CN106686644A - Method and system for calculating moving speed of terminal - Google Patents
Method and system for calculating moving speed of terminal Download PDFInfo
- Publication number
- CN106686644A CN106686644A CN201710019541.2A CN201710019541A CN106686644A CN 106686644 A CN106686644 A CN 106686644A CN 201710019541 A CN201710019541 A CN 201710019541A CN 106686644 A CN106686644 A CN 106686644A
- Authority
- CN
- China
- Prior art keywords
- terminal
- mobile base
- base station
- accessed
- time
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W24/00—Supervisory, monitoring or testing arrangements
- H04W24/08—Testing, supervising or monitoring using real traffic
Landscapes
- Engineering & Computer Science (AREA)
- Computer Networks & Wireless Communication (AREA)
- Signal Processing (AREA)
- Mobile Radio Communication Systems (AREA)
Abstract
The invention discloses a method for calculating moving speed of a terminal, and the method for calculating the moving speed of a terminal comprise the following steps: obtaining time required for the terminal to access a first mobile base station to access a target mobile base station, the target mobile base station is the final accessed mobile base station of the terminal; according to the mobile base station accessed to the terminal, displacement of the terminal is obtained by the sum of the distances between adjacent two mobile base stations; the terminal speed is obtained by the displacement of the terminal divided by the time required. The invention also discloses a system for calculating the moving speed of the terminal. According to access time of the mobile terminal obtained by the mobile base station and distance between mobile base stations, the mobile speed of the mobile terminal is obtained, situations that a series of uncertain factors such as signal interference and signal power control affecting the calculation of moving speed are avoided, the calculation accuracy is improved.
Description
Technical field
The present invention relates to communication field, more particularly to a kind of terminal translational speed computational methods and system.
Background technology
With continuing to develop for field of mobile communication, in order to obtain the speed of mobile terminal, big data analysis is carried out increasingly
Generally, for example it is large-scale to check that mobile terminal, in somewhere or certain particular moment speed, is made to count mobile end subscriber
The vehicles, or local route prosperity situation is sentenced in the change of different location speed using mobile end subscriber
It is disconnected.But the method for obtaining the speed of mobile terminal at mobile communication base station end of the current use, uses to receiving
The power of the signal of mobile terminal is judged, or the situation of change of the wavelength or frequency to receiving signal judges, with
The translational speed of mobile terminal is calculated, but the interference of interference source is easily received due to signals transmission, it is impossible to obtained exactly
Take the translational speed of mobile terminal.
The content of the invention
Translational speed computational methods and system it is a primary object of the present invention to provide a kind of terminal, it is intended to can accurately obtain
Take the translational speed of mobile terminal.
To achieve the above object, the present invention provides a kind of translational speed computational methods of terminal, the mobile speed of the terminal
Degree computational methods are comprised the following steps:
Obtain terminal and access first mobile base station to the time-consuming of target mobile base station is accessed, the target mobile base station is
The mobile base station that the terminal is finally accessed;
According in the mobile base station that the terminal was accessed, the distance between two adjacent two-by-two mobile base stations summation
Obtain the displacement of the terminal;
Displacement according to the terminal is divided by the time-consuming acquisition terminal velocity.
Preferably, in the mobile base station accessed according to the terminal, adjacent two-by-two two mobile base stations it
Between the displacement for obtaining the terminal apart from summation include:
Obtain the longitude and latitude of all mobile base stations that the terminal was accessed;
The displacement of the terminal is determined according to below equation:
Wherein, S corresponds to the displacement of the terminal;N corresponds to the sum of the mobile base station that the terminal is accessed;LatiIt is right
The latitude of i-th mobile base station that terminal described in Ying Yu is accessed;Lati+1Base is moved corresponding to the i+1 that the terminal is accessed
The latitude stood;xiI-th shifting that the terminal that the latitude of the i+1 mobile base station accessed corresponding to the terminal subtracts is accessed
The result of the latitude of dynamic base station;yiThe longitude of the i+1 mobile base station accessed corresponding to the terminal subtracts the terminal and connects
The result of the longitude of i-th mobile base station for entering;ReCorresponding to earth radius.
