CN104655941A - Electromagnetic radiation detection method and device and electronic equipment - Google Patents
Electromagnetic radiation detection method and device and electronic equipment Download PDFInfo
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- CN104655941A CN104655941A CN201510130173.XA CN201510130173A CN104655941A CN 104655941 A CN104655941 A CN 104655941A CN 201510130173 A CN201510130173 A CN 201510130173A CN 104655941 A CN104655941 A CN 104655941A
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Abstract
The embodiment of the invention discloses an electromagnetic radiation detection method, an electromagnetic radiation detection device and electronic equipment. The method comprises the following steps: collecting electromagnetic wave signals at the current position of electronic equipment by virtue of an electromagnetic wave signal collection device of the electronic equipment, so as to obtain multiple sample data; processing the sample data based on electromagnetic wave signal strength to obtain a processing result, wherein the processing result is used for representing total radiation magnetic induction quantity; comparing the total radiation magnetic induction quantity with a preset threshold to determine whether to generate prompt information. In other words, according to the embodiment, the electromagnetic radiation condition is measured based on the total radiation magnetic induction quantity, furthermore, the total radiation magnetic induction quantity is obtained by processing the sampling data based on the electromagnetic wave signal strength (such as a voltage value), so that by measuring the electromagnetic radiation by virtue of the total radiation magnetic induction quantity, the electromagnetic radiation condition can be accurately reflected.
Description
Technical field
The present invention relates to electronic technology field, more particularly, relate to a kind of detection method of electromagnetic radiation, device and electronic equipment.
Background technology
Universal along with industrial development and electronic equipment, electromagnetic radiation pollution is more and more serious, and people wish the electromagnetic radiation pollution situation can learning environment in time, with the environment avoiding electromagnetic radiation pollution serious.Existing electromagnetic radiation dose measurement equipment be directly by electromagnetic wave signal magnitude of voltage or Voltage Peak peak value or using the general radiative collision induction corresponding with Voltage Peak peak value as the physical quantity weighing electromagnetic radiation.But inventor is realizing finding in process of the present invention, current detection method of electromagnetic radiation is too simple, accurately can not reflect the electromagnetic radiation situation of user position.
Summary of the invention
The object of this invention is to provide a kind of detection method of electromagnetic radiation, device and electronic equipment, to detect electromagnetic radiation situation more accurately.
For achieving the above object, the invention provides following technical scheme:
A kind of detection method of electromagnetic radiation, described method comprises:
Gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas;
Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount;
Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.
Said method, preferably, described comparing based on described radiative collision induction total amount and predetermined threshold determines whether that producing information comprises:
Described radiative collision induction total amount and predetermined threshold are compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Determine whether to produce information based on described hazards of electromagnetic radiation grade.
Said method, preferably, also comprises:
Show described some sampled datas and/or described radiative collision induction total amount.
Said method, preferably, also comprises:
Radiative collision induction is obtained based on described some sampled datas;
Show described radiative collision induction.
Said method, preferably, the described electromagnetic wave signal harvester by electronic equipment gathers the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas and comprises:
Whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value;
When the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas.
Said method, preferably, describedly carries out process based on electromagnetic wave signal intensity to several sampled datas described and comprises:
Based on electromagnetic wave signal intensity, integral operation is carried out to several obtained sampled datas.
A kind of electromagnetic radiation detection device, described device comprises:
Acquisition module, for gathering the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas;
Processing module, for processing several sampled datas described based on electromagnetic wave signal intensity, obtains result, and described result is for characterizing radiative collision induction total amount;
Determination module, determines whether to produce information for comparing based on described radiative collision induction total amount and predetermined threshold.
Said apparatus, preferably, described determination module comprises:
Comparing unit, for described radiative collision induction total amount and predetermined threshold being compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Determining unit, produces information for determining whether based on described hazards of electromagnetic radiation grade.
Said apparatus, preferably, also comprises:
First display module, for showing described some sampled datas and/or described radiative collision induction total amount.
