WO2011118117A1

WO2011118117A1 - Radio reception activation control apparatus, radio receiver microcomputer and applied system

Info

Publication number: WO2011118117A1
Application number: PCT/JP2011/000637
Authority: WO
Inventors: 広和杉
Original assignee: パナソニック株式会社
Priority date: 2010-03-24
Filing date: 2011-02-04
Publication date: 2011-09-29
Also published as: JP2011199803A

Abstract

An addressed-to-another-apparatus pattern determining unit determines whether a telegraphic message received in a radio communication includes any addressed-to-another-apparatus pattern. If the addressed-to-another-apparatus pattern determining unit determines that the telegraphic message includes any addressed-to-another-apparatus pattern, then a radio power supply control unit performs a power-saving control for the radio power supply.

Description

Wireless reception activation control device, microcomputer for wireless receiver and application system

The present invention relates to a radio reception activation control device used for activation control of a radio receiver, and more particularly to a technique for reducing power consumption of radio reception control. The present invention also relates to a microcomputer used for a wireless receiver and its application system (wireless house alarm system, automatic meter reading system, entry system).

In recent years, many set products using wireless communication functions have appeared due to their convenience. Among these, products using batteries as driving power sources are demanded from the viewpoint of portability, and products characterized by low power consumption are increasing. In particular, products that operate without maintenance for a long period of time, such as wireless home alarms, are based on the assumption that they operate on battery power for more than 10 years, and it is hoped that low power consumption will be realized as soon as possible. It is rare.

Hereinafter, a conventional wireless receiver will be described with reference to the drawings. FIG. 8 is a block diagram showing the configuration of a wireless receiver in the prior art. In the wireless receiver 100, the signal received by the wireless reception antenna unit 1 is demodulated into a digital signal by the radio wave demodulation unit 2 and stored in the reception data buffer 4. When the radio wave demodulator 2 demodulates the analog signal (received signal) into a digital signal, the carrier output detector 3 measures the strength of the radio wave (electric field strength) received by the radio receiving antenna unit 1 and wirelessly transmits the result. The carrier function presence / absence determiner 9 of the communication function control unit 8 is notified. The carrier output presence / absence determiner 9 performs carrier sense processing based on the threshold set according to the specifications and the electric field strength detected by the carrier output detector 3. At this time, the carrier output presence / absence determiner 9 determines that there is no radio wave in the frequency band to be received if the received electric field strength is less than the threshold. The wireless power supply controller 12 cuts off the power supply to reduce power consumption based on the determination. On the other hand, if the received electric field strength is equal to or higher than the threshold value, it is determined that there is a radio wave in the frequency band to be received, the wireless power controller 12 continues to supply power, and the operation of the pattern comparator 6 addressed to itself starts. .

When the operation starts, the pattern comparator 6 addressed to its own device compares the pattern addressed to its own device stored in the pattern buffer 5 and the frame pattern stored in the received data buffer 4. The pattern addressed to itself is defined in advance by the wireless communication function control unit 8. In the comparison result, when the contents of the pattern buffer 5 addressed to the own device and the contents of the received data buffer 4 match, the pattern comparator 6 addressed to the own device notifies the wireless communication function control unit 8 that the pattern matches.

When the wireless communication function control unit 8 is notified of the pattern match, the wireless communication function control unit 8 receives data from the next bit onward as this data. As a result, the data stored in the reception data buffer 4 starts to be transferred from the confirmed reception data transfer unit 7 to the wireless communication function control unit 8.

However, so-called noise, which is not transmission data, is always present in the frequency band that the wireless receiver 100 is to receive. When noise exists, the carrier output detection unit 3 erroneously determines that there is a radio wave in the frequency band to be received (false sense). Then, the pattern comparator 6 addressed to itself starts the comparison operation and examines the data. Of course, the frame pattern does not match because of a false sense.

Assuming such a case, in order to stop useless comparison processing, a method of stopping the reception processing operation after a certain time (timeout time) has been prepared. However, power is supplied until the timeout time elapses after erroneous detection, and wasteful power is consumed.

Therefore, the following methods have been conventionally proposed. In this method, a time until communication scheduled to be performed next is described in a part of transmission data transmitted from the transmitter, and when the wireless receiver 100 receives the data, the intermittent reception cycle is based on the received data. The controller 11 determines the communication time scheduled to be executed next time and applies the determined communication time to the intermittent reception cycle controller 11. Thereby, the carrier sense period implemented using the carrier output detection unit 3 is controlled by the transmitter, and thus the possibility of erroneous sensing is reduced as much as possible. Therefore, efficient communication is realized, and current consumption generated while waiting for the timeout time is reduced. Such a transmission method is described in Patent Document 1, for example.

JP 2006-325055 A

The conventional technology aims to reduce power consumption as described above, but this technology can be realized only by a system (1: 1 communication) including one transmitter and one receiver. In a system (1: N communication) consisting of multiple transmitters and multiple receivers, or a system consisting of multiple transmitters and multiple receivers (N: N communication) I can't. When there are a plurality of transmitters, it is necessary to communicate the times for the next transmission between the plurality of transmitters even during the transmission period and perform timing adjustment between the transmitters. In addition, even if there is only one transmitter, there are actually many transmitters of other systems that are not equipped with the technology described in Patent Document 1. Eventually, the increase in current consumption due to false sensing Inevitable.

The present invention was created in view of such circumstances, and provides a wireless reception activation control device that shortens the time required to perform power saving control of a wireless power supply and enhances the power saving effect. It is an object.

<< 1 >> The present invention concerning the radio reception activation control device takes the following means in order to solve the above-mentioned problems. In order to facilitate understanding, description will be made with reference to FIG. 1 (however, the present invention is not limited by this figure).

