JP4837692B2 - Wiretap detector - Google Patents

Description

  The present invention relates to an eavesdropper detector that detects an eavesdropper.

  An eavesdropper detector that detects the presence or absence of an eavesdropper by detecting a radiowave signal emitted by the eavesdropper (see, for example, Patent Document 1), or detects that a sound wave signal emitted from a speaker is emitted as a radio wave signal. An eavesdropper detector that detects an eavesdropper has been disclosed (see, for example, Patent Document 2).

The wiretap detector disclosed in Patent Documents 1 and 2 narrows down the installation location where the wiretap is installed while sequentially reducing the output volume of the speaker when the wiretap is detected.
JP-A-49-24089 JP 2000-13500 A

  The wiretap detector disclosed in the above-mentioned Patent Documents 1 and 2 is high in detection accuracy of the wiretap, but always emits a loud sound. Therefore, the wiretap detector is disclosed to the user (user) of the wiretap detector and the surrounding people. It is uncomfortable and unsuitable for use in quiet environments, at midnight, or for continuous use.

  An object of the present invention is to provide a wiretap detector that can easily detect a wiretap while minimizing the influence on the surroundings even in a quiet environment.

A wiretap detector according to a first aspect of the present invention is a wiretap detector that detects a wiretap by determining whether or not a received sound is a specific sound that is emitted by a specific sound. A sound generation unit that generates sound, a reception level control unit that detects a reception level of a radio signal transmitted by the wiretap and controls the sounding unit based on a detection result, and a detection result of the wiretap An output level adjustment unit that adjusts the output level of the specific sound step by step, and a display unit that performs display at a display level corresponding to the output level that is adjusted stepwise by the output level adjustment unit. The level control unit compares the reception level with a predetermined threshold and determines that the wiretap is detected if the reception level is equal to or higher than the threshold, and the reception level is equal to or lower than the threshold. If it is determined that the wiretap was not detected. The output level adjusting unit lowers the output level of the specific sound by one step when the wiretap is detected, and raises the display level by one step, and when the wiretap is not detected, The output level is raised by one step and the display level is lowered by one step.

  Preferably, the output level adjustment unit does not change the output level of the specific sound even when the wiretap is detected when the output level of the specific sound is at the lowest level or the highest level.

  According to the present invention, it is possible to provide a wiretap detector that can easily detect a wiretap while minimizing the influence on the surroundings even in a quiet environment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing an embodiment of an eavesdropper detector according to this embodiment.

The wiretap detector 100 of FIG. 1 includes a receiving antenna 101, a receiving circuit 102, an amplifier 103, a bandpass filter 104, a microcomputer 105, a switching unit 107, a scanning unit 106, a VCO 108, a signal amplifier 109, a speaker 110, and a display unit 111. And a storage unit 112.
The reception circuit 102 includes a high frequency amplifier 1021, a mixer 1022, an intermediate frequency amplifier 1023, a reception level detection unit (reception level control unit) 1024, and a detector 1025.
The signal amplifier 109 includes a volume adjustment unit (output level adjustment unit) 1091. The signal amplifier 109 and the speaker 110 constitute a sound generation unit.

Next, each component of the bug detector 100 will be described.
The receiving antenna 101 receives a radio signal transmitted from the wiretap 200 and outputs the radio signal to the high frequency amplifier 1021 of the receiving circuit 102.

  The high frequency amplifier 1021 receives a radio signal received by the receiving antenna 101, amplifies a high frequency signal (for example, about 400 MHz), and outputs the amplified signal to the mixer 1022.

  The mixer 1022 receives the radio signal amplified by the high frequency amplifier 1021 and a signal having a predetermined frequency oscillated by the VCO 108, multiplies and mixes two signals having different frequencies, and outputs the mixed signal to the intermediate frequency amplifier 1023.

  The intermediate frequency amplifier 1023 amplifies only the intermediate frequency component (for example, about 10.7 MHz) in the signal input from the mixer 1022 and outputs the signal to the detector 1025.

  The reception level detection unit 1024 detects the reception level (RSSI; Received Signal Strength Indication) of the signal output from the intermediate frequency amplifier 1023 and outputs the detection signal SR to the microcomputer 105. The reception level detection unit 1024 determines whether or not the reception level exceeds a predetermined threshold. If the reception level exceeds the threshold, a true detection signal SR1 (for example, a high level voltage signal) If not exceeded, a false detection signal SR2 (for example, a low level voltage signal) is output to the microcomputer 105. The reception level is referred to by the microcomputer 105 at the time of scanning. The predetermined threshold is preferably set.

  The detector 1025 demodulates the signal input from the intermediate frequency amplifier 1023, extracts the audio signal, and outputs it to the amplifier 103.

  The amplifier 103 receives the audio signal from the detector 1025, amplifies it to a predetermined audio level, and outputs it to the bandpass filter 104.

  The band pass filter 104 extracts a specific frequency component from the amplified audio signal and outputs it to the microcomputer 105.

