CN106199671A - A kind of measurement processing method of radioprotective close rate and radioprotective detection equipment - Google Patents
A kind of measurement processing method of radioprotective close rate and radioprotective detection equipment Download PDFInfo
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- CN106199671A CN106199671A CN201610476305.9A CN201610476305A CN106199671A CN 106199671 A CN106199671 A CN 106199671A CN 201610476305 A CN201610476305 A CN 201610476305A CN 106199671 A CN106199671 A CN 106199671A
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- radiation dose
- dose rate
- radioprotective
- sudden change
- rate
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
- G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
- G01T1/02—Dosimeters
Abstract
The invention discloses measurement processing method and the radioprotective detection equipment of a kind of radioprotective close rate, including: carry out radiating particle detection, radiating particle according to detecting is calculated radiation dose rate, judge whether to detect that radiation dose rate is undergone mutation and compared the sudden change moment during X detection and be in mutation status, if, when the moment detection number of times to current time that suddenlys change is less than or equal to M, as radioprotective close rate output valve and will export to the meansigma methods of each radiation dose rate of current time from the sudden change moment;It is calculated average core radiation dose rate if it does not, be averaged with the radiation dose rate detected for first M time according to current radiation dose rate and export.The measurement processing side of the radioprotective close rate of the present invention is improved on the basis of consecutive mean counting method, can quickly respond in the sudden change of environmental radiation dose rate numerical value, and real-time performance is good, and detection efficiency is high.
Description
Technical field
The present invention relates to radioprotective detection technique field, particularly relate to a kind of radioprotective close rate measurement processing method and
Radioprotective detection equipment.
Background technology
Portable small-sized radioprotective detection equipment, because detection sensor bulk is limited, when detecting radioprotective close rate,
Numerical fluctuations is the biggest, uses consecutive mean counting method so most, and this kind of algorithm measurement data fluctuations is little, and numerical value shows
Stable, rate of false alarm can be reduced.But, owing to consecutive mean counting needs the multi-group data in a period of time is done average algorithm,
So the shortcoming of this algorithm to be response speed slow, especially when in environment, radiation dose rate instantaneous variation is bigger when, because of
Being substituted into doing averagely for front value, change in value is slow, and real-time response performance is poor.
Summary of the invention
For solving above-mentioned technical problem, the invention provides measurement processing method and the radioprotective of a kind of radioprotective close rate
Detection equipment.
The measurement processing method of the radioprotective close rate that the present invention provides, including:
Carrying out radiating particle detection, the radiating particle according to detecting is calculated radiation dose rate, it may be judged whether detection
Undergo mutation to radiation dose rate and during X detection, compare the sudden change moment and be in mutation status, if it is, prominent
Become the moment to the detection number of times of current time less than or equal to M time, by from the sudden change moment to each radiation dose rate of current time
Meansigma methods as radioprotective close rate output valve and export, at the detection number of times in sudden change moment to current time more than M
Time, it is averaged according to current radiation dose rate and the radiation dose rate detected for first M time and is calculated average core radiation agent
Dose rate also exports;Calculate if it does not, be averaged with the radiation dose rate detected for first M time according to current radiation dose rate
To average core radiation dose rate and export.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
Described method specifically includes:
Step 1, carries out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate;According to working as
Front radiation dose rate is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate;
Step 2, it is judged that whether described current radiation dose rate is more than N times of described average core radiation dose rate;If
It is, it is judged that whether sudden change instruction parameter is effective status, if not effective status, using current time as the sudden change moment, and
Sudden change instruction parameter is set to effective status, accumulative for sudden change parameter is set to initial value, if effective status, will sudden change
Accumulative parameter adds up fixed interval, forwards step 3 to, if it does not, by described average core radiation dose rate calculated in step 1
As radioprotective close rate output valve and export, forward step 1 to;
Step 3, it is judged that the accumulative parameter of sudden change has added up X fixed interval the most, if it is, arrange sudden change instruction parameter
For disarmed state, when the detection number of times in sudden change moment to current time is less than or equal to M, by from the sudden change moment to current time
The meansigma methods of each radiation dose rate is as radioprotective close rate output valve and exports, the detection in sudden change moment to current time
When number of times is more than M, using current radiation dose rate with the meansigma methods of radiation dose rate detected for first M time as radioprotective dosage
Rate output valve also exports, and forwards step 1 to, if it does not, using average core radiation dose rate calculated in step 1 as core
Radiation dose rate output valve also exports, and forwards step 1 to.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
In described step 1, determine described in the grade residing for value of radiating particle that detects, export corresponding with described grade
The prompt tone of frequency, the frequency of the highest corresponding prompt tone of value of described radiating particle is the highest.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
Described radiating particle is in grading range, and the value range of each grade is identical, or along with radiating in grading range
The value range of the most each grade of value of particle is gradually reduced.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
Described N is the value in the range of 10~20.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
Described M is the value in the range of 30~50.
