JP6534641B2 - Monitoring method, monitoring system, monitoring apparatus and monitoring program - Google Patents

Description

  The present invention relates to a monitoring method, a monitoring system, a monitoring device and a monitoring program.

  With the increase of mobile communication terminals such as smartphones and tablet terminals, an increase in traffic at a base station and the like are estimated. In order to cope with the increase of traffic etc. in the future wireless communication system, the technology of heterogeneous wireless networks performing wireless communication in a plurality of frequency bands has attracted attention. For example, as a next-generation cellular radio system, using a technology of heterogeneous radio network, a radio network using a relatively low frequency band (low frequency band) capable of securing planar coverage can be used as a high frequency band (high frequency band) A technology for overlaying a band has been proposed.

  A relatively wide frequency band can be used in a high frequency band (for example, 20 GHz band, 30 GHz band, 60 GHz band, etc. in a frequency band of 6 GHz or more), and therefore, a large capacity can be realized. Further, by densely arranging the base stations, further increase in capacity can be realized. Thus, it is possible to accommodate traffic in an area (high traffic area) where a large amount of traffic occurs.

  However, radio waves in the high frequency band are larger in attenuation of distance and shielding loss by shielding bodies such as a human body than in the low frequency band, and the shielding loss is a major problem in a wireless communication system. It is known that a large propagation loss is caused when a non-Line of Sight (NLoS) environment is caused by a shield. Further, in the small cell, the coverage area is narrow, and the shielding loss due to a human body such as a user in the area or a shielding object such as a car changes, and the influence on the wireless communication system becomes large. In this case, the shield in the area causes the deterioration of the radio wave intensity and degrades the reception quality of the user's mobile communication terminal. Particularly in a high traffic area, the number of human bodies such as users is expected to be large, and shielding loss due to a plurality of human bodies (hereinafter also referred to as “crowd”) is also a major cause of deterioration in reception quality. As described above, as the frequency band to be used becomes higher, the factor that degrades the reception quality increases. In addition, since the user does not know the deterioration factor, the quality of wireless communication experienced by the user (hereinafter, also referred to as “experience quality”) is degraded.

  Therefore, it is desirable to monitor a factor that degrades the reception quality in the area, to improve the reception quality based on the result of the monitoring, and to improve the quality of experience of the user. In addition, it is desirable for the communication carrier to be able to grasp the factors that degrade the reception quality and the user's perceived quality in maintenance and operation of the wireless network.

  As a method for estimating reception quality degradation, a ray tracing technique has been proposed that estimates propagation loss, propagation delay, arrival angle of radio waves, etc. in a wireless communication system, taking into consideration the influence of topography, buildings, etc. (See, for example, Non-Patent Document 1). In addition, by detecting a person using a depth image and associating and learning the state of the person in the depth image and the throughput of the wireless communication at that time, the throughput of wireless communication is obtained from the state of the person reflected in the depth image. A technique for estimating has been proposed (see, for example, Non-Patent Document 2).

Tetsuro Imai, Makoto Sumi, Tokio Taga, "A System for Estimating Macrocell Propagation in Urban Area Using Ray Tracing Method", NTT DoCoMo Technical Journal, vol. 12, no. 1, 2009 Hirotoshi Okamoto, Rishi Nishio, Masahiro Morikura, Koji Yamamoto, "Throughput estimation from depth images using on-line machine learning for millimeter wave communication control", SR 2015-96, 2016

  In the prior art, although degradation in reception quality can be detected, it is difficult to identify the factor causing degradation in reception quality. For example, in Non-Patent Document 1, it is possible to estimate the reception quality of the user's mobile communication terminal by estimating the propagation loss, but it is possible to use a crowd, a car, etc. existing between the user's mobile communication terminal and the base station. It is necessary to obtain in advance information indicating a shield. However, the presence or absence and the position of the shield change with time. For this reason, in the prior art, it is difficult to estimate the propagation loss while acquiring information on a shield that changes with time, and to specify in real time the factor that degrades the reception quality.

  In Non-Patent Document 2, the deterioration of the throughput of wireless communication is predicted from the state of the person in the depth image based on learning when one person periodically moves in a predetermined manner. However, each of the crowd including the user of the mobile communication terminal moves in a different irregular manner, and it is necessary to compare the status of each crowd in the depth image with the throughput of the wireless communication in comparison with the case of one person. Requires a long learning period, and the amount of processing also increases. In addition, in actual wireless communication, not only the crowd but also the movement of a shielding object such as a car needs to be considered, and the learning period is further extended and the processing amount is also increased.

  An object of the present invention is to monitor, for each mobile communication terminal, a factor that degrades the reception quality in wireless communication without increasing the processing amount.

According to a first aspect of the present invention, there is provided an acquisition step of acquiring surrounding information indicating a surrounding condition in a base station performing wireless communication with a terminal device, and terminal information indicating a state of the terminal device via the base station. And a monitoring step of monitoring whether there is a factor that degrades the quality of wireless communication between the base station and the terminal device using the received step of receiving from the received ambient information and the received terminal information. The control step of determining the control content for the base station based on the monitoring result in the monitoring step, and the control step of controlling the base station with the control content determined in the determination step; If it is determined that a factor exists, the total number of terminal devices whose quality has degraded due to the factor or the number of degraded terminals that is the total number per unit time, the factor is present Depending on the degradation quality which is the average value or median value of the quality of the case, the degradation period which is the period during which the quality degradation continues due to the factor, and the improvement difficulty level indicating the difficulty to improve the quality degradation due to the factor that determine the control contents Te.

  In a second aspect based on the first aspect, when the monitoring step is executed based on a request for monitoring by the terminal device, the method further comprises a notifying step of notifying the terminal device of a result of the monitoring.

A third invention is an imaging device for imaging the periphery of a base station performing wireless communication with a terminal device, an acquisition unit for acquiring an image from the imaging device as ambient information indicating a surrounding condition in the base station, and a terminal The quality of wireless communication between the base station and the terminal device is calculated using the receiving unit that receives terminal information indicating the state of the device from the terminal device via the base station, and the acquired image and the received terminal information. A monitoring unit that monitors whether or not there is a deterioration factor; and a control unit that determines the control content for the base station based on the monitoring result of the monitoring unit and controls the base station with the determined control content. If the control unit determines that there is a factor in the monitoring unit, the control unit is the total number of terminal devices whose quality has been degraded due to the factor or the number of degraded terminals per unit time, and the factor is Item when it exists Control content according to the degradation quality which is the average value or the median value, the degradation period which is the period when the degradation of quality continues due to the factor, and the improvement difficulty showing the degree of difficulty to improve the degradation of quality due to the factor you decide.

A fourth invention relates to an acquisition unit for acquiring ambient information indicating a surrounding situation in a base station that performs wireless communication with a terminal device, and terminal information indicating a state of the terminal device via the base station And a monitoring unit that monitors whether there is a factor that degrades the quality of wireless communication between the base station and the terminal device using the reception unit received from the terminal and the acquired ambient information and the received terminal information The control unit determines the control content for the base station based on the monitoring result in the monitoring unit, and includes a control unit that controls the base station with the determined control content, and the control unit determines that the monitoring unit has a factor In this case, the total number of terminal devices whose quality has degraded due to the factor or the number of degraded terminals that is the total number per unit time, the degradation quality being the average value or median of the quality when the factor exists, the quality according to the factor Deterioration of continues Deterioration period is that period, and that determine the control content in accordance with the improvements difficulty indicating the difficulty to improve the deterioration of the quality due to the factors.

A fifth invention is a monitoring program which causes a computer to operate as the monitoring device of the present invention.

  The present invention can monitor, for each mobile communication terminal, a factor that degrades the reception quality in wireless communication without increasing the processing amount.