  The microcomputer 105 A / D-converts the audio signal input from the band-pass filter 104 from an analog signal to a digital signal for each interrupt (sampling) frequency by a built-in A / D converter.

  The microcomputer 105 outputs a signal S1 for outputting an audio signal having a specific frequency to the signal amplifier 109. Further, the microcomputer 105 outputs a control signal S3 for controlling whether or not the signal amplifier 109 outputs an audio signal via the speaker 110 to the signal amplifier 109. Specifically, the microcomputer 105 outputs a control signal S31 to the signal amplifier 109 when the signal amplifier 109 outputs an audio signal, and outputs a control signal S32 to the signal amplifier 109 when not output.

  The microcomputer 105 performs processing based on the authenticity of the detection signal SR input from the reception level detection unit 1024. Specifically, when the true detection signal SR1 is input, the microcomputer 105 calculates the amplitude of a specific frequency component (for example, 1 kHz) from the A / D converted audio signal by a predetermined calculation method. When the false detection signal SR2 is input, the control signal S32 for stopping the sound output is output to the signal amplifier 109, and then the amplitude is calculated. The calculation method is not particularly limited, but the method described in the published patent publication “JP 2007-324914 A” is desirable.

  In the interrupt processing described later, the microcomputer 105 determines whether or not the amplitude of the specific frequency component is equal to or greater than a predetermined threshold value. Set the flag. Further, the microcomputer 105 determines whether or not to switch the sound volume level and the display level when the eavesdropper 200 is detected or when the scan frequency reaches the maximum, and when it is switched, the switching processing flag is set.

  The microcomputer 105 generates a pulse-like control signal S2 for adjusting the volume level using, for example, a smoothed voltage of PWM (Pulse Width Modulation), and outputs it to the volume adjusting unit 1091. In the present embodiment, the volume level is adjusted in five steps, but the number of steps to be set is suitably set and is not limited.

The microcomputer 105 generates a control signal S4 for controlling display contents and outputs the control signal S4 to the display unit 111. As a result, the display unit 111 displays a value corresponding to the output (volume) level of the signal amplifier 109 on the display unit 111. Here, the value corresponding to the output level includes the control value of the output level or the output level of the speaker 110.
The voltage may be controlled by a digital / analog (D / A) converter, which will be described later, without being limited to PWM.

  The microcomputer 105 counts the elapsed time from the scan start time using a counter (not shown) or the like, and determines whether or not the elapsed time has passed a predetermined time (about 100 ms in this embodiment).

  In the present embodiment, by using a hardware filter and signal processing (digital filter processing) by the microcomputer 105 in combination, a specific frequency can be discriminated with high selectivity (Q) by simple hardware and signal processing. In addition, a wiretap detector 100 capable of performing high-accuracy frequency discrimination and controlling the sound level of a dial tone based on the discriminated specific frequency level to detect a stable wiretap 200 can be realized. is doing.

A voltage comparison unit CPN of the scan unit 106, which will be described later, sets the end signal END to a high level when the scan frequency (the voltage VCNT of the current supply node NDI) becomes maximum. When the microcomputer 105 detects that the end signal END has become high level, the microcomputer 105 outputs a high level reset signal to the reset signal line RSTL of the scan unit 106 and resets the voltage of the current supply node NDI to the ground potential. As a result, the scanning process ends.
The operation performed by the microcomputer 105 can be processed in accordance with a program stored in the storage unit 112.

  Next, the scanning unit 106 and the switching unit 107 will be described. FIG. 2 is a circuit diagram illustrating a configuration example of the scanning unit and the switching unit according to the present embodiment.

  The scanning unit 106 includes pnp type transistors TR1 and TR2, resistors R1 to R4, and nodes ND1 to ND3, a voltage comparison unit CPN, a pnp type transistor TR3, resistors R5 to R7, and nodes ND4 and ND5. A first current source configured to generate a current IC3, a capacitor C1, a current supply node NDI, an npn transistor TR4 for resetting the current supply node NDI to a predetermined voltage, and a node ND6.

  The resistors R1 and R2 of the voltage comparison unit CPN are connected in series between the power supply potential VDD and the ground potential GND.

  The transistor TR1 has a base connected to the node ND1, an emitter connected to the node ND2, and a collector connected to the node ND3. The transistor TR2 has a base connected to the node ND4, an emitter connected to the node ND2, and a collector connected to the ground potential GND.

  Resistor R3 is connected between power supply potential VDD and node ND2, and resistor R4 is connected between ground potential GND and node ND3. The node ND3 is connected to the end signal line ENDL.

  The resistors R5 and R6 are connected in series between the power supply potential VDD and the ground potential GND, and the resistor R7 is connected between the power supply potential VDD and the emitter of the transistor TR3. Capacitor C1 is connected between current supply node NDI and ground potential GND. Further, the current supply node NDI is connected to the VCO 108 by the VCO control signal line VCNTL via the nodes ND6 and ND8.