Preferably, the displacement according to the terminal includes divided by the time-consuming acquisition terminal velocity:
Using the displacement of the terminal divided by the time-consuming acquisition terminal velocity;
The terminal velocity is multiplied by using modifying factor to be modified the terminal velocity, the modifying factor is with described
The quantity of the mobile base station that terminal was accessed and change.
Preferably, the span of the modifying factor is between 1 to 1.274.
Preferably, it is described to obtain time-consuming, the mesh that terminal accesses first mobile base station to access target mobile base station
Mark mobile base station is that the mobile base station that the terminal is finally accessed includes:
Determined according to below equation described time-consuming:
Wherein, T corresponds to described time-consuming;N corresponds to the sum of the mobile base station that the terminal is accessed;tk+1Corresponding to institute
State the time that terminal accesses+1 mobile base station of kth, tkK-th time of mobile base station is accessed corresponding to the terminal.
Additionally, the present invention provides a kind of translational speed computing system of terminal, the translational speed computing system of the terminal
Including:
First acquisition module, the time-consuming of first mobile base station to access target mobile base station is accessed for obtaining terminal,
The target mobile base station is the mobile base station that the terminal is finally accessed;
Second acquisition module, in the mobile base station accessed according to the terminal, two adjacent two-by-two movements
The distance between base station summation obtains the displacement of the terminal;
Computing module, for the displacement according to the terminal divided by the time-consuming acquisition terminal velocity.
Preferably, the computing module includes:
Acquiring unit, longitude and latitude for obtaining all mobile base stations that the terminal was accessed;
First computing unit, the displacement for determining the terminal according to below equation:
Wherein, S corresponds to the displacement of the terminal;N corresponds to the sum of the mobile base station that the terminal is accessed;LatiIt is right
The latitude of i-th mobile base station that terminal described in Ying Yu is accessed;Lati+1Base is moved corresponding to the i+1 that the terminal is accessed
The latitude stood;xiI-th shifting that the terminal that the latitude of the i+1 mobile base station accessed corresponding to the terminal subtracts is accessed
The result of the latitude of dynamic base station;yiThe longitude of the i+1 mobile base station accessed corresponding to the terminal subtracts the terminal and connects
The result of the longitude of i-th mobile base station for entering;ReCorresponding to earth radius.
Preferably, the computing module includes:
Second computing unit, for the displacement using the terminal divided by the time-consuming acquisition terminal velocity;
Amending unit, is modified for being multiplied by the terminal velocity using modifying factor to the terminal velocity, described
Modifying factor changes with the quantity of the mobile base station that the terminal was accessed.
Preferably, the span of the modifying factor of the amending unit is between 1 to 1.274.
Preferably, first acquisition module includes:
3rd computing unit, it is described time-consuming for being determined according to below equation:
Wherein, T corresponds to described time-consuming;N corresponds to the sum of the mobile base station that the terminal is accessed;tk+1Corresponding to institute
State the time that terminal accesses+1 mobile base station of kth, tkK-th time of mobile base station is accessed corresponding to the terminal.
The present invention extremely accesses the time-consuming of target mobile base station by according to by obtaining first mobile base station of terminal access,
The target mobile base station is the mobile base station that the terminal is finally accessed;According to the mobile base station that the terminal was accessed
In, the distance between two adjacent two-by-two mobile base stations summation obtains the displacement of the terminal;According to the displacement of the terminal
Divided by the time-consuming acquisition terminal velocity.The present invention obtains the turn-on time of mobile terminal by basis from mobile base station,
With the translational speed that the distance between mobile base station obtains the mobile terminal, it is to avoid use power calculation speed by mobile terminal
When suffer the situation that a series of uncertain factors such as signal interference, signal power control influence the speed of the terminal to calculate, carry
The high degree of accuracy for calculating.
