JP2003158462A - Wireless receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To clarify how much margin a signal from a wireless sensor has to noise radio waves. SOLUTION: A filter 10 to a filter 16 reduces a signal from an antenna 4 into a prescribed intermediate frequency. In a test mode, a control circuit 19 calculates a receiving strength level at that time when the control circuit 19 receives a signal from the wireless sensor, and calculates the receiving strength level of noise radio waves if not so. If the control circuit 19 decides that the signal is received from the wireless sensor, the control circuit 19 displays at least the receiving strength level of the signal from the wireless sensor, and an index of an S/N ratio calculated on the basis of the receiving strength level of the signal from the wireless sensor and the receiving strength level of the noise radio waves.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio receiver, and more particularly, to a radio receiver that compares a reception level of a regular signal with a noise level and displays an amount serving as an index of S / N ratio. Regarding the device.

[0002]

2. Description of the Related Art In a security system, various sensors and signals from these sensors are received to perform security processing, and when it is judged that an abnormal situation has occurred, a predetermined center such as a security center of a security company is provided. Although it is equipped with a device for reporting to a location, in recent years, a wireless sensor that wirelessly transmits a signal has come to be used as a sensor because of the ease of installation work and the like.

FIG. 7 shows a schematic configuration example of a security system using such a wireless sensor. In FIG.
1 is a wireless sensor, 2 is a wireless sensor antenna, 3 is a wireless receiver, 4 is a wireless receiver antenna,
Reference numeral 5 indicates a telephone line.

The wireless sensor 1 is installed at an appropriate location in the area to be guarded. Here, the wireless sensor 1 may be a wireless heat ray sensor, a wireless fire sensor, or any other wireless sensor. In short, as the wireless sensor 1, a wireless sensor that detects a predetermined state can be used.

Here, the detection of a predetermined state means, for example, that a wireless heat ray sensor detects that the intensity of heat rays has changed by a predetermined amount or more, and that a wireless fire sensor causes smoke. It is to detect that the amount or the temperature has exceeded a predetermined level. The same applies to other wireless sensors.

When the wireless sensor 1 detects a predetermined state, it wirelessly transmits a signal indicating that the predetermined state has been detected. This is what is called alerting in the field. Further, when the wireless sensor 1 is set to make a periodical notification at predetermined time intervals for the purpose of confirming whether the wireless sensor 1 is operating normally, the wireless sensor 1 will be at the time to make the periodical notification. , Wirelessly transmits a signal indicating that it is a periodical notification. Further, although the wireless sensor 1 is operated by using a battery as a power source, the battery voltage is monitored inside the wireless sensor 1, and when the voltage becomes equal to or lower than a predetermined voltage, a signal indicating that the battery voltage has dropped is wirelessly transmitted. Some also send. The signal transmitted by the wireless sensor 1 is an encoded code, which is digitally modulated by a predetermined modulation method and wirelessly transmitted.

There are various types of signals transmitted by the wireless sensor 1, and an example thereof is shown in FIG. In the form shown in FIG. 8, the bit synchronization signal is arranged at the beginning, the frame synchronization signal is arranged next, and then the ID number is arranged,
Security data is placed next, and a check bit is added at the end.

Here, the ID number is a unique number assigned to the wireless sensor 1, and when transmitting a signal indicating that a predetermined state has been detected, the security data indicates that fact. A code is written, and in the case of regular notification, a code indicating that it is a regular notification is written. The same applies to other cases, and a code corresponding to the content to be transmitted is written in this security data.
The check bit is a bit used for error correction or parity check performed on the wireless reception device 3 side.

Then, the bit synchronization signal, the frame synchronization signal, the ID in the signal transmitted from the wireless sensor 1
The bit lengths of the number, security data, and check bits are predetermined. That is, the total data length of the signal transmitted from the wireless sensor 1 is fixedly determined in advance, and therefore the time required to transmit the signal is also determined.

