KR20120063811A - Routing method in wireless sensor network - Google Patents

Abstract

PURPOSE: A routing method in a wireless sensor network is provided to reduce energy consumption in a routing process by balancing energy on the wireless sensor network. CONSTITUTION: A transmission node selected between a source node which senses new data and an intermediate node which receives forwarding data determines a transmission method based on a distance between the transmission node and a sync node(102). When the distance is smaller than limit values, a direct transmission method is determined as the transmission method(104). When the distance is bigger than the limit values, a multi-hop transmission method is determined as the transmission method. When the transmission method is determined as the multi-hop transmission method, the transmission node determines optimal hop neighbor nodes(106).

Description

Routing Method in Wireless Sensor Network

The present invention relates to a routing method in a network, and more particularly, to a routing method in a wireless network in which a plurality of nodes are randomly arranged.

Wireless Sensor Networks (WSNs), which detect physical state data such as light, sound, temperature, and movement by multiple sensors and collect them over a wireless link, have received a lot of attention in recent years. It has a wide range of applications, such as monitoring, production line monitoring, agricultural observation, health and smart homes. Typically, in a wireless sensor network, sensor nodes are randomly arranged in a physical environment to be monitored, and data collected by searching and routing a path from a source node to a destination node, that is, a sink node, is routed in an ad hoc manner. It is sent to the sink node in an autonomous and independent manner.

Since ad hoc networks pass data through nodes that can be moved, added, or removed without a fixed infrastructure, each node acts as a wired router. Here, routing refers to a process of transmitting monitoring data from a source node or an intermediate node to a sink node according to requirements in different applications.

In the implementation of routing in ad hoc wireless sensor networks, a method for optimizing and improving energy efficiency is very important, and energy efficiency and balancing are one of the main challenges for successful application of wireless sensor networks. Many energy efficient routing algorithms or protocols have been proposed so far using techniques such as clustering, data collection, multipath and location tracking, and the like.

Traditional routing protocols in wireless sensor networks can be broadly classified into three categories: data-centric, hierarchical and location-based routing protocols.

Among data-centric routing protocols, SPIN ("Energy-efficient communication protocol for wireless sensor networks", see Proc. Hawaii International Conference System Sciences, 2000, pp.1-10) utilizes data negotiation techniques between sensor nodes. It can be seen as the first data-centric routing protocol that reduces degrees and saves energy. Direct diffusion (see “Directed diffusion: A scalable and robust communication paradigm for sensor networks”, Proc. 6th Annual ACM / IEEE International Conference on Mobile Computing and Networking, 2000, pp.56-67) is another approach for wireless sensor networks. Is a data-centric routing protocol. The data generated by the sensor nodes is named as attribute-value pairs within the nodes. Once the sink node requires a certain type of information, a query may be sent, and the observed data may be collected and sent to the sink node. In addition, load balancing may be achieved.

Hierarchical routing protocols are suitable for wireless sensor networks because they provide excellent scalability for hundreds or thousands of sensors as well as data collection by cluster heads within each cluster. LEACH (see "Energy-efficient communication protocol for wireless sensor networks", Proc. Hawaii International Conference System Sciences, 2000, pp. 1-10) is one of the most popular hierarchical routing protocols for wireless sensor networks. This protocol extends network life by eight times over other conventional routing protocols, such as the direct transport protocol and the original transport energy protocol. However, 5% of the cluster head nodes are randomly selected and the cluster head nodes perform direct transmission to the sink nodes, which causes an imbalance in energy consumption. PEGASIS ("PEGASIS", see Proc. IEEE Aerospace Conference, 2002, pp.924-935) is considered an advanced version of LEACH. This protocol is a chain-based routing protocol that can save a lot of energy compared to LEACH. The message is collected along the chain and finally sent to the sink node via direct transmission by any node on the chain. The biggest disadvantage of PEGASIS is that it requires a general knowledge of the entire network.

The location-based routing protocol may obtain location information through a GPS device or other estimation algorithm based on received signal strength (RSS). Knowing the location information can reduce energy consumption through the power control mechanism and reduce communication overhead. MECN (see "Minimum energy mobile wireless networks", IEEE Journal on Sel. Areas Comm., 1999, pp. 1333-1344) provides a minimum energy network for wireless sensor networks under the support of low power GPS. The authors of "Minimum energy mobile wireless networks revisited" (Proc. Of IEEE International Conference on Communications (ICC'01), 2001, pp. 278-283) extend MECN to account for possible failures between arbitrary pairs of communication nodes. Doing.

