CN104777759A - Control method, device and electronic device - Google Patents

Abstract

The embodiment of the invention provides a control method, a device and an electronic device. The method is applied to the electronic device with an acquisition unit for information acquisition, and when the electronic device is in a working state, the acquisition unit has an enabled state and a disabled state. The method comprises steps: a first parameter is detected; according to the first parameter, a target state switching time interval for the acquisition unit is determined, wherein the target state switching time interval is the time interval between an Nth moment at which the acquisition unit is switched from the disabled state to the enabled state at the Nth time and an (N+1)th moment at which the acquisition unit is switched from the disabled state to the enabled state at the (N+1)th time, and the acquisition unit has lower power consumption in the disabled state than in the enabled state; and the acquisition unit is controlled to perform information acquisition according to the target state switching time interval. Adaptive dynamic adjustment can be carried out on the information acquisition time interval for the acquisition unit of the electronic device, power consumption of the electronic device is reduced, and the life of the electronic device is prolonged.

Description

A kind of control method, device and electronic equipment

Technical field

The present invention relates to parts awakening technology field, more particularly, relate to a kind of control method, device and electronic equipment.

Background technology

In current electronic equipment, there is numerous collecting units: collecting unit mainly carries out the collection of information, so that electronic equipment carries out processing to gathered information.Collecting unit makes the function of electronic equipment more diversified, but the work of numerous collecting units is also for electronic equipment brings a large amount of power consumptions, how on the function operation and power consumption of electronic equipment, seeking balance becomes the research point that those skilled in the art very pay close attention to.

The duty of the collecting unit in current electronic equipment controls manually by user, fixed time interval is adopted to carry out work, if what user was inartificial arranges the duty of collecting unit for closing, so collecting unit will adopt fixed time interval to carry out work always, this will bring a large amount of powder consumption of electronic equipments, affect the continuation of the journey of electronic equipment greatly; Can find out, existing collecting unit adopts fixed time interval to carry out work, and when manual control collecting unit is not closed, collecting unit will be in opening always, there is larger power consumption by making electronic equipment in this, affects the continuation of the journey of electronic equipment.

Summary of the invention

In view of this, the embodiment of the present invention provides a kind of control method, device and electronic equipment, and adopt fixed time interval to carry out work to solve existing manual control collecting unit, existing powder consumption of electronic equipment is comparatively large, affects the problem of the continuation of the journey of electronic equipment.

For achieving the above object, the embodiment of the present invention provides following technical scheme:

A kind of control method, be applied to electronic equipment, described electronic equipment has the collecting unit for information acquisition, and when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described method comprises:

Detect the first parameter;

Dbjective state interval switching time of described collecting unit is determined according to described first parameter, wherein, described dbjective state is spaced apart described collecting unit switches to described enabled state for the N time n-hour from described disable state switching time, the time interval in the N+1 moment of described enabled state is switched to for the N+1 time from described disable state with described collecting unit, wherein, described collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state;

Control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

The embodiment of the present invention also provides a kind of control device, be applied to electronic equipment, described electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described device comprises:

Detection module, for detecting the first parameter;

Determination module, for determining dbjective state interval switching time of described collecting unit according to described first parameter, wherein, described dbjective state is spaced apart described collecting unit switches to described enabled state for the N time n-hour from described disable state switching time, the time interval in the N+1 moment of described enabled state is switched to for the N+1 time from described disable state with described collecting unit, wherein, described collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state;

First controls acquisition module, carries out information acquisition for controlling described collecting unit according to described dbjective state interval switching time.

The embodiment of the present invention also provides a kind of electronic equipment, described electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described electronic equipment comprises control device described above.

Based on technique scheme, the control method that the embodiment of the present invention provides, by detecting the first parameter, thus according to dbjective state interval switching time of the first parameter determination collecting unit, dbjective state is spaced apart described collecting unit switches to enabled state for the N time n-hour from disable state switching time, the time interval in the N+1 moment of enabled state is switched to for the N+1 time from disable state with described collecting unit, wherein, collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state, information acquisition is carried out according to determined dbjective state interval switching time by controlling described collecting unit, thus achieve the automatic dynamic adjustment collecting unit of electronic equipment being carried out to the time interval of information acquisition, ensure that collecting unit is not adopt fixed time interval to carry out information acquisition always, but the adjustment in the time interval of adaptive information acquisition can be carried out by the first parameter, greatly reduce the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

Accompanying drawing explanation

In order to be illustrated more clearly in the embodiment of the present invention or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is some embodiments of the present invention, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

The first pass figure of the control method that Fig. 1 provides for the embodiment of the present invention;

Second process flow diagram of the control method that Fig. 2 provides for the embodiment of the present invention;

3rd process flow diagram of the control method that Fig. 3 provides for the embodiment of the present invention;

4th process flow diagram of the control method that Fig. 4 provides for the embodiment of the present invention;

5th process flow diagram of the control method that Fig. 5 provides for the embodiment of the present invention;

6th process flow diagram of the control method that Fig. 6 provides for the embodiment of the present invention;

7th process flow diagram of the control method that Fig. 7 provides for the embodiment of the present invention;

Fig. 8 provides the first pass figure at state interval switching time that really sets the goal for the embodiment of the present invention;

Fig. 9 provides second process flow diagram at state interval switching time that really sets the goal for the embodiment of the present invention;

8th process flow diagram of the control method that Figure 10 provides for the embodiment of the present invention;

9th process flow diagram of the control method that Figure 11 provides for the embodiment of the present invention;

The first structured flowchart of the control device that Figure 12 provides for the embodiment of the present invention;

The second structured flowchart of the control device that Figure 13 provides for the embodiment of the present invention;

The first structured flowchart of the first control acquisition module that Figure 14 provides for the embodiment of the present invention;

The first the alternate configurations block diagram of the determination module that Figure 15 provides for the embodiment of the present invention;

The second alternate configurations block diagram of the first control acquisition module that Figure 16 provides for the embodiment of the present invention;

The third structured flowchart of the control device that Figure 17 provides for the embodiment of the present invention;

The second alternate configurations block diagram of the determination module that Figure 18 provides for the embodiment of the present invention;

The third structured flowchart of the determination module that Figure 19 provides for the embodiment of the present invention;

The first structured flowchart of the detection module that Figure 20 provides for the embodiment of the present invention;

4th kind of structured flowchart of the determination module that Figure 21 provides for the embodiment of the present invention;

The second structured flowchart of the detection module that Figure 22 provides for the embodiment of the present invention;

The first structured flowchart of the second detecting unit that Figure 23 provides for the embodiment of the present invention;

5th kind of structured flowchart of the determination module that Figure 24 provides for the embodiment of the present invention;

6th kind of structured flowchart of the determination module that Figure 25 provides for the embodiment of the present invention;

7th kind of structured flowchart of the determination module that Figure 26 provides for the embodiment of the present invention;

8th kind of structured flowchart of the determination module that Figure 27 provides for the embodiment of the present invention;

The third structured flowchart of the detection module that Figure 28 provides for the embodiment of the present invention;

9th kind of structured flowchart of the determination module that Figure 29 provides for the embodiment of the present invention;

The 5th the first structured flowchart determining performance element that Figure 30 provides for the embodiment of the present invention;

The 5th the second structured flowchart determining performance element that Figure 31 provides for the embodiment of the present invention.

Embodiment

For making the object of the embodiment of the present invention, technical scheme and advantage clearly, below in conjunction with the accompanying drawing in the embodiment of the present invention, technical scheme in the embodiment of the present invention is clearly and completely described, obviously, described embodiment is the present invention's part embodiment, instead of whole embodiments.Based on the embodiment in the present invention, those of ordinary skill in the art, not making the every other embodiment obtained under creative work prerequisite, belong to the scope of protection of the invention.

The first pass figure of the control method that Fig. 1 provides for the embodiment of the present invention, the method can be applicable to the electronic equipment with collecting unit, this collecting unit can be used for information, in embodiments of the present invention, collecting unit has enabled state and disable state, when collecting unit is in enabled state, by the collection of the information of carrying out, when collecting unit is in disable state, the collection of information will do not carried out; With reference to Fig. 1, the method can comprise:

Step S100, detect the first parameter;

Optionally, the first parameter can be corresponding with the predetermined state of electronic equipment, and predetermined state can be the mobile status of electronic equipment, state of charge, geographic position variable condition etc.; According to the difference of the type of collecting unit, the type of the first parameter detected also can adjust, and for the type of first parameter that will detect, the embodiment of the present invention is not restricted.

Step S110, determine dbjective state interval switching time of described collecting unit according to described first parameter;

Optionally, state interval switching time of collecting unit can be the collecting unit contiguous time interval being in enabled state for twice; Dbjective state interval switching time can be the desired value at embodiment of the present invention state to be determined interval switching time, in embodiments of the present invention, and what dbjective state interval switching time was corresponding is virgin state interval switching time, laststate interval switching time at dbjective state interval switching time can be thought in virgin state interval switching time.

Optionally, for ease of understanding, t1 can be established, t2, t3 ... the time series of tn, wherein current time is t3, t1 and t2 is last time, and t4 ~ tn is future time instance, and state interval switching time of each adjacent moment collecting unit is different; Then be spaced apart dbjective state interval switching time switching time in t3 moment state to be determined, the state that the t2 moment adopts is spaced apart virgin state interval switching time switching time, As time goes on, the t4 moment becomes current time, then corresponding, the t4 moment, state to be determined was spaced apart dbjective state interval switching time switching time, the t3 moment to determine and state interval switching time adopted becomes virgin state interval switching time.