FIG. 1 illustrates an embodiment of a wireless communication system. It is a figure which shows an example of the user terminal shown in FIG. 1, a base station, and an analysis apparatus. It is a figure which shows an example of the image imaged with the camera shown in FIG. It is a figure which shows an example of the factor table shown in FIG. It is a figure which shows an example of the monitoring process in the analysis apparatus shown in FIG. It is a figure which shows another example of the monitoring process in the analysis apparatus shown in FIG. It is a figure which shows another example of the user terminal, base station, and analysis apparatus which were shown in FIG. It is a figure which shows an example of the monitoring process in the analysis apparatus shown in FIG. It is a figure which shows an example of the process in step S135 shown in FIG. It is a figure which shows another example of the monitoring process in the analyzer shown in FIG.

  Hereinafter, embodiments will be described using the drawings.

  FIG. 1 illustrates one embodiment of a wireless communication system.

  The radio communication system SYS shown in FIG. 1 includes a control station CT, two base stations 100 (100 (1), 100 (2)), and six user terminals UT (UT (1) -UT (6)). Have. The wireless communication system SYS may have two or more base stations 100. The wireless communication system SYS may also have a plurality of user terminals UT other than six.

  The control station CT is connected to the base station 100 and the external network NW via a wired or wireless connection. Also, the base station 100 is connected to the user terminal UT via radio.

  The control station CT is a computer device including an arithmetic processing device such as a processor and a storage device such as a hard disk device. The control station CT controls the operation of the base station 100 in order to transmit data between the user terminal UT and the network NW. The control station CT may be connected to the base station 100 via the network NW or a network different from the network NW.

  Further, the control station CT has an analysis device 200 (200 (1), 200 (2)). For example, the arithmetic processing unit of the control station CT functions as the analysis device 200 by executing the monitoring program stored in the storage device. The analysis device 200 may be realized by hardware mounted on the control station CT.

  The analysis apparatus 200 monitors, in the base station 100 to be monitored, whether there is a factor that degrades the quality in wireless communication with the user terminal UT, around the base station 100. The operation of the analysis device 200 will be described with reference to FIG. Note that one analysis device 200 may monitor two base stations 100 (1) and 100 (2). Further, instead of being disposed at the control station CT, the analysis apparatus 200 may be disposed at the base station 100 to be monitored and transmit the result of monitoring to the control station CT. The analysis device 200 is an example of a monitoring device.

  The base stations 100 (1) and 100 (2) are, for example, access points and cellular base stations. Each of base stations 100 (1) and 100 (2) performs wireless communication with user terminal UT in cell area AR 1 or cell area AR 2 via an antenna included in base station 100. When the radio communication system SYS includes two or more base stations 100, the cell area of each base station 100 preferably overlaps the cell area of the adjacent base station 100. The operation of the base station 100 will be described with reference to FIG.

  Further, in each base station 100, a camera CAM (CAM1, CAM2) is disposed. The camera CAM is, for example, a digital camera, and includes a lens and an imaging device such as a charge-coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS). The camera CAM images the periphery of the deployed base station 100 (that is, the cell area AR1 or the cell area AR2) and generates an image of the periphery of the base station 100. Then, the camera CAM transmits the generated image to the analysis apparatus 200 via the base station 100. The camera CAM is an example of an imaging device, and an image is an example of ambient information indicating the situation around the base station 100.

  That is, as a monitoring system that monitors whether there is a factor that degrades the quality of wireless communication with the user terminal UT, around the base station 100 in the wireless communication system SYS, the analysis device 200 and the camera CAM. Operate.

  The camera CAM may be disposed at a different location (for example, the roof of a building, etc.) different from the base station 100 which can overlook the entire cell area AR1 and the entire cell area AR2.

  In addition, the camera CAM preferably has a storage unit such as a buffer for temporarily storing a captured image, and an interface for outputting the image to the outside of the base station 100 or the like.

  Further, the camera CAM is disposed on the base station 100 while being mounted on a turntable or the like in order to capture the surroundings of the base station 100, and the surroundings of the base station 100 are arranged at predetermined angles such as 30 degrees and 45 degrees. May be imaged to generate a plurality of images. In this case, the camera CAM transmits the generated plurality of images to the analysis apparatus 200 as an image indicating the situation around the base station 100. Alternatively, a plurality of cameras CAM may be disposed in the base station 100, and may image the periphery of the base station 100, respectively. In this case, the plurality of cameras CAM transmit the captured images to the analysis apparatus 200 as an image indicating the situation around the base station 100.

  The user terminal UT is a mobile communication terminal such as a smartphone or a tablet type terminal, and performs wireless communication with the base station 100 (1) or the base station 100 (2) according to the position of the user terminal UT. The user terminal UT (4) shown in FIG. 1 is in a position where the cell areas AR1 and AR2 overlap each other. Therefore, the user terminal UT (4) can wirelessly communicate with both of the base stations 100 (1) and 100 (2). It is controlled by the base station 100 based on the received signal power of electromagnetic waves from each base station 100, the throughput with each base station 100, etc. which user station UT (4) performs wireless communication with which base station 100. Be done. The user terminal UT is an example of a terminal device.

  FIG. 2 shows an example of the user terminal UT, the base station 100 and the analysis device 200 shown in FIG.

  The user terminal UT (1) includes antennas ANT1a and ANT1b, a first transmission / reception unit 10, a control unit 20, a position acquisition unit 30, a storage unit 40, and a second transmission / reception unit 50. The user terminals UT (2) -UT (6) have the same elements as the user terminal UT (1).

  The first transmission / reception unit 10 receives an electromagnetic wave of a data signal including data transmitted from the base station 100 (1) via the antenna ANT1a. Then, the first transmission / reception unit 10 demodulates the electromagnetic wave of the received data signal based on the transmission parameters such as the modulation / demodulation scheme or the error correction coding scheme set in the user terminal UT (1), and demodulates it. The output data signal is output to the control unit 20. In addition, for example, when a data signal is received via the control unit 20, the first transmission / reception unit 10 performs modulation processing based on the set transmission parameter, and generates an electromagnetic wave of the data signal. The first transmission / reception unit 10 transmits the generated electromagnetic wave of the data signal to the base station 100 (1).

  On the other hand, the second transmission / reception unit 50 receives an electromagnetic wave of a control signal including a control instruction from the base station 100, the control station CT or the analysis device 200 via the antenna ANT1b. Then, the second transmission / reception unit 50 performs demodulation processing on the electromagnetic wave of the received control signal based on the set transmission parameter, and outputs the demodulated control signal to the control unit 20. In addition, the second transmission / reception unit 50 determines the position of the user terminal UT (1) acquired by the position acquisition unit 30 based on the control instruction from the base station 100 (1) or the like based on the set transmission parameter. The modulation process is performed with the identification information for identifying the user terminal UT (1) to generate the control signal. The second transmission / reception unit 50 transmits the generated control signal to the base station 100 (1).

  The frequency of the electromagnetic wave of the control signal transmitted and received by the second transmission / reception unit 50 is preferably different from the frequency of the electromagnetic wave transmitted / received by the first transmission / reception unit 10. When the frequencies of the electromagnetic wave of the control signal and the electromagnetic wave of the data signal are the same, the first transmission / reception unit 10 may have the function of the second transmission / reception unit 50, and the antenna ANT1b may be omitted.

  Control unit 20 is realized, for example, by a processor or the like included in user terminal UT (1) executing a program stored in storage unit 40 such as a memory, and controls the operation of user terminal UT (1). . For example, when the received signal is a control signal, the control unit 20 acquires a control instruction from the base station 100 (1), the control station CT, or the analysis device 200. When the control instruction instructs acquisition of position information of the user terminal UT (1), the control unit 20 causes the position acquisition unit 30 to acquire position information of the user terminal UT (1) based on the acquired instruction. Then, the control unit 20 outputs the position information acquired by the position acquisition unit 30 to the second transmission / reception unit 50 together with the identification information of the user terminal UT (1).

