JP2008054303A - Radio communication equipment, wireless lan system, interference detection method, and interference avoidance method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide radio communication equipment, a wireless LAN system, an interference detection method, and an interference avoidance method, detecting the occurrence of a communication error due to the occurrence of interference. <P>SOLUTION: Radio communication equipment 100 has a transmission packet interference error detection circuit 120 including an ED value detection circuit 105 for measuring an ED value before packet transmission, an Ack error detection circuit 106 for detecting an Ack error in regard to a transmitted packet, and a transmission packet interference error decision circuit 107. An interference error is decided when the Ack error is detected in regard to the packet transmitted under the condition that the measured ED value exceeds an interference decision threshold. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a wireless communication device, a wireless LAN system, an interference detection method, and an interference avoidance method that detect interference and avoid interference when interference occurs.

  In recent years, taking into account the ease of installation, the economics of introduction costs, etc., there are increasing cases of building a wireless LAN (hereinafter referred to as WLAN: Wireless Local Area Network) in offices and homes. A typical WLAN technology is IEEE 802.11 standardized by the Institute of Electrical and Electronics Engineers (IEEE). This standardized technology defines from the physical layer to the MAC (Medium Access Control) layer, which is the lower layer of the data link, in the OSI model. It is a specification that can be replaced, and can also provide a roaming function as an additional function because it is wireless.

  The WLAN, Bluetooth (registered trademark), and UWB (Ultra Wideband) are used as a system that can access a local network other than the carrier. WLAN is widely used in portable information terminals such as portable notebook personal computers with WLAN functions and PDAs (Personal Digital Assistants). In mobile phones that require lower power consumption, attention is paid to low-power short-distance two-way wireless communication systems such as Bluetooth (registered trademark) and UWB.

  In a wireless network, when a transmitter and a receiver are communicating at a specific frequency (communication channel), if another transmitter / receiver pair uses the same communication channel, the data transmission bandwidth is reduced. Therefore, a device that uses the communication channel later needs to automatically change to a free communication channel.

  As a wireless communication device for changing a communication channel, for example, in Patent Document 1, a wireless communication unit is provided with a 2.4 GHz band front end circuit and a 5 GHz band front end circuit, and two 2.4 GHz band and 5 GHz band signals are provided. By adapting to the frequency band, the number of channels that can be set simultaneously in the same area in the WLAN system is greatly increased, thereby reducing the possibility that the communication link is interrupted by jamming radio waves.

  FIG. 30 is a diagram illustrating a configuration of a wireless communication device in a conventional WLAN. In FIG. 30, the wireless communication device 10 includes an antenna 11, a transmission / reception selector switch (T / R SW) 12, a WLAN transmission circuit 13, a WLAN reception circuit 14, and a WLAN control circuit 15.

  The transmission / reception selector switch (T / R SW) 12 switches the SW at a transmission timing and a reception timing. The WLAN transmission circuit 13 transmits a signal in the WLAN. The WLAN receiving circuit 14 receives a signal in the WLAN. The WLAN control circuit 15 controls the WLAN transmission circuit 13 and the WLAN reception circuit 14.

  By the way, the WLAN can move each terminal forming the WLAN within a communicable range as compared with a wired LAN used before the introduction of the WLAN, and has high mobility. The boundary indicating is ambiguous. Since a boundary indicating a communicable range is ambiguous, when a plurality of WLANs exist adjacent to each other, a terminal may exist in a range where the communicable ranges of the plurality of WLANs overlap each other. is there. When these terminals receive respective radio waves in adjacent WLANs, radio interference problems may occur and throughput may be reduced.

[Radio interference detection technology]
As a method for detecting the radio wave interference, for example, Patent Document 2 discloses a technique for detecting interference based on an ID reception rate of a BSS (Basic Service Set) received from other than an AP (Access Point) with which the station is communicating. It is disclosed. The radio wave interference detection method described in Patent Document 2 includes an external BSSID reception rate calculation unit that calculates a reception rate of a frame including another BSS ID different from the corresponding BSS ID in the entire received frame, Based on the external BSSID reception rate calculated by the external BSSID reception rate calculation unit, it is detected whether interference has occurred between the BSSs.

  Patent Document 3 discloses a technique for determining interference based on the received power of a radio signal transmitted from a radio device other than the AP with which the station is communicating. The radio wave interference determination method described in Patent Document 3 is a function for determining whether or not interference should be avoided by determining the degree of interference from the interference amount monitor signal output from the wireless interface unit and changing the operation channel. It has.

[Radio interference avoidance technology]
When radio wave interference is detected, the following interference avoidance method is adopted. Patent Document 4 discloses a technique for performing interference avoidance by changing a frequency channel when radio wave interference is detected. The radio wave interference avoidance method described in Patent Document 4 is based on a signal received by a wireless antenna when a plurality of frequency channels are selectively set and wirelessly connected to an equipment terminal in a wireless network system. The radio wave level of each channel is measured at a predetermined cycle, and the measured others are compared with a predetermined threshold value to determine whether each frequency channel is used or not used, and stored as usage frequency statistical data for each frequency channel. During the wireless communication with the device terminal, the frequency channel is changed based on the statistical data as necessary.

Further, when a communication error occurs, fallback control is performed to decrease the transmission rate and increase the transmission distance. However, if the transmission rate is lowered to the minimum rate due to fallback, the throughput will be significantly reduced. In Patent Document 5, when an error occurs due to the occurrence of interference, in order to avoid a significant decrease in throughput due to the fall of the transmission rate to the lowest rate due to fallback, a reference throughput at the time of interference is set to be the throughput. The speed mode is controlled to ensure a certain level of throughput. Specifically, the presence / absence of interference from an interference device that operates in the same frequency band as the wireless communication device to receive and operates based on a standard different from the standard used for communication of the wireless communication device is determined wirelessly. When the communication device detects it, the wireless communication device sets the reference throughput when changing the speed mode as the interference throughput, thereby changing the speed mode.
JP 2002-33676 A JP 2006-109448 A Japanese Patent Laid-Open No. 2004-357056 JP 2005-333510 A JP 2005-278052 A

  However, such conventional radio wave interference avoiding methods have the following problems.

  (1) Even when interference occurs, a communication error occurs due to the influence of the interference wave, so fallback is performed to reduce the transmission rate. However, if the transmission rate is lowered by fallback, the packet length increases, which adversely affects the interference.

  FIG. 31 is a diagram illustrating a relationship between an interference wave and a communication carrier. As shown in FIG. 31A, interference waves are generated periodically or in bursts. In the communication carrier in which radio wave interference is occurring (see FIG. 31B), the transmission rate is controlled to be reduced by fallback to increase the transmission distance, as in the case where a communication error occurs. (See FIG. 31 (c)). Here, the communication carrier is the packet length of the frequency band transmitted and received by the wireless communication device, and when the wireless communication device detects an interference wave, it performs fallback control to change the throughput setting and lower the transmission rate. To do. As shown in FIG. 31C, the packet length increases due to fallback and the communication packet becomes longer on the time axis, so that the possibility that the communication packet after fallback collides with the next interference wave is increased. That is, it always shifts in the direction of colliding with the interference wave due to fallback.

  (2) When the number of retransmissions at the time of interference occurrence is set to be large in the case of a low rate, the jitter (variation on the time axis) in the radio section increases, so it is usually set to about 3 to 7 times.

  FIG. 32 is a diagram illustrating a relationship between an interference wave and the number of packet retransmissions.

  In the case of a low rate, the interference wave generation time region is retransmitted 3 to 7 times to avoid jitter in the radio section. However, as shown in FIG. 32, when communicating at a high rate, the packet length is short, so even if retransmission is repeated 3 to 7 times, the interference wave generation time region cannot be exceeded and the interference wave Cannot be avoided. That is, since the number of retransmissions is small, it is not possible to reach a time region where there is no interference wave.

  The above problems (1) and (2) will be described in more detail.

  FIG. 33 is a diagram illustrating the relationship between the interference wave and the number of packet retransmissions. FIG. 33A illustrates the problem (1), and FIG. 33B illustrates the problem (2).

  When the microwave oven is turned on in the frequency band of the communication carrier with which the wireless communication apparatus is transmitting and receiving, the microwave oven becomes an interference wave generation source, and the interval between the microwave ovens is an interference section. Note that the microwave oven generates interference radio waves over a wide frequency band including the 2.4 GHz frequency band used in WLAN, interferes in a burst manner when the microwave oven is ON, and is completely asynchronous with the WLAN. Cause interference. Further, Beacon is periodically transmitted from the access point and has a packet length of about 1 msec.

  A case where the microwave oven ON (interference section) is intermittently generated during 20 msec is taken as an example. As shown in FIG. 33 (a), when interference occurs during transmission, control is performed to reduce the transmission rate by a fallback operation together with the occurrence of a communication error. As a result, retransmission 1 with the packet length increased. , 2, 3,... However, since the packet size is large, it is not possible to pass through the gap of the microwave oven ON (interference section), and communication is impossible due to collision with an interference wave.

  Also, as shown in FIG. 33 (b), since interference occurs during transmission and the number of retransmissions is a specified number that is small even if retransmissions 1, 2, 3,... Are repeated, the microwave oven ON interval (interference interval) is set. Over-retransmission is not successful and interference cannot be avoided.

  In this way, conventionally, when receiving interference from a microwave oven or the like during WLAN communication, the packet length becomes longer due to a fall in the transmission rate due to fallback, and interference cannot be avoided with the specified number of packet retransmissions. There is a problem that disappears.

  The present invention has been made in view of this point, and provides a wireless communication device, a wireless LAN system, an interference detection method, and an interference avoidance method for detecting that a communication error has occurred due to the occurrence of interference. Objective.

  In addition, the present invention provides a wireless communication device, a wireless LAN system, an interference detection method, and an interference avoidance method capable of avoiding interference when affected by interference waves from an interference source such as a microwave oven during WLAN communication. The purpose is to provide.

  The wireless communication apparatus of the present invention includes a communication state determination unit that determines a wireless communication state, a packet error detection unit that detects that a transmitted or received packet is an error, and a wireless communication that is determined by the communication state determination unit When a state is a predetermined interference determination condition, an interference error determination unit that determines an interference error by an interference source when an error is detected by the packet error detection unit is employed.

  The wireless communication device of the present invention is a wireless communication device that performs fallback control to lower a transmission rate when a communication error occurs, and stops the fallback control and fixes the transmission rate to a constant rate when an interference error is detected. And the structure provided with the interference avoidance control means which increases the frequency | count of resending from normal communication is taken.

  The wireless communication device of the present invention is a wireless communication device that performs rate control to increase a transmission rate when communication errors are improved. When an interference error is detected, the fallback control is stopped and the transmission rate is set to a constant rate. A configuration is provided that includes interference avoidance control means that is fixed and increases the number of retransmissions over normal communication.

  The wireless communication apparatus of the present invention includes an interference detection unit that detects an interference error, an interference source determination unit that determines an interference source when an interference wave is generated, a transmission rate that matches the interference wave of the determined interference source, the number of retransmissions, And / or setting means for setting at least one of the transmission timings, and interference avoidance control means for performing interference avoidance control based on the set transmission rate, number of retransmissions, and / or transmission timing.

  The wireless LAN system of the present invention is a wireless LAN system for connecting a plurality of wireless communication devices through a wireless network, and has a configuration including the wireless communication device.

  The interference detection method of the present invention includes a step of measuring an interference wave level ED (Energy Detect) value before transmitting a packet, a step of detecting an Ack error for the transmitted packet, and the measured ED value exceeds an interference determination threshold value. A step of determining an interference error when the Ack error is detected for a packet transmitted under the above conditions.

  The interference detection method of the present invention includes a step of measuring an ED value before packet transmission, a step of detecting a transmission error in which a transmitted packet cannot be retransmitted at a predetermined number of retransmissions, and the measured ED value has exceeded an interference determination threshold value. And a step of determining an interference error when the transmission error is detected for a packet transmitted under conditions.

