JP2016178481A - Communication module and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize excellent radio communication in a radio communication function corresponding to a plurality of different communication standards, by suppressing interference at transmission/reception with a simple configuration with almost no restriction of mounting space.SOLUTION: In a communication module having a function for performing BT communication and wireless LAN communication simultaneously, a wiring pattern is formed so as to yield a signal at a level with which interference between BT communication and wireless LAN communication, resulting from a transmission signal provided from a WLAN IC 140 to a wiring for transmission LN3 at transmission in wireless LAN transmission, can be detected at a wiring for reception LN2, by a capacitive coupling between wirings by approximating the wiring for transmission LN3 for wireless LAN communication and the wiring for reception LN2 for BT communication on a circuit board. At a BT IC 130, a channel used for BT communication is set so as to avoid a channel used for wireless LAN communication based on a signal received from the wiring for reception LN2 by applying AFH modulation function.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a communication module and a communication control method thereof, and more particularly to a communication module having a wireless communication function corresponding to a plurality of communication standards and a communication control method in the communication module.

  2. Description of the Related Art In recent years, electronic devices having a wireless communication function for transmitting and receiving various data and signals directly with various devices or via a network or the like have been widely used. In particular, in electronic devices such as notebook personal computers, smartphones, tablet terminals, digital cameras, sports watches, etc., Bluetooth (registered trademark), Bluetooth slow energy (Bluetooth (registered trademark) low energy), wireless LAN A device having a wireless communication function corresponding to a plurality of communication standards such as (Local Area Network) and NFC (Near field communication) is also known.

  Here, since portable and portable electronic devices (so-called mobile devices) such as smartphones and tablet terminals are required to be small, light and power-saving, the wireless communication function as described above. There are restrictions on the mounting space and the battery capacity when mounting. Therefore, in recent years, a wireless communication function as described above is realized by mounting a plurality of integrated circuits (ICs) and antenna elements of different communication standards on a single substrate.

  In an electronic device having such a substrate structure, for example, Bluetooth (registered trademark) and wireless LAN are communication standards that use the same frequency band (2.4 GHz). Therefore, Bluetooth (registered trademark) communication and wireless LAN communication are used. Are simultaneously executed, there is a problem in that interference occurs between both signals, resulting in a decrease in communication speed (data transfer speed) or inability to communicate. Therefore, as described in, for example, Patent Document 1 and Patent Document 2, a method of performing communication control so as to avoid a collision of a used frequency band when transmitting and receiving data has been devised.

  For example, in Patent Document 1, data is transmitted and received in a communication apparatus having separate antennas corresponding to Bluetooth (registered trademark) communication and wireless LAN communication so as to monitor both transmission and reception states and avoid interference. A method for adjusting the timing and power at the time is described. Further, for example, in Patent Document 2, there is no collision when data is transmitted / received by an access point to a terminal device provided with a single antenna shared by both Bluetooth (registered trademark) communication and wireless LAN communication. As described above, there is described a method of controlling data transmission timing (data transfer sequence) and performing efficient data transfer with a single antenna.

JP 2008-235978 A JP 2011-82679 A

  When the method described in Patent Document 1 described above is applied to a mobile device, it is necessary to mount individual antennas corresponding to a plurality of communication standards, and thus there is a problem that restrictions arise in terms of mounting space. ing. Further, in the technique described in Patent Document 2, in the current situation where there are many manufacturers that provide integrated circuits (IC) for communication control mounted on terminal devices, access points and terminal devices that constitute a wireless LAN system However, in order to match the data transfer sequence of the communication control IC, a lot of man-hours and labor are required, which is not practical.

  Therefore, in view of the above-described problems, an object of the present invention is to provide an electronic device having a wireless communication function corresponding to a plurality of different communication standards, with a simple configuration and almost no restrictions on mounting space, and at the time of transmission / reception. It is an object of the present invention to provide a communication module that can realize good wireless communication by suppressing interference and a communication control method for the communication module.

The communication module according to the present invention includes:
A first communication circuit that performs a first communication using a first frequency band in a first communication standard;
A second communication circuit that performs a second communication using a second frequency band included in the first frequency band in a second communication standard different from the first communication standard;
A single antenna shared by the first communication and the second communication;
A reception wiring through which a reception signal by the first communication received by the antenna passes;
A transmission wiring through which a transmission signal in the second communication supplied to the antenna passes;
Have
The first communication circuit or the second communication circuit is configured to receive the signal when a capacitive signal between the reception wiring and the transmission wiring passes through the transmission wiring. The wiring has a proximity region adjacent to each other so that a specific signal having a magnitude capable of detecting interference between the first communication and the second communication is induced. To do.