  The transistor TR3 has a base connected to the node ND5, an emitter connected to the resistor R7, and a collector connected to the node ND4. The transistor TR4 has a base connected to the microcomputer 105 via a reset signal line RSTL, an emitter connected to the ground potential GND, and a collector connected to the node ND6.

  The switching unit 107 includes a pnp transistor TR5, nodes ND7 and ND8, and resistors R8 to R10, and determines whether to supply a second current source that generates the current IC4 and the current of the second current source. It has an npn transistor TR6 that operates as a switch.

  The transistor TR5 has a base connected to the node ND7, an emitter connected to the resistor R8, and a collector connected to the node ND8.

  The resistor R8 is connected between the power supply potential VDD and the emitter of the transistor TR5. The resistors R9 and R10 are connected in series between the power supply potential VDD and the collector of the transistor TR6.

  The transistor TR6 has a base connected to the microcomputer 105 via the switching signal line CNTL, an emitter connected to the ground potential GND, and a collector connected to the resistor R10.

  Further, the voltage VCNT of the current supply node NDI is supplied to the VCO control signal line VCNTL, the reset signal RST is supplied to the reset signal line RSTL, the switching signal CNT is supplied to the switching signal line CNTL, and the end signal END is supplied to the end signal line ENDL. , Respectively.

  The scan unit 106 charges the capacitor C1 using a first current source and a second current source (which the switching unit 107 has) that is switched on or off. The scan unit 106 compares the voltage of the current supply node NDI with the reference voltage in the voltage comparison unit CPN. When the voltage of the current supply node NDI reaches the reference voltage, the scan unit 106 sets the voltage of the capacitor C1 to a predetermined voltage ( For example, ground potential is reset.

  The scanning unit 106 outputs the voltage of the current supply node NDI to the VCO 108 until the voltage of the capacitor C1 is reset to a predetermined voltage.

  When the control signal is input from the microcomputer 105 and the reception level detected by the reception level detection unit 1024 is equal to or less than a predetermined value, the switching unit 107 switches the switch on. If the reception level is above a certain value, the switch is turned off.

  In the present embodiment, the scan speed can be switched (normal scan speed and low-speed scan speed) by the scan section 106 and the switching section 107 shown in FIG. 2, and the scan speed is improved.

  The VCO 108 receives the voltage of the current supply node NDI (FIG. 2) from the scan unit 106, and in order for the bug detector 100 to receive a radio signal stably, at a frequency corresponding to the input voltage from the scan unit 106. It oscillates and outputs a signal of a predetermined frequency to the mixer 1022.

  The signal amplifier 109 receives a signal S <b> 1 for transmitting a specific frequency sound (specific sound) from the microcomputer 105. The signal amplifier 109 receives a control signal S3 for switching whether or not to output the generated audio signal via the speaker 110. When the control signal S31 is input from the control signal S3, the signal amplifier 109 outputs the audio signal. When the control signal S32 is input, the output of the audio signal is stopped.

The volume adjusting unit 1091 will be described with reference to FIG. FIG. 3 is a diagram for explaining the volume adjusting unit according to the present embodiment.
The volume control unit 1091 is configured by an audio signal amplifier (Amplifier; hereinafter referred to as an amplifier), a smoothing circuit, etc. (not shown). The volume adjustment unit 1091 receives a control signal S2 for adjusting the volume level from the microcomputer 105, adjusts the volume level of the audio signal generated by the signal amplifier 109 in five stages using an amplifier, and the like. Output.

  Here, a circuit configuration of the volume adjusting unit 1091 will be described. As shown in FIG. 3, the volume adjusting unit 1091 smoothes the pulsed control signal S2 into a direct current by a smoothing circuit. For example, if the voltage of the control signal S2 input to the smoothing circuit is 5V, the frequency is 10 kHz, and the duty ratio is 50%, the smoothed voltage is half that of the 100% duty ratio, that is, 2.5V. The circuit configuration of the volume adjustment unit 1091 is not limited, but the volume can be controlled by the control signal S2 as long as the volume transmitted by the speaker 110 is proportional to the smoothed voltage.

  For convenience of explanation, the minimum volume level is appropriately described in five levels, such as volume VOL1, and the maximum volume level is volume VOL5. The maximum and minimum values of the volume level, the width between the volume levels, and the like can be suitably set.

  The display unit 111 will be described. FIG. 4 is a circuit diagram illustrating a configuration example of a main part of the display unit according to the present embodiment. As shown in FIG. 4, the display unit 111 includes switches SW1 to SW5, resistors R11 to R15, and LEDs 1 to LED5 as light emitting elements (LEDs). Each switch SW1-SW5, resistance R11-R15, and LED1-LED5 are each connected in series, and each connected in series is connected in parallel. One ends of the switches SW1 to SW5 are commonly connected to the power supply potential VDD, and the cathode sides of the LEDs 1 to LED5 are commonly connected to the ground potential.