  The interference detection method of the present invention includes a step of measuring a noise floor (NF) value that is a noise level at the time of receiving a received packet, a step of detecting that the received packet is a reception error including an FCS error, and a measured noise floor. And a step of determining an interference error when a reception error is detected for a packet received under a condition that the value exceeds an interference determination threshold value.

  The interference detection method of the present invention includes a step of measuring a Noisefloor value at the time of Beacon reception, a step of detecting that a received packet is a reception error including an FCS error, and the measured Noisefloor value exceeds an interference determination threshold value. And a step of determining an interference error when the reception error is detected for a packet received under conditions.

  The interference avoidance method of the present invention includes a step of stopping fallback control for lowering the transmission rate and fixing the transmission rate to a constant rate when detecting an interference error, and a step of increasing the number of retransmissions compared to normal communication.

  The interference avoidance method of the present invention includes a step of determining an interference source when an interference wave is generated, and a step of setting at least one of a transmission rate, the number of retransmissions, and / or a transmission timing that matches the interference wave of the determined interference source. And a step of performing interference avoidance control based on the set transmission rate, number of retransmissions, and / or transmission timing.

  According to the present invention, it is possible to detect that a communication error has actually occurred due to the cause of interference.

  Further, during WLAN communication, interference can be avoided and communication can be performed when affected by an interference wave from an interference source such as a microwave oven.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  The first to third embodiments are application examples of the interference detection circuit and method, and the fourth and fifth embodiments are application examples of the interference avoidance circuit and method.

(Embodiment 1)
FIG. 1 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 1 of the present invention. The present embodiment is an example applied to a wireless communication apparatus in WLAN.

  In FIG. 1, a wireless communication device 100 is a wireless communication terminal such as a mobile phone / PHS (Personal Handy-Phone System) or PDA that performs wireless communication, and has a WLAN function as a system that can access a local network other than a carrier. As information distribution services using networks other than carriers, there are low-power short-distance two-way wireless communication systems such as Bluetooth (registered trademark) and UWB in addition to WLAN.

  The wireless communication apparatus 100 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED (Energy Detect) value detection circuit 105, an Ack error detection circuit 106, and a transmission packet interference error. The determination circuit 107, the interference avoidance control circuit 108, the rate control circuit 109, the retransmission count control circuit 110, and the WLAN control circuit 111 are configured.

  The ED value detection circuit 105, the Ack error detection circuit 106, and the transmission packet interference error determination circuit 107 constitute a transmission packet interference error detection circuit 120 as a whole, and the interference avoidance control circuit 108, the rate control circuit 109, and the number of retransmissions. The control circuit 110 constitutes an interference avoidance circuit 130 as a whole.

  A transmission / reception selector switch (T / R SW) 102 switches the SW at the transmission timing and the reception timing. The WLAN transmission circuit 103 transmits a signal in the WLAN. The WLAN receiving circuit 104 receives signals in the WLAN. The WLAN control circuit 111 controls the WLAN transmission circuit 103 and the WLAN reception circuit 104. These are the same configurations as those of the wireless communication apparatus 10 of FIG.

[Configuration of Transmission Packet Interference Error Detection Circuit 120]
Before transmitting the packet, the ED value detection circuit 105 measures the level of the interference wave (ED value) and determines that it exceeds the interference determination threshold. The Ack error detection circuit 106 detects that Ack for the transmitted packet is missing. The transmission packet interference error determination circuit 107 determines that a transmission packet interference error has occurred from the ED value detected by the ED value detection circuit 105 and the Ack error detection detected by the Ack error detection circuit 106.

[Configuration of interference avoidance circuit 130]
The interference avoidance control circuit 108 controls the transmission rate and the number of retransmissions in order to avoid interference when an interference error occurs. The rate control circuit 109 actually changes the rate in accordance with the request of the interference avoidance control circuit 108. The retransmission number control circuit 110 changes the number of retransmissions according to the request from the interference avoidance control circuit 108. Details of the interference avoidance control by the interference avoidance circuit 130 will be described later in Embodiment 4 and Embodiment 5.

  Hereinafter, an interference detection method of the wireless communication apparatus configured as described above will be described.

  In the conventional example, it is merely detected whether or not an interference wave is generated, and it is not performed to detect whether or not a communication error has occurred due to the generation of the interference wave. In the present embodiment, it is determined whether the generated communication error is caused by interference or not. That is, this interference detection method detects whether or not a communication error has actually occurred due to the occurrence of interference. As this interference detection method, there is an interference detection method for three packets of a transmission packet, a reception packet, and a Beacon. In this embodiment, a transmission packet interference error detection method will be described.

  FIG. 2 is a diagram for explaining a transmission packet interference error detection method by the transmission packet interference error detection circuit 120. This interference detection method is called an Ack error determination method.

  In normal operation of WLAN, ED (Energy Detect) is used to detect whether there is a communication carrier of a system other than WLAN before transmitting a transmission packet or to detect whether an interference wave such as a microwave oven is generated. Carrier sense (CS) is performed to detect the value and the presence of a WLAN communication carrier.

  First, in the transmission packet interference error detection circuit 120, the ED value detection circuit 105 measures the ED value detected before packet transmission, and the Ack error detection circuit 106 transmits under conditions that exceed a preset interference determination threshold. An Ack response from an AP (Access Point) to the packet is detected. The transmission packet interference error determination circuit 107 determines that there is a transmission packet error due to interference when the Ack response from the AP for the transmitted packet is missing.

  The transmission packet interference error detection method will be specifically described with reference to FIG.

  (1) The ED value detection circuit 105 measures the ED value in order to detect the interference wave level transmitted in the vicinity before transmitting the packet. The measured ED value is compared with a preset interference determination threshold value to determine whether the ED value exceeds the interference determination threshold value (see FIG. 2a). Then, FIG. The transmission 1 collides with an interference section such as microwave oven ON, and Ack for the transmitted packet is lost (see FIG. 2c). Upon receiving the Ack loss, the WLAN control circuit 111 causes the WLAN transmission circuit 103 to retransmit the corresponding packet (see FIG. 2d). Also for this retransmission, the Ack is lost due to collision with the interference section.

  (2) The transmission packet interference error detection circuit 120 is different from the retransmission operation in FIG. At this timing, the Ack error detection circuit 106 detects missing Ack for the packet transmitted. That is, the Ack error detection circuit 106 performs Ack error determination as to whether or not Ack for the transmitted packet has been detected. Now, FIG. Suppose that an Ack loss and an interference determination threshold value excess of the ED value occur.

  (3) In the transmission packet interference error determination circuit 107, when a packet transmitted under the condition that the ED value detected in (1) exceeds the interference determination threshold value becomes an Ack error, a transmission packet error (interference error) due to interference occurs. (See FIG. 2f). In the prior art, the level of the interference wave was detected and it was determined that interference occurred, but it was not performed to detect whether an error actually occurred in the environment where the interference wave occurred. It was.

  The present invention is characterized in that the interference wave level is detected based on the ED value, and whether or not the packet transmitted under the condition where the interference wave is actually generated has an error is determined. The transmission packet interference error detection circuit 120 according to the present embodiment determines an interference error when a packet transmitted under the condition that the measured ED value exceeds the interference determination threshold value results in an Ack error.

  When the transmission packet interference error detection circuit 120 determines an interference error, the WLAN control circuit 111 causes the interference avoidance circuit 130 to execute the interference avoidance mode (see FIG. 2g).

  The interference avoidance control performed by the interference avoidance circuit 130 will be described later in the fourth to fifth embodiments.

  Here, in brief, when the interference is detected, the interference avoidance circuit 130 performs <rate setting> for setting the transmission rate to a preset rate and <retransmission count setting> for fixing the number of retransmissions. (See FIG. 2h.).

  Based on the interference avoidance control by the interference avoidance circuit 130, the rate setting and the retransmission number setting are performed, and according to the rate setting and the retransmission number setting, FIG. Packet transmission (transmission 2) shown in FIG. Here, this transmission 2 also collides with the interference section, and Ack for the transmitted packet is lost (see FIG. 2j). Upon receiving this Ack loss, when the WLAN control circuit 111 repeats retransmission of the packet to the WLAN transmission circuit 103 (see FIG. 2k), the retransmission succeeds through the interference period (see FIG. 21). Communication is OK when Ack is received (see FIG. 2m).

  The reason why the interference avoidance can be promptly performed is that the interference avoidance circuit 130 immediately performs the interference avoidance control by setting the rate and the number of retransmissions upon receiving the interference error detection by the transmission packet interference error detection circuit 120. is there.

  As described above, according to the present embodiment, radio communication apparatus 100 includes ED value detection circuit 105 that measures an ED value before packet transmission, Ack error detection circuit 106 that detects an Ack error for the transmitted packet, and A transmission packet interference error detection circuit 120 including a transmission packet interference error determination circuit 107 is provided, and an interference error is detected when an Ack error is detected for a packet transmitted under the condition that the measured ED value exceeds the interference determination threshold. Therefore, it is possible to detect that a communication error has actually occurred due to the occurrence of interference. In the conventional example, only whether or not an interference wave is generated is detected. On the other hand, in the present embodiment, it is possible to distinguish whether the generated communication error is due to an interference error or not, and it is possible to cope with the content of the communication error. For example, in the case of an interference error, interference avoidance control by the interference avoidance circuit 130 can be performed.

  Further, in the present embodiment, when interference is detected by the transmission packet interference error detection circuit 120, the interference avoidance circuit 130 sets the rate setting and the number of retransmissions and performs the interference avoidance control, so that FIG. Interference can be effectively avoided when affected by interference waves from an interference source such as the microwave oven shown.

(Embodiment 2)
FIG. 3 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 2 of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals, and description of overlapping portions is omitted. The present embodiment is an example applied to a transmission packet interference error detection method.

  In FIG. 3, a radio communication apparatus 200 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED value detection circuit 105, a transmission error detection circuit 211, a transmission packet interference error. The determination circuit 212, the interference avoidance control circuit 108, the rate control circuit 109, the retransmission count control circuit 110, and the WLAN control circuit 111 are configured.

  The ED value detection circuit 105, the transmission error detection circuit 211, and the transmission packet interference error determination circuit 212 constitute a transmission packet interference error detection circuit 220 as a whole. The transmission packet interference error detection circuit 220 replaces the Ack error detection circuit 106 and the transmission packet interference error determination circuit 107 of the transmission packet interference error detection circuit 120 in FIG. 1 with a transmission error detection circuit 211 and a transmission packet interference error determination circuit 212. Only the difference is.

  The transmission error detection circuit 211 detects as a transmission error that the transmitted packet could not be transmitted by the specified retransmission.

  The transmission packet interference error determination circuit 212 determines that a transmission packet interference error has occurred from the ED value detected by the ED value detection circuit 105 and the transmission error detection result detected by the transmission error detection circuit 211.

  Hereinafter, an interference detection method of the wireless communication apparatus configured as described above will be described. The first embodiment determines that an interference error has occurred when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value results in an Ack error. In the present embodiment, the operation is different only in that an interference error is determined when a packet transmitted under the same conditions cannot be transmitted even by a plurality of retransmissions.

  FIG. 4 is a diagram for explaining a transmission packet interference error detection method by the transmission packet interference error detection circuit 220. This interference error detection method is called a transmission error determination method.

  In normal operation of the WLAN, ED value detection and carrier sense (CS) for detecting the presence of a wireless LAN communication carrier are performed in order to detect whether another communication carrier exists before transmission of a transmission packet.

  First, in the transmission packet interference error detection circuit 220, the ED value detection circuit 105 measures the ED value to be detected before packet transmission, and the transmission error detection circuit 211 transmits under conditions that exceed a preset interference determination threshold. Detect whether the packet could be sent with the specified retransmission. The transmission packet interference error determination circuit 212 determines an interference error when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value cannot be transmitted even after a plurality of retransmissions.

  A transmission packet interference error detection method will be specifically described with reference to FIG.

