JP2005210656A - Terminal position detection method, and terminal position detection system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a position detection method and system in which a terminal position can be highly accurately detected while using an existing radio communication system having deviation in a signal strength output. <P>SOLUTION: A plurality of antennas 2a-2d at different positions and an attenuator 3 capable of attenuating reception signals from the antennas using a plurality of attenuation amounts are used to record, in a position detection server 5, a signal strength output from a base station for each antenna together with the attenuation amount with regard to a reception signal through the attenuation means, and a sample database in which the relationship of the position and the data is checked in advance, is compared with the measured value, thereby estimating and outputting the terminal position. <P>COPYRIGHT: (C)2005,JPO&amp;NCIPI

Description

  The present invention relates to a method for detecting a terminal position in a predetermined space using an existing wireless communication system and a system thereof, and more particularly, to determine a terminal position quickly and efficiently with a power-saving device such as Bluetooth. It relates to the technology to detect.

2. Description of the Related Art Conventionally, a method is known in which a radio wave is transmitted from a terminal wirelessly, the strength of the radio wave is received by a plurality of base stations, and the position of the terminal is detected based on the same principle as triangulation.
Further, a system for confirming the position of a user using an existing wireless LAN (802.11b) communication system has been proposed, as in a technique called RADAR disclosed in Non-Patent Document 1.

  RADAR uses a wireless LAN, does not require special hardware, and is simple to realize a system by software. On the other hand, it requires a lot of power consumption and is a terminal for long standby. There is a problem that a considerable battery must be provided on the side.

  P. Bahal and V.M. Padmanabhan. RADAR: An In-Building RF-based User Location and Tracking System. In Proc. IEEE INFOCOM, Tel-Aviv, Israel, March 2000.

  In addition, infrared communication and Bluetooth are known as wireless communication methods that can be easily used. Infrared communication has the advantage of a simple structure and low cost, but does not connect to light blocked by an obstacle, and has limitations that can only be used at a short distance, and is not suitable for position detection.

  Communication systems based on a standard called Bluetooth (Bluetooth) have come to be used for portable information terminals such as PDA (Personal Digital Assistance), mobile phones, notebook personal computers, and other general home appliances. Bluetooth is disclosed on the website shown in Non-Patent Document 2.

  https: // www. Bluetooth. org /

Bluetooth allows communication between different types of devices such as PCs and TVs, and can also be used for printing and image transmission. In addition, it uses radio waves in the 2.4 gigahertz frequency band and can be used without restrictions in any country. There are advantages you can do. The power consumption is smaller than that of the wireless LAN, and the chip has a small feature.
The use of such Bluetooth for position detection is preferable because it saves power and has few restrictions on the number of channels. Conventional techniques disclosed in Patent Documents 1 and 2 are disclosed.

  JP 2003-274441 A   JP 2003-78941 A

  However, any of the conventional techniques recognizes which Bluetooth base station is approached, and is not a system that can specify a more detailed position. This is because the output of the radio field intensity in Bluetooth has the following characteristics.

In other words, in existing systems aimed at communication over very short distances, the signal strength of the received radio wave is used as the actual signal strength as it is in order to clearly distinguish between the state where communication is possible and the state where communication is impossible. Instead, the data is converted once and output is biased when the intensity is high and when the intensity is low.
Such a configuration is effective in actual communication situations, and eliminating this mechanism itself not only impairs the function at the time of communication, but also requires a change in communication equipment, resulting in an increase in equipment cost. There is also a problem.

  Therefore, there has been a demand for a method capable of obtaining information corresponding to the radio wave intensity and performing highly accurate position detection using the existing wireless communication having such signal intensity output characteristics.

  An object of the present invention is to provide a position detection method and system capable of detecting a terminal position with high accuracy while using an existing wireless communication system with biased signal strength output.

In order to solve the above problems, the present invention provides the following terminal position detection method.
That is, according to the first aspect of the present invention, the signal strength output obtained at the base station when the signal from the terminal is received at the base station is a signal in which the actual signal strength is converted and biased to at least one of the magnitudes. This is a terminal position detection method using a wireless communication system in which intensity output is performed. In this method, a plurality of antennas having different positions are arranged, and attenuation processing of a plurality of different attenuation amounts is performed on the received signals received by all the antennas to obtain the signal strength output at each attenuation amount, and The relationship between the attenuation amount and the signal strength output at the antenna is compared with the result of measuring the relationship by installing the terminal in a plurality of positions in advance, and the position indicating the most approximate result is the current position of the terminal. Or it outputs as an existing area, It is characterized by the above-mentioned.