Brief description of the drawings
Fig. 1 is the schematic flow sheet of the translational speed computational methods first embodiment of terminal of the present invention;
Fig. 2 be terminal of the present invention translational speed computational methods 3rd embodiment according to the displacement of the terminal divided by institute
State the time-consuming refinement schematic flow sheet for obtaining the terminal velocity step;
Fig. 3 is the high-level schematic functional block diagram of the translational speed computing system first embodiment of terminal of the present invention;
Fig. 4 be terminal of the present invention translational speed computing system second embodiment in the refinement functional module of computing module show
It is intended to;
Fig. 5 be terminal of the present invention translational speed computing system 3rd embodiment in the refinement functional module of computing module show
It is intended to;
Fig. 6 be terminal of the present invention the embodiment of translational speed computing system the 5th in the first acquisition module refinement function mould
Block schematic diagram.
The realization of the object of the invention, functional characteristics and advantage will be described further referring to the drawings in conjunction with the embodiments.
Specific embodiment
It should be appreciated that the specific embodiments described herein are merely illustrative of the present invention, it is not intended to limit the present invention.
The present invention provides a kind of translational speed computational methods of terminal, reference picture 1, in the translational speed meter of terminal of the present invention
In calculation method first embodiment, the translational speed computational methods of the terminal are comprised the following steps:
Step S10, obtains terminal and accesses first mobile base station to the time-consuming of target mobile base station is accessed, and the target is moved
Dynamic base station is the mobile base station that the terminal is finally accessed;
The terminal is mobile phone, it is necessary to explanation is that in some embodiments, the terminal is other in the present embodiment
Using the terminal of mobile network, such as using the panel computer of mobile network, or use the bankcard consumption terminal of mobile network.
Step S20, according in the mobile base station that the terminal was accessed, between two adjacent two-by-two mobile base stations
The displacement of the terminal is obtained apart from summation;
Step S30, the displacement according to the terminal is divided by the time-consuming acquisition terminal velocity.
In the present embodiment, the terminal accesses first mobile base station in the t1 times, and the te times access the end
Terminate into target mobile base station.The terminal has successively accessed first mobile base station A, second mobile base station B, target movement
Base station C.The distance between described A and B is S (AB), and the distance between the B and C is S (BC), so the displacement S of the terminal
For:S(AB)+S(BC).The terminal velocity V=S/ (te-t1).The access of mobile terminal is obtained from mobile base station by basis
Time, and the distance between mobile base station obtains the translational speed of the mobile terminal, it is to avoid use power meter by mobile terminal
Suffer the situation that a series of uncertain factor influence translational speeds such as signal interference, signal power control are calculated when calculating speed, carry
The high degree of accuracy for calculating.
Translational speed computational methods first embodiment based on terminal of the present invention, calculates in the translational speed of terminal of the present invention
In method second embodiment, the step S20 includes:
Obtain the longitude and latitude of all mobile base stations that the terminal was accessed;
The displacement of the terminal is determined according to below equation:
Wherein, S corresponds to the displacement of the terminal;LatiThe latitude of i-th mobile base station accessed corresponding to the terminal
Degree;Lati+1The latitude of the i+1 mobile base station accessed corresponding to the terminal;xiCorresponding to the i+1 that the terminal is accessed
The latitude of individual mobile base station subtracts the result of the latitude of i-th mobile base station that the terminal is accessed;yiCorresponding to the terminal
The longitude of the i+1 mobile base station of access subtracts the result of the longitude of i-th mobile base station that the terminal is accessed;ReCorrespondence
In earth radius.
In the present embodiment, the terminal is also successively respectively connected to after accessing first mobile base station, A, B, C, D
With the target mobile base station E.Longitude and latitude (the Long of the A base stations1, Lat1), the longitude and latitude (Long of the B base stations2,
Lat2), the longitude and latitude (Long of the C base stations3, Lat3), the longitude and latitude (Long of the D base stations4, Lat4), the warp of the E base stations
Latitude (Long5, Lat5), according to x described in above-mentioned formula1=Lat2-Lat1, x2=Lat3-Lat2, x3=Lat4-Lat3, x4=
Lat5-Lat4;y1=Long2-Long1, y2=Long3-Long2, y3=Long4-Long3, y4=Long5-Long4.Substitute into following
Formula:
The S is obtained, it is necessary to explanation is the R in the present embodimenteValue is 6378.137 kms, the ReValue
Can be adjusted according to actual conditions according to particular problem.
