WO2015137758A1

WO2015137758A1 - Sensor node and method for transmitting data of sensor node, sink node and method for transmitting data of sink node

Info

Publication number: WO2015137758A1
Application number: PCT/KR2015/002434
Authority: WO
Inventors: 박형곤; 권민혜; 권정민
Original assignee: 이화여자대학교 산학협력단
Priority date: 2014-03-14
Filing date: 2015-03-13
Publication date: 2015-09-17
Also published as: KR20150107517A; KR101565685B1

Abstract

The present invention relates to a method for transmitting data and a sensor network for performing the method and, more particularly, may comprise a sink node for collecting data from a sensor node located within a range of transmission limitation and decoding the collected data to transmit the data to a gateway; and a sensor node for collecting data at a geographically moved position and transmitting, to the sink node, the collected data in consideration of the range of transmission limitation.

Description

Data transmission method of sensor node and sensor node, Data transmission method of sink node and sink node

The following description relates to a method of transmitting data between a sensor node and a sensor node, and a method of transmitting data between a sink node and a sink node. More specifically, data transmission is performed between a sensor node and a sink node using a transmission range in a sensor network. It is about a method.

The sensor network transfers data between highly mobile sensor nodes and sink nodes. In detail, the sensor node collects data at the moved location while moving geographically. In addition, the sink node receives data from highly mobile sensors located at a wide radius within a predetermined transmission range.

In this case, the sensors require a lot of power as the data is continuously transmitted to the sink node without any limitation. In addition, the power is multiplied squared in proportion to the distance from the sink node. As a result, typical sensor nodes using batteries generate battery consumption due to continuous data transmission.

Therefore, there is a need for a method capable of transmitting data to a sink node while minimizing power consumption and battery consumption by sensor node communication.

By limiting the transmission limit range for acquiring data from the sensor, it is possible to minimize the power consumed for wireless transmission as the highly mobile sensor moves away from the sink node. A data transmission method of a sink node may be provided.

Sensor node and sensor that can acquire and transmit information about collected data more efficiently based on limited transmission limit range by enabling the restoration of all data collected from sensor using the principle of compression sensing technique. A data transmission method of a node, a sink node, and a data transmission method of a sink node may be provided.

According to an embodiment, a data transmission method performed by a sink node may include receiving data from sensor nodes positioned within a transmission limit range; And decoding the received data and transmitting the received data to the gateway.

According to an embodiment, the transmitting may decode data received from a plurality of sensor nodes positioned within the transmission limit range based on a unit time.

The transmitting may include decoding the received data including temporary data of a plurality of sensor nodes located outside the transmission limit range at the unit time.

According to an embodiment, the transmitting may decode the collected data by using a compression sensing technique capable of approximate restoration of the data.

According to an embodiment, the sensor node may collect data within a predetermined radius of the sink node, and transmit the collected data to the sink node when the sensor node is located within the transmission limit range based on a unit time.

According to an embodiment, the transmission limit range may be set in consideration of the time at which the sensor node collects data and a distance between the sink node and the sensor node within a predetermined radius of the sink node.

According to an embodiment, a data transmission method performed by a sensor node may include collecting data within a predetermined radius of a sink node; And transmitting the collected data to the sink node in consideration of the transmission limit range.

In the collecting step according to an embodiment, the data may be collected at a point located within a predetermined radius of the sink node for a predetermined time based on the time when the sensor node is operated.

The transmitting may include transmitting the collected data to a sink node when the data is located within the transmission limit range based on a unit time in which data can be transmitted, and the transmission limit range is a predetermined radius of the sink node. It may be set in consideration of the power according to the time the sensor node collects data and the distance between the sink node and the sensor node within.

According to an embodiment, the sink node receives data from sensor nodes located within the transmission limit range, and decodes the collected data and transmits the data to a gateway by using a compression sensing technique capable of approximate restoration of the data. Can be.

In an embodiment, the sink node may include a data receiver configured to receive data from sensor nodes located within a transmission limit range; It may include a data decoding unit for decoding the received data transmitted to the gateway.