Concrete, dbjective state interval switching time can be collecting unit switches to enabled state for the N time n-hour from disable state, the time interval in the N+1 moment of enabled state is switched to for the N+1 time from disable state, i.e. the mistiming of N+1 moment and n-hour with collecting unit; Due in the collection of enabled state collecting unit by the information of carrying out, therefore collecting unit is power consumption lower than enabled state in the power consumption of disable state.

Step S120, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

Optionally, the embodiment of the present invention can collecting unit start when or before, determine dbjective state interval switching time, after determining dbjective state interval switching time, when collecting unit starts, collecting unit carries out information collection according to dbjective state interval switching time can be controlled; Optionally, the embodiment of the present invention also can when collecting unit be in running order, determine dbjective state interval switching time, state interval switching time of collecting unit is adjusted to dbjective state interval switching time by virgin state interval switching time, determined dbjective state interval switching time is different with virgin state interval switching time, thus realize the dynamic conditioning at state interval switching time, namely adaptive adjustment can be carried out according to the first detected parameter in dbjective state interval switching time.Method shown in Fig. 1 can be applicable to the whole process at the collecting unit work whole story, also can be applicable to any instant at the collecting unit work whole story.

The control method that the embodiment of the present invention provides, by detecting the first parameter, thus according to dbjective state interval switching time of the first parameter determination collecting unit, dbjective state is spaced apart described collecting unit switches to enabled state for the N time n-hour from disable state switching time, the time interval in the N+1 moment of enabled state is switched to for the N+1 time from disable state with described collecting unit, wherein, collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state, information acquisition is carried out according to determined dbjective state interval switching time by controlling described collecting unit, thus the time interval making the collecting unit of electronic equipment carry out information acquisition can carry out adaptive dynamic conditioning according to the first parameter, instead of adopt fixed time interval to carry out information acquisition always, reduce the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

Optionally, in embodiments of the present invention, first parameter can the predetermined state of electronic equipment corresponding, as the first parameter can characterize scene at electronic equipment and state, thus dbjective state interval switching time of described collecting unit is determined by the first parameter, can ensure under the scene at electronic equipment and state, the accuracy of collecting unit information acquisition; Collecting unit carries out the self-adaptation dynamic conditioning in the time interval of information acquisition simultaneously, and the power consumption of electronic equipment can be made to be dynamically adjustable; Can find out, the control method that the embodiment of the present invention provides can reach balance in the accuracy of the power consumption of electronic equipment and collecting unit Information Monitoring, when ensureing the accuracy of collecting unit information acquisition, reducing the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

Optionally, in embodiments of the present invention, collecting unit can be the unit that can carry out information acquisition arbitrarily, as gathered the collecting unit of monochrome information, gathers the collecting unit of acoustic information, the collecting unit etc. of collection position information.

Already described above, the embodiment of the present invention can when collecting unit be in running order, carry out the determination at dbjective state interval switching time, thus in the course of work of collecting unit, dynamic conditioning is carried out to state interval switching time, make collecting unit carry out the collection of information by state interval switching time of dynamic conditioning, thus in the course of work of collecting unit, realize the dynamically adjustable of powder consumption of electronic equipment, reduce the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.Corresponding, Fig. 2 shows corresponding control method flow process, the second process flow diagram of the control method that Fig. 2 provides for the embodiment of the present invention, and with reference to Fig. 2, the method can comprise:

Step S200, detect the first parameter;

Step S210, control described collecting unit and carry out information acquisition according to virgin state interval switching time;

Compare method shown in Fig. 1, virgin state interval switching time can think that collecting unit switches to the M moment of enabled state for the M time from disable state, switch to the time interval in the M+1 moment of enabled state for the M+1 time from disable state with collecting unit, wherein M is less than N; Can think that virgin state interval switching time is previous status interval switching time at dbjective state interval switching time.

Step S220, determine dbjective state interval switching time of described collecting unit according to described first parameter;

Step S230, contiguous for the described collecting unit time interval being in enabled state for twice is switched to described dbjective state interval switching time by described virgin state interval switching time;

Step S240, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

Optionally, contiguous for the collecting unit time interval carrying out information acquisition for twice can be switched to described dbjective state interval switching time by described virgin state interval switching time, thus control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

T1 can be established, t2, t3 ... the time series of tn, and state interval switching time of each adjacent moment collecting unit is different, if the state of t3 moment collecting unit is spaced apart dbjective state interval switching time switching time, the state of t2 moment collecting unit is spaced apart virgin state interval switching time switching time, then after determining virgin state interval switching time in t2 moment, and before the t2 moment carries out information acquisition according to virgin state interval switching time, the embodiment of the present invention can detect the first parameter, state interval switching time of collecting unit described in the t3 moment is determined according to described first parameter, thus contiguous for the described collecting unit time interval of carrying out information acquisition for twice is switched to described dbjective state interval switching time by described virgin state interval switching time, information acquisition is carried out according to described dbjective state interval switching time to control described collecting unit in the t3 moment.

Optionally, method shown in Fig. 2 is after detection first parameter, controls described collecting unit and carries out information acquisition according to virgin state interval switching time, namely the embodiment of the present invention can before the described collecting unit of control carries out information acquisition according to virgin state interval switching time, namely the determination carrying out dbjective state interval switching time is set about, the sequential at visible embodiment of the present invention determination dbjective state interval switching time is continuous print, the embodiment of the present invention can on determining a moment virgin state interval switching time after, adopt before virgin state interval switching time in a moment on this carries out information acquisition, namely the determination carrying out dbjective state interval switching time is started, thus ensure that the determination at dbjective state interval switching time in the course of work of collecting unit is carried out in real time, thus improve the accuracy at determined dbjective state interval switching time.Can in the course of work of collecting unit by method shown in Fig. 2, realize the dynamically adjustable in real time of state interval switching time of collecting unit, and determined dbjective state interval switching time has higher accuracy, thus realize the dynamically adjustable of powder consumption of electronic equipment, achieve the object reducing powder consumption of electronic equipment.

3rd process flow diagram of the control method that Fig. 3 provides for the embodiment of the present invention, with reference to Fig. 3, the method can comprise:

Step S300, control described collecting unit and carry out information acquisition according to virgin state interval switching time;

Step S310, detect the first parameter;

Step S320, determine dbjective state interval switching time of described collecting unit according to described first parameter;

Step S330, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

T1 can be established, t2, t3 ... the time series of tn, and state interval switching time of each adjacent moment collecting unit is different, if the state of t3 moment collecting unit is spaced apart dbjective state interval switching time switching time, the state of t2 moment collecting unit is spaced apart virgin state interval switching time switching time, then after the t2 moment carries out information acquisition according to virgin state interval switching time, the embodiment of the present invention can detect the first parameter, determine state interval switching time of collecting unit described in the t3 moment, thus contiguous for the described collecting unit time interval of carrying out information acquisition for twice is switched to described dbjective state interval switching time by described virgin state interval switching time, information acquisition is carried out according to described dbjective state interval switching time to control described collecting unit in the t3 moment.

Method shown in Fig. 3 after collecting unit carries out information acquisition according to virgin state interval switching time, can start the determination carrying out dbjective state interval switching time, thus ensure that determining in order of state interval switching time.

Known shown in composition graphs 2 and Fig. 3, the embodiment of the present invention is before dbjective state interval switching time determining described collecting unit according to described first parameter, or before detection first parameter, collecting unit is the collection of information of carrying out according to virgin state interval switching time, after dbjective state interval switching time determining described collecting unit according to the first parameter, contiguous for the collecting unit time interval of carrying out information acquisition for twice can be switched to described dbjective state interval switching time by described virgin state interval switching time.

Already described above, the embodiment of the present invention can collecting unit start when or before, carry out the determination at dbjective state interval switching time; Corresponding, Fig. 4 shows the 4th process flow diagram of the control method that the embodiment of the present invention provides, and with reference to Fig. 4, the method can comprise:

Step S400, detect the first parameter;

Step S410, start described collecting unit time, determine dbjective state interval switching time of described collecting unit according to described first parameter;

Step S420, start described collecting unit, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

Another kind of control method flow process can be: detect the first parameter; Before the described collecting unit of startup, determine dbjective state interval switching time of described collecting unit according to described first parameter; Start described collecting unit, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

Optionally, collecting unit start when or before, the embodiment of the present invention can determine described dbjective state interval switching time from multiple candidate state interval switching time, or calculates described dbjective state interval switching time according to the first detected parameter.

