JP7265402B2 - radio transmitter - Google Patents

Description

The present invention relates to radio transmitters.

2. Description of the Related Art Conventionally, a wireless sensor that operates using an output voltage from a battery as a power supply has been known (for example, Patent Document 1, etc.). A conventional wireless sensor including this wireless sensor has a transmitting/receiving circuit that outputs antenna power of a value corresponding to the value of the output voltage from the battery, and from the transmitting/receiving circuit to the antenna of the wireless sensor. Antenna power was supplied and a radio fire signal was output from the antenna. On the other hand, in order to comply with prescribed regulations (e.g., regulations of the Radio Law, etc.), wireless detectors are configured so that antenna power is supplied to the antenna within the standard range corresponding to the relevant regulations. I needed it.

However, in the wireless sensor, when the battery output voltage decreases, the antenna power from the transmitting/receiving circuit decreases, and when the battery output voltage increases, the antenna power from the transmitting/receiving circuit increases. change, the value of the antenna power could deviate from the reference range. Therefore, as a technique for preventing the value of the antenna power from deviating from the reference range, for example, a technique using a feedback circuit or a stabilized power supply circuit has been proposed.

In the technique using a feedback circuit, the antenna power supplied to the antenna is detected, and the detected power is used to feed back the transmission/reception circuit, thereby maintaining the antenna power at a constant value. was prevented from deviating from the reference range. In the technology using a stabilized power supply circuit, by providing a stabilized power supply circuit between the battery and the transmitting/receiving circuit, the power supply voltage of a certain value is generated by the stabilized power supply circuit based on the output voltage from the battery. By generating and supplying the generated power supply voltage to the transmitting/receiving circuit, the magnitude of the antenna power is kept constant and the value of the antenna power is prevented from deviating from the reference range.

JP 2012-234358 A

However, in the conventional technology for preventing the value of the antenna power from deviating from the reference range, the circuit configuration of the wireless sensor may become complicated or the power consumption may increase, as described below. had a nature.

That is, for example, in the conventional technology using a feedback circuit, in order to detect weak antenna power at high frequencies, a complicated circuit (for example, a pickup circuit for detecting high frequency current, or an amplifier circuit for amplifying high frequency current, etc.) ), which may complicate the circuit configuration of the wireless sensor. In addition, for example, in the conventional technology using a regulated power supply circuit, it is necessary to generate a power supply voltage at a relatively low level of the output voltage from the battery considering the possibility of fluctuation of the output voltage. There is a possibility that the efficiency will decrease and the power consumption will increase.

SUMMARY OF THE INVENTION It is an object of the present invention to simplify the circuit configuration and reduce power consumption in a wireless transmitter capable of keeping antenna power within a reference range.

In order to solve the above-mentioned problems and achieve the object, the wireless transmission device according to claim 1 transmits radio waves with an antenna power corresponding to a setting value set to itself and a power supply voltage supplied to itself. wherein the antenna power is information that associates a plurality of the power supply voltage values with a plurality of the set values at which the antenna power falls within a reference range at the plurality of power supply voltage values. Antenna power specific information storage means for storing specific information; Measuring means for measuring the power supply voltage; The antenna power specific information stored by the antenna power specific information storage means; and the power supply measured by the measuring means. setting control means for setting the set value to the radio transmission device so that the antenna power is within a reference range based on the voltage, and the antenna power specifying information storage means stores the radio transmission device. The lower limit value in the range of power supply voltage recommended to be supplied to the antenna is stored, and the lower limit value in the range of power supply voltage is such that the antenna power does not exceed the upper limit value of the reference range even if the set value is the maximum. When the power supply voltage measured by the measuring means is lower than the lower limit value in the range of power supply voltages stored in the antenna power specifying information storage means, the setting control means sets the maximum set value. set.

Further, the radio transmission device according to claim 2 is a radio transmission device that transmits radio waves with antenna power corresponding to a set value set to itself and a power supply voltage supplied to itself, wherein the plurality of power sources Antenna power specification information storage means for storing antenna power specification information, which is information that associates a voltage value with a plurality of the set values that allow the antenna power to fall within a reference range at a plurality of the power supply voltage values. a measuring means for measuring the power supply voltage, the antenna power specifying information stored in the antenna power specifying information storing means, and the power supply voltage measured by the measuring means, the antenna power being within a reference range. and setting control means for setting the setting value to the radio transmission device so that the set value is within the range of the power supply voltage recommended to be supplied to the radio transmission device. When the power supply voltage measured by the measuring means is higher than the upper limit value of the power supply voltage range stored in the antenna power specifying information storage means, the setting control means stores the upper limit value in the range. The lowest setting value is set among the plurality of setting values at which the antenna power is within the reference range at the upper limit value.

According to a third aspect of the present invention, there is provided a wireless transmission device according to the first or second aspect, wherein the wireless transmission device includes a battery that supplies the power supply voltage, and the measuring means includes a battery that supplies the power voltage. is measured as the power supply voltage.

