CN104042198B - Characteristic index collecting system and method - Google Patents
Characteristic index collecting system and method Download PDFInfo
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- CN104042198B CN104042198B CN201410318609.3A CN201410318609A CN104042198B CN 104042198 B CN104042198 B CN 104042198B CN 201410318609 A CN201410318609 A CN 201410318609A CN 104042198 B CN104042198 B CN 104042198B
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Abstract
A characteristic index collecting system comprises a wearing device and a remote server. The wearing device is used for enabling a user to collect physical indexes, environment indexes and dynamic indexes conveniently. The remote server is used for storing and calculating the physical indexes, the environment indexes and the dynamic indexes collected by the wearing device, and controlling the detecting frequency of the wearing device. The wearing device comprises a physical index detecting module, an environment index detecting module, a dynamic index detecting module and a communication module. The remote server comprises a database, a comparison module and a control module.
Description
Technical field
The invention belongs to medical instruments field, it is related to a kind of acquisition system of characteristic index and acquisition method, more specifically
For, the present invention relates to a kind of system by wearable device and remote server acquisition characteristics index and side
Method.
Background technology
Characteristic index is body index, environmental index, dynamic indicator (height above sea level, speed, longitude and latitude etc.)
It is referred to as, existing wearable index collection equipment, be all that requirement or prompting user are come with unified standard
To complete the collection of certain characteristic index, on such as market, most Wearable pedometer, is all based on user
The target such as " daily 10,000 steps ", " consuming 516 kilocalories by walking weekly " to complete adopting of body index
Collection and statistics;
Meanwhile, existing index collection equipment is engraved in running status and just can collect complete use when typically requiring
Family body index is it is impossible to dynamic according to the body index state of different user, ambient condition, speed and height above sea level etc.
State state carrys out adjustment detection frequency, causes the waste of resource and the trouble of user;
Additionally, existing Wearable device typically passes through battery operation, continual detection will lead to battery
Power consumption increases, and endurance reduces, the problems such as battery and shortened equipment life.
In this context, make a can be used for Wearable device, the collection of adaptive adjusting device,
The intelligent characteristic index collection system of transmission frequency is just particularly important, will have huge market prospects simultaneously.
The present invention provides a kind of characteristic index acquisition system and method, according to by the various biographies on wearable device
Sensor uploads to the letter such as body index data, environmental index data and dynamic indicator data of remote server
The change of breath carrys out the detection frequency of adaptive change equipment, thus solving above-mentioned technical problem.
Content of the invention
The present invention provides a kind of characteristic index acquisition system, comprises a wearable device and a remote server,;Institute
The wearable device stated is used for providing user to gather body index, environmental index and dynamic indicator portablely, described
Remote server be used for storing and calculate the body index that wearable device gathered, environmental index and dynamically finger
Mark and calculate detection FREQUENCY CONTROL value to control the detection frequency of wearable device;
Wherein, described wearable device comprise body Indexs measure module, an environmental index detection module,
One dynamic indicator detection module, a communication module, described remote server comprises a database, one compares
Module and a control module;
Wherein, described body index detection module is used for referring to the body of certain detection frequency detecting user
Mark, described environmental index detection module is used for referring to certain on-site environment of detection frequency detecting user
Mark, described dynamic indicator detection module is used for the dynamic indicator of certain detection frequency detecting user, institute
The communication module stated is used for uploading respectively described body index, environmental index, dynamic indicator to described long-range
In the database of server;
Described database is used for storing in chronological order respectively the body that communication module uploads, environment, dynamic
Index, also prestores several reference body index differences intervals and several corresponding bodies in described database
Body norm controlling value, identical reference atmosphere index be interval and corresponding environmental index controlling value, identical base
Quasi dynamic index is interval and corresponding dynamic indicator controlling value, and described database also prestores body index control
Value processed, environmental index controlling value, dynamic indicator controlling value combination corresponding detection FREQUENCY CONTROL value;
Described comparison module is used for the last body index data in called data storehouse and is referred to a front body
Mark data, and calculate the difference of the forward and backward data of body index twice, and with described reference body index error
Value interval is compared, and chooses corresponding body index controlling value, and described comparison module is additionally operable to transfer number
According to environmental index data the last in storehouse, and compare with described reference atmosphere index interval, choose and correspond to
Environmental index controlling value, described comparison module is additionally operable in called data storehouse the last dynamic indicator number
According to, and compare with described benchmark dynamic indicator interval, choose corresponding dynamic indicator controlling value;
Described control module is used for receiving body index controlling value, the environmental index control of comparison module selection
Value, dynamic indicator controlling value, and combine body index controlling value, environmental index controlling value, dynamic indicator control
Value processed, transfers three combinations of values corresponding detection FREQUENCY CONTROL values in described database, and sends detection frequency
Rate controls Value Data, and the communication module on described wearable device receives described detection FREQUENCY CONTROL Value Data,
And it is sent to body index detection module, environmental index detection module, dynamic indicator detection module to change inspection
Measured frequency.