  When the microcomputer 105 detects the wiretap 200, the display unit 111 receives a control signal S4 (not shown) according to the detection result of the wiretap 200, switches on the switch SW according to the control signal S4, and emits an LED. By doing so, the estimated distance between the user (user of the bug detector 100) and the bug 200 is displayed in five stages. This display stage is also simply referred to as a display level. The display unit 111 is provided with a light emitting element, a display panel, and the like (not shown), and can suitably display various information such as a power-on state and a detection result. The circuit configuration of the display unit 111 illustrated in FIG. 4 is an example of a main part, and is not limited to the present embodiment.

  The storage unit 112 is constituted by, for example, a flash ROM or a register, and stores, for example, a program having contents processed by the microcomputer 105 and temporary data, and is read appropriately by the microcomputer 105. The configuration, storage contents, etc. of the storage unit 112 are not particularly limited.

  The wiretap 200 has an antenna 201 and a microphone 202. The eavesdropper 200 acquires sound (sound wave signal) with the microphone 202, modulates the high frequency of the carrier wave with the sound wave signal, and sends it out via the antenna 201. A series of operations by the wiretap 200 is expressed as wiretapping. The configuration of the wiretap 200 is not particularly limited, but the wiretap 200 may have, for example, a VOX (Voice Operation Transmission) function. The VOX function is activated when the eavesdropper 200 receives sound and performs eavesdropping, and does not eavesdrop when it is silent. Therefore, in the silent state, the wiretap 200 does not send out a radio signal.

  Next, an eavesdropper detection process executed on the microcomputer 105 will be described. FIG. 5 is a flowchart showing an example of a wiretap detection process performed by the wiretap detector according to the present embodiment. FIG. 6 is a flowchart illustrating an example of interrupt processing according to the present embodiment.

  First, the wiretap detection process shown in FIG. 5 will be described, and then the interrupt process shown in FIG. 6 will be described.

(Step ST11)
As shown in FIG. 5, the main routine of the wiretap detection process is started.

(Step ST12)
First, as shown in FIG. 5, the wiretap detector 100 reflects the scan frequency set by the user, the frequency of sound to be transmitted, and the like in the storage unit 112 and the like, and initializes the registers in the storage unit 112. . The initial setting input by the user is set by an external input device (not shown) or the like.
In the following description, in order to cover frequencies from 139 MHz to 400 MHz that are frequently used in the bugging device 200, it is assumed that the scan frequency is 100 MHz to 500 MHz, and the volume level and the display level are both in five stages. Although details will be described later, if the frequency of the output audio signal is 1 kHz, the interrupt (sampling) frequency is set to 4 times 4 kHz.

(Step ST13)
The microcomputer 105 permits interrupt processing after sending a scan start signal (high level reset signal RST). Thereby, the scanning of the eavesdropping frequency and the interruption process are started.

(Step ST14)
The microcomputer 105 repeatedly determines whether to end the interrupt process.
Specifically, the microcomputer 105 determines whether or not to end the interrupt process by using a switching process flag (see step ST211 described later), and the interrupt process is repeatedly performed until the switching process flag is set ( NO) If the switching process flag is set (YES), the process of step ST15 is performed to prohibit the interrupt process.

(Step ST15)
The microcomputer 105 prohibits execution of interrupt processing. Thus, the wiretapping frequency scan process and the sound output are completed.
Note that interrupt processing is not performed until the processing of step ST13 is executed again.

(Step ST16)
The microcomputer 105 determines the presence / absence of the wiretap 200 based on the wiretap detection flag (see step ST29 described later). If the eavesdropper detection flag is set (YES), the microcomputer 105 determines that the eavesdropper 200 has been detected and performs the process of step ST17. If the eavesdropper detection flag is not set (NO), It is determined that the wiretap 200 has not been detected, and the process of step ST19 is performed.

(Step ST17)
When the microcomputer 105 detects the wiretap 200, the microcomputer 105 determines whether or not the current volume level is the minimum volume level (volume VOL1). If the microcomputer 105 determines that it is the minimum volume level (YES), it returns to the process of step ST13, and if it determines that it is not the minimum volume level (NO), performs the process of step ST18.

(Step ST18)
If the eavesdropper 200 is detected in step ST16 and it is determined in step ST17 that the volume level is not the minimum volume level, the microcomputer 105 controls the pulsed control signal S2 for lowering the volume level by one step, for example, by PWM. Is output to the volume adjustment unit 1091. For example, if the current volume level is volume VOL5, the volume adjustment unit 1091 generates an audio signal of volume VOL4 for the next scan process so that the volume is switched to volume VOL4.
The microcomputer 105 generates a control signal S4 and outputs it to the display unit 111 so as to increase the display level by one level. For example, if the display level at the current stage is the lowest level, the display unit 111 switches on the switch SW1 and switches off the other switches so that only the LED 1 is lit (see FIG. 4). reference).
Thus, when the wiretap 200 is detected in one scan (steps ST13 to ST15), the volume level is lowered by one step and the display level is raised by one step.