The embodiment of the present invention collecting unit start when or before, carrying out the determination at dbjective state interval switching time, collecting unit can being made when repeatedly starting, adopt different dbjective state intervals switching time to carry out information acquisition, collecting unit can dbjective state interval switching time of dynamically changeable be started, ensure that the power consumption of the electronic equipment of collecting unit when starting is adjustable, and dbjective state interval switching time that collecting unit adopts when each startup is corresponding with the first detected parameter, ensure that the self-adaptation that collecting unit can carry out dbjective state interval switching time according to the first parameter is dynamically determined, thus just can dbjective state interval switching time of guaranteed information acquisition accuracy when collecting unit is started, and make electronic equipment just can have lower power consumption when collecting unit starts, reduce the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

Optionally, after collecting unit starts, the embodiment of the present invention can also carry out the dynamic conditioning at state interval switching time in the course of work of collecting unit; Corresponding, Fig. 5 shows the 5th flow process of the control method that the embodiment of the present invention provides, and after the 5th flow process occurs in collecting unit startup, with reference to Fig. 5, the method can comprise:

Step S500, monitor the change of the first parameter;

If the change of described first parameter that step S510 detects meets pre-conditioned, upgrade state interval switching time of described collecting unit, to determine more new state interval switching time, described more new state interval switching time is corresponding with the first parameter after change;

After collecting unit starts, the embodiment of the present invention can detect the first parameter, when the change of the first detected parameter meets pre-conditioned, can upgrade state interval switching time of collecting unit, thus realize the dynamically adjustable of state interval switching time of collecting unit after collecting unit starts; More new state interval switching time can be when the change of the first parameter meets pre-conditioned herein, upgrade after state interval switching time, more new state interval switching time need be corresponding with the first parameter after change, the setting of concrete corresponded manner is determined by embody rule situation, is not restricted.Optionally, more new state interval switching time can and described collecting unit starts time or determined dbjective state interval switching time is different before.

Step S520, control described collecting unit and carry out information acquisition according to described more new state interval switching time.

T1 can be established, t2, t3 ... the time series of tn, the t1 moment is the Startup time of collecting unit, t2, t3 ... the tn moment is the operation time after collecting unit starts, then when the t1 moment arrives or before the t1 moment arrives, the embodiment of the present invention can detect the first parameter, dbjective state interval switching time of described collecting unit is determined according to described first parameter, thus when t1 moment collecting unit starts, control collecting unit and carry out information acquisition according to dbjective state interval switching time, collecting unit can dbjective state interval switching time of dynamically changeable be started, realize the dynamically adjustable of powder consumption of electronic equipment, when being in t2, t3 ... during the operation time of tn collecting unit, the embodiment of the present invention can also detect the first parameter, if when detecting that the change of the first parameter meets pre-conditioned, can upgrade state interval switching time of collecting unit, thus make state interval switching time after renewal corresponding with the first parameter after change, at t2, t3 ... in the tn moment, renewal repeatedly can be carried out in state interval switching time of collecting unit.

Shown in composition graphs 4 and Fig. 5, the embodiment of the present invention can when collecting unit repeatedly starts, adopt different dbjective state intervals switching time to carry out information acquisition, and after collecting unit starts, carry out the dynamic conditioning at state interval switching time according to the change of the first parameter at every turn; Thus when collecting unit starts, start with dbjective state interval switching time of dynamically changeable, and after collecting unit starts, carry out information acquisition with state interval switching time of dynamically changeable, ensure that the dynamically adjustable of collecting unit power consumption at any one time.

Optionally, the embodiment of the present invention determined dbjective state interval switching time can carry out choosing determining from state interval switching time of multiple candidate, as long as selected dbjective state interval switching time is corresponding with the first detected parameter; Optionally, dbjective state interval switching time can the first parameter of a corresponding range intervals, as first parameter of value within the scope of 1-100 may correspond to dbjective state interval switching time, the first parameter within the scope of 100-200 may correspond to again another dbjective state interval switching time.This mode choosing dbjective state interval switching time from state interval switching time of multiple candidate, the computation process at dbjective state interval switching time can be avoided, after have detected the first parameter, choosing of dbjective state interval switching time fast can be carried out, as long as candidate state interval switching time set by ensureing has higher accuracy, the accuracy at selected dbjective state interval switching time also can be guaranteed; This mode achieves determining fast of dbjective state interval switching time, and collecting unit is when repeatedly adjusting state interval switching time, all carry out according to state interval switching time of multiple candidate, ensure that repeatedly the vary stable that dbjective state interval switching time adjusts, collecting unit can be made to adjust back and forth between multiple fixing state interval switching time, ensure that the dynamic stability of collecting unit power consumption is adjustable.

Obviously, real-time calculating also is carried out by the first detected parameter in the embodiment of the present invention determined dbjective state interval switching time; This mode can make the correspondence of determined dbjective state interval switching time and the first parameter more accurate, ensure that each determined dbjective state interval switching time all has higher accuracy.

Optionally, the embodiment of the present invention carries out the detection of the first parameter by collecting unit; Corresponding, Fig. 6 shows the 6th flow process of the control method that the embodiment of the present invention provides, and with reference to Fig. 6, the method can comprise:

The first parameter that step S600, detection collecting unit gather;

Optionally, take collecting unit as the positional information collecting unit carrying out geographical location information collection, in embodiments of the present invention, can detect the geographical location information of the electronic equipment that collecting unit gathers respectively when switching to enabled state and switch to enabled state for the Y time for the X time, wherein Y is greater than X; Take collecting unit as the temperature information collecting unit carrying out temperature information collection, in embodiments of the present invention, the temperature information that collecting unit gathers respectively when switching to enabled state and switch to enabled state for the Y time for the X time can be detected, thus when temperature information change is less, raising state interval switching time, when temperature information changes greatly, reduce state interval switching time.

Step S610, the first parameter gathered according to collecting unit determine dbjective state interval switching time of described collecting unit;

Optionally, take collecting unit as positional information collecting unit be example, determining collecting unit after the X time switches to enabled state and switch to the displacement of the electronic equipment in the interval time of enabled state for the Y time, the displacement of electronic equipment is determined by this interval time, the translational speed of electronic equipment is determined according to displacement and interval time, thus by translational speed determination dbjective state interval switching time; Optionally, the displacement that the embodiment of the present invention also can directly be switched to enabled state by the X time and be switched to the electronic equipment in the interval time of enabled state for the Y time, carries out the determination at dbjective state interval switching time.

Step S620, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

The embodiment of the present invention carries out the determination at dbjective state interval switching time by the first parameter that collecting unit gathers, and do not need other unit to carry out the acquisition testing of the first parameter, the use of other unit can be reduced, further reduce the power consumption of electronic equipment.Further, carry out on the basis of the determination at dbjective state interval switching time in the first parameter gathered by collecting unit, the embodiment of the present invention can in the inside of collecting unit the integrated control chip with the control method function that the embodiment of the present invention provides, carried out the determination at dbjective state interval switching time by this control chip, and carry out information acquisition according to described dbjective state interval switching time.

Optionally, the electronic equipment applying the control method having the embodiment of the present invention to provide can comprise detecting unit, and this detecting unit is different from collecting unit, and the embodiment of the present invention also carries out the detection of the first parameter by detecting unit; Corresponding, Fig. 7 shows the 7th flow process of the control method that the embodiment of the present invention provides, and with reference to Fig. 7, the method can comprise:

Step S700, detect described first parameter by described detecting unit;

Take collecting unit as positional information collecting unit be example, the first parameter that detecting unit detects can be the parameter relevant to the change in location of electronic equipment, comprise the translational speed of electronic equipment, collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, the displacement etc. of electronic equipment; Take collecting unit as temperature information collecting unit be example, the first parameter that detecting unit detects can be the parameter relevant to Changes in weather, comprises humidity, Ultraviolet radiation degree etc.

Step S710, the first parameter detected according to described detecting unit determine dbjective state interval switching time of described collecting unit;

Optionally, can be the parameter relevant to the change in location of electronic equipment for the first parameter, the displacement of the electronic equipment that the embodiment of the present invention can detect according to detecting unit, translational speed carries out the determination at dbjective state interval switching time.

Step S720, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

The embodiment of the present invention carries out the determination at dbjective state interval switching time by the first parameter that the detecting unit different with collecting unit detects, and can reduce the number of times that collecting unit carries out information acquisition, thus reduces the power consumption of collecting unit.At the beginning of starting at collecting unit, the embodiment of the present invention carries out the determination at dbjective state interval switching time by the first parameter that detecting unit detects, thus after determining dbjective state interval switching time, start collecting unit, information acquisition is carried out according to described dbjective state interval switching time to control collecting unit, thus play the object that minimizing collecting unit carries out the number of times of information acquisition, reduce the power consumption of collecting unit.Optionally, the embodiment of the present invention also can at the beginning of collecting unit starts, the first parameter detected by detecting unit carries out the determination at dbjective state interval switching time, and after collecting unit starts, the information gathered by collecting unit carries out the determination at dbjective state interval switching time, after collecting unit startup, by the collection of the information of carrying out, therefore after collecting unit starts, the information that can directly utilize collecting unit to gather carries out the determination at dbjective state interval switching time, and avoid using detecting unit, thus reduce the power consumption of electronic equipment entirety.

T1 can be established, t2, t3 ... the time series of tn, the t1 moment is the Startup time of collecting unit, t2, t3 ... the tn moment is the operation time after collecting unit starts, then in the t1 moment, detecting unit can detect the first parameter, the first parameter determination dbjective state interval switching time detected by detecting unit, thus reduces the Information Monitoring number of times of collecting unit; And at t2, t3 ... the tn moment, because collecting unit carried out information acquisition, therefore by information determination dbjective state interval switching time that collecting unit gathers, thus detecting unit can not be used to carry out the determination at dbjective state interval switching time, decrease the use of detecting unit, the power consumption of electronic equipment can be reduced, ensure the continuation of the journey of electronic equipment.

Be positional information collecting unit below with collecting unit be example, the control method that the embodiment of the present invention provides is described.Optionally, positional information collecting unit can carry out positional information collection (as passed through GPS(Global Positioning System by satellite, GPS), the Big Dipper etc. carries out positional information collection), positional information collecting unit can also carry out positional information collection by base station, by wifi(Wireless Fidelity) carry out positional information collection.