The data decoder according to an embodiment may decode data received from a plurality of sensor nodes located within the transmission limit range based on a unit time.

The data decoder according to an embodiment may decode the received data including temporary data of a plurality of sensor nodes located outside the transmission limit range at the unit time.

The data decoder according to an embodiment may decode the collected data by using a compression sensing technique capable of approximate restoration of data.

The transmission limit range according to an embodiment may be set in consideration of the transmission time according to the time at which the sensor node collects data and the distance between the sink node and the sensor node within a predetermined radius of the sink node.

According to an embodiment, a sensor node may include a data collector configured to collect data within a predetermined radius of a sink node; It may include a data transmitter for transmitting the collected data to the sink node in consideration of the transmission limit range.

According to an embodiment, the data collector may collect data at a point located within a predetermined radius of the sink node for a predetermined time based on a time point when the sensor node is operated.

When the data transmission unit is located within the transmission limit range based on a unit time in which data can be transmitted, the data transmitter transmits the collected data to the sink node, and the transmission limit range is within a predetermined radius of the sink node. It may be set in consideration of the transmission power according to the time when the sensor node collects data and the distance between the sink node and the sensor node.

By limiting the transmission limit range for acquiring data from the sensor node, power consumption for wireless transmission can be minimized as the highly mobile sensor node moves away from the sink node.

By using the principle of compression sensing, it is possible to approximate recovery of all data collected from the sensor, so that information can be acquired and transmitted more efficiently about the collected data based on the transmission limit range.

1 is a diagram illustrating a structure of a sensor network according to an exemplary embodiment.

2 is a diagram illustrating a detailed configuration of a sensor node and a sink node according to an embodiment.

FIG. 3 is a diagram illustrating an operation sequence of a sensor node according to a flow of time, according to an exemplary embodiment.

4 is a diagram illustrating a task performing algorithm of a sensor node, according to an exemplary embodiment.

5 is a flowchart illustrating a work performed by a sensor node, according to an exemplary embodiment.

6 is a diagram illustrating a data decoding method according to an embodiment.

7 is a diagram illustrating a data transmission method according to an embodiment.

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

Referring to FIG. 1, a sensor network may include a high

mobility sensor node

102, 102 ′, a sink node 101, and a gateway 103. In addition, the sensor nodes 102 and 102 'may propose a structure that can more efficiently transfer data to the sink node 101 using the transmission limit range.

In detail, the

sensor nodes

102 and 102 ′ may collect data within a radius of the sink node 101. In addition, the

sensor nodes

102 and 102 ′ may perform a task based on a temporal flow. In other words, the sensor nodes 102 and 102 'may be divided into a data collection section, a time plot, a position movement, and a data transmission section based on a temporal flow.

The

sensor nodes

102 and 102 ′ may collect data at the current point within a predetermined radius of the sink node 101 in the data collection period. In addition, the

sensor nodes

102 and 102 ′ may move the current location geographically in the case of location movement and data transmission interval. The

sensor nodes

102 and 102 ′ may transmit data collected at the current location to the sink node 101. Here, the

sensor nodes

102 and 102 ′ may transmit data to the sink node based on whether they are located within a transmission limit range. Task execution according to the temporal flow of the sensor nodes 102 and 102 'will be described in detail with reference to FIG. 3.

Sink node 101 may receive data from sensor node 102 based on a transmission limit range. Here, the transmission limit range may mean a transmission range in which the sink node 101 may receive data from the sensor node 102. The transmission limit range is determined by the time at which the sensor nodes 102 and 102 'collect data within a certain radius of the sink node 101 and the distance between the sink node 101 and the sensor nodes 102 and 102'. In consideration of the power may be a limited range.

In one example, the transmission limit range may take into account the time for the sensor nodes 102 and 102 'to collect all L data within a certain radius of the sink node 101. In addition, the transmission limit range is a distance between the sink node 101 and the sensor nodes 102 and 102 'that can minimize battery consumption when the sensor nodes 102 and 102' transmit data. Can be taken into account. And, the transmission limit range may be set in consideration of time and power.