According to the wireless transmission device of claim 1, feedback processing is performed, for example, by setting the setting value so that the antenna power is within the reference range based on the antenna power specifying information and the measured power supply voltage. This eliminates the need for a complicated circuit to detect the antenna power, and it also eliminates the need to generate a constant value of the power supply voltage, so power efficiency can be maintained. In the wireless transmission device that can be built inside, it is possible to simplify the circuit configuration and reduce the power consumption.
In addition, if the measured power supply voltage is lower than the lower limit of the power supply voltage range, and the antenna power does not exceed the upper limit of the reference range even at the maximum setting value, the maximum setting value By setting , for example, it is possible to output higher antenna power while ensuring that the antenna power does not exceed the upper limit of the reference range, so that it is possible to improve disaster prevention.

According to the wireless transmission device of claim 2, feedback processing is performed by setting the setting value so that the antenna power is within the reference range based on the antenna power specifying information and the measured power supply voltage. This eliminates the need for a complicated circuit to detect the antenna power, and it also eliminates the need to generate a constant value of the power supply voltage, so power efficiency can be maintained. In the wireless transmission device that can be built inside, it is possible to simplify the circuit configuration and reduce the power consumption.
In addition, if the measured power supply voltage is higher than the upper limit of the range of power supply voltage that is recommended to be supplied, the lowest of the multiple setting values at which the antenna power is within the reference range at the upper limit. By setting the set value, for example, it is possible to output the antenna power with a margin from the upper limit of the reference range.

According to the radio transmission device of claim 3, the radio transmission device is provided with a battery that supplies power supply voltage, and by measuring the output voltage of the battery as the power supply voltage, for example, the output voltage fluctuates relatively sharply. Even in the case of using such a battery, it is possible to simplify the circuit configuration and reduce the power consumption in a wireless transmission device capable of keeping the antenna power within the reference range. Also, for example, the power consumption of the wireless transmission device can be reduced, so the life of the battery can be extended. In addition, for example, since it is not necessary to use a commercial power source, it is possible to provide a wireless transmission device that can be installed in any position and that is excellent in workability.

It is a block diagram of a sensor according to the present embodiment. Fig. 2 is a circuit block diagram of part of the sensor; It is an example of an antenna power specific graph. It is an example of antenna power specific information. 4 is a flowchart of setting processing; It is a flow chart of fire alarm processing.

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of a wireless transmission device according to the present invention will be described in detail below with reference to the drawings. In addition, this invention is not limited by this embodiment.

[Basic concept of the embodiment]
First, the basic concept of the embodiment will be explained. Embodiments generally relate to wireless transmission devices.

Here, the "radio transmitter" is a transmitter for transmitting radio waves, and more specifically, transmits radio waves with an antenna power corresponding to a set value set to itself and a power supply voltage supplied to itself. For example, it is a concept that includes disaster prevention-related devices, disaster prevention-unrelated devices, and the like.

First, "disaster prevention-related device" is a device used for the purpose of disaster prevention, and is a concept including, for example, detectors and repeaters. In addition, the "sensor" is a device that determines an abnormality in the monitored area. For example, concepts include smoke detectors, heat detectors, fire detectors, and gas leak detectors. In addition, the "monitoring area" is an area to be monitored by the sensor, and specifically, a space with a certain extent, an indoor or outdoor space, for example, This concept includes spaces such as corridors, stairs, and rooms in buildings. In addition, "detection target" is a target to be detected by a sensor, specifically related to abnormalities in the monitored area, for example, smoke, heat, flame, and toxic gases such as carbon monoxide It is a concept that includes A “relay device” is a device that relays a signal. For example, it is a concept that includes a device that relays a fire occurrence signal, which is a signal that identifies the occurrence of a fire between a detector and a disaster prevention receiver. be. "Disaster prevention-unrelated device" is a device used for purposes other than disaster prevention, and is a concept including, for example, mobile terminals such as mobile phones or tablet terminals, or stationary computers.

Further, the "set value" is a value set in the radio transmission device, specifically, a value set to determine the value of the antenna power of the radio transmission device. It is a value corresponding to a considerable amount. In addition, the "power supply voltage" is the voltage supplied to the power supply voltage to operate the wireless transmission device, specifically, the voltage supplied from the power supply, for example, supplied from a battery as a power supply. It is a concept that includes the voltage supplied from a commercial power supply as a power supply. Further, "antenna power" is power for outputting radio waves from a wireless transmission device, and specifically power supplied to an antenna of the wireless transmission device. Further, "radio wave" is an electromagnetic wave used for wireless communication and the like, and more specifically, it is transmitted from a wireless transmission device with power corresponding to antenna power.

In the embodiments described below, the "radio transmitter" is the "fire detector", the "monitored area" is the "room of the building", and the "detection target" is "smoke (specifically, smoke particles)” and the “power supply voltage” is the “voltage supplied from the battery as the power supply”.

(composition)
First, the configuration of the sensor according to this embodiment will be described. FIG. 1 is a block diagram of a sensor according to this embodiment, and FIG. 2 is a circuit block diagram of part of the sensor. FIG. 2 shows a schematic example of an electric circuit having a configuration that is particularly characteristic of the sensor 100. Electric circuits having configurations other than those shown in FIG. , and that any circuit including a known electric circuit can be applied.