Suppose that a message received in wireless communication is checked and it is positively determined whether or not the message contains a pattern addressed to another device. As a device for determining whether or not a pattern addressed to another device is included, a pattern determination device E10 addressed to the other device is provided. Here, it is assumed that the pattern addressed to the other device is known in advance, and the known pattern addressed to the other device is registered in the pattern determination unit E10 addressed to the other device. The pattern determiner E10 addressed to the other device actively checks whether the pattern is addressed to the other device while detecting whether the determination target is the pattern addressed to the own device by a separate means. That is why. As a result, it is determined whether a pattern addressed to the own device or a pattern addressed to another device is included earlier than the case of merely waiting until detection and confirmation of whether or not a pattern addressed to the own device is included. If it turns out that the pattern addressed to the other device is included, it means that the message does not include the pattern addressed to the own device, and if so, the power source for driving the receiver of the own device can be immediately controlled to save power. . While it is not clear that the pattern is destined for the other machine, it is uncertain whether it contains the pattern destined for the own machine or the pattern destined for the other machine. For example, it can be considered that the message does not include the pattern addressed to the other device, that is, the message can be regarded as addressed to the own device, so that the power supply state of the power source may be continued. A wireless power supply controller E20 is provided as a power saving control for the power supply that drives the receiver of the device itself. The wireless power supply controller E20 performs power-saving control of the power supply immediately when the determination result by the pattern determination unit E10 addressed to the other device indicates addressed to the other device. Note that the wireless power controller E20 may similarly perform power saving control of the power supply even in a negative carrier sense state. As for the configuration for determining a pattern addressed to the own device, the present invention itself is not necessarily an essential requirement.

In short, the wireless reception activation control device of the present invention is
Determining whether or not the message received via the own receiver includes a pattern addressed to another device that identifies that the message is addressed to another device communication group that does not include the own receiver. E10,
When the pattern determiner addressed to the other device determines that the pattern includes the pattern addressed to the other device, the wireless device includes a radio power controller and E20 for controlling power saving of a power source for driving the receiver. Is.

The pattern determination unit E10 addressed to the other device is a device configuration that receives the received message and actively checks that the received message contains a pattern addressed to the other device. If it is confirmed by the determination by the pattern determiner E10 addressed to the other device that the received message contains a pattern addressed to the other device, the fact is notified to the wireless power supply controller E20. Receiving the notification, the wireless power supply controller E20 immediately performs power saving control of the power supply. As a result, the reception processing operation can be stopped without waiting for the timeout process.

Here, consider a wireless receiver that has a pattern comparator addressed to its own device but does not have a pattern determination device E10 addressed to another device (equivalent to conventional technology). The pattern comparator addressed to the own device checks whether or not the received message contains a pattern addressed to the own device, but it takes a considerable time to determine this. There are various forms of radio waves in the surrounding space, of which only a few are destined for this machine. Therefore, the average probability of receiving a message containing a pattern addressed to the own device is low. Since it is low, it takes time to determine whether a pattern addressed to the machine is included.

On the other hand, in the present invention, since the pattern determination unit E10 intended to actively detect the pattern addressed to the other device is provided, the detection of the message including the pattern addressed to the other device, that is, the message addressed to the other device is accelerated. Since the time until power saving control of the wireless power source is shortened, the power saving effect is high.

According to the present invention, since the pattern determination device addressed to the other device is provided and the pattern addressed to the other device is positively detected, the detection of the message including the pattern addressed to the other device, that is, the message addressed to the other device is accelerated, The time required until power saving control of the wireless power source is shortened, and the power saving effect can be enhanced.

FIG. 1 is a block diagram showing a basic configuration of a radio reception activation control device of the present invention. FIG. 2 is a block diagram illustrating a configuration of a wireless receiver including the wireless reception activation control device according to the first embodiment of the present invention. FIG. 3A is a configuration diagram (part 1) of transmission / reception data in the embodiment of the present invention. FIG. 3B is a configuration diagram (part 2) of transmission / reception data in the embodiment of the present invention. FIG. 4 is a flowchart illustrating the operation of the wireless receiver according to the first embodiment of the present invention. FIG. 5 is a timing chart showing the operation of the wireless receiver according to the first embodiment of the present invention. FIG. 6A is a block diagram showing a wireless house alarm device constituting a wireless house alarm system which is a first example in Embodiment 2 of the present invention. FIG. 6B is a block diagram showing an automatic meter reading device constituting an automatic meter reading system that is a second example of the second embodiment of the present invention. FIG. 6C is a block diagram illustrating an entry device that constitutes an entry system that is a third example of Embodiment 2 of the present invention. FIG. 7 is a block diagram showing another configuration of the wireless house alarm system according to the second embodiment of the present invention. FIG. 8 is a block diagram showing a configuration of a wireless receiver in the prior art.

The wireless reception activation control device of the present invention having the above configuration <1> can be further advantageously developed in the following embodiment.

<< 2 >> The configuration of << 1 >> above will be examined at a more specific level. It is only necessary to know in advance what kind of pattern is addressed to other machines, but this is not necessarily the case. In the case of << 1 >>, it is assumed that a known pattern destined for another machine is preset in the pattern determination unit E10 destined for the other machine. In this section << 2 >>, it is assumed that an unknown pattern is targeted as a pattern addressed to another device.

Therefore, a pattern addressed to another device is collected in an actual wireless communication situation, and the collected pattern addressed to the other device is set in the pattern determination device E10 addressed to the other device. As a device configuration for that purpose, a setting device for collecting and setting patterns addressed to other devices is provided. The setter recognizes a pattern addressed to its own device specifying that it is addressed to its own device communication group including the own device receiver, and then detects a pattern included in the message that does not detect the pattern addressed to the own device. A pattern extractor E11 destined for the other machine that extracts the address as a pattern, and a pattern setter E12 destined for the other machine that sets the pattern destined for the other machine extracted by the pattern extractor E11 destined for the other machine in the pattern determiner E10. It is comprised as what was equipped (refer FIG. 1).