  (1) The ED value detection circuit 105 measures the ED value in order to detect the interference wave level transmitted in the vicinity before transmitting the packet. It is compared with a preset interference determination threshold value to determine whether the ED value exceeds the interference determination threshold value (see FIG. 4a). Then, FIG. The transmission 1 collides with an interference section such as a microwave oven ON, and Ack for the transmitted packet is lost (see FIG. 4c). Upon receiving the Ack loss, the WLAN control circuit 111 causes the WLAN transmission circuit 103 to retransmit the packet (see FIG. 4d). Also for this retransmission, the Ack is lost due to collision with the interference section.

  (2) The transmission error detection circuit 211 detects, as a transmission error, that the transmitted packet could not be transmitted by the specified retransmission. Now, FIG. Suppose that a transmission error and an interference determination threshold exceeding the ED value occur.

  (3) In the transmission packet interference error determination circuit 212, an error (transmission error) that is terminated when a packet transmitted under the condition that the ED value detected in (1) exceeds the interference determination threshold value cannot be transmitted even by the specified retransmission. Detect (see FIG. 4f). In the prior art, the level of the interference wave is detected and it is determined that interference has occurred, but it has not been performed to detect whether an error has occurred in an environment where the interference wave is generated.

  In the present invention, the interference wave level is detected based on the ED value, and it is actually determined whether or not the packet transmitted under the condition where the interference wave is generated cannot be transmitted even by the specified retransmission, resulting in a transmission error. It is characterized by doing. The transmission packet interference error detection circuit 220 according to the present embodiment determines an interference error when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value results in a transmission error.

  When the transmission packet interference error detection circuit 220 determines an interference error, the WLAN control circuit 111 causes the interference avoidance circuit 130 to execute the interference avoidance mode (see FIG. 4g).

  The interference avoidance control performed by the interference avoidance circuit 130 will be described later in the fourth and fifth embodiments.

  Here, in brief, when the interference is detected, the interference avoidance circuit 130 performs <rate setting> that sets the transmission rate to a preset rate and <retransmission count setting> that sets the number of retransmissions. (See FIG. 4h).

  Based on the interference avoidance control by the interference avoidance circuit 130, the rate setting and the retransmission count setting are performed. Packet transmission (transmission 2) shown in FIG. Here, this transmission 2 also collides with the interference section, and Ack for the transmitted packet is lost (see FIG. 4j). Upon receiving this Ack loss, when the WLAN control circuit 111 repeats retransmission of the packet to the WLAN transmission circuit 103 (see FIG. 4k), the retransmission succeeds through the interference period (see FIG. 41). Communication is OK when Ack is received (see FIG. 4m).

  The Ack error determination method according to the first embodiment described above is a method with excellent responsiveness for interference wave determination, but the determination based on the transmission error according to the present embodiment is to determine that the packet actually has an error. This is a certainty method. For example, even if there is an Ack error, the communication may actually continue without error by retransmission. Therefore, it is preferable to adaptively select an Ack error determination method with excellent responsiveness and a transmission error determination method with excellent reliability in a WLAN application environment.

(Embodiment 3)
FIG. 5 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 3 of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals, and description of overlapping portions is omitted. The present embodiment is an example applied to a received packet interference error detection method.

  In FIG. 5, a wireless communication apparatus 300 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, a noise floor (interference wave level) value measurement circuit 310, and a reception error detection circuit 311. A reception packet (Beacon) interference error determination circuit 312, an interference avoidance control circuit 108, a rate control circuit 109, a retransmission count control circuit 110, and a WLAN control circuit 111.

  The Noise floor value measurement circuit 310, the reception error detection circuit 311 and the reception packet (Beacon) interference error determination circuit 312 constitute a reception packet interference error detection circuit 320 as a whole. The reception packet interference error detection circuit 320 is used in place of the transmission packet interference error detection circuit 120 of FIG.

  The noise floor (NF) value measuring circuit 310 measures noise floor (noise level) measured before and after the received packet. The reception error detection circuit 311 determines that the received packet has an error (FCS error: Frame Check Sequence error). The received packet (including Beacon) interference error determination circuit 312 determines whether the received packet error is an interference error based on noise floor and information notified from the reception error detection circuit 311.

  Hereinafter, an interference detection method of the wireless communication apparatus configured as described above will be described.

  In the first and second embodiments, the interference error is determined from the transmission packet. The present embodiment is an interference detection method for detecting an interference error from a received packet and a Beacon.

  FIG. 6 is a diagram for explaining a reception packet interference error detection method by the reception packet interference error detection circuit 320.

  The Noise floor value at the time of receiving a packet is measured, and if a packet received in a state where a preset interference determination threshold is exceeded, an error is determined as a received packet error due to interference.

  The received packet interference error detection method will be specifically described with reference to FIG.

  (1) Noise floor value measurement circuit 310 measures noise floor measured before and after the received packet. Compared with a preset interference determination threshold value, it is determined whether the Noisefloor value exceeds the interference determination threshold value (see FIG. 6a). Then, FIG. Is received (reception 1). However, the reception 1 collides with an interference interval such as microwave oven ON and cannot be received, and the Ack for the received packet is not transmitted (see FIG. 6c). Upon receiving the Ack not transmitted, the WLAN control circuit 111 causes the WLAN transmitting circuit 103 to retransmit the corresponding packet (see FIG. 6D). This retransmission also collides with the interference section and Ack is not transmitted.

  (2) The reception packet interference error detection circuit 320 is different from the retransmission operation in FIG. At this timing, the reception error detection circuit 311 determines that the received packet has an error (FCS error). Now, FIG. Suppose that Noise floor value determination and FCS error occur.

  (3) In the received packet (Beacon) interference error determination circuit 312, when a packet received under the condition that the Noisefloor value detected in (1) exceeds the interference determination threshold value becomes an error, Determine (see FIG. 6f). In the prior art, the level of the interference wave is detected and it is determined that interference has occurred, but it has not been performed to detect whether an error has occurred in an environment where the interference wave is generated.

  The present invention is characterized in that the interference wave level is detected based on the Noisefloor value, and whether or not the packet received under the condition where the interference wave is actually generated has an error is determined. The received packet interference error detection circuit 320 according to the present embodiment determines that an interference error has occurred when a packet received in a state where the Noise floor value exceeds the interference determination threshold value causes an FCS error.

  When the reception packet interference error detection circuit 320 determines an interference error, the WLAN control circuit 111 causes the interference avoidance circuit 130 to execute the interference avoidance mode (see FIG. 6g).

  The interference avoidance control performed by the interference avoidance circuit 130 will be described later in the fourth and fifth embodiments.

  Here, in brief, when the interference is detected, the interference avoidance circuit 130 performs <rate setting> that sets the transmission rate to a preset rate and <retransmission count setting> that sets the number of retransmissions. (See FIG. 6h).

  Based on the interference avoidance control by the interference avoidance circuit 130, the rate setting and the retransmission count setting are performed. Packet transmission (transmission 1) shown in FIG. Here, this transmission 1 also collides with the interference section, and Ack for the transmitted packet is lost (see FIG. 6j). Upon receiving this Ack loss, when the WLAN control circuit 111 repeats retransmission of the packet to the WLAN transmission circuit 103 (see FIG. 6k), the retransmission succeeds through the interference period (see FIG. 61). After receiving the Ack (see FIG. 6m), if the received packet can be received in a section other than the interference (see FIG. 6n), the communication between the transmitted and received packets is OK (see FIG. 6o).

  As described above, according to the present embodiment, the wireless communication device 300 includes a noise floor value measuring circuit 310 that measures the received packet or the noise floor value of the beacon, and a reception error detection circuit that detects that the received packet is an FCS error. 311, a received packet (Beacon) interference error determination circuit 312, which is determined to be an interference error when an FCS error is detected for a packet received under the condition that the measured Noisefloor value exceeds the interference determination threshold. The same effect as in the first and second embodiments, that is, it is possible to detect that a communication error has actually occurred due to the occurrence of interference, and to distinguish whether the generated communication error is due to the interference error or not Can do.

  In this embodiment, the Noisefloor value of the received packet is measured, but the Noisefloor value at the time of Beacon acquisition may be measured, and the same effect can be obtained.

  Moreover, although the FCS error of the received packet is detected as the reception error, a reception error other than the FCS error or an S / N value may be used.

(Embodiment 4)
Embodiments 4 and 5 describe interference avoidance control for avoiding interference when interference occurs by the interference detection method.

  The interference avoidance circuit of this embodiment is an example applied to an interference avoidance circuit of a wireless communication apparatus in WLAN. Here, an example applied to the interference avoidance circuit 130 of the wireless communication apparatus of FIG. 1, FIG. 3, or FIG.

  For example, in FIG. 1, when an interference error occurs, the interference avoidance circuit 130 follows the request of the interference avoidance control circuit 108 that controls the transmission rate and the number of retransmissions, and the interference avoidance control circuit 108, in order to avoid interference. It comprises a rate control circuit 109 that actually changes the rate, and a retransmission number control circuit 110 that changes the number of retransmissions according to the request of the interference avoidance control circuit 108.

  Hereinafter, an interference avoidance method for the wireless communication apparatus configured as described above will be described.

  When the microwave oven is turned on in the frequency band of the communication carrier with which the wireless communication apparatus is transmitting and receiving, the microwave oven becomes an interference wave generation source, and the interval between the microwave ovens is an interference section. In the conventional example, as shown in FIG. 33 (a), when interference occurs at the time of transmission, the transmission rate is lowered by fallback, and as a result, the packet is retransmitted in a long state, and as shown in FIG. 33 (b). As described above, the number of retransmissions is a small prescribed number. For this reason, since the packet length becomes longer as the transmission rate is lowered due to fallback, the retransmitted packet cannot pass through the gap of the microwave oven ON (interference section), and is a specified number with a small number of retransmissions. Therefore, retransmission exceeding the microwave oven ON (interference section) is not realized.

  Therefore, in this embodiment, (1) the fallback control is stopped when interference is detected and the transmission rate is fixed to a constant rate, and (2) when retransmission is detected, the number of retransmissions is set higher than that of normal communication.

  FIG. 7 is a diagram illustrating a relationship between an interference wave and the number of packet retransmissions by the interference avoidance circuit 130 of the wireless communication apparatus according to the present embodiment. The case where the microwave oven ON (interference section) occurs intermittently during 20 msec is taken as an example. Beacon has a packet length of about 1 msec.

(1) Fixed transmission rate When interference is detected by the interference error detection circuits 120, 220, and 320 (see FIGS. 1, 3, and 5f), the interference avoidance circuit 130 shifts to <interference avoidance mode> (FIG. 1). , FIGS. 3 and 5g), the interference avoidance control circuit 108 stops the fallback control for the rate control circuit 109 and sets the transmission rate to a preset rate. For example, as shown in FIG. 7, the transmission rate is fixed at a rate that can be avoided in the gap between the microwave oven ON (interference section) and the next microwave oven ON (interference section). The rate control circuit 109 resends the packet without increasing the packet length by stopping the fallback control and fixing the transmission rate to a constant rate. This makes it possible to control the packet length to be assumed in advance when avoiding interference. Retransmission n and FIG. It is possible to pass through the gap of the microwave oven ON (interference section) as in Note that FIG. Is the Ack of retransmission n, FIG. Is Ack for reception.

(2) Setting of the number of retransmissions The interference avoidance control circuit 108 sets the number of retransmissions for the retransmission number control circuit 110 to a larger number of retransmissions than the normal operation. For example, in normal operation, the number of retransmissions is about 3 to 7, but when interference is detected, the number of retransmissions is set to 10 or more. This results in FIG. As shown in the retransmission n, the communication is successful when the retransmission is performed with the number of retransmissions exceeding the microwave oven ON (interference interval).

  The interference avoidance control described above will be described in more detail.

  FIG. 8 is a flowchart showing interference avoidance processing by the interference error avoidance circuit 130. In the figure, S indicates each step of the flow. FIG. 9 is a table showing the operation contents of interference wave level determination and interference error determination.