The communication control method according to the present invention includes:
A communication control method for communicating with a plurality of different communication standards,
In the first communication standard, the first communication circuit that performs the first communication using the first frequency band, and the second communication standard different from the first communication standard, the first communication standard Using a second communication circuit that performs second communication using a second frequency band included in the frequency band, and a single antenna shared by the first communication and the second communication When performing the first communication and the second communication,
Capacitive coupling between a reception wiring through which a reception signal by the first communication received by the antenna passes and a transmission wiring through which a transmission signal in the second communication supplied to the antenna passes To detect interference between the first communication and the second communication based on a specific signal induced in the reception wiring when a transmission signal passes through the transmission wiring. It is characterized by.

  According to the present invention, in an electronic device having a wireless communication function corresponding to a plurality of different communication standards, it has a simple configuration and hardly receives restrictions on mounting space, and suppresses interference at the time of transmission / reception, thereby achieving good wireless performance. Communication can be realized.

It is a schematic block diagram which shows one Embodiment of the communication module which concerns on this invention. It is the schematic for demonstrating the AFH modulation process applied to the communication module which concerns on one Embodiment. It is a schematic block diagram which shows an example of the wiring pattern applied to the communication module which concerns on one Embodiment. It is a figure which shows an example of the interference detection method between BT communication and wireless LAN communication in the communication module which concerns on one Embodiment. It is a flowchart which shows an example of the communication control method in the communication module which concerns on one Embodiment. It is a schematic block diagram which shows the application example of the electronic device to which the communication module which concerns on one Embodiment is applied.

Hereinafter, a communication module and a communication control method thereof according to the present invention will be described in detail with reference to embodiments.
(Communication module)
FIG. 1 is a schematic block diagram showing an embodiment of a communication module according to the present invention.

  As shown in FIG. 1, for example, the communication module 100 according to an embodiment of the present invention is roughly divided into an antenna 110, a front end module (hereinafter abbreviated as “FEM”) 120, and Bluetooth (registered trademark) communication. Integrated circuit (hereinafter abbreviated as “BT IC”) 130, wireless LAN communication integrated circuit (hereinafter abbreviated as “WLAN IC”) 140, and arithmetic circuit unit 150. Here, the present embodiment has a structure in which at least the FEM 120, the BT IC 130, and the WLAN IC 140 are mounted on a single substrate.

  The antenna 110 is a single antenna that transmits and receives an electromagnetic wave having a predetermined frequency according to a plurality of different communication standards. In the present embodiment, Bluetooth (registered trademark) communication (hereinafter abbreviated as “BT communication”) and The wireless LAN communication is shared in transmission / reception operations in two communication standards.

  The FEM (switching circuit) 120 has a function as a switching switch that selects one of a BT IC 130 and a WLAN IC 140 described later and connects to a single antenna 110. The FEM 120 may have a signal amplification function for amplifying a weak signal transmitted / received via the antenna 110, a filter function for cutting noise included in the transmission / reception signal, and the like.

  Here, the FEM 120 executes control for forcibly connecting the BT IC 130 to the antenna 110 by receiving an FEM switching signal output from the BT IC 130 described later. Further, the FEM 120 controls the WLAN IC 140 to be connected to the antenna 110 as a default when the BT IC 130 is not connected to the antenna 110. Such switching control in the FEM 120 is realized by connecting a BT priority control terminal, which is normally provided in the BT IC 130, to the FEM 120.

  The BT IC (first communication circuit) 130 performs wireless communication using radio waves in a frequency band centered around 2.4 GHz based on the well-known BT communication standard (first communication standard). That is, the BT IC 130 transmits / receives predetermined data and signals to / from an external device (not shown) that is a connection target of BT communication based on a command from the arithmetic circuit unit 150. To do. Here, when BT communication occurs, the BT IC 130 outputs an FEM switching signal to the FEM 120 to forcibly connect the BT IC 130 and the antenna 110. At this time, the BT IC 130 performs an AFH (Adaptive Frequency Hopping) modulation process based on a capacitance component generated between the signal wiring of the BT IC 130 and the signal wiring of the WLAN IC 140 due to the transmission signal transmitted from the WLAN IC 140. To select a frequency that avoids a use channel in wireless LAN communication and apply it to BT communication. This AFH modulation processing is a technique for preventing the loss of a BT communication signal that collides with a use channel of wireless LAN communication in BT communication and wireless LAN communication using the same frequency band, and avoids a collision of use channels. The generated hopping pattern is generated and BT communication is performed. Details of the AFH modulation processing will be described later.