According to this structure, even if the other apparatus destined patterns not know whether pre What, in actual radio communication environments, captures another machine destined pattern from the signal apparatus itself captured, taken other It becomes possible to effectively use the pattern addressed to the machine for the power saving control of the receiver.

In short, this section is the configuration of << 1 >> above.
A setter for collecting a pattern addressed to the other device via communication by the receiver of the own device, and setting a collected pattern addressed to the other device in a pattern determination device addressed to the other device,
In addition,
The setter is
Recognizing a pattern addressed to the own device specifying that it is addressed to the own device communication group including the own device receiver, and extracting a pattern included in the message that does not detect the pattern addressed to the own device as a pattern addressed to the other device A pattern extractor for other machines
A pattern setter addressed to the other device that sets the pattern addressed to the other device extracted by the pattern extractor addressed to the other device in the pattern determiner addressed to the other device;
It has.

This makes it possible to hold a pattern that is detected and collected in a state where a pattern addressed to the own device is not detected as a pattern addressed to another device. In other words, by dynamically capturing patterns addressed to other devices from messages addressed to other wireless receivers, it is possible to immediately confirm that the message is addressed to another device even if reception starts due to a false sense. It is possible to determine, and it is possible to stop the reception processing operation without waiting for the timeout process.

<< 3 >> The pattern extractor E11 destined for the other apparatus in the configuration of the above << 2 >> is examined. In this section, the pattern extractor E11 addressed to the other device is configured to include a frame synchronization boundary detector that detects the boundary between the bit synchronization pattern and the frame pattern in the received data. The frame synchronization boundary detector is configured to send a message after the completion of the bit synchronization pattern as a pattern addressed to the other device to the pattern setting device E12 addressed to the other device.

With this configuration, it is possible to collect and hold frame patterns uniquely lent by each system as patterns addressed to other devices.

<< 4 >> The pattern setting device E12 destined for the other machine in the configuration of the above << 2 >> and << 3 >> will be examined. In this section, the pattern setting unit E12 addressed to the other device counts the patterns addressed to the other device extracted from the pattern extractor (frame synchronization boundary detector) E11 addressed to the other device, and the patterns destined for the other device that are counted for detection to the other device. Is sent to the pattern determination device E10 addressed to other devices. Further, the pattern determination unit E10 addressed to the other device is configured to make a determination addressed to the other device using the pattern addressed to the other device sent from the pattern setting unit E12 addressed to the other device.

If configured in this way, unique frame patterns in each group are tabulated as patterns addressed to other devices, and the tabulated result is used as a pattern addressed to other devices for determination to address other devices. As a result, as in << 1 >>, the detection of a message addressed to another device is accelerated, and the time until power saving control of the wireless power supply is shortened. As a result, the power saving effect is high.

<< 5 >> In the configurations of << 1 >> to << 4 >> above, it is conceivable that the communication form is a specific low power radio. If the specific low power radio is adopted, the effect of reducing power consumption can be further promoted, which is particularly advantageous for a battery-operated system.

<6> In connection with the above-described wireless reception activation control device, there is a development as a microcomputer for a wireless receiver. The microcomputer
A pattern addressed to another device for determining whether or not a message received via the own device receiver includes a pattern addressed to another device that identifies that the message is addressed to another device communication group not including the own device receiver A determiner;
When the pattern determination device addressed to the other device determines that the pattern includes the pattern addressed to the other device, a wireless power supply controller that performs power saving control of a power source that drives the receiver of the device;
It has. By providing the wireless reception function to the microcomputer, it is possible to reduce the size and power consumption of the device.

<< 7 >> Further, in connection with the above-described wireless reception activation control device, there is a development as a wireless house alarm system. The system is
One or more transmitters, and one or more receivers having the wireless reception activation control device of claim 1,
The transmitter has a sensor function for detecting an environmental change in the vicinity of the transmitter, and is configured to transmit an alarm signal toward the receiver when the environmental change is detected by the sensor function.
The receiver further includes an alarm function for issuing an alarm to the outside, and is configured to operate the alarm function when the alarm signal is received.

Here, the transmitter has a sensor function, and is configured to transmit an alarm signal to the receiver when the sensor function is activated. The receiver is any one of the above << 1 >> to << 5 >>, further has an alarm function, and is configured to operate the alarm function when an alarm signal from the transmitter is received. . If comprised in this way, in a wireless house alarm system, the battery life of a receiver will become long and it will become possible to construct a highly reliable system.

<8> Further, in connection with the above-described wireless reception activation control device, there is a development as an automatic meter reading system for an electric meter, a gas meter, or a water meter. that is,
One or more transmitters, and one or more receivers having the wireless reception activation control device of claim 1,
The transmitter further has a measurement function for measuring a usage amount of a commercial power source, gas fuel, or water. When the measurement function is activated, a meter reading information signal indicating a measurement result of the measurement function is directed to the receiver. Configured to send,
The receiver further has a meter reading information collecting function, and is configured to collect meter reading information for each transmitter by operating the meter reading information collecting function when receiving the meter reading information signal. If comprised in this way, in the automatic meter-reading system, the battery life of a radio receiver will become long and it will become possible to construct a highly reliable system.

