JP2018042015A - Control device and ISM device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve communication quality by reducing interference from ISM (Industry Science Medical) equipment.SOLUTION: A control device 101 is provided that is applied to a communication system in which an access point B 121 and radio terminal devices B-1, B-2 perform radio communication. The control device comprises: a first electromagnetic sensor A 103 executing at least one of measurement of intensity of an interference radio wave exerting interference on the radio communication or estimation of a position of an interference source generating the interference radio wave; a second electromagnetic sensor B 104 measuring a propagation path state of a network managed by an access point B 121; and a communication unit which acquires at least a result of the measurement of intensity of the interference radio wave or a result of the estimation of a position of the interference source from the first electromagnetic sensor A 103 and notifies the access point B 121 or at least one of the radio terminal devices B-1, B-2 connecting with the access point B 121 of at least one of the acquired result of the measurement of intensity of the interference radio wave or result of the estimation of the position of the interference source.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control device and an ISM device applied to a communication system in which an access point and a wireless terminal device perform wireless communication.

  In recent years, various uses of radio waves have progressed. In particular, the number of devices using an ISM (Industry Science Medical) band, that is, a frequency band called an “industrial science medical band” is increasing. This frequency band is allocated by the ITU (International Telecommunication Union) as a high-frequency energy source for industries, science, and medical uses other than wireless communications, and microwave ovens are very popular as consumer devices that use this frequency band. .

  In addition, use as a license-free wireless communication device in this frequency band is also in progress, and in particular, the 2.4 GHz band is also used for so-called wireless LAN devices and other low-power data communication devices.

  For example, Patent Document 1 discloses a technique related to a network that operates in an ISM band. The technique relates to a transmission power control method related to a radio interface channel, and determines a quality of service indicator of a signal transmitted through a second radio interface channel, and determines the first radio interface channel. An interference level corresponding to interference to the second radio interface channel due to transmission is determined. As a result, when a signal is transmitted on the second radio interface channel, the quality of service is greater than or equal to a predetermined value, and the interference level is greater than or equal to a predetermined value, the signal associated with the first radio interface channel Is configured to issue a request to change the transmission power to be transmitted.

JP 2004-274745 A

  However, for low-power data communication devices such as wireless LAN devices, the intensity of radio waves emitted by ISM devices typified by microwave ovens cannot be ignored. While an ISM device is operating, communication devices around the device will be disturbed. Interference due to radio waves generated by ISM devices is legally recognized, and basically only allows a reduction in communication quality. When a communication device is executing an application that requires a wide band, if a radio wave is emitted from a surrounding ISM device, the execution of this application may be hindered.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a control device and an ISM device that can reduce interference from an ISM device and improve communication quality.

  In order to achieve the above object, the following measures are taken in one aspect of the present invention. That is, a control device according to an aspect of the present invention is a control device applied to a communication system in which an access point and a terminal device perform wireless communication, and measures the intensity of interference radio waves that interfere with the wireless communication or the A first electromagnetic sensor that performs at least one of estimation of a position of an interference source that generates an interference radio wave; a second electromagnetic sensor that measures a propagation path state of a network managed by the access point; and the first electromagnetic sensor From the sensor, obtain at least one of the measurement result of the interference radio wave intensity or the estimation result of the position of the interference source, and obtain at least one of the obtained measurement result of the interference radio wave intensity or the estimation result of the position of the interference source A communication unit for notifying at least one of the access point or a wireless terminal device connected to the access point , Comprising a.

  According to the present invention, it is possible to reduce interference from an ISM device and improve communication quality.

It is a figure which shows the outline | summary of an example of the radio | wireless communications system to which this embodiment is applied. In electromagnetic sensor A * 103, it is a figure which shows the structural example in the case of utilizing the method of estimating the generation source of an electromagnetic wave by DOA estimation. In electromagnetic sensor A103, it is a figure which shows the structural example in the case of using a several antenna and estimating the generation source of an electromagnetic wave using the directivity of each antenna. In electromagnetic sensor A103, it is a figure which shows the structural example in the case of estimating the generation source of an electromagnetic wave by performing the signal detection corresponding to the combination of a several antenna element using the antenna which made the several antenna element the net shape. is there. It is a sequence chart which shows operation | movement of an ISM apparatus, the electromagnetic sensor A, a control apparatus, and the electromagnetic sensor B. It is a figure which shows an example at the time of changing the average transmission power by changing the duty ratio of the oscillation time at the time of transmitting an electromagnetic wave intermittently. It is a figure which shows an example at the time of changing the average transmission power by changing the duty ratio of the oscillation time at the time of transmitting an electromagnetic wave intermittently. It is a figure which shows an example at the time of turning ON / OFF the input of a voltage doubler rectifier circuit with a period longer than the period of the input signal of a voltage doubler rectifier circuit. It is a sequence chart which shows operation | movement of an ISM apparatus, a control apparatus, and the electromagnetic sensor B. 3 is a sequence chart showing operations of an electromagnetic sensor A, a control device, and an electromagnetic sensor B. It is a sequence chart which shows operation | movement of an ISM apparatus, the electromagnetic sensor A, the electromagnetic sensor C, a control apparatus, and the electromagnetic sensor B. It is a figure which shows the structural example applied when the frequency of the channel which a some access point uses is the same.

  Hereinafter, a wireless communication technique according to an embodiment of the present invention will be described in detail with reference to the drawings.

(First embodiment)
An outline of an example of a wireless communication system to which the present embodiment is applied is shown in FIG. The control device 101 includes a communication unit 101a as an interface for performing wireless communication or wired communication, and a determination unit 101b that determines a signal received from each sensor. The control device 101 is connected to a plurality of electromagnetic sensors (electromagnetic sensors A and 103, electromagnetic sensors B and 104, and electromagnetic sensors C and 105) and the display device 102, and performs information collection and communication using the respective electromagnetic sensors. Information display using the display device 102 can be performed. Connections between the respective electromagnetic sensors, the display device 102 and the control device 101 may be performed by wire or wirelessly.