As described above, the form of the signal transmitted from the wireless sensor 1 is various, but what is important here is that the total data length of the transmitted signal is fixedly determined. .

Since the wireless sensor as described above is well known, detailed description thereof will be omitted. Further, here, it is assumed that the form of the signal transmitted from the wireless sensor 1 is as shown in FIG.

The signal wirelessly transmitted from the wireless sensor 1 is received by the wireless receiver 3, and the operation in that case is as follows. The ID number assigned to the wireless sensor 1 is registered in the wireless reception device 3, and the
Radio waves in the specified frequency band are being received. Then, when the signal is transmitted from the wireless sensor 1, the wireless reception device 3 receives all data from the bit synchronization signal to the check bit and performs error correction or parity check using the check bit, Further, it is determined whether or not the received ID number is registered, and when it is determined that the ID number is registered, it is determined that the received signal is a regular signal transmitted from the wireless sensor 1 for the first time.

Therefore, strictly speaking, the timing at which the radio receiving apparatus 3 judges that the received signal is the normal signal from the wireless sensor 1 is strictly as shown in FIG. After a certain finite time △
After t. This time Δt is generally a very short time, although it depends on the capability of the CPU used as the control device of the wireless reception device 3 and the like.

When it is determined that the regular signal from the wireless sensor 1 is received, the radio receiving device 3 executes a predetermined security process based on the signal.
Although this security processing is well known, for example, when it is determined that an abnormality has occurred, the center device (not shown) of the security company is notified via the telephone line 5 that an abnormal situation has occurred. . In addition, when there is a periodic notification, the wireless reception device 3 can recognize that the wireless sensor 1 is operating normally. Further, when the battery voltage drops, the center device is notified via the telephone line 5 that the battery voltage of the wireless sensor 1 has dropped. By this notification, the security company can know that it is time to replace the battery of the wireless sensor 1.

Although only one wireless sensor 1 is shown in FIG. 7, this is shown as a representative in order not to complicate the drawing, and a plurality of wireless sensors are actually installed. It is often the case. A unique ID number is set for each wireless sensor.

[0016]

By the way, in the case of constructing a security system using the above-mentioned wireless sensor, the wireless sensor 1 and the wireless receiving device 3 are installed at desired positions respectively, but after installation, A test is performed in order to confirm whether or not the signal from the wireless sensor 1 can be normally received by the wireless reception device 3.

In the test, the wireless sensor 1 is compulsorily issued. For example, when the wireless sensor 1 is a wireless heat ray sensor, a person may move within the field of view. Then, at that time, it is general to confirm whether or not the signal from the wireless sensor 1 can be received by the wireless reception device 3, but in recent years, reception of a radio wave when the signal from the wireless sensor 1 is normally received. Some are designed to detect and display the intensity. By displaying the reception strength in this way, it is possible to confirm how strong the radio wave from the wireless sensor 1 is.

However, in general, there are various devices that radiate radio waves around the area where the wireless sensor 1 and the wireless receiver 3 are installed, and among them, the frequency transmitted from the wireless sensor 1 is included. There may be one that radiates a radio wave of the same frequency as or near the same frequency, and the radio wave from such a peripheral device is received by the radio receiver 3
To become noise.

Therefore, even if the reception intensity when the signal from the wireless sensor 1 is normally received is high, if the intensity of the radio wave that is noise radiated from the surrounding equipment is high, the radio wave from the wireless sensor 1 is transmitted. It is difficult to receive normally, and conversely, even when the reception intensity when the signal from the wireless sensor 1 is normally received is low, the intensity of the radio wave that becomes noise radiated from surrounding devices is very high. If it is small, the radio wave from the wireless sensor 1 can be normally received.

In other words, it is effective to display the reception intensity when the signal from the wireless sensor 1 is normally received, but more effective is the reception when the signal from the wireless sensor 1 is normally received. It can be said that it indicates how much there is a difference between the intensity and the reception intensity of a radio wave that becomes noise, that is, how much the margin for noise is.