Fig. 2 is refer to, the translational speed computational methods first embodiment based on terminal of the present invention, in the shifting of terminal of the present invention
In dynamic speed calculation method 3rd embodiment, the step S30 includes:
Step S33, using the displacement of the terminal divided by the time-consuming acquisition terminal velocity;
Step S34, is multiplied by the terminal velocity and the terminal velocity is modified using modifying factor, the modifying factor
Son changes with the quantity of the mobile base station that the terminal was accessed.
Because terminal existence time difference when mobile base station is accessed, to reduce because of access mobile base station quantity
The error for building up, is modified using modifying factor to the speed in described.Specifically, in the present embodiment, calculate
The terminal velocity is 20 kilometers/hour, and when the terminal has intervened 3 mobile base stations altogether, choosing the modifying factor is
1.216, be multiplied by the held speed using the modifying factor, obtain it is described it is revised state terminal velocity for 23 kilometers/it is small
When.Cause that the speed that calculates and actual speed are more coincide by using the modifying factor, improve computational accuracy.
Translational speed computational methods 3rd embodiment based on terminal of the present invention, calculates in the translational speed of terminal of the present invention
In method fourth embodiment, the span of the modifying factor is between 1 to 1.274.
It is set as from 1 to 1.274 by the span of the modifying factor, the calculating essence can be significantly improved
Degree.Specifically in the present embodiment, when the terminal has intervened 10 mobile base stations altogether, it is 1.086 to choose the modifying factor.
Translational speed computational methods first embodiment based on terminal of the present invention, calculates in the translational speed of terminal of the present invention
In the embodiment of method the 5th, the step S10 includes:
Determined according to below equation described time-consuming:
Wherein, T corresponds to described time-consuming;ti+1The time of i+1 mobile base station, t are accessed corresponding to the terminalkIt is right
Terminal described in Ying Yu accesses i-th time of mobile base station.Specifically in the present embodiment, the terminal has successively accessed first
Mobile base station A, second mobile base station B, target mobile base station C.The time for accessing the A is t1, access the B
Time be t2, the time for accessing the C is t3, time-consuming formula is calculated according to described, obtain the time-consuming=(t2-
t1)+(t3-t2).Mobile base station time segmentation calculating is accessed by using the terminal and obtains described time-consuming so that avoided
When the terminal is not online, the time error for causing further increases computational accuracy.
The present invention provides a kind of translational speed computing system of terminal, Fig. 3 is refer to, in the translational speed of terminal of the present invention
In computing system first embodiment, the translational speed computing system of the terminal includes:
First acquisition module 10, first mobile base station to the consumption for accessing target mobile base station is accessed for obtaining terminal
When, the target mobile base station is the mobile base station that the terminal is finally accessed;
The terminal is mobile phone, it is necessary to explanation is that in some embodiments, the terminal is other in the present embodiment
Using the terminal of mobile network, such as using the panel computer of mobile network, or use the bankcard consumption terminal of mobile network.
Second acquisition module 20, in the mobile base station accessed according to the terminal, two adjacent two-by-two shiftings
The distance between dynamic base station summation obtains the displacement of the terminal;
Computing module 30, for the displacement according to the terminal divided by the time-consuming acquisition terminal velocity.