  Further, for example, when the received signal is a data signal, the control unit 20 displays the received data on a display unit such as a liquid crystal monitor included in the user terminal UT (1). Alternatively, when the control unit 20 receives an input instruction from the user via the input unit such as a touch panel included in the user terminal UT (1), the control unit 20 transmits or receives data specified by the received input instruction or the input instruction. Output to section 10.

  In addition, the control unit 20 may function as a quality measurement unit that measures reception quality using, for example, a data signal received via the antenna ANT1a and the first transmission / reception unit 10. The reception quality measured by the control unit 20 includes, for example, received signal power of an electromagnetic wave of a data signal, interference signal power, signal to noise ratio (SNR: Signal to Noise Ratio), signal to interference and noise ratio (SINR: Signal to Interference) and noise ratio) and throughput. Then, the control unit 20 stores the measured reception quality in the storage unit 40, for example, to calculate the average value or the median value of the reception quality measured in a fixed period. Alternatively, the control unit 20 may calculate the reception quality using the reception quality stored in the storage unit 40 and the equation (1).

γ = δ ₀ + δ ₁ (1-β) + δ ₂ β (1-β) + δ ₃ β ² (1-β) + ... + δ _T β ^T-1 (1-β) (1)
Here, γ is the reception quality actually used, δt is the reception quality measured before t measurements, and β is the forgetting factor. That is, equation (1) shows an example of calculation using reception quality measured T times ago. Then, the reception quality γ at the time of measurement is temporarily calculated by taking into consideration the reception quality measured in the past while emphasizing the reception quality measured most recently using Equation (1). Even if it is degraded or improved, it can be obtained with a stable value.

  Then, the control unit 20 transmits the measurement result, together with the position information and the identification information, to the base station 100 (1) or the like.

  When the control signal received from base station 100 instructs to measure the reception quality, control unit 20 may measure the reception quality using the received control signal.

  For example, when the control unit 20 receives a control signal instructing measurement of reception quality, the position acquisition unit 30 receives a signal from a GPS (Global Positioning System) satellite via the antenna ANT1a or the antenna ANT1b. Then, the position acquisition unit 30 detects the position of the user terminal UT (1) from the received signal, and acquires it as position information. The position acquisition unit 30 may receive GPS satellite signals at any timing set in the user terminal UT (1) to acquire position information. Then, the position acquisition unit 30 outputs the acquired position information to the control unit 20. Then, the control unit 20 outputs the received position information to the second transmission / reception unit 50 together with the information indicating the measured reception quality and the identification information of the user terminal UT (1), and the second transmission / reception unit 50 receives the antenna ANT1b. Control signal including information on reception quality, position information, and identification information to the base station 100 (1). Hereinafter, the information on the reception quality, the position information and the identification information are also referred to as "terminal information".

  The position acquisition unit 30 may acquire the position information of the user terminal UT (1) using a Quasi-Zenith Satellite System (QZSS) or an indoor messaging system (IMES). In addition, the position acquisition unit 30 transmits an electromagnetic wave emitted from an access point of Wi-Fi (Wireless Fidelity) (registered trademark), an electromagnetic wave emitted from the base station 100, or communication such as iBeacon (registered trademark) or Bluetooth (registered trademark). Position information of the user terminal UT (1) may be acquired using a beacon signal or the like based on the standard. Also, from the positioning performed by causing the microphone or the like included in the user terminal UT (1) to receive an ultrasonic wave, or the positioning performed by transmitting information such as data by causing the LED or the like to blink, the position acquisition unit 30 The position information of the user terminal UT (1) may be acquired.

  In addition, the position acquisition unit 30 performs a matching process on an image obtained by imaging a periphery of the user terminal UT (1) by a camera included in the user terminal UT (1) with an image formed in advance in a database. The position information of the terminal UT (1) may be acquired. Further, the position acquisition unit 30 executes a matching process between information of height difference detected using the barometric pressure sensor included in the user terminal UT (1) and information of height difference in a specific route made into a database in advance. Thus, position information of the user terminal UT (1) may be acquired. In addition, the position acquisition unit 30 is a user based on the measurement result of the moving direction or speed measured by the acceleration sensor, the gyro sensor or the geomagnetic sensor included in the user terminal UT (1), or a combination of a plurality of measurement results and the like. The position information of the terminal UT (1) may be acquired.

  The storage unit 40 is a memory or the like, and stores programs executed by the processor or the like of the user terminal UT (1), identification information of the user terminal UT (1), and data such as reception quality measured by the control unit 20. .

  Next, the base station 100 (1) has antennas ANT2a and ANT2b, a first transmission / reception unit 110, a second transmission / reception unit 120, a control unit 130, and an IF (Interface) unit 140. Base station 100 (2) has the same elements as base station 100 (1).

  The antennas ANT2a and ANT2b are, for example, antennas having one or more beams covering the cell area AR1 shown in FIG. The antennas ANT2a and ANT2b adjust radio parameters such as beam width, direction, and tilt angle based on a control instruction from the control unit 130. Note that the wireless parameters also include transmission signal power and the like at which the first transmission / reception unit 110 and the second transmission / reception unit 120 transmit electromagnetic waves.

  The first transmission / reception unit 110 receives a data signal including data transmitted from the user terminal UT via the antenna ANT2a. The first transmission / reception unit 110 down-converts the received data signal, and performs demodulation processing on the received data signal based on the transmission parameter set in the user terminal UT. The first transmission / reception unit 110 outputs the demodulated data signal to the control unit 130. Further, the first transmission / reception unit 110 modulates the data signal including the data addressed to the user terminal UT based on the transmission parameter set in the user terminal UT, and transmits the electromagnetic wave of the modulated data signal to the user terminal UT Do.

  The second transmission / reception unit 120 receives a control signal including identification information of the user terminal UT, position information, terminal information of reception quality and the like transmitted from the user terminal UT. The second transmission / reception unit 120 downconverts the received control signal, and executes demodulation processing on the received control signal based on the transmission parameter set in the user terminal UT. The second transmission / reception unit 120 outputs the demodulated control signal to the control unit 130. Further, second transmission / reception unit 120 modulates a control signal including a control instruction of control unit 130 for user terminal UT based on a transmission parameter set in user terminal UT, and modulates the control signal to user terminal UT. Send to

  The frequency of the electromagnetic wave of the control signal transmitted and received by the second transmission / reception unit 120 is preferably different from the frequency of the electromagnetic wave transmitted / received by the first transmission / reception unit 110. When the frequencies of the electromagnetic wave of the control signal and the electromagnetic wave of the data signal are the same, the first transmission / reception unit 110 may have the function of the second transmission / reception unit 120, and the antenna ANT2b may be omitted.

  The control unit 130 is realized, for example, by a processor or the like included in the base station 100 (1) executing a program stored in a storage device such as a memory included in the base station 100 (1). Control the operation of (1). For example, the control unit 130 outputs the received data signal and control signal to the control station CT via the IF unit 140.

  Further, the control unit 130 controls the beam width and the like of the antennas ANT2a and ANT2b based on the control instruction of the wireless parameter received from the analysis apparatus 200 (1) via the IF unit 140, and position in the cell area AR1. Improve the reception quality for the user terminal UT.

  The IF unit 140 is an input / output interface or the like, and communicates with the control station CT. In addition, the IF unit 140 is connected to the camera CAM1 via a wired or wireless connection. Then, for example, when the control signal received from the control station CT is an imaging instruction for the camera CAM1, the IF unit 140 outputs the received control signal to the camera CAM1 based on the control instruction of the control unit 130. The IF unit 140 outputs an image around the base station 100 captured by the camera CAM1 to the control station CT.

  The base station 100 (1) may have a network interface for connecting to a network such as the network NW. In this case, the base station 100 (1) may communicate with the control station CT via the network interface.