  First, the interference error detection circuits 120, 220, and 320 monitor the communication state in step S1, and the interference wave level is determined in step S2. As shown in the table of FIG. 9, in the case of using [transmission packet], the interference wave level determination measures the ED value before transmission, and whether or not the measured ED value exceeds the interference determination threshold value. (See Embodiments 1 and 2). When [Reception Packet] is used, the Noisefloor value at the time of reception is measured, and it is determined whether or not the measured Noisefloor value exceeds the interference determination threshold (see Embodiment 3). When the ED value or Noise floor value is less than the interference determination threshold value, the interference wave is not generated. Therefore, the transition to the interference avoiding operation is not performed and the normal communication state is continued. Return.

  If the ED value or Noise floor value exceeds the interference determination threshold value in step S2, interference error determination is performed in step S3. As shown in the table of FIG. 9, when using [transmission packet] for interference wave error determination, the Ack from the AP for the packet transmitted under the condition that the ED value exceeds the interference determination threshold is missing. In this case, an interference error is determined (see Embodiment 1). Alternatively, an interference error is determined when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value cannot be transmitted in the specified retransmission (see Embodiment 2). When [Received packet] is used, an interference error is determined when a packet received under the condition that the Noisefloor value exceeds the interference determination threshold is an error. In this way, when a packet transmitted or received in an environment where a large level is generated in which the interference wave level exceeds a preset interference determination threshold value, an error is determined as an interference error. .

  If the ED value or Noisefloor value exceeds the interference determination threshold value in step S3 but no error has occurred, this interference avoidance need not be executed and the normal communication state is continued. If it is determined in step S3 that there is an interference error, the transmission rate is set to a fixed rate set in advance so that communication can be performed in the gap of the interference source (eg, microwave oven ON) in step S4, and retransmitted in step S5. This flow is finished after setting the number of retransmissions to make the number of times larger than that of normal communication. In the transmission rate setting, the rate control circuit 109 stops the fallback control and sets the transmission rate to a preset transmission rate. In the retransmission count setting, the retransmission count control circuit 110 sets a retransmission count larger than that in the normal operation. For example, in normal communication, the number of retransmissions is increased from about 3 to 7 times to about 10 times.

  By performing the interference avoidance operation described above, the rate is set so that the fallback control is stopped and the packet length is fixed, and the retransmission is increased and the retransmission is performed. The number of retransmissions set in advance to be the same size will be retransmitted more than the normal number of times, and the hit rate through the interference source gap will improve, and the effect of enabling communication through the interference source gap can be expected. .

  As described above, according to the present embodiment, the interference avoidance circuit 130 including the interference avoidance control circuit 108, the rate control circuit 109, and the retransmission number control circuit 110 is provided. The fallback control is lowered to fix the transmission rate to a constant rate, and the number of retransmissions is set to be higher than the normal communication, so that it is possible to communicate in the gap of the interference source while retransmitting with a certain packet length, Interference can be avoided and communication can be performed when affected by an interference wave from an interference source such as a microwave oven during WLAN communication.

(Embodiment 5)
In the fourth embodiment, the fallback control is stopped when interference is detected, the transmission rate is fixed at a constant rate, and the number of retransmissions is set to be larger than that of normal communication, so that interference can be avoided in the gap of the interference source. It became possible. The present embodiment is an example in which the transmission rate and the number of retransmissions at the time of avoiding the interference are set according to the data size to be transmitted.

  FIG. 10 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 5 of the present invention. The same components as those in FIGS. 1 and 5 are denoted by the same reference numerals, and description of overlapping portions is omitted. This embodiment is an example applied to an interference error detection method for transmission packets and reception packets.

  In FIG. 10, a wireless communication apparatus 400 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED value detection circuit 105, an Ack error detection circuit 106, a transmission packet interference error. Determination circuit 107, Noise floor (interference wave level) value measurement circuit 310, reception error detection circuit 311, reception packet (Beacon) interference error determination circuit 312, packet size input circuit 431, rate / retransmission count determination circuit 432, interference avoidance control circuit 433, a rate control circuit 109, a retransmission count control circuit 110, and a WLAN control circuit 111.

  The ED value detection circuit 105, Ack error detection circuit 106, transmission packet interference error determination circuit 107, Noise floor value measurement circuit 310, reception error detection circuit 311, and reception packet interference error determination circuit 312 as a whole are packet interference error detection circuits. The packet size input circuit 431, the rate / retransmission number determination circuit 432, the interference avoidance control circuit 433, the rate control circuit 109, and the retransmission number control circuit 110 constitute an interference avoidance circuit 430 as a whole.

  The packet interference error detection circuit 420 is configured to have both the transmission packet interference error detection circuit 120 of FIG. 1 and the reception packet interference error detection circuit 320 of FIG.

  In the interference avoidance circuit 430, a packet size input circuit 431 and a rate / retransmission count determination circuit 432 are added to the interference avoidance circuit 130 of FIG. 1, and the interference avoidance control circuit 433 sets the transmission rate and the number of retransmissions to the data size to be transmitted. The difference is that control is set accordingly.

  The packet size input circuit 431 inputs the packet size to be transmitted to the rate / retransmission number determination circuit 432.

  The rate / retransmission count determination circuit 432 determines the rate / retransmission count according to a preset table from the input packet size.

  FIG. 11 is a diagram illustrating an example of an interference avoidance table referred to by the rate / retransmission count determination circuit 432.

  11, the interference avoidance setting table 500 includes transmission rates A, B, C... [Mbps] at packet sizes P (A), P (B), P (C),. R (B), R (C),... Are stored in advance as table values. For example, when the transmission data size (packet size) P (A) is input, the transmission rate and the number of retransmissions corresponding to the packet size P (A) are referred to. In this case, the transmission rate A [Mbps] and the retransmission are retransmitted. The number of times R (A) is read out.

  Hereinafter, an interference avoidance method for the wireless communication apparatus configured as described above will be described.

  FIG. 12 is a diagram illustrating the relationship between the interference wave by the interference avoidance circuit 430 of the wireless communication apparatus according to the present embodiment and the number of packet retransmissions. The case where the microwave oven ON (interference section) occurs intermittently during 20 msec is taken as an example. Further, the packet length of Beacon is about 1 msec.

  In this embodiment, the transmission rate and the number of retransmissions when avoiding interference are set according to the data size to be transmitted. The basic operation after setting the transmission rate and the number of retransmissions is the same as in the fourth embodiment.

(1) Data size input to be transmitted When interference is detected by the interference error detection circuit 420, the interference avoidance circuit 430 shifts to <interference avoidance mode>.

  The packet size input circuit 431 of the interference avoidance circuit 430 inputs the packet size to be transmitted to the rate / retransmission number determination circuit 432.

(2) Transmission Rate / Retransmission Count Determination The rate / retransmission count determination circuit 432 refers to the interference avoidance setting table 500 and sets the transmission rates A, B, C... [Mbps] corresponding to the input packet size to be transmitted. The number of retransmissions R (A), R (B), R (C),. In FIG. 12A, the transmission data size (packet size) P (A) is input, and the transmission rate A [Mbps] and the number of retransmissions R (A) corresponding to the packet size P (A) are read. FIG. 12B shows a case where the data size (packet size) P (C) to be transmitted is input, the transmission rate C [Mbps] corresponding to the packet size P (C), and the number of retransmissions R (C ) Is read and set.

(3) Transmission Rate Setting The interference avoidance control circuit 433 stops the fallback control for the rate control circuit 109 and fixes the transmission rate to the rate set by the rate / retransmission number determination circuit 432. For example, as shown in FIG. 12A, the transmission rate corresponds to the generated transmission packet size P (A), and the transmission rate is avoided in the gap between the microwave oven ON (interference section) and the next microwave oven ON (interference section). The transmission rate is fixed at A [Mbps]. In the present embodiment, the transmission rate set by the rate control circuit 109 is variable according to the data size to be transmitted. For example, as shown in FIG. 12B, when the generated transmission data size is the packet size P (C), a packet of this transmission data size can be transmitted, and the microwave oven ON (interference section) and the next Is set to a transmission rate C [Mbps] that can be avoided in the gap of the microwave oven ON (interference section). In FIG. 12, the retransmission and reception transmission rates A [Mbps] and C [Mbps] differ according to the packet size P (A) and the packet size P (C), but the microwave oven is ON (interference section). Thus, the transmission packet and the retransmission packet length are set to packet sizes capable of avoiding interference corresponding to the transmission data size, and the retransmission shown in FIGS. 12A and 12B is performed. By repeating the above, it becomes possible to pass through the gap of the microwave oven ON (interference section).

(4) Setting of Retransmission Count The interference avoidance control circuit 433 sets the retransmission count to the retransmission count determined by the rate / retransmission count determination circuit 432 for the retransmission count control circuit 110. The basic value of the number of retransmissions determined by the rate / retransmission number determination circuit 432 is a number of retransmissions larger than the normal operation, and the number of retransmissions adjusted according to the transmission data size is set. In FIG. 12, the number of retransmissions R (A) and the number of retransmissions R (C) are set according to the packet size P (A) and the packet size P (C), respectively. In normal operation, the number of retransmissions is about 3 to 7, but when interference is detected, the number of retransmissions R (A) and R (C) of 10 or more times is set. As a result, as shown in retransmission n in FIGS. 12A and 12B, the retransmission is repeated so as to exceed the microwave oven ON (interference section), whereby communication by retransmission succeeds.

  The interference avoidance control described above will be described in more detail.

  FIG. 13 is a flowchart showing interference avoidance processing by the interference error avoidance circuit 430. Steps that perform the same processing as in the flow of FIG. 8 are denoted by the same reference numerals.

  First, the interference error detection circuit 420 monitors the communication state in step S1, and the interference wave level is determined in step S2. As shown in the table of FIG. 9, in the case of using [transmission packet], the interference wave level determination measures the ED value before transmission, and whether or not the measured ED value exceeds the interference determination threshold value. Determine whether. When [Reception packet] is used, the Noisefloor value at the time of reception is measured, and it is determined whether or not the measured Noisefloor value exceeds the interference determination threshold value. If the ED value or NF value is less than the interference determination threshold, it is determined that no interference wave is generated because the level of the interference wave is low, and the process returns to step S1.

  If the ED value or Noise floor value exceeds the interference determination threshold value in step S2, interference error determination is performed in step S3. As shown in the table of FIG. 9, the interference wave error determination, when [transmission packet] is used, lacks Ack from the AP for the packet transmitted under the condition that the ED value exceeds the interference determination threshold value. If it is, it is determined as an interference error. Alternatively, an interference error is determined when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value cannot be transmitted in the specified retransmission. When [Received packet] is used, an interference error is determined when a packet received under the condition that the Noisefloor value exceeds the interference determination threshold is an error. In this way, when a packet transmitted or received under the condition in which an interference wave is generated becomes an error, it is determined as an interference error.

  When it is determined in step S3 that the ED value or Noise floor value exceeds the interference determination threshold but is not an interference error, communication can be continued even in a state where an interference wave is generated. Continue communication.

  If it is determined in step S3 that there is an interference error, the packet size is calculated in step S11. The generated transmission data size is input by the packet size input circuit 431, and the packet size is calculated from this packet size input. Next, according to the packet size calculated in step S12, the transmission rate is set by referring to the preset interference avoidance setting table 500, and in step S13, the number of retransmissions is set by referring to the interference avoidance setting table 500. End the flow. The transmission rate set with reference to the interference avoidance setting table 500 is a fixed transmission rate set in advance so that communication can be performed in a gap between interference sources (for example, a microwave oven ON). The number of retransmissions set with reference to the interference avoidance setting table 500 is a number of retransmissions larger than that in the normal operation.

  By the above-described interference avoidance operation, the rate is set to a fixed packet length by stopping the fallback control, and retransmission is performed by increasing the number of retransmissions, so that when the interference error is detected, the packet size set in advance for avoiding interference can be retransmitted. The number of re-transmissions is larger than the normal number of times, and the hit rate through the gap of the interference source is improved, and the effect of enabling communication through the gap of the interference source can be expected.

