JP4561436B2 - Wireless terminal device, wireless module, and wireless module control method - Google Patents

Description

  The present invention relates to a wireless communication technique, and more particularly to a power saving technique for reducing power consumption by a standby function of a Bluetooth (registered trademark) wireless communication system.

In Bluetooth, which is a general-purpose wireless interface (see Non-Patent Document 1, etc.), standby functions such as sniff and park are defined as functions of a wireless module used in a wireless terminal device on the slave side.
This standby function reduces power consumption in the wireless module by activating the wireless module in the wireless terminal device on the slave side in synchronization with the beacon transmitted from the communication partner on the master side in a fixed cycle. It is a power function.

  In this type of wireless module, as a main configuration, a wireless transmission / reception unit that actually transmits / receives a wireless signal and a module control unit that controls the entire wireless module are provided. As an operation state, a standby function is realized by switching control between a standby state with low power consumption and a normal operation state.

In the standby function, the module control unit is synchronized with the beacon from the slave side by stopping power supply to the wireless transmission / reception unit and operating by supplying power only to some circuits such as timers in the module control unit. Wait for the start timing.
When the activation timing arrives, power is supplied to each circuit of the module control unit and the wireless transmission / reception unit, thereby performing wireless communication with the master side according to the beacon.

  When the wireless communication is completed, the module control unit returns to the original standby state by stopping the power supply to the wireless transmission / reception unit and stopping the power supply to other than a part of the circuits. Thereby, in the period when a beacon does not arrive, the power consumption in a wireless module is reduced.

  In such a wireless terminal device having a standby function, the module control unit may be configured to output a host awakening signal synchronized with the start / stop of power supply to the wireless transmission / reception unit. Thus, by setting the host control unit of the wireless terminal device on which the wireless module is mounted in the standby state, it is possible to realize power saving not only in the wireless module but also in the host control unit.

The applicant has not yet found prior art documents related to the present invention by the time of filing other than the prior art documents specified by the prior art document information described in this specification.
www.bluetooth.org/spec/

However, in such a conventional technology, the host wake-up signal output from the module control unit based on the standby function of the wireless module is transmitted wirelessly regardless of the presence or absence of a communication message (packet) addressed to the wireless terminal device from the master side. Output in synchronization with the normal operation of the module.
At this time, although the communication message is not received and the control processing in the host control unit is unnecessary, the host control unit returns from the low power consumption mode due to the host awakening signal, so that power consumption is wasted. There was a problem.

  The present invention is for solving such a problem, and provides a wireless terminal device, a wireless module, and a wireless module control method capable of reducing the power consumption of the entire wireless terminal device more effectively according to the presence or absence of a communication message. It is intended to provide.

In order to achieve such an object, a wireless terminal device according to the present invention includes a wireless module that performs data communication with a partner wireless device in accordance with a Bluetooth (registered trademark) wireless communication system, and a partner using the wireless module. It has a host control unit that performs desired function processing by exchanging various communication messages with the wireless device, and the wireless module performs data communication by intermittent operation in synchronization with a beacon transmitted at regular intervals from the partner wireless device. After the data communication with the counterpart wireless device is finished, the wireless terminal device confirms whether or not a communication message addressed to the wireless terminal device is received by the data communication. If a communication message is received, a host awakening signal is output to the host control unit, and if a communication message addressed to the wireless terminal device is not received, the host Host awakening means that does not output an awakening signal is provided, and the host control unit shifts the operation state of the host control unit from a standby state with low power consumption in the host control unit to a normal operation state according to the host awakening signal Host management means is provided.

  At this time, the host control unit is further provided with module awakening means for outputting a module awakening signal to the wireless module when it is necessary to exchange a communication message with the counterpart wireless device. Further, module management means for shifting the operating state of the wireless module from the standby state with low power consumption in the wireless module to the normal operating state may be further provided.

In addition, the wireless module according to the present invention exchanges various communication messages with a wireless module that performs data communication with the wireless device of the counterpart in accordance with the Bluetooth (registered trademark) wireless communication system, and with the wireless module. A wireless module that is used in a wireless terminal device having a host control unit that performs desired function processing, and performs data communication by intermittently operating in synchronization with a beacon transmitted at regular intervals from a counterpart wireless device, After data communication with the counterpart wireless device is completed, it is confirmed whether or not a communication message addressed to the wireless terminal device is received by the data communication, and if a communication message addressed to the wireless terminal device is received, the host control unit Transition from standby state to normal operation state to reduce power consumption at the host control unit by outputting a host wake-up signal So, if it does not receive a communication message addressed to the wireless terminal device, and a host awakening means for maintaining a host controller in a standby state without printing a host awakening signal.