The measurement processing method of above-mentioned radioprotective close rate also has the following characteristics that
Described X is the value in the range of 3~10.
The radioprotective detection equipment that the present invention provides includes: detection module, judge module, the first processing module, at second
Reason module;
Described detection module, is used for carrying out radiating particle detection, is calculated radiation agent according to the radiating particle detected
Dose rate;
Judge module, is used for judging whether to detect that radiation dose rate is undergone mutation and compares during X detection
The sudden change moment is in mutation status;
First processing module, for when the judged result of described judge module is for being, in the sudden change moment to current time
Detection number of times less than or equal to M time, using from the sudden change moment to the meansigma methods of each radiation dose rate of current time as core spoke
Penetrate close rate output valve and export, when the moment detection number of times to current time that suddenlys change is more than M, according to current radiation
Close rate is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate and exports;
Second processing module, for when the judged result of described judge module is no, according to current radiation dose rate
It is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate and exports.
Radioprotective detection equipment also has the following characteristics that
Described radioprotective detection equipment also includes reminding module;
Described detection module, is additionally operable to the grade residing for value of radiating particle that detects described in determining and notifies to the most described
Reminding module;
Described reminding module, for exporting the prompt tone of the frequency corresponding with described grade.
Radioprotective detection equipment also has the following characteristics that
Radioprotective detection equipment includes: arrange module;
Described module is set, determines each grade and notify that the value range making each grade is identical to described detection module, or
Person, along with in grading range, the value range of the most each grade of the value of radiating particle is gradually reduced.
The measurement processing side of the radioprotective close rate of the present invention is improved on the basis of consecutive mean counting method,
The sudden change of environmental radiation dose rate numerical value can quickly respond, and real-time performance is good, and detection efficiency is high;Meanwhile, sensor detection is used
To predecessor accurately judge that radiation level corresponding different radiation level interval carry out auditory tone cues to user accordingly,
Accuracy is high, brings good use to experience to user.
Accompanying drawing explanation
The accompanying drawing of the part constituting the present invention is used for providing a further understanding of the present invention, and the present invention's is schematic real
Execute example and illustrate for explaining the present invention, being not intended that inappropriate limitation of the present invention.In the accompanying drawings:
Fig. 1 is the flow chart of the measurement processing method of embodiment center radiation dose rate;
Fig. 2 is the flow chart of the measurement processing method of specific embodiment center radiation dose rate;
Fig. 3 is the structure chart of embodiment center radiation detecting apparatus.
Detailed description of the invention
For making the purpose of the embodiment of the present invention, technical scheme and advantage clearer, below in conjunction with the embodiment of the present invention
In accompanying drawing, the technical scheme in the embodiment of the present invention is clearly and completely described, it is clear that described embodiment is
The a part of embodiment of the present invention rather than whole embodiments.Based on the embodiment in the present invention, those of ordinary skill in the art
The every other embodiment obtained under not making creative work premise, broadly falls into the scope of protection of the invention.Need
Illustrating, in the case of not conflicting, the embodiment in the application and the feature in embodiment can mutual combination in any.