Said apparatus, preferably, also comprises:
Acquisition module, for obtaining radiative collision induction based on described some sampled datas;
Second display module, for showing described radiative collision induction.
Said apparatus, preferably, described acquisition module comprises:
Whether monitoring means, exceed predetermined strength value for the intensity of monitoring the electromagnetic wave signal received;
Collecting unit, when the intensity for monitoring out the electromagnetic wave signal received when described monitoring means exceeds predetermined strength value, harvester gathers the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas.
Said apparatus, preferably, described processing module comprises:
Processing unit, for carrying out integral operation based on electromagnetic wave signal intensity to several obtained sampled datas.
A kind of electronic equipment, comprises the electromagnetic radiation detection device as above described in any one.
Known by above scheme, a kind of detection method of electromagnetic radiation, device and electronic equipment that the application provides, gathered the electromagnetic wave signal of the current position of described electronic equipment, obtain several sampled datas by the electromagnetic wave signal harvester of electronic equipment; Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount; Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.That is, in the embodiment of the present invention, electromagnetic radiation situation is weighed based on radiative collision induction total amount, and, radiative collision induction total amount carries out process based on electromagnetic wave signal intensity (as magnitude of voltage) to sampled data to obtain, therefore, by radiative collision induction total amount, measurement is carried out to electromagnetic radiation and can reflect electromagnetic radiation situation more accurately.
Accompanying drawing explanation
In order to be illustrated more clearly in the embodiment of the present invention or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only some embodiments of the present invention, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.
Fig. 1 is the schematic diagram of traditional detection method of electromagnetic radiation;
When Fig. 2 is for using electromagnet radiation detection instrument to detect in actual environment, a kind of waveform of the actual electromagnetic radiation detected;
When Fig. 3 is for using electromagnet radiation detection instrument to detect in actual environment, the another kind of waveform of the actual electromagnetic radiation detected;
A kind of realization flow figure of the detection method of electromagnetic radiation that Fig. 4 provides for the embodiment of the present application;
A kind of structural representation of the electromagnetic radiation detection device that Fig. 5 provides for the embodiment of the present application;
A kind of structural representation of the determination module that Fig. 6 provides for the embodiment of the present application;
The another kind of structural representation of the electromagnetic radiation detection device that Fig. 7 provides for the embodiment of the present application;
Another structural representation of the electromagnetic radiation detection device that Fig. 8 provides for the embodiment of the present application;
A kind of structural representation of the acquisition module that Fig. 9 provides for the embodiment of the present application.
Term " first ", " second ", " the 3rd " " 4th " etc. (if existence) in instructions and claims and above-mentioned accompanying drawing are for distinguishing similar part, and need not be used for describing specific order or precedence.Should be appreciated that the data used like this can be exchanged in the appropriate case, so that the embodiment of the application described herein can be implemented with the order except illustrated here.
Embodiment
Below in conjunction with the accompanying drawing in the embodiment of the present invention, be clearly and completely described the technical scheme in the embodiment of the present invention, obviously, described embodiment is only the present invention's part embodiment, instead of whole embodiments.Based on the embodiment in the present invention, those of ordinary skill in the art, not making the every other embodiment obtained under creative work prerequisite, belong to the scope of protection of the invention.
In order to better the embodiment of the present invention is described, first traditional detection method of electromagnetic radiation is described.The electromagnetic radiation safety standard that current country promulgates is an intensity threshold.As shown in Figure 1, Fig. 1 is the schematic diagram of traditional detection method of electromagnetic radiation.V
0for bias voltage, when pulses of radiation voltage signal exceedes voltage threshold V
thtime, just can report to the police to point out electromagnetic radiation to exceed standard.Needs illustrate, through demarcating the corresponding relation that can obtain between radiation voltage and electromagnetic radiation intensity, usually, radiation voltage is larger, and electromagnetic radiation intensity is stronger.Therefore, when detecting that pulses of radiation voltage exceeds voltage threshold, just mean that corresponding electromagnetic radiation intensity exceedes electromagnetic radiation intensity threshold value EM
th, wherein, electromagnetic radiation intensity threshold value EM
thdemarcate and voltage threshold V for passing through
thcorresponding electromagnetic radiation intensity threshold value.