(Step ST19)
On the other hand, if the bug 200 is not detected in step ST16, the microcomputer 105 determines whether or not the current volume level is the maximum volume level (volume VOL5). When the microcomputer 105 determines that the volume level is the maximum (YES), the process returns to step ST13 while maintaining the volume level and the display level, and the scanning process is restarted and determines that the volume level is not the maximum level ( NO), the process of step ST110 is performed.

(Step ST110)
If the eavesdropper 200 is not detected in step ST16 and it is determined in step ST19 that the volume level is not the maximum volume level (volume VOL5), the microcomputer 105 uses, for example, a pulse for raising the volume level by one step by PWM. Control signal S2 is generated and output to volume control section 1091. For example, if the current volume level is the volume VOL3, the volume adjustment unit 1091 generates an audio signal of the volume VOL4 for the next scanning process so as to switch to the volume VOL4.
The microcomputer 105 generates a control signal S4 and outputs it to the display unit 111 so as to lower the display level by one step. For example, if LED1 to LED3 are lit at the current stage, display unit 111 keeps switches SW1 to SW2 on and switches switch SW3 to off so that only LEDs 1 to LED2 are lit.
As described above, when the wiretap 200 is not detected in one scan, the volume level is increased by one step and the display level is decreased by one step.
Thereafter, the process returns to step ST13 again.

  Next, the interrupt process executed in steps ST13 to ST15 will be described with reference to FIG.

(Step ST21)
The interrupt processing routine is started. When the wiretap 200 is detected by performing calculation in step ST27 described later, the frequency at which the interrupt process is performed is the A / D conversion sampling frequency, which is four times the frequency of the output sound. For example, if the output sound is 1 kHz, the interrupt frequency is 4 kHz.

(Step ST22)
The microcomputer 105 switches the signal level of the signal S1 for outputting an audio signal of a specific frequency and outputs it to the signal amplifier 109. The signal amplifier 109 generates an audio signal. If the interrupt frequency is 4 kHz, an audio signal of 1 kHz is output. Therefore, processing is performed by switching the signal level (low level if high level, high level if low level) every two interrupt processes.

(Step ST23)
The microcomputer 105 A / D-converts the audio signal input from the band-pass filter 104 from an analog signal to a digital signal for each interrupt process by a built-in A / D converter.

(Step ST24)
The microcomputer 105 counts the elapsed time from the scan start time (for example, immediately after step ST13) using a counter or the like (not shown), and whether or not the maximum volume and a predetermined time (about 100 ms in this embodiment) have elapsed. Determine whether. When the elapsed time has passed the predetermined time (YES), the process of step ST25 is executed, and when the elapsed time has not passed the predetermined time (NO), the process of step ST27 is executed. The setting of the elapsed time is not limited to the present embodiment, and can be suitably set.

(Step ST25)
The microcomputer 105 performs processing based on the authenticity of the detection signal SR input from the reception level detection unit 1024. Specifically, the microcomputer 105 performs the process of step ST27 when the true detection signal SR1 is input, and performs the process of step ST26 when the false detection signal SR2 is input.

(Step ST26)
If the detection signal SR is a false detection signal SR2 in step ST25, the microcomputer 105 outputs a control signal S32 for stopping the output of the audio signal to the signal amplifier 109. Accordingly, the signal amplifier 109 receives the control signal S32, stops (cancels) the output of the audio signal, and performs the process of step ST27.

By the way, since the wiretap 200 outputs a radio wave signal during operation (wiretapping), when the wiretap detector 100 approaches the wiretap 200, there is a reception area where the reception level exceeds the threshold value. That is, that the reception level does not exceed the predetermined threshold value indicates that the bug detector 100 is located outside the reception area.
The process of step ST26 prevents the bug detector 100 from emitting (outputting) unnecessary sounds.

(Step ST27)
On the other hand, if the detection signal SR is the true detection signal SR1 in step ST25, the microcomputer 105 outputs a control signal S31 for outputting an audio signal having a specific frequency to the signal amplifier 109, and the signal amplifier 109 Output an audio signal of a specific frequency.
The microcomputer 105 calculates the amplitude (that is, voltage) of the specific frequency component (for example, 1 kHz) by a predetermined calculation method.

(Step ST28)
If the magnitude of the amplitude of the specific frequency component calculated in step ST27 is equal to or greater than the threshold (YES), the microcomputer 105 determines that the bug 200 has been detected and performs the process of step ST29. If it is less than or equal to the threshold (NO), it is determined that the wiretap 200 has not been detected, and the process of step ST210 is performed.

(Step ST29)
When the magnitude of the amplitude of the specific frequency component is equal to or greater than the threshold value, the microcomputer 105 sets an eavesdropper detection flag and performs the process of step ST210. Note that the wiretap detection flag in step ST29 is used for the process in step ST16.

(Step ST210)
The microcomputer 105 determines that the switching process is to be performed when the end signal END becomes high level or when the bug detection flag is set in the process of step ST29 (YES), and performs the process of step ST211. If none of them (NO), the process of step ST212 is performed, and the interrupt process is terminated.