  At this time, module management means for shifting the operation state of the wireless module from the standby state with low power consumption in the wireless module to the normal operation state according to the module awakening signal from the host control unit may be further provided.

In addition, the wireless module control method according to the present invention includes a wireless module that performs data communication with a counterpart wireless device in accordance with the Bluetooth (registered trademark) wireless communication system, and uses the wireless module to exchange various communication messages with the counterpart wireless device. Used in a wireless terminal device that has a host control unit that performs desired function processing by exchanging data, and controls a wireless module that performs data communication by intermittent operation in synchronization with a beacon transmitted from a partner wireless device at regular intervals After the data communication with the counterpart wireless device is completed , the wireless module control method is performed to check whether the communication message addressed to the wireless terminal device is received by the data communication, and the communication message addressed to the wireless terminal device is If received, it outputs a host wake-up signal to the host controller, reducing the power consumption of the host controller. A transition from the standby state to the normal operation state, and a step of maintaining the host control unit in the standby state without outputting a host awakening signal when a communication message addressed to the wireless terminal device is not received. ing.

  At this time, a step of shifting the operating state of the wireless module from a standby state with low power consumption in the wireless module to a normal operating state may be further provided in response to a module awakening signal from the host control unit.

According to the present invention, after the data communication with the partner wireless device corresponding to the beacon from the partner wireless device is completed by the wireless module, it is confirmed whether the communication message addressed to the wireless terminal device is received by the data communication. When a communication message addressed to the wireless terminal device is received, a host awakening signal is output to the host control unit, the host control unit shifts from the standby state to the normal operation state, and communication addressed to the wireless terminal device is performed. If no electronic message is received, the host awakening signal is not output and the host control unit is maintained in the standby state.

Therefore, using the standby function of the Bluetooth wireless communication method of the wireless module, the wireless module performs data communication with the partner wireless device by intermittently operating in synchronization with the beacon transmitted from the partner wireless device at regular intervals. At the same time, when switching the operation state of the host control unit between the standby state where power consumption is reduced by function restriction and the normal operation state without function restriction in synchronization with the intermittent operation of this wireless module, The power saving operation of the host control unit can be controlled according to the presence or absence.
Thereby, compared with the case where a host control part is normally operated each time in synchronization with the normal operation period of the wireless module, power consumption can be reduced more effectively in the entire wireless terminal device.

Next, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
First, with reference to FIG. 1, the radio | wireless terminal apparatus concerning the 1st Embodiment of this invention is demonstrated. FIG. 1 is a block diagram showing a configuration of a radio terminal apparatus according to the first embodiment of the present invention.
The wireless terminal device (slave side) 1 is a terminal that realizes various functions by performing wireless data communication with a counterpart wireless device (master side) 2 via a wireless line 3 based on a Bluetooth (registered trademark) wireless communication system. The apparatus includes a wireless module 11, a function processing unit 14, and a host control unit 15.

  In the present embodiment, using the standby function of the Bluetooth wireless communication system of the wireless module 11, the wireless module 11 performs an intermittent operation in synchronization with a beacon transmitted from the wireless device 2 at regular intervals. While performing data communication with the wireless device 2, the operation of the host control unit 15 is synchronized with the intermittent operation of the wireless module 11 in either a standby state in which power consumption is reduced by function restriction or a normal operation state without function restriction. When switching control of the state, when a communication telegram addressed to the wireless terminal device 1 is received from the counterpart wireless device 2 according to the beacon, the host module 15 outputs a host awakening signal 17 to the host control unit 15. The host controller 15 is shifted from the standby state to the normal operation state, and the communication message addressed to the wireless terminal device 1 is not received. Case is that in order to maintain the host controller 15 does not output the host awakening signal 17 to the standby state.

Hereinafter, the configuration of the wireless terminal device 1 will be described in detail with reference to FIG.
The wireless module 11 is a functional module that provides a wireless interface compliant with the Bluetooth wireless communication system, and various functional units are integrally mounted as one component constituting the wireless terminal device 1.
The main functional units provided in the wireless module 11 include a wireless transmission / reception unit 12 and a module control unit 13.

