CN203840467U - Camera device image stabilization testing system - Google Patents

Abstract

The invention discloses a camera device image stabilization testing system which is applied to the fields of development and testing of image stabilization of a shooting module group. The testing system includes a vibration unit, a fixing unit arranged at the far end of the vibration unit, and a kinetic energy supply unit arranged at the near end of the vibration unit. The fixing unit is used for installing a shooting device and the kinetic energy supply unit is used for driving the vibration unit to move, so that the fixing unit drives the shooting device to move to stimulate the shaking process. The camera device image stabilization testing system can reproduce shaking phenomena in multiple directions during use.

Description

The anti-shake technical testing system of camera head

Technical field

The utility model relates to a kind of anti-shake test macro, particularly a kind of anti-shake technological development of camera head and anti-shake technical testing system of the camera head of test of being applied to.

Background technology

Along with the development of mobile electronic device, especially in intelligent communication field, user, when pursuing the more convenient operating system of intelligent communication equipment, also more and more pays close attention to the quality of the image capture function of intelligent communication equipment.

In intelligent communication field, image capture function mainly realizes by camera module, specifically, camera module is organic set of optical element and electronic component, come co-treatment to record the light for the treatment of pickup image object, and this light is carried out to photoelectric conversion, then reduce and show the image of this object via relevant equipment.The fine or not influencing factor of the picture quality of therefore, absorbing for Intelligent mobile equipment mainly contains: the quality of the material of camera module and degree reasonable in design; The anti-shake technology that camera module adopts etc.

Admittedly, for same camera module, different users uses it to carry out image capture work, may obtain different results.This be because, user, use in the process of image of this camera module picked-up object, can there is certain shake in user's hand, thereby, for the imaging of this camera module, cause certain deviation.Therefore, how to solve camera module jitter problem in use, it is the difficult problem that the technical staff in camera module field faces always, and in the process addressing this problem, the kind of the anti-shake technology of camera module is on the increase, and the anti-shake technology of camera module is also constantly being improved and development.

As the auxiliary development instrument of the anti-shake technology of camera module, it is mainly used in the development& testing of the anti-shake technology of camera module, is more and more subject in recent years the technical staff's in camera module field attention.Yet, very huge of such auxiliary development instrument volume, and system complexity very, expensive, operating process is numerous and diverse, the technical staff need to such product operation experience can use, and therefore, can not meet the technical staff in camera module field for the demand of the instrument of auxiliary development camera module dither technique.

Therefore, need in the market the anti-shake technological development of a economical and practical camera head and test platform badly.

Utility model content

Main advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the anti-shake technical testing system applies of described camera head, in the development& testing of the anti-shake technology of camera head, can reduce construction cycle and the difficulty of the anti-shake technology of camera head effectively.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the combination of the anti-shake technical testing system of described camera head each several part structure is compact, scientific arrangement, not only can effectively control its material cost, but also can be by regulating its different rotating shaft, come analog subscriber to there is the dither process of hand in the process of mobile device of camera head in use, reappear truly arbitrary dimension of same time dither process of (comprising horizontal direction, vertical direction, pitching, rolling etc.).

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the software interface of the anti-shake technical testing system of described camera head is easy to use, and can, by revising relevant parameter, revise and realize the different result of use of the anti-shake technical testing system of described camera head.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, vibration frequency and the amplitude of the anti-shake technical testing system of described camera head can be effectively controlled, and can demonstrate intuitively by display element the numerical value of vibration frequency, so that operator can operate on it easily and control.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the anti-shake technical testing system of described camera head reliability in the process of using is high, starting-up response speed and to stop speed fast, can improve the efficiency of the reliability of the anti-shake technology of utilizing its test camera head.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the anti-shake technical testing system of described camera head can improve the quality of camera head effectively, with this, improves the product yield of the mobile device with camera head.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the anti-shake technical testing system of described camera head is in the process of the anti-shake technology of development& testing camera head, can monitor and guarantee correctness and the accuracy of the anti-shake technology of camera head, therefore, the anti-shake technical testing system of described camera head can meet the demand in market effectively.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, the anti-shake technical testing system of described camera head allows layman to carry out skilled operation to it, practical, thereby, can improve greatly the production efficiency of camera head, and then, cost of labor and the cost of manufacture of reduction camera head.

Another advantage of the present utility model is, provide a kind of camera head anti-shake technical testing system, with respect to traditional anti-shake technology development platform, the anti-shake technical testing system configuration of described camera head is simple, raw material wide material sources and have lower cost, conveniently assemble and safeguard.

Another advantage of the present utility model is, provides a kind of camera head anti-shake technical testing system, and it is simple in structure, easy to use, can meet the demand in market.Therefore, the anti-shake technical testing system of described camera head has the good market space and prospect.