Inventor is realizing finding in process of the present invention, and traditional is too simple as the detection method of electromagnetic radiation of evaluation electromagnetic radiation intensity using radiation intensity, accurately can not reflect the electromagnetic radiation situation of user position.Concrete,
Find when inventor uses electromagnet radiation detection instrument to detect in actual environment, the actual electromagnetic radiation waveform detected mainly contains Fig. 2 and Fig. 3 two kinds of waveforms.
About radiation intensity, in unit interval Δ t, only have two pulses to exceed threshold value in Fig. 2, and amplitude is larger; In unit interval Δ t, have multiple pulse to exceed threshold value in Fig. 3, but amplitude is less.
Inventor studies discovery, and its radiation amount of large pulse of of short duration existence may be very little, and as electrostatic, pulse height is very large, but its radiation amount is very little, can't produce radiation hazard to human body.And amplitude little (exceeding threshold value) but the much bigger pulse of radiation amount is obviously larger to the harm of health, therefore, traditional is too simple as the detection method of electromagnetic radiation of the standard of evaluation electromagnetic radiation situation using radiation intensity, accurately can not reflect the electromagnetic radiation situation of user position.Based on this, the embodiment of the present invention proposes using electromagnetic radiation total amount as the standard weighing electromagnetic radiation state.
About radiation amount, in Fig. 2 and Fig. 3, dash area corresponds to electromagnetic radiation total amount when electromagnetic radiation intensity exceeds threshold value:
In unit interval Δ t, in observation and comparison Fig. 2 and Fig. 3 dash area area and, the hatched area in visible Fig. 3 and than hatched area in Fig. 2 and large.Namely its electromagnetic radiation total amount of pulse shown in Fig. 3 is larger.
Refer to Fig. 4, a kind of realization flow figure of the detection method of electromagnetic radiation that Fig. 4 provides for the embodiment of the present invention, can comprise:
Step S41: the electromagnetic wave signal being gathered the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtains several sampled datas;
In the embodiment of the present invention, in electronic equipment, be provided with electromagnetic wave signal harvester, in order to gather the electromagnetic wave signal at electronic equipment position place.
When gathering electromagnetic wave signal, electromagnetic wave signal harvester can, by the sampling process of cycle startup to electromagnetic wave signal, namely not be Real-time Collection electromagnetic wave signal, but start sampling process by the cycle, such as, can start a sampling process each second, each sampling duration is 150ms, in the sampling process of this 150ms, sampling interval is 100 μ s, and namely every 100 μ s gather data, like this, in the sampling process of this 150ms, 1500 sampled datas will be obtained.
Wherein, sampling duration is greater than the cycle of fluctuation of signal to be collected, and how many concrete sampling durations is for being determined by experiment.
Step S42: based on electromagnetic wave signal intensity, several sampled datas described are processed, obtain result, described result is for characterizing radiative collision induction total amount;
In the embodiment of the present invention, electromagnetic wave signal intensity can characterize with the magnitude of voltage of electromagnetic wave signal.Radiative collision induction total amount can be characterized by total amount of electric charge.
If start sampling process by the cycle, then, in the embodiment of the present invention, process, obtain result by the cycle based on electromagnetic wave signal intensity to several sampled datas described, described result is for characterizing radiative collision induction total amount.Namely each cycle obtains a result.
Step S43: compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.
In the embodiment of the present invention, radiative collision can be responded to total amount and predetermined threshold compares, to determine whether according to comparative result to produce information.Such as, if it is smaller to go out radiative collision induction total amount by multilevel iudge, when can not produce harm to human body, can not point out.Certainly, also can point out, prompting user current radiation can not produce harm to human body.
Described predetermined threshold can only have one, also can have multiple.Specifically can be determined by experiment according to the actual demand of people.
Described information can be text prompt, also can be voice message, or light prompt etc.