Recently, new types of hop to distance based routing algorithms and / or protocols have been proposed. In "Power-aware Localized Routing in Wireless Networks" (IEEE Transaction on Parallel and Distributed Systems 2001, pp. 1121-1133), the authors present a pioneering work on studying different energy models under typical wireless network environments. In "Energy Balanced Data Propagation in Wireless Sensor Networks" (Wireless Networks, 2006, pp. 691-707), the authors present a study on the selection of a transmission scheme in terms of probability. In this document the authors suggest to the transfer of data to the sink in a multi-hop (multi-hop) way with a probability P _i node, and transmitting the data to a single hop system with a probability (1-P _i). The authors of "On the Problem of Energy Efficiency of Multi-hop vs One-hop Routing in Wireless Sensor Networks" (the 21st International Conference on Advanced Information Networking and Applications Workshops (AINAW), 2007, pp. 380-385) We present the results of energy consumption in hop and multi-hop transmission. They argue that the superiority of multi-hop routing over single-hop routing depends on the distance between source and sink and the cost of reception.

The metric of hop number, or hop distance, has a significant impact on many network metrics such as energy consumption, routing overhead, interference, and latency. Even in the sense, if the number of hops is very large, energy consumption can be reduced by paying for the cost of end-to-end latency and large control overhead. If the number of hops is very small, as in direct transmission, the latency is very small, but due to the inherent nature of wireless communications, energy consumption can be very large. Therefore, in order to achieve energy efficiency and balance, it is necessary to set an appropriate hop number with a suitable individual distance.

On the other hand, the hot spot problem is an important factor directly affecting the network lifetime of the wireless sensor network. Hot spot problems are caused by the energy consumption imbalance between the sensors. This is a big challenge that must be overcome in wireless sensor networks with random and dynamic topologies. For example, if all sensors use direct transmission, the nodes near the sink node will reach early life, even if the nodes near the sink node have a lot of residual energy, because energy consumption is proportional to the square of the distance. . On the other hand, when multi-hop transmission is used, nodes that are far from the sink node in the process of using short-range multi-hop transmission end up early because the nodes near the sink node have more traffic to forward even though there is more residual energy. .

Therefore, in order to alleviate the hot spot problem, it is necessary to balance energy consumption among all sensors in consideration of factors such as transmission scheme, transmission distance, and residual energy.

SUMMARY OF THE INVENTION The present invention has been made to solve this problem, and in the wireless sensor network, by balancing all sensor nodes to consume energy at a similar rate during the routing process, energy balancing and efficiency can be achieved. It is a technical problem to provide a routing method that can alleviate a hot spot problem.

The routing method of the present invention for achieving the above technical problem is suitable for use in a wireless sensor network having a plurality of sensor nodes and sink nodes.

First, the transmitting node determines a transmission method based on the distance between the transmitting node and the sink node. Here, the transmitting node may be a source node to detect new data and transmit it to the sink node, or may be an intermediate node that receives data sensed by the source node and forwards it to the sink node. In determining the transmission method, when the distance between the sink node and the sink node is smaller than a predetermined lower limit value, the transmitting node determines the direct transmission method as the transmission method, and when the distance to the sink node is not smaller than the lower limit value, The hop transmission method is determined as the transmission method.

If the transmission scheme is determined to be a multi-hop transmission scheme, the transmitting node determines the optimal next hop neighbor node. In this case, the transmitting node satisfies a first condition for reducing the distance between itself and the next hop neighbor node, the distance between the next hop neighbor node and the sink node, and a second condition for selecting a node having a large residual energy. The next hop neighbor node among the plurality of sensor nodes is determined.

Once the next hop neighbor node is determined, the transmitting node will send data to the next hop neighbor node.

According to a preferred embodiment, in determining the next hop neighbor node, first determine the next hop candidate nodes whose distance from the transmitting node is less than the first reference value and the distance from the sink node is less than the second reference value. The node having the maximum residual energy among the next hop candidate nodes is selected as the next hop neighbor node.

In a preferred embodiment, each of the plurality of sensor nodes includes a neighbor node table for storing a distance to each of the sink node and at least some of the other sensor nodes, and an energy level table for storing energy levels of the other nodes. And the next hop neighbor node is determined with reference to the neighbor node table and the energy level table.

