CN109883278A - Detonator section method for distinguishing and device are determined in a kind of interference drop vibration explosion of elementary errors - Google Patents
Detonator section method for distinguishing and device are determined in a kind of interference drop vibration explosion of elementary errors Download PDFInfo
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Abstract
The embodiment of the present invention discloses in a kind of interference drop vibration explosion of elementary errors and determines detonator section method for distinguishing and device, is related to engineering explosion field, can accurately determine that the section for the filled detonator of blasthole that adjacent spaces are detonated is other.The described method includes: determining the optimal short-delay time of the blasthole detonation of adjacent spaces detonation;According to the optimal short-delay time, determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other.Described device, electronic equipment and readable storage medium storing program for executing include module used to perform the method.The present invention is suitable for determining that the section of the filled detonator of blasthole of adjacent spaces detonation is other.
Description
Technical field
The present invention relates to determine the other side of detonator section in engineering explosion field more particularly to a kind of interference drop vibration explosion of elementary errors
Method, device, electronic equipment and readable storage medium storing program for executing.
Background technique
Being constantly progressive and develop with society, higher requirements are also raised for improvement of the mankind to own existence environment,
Incident is utilization and the exploitation to the energy and resource, and in this process, explosion is as one kind in mining and base
It builds that one of construction is convenient, efficient technological means, promotes China's building in mining and various basic common structures
If process.However, explosion itself can bring violent vibration, to around explosion place environment and people's life impact,
So needing to consider to reduce vibration effect of explosion in blasting process.
Elementary errors interference drop vibration is one of common technological means in current Geotechnical Engineering Blasting, wherein detonator section is other really
Being scheduled in elementary errors drop vibration design is particularly important, and the other determination of detonator section again relies on optimal short-delay time and detonator delay
The determination of error.Since the extension error of each section of other detonator is not quite similar, even if optimal short-delay time has been determined, detonator section is other
Determination still lack necessary foundation.With the appearance of high-precision electronic detonator, the accurate control of blasting time has become possibility,
But since electric detonator is expensive, at present can not also large-scale application engineering on site, so interfering drop vibration in elementary errors at present
In design, detonator section is not still empirically determined.
Summary of the invention
In view of this, the embodiment of the present invention, which is provided in a kind of interference drop vibration explosion of elementary errors, determines detonator section method for distinguishing, dress
It sets, electronic equipment and readable storage medium storing program for executing, can accurately determine that the section of the filled detonator of blasthole of adjacent spaces detonation is other.
In a first aspect, the embodiment of the present invention, which is provided in a kind of interference drop vibration explosion of elementary errors, determines detonator section method for distinguishing, packet
It includes: determining the optimal short-delay time of the blasthole detonation of adjacent spaces detonation;According to the optimal short-delay time, determine described adjacent
The section for being spaced the filled detonator of blasthole of detonation is other.
A kind of specific implementation according to an embodiment of the present invention, it is described according to the optimal short-delay time, determine detonator
Section it is other, comprising: according to the optimal short-delay time, determine each section not with the probability of the optimal short-delay time detonation;It will
The section of the maximum probability of the optimal short-delay time detonation is other, the section as filled detonator in first blasthole and the second blasthole
Not.
A kind of specific implementation according to an embodiment of the present invention, it is described according to the optimal short-delay time, it determines each
Section is not with the probability of the optimal short-delay time detonation, comprising:
According to the following formula, each section is calculated not with the probability of the optimal short-delay time detonation:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1, tn), i is that detonator section is other, ±
tmσ for the upper and lower limit of i-th section of other detonator delay burst error, with every section of other detonatoriIt is related, σiThe mark of i-th section of function other detonator
Poor, the F (t of standardj)、F(tk-tj) be respectively i-th section of other detonator delay error be tjAnd tk-tjProbability value.
Second aspect, the embodiment of the present invention provide in a kind of interference drop vibration explosion of elementary errors and determine the other device of detonator section, packet
It includes: optimal short-delay time determining module, the other determining module of detonator section, wherein optimal short-delay time determining module, for determining phase
The optimal short-delay time of the blasthole detonation of neighbour interval detonation;The other determining module of detonator section is used for according to the optimal short-delay time,
Determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other.