The sensor 100 shown in FIG. 1 is a wireless transmission device, and more specifically, a device that determines a fire by detecting smoke, which is a detection target in a monitoring area. It operates with a power supply voltage, and includes, for example, a power supply unit 11 , a detection unit 12 , an alarm unit 13 , a communication unit 14 , a recording unit 15 and a control unit 16 .

(Configuration - power supply)
The power supply unit 11 in FIG. 1 is supply means for supplying power supply voltage to the sensor 100 . Although the specific type and configuration of the power supply unit 11 are arbitrary, for example, the power supply unit 11 can be configured to include the battery 111 shown in FIG. A battery 111 supplies a power supply voltage to operate the sensor 100, and is an arbitrary battery such as a lithium battery.

(Construction-Detector)
The detection unit 12 in FIG. 1 is detection means for detecting the concentration of smoke in the monitoring area. Although the specific type and configuration of the detection unit 12 are arbitrary, for example, the detection unit 12 can be of a scattered light type and can be configured to include a light emitting unit and a light receiving unit (not shown).

(Configuration - alarm unit)
The alarm unit 13 in FIG. 1 is alarm means for outputting an alarm when the sensor 100 determines fire. Although the specific type and configuration of the alarm unit 13 are arbitrary, for example, it is provided with a speaker (not shown) that outputs an alarm by voice, or an indicator lamp (not shown) that outputs an alarm by light emission display. is.

(Configuration - communication unit)
The communication unit 14 in FIG. 1 is communication means for transmitting radio waves. Although the specific type and configuration of the communication unit 14 are arbitrary, for example, the antenna 141 shown in FIG. 2 can be included in the configuration. The antenna 141 outputs radio waves, and for example, outputs radio waves of power corresponding to the antenna power supplied thereto.

(Configuration - recording unit)
The recording unit 15 in FIG. 1 is recording means for recording programs and various data necessary for the operation of the sensor 100, and is particularly antenna power specific information storage means for storing antenna power specific information. It is configured using a hard disk (not shown) as a recording device. However, instead of or together with hard disks, magnetic recording media such as magnetic disks, optical recording media such as DVDs and Blu-ray discs, or electrical recording media such as Flash, ROM, USB memory, SD cards, etc. any recording medium can be used.

Also, the recording unit 15 stores, for example, a fire determination threshold value and antenna power specifying information. The "fire determination threshold" is a threshold used to determine whether a fire has occurred in the monitoring area, and is compared with the concentration of smoke detected by the detector 12 in FIG. As for the fire determination threshold, it is assumed that "10 (%/m)" is input and stored as an example using an input means (not shown).

Further, the "antenna power specifying information" is information that associates a plurality of power supply voltage values with a plurality of set values that allow the antenna power to fall within a reference range at the plurality of power supply voltage values. It is information that identifies a plurality of set values and a plurality of antenna power values corresponding to the plurality of set values by a plurality of power supply voltage values. be. The "reference range" is a range that serves as a reference for the antenna power to be supplied, and more specifically, is a range of antenna power that is allowed to be supplied. Although this reference range can be set arbitrarily, here, for example, based on a predetermined law (for example, the Radio Law or regulations related to the law), it corresponds to the power of the radio wave to be output. Based on the reference value, a value that is 20% higher than the reference value is set as the reference upper limit (upper limit), and a value that is lower than the reference value by 50% of the reference value is set as the reference lower limit. As the value (lower limit), a range from the reference lower limit value to less than the reference upper limit value is used. Specifically, here, for example, the reference value is 10.0 (mW), and the reference range is the reference lower limit value of 5.0 (mW) or more to the reference upper limit value of 12.0 (mW) or less. We will use

FIG. 3 is an example of an antenna power specific graph. It should be noted that numerical values specifically described in FIG. 3 are described for convenience of explanation (the same applies to FIG. 4). An "antenna power specific graph" is a graph that specifies a plurality of set values and a plurality of antenna power values corresponding to the plurality of set values by a plurality of power supply voltage values. 3 is a graph defined by design specifications, actual measurements, or the like for an electric circuit (for example, a wireless IC (Integrated Circuit) 16a described later in FIG. 2). In this antenna power specific graph, the vertical axis indicates the value of the magnitude of the antenna power, and the horizontal axis indicates the set value. , and specifies the register value to be set in the register of the wireless IC 16a in decimal numbers. This indicates that the value of the current output from the wireless IC 16a (that is, the value of the antenna power) increases as the number increases. Also, as shown in FIG. 3, the antenna power specific graph is provided to the wireless IC 16a by, for example, plotting a setting value set in the wireless IC 16a and a plot of the antenna power value when the setting value is set. Specifically, it includes a first antenna power specific curve L1, a second antenna power specific curve L2, and a third antenna power specific curve L3.