Further, in aforesaid characteristic index acquisition system, described body index detection module comprises one
Blood pressure sensor, a heart rate sensor, an EGC sensor, a body temperature trans;Described environmental index
Detection module comprises an environment temperature sensor, fine particle (PM2.5) sensor;Described dynamic indicator
Detection module comprises a velocity sensor, an altitude sensor.
Further, described communication module is GPRS transmission equipment.
Further, described dynamic indicator detection module is a six-axle acceleration sensor, described six axles
Acceleration transducer is combined with three-axis gyroscope for three axis accelerometer.
Further, described body index comprise blood pressure high pressure index (SBP), blood pressure low pressure index (DBP),
Heart rate index (HP) and body temperature index (BTemp);Described environmental index comprises environment temperature index (ATemp)
With fine particle (PM2.5) index;Described dynamic indicator comprises speed index (S) and height above sea level refers to
Mark (H).
The present invention also provides a kind of characteristic index acquisition method, based on aforesaid characteristic index acquisition system to
The body index at family, environmental index and dynamic indicator are detected, concretely comprise the following steps:
Step one, by the body index detection module on described wearable device with certain detection frequency to
The body index at family is detected, by described environmental index detection module with certain detection frequency detecting
The on-site environmental index of user, by described dynamic indicator detection module with certain detection frequency detecting
The dynamic indicator of user;
Step 2, uploads described body index, environmental index, dynamic respectively by described communication module
The index extremely database of described remote server simultaneously stores;
Step 3, by body index data the last in described comparison module called data storehouse with previous
Secondary body index data, and calculate the difference of the forward and backward data of body index twice, and with described benchmark body
Body index difference interval is compared, and chooses corresponding body index controlling value, the most simultaneously storehouse in called data
A nearly environmental index data, and compare with described reference atmosphere index interval, choose corresponding environment and refer to
Mark controlling value, the last dynamic indicator data in called data storehouse simultaneously, and dynamically refer to described benchmark
Mark interval is compared, and chooses corresponding dynamic indicator controlling value;
Step 4, receives, by described control module, body index controlling value, the environment that comparison module is chosen
Norm controlling value, dynamic indicator controlling value, and combine aforementioned three item data, transfer three in described database
Combinations of values corresponding detection FREQUENCY CONTROL value, and send detection FREQUENCY CONTROL Value Data, described wearable device
On communication module receive described detection FREQUENCY CONTROL Value Data, and be sent to body index detection module,
Environmental index detection module, dynamic indicator detection module are to change detection frequency.
Further, described body index comprise blood pressure high pressure index (SBP), blood pressure low pressure index (DBP),
Heart rate index (HP) and body temperature index (BTemp), described environmental index comprises environment temperature index (ATemp)
With fine particle (PM2.5) index, described dynamic indicator comprises speed index (S) and height above sea level refers to
Mark (H).
Characteristic index acquisition system proposed by the invention being capable of adaptive adjustment characteristic index detection with method
With the frequency uploading, keep detection running status without the moment;Additionally, the present invention reaches effective detection difference
Body index under state, especially undergos mutation when body index, user environment is undergone mutation or user
The factors such as speed, height above sea level can efficiently detect the body index of user in the case of undergoing mutation;Meanwhile,
User's body index is steady, environment constant in the case of, then adjustment detection frequency is so that wearable device
More power saving, endurance are more long, equipment life is longer.
Brief description
Fig. 1 is a kind of workflow diagram of characteristic index acquisition system provided by the present invention;
Fig. 2 is the outside drawing of wearable device in a kind of provided by the present invention characteristic index acquisition system;
Fig. 3 is the cut-away view of wearable device in a kind of provided by the present invention characteristic index acquisition system.