In the present embodiment, the first acquisition module 10 obtains the terminal and accesses described first mobile base in the t1 times
Stand, the te times access the terminal and access target mobile base station, the second acquisition module 20 obtains the te times.The terminal elder generation
After accessed first mobile base station A, second mobile base station B, target mobile base station C.The distance between described A and B is S
(AB), the distance between described B and C is S (BC), and the displacement S that computing module 30 calculates the terminal is:S(AB)+S(BC).Institute
State terminal velocity V=S/ (te-t1).By basis from mobile base station obtain mobile terminal turn-on time, and mobile base station it
Between distance obtain the translational speed of the mobile terminal, it is to avoid suffer that signal is done during by mobile terminal using power calculation speed
Disturb, the situation that a series of uncertain factors influence translational speeds such as signal power control are calculated, improve the degree of accuracy of calculating.
Fig. 4 is refer to, the translational speed computing system first embodiment based on terminal of the present invention, in the shifting of terminal of the present invention
In dynamic speed calculation system second embodiment, the computing module 30 includes:
Acquiring unit 31, longitude and latitude for obtaining all mobile base stations that the terminal was accessed;
First computing unit 32, the displacement for determining the terminal according to below equation:
Wherein, S corresponds to the displacement of the terminal;LatiThe latitude of i-th mobile base station accessed corresponding to the terminal
Degree;Lati+1The latitude of the i+1 mobile base station accessed corresponding to the terminal;xiCorresponding to the i+1 that the terminal is accessed
The latitude of individual mobile base station subtracts the result of the latitude of i-th mobile base station that the terminal is accessed;yiCorresponding to the terminal
The longitude of the i+1 mobile base station of access subtracts the result of the longitude of i-th mobile base station that the terminal is accessed;ReCorrespondence
In earth radius.
In the present embodiment, the terminal is also successively respectively connected to after accessing first mobile base station, A, B, C, D
With the target mobile base station E.Acquiring unit 31 obtains the longitude and latitude (Long of the A base stations1, Lat1), the warp of the B base stations
Latitude (Long2, Lat2), the longitude and latitude (Long of the C base stations3, Lat3), the longitude and latitude (Long of the D base stations4, Lat4), institute
State the longitude and latitude (Long of E base stations5, Lat5), according to x described in above-mentioned formula1=Lat2-Lat1, x2=Lat3-Lat2, x3=
Lat4-Lat3, x4=Lat5-Lat4;y1=Long2-Long1, y2=Long3-Long2, y3=Long4-Long3, y4=Long5-
Long4.First computing unit 32 substitutes into following formula:
The S is obtained, it is necessary to explanation is the R in the present embodimenteValue is 6378.137 kms, the ReValue
Can be adjusted according to actual conditions according to particular problem.
Fig. 5 is refer to, the translational speed computing system second embodiment based on terminal of the present invention, in the shifting of terminal of the present invention
In dynamic speed calculation system 3rd embodiment, the computing module 30 includes:
Second computing unit 33, for the displacement using the terminal divided by the time-consuming acquisition terminal velocity;
Amending unit 34, is modified, institute for being multiplied by the terminal velocity using modifying factor to the terminal velocity
Modifying factor is stated to change with the quantity of the mobile base station that the terminal was accessed.
Because terminal existence time difference when mobile base station is accessed, to reduce because of access mobile base station quantity
The error for building up, is modified using modifying factor to the speed in described.Specifically, in the present embodiment, second calculate
The terminal velocity that unit 33 is calculated is 20 kilometers/hour, when the terminal has intervened 3 mobile base stations altogether, amendment
It is 1.216 that unit 34 chooses the modifying factor, and the held speed is multiplied by using the modifying factor, after obtaining the amendment
State terminal velocity for 23 kilometers/hour.The speed that calculates and actual speed are caused more by using the modifying factor
It coincide, improves computational accuracy.
Translational speed computing system 3rd embodiment based on terminal of the present invention, calculates in the translational speed of terminal of the present invention
In system fourth embodiment, the span of the modifying factor of the amending unit is between 1 to 1.274.
It is set as from 1 to 1.274 by the span of the modifying factor, the calculating essence can be significantly improved
Degree.Specifically in the present embodiment, when the terminal has intervened 10 mobile base stations altogether, it is 1.086 to choose the modifying factor.
