JP2007285914A - Radiation measuring apparatus and noise elimination method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a radiation measuring apparatus, especially a personal radiation dosimeter from malfunctioning caused by extraneous electric waves, or vibrational impacts. <P>SOLUTION: A noise sensor 102 for detecting electromagnetic noise and an impact sensor 103 for detecting the impact are provided, and a signal processing section 104 processes a signal 108 which is output by a radiation sensor 101 as an invalid signal, when at least one of a noise detection signal 109 and an impact detection signal 110 is valid, thereby preventing the malfunctions due to noise. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a radiation measurement apparatus and a noise removal method, and more particularly to a noise removal method caused by an external electromagnetic wave or a vibration shock.

In a radiation measuring apparatus such as a personal dosimeter, a technique is generally used in which radiation is detected by a semiconductor sensor, and the detection signal is counted and displayed as a dose.
When a semiconductor sensor or a substrate on which the semiconductor sensor is mounted receives an external electromagnetic wave, noise is generated due to the electromagnetic wave, causing malfunction. Further, when a physical shock is applied, noise is generated due to physical distortion of the semiconductor sensor or a circuit surrounding the semiconductor sensor, causing a malfunction.
Japanese Unexamined Patent Publication No. 2001-51062 (page 4, FIG. 1)

In order to ensure highly reliable measurement, it is essential to reduce the dose miscounting caused by external electromagnetic waves and vibration shocks, and it is effective to shield the device against external electromagnetic waves. There is a limit to spending the man-hours to be applied and to further downsize the apparatus, and a more reliable noise removal method is desired. In addition, it can be assumed that shock absorbers are put in the device against vibration shock, but the effect is not sufficient, and it becomes a big obstacle to downsizing the device and manufacturing inexpensive products. Yes.
The present invention has been made in view of the above problems, and an object of the present invention is to perform highly reliable radiation measurement by removing noise and to provide a noise removal method.

  In order to solve the above-mentioned object, the first invention is a radiation sensor that detects radiation, a noise sensor that detects electromagnetic noise, an impact sensor that detects an impact, a signal from the noise sensor, or the impact A signal processing unit that invalidates the signal output from the radiation sensor when at least one of the signals from the sensor is recognized.

The second invention is the configuration described in the first invention,
The signal processing unit
A first signal converter that receives a signal output from the radiation sensor and outputs a pulse when the intensity of the signal exceeds a threshold; a radiation counter that converts the number of pulse outputs into a digital count;
A second signal converter that receives a signal output from the noise sensor and outputs a pulse when the intensity of the signal exceeds a threshold; a noise counter that converts the number of pulse outputs into a digital count;
A third signal converter that receives a signal output from the impact sensor and outputs a pulse when the intensity of the signal exceeds a threshold; an impact counter that converts the number of pulse outputs into a digital count;
The radiation counter, the noise counter, and a computing unit that performs a statistical calculation of the radiation dose according to the counts indicated by the impact counter, and the computing unit includes a working storage unit.

The third invention is the configuration described in the second invention,
The arithmetic unit repeats arithmetic processing every cycle,
Radiation counter storage means for saving the value of the radiation counter;
Noise counter storage means for saving the value of the noise counter;
Impact counter storage means for saving the value of the impact counter;
With
The value of the radiation counter storage means saved one cycle ago is the radiation counter previous value, the radiation counter value obtained in the current cycle is the radiation counter current value,
The value of the noise counter storage means saved before the one cycle is the previous value of the noise counter, the value of the noise counter obtained in the current cycle is the noise counter current value,
The value of the impact counter storage means saved in the previous cycle is the impact counter previous value, the value of the impact counter obtained in the current cycle is the impact counter current value,
The radiation counter previous value and the radiation counter current value are compared, the noise counter previous value and the noise counter current value are compared, and the impact counter previous value and the impact counter current value are compared. And
When the radiation counter previous value is different from the radiation counter current value, the noise counter previous value and the noise counter current value are equal, and the impact counter previous value and the impact counter current value are equal, the radiation dose calculation process Run
When the previous value of the radiation counter is different from the current value of the radiation counter, the previous value of the noise counter is different from the current value of the noise counter, or when the previous value of the impact counter is different from the current value of the impact counter, the radiation dose calculation is performed. Do not execute the process,
If the previous value of the radiation counter and the current value of the radiation counter are equal, the radiation dose calculation process is not performed,
When the noise counter current value reaches a predetermined value, the noise counter value is initialized at the current cycle timing, and the initialized value is saved in the noise counter storage means,
When the impact counter current value reaches a predetermined value, the impact counter value is initialized at the current cycle timing, and the initialized value is saved in the impact counter storage means,
If the noise counter current value does not reach a predetermined value, the noise counter current value is saved in the noise counter storage means,
If the impact counter current value does not reach a predetermined value, the impact counter current value is saved in the impact counter storage means,
The radiation counter current value is saved in the radiation counter storage means for each period.
It is characterized by that.