Description of reference numerals:
100 wearable device
101 body indexs, environmental index, dynamic indicator data upload link
102 remote servers
103 detection FREQUENCY CONTROL value transmitting link roads
Specific embodiment
A kind of embodiment of the present invention is a kind of characteristic index acquisition system, comprises a wearable device long-range with one
Server.Wearable device as shown in Figure 2 and Figure 3, blood pressure sensor, heart rate sensor,
One EGC sensor, a body temperature trans collectively constitute body index detection module, an environment temperature
Sensor, fine particle (PM2.5) sensor (not indicating in an in figure) composition environmental index detection mould
Block, a six-axle acceleration sensor forms dynamic indicator detection module, and GPRS transmission equipment constitutes communication mould
Block.Body index detection module be used for gathering body blood pressure high pressure index (SBP), blood pressure low pressure index (DBP),
Heart rate index (HP) and body temperature index (BTemp), environmental index detection module is used for gathering environment temperature and refers to
Mark (ATemp) and fine particle (PM2.5) index, aforesaid six-axle acceleration sensor is used for gathering speed
Degree index (S) and height above sea level index (H).
Remote server 102 in system shown in Figure 1 comprise a database (not in figure indicate), one
Comparison module (not indicating in figure) and a control module (not indicating in figure).Wherein database is used
In the body that storage communication module uploads in chronological order respectively, environment, dynamic indicator, in described database
Also prestore several reference body index differences intervals and several corresponding body index controlling values A, phase
With reference atmosphere index is interval and corresponding environmental index controlling value B, identical benchmark dynamic indicator is interval
And corresponding dynamic indicator controlling value C, described database also prestores body index controlling value A, environment refers to
Mark controlling value B, dynamic indicator controlling value C in combination corresponding detection FREQUENCY CONTROL value D.Described comparison mould
Block is used for the last body index data and a front body index data in called data storehouse, and before calculating,
The difference of body index data twice afterwards, and be compared with described reference body index difference interval, choosing
Take corresponding body index controlling value A, described comparison module is additionally operable in called data storehouse the last ring
Border achievement data, and compare with described reference atmosphere index interval, choose corresponding environmental index controlling value
B, described comparison module is additionally operable in called data storehouse the last dynamic indicator data, and with described
Benchmark dynamic indicator interval is compared, and chooses corresponding dynamic indicator controlling value C;Described control module is used for
Body index controlling value A of reception comparison module selection, environmental index controlling value B, dynamic indicator controlling value
C, and combine body index controlling value A, environmental index controlling value B, dynamic indicator controlling value C, transfer
Three combinations of values corresponding detection FREQUENCY CONTROL values D in described database, and send detection FREQUENCY CONTROL value
D data, the communication module on described wearable device receives described detection FREQUENCY CONTROL value D data, and passes
Deliver to body index detection module, environmental index detection module, dynamic indicator detection module to change detection frequency
Rate.
Wherein, as shown in table 1 below, aforesaid reference body index difference is interval to be 5 piecewise intervals and 5
Individual corresponding body index controlling value A can be divided into A0, A1, A2, A3, A4, and wherein first interval is SBP
< 10, DBP < 10HP < 10, BTemp < 0.5, corresponding body index controlling value is A0;Second interval
For 20 > SBP >=10,20 > DBP >=10,20 > HP >=10,1 > BTemp >=0.5, corresponding body index
Controlling value is A1;3rd interval is 30 > SBP >=20,30 > DBP >=20,30 > HP >=20,1.5 > BTemp
>=1, corresponding body index controlling value is A2;4th interval for 40 > SBP >=30,40 > DBP >=20,
40 > HP >=30,2 > BTemp >=1.5, corresponding body index controlling value is A3;5th interval is SBP
>=40, DBP >=40, HP >=40, BTemp >=2, corresponding body index controlling value is A4;Described ratio
The last compared with module calls with last body blood pressure high pressure index (SBP), blood pressure low pressure index (DBP),
Heart rate index (HP) and body temperature index (BTemp) calculating difference, and according to described reference body index
Difference interval computation respective body index controlling value, it is maximum that comparison module chooses described body controlling value sequence number
Conduct final body index controlling value.Such as SBP difference is 15, corresponding A 1, and DBP difference is 10, right
Answer A1, HP difference is 30, corresponding A 3, BTemp difference is 0.5, corresponding A 1, then body index controls
Value the maximum is A3, and corresponding interval interval for the in following table the 4th, final body index controlling value is A3.