A kind of specific implementation according to an embodiment of the present invention, the other determining module of detonator section, comprising:
Detonate probability determination module, detonator section not determine submodule, wherein detonation probability determination module, be used for according to institute
Optimal short-delay time is stated, determines each section of probability not detonated with the optimal short-delay time;Detonator section not Que Ding submodule, use
It is other in the section for the maximum probability that the optimal short-delay time detonates, as filled detonator in first blasthole and the second blasthole
Section it is other.
A kind of specific implementation according to an embodiment of the present invention, the detonation probability determination module, comprising: calculate detonation
Probabilistic module, for according to the following formula, calculating each section not with the probability of the optimal short-delay time detonation:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1, tn), i is that detonator section is other, ±
tmσ for the upper and lower limit of i-th section of other detonator delay burst error, with every section of other detonatoriIt is related, σiThe mark of i-th section of function other detonator
Poor, the F (t of standardj)、F(tk-tj) be respectively i-th section of other detonator delay error be tjAnd tk-tjProbability value.
The third aspect, the embodiment of the present invention provide a kind of electronic equipment, and the electronic equipment includes: shell, processor, deposits
Reservoir, circuit board and power circuit, wherein circuit board is placed in the space interior that shell surrounds, processor and memory setting
On circuit boards;Power circuit, for each circuit or the device power supply for above-mentioned electronic equipment;Memory is for storing and can hold
Line program code;Processor is run and executable program code pair by reading the executable program code stored in memory
The program answered, for executing method described in aforementioned any implementation.
Fourth aspect, the embodiment of the present invention also provide computer readable storage medium, the computer-readable storage medium
Matter is stored with one or more program, and one or more of programs can be executed by one or more processor, with reality
Method described in existing aforementioned any implementation.
Determine that detonator section method for distinguishing, device electronics are set in a kind of elementary errors interference drop vibration explosion provided in an embodiment of the present invention
Standby and readable storage medium storing program for executing, the optimal short-delay time of the blasthole detonation by determining adjacent spaces detonation, further according to described optimal
Short-delay time, and on the basis of considering detonator delay error, when proposing a kind of blasthole of adjacent spaces detonation with optimal elementary errors
Between the probability calculation formula that detonates, and then determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other, can relatively accurately
Ground determines that the section of the filled detonator of blasthole of adjacent spaces detonation is other, and to solve to be empirically determined in the prior art, detonator section is other to be asked
Topic.
Detailed description of the invention
In order to more clearly explain the embodiment of the invention or the technical proposal in the existing technology, to embodiment or will show below
There is attached drawing needed in technical description to be briefly described, it should be apparent that, the accompanying drawings in the following description is only this
Some embodiments of invention for those of ordinary skill in the art without creative efforts, can be with
Other attached drawings are obtained according to these attached drawings.
Fig. 1 is the process that detonator section method for distinguishing is determined in a kind of elementary errors interference drop vibration explosion provided in an embodiment of the present invention
Figure;
Fig. 2 is the schematic diagram of target position and the first blasthole and the second blasthole in demolition site;
Fig. 3 is to determine that the other apparatus structure of detonator section shows in a kind of elementary errors interference drop vibration explosion provided in an embodiment of the present invention
It is intended to;
Fig. 4 is the structural schematic diagram of electronic equipment one embodiment of the present invention.
Specific embodiment
The embodiment of the present invention is described in detail with reference to the accompanying drawing.
It will be appreciated that described embodiments are only a part of the embodiments of the present invention, instead of all the embodiments.Base
Embodiment in the present invention, it is obtained by those of ordinary skill in the art without making creative efforts it is all its
Its embodiment, shall fall within the protection scope of the present invention.
In a first aspect, the embodiment of the present invention, which is provided in a kind of interference drop vibration explosion of elementary errors, determines detonator section method for distinguishing, energy
The section of enough filled detonators of blasthole for accurately determining adjacent spaces detonation is other.
Fig. 1 is the process that detonator section method for distinguishing is determined in a kind of elementary errors interference drop vibration explosion provided in an embodiment of the present invention
Figure, as shown in Fig. 1.
The method of the present embodiment may include:
Step 11 determines the optimal short-delay time that the blasthole of adjacent spaces detonation is detonated.
In the present embodiment, multiple blastholes would generally be arranged in demolition site, to realize Accelerating The Construction speed, save manpower money
The purpose in source.