  As described above, according to the present embodiment, since the transmission rate and the number of retransmissions are set according to the packet size to be transmitted, an appropriate transmission rate and number of retransmissions are set when retransmission is performed with a fixed packet length. In the case of WLAN communication, it is possible to expect an effect of further improving the effectiveness of interference avoidance when affected by an interference wave from an interference source such as a microwave oven.

  Here, in the present embodiment, the transmission rate and the number of retransmissions are set according to the interference avoidance setting table 500 set in advance according to the packet size to be transmitted, but the transmission rate or the number of retransmissions according to the data size to be transmitted. Any method may be used as long as it is set. For example, in setting the transmission rate, a method may be used in which the transmission rate is calculated so as to obtain a certain packet length from the packet size to be transmitted without having a table. Alternatively, a method may be used in which a packet length at the time of interference avoidance is set in advance, and a transmission rate that automatically becomes the packet length is calculated from the generated transmission data size. Alternatively, a method may be used in which the time of a gap between interference waves for a certain period is detected and the transmission rate and the number of retransmissions that can be communicated in the gap are calculated.

(Embodiment 6)
According to Embodiments 4 and 5 described above, it is possible to effectively avoid interference from jamming waves caused by interference sources such as a microwave oven during WLAN communication.

  In the fourth and fifth embodiments, at the time of avoiding interference, the number of retransmissions is set to about 14 times at a fixed transmission rate (for example, 11 Mbps). This is because the number of retransmissions was set assuming interference avoidance in the microwave oven.

  However, when an interference source other than the microwave oven occurs, there is a possibility that proper interference avoidance cannot be achieved with a transmission rate of 11 Mbps and the number of retransmissions of 14 times. Interference sources other than microwave ovens include radio wave interference caused by medical equipment. In addition, radio wave interference by a specific low power short-distance two-way wireless communication system such as Bluetooth or UWB is also conceivable.

  Therefore, in the following sixth to tenth embodiments, an interference avoidance method that sets a transmission rate, the number of retransmissions, and / or a transmission timing that match an interference source when interference occurs and performs interference avoidance more effectively will be described.

  The following three methods are proposed according to the transmission rate, the number of retransmissions, and the transmission timing determination method.

(1) Interference avoidance method based on interference mapping (2) Interference avoidance method based on interference error rate (IER) and packet error rate (PER) (3) Interference avoidance method based on interference pattern list It is an example of the interference avoidance method by mapping.

  FIG. 14 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 6 of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals, and description of overlapping portions is omitted.

  14, a wireless communication apparatus 600 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED (Energy Detect) value detection circuit 105, an Ack error detection circuit 106, A transmission packet interference error determination circuit 107, a WLAN control circuit 611, an interference mapping processing circuit 612, an interference avoidance control circuit 631, a rate control circuit 109, a retransmission count control circuit 110, and a transmission timing control circuit 632 are configured.

  The ED value detection circuit 105, the Ack error detection circuit 106, and the transmission packet interference error determination circuit 107 constitute a transmission packet interference error detection circuit 120 as a whole. The interference avoidance control circuit 631, the rate control circuit 109, the number of retransmissions The control circuit 110 and the transmission timing control circuit 632 constitute an interference avoidance circuit 630 as a whole.

  Before transmitting a packet, the ED value detection circuit 105 measures the level (ED value) of an interference wave, compares it with an interference threshold value, and determines whether or not it exceeds the threshold value.

  The Ack error detection circuit 106 determines whether or not Ack for the transmitted packet is missing.

  The transmission packet interference error determination circuit 107 determines whether a transmission packet interference error has occurred from the ED value detection circuit 105 and the Ack error detection circuit 106.

  The WLAN control circuit 611 causes the interference avoidance circuit 630 to execute the interference avoidance mode based on the determination result of the interference error from the transmission packet interference error detection circuit 120.

  The interference mapping processing circuit 612 maps whether the transmitted packet is successful or unsuccessful, and determines the number of retransmissions, the transmission rate, and the transmission timing from the mapping result.

  The interference avoidance control circuit 631 controls the transmission rate, the number of retransmissions, and the transmission timing to avoid interference based on the number of retransmissions, the transmission rate, and the transmission timing determined by the interference mapping processing circuit 612.

  The rate control circuit 109 actually changes the rate in accordance with the request of the interference avoidance control circuit 631. The retransmission number control circuit 110 sets the number of retransmissions according to the request of the interference avoidance control circuit 631. The transmission timing control circuit 632 sets the transmission timing in accordance with a request from the interference avoidance control circuit 631.

  Hereinafter, an interference avoidance method of radio communication apparatus 600 configured as described above will be described.

[Basic concept of interference avoidance method by interference mapping]
FIG. 15 is a diagram illustrating a relationship among interference waves, the number of packet retransmissions, and transmission timing by the interference mapping processing circuit 612 of the wireless communication apparatus 600.

  As shown to Fig.15 (a), the interference wave other than a microwave oven or a microwave oven has generate | occur | produced intermittently. It is assumed that the transmitted packet collides with an x mark in FIG. 15A due to an intermittently generated interference wave, fails, and passes through a circle mark in FIG.

  The interference avoidance method using interference mapping according to the present embodiment (1) stores the timing when transmission is OK when an interference wave is generated, and sets the number of retransmissions and the transmission rate corresponding to the cycle. (2) Also, the transmission timing is adjusted from the timing when communication is OK. In this embodiment, the interference mapping processing circuit 612 of the WLAN control circuit 611 stores the timing when the transmitted packet is OK, and creates an interference mapping indicating whether the transmission is successful or unsuccessful. For example, a transmission success / failure mapping shown in FIG. 15A is created. The interference avoidance control circuit 631 controls the number of retransmissions and the transmission timing based on the mapping result from the interference mapping processing circuit 612. Then, the retransmission number control circuit 110 sets the number of retransmissions according to the request of the interference avoidance control circuit 631. The transmission timing control circuit 632 sets the transmission timing in accordance with a request from the interference avoidance control circuit 631.

  As shown in FIG. 15 (b), when the interference wave is generated, the timing at which the transmission is OK is stored, and an interference mapping indicating whether the transmission has succeeded or failed is created. The optimum number of retransmissions is determined from the mapping result. Here, based on the mapping result, the interference avoidance control circuit 631 sets the number of retransmissions 5 required for transmission in the gap of the intermittently generated interference wave. As can be seen from FIGS. 15 (a) and 15 (b), assuming that the packet size is a predetermined size, if the number of retransmissions of the transmission packet is not set to 5 or more, the transmission fails without reaching the gap of the interference wave. On the other hand, even if the number of retransmissions is set more than that, it is wasted due to the interference wave. Therefore, the optimum number of retransmissions in this case is 5. The optimum number of retransmissions can be set from the mapping result by the interference mapping processing circuit 612.

  Similarly, as shown in FIG. 15C, the transmission timing is determined from the mapping result by the interference mapping processing circuit 612. In the present embodiment, the interference avoidance control circuit 631 sets a transmission timing necessary for transmission in a gap of intermittently generated interference waves based on the mapping result from the interference mapping processing circuit 612. As can be seen from FIGS. 15 (a) and 15 (c), when retransmission is performed at the transmission timing shown in FIG. 15 (c), transmission succeeds in a gap between intermittently generated interference waves.

  From the above, the interference avoidance method by interference mapping can employ (1) a method for determining transmission timing and (2) a method for determining the optimum number of retransmissions from the mapping result. Details of these interference avoidance methods will be described later with reference to the control flows of FIGS.

  FIG. 16 is a diagram illustrating an example of interference mapping processing of the interference mapping processing circuit 612 of the wireless communication apparatus 600. FIG. 16A is an example of the interference mapping, and FIG. 16B is estimated based on the interference mapping. The interference source generation estimation result is shown.

  As shown in FIG. 16A, the interference mapping maps transmission completion (transmission success / failure) and transmission rate for each transmission time t1-tn.

  This interference mapping is performed in order to grasp the characteristics of the interference source. The time when the packet was transmitted, whether the packet was actually transmitted, and the transmission rate of the transmitted packet are stored on the interference mapping.

  For example, in the case of assuming a packet such as VoIP (Voice over Internet Protocol), this mapping monitors whether or not a packet transmitted about 2 sec of about 100 packets from a VoIP packet cycle of 20 ms can be normally transmitted. See the trend. Also, from the characteristics of the interference source, the microwave oven has a frequency of about 50 Hz / 60 Hz and Bluetooth has a period of about 1 ms. Therefore, the characteristics of the interference source can be detected by monitoring about 2 ms. Among them, the pattern of the interference source is analyzed from the time when transmission was actually possible, and the timing and period at which it can be predicted that no interference has occurred are calculated.

  In the interference mapping example of FIG. 16A, it is expected that an interference source is generated at a period of t8-t4, and the interference source is stopped at a period of transmission times t4, t8, t12. FIG. 16B shows an interference source generation estimation result estimated by the interference mapping.

  In the present embodiment, the interference avoidance control circuit 631 determines an appropriate number of retransmissions, transmission rate, and transmission timing from the period and timing calculated based on the mapping result by the interference mapping processing circuit 612.

  FIG. 17 is a flowchart showing mapping processing by the interference mapping processing circuit 612 and interference avoidance processing by the interference avoidance control circuit 631. This control flow is an example applied to a method for determining transmission timing from the mapping result.

  In step S21, the transmission packet interference error detection circuit 120 detects the interference error and outputs the detected interference error to the interference mapping processing circuit 612 of the WLAN control circuit 611.

  In step S22, the interference mapping processing circuit 612 starts interference mapping. The interference mapping processing circuit 612 maps the success / failure of transmission traffic and its time as shown in FIG.

  In step S23, the interference avoidance control circuit 631 detects the transmission success timing, and in step S24 detects the interference source period. The interference avoidance control circuit 631 detects the transmission success timing and period based on the mapping result from the interference mapping processing circuit 612. For example, the transmission timing shown in FIG.

  In step S25, the interference avoidance control circuit 631 determines the transmission rate to be operated for interference avoidance from the transmission success timing and its period, and determines the number of retransmissions in step S26. Based on the mapping result from the interference mapping processing circuit 612, the interference avoidance control circuit 631 determines the transmission rate and the number of retransmissions to be operated for interference avoidance. For example, the number of retransmissions shown in FIG.

  In step S27, the interference avoidance control circuit 631 sets the transmission rate, the number of retransmissions, and the transmission timing in the rate control circuit 109, the retransmission number control circuit 110, and the transmission timing control circuit 632, respectively. 110 and the transmission timing control circuit 632 start an interference avoidance operation and end this flow.

  FIG. 18 is a flowchart showing mapping processing by the interference mapping processing circuit 612 and interference avoidance processing by the interference avoidance control circuit 631. This control flow is an example applied to a method for determining the optimum number of retransmissions from the mapping result.

  In step S31, the transmission packet interference error detection circuit 120 detects the interference error and outputs the detected interference error to the interference mapping processing circuit 612 of the WLAN control circuit 611.

  In step S32, the interference avoidance control circuit 631 sets the transmission rate to a preset rate so that communication is possible in the gap between interference sources (for example, microwave oven ON), and sets the number of retransmissions in step S33. The present embodiment is an interference avoidance method that sets the transmission rate, the number of retransmissions, and the transmission timing that match the interference source based on the mapping result. In steps S32 and S33, basic settings of the transmission rate, the number of retransmissions, and the transmission timing are set prior to the interference mapping.

  In step S34, the interference mapping processing circuit 612 starts interference mapping, and completes the interference mapping in step S35. The interference mapping processing circuit 612 maps the success / failure of transmission traffic and its time as shown in FIG.

  In step S36, the interference avoidance control circuit 631 detects the transmission success timing and also detects the interference source period. The interference avoidance control circuit 631 detects the transmission success timing and period based on the mapping result from the interference mapping processing circuit 612. For example, the transmission timing shown in FIG.

  In step S37, the interference avoidance control circuit 631 determines whether or not the number of retransmissions set by the mapping result has been executed. If all retransmissions have not been executed, the number of retransmissions is changed in step S38, and the process returns to step S34 to perform interference mapping processing.