Regarding the wireless IC 16a, based on the specifications of the wireless IC 16a, the range is from the lower limit operating voltage (for example, 2.0 (V)) to the upper limit operating voltage (for example, 3.4 (V)). It is recommended to supply a power supply voltage within the operating voltage range (range of power supply voltage) to operate the radio IC 16a. shows the setting value set in the wireless IC 16a and the value of the antenna power supplied from the wireless IC 16a to the antenna 141 when the setting value is set when the power supply voltage of the second antenna is supplied. The power specific curve L2 and the third antenna power specific curve L3 are 2.8 (V), which is the voltage between the lower limit operating voltage and the upper limit operating voltage, and 3.4 (V), which is the upper limit operating voltage, to the wireless IC 16a. shows the set value and the value of the antenna power when the power supply voltage of . In particular, it is desirable that the lower limit operating voltage (for example, 2.0 (V)) is set so low that the antenna power does not exceed the upper limit of the reference range even when the set value is maximized. will be described with an example.

FIG. 4 is an example of antenna power specifying information. In this embodiment, it is assumed that the antenna power specifying information shown in FIG. 4 is stored in the recording unit 15 shown in FIG. The antenna power specifying information is configured by, for example, mutually associating the item "power supply voltage information", the item "setting value information", the item "antenna power information", and the information corresponding to each item. Here, the information corresponding to the item "power supply voltage information" is the power supply voltage information specifying the value of the power supply voltage supplied to the wireless IC 16a (in FIG. 4, the unit is V, such as "2.0"). . The information corresponding to the item "set value information" is set value information specifying the set value set in the wireless IC 16a (in FIG. 4, the decimal register value corresponding to the horizontal axis in FIG. 3). "5" etc.). The item "antenna power information" is antenna power information specifying the value of the antenna power output by the wireless IC 16a (in FIG. 4, the unit is mW, "5.5", etc.). It is assumed that each piece of information is stored using input means (not shown) based on the design specifications or actual measurements of the electric circuit (for example, the wireless IC 16a) mounted on the sensor 100. FIG.

(Configuration - control unit)
The control unit 16 in FIG. 1 is control means for controlling the sensor 100. Specifically, various programs (basic control programs such as an OS, a basic control program such as an OS, and (including an application program that is activated by the computer and implements a specific function), and an internal memory such as a RAM for storing programs and various data. In particular, the control program according to the embodiment substantially configures each section of the control section 16 by being installed in the sensor 100 via any recording medium or network.

The control unit 16 functionally and conceptually includes a measurement unit 161 and a setting control unit 162 . The measuring unit 161 is measuring means for measuring the power supply voltage. Further, the setting control unit 162 sets the sensor 100 so that the antenna power is within the reference range based on the antenna power specifying information stored in the recording unit 15 and the power supply voltage measured by the measuring unit 161. Setting control means for setting values. Although the implementation method of each of these means is arbitrary, for example, they are implemented as at least part of the functions of the wireless IC 16a in FIG.

(Configuration - control section - wireless IC)
The wireless IC 16a is output control means for performing various controls related to the output of radio waves. It operates by a power supply voltage, and outputs antenna power of a value corresponding to the value of the power supply voltage supplied to itself and the setting value set to itself. It has a voltage measurement terminal T2, an antenna power output terminal T3, the measurement section 161 described above, and a setting control section 162. FIG. An arbitrary buffer circuit (for example, an arbitrary circuit such as a diode, a resistor, a capacitor, and an amplifier) may be provided around the wireless IC 16a. omitted.

The power terminal T1 is a terminal to which a power supply voltage (that is, electric power) output from the battery 111 is supplied, and is electrically connected to the battery 111, for example. Also, the voltage measurement terminal T2 is a terminal for measuring the output voltage of the battery 111 (that is, the power supply voltage), and is electrically connected between the power supply terminal T1 and the battery 111, for example. . The antenna power output terminal T3 is a terminal for outputting antenna power, and is electrically connected to the antenna 141, for example. The measurement unit 161 is the above-described measurement means, and measures the voltage supplied to the voltage measurement terminal T2, for example. The setting control unit 162 is the above-described setting control means, and sets a setting value in the wireless IC 16a so that, for example, the antenna power is within the reference range. Note that "setting a setting value in the wireless IC 16a so that the antenna power is within the reference range" includes, for example, setting the antenna power within the reference range by setting a setting value in the wireless IC 16a. It is a concept. It is assumed that the antenna power does not fall within the reference range regardless of which set value is set due to the specifications of the wireless IC 16a and the environment in which the wireless IC 16a is used (for example, the value of the supplied power supply voltage). However, in such a case, for "set the setting value in the wireless IC 16a so that the antenna power is within the reference range", for example, set the wireless IC 16a to a setting value that makes the antenna power closest to the reference range. It may be interpreted as a concept indicating Processing performed by each unit of the control unit 16 will be described later.

(process)
The processing performed by the sensor 100 of FIG. 1 configured in this manner will now be described. Specifically, setting processing and fire alarm processing will be described.

(processing - setting processing)
FIG. 5 is a flowchart of setting processing. A “setting process” is a process of setting a set value in the sensor 100 . The timing for executing this setting process is arbitrary, but for example, after turning on the power of the sensor 100, the repeated execution will be started, and the description will be made after the start of execution (the same applies to the fire alarm process).