The fourth invention is the configuration described in the first invention,
The signal processing unit
A first signal converter that receives a signal output from the radiation sensor and outputs a first pulse when the signal intensity exceeds a threshold; a radiation counter that converts the number of pulse outputs into a digital count; ,
A second signal converter that receives a signal output from the noise sensor and outputs a second pulse when the intensity of the signal exceeds a threshold;
When the second pulse is input, it outputs one first extended pulse with a fixed time width to the output, and when the second pulse is input again during the first extended pulse output, A first multivibrator circuit for outputting a first extension pulse for a further fixed time; and
A third signal conversion unit that receives a signal output from the impact sensor and outputs a third pulse when the intensity exceeds a threshold;
When the third pulse is input, it outputs one second extended pulse with a fixed time width to the output, and when the third pulse is input again during the second extended pulse output, A second multivibrator circuit for outputting a second extended pulse for a certain period of time;
The radiation counter does not count the number of the first pulses when the first extension pulse or the second extension pulse is input,
An arithmetic unit that performs a statistical calculation of the radiation dose according to the count indicated by the radiation counter, and the arithmetic unit includes work storage means.

A fifth aspect of the invention relates to a radiation sensor that detects radiation, a noise sensor that detects electromagnetic noise, and a signal that invalidates a signal output from the radiation sensor when a signal from the noise sensor is recognized. And a processing unit.
A sixth invention includes a radiation sensor that detects radiation, an impact sensor that detects an impact, and a signal processing unit that invalidates a signal output from the radiation sensor when a signal from the impact sensor is recognized, , Including.

  According to the above configuration, it is possible to prevent erroneous detection of radiation caused by noise based on a signal output from the noise sensor or the impact sensor even if noise is generated due to an external electromagnetic wave or vibration shock. .

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a preferred embodiment of the first invention of the present invention, and is a conceptual diagram showing an overall configuration. For example, the apparatus shown in FIG. 1 is a portable personal dosimeter.
The apparatus shown in FIG. 1 includes a power supply 100, a radiation sensor 101, a noise sensor 102, an impact sensor 103, a signal processing unit 104, a display 105, and a resonator 106. In addition to this configuration, a circuit such as a communication unit that communicates with the outside can be added as necessary. The power source 100 is a power source for operating sensors and circuits of each configuration. In the case of a portable personal dosimeter, power is supplied to the circuit using a battery or the like. The radiation sensor 101 is constituted by, for example, a semiconductor detector, and extraneous radiation is detected by this radiation sensor and a signal 108 is output. The noise sensor 102 detects an external electromagnetic wave and outputs a signal 109. The impact sensor 103 detects vibration and impact and outputs a signal 110. The signal 108, the signal 109, and the signal 110 are connected to the signal processing unit 104, respectively.

  FIG. 2 shows a preferred embodiment relating to the second invention, and is an overall device configuration diagram showing an internal configuration of the signal processing unit 104 shown in FIG. In FIG. 2, the signal processing unit 104 includes a signal conversion unit 401, a signal conversion unit 402, a signal conversion unit 403, a radiation counter 408, a noise counter 409, an impact counter 410, and a calculator 404, and the signal 108 is a signal conversion unit. In the unit 401, the signal 109 is connected to the signal conversion unit 402, and the signal 110 is connected to the signal conversion unit 403. Components requiring the same configuration as in FIG.

FIG. 3 is an overall apparatus configuration diagram illustrating the signal conversion unit 401, the signal conversion unit 402, and the signal conversion unit 403 shown in FIG. 2 in more detail. Components requiring the same configuration as in FIGS. 1 and 2 are denoted by the same reference numerals.
In FIG. 3, the signal converter 401 includes an amplifier 501 and a voltage comparator 504, receives the signal 108 output from the radiation sensor 101, amplifies the signal by the amplifier 501, and converts the voltage of the amplified signal 510 into a voltage. The comparator 504 compares the voltage with the reference voltage, and outputs a pulse 405 corresponding to the signal component when the voltage of the signal 510 exceeds the reference voltage.

The signal converter 402 includes an amplifier 502 and a voltage comparator 505. The signal converter 402 receives the signal 109 output from the noise sensor 102, amplifies the signal by the amplifier 502, and the voltage of the amplified signal 511 by the voltage comparator 505. The voltage is compared with the reference voltage, and when the voltage of the signal 511 exceeds the reference voltage, a pulse 406 corresponding to the signal component is output.
The signal converter 403 includes an amplifier 503 and a voltage comparator 506. The signal converter 403 receives the signal 110 output from the impact sensor 103, amplifies the signal by the amplifier 503, and the voltage of the amplified signal 512 by the voltage comparator 506. The voltage is compared with the reference voltage, and when the voltage of the signal 512 exceeds the reference voltage, a pulse 407 corresponding to the signal component is output.

The radiation counter 408 receives the pulse 405 and counts the number thereof, the radiation counter 409 receives the pulse 406 and counts the number thereof, the radiation counter 410 receives the pulse 407 and counts the number thereof, The counter is connected to the calculator 404.
The arithmetic unit 404 is a general microprocessor that repeatedly executes a program every cycle. The memory 411 is used for saving work data in executing the program, and has an area as shown in FIG. 3a for calculating the radiation dose. In FIG. 3 a, the calculation period 404 includes a save memory 1 that saves the value of the radiation counter 408, a save memory 2 that saves the value of the noise counter 409, and a save memory 3 that saves the value of the impact counter 410. The value of the radiation counter 408 obtained at each cycle is saved in the save memory 1 at the above specific address address, and the value of the noise counter 409 obtained at every cycle is saved in the save memory 2 for each cycle. The obtained value of the impact counter 410 is saved in the save memory 3. Although the example in which the memory 411 is provided inside the calculation period 404 is shown, the memory 411 may be connected outside the calculation period 404.