The wireless transmission / reception unit 12 is a circuit unit that transmits / receives a wireless signal in accordance with the Bluetooth wireless communication system, and performs a data communication via the wireless line 3 by transmitting / receiving a wireless signal to / from the counterpart wireless device 2. have.
The module control unit 13 makes the Bluetooth wireless communication system possible by cooperating hardware composed of a CPU and its peripheral circuits and a program stored in advance in a memory (not shown) provided in these CPUs or peripheral circuits. A functional unit for controlling the wireless transmission / reception unit 12 is realized in compliance.

  The main functional means realized by the module control unit 13 include a communication control means 13A, a module management means 13B, and a host awakening means 13C.

The communication control unit 13 </ b> A has a function of controlling the data transmission / reception unit 12 to control data communication between the counterpart wireless device 2 and the host control unit 15.
The module management unit 13B has a function of controlling the operation of the wireless module 11 based on specifications such as a standby function conforming to the Bluetooth wireless communication system.
When the communication control unit 13A receives a communication message addressed to the wireless terminal device 1, the host awakening unit 13C outputs a host awakening signal 17 to wake up the host control unit 15 from the standby state and enter the normal operation state. It has a function to migrate.

  The function processing unit 14 has a function of providing various functions of the wireless terminal device 1 based on control from the host control unit 15, for example, various terminal functions such as voice call, content display, settlement, and data management.

The host control unit 15 provides a desired terminal function by cooperating hardware including a CPU or its peripheral circuit and a program stored in advance in the CPU or a memory provided in the peripheral circuit. Implement various functional means.
As main functional means realized by the host control unit 15, there are a data communication means 15A, a function control means 15B, and a host management means 15C.

The data communication unit 15A has a function of performing data communication with the counterpart wireless device 2 via the wireless module 11.
The function control unit 15B has a function of controlling the function processing unit 14 based on the content of the communication message from the counterpart wireless device 2 received by the data communication unit 15A, and an instruction from the function processing unit 14 based on a user operation or the like. And a function of outputting a communication message addressed to the counterpart wireless device 2 to the data communication means 15A.

  The host management unit 15C moves the host control unit 15 from the normal operation state without function restriction to the standby state in which the function is restricted and power consumption is reduced in accordance with the end of the processing in the data communication unit 15A or the function control unit 15B. A function of shifting the operating state, a function of waking up from the standby state in response to the host awakening signal 17 from the wireless module 11 and shifting the operating state of the host control unit 15 to the normal state, and an output from the function processing unit 14 In response to a signal (interrupt input signal), the host controller 15 has a function of waking up from the standby state and shifting the operation state of the host control unit 15 to the normal state.

A data signal 16 and a host awakening signal 17 are exchanged between the host control unit 15 and the module control unit 13.
The data signal 16 is a signal (serial communication signal) for exchanging various data between the host control unit 15 and the module control unit 13. The main data exchanged by the data signal 16 includes data exchanged by data communication with the counterpart wireless device 2 and exchange between the host control unit 15 and the module control unit 13 for controlling the wireless module 11. Control data to be used.

The host awakening signal 17 is a control signal output from the module control unit 13 to the host control unit 15 in order to awaken the operation state of the host control unit 15 from the standby state and shift to the normal operation state. Note that a wireless module compliant with the Bluetooth wireless communication system has a 1-bit output terminal as a standard specification, and the host awakening signal 17 may be output from this output terminal.
The host control unit 15 may connect the host awakening signal 17 to an interrupt input port provided in a general CPU. As a result, the host management means 15C detects an interrupt input by the host awakening signal 17, and shifts the host control unit 15 from the standby state to the normal operation state.

[Standby function]
Next, a standby function based on the Bluetooth wireless communication specification will be described.
The wireless module 11 of the wireless terminal device 1 has a standby function based on the Bluetooth wireless communication specification.
The standby function is a master function of two operation states of the wireless module 11, that is, a standby state (sleep mode) in which the function is limited to reduce power consumption and a normal operation state (wake-up mode) without function restriction. Power saving function for reducing power consumption in the wireless module 11 by operating the wireless module 11 normally only during a necessary period by switching control at the start timing synchronized with the beacon from the side and causing the wireless module 11 to operate intermittently It is controlled by the module management means 13B of the module control unit 13.