  The electromagnetic sensor A 103 is a device that detects radio wave emission of one or a plurality of ISM devices. In this embodiment, two ISM devices 111 and 112 are targeted. These ISM devices are devices that use the 2.4 GHz ISM band, and examples thereof include a microwave oven, an industrial microwave heating device, and a medical heating device. Further, the configuration of the device according to the present embodiment may be changed so that an ISM band other than the 2.4 GHz band is targeted. Electromagnetic sensor B104 is a device that detects radio waves emitted by communication equipment that uses the same frequency band as ISM equipment, in this embodiment, 2.4 GHz ISM band, and uses these 2.4 GHz ISM bands. It also has a function to communicate with the communication equipment. The target of the electromagnetic sensor B / 104 is a network managed by the access point B / 121, and two wireless terminal devices 122 and 123 and the electromagnetic sensor B / 104 are connected to the access point B / 121. The electromagnetic sensor C105 is a device that detects radio waves emitted by communication devices using a frequency band other than the ISM band, in this embodiment, the 5 GHz band, and also has a function of communicating with communication devices using these 5 GHz bands. . The target of the electromagnetic sensor C · 105 is a network managed by the access point C · 131. Two wireless terminal devices 132 and 133 and the electromagnetic sensor C · 105 are connected to the access point C · 131.

  The ISM devices 111 and 112 may have a communication function. In the case of having a communication function, a function of connecting to the access point B • 121 or the access point C • 131 may be provided. Thereby, the ISM devices 111 and 112 and the control device 101 may communicate with each other. Also, the number of access points that use a frequency band other than the ISM band is not one, but a plurality of access points may be prepared, and the frequency bands used by the respective access points may be different.

  Electromagnetic sensor A103 detects the radio wave emitted from the surrounding ISM device, estimates the approximate position of the ISM device that emitted the radio wave, and measures the electric field strength at the time of reception. A configuration example of the electromagnetic sensor A 103 will be described with reference to FIG.

  FIG. 2A is a configuration example in the case of using a method of estimating a generation source of radio waves by arrival angle (DOA) estimation in electromagnetic sensors A and 103. Two arrival angle (DOA) estimation units 201 and 203 are provided, and each arrival angle estimation unit includes array antennas 202 and 204. The interval between the two arrival angle estimation units 201 and 203 is fixed. The two arrival angle estimation units 201 and 203 are connected to the control unit 205, and the control unit 205 is a triangle based on the arrival angle of the radio wave estimated by the two arrival angle estimation units and a predetermined interval between the two arrival angle estimation units. The direction and distance of the radio wave source are estimated based on the surveying principle. Information on the direction and distance of these radio wave generation sources and the electric field strength at the time of reception are notified to the control device 101 via the communication unit 206. Any method may be used for angle-of-arrival estimation using an array antenna. For example, various methods such as a beam former method, a capon method, and a linear prediction method may be used.

  FIG. 2B is a configuration example in the case where the electromagnetic sensor A · 103 uses a plurality of antennas and estimates the generation source of the radio wave by using the directivity of each antenna. In this example, a leaky coaxial cable (LCX) is used as an antenna having directivity, and it is detected whether or not radio waves are emitted from a preset range. LCXs 213 and 214 are connected to the two signal detection units 211 and 212 that detect radio waves emitted from the ISM device, and cables are connected. The LCX 213 sets the leakage characteristics and arrangement of the LCX so that the ISM device can detect that the ISM device has emitted radio waves in the range 217, and the LCX 214 can detect that the ISM device has emitted radio waves in the range 218. In this example, ISM devices A- 1 and 111 are arranged in the range 217, and ISM devices A- 2 and 112 are arranged in the range 218. The control unit 215 notified of the signal detection from any of the signal detection units can estimate that radio waves are emitted from the ISM device in the range 217 or 218, and control the result via the communication unit 216. Notify the device 101.

  FIG. 2C shows a configuration example in the case of estimating the generation source of radio waves by performing signal detection corresponding to a combination of a plurality of antenna elements by using an antenna in which a plurality of antenna elements are meshed in the electromagnetic sensor A103. It is. In this example, LCX is used as an antenna element, a plurality of LCXs are arranged in a lattice pattern, and a group of a plurality of LCX 229 to LCX 232 arranged in a vertical direction and a group of a plurality of LCX 225 to LCX 228 arranged in a horizontal direction, respectively. It is estimated that there is a radio wave generation source near the intersection of LCX where a strong signal is detected in each group. The vertical direction and the horizontal direction written here are directions given for convenience about two axes intersecting on a plane, and there is no particular limitation. For example, the north-south direction may be treated as the vertical direction and the east-west direction as the horizontal direction, and a trapezoidal or parallelogram-shaped mesh may be used so that the LCX does not intersect at right angles when the LCX is arranged in accordance with the structure of the building. You may arrange as follows.

  There are two signal detection units 221 and 222 that detect radio waves emitted from the ISM device. A switching unit 223 is connected to the signal detection unit 221, and a switching unit 224 is connected to the signal detection unit 222. The switching unit 223 is connected to the LCX 225 to LCX 228 arranged in the horizontal direction, and selects and connects either the signal detection unit 221 or the LCX 225 to LCX 228. Similarly, the switching unit 224 is connected to LCX 229 to LCX 232 arranged in the vertical direction, and selects and connects one of the signal detection unit 222 and LCX 229 to LCX 232. The control unit 233 controls the signal detection units 221 and 222 and the switching units 223 and 224, changes the combination of LCXs connected to the signal detection units 221 and 222 every predetermined time, and uses either of the two antennas for the ISM band. Continue to search for a combination of LCX that receives the radio wave at a predetermined intensity or higher. When such a combination of LCXs is found, the control unit 233 estimates the vicinity of the intersection of those LCXs as a radio wave generation source in the ISM band. The control unit 233 notifies the control apparatus 101 of this estimation result via the communication unit 234.