  FIG. 4 shows processing steps for performing the noise removal calculation in the present invention, and is an operation flowchart of the signal processing unit of the apparatus shown in FIG. In FIG. 4, the operation from the program start to point A will be described. A process 601 performs a process of reading the counter values of the radiation counter 408, the noise counter 409, and the impact counter 410. The process 601a reads the save memory 1, the save memory 2, and the save memory 3. The flow of the determination 602, the determination 603, the determination 604, and the processing 605 will be described collectively. As a result of comparing the value of the radiation counter with the value of the save memory 1, when the value is not equal, the value of the noise counter and the value of the save memory 2 are equal, and the value of the impact counter and the value of the save memory 3 are equal, That is, in such a case, it is determined that there is no trace of receiving noise and no trace of radiation is received, radiation dose calculation processing 605 is performed, and the value of the radiation counter and the value of the save memory 1 are compared. If the values are not equal and the value of the noise counter and the value of the save memory 2 are different, or the value of the impact counter and the value of the save memory 3 are different, it is determined that the counter has miscounted due to some noise, and the radiation dose The arithmetic processing 605 is not performed, and when the value of the radiation counter and the value of the save memory 1 are compared, and the values are equal, radiation is performed during one operation cycle of the computing unit 404. Determined to be not received, the radiation dose calculation processing 605 is not performed.

  Next, the operation from point A to point B in FIG. 4 will be described. In the determination 606, it is determined whether or not the value of the noise counter 409 obtained in the process 601 has reached a carry. If the carry has reached a carry, the process proceeds to a process 607 to initialize the value of the noise counter 409. At the same time, the initialized value is saved in the save memory 2. If the value of the noise counter 409 has not reached the carry, the process proceeds to process 608 and the value of the noise counter 409 obtained in process 601 is saved in the save memory 2.

  Next, the operation from point B to point C in FIG. 4 will be described. In the determination 609, it is determined whether or not the value of the impact counter 410 obtained in the process 601 has reached a carry. If the carry has reached a carry, the process proceeds to a process 610 to initialize the value of the impact counter 410. At the same time, the initialized value is saved in the save memory 3, and the process proceeds to step 612. If the counter value has not reached the carry, the process proceeds to process 611, the value of the impact counter 410 obtained in process 601 is saved in the save memory 3, and the process proceeds to process 612. In process 612, the value of the radiation counter 408 obtained in process 601 is saved in the save memory 1.

In this way, it is possible to determine whether the radiation was actually received or whether it was a false detection caused by external noise or impact, and whether or not to calculate the radiation dose can be sorted according to the determination conditions. Therefore, highly accurate and reliable radiation measurement becomes possible.
Note that there is a method of setting a threshold value for the determination value in the comparison determination described in the determinations 603 and 604. In addition, if the threshold value of the determination value can be variably set, it is advantageous because it is possible to control whether or not the radiation dose calculation process is performed based on the magnitude of noise reception frequency.

  FIG. 5 is a timing chart showing the operation shown in the apparatus shown in FIG. This timing chart explains the overall operation for simulating the case of receiving radiation and the case of receiving noise. In FIG. 5, since the signal 108, signal 109, and signal 110 are not output during the operation unit operating periods P0 to P2, no radiation is detected, and no noise caused by radio waves or impacts is detected. The values of the radiation counter 408, noise counter 409, and impact counter are “0”. Accordingly, since there is no change in the radiation counter, no arithmetic processing is performed in the arithmetic unit operation cycles P0 to P2.

  During the operation unit operating periods P2 to P3, the radiation sensor 101 and the noise sensor 102 react due to some external noise, and the signal 108 and the signal 109 are output, and are amplified by the amplifier 501 and the amplifier 502, respectively. 511 is output. Signal 510 and signal 511 are pulsed by voltage comparator 504 and voltage comparator 505, and pulse 405 and pulse 406 are output. By outputting the pulse 405 and the pulse 406, the radiation counter 408 and the noise counter 409 count and become “1”, respectively. Since the value of the radiation counter 408 changes from “0” to “1” between P2 and P3, there is a possibility that some radiation has been detected, but the value of the noise counter 409 is also “0” to “1”. Therefore, the count performed by the radiation counter 408 during the calculator operation periods P2 to P3 is determined as an erroneous count caused by noise, and the radiation dose calculation process is not performed.

  During the operation period P4 to P5, the radiation sensor 101 and the impact sensor 103 react due to some external impact, and the signal 108 and the signal 110 are output, and are amplified by the amplifier 501 and the amplifier 503, respectively. 512 is output. The signal 510 and the signal 512 are pulsed by the voltage comparator 504 and the voltage comparator 506, and a pulse 405 and a pulse 407 are output. By outputting the pulse 405 and the pulse 407, the value of the radiation counter 408 changes from “1” to “2”, and the value of the impact counter 410 changes from “0” to “1”. Since the value of the radiation counter 408 changes from “1” to “2” between P4 and P5, there is a possibility that some radiation has been detected, but the value of the impact counter 410 changes from “0” to “1”. Therefore, it is determined that the count performed by the radiation counter 408 during the calculator operation periods P4 to P5 is an erroneous count caused by noise, and the radiation dose calculation process is not performed.