  The WLAN IC (second communication circuit) 140, based on the well-known wireless LAN communication standard (second communication standard) 140, emits radio waves in a frequency band centered around 2.4 GHz, similar to the BT IC 130 described above. Use to perform wireless communication. That is, the WLAN IC 140 transmits predetermined data and signals to and from an external device (not shown) that is a connection target of wireless LAN communication based on a command from the arithmetic circuit unit 150. Send and receive.

  The BT IC 130 and the WLAN IC 140 described above are connected to the arithmetic circuit unit 150 via an interface such as SDIO (Secure Digital Input / Output), for example. Here, SDIO is the same type of interface as SD, which is a kind of memory card standard.

  The arithmetic circuit unit 150 is an arithmetic processing device such as a CPU (central processing unit) or MPU (microprocessor unit), and executes at least BT communication in the BT IC 130 and the WLAN IC 140 by executing a predetermined control program. The execution state of the wireless LAN communication is controlled.

Next, the AFH modulation function mounted on the BT IC 130 according to the present embodiment will be described with reference to the drawings.
FIG. 2 is a schematic diagram for explaining AFH modulation processing applied to the communication module according to the present embodiment. FIG. 2A is a diagram showing a typical frequency spectrum in BT communication and wireless LAN communication, and FIG. 2B is a frequency spectrum showing a hopping pattern of a used channel generated by AFH modulation processing. .

  As described above, the BT communication and the wireless LAN communication execute wireless communication using substantially the same frequency band centered around 2.4 GHz. Here, when performing wireless LAN communication and BT communication simultaneously, the following communication methods are applied. For example, as shown in FIG. 2A, in wireless LAN communication, communication is performed by occupying a fixed channel (for example, central frequency 2.437 MHz, occupied frequency width 22 MHz, number of channels = 6). On the other hand, in BT communication, communication is performed by randomly switching the channel to be used from a number of channels with a narrow preset frequency width (for example, channel frequency width 1 MHz, number of channels = 79, total frequency width 80 MHz) ( Hopping communication). Here, the transmission output (power) in general wireless LAN communication is approximately 15 dBm (30 mW), whereas the transmission output in BT communication is approximately 4 dBm (2.5 mW) or less. That is, in wireless LAN communication, the frequency width occupied by the channel is approximately 20 times that of BT communication, and the transmission output (mW order power) is 10 times or more. Therefore, when the wireless LAN communication and the BT communication are performed at the same time, if a collision (interference) between the wireless LAN and the BT transmission / reception signal occurs, the transmission / reception signal of the BT communication colliding with the use channel of the wireless LAN communication is lost and the throughput is increased. It is known that the communication rate is lowered or communication is disabled.

  In order to solve such a problem, an AFH modulation function is introduced in the communication standard 1.2 of Bluetooth (registered trademark). The AFH modulation function detects a channel in which loss of transmission / reception signals of the BT communication frequently occurs due to a collision of used channels in the wireless LAN communication and the BT communication having the related frequency spectrum as shown in FIG. Then, for example, as shown in FIG. 2B, by adjusting so that the detected channel is not used, a hopping pattern that avoids the channel used in wireless LAN communication is generated as needed to perform BT communication. Thereby, the collision of the transmission / reception signal of wireless LAN and BT is avoided, and the quality of BT communication is ensured. Such an AFH modulation function is normally installed in the BT IC of the Bluetooth (registered trademark) communication standard 1.2 or later.

Next, a wiring pattern applied to the BT IC 130 and the WLAN IC 140 according to the present embodiment and an interference detection method between BT communication and wireless LAN communication will be described with reference to the drawings.
FIG. 3 is a schematic configuration diagram illustrating an example of a wiring pattern applied to the communication module according to the present embodiment. FIG. 3A is a diagram showing a wiring pattern applied to this embodiment, and FIG. 3B is a diagram showing a wiring pattern as a comparative example.