  Hereinafter, in the present embodiment, it is assumed that the control device 101 can operate the ISM devices 111 and 112. The means for operating is not specified, but the wireless network is connected via the access point B 121 or the access point C 131 connected to the control device 101, and the operation is performed via the wireless network. Also good.

  In this embodiment, the control device 101 measures the channel utilization rate and error rate of the wireless network managed by the access point B 121 using the electromagnetic sensor B 104, and controls the radio wave emitted by the ISM device based on the result. An example is shown. An example of the control flow of this system is shown in FIG. In step S301, the electromagnetic sensor B · 104 monitors the signal transmitted from the access point B · 121 and the signal strength of the channel used by the access point B · 121, and the wireless terminal device using the access point B · 121. It is determined whether the error rate of communication with is high. Although the error rate determination method is not particularly specified, whether or not the serial number of the transmission packet transmitted by the access point B · 121 is duplicated continues, the channel signal strength is strong, and the access point B · 121 It may be determined by various methods, such as whether or not the packet transmitted by the computer continues to be unobservable, whether a large number of packets requesting retransmission are transmitted, and whether the ratio of retransmitted packets is high. Further, it may be determined that the error rate has increased by notifying the wireless terminal devices 122 and 123 connected to the access point B 121 that the error rate has increased via the access point. .

  Further, it may be determined that the error rate has increased by notifying the electromagnetic sensor A • 103 that the error rate has increased from the access point B • 121. If it is determined in step S301 that the error rate of communication managed by the access point B • 121 has increased, the electromagnetic sensor B • 104 increases the error rate of communication managed by the access point B • 121 to the control device 101. A message 302 indicating that this is transmitted. The control device 101 that has received the message 302 transmits a message 303 that instructs the electromagnetic sensor A 103 to infer whether there is an ISM device that is an interference source by transmitting a radio wave. A communication method between the control device 101 and the electromagnetic sensors A and 103 is not particularly specified. However, when a communication method using the ISM band is used, there is a possibility of receiving radio wave interference from the ISM device. In such a case, communication may be performed while the ISM device is intermittently transmitting. A communication method using a frequency other than the frequency band used by the ISM device to be detected may be used. A communication method using a wired connection between the control device 101 and the electromagnetic sensor A 103 may be used.

  Receiving the message 303, the electromagnetic sensor A · 103 checks whether or not an ISM band radio wave is emitted around the electromagnetic sensor A · 103. If the electromagnetic sensor A · 103 is emitted, the estimation of the approximate position of the source is performed in step S304. Do. Thereafter, the estimated approximate location of the source and the electric field strength of the received radio wave are transmitted to the control apparatus 101 by a message 305. The control apparatus 101 that has received the message 305 checks whether the message 305 includes the estimation result of the ISM band radio wave transmission source. If it is included, the control apparatus 101 transmits the message 306 to the device. An instruction is given to reduce the degree of interference by radio waves in the ISM band or to reduce the time for receiving interference.

  The ISM device that has received the message 306 controls its radio wave emission so that the interference of radio waves in the ISM band being emitted becomes low. This control method is not specified, but as an example, methods such as lowering the emission intensity of radio waves, performing intermittent transmission of radio waves, increasing the interval of intermittent transmission, changing the transmission frequency, changing the transmission frequency randomly, etc. May be used. Further, the transmission time may be shortened by increasing the intensity of the ISM band radio wave so as to shorten the processing time of the ISM band radio wave. An outline of this example is shown in FIG.

  FIGS. 4A and 4B show an example of changing the average transmission power by changing the duty ratio of the oscillation time when intermittently transmitting radio waves. When a magnetron is used as an oscillator in an ISM device, it does not oscillate unless a high-voltage anode voltage is applied. The configuration of the voltage doubler rectifier circuit is less in the half-wave method than in the two-wave method. In general, a configuration in which the anode voltage is intermittently applied to intermittently oscillate the radio wave because the peak intensity of the leaked radio wave allowed is higher. In order to reduce the size of power transformers for ISM devices, inverter-type power supplies that can change the duty ratio of the input signal of the voltage doubler rectifier circuit are often used. By changing this duty ratio, the average power of the output signal of the magnetron can be reduced. Can be changed. FIG. 4A shows a state in which the ratio of the low anode voltage (t2, t2 ′) to the oscillation period (t1, t1 ′) of the inverter is shorter, and FIG. 4B shows a longer state. In the case of a configuration that does not use an inverter, the cycle of the input signal of the voltage doubler rectifier circuit for anode voltage cannot be changed, so that the voltage doubler rectifier circuit has a cycle longer than the cycle of the input signal of the voltage doubler rectifier circuit as shown in FIG. The average power of the output signal of the magnetron may be changed by turning on (t3) and turning off (t4).

  In FIG. 3, the control apparatus 101 that has transmitted the message 306 checks again whether the electromagnetic sensor A • 103 is emitting radio waves in the ISM band around the electromagnetic sensor A • 103. A message 307 is transmitted to the electromagnetic sensor A 103 so as to estimate the approximate position. The electromagnetic sensor A · 103 that has received the message 307 checks again whether or not the ISM band radio wave is emitted around the electromagnetic sensor A · 103 in step S308, and if it is, the estimation of the approximate position of the source is performed. In addition, the electric field strength of radio waves is measured. Thereafter, the electromagnetic sensor A 103 transmits a message 309 to the control apparatus 101, and is notified of the approximate position of the source estimated in the message 309 and the electric field strength of the received radio wave.