  According to a second aspect of the present invention, in the terminal position detection method according to the first aspect, the plurality of antennas are connected to the same base station, and the received signals from the respective antennas are sequentially switched in the base station. It is characterized in that the relationship between the attenuation amount and the signal strength output in each antenna is obtained.

  Further, in the invention according to claim 3, in any one of the above-described terminal position detection methods, the relationship between the attenuation amount and the signal intensity output at each antenna is expressed as (number of antennas × number of types of attenuation) dimension signal intensity. A configuration in which the position where the difference in vector quantity from the previously measured result expressed in the same vector data format is the smallest is output as the current location or area of the terminal. provide.

  According to a fourth aspect of the present invention, in the third aspect of the present invention, when the difference between the vector quantities is obtained, the Euclidean distance between the vectors is calculated, and the position where the Euclidean distance is minimized is determined as the current position of the terminal. It outputs as an existing position or existing area.

  The invention according to claim 5 is characterized in that the wireless communication system is a Bluetooth link.

In the present invention, the following terminal position detection system can also be provided.
That is, in the invention according to claim 6, the signal strength output obtained at the base station when the signal from the terminal is received by the base station is converted to the signal strength that is biased to at least one of the magnitudes by converting the actual signal strength. A terminal position detection system using a wireless communication system configured to output, a plurality of antennas having different positions, attenuation means capable of performing attenuation processing on received signals from each antenna with a plurality of attenuation amounts, and the attenuation Recording means for recording the signal strength output from the base station together with the attenuation amount for each antenna with respect to the received signal that passed through the means, and the relationship between the attenuation amount and the signal strength output for each antenna was measured by installing terminals in a plurality of positions in advance. The sample database provided with the result, the recorded value in the recording means, and the sample database are compared, and the position indicating the most approximate result is And a comparison output means for outputting a present position or existence region of the resident.

  A seventh aspect of the present invention is the terminal position detection system according to the sixth aspect, further comprising input switching means for connecting a plurality of antennas to the same base station and sequentially switching received signals from the respective antennas in the base station. It is characterized by that.

  According to the eighth aspect of the present invention, the relationship between the attenuation amount and the signal strength output in each antenna is expressed in the vector data format of the signal strength output in the dimension (number of antennas × number of types of attenuation amounts) and recorded in the recording means. At the same time, the sample database is also stored in the same vector data format, the calculation means for calculating the difference between the two vector quantities, and the position where the calculation result is the minimum as the current presence position or existence region of the terminal It outputs from a comparison output means.

According to the ninth aspect of the present invention, when calculating the difference between the vector quantities, the calculating means calculates an Euclidean distance between the vectors, and determines a position where the Euclidean distance is minimum as a current location of the terminal or The terminal position detection method according to claim 8, wherein the terminal position is output from the comparison output means as the existence area.
Moreover, based on invention of Claim 10, the said radio | wireless communications system can also provide the terminal location detection system which is a Bluetooth link.

The following effects are produced by the above invention. That is, according to the first and sixth aspects of the present invention, a relationship between the attenuation amount and the signal strength output can be obtained by performing attenuation processing of a plurality of attenuation amounts on the received signal. it can.
If the signal strength output suddenly decreases even with a small amount of attenuation, this indicates that the actual received signal strength is on the small side, and the signal strength output suddenly decreases for the first time when the amount of attenuation is large. Indicates that the actual received signal strength is on the large side. Due to these relationships, the received signal strength can be detected in a pseudo manner.

In addition, since the present system can be constructed with a simple configuration simply by adding an attenuator known as an attenuator, an existing communication system can be utilized, and the communication function can be used as before.
These systems contribute to the reduction of equipment costs and good maintainability.

  In the terminal position detection method / system according to claims 2 and 7, the establishment of a connection with the terminal can be completed only once by using one base station, which contributes to shortening of the detection time. That is, in this system, in order to communicate (measure signal strength) between a terminal and a plurality of antennas, if a base station is provided for each of the plurality of antennas, a connection is established for each communication with each antenna. There is a problem that the communication time becomes extremely long. In this regard, as a single base station, it is possible to establish a connection only once by switching only the antenna.