Fig. 1 is the flow chart of the measurement processing method of embodiment center radiation dose rate.The measured place of radioprotective close rate
Reason method includes: carry out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate, it may be judged whether inspection
Measure radiation dose rate undergo mutation and X time detection during compare sudden change the moment be in mutation status, if it is,
The sudden change moment to the detection number of times of current time less than or equal to M time, by from the sudden change moment to each radiation dose of current time
The meansigma methods of rate is as radioprotective close rate output valve and exports, and is more than to the detection number of times of current time in the sudden change moment
During M, it is averaged according to current radiation dose rate and the radiation dose rate detected for first M time and is calculated average core radiation agent
Dose rate also exports;Calculate if it does not, be averaged with the radiation dose rate detected for first M time according to current radiation dose rate
To average core radiation dose rate and export.
Fig. 2 is the flow chart of the measurement processing method of specific embodiment center radiation dose rate.The survey of radioprotective close rate
Amount processing method specifically includes:
Step 1, carries out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate;According to working as
Front radiation dose rate is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate;
Step 2, it is judged that whether described current radiation dose rate is more than N times of described average core radiation dose rate;If
It is, it is judged that whether sudden change instruction parameter is effective status, if not effective status, using current time as the sudden change moment, and
Sudden change instruction parameter is set to effective status, accumulative for sudden change parameter is set to initial value, if effective status, will sudden change
Accumulative parameter adds up fixed interval, forwards step 3 to, if it does not, by described average core radiation dose rate calculated in step 1
As radioprotective close rate output valve and export, forward step 1 to;
Step 3, it is judged that the accumulative parameter of sudden change has added up X fixed interval the most, if it is, arrange sudden change instruction parameter
For disarmed state, when the detection number of times in sudden change moment to current time is less than or equal to M, by from the sudden change moment to current time
The meansigma methods of each radiation dose rate is as radioprotective close rate output valve and exports, the detection in sudden change moment to current time
When number of times is more than M, using current radiation dose rate with the meansigma methods of radiation dose rate detected for first M time as radioprotective dosage
Rate output valve also exports, and forwards step 1 to, if it does not, using average core radiation dose rate calculated in step 1 as core
Radiation dose rate output valve also exports, and forwards step 1 to.
In said method, step 1 also comprises determining that described in the grade residing for value of radiating particle that detects, output
The prompt tone of the frequency corresponding with grade, the frequency of the highest corresponding prompt tone of value of radiating particle is the highest.Radiating particle is in classification
In the range of, the value range of each grade is identical.It is classified as 5 grades the most altogether, minimum and the difference of peak in the grade of every grade
Identical.Or, along with in grading range, the value range of the most each grade of the value of radiating particle is gradually reduced.
Wherein, N is the value in the range of 10~20, and M is the value in the range of 30~50, and X is the value in the range of 3~10.
Fig. 3 is the structure chart of embodiment center radiation detecting apparatus.With reference to Fig. 3, radioprotective detection equipment includes: detection mould
Block, judge module, the first processing module, the second processing module;
Detection module, is used for carrying out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate;
Judge module, is used for judging whether to detect that radiation dose rate is undergone mutation and compares during X detection
The sudden change moment is in mutation status;
First processing module, for when the judged result of judge module is for being, in the inspection in sudden change moment to current time
When surveying number of times less than or equal to M, using the meansigma methods from the sudden change moment to each radiation dose rate of current time as radioprotective agent
Dose rate output valve also exports, when the moment detection number of times to current time that suddenlys change is more than M, according to current radiation dose
Rate is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate and exports;
Second processing module, for when the judged result of judge module is no, according to current radiation dose rate and front M
The secondary radiation dose rate detected is averaged and is calculated average core radiation dose rate and exports.