The detection method of electromagnetic radiation that the embodiment of the present invention provides, is gathered the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas by the electromagnetic wave signal harvester of electronic equipment; Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount; Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.That is, in the embodiment of the present invention, electromagnetic radiation situation is weighed based on radiative collision induction total amount, and, radiative collision induction total amount carries out process based on electromagnetic wave signal intensity (as magnitude of voltage) to sampled data to obtain, therefore, by radiative collision induction total amount, measurement is carried out to electromagnetic radiation and can reflect electromagnetic radiation situation more accurately.
Optionally, described comparing based on described radiative collision induction total amount and predetermined threshold determines whether that producing information can comprise:
Described radiative collision induction total amount and predetermined threshold are compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Concrete, different hazards of electromagnetic radiation grades can be divided according to predetermined threshold.Such as, suppose that predetermined threshold has two, be respectively the first predetermined threshold and the second predetermined threshold, and the first predetermined threshold is less than the second predetermined threshold, then, three hazards of electromagnetic radiation grades can be divided into according to predetermined threshold.When radiative collision induction total amount is less than the first predetermined threshold, be in the first hazards of electromagnetic radiation grade; When radiative collision induction total amount is more than or equal to the first predetermined threshold, when being less than the second predetermined threshold, be in the second hazards of electromagnetic radiation grade; When radiative collision induction total amount is more than or equal to the second predetermined threshold, be in the 3rd hazards of electromagnetic radiation grade.Wherein, hazards of electromagnetic radiation higher grade, represents that harm is larger.Hazards of electromagnetic radiation lower grade, endangers less, or be safe from harm (as the lowest class).
Determine whether to produce information based on described hazards of electromagnetic radiation grade.
Optionally, the detection method of electromagnetic radiation that the embodiment of the present invention provides can comprise further:
Show described some sampled datas and/or described radiative collision induction total amount, so that user understands radiation event in more detail.
In the embodiment of the present invention, can showing sampled data in the mode of oscillogram, also directly can show the numerical value of sampled data.
Radiative collision induction total amount can show numerical value.
Certainly, if there is information, can also display reminding information.
Further, the detection method of electromagnetic radiation that the embodiment of the present invention provides can also comprise:
Radiative collision induction is obtained based on described some sampled datas;
Radiative collision induction can be obtained based on the peak-to-peak value of described some sampled datas, concrete, using magnetic induction density corresponding for the peak-to-peak value of described some sampled datas as radiative collision induction.
Show described radiative collision induction.
In the embodiment of the present invention, not only measuring radiation magnetic induction total amount, also measuring radiation magnetic induction density.The dimension that user can be made never same understands magnetic radiation situation.
Such as, the duration section that magnetic induction density exceedes predetermined threshold can be recorded, when judging that magnetic radiation is stronger by radiative collision induction total amount, position when helping user to determine that magnetic radiation induction is stronger residing for it, to avoid again entering that stronger region of magnetic radiation induction.
Optionally, the described electromagnetic wave signal harvester by electronic equipment gathers the electromagnetic wave signal of the current position of described electronic equipment, and obtaining several sampled datas can comprise:
Whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value;
When the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas.
In the embodiment of the present invention, in order to reduce the power consumption of electronic equipment, whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value, only have when the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, just start to carry out collection electromagnetic wave signal, and when the intensity of the electromagnetic wave signal received is less than predetermined strength value, illustrate that electromagnetic wave signal can not produce harm to human body, now electromagnet radiation detection can be carried out, to reduce powder consumption of electronic equipment.
Certainly, whether monitor to judge whether to carry out electromagnet radiation detection for optional function to the intensity of the electromagnetic wave signal received, can be selected by user.
Optionally, describedly based on electromagnetic wave signal intensity, process is carried out to several sampled datas described and can comprise:
Based on electromagnetic wave signal intensity, integral operation is carried out to several obtained sampled datas.Specifically can referring to formula (1).