Optimal short-delay time, adjacent shot hole blasting time interval one after another, with time interval detonation, two shot hole blastings are produced
Raw energy field influences each other, and demolition effect not only can be improved, but also can reduce blasting vibration effect, shock wave and slungshot danger
Evil.
Step 12, according to the optimal short-delay time, determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other.
In the present embodiment, according to optimal short-delay time and each section not with the probability of the optimal short-delay time detonation, energy
Enough determine that the section of filled detonator in first blasthole and the second blasthole is other.
The present embodiment is determined by optimal short-delay time and each section not with the probability of the optimal short-delay time detonation
The section of filled detonator is other in first blasthole and the second blasthole, thus, in demolition site, realize optimal with greater probability realization
Short-delay time detonation reaches good drop vibration effect.
The present embodiment passes through the optimal short-delay time for determining the blasthole detonation of adjacent spaces detonation, further according to described optimal micro-
The poor time, and on the basis of considering detonator delay error, propose a kind of blasthole of adjacent spaces detonation with optimal short-delay time
The probability calculation formula of detonation, and then determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other, it can be accurately
It determines that the section of the filled detonator of blasthole of adjacent spaces detonation is other, foundation is provided for the other determination of detonator section, to solve the prior art
In the other problem of detonator section is empirically determined.
In an embodiment of the present invention, according to the optimal short-delay time, the blasthole institute of the adjacent spaces detonation is determined
The section for filling detonator is other, comprising:
R1, according to the optimal short-delay time, determine each section not with the probability of the optimal short-delay time detonation.
In the present embodiment, under identical optimal short-delay time, each section of other two hairs blasting cap initiation probability is different.
B2, the section for the maximum probability that the optimal short-delay time detonates are other, as first blasthole and the second blasthole
The section of middle filled detonator is other.
It is in the present embodiment, the section of the maximum probability of each of determining section of other optimal short-delay time detonation is other, as the
The section of filled detonator is other in one blasthole and the second blasthole.
The present embodiment, the probability to be detonated by each section of determination other detonator with optimal short-delay time, by optimal short-delay time
The section of the maximum probability of detonation is other, and the section as the filled detonator of adjacent two successively to detonate blasthole is other, can be improved two big guns
A possibility that hole is detonated with optimal short-delay time, to reach good drop vibration effect.
In an embodiment of the present invention, described according to the optimal short-delay time, determine each section not with described optimal micro-
The probability of poor time detonation, comprising:
According to the following formula, each section is calculated not with the probability of the optimal short-delay time detonation:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1, tn), i is that detonator section is other, ±
tmσ for the upper and lower limit of i-th section of other detonator delay burst error, with every section of other detonatoriIt is related, σiFor the mark of i-th section of other detonator
Poor, the F (t of standardj)、F(tk-tj) be respectively single detonator delay error be tjAnd tk-tjProbability value.
In the present embodiment, in the upper and lower limit of detonator delay burst error, traversal calculate same section of other two detonator with
The probability of optimal short-delay time detonation.
The present embodiment, the probability to be detonated by each section of determination other two hairs detonator with optimal short-delay time, can be improved
A possibility that two blastholes are with optimal millisecond detonating, to reach good drop vibration effect.
As an optional embodiment, the probability of each section of other any extension error detonation of single-shot detonator is determined, comprising:
R11, each section of detonator delay mean value and sample standard deviation are obtained.
In the present embodiment, every section of other detonator sample size is not less than 100.
B12, recurrence calculating is carried out to sample standard deviation, obtains standard deviation with the variation relation of detonator delay mean value.
In the present embodiment, due to same section of other detonator, under different samples, obtained sample standard deviation also phase not to the utmost
Together, it is calculated so sample standard deviation can be returned, carries out interval estimation to standard deviation is returned, and take the upper limit of predetermined confidence level
As standard deviation.
B13, the probability that each section of other single-shot detonator is detonated with any extension error is determined, comprising:
According to the following formula, the probability that each section of other single-shot detonator is detonated with any extension error is calculated:
Wherein,For normpdf, x is extension error, and σ is standard deviation, and a, b are to prolong
Two endpoints in period error section.
