501 includes a preamble of 1 byte, an address of 5 bytes, length information 403 of 1 byte, a head of 1 byte, and a cyclic redundancy checking (CRC) code.

The gateway 102 can know the length of the data packets DP1 to DP23 based on the length information 503 in the communication pocket.

A head of 1 byte has a data-packet identification number (IDpack) of 5 bits, an even-odd information ID (IDevod) of 1 bit, a data presence-information ID (IDtran) of 1 bit, and 1 bit of Contains the response request ID (IDreac). The data-packet identification number IDpack means a serial number of each data-packet DP1 to DP23. The even-odd information ID (IDevod) is information for transaction processing. The data presence-information ID (IDtran) indicates whether actual data exists in a payload of 32 bytes. The response request ID IDreac indicates whether the gateway (102 in FIG. 2) should respond.

As described above, according to the monitoring system of the present embodiment, the gateway periodically transmits a beacon signal to the network camera by a second period longer than the first period while the video data from the network camera is received. do.

That is, the network camera periodically receives a beacon signal with a relatively long second period while transmitting image data to the gateway. Here, the second period in the network camera includes a beacon standby period and an image transmission period.

Accordingly, the network camera may periodically transmit image data to the gateway by applying a relatively long image transmission period. That is, since a relatively large amount of image data may be transmitted for a predetermined time, the total transmission time of the image data may be relatively short.

Therefore, according to the monitoring system of the present embodiment, the network camera can reduce the total transmission time of image data without relatively increasing the image compression rate, and thus the battery life of the network camera can be relatively extended.

So far, the present invention has been focused on preferred embodiments. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention can be implemented in modified forms without departing from the essential characteristics of the present invention.

Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the above description, and it should be construed that the invention claimed by the claims and inventions equivalent to the claimed invention are included in the present invention.

It is highly likely to be used not only in surveillance systems but also in general video transmission fields.

101: network camera, 102: gateway,
103: client device;
Mgw: operation timing diagram of the gateway,
Mca: operation timing diagram of network camera,
T1: first cycle, T2: second cycle,
T1b, T2b: beacon standby cycle, T1s: inactivity cycle,
T2t: Video transmission period.

Claims (6)

delete A monitoring system in which a network camera communicates with a client device through a gateway,
As the gateway periodically transmits a beacon signal to the network camera according to a first cycle, the network camera determines whether an event occurs every time it receives the beacon signal,
The gateway periodically transmits the beacon signal to the network camera by a second period longer than the first period while the image data from the network camera is received,
The first period in the network camera includes a beacon standby period and an inactivity period,
and the phase of the first period in the network camera is ahead of the phase of the first period in the gateway by the beacon waiting period. 3. The method of claim 2,
The second period in the network camera includes a beacon waiting period and an image transmission period,
and the phase of the second period in the network camera is ahead of the phase of the second period in the gateway by the beacon waiting period. 4. The monitoring system of claim 3, wherein the beacon waiting period in the first period has a length of time equal to the beacon waiting period in the second period. A monitoring system in which a network camera communicates with a client device through a gateway,
As the gateway periodically transmits a beacon signal to the network camera according to a first cycle, the network camera determines whether an event occurs every time it receives the beacon signal,
The gateway periodically transmits the beacon signal to the network camera by a second period longer than the first period while the image data from the network camera is received,
The network camera is
When it is determined that an event has occurred, the video data is transmitted to the gateway after transmitting an event occurrence signal to the gateway. A monitoring system in which a network camera communicates with a client device through a gateway,
As the gateway periodically transmits a beacon signal to the network camera according to a first cycle, the network camera determines whether an event occurs every time it receives the beacon signal,
The gateway periodically transmits the beacon signal to the network camera by a second period longer than the first period while the image data from the network camera is received,
The gateway is
A monitoring system for periodically transmitting the beacon signal to the network camera according to the second period from the time of reception of the event occurrence signal to the end of reception of the image data.

Images