  In the communication module 100 according to the present embodiment, for example, as shown in FIG. 3A, the FEM 120 and the BT IC 130 are connected by a transmission (TX) wiring LN1 and a reception (RX) wiring LN2. The transmission wiring LN1 and the reception wiring LN2 are arranged adjacent to each other without crossing each other. Further, the FEM 120 and the WLAN IC 140 are connected by a transmission (TX) line LN3 and a reception (RX) line LN4. The transmission wiring LN3 and the reception wiring LN4 are wired so as to be adjacent to each other without crossing each other. Then, the reception wiring LN2 on the BT IC 130 side and the transmission wiring LN3 on the WLAN IC 140 side are wired so as to be adjacent to each other without crossing each other, and an arbitrary region in the middle of the wiring path (in the drawing, A wiring pattern is formed so as to be close to each other in a region ARx surrounded by a dotted line. Here, in the area ARx, it is set so that a capacitive coupling (capacitive coupling) having a predetermined capacitance component is generated between the reception wiring LN2 and the transmission wiring LN3 that are close to each other with the distance D between the wirings. .

  Generally, the transmission / reception wiring in the communication module is not mixed with transmission / reception signals between BT communication and wireless LAN communication as in the comparative example shown in FIG. 3B (that is, between adjacent wirings). In order to prevent capacitive coupling as much as possible, the wiring is separated by a certain distance or more. In FIG. 3B, a transmission (TX) line LP1 and a reception (RX) line LP2 that connect the FEM 120 and the BT IC 130, a transmission (TX) line LP3 that connects the FEM 120 and the WLAN IC 140, and A comparative example in which a wiring pattern is formed so as to be relatively far away from the reception (RX) wiring LP4 is shown.

  On the other hand, in the communication module 100 according to the present embodiment, as shown in FIG. 3A, the reception wiring LN2 that connects the FEM 120 and the BT IC 130 and the transmission wiring that connects the FEM 120 and the WLAN IC 140 are used. The wiring pattern is formed so that the wiring LN3 approaches in the area ARx and capacitive coupling having a predetermined capacitive component occurs. In this way, by wiring the reception wiring LN2 on the BT IC 130 side and the transmission wiring LN3 on the WLAN IC 140 side so as to approach intentionally, a transmission signal transmitted from the WLAN IC 140 to the transmission wiring LN3 is obtained. As a result, a reception signal (specific signal) including a signal component based on a capacitance component generated between the reception wiring LN2 and the transmission wiring LN3 can be received by the BT IC 130 via the reception wiring LN2. As a result, the BT IC 130 executes the AFH modulation process described above at the transmission timing of the transmission signal from the WLAN IC 140 (or the reception timing of the reception signal at the BT IC 130) to avoid the use channel of the wireless LAN communication. A hopping pattern is generated and BT communication is performed.

  Here, in the wiring pattern shown in FIG. 3A, the value of the capacitive component of the capacitive coupling generated between the reception wiring LN2 and the transmission wiring LN3 in the area ARx is the inter-wiring distance D and the reception wiring. It is determined by the wiring width, wiring thickness, and the like of the wiring LN2 and the transmission wiring LN3. As a rule, the smaller the inter-wiring distance D is, the larger the wiring width is, the larger the capacitance component value is. Here, if the value of the capacitive component of capacitive coupling is too large, the signal component generated due to the transmission signal transmitted from the WLAN IC 140 to the FEM 120 via the transmission line LN3 by wireless LAN communication becomes too large. As a result, the signal component received by the BT IC 130 becomes excessive, and the BT IC 130 cannot communicate on all channels. On the other hand, if the value of the capacitive component of capacitive coupling is too small, the signal component generated due to the transmission signal transmitted from the WLAN IC 140 to the FEM 120 via the transmission line LN3 by wireless LAN communication becomes too small. Therefore, the signal component is not substantially received by the BT IC 130, and the BT IC 130 cannot execute the AFH modulation process. Therefore, the value of the capacitive component of the capacitive coupling is smaller than a value at which communication cannot be performed on all channels in BT communication due to interference due to radio waves in wireless LAN communication, and larger than a value at which AFH modulation processing cannot be performed. Is set.