  The control apparatus 101 that has received the message 309 transmits a message 310 to the electromagnetic sensor B · 104 as a result of the control based on the contents of the message 305 and the message 309. The message 310 is transmitted in response to the message 302, and the message 310 may include information on the received electric field strength before and after the control on the ISM device, the approximate position of the estimated ISM device, and the like. In addition, the electromagnetic sensor B · 104 that has received the message 310 notifies the access point B · 121 or the wireless terminal devices 122 and 123 managed by the access point B · 121 of at least part of the information included in the message 310. You may do it. In addition, the access point B 121 or the wireless terminal device 122 or 123 managed by the access point B 121 receives the information included in the message 310 directly from the control device 101 instead of via the electromagnetic sensor B 104. Also good. Thereby, the access point B 121 and the wireless terminal devices 122 and 123 may know that the electromagnetic environment of the ISM band has changed, and may change the communication method, the frequency of communication, and the like.

  Thereafter, the electromagnetic sensor B · 104 monitors the signal transmitted from the access point B · 121 and the signal strength of the channel used by the access point B · 121 in step S311, and uses the subsequent access point B · 121. It is determined whether the error rate of communication with the wireless terminal device is high. If it is determined that the error rate has decreased, the electromagnetic sensor B • 104 transmits a message 312 to the control apparatus 101 to notify that the error rate has decreased. The message 312 is relatively less affected by the ISM band radio waves emitted by ISM devices, such as when the frequency of communications managed by the access point B 121 decreases sufficiently, not when the error rate decreases. It may be sent when The control device 101 that has received the message 312 transmits a message 313 to the electromagnetic sensor A 103 so as to estimate the approximate position of the source that transmits the radio waves in the ISM band and measure the electric field strength of the received signal. Notify The electromagnetic sensor A · 103 that has received the message 313 checks whether or not an ISM band radio wave is emitted around the electromagnetic sensor A · 103 in step S314, and if so, estimates the approximate location of the source, and Measure the electric field strength of radio waves.

  Thereafter, the electromagnetic sensor A 103 transmits a message 315 to the control device 101 to notify the control device 101 of the approximate position of the estimated source and the measured electric field strength. The control device 101 that has received the message 315 determines whether the ISM device that has transmitted the message 306 continues to emit radio waves from the information included in this message, the information included in the message 305 and the message 309, and other information. When it is determined that the emission is continued, a message 316 is transmitted to notify that suppression of radio wave interference may be stopped. If the message can be received when the ISM device is not emitting radio waves, the message 316 may be transmitted without confirming the emission of radio waves. The ISM device that has received the message 316 may stop transmitting so as to reduce interference, and restore the transmission output.

  By operating each device as described above, it is possible to reduce the interference from the ISM device with respect to the communication managed by the access point B 121 under the control of the control device 101, and to improve the communication quality.

(Second Embodiment)
In the second embodiment, before the ISM device emits a radio wave to the ISM band, it makes an inquiry to the control device whether there is a possibility that the radio wave emitted from the ISM device may interfere with communication. An example of a method for emitting radio waves based on The configuration of the device is the same as in the first embodiment. An example of a message flow for the processing of this embodiment is shown in FIG. Hereinafter, a description will be given with reference to FIG.

  In the standby state, the ISM device receives a radio wave output instruction for heating or the like (step S401). When this output instruction is input, the ISM device transmits a message 402 for inquiring about the possibility of causing interference when the radio wave is emitted in the ISM band to the control device 101. The control device 101 may include information related to the output of radio waves from the ISM device, position information of the ISM device, and the like in the message 402. The control device 101 that has received the message 402 measures the channel usage rate and error rate in the channel that is currently communicating with the electromagnetic sensor B · 104 in step S404, and interferes when radio waves are emitted by the ISM device. Thus, it is determined whether there is a possibility that the communication quality is deteriorated, and the result is transmitted as a message 405 to the control apparatus 101. The method for determining the possibility of communication quality deterioration due to this interference is not particularly specified. For example, the access point B 121, which determines that communication quality is deteriorated due to interference when the channel usage rate is higher than a certain value, is managed. If the current average error rate of communication is higher than a certain value, the communication quality deteriorates due to interference. If the signal strength of the signal received by the access point B 121 for communication is lower than a certain value, the communication quality decreases due to interference. A method such as lowering may be used. After determining that the communication quality may be deteriorated due to the interference, the electromagnetic sensor B · 104 transmits a message 405 to the control apparatus 101 and notifies the determination result.

  The control apparatus 101 that has received the message 405 transmits a message 406 including the content notified in the message 405 to the ISM device that has transmitted the message 402. When the ISM device that has received the message 406 is notified by the message 406 that the electromagnetic sensor B · 104 may be deteriorated in communication quality due to interference caused by radio wave emission of the ISM device, it interferes with other devices. The output at the time of radio wave emission is set so as to decrease (step S407). In addition, if the message 406 does not notify the possibility that the communication quality is deteriorated due to the interference caused by the radio wave emission of the ISM device, the ISM device that has received the message 406 does not limit the output when the radio wave is emitted. After setting the output for radio wave emission, the ISM device that has received the message 406 emits the radio wave with the output set in step S408 based on the content of the message 406.

  As described above, the ISM device inquires about restrictions on radio wave emission via the control device, determines the influence of interference due to the radio wave emitted by the ISM device based on the actual communication status, and determines the result of the radio wave emission from the ISM device. By reflecting, it is possible to reduce the influence of interference caused by radio wave emission from the ISM device.