Corresponding with embodiment of the method, the embodiment of the present invention also provides a kind of electromagnetic radiation detection device, and a kind of structural representation of the electromagnetic radiation detection device that the embodiment of the present invention provides as shown in Figure 5, can comprise:
Acquisition module 51, processing module 52 and determination module 53; Wherein,
Acquisition module 51, for gathering the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas;
When gathering electromagnetic wave signal, acquisition module 51 can, by the sampling process of cycle startup to electromagnetic wave signal, namely not be Real-time Collection electromagnetic wave signal, but start sampling process by the cycle, such as, can start a sampling process each second, each sampling duration is 150ms, in the sampling process of this 150ms, sampling interval is 100 μ s, and namely every 100 μ s gather data, like this, in the sampling process of this 150ms, 1500 sampled datas will be obtained.
Wherein, sampling duration is greater than the cycle of fluctuation of signal to be collected, and how many concrete sampling durations is for being determined by experiment.
Processing module 52, for processing several sampled datas described based on electromagnetic wave signal intensity, obtains result, and described result is for characterizing radiative collision induction total amount;
In the embodiment of the present invention, electromagnetic wave signal intensity can characterize with the magnitude of voltage of electromagnetic wave signal.Radiative collision induction total amount can be characterized by total amount of electric charge.
If start sampling process by the cycle, then, in the embodiment of the present invention, process, obtain result by the cycle based on electromagnetic wave signal intensity to several sampled datas described, described result is for characterizing radiative collision induction total amount.Namely each cycle obtains a result.
Determination module 53 determines whether to produce information for comparing based on described radiative collision induction total amount and predetermined threshold.
In the embodiment of the present invention, radiative collision can be responded to total amount and predetermined threshold compares, to determine whether according to comparative result to produce information.Such as, if it is smaller to go out radiative collision induction total amount by multilevel iudge, when can not produce harm to human body, can not point out.Certainly, also can point out, prompting user current radiation can not produce harm to human body.
Described predetermined threshold can only have one, also can have multiple.Specifically can be determined by experiment according to the actual demand of people.
Described information can be text prompt, also can be voice message, or light prompt etc.
The electromagnetic radiation detection device that the embodiment of the present invention provides, is gathered the electromagnetic wave signal of the current position of electronic equipment, obtains several sampled datas by acquisition module; Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount; Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.That is, in the embodiment of the present invention, electromagnetic radiation situation is weighed based on radiative collision induction total amount, and, radiative collision induction total amount carries out process based on electromagnetic wave signal intensity (as magnitude of voltage) to sampled data to obtain, therefore, by radiative collision induction total amount, measurement is carried out to electromagnetic radiation and can reflect electromagnetic radiation situation more accurately.
Optionally, a kind of structural representation of determination module 53 as described in Figure 6, can comprise;
Comparing unit 61 and determining unit 62; Wherein,
Comparing unit 61 is for comparing described radiative collision induction total amount and predetermined threshold, and obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Concrete, different hazards of electromagnetic radiation grades can be divided according to predetermined threshold.Such as, suppose that predetermined threshold has two, be respectively the first predetermined threshold and the second predetermined threshold, and the first predetermined threshold is less than the second predetermined threshold, then, three hazards of electromagnetic radiation grades can be divided into according to predetermined threshold.When radiative collision induction total amount is less than the first predetermined threshold, be in the first hazards of electromagnetic radiation grade; When radiative collision induction total amount is more than or equal to the first predetermined threshold, when being less than the second predetermined threshold, be in the second hazards of electromagnetic radiation grade; When radiative collision induction total amount is more than or equal to the second predetermined threshold, be in the 3rd hazards of electromagnetic radiation grade.Wherein, hazards of electromagnetic radiation higher grade, represents that harm is larger.Hazards of electromagnetic radiation lower grade, endangers less, or be safe from harm (as the lowest class).
Determining unit 62 produces information for determining whether based on described hazards of electromagnetic radiation grade.
Optionally, on basis embodiment illustrated in fig. 5, the another kind of structural representation of the electromagnetic radiation detection device that the embodiment of the present invention provides as shown in Figure 7, can also comprise:
First display module 71, for showing described some sampled datas and/or described radiative collision induction total amount, so that user understands radiation event in more detail.