  More specifically, in this embodiment, in order to reduce the influence on the throughput in the BT communication, the value of the capacitive component of the capacitive coupling is set so that the strength is equal to or less than the blocking characteristic of the BT IC 130. Here, the blocking characteristic of the BT IC 130 is such that the transmission output (power) from the WLAN IC 140 input to the reception (RX) side of the BT IC 130 via the reception wiring LN2 due to interference due to radio waves of wireless LAN communication is BT It refers to the minimum power in a state where communication on all channels in communication cannot be performed. That is, when power weaker than the minimum power is input, the BT IC 130 can secure a communication channel.

  As a specific numerical example, for example, 13 dBm is assumed as a transmission output (power) from the WLAN IC 140. As a specification of the BT IC 130, when power is input from the WLAN IC 140 to the reception (RX) side, communication on all channels in BT communication becomes impossible. When the minimum power from the WLAN IC 140 is −20 dBm The capacitive coupling generated between the reception wiring LN2 and the transmission wiring LN3 needs to be set to be smaller than −33 dBm. In addition, even when power from the WLAN IC 140 is input to the reception (RX) side of the BT IC 130, communication is possible on all channels in BT communication, and the maximum power from the WLAN IC 140 is −80 dBm. In order to execute the AFH modulation process in the BT IC 130, the capacitive coupling generated between the reception wiring LN2 and the transmission wiring LN3 needs to be set to be larger than −93 dBm.

  FIG. 4 is a diagram illustrating an example of an interference detection method between BT communication and wireless LAN communication in the communication module according to the present embodiment. FIG. 4A is a diagram illustrating an interference detection method between BT communication and wireless LAN communication in the present embodiment, and FIG. 4B is an interference detection method between BT communication and wireless LAN communication as a comparative example. FIG.

  Conventionally, in a communication module that supports BT communication and wireless LAN communication, as in the comparative example shown in FIG. 4B, a BT IC equipped with an AFH modulation function is simultaneously with the reception timing of a received signal in the WLAN IC. Only at the transmission / reception timing of BT communication to be performed, interference between wireless LAN communications is detected and AFH modulation processing can be performed. For this reason, conventionally, the transmission timing of the transmission signal of the WLAN IC is normally controlled so as not to coincide with the transmission / reception timing of the BT communication. However, FIG. 4B corresponds to FIG. 4A corresponding to the present invention. 4 (b), as in FIG. 4 (a), the transmission timing of the transmission signal of the WLAN IC is at least partly the same as the transmission / reception timing of the BT communication. It was set as the state controlled so that it might become.

  On the other hand, in the communication module 100 according to the present embodiment, the following interference detection method between BT communication and wireless LAN communication can be realized by applying the wiring pattern as described above. That is, in the communication module 100 of the present embodiment, as shown in FIG. 4A, the transmission timing of the transmission signal transmitted from the WLAN IC 140 via the transmission line LN3 is at least partly the transmission / reception timing of BT communication. It is controlled so that it may be performed at an overlapping timing. As in the prior art, the BT IC 130 detects interference between wireless LAN communications at the transmission / reception timing of the BT communication performed simultaneously with the reception timing of the reception signal in the WLAN IC 140, and performs the AFH modulation processing in addition to performing the AFH modulation processing. Even at the transmission / reception timing of the BT communication performed at a timing at least partially overlapping with the transmission timing of the transmission signal transmitted from the transmission line LN3, the AFH modulation processing is performed. It can be carried out.

  Thereby, in the BT communication that frequently switches the use channel, the frequency of detecting the interference with the wireless LAN communication and performing the AFH modulation process can be increased more than before, and the interference between the BT communication and the wireless LAN communication can be further increased. The performance of the BT communication can be improved by appropriately suppressing.

  That is, in the communication module 100 according to the present embodiment, as illustrated in FIG. 3A, the reception wiring LN2 that connects the FEM 120 that switches and controls connection with a single antenna and the BT IC 130, and the FEM 120 And the transmission line LN3 that connects the WLAN IC 140 approach each other at a predetermined inter-wiring distance D, so that a capacitive coupling having a predetermined capacitance component is generated between the reception line LN2 and the transmission line LN3. A wiring pattern is formed. As a result, the reception signal including the signal component based on the capacitance component generated between the reception wiring LN2 and the transmission wiring LN3 due to the transmission signal transmitted from the WLAN IC 140 to the transmission wiring LN3 is received. It can be received by the BT IC 130 via LN2. Therefore, as shown in FIG. 4A, the communication module 100 with a simple configuration allows the BT IC 130 to perform wireless LAN communication not only at the reception timing of the reception signal at the WLAN IC 140 but also at the transmission timing of the transmission signal at the WLAN IC 140. Can be detected. Thereby, the execution frequency of AFH modulation processing can be increased, and the possibility that interference between BT communication and wireless LAN communication can be avoided can be improved. In addition, the above-described interference detection method between BT communication and wireless LAN communication can be realized by applying the AFH modulation function that is normally provided in the BT IC 130 without requiring the intervention by the arithmetic circuit unit 150. it can.