However, in the prior art, since only the reception intensity when the signal from the wireless sensor 1 is normally received is displayed at the time of the test, it is not possible to know how much margin there is for noise. Met.

In the above, a radio receiving apparatus used in a security system using a wireless sensor has been described, but the above-mentioned problems are generally the same in a radio receiving apparatus.

Therefore, the present invention displays at least the difference between the reception intensity when a regular signal is received and the reception intensity when a noise other than the regular signal is received in a radio receiving device which receives radio waves. An object of the present invention is to provide a wireless reception device.

[0024]

In order to achieve the above object, a radio receiving apparatus according to claim 1 has a reception intensity of a regular signal when a regular signal is received when a test mode is set. If the level is not calculated, if not, the reception strength level of the noise radio wave is calculated. If it is determined that the normal signal is received, at least the reception strength level of the normal signal and the reception strength level of the normal signal And S / N calculated based on the received strength level of noise radio waves
It is characterized by displaying a ratio index. According to a second aspect of the present invention, in the wireless reception device according to the first aspect, when the reception intensity level of the regular signal is detected, when it is determined that the regular signal is received, among the reception intensity signals captured up to that time. It is characterized in that it is performed based on the reception intensity signal at a predetermined position. According to a third aspect of the present invention, in the wireless reception device according to the first aspect, when the reception intensity level of the noise radio wave is detected, it is not possible to determine that a predetermined number of reception intensity signals have been taken and a regular signal has been received. Is
It is characterized in that it is performed by obtaining an average value of the predetermined number of received intensity signals that have been fetched until then. Claim 4
The wireless receiving device according to claim 1, wherein the reception intensity level of the noise radio wave is detected by capturing a predetermined number of reception intensity signals, and excluding a final predetermined number of sample values of the captured reception intensity signals, It is characterized by performing the average value of the remaining sample values. Claim 5
The wireless receiving device described above is a wireless receiving device that receives a signal wirelessly transmitted from a wireless sensor, and based on an output of the frequency reducing means for reducing the received signal to a predetermined intermediate frequency, and the frequency reducing means. A reception intensity detection circuit that detects the reception intensity and outputs a reception intensity signal, a demodulation circuit that demodulates the output of the frequency reduction means, a control circuit, a display unit, and an operation unit. When the test mode is set by the operation unit, when the signal of the wireless sensor is received, the reception intensity level at that time is obtained, otherwise, the reception intensity level of the noise electric wave is obtained, and the signal from the wireless sensor is obtained. When it is determined that the signal has been received, at least the reception strength level of the signal from the wireless sensor and the signal from the wireless sensor And displaying an indication of the S / N ratio calculated based on the signal strength level and the noise radio wave reception intensity level. The radio receiving apparatus according to claim 6, wherein the reception intensity level of the signal from the wireless sensor is detected at the time when it is determined that the signal from the wireless sensor is received, and the reception intensity taken up to that time. It is characterized in that it is performed based on the reception intensity signal at a predetermined position in the signal. In the wireless receiving device according to claim 7, in claim 5, the detection of the reception intensity level of the noise radio wave cannot be judged to have received a predetermined number of reception intensity signals and received a signal from the wireless sensor in the meantime. In this case, it is characterized in that it is carried out by obtaining an average value of the predetermined number of received intensity signals that have been captured so far. According to a fifth aspect of the present invention, in the wireless reception device according to the fifth aspect, the reception intensity level of the noise radio wave is detected by capturing a predetermined number of reception intensity signals, and obtaining a final predetermined number of sample values of the captured reception intensity signals. Except for this, it is characterized by performing the average value of the remaining sample values. The radio receiving apparatus according to claim 9 is the display of the reception intensity level of the signal from the wireless sensor according to claim 5, wherein the range of the reception intensity signal is divided into a predetermined number of stages, and the signal from the wireless sensor is displayed. It is characterized in that it is performed by displaying at which stage the received intensity at the time of reception is divided into levels. The wireless receiver according to claim 10 is the wireless receiver according to claim 5.
In the display of the S / N ratio index, the range of the reception intensity signal is divided into a predetermined number of levels, and the reception intensity when the signal from the wireless sensor is received is divided into the levels. It is characterized in that it is performed by a value obtained by subtracting a value indicating which stage of the level-divided level the received intensity of the noise radio wave is from a value indicating the presence.