The module management unit 13B is a timer function provided in the module control unit 13, and controls the switching between the standby state and the normal operation state of the wireless module 11 by measuring the activation timing synchronized with the beacon from the master side. .
When shifting the wireless module 11 to the standby state, the module management unit 13B stops the power supply to the wireless transmission / reception unit 12 and shifts the module control unit 13 from the normal operation state to the standby state.
On the other hand, when shifting the wireless module 11 to the normal operation state, the module management unit 13B supplies power to the wireless transmission / reception unit 12 and also shifts the module control unit 13 from the standby state to the normal operation state.

The standby state (sleep mode) of the module control unit 13 means that power is supplied only to a part of the circuits constituting the module control unit 13 that constitute necessary functions and power is supplied to other circuit units. By stopping, it is a power saving operation state for reducing the power consumption in the module control unit 13, and in this state, usable functions are limited, and the wireless communication unit 2 using the wireless transmission / reception unit 12 is restricted. Data communication is not possible.
The normal operation state (wake mode) of the module control unit 13 is a state in which power is supplied to each circuit unit of the module control unit 13 to operate, and there are no restrictions on usable functions. Data communication with the partner wireless device 2 used can be performed.

  At this time, as a main circuit unit for continuing power supply in the standby state of the module control unit 13, the CPU timer circuit and the interrupt input detection circuit constituting the module control unit 13 are awakened from the standby state and are in a normal operation state. There is a circuit part related to the functions required to shift to

  On the other hand, the host control unit 15 switches the standby state and the normal operation state by the host management unit 15C according to the necessity of the processing operation in the host control unit 15, thereby reducing the power consumption in the host control unit 15. Power saving operation is performed to reduce the power consumption.

The standby state (sleep mode) of the host control unit 15 means that power is supplied only to a part of the circuits constituting the host control unit 15 that constitute necessary functions, and power is supplied to other circuit units. By stopping, it is a power saving operation state for reducing the power consumption in the host control unit 15. In this state, usable functions are limited, and various functions can be provided using the function processing unit 14. Can not.
Further, the normal operation state (wake mode) of the host control unit 15 is a state in which power is supplied to each circuit unit of the host control unit 15 and the functions usable in this state are not limited. Various functions can be provided using the unit 14.

  At this time, the main circuit unit that continues to supply power in the standby state of the host control unit 15 is awakened from the standby state, such as an interrupt input detection circuit that detects an interrupt signal from an external circuit unit such as the function processing unit 14. Therefore, there is a circuit section relating to functions required to shift to the normal operation state.

[Operation of First Embodiment]
Next, the operation of the wireless terminal device according to the first embodiment of the present invention will be described with reference to FIG. 2 and FIG. FIG. 2 is a flowchart showing a procedure of module control processing in the wireless module used in the wireless communication apparatus according to the first embodiment of the present invention. FIG. 3 is a timing chart showing the operation of the wireless communication apparatus according to the first embodiment of the present invention.

In the Bluetooth wireless communication specification, a wireless communication network called a piconet is configured by a plurality of wireless devices existing in a predetermined wireless communication area, whereby wireless communication is performed between the wireless devices.
This piconet has one master that controls synchronization of wireless communication by transmitting a synchronization signal called a beacon at predetermined intervals, and one or more slaves that perform wireless communication with the master in synchronization with the beacon from this master. Consists of
Here, as shown in FIG. 1 described above, the case where the counterpart wireless device 2 operates as a master and the wireless terminal device 1 operates as a slave will be described as an example.

The wireless module 11 performs module control processing as shown in FIG. 2 based on the standby function described above.
First, the module control unit 13 repeatedly counts the activation timing period ta that has the same time length as the beacon period tb from the counterpart wireless device 2 and arrives before the beacon only during the beacon detection preparation period by the module management unit 13B. (Step 100).
At this time, until the start timing comes, the wireless module 11 is controlled to be switched to the standby state, the power supply to the wireless transmission / reception unit 12 is stopped, and the module control unit 13 is in the standby state.

When the timer function has timed out and the activation timing has arrived (step 100: YES / FIG. 3: time T11), the module management unit 13B resumes the power supply to each circuit unit of the module control unit 13 to The control unit 13 is awakened from the standby state to shift to the normal operation state, and power supply to the wireless transmission / reception unit 12 is resumed.
As a result, the entire wireless module 11 shifts from the standby state to the normal operation state (step 101).