Radioprotective detection equipment also includes reminding module;Detection module is additionally operable to determine the value institute of the radiating particle detected
Place grade and notify to reminding module;Reminding module is for exporting the prompt tone of the frequency corresponding with grade.
Radioprotective detection equipment includes: arrange module;Module is set for determining each grade and notifying to detection module, makes
The value range of each grade is identical, or, along with in grading range the value range of the most each grade of the value of radiating particle by
The least.
The measurement processing side of the radioprotective close rate of the present invention is improved on the basis of consecutive mean counting method,
The sudden change of environmental radiation dose rate numerical value can quickly respond, and real-time performance is good, and detection efficiency is high;Meanwhile, sensor detection is used
To predecessor accurately judge that radiation level corresponding different radiation level interval carry out auditory tone cues to user accordingly,
Accuracy is high, brings good use to experience to user.
Descriptions above can combine enforcement individually or in every way, and these variant all exist
Within protection scope of the present invention.
It should be noted that in this article, term " includes ", " comprising " or its any other variant are intended to non-row
Comprising of his property, so that include that the article of a series of key element or equipment not only include those key elements, but also include not
There are other key elements being expressly recited, or also include the key element intrinsic for this article or equipment.There is no more limit
In the case of system, statement " including ... " key element limited, it is not excluded that including article or the equipment of described key element
In there is also other identical element.
Above example is only in order to illustrate technical scheme and unrestricted, reference only to preferred embodiment to this
Bright it is described in detail.It will be understood by those within the art that, technical scheme can be modified
Or equivalent, without deviating from the spirit and scope of technical solution of the present invention, all should contain the claim model in the present invention
In the middle of enclosing.
Claims (10)
1. the measurement processing method of a radioprotective close rate, it is characterised in that including:
Carrying out radiating particle detection, the radiating particle according to detecting is calculated radiation dose rate, it may be judged whether spoke detected
Penetrate close rate undergo mutation and X time detection during compare sudden change the moment be in mutation status, if it is, sudden change time
When the detection number of times carved to current time is less than or equal to M, flat by each radiation dose rate from the sudden change moment to current time
Average is as radioprotective close rate output valve and exports, when the moment detection number of times to current time that suddenlys change is more than M, and root
It is averaged according to current radiation dose rate and the radiation dose rate that detects for first M time and is calculated average core radiation dose rate also
Output;It is calculated average if it does not, be averaged according to current radiation dose rate and the radiation dose rate detected for first M time
Radioprotective close rate also exports.
2. the measurement processing method of radioprotective close rate as claimed in claim 1, it is characterised in that
Described method specifically includes:
Step 1, carries out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate;According to current
Radiation dose rate and the radiation dose rate detected for first M time are averaged and are calculated average core radiation dose rate;
Step 2, it is judged that whether described current radiation dose rate is more than N times of described average core radiation dose rate;If it is, sentence
Whether disconnected sudden change instruction parameter is effective status, if not effective status, using current time as the sudden change moment, and will sudden change
Instruction parameter is set to effective status, and accumulative for sudden change parameter is set to initial value, if effective status, by accumulative for sudden change ginseng
The accumulative fixed interval of number, forward step 3 to, if it does not, using described average core radiation dose rate calculated in step 1 as core
Radiation dose rate output valve also exports, and forwards step 1 to;
Step 3, it is judged that the accumulative parameter of sudden change has added up X fixed interval the most, if it is, be set to nothing by sudden change instruction parameter
Effect state, when the detection number of times in sudden change moment to current time is less than or equal to M, by each spoke from the sudden change moment to current time
The meansigma methods penetrating close rate as radioprotective close rate output valve and exports, the detection number of times in sudden change moment to current time
During more than M, current radiation dose rate is defeated as radioprotective close rate with the meansigma methods of the radiation dose rate detected for first M time
Go out value and export, forwarding step 1 to, if it does not, using average core radiation dose rate calculated in step 1 as radioprotective
Close rate output valve also exports, and forwards step 1 to.