(Communication control method)
Next, a communication control method (communication control process) in the communication module according to the present embodiment will be described. Here, the configuration of the communication module and the interference detection method between BT communication and wireless LAN communication will be described as appropriate.
FIG. 5 is a flowchart illustrating an example of a communication control method in the communication module according to the present embodiment.

  In the communication control method in the communication module 100 according to the present embodiment, for example, as shown in the flowchart of FIG. 5, first, the arithmetic circuit unit 150 uses the BT IC 130 and the WLAN IC 140 simultaneously with the communication module activated. Then, it is determined whether or not the BT communication and the wireless LAN communication are simultaneously executed (step S102).

  If the BT communication and the wireless LAN communication are not performed simultaneously (No in step S102), the FEM 120 is controlled to be switched so that the circuit on the side used by the communication is connected to the antenna 110 (step S102). S104). That is, when performing BT communication, the FEM 120 controls the BT IC 130 to connect to the antenna 110, and when performing wireless LAN communication, the FEM 120 connects the WLAN IC 140 to the antenna 110. To control.

  After that, returning to step S102, the arithmetic circuit unit 150 determines again the execution state of the BT communication and the wireless LAN communication, and the above-described step S102 until it is determined that the BT IC 130 and the WLAN IC 140 are simultaneously used. The processing operation of S104 is repeatedly executed.

  On the other hand, when the BT communication and the wireless LAN communication are simultaneously performed (Yes in step S102), the BT IC 130 used in the BT communication is based on the FEM switching signal output from the BT IC 130. The FEM 120 is controlled to be connected to (step S106). Then, the BT IC 130 starts receiving a reception signal input via the reception wiring LN2 (step S108). That is, the BT IC 130 is a signal component based on a capacitance component generated between the reception wiring LN2 and the transmission wiring LN3 due to a transmission signal transmitted from the WLAN IC 140 via the transmission wiring LN3 by wireless LAN communication. Is received via the reception wiring LN2.

  Thereby, the BT IC 130 receives the reception signal including the signal component due to the transmission signal transmitted from the WLAN IC 140 in addition to the reception timing of the reception signal in the wireless LAN communication, and the BT communication and the wireless LAN communication described above. Interference detection processing is executed. Then, at each detection timing described above, the BT IC 130 determines whether there is a channel that cannot be used due to collision of the use channel in the BT communication due to radio wave interference in the wireless LAN communication, or a decrease in the throughput of the BT communication occurs. It is determined whether or not there is (step S110).

  When there is no unusable channel in BT communication or when there is no reduction in throughput (No in step S110), the BT IC 130 determines that there is no possibility of interference between BT communication and wireless LAN communication. The AFH modulation process is not executed (step S112).

  On the other hand, when there is an unusable channel in BT communication or when throughput is reduced (Yes in step S110), the BT IC 130 determines that interference occurs between the BT communication and the wireless LAN communication. Then, an AFH modulation process for selecting a frequency that avoids a use channel in wireless LAN communication and applying it to BT communication is executed (step S114).

  After performing the presence / absence of interference between the BT communication and the wireless LAN communication and the execution control of the AFH modulation process (steps S110 to S114), the process returns to step S102, and the arithmetic circuit unit 150 performs the BT communication and the wireless communication. The execution state of the LAN communication is determined again, and the above-described series of processing operations in steps S102 to S114 are repeatedly executed.

  Although not shown in the flowchart shown in FIG. 5, the arithmetic circuit unit 150 constantly or periodically changes the state in which the control operation is interrupted or terminated during the execution of the series of communication control operations described above. If the change is detected by monitoring, the communication control operation is forcibly terminated. Specifically, the arithmetic circuit unit 150 detects a cutoff or a decrease in driving power to the communication module 100, a processing operation being executed, an abnormality in a control program, or the like, and forcibly interrupts a series of communication control operations. To finish.