According to an aspect of the present utility model, it provides a kind of camera head anti-shake technical testing system, meet above-mentioned advantage and other advantages, the anti-shake technical testing system of wherein said camera head comprises a vibration unit, be arranged at a fixed cell of described vibration unit far-end, an and kinetic energy feed unit that is arranged at described vibration unit near-end, wherein said fixed cell is used for installing a camera head, described kinetic energy feed unit is used for ordering about described vibration unit motion, thereby make described fixed cell drive described camera head motion, with analog dither process.

According to the utility model one embodiment, the anti-shake technical testing system of described camera head also comprises a pedestal, wherein said pedestal comprises a base body, and the end two stands that is fixed on described base body and be arranged in parallel, and every described support has an installing hole; Described vibration unit sidepiece comprises an installation elements, and the both ends of wherein said installation elements are arranged at respectively the described installing hole of every described support.

According to the utility model one embodiment, described pedestal also comprises an adjustment element, described adjustment element is arranged between described base body and described kinetic energy feed unit, to guarantee that the anti-shake technical testing system of described camera head is under unused state, described vibration unit is parallel with described base body.

According to the utility model one embodiment, described pedestal also comprises a stopping element, and an end of described stopping element is extended and is fixed on described base body, and described kinetic energy feed unit is installed on described stopping element.

According to the utility model one embodiment, described installation elements both ends comprise respectively a bearing, and every described bearing is arranged at the described installing hole of every described support.

According to the utility model one embodiment, described vibration unit and described pedestal are made by aluminium.

According to the utility model one embodiment, described vibration unit comprises one first vibrating elements, and near-end is arranged at one second vibrating elements of described the first vibrating elements, wherein said fixed cell is arranged at the far-end of described the second vibrating elements, and the synchronized movement of described the first vibrating elements and described the second vibrating elements.

According to the utility model one embodiment, described vibration unit also comprises a connection element that is arranged at described the second vibrating elements far-end, and wherein said connection element has a location hole, and with spaced one first location notch of described location hole; Described retaining element has one first setting element, one second setting element and one second location notch; Described the first setting element is arranged at described location hole and described the second location notch simultaneously, and described the second setting element is arranged at described the first location notch and described the second location notch simultaneously.

According to the utility model one embodiment, described the first location notch is arc, in the track that described the second setting element is able to form at described the first location notch, slides.

According to the utility model one embodiment, described kinetic energy feed unit comprises a power supply, one control unit and a mechanical energy generating means, wherein said control unit and described mechanical energy generating means are electrically connected to respectively described power supply, and described control unit is for controlling the operational factor of described mechanical energy generating means.

According to the utility model one embodiment, described mechanical energy generating means comprises a mechanical energy generation member, and one first actuated element coupling with described mechanical energy generation member; Described vibration unit also comprises one second actuated element mutually exchanging with described the first actuated element, and the synchronized movement of described the first actuated element and described the second actuated element.

According to the utility model one embodiment, described mechanical energy generating means comprises a mechanical energy generation member, and one first actuated element coupling with described mechanical energy generation member; Described vibration unit has a guiding groove, described the first actuated element is extended to described guiding groove, and when described mechanical energy generation member produces kinetic energy, described the first actuated element is able to, via described guiding groove, this kinetic energy is conducted to described vibration unit, thereby, make described fixed cell analog dither process.

According to the utility model one embodiment, described the first actuated element is eccentric wheel.

According to the utility model one embodiment, described guiding groove is circular, oval or special-shaped.

According to the utility model one embodiment, described kinetic energy feed unit comprises a power supply, one control unit and an electromagnetic energy generating means, wherein said control unit and described electromagnetic energy generating means are electrically connected to respectively described power supply, and described control unit is for controlling the operational factor of described electromagnetic energy generating means.

According to the utility model one embodiment, described electromagnetic energy generating means comprises one first electromagnetic component that is arranged at described base body, and one second electromagnetic component that is arranged at described vibration unit and mutually exchanges with described the first electromagnetic component; Wherein, when described the first electromagnetic component and described the second electromagnetic component electromagnetic ground induction, described kinetic energy feed unit is ordered about described vibration unit reciprocating motion, thereby, make described fixed cell analog dither process.

According to the utility model one embodiment, described control unit comprises a display element, it is for showing the service data of described kinetic energy feed unit, an and parameter modification port, it is for revising or change the operational factor of described kinetic energy feed unit, and wherein said display element and described parameter modification port are respectively coupled to described control unit.

According to the utility model one embodiment, described control unit comprises a display element, it is for showing the service data of described kinetic energy feed unit, an and parameter modification port, it is for revising or change the operational factor of described kinetic energy feed unit, and wherein said display element and described parameter modification port are respectively coupled to described control unit.

According to the utility model one embodiment, described camera head is selected from camera module, have a kind of in the mobile phone of camera and digital camera.

