KR101911503B1 - Wireless positioning system and method based on probabilistic approach in indoor environment - Google Patents

Abstract

The present invention relates to an anchor communication system comprising at least three or more anchor transmitters for transmitting radio signals in which unique identification information is recorded at mutually spaced locations in a room, and a transmitter for receiving a radio signal transmitted from each of the anchor transmitters, And a mobile body for calculating its own position using the signal strength. The mobile station sets estimation points for a known position in a dead zone formed by connecting anchor transmitters, Calculating a unit probability corresponding to each of the anchor transmitters by a probability calculation formula set for a first spacing distance between the point and the anchor transmitter and a second spacing distance calculated from the signal strength received from the anchor transmitter in the moving body, Calculates a cumulative probability of multiplying the unit probabilities by the estimated points, The cumulative probability for each estimated point calculated is calculated from the number of estimated points selected by applying a number of times to the number of estimated points while rotating the roulette with the tracking point occupied area set in proportion to the number of tracking points and the cumulative probability value of each tracking point, The position of the estimated point having the largest number of times is determined to be the current position. According to the probability based near field wireless positioning system and method in such an indoor environment, it is possible to improve the accuracy of position error with respect to radio wave interference.

Description

Technical Field [0001] The present invention relates to a probability based near field wireless position measurement system and method in an indoor environment,

The present invention relates to a probability based near field wireless position measurement system and method in an indoor environment, and more particularly, to a probability based near field wireless position measurement system and method in an indoor environment capable of improving accuracy of a position error.

Recently, with the rapid development of wireless communication technology, there is a growing interest in LBS (Location Based System), which is one of the core technologies of ubiquitous computing. Positioning technology, a core technology of location-based services, is widely used for GPS positioning in outdoor environments.

However, since it is difficult to apply GPS in an indoor environment, a new positioning technique is required. Therefore, many studies related to the current position measurement have been made, and some issues are emerging.

There are many studies on the most important accuracy problem in the field of position measurement. Here, NLOS (Non Line of Sight) problem has the biggest influence on accuracy in position measurement. Location measurement in a wireless environment is influenced by many environmental factors due to the nature of radio waves. The LOS (Line of Sight) propagation environment is an essential element for high accuracy, but in real-world environments, direct path is disturbed by many factors.

Important disturbances include path loss, multipath propagation, and NLOS. Such interference causes problems such as reflection and diffraction of radio waves, and as a result, the length of the path becomes long, making it difficult to accurately measure the position.

This NLOS problem is recognized as an important factor for improving the positional accuracy, and many studies for NLOS discovery and mitigation are continuing.

Therefore, there is a demand for a method for increasing the accuracy of position measurement in a room in consideration of a radio interference factor.

[0001] Korean Patent Laid-Open No. 10-2010-0073744

SUMMARY OF THE INVENTION It is an object of the present invention to provide a probability based near field wireless position measurement system and method in an indoor environment capable of reducing a position measurement error caused by a radio wave interference factor.

According to an aspect of the present invention, there is provided a probability-based short-range wireless position measurement system in an indoor environment, including at least three anchor transmitters for transmitting radio signals in which unique identification information is recorded at mutually spaced locations in a room, And a mobile body for receiving a radio signal transmitted from each of the anchor transmitters and calculating a position of the mobile station based on the unique identification information and the signal strength of the received radio signal, Calculating a first distance between the estimated point and the anchor transmitter and a second distance calculated from the signal strength received from the anchor transmitter in the mobile body by setting the estimated points for a known position in the dead zone defined by connecting the transmitters, According to the probability calculation formula set for the separation distance, The cumulative probability of each of the calculated points is calculated for each of the estimated points, and the calculated cumulative probability for each of the estimated points is stored in the roulette plate as the number of follow-up points and the cumulative probability value of each follow- The position of the estimated point having the largest number of selection points among the estimated points selected by applying the number of times by the number of estimated points while rotating the roulette set in the track point occupied area proportionally is determined as the current position.

The probability calculation equation

Here, Wi is a unit probability for an anchor transmitter i, di is a second spacing distance calculated from the signal strength between the moving body and the anchor transmitter i, and di ^* is a first spacing distance between the estimated point and the anchor transmitter i.