Already described above, the determination at geographical location information realize target state interval switching time of the electronic equipment that the embodiment of the present invention gathers when switching to enabled state and switch to enabled state for the Y time for the X time respectively by collecting unit, its concrete implementation can be: determine that switching to enabled state at collecting unit from the X time switches in the interval time of enabled state to the Y time by described geographical location information, the displacement of electronic equipment, by the displacement of electronic equipment and the translational speed determining electronic equipment interval time, thus dbjective state interval switching time of described collecting unit is determined according to translational speed, determined that by translational speed the roughly principle at dbjective state interval switching time of described collecting unit can be: translational speed is faster, dbjective state interval switching time is shorter, translational speed is slower, dbjective state interval switching time is longer, but when translational speed is too fast exceed limit value time, shorter dbjective state interval switching time is meaningless, now needs to reduce dbjective state interval switching time, does not even carry out the switching of dbjective state.

Another kind of implementation can be: determine that switching to enabled state at collecting unit from the X time switches in the interval time of enabled state to the Y time according to described geographical location information, the displacement of electronic equipment, determines dbjective state interval switching time of described collecting unit according to displacement.

Already described above, the parameter that change in location that is that the embodiment of the present invention also detects by detecting unit and electronic equipment is relevant carries out the determination at dbjective state interval switching time, its concrete implementation can be: when change in location correlation parameter is translational speed, directly can be carried out the determination at dbjective state interval switching time by translational speed; When change in location correlation parameter collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, during the displacement of electronic equipment, translational speed is calculated by displacement and interval time, thus by translational speed determination dbjective state interval switching time; When change in location correlation parameter is that collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, during the displacement of electronic equipment, can directly by displacement determination dbjective state interval switching time.

Optionally, the embodiment of the present invention is by translational speed determination dbjective state interval switching time.Concrete, first can determine the translational speed of electronic equipment; If described translational speed is less than predetermined speed, determine that dbjective state is spaced apart the very first time interval switching time, very first time interval was greater than for second time interval, and second time interval was the state switching time interval of translational speed when being greater than predetermined speed; If described translational speed is greater than predetermined speed, determine that dbjective state was spaced apart for second time interval switching time, second time interval was less than very first time interval, and the very first time is spaced apart state interval switching time when translational speed is greater than predetermined speed.

Optionally, predetermined speed can be the critical velocity of user's state of going on a journey when changing, and as user walks line state and the critical velocity of state by bike, walks the critical velocity etc. of line state and running state.Be the critical velocity walking line state and running state be at a predetermined velocity example, if detect, the translational speed of electronic equipment is less than predetermined speed, then can determine that the trip state of user is for walking line state, can determine that dbjective state is spaced apart the very first time interval switching time, if detect, the translational speed of electronic equipment is greater than predetermined speed, the present condition that goes out then can determining user is running state, can determine that dbjective state was spaced apart for second time interval switching time, very first time interval was greater than for second time interval.Namely electronic equipment translational speed from be less than predetermined speed become be greater than predetermined speed time, reduce state interval switching time of collecting unit, the number of times of collecting unit Information Monitoring within the unit interval will increase, electronic equipment translational speed from be greater than predetermined speed become be less than predetermined speed time, increase state interval switching time of collecting unit, the number of times of collecting unit Information Monitoring within the unit interval will reduce.

Be understandable that, when translational speed from be less than predetermined speed become be greater than predetermined speed time, along with the increase of translational speed, the change of the geographic position of user will be very fast, therefore collecting unit needs to carry out information acquisition comparatively frequently, just can ensure the accuracy of gathered information; And when translational speed from be greater than predetermined speed become be less than predetermined speed time, along with the reduction of translational speed, the geographic position change of user is slower, therefore collecting unit does not need to carry out information acquisition comparatively frequently, information acquisition can be carried out with relatively little frequency, just can ensure the accuracy of gathered information, thus less power consumption can realize information acquisition accurately; The power consumption of electronic equipment and the balance of collecting unit information acquisition accuracy can be ensured by the mode at translational speed determination dbjective state interval switching time of electronic equipment.

Optionally, Fig. 8 shows the first pass figure determining dbjective state interval switching time, and with reference to Fig. 8, this flow process can comprise:

Step S800, determine the translational speed of electronic equipment;

Optionally, the geographical location information of the electronic equipment gathered respectively when switching to enabled state and switch to enabled state for the Y time for the X time by collecting unit carries out the determination of translational speed; Also the collecting unit detected by detecting unit carries out the determination of translational speed switching to enabled state and the displacement switched to for the Y time in the interval time of enabled state for the X time, if detecting unit is range sensor etc.; Also the determination of the translational speed of electronic equipment is directly carried out by detecting unit, if detecting unit is speed pickup etc.

If the described translational speed of step S810 is less than predetermined First Speed, determine that the numerical value at dbjective state interval switching time is the first value, described first value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed;

If the described translational speed of step S820 is between predetermined First Speed and predetermined second speed, determine that the numerical value at dbjective state interval switching time is the second value, described second value is less than the first value, and described first value is the numerical value at state interval switching time when translational speed is less than predetermined First Speed;

If the described translational speed of step S830 is greater than predetermined second speed, determine that the numerical value at dbjective state interval switching time is the 3rd value, described 3rd value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed.

It should be noted that the arbitrary step in step S810, S820 and S830 all can be implemented separately, implement after also any at least two steps wherein can being combined.

Determined by dbjective state interval switching time of translational speed to collecting unit, when translational speed is very fast, dbjective state interval switching time can be shortened, improve the accuracy that positional information gathers; When translational speed is slower, extend dbjective state interval switching time, due to slower translational speed, larger geographic position can not be brought to change, therefore dbjective state interval switching time is extended, the accuracy of location information collection can't cause too large impact, but extend the power consumption that dbjective state interval switching time can reduce collecting unit, ensure the continuation of the journey of electronic equipment; And when translational speed is too fast exceed limit value time, shorter dbjective state interval switching time is meaningless, now need reduce dbjective state interval switching time, even do not carry out the switching of dbjective state, to ensure the continuation of the journey of electronic equipment.

Optionally, the defining method at interval switching time of dbjective state shown in Fig. 8 can be applicable in the scene of the different trip mode of user, predetermined First Speed can be the critical value of walk speed and the velocity of user, be less than predetermined First Speed and then think that user is in away line state, predetermined second speed can be the critical value of user's velocity and the vehicles (as aircraft, train etc.) speed, be greater than predetermined second speed and then think that user is in the state ridden public transportation means, between predetermined First Speed and second speed, then think that user is in running state; When user is in away line state, dbjective state interval switching time can be improved, to reduce the number of times that collecting unit carries out information acquisition within the unit interval, reduce power consumption; When user is in running state, dbjective state time interval switching time can be reduced, to increase the number of times that collecting unit carries out information acquisition within the unit interval, the accuracy that guarantee information gathers; When user is in the state ridden public transportation means, due to motion at a high speed and cannot the validity that gathers of guarantee information, therefore cocoa improves dbjective state interval switching time, to reduce the number of times that collecting unit carries out information acquisition within the unit interval, reduces power consumption.

Therefore when translational speed from be less than predetermined First Speed become between predetermined First Speed and predetermined second speed time, state interval switching time can be switched to the second value by the first value, now, second value is dbjective state interval switching time, described first value is greater than the second value, thus within the unit interval, increase the number of times that collecting unit carries out information acquisition, promote the accuracy that collecting unit carries out information acquisition; When translational speed is by between predetermined First Speed and predetermined second speed, become when being less than predetermined First Speed, state interval switching time can be switched to the first value by the second value, first value is greater than the second value, now, first value is dbjective state interval switching time, thus within the unit interval, reduce the number of times that collecting unit carries out information acquisition, and the basis of guarantee information collection accuracy reduces the power consumption of collecting unit; When translational speed is by between predetermined First Speed and predetermined second speed, become when being greater than predetermined second speed, state interval switching time can be switched to the 3rd value by the second value, now, 3rd value is dbjective state interval switching time, 3rd value is greater than the second value, thus within the unit interval, reduce the number of times that collecting unit carries out information acquisition, and the basis of guarantee information collection accuracy reduces the power consumption of collecting unit; When translational speed becomes from when being greater than predetermined second speed, time between predetermined First Speed and predetermined second speed, state interval switching time can be switched to the second value by the 3rd value, now, second value is dbjective state interval switching time, thus within the unit interval, increase the number of times that collecting unit carries out information acquisition, promote the accuracy that collecting unit carries out information acquisition.

Under different trip modes, the information acquisition accuracy of collecting unit can be ensured, and realizes the reduction of powder consumption of electronic equipment by the defining method at interval switching time of dbjective state shown in Fig. 8.With user's trip mode of a day be: walk to work, go by taxi airport, airport lounge is removed in running, another city is gone to go on business by air, to run out airport, hotel ccommodation of going by foot is example, the control method provided by the embodiment of the present invention, can do following control to dbjective state interval switching time of collecting unit:

Step S10, detect the first parameter;

Step S11, translational speed by the first parameter determination electronic equipment;

First parameter can be directly translational speed parameter, also can be displacement, geo-location parameter etc.

Step S12, determine that translational speed is less than predetermined First Speed, dbjective state interval switching time is defined as the first value;

Be less than predetermined First Speed and represent that user is in away line state, the scene of corresponding walk to work; First value can be chosen (the selected time interval is corresponding with translational speed) from the time interval of multiple candidate, also can calculate according to translational speed.