  During the operation period P5 to P6, the radiation sensor 101 reacts upon detection of radiation, and the signal 108 is output. The signal is amplified by the amplifier 501 and the signal 510 is output. The signal 510 is pulsed by the voltage comparator 504 and a pulse 405 is output. As the pulse 405 is output, the value of the radiation counter 408 changes from “2” to “3”. Since the value of the radiation counter 408 changes from “2” to “3” during the calculator operation periods P5 to P6, and the values of the noise counter 409 and the impact counter 410 do not change, the count at which normal radiation is detected. The radiation dose calculation process is performed.

  During the operation unit operating periods P6 to P7, the radiation dose calculation process is performed because it is a count of detected normal radiation based on the same idea as P5 to P6. Since there are no changes in the values of the radiation counter 408, noise counter 409, and impact counter 410 during the operation unit operating periods P7 to P10, no arithmetic processing is performed.

  During the operation period P10 to P11, the radiation sensor 101, the noise sensor 102, and the impact sensor react due to some external noise, and the signal 108, the signal 109, and the signal 110 are output. The amplifier 501, the amplifier 502, and the amplifier are respectively output. The signal 510, the signal 511, and the signal 512 are output after being amplified at 503. Signal 510, signal 511, and signal 512 are pulsed by voltage comparator 504, voltage comparator 505, and voltage comparator 506, and pulse 405, pulse 406, and pulse 407 are output. By outputting the pulse 405, the pulse 406, and the pulse 407, the radiation counter 408, the noise counter 409, and the impact counter 410 count and increment each count by +1. Since the value of the radiation counter 408 has changed between the calculator operation periods P10 to P11, there is a possibility that some radiation has been detected, but the values of the noise counter 409 and the impact counter 410 have also changed. The counting up of the radiation counter 408 during the operation period P10 to P11 is determined to be an erroneous count caused by noise, and the radiation dose calculation process is not performed. For the sake of convenience, the values of various counters are indicated with “0” as the starting point.

  FIG. 6 shows a preferred embodiment relating to the fourth invention, and is an overall device configuration diagram showing an internal configuration of the signal processing unit 104 shown in FIG. In FIG. 6, the signal processing unit 104 includes a signal conversion unit 401, a signal conversion unit 402, a signal conversion unit 403, a radiation counter 700, a multivibrator circuit 701, a multivibrator circuit 702, and a calculator 404. Note that components having the same configurations as those in FIGS. 1, 2, and 3 are denoted by the same reference numerals.

The signal conversion unit 401 includes an amplifier 501 and a voltage comparator 504. The signal converter 401 receives the signal 108 output from the radiation sensor 101, amplifies the signal by the amplifier 501, and the voltage of the amplified signal 510 by the voltage comparator 504. When the voltage of the signal 510 exceeds the reference voltage, a pulse 405 corresponding to the signal component is output.
The signal converter 402 includes an amplifier 502 and a voltage comparator 505. The signal converter 402 receives the signal 109 output from the noise sensor 102, amplifies the signal by the amplifier 502, and the voltage of the amplified signal 511 by the voltage comparator 505. When the voltage of the signal 511 exceeds the reference voltage, a pulse 406 corresponding to the signal component is output.

The signal conversion unit 403 includes an amplifier 503 and a voltage comparator 506, receives the signal 110 output from the shock sensor 102, amplifies the signal by the amplifier 503, and a voltage comparator 506 converts the voltage of the amplified signal 512 by the voltage comparator 506. When the voltage of the signal 512 exceeds the reference voltage, a pulse 407 corresponding to the signal component is output.
The multivibrator circuit 701 receives the pulse 406, outputs a signal 703, which is a single pulse signal with an extended width of a predetermined time, and receives the pulse 406 again while the signal 703 is output. It is a multivibrator circuit that outputs only.

The multivibrator circuit 702 receives the pulse 407, outputs a signal 704 which is a single pulse signal with an extended width of a certain time as an output, and receives the pulse 407 again during the output of the signal 704, and further receives the signal 704 for a certain time. It is a multivibrator circuit that outputs only.
When the signal 703 and the signal 704 are output, the signal indicates a trace of reception of some noise. By using this signal to perform counting control of the radiation counter 408, erroneous counting due to noise can be prevented.

The radiation counter 700 is a counter with a count enable that does not count the pulse 405 when either the signal 703 or the signal 704 is valid, and counts the pulse 405 when both the signal 703 and the signal 704 are invalid.
As described above, when both the signal 703 and the signal 704 are invalid, it is possible to prevent the erroneous count caused by the noise reception by counting the pulses 405 by enabling the so-called noise reception is not recognized. .

  The computing unit 404 is a general microprocessor that repeatedly executes a program every cycle. The count indicated by the radiation counter 700 is referred to every period, and when a change is recognized in the value, the radiation dose is calculated. The memory 411 is used for saving work data when executing a program. Although the illustrated memory 411 is provided inside the calculation period 404, the memory 411 may be connected outside the calculation period 404.