According to the present invention, when the transmitting node, that is, the source node or the intermediate node, determines the next hop neighbor node, the individual distances between the nodes are treated as the primary criterion, and the residual energy is considered as the secondary criterion. In consideration, rather than trying to reduce the total energy consumption, each node will consume energy at a similar reduction rate.

Through this energy balance, the hot spot phenomenon can be alleviated, energy consumption can be reduced during the routing process, and the network life can be greatly extended.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings,
1 is a table showing a determination method for the transmission scheme and individual distance in the distance-based energy aware routing (DEAR) method of the present invention.
2 shows an example of a wireless sensor network to which the routing method of the present invention is applied.
3 is a block diagram of a sensor node device constituting each of the sensor nodes shown in FIG. 2.
4 is a flowchart showing a preferred embodiment of the distance-based energy aware routing method according to the present invention.
FIG. 5 is a detailed flowchart illustrating selection criteria for determining an optimal next hop neighbor node for multi-hop transmission in steps 106 and 114 of FIG. 4.
6 is a graph showing the distribution of various multi-hop paths given the distance from the source node to the sink node.
7 is a graph comparing average energy consumption between the routing algorithm of the present invention and three types of general purpose routing algorithms.
8 is a graph illustrating a comparison of the average network life between the routing algorithm of the present invention and three types of general purpose routing algorithms.

The Distance Based Energy Aware Routing (DEAR) algorithm of the present invention is based on the theoretical and experimental analysis of a conventional energy model called a First Order Radio Model.

The energy E _Tx consumed by the wireless device to transmit the l-bit message depends on the distance d as shown in Equation 1 below.

The energy E _Rx consumed to receive the message and the energy E _Fx consumed to forward the message are shown in Equations 2 and 3, respectively.

Table 1 summarizes the definitions of radio parameters included in Equations 1 to 3.

parameter Justice value E _elect Energy Consumption to Drive Wireless Devices 50 nJ / bit ε _fs Free Space Model of Transmitter Amplifier 10 pJ / bit / ㎡ ε _mp Multipath Model of Transmitter Amplifier 0.0013 pJ / bit / m2 ℓ Data length 2000 bit d ₀ Distance threshold

m

m

Hereinafter, n sensor nodes along the path from the source node to the sink node are each distance {d ₁ , d ₁ ,... , d _n }, and the distance from the source node to the sink node is d and node 1 is the farthest node from the sink node.

Assuming that each node in turn sends a l-bit message to the remote sink node, the i-th node transmits its own l-bit data once and forwards another message (i-1) times. Therefore, the energy consumption at the i-th node is expressed by Equation 4.

If E _i = E _{i +1} , the following Equation 5 is finally obtained.

Since d _n > 0, the following equation must be satisfied.

Based on Equation 6, the lower limits d ₁ and d _i of the distance for each n value in the range of n = [2: 9] can be obtained as shown in FIG. ₁ . Here, a value of epsilon _amp = 0.001 pJ / bit / m ⁴ and E _elect = 50 nJ / bit was used. Given a multi-hop number n, the minimum distance d from the source node to the sink node as well as the lower limit d ₁ of the distance can be calculated using the table of FIG. 1. For example, when d = 300, in fact, d ₁ (2)> 100 or d ₁ (3)> 118.9, so only two- or three-hop paths can be used.

Meanwhile, when the distance d from the source node to the sink node is given, there may be several multi-hop paths having different hop numbers n. In this case, the maximum number of hops for which energy consumption is minimized for each sensor node is an optimal multi-hop number.

이기 때문에 9-홉 경로를 선택할 수는 없다는 것을 주목해야 한다.In Table 2, given the distance d from the source node to the sink node, we can see the different sets of d ₁ (n). For example, when d = 800, an 8-hop path with d ₁ (8) = 164.8 or a 7-hop path with d ₁ (7) = 170.5 can be selected. The corresponding individual distance d _i can be obtained by inferring from Equation 6. here,

Note that you cannot choose the 9-hop path.

Therefore, when d = 800, an n-hop path can be selected within a range of n∈ [2,8]. And, it is desirable to choose an 8-hop path with d ₁ (8) = 164.8, because each node consumes minimal energy.

d 800 900 1000 d ₁ (n) d ₁ (8) = 164.8 d ₁ (9) = 169.7 d ₁ (10) = 174.3 d ₁ (7) = 170.5 d ₁ (8) = 174.2 d ₁ (9) = 177.8 d ₁ (6) = 183.7 d ₁ (7) = 184.7 d ₁ (8) = 186.3

Based on the above analysis, the distance-based energy aware routing (DEAR) method according to the present invention will be described.