Fig. 6 is refer to, the translational speed computational methods first embodiment based on terminal of the present invention, in the shifting of terminal of the present invention
In the dynamic embodiment of speed calculation method the 5th, first acquisition module 10 includes:
3rd computing unit 11, it is described time-consuming for being determined according to below equation:
Wherein, T corresponds to the terminal velocity;ti+1The time of i+1 mobile base station is accessed corresponding to the terminal,
tkI-th time of mobile base station is accessed corresponding to the terminal.It is specific in the present embodiment, the terminal has successively accessed the
One mobile base station A, second mobile base station B, target mobile base station C.The time for accessing the A is t1, access described
The time of the B is t2, the time for accessing the C is t3, the formula that the 3rd computing unit 11 takes according to the calculating,
Obtain the time-consuming=(t2-t1)+(t3-t2).Mobile base station time segmentation is accessed by using the terminal and calculates acquisition institute
State time-consuming so that avoid the terminal it is not online when, the time error for causing further increases computational accuracy.
The preferred embodiments of the present invention are these are only, the scope of the claims of the invention is not thereby limited, it is every to utilize this hair
Equivalent structure or equivalent flow conversion that bright specification and accompanying drawing content are made, or directly or indirectly it is used in other related skills
Art field, is included within the scope of the present invention.
Claims (10)
1. translational speed computational methods of a kind of terminal, it is characterised in that the translational speed computational methods of the terminal include with
Lower step:
Obtain terminal and access first mobile base station to the time-consuming of target mobile base station is accessed, the target mobile base station is described
The mobile base station that terminal is finally accessed;
According in the mobile base station that the terminal was accessed, the distance between two adjacent two-by-two mobile base stations summation is obtained
The displacement of the terminal;
Displacement according to the terminal is divided by the time-consuming acquisition terminal velocity.
2. translational speed computational methods of terminal as claimed in claim 1, it is characterised in that described to be connect according to the terminal
In the mobile base station for entering, the displacement that the distance between two adjacent two-by-two mobile base stations summation obtains the terminal includes:
Obtain the longitude and latitude of all mobile base stations that the terminal was accessed;
The displacement of the terminal is determined according to below equation:
Wherein, S corresponds to the displacement of the terminal;N corresponds to the sum of the mobile base station that the terminal is accessed;LatiCorrespond to
The latitude of i-th mobile base station that the terminal is accessed;Lati+1The i+1 mobile base station accessed corresponding to the terminal
Latitude;xiI-th movement base that the terminal that the latitude of the i+1 mobile base station accessed corresponding to the terminal subtracts is accessed
The result of the latitude stood;yiThe longitude of the i+1 mobile base station accessed corresponding to the terminal subtracts what the terminal was accessed
I-th result of the longitude of mobile base station;ReCorresponding to earth radius.
3. translational speed computational methods of terminal as claimed in claim 1 or 2, it is characterised in that described according to the terminal
Displacement time-consuming obtain the terminal velocity and include divided by described:
Using the displacement of the terminal divided by the time-consuming acquisition terminal velocity;
The terminal velocity is multiplied by using modifying factor to be modified the terminal velocity, the modifying factor is with the terminal
The quantity of the mobile base station accessed and change.
4. translational speed computational methods of terminal as claimed in claim 3, it is characterised in that the value model of the modifying factor
It is trapped among between 1 to 1.274.
5. translational speed computational methods of terminal as claimed in claim 1 or 2, it is characterised in that the acquisition terminal is accessed
First mobile base station is the shifting that the terminal is finally accessed to the time-consuming of target mobile base station, the target mobile base station is accessed
Dynamic base station includes:
Determined according to below equation described time-consuming:
Wherein, T corresponds to described time-consuming;N corresponds to the sum of the mobile base station that the terminal is accessed;tk+1Corresponding to the end
Terminate the time into+1 mobile base station of kth, tkK-th time of mobile base station is accessed corresponding to the terminal.