  Also, the camera CAM 1 is connected to the control station CT via the IF unit 140, but may be directly connected to the control station CT via wire or wireless, and is connected to the control station CT via the network NW etc. May be

  Next, the control station CT is a computer device having an arithmetic processing unit and a storage device. For example, when the arithmetic processing unit of the control station CT executes the monitoring program stored in the storage device, two processing units including the IF unit 210, the network IF unit 220, the control unit 230, the monitoring unit 240 and the storage unit 250 are provided. It functions as the analysis device 200. The analysis device 200 (2) has the same elements as the analysis device 200 (1). The IF unit 210, the network IF unit 220, the control unit 230, the monitoring unit 240, and the storage unit 250 included in the analysis apparatus 200 may be realized by hardware mounted on the control station CT.

  The IF unit 210 is an input / output interface or the like, and communicates with the base station 100 (1). The IF unit 210 receives, for example, a control signal including terminal information and the like transmitted by the user terminal UT from the base station 100 (1), and a data signal. Then, the IF unit 210 outputs the received control signal and data signal to the control unit 230. In addition, IF unit 210 transmits a control signal including a control instruction of control unit 230 to user terminal UT or base station 100 (1) or a data signal addressed to user terminal UT received through network IF unit 220, as a base station. Output to 100. The IF unit 210 is an example of an acquisition unit and a reception unit.

  The network IF unit 220 is a network interface or the like, and communicates with the network NW. Also, the network IF unit 220 may transmit and receive control signals and data signals to and from the base station 100 (1) via the network NW. In this case, the network IF unit 220 is another example of an acquisition unit and a reception unit.

  The control unit 230 controls, for example, the operation of the analysis device 200 (1). For example, when the data signal is received from the user terminal UT, the control unit 230 refers to the information indicating the transmission destination stored in the header or the like included in the received data signal, and transmits the transmission destination via the network IF unit 220. Transfer the data signal to the network NW for transmission to the network NW. Further, the control unit 230 receives, via the network IF unit 220, a data signal addressed to the user terminal UT wirelessly communicating with the base station 100 (1) from the network NW.

  In addition, for example, the control unit 230 outputs a control signal for acquiring terminal information of each of the user terminals UT wirelessly communicating with the base station 100 (1) to each of the user terminals UT via the IF unit 210. . Then, control unit 230 receives a control signal including terminal information from each of user terminals UT, stores the received terminal information of each user terminal UT in storage unit 250, and outputs it to monitoring unit 240.

  In addition, the control unit 230 outputs, for example, a control signal for acquiring an image indicating the situation around the base station 100 (1) to the camera CAM 1 via the IF unit 210. Then, the control unit 230 receives an image captured by the camera CAM1 via the base station 100 (1), and outputs the received image to the monitoring unit 240. The control unit 230 outputs the control instruction of the wireless parameter to the base station 100 (1) using the result of the monitoring process by the monitoring unit 240 and the terminal information of each user terminal UT.

  The monitoring unit 240 uses the image captured by the camera CAM1 and the terminal information of each user terminal UT wirelessly communicating with the base station 100 (1) to wirelessly communicate between the base station 100 (1) and each user terminal UT. Monitor whether there is a factor that degrades the quality of communication. The operation of the monitoring unit 240 will be described with reference to FIG.

  The storage unit 250 is a hard disk drive or a memory. The storage unit 250 stores a program including a control program and a monitoring program executed by the processing unit of the control station CT, terminal information of each user terminal UT wirelessly communicating with the base station 100 (1), and a factor table FT. .

  The monitoring program may be distributed, for example, by being recorded on a portable storage medium such as an optical disc such as a DVD (Digital Versatile Disc) or a USB (Universal Serial Bus) memory. Alternatively, the monitoring program may be downloaded through the network such as the network NW via the network IF 220 and stored in the storage unit 250.

  FIG. 3 shows an example of an image captured by the camera CAM1 shown in FIG. As shown in FIG. 3, the user USR of the user terminal UT (1), the building OBJ1, and the car OBJ2 appear in the image IMG showing the situation around the base station 100 (1).

  For example, the monitoring unit 240 may use position information included in terminal information of each user terminal UT, base station information indicating a position where the base station 100 (1) is disposed, and an imaging direction of the image IMG captured by the camera CAM1. The position IP of the user terminal UT (1) on the image IMG is obtained using the imaging information indicating the position and the information indicating the height at which the camera CAM 1 is installed at the base station 100 (1). The base station information of the base station 100 (1) and the information of the height at which the camera CAM 1 is installed in the base station 100 (1) are stored in advance in the storage unit 250.

  Further, imaging information such as an imaging direction in which the image IMG is imaged is added to the image IMG based on, for example, a format such as Exif (Exchangeable image file format). Note that the imaging direction of the image IMG shown in FIG. 3 (that is, the optical axis direction of the camera CAM1) is the center IC of the image IMG.

  For example, the monitoring unit 240 extracts an image area IA of a predetermined size centering on the obtained position IP of the user terminal UT from the image captured by the camera CAM1. In FIG. 3, the image area IA is indicated by a dashed rectangle. Then, the monitoring unit 240 performs the correlation process using the extracted image area IA and a template image respectively indicating the building OBJ1 or the car OBJ2 or the like that may cause deterioration of the reception quality. The monitoring unit 240 determines whether there is a template image for which the calculated correlation coefficient is equal to or greater than a predetermined value. The monitoring unit 240 performs wireless communication between the base station 100 (1) and the user terminal UT in the extracted image area (that is, around the user terminal UT) when there is no template image whose correlation coefficient is equal to or more than a predetermined value. It is judged that there is no shield (factor) to be deteriorated.

  If there is no template image for which the correlation coefficient is equal to or more than a predetermined value, the monitoring unit 240 may determine that the cause is “other”. In this case, it is preferable that the control unit 230 not output the control instruction of the wireless parameter to the base station 100 (1).

  On the other hand, when there is a template image in which the correlation coefficient is equal to or more than a predetermined value, the monitoring unit 240 detects that the shielding object such as the building OBJ1 whose correlation coefficient indicates a predetermined value or more is present in the extracted image area. It is determined that it exists between (1) and the user terminal UT.

  In the case of the image IMG shown in FIG. 3, since the building OBJ1 and the car OBJ2 are not between the base station 100 (1) and the user terminal UT, the monitoring unit 240 selects the base station 100 (1) and the user terminal UT. It is determined that there is no shield that degrades the wireless communication with (1).

  Then, for example, each user who wirelessly communicates with the base station 100 (1) in association with time information indicating the monitored time and the distance and direction with the base station 100 (1) at the monitored time. The result of monitoring of the terminal UT is stored in the storage unit 250. The monitoring unit 240 also stores the result of monitoring in the factor table FT stored in the storage unit 250. The factor table FT will be described with reference to FIG.

  A template image of a crowd, a building, a car or the like is stored in advance in the storage unit 250. In addition, it is preferable that the size of the image area IA extracted by the monitoring unit 240 be appropriately set in accordance with a crowd, a building or a shielding object such as a car.

  FIG. 4 shows an example of the factor table FT shown in FIG. The factor table FT has a plurality of entries including a factor area, an area of deterioration period, an area of improvement difficulty level, an area of a template image, an area of deterioration quality, and an area of the number of deteriorated terminals.

  In the area of the factor, names of a crowd such as a building (outdoor), a building (indoor), a car, etc. which degrades the reception quality are stored. The building (outdoor) and the building (indoor) indicate whether the user terminal UT is outside or inside the building, respectively. In the area of the factor, a shield corresponding to the type of a building or a car may be stored, such as a house, a high-rise building, or a passenger car or a truck.