<< 9 >> Also, in connection with the above-described wireless reception activation control device, there is a development as an entry system. that is,
A transmitter and a receiver having the wireless reception activation control device according to claim 1;
The transmitter has a function of generating a wireless transmission request based on an input operation via an interface, and when the transmission request generation function is operated, an unlock signal or a lock signal is transmitted to the receiver. Composed of
The receiver has a locking / unlocking function for unlocking and locking the locking device, and when receiving the unlocking signal or the locking signal, operates the locking / unlocking function based on the received signal. It is configured. If comprised in this way, in the entry system, the battery life of a radio | wireless receiver will become long and it will become possible to construct | assemble a highly reliable system.

<< 10 >> A preferable example of the entry system having the above-described structure <9> is one in which the locking device is constituted by a car key device.

Hereinafter, embodiments of a wireless receiver including the wireless reception activation control device of the present invention will be described with reference to the drawings. In addition, since the component which attached | subjected the same code | symbol in the Example performs the same operation | movement, description may be abbreviate | omitted again.

Example 1
FIG. 2 is a block diagram illustrating a configuration of the wireless receiver 100 including the wireless reception activation control device according to the first embodiment of the present invention.

A radio receiver (own receiver) 100 includes a radio receiving antenna unit 1, a radio wave demodulating unit 2, a carrier output detecting unit 3, a received data buffer 4, a pattern buffer 5 addressed to the own device, and a pattern addressed to the own device. Comparator 6, deterministic reception data transfer unit 7, wireless communication function control unit 8, carrier output presence / absence determination unit 9, wireless reception data processor 10, wireless power supply controller 12, and frame synchronization boundary detector 21 A pattern buffer 22 addressed to the other machine, a pattern comparator 23 addressed to the other machine, a pattern determination unit 24 addressed to the other machine, and a pattern setting unit 25 addressed to the other machine. The carrier output detection unit 3 is included in the radio wave demodulation unit 2. The pattern determiner 24 addressed to the other machine includes a pattern buffer 22 addressed to the other machine and a pattern comparator 23 addressed to the other machine. The wireless communication function controller 8 includes a carrier output presence / absence determiner 9, a wireless reception data processor 10, a wireless power controller 12, and a pattern setter 25 addressed to another device. The frame synchronization boundary detector 21 includes a pattern extractor addressed to other devices. The setting device of the present invention includes a frame synchronization boundary detector (pattern extractor for other device) 21 and a pattern setting device 25 for another device.

The wireless reception antenna unit 1 receives transmission radio waves. The radio wave demodulator 2 demodulates the radio wave received by the radio receiving antenna unit 1 into data. The carrier output detector 3 measures the strength of the received radio wave. The reception data buffer 4 stores demodulated data. The pattern comparator 6 addressed to the own apparatus compares and determines the frame pattern in the received data temporarily stored in the received data buffer 4 and the frame pattern addressed to the own apparatus stored in the pattern buffer 5 addressed to the own apparatus. The definite reception data transfer unit 7 stores data immediately after the pattern comparator 6 determines that the comparison coincides with the own device. The carrier output presence / absence determiner 9 determines the strength of the radio wave measured by the carrier output detector 3. The wireless reception data processor 10 processes the data transmitted from the fixed reception data transfer unit 7. The wireless power supply controller 12 ends wireless reception when the carrier absence determination or data reception ends. The wireless power controller 12 corresponds to E20 in FIG. The frame synchronization boundary detector 21 detects the data after the bit synchronization pattern as a pattern addressed to another device. The frame synchronization boundary detector 21 is an example of the configuration of the pattern extractor E11 addressed to the other apparatus in FIG.

The pattern buffer 22 addressed to the other device stores the pattern addressed to the other device detected by the frame synchronization boundary detector 21 via the pattern setting device 25 addressed to the other device described later. The pattern comparator 23 addressed to the other device compares the frame pattern in the received data temporarily stored in the received data buffer 4 with the pattern addressed to the other device stored in the pattern buffer 22 addressed to the other device. The comparator 23 corresponds to E10 in FIG. The pattern setting unit 25 addressed to the other device is a component unique to the present invention in the wireless communication function control unit 8, and aggregates the patterns addressed to the other device detected by the frame synchronization boundary detector 21, and outputs the pattern buffer addressed to the other device. Set to 22. The setting device 25 corresponds to E12 in FIG. The wireless communication function controller 8 includes a carrier output presence / absence determiner 9, a wireless reception data processor 10, a wireless power controller 12, and a pattern setter 25 addressed to another device. The pattern determination unit 24 addressed to the other machine corresponds to E10 in FIG. 1, and the pattern setting unit 25 addressed to the other machine corresponds to E12 in FIG.

It should be noted that the pattern destined for the other device stored in the pattern buffer 22 for the other device does not have to be one pattern, and it is possible to sequentially compare a plurality of patterns. In other words, there may be a plurality of determination patterns destined for other machines determined by the pattern judgment unit 24 addressed to other machines.

Hereinafter, the operation of this embodiment will be described. Since the present invention has the greatest feature in the received data handling configuration, the wireless receiver 100 is taken as an example in the above description of the present embodiment. However, in order to explain the details of the operation of the present invention, it is necessary to assume a transmission / reception system including a plurality of transmitters / receivers that transmit / receive data to / from each other. Therefore, in the following description, the wireless transceiver having the wireless receiver 100 is described with reference numeral 100 '.

3A and 3B show the structure of data used for communication. Consider two types of data D and D * Ｄ. The data D shown in FIG. 3A is data that can be handled in common by a local communication group to which a plurality of wireless transceivers including the wireless transceiver 100 ′ belong, and the wireless transceiver 100 ′ that has transmitted the data D is It is another wireless transceiver that belongs to the communication group. Hereinafter, the wireless transceiver 100 ′ that transmits the data D is referred to as a wireless transceiver 100 ′ (D), and the wireless transceiver 100 ′ that receives the data D in the local communication group is referred to as a wireless transceiver 100A ′. To distinguish.