In the terminal position detection method / system according to claim 3 or 8, by using the vector data format, calculation is simple, and processing can be performed with a small storage capacity and calculation amount. In particular, as in the invention described in claim 4 or 9, the method using the Euclidean distance has a small amount of calculation and contributes to shortening of the position detection time.
Since the invention according to claim 5 or 10 is configured to use an existing Bluetooth link, the present invention can be carried out using a Bluetooth tag already mounted on a PDA or the like. By adopting a standardized communication system, the position can be detected regardless of the type of tag, so that the system can be generalized.

Hereinafter, embodiments of the present invention will be described based on examples shown in the drawings. The embodiment is not limited to the following.
FIG. 1 is an overall configuration diagram of a terminal position detection system according to the present invention. The terminal is, for example, a portable information terminal PDA (10) that incorporates a known Bluetooth module (11) so that Bluetooth can be used.

Then, four (2a), (2b), (2c) and (2d) Bluetooth antennas are installed in a predetermined space where position detection is performed, for example, in a certain room (1). The radix of the antenna is arbitrary and can be installed according to the size of the room, but it is desirable to install it with a sufficient interval.
Note that when the area for position detection is limited indoors, the antenna density near the area may be high, and the density may be low in other areas.

  In the present invention, a variable attenuator capable of attenuating the received signal from the antenna and freely changing the attenuation amount is provided in the base station (4). In FIG. 1, the base station is depicted outdoors, but the variable attenuator (3), the base station (4), and the position detection server (5) may be indoors or outdoors.

All signals from the antennas (2a) to (2d) are input to the same base station (4). A block diagram of the base station (4) is shown in FIG. The base station (4) is provided with an antenna switching unit (21) in addition to the access point (20) in the existing Bluetooth communication system. The variable attenuator (3) described above is arranged between the antenna switching (21) and the access point (20).
The configuration of the access point (20) is publicly known, and a signal input / output unit (24) that controls input / output of signals to / from the antenna, and a communication module that establishes communication and relays signals to other devices such as servers and clients. (22) A signal strength output unit (23) for notifying the connected device of the received signal strength is provided.

In the present invention, the antenna switching unit (21) is connected to the signal input / output unit (24) of the access point (20), and is switched according to an instruction from the position detection server (5) described later. Therefore, an antenna switching processing unit (25) capable of communicating with the position detection server (5) is provided, and when the antenna switching instruction signal is received, the switching circuit is operated to switch the connected antennas (2a) to (2d). It is configured.
With such a configuration, for example, in the case of a communication system that requires 3 seconds to establish a connection once, 12 seconds are conventionally required for four base stations, but this can be shortened to 3 seconds.

  FIG. 3 is a block diagram of the position detection server (5) according to the present invention. The position detection server (5) can be easily composed of a general personal computer, workstation, etc., and such a device is mainly composed of a CPU that performs information processing / arithmetic processing, and a memory (31) associated therewith. ), A hard disk (32), a monitor (33) for displaying a screen, a network adapter (34) for controlling communication functions, a printer (not shown), a keyboard / mouse, and the like.

  In the present invention, the CPU (30) connects the attenuators (3a) to (3d) and the network adapter (34) to the network, and the attenuation setting unit (35) sets the attenuator (3 ) Software control. As described above, an attenuator capable of setting an attenuation amount by external signal control is known.

At the same time, the attenuation setting unit (35) switches the antenna input to the antenna switching processing unit (25), and gives the condition of each attenuation to each antenna input. The recording unit (36) receives the set value of the attenuation setting unit (35) and the signal intensity from the signal intensity output unit (23) of the access point (20) and records them in the hard disk (32).
The data format obtained at this time is a set of signal intensity output values using the antenna number and attenuation as parameters, and can be represented by vector data of the number of dimensions of the number of antennas × attenuation types.

Here, the significance of changing the attenuation as described above will be described.
In a wireless communication system intended for communication at a very short distance, such as Bluetooth, when outputting the signal strength received at the access point, the actual RF level is not output as it is, but the RSSI (Received signal strength indicator). ) And output to the connected device.
Here, if the RF level and the RSSI value are linear, the connected device can estimate the distance from the terminal from the radio wave intensity and detect the position in the same manner as triangulation. 4 has the characteristics shown in FIG.