[0025]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. Note that the wireless reception device according to the present invention can be generally applied to a device that receives wireless, but hereinafter, an embodiment of a wireless reception device that receives a signal from a wireless sensor will be described.

FIG. 1 is a diagram showing an embodiment of a radio receiving apparatus according to the present invention. In the figure, 10 is a filter, 11 is a mixer, 12 is a first local oscillator, 13 is a filter, 14 is a mixer, 15 Is a second local oscillator, 16 is a filter, 17
Is a demodulation circuit, 18 is a reception intensity detection circuit, 19 is a control circuit, 20 is an operation unit, 21 is a display unit, and 22 is a line control unit. In FIG. 1, the same components as those shown in FIG. 7 are designated by the same reference numerals. Further, here, the form of the signal transmitted from the wireless sensor (not shown in FIG. 1) is as shown in FIG.

The filter 10 is a bandpass filter (BP) whose center frequency is the transmission frequency of the wireless sensor.
The signal from the antenna 4 is limited to a predetermined frequency band centered on the transmission frequency of the wireless sensor by the filter 10. The output of the filter 10 is mixed in the mixer 11 with the first station oscillation frequency from the first local oscillator 12 to form a first intermediate frequency signal. The filter 13 is a BPF whose center frequency is the first intermediate frequency, and the filter 13 limits the first intermediate frequency signal to a predetermined frequency band centered on the first intermediate frequency.

The first intermediate frequency signal output from the mixer 11 is mixed with the second station oscillation frequency from the second local oscillator 15 in the mixer 14 to form a second intermediate frequency signal. The filter 16 is a BPF whose center frequency is the second intermediate frequency, and the filter 16 limits the second intermediate frequency signal to a predetermined frequency band centered on the second intermediate frequency. In this way, the filters 10 to 16
The circuits up to are frequency reducing means for reducing the signal from the antenna 4 to a predetermined intermediate frequency. In FIG. 1, the local oscillator and the mixer are arranged in two stages to reduce the frequency to a predetermined intermediate frequency, but the invention is not limited to this configuration,
In short, it suffices to have a configuration capable of finally reducing the frequency to a desired intermediate frequency.

The second intermediate frequency signal output from the filter 16 is input to the demodulation circuit 17 and the reception intensity detection circuit 18. The demodulation circuit 17 corresponds to the digital modulation method performed by the wireless sensor, and the signal obtained by demodulation is input to the control circuit 19. And the control circuit 1
Reference numeral 9 interprets the signal output from the demodulation circuit 17 to determine whether or not the signal is from the wireless sensor. The method of this determination is as described above.

The reception strength detection circuit 18 detects the reception strength of a radio wave and outputs a reception strength signal which is a signal corresponding to the reception strength. Specifically, RSSI (Received
A signal strength indicator) circuit may be used. Here, an RSSI circuit is used. RS
Since the SI circuit is well known as a circuit for detecting the intensity of received radio waves, detailed description thereof will be omitted.

The RSSI circuit outputs an input intermediate frequency signal, that is, a voltage corresponding to the second intermediate frequency signal level in FIG. 1, and its characteristic is that of the input intermediate frequency signal as shown in FIG. The output voltage increases substantially linearly as the signal level increases, and the output voltage saturates and becomes constant above a certain level of the intermediate frequency signal. The minimum value V _min is defined for the RSSI output voltage, and the range from the minimum value V _min to the maximum value (saturation voltage) V _max is called the RSSI output range. Then, here, the reception strength detection circuit 18 includes an A / D converter that converts the RSSI output voltage into a digital value. Therefore, the voltage corresponding to the level of the input intermediate frequency signal from the reception intensity detection circuit 18 is A
The data is D / D converted and input to the control circuit 19 as digital data.