The data D * shown in FIG. 3B is data that cannot be handled by the own device communication group, and the wireless transceiver that has transmitted this data D * has a communication group different from the own device communication group (hereinafter referred to as other device communication). Belonging to a group). Hereinafter, the wireless transceiver 100 ′ that transmits the data D * is referred to as a wireless transceiver 100 ′ (D *), and the other wireless transceiver 100 ′ that receives the data D * in the other-device communication group is referred to as the wireless transceiver 100B. Call it 'and distinguish between the two.

The data D is composed of a bit synchronization pattern P1, a frame pattern P2, and data P3. Similarly, the data D * is composed of a bit synchronization pattern Q1, a frame pattern Q2, and data Q3. The leading bit synchronization patterns P1 and Q1 are fixed patterns (for example, data that alternately repeats “0”, “1” or “1”, “0”). The bit synchronization patterns P1 and Q1 are used for timing adjustment and frequency adjustment for punching out data necessary for the radio transceivers 100A ′ and 100B ′ to receive subsequent frame patterns P2 and Q2 and data P3 and Q3. It is done. The frame patterns P2 and Q2 immediately after the bit synchronization patterns P1 and Q1 are patterns arranged immediately before the data P3 and Q3, respectively, and are unique patterns for each group. That is, the frame pattern P2 and the frame pattern Q2 are different from each other. The frame patterns P2 and Q2 indicate that the data P3 and Q3 are immediately after that.

Data P3 is data actually required by the radio transceiver 100A '. Data Q3 is data actually required by the radio transceiver 100B '. Here, the radio transceivers 100 ′ (D) and 100A ′ belonging to the own apparatus communication group and the radio transceivers 100 ′ (D *) and 100B ′ belonging to the other apparatus communication group exist in the same space. It shall be. The frame pattern P2 of data D is set in the pattern buffer 5 addressed to the own device of the wireless transceiver 100A 'belonging to the own device communication group.

Next, the operation of the wireless transceiver 100A 'of the present embodiment configured as described above will be described with reference to the flowchart of FIG. First, in step S1, the radio reception antenna unit 1 receives a radio signal radio wave.

Next, in step S2, carrier sense is executed for the radio wave received by the wireless reception antenna unit 1. This carrier sense is performed as follows. First, the radio wave demodulator 2 demodulates the received signal into digital data. Further, the carrier output detector 3 measures the electric field strength (carrier) of the received signal. The measured electric field strength is sent to a carrier output presence / absence determiner 9 in the wireless communication function control unit 8. The carrier output presence / absence determiner 9 determines whether the electric field intensity of the received signal (received radio wave) is greater than or equal to a prescribed threshold value. If it is less than the threshold value, it is determined that there is no carrier, and the process proceeds to step S10 (wireless power supply stop). In step S10, the wireless power supply controller 12 cuts off the power supply to reduce current consumption.

On the other hand, if the electric field strength of the received radio wave is equal to or greater than the threshold value, it is determined that there is a carrier, and the process proceeds to step S3 (digital signal demodulation). Here, a rough flow of the operation after step S3 will be described. When the received data is not addressed to the own device communication group (when addressed to the other device communication group), the flow proceeds from step S3 → S4 → S5 → S6 → S10. On the other hand, when the received data is addressed to the own device communication group (not addressed to the other device communication group), the flow is step S3 → S7 → S8 → S9 → S10.

In step S3, the radio wave demodulator 2 performs digital signal demodulation on the received signal and sends the demodulated data to the received data buffer 4.

When the process of step S3 is completed, the routine of steps S4 to S5, the routine of step S6, and the routine of steps S7 to S9 are processed in parallel.

(1) Description of Routines of Steps S4 to S5 In this routine, the received data is considered to be data D * and the following processing is performed. In step S4, the frame synchronization boundary detector 21 tries to detect the frame boundary. That is, an attempt is made to detect the boundary between the bit synchronization pattern Q1 and the frame pattern Q2 in the data D *. When the frame boundary is not detected, it is determined that the received data is not data D *, and the process returns to step S3. When the frame boundary is detected, it is determined that the received data is data D *, and the process proceeds to step S5.

In step S5, the frame synchronization boundary detector 21 acquires a pattern addressed to the other device from the data D *, and sends the acquired pattern addressed to the other device to the pattern setting device 25 addressed to the other device. The pattern addressed to the other device is a data pattern portion excluding the bit synchronization pattern Q1 in the received data D *. The pattern setter 25 addressed to the other device holds the pattern addressed to the other device received from the frame synchronization boundary detector 21. Further, the pattern setting unit 25 addressed to the other device transfers the pattern addressed to the other device to the pattern buffer 22 addressed to the other device, and then returns to step S3. When a pattern setter 25 destined for another machine holds a plurality of patterns destined for another machine, an appropriate one is selected and transferred to the pattern buffer 22 destined for the other machine.

(2) Description of Routine of Step S6 In this routine, the received data is considered to be data D * and the following processing is performed. In step S6, the pattern comparator 23 addressed to the other device compares the frame pattern of the received data temporarily held in the received data buffer 4 with the pattern addressed to the other device stored in the pattern buffer 22 addressed to the other device. To do. At this time, the pattern selected by the pattern setting unit 25 addressed to the other device is the one received from the frame synchronization boundary detector 21. If the two patterns do not match, it is determined that the received data is not data D *, and the process returns to step S3. On the other hand, if the two patterns match, it is determined that the received data is data D *, the fact is notified to the wireless power controller 12, and the process proceeds to step S10 (wireless power stop). In step S10, the wireless power supply controller 12 cuts off the power supply and reduces the current consumption.