(Third embodiment)
In the present embodiment, when there is no communication path between the control device and the ISM device, it is possible to display information on the ISM device causing the interference on the display device and take measures against the interference. An example will be described. The configuration of the device is the same as in the first embodiment. An example of the message flow in this embodiment is shown in FIG. Hereinafter, an example of the control of the present embodiment will be described with reference to FIG.

  First, in step S501, the electromagnetic sensor B · 104 monitors the signal transmitted from the access point B · 121 and the signal strength of the channel used by the access point B · 121, and the radio using the access point B · 121. It is determined whether the error rate of communication with the terminal device is high. If it is determined that the error rate is high, the electromagnetic sensor B · 104 sends a message 502 to the control device 101 to notify that the error rate of communication managed by the access point B · 121 is high. The possibility of interference occurring at the access point B 121 is shown. The control apparatus 101 that has received the message 502 transmits a message 503 to the electromagnetic sensor A · 103 in order to estimate the approximate position of the interference source if there is an ISM device or the like causing interference. The ISM device emits radio waves in the ISM band, or if so, instructs to estimate the approximate position of the radio wave source.

  The electromagnetic sensor A 103 that has received the message 503 monitors the ISM band in step S504, checks whether there is an ISM device that emits radio waves in the ISM band, and estimates that the ISM device is emitting radio waves. In this case, the approximate location of the radio wave source is estimated. The method for determining whether or not the ISM device is emitting radio waves is not particularly specified, but as an example, it can be assumed that the ISM device is emitting radio waves by periodically detecting a signal having an electric field strength of a certain value or more. A method of estimating the angle of arrival in accordance with the emission of the radio wave of the ISM device and the approximate position can be used. This is because when the ISM device is a microwave oven, emission of radio waves is intermittently performed in accordance with the frequency of the input power supply or the oscillation frequency of the step-up inverter for generating an anode voltage that operates at several tens of KHz. For example, when a signal having an electric field strength of a certain value or more is received and a radio signal in a format used by the access point B • 121 cannot be demodulated, a radio wave is transmitted from the ISM device. Any method that determines that it is fired can be used.

  The electromagnetic sensor A103 is used to determine whether there is an ISM device that emits radio waves, and when the ISM device estimates that the ISM device is emitting radio waves, The result of estimating the approximate location of the source of the radio wave when the message 505 is transmitted to 101 and it is estimated whether there is an ISM machine emitting the radio wave, or when the ISM device is emitting the radio wave. To be notified. When the message 505 includes information indicating that there is an ISM device that emits radio waves, the control device that displays the message 505 displays on the display device 102 that there is an ISM device that emits radio waves ( Step S506). At this time, the approximate position of the radio wave generation source included in the message 505 may be displayed together. By emitting radio waves from ISM devices and displaying radio wave generation sources on the display device 102, the administrator of the wireless network using the access point B 121 can easily investigate the interference sources for the wireless network. Is possible.

  The electromagnetic sensor B · 104 continues to monitor the channel used by the access point B · 121, and in step S507, monitors the signal transmitted from the access point B · 121 and the signal strength of the channel used by the access point B · 121. Then, it is determined whether the error rate of communication with the wireless terminal device using the access point B • 121 is high. When the error rate is not high, the electromagnetic sensor B · 104 transmits a message 508 to the control device, and the error rate of communication with the wireless terminal device using the access point B · 121 is not high. Notify that The control apparatus 101 that has received the message 508 deletes the result displayed in step S506 displayed on the display apparatus 102 in step S509. When the time until the display result is deleted in step S509 after the display in step S506 is short, the time until the display result is deleted may be slightly extended to ensure the visibility of the result displayed in step S506. This makes it easy to determine which ISM device has interfered with the network managed by the access point B 121.

  By operating as described above, it becomes easy for the administrator of the network that uses the access point B 121 to estimate the ISM device that is causing interference with this network, and the management of the appropriate ISM device is facilitated. By making it easy, it becomes possible to improve the efficiency of the network.

(Fourth embodiment)
In this embodiment, when interference of radio waves emitted by an ISM device is estimated for a certain access point, an access point using another frequency as a connection destination of a terminal device connected to the access point, An example of changing to an access point with less interference at the same frequency will be described.

  An example of processing for changing the connection destination of a terminal device connected to an access point to an access point using another frequency when interference of radio waves emitted by an ISM device is estimated for a certain access point A message flow diagram is shown in FIG. The configuration of the device is the same as in the first embodiment. First, in step S601, the electromagnetic sensor B · 104 monitors the signal transmitted from the access point B · 121 and the signal strength of the channel used by the access point B · 121, and the radio using the access point B · 121. It is determined whether the error rate of communication with the terminal device is high.

  If it is determined that the error rate is high, the electromagnetic sensor B · 104 transmits a message 602 to the control device 101, and the error rate of the access point B · 121 may be high to the control device 101. Notify that. The control apparatus 101 that has received the message 602 transmits a message 603 to the electromagnetic sensor A · 103, checks whether or not an ISM band radio wave is emitted around the electromagnetic sensor A · 103, and occurs if it is emitted. Directs an estimate of the approximate location of the source. In addition, a message 604 is transmitted to the electromagnetic sensor C · 105, and the channel usage rate and error rate of the wireless network managed by the access point C · 131 are measured to the electromagnetic sensor C · 105. The access point C · 131 estimates whether the access point C · 131 is operating normally, whether the performance of the network has deteriorated due to the influence of interference or the like, or whether the channel usage rate is higher than a predetermined value. Instructs to determine whether another terminal device can be added to the network managed by.