In the present embodiment, extension error can regard stochastic variable as, when i-th section of detonator quantity of same batch is sufficiently large, delay
Error Normal Distribution, is denoted as xi~N (0, σ2), xiFor the extension error of i-th section of detonator, σ is standard deviation.
The present embodiment by carrying out recurrence calculating to each section of other detonator sample, and takes certain confidence level upper limit conduct
When each section of other detonator standard deviation, i.e. each section of other detonator delay burst error maximum, each section of other detonator is calculated with described optimal
The probability of short-delay time detonation, can more accurately calculate the detonation probability of every section of other detonator.
A specific embodiment is used below, and the technical solution of embodiment of the method shown in Fig. 1 is described in detail.
Fig. 2 is the schematic diagram of target position and the first blasthole and the second blasthole in demolition site.
Elementary errors interference drop vibration target be a building, building be respectively at a distance from the first blasthole, the second blasthole 55m and
50m, the first blasthole, the second blasthole be the adjacent blasthole successively detonated, and the first blasthole, the second blasthole detonation optimal elementary errors
Time is 15ms-25ms.
Step 1 is sampled detection to each section used in demolition site other detonator, and the delay for obtaining each section of other detonator is equal
Value and sample standard deviation.The sample number of each section of other detonator is 200.
Step 2 carries out recurrence calculating to sample standard deviation, obtains the standard deviation distribution of each section of detonator under 95% confidence level
Section can use standard deviation of the 95% confidence level upper limit as different sections of other detonators.
Step 3, the single-shot detonator delay probability of error calculate.Extension error can regard stochastic variable as, when i-th section of thunder of same batch
When pipe quantity is sufficiently large, Normal Distribution is denoted as ti~N (0, σ2), in formula, tiFor the extension error of i-th section of detonator, σ is mark
The corresponding standard deviation of the corresponding 95% confidence level upper limit of i-th section of detonator delay mean value quasi- poor, that upper step is calculated.
According to normpdfBy being integrated to any extension burst error (a, b), i.e.,
The probability value under i-th section of detonator arbitrarily extension error can be acquiredIn formula, extension error of the x for i-th section of detonator, a,
b∈(±1.96 σ)。
Step 4, according to the following formula calculates each section not with the probability of the optimal short-delay time detonation:
Wherein, t1、tnFor 15ms and 25ms, tkNumerical value can use 15ms, 16ms etc. between 15ms-25ms.I is detonator
Section is other, ± tmFor the upper and lower limit of i-th section of other detonator delay burst error, ± 1.96 σi, σiFor the standard deviation of i-th section of other detonator, F
(tj)、F(tk-tj) be respectively single detonator delay error be tjAnd tk-tjProbability value.
Step 5, according to above-mentioned formula, can calculate each section not, the probability that is successively detonated with optimal short-delay time of two hair detonators,
It obtains with the section of optimal short-delay time detonation maximum probability not being section other 11.
Fig. 3 is to determine that the other apparatus structure of detonator section shows in a kind of elementary errors interference drop vibration explosion provided in an embodiment of the present invention
It is intended to, as shown in figure 4, the device of the present embodiment may include: optimal short-delay time determining module 1a, the other determining module of detonator section
2a, wherein optimal short-delay time determining module 1a, the optimal short-delay time of the blasthole detonation for determining adjacent spaces detonation;
The other determining module 2a of detonator section, for determining the filled thunder of blasthole of the adjacent spaces detonation according to the optimal short-delay time
The section of pipe is other.
The device of the present embodiment can be used for executing the technical solution of embodiment of the method shown in Fig. 1, realization principle and skill
Art effect is similar, and details are not described herein again.
In an embodiment of the present invention, the other determining module 2a of the detonator section, further includes: detonation probability determination module 2a1,
Detonator section Que Ding submodule 2a2, wherein
Detonate probability determination module 2a1, for according to the optimal short-delay time, determine each section not with described optimal micro-
The probability of poor time detonation;
Detonator section not Que Ding submodule 2a2, for the section of the maximum probability of the optimal short-delay time detonation is other, as
The section of filled detonator is other in first blasthole and the second blasthole.