3. the measurement processing method of radioprotective close rate as claimed in claim 1, it is characterised in that including: in described step 1,
Grade residing for the value of the radiating particle detected described in determining, exports the prompt tone of the frequency corresponding with described grade, described
The frequency of the highest corresponding prompt tone of value of radiating particle is the highest.
4. the measurement processing method of radioprotective close rate as claimed in claim 3, it is characterised in that
Described radiating particle is in grading range, and the value range of each grade is identical, or along with radiating particle in grading range
The value range of the most each grade of value be gradually reduced.
5. the measurement processing method of radioprotective close rate as claimed in claim 1, it is characterised in that
Described N is the value in the range of 10~20.
6. the measurement processing method of radioprotective close rate as claimed in claim 1, it is characterised in that
Described M is the value in the range of 30~50.
7. the measurement processing method of radioprotective close rate as claimed in claim 1, it is characterised in that
Described X is the value in the range of 3~10.
8. radioprotective detection equipment, it is characterised in that including: detection module, judge module, the first processing module, the second process
Module;
Described detection module, is used for carrying out radiating particle detection, and the radiating particle according to detecting is calculated radiation dose rate;
Judge module, is used for judging whether to detect that radiation dose rate is undergone mutation and compares sudden change during X detection
Moment is in mutation status;
First processing module, for when the judged result of described judge module is for being, in the inspection in sudden change moment to current time
When surveying number of times less than or equal to M, using the meansigma methods from the sudden change moment to each radiation dose rate of current time as radioprotective agent
Dose rate output valve also exports, when the moment detection number of times to current time that suddenlys change is more than M, according to current radiation dose
Rate is averaged with the radiation dose rate detected for first M time and is calculated average core radiation dose rate and exports;
Second processing module, for when the judged result of described judge module is no, according to current radiation dose rate and front M
The secondary radiation dose rate detected is averaged and is calculated average core radiation dose rate and exports.
9. radioprotective detection equipment as claimed in claim 8, it is characterised in that also include: reminding module;
Described detection module, is additionally operable to the grade residing for value of radiating particle that detects described in determining and notifies to described prompting
Module;
Described reminding module, for exporting the prompt tone of the frequency corresponding with described grade.
10. radioprotective detection equipment as claimed in claim 9, it is characterised in that also include: module is set;
Described module is set, determines each grade and notify that the value range making each grade is identical to described detection module, or,
Along with in grading range, the value range of the most each grade of the value of radiating particle is gradually reduced.
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Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US8053736B2 (en) * | 2006-05-04 | 2011-11-08 | Iba S.A. | Detector response modeling |
CN104360368A (en) * | 2014-12-04 | 2015-02-18 | 江苏超敏仪器有限公司 | Data processing method for pulse signals in personal alarm dosimeter |
CN105158787A (en) * | 2015-06-03 | 2015-12-16 | 南京航空航天大学 | Dose rate detector and dose rate detection method |
CN105301623A (en) * | 2015-09-21 | 2016-02-03 | 赵润林 | Smart radiation detection apparatus and detection method |
CN105408770A (en) * | 2013-07-23 | 2016-03-16 | 日立阿洛卡医疗株式会社 | Radiation measurement device |
-
2016
- 2016-06-24 CN CN201610476305.9A patent/CN106199671B/en active Active
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US8053736B2 (en) * | 2006-05-04 | 2011-11-08 | Iba S.A. | Detector response modeling |
CN105408770A (en) * | 2013-07-23 | 2016-03-16 | 日立阿洛卡医疗株式会社 | Radiation measurement device |
CN104360368A (en) * | 2014-12-04 | 2015-02-18 | 江苏超敏仪器有限公司 | Data processing method for pulse signals in personal alarm dosimeter |
CN105158787A (en) * | 2015-06-03 | 2015-12-16 | 南京航空航天大学 | Dose rate detector and dose rate detection method |
CN105301623A (en) * | 2015-09-21 | 2016-02-03 | 赵润林 | Smart radiation detection apparatus and detection method |
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