As sensor nodes 102 and 102 'move away from the sink node, power consumed for wireless transmission may increase. Herein, the amount of power of the sensor nodes 102 and 102 'may increase by the square of the transmission distance. Accordingly, the sink node 101 may set the transmission limit range to receive data from the sensor nodes 102 and 102 'more efficiently. That is, the sink node 101 may receive data of the sensor nodes 102 and 102 'existing within the transmission limit range, thereby minimizing the amount of battery and power of the sensor nodes 102 and 102'.

In one example, sink node 101 may collect data from sensor node 102 located within a transmission limit range. In addition, the sink node 101 may not collect data from the sensor node 102 'located outside the transmission limit range. However, if the sensor node 102 'is located within the transmission limit range as it moves, the sink node 101 may collect data from the sensor node 102'.

The sink node 101 may decode the data collected from the sensor node 102 and transmit it to the gateway 103. At this time, the sink node 101 may recover the collected data to the original data approximately by using the principle of the compression sensing technique.

As a result, the sink node 101 decrypts the data collected from the sensor node 102 located within the transmission limit range by using the principle of the compression sensing technique, so that the original data can be recovered by only the collected data.

Referring to FIG. 2, the sensor network may include a sensor node 201 and a sink node 204. The sensor node 201 may include a data collector 202 and a data transmitter 203. In addition, the sensor node 201 is highly mobile and may collect data while moving a position within a predetermined radius of the sink node for a predetermined time. The sensor node 201 may collect data within a certain radius of the node until collecting L data. The sensor node 201 may be a sensor that transmits the collected data to the sink node 204 based on the number of n transmissions.

The data collector 202 may collect data at a current point within a radius of the sink node. Here, the data collected by the sensor node 201 may include natural information existing within a predetermined radius of the sink node 204 at the current point. In addition, data including natural information may have a sparity characteristic through domain transformation.

For example, data collected for a predetermined time at the N-th sensor node may be represented by a data set, and the data set may be represented by Equation 1 below.

Here, the data set may be composed of L pieces of data. And,

May mean i-th data collected by the N-th sensor node. The data collected by the N th sensor node may include sparse characteristics through domain transformation.

In addition, the dataset is random

The data is k-sparse in the domain and can be assumed to be information promised with a decoder. Based on these assumptions, the dataset is

Can be expressed as

May be represented as in Equation 2.

May be an orthonormal transform unitary matrix. And,

Has k nonzero elements

May be a domain coefficient. (K <L)

The data transmitter 203 may collect all L data from the data collector 202 and then transmit the collected data to the sink node 201 based on a unit time. Here, the unit time may mean one session in which a plurality of sensor nodes can transmit data to the sink node 204.

The data transmitter 203 may determine whether a current point moved while moving a predetermined radius of the sink node 204 is located within a transmission limit range based on the unit time. The data transmitter 203 may transmit the collected data to the sink node 204 when the moved current point is located within a transmission limit range. The data transmitter 203 may transmit n times of data to the sink node based on the unit time. Here, since the data transmitter 203 transmits data to the sink node according to whether the data transmitter 203 is located within the transmission limit range, the data transmitter 203 may not transmit data to the sink node every time for a unit time. In addition, the data generator 203 may measure the number of transmissions according to the unit time even if the data is not transmitted to the sink node.

The sink node 204 may receive the data from the sensor node 201, decode the data, and transmit the received data to the gateway. The sink node 204 may include a data receiver 205 and a data decoder 206.

The data receiver 205 may receive data from the sensor node 201 located within the transmission limit range. In detail, the data receiver 205 may receive data collected while moving within a predetermined radius of the sink node 204. In this case, the data receiving unit 205 is a unit time in which the sensor node 201 can collect and transmit all L pieces of data, and can receive data from the sensor node 201 based on a condition located within a transmission limit range. have.

The transmission limit range may be a range that is set in consideration of the time when the sensor node collects data and the distance between the sink node and the sensor node within a predetermined radius of the sink node. This transmission limit range may be set when the condition as shown in Equation 3 is satisfied.

here,

to be.

Here, p means the ratio of the area of the transmission limit range, d may mean the cell size of the sink node 204.