  FIG. 7 is a timing chart for explaining the operation of the fourth invention. 6 and 7, since the signals 108, 109, and 110 are not output during the operation unit operating periods P0 to P2, no radiation is detected, and no noise caused by radio waves or shocks is detected. The values of the radiation counter 408, the noise counter 409, and the impact counter are “0”. Since there is no change in the radiation counter, no arithmetic processing is performed between the arithmetic unit operation periods P0 to P2.

  During the operation period P2 to P3, the radiation sensor 101 and the noise sensor 102 react due to some external noise, and the signal 108 and the signal 109 are output, which are amplified by the amplifier 501 and the amplifier 502, respectively, and the signal 510 and the signal 511 is output. Signal 510 and signal 511 are pulsed by voltage comparator 504 and voltage comparator 505, and pulse 405 and pulse 406 are output. By outputting the pulse 406, the multivibrator circuit 701 outputs a signal 703 with an extended pulse length. When the signal 703 is at the H level, the radiation counter 408 does not perform the counting operation, so the value of the radiation counter 408 remains “0” and does not change. The calculator 404 checks a change in the value of the radiation counter every operation cycle, and performs a radiation dose calculation process when the change is recognized in the value.

  During the operation period P4 to P5, the radiation sensor 101 and the impact sensor 102 react due to some external impact, and the signal 108 and the signal 110 are output, and are amplified by the amplifier 501 and the amplifier 503, respectively. 512 is output. The signal 510 and the signal 512 are pulsed by the voltage comparator 504 and the voltage comparator 506, and a pulse 405 and a pulse 407 are output. When the pulse 407 is output, the multivibrator circuit 702 outputs a signal 704 with an extended pulse length. When the signal 704 is at the H level, the radiation counter 408 does not perform the counting operation, so the value of the radiation counter 408 remains “0” and does not change. The calculator 404 checks the change of the value of the radiation counter every cycle, and performs the radiation dose calculation process when the change is recognized in the value.

  During the operation period P5 to P6, the radiation sensor 101 reacts upon detection of radiation, and the signal 108 is output. The signal is amplified by the amplifier 501 and the signal 510 is output. The signal 510 is pulsed by the voltage comparator 504 and a pulse 405 is output. Since both the signal 703 and the signal 704 are L, the pulse 405 is counted by the radiation counter 408, and the value becomes “1”. Since the value of the radiation counter 408 has changed from “0” to “1” during P5 to P6, in this case, a radiation dose calculation process is performed.

  During the calculator operation periods P6 to P7, the radiation dose calculation process is performed because the count value of the radiation counter 408 has changed from “1” to “2”.

  Since there is no change in the value of the radiation counter 408 during the calculation period operation cycles P7 to P10, the calculation process is not performed.

  During the operation period P10 to P11, the radiation sensor 101, the noise sensor 102, and the impact sensor react due to some external noise, and the signal 108, the signal 109, and the signal 110 are output. The amplifier 501, the amplifier 502, and the amplifier are respectively output. The signal 510, the signal 511, and the signal 512 are output after being amplified at 503. Signal 510, signal 511, and signal 512 are pulsed by voltage comparator 504, voltage comparator 505, and voltage comparator 506, and pulse 405, pulse 406, and pulse 407 are output. The multivibrator circuit 701 outputs a signal 703 in which the pulse length is extended by the output of the pulse 406. Since the pulse 406 is received during the output of the signal 703, the multivibrator circuit 701 further outputs the signal 703. The multivibrator circuit 702 outputs a signal 704 obtained by extending the pulse length by outputting the pulse 407. The signals 703 and 704 are count enable signals of the radiation counter 408. When the signal 704 is at the H level, the radiation counter 408 does not perform the counting operation, and the value of the radiation counter 408 remains “2”. Do not perform arithmetic processing. For the sake of convenience, the values of various counters are indicated with “0” as the starting point.

  FIG. 8 is a conceptual diagram showing the overall configuration in a preferred embodiment relating to the fifth invention of the present invention, and is a portable personal dose focused on preventing malfunction due to noise caused by external electromagnetic waves of the apparatus shown in FIG. It is a total. The apparatus shown in FIG. 8 includes a power supply 100, a radiation sensor 101, a noise sensor 102, a signal processing unit 204, a display 105, and a resonator 106. In addition to this configuration, a circuit such as a communication unit that communicates with the outside can be added as necessary. The power source 100 is a power source for operating sensors and circuits of each configuration. In the case of a portable personal dosimeter, power is supplied to the circuit using a battery or the like. The radiation sensor 101 is composed of, for example, a semiconductor detector, and external radiation is detected by the radiation sensor 101 and a signal 108 is output. The noise sensor 102 detects an external electromagnetic wave and outputs a signal 109. Each of the signal 108 and the signal 109 is connected to the signal processing unit 204. This apparatus is obtained by removing the impact sensor 103 from the apparatus shown in FIG. 1, and a small and inexpensive dosimeter can be realized by removing an internal circuit for the purpose of impact detection. Components requiring the same configuration as in FIG.