2 shows an example of a wireless sensor network to which the routing method of the present invention is applied. The illustrated wireless sensor network includes a plurality of sensor nodes 20a to 20n randomly arranged in the sensing target region 10 to be monitored, and a base station BS installed inside or outside the sensing target region 10. That is, the sink node 30 is included. The sink node 30 may be connected to the user terminal 50 through a public network.

In a preferred embodiment, at least some of the sensor nodes 20a-20n may be mobile and others may be fixed. Regardless of mobility, each sensor node 20a-20n is homogeneous, and communication links between them are preferably configured symmetrically. In addition, it is desirable that there is no large obstacle between the source node and the sink node.

3 is a block diagram of sensor node devices constituting each of the sensor nodes 20a to 20n. Each sensor node device includes a sensor module 70, a wireless communication unit 72, an antenna 74, a microcontroller 76, a flash memory 78, and an SRAM 80.

The sensor module 70 detects and converts physical states such as light, sound, temperature, and movement into digital data. The wireless communication unit 72 communicates with other sensor nodes 20a-20n or sink node 30 via antenna 74 in a manner compliant with Zigbee, Bluetooth, or Wi-Fi standards. Send and receive. In particular, in a preferred embodiment, it is desirable to allow the transmission output of the wireless communication unit 72 to be varied in several steps without collision with the MAC layer under the control of the microcontroller 76.

When the microcontroller 72 receives new sensing data from the sensor module 70 or receives sensing data to be relayed from other sensor nodes 20a to 20n, the microcontroller 72 detects the sensing data through the wireless communication unit 72 and the antenna 74. Is transmitted to any one of the other sensor nodes 20a to 20n and the sink node 30 determined according to a predetermined rule. In addition, the microcontroller 72 may transmit a Route Request (RREQ) message or an Acknowledgment (ACK) message as described below.

The flash memory 78 stores setting data necessary for device operation. In particular, according to the present invention, the flash memory 78 stores a neighbor node table which stores addresses of neighbor nodes and sink nodes in the vicinity of the device and distances to the corresponding nodes. Here, the distance to the neighboring node or the sink node can be obtained by using triangulation or another positioning method. However, in another embodiment, with each node acquiring its own location information using a common positioning method, such location information is exchanged between the node devices as described below, and each node device is changed by mathematical inference. You can also calculate individual distances to nodes.

Meanwhile, the SRAM 80 stores temporary data generated during device operation. For example, the SRAM 80 stores an energy level table for storing energy levels of the device itself and neighbor nodes. In addition, the SRAM 80 may additionally store a route table that stores information about a route associated with the corresponding device. In the systems shown in Figs. 2 and 3, each node device is in communication with neighboring nodes in a normal state, exchanging their information, such as location information and energy level information, via a beacon signal.

In a preferred embodiment of the present invention, the neighbor node table and energy level table of each sensor node device store only the information about some nodes and sink nodes in the neighborhood, not the global network topology information. The distance-based energy aware routing (DEAR) method of the present invention performed by the microcontroller 72 may be referred to as a distributed local routing algorithm.

4 is a flowchart showing a preferred embodiment of a distance-based energy aware routing (DEAR) method according to the present invention.

First, the sensor nodes 20a to 20n continuously determine whether new data is detected (step 100). When new data is detected in step 100, the sensor nodes 20a to 20n obtained from the sensed data, that is, the source node, initiate a path setting step to transmit the detected data to the sink node BS.

First, the source node determines a transmission method based on the distance d from the source node to the sink node BS (step 102). Specifically, if the distance d from the source node to the sink node BS is smaller than the lower limit d ₁ (n = 2) of the distance when n = 2, that is, the value 100 in the example of FIG. Determines to use the direct transmission method and transmits data directly to the sink node BS (step 104). On the other hand, if the distance d from the source node to the sink node BS is greater than the lower limit d ₁ (n = 2) of the distance when n = 2, the source node transmits data to the sink node BS by the multi-hop transmission method. To be sent).

If the multi-hop transmission scheme is selected in step 102, the source node (for example, 20a of FIG. 2) is optimal based on the distance to each neighbor node and the energy level of each neighbor node based on the neighbor node table and the energy level table. The next hop neighbor node 20b is determined (step 106).