Step S13, determine that translational speed is greater than predetermined second speed, dbjective state interval switching time is defined as the 3rd value;

Be greater than predetermined second speed and represent that user is in traffic behavior, correspondence goes by taxi the scene on airport.

Step S14, determine that translational speed is between predetermined First Speed and predetermined second speed, dbjective state interval switching time is defined as the second value;

Second value is less than the first value and the 3rd value, realizes the increase of the number of times of collecting unit Information Monitoring in the unit interval, and translational speed represents that between predetermined First Speed and predetermined second speed user is in running state, and corresponding running removes airport lounge;

Step S15, determine that translational speed is greater than predetermined second speed, dbjective state interval switching time is defined as the 3rd value;

State interval switching time is adjusted to the 3rd value by the second value, realize the reduction of the number of times of collecting unit Information Monitoring in the unit interval, translational speed is greater than predetermined second speed and represents for being in traffic behavior, corresponding scene of going to another city to go on business by air;

Step S16, determine that translational speed is between predetermined First Speed and predetermined second speed, dbjective state interval switching time is defined as the second value;

The scene on the corresponding airport of running out of step S16.

Step S17, determine that translational speed is less than predetermined First Speed, dbjective state interval switching time is defined as the first value.

The scene of the corresponding hotel ccommodation of going by foot of step S17.

Optionally, Fig. 9 shows the second process flow diagram determining dbjective state interval switching time, and with reference to Fig. 9, the method can comprise:

Step S900, determine the displacement that electronic equipment switches to enabled state at described collecting unit at the X time and switches to for the Y time in the interval time of enabled state;

Displacement is determined by the geographical location information of the electronic equipment that collecting unit gathers respectively when switching to enabled state and switch to enabled state for the Y time for the X time; Also directly detect by detecting unit; Also, carry out the detection of translational speed by detecting unit after, the displacement that collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state is determined.

If the described displacement of step S910 is less than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 4th value, described 4th value is greater than the 5th value, and described 5th value is the numerical value at state interval switching time when displacement is greater than predetermined first distance;

If collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, the displacement of electronic equipment is less than predetermined first distance, then electronic equipment displacement not far is described, without the need to carrying out information acquisition frequently, therefore dbjective state wakeup time interval can be increased, to realize the reduction of collecting unit Information Monitoring number of times in the unit interval, on the basis of guarantee information collection accuracy, reduce the power consumption of collecting unit.

If the described displacement of step S920 is greater than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 5th value, described 5th value is less than the 4th value, and described 4th value is the numerical value at state interval switching time when displacement is less than predetermined first distance.

If collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, the displacement of electronic equipment is greater than predetermined first distance, then illustrate that electronic equipment displacement is far away, need to carry out information acquisition frequently, with the accuracy that guarantee information gathers, therefore dbjective state wakeup time interval can be reduced, to realize the increase of collecting unit Information Monitoring number of times in the unit interval.

Under dbjective state interval determining method switching time of collecting unit shown in Fig. 9 can be applicable to user's different motion scene, the dynamic conditioning at state interval switching time of collecting unit.As user perform physical exercise on treadmill, Spinning time, collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, and the displacement of electronic equipment is constant, therefore can increase dbjective state wakeup time interval; And user is when the motion such as carrying out riding or jog, collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state, and it is greatly that the displacement of electronic equipment changes, and therefore can reduce dbjective state wakeup time interval.

Optionally, step S910 and step S920 can implement separately, without the need to both in conjunction with enforcement.

The embodiment of the present invention switches to enabled state and switches to displacement determination dbjective state interval switching time in the interval time of enabled state for the Y time at described collecting unit at the X time by electronic equipment, when displacement is less than predetermined first distance, illustrate that the geographic position situation of change change of electronic equipment is slower, therefore collecting unit does not need to carry out information acquisition comparatively frequently, information acquisition can be carried out with relatively little frequency, just can ensure the accuracy of gathered information, thus less power consumption can realize information acquisition accurately; When displacement is greater than predetermined first distance, illustrate that the geographic position change of user will be very fast, therefore collecting unit needs to carry out information acquisition comparatively frequently, just can ensure the accuracy of gathered information; The power consumption of electronic equipment and the balance of collecting unit information acquisition accuracy can be ensured by the mode at displacement determination dbjective state interval switching time of electronic equipment.

It should be noted that above for the description that collecting unit is done for the collecting unit carrying out geographical location information collection, be only the control method better understood the embodiment of the present invention and provide, it should not become the restriction of scope.Obvious collecting unit can also be the collecting unit etc. carrying out temperature information collection.

Optionally, the electronic equipment applying the control method having the embodiment of the present invention to provide can be Wearable, and this Wearable comprises wearing parts, and these wearing parts are for being fixed on a part for the health of user by electronic equipment; Optionally, these wearing parts can be that wrist wears parts, and for electronic equipment being fixed on the wrist of user, these wearing parts also can be wear parts, for being fixed on the user's head by electronic equipment.

A few category informations that Wearable is often used for user comparatively pays close attention to gather, the collecting unit for Information Monitoring of at least one class of accessible site in Wearable; As Wearable can carry out the collection of geographical location information, or the healthy parameter (as heartbeat, pulse, cadence etc.) of user is gathered; Wearable is due to small volume, therefore battery capacity is usually less, generally all below 1000 milliamperes, but in order to guarantee information gather accuracy, therefore often need to carry out information acquisition frequently, but this will bring larger power consumption again, under therefore solving Wearable scene, battery capacity less with information acquisition accurately contradiction be very important problem.It is less that the control method provided by the embodiment of the present invention can solve Wearable battery capacity, with information acquisition contradictory problems accurately.The embodiment of the present invention detects the first parameter by the collecting unit in Wearable or detecting unit, pass through dbjective state interval switching time of the first detected parameter determination collecting unit, thus control described collecting unit and carry out information acquisition according to described dbjective state interval switching time, make dbjective state interval switching time can do adaptive dynamic conditioning according to the first parameter, ensure determining as required of dbjective state interval switching time, thus on the basis of guarantee information collection accuracy, use less powder consumption of electronic equipment.

Yes merit attention, a collecting unit application in the electronic device can be: the information that electronic equipment can utilize collecting unit to gather periodically is monitored realization of goal, the information that collecting unit gathers can process by electronic equipment, thus draw the monitoring result to target, in order to ensure in whole monitoring periods, the accuracy of target monitoring and real-time, this just requires that collecting unit has higher information acquisition frequency.As electronic equipment can utilize geographic position collecting unit the geographical location information that gathers, carry out the drafting of traffic route, in order to draw out the situation of route road conditions really, therefore under needing collecting unit to be in higher information acquisition frequency state, the mistake that route so just can be avoided to draw is (as not high in the information acquisition frequency due to collecting unit, script winding raod line may be depicted as straight line, thus draw out the route of mistake).User's body health parameters information (as heartbeat, the pulse etc.) physical condition to user that and for example electronic equipment can utilize collecting unit to gather is monitored, in order to ensure real-time and the accuracy of user's body health monitoring, therefore collecting unit is just needed to have higher information acquisition frequency, so just can make monitoring timely when user healthy not good, avoid the generation of fortuitous event.Therefore the information gathered at collecting unit is for periodically monitoring realization of goal, the embodiment of the present invention needs to ensure that collecting unit has higher information acquisition frequency, be chosen as collecting unit and carry out real-time information acquisition, can by the state interval switching time vanishing of collecting unit.

Corresponding, the embodiment of the present invention can determine the application scenarios of the information that collecting unit gathers, if the information that collecting unit gathers is for periodically monitoring realization of goal, state interval switching time that then can maintain collecting unit is less than predetermined time interval all the time, and predetermined time interval can be the critical value that collecting unit has higher information acquisition frequency.The accuracy of target monitoring result can be ensured like this, and meet the requirement of Real-Time Monitoring.

Optionally, the embodiment of the present invention also by detecting the dump energy parameter of electronic equipment, thus determines dbjective state interval switching time of described collecting unit according to described dump energy parameter.8th process flow diagram of the control method that Figure 10 provides for the embodiment of the present invention, with reference to Figure 10, the method can comprise:

The dump energy parameter of step S1000, detected electrons equipment;

Optionally, there is by power management chip etc. the detection of the software simulating dump energy parameter of battery cell monitoring function.

Step S1100, to estimate that according to the hardware configuration information of described electronic equipment described electronic equipment needs the electricity consumed;

Optionally, hardware configuration information can be CUP type, CPU check figure, the hardware configuration parameters such as type of memory.

Step S1200, according to described dump energy parameter, and described need consume electricity determine the electricity supplying described collecting unit work;

If step S1300 is greater than predetermined electricity for the electricity supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 6th value, described 6th value is less than the 7th value, and described 7th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being less than predetermined electricity;

If step S1400 is less than predetermined electricity for the electricity supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 7th value, described 7th value is greater than the 6th value, and described 6th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being greater than predetermined electricity.

Optionally, step S1300, S1400 can implement separately.

Optionally, the embodiment of the present invention can for supply described collecting unit work more time, reduce state interval switching time, to increase the number of times of collecting unit Information Monitoring within the unit interval, promote the information acquisition accuracy of collecting unit; For supply described collecting unit work less time, enlarging state interval switching time, to reduce the number of times of collecting unit Information Monitoring within the unit interval, reduces the power consumption of collecting unit; Thus balance is kept in the accuracy and power consumption of information acquisition.