  The electromagnetic sensor A · 103 that has received the message 603 checks whether or not the ISM band radio wave is emitted around the electromagnetic sensor A · 103 in step S605, and if so, estimates the approximate position of the source. . The electromagnetic sensor A 103 transmits the estimation result as a message 607 to the control device 101. The electromagnetic sensor C · 105 that has received the message 604 measures the channel usage rate and error rate of the wireless network managed by the access point C · 131 in step S606, and another terminal is added to the network managed by the access point C · 131. Determine whether you can add a device. The electromagnetic sensor C • 105 transmits this determination result to the control apparatus 101 as a message 608.

  The control device 101 may perform an instruction for the electromagnetic sensor A · 103 and an instruction for the electromagnetic sensor C · 105 in parallel, or after obtaining a result of the instruction for the electromagnetic sensor A · 103, You may give instructions. When the measurement time of the electromagnetic sensors A and 103 and the electromagnetic sensors C and 105 is long to some extent, it is efficient to perform the measurements of the respective electromagnetic sensors in parallel, and when these measurement times are sufficiently short, The determination result of the sensor A · 103 is examined, and when it is estimated that interference has occurred from the ISM device, an instruction is given to the electromagnetic sensor C · 105, thereby reducing the amount of messages instructed to the electromagnetic sensor. It becomes possible.

  The control apparatus 101 that has received the message 607 and the message 608 determines whether interference by the ISM device has occurred based on the message 607, and the network controlled by the access point C · 131 based on the message 608 is another wireless network. It is determined whether the terminal device connection can be accepted. If the control device 101 determines that the network managed by the access point B • 121 receives interference from the ISM device and can move the wireless terminal device to the network managed by the access point C • 131, the control device 101 performs frequency shift processing in step S609. In this frequency shift process, the connection destination of one or more terminal devices connected to the access point B • 121 is changed to the access point C • 131, and the method and procedure are not particularly specified. As an example, in the case of a wireless LAN, the connection destination can be changed using a Channel Switch procedure, a Fast BSS Transaction procedure, a Media Independent Handover procedure, or the like.

  Thereafter, the electromagnetic sensor B · 104 monitors the signal transmitted from the access point B · 121 in step S610 and the signal strength of the channel used by the access point B · 121, and the radio using the access point B · 121. It is determined whether the error rate of communication with the terminal device is high. If it is determined that the state has changed, a message 611 is transmitted to the control device 101 to notify the state of the new channel. The control apparatus 101 that has received the message 611 transmits a message 612 that instructs the electromagnetic sensor A · 103 to transmit radio waves to infer whether there is an ISM device that is an interference source. Receiving the message 612, the electromagnetic sensor A · 103 checks whether or not an ISM band radio wave is emitted around the electromagnetic sensor A · 103. If the electromagnetic sensor A · 103 is emitted, the electromagnetic sensor A · 103 estimates the approximate position of the source in step S613. .

  The estimation result is transmitted to the control apparatus 101 as a message 614. The control apparatus 101 that has received the message 614 may transmit a message for controlling the access point B 121 based on the content of the message 611 and the content of the message 614. Further, nothing is required depending on the content of the message 611 and the content of the message 614. As an example, the content of the message 611 indicates that the communication of the access point B 121 is not receiving interference, and the content of the message 614 indicates that no radio wave is emitted from the ISM device. If you can do nothing. In addition, when the content of the message 611 indicates that the access point B 121 has received interference and the content of the message 614 indicates that radio waves are emitted from the ISM device, the display device 102 receives radio waves from the ISM device. You may instruct to display that there is a fire.

  The above procedure has been described with respect to an example in which the frequencies of the channels used by the access point B 121 and the access point C 131 are different. It is. When the positions of the plurality of access points are different and the interference states due to the emission of radio waves from the ISM device are different, the procedure shown in FIG. 7 can be applied. An example of this applicable configuration is shown in FIG.

  Instead of the access point B · 121 and the access point C · 131, the access point B-1 · 701 and the access point B-2 · 702 using the ISM band are used, and the electromagnetic sensor B · 104 is used instead of the electromagnetic sensor B · 104. -1 · 703 and electromagnetic sensor B-2 · 704 are used instead of electromagnetic sensor C · 105. Access points B-1, 701, B-2, 702, electromagnetic sensors B-1, 703, and electromagnetic sensors B-2, 704 all use the ISM band. The electromagnetic sensors B-1 and 703 and the electromagnetic sensors B-2 and 704 are arranged differently, and can measure the channel usage rate and error rate of the access points B-1 and 701 and the access points B-2 and 702, respectively. With such a configuration, a terminal device connected to an access point receiving a lot of interference can execute a procedure substantially equivalent to the procedure shown in FIG. 8 even with a plurality of access points having the same frequency. Can be moved to an access point with less influence of interference.

  Using the procedure described above, the efficiency of communication is improved by moving the terminal device connected to the access point that is subject to interference from radio waves emitted from the ISM device to the access point that is less affected by the interference. Is possible.

  The above is based on the premise that each access point is connected to a backbone line (distribution line), but a so-called mesh network that uses access points that are not connected to the backbone line by connecting the access points with a wireless line. You may apply to. In a mesh network, a wireless terminal device and a backbone line are connected via a plurality of access points. When selecting a route to be used, avoid an access point that is frequently interfered by radio waves emitted from ISM equipment. good. Interference detection using radio waves emitted from the ISM device may be dynamically performed using an electromagnetic sensor, and a route may be selected every time the interference state changes. A method other than the electromagnetic sensor, for example, a method of directly monitoring the operation of the ISM device may be used, and the route may be reselected when the interference is expected to change.

  In the above embodiment, each function is arranged in the control device, the access point, and the electromagnetic sensor. However, the configuration of the device is not limited to the configuration shown in each embodiment. For example, the access point includes the function of the control device. Alternatively, the electromagnetic sensor may include the function of the control device.