(Step ST211)
When switching the sound volume level and the display level, the microcomputer 105 sets a switching process flag and ends the interrupt process (step ST212).

  The processing shown in FIGS. 5 and 6 described above is formed as a program according to the procedure, and is configured to be executed by the microcomputer 105 such as a CPU. A part of the processing described above can also be realized by hardware.

Finally, the overall operation of the wiretap detector 100 will be described with reference to FIG.
FIG. 7 is a timing chart for explaining operations of the switching unit and the scanning unit according to the present embodiment. 7A shows the voltage VCNT of the current supply node NDI, FIG. 7B shows the end signal END, FIG. 7C shows the reset signal RST, and FIG. 7D shows the reception level detection. 7E shows the reception level of the unit 1024, FIG. 7E shows the switching signal CNT, and LEV in FIG. 7D shows a constant value of the reception level.

  First, the operation of the receiving circuit 102 will be mainly described.

  The high frequency amplifier 1021 amplifies the high frequency signal, and the mixer 1022 multiplies the amplified high frequency signal and a signal of a predetermined frequency output from the VCO 108.

  The VCO 108 generates a signal with a predetermined frequency based on the control signal of the scan unit 106, generates a signal with a predetermined frequency according to the output voltage of the scan unit 106, and outputs the signal to the mixer 1022.

  The intermediate frequency amplifier 1023 takes out an intermediate frequency component signal from the signal input from the mixer 1022 and multiplied and outputs the signal to the detector 1025 and the reception level detection unit 1024.

  The reception level detection unit 1024 determines whether or not the reception level of the intermediate frequency signal exceeds a predetermined threshold value. When the reception level detection unit 1024 exceeds the threshold value, a true detection signal SR1 (for example, a high level signal) is output. If the threshold value is not exceeded, a false detection signal SR2 (for example, a low level signal) is output to the microcomputer 105.

  Subsequently, the amplifier 103 amplifies the audio signal detected by the detector 1025 to a predetermined audio level and outputs the amplified audio signal to the bandpass filter 104. Then, the band pass filter 104 extracts a specific frequency component from the amplified audio signal and outputs it to the microcomputer 105.

  Next, with reference to the operation of the scan unit 106, the operation until the scan unit 106 scans and the VCO 108 outputs a signal having a predetermined frequency to the mixer 1022 will be described.

  The switching unit 107 switches the switch on or off based on a control signal from the microcomputer 105.

  The switching unit 107 switches the switch on when the reception level detected by the reception level detection unit 1024 is a predetermined value or less, and switches the switch off when the reception level of the radio signal is equal to or higher than the predetermined value.

  The scanning unit 106 scans at a low speed or a normal scanning speed according to the control signal of the microcomputer 105 and the switching of the switch of the switching unit 107.

  Specifically, when the switch of the switching unit 107 is on, the scan unit 106 charges the capacitor with the first and second current sources (normal scan speed). When the switch of the switching unit 107 is off, the scan unit 106 charges the capacitor with only the first current source (low speed scan).

  Scan unit 106 performs scanning until the voltage of current supply node NDI reaches a predetermined voltage, and outputs the voltage of current supply node NDI to VCO 108.

  Here, operations of the scanning unit 106 and the switching unit 107 will be described in more detail.

  At the start of the scanning process, as shown in FIG. 7C, the microcomputer 105 propagates the high level reset signal RST to the reset signal line RSTL, whereby the transistor TR4 is turned on, and the voltage of the current supply node NDI is grounded. The potential is reset to GND, and the charge of the capacitor C1 becomes zero.

  Thereafter, as shown in FIG. 7C, the microcomputer 105 propagates the low level reset signal RST to the reset signal line RSTL, so that the transistor TR4 is turned off, and as shown in FIG. Charging starts.

(Normal scan)
The microcomputer 105 monitors the output of the reception level detection unit 1024. As shown in FIG. 7D, the reception level output by the reception level detection unit 1024 is a constant value (hereinafter referred to as LEV in the description of FIG. 7). In the following case, as shown in FIG. 7E, the transistor TR6 is turned on by propagating the high-level switching signal CNT to the switching signal line CNTL, and the current IC4 generated by the second current source Is supplied to the capacitor C1 through the current supply node NDI.

  At this time, the capacitor C1 is charged by the currents IC3 and IC4 generated by the first and second current sources, and the voltage VCNT of the current supply node NDI rises as shown in FIG. 7A.

  The voltage VCNT is propagated to the VCO control signal line VCNTL and output to the VCO 108.

(Low speed scan)
As shown in FIG. 7D, when the reception level output from the reception level detector 1024 is equal to or higher than a certain value, the microcomputer 105 sets the low level to the switching signal line CNTL as shown in FIG. By propagating the switching signal CNT, the transistor TR6 is switched off, and the current IC4 generated by the second current source is not supplied to the capacitor C1 via the current supply node NDI.

  At this time, the capacitor C1 is charged only by the current IC3 generated by the first current source, and the voltage VCNT rises as shown in FIG. The rise in voltage VCNT at this time rises more slowly than during normal scanning in which capacitor C1 is charged with current IC3 and current IC4.