As shown in table 2 below, described reference atmosphere index is interval to be 5 piecewise intervals and 5 corresponding rings
Border norm controlling value B0, B1, B2, B3, B4, wherein first interval are 28 >=ATemp >=18, PM < 100,
Corresponding environmental index controlling value is B0;Second interval be 17 >=ATemp >=12,33 >=ATemp >=29,100
< PM < 150, corresponding environmental index controlling value is B1;3rd interval is 11 >=ATemp >=0,36 >=ATemp
>=34,150 < PM < 200, corresponding environmental index controlling value is B2;4th interval for 0 > ATemp >=-10,
39 >=ATemp >=37,200 < PM < 300, corresponding environmental index controlling value is B3;5th interval is ATemp
< -10, ATemp >=40,300 < PM < 500, corresponding environmental index controlling value is B4;Described compare mould
Block transfers environment temperature index (ATemp) and fine particle (PM2.5) index of the last time, and according to
The each self-corresponding environmental index controlling value of described reference atmosphere index interval computation, chooses ring in aforementioned index
One of border norm controlling value sequence number maximum is final environmental index controlling value.For example the last ATemp
For 19 degree, corresponding B0, PM2.5 are 250, corresponding B3, then the maximum is B3, and corresponding to interval is following table
In the 4th interval, corresponding environmental index controlling value is B3.
As shown in table 3 below, described benchmark dynamic indicator interval for 5 piecewise intervals be 5 corresponding dynamic
State norm controlling value C0, C1, C2, C3, C4, wherein first interval are S=0 or S >=25, H=0 or H
>=10000, corresponding dynamic indicator controlling value is C0;Second interval is 5 >=S > 0,400 >=H > 0, right
The dynamic indicator controlling value answered is C1;3rd interval is 10 >=S > 5,1000 >=H > 400, corresponding dynamic
Norm controlling value is C2;4th interval is 15 >=S > 10,3000 >=H > 1000, corresponding dynamic indicator control
System is worth for C3;5th interval is 25 > S > 15,10000 > H > 3000, corresponding dynamic indicator controlling value
For C4;Described comparison module transfers speed index (S) and the height above sea level index (H) of the last time, and
According to the described each self-corresponding dynamic indicator controlling value of benchmark dynamic indicator interval computation, select in aforementioned index
Take dynamic indicator controlling value sequence number maximum one is final dynamic indicator controlling value.For example, the speed recording
Index S is 15, corresponding C0, and height above sea level is 4000, corresponding C4, then final dynamic indicator controlling value is
C4.
As shown in table 4 below, described detection FREQUENCY CONTROL value is respectively D0, D1, D2, D3, D4 five etc.
Level, its middle grade one is to detect once for one hour, i.e. D0=1/60min;Grade two is detection one in 30 minutes
Secondary, i.e. D1=1/30min;Grade three is to detect once for 15 minutes, i.e. D2=1/15min;Grade four is 5
Minute detects once, i.e. D3=1/5min;Grade five is to detect once for 1 minute, i.e. D4=1/1min;Described
Detection FREQUENCY CONTROL value and described body index controlling value, environmental index controlling value, dynamic indicator controlling value
Combination corresponding relation be:Corresponding aforementioned three item data of D0 are the combination of A0B0C0;Corresponding described three of D1
Data A, B, the sequence number at least of C are equal to 1, and remaining sequence number is respectively less than 1 combination;D2 corresponds to institute
The sequence number at least one stating three item data A, B, C is equal to 2, and remaining sequence number is respectively less than 2 combination;D3
The sequence number of corresponding described three item data A, B, C at least one is equal to 3, and remaining sequence number is respectively less than 3 group
Close;The sequence number at least one of corresponding described three item data A, B, the C of D4 is equal to 4, and remaining sequence number is respectively less than
4 combination.The body index controlling value that for example comparison module calculates is A1, and environmental index controlling value is B3,
Dynamic indicator controlling value is C4, then control module is calculated detection FREQUENCY CONTROL value is D4.