First, as shown in FIG. 5, the measurement unit 161 measures the power supply voltage at SA1. Although the specific method is arbitrary, for example, the measurement unit 161 is provided with an arbitrary voltage measurement circuit, and using this voltage measurement circuit, the voltage supplied to the voltage measurement terminal T2 in FIG. , the output voltage of the battery 111). Here, for example, 2.4 (V) is measured as the power supply voltage.

Returning to FIG. 5, at SA2, the setting control unit 162 determines whether or not the operating voltage range is exceeded. Although any specific method can be used, for example, it is assumed that the operating voltage range of the wireless IC 16a in FIG. The power supply voltage measured in SA1 is acquired, and it is determined whether or not the acquired power supply voltage deviates from the recorded operating voltage range of the wireless IC 16a. Then, if the power supply voltage measured at SA1 is less than the lower limit operating voltage (eg, 2.0 (V)) or greater than the upper limit operating voltage (eg, 3.4 (V)), the power supply voltage measured at SA1 deviates from the operating voltage range (YES in SA2), and proceeds to SA3. If the power supply voltage measured at SA1 is between the lower limit operating voltage and the upper limit operating voltage, it is determined that the power supply voltage measured at SA1 does not deviate from the operating voltage range (NO at SA2), and the process proceeds to SA4. Transition. Here, for example, when the power supply voltage measured at SA1 is 2.4 (V), it is determined that the power supply voltage measured at SA1 does not deviate from the operating voltage range.

Returning to FIG. 5, at SA3, the setting control unit 162 warns of deviation from the operating voltage range. A specific method is arbitrary, but for example, an alarm is output via a speaker and an indicator lamp (not shown) of the alarm unit 13 in FIG. Here, for example, a warning voice saying "Power supply voltage is abnormal. Please check around the battery when inspecting" is output through the speaker, and by blinking the indicator light, the operating voltage range is deviated. output an alarm specifying that the

Returning to FIG. 5, after determining that the voltage does not deviate from the operating voltage range in the determination of SA2 (NO in SA2), the setting control unit 162 determines the set value in SA4. Any specific method may be used. Determine the value of the antenna power to be within the reference range. More specifically, focusing on the fact that the antenna power specification graph in FIG. 3 can be drawn based on each information in FIG. 4, furthermore, since the power supply voltage is within the operating voltage range, Focusing on the point that the relationship between the set value and the antenna power is specified by the area surrounded by the first antenna power specifying curve L1 and the third antenna power specifying curve L3 in FIG. 3, the value of the antenna power is within the reference range Determined to be Here, for example, when the power supply voltage measured at SA1 is 2.4 (V), the first antenna power specific curve L1 and the second antenna power specific curve L1 and the second In the region between the antenna power specific curves L2, the first antenna power specific curve L1 with the lower power supply voltage is equal to or higher than the reference lower limit value of the reference range, and the second antenna power specific curve L2 with the higher power supply voltage to obtain "5" to "9" as setting values that are less than the reference upper limit value of the reference range, and one of the obtained setting values of "5" to "9" is set by an arbitrary method (here, more A method of specifying a higher (larger) setting value is used in consideration of reliably performing wireless transmission), and the specified setting value "9" is determined.

Returning to FIG. 5, at SA5, the setting control unit 162 sets the setting value. Although the specific method is arbitrary, the setting value determined in SA4 is acquired, and the acquired setting value is set in the register of the wireless IC 16a. Here, for example, "9" is set. This completes the setting process.

(Processing - Fire Alarm Processing)
FIG. 6 is a flowchart of fire alarm processing. The "fire alarm process" is a process of issuing a fire alarm, specifically, at least a process of outputting a fire radio signal, which is a radio signal for alarming the occurrence of a fire, For example, it is a process that is executed after the setting process is executed at least once.

First, as shown in FIG. 6, at SB1, the control unit 16 determines whether or not a fire has occurred. Although any specific method can be used, for example, the concentration of smoke detected by the detection unit 12 in FIG. and make a decision based on the comparison result. Specifically, when the density of the acquired smoke is less than the fire determination threshold, it is determined that no fire has occurred (NO in SB1), and SB1 is repeated until it is determined that a fire has occurred. Execute. If the obtained density of smoke is equal to or higher than the fire determination threshold value, it is determined that a fire has occurred (YES at SB1), and the process proceeds to SB2. Here, for example, when the acquired density of smoke is "15", the fire determination threshold is "10", so it is determined that a fire has occurred.

Returning to FIG. 6, at SB2, the control unit 16 issues a fire alarm. A specific method is arbitrary, but for example, an alarm is output via a speaker and an indicator lamp (not shown) of the alarm unit 13 in FIG. Here, for example, an alarm sound such as "Woo, woo, a fire has broken out" is output through a speaker, and an indicator lamp is turned on to start outputting an alarm specifying the occurrence of a fire.