The control circuit 19 defines two operation modes, an operation mode and a test mode. The operation of the control circuit 19 will be described in detail later.

The operation unit 20 sets whether the security status of the security area is the security status or the release status, and the control circuit 1
It is for performing various settings such as the setting of the operation mode of 9 and can be constituted by appropriate keys or buttons including a ten-key pad. The keys other than the ten-key pad include, for example, a sharp key, an asterisk key, a warning button for setting the security status of the security area to the security status, and a release button for setting the security status of the security area to the unlock status.

The display unit 21 is a display device capable of displaying characters,
For example, a liquid crystal display device can be used, but a level meter having a plurality of light emitting diodes (LEDs) may be used to display the reception intensity and the S / N ratio index, which will be described later. . Here, a liquid crystal display device capable of displaying characters is used.

The line control unit 22 is for notifying the center device via the telephone line 5, and is composed of a modem when the telephone line 5 is an analog line and a terminal adapter when the telephone line 5 is an ISDN line. Composed.

The operation will be described below. Control circuit 1
9 includes a display level table (not shown in FIG. 1) in which the reception intensity display level is associated with the RSSI output voltage. For example, when considering displaying the reception strength level of a signal from a wireless sensor, RS
Displaying the SI output voltage value as it is would require specialized knowledge to evaluate the displayed RSSI output voltage value, but this is not desirable. Therefore, a stepwise display is performed. for that purpose,
Divide the RSSI output voltage into several levels,
By displaying the level of the received intensity level when the signal from the wireless sensor is received, it is possible to display such a level without any specialized knowledge. The reception strength level can be easily determined. The number of levels into which the RSSI output voltage is divided is arbitrary.

An example of such a display level table is shown in FIG. FIG. 3 is an example of a display level table in the case of displaying the reception intensity level in four stages of “0” to “3”. As shown by V ₁ , V ₂ and V ₃ in FIG. Three threshold voltages are set within the range, and when the RSSI output voltage is less than V ₁ , the reception strength level is “0”.
Is displayed, and when the RSSI output voltage is V ₁ or more and less than V ₂ , "1" is displayed as the reception strength level, and when the RSSI output voltage is V ₂ or more and less than V ₃ , the reception strength level is "2". Is displayed, and when the RSSI output voltage is V ₃ or more, “3” is displayed as the reception intensity level.

In FIG. 3, the display level is "0" ...
Although it is displayed with the number "3", it may be displayed with the number of antennas as is done with a mobile phone or the like, or "good", "good", "bad",
Characters such as "impossible" may be displayed. Here, for convenience, the numbers are displayed.

When performing actual security, the operation mode is set by the operation unit 20. As a result, the control circuit 19 operates in the operation mode and executes a predetermined security process. Since the security processing is the same as the conventional one, the description is omitted. Further, in the operation mode, the control circuit 19 does not take in the RSSI output voltage from the reception intensity detection circuit 20.

After the wireless sensor and the wireless receiving device 3 are installed, when a test for confirming whether or not the wireless receiving device 3 can normally receive the signal from the wireless sensor is performed, the operation unit 20 is used to perform a test mode. To set.

As a result, the control circuit 19 operates in the test mode. In this test mode, the control circuit 1
Reference numeral 9 denotes a reception strength level when a signal is received from the wireless sensor (this is referred to as a signal strength level in this specification) and a reception strength level when a signal is not received from the wireless sensor (herein, referred to as a signal strength level). This is referred to as a noise intensity level), and at least the signal intensity level and the S / N ratio index are displayed on the display unit 21.
Here, the signal strength level is displayed at the stage determined by the display level table. In addition, the S / N ratio index is obtained when the noise intensity level is represented at the stage defined in the display level table from the value at the stage when the signal intensity level is represented at the stage defined in the display level table. Displayed as the value obtained by subtracting the value at the stage. Further, in the test mode, the control circuit 19 does not notify the center device even if the signal from the wireless sensor indicates a warning. This is because, in the test mode, the wireless sensor is compulsorily issued as described above.