According to another aspect of the present invention, there is provided a probability-based short-range wireless position measurement method in an indoor environment, the method comprising: receiving at least three anchor transmitters A short range radio position measuring method for receiving a radio signal transmitted from each of a plurality of mobile stations and calculating its own position using radio signal unique identification information and signal strength, comprising: The mobile station sets estimation points for a known position in a dead zone formed by connecting the anchor transmitters in the mobile body, and calculates a first distance between the estimation point and the anchor transmitter and a first distance between the anchor transmitter and the anchor transmitter, Calculating a unit probability corresponding to each of the anchor transmitters by a probability calculation formula set for a second spacing distance calculated from the first and second spacings, and calculating a cumulative probability of multiplying each of the calculated unit probabilities by the estimated points; I. The cumulative probability for each estimated point calculated in the above step is selected by applying the number of times corresponding to the number of estimated points while rotating the roulette in which the track point occupied area is set in proportion to the number of tracking points and the cumulative probability value of each tracking point in the roulette board It is determined that the position of the estimated point having the largest number of selection points among the estimated points is determined as the current position.

According to the present invention, the probability based near field wireless position measurement system and method in an indoor environment provides an advantage of improving the accuracy of position error with respect to radio wave interference.

FIG. 1 is a diagram illustrating a probability based near field wireless positioning system in an indoor environment according to the present invention,
Fig. 2 is a block diagram of the moving body of Fig. 1,
FIG. 3 is a flowchart for explaining a probability based near field wireless positioning process in an indoor environment according to the present invention,
4 and 5 are views for explaining a position measuring process according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a probability based near field wireless positioning system and method in an indoor environment according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a probability based short range wireless positioning system in an indoor environment according to the present invention, and FIG. 2 is a block diagram of the mobile station of FIG. 1.

1 and 2, a probability based near field wireless positioning system 100 in an indoor environment according to the present invention includes first to fourth anchor transmitters A1 to A4 (11 to 14), a mobile station T (20).

The first to fourth anchor transmitters A1 to A4 (11 to 14) transmit radio signals in which unique identification information is recorded at mutually spaced locations in the room.

It is needless to say that, unlike the illustrated example, three or five or more anchor transmitters may be applied.

The mobile unit (T) 20 receives the radio signals transmitted from the first to fourth anchor transmitters 11 to 14, and calculates its own position using the unique identification information and the signal strength of the received radio signal .

The moving body 20 includes a signal receiving unit 21 for receiving a radio signal transmitted from each of the first to fourth anchor transmitters 11 to 14, And a position output unit 23 which is controlled by the position calculating unit 22 and outputs the calculated position information.

The position output unit 23 can be applied to a display unit that displays the calculated position information.

The position calculating process of the position calculating unit 22 will be described with reference to FIGS. 3 to 5. FIG.

First, the position calculating unit 22 sets the estimated points c1 to c5 for an arbitrary known position in the closed partition area 15 formed by connecting the first to fourth anchor transmitters 11 to 14 (Step 110).

The position information of the estimated points c1 to c5 and the position information of the first to fourth anchor transmitters 11 to 14 are recorded in the position calculating section 22. [

In the illustrated example, only five estimation points are illustrated in order to avoid the complexity of the drawing, and it is appropriately applied according to the applied environment and system, and preferably 100 to 500 is applied.

In addition, the estimation point can be selected in various ways such as a method of selecting a predetermined number of estimation points corresponding to a random number generated using a random number generator.

Next, the first to fourth anchor transmitters 11 to 14 receive the first distance from the selected estimation points c1 to c5 and the first to fourth anchor transmitters 11 to 14 at the mobile 20, The first to fourth anchor transmitters 11 to 14 are calculated in accordance with the probability equations set for the second spacing distance calculated from the received signal strengths, and the cumulative probability of mutually multiplying each of the calculated unit probabilities (Step 120).

Here, the unit probability calculation equation can be expressed by the following equation (1).

Here, Wi is a unit probability for an anchor transmitter i, di is a second spacing distance calculated from the signal strength between the moving body and the anchor transmitter i, and di ^* is a first spacing distance between the estimated point and the anchor transmitter i.

A process for calculating the estimated point indicated by reference numeral c1 will be described.