And,

Is the distance between sensor node 201 and sink node 204

As far away as

This may mean tx power required to receive power.

In addition, the transmission limit range may satisfy a condition as shown in Equation 4 as a condition that there is a gain in terms of power related to the sensor node 201.

here,

Is the unit time transmitted by the sensor node 204 once, the unit time taken by the sensor node 204 to transmit m times is

Can be. Based on this, the limit transmission range may be represented by Equation 5.

That is, the limit transmission range may be inversely proportional to the square root of the unit time spent by the sensor node 201 transmitting the m data to the sink node 204. Therefore, the limit transmission range may be set in consideration of the delay sensitivity of the system or application of the sensor network.

In addition, the power gain of the limited transmission range can be expressed as Equation 6.

After all, the power gain of the marginal transmission range is

Proportional to,

Can be inversely proportional to The power gain of the limited transmission range may be set in consideration of Table 1 below.

The data decoder 206 may decode the data received from the sensor node 201 and transmit it to the gateway. The data decoder 206 may generate a result value by calculating data received from the sensor node 201 located within a transmission limit range. The result value may be a value generated to approximate the original data based on the received data. A method of decoding data will be described in detail with reference to FIG. 6.

Sensor nodes can perform tasks based on time flow. In detail, the sensor node may be configured of a data collection section, a position movement, and a data transmission section based on a temporal flow.

The data collection section may be a section for sensing data. In other words, the data collection section may be a section in which the sensor node operates for the purpose of acquiring data. Also, the data collection section may be a section in which the sensor node operates to acquire L pieces of data for L time on the basis of the point in time at which the sensor node starts to operate.

In addition, the sensor node may be allowed to move depending on the application for a narrow range of sensing. In addition, the sensor node may not transmit the collected data while collecting data by the data collection section. That is, the sensor node may collect data while moving in a narrow range during the data collection period.

The location movement and data transmission section may be a section in which the sensor node operates for the purpose of geographical movement and data transmission of the sensor node. In detail, in the case of the location movement and the data transmission interval, the sensor node may transmit the collected data to the sink node while moving the location for a unit time in which n data transmission occurs. In this case, the sensor node may transmit data to the sink node if it is located within the transmission limit range.

In addition, the sensor node may not perform a sensing process when the sensor node is moved in the position movement and data transmission period. In the case of the position movement and the data transmission section, the sensor node may perform only an operation of transmitting data by determining whether the sensor node is located within a range of position movement and transmission limitation.

When n data transmission occurs during the position movement and data transmission interval, the sensor node is switched to the data collection interval again, and this process may be repeatedly performed.

The work performed by the sensor node may be represented as shown in FIG. 4. That is, the sensor node may transmit data to the sink node when it is located within the transmission limit while repeatedly performing data collection and data transmission.

5 is a flowchart illustrating a work performed by a sensor node according to an exemplary embodiment.

Referring to FIG. 5, the sensor node may be divided into a data collection section, a position movement, and a data transmission section. The sensor node may operate the operation from step 501 to step 504 as a data collection interval. In addition, the sensor node may operate the movement of the position and the data transmission interval from operation 505 to operation 511.

In operation 501, the sensor node may designate a collection unit time t for collecting data as a time point for collecting data. Here, t denotes a collection unit time, and the initial value of t may be '0'. The sensor node may initialize the value of t to '1' based on a time point for collecting data.

In step 502 the sensor node may collect data present within a radius of the sink node. In this case, the sensor node may collect data at a 1: 1 ratio in response to the collection unit time.

In step 503, the sensor node may increase the collection unit time by '1'. At this time, t may have a value of '1' increased to a value initialized to the existing value of t. For example, t may have a value of '2', in which an increment value '1' is added to an existing value '1' through step 503.

In step 504, the sensor node may collect data until the collection unit time has the same value based on a condition that the value of the collection unit time is greater than the number L of data per session. That is, the sensor node may collect L data by collecting data during the collection unit time t.

When collecting L data, in step 505, the sensor node may set '1' of the variable i for measuring the number of times of transmitting data to the sink node.

In step 506 the sensor node may move its current position within a radius of the sink node. The sensor node is a highly mobile sensor, and may move a current position per session.