When the control circuit 19 recognizes that the test mode has been set by the operation unit 20, the control circuit 19 starts taking in the reception intensity signal, specifically the RSSI output voltage, which is the output from the reception intensity detection circuit 18. To do. The signal strength level is detected when the signal from the wireless sensor is received, and the noise strength level is detected when the signal from the wireless sensor is not received.

First, the detection of the signal strength level will be described. Hereinafter, the period for capturing the RSSI output voltage from the reception strength detection circuit 18 is t _p , and the signal transmission time from the wireless sensor is t _s. The signal transmission time t _s from the wireless sensor is the RSSI output voltage capturing period t _p
Is an integral multiple of. That is, it is assumed that there is a relationship of t _s = m × t _p (1) where m is a natural number. Further, the RSSI output voltage acquisition cycle t _p is the time Δt shown in FIG. 8, that is, the control circuit 19 receives all the signals up to the check bit of the signal from the wireless sensor, and then the signal is the signal from the wireless sensor. Take longer than the time required to determine that there is. In fact, according to the experiment, the RSSI output voltage acquisition period t _p may be about 100 msec, and if this is the case, it can be set larger than Δt.

At this time, the control circuit 19 causes the demodulation circuit 17
(M-1) RSSI output voltage from the last to the m-th RSSI output voltage captured up to that point when it is determined that the signal is from the wireless sensor Always corresponds to the reception intensity during the reception of the signal from the wireless sensor.

This will be described with reference to FIG. Figure 4
Then, m = 5. Since the timing of capturing the RSSI output voltage and the timing of transmitting the signal from the wireless sensor are asynchronous, the timing of both is shown in FIG.
There are various types as shown in (a) to (e). Note that in FIG. 4, T indicates the timing of fetching the RSSI output voltage. However, in any of FIGS. 4A to 4E, when the control circuit 19 determines that the signal is from the wireless sensor, the RSS captured up to this point is
Four RSs from the last to the fifth of the I output voltage
The SI output voltage is always detected while receiving the signal from the wireless sensor.

When the control circuit 19 determines that the signal is from the wireless sensor, the control circuit 19 adopts the (m-1) sample values from the last to the mth of the RSSI output voltage taken up to that point. Then, the average value of them is calculated and used as the signal strength level.

As described above, when it is determined that the signal is from the wireless sensor, only the sample value at a predetermined position of the sample values taken up to that point is adopted,
The signal strength level can be obtained by taking the average.

Next, the detection of the noise intensity level will be described. The noise intensity is the reception intensity of the radio wave when the signal from the wireless sensor is not received as described above. To detect this noise intensity level, a convenient method is to take in a specified number of RSSI output voltages, and if it cannot be determined that a signal from a wireless sensor was received during that time, a specified number There is a method in which all the sample values of are set as the reception intensity of noise radio waves, the average value thereof is obtained, and the average value is set as the noise intensity level.

When it is determined that the signal from the wireless sensor is received while the predetermined number of RSSI output voltages are being captured, all the sample values captured up to that point are discarded and the signal from the wireless sensor is discarded. After the reception is completed, the noise intensity detection is started again.

Of course, as shown in FIG. 5, the last several sample values adopted as the reception intensity of the noise radio wave may correspond to the reception intensity of the signal from the wireless sensor. However, when the number of samples for obtaining the average value is larger than m, the signal strength from the wireless sensor is averaged, and thus it can be used as a measure of the reception strength of noise radio waves.