  When all the retransmissions are executed, the optimum number of retransmissions at the transmission rate set in step S39 is determined.

  In step S40, the interference avoidance control circuit 631 determines whether or not all the set transmission rates have been executed. If all transmission rates are not executed, the transmission rate is changed in step S41, and the process returns to step S33 to determine the optimum number of retransmissions in the same manner.

  When all the transmission rates are executed, the interference avoidance control circuit 631 selects the best transmission rate and the number of retransmissions from the results at the respective transmission rates in step S42. The interference avoidance control circuit 631 determines the optimum transmission rate and the number of retransmissions to be operated in interference avoidance based on the mapping result from the interference mapping processing circuit 612.

  In step S43, the interference avoidance control circuit 631 sets the transmission rate, the number of retransmissions, and the transmission timing in the rate control circuit 109, the retransmission number control circuit 110, and the transmission timing control circuit 632, respectively. 110 and the transmission timing control circuit 632 start an interference avoidance operation and end this flow.

  As described above, according to the present embodiment, when an interference wave is generated, the timing when transmission is OK is stored, and the number of retransmissions and the transmission rate corresponding to the cycle are set. Also, the transmission timing is adjusted from the timing when communication is OK. As a result, the number of retransmissions, the transmission rate, and the transmission timing that match the period of the interference wave can be set, and the transmission time occupation time can be optimized. Therefore, even when an interference source other than the microwave oven is generated, it is possible to more appropriately avoid interference.

(Embodiment 7)
In the sixth embodiment, the transmission time occupation time is optimized by setting the transmission rate, the number of retransmissions, and the transmission timing that match the interference source when interference occurs.

  Embodiment 7 is an example in which an interference error rate (IER) is detected and an optimum transmission rate and number of retransmissions are set.

  FIG. 19 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 7 of the present invention. The same components as those in FIG. 14 are denoted by the same reference numerals, and description of overlapping portions is omitted. The present embodiment is an example applied to a method for controlling the number of retransmissions and transmission rate by detecting an interference error rate (IER).

  19, a wireless communication apparatus 700 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED value detection circuit 105, an Ack error detection circuit 106, a transmission packet interference error. A determination circuit 107, a WLAN control circuit 711, an IER detection circuit 712, an interference avoidance parameter execution circuit 713, an interference avoidance control circuit 731, a rate control circuit 109, a retransmission count control circuit 110, and a transmission timing control circuit 632 are configured. .

  The ED value detection circuit 105, the Ack error detection circuit 106, and the transmission packet interference error determination circuit 107 constitute a transmission packet interference error detection circuit 120 as a whole. The interference avoidance control circuit 731, the rate control circuit 109, the number of retransmissions The control circuit 110 and the transmission timing control circuit 632 constitute an interference avoidance circuit 730 as a whole.

  The WLAN control circuit 711 causes the interference avoidance circuit 730 to execute the interference avoidance mode based on the determination result of the interference error from the transmission packet interference error detection circuit 120.

  The IER detection circuit 712 detects an interference error rate at which an interference error has occurred.

  The interference avoidance parameter execution circuit 713 changes the number of retransmissions, the transmission rate, and the transmission timing while detecting the IER, and determines an interference avoidance parameter that minimizes the IER.

  The interference avoidance control circuit 731 controls the transmission rate and the number of retransmissions for interference avoidance based on the interference avoidance parameter determined by the interference avoidance parameter execution circuit 713.

  The rate control circuit 109 actually changes the rate according to the request of the interference avoidance control circuit 731. The retransmission number control circuit 110 sets the number of retransmissions in accordance with a request from the interference avoidance control circuit 731. The transmission timing control circuit 632 sets the transmission timing in accordance with the request from the interference avoidance control circuit 731.

  Hereinafter, a retransmission number and transmission rate control method based on IER detection of the wireless communication apparatus 700 configured as described above will be described.

[Basic concept of number of retransmissions and transmission rate control method by IER detection]
In the fourth and fifth embodiments, since the number of retransmissions is fixed to about 15 by default, the transmission time occupied by one terminal is large, which may affect the communication of other terminals.

  Therefore, in this embodiment, when an interference wave is generated, the transmission rate and the number of retransmissions that minimize the error rate are set while detecting the IER.

  First, an interference error rate (IER) is defined based on the interference detection method described in the first to third embodiments.

  In Embodiments 1 to 3, when a packet error occurs, it is possible to determine whether the transmitted packet is an error due to interference or an error other than interference. It is also possible to calculate the interference error rate and the overall packet error rate.

  The equation for calculating the interference error rate is shown in the following equation (1), and the equation for calculating the packet error rate is shown in the following equation (2).

Interference error rate = number of interference error packets / number of transmitted packets (1)
Packet error rate = number of transmission error packets / number of transmission packets (2)
The number of transmission packet errors is the number of all packets in which transmission has failed without completing transmission, and includes all errors due to interference.

  FIG. 20 is a diagram illustrating the relationship between IER detection by the IER detection circuit 712 of the wireless communication apparatus 700, the number of packet retransmissions, and the transmission rate.

  As shown to Fig.20 (a), the interference wave other than a microwave oven or a microwave oven has generate | occur | produced intermittently. It is assumed that the transmitted packet collides with an x mark in FIGS. 20B to 20D due to an intermittently generated interference wave and fails, and passes through with a circle mark and becomes a success.

  In the present embodiment, the number of retransmissions and the transmission rate are adjusted while detecting IER.

  The number of retransmissions by IER detection and the result of the transmission rate control method are as follows.

  As shown in FIG. 20B, the number of retransmissions is set to 2 and the transmission rate is set to 5.5M to detect IER. The interference error rate is 66%.

  As shown in FIG. 20 (c), the number of retransmissions is set to 3 and the transmission rate is set to 5.5M to detect IER. The interference error rate is 33%.

  As shown in FIG. 20 (d), the number of retransmissions is set to 4 and the transmission rate is set to 11M to detect IER. The interference error rate is 0%.

  As described above, when the interference wave is generated, the number of retransmissions and the transmission rate matching the interference source can be set by setting the transmission rate and the number of retransmissions that minimize the error rate while detecting the IER.

  FIG. 21 is a flowchart showing the IER detection by the IER detection circuit 712, the optimum interference avoidance parameter determination by the interference avoidance parameter execution circuit 713, and the interference avoidance processing by the interference avoidance control circuit 731.

  In step S51, the transmission packet interference error detection circuit 120 detects an interference error and outputs the detected interference error to the IER detection circuit 712 of the WLAN control circuit 711.

  In step S52, the interference avoidance control circuit 731 sets a transmission rate to a preset rate so that communication can be performed in the gap between interference sources (for example, microwave oven ON), and sets the number of retransmissions in step S53. The present embodiment is an interference avoidance method that detects IER and sets an optimum transmission rate and number of retransmissions. In steps S52 and S53, the transmission rate and the number of retransmissions are set in advance prior to the IER detection.

  In step S54, the IER detection circuit 712 detects the IER when transmission is performed with the transmission rate and the number of retransmissions set.

  In step S55, the interference avoidance control circuit 731 determines whether or not all of the set number of retransmissions has been executed. If the number of retransmissions has not been executed, the number of retransmissions is changed in step S56, and the process returns to step S54 to perform IER detection.

  If all retransmissions have been executed, the interference avoidance parameter execution circuit 713 determines the optimum number of retransmissions at the transmission rate being executed in step S57.

  In step S58, the interference avoidance control circuit 731 determines whether or not all the set transmission rates have been executed. If all the transmission rates have not been executed, the transmission rate is changed in step S59, and the process returns to step S53. Similarly, the optimum number of retransmissions at that transmission rate is determined.

  When all the transmission rates are executed, the interference avoidance parameter execution circuit 713 selects the best transmission rate and the number of retransmissions from the results at the respective transmission rates in step S60. The interference avoidance parameter execution circuit 713 changes the number of retransmissions, the transmission rate, and the transmission timing while detecting the IER, and determines an interference avoidance parameter that minimizes the IER.

  In step S61, the interference avoidance control circuit 731 sets the transmission rate, the number of retransmissions, and the transmission timing in the rate control circuit 109, the retransmission number control circuit 110, and the transmission timing control circuit 632, respectively. 110 and the transmission timing control circuit 632 start an interference avoidance operation and end this flow.

  As described above, according to the present embodiment, when an interference wave is generated, the IER is detected, and the transmission rate and the number of retransmissions that minimize the IER are set, thereby setting the number of retransmissions and the transmission rate that match the interference source. Thus, interference avoidance considering actual communication quality can be realized, and the occupied time of the transmission packet can be optimized.

(Embodiment 8)
The eighth embodiment is an example in which IER is detected and optimum transmission timing is set.

  The configuration of the wireless communication apparatus in WLAN according to Embodiment 8 of the present invention is the same as that in FIG.

  In the present embodiment, the interference avoidance parameter execution circuit 713 of the WLAN control circuit 711 sets the transmission timing that matches the interference source.

  The interference avoidance control circuit 731 controls the transmission timing for interference avoidance based on the interference avoidance parameter determined by the interference avoidance parameter execution circuit 713.

  Hereinafter, a transmission timing control method based on IER detection of the wireless communication apparatus configured as described above will be described.

  FIG. 22 is a diagram illustrating a relationship between IER detection by the IER detection circuit 712 of the wireless communication apparatus 700 and adjustment of transmission timing.

  As shown to Fig.22 (a), the interference wave other than a microwave oven or a microwave oven has generate | occur | produced intermittently. It is assumed that the transmitted packet collides with an x mark in FIGS. 22B to 22D due to an intermittently generated interference wave, fails, and passes through with a circle and becomes a success.

  In this embodiment, the transmission timing is adjusted while detecting the IER.

  The adjustment result of the transmission timing by IER detection is as follows.

  The transmission timing shown in FIGS. 22B and 22C is a failure.

  As shown in FIG. 22D, the number of retransmissions can be minimized by adjusting the transmission timing while detecting the IER.

  FIG. 23 is a flowchart showing IER detection by the IER detection circuit 712, transmission timing adjustment by the interference avoidance parameter execution circuit 713, and interference avoidance processing by the interference avoidance control circuit 731.

  In step S71, the transmission packet interference error detection circuit 120 detects an interference error and outputs the detected interference error to the IER detection circuit 712 of the WLAN control circuit 711.

  In step S72, the interference avoidance control circuit 731 sets a transmission timing so that communication is possible in a gap between interference sources (for example, a microwave oven ON).

  In step S73, the IER detection circuit 712 detects the IER when transmission is performed at the set transmission timing.

  In step S74, the interference avoidance control circuit 731 determines whether or not all the set transmission timings have been executed. If all the set transmission timings have not been executed, the transmission timing is changed in step S75, and the process returns to step S73 to perform IER detection.

  When all the set transmission timings are executed, the interference avoidance parameter execution circuit 713 selects the transmission timing with the smallest IER in step S76.

  In step S77, the interference avoidance control circuit 731 sets the transmission rate, the number of retransmissions, and the transmission timing in the rate control circuit 109, the retransmission number control circuit 110, and the transmission timing control circuit 632, respectively. 110 and the transmission timing control circuit 632 start an interference avoidance operation and end this flow.

  As described above, according to the present embodiment, when an interference wave is generated, the number of retransmissions can be minimized by detecting the IER and setting the transmission timing so that the IER is minimized. Transmission time occupation time can also be minimized.

(Embodiment 9)
In the ninth embodiment, in addition to IER detection, a packet error rate (PER) detection is further performed, and a transmission rate and retransmission count control method using PER and IER is an example.

  FIG. 24 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 9 of the present invention. The same components as those in FIGS. 3 and 19 are denoted by the same reference numerals, and description of overlapping portions is omitted. This embodiment is an example applied to a method for controlling the number of retransmissions and transmission rate by PER and IER detection.