  (1) Embodiments according to the present invention can also take the following aspects. That is, the control device is applied to a communication system in which an access point and a wireless terminal device perform wireless communication, and measures the intensity of an interference radio wave that interferes with the radio communication or the position of an interference source that generates the interference radio wave. A first electromagnetic sensor that performs at least one of estimation, a second electromagnetic sensor that measures a propagation path state of a network managed by the access point, and a measurement of the intensity of the interference radio wave from the first electromagnetic sensor At least one of the result or the estimation result of the position of the interference source is acquired, and at least one of the acquired measurement result of the interference radio wave intensity or the estimation result of the position of the interference source is connected to the access point or the access point A communication unit that notifies at least one of the wireless terminal devices.

  (2) Moreover, the control apparatus which concerns on 1 aspect of this invention judged that the said radio | wireless communication has received interference by the propagation path state of the network which the said access point acquired from the said 2nd electromagnetic sensor manages In this case, the information processing apparatus further includes a determination unit that causes the first electromagnetic sensor to execute measurement of the intensity of an interference radio wave that interferes with the wireless communication and estimate a position of an interference source that generates the interference radio wave.

  (3) In the control device according to an aspect of the present invention, when the determination unit determines that the wireless communication is receiving interference, the determination unit instructs the interference source to reduce the degree of interference. Or, give instructions to reduce the time of interference.

  (4) In the control device according to the aspect of the present invention, the determination unit lowers the degree of interference with respect to the interference source with respect to the second electromagnetic sensor after performing the instruction. Notify that the instruction or instruction to reduce the time for giving interference is given.

  (5) A control device according to an aspect of the present invention is a control device that monitors the emission of radio waves from a device that is an interference source with respect to a communication system in which an access point and a wireless terminal device perform wireless communication. A first electromagnetic sensor that performs measurement of the intensity of an interference radio wave that interferes with the wireless communication, and an interference source that interferes with the radio communication is found based on the measured intensity of the interference radio wave, A display device for displaying the presence of the interference source on a screen.

  (6) In the control device according to the aspect of the present invention, the first electromagnetic sensor performs estimation of a position of an interference source that generates the interference radio wave, and the display device performs the estimated interference. Displays the source location.

  (7) In addition, a control device according to an aspect of the present invention includes a second electromagnetic sensor that measures a propagation path state in the wireless communication channel, and the first electromagnetic sensor has a deterioration in the propagation path state. In the case of measuring the intensity of the interference radio wave or estimating the position of the interference source that generates the interference radio wave, the display device displays the presence of the interference source on the screen or the estimated interference source. Display position.

  (8) Moreover, the control apparatus which concerns on 1 aspect of this invention is a control apparatus applied to the communication system with which a 1st access point and a radio | wireless terminal apparatus perform radio | wireless communication, Comprising: The interference which gives interference to the said radio | wireless communication A first electromagnetic sensor that performs at least one of measurement of radio wave intensity or estimation of a position of an interference source that generates the interference radio wave, and second that measures a propagation path state of a network managed by the first access point. When the electromagnetic sensor, the determination unit that determines the measured propagation path state, and the determination unit determine that the measured propagation path state is deteriorated by interference radio waves emitted from an interference source, A second access point that is different from the first access point is a wireless terminal device connected to the first access point with respect to the first access point. And a communication unit that instructs to connect to.

  (9) In the control device according to the aspect of the present invention, the frequency channel used by the second access point is different from the frequency channel used by the first access point.

  (10) In the control device according to the aspect of the present invention, the second access point uses the same frequency channel as the frequency channel used by the first access point and is emitted from the interference source. Used when there is little interference due to interference radio waves.

  (11) A control device according to an aspect of the present invention is a control device connected to an ISM device, and is monitored by a communication unit that receives an inquiry at the time of radio wave emission from the ISM device, and an electromagnetic sensor. A determination unit that determines whether the channel state of the channel is deteriorated due to interference caused by radio wave emission from the ISM device, and the communication unit notifies the ISM device of the determination result. .

  (12) An ISM device according to an aspect of the present invention is an ISM device controlled by a control device, and prior to the emission of radio waves, the control device monitors the electromagnetic sensor by the emission of radio waves. An inquiry is made as to whether or not the channel state of the channel being used deteriorates.

  (13) In addition, the ISM device according to one aspect of the present invention may emit radio waves without restriction or reduce interference based on information notified from the control device after the inquiry. Switch whether to limit the emission of radio waves.

  The program that operates in the apparatus related to the present invention may be a program that controls a central processing unit (CPU) or the like to function a computer so as to realize the functions of the embodiments related to the present invention. The program or information handled by the program is temporarily stored in a volatile memory such as a Random Access Memory (RAM), a nonvolatile memory such as a flash memory, a Hard Disk Drive (HDD), or other storage device system.

  A program for realizing the functions of the embodiments according to the present invention may be recorded on a computer-readable recording medium. You may implement | achieve by making a computer system read the program recorded on this recording medium, and executing it. The “computer system” here is a computer system built in the apparatus, and includes hardware such as an operating system and peripheral devices. The “computer-readable recording medium” refers to a semiconductor recording medium, an optical recording medium, a magnetic recording medium, a medium that dynamically holds a program for a short time, or other recording medium that can be read by a computer. Also good.

  In addition, each functional block or various features of the apparatus used in the above-described embodiments can be implemented or executed by an electric circuit, for example, an integrated circuit or a plurality of integrated circuits. Electrical circuits designed to perform the functions described herein can be general purpose processors, digital signal processors (DSPs), application specific integrated circuits (ASICs), field programmable gate arrays (FPGAs), or others Programmable logic devices, discrete gate or transistor logic, discrete hardware components, or combinations thereof. A general purpose processor may be a microprocessor or a conventional processor, controller, microcontroller, or state machine. The electric circuit described above may be configured by a digital circuit or an analog circuit. In addition, when an integrated circuit technology that replaces the current integrated circuit appears due to progress in semiconductor technology, one or more aspects of the present invention can use a new integrated circuit based on the technology.