Returning to FIG. 6, at SB3, the setting control unit 162 outputs a fire occurrence radio signal. Here, the "fire occurrence radio signal" is a radio signal (that is, radio wave) that specifies the occurrence of a fire. Specifically, it is a radio signal output from the sensor 100. to a disaster prevention receiver (not shown) directly or indirectly. Although any specific method can be used, for example, the setting control unit 162 in FIG. Supplying the corresponding antenna power to the antenna 141 initiates the output of the fire outbreak radio signal. Here, for example, when the power supply voltage output from the battery 111 is 2.4 (V) and "9" is set in SA5, 8.0 (mW) and 11.6 (mW) in FIG. ), that is, the antenna power within the reference range is supplied to output the fire occurrence radio signal.

If it is repeatedly determined that there is a deviation (YES in SA2) at SA2 in FIG. Although there is a possibility, from the viewpoint of improving disaster prevention, etc., if the setting value is not set in SA5, the following processing is performed.

First, the setting control unit 162 acquires the value of the power supply voltage most recently measured in SA1 of FIG. These obtained results are compared with each other. Then, if the acquired power supply voltage value is less than the lower limit operating voltage value ("2.0" V in FIG. 3), the maximum set value (for example, the set value shown in FIG. 3) is set at SB3. ("1" to "17") are set to "17") to output the fire occurrence radio signal. In addition, when the acquired power supply voltage value is larger (higher) than the upper limit operating voltage value (“3.4” V in FIG. 3), a plurality of set values ( That is, in FIG. 3, "2", which is the lowest setting value among "2" to "6"), is specified, and the specified "2" is set as the setting value to output the fire occurrence radio signal. and

Returning to FIG. 6, at SB4, the control unit 16 determines whether or not to restore. A specific method is arbitrary, but for example, determination is made based on whether or not a predetermined restoration operation has been performed on the sensor 100 . If the predetermined recovery operation has not been performed, it is determined that recovery is not to be performed (NO in SB4), and SB4 is repeatedly executed until it is determined that recovery is to be performed. Also, if a predetermined restoration operation has been performed, it is determined that restoration is to be performed (YES at SB4), and the process proceeds to SB5.

Next, at SB5, the control unit 16 performs restoration. Although the specific method is arbitrary, for example, the output of the alarm started at SB2 and the fire occurrence radio signal started at SB3 are stopped and restored. This completes the fire alarm process.

(Effect of Embodiment)
As described above, according to the present embodiment, by setting the set value so that the antenna power is within the reference range based on the antenna power specifying information and the measured power supply voltage, for example, feedback processing can be performed. Since there is no need for a complicated circuit to detect the antenna power, power efficiency can be maintained because there is no need to generate a constant supply voltage, so the antenna power can be controlled within the reference range. In the sensor 100 that can do so, it is possible to simplify the circuit configuration and reduce power consumption.

In addition, the sensor 100 is provided with a battery 111 that supplies power supply voltage, and by measuring the output voltage of the battery 111 as the power supply voltage, for example, even when the battery 111 whose output voltage fluctuates relatively sharply is used, In the sensor 100 that can keep the antenna power within the reference range, the circuit configuration can be simplified and the power consumption can be reduced. Also, for example, the power consumption of the sensor 100 can be reduced, so the life of the battery 111 can be extended. In addition, for example, since it is not necessary to use a commercial power source, it is possible to provide the sensor 100 that can be installed in any position and has excellent workability without a wired connection.

In addition, if the measured power supply voltage is lower than the lower limit of the power supply voltage range, and the antenna power does not exceed the upper limit of the reference range even at the maximum setting value, the maximum setting value By setting , for example, it is possible to output higher antenna power while ensuring that the antenna power does not exceed the upper limit of the reference range, so that it is possible to improve disaster prevention.

In addition, if the measured power supply voltage is higher than the upper limit of the range of power supply voltage that is recommended to be supplied, the lowest of the multiple setting values at which the antenna power is within the reference range at the upper limit. By setting the set value, for example, it is possible to output the antenna power with a margin from the upper limit of the reference range.

[Modification to Embodiment]
Although the embodiments according to the present invention have been described above, the specific configuration and means of the present invention can be arbitrarily modified and improved within the scope of the technical ideas of each invention described in the claims. can be done. Such modifications will be described below.

(Problem to be solved and effect of invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the contents described above, and may differ depending on the details of the implementation environment and configuration of the invention. or only part of the effects described above.

(Regarding decentralization and integration)
Moreover, the configuration described above is functionally conceptual, and does not necessarily have to be physically configured as illustrated. That is, the specific form of distribution or integration of each part is not limited to the illustrated one, and all or part of them can be functionally or physically distributed or integrated in arbitrary units.

(Regarding the setting process (Part 1))
Also, after SA3 in FIG. 5 of the above-described embodiment, the process may be shifted to SA4 without ending the process. In SA4 in this case, the amount of deviation of the power supply voltage from the lower limit operating voltage (eg, 2.0 (V) in FIG. 3) or the upper limit operating voltage (eg, 3.4 (V) in FIG. 3) is considered. Then, the setting value may be determined so that the antenna power is within the reference range or close to the reference range, and the setting value may be set at SA5.