6. the translational speed computing system of a kind of terminal, it is characterised in that the translational speed computing system of the terminal includes:
First acquisition module, first mobile base station is accessed to the time-consuming of target mobile base station is accessed for obtaining terminal, described
Target mobile base station is the mobile base station that the terminal is finally accessed;
Second acquisition module, in the mobile base station accessed according to the terminal, two adjacent two-by-two mobile base stations
The distance between summation obtain the displacement of the terminal;
Computing module, for the displacement according to the terminal divided by the time-consuming acquisition terminal velocity.
7. the translational speed computing system of terminal as claimed in claim 6, it is characterised in that the computing module includes:
Acquiring unit, longitude and latitude for obtaining all mobile base stations that the terminal was accessed;
First computing unit, the displacement for determining the terminal according to below equation:
Wherein, S corresponds to the displacement of the terminal;N corresponds to the sum of the mobile base station that the terminal is accessed;LatiCorrespond to
The latitude of i-th mobile base station that the terminal is accessed;Lati+1The i+1 mobile base station accessed corresponding to the terminal
Latitude;xiI-th movement base that the terminal that the latitude of the i+1 mobile base station accessed corresponding to the terminal subtracts is accessed
The result of the latitude stood;yiThe longitude of the i+1 mobile base station accessed corresponding to the terminal subtracts what the terminal was accessed
I-th result of the longitude of mobile base station;ReCorresponding to earth radius.
8. the translational speed computing system of the terminal as described in any one of claim 6 to 7, it is characterised in that the calculating mould
Block includes:
Second computing unit, for the displacement using the terminal divided by the time-consuming acquisition terminal velocity;
Amending unit, is modified, the amendment for being multiplied by the terminal velocity using modifying factor to the terminal velocity
The factor changes with the quantity of the mobile base station that the terminal was accessed.
9. the translational speed computing system of terminal as claimed in claim 8, it is characterised in that the modifying factor of the amending unit
The span of son is between 1 to 1.274.
10. the translational speed computing system of the terminal as described in any one of claim 6 to 7, it is characterised in that described first obtains
Modulus block includes:
3rd computing unit, it is described time-consuming for being determined according to below equation:
Wherein, T corresponds to described time-consuming;N corresponds to the sum of the mobile base station that the terminal is accessed;tk+1Corresponding to the end
Terminate the time into+1 mobile base station of kth, tkK-th time of mobile base station is accessed corresponding to the terminal.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201710019541.2A CN106686644A (en) | 2017-01-11 | 2017-01-11 | Method and system for calculating moving speed of terminal |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201710019541.2A CN106686644A (en) | 2017-01-11 | 2017-01-11 | Method and system for calculating moving speed of terminal |
Publications (1)
Publication Number | Publication Date |
---|---|
CN106686644A true CN106686644A (en) | 2017-05-17 |
Family
ID=58849498
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201710019541.2A Pending CN106686644A (en) | 2017-01-11 | 2017-01-11 | Method and system for calculating moving speed of terminal |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN106686644A (en) |
Citations (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101072436A (en) * | 2007-03-29 | 2007-11-14 | 北京邮电大学 | Two-hop cellular relay network switching method for base station integrated control |
CN102360439A (en) * | 2011-10-24 | 2012-02-22 | 中国科学院自动化研究所 | Performance testing method for electronic tag |
CN103167511A (en) * | 2011-12-15 | 2013-06-19 | 中国电信股份有限公司 | Processing method and device for acquiring station spacing of base stations in wireless communication network |
CN103856978A (en) * | 2012-12-06 | 2014-06-11 | 中国联合网络通信集团有限公司 | Mobile network quality assessing method and device |
CN104021680A (en) * | 2014-06-18 | 2014-09-03 | 兴天通讯技术(天津)有限公司 | Traffic flow prediction method and system based on mobile terminals |