As is clear from the figure, the RSSI value is output as -10 as an unreceivable value until the RF level is near -70 dBm, and when it reaches -65 dBm, RSSI = 0 is output as the preferred reception range suddenly. This range is called Golden Received Power Range, and is converted so that 0 is output as much as possible in a communicable state in order to clearly communicate the state to the device side.
As a result of this conversion, on the device side, the communicable state and the impossible state are clearly distinguished, and the establishment of the Bluetooth link is facilitated.

On the other hand, since 0 is almost always output in the communicable state, the actual signal strength cannot be recognized on the device side, and in particular, the position detection method as described above cannot be used. Further, for example, when the antenna and the terminal are extremely close to each other such as several centimeters, the RSSI is larger than 0 and cannot be used for position detection.
According to the present inventors, these characteristics are still the same even if the disturbance of the Bluetooth signal is removed in an anechoic room, and it has been found that the problem cannot be cleared even by removing a disturbance such as multipath.

  Therefore, the present invention proposes to shift the RF level as shown in FIG. 5 by changing the attenuation using the attenuator (3).

  That is, the received signal received by the antenna is attenuated sequentially by the attenuator to 0 dB, −3 dB, −6 dB, and −9 dB. Then, as shown in FIG. 5, the characteristics of the RF level versus the RSSI value shift. In the case of (A) of 0 dB, the RSSI becomes 0 even at a low RF level, whereas the graph gradually shifts when the attenuation is increased, and in the case of (D) of −9 dB, the RF level is considerably strong. Otherwise, RSSI will not be zero.

  In this way, for example, when a signal having an RF level α is received by one antenna and a signal β is received by another antenna, RSSI = 0 in each of the conventional methods, and the signal strength cannot be distinguished. However, in this method, it is possible to distinguish between 0, 0 in the case of (B), -10, 0 in the case of (C), -10, -3 in the case of (D). become.

Expressed as the vector data described above, when α is the received signal strength at antenna 1 and β is at antenna 2,

It can be expressed as Equation 1. Such vector data is recorded on the hard disk (32) by the recording unit (36). In this embodiment, the number of antennas is four and the amount of attenuation is four, so 16-dimensional vector data is obtained.
Such data represents the radio wave intensity, but the present invention introduces a method for estimating which position is compared with sample data without using triangulation.

That is, terminals are arranged in advance in a plurality of locations in the room (1), the vector data at that time is collected, and the set of the position and data is stored in the hard disk (32) as a sample database.
Then, the arithmetic processing unit (37) of the CPU calculates the difference in vector quantity between the vector data measured this time and each vector data in the sample database.

Any method can be used as a method for obtaining the difference between the vector quantities. For example, the Euclidean distance between the two can be obtained. Alternatively, there is a method of simply adding absolute values of differences between components or multiplying a specific component by a weight.
When obtaining the Euclidean distance, it is calculated by adding all the squares of the differences between the components and obtaining the square root thereof as is well known.

The arithmetic processing unit (37) sequentially calculates the distance between the vector data of the sample database and the vector data of the measurement result, and selects the one with the smallest distance in the comparison output unit (38).
Then, the position corresponding to the vector data in the sample database is output from the monitor (33) or the like as the position of the terminal to be measured.

At this time, for example, the room (1) is divided into 3 × 3 squares in advance, and a terminal is installed at the central point of each square to collect sample data of nine areas. The configuration may be such that the result is output as an area.
Alternatively, if the sample database is constructed for each booth in the room without dividing the room equally, the position in each booth can be output, for example, near the television in the room, near the sofa, near the window, etc. it can.

Finally, in the laboratory (40) as shown in FIG. 6, a comparative experiment of position detection accuracy is performed when four antennas are installed on a ceiling with a height of 2 m and divided into nine areas of 1.75 m square. Show.
In the laboratory (40), a computer, a desk, a table, a large plasma display, a speaker, and the like are arranged, and three faces are surrounded by a wooden wall.

  Table 1 shows the position detection accuracy when the attenuator is varied as in the present invention and when it is attenuated by a certain amount without being varied (each 0, -3, -6, and -9 dB).

As shown in Table 1, the detection accuracy is as low as 38% when the conventional Bluetooth is not attenuated at all, and is improved to 72% when attenuated by -6 dB. However, this depends on the relationship between the measurement environment and the output of the terminal used, and does not indicate that −6 dB is optimal for general use.
On the other hand, when the amount of attenuation is made variable as in the present invention, the detection accuracy is increased to 92%, which is considered to be further improved by adjusting the number of installed antennas and the position.