For example, user's wearable device under effective linking status, and body index is detected by wearable device,
Initial conditions are that detection in every 30 minutes once uploads a grade two (D1).Now in May, 2014 time
Afternoon 17 on the 13rd:34 points, location is Shanghai, and user's items sign data is:SBP96, DBP64, HR88,
BTemp36.4 degree, ATemp27 degree, PM156, speed 2km/h.This organizes body index, environmental index, moves
, after GPRS module is uploaded to remote server, comparison module can be by before this data and user for state achievement data
Data Comparison, and previous secondary data is SBP86, DBP56, HR68, then this time on as shown by data heart rate
Rise higher (A2), then integrated environment index judges that (B2) and dynamic indicator judge (C1), system can be lifted
, to grade three (D2), detection in 15 minutes once uploads once, and this is arranged for collection, upload data frequency
Pass to wearable device to be configured updating.Hereafter, wearable device can detect and upload once every 15 minutes
Data.If this user geographical position is in Beijing, PM is 430 (B4), then collection, upload data frequency meeting quilt
It is adjusted to grade four (D3) to survey once for 5 minutes.If now other situations are constant, heart rate persistently rises (A4),
Then collection, upload frequencies can be adjusted to grade five (D4) 1 minute once by system self-adaption.If but the hereafter heart
While rate convergence is normal there is big change (highly raw tall and big in 1 myriametre etc.) (C0) in dynamic indicator, then
Consider that user is taking flight traffic, health is good, then gather, uploading data frequency can by system certainly
Adapt to pull back to grade one (D0), 1 hour once.
An alternative embodiment of the invention is a kind of characteristic index acquisition method as shown in Figure 1, aforesaid spy
Body index, environmental index and the dynamic indicator of levying index collection system of users are detected, concrete steps
For:
Step one, by the body index detection module on described wearable device 100 with certain detection frequency
The body index of user is detected, by described environmental index detection module with certain detection frequency
The detection on-site environmental index of user, by described dynamic indicator detection module with certain detection frequency
The dynamic indicator of detection user;
Step 2, by described communication module respectively through body index, environmental index, dynamic indicator number
Upload described body index, environmental index, dynamic indicator to described remote server according to uploading link 101
102 database simultaneously stores;
Step 3, by body index data the last in described comparison module called data storehouse with previous
Secondary body index data, and calculate the difference of the forward and backward data of body index twice, and with described benchmark body
Body index difference interval is compared, and chooses corresponding body index controlling value, the most simultaneously storehouse in called data
A nearly environmental index data, and compare with described reference atmosphere index interval, choose corresponding environment and refer to
Mark controlling value, the last dynamic indicator data in called data storehouse simultaneously, and dynamically refer to described benchmark
Mark interval is compared, and chooses corresponding dynamic indicator controlling value;
Step 4, receives, by described control module, body index controlling value, the environment that comparison module is chosen
Norm controlling value, dynamic indicator controlling value, and combine aforementioned three item data, transfer three in described database
Combinations of values corresponding detection FREQUENCY CONTROL value, and send inspection by detecting FREQUENCY CONTROL value transmitting link road 103
Measured frequency controls Value Data, and the communication module on described wearable device 100 receives described detection FREQUENCY CONTROL
Value Data, and it is sent to body index detection module, environmental index detection module, dynamic indicator detection module
To change detection frequency.
Aforesaid body index comprises blood pressure high pressure index (SBP), blood pressure low pressure index (DBP), heart rate refer to
Mark (HP) and body temperature index (BTemp), described environmental index comprise environment temperature index (ATemp) and
Fine particle (PM2.5) index, described dynamic indicator comprises speed index (S) and height above sea level index
(H);
Described reference body index difference is interval to be 5 piecewise intervals and 5 corresponding body indexs control