FIG. 9 is an overall configuration diagram of the apparatus illustrating the signal processing unit 204 shown in FIG. 8 in detail. In addition, the thing which requires the same structure as the structure relevant to FIG.
In FIG. 9, the signal processing unit 204 includes a signal conversion unit 401 including an amplifier 501 and a voltage comparator 504, a signal conversion unit 402 including an amplifier 502 and a voltage comparator 505, a radiation counter 408, and a noise counter 409. , A calculator 404 and a memory 412.

  The arithmetic unit 404 is a general microprocessor that repeatedly executes a program every cycle. The memory 412 is used for saving work data in executing the program, and has an area as shown in FIG. 9a for calculating the radiation dose. In FIG. 9a, in the calculation period 404, the save memory 1 that saves the value of the radiation counter 408 and the save memory 2 that saves the value of the noise counter 409 are arranged at specific address addresses on the memory 412, and are obtained every period. The obtained value of the radiation counter 408 is saved in the save memory 1, and the value of the noise counter 409 obtained for each period is saved in the save memory 2. Although the example in which the memory 412 is provided inside the calculation period 404 is shown, the memory 412 may be connected outside the calculation period 404.

  The operation will be described in detail. The signal 108 output from the radiation sensor 101 is amplified by an amplifier 501, and the voltage of the amplified signal 510 is compared with a reference voltage by a voltage comparator 504. When the voltage of the signal 510 exceeds the reference voltage, the signal component is obtained. A corresponding pulse 405 is output, and the pulse 405 is counted by the radiation counter 408. The signal 109 output from the noise sensor 102 is amplified by the amplifier 502, and the voltage of the amplified signal 511 is compared with the reference voltage by the voltage comparator 505. When the voltage of the signal 511 exceeds the reference voltage, the signal component is converted into the signal component. A corresponding pulse 406 is output, and the pulse 406 is counted by the radiation counter 409.

  The processing steps for performing the noise removal calculation in the fifth invention will be described with reference to FIG. Note that the same reference numerals are used for the same processes as those in FIG. In FIG. 10, the operation from program start to point A will be described. A process 601 performs a process of reading the counter values of the radiation counter 408 and the noise counter 409. A process 601a reads the save memory 1 and the save memory 2. The flow of the determination 602, the determination 603, and the processing 605 will be described collectively. As a result of comparing the value of the radiation counter and the value of the evacuation memory 1, when the value is not equal and the value of the noise counter and the value of the evacuation memory 2 are equal, that is, in this case, there is no trace of receiving noise. It is determined that there is a trace of radiation, and the radiation dose calculation process 605 is performed. As a result of comparing the value of the radiation counter with the value of the save memory 1, the values are not equal, and the noise counter value and the save memory 2 If the values are different, it is determined that the counter has miscounted due to some noise, and the radiation dose calculation processing 605 is not performed. If the values of the radiation counter and the value of the save memory 1 are compared, It is determined that no radiation has been received during one operation cycle of the device 404, and the radiation dose calculation processing 605 is not performed.

  Next, the operation from point A to point B in FIG. 10 will be described. In the determination 606, it is determined whether or not the value of the noise counter 409 obtained in the process 601 has reached a carry. If the carry has reached a carry, the process proceeds to a process 607 to initialize the value of the noise counter 409. At the same time, the initialized value is saved in the save memory 2. If the value of the noise counter 409 has not reached the carry, the process proceeds to process 608 and the value of the noise counter 409 obtained in process 601 is saved in the save memory 2.

Next, the operation from point B to point C in FIG. 10 will be described. In process 612, the value of the radiation counter 408 obtained in process 601 is saved in the save memory 1.
By doing this, it is possible to determine whether the radiation was actually received or whether it was a false detection caused by external noise, and whether to perform the radiation dose calculation under that judgment condition can be distributed, Accurate and reliable radiation measurement is possible.

  FIG. 11 is a conceptual diagram showing the overall configuration of a preferred embodiment relating to the sixth invention of the present invention, and is a portable personal dosimeter that focuses on prevention of malfunction due to noise caused by the impact of the apparatus shown in FIG. It is. The apparatus shown in FIG. 11 includes a power supply 100, a radiation sensor 101, a noise sensor 102, a signal processing unit 304, a display 105, and a resonator 106. In addition to this configuration, a circuit such as a communication unit that communicates with the outside can be added as necessary. The power source 100 is a power source for operating sensors and circuits of each configuration. In the case of a portable personal dosimeter, power is supplied to the circuit using a battery or the like. The radiation sensor 101 is constituted by, for example, a semiconductor detector, and extraneous radiation is detected by this radiation sensor and a signal 108 is output. The noise sensor 102 detects an external electromagnetic wave and outputs a signal 109. The signal 108 and the signal 109 are each connected to the signal processing unit 304. This apparatus is obtained by removing the noise sensor 102 from the apparatus shown in FIG. 1, and a small and inexpensive dosimeter can be realized by removing an internal circuit intended to remove external electromagnetic noise. Components requiring the same configuration as in FIG.

FIG. 12 is an overall configuration diagram of the apparatus illustrating the signal processing unit 304 shown in FIG. 11 in detail. In addition, the thing which requires the same structure as the structure relevant to FIG.
In FIG. 12, a signal processing unit 304 includes a signal conversion unit 401 configured by an amplifier 501 and a voltage comparator 504, a signal conversion unit 403 configured by an amplifier 503 and a voltage comparator 506, a radiation counter 408, an impact counter 410, , An arithmetic unit 404 and a memory 413.