In step 507, the sensor node determines the geographic distance between the current location and the sink node.

) Can be measured.

In step 508, the sensor node may determine whether the geographical distance between the current location and the sink node is within a transmission limit range. That is, the sensor node may consider the geographical distance in order to minimize the power and battery consumption generated when transmitting data. In addition, the sensor node may determine whether the current location is within a transmission limit range.

If located within the transmission limit range (Yes 508), the sensor node may transmit the collected data to the sink node in step 509. As a result, after collecting data, the sensor node may consider power consumption generated by continuously transmitting data to the sink node without any limitation in a certain radius of the sink node. The sensor node may transmit data based on a transmission limit range instead of continuously transmitting data to the sink node without any limitation. Accordingly, the sensor node can minimize unnecessary power consumption and battery consumption.

If it is not within the transmission limit range (No in step 508), in step 510 the sensor node may increase the value of the variable i to measure the number of transmissions by '1'. In addition, the sensor node may transmit data to the sink node and increase the value of the variable i to measure the number of times of transmission by '1'.

In operation 511, the sensor node may compare the number of transmissions per session with the value of the variable i and transmit data while moving by the number of transmissions per session provided that the number of transmissions per session is less than or equal to the number of transmissions per session.

6 is a diagram illustrating a data decoding method according to an embodiment.

Referring to FIG. 6, the sink node may decode data collected from a sensor node located within a transmission limit range and transmit the decoded data to the gateway.

In detail, the sink node decodes the collected data and returns a result thereof.

Can be sent to the gateway. Herein, the result value may be expressed as in Equation 7.

here,

May be a set of data collected from each sensor node. In addition, data that is not transmitted because the sensor node is located outside the transmission limit range may be designated as an arbitrary value.

Sensing Matrix (

) May indicate whether each sensor node is included in the transmission limit range. In other words, the sensing matrix may indicate whether each sensor node is located within a transmission limit range based on one session. The sensing matrix can be expressed as Equation 8.

The sensing matrix may be displayed as '1' if the sensor node is located within the transmission limit range based on one session, and may be displayed as '0' if it is not located.

Specifically, the sensing matrix (

) May indicate whether the sensor node j is included in the transmission limit range at a unit time i as a row i column j element of the sensing matrix. here,

Is the geographical location between the sensor node and the sink node.

May mean a transmission limit range.

Sensing Matrix (

) May be independently determined as 0 or 1 according to a Bernoulli process in consideration of the characteristic of a highly mobile sensor that is independently randomly positioned. In addition, the sensing matrix may satisfy a Restricted Isometry Property (RIP).

The sink node may transmit the result value and the sensing matrix to the gateway.

The gateway may recover the original data by receiving the result value and the sensing matrix from the sink node. The gateway may approximately restore the original data through a process as shown in Equation (9).

In step 701 the sensor node 102 may collect data at the current point within a certain radius of the sink node. In this case, the sensor node 102 may collect data at a point where the location is geographically moved.

In step 702, if the sensor node 102 collects L data for a predetermined time, the sensor node 102 may transmit the collected data to the sink node 101 based on the unit time. In this case, the sensor node 102 may determine whether the current point exists within a transmission limit range. The sensor node 102 may determine the set transmission limit range in consideration of the power according to the time when the sensor node collects data and the distance between the sink node and the sensor node within a predetermined radius of the sink node. In addition, when the sensor node 102 exists within the transmission limit range, the sensor node 102 may transmit the collected data to the sink node 101.

In step 703, the sink node 101 may collect data from the sensor node 102 located within the transmission limit range based on one session. In other words, the sink node 101 may collect data for sensor nodes located within a transmission limit range per session. That is, the sink node 101 cannot collect data from sensor nodes located outside the transmission limit range.

In operation 704, the sink node 101 may decode the collected data and transmit the decoded data to the gateway. In this case, the sink node 101 may transmit a data set collected from each sensor node, that is, a result value, to the gateway 103. The sink node 101 may transmit a sensing matrix indicating whether each sensor node is located within a transmission limit range based on one session to the gateway 103.