(Regarding the setting process (Part 2))
Also, in order to determine the setting value in SA4 of FIG. A correction means (correction value or correction formula) for obtaining the relationship between the set value information and the antenna power information between the .4" is stored in the recording unit 15, and the stored correction means is used may be used to determine the set value.

(About the circuit block (part 1))
Further, the circuit blocks of the above embodiments may be changed arbitrarily. For example, the wireless IC 16a may omit the voltage measurement terminal T2 and measure the power supply voltage at the power supply terminal T1 side.

(Regarding the circuit block (part 2))
Further, all the functions for controlling the sensor 100 may be implemented in the wireless IC 16a of FIG. 2 of the above embodiment, or at least one of the measurement unit 161 and the setting control unit 162 may be implemented in the wireless IC 16a. may be implemented in a circuit different from

(Regarding antenna power identification information (part 1))
Further, regarding the antenna power specifying information of the above-described embodiment, for each range of a plurality of power supply voltage values, a plurality of set values that allow the antenna power to fall within the reference range at a plurality of power supply voltage values can be set at the time of shipment. may be stored as the antenna power specifying information.

(Regarding antenna power identification information (part 2))
Further, in the above-described embodiment, as the antenna power specifying information of the recording unit 15, as shown in FIG. 4, a case has been described in which three pieces of power supply voltage information are stored, but the present invention is not limited to this. For example, the voltage resolution between the lower limit operating voltage and the upper limit operating voltage may be improved and four or more may be stored, or "2.8" may be omitted and two may be stored. In particular, in FIG. 4, when four or more pieces of power supply voltage information are stored as the antenna power specifying information, the information closest to the power supply voltage measured at SA1 is used when determining the set value at SA4 in FIG. to determine the setting value.

(Regarding antenna power identification information (Part 3))
In the above-described embodiment, the antenna power specifying information in the recording unit 15 corresponds to the antenna power specifying graph of FIG. 3 regardless of whether the antenna power is within the reference range, as shown in FIG. Although the case of storing each piece of information has been described, the present invention is not limited to this. For example, only the information corresponding to the antenna power within the reference range may be stored as each information in FIG. 4, and each process may be performed using this information. In other words, as long as it is information that associates a plurality of power supply voltage values with a plurality of setting values that make the antenna power within the reference range at the plurality of power supply voltage values, arbitrary information is stored and processed. good too.

(Regarding antenna power identification information (part 4))
Further, in the above-described embodiment, a case has been described in which table information is stored as the antenna power specifying information in the recording unit 15, but the present invention is not limited to this. For example, along with the table information or instead of the table information, arbitrary information such as mathematical formula information specifying a formula corresponding to the antenna power specific graph in FIG. 3 or image information specifying an image of the antenna power specific graph It may be stored as power specific information and each process may be performed using this information.

(For other information)
Further, the recording unit 15 of the above embodiment stores the maximum value of the power supply voltage that does not exceed the upper limit value of the reference range even if the setting value is the maximum, and the setting control unit 162 stores the maximum value of the power supply voltage If the power supply voltage measured by the measuring unit 161 is lower than the maximum value stored in 15, the maximum set value may be set. Here, for example, a plurality of power supply voltages lower than the reference upper limit value of 12.0 (mW) at the maximum setting value “17” in FIG. is 2.07 (V), which is slightly higher than 2.0 (V) corresponding to the first antenna power specific curve L1 in FIG. When the power supply voltage measured by the measuring unit 161 is lower than "2.07" V, the maximum setting value "17" is set. With this configuration, if the measured power supply voltage is lower than the maximum value of the power supply voltages at which the antenna power does not exceed the upper limit of the reference range even at the maximum set value, the maximum set value is set. By doing so, for example, higher antenna power can be output, so that disaster prevention can be improved.

(About features)
Moreover, the features of the above embodiment and the features of the modifications may be combined arbitrarily.

(Appendix)
The wireless transmission device of Supplementary Note 1 is a wireless transmission device that transmits radio waves with an antenna power corresponding to a set value set to itself and a power supply voltage supplied to itself, wherein a plurality of power supply voltage values; Antenna power specification information storage means for storing antenna power specification information that is information that associates a plurality of the set values with which the antenna power is within a reference range at a plurality of the power supply voltage values, and storing the power supply voltage. Based on the measuring means for measuring, the antenna power specifying information stored in the antenna power specifying information storing means, and the power supply voltage measured by the measuring means, the antenna power is adjusted to be within a reference range. and setting control means for setting the setting value to the wireless transmission device.

Further, the radio transmitting device according to appendix 2 is the radio transmitting device according to appendix 1, wherein the radio transmitting device includes a battery that supplies the power supply voltage, and the measuring unit measures the output voltage of the battery to the power supply. Measured as voltage.

Further, the radio transmitting apparatus according to appendix 3 is the radio transmitting apparatus according to appendix 1 or 2, wherein the antenna power specifying information storage means is the power supply voltage recommended to be supplied to the radio transmitting apparatus. A lower limit value in the range is stored, and the lower limit value in the power supply voltage range is a value such that the antenna power does not exceed the upper limit value of the reference range even if the set value is maximized, and the setting control means is configured to store the antenna power When the power supply voltage measured by the measuring means is lower than the lower limit value in the range of power supply voltages stored in the specific information storage means, the maximum set value is set.