As a method of strictly obtaining the reception intensity of only noise radio waves, n is a natural number larger than (m + 1), predetermined n RSSI output voltages are taken as sample values, and the last (m + 1) of the sample values are taken. ) There is a method in which the sample values are discarded, only the remaining (n- (m + 1)) sample values are adopted, the average value thereof is taken, and the average value is taken as the noise intensity level. That is, for example, in FIG.
As can be easily understood from (a) and (b), it is the maximum last (m + 1) that may correspond to the signal strength from the wireless sensor among the n samples. This is because the removed one corresponds to the reception intensity of only noise radio waves.

Thus, the reception intensity of only noise radio waves is obtained by discarding the last predetermined number of sample values of the predetermined n sample values that have been taken in and obtaining the average value of the remaining sample values. You can

Also in this method, when it is determined that the signal from the wireless sensor is received while capturing n RSSI output voltages as sample values, all the sample values captured so far are discarded, After the reception of the signal from the wireless sensor is completed, the noise intensity detection is started again.

When the control circuit 19 obtains one noise intensity level, it temporarily stores it, detects the noise intensity level again, and obtains the next noise intensity level. The operation of temporarily storing the noise intensity level and deleting the noise intensity level stored until then is repeatedly executed. Thus, in the test mode, the control circuit 19 performs the above-described signal strength level detection operation when it is determined that the signal from the wireless sensor is received, and otherwise performs the noise strength detection operation. To do.

When the control circuit 19 determines that the signal from the wireless sensor is received, the control circuit 19 refers to the display level table and detects the detected signal strength level and the noise strength level stored at that time. Respectively, at which stage in the display level table, the value of the stage in the display level table of the signal strength level is subtracted from the value of the stage in the display level table of the signal strength level. Is used as an index of the S / N ratio.

Then, the control circuit 19 displays at least the value of the stage in the display level table of the signal strength level and the index of the S / N ratio on the display section 21. An example of the display is shown in FIG. In FIG. 6, the signal level is 3 and the S / N ratio is 2. However, the “signal level” value is the value of the detected signal strength level at the stage in the display level table. The “S / N ratio” is the value of the above S / N ratio index. Needless to say, the value of the stage in the display level table of the noise intensity level may be displayed if the number of characters displayed on the display unit 21 is sufficient.

When the control circuit 19 determines that the signal from the wireless sensor is received in the test mode, each time the control circuit 19 determines at least the value of the signal strength level in the display level table and the S / N ratio. The operation of displaying the ratio index on the display unit 21 is executed.

As described above, in the radio receiving device, in the test mode, when the regular signal is received, the reception intensity level of the regular signal is detected, and when it is not, the reception intensity of the noise radio wave is detected. When it operates and it is determined that a regular signal is received, at each time, at least,
Since the reception strength level of the regular signal and the S / N ratio index obtained based on the reception strength level of the regular signal and the reception strength level of the noise electric wave are displayed, only the reception strength of the electric wave of the regular signal is displayed. In addition, the margin for noise can be easily evaluated.

It should be noted that depending on the value displayed on the display unit 21,
When it is determined that the signal from the wireless sensor cannot be received, or when it is determined that the margin for noise is small, the wireless sensor and / or the wireless reception device 3 is rearranged.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of a wireless reception device according to the present invention.

FIG. 2 is a diagram for explaining characteristics of an RSSI circuit.

FIG. 3 is a diagram showing an example of a display level table used when the reception intensity level of a radio wave is divided into several levels.

FIG. 4 is a diagram for explaining how to detect a signal strength level.

FIG. 5 is a diagram for explaining a simple method of detecting a noise intensity level.

FIG. 6 is a diagram showing an example of a display on a display unit 21 in a test mode.

FIG. 7 is a diagram showing a schematic configuration example of a security system using a wireless sensor.

FIG. 8 is a diagram showing an example of a form of a signal transmitted by a wireless sensor.