The gateway 103 may recover the original data by receiving the result value and the sensing matrix from the sink node 101.

The present invention proposes a system for reducing data transmission power consumption in a wireless sensor network environment composed of highly mobile sensors. In the proposed system, the transmission limit range smaller than the original transmission range was set to minimize the data transmission power, and the data recovery was possible by using the principle of the compression sensing technique even when the data was not transmitted outside the limit transmission range. .

Methods according to an embodiment of the present invention can be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

Claims

In the data transmission method performed by the sink node,

Receiving data from sensor nodes located within a transmission limit range;

Decrypting the received data and transmitting the decoded data to a gateway

Data transmission method comprising a.
The method of claim 1,

The transmitting step,

A data transmission method for decoding data received from a plurality of sensor nodes located within the transmission limit range based on a unit time.
The method of claim 2,

The transmitting step,

And decoding the received data including temporary data of a plurality of sensor nodes located outside the transmission limit range in the unit time.
The method of claim 2,

The transmitting step,

A data transmission method for decoding the received data by using a compression sensing technique (compressive sensing) capable of approximate recovery of data.
The method of claim 1,

The sensor node,

Collect data within a radius of the sink node,

And transmitting the received data to the sink node when it is within the transmission limit range based on a unit time.
The method of claim 1,

The transmission limit range is

The data transmission method is set in consideration of the power according to the time the sensor node collects data within a predetermined radius of the sink node and the distance between the sink node and the sensor node.
In the data transmission method performed by the sensor node,

Collecting data within a radius of the sink node;

Transmitting the collected data to a sink node in consideration of a transmission limit range

Data transmission method comprising a.
The method of claim 7, wherein

The collecting step,

A data transmission method of collecting data at a point located within a predetermined radius of a sink node for a predetermined time based on when a sensor node operates.
The method of claim 7, wherein

The transmitting step,

If the data is located within the transmission limit range based on the unit time that can be transmitted, and transmits the collected data to the sink node,

The transmission limit range is

The data transmission method is set in consideration of the power according to the time the sensor node collects data within a predetermined radius of the sink node and the distance between the sink node and the sensor node.
The method of claim 7, wherein

The sink node,

Receive data from sensor nodes located within the transmission limit range,

A data transmission method of decoding and transmitting the collected data to a gateway by using a compression sensing technique capable of approximate restoration of data.
A data receiver configured to receive data from sensor nodes located within a transmission limit range;

Data decoding unit for decoding the received data and transmits to the gateway

Sink node comprising a.
The method of claim 11,

The data decoding unit,

And a sink node for decoding data received from a plurality of sensor nodes located within the transmission limit range based on unit time.
The method of claim 12,

The data decoding unit,

And a sink node to decode the received data including temporary data of a plurality of sensor nodes located outside the transmission limit range at the unit time.
The method of claim 12,

The data decoding unit,

And a sink node that decodes the received data by using a compression sensing technique capable of approximate restoration of data.
The method of claim 11,

The sensor node,

Collect data within a radius of the sink node,

The sink node for transmitting the received data to the sink node when located within the transmission limit range based on a unit time.
The method of claim 11,

The transmission limit range is

And a sink node set in consideration of a transmission time according to a time at which a sensor node collects data within a predetermined radius of the sink node and a distance between the sink node and the sensor node.
A data collector configured to collect data within a radius of the sink node;

Data transmission unit for transmitting the collected data to the sink node in consideration of the transmission limit range

Sensor node comprising a.
The method of claim 17,

The data collection unit,

A sensor node that collects data at a point located within a certain radius of the sink node for a predetermined time from when the sensor node operates.
The method of claim 17,

The data transmission unit,

If the data is located within the transmission limit range based on the unit time that can be transmitted, and transmits the collected data to the sink node,

The transmission limit range is

The sensor node is set in consideration of the transmission power according to the time the sensor node collects data within the radius of the sink node and the distance between the sink node and the sensor node.
The method of claim 17,

The sink node,

Receive data from sensor nodes located within the transmission limit range,

A sensor node that decodes the collected data and transmits the collected data to a gateway by using compression sensing.