  As described above, in this embodiment, in the communication module having the function of simultaneously executing the BT communication and the wireless LAN communication, the transmission wiring LN3 in the wireless LAN communication and the reception wiring LN2 in the BT communication are approached on the substrate. Thus, the wiring pattern is formed so that weak capacitive coupling occurs. Then, the AFH modulation function that BT IC 130 is provided as a standard is applied, and the execution state of the wireless LAN communication is determined in BT IC 130 based on the received signal including the signal component caused by the transmission signal transmitted from WLAN IC 140. In addition to sensing, a channel used in BT communication is set so as to avoid a channel used in wireless LAN communication.

  As a result, in a communication module that shares a single antenna for BT communication and wireless LAN communication, a predetermined capacitance coupling occurs between the reception wiring LN2 of the BT IC 130 and the transmission wiring LN3 of the WLAN IC 140. Thus, for example, by adopting a simple configuration approached at a predetermined distance, the interference between the BT communication and the wireless LAN communication is reduced by the BT IC 130 having the AFH modulation function without requiring the intervention by the arithmetic circuit unit 150. By avoiding this, good wireless communication can be realized. Therefore, according to the present embodiment, there is no need to provide a plurality of antennas or to provide a new configuration in order to avoid interference between BT communication and wireless LAN communication. Can be suppressed. Further, since the intervention in the communication control operation of the arithmetic circuit unit can be eliminated as much as possible, man-hours and labors such as matching of specifications when developing the communication control IC can be greatly reduced.

(Application example)
FIG. 6 is a schematic configuration diagram illustrating an application example of an electronic device to which the communication module according to the present embodiment is applied.
The communication module 100 shown in the above-described embodiment is a wireless device that supports a plurality of communication standards for transmitting and receiving various data and signals directly with an external device to be connected or via a network or the like. It can be satisfactorily mounted on an electronic device having a communication function. Specifically, for example, an electronic device 200A such as a smartphone or a tablet terminal as shown in FIG. 6A, a wearable terminal 200B such as a sports watch as shown in FIG. The present invention can be favorably applied to electronic devices such as personal computers and digital cameras that are portable or portable and subject to restrictions on mounting space.

  In the above-described embodiment, as a different communication standard using the same frequency band, in a communication module having a wireless communication function corresponding to BT communication and wireless LAN communication, an AFH mounted on a BT IC that performs BT communication is used. Although the case where the modulation function is applied to avoid interference between the BT communication and the wireless LAN communication has been described in detail, the present invention is not limited to this. In other words, the present invention has a wireless communication function corresponding to a plurality of communication standards that use the same or equivalent (approximate) frequency bands to each other. As long as the AFH modulation function can be mounted on the communication integrated circuit on the side that performs the processing for avoiding the above, it can be applied satisfactorily. Therefore, for example, by installing an AFH modulation function in a communication integrated circuit of a communication standard that has been uniquely established, a wiring pattern such that the capacitive coupling as described above occurs between signal wirings connected to each communication integrated circuit. May be formed.

As mentioned above, although some embodiment of this invention was described, this invention is not limited to embodiment mentioned above, It includes the invention described in the claim, and its equivalent range.
Hereinafter, the invention described in the scope of claims of the present application will be appended.

(Appendix)
[1]
A first communication circuit that performs a first communication using a first frequency band in a first communication standard;
A second communication circuit that performs a second communication using a second frequency band included in the first frequency band in a second communication standard different from the first communication standard;
A single antenna shared by the first communication and the second communication;
A reception wiring through which a reception signal by the first communication received by the antenna passes;
A transmission wiring through which a transmission signal in the second communication supplied to the antenna passes;
Have
The first communication circuit or the second communication circuit is configured to receive the signal when a capacitive signal between the reception wiring and the transmission wiring passes through the transmission wiring. The wiring has a proximity region adjacent to each other so that a specific signal having a magnitude capable of detecting interference between the first communication and the second communication is induced. Communication module.

[2]
A switching circuit for switching the connection between the first communication circuit or the second communication circuit and the antenna;
The first communication circuit, the second communication circuit, and the switching circuit are mounted on a single substrate,
The reception wiring is a signal wiring that connects the first communication circuit and the switching circuit, and the transmission wiring is a signal wiring that connects the second communication circuit and the switching circuit. The communication module according to [1], wherein

[3]
The value of the capacitive coupling in the proximity region is a value that makes the communication impossible in the entire frequency band used in the first communication due to interference between the first communication and the second communication. And a value larger than a value that makes it impossible to set the frequency band used in the first communication so as to avoid the frequency band used in the second communication. The communication module according to [1] or [2].