In the embodiment of the present invention, can showing sampled data in the mode of oscillogram, also directly can show the numerical value of sampled data.
Radiative collision induction total amount can show numerical value.
Certainly, the first display module 71 also go for embodiment illustrated in fig. 6 in.
Certainly, if there is information, the first display module 71 can also be used for display reminding information.
Optionally, on basis embodiment illustrated in fig. 5, another structural representation of the electromagnetic radiation detection device that the embodiment of the present invention provides as shown in Figure 8, can also comprise;
Acquisition module 81 and the second display module 82; Wherein,
Acquisition module 81 is for obtaining radiative collision induction based on described some sampled datas;
Radiative collision induction can be obtained based on the peak-to-peak value of described some sampled datas, concrete, using magnetic induction density corresponding for the peak-to-peak value of described some sampled datas as radiative collision induction.
Second display module 82 is for showing described radiative collision induction.
In the embodiment of the present invention, not only measuring radiation magnetic induction total amount, also measuring radiation magnetic induction density.The dimension that user can be made never same understands magnetic radiation situation.
Such as, the duration section that magnetic induction density exceedes predetermined threshold can be recorded, when judging that magnetic radiation is stronger by radiative collision induction total amount, position when helping user to determine that magnetic radiation induction is stronger residing for it, to avoid again entering that stronger region of magnetic radiation induction.
Needs illustrate, the function of the first display module 71 and the function of the second display module 82 can be integrated in same functional module, and namely the first display module 71 and the second display module 82 can be same functional module.
Optionally, a kind of structural representation of acquisition module 51 as shown in Figure 9, can comprise:
Monitoring means 91 and collecting unit 92; Wherein,
Whether monitoring means 91 exceeds predetermined strength value for the intensity of monitoring the electromagnetic wave signal received;
Collecting unit 92 is for when the intensity that described monitoring means 91 monitors out the electromagnetic wave signal received exceeds predetermined strength value, and harvester gathers the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas.
In the embodiment of the present invention, in order to reduce the power consumption of electronic equipment, whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value, only have when the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, just start to carry out collection electromagnetic wave signal, and when the intensity of the electromagnetic wave signal received is less than predetermined strength value, illustrate that electromagnetic wave signal can not produce harm to human body, now electromagnet radiation detection can be carried out, to reduce powder consumption of electronic equipment.
Certainly, whether monitor to judge whether to carry out electromagnet radiation detection for optional function to the intensity of the electromagnetic wave signal received, can be selected by user.
The embodiment of the present invention also provides a kind of electronic equipment, and this electronic equipment comprises the electromagnetic radiation detection device as above described in any embodiment.Concrete,
The storer that this electronic equipment can comprise processor and be coupled with described processor; Wherein, this processor is configured to:
Gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas;
Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount;
Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.
Be configured to compare based on described radiative collision induction total amount and predetermined threshold the processor determining whether to produce information be configured to further:
Described radiative collision induction total amount and predetermined threshold are compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Determine whether to produce information based on described hazards of electromagnetic radiation grade.
Processor is configured to further:
Show described some sampled datas and/or described radiative collision induction total amount.
Processor can be configured to further:
Radiative collision induction is obtained based on described some sampled datas;
Show described radiative collision induction.
Be configured to the electromagnetic wave signal being gathered the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, the processor obtaining several sampled datas is configured to further:
Whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value;
When the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas.
Be configured to be configured to further the processor that several sampled datas described process based on electromagnetic wave signal intensity:
Based on electromagnetic wave signal intensity, integral operation is carried out to several obtained sampled datas.
To the above-mentioned explanation of the disclosed embodiments, professional and technical personnel in the field are realized or uses the present invention.To be apparent for those skilled in the art to the multiple amendment of these embodiments, General Principle as defined herein can without departing from the spirit or scope of the present invention, realize in other embodiments.Therefore, the present invention can not be restricted to these embodiments shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.