The sequence of steps S4, S5, S6, and S10 described here is the point in this embodiment.

(3) Description of Routine of Steps S7 to S9 In this routine, the received data is considered to be data D, and the following processing is performed. In step S7, the pattern comparator 6 addressed to its own device compares the frame pattern in the data of the reception data buffer 4 with the frame pattern addressed to its own device specified in the pattern buffer 5 addressed to its own device. If the two patterns do not match, it is determined that the received data is not data D, and the process returns to step S3. On the other hand, when both patterns match, it is determined that the received data is data D, and the process proceeds to step S8.

Next, in step S8, data reception is started. In other words, the wireless communication function control unit 8 that has received the notification of the pattern match activates the fixed reception data transfer unit 7 to check the data read from the reception data buffer 4 after confirming the match data, and the wireless reception data processor 10. Forward to. When the prescribed data has been received (reading from the received data buffer 4 is completed), the process proceeds to step S9.

Next, in step S9, a data reception completion process is performed, and then the process proceeds to step S10 to notify the wireless power controller 12 to cut off the power supply (wireless power supply stop).

In the above, when the processing result becomes negative in step S4, step S6, and step S7, the process returns to the digital signal demodulation process in step S3 again. Thereafter, the same operation is repeated again after receiving the next bit. .

FIG. 5 is a timing chart for explaining the operation of the wireless receiver 100 constituting the wireless transceiver 100A '. Immediately after the determination that there is a carrier, wireless receiver 100 determines whether or not the transmission data is addressed to itself using a frame pattern. As described above, the frame pattern used here is unique for each communication group, and the radio receiver 100 grasps in advance the frame pattern (P2) addressed to itself, and is exemplified by the period R1. Thus, when the prescribed data P3 is received, the receiving operation is stopped (the operation of steps S7 → S8 → S9 → S10 in FIG. 4).

However, since the frame pattern (Q2) used in the other device communication group is unknown to the radio transceiver 100, it cannot be determined whether it is destined for the own device, and will be exemplified in the period R2. Even if the data D * (Q3) is completely transmitted, the reception processing operation cannot be stopped unless the specified timeout period elapses.

Therefore, in this embodiment, the data in the reception data buffer 4 is sent to the frame synchronization boundary detector 21 immediately after it is determined that there is carrier sense. Thereby, the frame synchronization boundary detector 21 performs the frame boundary detection operation of step S4, and detects the boundary between the bit synchronization patterns P1 and Q1 and the frame patterns P2 and Q2. Following the detection of the boundary, the frame synchronization boundary detector 21 performs a pattern acquisition process addressed to the other device in step S5, and sends the pattern addressed to the other device detected by this processing to the pattern setting device 25 addressed to the other device. As a result, the pattern setting unit 25 destined for the other device determines that the data D * is present with carrier sense in the period R2, stores the frame pattern, and starts the comparison. As a result, the frame pattern Q2 of the data D * can be dynamically acquired. Thereafter, by using the frame pattern Q2 as a pattern addressed to another device, even if it is determined again that the data D * has carrier sense in the period R3, the pattern determiner 24 addressed to the other device and the carrier addressed to the other device (other It is possible to quickly determine that it is addressed to the machine communication group and not to the own machine (not addressed to the own machine communication group), and based on the determination result, the wireless power supply can be stopped to reduce current consumption (see FIG. Step 4 from step S6 to S10).

For example, the frame synchronization boundary detector 21 detects the boundary by the following method. That is, the bit synchronization pattern is set to data that repeats “0” and “1” alternately (hexadecimal 0x55), and data that repeats “1” and “0” alternately (hexadecimal). 0xAA) may be set. In the former case, if “11” data is detected, it is determined that a boundary has been detected. In the latter case, if “00” data is detected, it may be determined that a boundary has been detected.

Specifically, in the case where the bit synchronization pattern is a pattern repeating 0x55, in the vicinity of the boundary between the bit synchronization pattern and the frame pattern, “... The portion that becomes “11” is the boundary, and the subsequent data including the second “1” at the “11” location detected for the first time becomes the frame pattern data. Here, when the detection target is a signal (data) addressed to itself, the frame synchronization boundary detector 21 knows in advance the number of bits for determining whether or not the frames match. Therefore, when the data of the number of bits is received and the frame synchronization boundary detector 21 determines that it is not the coincident frame pattern, the data is sent to the pattern setter 25 destined for other devices. In the case of the above example, the pattern addressed to the other device is “11100110.

Actually, it is conceivable that the frame pattern of the data D * includes “01” as in the bit synchronization pattern such as “0111100110...”, “10111100110”. However, in any case, since the pattern “11100110...” Addressed to the other machine is used as the pattern addressed to the other machine, it is determined as the pattern addressed to the other machine, and there is no problem.

The pattern setter 25 destined for the other device sums up the patterns destined for the other device sent from the frame synchronization boundary detector 21 and then selects the pattern judged to have the highest possibility of mismatch detection by the summation as the pattern destined for the other device. Store in the buffer 22. By doing in this way, the effect of reducing current consumption can be further increased. The highest possibility of mismatch detection is considered, for example, when a pattern addressed to the same other device is counted many times, or there is a frame pattern that occurs only in a certain time zone.

Note that the present invention is effective in a wireless receiver. However, since the transmitter always has a frame pattern even if it has a conventional configuration, the effects of the present invention can be obtained.