  In the area of the degradation period, a period in which the degradation of the reception quality in the user terminal UT by the shield stored in the factor region is continued is stored. For the period stored in the degradation period area, for example, a fixed value based on the experience of the communication carrier may be stored, or an arbitrary value may be stored first and updated appropriately by the monitoring unit 240 . Further, in the area of improvement difficulty level, information indicating the degree of difficulty for improving the deterioration of the reception quality due to the shield stored in the area of the factor is stored. The difficulty level stored in the area of the improvement difficulty level may be, for example, a fixed value corresponding to the processing capability of the wireless communication in the base station 100 or the like, and an arbitrary value is stored first and the monitoring unit 240 May be updated as appropriate.

  In the area of the template image, data of the template image indicating the shield stored in the area of the factor is stored. In the area of the template image, the address of the storage unit 250 in which the data of the template image is stored may be stored instead of the data of the template image. Also, the monitoring unit 240 uses the reception quality information included in the terminal information of the user terminal UT and the monitoring result as a feature depending on the location of the base station 100 in the degradation quality area. The average value or the median value of the reception quality calculated for each shielding stored in the area of is stored.

  In the area of the number of degraded terminals, the monitoring unit 240 uses the reception quality information included in the terminal information of the user terminal UT and the monitoring result as a feature depending on the location where the base station 100 is arranged. The total number of user terminals UT whose reception quality has deteriorated or the total number per unit time calculated for each shielding stored in the area is stored.

  Then, the control unit 230 wirelessly improves the reception quality of the wireless communication between the base station 100 (1) and the user terminal UT based on the monitoring result by the monitoring unit 240 and the factor table FT shown in FIG. The control instruction of the parameter is output to the base station 100 (1) via the IF unit 210.

  FIG. 5 shows an example of monitoring processing in the analysis apparatus 200 shown in FIG. For example, the processing from step S100 to step S130 is executed by the analysis device 200 (1). Also, the processes of step S200 to step S220 are executed by the base station 100 (1). Further, the processes of steps S300 and S310 are executed by the camera CAM1, and the processes of steps S400 and S410 are executed by the user terminal UT (1). That is, FIG. 5 shows an embodiment of a monitoring method and a monitoring program.

  The processes in steps S100 to S130, the processes in steps S200 to S220, the processes in steps S300 and S310, and the processes in steps S400 and S410 communicate in the wireless communication system SYS shown in FIG. It is preferably performed in parallel with the processing.

  In addition, the operation of base station 100 (2) and the operation of each of user terminals UT (2) -UT (6) are the operations of base station 100 (1) and the operations of user terminal UT (1) shown in FIG. Are the same as or similar to the above, and the description thereof is omitted.

  In step S100, control unit 230 instructs control signal instructing acquisition of an image indicating a situation around base station 100 (1) and terminal information of user terminal UT (1) or the like via IF unit 210. It outputs to base station 100 (1).

  Next, in step S110, control unit 230 transmits a signal including an image around base station 100 (1) captured by camera CAM 1 and a control signal including terminal information of user terminal UT (1) to a base. It receives through the station 100 (1), respectively.

  Next, in step S120, the monitoring unit 240 causes deterioration in reception quality in the user terminal UT (1) or the like that wirelessly communicates with the base station 100 (1) using the image and terminal information received in step S110. Monitor if there is any. For example, the monitoring unit 240 may include position information of the user terminal UT (1) included in the terminal information, base station information of the base station 100, imaging information indicating an imaging direction of an image captured by the camera CAM1, and the camera CAM1. The position of the user terminal UT (1) in the image is determined using the information indicating the height installed in the base station 100 (1).

  Then, the monitoring unit 240 extracts an image area of a predetermined size centering on the position of the user terminal UT (1) obtained from the image captured by the camera CAM1. The monitoring unit 240 executes correlation processing using the template image of each shielding object stored in the area of the template image of the factor table FT shown in FIG. 4 and the extracted image area. If there is no template image whose correlation coefficient is equal to or more than a predetermined value, the monitoring unit 240 sets the base station 100 (1) and the user terminal UT (in the vicinity of the user terminal UT (1)) in the extracted image area. It is determined that there is no shield (factor) that degrades the wireless communication with 1). On the other hand, when there is a template image in which the correlation coefficient is equal to or more than a predetermined value, the monitoring unit 240 removes a shielding object such as a crowd whose correlation coefficient indicates a predetermined value or more in the extracted image area. It is determined that it exists between 1) and the user terminal UT (1).

  The monitoring unit 240 is used for monitoring of the user terminal UT (1) that performs wireless communication with the base station 100 (1) in association with the monitored time information and the distance and direction with the base station 100 (1) at the monitored time. The result is stored in the storage unit 250. The monitoring unit 240 also updates the information stored in the area such as the degradation quality of the factor table FT based on the monitoring result.

  Next, in step S130, the control unit 230 uses the IF unit 210 to improve the reception quality of wireless communication in the user terminal UT (1) using the monitoring result in step S120 and the factor table FT. The control instruction of the wireless parameter is output to the base station 100 (1) via

  Then, the analysis device 200 (1) ends the monitoring process. The analysis device 200 (1) repeatedly executes the processing from step S100 to step S130 at predetermined time intervals, for example.

  On the other hand, in step S200, control unit 130 controls IF unit 140 for a control signal for instructing acquisition of an image indicating the situation around base station 100 (1) among control signals received from analysis apparatus 200 (1). It outputs to camera CAM1 through.

  Next, in step S210, the control unit 130 transmits a control signal for acquiring terminal information to the user terminal UT (1) among the control signals received from the analysis device 200 (1), the second transmission / reception unit 120 and It transmits to user terminal UT (1) via antenna ANT2b.

  Preferably, control unit 130 executes the process of step S200 and the process of step S210 in parallel. Thus, it is possible to match the timing at which the camera CAM 1 captures an image with the timing at which the user terminal UT (1) acquires terminal information.

  When the control unit 130 receives a signal including an image captured by the camera CAM1 and a control signal including terminal information of the user terminal UT (1), the control unit 130 transfers the signals to the analysis apparatus 200 (1).

  Next, in step S220, the control unit 130 determines wireless parameters such as the beam width, direction, tilt angle, and transmission power of the antennas ANT2a and ANT2b based on the control instruction of the wireless parameters received from the analyzer 200 (1). Control.

  Then, each time the base station 100 (1) receives, for example, a control signal instructing acquisition of an image and terminal information from the analysis device 200 (1), the base station 100 (1) executes the processing from step S200 to step S220.

  On the other hand, in step S300, the camera CAM 1 captures an image showing the situation around the base station 100 (1) based on the control signal received from the base station 100 (1).

  Next, in step S310, the camera CAM 1 transmits a signal including the image captured in step S300 to the analysis device 200 (1).

  Then, each time the camera CAM 1 receives a control signal from the base station 100 (1), the camera CAM 1 executes the processes of steps S300 and S310.

  On the other hand, in step S400, when control unit 20 receives a control signal instructing acquisition of terminal information from base station 100 (1), the data signal received from base station 100 via antenna ANT1a and first transmission / reception unit 10 The reception quality such as the reception signal power is measured using the electromagnetic wave of The control unit 20 stores the measured reception quality in the storage unit 40. Then, the control unit 20 calculates the average value or the median value of the reception quality measured in a fixed period. Alternatively, the control unit 20 may calculate the reception quality using the past reception quality and Expression (1).

  When the control unit 20 receives a control signal instructing acquisition of terminal information, the position acquisition unit 30 receives a signal from a GPS satellite via the antenna ANT1a or the antenna ANT1b. The position acquisition unit 30 detects the position of the user terminal UT (1) from the received signal, and acquires it as position information. Then, the position acquisition unit 30 outputs the acquired position information to the control unit 20.