Value A0, A1, A2, A3, A4, wherein first interval are SBP < 10, DBP < 10, HP < 10, BTemp
< 0.5, corresponding body index controlling value is A0;Second interval be 20 > SBP >=10,20 > DBP >=10,
20 > HP >=10,1 > BTemp >=0.5, corresponding body index controlling value is A1;3rd interval is 30 > SBP
>=20,30 > DBP >=20,30 > HP >=20,1.5 > BTemp >=1, corresponding body index controlling value is
A2;4th interval is 40 > SBP >=30,40 > DBP >=20,40 > HP >=30,2 > BTemp >=1.5,
Corresponding body index controlling value is A3;5th interval is SBP >=40, DBP >=40, HP >=40, BTemp
>=2, corresponding body index controlling value is A4;Described comparison module is transferred the last with last
Body blood pressure high pressure index (SBP), blood pressure low pressure index (DBP), heart rate index (HP) and body temperature index (BTemp)
And calculating difference, and according to the described respective body index controlling value of reference body index difference interval computation,
Comparison module chooses the maximum conduct final body index controlling value of described body controlling value sequence number;
Described reference atmosphere index is interval to be 5 piecewise intervals and 5 corresponding environmental index controlling values
B0, B1, B2, B3, B4, wherein first interval are 28 >=ATemp >=18, PM < 100, corresponding environment
Norm controlling value is B0;Second interval is 17 >=ATemp >=12,33 >=ATemp >=29,100 < PM < 150,
Corresponding environmental index controlling value is B1;3rd interval be 11 >=ATemp >=0,36 >=ATemp >=34,150
< PM < 200, corresponding environmental index controlling value is B2;4th interval for 0 > ATemp >=-10,39 >=
ATemp >=37,200 < PM < 300, corresponding environmental index controlling value is B3;5th interval is ATemp
< -10, ATemp >=40,300 < PM < 500, corresponding environmental index controlling value is B4;Described compare mould
Block transfers environment temperature index (ATemp) and fine particle (PM2.5) index of the last time, and according to
The each self-corresponding environmental index controlling value of described reference atmosphere index interval computation, chooses ring in aforementioned index
One of border norm controlling value sequence number maximum is final environmental index controlling value;
Described benchmark dynamic indicator is interval to be 5 corresponding dynamic indicator controlling values for 5 piecewise intervals
C0, C1, C2, C3, C4, wherein first interval are S=0 or S >=25, H=0 or H >=10000, corresponding
Dynamic indicator controlling value be C0;Second interval is 5 >=S > 0,400 >=H > 0, corresponding dynamic indicator control
System is worth for C1;3rd interval is 10 >=S > 5,1000 >=H > 400, and corresponding dynamic indicator controlling value is
C2;4th interval is 15 >=S > 10,3000 >=H > 1000, and corresponding dynamic indicator controlling value is C3;The
Five intervals are 25 > S > 15,10000 > H > 3000, and corresponding dynamic indicator controlling value is C4.
Described detection FREQUENCY CONTROL value is respectively five grades of D0, D1, D2, D3, D4, its middle grade one
For detection in a hour once, i.e. D0=1/60min;Grade two is to detect once for 30 minutes, i.e. D1=1/30min;
Grade three is to detect once for 15 minutes, i.e. D2=1/15min;Grade four is to detect once, that is, for 5 minutes
D3=1/5min;Grade five is to detect once for 1 minute, i.e. D4=1/1min;
Described detection FREQUENCY CONTROL value and described body index controlling value, environmental index controlling value, dynamically finger
Mark controlling value combination corresponding relation be:Corresponding aforementioned three item data of D0 are the combination of A0B0C0;D1 corresponds to
The sequence number of described three item data A, B, C at least one is equal to 1, and remaining sequence number is respectively less than 1 combination;
The sequence number at least one of corresponding described three item data A, B, the C of D2 is equal to 2, and remaining sequence number is respectively less than 2
Combination;The sequence number at least one of corresponding described three item data A, B, the C of D3 is equal to 3, and remaining sequence number is all little
In 3 combination;The sequence number at least one of corresponding described three item data A, B, the C of D4 is equal to 4, remaining sequence
Number be respectively less than 4 combination.
Those of ordinary skill in the art can be in other optional structures of anticipation and embodiment or above-described embodiment
On changed.Above-mentioned all embodiments belong within the scope of the present invention, but are not used in the restriction present invention
Protection domain.