In the above, on the premise of the local communication group including one transceiver (sender) and a plurality of transceivers (receivers), the wireless transceiver 100 (D *) belonging to the other communication group transmits The present invention has been described by taking, as an example, the case where the wireless transmitter / receiver 100B ′ belonging to the own communication group erroneously starts receiving data addressed to another wireless receiver. However, as a matter of course, in a configuration having a plurality of transceivers (transmission sources) and a plurality of transceivers (reception sources) as the own device / other device communication group, the wireless transceivers belonging to the other device communication group transmit. It goes without saying that the present invention can be implemented in the same manner even when data addressed to a wireless transceiver for another device communication group is erroneously started to be received by a wireless receiver belonging to the own device communication group. .

Further, in a local communication group including one transmitter / receiver (sender) and a plurality of transmitter / receivers (receiver), communication with other devices transmitted from a transmitter belonging to another device communication group. Even when the data addressed to the group is erroneously started, the present invention can be similarly realized. In addition, in the own device communication group comprising a plurality of transmitters and a plurality of receivers, even when the data addressed to the other device communication group transmitted from the transmitter belonging to the other device communication group is erroneously started, This is realized in the same manner as described above.

As can be seen from these facts, the object of the present embodiment described above can be achieved in various systems by dynamically acquiring patterns addressed to other devices and comparing the acquired patterns addressed to other devices. it can.

(Example 2)
FIG. 6A is a block diagram illustrating a wireless house alarm device 300 constituting the wireless house alarm system according to the second embodiment of the present invention. The wireless house alarm device 300 includes a control microcomputer 31, a sensor 32, an alarm device 33, a radio transmitter 200, and a radio receiver 100, and the alarm device 300 is controlled by the control microcomputer 31. The sensor 32 detects fire (heat) and smoke (these are specific examples of environmental change) when a fire (environmental change in the vicinity of the system) occurs, and the detection information is wirelessly transmitted to the alarm device 33 via the control microcomputer 31. To the machine 200. Upon receiving the fire occurrence information, the wireless transmitter 200 receives another wireless house alarm device group (for example, another wireless house in the same house) belonging to the same system (own apparatus communication group) via its own wireless communication function. The fire occurrence information is transmitted to the alarm device group), and at the same time, an alarm is issued to the user via the alarm device 33. Each wireless house alarm device 300 is always in a reception waiting state, and upon receiving the fire occurrence information transmitted by another wireless house alarm device 300 ′ belonging to the same system (own device communication group), the wireless house alarm device 300 An alarm is issued via its own alarm device 33. As a result, alarms are issued simultaneously from the wireless

alarm device systems

300, 300 ′,... Belonging to the same system (own device communication group).

Since each wireless

house alarm device

300, 300 ′,... Is always in a reception waiting state, when similar data is transmitted from a wireless house alarm device belonging to another system (another device communication group) sharing the transmission / reception space, There is a possibility that the wireless home alarm device 300 belonging to the same system (own device communication group) that has detected this data will be erroneously sensed and start receiving. However, by applying the present invention, once the wireless house alarm device 300 belonging to the same system (own device communication group) determines that the pattern is addressed to another device, the data is detected thereafter. However, it is possible to determine that the detected data is data transmitted by a wireless house alarm device belonging to another system (another device communication group) and to quickly stop the reception processing operation. It is possible to easily develop a system that does not cause information complication among a plurality of own device / other device communication group systems sharing a wireless transmission / reception space.

Further, in the wireless house alarm device 300 to which the present invention is applied, when the battery drive is general and the remaining battery level is low, the alarm operation is not only hindered but also belongs to the same system (own device communication group). The alarm information cannot be wirelessly communicated to other wireless house alarm devices 300, which may increase the damage. However, by adopting the present invention, it is possible to realize the wireless house alarm device 300 that satisfies a long battery life, and thus such a problem is prevented in advance.

Further, as shown in FIG. 7, the configuration of the present invention is applied to the control microcomputer 31, wireless receiver 100, and wireless transmitter 200 in the wireless home alarm device 300 of FIG. The same effect can be obtained also in the wireless house alarm device 350 provided with the control microcomputer 250 having the above. The wireless home alarm device 350 that senses fire or smoke is connected to another wireless home alarm device group (for example, another wireless home alarm device group in the same house) belonging to the same system (own device communication group) as a control microcomputer. In addition to notifying the fire occurrence information using the 250 wireless transmission function, an alarm is issued to the user via the alarm device 33. In the alarm device 350 other than the wireless house alarm device 350 closest to the fire source, when the notification information issued from the wireless house alarm device 350 that detects the fire is received using the wireless communication function of the control microcomputer 250, An alarm is issued via its own alarm device 33.

As described above, in this embodiment, the frame pattern transmitted by the wireless house alarm device belonging to another system (other equipment communication group) is dynamically recognized and acquired as a pattern addressed to the other equipment. By comparing the patterns to the machine, the intended purpose is achieved.

Further, even within the same system, communication may be performed by excluding other devices only between a specific wireless transmitter and a specific wireless receiver. For example, the present invention can be applied to a configuration in which selective communication is performed between devices registered with each other in the same system.

In the second embodiment, the example in which the present invention is implemented in a communication group including one transmitter and a plurality of receivers has been described. However, of course, the present invention is similarly applied to a communication group composed of one transmitter and one receiver and a communication group composed of a plurality of transmitters and a plurality of receivers. Needless to say, you can.

Further, the present invention is not limited to the wireless house alarm system, and can be similarly implemented in the automatic meter reading system 400 shown in FIG. 6B and the entry system 500 shown in FIG. 6C. The automatic meter reading system 400 includes a transmission device 400A and a reception device 400B. The transmitting device 400A includes a wireless transmitter 200, a control microcomputer 31A, and a measuring device 34 that measures the amount of commercial power, gas fuel, or water used. The receiving device 400B includes the wireless receiver 100 having the wireless reception activation control device of the present invention and the control microcomputer 31B.