  Next, in step S410, the control unit 20 performs terminal information of the information indicating the reception quality measured in step S400, the position information acquired by the position acquisition unit 30, and the identification information of the user terminal UT (1). Output to the second transmission / reception unit 50 as The second transmission / reception unit 50 transmits a control signal including terminal information to the base station 100 (1) via the antenna ANT1b.

  Then, every time the user terminal UT (1) receives a control signal from the base station 100 (1), the user terminal UT (1) executes the processes of steps S400 and S410.

  In the process shown in FIG. 5, the base station 100 (1) outputs a control signal of an instruction to acquire an image indicating the situation around the base station 100 (1) to the camera CAM1, and acquires terminal information. You may start at the timing which transmits a control signal to user terminal UT (1) etc. In this case, the process of step S100 shown in FIG. 5 is preferably omitted.

  FIG. 6 shows another example of monitoring processing in the analysis device 200 shown in FIG. The process shown in FIG. 6 is executed, for example, when the user of the user terminal UT (1) feels that the quality of experience of wireless communication in the user terminal UT (1) is degraded. For example, the process shown in FIG. 6 is executed when an instruction to request investigation of the cause of deterioration in the quality of sensation is received from the user via an input unit such as a touch panel of the user terminal UT (1). Note that among the processes of the steps shown in FIG. 6, the same or similar processes as those shown in FIG. 5 are denoted by the same step numbers, and detailed description will be omitted.

  Further, the operation of base station 100 (2) and the operation of each of user terminals UT (2) -UT (6) are the operations of base station 100 (1) and the operations of user terminal UT (1) shown in FIG. And the description is omitted.

  In step S400a, the control unit 20 determines whether or not a request for requesting investigation of a cause of deterioration in the quality of sensation has been received from the user via the input unit of the user terminal UT (1). When the request instruction is received, the process of the user terminal UT (1) proceeds to step S400 b. On the other hand, when the request instruction has not been received, the process of the user terminal UT (1) waits for step S400a until the request instruction is received.

  Next, in step S400b, control unit 20 uses the electromagnetic wave of the data signal received from base station 100 (1) via antenna ANT1a and first transmission / reception unit 10, similarly to step S400 shown in FIG. , And the reception quality such as the reception signal power. The control unit 20 stores the measured reception quality in the storage unit 40. Then, the control unit 20 calculates the average value or the median value of the reception quality measured in a fixed period.

  Further, when receiving the request instruction, the position acquisition unit 30 receives a signal from the GPS satellite via the antenna ANT1a or the antenna ANT1b, as in step S400 shown in FIG. The position acquisition unit 30 detects the position of the user terminal UT (1) from the received signal, and acquires it as position information. Then, the position acquisition unit 30 outputs the acquired position information to the control unit 20.

  Next, in step S415, the control unit 20 performs terminal information of the information indicating the reception quality measured in step S400b, the position information acquired by the position acquisition unit 30, and the identification information of the user terminal UT (1). Output to the second transmission / reception unit 50 as The second transmission / reception unit 50 transmits the control signal of the request instruction including the terminal information to the analysis device 200 (1) via the antenna ANT1b.

  Next, in step S420, when the control unit 20 receives a control signal including the monitoring result from the analysis device 200 (1), the control unit 20 displays the received monitoring result on the display unit of the user terminal UT (1). For example, when the cause of deterioration of the sensory quality in the user terminal UT (1) is a building, the control unit 20 displays on the display unit that “communication is delayed due to the shadow of the building” or the like. Alternatively, if the cause of the deterioration in the quality of experience in the user terminal UT (1) is that the distance to the base station 100 (1) is long, the control unit 20 “slows communication because it is far from the base station "Etc. will be displayed on the display unit.

  Then, each time the user terminal UT (1) receives a request instruction from the user, the user terminal UT (1) executes the processing of step S400a, step S400b, step S415, and step S420.

  On the other hand, in step S200a, when control unit 130 receives a control signal of a request instruction including terminal information from user terminal UT (1), control unit 130 of base station 100 (1) as in step S200 shown in FIG. A control signal for instructing acquisition of an image indicating a surrounding situation is output to the camera CAM1. Further, the control unit 130 transfers the received control signal of the request instruction to the analysis device 200 (1).

  When the camera CAM 1 receives the signal including the captured image from the camera CAM 1 after the camera CAM 1 executes the processes of step S 300 and step S 310, the control unit 130 analyzes the signal of the image as in the case of FIG. Transfer to the device 200 (1). In addition, when the control unit 130 receives a control signal including the monitoring result from the analysis device 200 (1), the control unit 130 transfers the received control signal to the user terminal UT (1).

  After performing the process of step S200a, the base station 100 (1) performs the process of step S220. Then, each time base station 100 (1) receives a control signal of a request instruction from user terminal UT (1), it performs the processes of step S200a and step S220.

  On the other hand, in step S110a, control unit 230 generates an image indicating a situation around base station 100 (1) captured by camera CAM 1 and a control signal of a request instruction including terminal information from user terminal UT (1). , And via the base station 100 (1).

  Then, the analysis apparatus 200 (1) executes the process of step S110a and step S120, and then executes the process of step S125.

  In step S125, in order to notify the user terminal UT (1) of the monitoring result in step S120, the control unit 230 controls the control signal storing the monitoring result through the base station 100 (1) to the user terminal UT ( Output to 1).

  After executing the process of step S125, the analysis device 200 (1) executes the process of step S130. Then, every time the analysis device 200 (1) receives a control signal of a request instruction from the user terminal UT (1), the analysis device 200 (1) executes the processing of step S110a, step S120, step S125 and step S130.

  As described above, in the embodiment illustrated in FIG. 1 to FIG. 6, the analysis device 200 includes an image indicating the situation around the base station 100 captured by the camera CAM disposed in the base station 100 to be monitored, and each user terminal It is monitored for each user terminal UT whether there is a factor that degrades the quality of wireless communication with the base station 100 using the terminal information acquired from the UT. That is, since the wireless communication system SYS does not execute processing such as learning the movement of the shield that degrades the reception quality, the amount of processing is suppressed, and factors that degrade the quality of wireless communication are monitored for each user terminal UT. it can. Then, the analysis device 200 controls the wireless parameter of the base station 100 based on the monitoring result and the terminal information, so that the wireless communication system SYS receives the reception quality of the wireless communication in each user terminal UT and each user. Quality of experience can be improved.

  FIG. 7 shows another example of the user terminal UT, the base station 100 and the analysis device 200 shown in FIG. Elements having the same or similar functions as the elements described in FIGS. 1 and 2 are denoted by the same or similar reference numerals, and detailed description thereof is omitted.

  Similar to the user terminal UT (1) shown in FIG. 2, the user terminal UT (1) has the antennas ANT1a and ANT1b, the first transmission / reception unit 10, the control unit 20, the position acquisition unit 30, the storage unit 40, and the second transmission / reception It has a section 50. The user terminals UT (2) to UT (6) also have the same elements as the user terminal UT (1).

  The base station 100 (1) includes antennas ANT2a and ANT2b, a first transmission / reception unit 110, a second transmission / reception unit 120, a control unit 130a, and an IF unit 140. Base station 100 (2) has the same elements as base station 100 (1).

  Similar to the control unit 130 shown in FIG. 2, the control unit 130 a is realized by a processor or the like included in the base station 100 (1) executing a program stored in the storage device of the base station 100 (1). Control the operation of the base station 100 (1). The control unit 130 a outputs, for example, the received data signal and control signal to the control station CT via the IF unit 140.

  In addition, control unit 130a controls the beam width and the like of antennas ANT2a and ANT2b based on the control instruction of the wireless parameter received from analysis apparatus 200 (1) via IF unit 140, and is positioned in cell area AR1. Improve the reception quality for the user terminal UT. The operation of the control unit 130 a will be described with reference to FIGS. 8 and 9.