Claims (4)
1. a kind of characteristic index acquisition system, comprises a wearable device and a remote server;
Described wearable device is used for providing user to gather body index, environmental index and dynamic indicator portablely,
Described remote server is for storing and calculating the body index that wearable device is gathered, environmental index and move
State index simultaneously calculates detection FREQUENCY CONTROL value to control the detection frequency of wearable device;
Wherein, described wearable device comprise body Indexs measure module, an environmental index detection module,
One dynamic indicator detection module, a communication module, described remote server comprises a database, one compares
Module and a control module;
Wherein, described body index detection module is used for referring to the body of certain detection frequency detecting user
Mark, described environmental index detection module is used for referring to certain on-site environment of detection frequency detecting user
Mark, described dynamic indicator detection module is used for the dynamic indicator of certain detection frequency detecting user, institute
The communication module stated is used for uploading respectively described body index, environmental index, dynamic indicator to described long-range
In the database of server;
Described database is used for storing in chronological order respectively the body that communication module uploads, environment, dynamic
Index, also prestores several reference body index differences intervals and several corresponding bodies in described database
Body norm controlling value, several reference atmosphere indexs are interval and corresponding environmental index controlling value, several bases
Quasi dynamic index is interval and corresponding dynamic indicator controlling value, and described database also prestores body index control
Value processed, environmental index controlling value, dynamic indicator controlling value combination corresponding detection FREQUENCY CONTROL value;
Described comparison module is used for the last body index data in called data storehouse and is referred to a front body
Mark data, and calculate the difference of the forward and backward data of body index twice, and with described reference body index error
Value interval is compared, and chooses corresponding body index controlling value;Described comparison module is additionally operable to transfer number
According to environmental index data the last in storehouse, and compare with described reference atmosphere index interval, choose and correspond to
Environmental index controlling value;Described comparison module is additionally operable in called data storehouse the last dynamic indicator number
According to, and compare with described benchmark dynamic indicator interval, choose corresponding dynamic indicator controlling value;
Described control module is used for receiving body index controlling value, the environmental index control of comparison module selection
Value, dynamic indicator controlling value, and combine body index controlling value, environmental index controlling value, dynamic indicator control
Value processed, transfers three combinations of values corresponding detection FREQUENCY CONTROL values in described database, and sends detection frequency
Rate controls Value Data;Communication module on described wearable device receives described detection FREQUENCY CONTROL Value Data,
And it is sent to body index detection module, environmental index detection module, dynamic indicator detection module to change inspection
Measured frequency;
Described body index comprises blood pressure high pressure index S BP, blood pressure low pressure index DBP, heart rate index HP
With body temperature index BTemp;Described environmental index comprises environment temperature index ATemp and fine particle PM2.5
Index;Described dynamic indicator comprises speed index S and height above sea level index H;
Described reference body index difference is interval to be 5 piecewise intervals and 5 corresponding body indexs control
Value A0, A1, A2, A3, A4, wherein first interval are SBP < 10, DBP < 10, HP < 10, BTemp
< 0.5, corresponding body index controlling value is A0;Second interval be 20 > SBP >=10,20 > DBP >=10,
20 > HP >=10,1 > BTemp >=0.5, corresponding body index controlling value is A1;3rd interval is 30 > SBP
>=20,30 > DBP >=20,30 > HP >=20,1.5 > BTemp >=1, corresponding body index controlling value is
A2;4th interval is 40 > SBP >=30,40 > DBP >=20,40 > HP >=30,2 > BTemp >=1.5,
Corresponding body index controlling value is A3;5th interval is SBP >=40, DBP >=40, HP >=40 or BTemp
>=2, corresponding body index controlling value is A4;Described comparison module is transferred the last with last
Body blood pressure high pressure index S BP, blood pressure low pressure index DBP, heart rate index HP and body temperature index BTemp are simultaneously
Calculating difference, and according to the described respective body index controlling value of reference body index difference interval computation,
Comparison module chooses the maximum conduct final body index controlling value of described body controlling value sequence number;
Described reference atmosphere index is interval to be 5 piecewise intervals and 5 corresponding environmental index controlling values
B0, B1, B2, B3, B4, wherein first interval are 28 >=ATemp >=18, PM < 100, corresponding environment
Norm controlling value is B0;Second interval is 17 >=ATemp >=12,33 >=ATemp >=29,100 < PM < 150,
Corresponding environmental index controlling value is B1;3rd interval be 11 >=ATemp >=0,36 >=ATemp >=34,150