  24, a wireless communication apparatus 800 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED value detection circuit 105, a transmission error detection circuit 211, a transmission packet interference error. A determination circuit 212, a WLAN control circuit 811, an IER detection circuit 712, a PER detection circuit 812, an interference avoidance parameter execution circuit 813, an interference avoidance control circuit 831, a rate control circuit 109, a retransmission number control circuit 110, and a transmission timing control circuit 632 It is prepared for.

  The ED value detection circuit 105, the transmission error detection circuit 211, and the transmission packet interference error determination circuit 212 constitute a transmission packet interference error detection circuit 220 as a whole. The interference avoidance control circuit 831, the rate control circuit 109, the number of retransmissions The control circuit 110 and the transmission timing control circuit 632 constitute an interference avoidance circuit 830 as a whole.

  The transmission error detection circuit 211 detects as a transmission error that the transmitted packet could not be transmitted by the specified retransmission.

  The transmission packet interference error determination circuit 212 determines that a transmission packet interference error has occurred from the ED value detected by the ED value detection circuit 105 and the transmission error detection result detected by the transmission error detection circuit 211.

  In the sixth to eighth embodiments, an interference error is determined when a packet transmitted under the condition that the ED value exceeds the interference determination threshold value results in an Ack error. In the present embodiment, an interference error is determined when a packet transmitted under the same conditions cannot be transmitted even after a plurality of retransmissions. However, in this embodiment, the transmission packet interference error detection circuit 220 may include the Ack error detection circuit 107.

  The WLAN control circuit 811 causes the interference avoidance circuit 830 to execute the interference avoidance mode based on the interference error determination result from the transmission packet interference error detection circuit 220.

  The IER detection circuit 712 detects an interference error rate (IER) at which an interference error has occurred.

  The PER detection circuit 812 detects an error for a transmission packet for each packet, and detects a packet error rate (PER).

  The interference avoidance parameter execution circuit 813 changes the number of retransmissions, the transmission rate, and the transmission timing while detecting IER and PER, and determines an interference avoidance parameter that minimizes PER and IER.

  The interference avoidance control circuit 831 controls the transmission rate and the number of retransmissions for interference avoidance based on the interference avoidance parameter determined by the interference avoidance parameter execution circuit 813.

  The rate control circuit 109 actually changes the rate in accordance with the request of the interference avoidance control circuit 831. The retransmission number control circuit 110 sets the number of retransmissions according to the request from the interference avoidance control circuit 831. The transmission timing control circuit 632 sets the transmission timing in accordance with a request from the interference avoidance control circuit 831.

  Hereinafter, a retransmission number and transmission rate control method by PER and IER detection of the wireless communication apparatus 800 configured as described above will be described.

  FIG. 25 is a diagram illustrating a relationship between IER detection by the IER detection circuit 712 of the wireless communication apparatus 800 and adjustment of PER and transmission timing by the PER detection circuit 812.

  In this embodiment, when an interference wave is generated, an optimum transmission rate and number of retransmissions are set while detecting PER and IER.

  As shown in FIG. 25, interference waves are generated intermittently.

  When an interference wave is generated, the PER detection circuit 812 detects PER, and the IER detection circuit 712 detects IER (see FIG. 25a).

  While detecting IER and PER, the interference avoidance parameter execution circuit 813 determines an interference avoidance parameter that provides an optimal transmission rate and number of retransmissions (see FIG. 25b).

  FIG. 25c. Then, transmission was performed at a transmission rate of 11 Mbps and the number of retransmissions twice, and IER = 0% and PER = 10% were detected. FIG. 25d. Then, transmission was performed at a transmission rate of 5.5 Mbps and the number of retransmissions of 2 times, and IER = 0% and PER = 2% were detected. FIG. 25c. d. When the two transmission packets shown in FIG. 2 are compared, since the IER is 0%, the optimum transmission rate and the number of retransmissions cannot be determined only by the IER detection. In this case, when the PER is 10% when the IER is 0%, the transmission rate and the number of retransmissions at which the PER is optimal cannot be set by the control of only the IER. In this embodiment, detection of PER is added. For example, when two transmission rates of 5.5 Mbps and 11 Mbps can be detected at which the IER is 0%, the transmission rate at which the PER is minimized is selected.

  The interference avoidance control circuit 831 changes the transmission rate and the number of retransmissions based on the interference avoidance parameter determined by the interference avoidance parameter execution circuit 813, and sets the transmission rate and the number of retransmissions with the smallest PER and IER (see FIG. 25e.). As a result, FIG. The transmission rate of 5.5 Mbps and the number of retransmissions of 4 are set as the optimal transmission rate and the number of retransmissions.

  FIG. 26 is a flowchart showing an interference avoidance process by setting a transmission rate and the number of retransmissions using PER and IER.

  In step S 81, the transmission packet interference error detection circuit 220 detects the interference error and outputs the detected interference error to the IER detection circuit 712 and the PER detection circuit 812 of the WLAN control circuit 811.

  In step S82, the interference avoidance control circuit 731 sets the transmission rate to a preset rate so that communication can be performed in the gap between interference sources (for example, microwave oven ON), and sets the number of retransmissions in step S83. The present embodiment is an interference avoidance method that detects PER and IER and sets an optimum transmission rate and number of retransmissions. In steps S82 and S83, the transmission rate and the number of retransmissions are set in advance prior to PER and IER detection.

  In step S84, the IER detection circuit 712 sets the transmission rate and the number of retransmissions, and detects and stores the IER when transmission is executed.

  In step S85, the PER detection circuit 812 detects and stores the PER when transmission is executed with the transmission rate and the number of retransmissions set.

  In step S86, the interference avoidance control circuit 831 determines whether or not all of the set number of retransmissions has been executed. If all the retransmissions have not been executed, the number of retransmissions is changed in step S87, and the process returns to step S84 to perform IER detection and PER detection.

  If all retransmissions have been executed, the interference avoidance parameter execution circuit 813 determines the optimum number of retransmissions at the transmission rate being executed in step S88.

  In step S89, the interference avoidance control circuit 831 determines whether or not all the set transmission rates have been executed. If all the transmission rates have not been executed, the transmission rate is changed in step S90, and the process returns to step S83. Similarly, the optimum number of retransmissions at that transmission rate is determined.

  When all the transmission rates are executed, the interference avoidance parameter execution circuit 813 selects the transmission rate and the number of retransmissions that provide the best IER and PER from the results at the respective transmission rates in step S91.

  In step S92, the interference avoidance control circuit 831 sets the transmission rate, the number of retransmissions, and the transmission timing in the rate control circuit 109, the retransmission number control circuit 110, and the transmission timing control circuit 632, respectively. 110 and the transmission timing control circuit 632 start an interference avoidance operation and end this flow.

  As described above, according to the present embodiment, the number of retransmissions and the transmission rate that match the interference source are set by detecting PER and IER and setting the transmission rate and the number of retransmissions that minimize PER and IER. be able to. As a result, interference avoidance considering actual communication quality can be realized, and the occupied time of the transmission packet can be optimized.

  In particular, a rate at which an error occurring in an actual transmission path is minimized can be set by simultaneously detecting PER in addition to IER detection. For example, even when the IER of the executed transmission rate is 0% and the optimal transmission rate and the number of retransmissions cannot be set by the control of only the IER, the transmission that minimizes the PER by detecting the PER. The rate can be selected.

(Embodiment 10)
Embodiment 10 is an example applied to an interference avoidance method using an interference avoidance pattern list.

  FIG. 27 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 10 of the present invention. The same components as those in FIG. 19 are denoted by the same reference numerals, and description of overlapping portions is omitted.

  27, a wireless communication apparatus 900 includes an antenna 101, a transmission / reception changeover switch (T / R SW) 102, a WLAN transmission circuit 103, a WLAN reception circuit 104, an ED value detection circuit 105, an Ack error detection circuit 106, a transmission packet interference error. The determination circuit 107, the WLAN control circuit 911, the interference avoidance parameter execution circuit 912, the interference avoidance control circuit 931, the rate control circuit 109, the retransmission count control circuit 110, and the transmission timing control circuit 632 are configured.

  The ED value detection circuit 105, the Ack error detection circuit 106, and the transmission packet interference error determination circuit 107 constitute a transmission packet interference error detection circuit 120 as a whole. The interference avoidance control circuit 931, the rate control circuit 109, the number of retransmissions The control circuit 110 and the transmission timing control circuit 632 constitute an interference avoidance circuit 930 as a whole.

  The WLAN control circuit 911 causes the interference avoidance circuit 930 to execute the interference avoidance mode based on the determination result of the interference error from the transmission packet interference error detection circuit 120.

  The interference avoidance pattern execution circuit 912 executes a predetermined interference avoidance pattern, detects the best pattern from the result, and communicates with the interference avoidance control circuit according to the determined transmission rate and the number of retransmissions. Instruct to implement.

  FIG. 28 is a diagram illustrating an example of an interference avoidance pattern list held by the interference avoidance pattern execution circuit 912.

  28, the interference avoidance pattern list 1000 stores a plurality of interference avoidance patterns 1, 2,... Corresponding to the interference sources in advance as a list. For example, in the interference avoidance pattern 1, the assumed interference source is “microwave oven”, the transmission rate is “11 Mbps”, and the number of retransmissions is “20 times”. In the interference avoidance pattern 2, the assumed interference source is “Bluetooth”, the transmission rate is “5.5 Mbps”, and the number of retransmissions is “10 times”. Even if the assumed interference source is the same type of “microwave oven”, a plurality of interference avoidance patterns having different transmission rates or different numbers of retransmissions may be provided. Any assumed interference source may be used, for example, radio wave interference caused by medical equipment. The interference avoidance pattern is an example, and a setting example and a list form are not limited.

  Hereinafter, an interference avoidance method using the interference avoidance pattern list 1000 of the wireless communication apparatus 900 configured as described above will be described.

  FIG. 29 is a flowchart showing interference avoidance processing by the interference avoidance pattern list 1000.

  In step S101, the transmission packet interference error detection circuit 120 detects an interference error and outputs the detected interference error to the interference avoidance parameter execution circuit 912 of the WLAN control circuit 911.

  In step S102, the interference avoidance parameter execution circuit 912 sets the transmission rate and the number of retransmissions according to the interference avoidance pattern list assumed in advance, and executes transmission. Here, the interference avoidance pattern 1 is read from the interference avoidance pattern list 1000 of FIG. 28, and transmission is executed by setting the transmission rate and the number of retransmissions of the interference avoidance pattern 1.

  In step S103, IER / PER when transmission is executed at the transmission rate and the number of retransmissions set by the interference avoidance pattern 1 is detected.

  In step S104, it is determined whether or not all the interference avoidance patterns in the interference avoidance pattern list 1000 have been executed.

  If not all interference avoidance patterns have been executed, the next interference avoidance pattern is executed in step S105, and the process returns to step S103.

  When all the interference avoidance patterns are executed in step S104, the interference avoidance control circuit 931 determines the best interference avoidance pattern in the execution in step S106.

  In step S107, the interference avoidance control circuit 931 starts the interference avoidance operation according to the determined transmission rate of the interference avoidance pattern and the number of retransmissions, and ends this flow.

  As described above, according to this embodiment, the interference avoidance pattern list 1000 storing a plurality of interference avoidance patterns is prepared in advance, and the interference avoidance patterns are read from the assumed interference avoidance pattern list 1000 and sequentially applied. The interference avoidance pattern can be easily determined, and interference avoidance control can be performed quickly.

  The above description is an illustration of a preferred embodiment of the present invention, and the scope of the present invention is not limited to this. For example, although a specific interference source such as a microwave oven that does not belong to the wireless LAN system has been described, any interference source may be used, and all interference devices that affect inside and outside the wireless LAN system can be applied.

  In each of the above embodiments, the names wireless communication device, wireless LAN system, interference detection method, and interference avoidance method are used. However, this is for convenience of explanation, and a mobile terminal, a wireless communication device, and a wireless communication control method are used. Of course, a method of eliminating radio wave interference may be used.