  The voltage VCNT is propagated to the VCO control signal line VCNTL and output to the VCO 108.

(Normal scan)
As shown in FIG. 7D, if the reception level output from the reception level detection unit 1024 is switched again below a certain value, the microcomputer 105 again switches to the switching signal line CNTL as shown in FIG. The high-level switching signal CNT is propagated, the transistor TR6 is turned on, and the output of the second current source is turned on.

  At this time, the capacitor C1 is charged by the currents IC3 and IC4 generated by the first and second current sources, and the voltage VCNT of the current supply node NDI rises as shown in FIG. 7A.

  The voltage VCNT is propagated to the VCO control signal line VCNTL and output to the VCO 108.

  The voltage comparison unit CPN compares the voltage of the current supply node NDI with the voltage of the node ND1. When the voltage VCNT of the current supply node NDI reaches the voltage VB1 divided by the resistors R1 and R2 (the voltage of the node ND1), the potential of the node ND3 rises as shown in FIG. The end signal END of the line ENDL is switched to the high level, and the high level end signal END is output to the microcomputer 105.

  As shown in FIG. 7C, the microcomputer 105 causes the reset signal RST to propagate again to the reset signal line RSTL, whereby the voltage of the current supply node NDI is reset to the ground potential GND.

  This time is the maximum scan frequency (500 MHz in this embodiment), and one scan is completed.

  In other words, when the reception level is below a certain value, the switching unit 107 switches on the transistor TR6 and charges the capacitor C1 with the currents IC3 and IC4 (normal scan). When the reception level is greater than or equal to a certain value, the switching unit 107 switches off the transistor TR6 and charges the capacitor C1 with only a smaller current IC3 than when the reception level is less than or equal to the certain value (low speed scan).

  In other words, when the reception level is equal to or lower than a certain value, the switching unit 107 switches on the second current source, so that the capacitor C1 is charged in a short time and the frequency band in which the bugger 200 does not transmit is normally set. Scan faster than usual.

  The wiretap detector 100 performs scanning while continuously changing the sound volume transmitted from the speaker 110. Therefore, the oscillation frequency of the VCO 108 does not need to be fixed.

  In the present embodiment, the switching unit switches the scan speed according to the reception level of the reception signal, so that sufficient time for performing signal processing for determining whether the radio signal includes specific information is secured. .

  On the other hand, the VCO 108 generates a signal having a predetermined frequency according to the output voltage of the scan unit 106. In this way, the VCO 108 outputs a signal having a predetermined frequency to the mixer 1022.

  The usage of the bug detector 100 will be described. For example, the user holds the wiretap detector 100 and moves around the area where the wiretap 200 seems to be installed. When the volume level is at the minimum level and the display level is at the maximum level, it can be estimated that it is closest to the installation location of the bugger 200.

  According to the present embodiment, the reception level detection unit 1024 that detects the reception level of the radio signal transmitted by the wiretap 200, the signal amplifier 109 that generates a specific sound, and the detection result of the reception level detection unit 1024 are used. The microcomputer 105 that controls the signal amplifier 109 is provided, and the reception level detection unit 1024 compares the reception level with a predetermined threshold value, and determines whether or not to emit a specific sound according to the comparison result.

  Accordingly, the wiretap detector can emit sound only when necessary, and can be used in a quiet environment without causing discomfort to the user and the surrounding people.

  When an eavesdropper is detected in one scan, the volume level is lowered by one step and the display level is raised by one step. On the other hand, if no wiretap is detected in one scan, the volume level is increased by one level and the display level is decreased by one level. By repeating this alternately, the user can easily estimate the distance to the wiretapping device using the volume as a clue.

  Since the change of the volume and the display is automatically and continuously executed by the microcomputer 105, the user does not need to adjust the volume manually, and the user can easily move to the place where the wiretap is installed. There is an advantage that can be reached. Therefore, an eavesdropper can be easily found without requiring specialized knowledge.

  This wiretap detector has a merit that it can cope with detection of a wiretap equipped with a VOX function because a specific sound is periodically transmitted regardless of the reception level.

(Second Embodiment)
Another embodiment will be described. FIG. 8 is a block diagram showing an embodiment of the wiretap detector according to the present embodiment. In the description of the present embodiment, only differences from the first embodiment will be described.

  As shown in FIG. 8, the wiretap detector 100 a includes a switch circuit 113. The switch circuit 113 includes a switch SW113, and one end of the switch SW113 is connected to the signal amplifier 109a and the other end is connected to the speaker 110.

  The reception level detection unit 1024a outputs the detection signal SR directly to the switch SW113. The reception level detection unit 1024a determines whether or not the reception level exceeds a predetermined threshold value. If the reception level exceeds the threshold value, a true detection signal SR1 (for example, a high-level voltage signal) is output as the threshold value. If not exceeded, a false detection signal SR2 (for example, a low level voltage signal) is directly output to the switch SW113.