< PM < 200, corresponding environmental index controlling value is B2;4th interval for 0 > ATemp >=-10,39 >=
ATemp >=37,200 < PM < 300, corresponding environmental index controlling value is B3;5th interval is ATemp
< -10, ATemp >=40,300 < PM < 500, corresponding environmental index controlling value is B4;Described compare mould
Block transfers environment temperature index ATemp and the fine particle PM2.5 index of the last time, and according to described
The each self-corresponding environmental index controlling value of reference atmosphere index interval computation, chooses environmental index in aforementioned index
One of controlling value sequence number maximum is final environmental index controlling value;
Described benchmark dynamic indicator is interval to be 5 corresponding dynamic indicator controlling values for 5 piecewise intervals
C0, C1, C2, C3, C4, wherein first interval are S=0 or S >=25 or H=0 or H >=10000, corresponding
Dynamic indicator controlling value be C0;Second interval is 5 >=S > 0 or 400 >=H > 0, corresponding dynamic indicator
Controlling value is C1;3rd interval is 10 >=S > 5 or 1000 >=H > 400, corresponding dynamic indicator controlling value
For C2;4th interval is 15 >=S > 10 or 3000 >=H > 1000, and corresponding dynamic indicator controlling value is C3;
5th interval is 25 > S > 15 or 10000 > H > 3000, and corresponding dynamic indicator controlling value is C4;Described
Comparison module be used for transferring the speed index S and height marker H of the last time, and according to described benchmark
The each self-corresponding dynamic indicator controlling value of dynamic indicator interval computation, and choose dynamic indicator controlling value sequence number
Big one is final dynamic indicator controlling value;
Described detection FREQUENCY CONTROL value is respectively five grades of D0, D1, D2, D3, D4, its middle grade one
For detection in a hour once, i.e. D0=1/60min;Grade two is to detect once for 30 minutes, i.e. D1=1/30min;
Grade three is to detect once for 15 minutes, i.e. D2=1/15min;Grade four is to detect once, that is, for 5 minutes
D3=1/5min;Grade five is to detect once for 1 minute, i.e. D4=1/1min;
It is characterized in that:Described detection FREQUENCY CONTROL value and described body index controlling value, environmental index control
Value processed, the corresponding relation of dynamic indicator controlling value combination are:Corresponding aforementioned three item data of D0 are A0B0C0's
Combination;The sequence number at least one of corresponding described three item data A, B, the C of D1 is equal to 1, and remaining sequence number is all little
In 1 combination;The sequence number at least one of corresponding described three item data A, B, the C of D2 is equal to 2, remaining sequence
Number be respectively less than 2 combination;The sequence number at least one of corresponding described three item data A, B, the C of D3 is equal to 3,
Remaining sequence number is respectively less than 3 combination;The sequence number at least one etc. of corresponding described three item data A, B, the C of D4
In 4, remaining sequence number is respectively less than 4 combination.
2. characteristic index acquisition system as claimed in claim 1 is it is characterised in that described body index detects mould
Block comprises a blood pressure sensor, a heart rate sensor, an EGC sensor, a body temperature trans;Described
Environmental index detection module comprises an environment temperature sensor, fine particle PM2.5 sensor;Described is dynamic
State Indexs measure module comprises a velocity sensor, an altitude sensor.
3. characteristic index acquisition system as claimed in claim 1 is it is characterised in that described communication module is GPRS
Transmission equipment.
4. characteristic index acquisition system as claimed in claim 1 is it is characterised in that described dynamic indicator detects mould
Block is a six-axle acceleration sensor, and described six-axle acceleration sensor is three axis accelerometer and three axle tops
Spiral shell instrument combines.
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| CN105635234B (en) | 2014-11-29 | 2020-02-21 | 华为技术有限公司 | Method and device for managing human body equipment |
| CN104392352A (en) | 2014-12-10 | 2015-03-04 | 京东方科技集团股份有限公司 | Intelligent wearable device and non-contact payment method |
| CN104754710B (en) * | 2015-03-04 | 2018-05-01 | 广东欧珀移动通信有限公司 | A kind of equipment electricity saving method and equipment |
| WO2016193049A1 (en) * | 2015-06-05 | 2016-12-08 | Koninklijke Philips N.V. | Device and method for monitoring a subject |
| CN104992394A (en) * | 2015-07-24 | 2015-10-21 | 宽度科技有限公司 | Remote health physical examination management method |
| CN105249949A (en) * | 2015-09-22 | 2016-01-20 | 深圳市元征科技股份有限公司 | Heart rate test method and apparatus |
| CN105635946A (en) * | 2015-12-23 | 2016-06-01 | 木牙(天津)科技有限公司 | System with wearable terminal which output data based on power saving mode and method |
| CN107913059A (en) * | 2016-10-09 | 2018-04-17 | 炬芯(珠海)科技有限公司 | The method and its equipment of a kind of monitor heart rate |
| CN106691458B (en) * | 2016-11-19 | 2019-11-12 | 广东乐源数字技术有限公司 | A kind of method and system of oximetry data optimization |
| CN110750131A (en) * | 2019-09-18 | 2020-02-04 | 维沃移动通信有限公司 | Temperature control method and device, terminal equipment and storage medium |
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| US8738925B1 (en) * | 2013-01-07 | 2014-05-27 | Fitbit, Inc. | Wireless portable biometric device syncing |
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