In an embodiment of the present invention, the detonation probability determination module 2a1, comprising:
Detonation probabilistic module 2a11 is calculated, for according to the following formula, calculating each section of other detonator with the optimal elementary errors
The probability of time detonation:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1, tn), i is that detonator section is other, ±
tmσ for the upper and lower limit of i-th section of other detonator delay burst error, with every section of other detonatoriIt is related, σiFor the mark of i-th section of other detonator
Poor, the F (t of standardj)、F(tk-tj) be respectively i-th section of other detonator delay error be tjAnd tk-tjProbability value.
As an optional embodiment, the calculating detonation probabilistic module 2a11, comprising: calculate single-shot blasting cap initiation probability
Module 2011a, for determining the probability of each section of other any extension error detonation of single-shot detonator.
As an optional embodiment, single-shot blasting cap initiation probabilistic module 2011a is calculated, comprising: sample acquisition module c1,
Standard deviation returns computing module c2, the probability evaluation entity c3 of single-shot blasting cap initiation, wherein
Sample acquisition module c1, for obtaining each section of detonator delay mean value and sample standard deviation;
Standard deviation returns computing module c2 and obtains standard deviation for carrying out recurrence calculating to sample standard deviation and prolong with detonator
The variation relation of hourly value;
The probability evaluation entity c3 of single-shot blasting cap initiation, for determining that each section of other single-shot detonator is risen with any extension error
Quick-fried probability.
The third aspect, the embodiment of the present invention also provide a kind of electronic equipment, and the electronic equipment includes aforementioned any implementation
Device described in example.
Fig. 4 is the structural schematic diagram of electronic equipment one embodiment of the present invention, Fig. 1 of the present invention may be implemented, implementations shown in 2
The process of example, as shown in figure 4, above-mentioned electronic equipment may include: shell 41, processor 42, memory 43, circuit board 44 and electricity
Source circuit 45, wherein circuit board 44 is placed in the space interior that shell 41 surrounds, and processor 42 and memory 43 are arranged in circuit
On plate 44;Power circuit 45, for each circuit or the device power supply for above-mentioned electronic equipment;Memory 43 is for storing and can hold
Line program code;Processor 42 is run by reading the executable program code stored in memory 43 and executable program
The corresponding program of code, for executing method described in aforementioned any embodiment.
Processor 42 to the specific implementation procedures of above-mentioned steps and processor 42 by operation executable program code come
The step of further executing may refer to the description of Fig. 1-3 illustrated embodiment of the present invention, and details are not described herein.
The electronic equipment exists in a variety of forms, including but not limited to:
(1) super mobile personal computer equipment: this kind of equipment belongs to the scope of personal computer, there is calculating and processing function
Can, generally also have mobile Internet access characteristic.This Terminal Type includes: PDA, MID and UMPC equipment etc., such as iPad.
(2) server: providing the equipment of the service of calculating, and the composition of server includes that processor, hard disk, memory, system are total
Line etc., server is similar with general computer architecture, but due to needing to provide highly reliable service, in processing energy
Power, stability, reliability, safety, scalability, manageability etc. are more demanding.
(3) other electronic equipments with data interaction function.
Fourth aspect, the embodiment of the present invention also provide computer readable storage medium, the computer-readable storage medium
Matter is stored with one or more program, and one or more of programs can be executed by one or more processor, with reality
Method described in existing aforementioned any implementation.
It should be noted that, in this document, relational terms such as first and second and the like are used merely to a reality
Body or operation are distinguished with another entity or operation, are deposited without necessarily requiring or implying between these entities or operation
In any actual relationship or order or sequence.Moreover, the terms "include", "comprise" or its any other variant are intended to
Non-exclusive inclusion, so that the process, method, article or equipment including a series of elements is not only wanted including those
Element, but also including other elements that are not explicitly listed, or further include for this process, method, article or equipment
Intrinsic element.In the absence of more restrictions, the element limited by sentence "including a ...", it is not excluded that
There is also other identical elements in process, method, article or equipment including the element.
Each embodiment in this specification is all made of relevant mode and describes, same and similar portion between each embodiment
Dividing may refer to each other, and each embodiment focuses on the differences from other embodiments.
For Installation practice, since it is substantially similar to the method embodiment, so the comparison of description is simple
Single, the relevent part can refer to the partial explaination of embodiments of method.
For convenience of description, description apparatus above is to be divided into various units/modules with function to describe respectively.Certainly, exist
Implement to realize each unit/module function in the same or multiple software and or hardware when the present invention.