US20150172967A1 (en) * | 2013-12-13 | 2015-06-18 | Fujitsu Limited | Base station and cell selection method |
CN104853367A (en) * | 2014-02-13 | 2015-08-19 | 普天信息技术有限公司 | Terminal movement speed estimation method and device thereof |
CN106060923A (en) * | 2016-06-30 | 2016-10-26 | 广西英伦信息技术股份有限公司 | Speed measuring method based on base station |
-
2017
- 2017-01-11 CN CN201710019541.2A patent/CN106686644A/en active Pending
Patent Citations (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101072436A (en) * | 2007-03-29 | 2007-11-14 | 北京邮电大学 | Two-hop cellular relay network switching method for base station integrated control |
CN102360439A (en) * | 2011-10-24 | 2012-02-22 | 中国科学院自动化研究所 | Performance testing method for electronic tag |
CN103167511A (en) * | 2011-12-15 | 2013-06-19 | 中国电信股份有限公司 | Processing method and device for acquiring station spacing of base stations in wireless communication network |
CN103856978A (en) * | 2012-12-06 | 2014-06-11 | 中国联合网络通信集团有限公司 | Mobile network quality assessing method and device |
US20150172967A1 (en) * | 2013-12-13 | 2015-06-18 | Fujitsu Limited | Base station and cell selection method |
CN104853367A (en) * | 2014-02-13 | 2015-08-19 | 普天信息技术有限公司 | Terminal movement speed estimation method and device thereof |
CN104021680A (en) * | 2014-06-18 | 2014-09-03 | 兴天通讯技术(天津)有限公司 | Traffic flow prediction method and system based on mobile terminals |
CN106060923A (en) * | 2016-06-30 | 2016-10-26 | 广西英伦信息技术股份有限公司 | Speed measuring method based on base station |
Non-Patent Citations (1)
Title |
---|
杨秀清等: "基于频域信道信息的基站端估计终端移动速度方法", 《数据采集与处理》 * |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN104978947B (en) | Adjusting method, dispaly state regulating device and the display device of dispaly state | |
CN103353923B (en) | Adaptive space interpolation method and system thereof based on space characteristics analysis | |
CN112711899B (en) | Fusion prediction method for height of evaporation waveguide | |
CN102645173A (en) | Multi-vision-based bridge three-dimensional deformation monitoring method | |
US20110054868A1 (en) | Atmospheric flow simulation method considering influence of terrain elevation data resolution | |
CN108459298A (en) | A kind of outdoor positioning method based on LoRa technologies | |
CN109448124B (en) | Water quality simulation method and device for river channel | |
CN103220780A (en) | Indoor positioning method, device and system | |
CN109597028A (en) | Robust positioning method based on arrival time under the conditions of a kind of mixing sighting distance non line of sight | |
CN109581281A (en) | Moving objects location method based on reaching time-difference and arrival rate difference | |
CN106093849A (en) | A kind of Underwater Navigation method based on range finding with neural network algorithm | |
CN109672635A (en) | A kind of relativity of time domain estimation method, device and equipment | |
CN111854732A (en) | Indoor fingerprint positioning method based on data fusion and width learning | |
CN107564125A (en) | Drainage pipeline networks inspection treating method and apparatus | |
CN110186458A (en) | Indoor orientation method based on OS-ELM fusion vision and Inertia information | |
CN105510706A (en) | High-precision undersampling frequency measurement method | |
Zhang et al. | Generative adversarial networks based digital twin channel modeling for intelligent communication networks | |
CN109521444A (en) | A kind of fitting of crustal movement GPS horizontal velocity field adaptive least square estimates algorithm | |
CN101726725A (en) | Wireless sensor network node positioning method based on global optimization strategy | |
CN106686644A (en) | Method and system for calculating moving speed of terminal | |
CN108279007A (en) | A kind of localization method and device based on random signal | |
CN102346029B (en) | Device for detecting observing angle of overhead line sag and control method thereof | |
CN104266646B (en) | Method and device for determining movement direction of terminal | |
CN102841364A (en) | GPS (global position system) velocity measurement implementation method and GPS velocity meter | |
CN109581280A (en) | The adaptive tuning on-line method, system and device of terminal |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
RJ01 | Rejection of invention patent application after publication | ||
RJ01 | Rejection of invention patent application after publication |
Application publication date: 20170517 |