  Further, the type, number, connection method, and the like of each circuit unit constituting the wireless communication device are not limited to the above-described embodiments.

  The interference detection method and interference avoidance method described above can also be realized by a program for causing the interference detection method and interference avoidance method to function. This program is stored in a computer-readable recording medium.

A wireless communication device, a wireless LAN system, an interference detection method, and an interference avoidance method according to the present invention include:
It has the effect of detecting the occurrence of interference and avoiding this interference, and is particularly effective for a wireless communication device and a wireless communication control method that constitute a wireless LAN system that connects a plurality of wireless communication devices through a wireless network.

1 is a block diagram showing a configuration of a wireless communication apparatus in a WLAN according to Embodiment 1 of the present invention. The figure explaining the transmission packet interference error detection method by the transmission packet interference error detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment FIG. 3 is a block diagram showing a configuration of a wireless communication apparatus in a WLAN according to Embodiment 2 of the present invention. The figure explaining the transmission packet interference error detection method by the transmission packet interference error detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment FIG. 5 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 3 of the present invention. The figure explaining the reception packet interference error detection method by the reception packet interference error detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment The figure which shows the relationship between the interference wave by the interference avoidance circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and the number of packet retransmissions The flowchart which shows the interference avoidance process by the interference error avoidance circuit of the radio | wireless communication apparatus which concerns on the said embodiment The figure which shows the operation | movement content of interference wave level determination and interference error determination of the radio | wireless communication apparatus which concerns on the said embodiment as a table | surface. FIG. 9 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 5 of the present invention. The figure which shows an example of the interference avoidance table which the rate / retransmission number determination circuit of the radio | wireless communication apparatus which concerns on the said embodiment refers. The figure which shows the relationship between the interference wave by the interference avoidance circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and the number of packet retransmissions The flowchart which shows the interference avoidance process by the interference error avoidance circuit of the radio | wireless communication apparatus which concerns on the said embodiment FIG. 9 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 6 of the present invention. The figure which shows the relationship between the interference wave by the interference mapping process circuit of the radio | wireless communication apparatus which concerns on the said embodiment, the packet retransmission number, and transmission timing The figure which shows an example of the interference mapping process of the interference mapping process circuit of the radio | wireless communication apparatus which concerns on the said embodiment. The flowchart which shows the mapping process by the interference mapping process circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and the interference avoidance process by an interference avoidance control circuit The flowchart which shows the mapping process by the interference mapping process circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and the interference avoidance process by an interference avoidance control circuit FIG. 7 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 7 of the present invention. The figure which shows the relationship between IER detection by the IER detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment, the number of packet retransmissions, and a transmission rate FIG. 5 is a flowchart showing IER detection by the IER detection circuit of the wireless communication apparatus according to the embodiment, determination of optimum interference avoidance parameters by the interference avoidance parameter execution circuit, and interference avoidance processing by the interference avoidance control circuit; The figure which shows the relationship between IER detection by the IER detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and adjustment of transmission timing The flowchart which shows the interference avoidance process by the IER detection by the IER detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment, transmission timing adjustment by an interference avoidance parameter execution circuit, and an interference avoidance control circuit FIG. 9 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 9 of the present invention. The figure which shows the relationship of IER detection by the IER detection circuit of the radio | wireless communication apparatus which concerns on the said embodiment, and adjustment of PER and transmission timing by a PER detection circuit The flowchart which shows the interference avoidance process by the transmission rate and the retransmission number setting which used PER and IER of the radio | wireless communication apparatus which concerns on the said embodiment FIG. 10 is a block diagram showing a configuration of a wireless communication apparatus in WLAN according to Embodiment 10 of the present invention. The figure which shows an example of the interference avoidance pattern list which the interference avoidance pattern execution circuit of the radio | wireless communication apparatus which concerns on the said embodiment hold | maintains The flowchart which shows the interference avoidance process by the interference avoidance pattern list | wrist of the radio | wireless communication apparatus which concerns on the said embodiment. The figure which shows the structure of the radio | wireless communication apparatus in the conventional WLAN. Diagram showing relationship between interference wave and communication carrier The figure which shows the relationship between the interference wave and the number of packet retransmissions The figure which shows the relationship between the interference wave and the number of packet retransmissions

Explanation of symbols

100, 200, 300, 400, 600, 700, 800, 900 Wireless communication device 101 Antenna 102 Transmission / reception changeover switch (T / R SW)
DESCRIPTION OF SYMBOLS 103 WLAN transmission circuit 104 WLAN reception circuit 105 ED value detection circuit 106 Ack error detection circuit 107 Transmission packet interference error determination circuit 108 Interference avoidance control circuit 109 Rate control circuit 110 Retransmission count control circuit 111,611,711,811,911 WLAN control Circuit 120, 220 Transmission packet interference error detection circuit 130, 630, 730, 830, 930 Interference avoidance circuit 211 Transmission error detection circuit 212 Transmission packet interference error determination circuit 310 Noise floor (interference wave level) value measurement circuit 311 Reception error detection circuit 312 Received packet (Beacon) interference error determination circuit 320 Received packet interference error detection circuit 420 Packet interference error detection circuit 431 Packet size input circuit 432 Rate / Retransmission The number decision circuit 433,631,731,831,931 DAA control circuit 632 transmits the timing control circuit 712 IER detection circuit 713,813,912 interference avoidance parameters execution circuit 812 PER detecting circuit 1000 interference avoidance pattern list

Claims (32)

Communication state determining means for determining a wireless communication state;
A packet error detection means for detecting that the transmitted or received packet is in error;
Interference error determination means for determining an interference error by an interference source when an error is detected by the packet error detection means when the wireless communication state determined by the communication state determination means is in a predetermined interference determination condition. Wireless communication device.   The wireless communication apparatus according to claim 1, wherein the communication state determination unit measures an ED value before packet transmission.   The wireless communication apparatus according to claim 1, wherein the communication state determination unit measures an interference wave level before packet transmission.   The wireless communication apparatus according to claim 1, wherein the communication state determination unit measures a Noisefloor value when a received packet is acquired.   The wireless communication apparatus according to claim 1, wherein the communication state determination unit measures a Noisefloor value when receiving Beacon.   The wireless communication apparatus according to claim 1, wherein the communication state determination unit measures an S / N when a received packet is acquired.   The wireless communication apparatus according to claim 1, wherein the packet error detection unit detects an Ack error with respect to the transmitted packet.   The wireless communication apparatus according to claim 1, wherein the packet error detection unit detects that the transmitted packet cannot be retransmitted at a predetermined number of retransmissions.   The wireless communication apparatus according to claim 1, wherein the packet error detection unit detects that the received packet is an FCS error. A wireless communication device that performs fallback control to reduce a transmission rate when a communication error occurs,
A wireless communication apparatus comprising interference avoidance control means for stopping the fallback control to fix a transmission rate to a constant rate and increasing the number of retransmissions over normal communication when an interference error is detected. A wireless communication device that performs rate control to increase a transmission rate when a communication error is improved,
A wireless communication apparatus comprising interference avoidance control means for stopping fallback control to fix a transmission rate to a constant rate and increasing the number of retransmissions over normal communication when an interference error is detected.   The radio communication apparatus according to claim 10 or 11, wherein the interference avoidance control unit sets the transmission rate of a packet size passing through the gap for a gap in an interference section of a specific interference source.   The radio communication apparatus according to claim 10 or 11, wherein the interference avoidance control unit sets the number of retransmissions reaching the gap for a gap in an interference section of a specific interference source.   The radio communication apparatus according to claim 10 or 11, wherein the interference avoidance control unit sets the transmission rate and / or the number of retransmissions according to a packet size to be transmitted. Furthermore, an interference detection means for detecting an interference error is provided,
The interference detection means includes
Communication state determining means for determining a wireless communication state;
A packet error detection means for detecting that the transmitted or received packet is in error;
Interference error determination means for determining an interference error by an interference source when an error is detected by the packet error detection means when the wireless communication state determined by the communication state determination means is in a predetermined interference determination condition. The wireless communication apparatus according to claim 10 or 11. Interference detection means for detecting interference errors;
Interference source determining means for determining an interference source when an interference wave is generated;
Setting means for setting at least one of the transmission rate, the number of retransmissions, and / or the transmission timing that match the interference wave of the determined interference source;
An interference avoidance control unit that performs interference avoidance control based on a set transmission rate, number of retransmissions, and / or transmission timing.   The wireless communication apparatus according to claim 16, wherein the setting means maps whether the transmitted packet is successful or unsuccessful, and sets a transmission rate, the number of retransmissions, and / or a transmission timing based on the mapping result.   The wireless communication apparatus according to claim 16, wherein the setting unit detects an interference error rate (IER) and sets a transmission rate, a number of retransmissions, and / or a transmission timing at which the interference error rate is minimized.   The setting unit detects an interference error rate (IER) and a packet error rate (PER), and sets a transmission rate, a number of retransmissions, and / or a transmission timing at which the interference error rate and the packet error rate are minimized. 16. The wireless communication device according to 16.   The wireless communication according to claim 16, wherein the setting unit includes an interference avoidance pattern list storing a plurality of interference avoidance patterns, and sets a transmission rate, the number of retransmissions, and / or a transmission timing based on the interference avoidance pattern list. apparatus. The interference detection means includes
Communication state determining means for determining a wireless communication state;
A packet error detection means for detecting that the transmitted or received packet is in error;
Interference error determination means for determining an interference error by an interference source when an error is detected by the packet error detection means when the wireless communication state determined by the communication state determination means is in a predetermined interference determination condition. The wireless communication apparatus according to claim 16. A wireless LAN system for connecting a plurality of wireless communication devices through a wireless network,
The wireless communication system according to any one of claims 1 to 21, wherein the wireless communication device is a wireless LAN system. Measuring the ED value before packet transmission;
Detecting an Ack error for the transmitted packet;
An interference detection method comprising: determining an interference error when the Ack error is detected for a packet transmitted under a condition in which the measured ED value exceeds an interference determination threshold. Measuring the ED value before packet transmission;
Detecting a transmission error in which a transmitted packet cannot be retransmitted at a predetermined number of retransmissions;
An interference detection method comprising: determining an interference error when a transmission error is detected for a packet transmitted under a condition in which a measured ED value exceeds an interference determination threshold. Measuring a Noisefloor value at the time of receiving a packet;
Detecting that the received packet is a reception error including an FCS error;
An interference detection method comprising: determining an interference error when a reception error is detected for a packet received under a condition that a measured Noisefloor value exceeds an interference determination threshold. Measuring the Noisefloor value when receiving Beacon;
Detecting that the received packet is a reception error including an FCS error;
An interference detection method comprising: determining an interference error when a reception error is detected for a packet received under a condition that a measured Noisefloor value exceeds an interference determination threshold. When detecting an interference error, the step of stopping the fallback control for lowering the transmission rate and fixing the transmission rate to a constant rate;
Increasing the number of retransmissions over normal communication.   28. The interference avoidance method according to claim 27, wherein, in the transmission rate step, the transmission rate of a packet size passing through the gap is set for a gap in an interference section of a specific interference source.   28. The interference avoidance method according to claim 27, wherein, in the retransmission count step, the number of retransmissions reaching the gap is set for a gap in an interference section of a specific interference source. In the transmission rate step, the transmission rate is set according to the packet size to be transmitted,
28. The interference avoidance method according to claim 27, wherein, in the retransmission number step, the number of retransmissions is set according to a packet size to be transmitted. Determining an interference source when an interference wave is generated;
Setting at least one of a transmission rate, the number of retransmissions, and / or transmission timing that matches the interference wave of the determined interference source;
Performing interference avoidance control based on the set transmission rate, number of retransmissions, and / or transmission timing. Furthermore, it has an interference detection step for detecting an interference error,
In the interference detection step,
Determining a wireless communication state;
Detecting that a transmitted or received packet is in error;
32. The interference avoidance method according to claim 27 or 31, wherein when the determined wireless communication state is a predetermined interference determination condition, the step of determining an interference error when the error is detected is sequentially executed.

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