Those of ordinary skill in the art will appreciate that realizing all or part of the process in above-described embodiment method, being can be with
Relevant hardware is instructed to complete by computer program, the program can be stored in a computer-readable storage medium
In, the program is when being executed, it may include such as the process of the embodiment of above-mentioned each method.Wherein, the storage medium can be magnetic
Dish, CD, read-only memory (Read-Only Memory, ROM) or random access memory (Random Access
Memory, RAM) etc..
The above description is merely a specific embodiment, but scope of protection of the present invention is not limited thereto, any
In the technical scope disclosed by the present invention, any changes or substitutions that can be easily thought of by those familiar with the art, all answers
It is included within the scope of the present invention.Therefore, protection scope of the present invention should be subject to the protection scope in claims.
Claims (8)
1. determining detonator section method for distinguishing in a kind of elementary errors interference drop vibration explosion characterized by comprising
Determine the optimal short-delay time of the blasthole detonation of adjacent spaces detonation;
According to the optimal short-delay time, determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other.
2. determining detonator section method for distinguishing according to claim 1, which is characterized in that it is described according to the optimal elementary errors when
Between, determine that the section of the filled detonator of blasthole of the adjacent spaces detonation is other, comprising:
According to the optimal short-delay time, each section of probability not detonated with the optimal short-delay time is determined;
The section of the maximum probability of the optimal short-delay time detonation is other, as filled thunder in first blasthole and the second blasthole
The section of pipe is other.
3. determining detonator section method for distinguishing according to claim 2, which is characterized in that it is described according to the optimal elementary errors when
Between, determine each section of probability not detonated with the optimal short-delay time, comprising:
According to the following formula, each section is calculated not with the probability of the optimal short-delay time detonation:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1,tn), i is that detonator section is other, ± tmFor
The upper and lower limit of i-th section of other detonator delay burst error, the σ with every section of other detonatoriIt is related, σiFor the standard deviation of i-th section of other detonator,
F(tj)、F(tk-tj) be respectively i-th section of other detonator delay error be tjAnd tk-tjProbability value.
4. determining the other device of detonator section in a kind of interference drop vibration explosion of elementary errors, which is characterized in that described device includes:
Optimal short-delay time determining module, the optimal short-delay time of the blasthole detonation for determining adjacent spaces detonation;
The other determining module of detonator section, for determining that the blasthole of the adjacent spaces detonation is filled according to the optimal short-delay time
The section of detonator is other.
5. the determining other device of detonator section according to claim 4, which is characterized in that the other determining module of detonator section,
Include:
Detonate probability determination module, for according to the optimal short-delay time, determine each section not with the optimal short-delay time
The probability of detonation;
Detonator section not Que Ding submodule, for the section of the maximum probability of the optimal short-delay time detonation is other, as described the
The section of filled detonator is other in one blasthole and the second blasthole.
6. the determining other device of detonator section according to claim 5, which is characterized in that the detonation probability determination module,
Include:
Detonation probabilistic module is calculated, for according to the following formula, calculating each section not with the general of the optimal short-delay time detonation
Rate:
Wherein, t1、tnMinimum time and maximum time for optimal short-delay time, tk∈(t1,tn), i is that detonator section is other, ± tmFor
The upper and lower limit of i-th section of other detonator delay burst error, the σ with every section of other detonatoriIt is related, σiFor the standard deviation of i-th section of other detonator,
F(tj)、F(tk-tj) be respectively i-th section of other detonator delay error be tjAnd tk-tjProbability value.
7. a kind of electronic equipment, which is characterized in that the electronic equipment includes: shell, processor, memory, circuit board and electricity
Source circuit, wherein circuit board is placed in the space interior that shell surrounds, and processor and memory setting are on circuit boards;Power supply
Circuit, for each circuit or the device power supply for above-mentioned electronic equipment;Memory is for storing executable program code;Processing
Device runs program corresponding with executable program code by reading the executable program code stored in memory, for holding
Method described in the aforementioned any claim of row.
8. a kind of computer readable storage medium, which is characterized in that the computer-readable recording medium storage have one or
Multiple programs, one or more of programs can be executed by one or more processor, to realize that aforementioned any right is wanted
Seek the method.
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