In the automatic meter reading system 400, when the measuring instrument 34 is operated, the transmitter 200 transmits a meter reading information signal indicating the measurement result of the measuring instrument 34 to the wireless receiver 100. The wireless receiver 100 further has a meter reading information collecting function, and when receiving a meter reading information signal, operates the meter reading information collecting function to collect meter reading information for each transmitter. The collection of meter reading information is specifically performed by the microcomputer 31B on the receiving device 400B side.

In addition, as an automatic meter reading system such as electricity, gas, or water that can be used in the present invention, a communication group including one transmitter and one receiver, or one transmitter and a plurality of receivers. System (communication group), a system comprising a plurality of transmitters and one receiver (communication group), a system comprising a plurality of transmitters and a plurality of receivers (communication group) Needless to say, it can be implemented in the same way.

The entry system 500 includes a transmission device 500A and a reception device 500B. The transmission device 500A includes an operation unit 35, an interface 36, a wireless transmitter 200, and a control microcomputer 31A. The receiving device 500B includes the wireless receiver 100 having the wireless reception activation control device of the present invention, the control microcomputer 31B, and the locking / unlocking device 37 that unlocks and locks the locking device α.

When the lock request operation or unlock request operation performed by the operator (not shown) on the operation unit 35 is notified to the control microcomputer 31A via the interface 36, the wireless transmitter 500A The wireless transmission request corresponding to the request is output to the wireless transmitter 200. The wireless transmitter 200 that has received the transmission request transmits an unlock signal or a lock signal to the wireless receiver 100. When the wireless receiver 100 receives the unlocking signal or the locking signal, the control microcomputer 31B operates the locking / unlocking machine 35 based on the received signal to perform the unlocking operation of the locking device α.

The wireless reception activation control device according to the present invention is particularly useful for battery-driven wireless communication devices because of low power consumption. Moreover, it is useful for a system in which power saving is indispensable, for example, a wireless home alarm system.

E10 Pattern determiner for other devices E11 Pattern extractor for other devices E12 Pattern setter for other devices E20 Wireless power supply controller 21 Frame synchronization boundary detector 22 Pattern buffer for other devices 23 Pattern comparator for other devices 24 Pattern for other devices Judgment device 25 Pattern setting device for other devices 100 Wireless receiver

Claims

Determining whether or not the message received via the own receiver includes a pattern addressed to another device that identifies that the message is addressed to another device communication group that does not include the own receiver. And
When the pattern determiner addressed to the other device determines that the message includes a pattern addressed to the other device, a wireless power controller that controls power saving for driving the power receiver,
With
Wireless reception activation control device.
A setter for collecting a pattern addressed to the other device via communication by the receiver of the own device, and setting a collected pattern addressed to the other device in a pattern determination device addressed to the other device,
In addition,
The setter is
Recognizing a pattern addressed to the own device specifying that it is addressed to the own device communication group including the own device receiver, and extracting a pattern included in the message that does not detect the pattern addressed to the own device as a pattern addressed to the other device A pattern extractor for other machines
A pattern setter addressed to the other device that sets the pattern addressed to the other device extracted by the pattern extractor addressed to the other device in the pattern determiner addressed to the other device;
With
The wireless reception activation control device according to claim 1.
The pattern extractor addressed to the other machine is:
A frame synchronization boundary detector for detecting a boundary between a bit synchronization pattern and a frame pattern in the message;
In addition,
The pattern extractor addressed to the other device is configured to extract a data area after the boundary is detected by the frame synchronization boundary detector as a pattern addressed to the other device.
The wireless reception activation control device according to claim 2.
The pattern setter addressed to the other device is configured to aggregate the patterns addressed to the other device extracted by the pattern extractor addressed to the other device and send the aggregated patterns to the pattern determiner addressed to the other device.
The wireless reception activation control device according to claim 2.
The communication mode performed by the own receiver is a specific low power radio.
The wireless reception activation control device according to claim 1.
Determining whether or not the message received via the own receiver includes a pattern addressed to another device that identifies that the message is addressed to another device communication group not including the own receiver And
When the pattern determination device addressed to the other device determines that the pattern includes the pattern addressed to the other device, a wireless power supply controller that performs power saving control of a power source that drives the receiver of the device;
A microcomputer for a wireless receiver comprising:
One or more transmitters, and one or more receivers having the wireless reception activation control device of claim 1,
The transmitter includes a sensor that detects an environmental change in the vicinity of the transmitter, and the transmitter is configured to transmit an alarm signal to the receiver when the sensor detects the environmental change.
The receiver further includes an alarm device that issues an alarm to the outside, and the alarm device is configured to operate when the receiver receives the alarm signal.
Wireless house alarm system.
One or more transmitters, and one or more receivers having the wireless reception activation control device of claim 1,
The transmitter further has a measurement function for measuring a usage amount of a commercial power source, gas fuel, or water. When the measurement function is activated, a meter reading information signal indicating a measurement result of the measurement function is directed to the receiver. Configured to send,
The receiver further has a meter reading information collecting function, and is configured to collect meter reading information for each transmitter by operating the meter reading information collecting function when receiving the meter reading information signal.
Automatic meter reading system.
A transmitter and a receiver having the wireless reception activation control device according to claim 1;
The transmitter has a function of generating a wireless transmission request based on an input operation via an interface, and when the transmission request generation function is operated, an unlock signal or a lock signal is transmitted to the receiver. Composed of
The receiver includes a locking / unlocking machine that unlocks and locks the locking device. When the unlocking signal or the locking signal is received, the receiver is based on the received unlocking signal or the locking signal. Configured to operate the unlocking function,
Entry system.
The locking device is a car key device;
The entry system according to claim 9.