When the next hop neighbor node 20b is selected, the source node 20a requests a route establishment by sending a Route Request (RREQ) message to the next hop neighbor node 20b by encapsulating its location information. (Step 108). When the next hop neighbor node 20b receives the RREQ message, it sends an acknowledgment (ACK) message to the previous node and responds (step 110).

The neighbor node 20b then adds its location information into the RREQ message and transmits it to the next hop neighbor node 20c, which process is performed repeatedly. Accordingly, the RREQ message reaches the sink node BS with complete path information (step 114).

Finally, the sink node BS sends a Route Reply (RREP) message to confirm receipt of the RREQ message, and traffic transmission can be started (step 116).

If the source node 20a detects a link error in the path setting process (step 112), the source node 20a may select another appropriate neighbor node (e.g., FIG. Select 2 to 20k) to restart the routing step. If the intermediate nodes 20b to 20e detect a link error in step 112, the intermediate nodes 20b to 20e first attempt a local link recovery process (step 110). In other words, the intermediate node attempts to select another suitable neighbor node in a manner similar to steps 106-110. If local link recovery was successful, the routing process may resume from step 114. On the contrary, when local link recovery fails, a path error (RERR) message is transmitted backward from the corresponding intermediate nodes 20b to 20e to the source node 20a based on the information stored in the RREQ message. In addition, the intermediate nodes 20b to 20e notify the nodes related to the failure path (step 120).

Finally, the path including the relevant intermediate nodes from the source node 20a is deleted from the path table of each device (step 122), and a new path setting step is initiated by the source node 20a (step 124).

FIG. 5 shows in more detail the selection criteria for the source node to determine an optimal next hop neighbor node for multi-hop transmission in step 106 of FIG. 4.

의 관계를 만족시키는 다음 홉 후보 노드들의 집합(A)을 선별한다(제150단계). 여기서, 메트릭(Δ)은 조정 파라미터로써, 도 1 및 위에서 설명한 예와 같은 실질적인 네트웍 토폴로지 하에서 예컨대 [20,40] 범위 내에 있는 값으로 정해질 수 있다.First, the source node has a distance between source node i and its neighbor node j

In step 150, a set A of next hop candidate nodes satisfying the relation is selected. Here, the metric Δ may be an adjustment parameter, and may be determined to be a value within a range of, for example, [20, 40] under the actual network topology as shown in FIG. 1 and the example described above.

의 관계를 만족하는 다음 홉 후보 노드들의 부분집합(B)을 선별한다(제152단계).Subsequently, the source node may be configured such that the distance from node j to sink node BS is smaller than the distance from source node i to sink node BS among nodes belonging to the set A of next hop candidate nodes.

A subset B of the next hop candidate nodes satisfying the relationship of the neighbors is selected (step 152).

).In step 154, the source node selects the subset C of the next hop candidate nodes by selecting one or more nodes closest to the sink node BS among the nodes belonging to the subset B of the next hop candidate nodes. (In other words,

).

In step 156, the source node, among the nodes belonging to the subset C of the next hop candidate nodes, the final next hop node j selects the node j ^* having the maximum residual energy as the final next hop neighbor node.

As such, in a preferred embodiment, the individual distances between nodes are treated as primary parameters in the routing process, and the residual energy is considered as secondary parameters.

On the other hand, in the above description based on the selection criteria for the source node to determine the optimal next hop neighbor node for multi-hop transmission in step 106 of Figure 4, the determination process of Figure 5 is intermediate in step 114 of FIG. The same can be applied to the process of the node determining the optimal next hop neighbor node.

6 shows the distribution of various multi-hop paths when the distance d from the source node to the sink node is given as 800 as shown in Equation 5 and FIG. 1. When d = 800, there are several multi-hop path options with hop number n in the range [2,8]. Of these, you eventually choose an eight-hop path, because each node consumes the least energy. It should be noted that under real network topologies, the realistic value d ₁ (8) is larger than the theoretical value. On the other hand, through such a routing method, both energy efficiency and energy balance can be achieved.

7 is a graph comparing average energy consumption between the routing algorithm of the present invention and three types of general purpose routing algorithms.

In FIG. 7, it is assumed that 300 sensor nodes are randomly arranged in an area of 300 있고 300 m 2 and the sink node BS is located at the center of the area. In this case, the maximum transmission radius is 150 meters. Each node transmits a 2000-bit message to the BS in turn by direct transmission or multi-hop transmission based on different routing algorithms. The average energy consumption was compared with the DEAR algorithm of the present invention and three general-purpose routing algorithms, namely, a direct transmission, a greedy algorithm, and a maximum residual energy (MRE) algorithm.