  The control station CT is a computer device having an arithmetic processing unit and a storage unit. For example, when the arithmetic processing unit of the control station CT executes the monitoring program stored in the storage device, two processing units including the IF unit 210, the network IF unit 220, the control unit 230a, the monitoring unit 240 and the storage unit 250 are provided. It functions as the analysis device 200. The analysis device 200 (2) has the same elements as the analysis device 200 (1). In addition, the IF unit 210, the network IF unit 220, the control unit 230a, the monitoring unit 240, and the storage unit 250 included in the analysis apparatus 200 may be realized by hardware installed in the control station CT.

  The control unit 230a controls the operation of the analysis device 200 (1), similarly to the control unit 230 shown in FIG. For example, when a data signal is received from the user terminal UT, the control unit 230a refers to the information indicating the transmission destination stored in the header or the like included in the received data signal, and transmits the transmission destination via the network IF unit 220. Transfer the data signal to the network NW for transmission to the network NW. Further, the control unit 230a receives, via the network IF unit 220, a data signal addressed to the user terminal UT wirelessly communicating with the base station 100 (1) from the network NW.

  Further, similar to the control unit 230 shown in FIG. 2, the control unit 230 a transmits control signals for acquiring terminal information of each of the user terminals UT wirelessly communicating with the base station 100 (1) to the IF unit 210. The data is output to each of the user terminals UT. Then, control unit 230a receives a control signal including terminal information from each of user terminals UT, stores the received terminal information of each user terminal UT in storage unit 250, and outputs it to monitoring unit 240.

  Further, similarly to the control unit 230 shown in FIG. 2, the control unit 230 a sends a control signal for acquiring an image indicating the situation around the base station 100 (1) to the camera CAM 1 via the IF unit 210. Output. Then, the control unit 230a receives an image captured by the camera CAM1 via the base station 100 (1), and outputs the received image to the monitoring unit 240. The control unit 230a outputs the control instruction of the wireless parameter to the base station 100 (1) using the result of the monitoring process by the monitoring unit 240 and the terminal information of each user terminal UT. The operation of the control unit 230a will be described with reference to FIG. 8 and FIG.

  FIG. 8 shows an example of monitoring processing in the analysis apparatus 200 shown in FIG. In the processes of the steps shown in FIG. 8, the same or similar processes as those shown in FIG. 5 are denoted by the same step numbers, and the detailed description will be omitted.

  For example, the processing of step S100, step S110, step S120, step S135 and step S140 is executed by the analysis device 200 (1). Also, the processes of step S200, step S210, and step S220a are executed by the base station 100 (1). Further, the processes of steps S300 and S310 are executed by the camera CAM1, and the processes of steps S400 and S410 are executed by the user terminal UT (1). That is, FIG. 8 shows another embodiment of a monitoring method and a monitoring program.

  The processes of steps S100, S110, S120, S135 and S140, the processes of steps S200, S210 and S220a, the processes of steps S300 and S310, and the processes of steps S400 and S410 , Preferably in parallel with the communication processing in the wireless communication system SYS.

  The operation of base station 100 (2) and the operation of each of user terminals UT (2) -UT (6) are the same as the operation of base station 100 (1) and the operation of user terminal UT (1) shown in FIG. And the description is omitted.

  The analysis apparatus 200 (1) executes the process of step S 135 after executing the processes of step S 100 to step S 120 as in the process shown in FIG.

  In step S135, the control unit 230a uses the result of monitoring in step S120 and the factor table FT shown in FIG. 4 to improve the reception quality of wireless communication in the user terminal UT (1). The control content (policy) of the wireless parameter in 100 (1) is determined. The process of step S135 will be described with reference to FIG.

  In step S140, control unit 230a outputs the control content determined in step S135 to base station 100 (1) via IF unit 210.

  Then, the analysis device 200 (1) ends the monitoring process. The analysis device 200 (1) repeatedly executes, for example, the processing of step S100, step S110, step S120, step S135 and step S140 at predetermined time intervals.

  On the other hand, the base station 100 (1) executes the process of step S220a after executing the processes of step S200 and step S210 as in the process shown in FIG.

  In step S220a, the control unit 130a controls wireless parameters such as the beam width, direction, tilt angle, and transmission power of the antennas ANT2a and ANT2b based on the control content of the wireless parameters received from the analysis device 200 (1). .

  Then, each time base station 100 (1) receives, for example, a control signal instructing acquisition of an image and terminal information from analysis apparatus 200 (1), base station 100 (1) executes the processing of step S200, step S210, and step S220a. .

  Also, as in the process shown in FIG. 5, the camera CAM 1 executes the processes of steps S300 and S310 each time a control signal is received from the base station 100 (1). Also, each time the user terminal UT (1) receives a control signal from the base station 100 (1), the user terminal UT (1) executes the processes of steps S400 and S410.

  FIG. 9 shows an example of the process in step S135 shown in FIG.

  In step S500, the control unit 230a determines the number of deteriorated terminals corresponding to the shielding object that degrades the reception quality of the user terminal UT (1) determined by the monitoring unit 240 in step S120 among the factor table FT illustrated in FIG. Read the value stored in the area of. Then, the control unit 230a determines whether or not the value of the read number of degraded terminals is equal to or more than the threshold value α. If the number of deteriorated terminals is equal to or greater than the threshold α, the process of the analysis device 200 (1) proceeds to step S510. On the other hand, when the number of deteriorated terminals is less than the threshold value α, the process of the analysis device 200 (1) proceeds to step S560. It is preferable that the threshold value α be appropriately set according to the processing capacity of wireless communication in the base station 100, the shield specified by the monitoring unit 240, and the like, and be stored in the storage unit 250 in advance.

  Next, in step S510, control unit 230a sets the area of the degradation quality corresponding to the shielding object that degrades the reception quality of user terminal UT (1) determined by monitoring unit 240 in step S120 in factor table FT. Read out the stored value. Then, the control unit 230a determines whether the read deterioration quality value is equal to or more than the threshold value β. If the deterioration quality is equal to or higher than the threshold β, the process of the analysis device 200 (1) proceeds to step S520. On the other hand, if the deterioration quality is less than the threshold value β, the process of the analysis device 200 (1) proceeds to step S560. It is preferable that the threshold value β be appropriately set according to the processing capability of wireless communication in the base station 100, the shield specified by the monitoring unit 240, and the like, and be stored in the storage unit 250 in advance.

  Next, in step S520, control unit 230a sets the region of the degradation period corresponding to the shielding object that degrades the reception quality of user terminal UT (1) determined by monitoring unit 240 in step S120 in factor table FT. Read out the stored value. Then, the control unit 230a determines whether the value of the read deterioration period is equal to or more than the threshold ε. If the degradation period is equal to or greater than the threshold ε, the process of the analysis device 200 (1) proceeds to step S530. On the other hand, when the degradation period is less than the threshold value ε, the process of the analysis device 200 (1) proceeds to step S540. It is preferable that the threshold value ε be appropriately set according to the processing capability of wireless communication in the base station 100, the shield specified by the monitoring unit 240, and the like, and be stored in advance in the storage unit 250.

  Next, in step S530, control unit 230a sets the area of the improvement difficulty level corresponding to the shielding object that degrades the reception quality of user terminal UT (1) determined by monitoring unit 240 in step S120 in factor table FT. Read out the value stored in. Then, the control unit 230a determines whether or not the read value of the improvement difficulty level is equal to or less than the threshold value δ. If the improvement difficulty level is equal to or less than the threshold value δ, the process of the analysis device 200 (1) proceeds to step S540. On the other hand, when the improvement difficulty level exceeds the threshold value δ, the process of the analysis device 200 (1) proceeds to step S550. It is preferable that the threshold value δ be appropriately set according to the processing capability of wireless communication in the base station 100, the shield specified by the monitoring unit 240, etc., and stored in the storage unit 250 in advance.