[4]
The first communication circuit detects the interference between the first communication and the second communication by receiving the specific signal through the reception wiring, and at least the second communication circuit The communication module according to any one of [1] to [3], wherein a frequency band used in the first communication is adjusted so as to avoid a frequency band used in communication.

[5]
The function of adjusting a frequency band used in the first communication in the first communication circuit is an AFH modulation function. The communication module according to [4].

[6]
The first communication is Bluetooth communication, the second communication is wireless LAN communication,
The communication module according to any one of [1] to [5], wherein the first communication and the second communication use a frequency band of 2.4 GHz.

[7]
A communication control method for communicating with a plurality of different communication standards,
In the first communication standard, the first communication circuit that performs the first communication using the first frequency band, and the second communication standard different from the first communication standard, the first communication standard Using a second communication circuit that performs second communication using a second frequency band included in the frequency band, and a single antenna shared by the first communication and the second communication When performing the first communication and the second communication,
Capacitive coupling between a reception wiring through which a reception signal by the first communication received by the antenna passes and a transmission wiring through which a transmission signal in the second communication supplied to the antenna passes To detect interference between the first communication and the second communication based on a specific signal induced in the reception wiring when a transmission signal passes through the transmission wiring. A communication control method characterized by the above.

100 communication module 110 antenna 120 FEM
130 BT IC
140 WLAN IC
150 Arithmetic circuit unit 200A, 200B Electronic equipment LN1, LN3 Transmission wiring LN2, LN4 Reception wiring

Claims (7)

A first communication circuit that performs a first communication using a first frequency band in a first communication standard;
A second communication circuit that performs a second communication using a second frequency band included in the first frequency band in a second communication standard different from the first communication standard;
A single antenna shared by the first communication and the second communication;
A reception wiring through which a reception signal by the first communication received by the antenna passes;
A transmission wiring through which a transmission signal in the second communication supplied to the antenna passes;
Have
The first communication circuit or the second communication circuit is configured to receive the signal when a capacitive signal between the reception wiring and the transmission wiring passes through the transmission wiring. The wiring has a proximity region adjacent to each other so that a specific signal having a magnitude capable of detecting interference between the first communication and the second communication is induced. Communication module. A switching circuit for switching the connection between the first communication circuit or the second communication circuit and the antenna;
The first communication circuit, the second communication circuit, and the switching circuit are mounted on a single substrate,
The reception wiring is a signal wiring that connects the first communication circuit and the switching circuit, and the transmission wiring is a signal wiring that connects the second communication circuit and the switching circuit. The communication module according to claim 1.   The value of the capacitive coupling in the proximity region is a value that makes the communication impossible in the entire frequency band used in the first communication due to interference between the first communication and the second communication. And a value larger than a value that makes it impossible to set the frequency band used in the first communication so as to avoid the frequency band used in the second communication. The communication module according to claim 1 or 2.   The first communication circuit detects the interference between the first communication and the second communication by receiving the specific signal through the reception wiring, and at least the second communication circuit 4. The communication module according to claim 1, wherein a frequency band used in the first communication is adjusted so as to avoid a frequency band used in communication.   5. The communication module according to claim 4, wherein the function of adjusting the frequency band used in the first communication in the first communication circuit is an AFH modulation function. The first communication is Bluetooth communication, the second communication is wireless LAN communication,
The communication module according to claim 1, wherein the first communication and the second communication use a frequency band of 2.4 GHz. A communication control method for communicating with a plurality of different communication standards,
In the first communication standard, the first communication circuit that performs the first communication using the first frequency band, and the second communication standard different from the first communication standard, the first communication standard Using a second communication circuit that performs second communication using a second frequency band included in the frequency band, and a single antenna shared by the first communication and the second communication When performing the first communication and the second communication,
Capacitive coupling between a reception wiring through which a reception signal by the first communication received by the antenna passes and a transmission wiring through which a transmission signal in the second communication supplied to the antenna passes To detect interference between the first communication and the second communication based on a specific signal induced in the reception wiring when a transmission signal passes through the transmission wiring. A communication control method characterized by the above.

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