It can be seen from FIG. 7 that the direct transfer algorithm consumes the most energy because the average distance from the source node to the sink node is relatively far. The DEAR algorithm of the present invention minimizes energy consumption due to its distance-based nature. The greedy algorithm and the MRE algorithm showed moderate performance in up to 100 simulations. Compared with other algorithms, it can be seen that the DEAR algorithm can reduce energy consumption as well as balance energy consumption for the sensors.

In the case of a greedy routing algorithm, each node selects neighboring nodes by approximating an individual distance r _i to the transmission radius R during the routing process, which increases energy consumption as the transmission radius R increases. . In the case of the MRE algorithm, each node selects the next hop as a node with a relatively high residual energy, which could randomly distribute the multi-hop number and the individual distance. In the case of the DEAR algorithm of the present invention, it is always possible to find a suitable next hop with a suitable individual distance and residual energy.

8 shows a comparison of the average network life between the routing algorithm of the present invention and the three general purpose routing algorithms. Here, network life is defined as the time at which the energy of the first node is depleted, since this time causes the occurrence of subsequent network partitions or isolation areas.

In FIG. 8, it can be seen that direct transmission usually has the shortest lifespan in a large network environment or when the average distance from the source node to the sink node is relatively large. In the case of the MRE algorithm, since each node selects the next hop based on the residual energy, which is often independent of the distance distribution, the final multi-hop path has fewer hops and can consume more average energy. . In the case of a greedy routing algorithm, the network lifetime is relatively long because each node tends to select nodes close to R as the next hop nodes in order to most easily route to the sink node. It is short and consumes a lot of energy. In contrast, the DEAR algorithm of the present invention exhibits the longest network life due to its energy efficiency and balancing properties.

Given the distance from the source node to the sink node and the hardware parameter values in Table 1, we can determine the transmission scheme, the optimal number of multi-hops, and the corresponding individual distances. The key difference between the DEAR algorithm and other algorithms of the present invention is that in the present invention each node consumes energy at a similar reduction rate rather than trying to reduce the total energy consumption in each routing process.

As such, according to the routing method of the present invention, energy consumption is greatly reduced and network life can be significantly extended.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

For example, the table of FIG. 1, which represents the lower limit of each individual distance, may vary depending on the physical environment or application. In addition, hardware parameter values are also not limited to the values in Table 1.

The method is also applicable to many other types of energy efficient routing algorithms or protocols for wireless sensor networks.

Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

10: detection target area
20a-20n: sensor node
20a: source node
BS: Sink Node
RREQ: Route Request Message
ACK: Acknowledgment message
RREP: Route Reply Message
RERR: Route Error Message

Claims (3)

A routing method in a wireless sensor network having a plurality of sensor nodes and sink nodes,
(a) A transmission node, which is determined as one of a source node that detects new data and an intermediate node that receives data to forward, determines a transmission method based on a distance between the transmission node and the sink node, wherein the transmission node and the sink node are determined. Determining a direct transmission scheme as the transmission scheme when the distance is smaller than a predetermined lower limit value, and determining a multi-hop transmission scheme as the transmission scheme when the distance between the transmitting node and the sink node is not smaller than the lower limit value. ;
(b) when the transmission method is determined as the multi-hop transmission method, the transmitting node determines an optimal next hop neighbor node, wherein the distance between the transmitting node and the next hop neighbor node, the next hop neighbor node, and the sink are determined. Determining the next hop neighbor node among the plurality of sensor nodes to satisfy a first condition for reducing the distance between nodes and a second condition for selecting a node having a large residual energy; And
(c) the transmitting node transmitting the data to the next hop neighbor node;
Routing method comprising a. The method according to claim 1, wherein step (b)
(b1) determining next hop candidate nodes whose distance from the transmitting node is less than a first reference value and the distance from the sink node is less than a second reference value; And
(b2) selecting a node having a maximum residual energy among the next hop candidate nodes as the next hop neighbor node;
Routing method comprising a. 3. The sensor of claim 1, wherein each of the plurality of sensor nodes includes a neighbor node table for storing a distance to each of the sink node and at least some of the other sensor nodes, and energy for storing energy levels of the other nodes. And a level table, wherein the next hop neighbor node is determined by referring to the neighbor node table and the energy level table.

Images