9th process flow diagram of the control method that Figure 11 provides for the embodiment of the present invention, with reference to Figure 11, the method can comprise:

The dump energy parameter of step S2000, detected electrons equipment;

If step S2100 described dump energy parameter is greater than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 8th value, described 8th value is less than the 9th value, and described 9th value is the numerical value at the state switching time interval of described dump energy parameter when being less than predetermined dump energy parameter;

If step S2200 described dump energy parameter is less than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 9th value, described 9th value is greater than the 8th value, and described 8th value is the numerical value at the state switching time interval of described dump energy parameter when being greater than predetermined dump energy parameter.

Optionally, step S2100, S2200 can implement separately.

Optionally, the embodiment of the present invention when dump energy is more, can reduce state interval switching time, to increase the number of times of collecting unit Information Monitoring within the unit interval, promotes the information acquisition accuracy of collecting unit; When dump energy is less, enlarging state interval switching time, to reduce the number of times of collecting unit Information Monitoring within the unit interval, reduces the power consumption of collecting unit; Thus balance is kept in the accuracy and power consumption of information acquisition.

The control method that the embodiment of the present invention provides can carry out automatic dynamic adjustment to the time interval that the collecting unit of electronic equipment carries out information acquisition, greatly reduces the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

Be described the control device that the embodiment of the present invention provides below, control device described below can mutual corresponding reference with above-described control method.

The first structured flowchart of the control device that Figure 12 provides for the embodiment of the present invention, this control device can be applicable to electronic equipment, this electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state; With reference to Figure 12, this control device can comprise:

Detection module 100, for detecting the first parameter;

Determination module 200, for determining dbjective state interval switching time of described collecting unit according to described first parameter, wherein, described dbjective state is spaced apart described collecting unit switches to described enabled state for the N time n-hour from described disable state switching time, the time interval in the N+1 moment of described enabled state is switched to for the N+1 time from described disable state with described collecting unit, wherein, described collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state;

First controls acquisition module 300, carries out information acquisition for controlling described collecting unit according to described dbjective state interval switching time.

The second structured flowchart of the control device that Figure 13 provides for the embodiment of the present invention, shown in Figure 12 and Figure 13, shown in Figure 13, control device also comprises:

Second controls acquisition module 400, for described determine dbjective state interval switching time of described collecting unit according to described first parameter before, or before described detection first parameter, control described collecting unit and carry out information acquisition according to virgin state interval switching time, virgin state is spaced apart described collecting unit switches to described enabled state for the M time M moment from described disable state switching time, switch to the time interval in the M+1 moment of described enabled state for the M+1 time from described disable state with described collecting unit, M is less than N.

Corresponding, on the basis of control device shown in Figure 13, Figure 14 shows the first alternate configurations of the first control acquisition module 300, and with reference to Figure 14, first controls acquisition module 300 can comprise:

First control module 310, for contiguous for the described collecting unit time interval being in enabled state for twice is switched to described dbjective state interval switching time by described virgin state interval switching time, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

Figure 15 shows the first alternate configurations of determination module 200, and with reference to Figure 15, determination module 200 can comprise:

First determining unit 210, for start described collecting unit time or before, determine dbjective state interval switching time of described collecting unit according to described first parameter.

Corresponding, on the basis of determination module 200 shown in Figure 15, Figure 16 shows the second alternate configurations of the first control acquisition module, and with reference to Figure 16, first controls acquisition module 300 can comprise:

Start and control collecting unit 320, for starting described collecting unit, controlling described collecting unit and carrying out information acquisition according to described dbjective state interval switching time.

Corresponding, on the basis of determination module 200 shown in Figure 15, Figure 17 shows the third structured flowchart of the control device that the embodiment of the present invention provides, and shown in Figure 12 and Figure 17, described device also comprises:

Parameters variation detection module 500, for monitoring the change of described first parameter;

Adjusting module 600, if when the change for described first parameter detected meets pre-conditioned, upgrade state interval switching time of described collecting unit, to determine more new state interval switching time, described more new state interval switching time is corresponding with the first parameter after change;

3rd controls acquisition module 700, carry out information acquisition for controlling described collecting unit according to described more new state interval switching time, when described more new state interval switching time and described collecting unit start or before, determined dbjective state interval switching time is different.

Optionally, Figure 18 shows the second alternate configurations of determination module 200, and with reference to Figure 18, determination module 200 can comprise:

Choose unit 220, for determining described dbjective state interval switching time according to described first parameter from multiple candidate target state interval switching time.

Optionally, Figure 19 shows the third optional knot of determination module 200, and with reference to Figure 19, determination module 200 can comprise:

Computing unit 221, for calculating described dbjective state interval switching time according to described first parameter.

Optionally, Figure 20 shows the first alternate configurations of detection module 100, and with reference to Figure 20, detection module 100 can comprise:

First detecting unit 110, for detecting described first parameter that described collecting unit gathers.

Corresponding, on the basis of detection module 100 shown in Figure 20, Figure 21 shows the 4th kind of alternate configurations of determination module 200, and with reference to Figure 21, determination module 200 can comprise:

Second determining unit 230, described first parameter for gathering according to described collecting unit determines dbjective state interval switching time of described collecting unit.

Optionally, the first parameter that collecting unit gathers can be: the geographical location information of the described electronic equipment that collecting unit gathers respectively when switching to enabled state and switch to enabled state for the Y time for the X time, and Y is greater than X; Corresponding, dbjective state interval switching time of described collecting unit can be determined according to described geographical location information.

Optionally, determine that dbjective state interval switching time of described collecting unit can be according to described geographical location information: determine that described collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state according to described geographical location information, the displacement of described electronic equipment; According to described displacement and the translational speed determining electronic equipment described interval time; Dbjective state interval switching time of described collecting unit is determined according to described translational speed.Also can be: determine that described collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state according to described geographical location information, the displacement of described electronic equipment; Dbjective state interval switching time of described collecting unit is determined according to described displacement.

Optionally, described electronic equipment can comprise detecting unit; Corresponding, Figure 22 shows the second alternate configurations of the detection module 100 that the embodiment of the present invention provides, and with reference to Figure 22, detection module 100 can comprise:

Second detecting unit 120, for detecting described first parameter by described detecting unit, described detecting unit is different from described collecting unit.

Optionally, Figure 23 shows the first alternate configurations of the second detecting unit 120, and with reference to Figure 23, the second detecting unit 120 can comprise:

First detection sub-unit 121, for detecting the parameter relevant to the change in location of electronic equipment by described detecting unit.

Corresponding, on the basis of the second detecting unit 120 shown in Figure 23, Figure 24 shows the 5th kind of alternate configurations of the determination module 200 that the embodiment of the present invention provides, and with reference to Figure 24, determination module 200 can comprise:

3rd determining unit 240, the parameter for being correlated with according to described change in location determines dbjective state interval switching time of described collecting unit.

Optionally, detecting the parameter relevant to the change in location of electronic equipment by detecting unit can be: by the translational speed of detecting unit detected electrons equipment; Corresponding, determine that dbjective state interval switching time of described collecting unit can be: dbjective state interval switching time determining described collecting unit according to described translational speed according to the parameter that described change in location is correlated with.

Optionally, detecting the parameter relevant to the change in location of electronic equipment by detecting unit can be: the displacement being switched to enabled state and switch to for the Y time in the interval time of enabled state at described collecting unit at the X time by detecting unit detected electrons equipment; Corresponding, determine that dbjective state interval switching time of described collecting unit comprises according to the parameter that described change in location is correlated with: according to described displacement and described interval time, determine the translational speed of electronic equipment; Dbjective state interval switching time of described collecting unit is determined according to described translational speed.

Optionally, detecting the parameter relevant to the change in location of electronic equipment by detecting unit can be: the displacement being switched to enabled state and switch to for the Y time in the interval time of enabled state at described collecting unit at the X time by detecting unit detected electrons equipment; Corresponding, determine that dbjective state interval switching time of described collecting unit can be: dbjective state interval switching time determining described collecting unit according to described displacement according to the parameter that described change in location is correlated with.

Optionally, Figure 25 shows the 6th kind of alternate configurations of the determination module 200 that the embodiment of the present invention provides, and with reference to Figure 25, determination module 200 can comprise:

First translational speed determining unit 201, for determining the translational speed of electronic equipment;

First determines performance element 202, if when being less than predetermined speed for described translational speed, determine that dbjective state is spaced apart the very first time interval switching time, very first time interval was greater than for second time interval, and second time interval was the state switching time interval of translational speed when being greater than predetermined speed

Second determines performance element 203, if when being greater than predetermined speed for described translational speed, determine that dbjective state was spaced apart for second time interval switching time, second time interval was less than very first time interval, and the very first time is spaced apart state interval switching time when translational speed is greater than predetermined speed.

Optionally, Figure 26 shows the 7th kind of alternate configurations of the determination module 200 that the embodiment of the present invention provides, and with reference to Figure 26, determination module 200 can comprise:

Second translational speed determining unit 250, for determining the translational speed of electronic equipment;

3rd determines performance element 251, if when being less than predetermined First Speed for described translational speed, determine that the numerical value at dbjective state interval switching time is the first value, described first value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed; And/or, if when described translational speed is between predetermined First Speed and predetermined second speed, determine that the numerical value at dbjective state interval switching time is the second value, described second value is less than the first value, and described first value is the numerical value at state interval switching time when translational speed is less than predetermined First Speed; And/or, if when described translational speed is greater than predetermined second speed, determine that the numerical value at dbjective state interval switching time is the 3rd value, described 3rd value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed.