  The switch circuit 113 directly receives the detection signal SR from the reception level detection unit 1024a, and switches the switch SW113 on or off. Specifically, the switch circuit 113 switches the switch SW113 on when the true detection signal SR1 is input, and switches the switch SW113 off when the false detection signal SR2 is input. In addition, although switch SW113 is comprised by the switching transistor, for example, the structure of switch SW113 and switch circuit 113 etc. are not limited to this embodiment.

  That is, the audio signal generated by the signal amplifier 109a is transmitted as a specific sound through the speaker 110a only when the detection signal SR is directly input from the reception level detection unit 1024a to the switch circuit 113 and the switch SW113 is turned on. The

  According to the present embodiment, the bug detector can be used in a quiet environment without causing discomfort to the user and the surrounding people, and the calculation load applied to the microcomputer 105 is reduced. Can be executed quickly. This embodiment is effective for a microcomputer with a low processing speed and a microcomputer with few input / output ports.

  There is no need to match the volume level and the display level. For example, the volume level may be set to 6 levels and the display level may be set to 3 levels, and the display level may be increased by 1 level each time the volume level decreases by 2 levels.

The transmission of sound at a specific frequency does not need to be linked to scanning. For example, sound may be transmitted periodically using a timer or the like. The sound output period is not particularly limited. The process of step ST25 may be executed at all sound volume levels.
There is no need to match the volume level and the display level. For example, the volume level may be set to 6 levels and the display level may be set to 3 levels, and the display level may be increased by 1 level each time the volume level decreases by 2 levels.

  The program for executing the wiretapping detection process according to the present embodiment is accessed by a recording medium such as a semiconductor memory, a magnetic disk, an optical disk, and a floppy (registered trademark) disk, and is executed by a computer in which the recording medium is set. Can be configured.

  The present invention can be variously modified by those skilled in the art without departing from the scope of the present invention.

It is a block diagram which shows one form of the wiretap detector which concerns on 1st Embodiment. It is a circuit diagram which shows the structural example of the scanning part and switching part which concern on 1st Embodiment. It is a figure for demonstrating the volume adjustment part which concerns on 1st Embodiment. It is a circuit diagram which shows the structural example of the principal part of the display part which concerns on 1st Embodiment. It is a flowchart which shows the example of a bug detection process by the bug detector according to the first embodiment. It is a flowchart which shows the example of an interruption process concerning 1st Embodiment. 6 is a timing chart for explaining operations of a switching unit and a scanning unit according to the first embodiment. It is a block diagram which shows one form of the wiretap detector which concerns on 2nd Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Wiretap detector, 101 ... Reception antenna, 102 ... Reception circuit, 103 ... Amplifier, 104 ... Band pass filter, 105 ... Microcomputer (CPU), 106 ... Scan part, 107 ... Switching part, 108 ... VCO, 109 DESCRIPTION OF SYMBOLS ... Signal amplifier, 110 ... Speaker, 111 ... Display part, 112 ... Memory | storage part, 113 ... Switch circuit, 1021 ... High frequency amplifier, 1022 ... Mixer, 1023 ... Intermediate frequency amplifier, 1024 ... Reception level detection part, 1025 ... Detector , 1091 ... Volume control unit, 200 ... Wiretap, 201 ... Antenna of wiretap, 202 ... Microphone, C1 ... Capacitor, IC3, IC4 ... Current source, ND1-ND8 ... Node, NDI ... Current supply node, R1- R10: resistance, TR1 to TR3, TR5: pnp type transistor, TR4 TR6 ... npn type transistor, VCNTL ... VCO control signal line, RSTL ... reset signal line, CNTL ... switching signal line, ENDL ... end signal line, VCNT ... VCO control signal, RST ... reset signal, CNT ... switching signal, END ... End signal, SW113... Switch.

Claims (2)

An eavesdropper detector that emits a specific sound and determines whether the received sound is a specific sound emitted by itself, and detects the eavesdropper,
A pronunciation section that produces the specific sound;
A reception level control unit that detects a reception level of a radio signal transmitted by the wiretap and controls the sound generation unit based on a detection result ;
An output level adjusting unit that adjusts the output level of the specific sound stepwise according to the detection result of the wiretapping device;
A display unit that performs display at a display level corresponding to the output level that is adjusted stepwise by the output level adjustment unit,
The reception level control unit compares the reception level with a predetermined threshold value. If the reception level is equal to or higher than the threshold value, the reception level control unit determines that the wiretap is detected, and the reception level is equal to the threshold value. If it is less than the value, it is determined that the wiretap was not detected,
When the wiretap is detected, the output level adjustment unit lowers the output level of the specific sound by one step and raises the display level by one step, and when the wiretap is not detected, the output level of the specific sound A wiretap detector that raises the display level by one step and lowers the display level by one step . The output level adjuster is
When the output level of the specific sound is minimum phase or maximum phase, wiretap detector according to claim 1, wherein said listening device does not change the output level of the specific sound be detected.

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