The first distance d1 to the distance d4 between the first to fourth anchor transmitters 11 to 14 that know the position with respect to the estimated point C1 that knows the position and the first to fourth anchor transmitters 11 to 14, If the unit probability for the first anchor transmitter 11 is W (c1) 1 with respect to the second spacing distance d1 ^* to d4 ^* calculated from the signal strength transmitted from the mobile unit 20, (2) "

Similarly, the unit probability calculated by applying d2, d2 * to the second anchor transmitter 12 with respect to the estimation point C1 is W (c1) 2, and d3, d3 And the unit probability calculated by applying d4 and d4 * to the fourth anchor transmitter 14 is W (c1) 4, then the estimated point C1 ) Is calculated by the following equation (3). &Quot; (3) "

Likewise, the cumulative probability is calculated for the remaining estimated points.

Next, the cumulative probability for each estimated point is calculated in proportion to the number of tracking points and the cumulative probability value of each tracking point, while rotating the roulette 50 in which the tracking point occupied area is set in the roulette board 50 To extract the selected estimation points (step 130).

That is, as shown in FIG. 5, when the cumulative probability of the estimated point C1 is 0.4, an estimated point is assigned to the roulette board 50 to have occupied areas 52 of 0.4. Likewise, the remaining estimated points are formed to have occupied areas corresponding to the cumulative probability values. Then, the roulette board 50 is rotated and the dots are thrown to extract the estimated points corresponding to the occupied areas landed on the selected estimated points .

This estimation point extraction process proceeds by the number of estimated estimation points applied.

The roulette method extraction process described above is processed by software operation.

Finally, the position of the estimated point having the largest number of times of selection is determined to be the current position (step 140).

According to the probability based near field wireless positioning system and method in such an indoor environment, it is possible to improve the accuracy of position error with respect to radio wave interference.

11 to 14: First to fourth anchor transmitters (A1 to A4)
20: Moving object (T)

Claims (3)

At least three or more anchor transmitters for transmitting radio signals in which unique identification information is recorded at mutually spaced locations in the room; and a radio receiver for receiving the radio signals transmitted from each of the anchor transmitters, A short range wireless positioning system having a mobile body for calculating its own position using an intensity,
The moving body
Calculating a first distance between the estimated point and the anchor transmitter and a second distance between the estimated point and the anchor transmitter calculated from the signal strength received from the anchor transmitter in the moving object, Calculates a unit probability corresponding to each of the anchor transmitters by a probability calculation formula set for the second spacing distance, calculates a cumulative probability that is obtained by multiplying each of the calculated unit probabilities by the estimated points, and calculates a cumulative probability The roulette plate is rotated by a roulette with a tracking point occupied area in proportion to the number of tracking points and the cumulative probability value of each tracking point and the number of times corresponding to the number of estimation points is applied, The position of the point is determined to be the current position,
The probability calculation equation

Where Wi is a unit probability for an anchor transmitter i, di is a second spacing distance calculated from the signal strength between the moving body and the anchor transmitter i, and di ^* is a first spacing distance between the estimated point and the anchor transmitter i Probability based near field wireless positioning system in indoor environment. delete A mobile station receives a radio signal transmitted from each of at least three anchor transmitters each transmitting a radio signal in which unique identification information is recorded at mutually spaced locations in the room, The method comprising the steps of:
end. The mobile station sets estimation points for a known position in a dead zone formed by connecting the anchor transmitters in the mobile body, and calculates a first distance between the estimation point and the anchor transmitter and a first distance between the anchor transmitter and the anchor transmitter, Calculating a unit probability corresponding to each of the anchor transmitters by a probability calculation formula set for a second spacing distance calculated from the first and second spacings, and calculating a cumulative probability of multiplying each of the calculated unit probabilities by the estimated points;
I. The cumulative probability for each estimated point calculated in the above step is selected by applying the number of times corresponding to the number of estimated points while rotating the roulette in which the track point occupied area is set in proportion to the number of tracking points and the cumulative probability value of each tracking point on the roulette board The position of the estimated point having the largest number of selection times among the estimated points is determined to be the current position,
The probability calculation equation

Where Wi is a unit probability for an anchor transmitter i, di is a second spacing distance calculated from the signal strength between the moving body and the anchor transmitter i, and di ^* is a first spacing distance between the estimated point and the anchor transmitter i A Probabilistic Near Range Wireless Position Measurement Method in Indoor Environments.

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