Figure 27 shows the 8th kind of alternate configurations of the determination module 200 that the embodiment of the present invention provides, and with reference to Figure 27, determination module 200 can comprise:

Displacement determining unit 260, for determining the displacement that electronic equipment switches to enabled state at described collecting unit at the X time and switches to for the Y time in the interval time of enabled state, Y is greater than X;

4th determines performance element 261, if when described displacement is less than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 4th value, described 4th value is greater than the 5th value, and described 5th value is the numerical value at state interval switching time when displacement is greater than predetermined first distance; And/or, if when described displacement is greater than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 5th value, described 5th value is less than the 4th value, and described 4th value is the numerical value at state interval switching time when displacement is less than predetermined first distance.

Figure 28 shows the third alternate configurations of the detection module 100 provided that the embodiment of the present invention provides, and with reference to Figure 28, detection module 100 comprises:

Residual capacity measurement unit 130, for the dump energy parameter of detected electrons equipment.

Corresponding, Figure 29 shows the 9th kind of alternate configurations of determination module 200, and with reference to Figure 29, determination module 200 can comprise:

5th determines performance element 270, for determining dbjective state interval switching time of described collecting unit according to described dump energy parameter.

Optionally, Figure 30 shows the first alternate configurations that the 5th determines performance element 270, and with reference to Figure 30, the 5th determines that performance element 270 can comprise:

Estimate subelement 2701, for estimating that according to the hardware configuration information of described electronic equipment described electronic equipment needs the electricity consumed;

Subelement 2702 is determined in electricity supply, and for according to described dump energy parameter, and the described electricity consumed that needs determines the electricity supplying described collecting unit work;

First determines to perform subelement 2703, if when being greater than predetermined electricity for the electricity for supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 6th value, described 6th value is less than the 7th value, and described 7th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being less than predetermined electricity; And/or, if when the electricity for supplying described collecting unit work is less than predetermined electricity, determine that the numerical value at dbjective state interval switching time is the 7th value, described 7th value is greater than the 6th value, and described 6th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being greater than predetermined electricity.

Optionally, Figure 31 shows the second alternate configurations that the 5th determines performance element 270, and with reference to Figure 31, the 5th determines that performance element 270 can comprise:

Second determines to perform subelement 2710, if when being greater than predetermined dump energy parameter for described dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 8th value, described 8th value is less than the 9th value, and described 9th value is the numerical value at the state switching time interval of described dump energy parameter when being less than predetermined dump energy parameter; And/or, if when described dump energy parameter is less than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 9th value, described 9th value is greater than the 8th value, and described 8th value is the numerical value at the state switching time interval of described dump energy parameter when being greater than predetermined dump energy parameter.

The control device that the embodiment of the present invention provides can carry out adaptive dynamic conditioning to the time interval that the collecting unit of electronic equipment carries out information acquisition, greatly reduces the power consumption of electronic equipment, ensure that the continuation of the journey of electronic equipment.

The embodiment of the present invention also provides a kind of electronic equipment, and this electronic equipment can comprise control device described above, and the description of control device can refer to the description of Figure 12-Figure 31 corresponding part above, repeats no more herein.

In this instructions, each embodiment adopts the mode of going forward one by one to describe, and what each embodiment stressed is the difference with other embodiments, between each embodiment identical similar portion mutually see.For device disclosed in embodiment, because it corresponds to the method disclosed in Example, so description is fairly simple, relevant part illustrates see method part.

Professional can also recognize further, in conjunction with unit and the algorithm steps of each example of embodiment disclosed herein description, can realize with electronic hardware, computer software or the combination of the two, in order to the interchangeability of hardware and software is clearly described, generally describe composition and the step of each example in the above description according to function.These functions perform with hardware or software mode actually, depend on application-specific and the design constraint of technical scheme.Professional and technical personnel can use distinct methods to realize described function to each specifically should being used for, but this realization should not thought and exceeds scope of the present invention.

The software module that the method described in conjunction with embodiment disclosed herein or the step of algorithm can directly use hardware, processor to perform, or the combination of the two is implemented.Software module can be placed in the storage medium of other form any known in random access memory (RAM), internal memory, ROM (read-only memory) (ROM), electrically programmable ROM, electrically erasable ROM, register, hard disk, moveable magnetic disc, CD-ROM or technical field.

To the above-mentioned explanation of the disclosed embodiments, professional and technical personnel in the field are realized or uses the present invention.To be apparent for those skilled in the art to the multiple amendment of these embodiments, General Principle as defined herein can without departing from the spirit or scope of the present invention, realize in other embodiments.Therefore, the present invention can not be restricted to these embodiments shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.

Claims (32)

1. a control method, is characterized in that, is applied to electronic equipment, described electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described method comprises:

Detect the first parameter;

Dbjective state interval switching time of described collecting unit is determined according to described first parameter, wherein, described dbjective state is spaced apart described collecting unit switches to described enabled state for the N time n-hour from described disable state switching time, the time interval in the N+1 moment of described enabled state is switched to for the N+1 time from described disable state with described collecting unit, wherein, described collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state;

Control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

2. control method according to claim 1, is characterized in that, described determine dbjective state interval switching time of described collecting unit according to described first parameter before, or before described detection first parameter, described method also comprises:

Control described collecting unit and carry out information acquisition according to virgin state interval switching time, virgin state is spaced apart described collecting unit switches to described enabled state for the M time M moment from described disable state switching time, switch to the time interval in the M+1 moment of described enabled state for the M+1 time from described disable state with described collecting unit, M is less than N;

The described collecting unit of described control carries out information acquisition according to described dbjective state interval switching time and comprises:

Contiguous for the described collecting unit time interval being in enabled state for twice is switched to described dbjective state interval switching time by described virgin state interval switching time, controls described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

3. control method according to claim 1, is characterized in that, describedly determines that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Start described collecting unit time or before, determine dbjective state interval switching time of described collecting unit according to described first parameter;

The described collecting unit of described control carries out information acquisition according to described dbjective state interval switching time and comprises:

Start described collecting unit, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

4. control method according to claim 3, is characterized in that, described method also comprises:

Monitor the change of described first parameter;

If the change of described first parameter detected meets pre-conditioned, upgrade state interval switching time of described collecting unit, to determine more new state interval switching time, described more new state interval switching time is corresponding with the first parameter after change;

Control described collecting unit and carry out information acquisition according to described more new state interval switching time, when described more new state interval switching time and described collecting unit start or before, determined dbjective state interval switching time is different.

5. control method according to claim 1, is characterized in that, describedly determines that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

From multiple candidate state interval switching time, described dbjective state interval switching time is determined according to described first parameter; Or

Described dbjective state interval switching time is calculated according to described first parameter.

6. control method according to claim 1, is characterized in that, described detection first parameter comprises:

Detect described first parameter that described collecting unit gathers;

Describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Described first parameter gathered according to described collecting unit determines dbjective state interval switching time of described collecting unit.

7. control method according to claim 6, is characterized in that, described first parameter that the described collecting unit of described detection gathers comprises:

Detect the geographical location information of the described electronic equipment that described collecting unit gathers respectively when switching to enabled state and switch to enabled state for the Y time for the X time, Y is greater than X;

Describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Dbjective state interval switching time of described collecting unit is determined according to described geographical location information.

8. control method according to claim 7, is characterized in that, describedly determines that dbjective state interval switching time of described collecting unit comprises according to described geographical location information:

Determine that described collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state according to described geographical location information, the displacement of described electronic equipment;

According to described displacement and the translational speed determining electronic equipment described interval time;

Dbjective state interval switching time of described collecting unit is determined according to described translational speed.

9. control method according to claim 7, is characterized in that, describedly determines that dbjective state interval switching time of described collecting unit comprises according to described geographical location information:

Determine that described collecting unit switches to enabled state at the X time and switches to for the Y time in the interval time of enabled state according to described geographical location information, the displacement of described electronic equipment;

Dbjective state interval switching time of described collecting unit is determined according to described displacement.

10. control method according to claim 1, is characterized in that, described electronic equipment comprises detecting unit, and described detection first parameter comprises:

Detect described first parameter by described detecting unit, described detecting unit is different from described collecting unit.

11. control methods according to claim 10, is characterized in that, describedly detect the first parameter by described detecting unit and comprise:

The parameter relevant to the change in location of electronic equipment is detected by described detecting unit;

Describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

The parameter of being correlated with according to described change in location determines dbjective state interval switching time of described collecting unit.

12. control methods according to claim 1, is characterized in that, describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Determine the translational speed of described electronic equipment;

If described translational speed is less than predetermined speed, determine that dbjective state is spaced apart the very first time interval switching time, very first time interval was greater than for second time interval, and second time interval was the state switching time interval of translational speed when being greater than predetermined speed;

If described translational speed is greater than predetermined speed, determine that dbjective state was spaced apart for second time interval switching time, second time interval was less than very first time interval, and the very first time is spaced apart state interval switching time when translational speed is greater than predetermined speed.

13. control methods according to claim 1, is characterized in that, describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Determine the translational speed of described electronic equipment;

If described translational speed is less than predetermined First Speed, determine that the numerical value at dbjective state interval switching time is the first value, described first value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed; And/or,

If described translational speed is between predetermined First Speed and predetermined second speed, determine that the numerical value at dbjective state interval switching time is the second value, described second value is less than the first value, and described first value is the numerical value at state interval switching time when translational speed is less than predetermined First Speed; And/or,

If described translational speed is greater than predetermined second speed, determine that the numerical value at dbjective state interval switching time is the 3rd value, described 3rd value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed.