Thereafter, when the beacon from the counterpart wireless device 2 is detected by the wireless transmission / reception unit 12 (step 102: YES / FIG. 3: time T12), the module control unit 13 causes the wireless transmission / reception unit 12 to be switched by the communication control unit 13A. Control is performed to perform data communication with the counterpart wireless device 2 via the wireless section 3 (step 103).
After this data communication is completed, the module control unit 13 confirms whether or not the communication control unit 13A has received a communication message addressed to the wireless terminal device 1 from the counterpart wireless device 2 by the host awakening unit 13C (step 104 / FIG. 3: Time T13).

Here, when the communication message addressed to the wireless terminal device 1 is not received (step 104: NO), the host control unit 15 does not need to perform processing according to the communication message. The host awakening signal 17 is not output to the control unit 15.
Thereby, since the standby state is continuously maintained in the host control unit 15, the power consumed by the host control unit 15 in the period 15A of FIG. 3 can be reduced, and the host control unit is synchronized with the normal operation period of the wireless module 11. Compared with the case where 15 is normally operated, the power consumption in the whole radio | wireless terminal apparatus 1 can be reduced.

  Thereafter, the module management unit 13B stops the power supply to the wireless transmission / reception unit 12 and shifts the entire wireless module 11 to the standby state by shifting the module control unit 13 from the normal operation state to the standby state (Step S1). 107) The standby processing of the wireless module 11 returns to Step 100.

On the other hand, when a communication message addressed to the wireless terminal device 1 is received in response to the arrival of the activation timing at time T21 in FIG. 3 (step 104: YES), the host control unit 15 performs processing corresponding to the communication message. There is a need to do.
Therefore, the host awakening means 13C outputs a host awakening signal 17 for waking up the host control unit 15 from the standby state and shifting to the normal operation state (step 105 / FIG. 3: time T23).

In response to this, the host control unit 15 awakens from the standby state and shifts to the normal operation state by the host management unit 15C.
Then, the communication control unit 13A outputs the communication message received from the counterpart wireless device 2 to the host control unit 15 via the data signal 16 (step 106).
In this way, the host control unit 15 receives the communication message from the module control unit 13 and performs processing according to the communication message.

Thereafter, the module management unit 13B stops power supply to the wireless transmission / reception unit 12 after a predetermined time has elapsed or in response to a standby instruction notified via the data signal 16 in response to the end of processing in the host control unit 15. At the same time, the module control unit 13 is shifted from the normal operation state to the standby state (step 107).
As a result, the module control processing of the wireless module 11 returns to step 100.

  Thus, in the present embodiment, when the communication control unit 13A of the wireless module 11 receives a communication message addressed to the wireless terminal device 1 according to the beacon from the counterpart wireless device 2, the host awakening unit 13C When the host awakening signal 17 is output to the host control unit 15 to cause the host control unit 15 to shift from the standby state to the normal operation state and no communication message addressed to the wireless terminal device 1 is received, the host awakening means The host awakening signal 17 is not output from 13C, and the host control unit 15 is maintained in the standby state.

Therefore, by utilizing the standby function of the Bluetooth wireless communication system of the wireless module 11, the wireless module and the partner wireless device 2 and the data are intermittently operated in synchronization with the beacon transmitted from the partner wireless device 2 at regular intervals. In addition to performing communication, the operation state of the host control unit 15 is controlled to be switched between a standby state in which power consumption is reduced by function restriction and a normal operation state without function restriction in synchronization with the intermittent operation of the wireless module 11. At this time, the power saving operation of the host control unit 15 can be controlled according to the presence or absence of a communication message.
Thereby, compared with the case where the host control unit 15 is normally operated in synchronization with the normal operation period of the wireless module 11, the power consumption of the entire wireless terminal device 1 can be reduced more effectively.

[Second Embodiment]
Next, with reference to FIG. 4, the radio | wireless terminal apparatus concerning the 2nd Embodiment of this invention is demonstrated. FIG. 4 is a block diagram showing a configuration of a radio terminal apparatus according to the second embodiment of the present invention.
In the first embodiment described above, the case where the module controller 13 of the wireless module 11 controls the power saving operation of the host controller 15 has been described.
In the present embodiment, a case where the host controller 15 controls the power saving operation of the wireless module 11 will be described.

  In the wireless terminal device 1, when the host control unit 15 is in a standby state, for example, when an interrupt input signal from the function processing unit 14 is input to the host control unit 15 in accordance with a user operation, the interrupt input signal Is detected by the host management means 15C, the host control unit 15 is awakened from the standby state and shifts to the normal operation state, and the function control means 15B executes the necessary function processing.