  In step S540, for example, when the control unit 230a determines that the degradation period is less than the threshold ε (the degradation period is short) in step S520, or the improvement difficulty is the threshold δ or less in step S530 (the improvement of the reception quality is easy), for example , Change the beam width, direction, tilt angle, etc. of the antennas ANT2a, ANT2b, or increase the transmission signal power at which the first transmission / reception unit 110 and the second transmission / reception unit 120 of the base station 100 (1) transmit electromagnetic waves The control content of the wireless parameter to improve the reception quality of the user terminal UT (1) is determined. Then, the analysis device 200 (1) ends the process of step S135, and proceeds to the process of step S140.

  In step S550, when it is determined in step S530 that the improvement difficulty level exceeds the threshold δ (the improvement in reception quality is difficult), the control unit 230a changes, for example, the beam width, direction, tilt angle, transmission power, etc. By reducing the cell area AR1 and reducing the number of degraded terminals etc., the control content of the wireless parameter for improving the reception quality of the user terminal UT (1) is determined. Then, the analysis device 200 (1) ends the process of step S135, and proceeds to the process of step S140.

  In step S560, when control unit 230a determines that the number of degraded terminals is less than threshold α in step S530 or the degradation quality is less than threshold β in step S510, the reception quality of user terminal UT (1) is not degraded. Alternatively, it is determined that the deterioration of the reception quality is small, and control contents to maintain the current radio parameters are determined. Then, the analysis device 200 (1) ends the process of step S135, and proceeds to the process of step S140.

  Note that the control unit 230a may execute the process of step S135 on the user terminal UT in the predetermined direction and the predetermined distance range in the base station 100 (1). As a result, it is possible to finely improve the deterioration of the reception quality. In this case, it is preferable that the predetermined direction and the predetermined distance range be preset according to the place where base station 100 (1) is arranged, and stored in storage unit 250.

  Also, the process of step S500 and the process of step S510 shown in FIG. 9 may be performed in the reverse order.

  Further, in the processes shown in FIGS. 8 and 9, the base station 100 (1) outputs a control signal for instructing acquisition of an image indicating the situation around the base station 100 (1) to the camera CAM1, and the terminal information It may start at the timing which transmits the control signal which acquires to user terminal UT (1) etc. In this case, the process of step S100 shown in FIG. 8 is preferably omitted.

  FIG. 10 shows another example of the monitoring process in the analysis apparatus 200 shown in FIG. The process shown in FIG. 10 is executed, for example, when the user of the user terminal UT (1) feels that the quality of sensation in the user terminal UT (1) is lowered, similarly to the process shown in FIG. Ru. Among the processes of the steps shown in FIG. 10, the same or similar processes as those shown in FIGS. 6 and 8 are denoted by the same step numbers, and the detailed description will be omitted.

  Further, the operation of base station 100 (2) and the operation of each of user terminals UT (2) -UT (6) are the operations of base station 100 (1) and the operations of user terminal UT (1) shown in FIG. And the description is omitted.

  As described above, in the embodiments illustrated in FIG. 7 to FIG. 10, the analysis device 200 includes an image indicating the situation around the base station 100 captured by the camera CAM disposed in the base station 100 to be monitored, and each user terminal It is monitored for each user terminal UT whether there is a factor that degrades the quality of wireless communication with the base station 100 using the terminal information acquired from the UT. That is, since the wireless communication system SYS does not execute processing such as learning the movement of the shield that degrades the reception quality, the amount of processing is suppressed, and factors that degrade the quality of wireless communication are monitored for each user terminal UT. it can. Then, the analysis device 200 determines the control content (policy) of the wireless parameter for the base station 100 based on the monitoring result and the terminal information, so that the wireless communication system SYS can perform wireless communication in each user terminal UT. It is possible to improve the reception quality and the sensory quality of each user.

  The features and advantages of the embodiments will be apparent from the foregoing detailed description. This is intended to cover the features and advantages of the embodiments as described above without departing from the spirit and scope of the claims. Also, all modifications and variations should be readily apparent to those skilled in the art. Accordingly, there is no intention to limit the scope of the embodiments having the invention to those described above, and it is also possible to rely on appropriate modifications and equivalents included in the scope disclosed in the embodiments.

10, 110 ... 1st transmission / reception unit; 50, 120 ... 2nd transmission / reception unit; 20, 130, 130a, 230, 230a ... control unit; 30 ... position acquisition unit; 40, 250 ... storage unit; 140, 210 ... IF unit 200 (1), 200 (2) ... analysis device; 220 ... network IF unit; 240 ... monitoring unit; 100 (1), 100 (2) ... base station; ANT1a, ANT1b, ANT2a, ANT2b ... antenna; CAM 2: Camera; CT: Control station; IMG: Image; SYS: Wireless communication system; UT (1)-UT (6): user terminal

Claims (5)

An acquisition step of acquiring surrounding information indicating a surrounding situation in a base station performing wireless communication with a terminal device;
Receiving terminal information indicating a state of the terminal apparatus from the terminal apparatus via the base station;
A monitoring step of monitoring whether there is a factor that degrades the quality in wireless communication between the base station and the terminal device using the acquired ambient information and the received terminal information;
A determination step of determining control content for the base station based on the result of monitoring in the monitoring step;
Control step of controlling the base station according to the control content determined in the determination step ;
In the determination step, when it is determined in the monitoring step that the factor is present, the number of degraded terminals, which is the total number of the terminal devices whose quality has been degraded due to the factor or the total number per unit time, is present The degradation quality which is the average value or the median value of the quality in the case, the degradation period which is the period during which the degradation of the quality continues due to the factor, and the improvement difficulty showing the difficulty to improve the degradation of the quality due to the factor monitoring wherein the that determine the control content in accordance with the time. In the monitoring method according to claim 1,
A monitoring step of notifying the terminal device of the result of the monitoring when the monitoring step is executed based on the monitoring request by the terminal device. An imaging device for imaging the periphery of a base station that performs wireless communication with a terminal device;
An acquisition unit that acquires an image from the imaging apparatus as ambient information indicating a surrounding situation in the base station; and a receiving unit that receives terminal information indicating a state of the terminal device from the terminal device via the base station , using said terminal information received and the acquired images, a monitoring unit for factors that degrade the quality of the wireless communication between the base station and the terminal device monitors whether there, the monitoring Determining a control content for the base station based on a result of monitoring in a control unit, and a control unit for controlling the base station with the determined control content ;
When the control unit determines that the factor is present in the monitoring unit, the factor is the total number of terminal devices whose quality has been degraded due to the factor or the number of degraded terminals per unit time, and the factor is present The degradation quality which is the average value or the median value of the quality in the case, the degradation period which is the period during which the degradation of the quality continues due to the factor, and the improvement difficulty showing the difficulty to improve the degradation of the quality due to the factor monitoring system, characterized in that that determine the control content in accordance with the time. An acquisition unit configured to acquire ambient information indicating a surrounding situation in a base station that performs wireless communication with a terminal device;
A receiving unit that receives terminal information indicating the state of the terminal apparatus from the terminal apparatus via the base station;
A monitoring unit that monitors whether there is a factor that degrades the quality of wireless communication between the base station and the terminal device using the acquired surrounding information and the received terminal information;
A control unit that determines control content for the base station based on a result of monitoring by the monitoring unit, and controls the base station based on the determined control content ;
When the control unit determines that the factor is present in the monitoring unit, the factor is the total number of terminal devices whose quality has been degraded due to the factor or the number of degraded terminals per unit time, and the factor is present The degradation quality which is the average value or the median value of the quality in the case, the degradation period which is the period during which the degradation of the quality continues due to the factor, and the improvement difficulty showing the difficulty to improve the degradation of the quality due to the factor monitoring apparatus characterized by that determine the control content in accordance with the time. A monitoring program operating a computer as the monitoring device according to claim 4 .

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