  In addition, this invention is not limited to the above-mentioned embodiment. In the embodiment, an example of the apparatus has been described. However, the present invention is not limited to this, and a stationary or non-movable electronic device installed indoors or outdoors, such as an AV device, a kitchen device, It can be applied to terminal devices or communication devices such as cleaning / washing equipment, air-conditioning equipment, office equipment, vending machines, and other daily life equipment.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design changes and the like without departing from the gist of the present invention. The present invention can be modified in various ways within the scope of the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments are also included in the technical scope of the present invention. It is. Moreover, it is the element described in each said embodiment, and the structure which substituted the element which has the same effect is also contained.

  The present invention is applicable to a wireless communication device.

101 Control Device 101a Communication Unit 101b Determination Unit 102 Display Device 103 Electromagnetic Sensor A
104 Electromagnetic sensor B
105 Electromagnetic sensor C
111 ISM Equipment A-1
112 ISM equipment A-2
121 Access point B
122 Wireless terminal apparatus B-1
123 Wireless terminal device B-2
131 Access point C
132 Wireless terminal apparatus C-1
133 wireless terminal C-2
201, 203 Arrival angle estimation unit 202, 204 Array antenna 205 Control unit 206 Communication unit 211, 212 Signal detection unit 213, 214 LCX
215 Control unit 216 Communication unit 221, 222 Signal detection unit 223, 224 Switching unit 233 Control unit 234 Communication unit 701 Access point B-1
702 Access point B-2
703 Electromagnetic sensor B-1
704 Electromagnetic sensor B-2

Claims (13)

A control device applied to a communication system in which an access point and a wireless terminal device perform wireless communication,
A first electromagnetic sensor that performs at least one of measurement of an intensity of an interference radio wave that interferes with the wireless communication or estimation of a position of an interference source that generates the interference radio wave;
A second electromagnetic sensor for measuring a propagation path state of a network managed by the access point;
At least one of the measurement result of the interference radio wave intensity or the estimation result of the position of the interference source is acquired from the first electromagnetic sensor, and the acquired measurement result of the interference radio wave intensity or the position of the interference source is estimated. And a communication unit that notifies at least one of the results to at least one of the access point or the wireless terminal device connected to the access point.   When it is determined that the wireless communication is interfered by the propagation path state of the network managed by the access point acquired from the second electromagnetic sensor, the wireless communication is performed with respect to the first electromagnetic sensor. The control apparatus according to claim 1, further comprising: a determination unit that performs measurement of the intensity of an interference radio wave that causes interference and estimation of a position of an interference source that generates the interference radio wave.   3. The determination unit according to claim 2, wherein when the determination unit determines that the wireless communication is receiving interference, the determination unit instructs the interference source to reduce the degree of interference or decreases the time during which interference is applied. Control device.   The determination unit, after giving the instruction, notifies the second electromagnetic sensor that an instruction to lower the degree of interference or an instruction to reduce the time for giving interference is given to the interference source. The control device according to claim 3. A control device that monitors the emission of radio waves from a device that is an interference source for a communication system in which an access point and a wireless terminal device perform wireless communication,
A first electromagnetic sensor that performs measurement of the intensity of an interfering radio wave that interferes with the wireless communication;
A control device comprising: a display device that displays the presence of the interference source on a screen when an interference source that interferes with the wireless communication is found based on the measured intensity of the interference radio wave. The first electromagnetic sensor performs estimation of a position of an interference source that generates the interference radio wave,
The control device according to claim 5, wherein the display device displays the estimated position of the interference source. A second electromagnetic sensor for measuring a propagation path state in the wireless communication channel;
The first electromagnetic sensor, when the propagation path state is deteriorated, performs measurement of the intensity of an interference radio wave or estimation of a position of an interference source that generates the interference radio wave,
The control device according to claim 6, wherein the display device displays the presence of the interference source on a screen or displays the estimated position of the interference source. A control device applied to a communication system in which a first access point and a wireless terminal device perform wireless communication,
A first electromagnetic sensor that performs at least one of measurement of an intensity of an interference radio wave that interferes with the wireless communication or estimation of a position of an interference source that generates the interference radio wave;
A second electromagnetic sensor for measuring a propagation path state of a network managed by the first access point;
A determination unit for determining the measured propagation path state;
When the determination unit determines that the measured propagation path state is deteriorated by an interference radio wave emitted from an interference source, the determination unit is connected to the first access point with respect to the first access point. And a communication unit that instructs the wireless terminal device to connect to a second access point different from the first access point.   The control device according to claim 8, wherein a frequency channel used by the second access point is different from a frequency channel used by the first access point.   The said 2nd access point uses the same frequency channel as the frequency channel which the said 1st access point uses, and is used when there is little interference by the interference electromagnetic wave emitted from the said interference source. Control device. A control device connected to an ISM device,
A communication unit for receiving an inquiry at the time of radio wave emission from the ISM device;
A determination unit that determines whether the propagation path state of the channel monitored by the electromagnetic sensor is deteriorated due to interference caused by radio wave emission from the ISM device,
The said communication part is a control apparatus which notifies the result of the said determination with respect to the said ISM apparatus. An ISM device controlled by a control device,
An ISM device that inquires of the control device whether or not the propagation path state of a channel monitored by an electromagnetic sensor deteriorates due to the emission of radio waves prior to the emission of radio waves.   13. The method according to claim 12, wherein after the inquiry, based on information notified from the control device, switching between whether to emit radio waves without limitation or to limit radio waves to reduce interference is performed. ISM device.

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