  In this function processing, when data communication with the counterpart wireless device 2 is necessary, in the conventional general wireless terminal device, the host control unit according to the next activation timing autonomously managed by the wireless module 11 The communication message is output from 15 to the wireless module 11 and transmitted from the wireless module 11 to the counterpart wireless device 2 in response to the beacon from the counterpart wireless device 2.

In the present embodiment, the module awakening signal 18 is detected in the standby state, the module control unit 13 is awakened to shift to the normal operation state, and power supply to the wireless transmission / reception unit 12 is started. A function for shifting the entire module 11 from the standby state to the normal operation state is provided in the module management unit 13B of the wireless module 11, and the module awakening signal 18 is output from the module awakening unit 15D of the host control unit 15 at an arbitrary timing. Thus, the wireless module 11 is shifted from the standby state to the normal operation state.
Other configurations are the same as those in FIG. 1 described above, and a detailed description thereof is omitted here.

[Operation of Second Embodiment]
Next, with reference to FIG. 5, the operation of the radio terminal apparatus according to the second embodiment of the present invention will be described. FIG. 5 is a timing chart showing the operation of the wireless terminal device according to the second embodiment of the present invention. In FIG. 5, the same or equivalent parts as those in FIG. 3 are given the same reference numerals.

  First, in response to the arrival of the activation timing at time T11, the module control unit 13 of the wireless module 11 executes steps 100 to 104 in FIG. At this time, since the communication message addressed to the wireless terminal device 1 has not been received (FIG. 3: Step 104: NO), the host awakening signal 17 is not output to the host control unit 15, and the process proceeds to Step 107. Then, the wireless module 11 returns to the standby state again.

Thereafter, at time T31, for example, when an interrupt input signal is output from the function processing unit 14 and is detected by the host management unit 15C of the host control unit 15, the host management unit 15C wakes up the host control unit 15 from the standby state. To shift to the normal operation state.
In response to this, the host control unit 15 starts function processing for controlling the function processing unit 14 by the function control unit 15B.

At time T <b> 32, when it is necessary to exchange a communication message with the counterpart wireless device 2 by the function processing in the function control unit 15 </ b> B, the host control unit 15 changes the module awakening unit 15 </ b> C to the wireless module 11. On the other hand, the module awakening signal 18 is output.
In the module control unit 13 of the wireless module 11, when the module management unit 13B detects the module awakening signal 18 from the host control unit 15, the wireless module 11 is awakened from the standby state and shifted to the normal operation state.
Note that a wireless module conforming to the Bluetooth wireless communication system has a 1-bit input terminal as a standard specification, and the module awakening signal 18 may be input from this input terminal.

In response to this, the host control unit 15 outputs a communication message to be transmitted to the counterpart wireless device 2 to the wireless module 11 via the data signal 16 by the data communication unit 15A.
The module control unit 13 receives the communication message from the host control unit 15 by the communication control unit 13A, and transmits the communication message from the wireless transmission / reception unit 12 to the counterpart wireless device 2 via the wireless section 3.
Thereby, compared with the case where a communication telegram is transmitted according to the beacon from the other party radio | wireless apparatus 2 in subsequent time T22, a communication telegram can be transmitted from the radio | wireless terminal apparatus 1 to the other party radio | wireless apparatus 2 as needed. it can.

  As described above, in the present embodiment, the module management unit 13B of the wireless module 11 detects the module awakening signal 18 when the module control unit 13 is in the standby state, and the entire wireless module 11 is in the normal operation state from the standby state. Since the module awakening signal 18 is output from the module awakening means 15D of the host control unit 15 at an arbitrary timing, the wireless module 11 is shifted from the standby state to the normal operation state. The wireless module 11 can be shifted to the normal operation state from the host control unit 15 at an arbitrary timing.

  Thereby, for example, when transmission of a communication message from the wireless terminal device 1 to the counterpart wireless device 2 becomes necessary, the module control signal 18 is immediately output from the host control unit 15 to wake up the wireless module 11. The wireless terminal device 1 can transmit a desired communication message from the wireless terminal device 1 to the partner wireless device 2 without waiting for a beacon from the partner wireless device 2, and the wireless terminal device 1 generated due to waiting for the beacon. The delay of the function processing at can be reduced.