  The arithmetic unit 404 is a general microprocessor that repeatedly executes a program every cycle. The memory 413 is used for saving work data in executing the program, and has an area as shown in FIG. 12a for calculating the radiation dose. In FIG. 12a, in the calculation period 404, the save memory 1 that saves the value of the radiation counter 408 and the save memory 3 that saves the value of the impact counter 410 are arranged at specific address addresses on the memory 413, and are obtained every period. The value of the radiation counter 408 obtained is saved in the save memory 1, and the value of the impact counter 410 obtained for each cycle is saved in the save memory 3. Although the example in which the memory 413 is provided inside the calculation period 404 is shown, the memory 413 may be connected outside the calculation period 404.

  The operation will be described in detail. The signal 108 output from the radiation sensor 101 is amplified by an amplifier 501, and the voltage of the amplified signal 510 is compared with a reference voltage by a voltage comparator 504. When the voltage of the signal 510 exceeds the reference voltage, the signal component is obtained. A corresponding pulse 405 is output, and the pulse 405 is counted by the radiation counter 408. The signal 110 output from the impact sensor 103 is amplified by the amplifier 503, and the voltage of the amplified signal 512 is compared with the reference voltage by the voltage comparator 506. When the voltage of the signal 512 exceeds the reference voltage, the signal component is converted into the signal component. A corresponding pulse 407 is output and the pulse 407 is counted by the impact counter 410.

  Processing steps for performing the noise removal calculation in the sixth invention will be described with reference to FIG. Note that the same reference numerals are used for the same processes as those in FIG. In FIG. 13, the operation from program start to point A will be described. A process 601 performs a process of reading the counter values of the radiation counter 408 and the impact counter 410. A process 601a reads the save memory 1 and the save memory 3. The flow of the determination 602, the determination 604, and the processing 605 will be described collectively. As a result of comparing the value of the radiation counter with the value of the evacuation memory 1, when the value is not equal and the value of the impact counter and the value of the evacuation memory 3 are equal, that is, in this case, there is no trace of receiving noise. It is determined that a trace of radiation remains, and a radiation dose calculation process 605 is performed. As a result of comparing the value of the radiation counter with the value of the save memory 1, the values are not equal, and the value of the impact counter and the save memory 3 If the values are different from each other, it is determined that the counter has erroneously counted due to some noise, and the radiation dose calculation processing 605 is not performed. It is determined that no radiation has been received during one operation cycle of the device 404, and the radiation dose calculation processing 605 is not performed.

  Next, the operation from point A to point C in FIG. 13 will be described. In the determination 609, it is determined whether or not the value of the impact counter 410 obtained in the process 601 has reached a carry. If the carry has reached a carry, the process proceeds to a process 610 to initialize the value of the impact counter 410. At the same time, the initialized value is saved in the save memory 3. When the value of the impact counter 410 has not reached the carry, the process proceeds to process 611 and the value of the impact counter 410 obtained in process 601 is saved in the save memory 3. In process 612, the value of the radiation counter 408 obtained in process 601 is saved in the save memory 1.

In this way, it is possible to determine whether the radiation is actually received or whether it is a false detection caused by the noise caused by the impact, and whether to calculate the radiation dose according to the determination condition Therefore, highly accurate and reliable radiation measurement can be performed.
In general, it is preferable to use a single sensor having both functions of the noise sensor 102 and the impact sensor 103. By using a sensor that detects both external electromagnetic noise and impact noise, an amplifier and a voltage comparator Therefore, the assets of the counter can be reduced, and a high-performance and small-sized radiation measuring device can be realized.

Industrial applicability

  According to the present invention, it is possible to measure radiation with high accuracy by removing noise caused by radio waves, vibration shocks, etc., and a wide range of applicability in all fields of radiation measurement and noise removal methods can be expected. In particular, the utility value for portable personal dosimeters is great.

The figure which shows embodiment regarding Claim 1 of this invention The figure which shows embodiment regarding Claim 2 of this invention Detailed view showing an embodiment of claim 2 of the present invention The figure which shows the working memory area of this invention The flowchart figure which shows embodiment regarding Claim 3 of this invention Operation timing chart showing an embodiment of the present invention The figure which shows embodiment regarding Claim 4 of this invention Operation timing chart showing an embodiment of the present invention The figure which shows embodiment regarding Claim 5 of this invention The figure which shows embodiment regarding Claim 5 of this invention The figure which shows the working memory area regarding claim 5 of this invention The flowchart figure which shows embodiment regarding Claim 5 of this invention The figure which shows embodiment concerning Claim 6 of this invention The figure which shows embodiment concerning Claim 6 of this invention The figure which shows the working memory area regarding claim 6 of this invention The flowchart figure which shows embodiment regarding Claim 6 of this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Power supply 101 ... Radiation sensor 102 ... Noise sensor 103 ... Impact sensor 104, 204, 304 ... Signal processing part 105 ... Display device 106 ... Resonator 108 ... Signal 109 ... Signal 110 ... Signal

401, 402, 403 ... signal conversion unit 404 ... computing units 405, 406, 407 ... pulse 408 ... radiation counter 409 ... noise counter 410 ... impact counter 411, 412, 413 ... memory

501, 502, 503... Amplifier 504, 505, 506... Voltage comparator 510, 511, 512.