The radio transmission device of appendix 4 is the radio transmission device according to any one of appendices 1 to 3, wherein the antenna power specifying information storage means is the power supply voltage recommended to be supplied to the radio transmission device. When the power supply voltage measured by the measuring means is higher than the upper limit value of the power supply voltage range stored in the antenna power specifying information storage means, The lowest setting value is set among the plurality of setting values at which the antenna power is within the reference range at the upper limit value.

(Effect of Supplementary Note)
According to the wireless transmission device according to appendix 1, feedback processing is performed, for example, by setting a set value so that the antenna power is within the reference range based on the antenna power specifying information and the measured power supply voltage. Since there is no need for a complicated circuit for detecting the antenna power, power efficiency can be maintained because there is no need to generate a constant value of the power supply voltage, so the antenna power can be detected within the reference range. It is possible to simplify the circuit configuration and reduce the power consumption in the wireless transmission device capable of

According to the radio transmission device described in appendix 2, the radio transmission device includes a battery that supplies power supply voltage, and by measuring the output voltage of the battery as the power supply voltage, for example, the output voltage fluctuates relatively sharply. Even when a battery is used, it is possible to simplify the circuit configuration and reduce the power consumption in a wireless transmission device that can keep the antenna power within the reference range. Also, for example, the power consumption of the wireless transmission device can be reduced, so the life of the battery can be extended. In addition, for example, since it is not necessary to use a commercial power source, it is possible to provide a wireless transmission device that can be installed in any position and that is excellent in workability.

According to the wireless transmission device described in appendix 3, the lower limit value in the range of the power supply voltage, which is the lower limit value at which the antenna power does not exceed the upper limit value of the reference range even if the set value is set to the maximum, is measured. When the power supply voltage is low, by setting the maximum set value, for example, it is possible to output higher antenna power while ensuring that the antenna power does not exceed the upper limit of the standard range, improving disaster prevention. It is possible to

According to the wireless transmission device described in appendix 4, when the measured power supply voltage is higher than the upper limit value in the range of power supply voltage that is recommended to be supplied, the antenna power is within the reference range at the upper limit value. By setting the lowest setting value among the plurality of setting values, for example, it is possible to output the antenna power with a margin between it and the upper limit value of the reference range.

REFERENCE SIGNS LIST 11 power supply unit 12 detection unit 13 alarm unit 14 communication unit 15 recording unit 16 control unit 16a wireless IC
100 sensor 111 battery 141 antenna 161 measurement unit 162 setting control unit L1 first antenna power specific curve L2 second antenna power specific curve L3 third antenna power specific curve T1 power supply terminal T2 voltage measurement terminal T3 antenna power output terminal

Claims (3)

A wireless transmission device that transmits radio waves with an antenna power corresponding to a set value set to itself and a power supply voltage supplied to itself,
Antenna power specification storing antenna power specification information, which is information associating a plurality of power supply voltage values with a plurality of set values at which the antenna power falls within a reference range at the plurality of power supply voltage values. information storage means;
measuring means for measuring the power supply voltage;
Based on the antenna power specifying information stored in the antenna power specifying information storage means and the power supply voltage measured by the measuring means, the radio transmitting apparatus is configured so that the antenna power is within a reference range. setting control means for setting a setting value;
with
the antenna power identification information storage means stores a lower limit value in the range of the power supply voltage recommended to be supplied to the radio transmission device;
The lower limit value in the range of the power supply voltage is a value such that the antenna power does not exceed the upper limit value of the reference range even if the set value is the maximum,
The setting control means sets the maximum set value when the power supply voltage measured by the measuring means is lower than the lower limit value in the range of the power supply voltage stored in the antenna power specifying information storage means.
radio transmitter. A wireless transmission device that transmits radio waves with an antenna power corresponding to a set value set to itself and a power supply voltage supplied to itself,
Antenna power specification storing antenna power specification information, which is information associating a plurality of power supply voltage values with a plurality of set values at which the antenna power falls within a reference range at the plurality of power supply voltage values. information storage means;
measuring means for measuring the power supply voltage;
Based on the antenna power specifying information stored in the antenna power specifying information storage means and the power supply voltage measured by the measuring means, the radio transmitting apparatus is configured so that the antenna power is within a reference range. setting control means for setting a setting value;
with
The antenna power identification information storage means stores an upper limit value in the range of the power supply voltage recommended to be supplied to the radio transmission device,
When the power supply voltage measured by the measuring means is higher than the upper limit value in the power supply voltage range stored in the antenna power specifying information storage means, the setting control means sets the antenna power as a reference at the upper limit value. setting the lowest setting value among the plurality of setting values within the range;
radio transmitter. The wireless transmission device comprises a battery that supplies the power supply voltage,
The measuring means measures the output voltage of the battery as the power supply voltage,
The radio transmission device according to claim 1 or 2 .

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