As described above, the present invention can provide a variable attenuator between an antenna and a base station even in a wireless communication system in which the signal strength output is biased with respect to the actual signal strength as in Bluetooth. Position detection can be made possible by installing it in between.
Although the attenuator is freely variable by software, a plurality of attenuators with fixed attenuations may be switched in the same manner as the antenna switching to measure other types of attenuation. According to the said structure, although an attenuator can be comprised by one, you may install an attenuator for every antenna.

In addition to the measurement of the planar position as in this embodiment, the antennas can be distributed and arranged in three dimensions to measure the positions in three dimensions. Even in that case, it can be expressed in the vector data format.
The number of antennas and attenuators installed and the number of types of attenuation in the attenuators can be arbitrarily set.

  1 is an overall configuration diagram of a terminal position detection system according to the present invention.   It is a block diagram of the base station which concerns on this invention.   It is a block diagram of the position detection server which concerns on this invention.   It is a graph which shows the characteristic of RF level versus RSSI value.   It is explanatory drawing which shows the principle of the characteristic shift which concerns on this invention.   It is a top view of the test chamber which performed the test by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Indoor 2a-2d Antenna 3 Variable attenuator 4 Base station 5 Position detection server

Claims (10)

A radio communication system in which a signal strength output obtained at a base station when a signal from a terminal is received by the base station is converted to an actual signal strength and output to a signal strength biased to at least one of large and small A terminal position detection method to be used,
Arrange multiple antennas with different positions,
Attenuation processing of a plurality of different attenuation amounts is performed on reception signals received by all antennas, and the above signal strength output at each attenuation amount is obtained, and
Compare the relationship between the amount of attenuation and the signal strength output in each antenna with the result of measuring the relationship by installing terminals in a plurality of positions in advance,
A terminal position detection method, comprising: outputting a position indicating the most approximate result as a current presence position or existence region of the terminal. In the terminal position detection method,
Connecting the plurality of antennas to the same base station;
The terminal position detection method according to claim 1, wherein the base station obtains the relationship between the attenuation and the signal strength output at each antenna by sequentially switching received signals from the respective antennas. In the terminal position detection method,
The relationship between the amount of attenuation and the signal strength output at each antenna is expressed in the vector data format of the signal strength output in the dimension (number of antennas × number of types of attenuation), and the previously measured result expressed in the same vector data format 3. The terminal position detection method according to claim 1, wherein a position where a difference in vector amount between the first terminal and the second terminal is a minimum is output as a current position or area of the terminal. The Euclidean distance between vectors is calculated when the difference between the vector quantities is obtained, and the position where the Euclidean distance is minimized is output as the current presence position or existence region of the terminal. The terminal position detection method according to claim 1. The terminal position detection method according to claim 1, wherein the wireless communication system is a Bluetooth link. A radio communication system in which a signal strength output obtained at a base station when a signal from a terminal is received by the base station is converted to an actual signal strength and output to a signal strength biased to at least one of large and small A terminal position detection system to be used,
Multiple antennas in different positions,
Attenuating means capable of attenuating each received signal from each antenna with a plurality of attenuation amounts;
Recording means for recording the signal strength output from the base station together with the amount of attenuation for the received signal that has passed through the attenuation means;
A sample database with results of measuring the relationship between attenuation and signal strength output for each antenna by installing terminals in a plurality of positions in advance,
Comparison output means for comparing the recorded value in the recording means with the sample database and outputting the position indicating the closest approximation as the current location or area of the terminal. Terminal position detection system. In the terminal position detection system,
Connecting the plurality of antennas to the same base station;
The terminal position detection system according to claim 6, further comprising input switching means for sequentially switching received signals from the antennas in the base station. In the terminal position detection system,
The relationship between the amount of attenuation and the signal strength output at each antenna is represented in the recording means in the form of a vector data format of (number of antennas × number of types of attenuation) dimension signal strength, and the sample database has the same vector. Store it in data format,
A computing means for computing the difference between the two vector quantities;
The terminal position detection system according to claim 6 or 7, wherein the position where the calculation result is minimum is output from the comparison output means as the current presence position or existence region of the terminal. When calculating the vector amount difference, the computing means calculates the Euclidean distance between the vectors, and outputs the position at which the Euclidean distance is minimum as the current presence position or existence area of the terminal from the comparison output means. The terminal position detection system according to claim 8. The terminal position detection system according to any one of claims 6 to 9, wherein the wireless communication system is a Bluetooth link.

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