14. control methods according to claim 1, is characterized in that, describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Determine the displacement that described electronic equipment switches to enabled state at described collecting unit at the X time and switches to for the Y time in the interval time of enabled state, Y is greater than X;

If described displacement is less than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 4th value, described 4th value is greater than the 5th value, and described 5th value is the numerical value at state interval switching time when displacement is greater than predetermined first distance; And/or,

If described displacement is greater than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 5th value, described 5th value is less than the 4th value, and described 4th value is the numerical value at state interval switching time when displacement is less than predetermined first distance.

15. control methods according to claim 1, is characterized in that, described detection first parameter comprises:

The dump energy parameter of detected electrons equipment;

Describedly determine that dbjective state interval switching time of described collecting unit comprises according to described first parameter:

Dbjective state interval switching time of described collecting unit is determined according to described dump energy parameter.

16. control methods according to claim 15, is characterized in that, describedly determine that dbjective state interval switching time of described collecting unit comprises according to described dump energy parameter:

Estimate that described electronic equipment needs the electricity consumed according to the hardware configuration information of described electronic equipment;

According to described dump energy parameter, and the described electricity consumed that needs determines the electricity supplying described collecting unit work;

If be greater than predetermined electricity for the electricity supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 6th value, described 6th value is less than the 7th value, and described 7th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being less than predetermined electricity; And/or,

If be less than predetermined electricity for the electricity supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 7th value, described 7th value is greater than the 6th value, and described 6th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being greater than predetermined electricity.

17. control methods according to claim 15, is characterized in that, describedly determine that dbjective state interval switching time of described collecting unit comprises according to described dump energy parameter:

If described dump energy parameter is greater than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 8th value, described 8th value is less than the 9th value, and described 9th value is the numerical value at the state switching time interval of described dump energy parameter when being less than predetermined dump energy parameter;

And/or,

If described dump energy parameter is less than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 9th value, described 9th value is greater than the 8th value, and described 8th value is the numerical value at the state switching time interval of described dump energy parameter when being greater than predetermined dump energy parameter.

18. 1 kinds of control device, is characterized in that, be applied to electronic equipment, described electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described device comprises:

Detection module, for detecting the first parameter;

Determination module, for determining dbjective state interval switching time of described collecting unit according to described first parameter, wherein, described dbjective state is spaced apart described collecting unit switches to described enabled state for the N time n-hour from described disable state switching time, the time interval in the N+1 moment of described enabled state is switched to for the N+1 time from described disable state with described collecting unit, wherein, described collecting unit in the power consumption of described disable state lower than the power consumption in described enabled state;

First controls acquisition module, carries out information acquisition for controlling described collecting unit according to described dbjective state interval switching time.

19. control device according to claim 18, is characterized in that, described device also comprises:

Second controls acquisition module, for described determine dbjective state interval switching time of described collecting unit according to described first parameter before, or before described detection first parameter, control described collecting unit and carry out information acquisition according to virgin state interval switching time, virgin state is spaced apart described collecting unit switches to described enabled state for the M time M moment from described disable state switching time, switch to the time interval in the M+1 moment of described enabled state for the M+1 time from described disable state with described collecting unit, M is less than N;

Described first controls acquisition module comprises:

First control module, for contiguous for the described collecting unit time interval being in enabled state for twice is switched to described dbjective state interval switching time by described virgin state interval switching time, control described collecting unit and carry out information acquisition according to described dbjective state interval switching time.

20. control device according to claim 18, is characterized in that, described determination module comprises:

First determining unit, for start described collecting unit time or before, determine dbjective state interval switching time of described collecting unit according to described first parameter;

Described first controls acquisition module comprises:

Start and control collecting unit, for starting described collecting unit, controlling described collecting unit and carrying out information acquisition according to described dbjective state interval switching time.

21. control device according to claim 20, is characterized in that, described device also comprises:

Parameters variation detection module, for monitoring the change of described first parameter;

Adjusting module, if when the change for described first parameter detected meets pre-conditioned, upgrade state interval switching time of described collecting unit, to determine more new state interval switching time, described more new state interval switching time is corresponding with the first parameter after change;

3rd controls acquisition module, carry out information acquisition for controlling described collecting unit according to described more new state interval switching time, when described more new state interval switching time and described collecting unit start or before, determined dbjective state interval switching time is different.

22. control device according to claim 18, is characterized in that, described determination module comprises:

Choose unit, for determining described dbjective state interval switching time according to described first parameter from multiple candidate state interval switching time;

Or computing unit, for calculating described dbjective state interval switching time according to described first parameter.

23. control device according to claim 18, is characterized in that, described detection module comprises:

First detecting unit, for detecting described first parameter that described collecting unit gathers;

Described determination module comprises:

Second determining unit, described first parameter for gathering according to described collecting unit determines dbjective state interval switching time of described collecting unit.

24. control device according to claim 18, it is characterized in that, described electronic equipment comprises detecting unit, described detection module comprises:

Second detecting unit, for detecting described first parameter by described detecting unit, described detecting unit is different from described collecting unit.

25. control device according to claim 24, is characterized in that, described second detecting unit comprises:

First detection sub-unit, for detecting the parameter relevant to the change in location of electronic equipment by described detecting unit;

Described determination module comprises:

3rd determining unit, the parameter for being correlated with according to described change in location determines dbjective state interval switching time of described collecting unit.

26. control device according to claim 18, is characterized in that, described determination module comprises:

First translational speed determining unit, for determining the translational speed of electronic equipment;

First determines performance element, if when being less than predetermined speed for described translational speed, determine that dbjective state is spaced apart the very first time interval switching time, very first time interval was greater than for second time interval, and second time interval was the state switching time interval of translational speed when being greater than predetermined speed

Second determines performance element, if when being greater than predetermined speed for described translational speed, determine that dbjective state was spaced apart for second time interval switching time, second time interval was less than very first time interval, and the very first time is spaced apart state interval switching time when translational speed is greater than predetermined speed.

27. control device according to claim 18, is characterized in that, described determination module comprises:

Second translational speed determining unit, for determining the translational speed of electronic equipment;

3rd determines performance element, if when being less than predetermined First Speed for described translational speed, determine that the numerical value at dbjective state interval switching time is the first value, described first value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed; And/or, if when described translational speed is between predetermined First Speed and predetermined second speed, determine that the numerical value at dbjective state interval switching time is the second value, described second value is less than the first value, and described first value is the numerical value at state interval switching time when translational speed is less than predetermined First Speed; And/or, if when described translational speed is greater than predetermined second speed, determine that the numerical value at dbjective state interval switching time is the 3rd value, described 3rd value is greater than the second value, and described second is worth the numerical value for state interval switching time when translational speed is between predetermined First Speed and predetermined second speed.

28. control device according to claim 18, is characterized in that, described determination module comprises:

Displacement determining unit, for determining the displacement that described electronic equipment switches to enabled state at described collecting unit at the X time and switches to for the Y time in the interval time of enabled state, Y is greater than X;

4th determines performance element, if when being less than predetermined first distance for described displacement, determine that the numerical value at dbjective state interval switching time is the 4th value, described 4th value is greater than the 5th value, and described 5th value is the numerical value at state interval switching time when displacement is greater than predetermined first distance; And/or, if when described displacement is greater than predetermined first distance, determine that the numerical value at dbjective state interval switching time is the 5th value, described 5th value is less than the 4th value, and described 4th value is the numerical value at state interval switching time when displacement is less than predetermined first distance.

29. control device according to right 18, it is characterized in that, described detection module comprises:

Residual capacity measurement unit, for the dump energy parameter of detected electrons equipment;

Described determination module comprises:

5th determines performance element, for determining dbjective state interval switching time of described collecting unit according to described dump energy parameter.

30. control device according to claim 29, is characterized in that, the described 5th determines that performance element comprises:

Estimate subelement, for estimating that according to the hardware configuration information of described electronic equipment described electronic equipment needs the electricity consumed;

Subelement is determined in electricity supply, and for according to described dump energy parameter, and the described electricity consumed that needs determines the electricity supplying described collecting unit work;

First determines to perform subelement, if when being greater than predetermined electricity for the electricity for supplying described collecting unit work, determine that the numerical value at dbjective state interval switching time is the 6th value, described 6th value is less than the 7th value, and described 7th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being less than predetermined electricity; And/or, if when the electricity for supplying described collecting unit work is less than predetermined electricity, determine that the numerical value at dbjective state interval switching time is the 7th value, described 7th value is greater than the 6th value, and described 6th value is the numerical value at electricity for supplying described collecting unit work state interval switching time when being greater than predetermined electricity.

31. control device according to claim 29, is characterized in that, the described 5th determines that performance element comprises:

Second determines to perform subelement, if when described dump energy parameter is greater than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 8th value, described 8th value is less than the 9th value, and described 9th value is the numerical value at the state switching time interval of described dump energy parameter when being less than predetermined dump energy parameter; And/or, if when described dump energy parameter is less than predetermined dump energy parameter, determine that the numerical value at dbjective state interval switching time is the 9th value, described 9th value is greater than the 8th value, and described 8th value is the numerical value at the state switching time interval of described dump energy parameter when being greater than predetermined dump energy parameter.

32. 1 kinds of electronic equipments, it is characterized in that, described electronic equipment has the collecting unit for information acquisition, when described electronic equipment is in running order, described collecting unit has enabled state and disable state, and described electronic equipment comprises the control device described in any one of claim 18-31.