Claims (13)
1. a detection method of electromagnetic radiation, is characterized in that, described method comprises:
Gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas;
Process several sampled datas described based on electromagnetic wave signal intensity, obtain result, described result is for characterizing radiative collision induction total amount;
Compare based on described radiative collision induction total amount and predetermined threshold and determine whether to produce information.
2. method according to claim 1, is characterized in that, described comparing based on described radiative collision induction total amount and predetermined threshold determines whether that producing information comprises:
Described radiative collision induction total amount and predetermined threshold are compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Determine whether to produce information based on described hazards of electromagnetic radiation grade.
3. method according to claim 1, is characterized in that, also comprises:
Show described some sampled datas and/or described radiative collision induction total amount.
4. method according to claim 1, is characterized in that, also comprises:
Radiative collision induction is obtained based on described some sampled datas;
Show described radiative collision induction.
5. method according to claim 1, is characterized in that, the described electromagnetic wave signal harvester by electronic equipment gathers the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas and comprises:
Whether the intensity of monitoring the electromagnetic wave signal received exceeds predetermined strength value;
When the intensity of monitoring out the electromagnetic wave signal received exceeds predetermined strength value, gathered the electromagnetic wave signal of the current position of described electronic equipment by the electromagnetic wave signal harvester of electronic equipment, obtain several sampled datas.
6. method according to claim 1, is characterized in that, describedly carries out process based on electromagnetic wave signal intensity to several sampled datas described and comprises:
Based on electromagnetic wave signal intensity, integral operation is carried out to several obtained sampled datas.
7. an electromagnetic radiation detection device, is characterized in that, described device comprises:
Acquisition module, for gathering the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas;
Processing module, for processing several sampled datas described based on electromagnetic wave signal intensity, obtains result, and described result is for characterizing radiative collision induction total amount;
Determination module, determines whether to produce information for comparing based on described radiative collision induction total amount and predetermined threshold.
8. device according to claim 7, is characterized in that, described determination module comprises:
Comparing unit, for described radiative collision induction total amount and predetermined threshold being compared, obtain comparative result, described comparative result is for characterizing hazards of electromagnetic radiation grade;
Determining unit, produces information for determining whether based on described hazards of electromagnetic radiation grade.
9. device according to claim 7, is characterized in that, also comprises:
First display module, for showing described some sampled datas and/or described radiative collision induction total amount.
10. device according to claim 7, is characterized in that, also comprises:
Acquisition module, for obtaining radiative collision induction based on described some sampled datas;
Second display module, for showing described radiative collision induction.
11. devices according to claim 7, is characterized in that, described acquisition module comprises:
Whether monitoring means, exceed predetermined strength value for the intensity of monitoring the electromagnetic wave signal received;
Collecting unit, when the intensity for monitoring out the electromagnetic wave signal received when described monitoring means exceeds predetermined strength value, harvester gathers the electromagnetic wave signal of the current position of described electronic equipment, obtains several sampled datas.
12. devices according to claim 7, is characterized in that, described processing module comprises:
Processing unit, for carrying out integral operation based on electromagnetic wave signal intensity to several obtained sampled datas.
13. 1 kinds of electronic equipments, is characterized in that, comprise the electromagnetic radiation detection device as described in claim 7-12 any one.
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CN105099579A (en) * | 2015-07-28 | 2015-11-25 | 中国联合网络通信集团有限公司 | Electromagnetic radiation assessment method and electromagnetic radiation assessment equipment |
CN105259427A (en) * | 2015-09-25 | 2016-01-20 | 联想(北京)有限公司 | Radiation detection method and electronic equipment |
CN108089065A (en) * | 2017-12-06 | 2018-05-29 | 深圳市环境监测中心站 | Detection method of electromagnetic radiation, device, electronic equipment and storage medium |
CN109239471A (en) * | 2018-10-31 | 2019-01-18 | 北京小米移动软件有限公司 | The exceeded processing method and processing device of amount of electromagnetic radiation |
CN112986709A (en) * | 2019-12-17 | 2021-06-18 | 中国科学院沈阳自动化研究所 | Device and method for monitoring health state of underwater robot through electromagnetic information |
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