[Explanation of symbols]

1 ... Wireless sensor, 2 ... Wireless sensor antenna, 3 ... Radio receiver, 4 ... Radio receiver antenna,
5 ... Telephone line, 10 ... Filter, 11 ... Mixer, 12 ...
First local oscillator, 13 ... Filter, 14 ... Mixer, 15
... second local oscillator, 16 ... filter, 17 ... demodulation circuit,
18 ... Reception strength detection circuit, 19 ... Control circuit, 20 ... Operation part, 21 ... Display part, 22 ... Line control part.

Claims (10)

[Claims] 1. When a test mode is set,
When a regular signal is received, the reception intensity level of the regular signal is obtained. Otherwise, the reception intensity level of the noise electric wave is obtained, and when it is determined that the regular signal is received, at least the Reception strength level, and
A wireless reception device, which displays an S / N ratio index obtained based on the reception intensity level of a regular signal and the reception intensity level of a noise radio wave. 2. The detection of the reception intensity level of the regular signal is based on the reception intensity signal at a predetermined position among the reception intensity signals fetched up to that time when it is determined that the regular signal is received. The method according to claim 1, wherein
The wireless receiving device described. 3. When the reception intensity level of the noise radio wave is detected, when a predetermined number of reception intensity signals are taken and it is not determined that a regular signal is received during that period,
2. The wireless reception device according to claim 1, wherein the wireless reception device is performed by obtaining an average value of the predetermined number of received intensity signals that have been captured until then. 4. The reception intensity level of the noise radio wave is detected by taking in a predetermined number of reception intensity signals, excluding the last predetermined number of sample values of the received reception intensity signals, and averaging the remaining sample values. The wireless reception device according to claim 1, wherein the wireless reception device is performed by determining. 5. A radio receiving apparatus for receiving a signal wirelessly transmitted from a wireless sensor, the frequency reducing means for reducing the received signal to a predetermined intermediate frequency, and receiving based on the output of the frequency reducing means. A reception strength detection circuit that detects the strength and outputs a reception strength signal, a demodulation circuit that demodulates the output of the frequency reduction means, a control circuit, a display unit, and an operation unit, the control circuit, When the test mode is set by the operation unit, when the signal of the wireless sensor is received, the reception intensity level at that time is obtained, otherwise, the reception intensity level of the noise electric wave is obtained, and the signal from the wireless sensor is received. If it is determined that at least the reception strength level of the signal from the wireless sensor and the reception strength of the signal from the wireless sensor are Radio receiving apparatus and displaying an indication of the S / N ratio calculated based on the level and the noise radio wave reception intensity level. 6. The reception intensity level of a signal from the wireless sensor is detected when a signal from the wireless sensor is determined to be received, and the reception intensity at a predetermined position in the reception intensity signal captured up to that point. The wireless reception device according to claim 5, wherein the wireless reception device is performed based on a signal. 7. The reception intensity level of the noise radio wave is detected by capturing a predetermined number of reception intensity signals, and if it cannot be determined that a signal from a wireless sensor is received during that period, the predetermined intensity that has been captured until then is detected. The wireless reception device according to claim 5, wherein the wireless reception device is performed by obtaining an average value of the reception intensity signals of the number. 8. The reception intensity level of the noise radio wave is detected by capturing a predetermined number of reception intensity signals and excluding the last predetermined number of sample values of the captured reception intensity signals, and averaging the remaining sample values. The wireless reception device according to claim 5, wherein the wireless reception device is performed by determining. 9. The display of the reception intensity level of the signal from the wireless sensor divides the range of the reception intensity signal into a predetermined number of stages, and the reception intensity when the signal from the wireless sensor is received is divided into levels. The wireless reception device according to claim 5, wherein the wireless reception device is performed by displaying which stage of the steps. 10. The display of the S / N ratio index is such that the range of the reception intensity signal is divided into predetermined levels and the reception intensity when the signal from the wireless sensor is received is divided into levels. 6. The radio receiving apparatus according to claim 5, wherein a value indicating which stage of the level-divided level the reception intensity of the noise radio wave is subtracted from is a value indicating which stage the stage is. .