  In this embodiment, the case where a communication message is generated has been described as an example. However, when there is no communication message, for example, the host controller 15 also uses it for processing such as so-called health check for checking the operation of the wireless module 11. Yes, health check can be performed at any time.

It is a block diagram which shows the structure of the radio | wireless terminal apparatus concerning the 1st Embodiment of this invention. It is a flowchart which shows the module control process in the radio | wireless terminal apparatus concerning the 1st Embodiment of this invention. It is a sequence diagram which shows operation | movement of the radio | wireless terminal apparatus concerning the 1st Embodiment of this invention. It is a block diagram which shows the structure of the radio | wireless terminal apparatus concerning the 2nd Embodiment of this invention. It is a sequence diagram which shows operation | movement of the radio | wireless terminal apparatus concerning the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Wireless terminal device, 11 ... Wireless module, 12 ... Wireless transmission / reception part, 13 ... Module control part, 13A ... Communication control means, 13B ... Module management means, 13C ... Host awakening means, 14 ... Function processing part, 15 ... Host Control unit, 15A ... data communication means, 15B ... function control means, 15C ... host management means, 16 ... data signal, 17 ... host wake-up signal, 18 ... module wake-up signal, 2 ... counterpart wireless device, 3 ... wireless section.

Claims (6)

Host control that performs desired function processing by exchanging various communication messages with the partner wireless device using this wireless module, and a wireless module that performs data communication with the partner wireless device in accordance with the Bluetooth (registered trademark) wireless communication system A wireless terminal device for performing the data communication by intermittently operating in synchronization with a beacon transmitted at regular intervals from the counterpart wireless device in the wireless module,
After the data communication with the counterpart wireless device is completed , the wireless module confirms whether a communication message addressed to the wireless terminal device is received by the data communication, and receives a communication message addressed to the wireless terminal device. A host awakening signal that outputs a host awakening signal to the host control unit, and does not output the host awakening signal when a communication message addressed to the wireless terminal device is not received;
The host control unit has host management means for shifting the operation state of the host control unit from a standby state with low power consumption in the host control unit to a normal operation state in response to the host awakening signal. A wireless terminal device. The wireless terminal device according to claim 1,
The host control unit further includes module awakening means for outputting a module awakening signal to the wireless module when it is necessary to exchange a communication message with the counterpart wireless device,
The wireless module further includes module management means for shifting the operating state of the wireless module from a standby state with low power consumption in the wireless module to a normal operating state in response to the module awakening signal. Terminal device. Host control that performs desired function processing by exchanging various communication messages with the partner wireless device using this wireless module, and a wireless module that performs data communication with the partner wireless device in accordance with the Bluetooth (registered trademark) wireless communication system A wireless module that performs the data communication by intermittently operating in synchronization with a beacon transmitted at regular intervals from a counterpart wireless device,
After the data communication with the counterpart wireless device is completed, it is confirmed whether or not a communication message addressed to the wireless terminal device is received by the data communication, and if the communication message addressed to the wireless terminal device is received, the host When a host wake-up signal is output to the control unit to shift from a standby state that reduces power consumption in the host control unit to a normal operation state, and a communication message addressed to the wireless terminal device is not received A wireless module comprising host awakening means for maintaining the host control unit in the standby state without outputting the host awakening signal. The wireless module according to claim 3, wherein
The wireless communication system further comprises module management means for shifting the operation state of the wireless module from a standby state with low power consumption in the wireless module to a normal operation state in response to a module awakening signal from the host control unit. module. Host control that performs desired function processing by exchanging various communication messages with the partner wireless device using this wireless module, and a wireless module that performs data communication with the partner wireless device in accordance with the Bluetooth (registered trademark) wireless communication system A wireless module control method for controlling a wireless module that performs the data communication by intermittently operating in synchronization with a beacon transmitted at regular intervals from a counterpart wireless device,
After the data communication with the counterpart wireless device is completed, it is confirmed whether or not a communication message addressed to the wireless terminal device is received by the data communication, and if the communication message addressed to the wireless terminal device is received, the host Transitioning from the standby state to reducing the power consumption in the host control unit to the normal operation state by outputting a host awakening signal to the control unit;
And a step of maintaining the host control unit in the standby state without outputting the host awakening signal when a communication telegram addressed to the wireless terminal device is not received. The wireless module control method according to claim 5,
The wireless module control further comprising a step of shifting the operation state of the wireless module from a standby state with low power consumption in the wireless module to a normal operation state in response to a module awakening signal from the host control unit. Method.

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