601 605 607 608 610 611 612 processing 602 603 604 determination

700 ... Radiation counters 701, 702 ... Multivibrator circuits 703, 704 ... Signals

P0-P12 ... Calculator operation cycle

Claims (6)

A radiation sensor for detecting radiation;
A noise sensor that detects electromagnetic noise;
An impact sensor for detecting impact,
When at least one of the signal from the noise sensor or the signal from the impact sensor is recognized, a signal processing unit that invalidates the signal output from the radiation sensor;
A radiation measurement apparatus comprising: The apparatus of claim 1.
The signal processing unit
A first signal converter that receives a signal output from the radiation sensor and outputs a pulse when the intensity of the signal exceeds a threshold; a radiation counter that converts the number of pulse outputs into a digital count;
A second signal converter that receives a signal output from the noise sensor and outputs a pulse when the intensity of the signal exceeds a threshold; a noise counter that converts the number of pulse outputs into a digital count;
A third signal converter that receives a signal output from the impact sensor and outputs a pulse when the intensity of the signal exceeds a threshold; an impact counter that converts the number of pulse outputs into a digital count;
A radiation measuring apparatus comprising: a computing unit that performs statistical calculation of radiation dose according to the counts indicated by the radiation counter, the noise counter, and the impact counter, and the computing unit includes a working storage unit. A noise elimination calculation method in the apparatus according to claim 2,
The arithmetic unit repeats arithmetic processing every cycle,
Radiation counter storage means for saving the value of the radiation counter;
Noise counter storage means for saving the value of the noise counter;
Impact counter storage means for saving the value of the impact counter;
With
The value of the radiation counter storage means saved one cycle ago is the radiation counter previous value, the radiation counter value obtained in the current cycle is the radiation counter current value,
The value of the noise counter storage means saved before the one cycle is the previous value of the noise counter, the value of the noise counter obtained in the current cycle is the noise counter current value,
The value of the impact counter storage means saved in the previous cycle is the impact counter previous value, the value of the impact counter obtained in the current cycle is the impact counter current value,
The radiation counter previous value and the radiation counter current value are compared, the noise counter previous value and the noise counter current value are compared, and the impact counter previous value and the impact counter current value are compared. And
When the radiation counter previous value is different from the radiation counter current value, the noise counter previous value and the noise counter current value are equal, and the impact counter previous value and the impact counter current value are equal, the radiation dose calculation process Run
When the previous value of the radiation counter is different from the current value of the radiation counter, the previous value of the noise counter is different from the current value of the noise counter, or when the previous value of the impact counter is different from the current value of the impact counter, the radiation dose calculation is performed. Do not execute the process,
If the previous value of the radiation counter and the current value of the radiation counter are equal, the radiation dose calculation process is not performed,
When the noise counter current value reaches a predetermined value, the noise counter value is initialized at the current cycle timing, and the initialized value is saved in the noise counter storage means,
When the impact counter current value reaches a predetermined value, the impact counter value is initialized at the current cycle timing, and the initialized value is saved in the impact counter storage means,
If the noise counter current value does not reach a predetermined value, the noise counter current value is saved in the noise counter storage means,
If the impact counter current value does not reach a predetermined value, the impact counter current value is saved in the impact counter storage means,
The radiation counter current value is saved in the radiation counter storage means for each period.
A noise elimination calculation method characterized by the above. The apparatus of claim 1.
The signal processing unit
A first signal converter that receives a signal output from the radiation sensor and outputs a first pulse when the signal intensity exceeds a threshold; a radiation counter that converts the number of pulse outputs into a digital count; ,
A second signal converter that receives a signal output from the noise sensor and outputs a second pulse when the intensity of the signal exceeds a threshold;
When the second pulse is input, it outputs one first extended pulse with a fixed time width to the output, and when the second pulse is input again during the first extended pulse output, A first multivibrator circuit for outputting a first extension pulse for a further fixed time; and
A third signal conversion unit that receives a signal output from the impact sensor and outputs a third pulse when the intensity exceeds a threshold;
When the third pulse is input, it outputs one second extended pulse with a fixed time width to the output, and when the third pulse is input again during the second extended pulse output, A second multivibrator circuit for outputting a second extended pulse for a certain period of time;
The radiation counter does not count the number of the first pulses when the first extension pulse or the second extension pulse is input,
A radiation measuring apparatus comprising: a computing unit that performs a statistical calculation of radiation dose according to the count indicated by the radiation counter, and the computing unit includes a working storage unit. A radiation sensor for detecting radiation;
A noise sensor that detects electromagnetic noise;
When a signal from the noise sensor is recognized, a signal processing unit that invalidates the signal output from the radiation sensor;
A radiation measurement apparatus comprising: A radiation sensor for detecting radiation;
An impact sensor for detecting impact,
When a signal from the impact sensor is recognized, a signal processing unit that invalidates the signal output from the radiation sensor,
A radiation measurement apparatus comprising:

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