Accompanying drawing explanation

Fig. 1 is according to the schematic perspective view of a preferred embodiment of the utility model.

Fig. 2 is according to the schematic perspective view of the utility model above preferred embodiment kinetic energy transmission implementation.

Fig. 3 is according to the schematic perspective view of an another kinetic energy transmission implementation of the utility model above preferred embodiment.

Fig. 4 is according to the distortion execution mode of the kinetic energy feed unit of the utility model above preferred embodiment.

Fig. 5 is the each several part block diagram according to the control unit of the utility model above preferred embodiment.

Embodiment

Below describe and be used for disclosing the utility model so that those skilled in the art can realize the utility model.Preferred embodiment in below describing only as an example, it may occur to persons skilled in the art that other apparent modification.The other technologies scheme that the basic principle of the present utility model defining in the following description can be applied to other embodiments, deformation program, improvement project, equivalent and not deviate from spirit and scope of the present utility model.

That it is applied to the development& testing of the anti-shake technology of camera head according to the anti-shake technical testing system of the camera head of a preferred embodiment of the utility model as shown in Figure 1.Correspondingly, the anti-shake technical testing system of described camera head comprises a vibration unit 10, one fixed cell 20 and a kinetic energy feed unit 30, wherein said kinetic energy feed unit 30 provides power source for the anti-shake technical testing system of described camera head, with the dither process of analog subscriber hand when use has the mobile device of camera head.

According to this preferred embodiment of the present utility model, described vibration unit 10 has a far-end, and it extends to suitable position, and described fixed cell 20 is arranged at the far-end of described vibration unit 10; And a near-end, described kinetic energy feed unit 30 adjoins the near-end that is arranged at described vibration unit 10, and described kinetic energy feed unit 30 is able to mutually exchange with described vibration unit 10.In other words, when described kinetic energy feed unit 30 output kinetic energy, described vibration unit 10 is responded to and is conducted this kinetic energy to described fixed cell 20, thereby, make the dither process of described fixed cell 20 analog subscriber hands.Described fixed cell 20 is for a camera head to be tested is installed, and described camera head is selected from camera module, have a kind of in the mobile phone of camera and digital camera etc.

In said process, the kinetic energy that described vibration unit 10 produces with described kinetic energy feed unit 30 with described fixed cell 20 frequency acting on described vibration unit 10 are consistent.That is to say, the synchronized movement of described fixed cell 20 and described vibration unit 10, so that the anti-shake technical testing system of described camera head can facilitate and accurately be monitored by operator.

It is worth mentioning that, the kinetic energy that described kinetic energy feed unit 30 produces acts on described vibration unit 10 off and on, or described kinetic energy feed unit 30 produces off and on kinetic energy and acts on described vibration unit 10, thereby, make described vibration unit 10 realize reciprocating motion.

Specifically, when the kinetic energy of described kinetic energy feed unit 30 generations acts on described vibration unit 10, described vibration unit 10 has motion and the displacement towards preset direction; The kinetic energy producing when described kinetic energy feed unit 30 does not act on described vibration unit 10 or when described kinetic energy feed unit 30 does not produce kinetic energy, and described vibration unit 10 is because the gravity of self has motion and the displacement of returning to predeterminated position; When repeating above-mentioned two processes between described vibration unit 10 and described kinetic energy feed unit 30, described vibration unit 10 has been realized the reciprocating motion of expection.Thereby, the dither process of user's hand that made the anti-shake technical testing system simulation of described camera head.

The anti-shake technical testing system of described camera head also comprises a pedestal 40, as shown in Figure 1, described vibration unit 10 is arranged at respectively described pedestal 40 with described kinetic energy feed unit 30, wherein said kinetic energy feed unit 30 is driven described vibration unit 10 to do the motion with respect to described pedestal 40, that is to say, described vibration unit 10 is arranged at described pedestal 40 movably.

Described vibration unit 10 sidepieces comprise an installation elements 11, described pedestal 40 comprises a base body 41, and the end two stands 42 that is fixed on described base body 41 and be arranged in parallel, wherein every described support 42 has an installing hole 421, and the both ends of described installation elements 11 are arranged at respectively the described installing hole 421 of every described support 42.Described vibration unit 10 is able to take described installation elements 11 and moves reciprocatingly as axle.

The both ends of described installation elements 11 comprise respectively a bearing 111, every described bearing 111 is arranged in every described installing hole 421, when vibration unit 10 be take described installation elements 11 when axle is done the motion with respect to described base body 41, the vibration that every described bearing 111 produces for reducing the friction between described installation elements 11 and described support 42.Thereby, make the Oscillation Amplitude of described vibration unit 10 and effect can access control more accurately.

Described pedestal 40 also comprises an adjustment element 43, described adjustment element 43 is arranged between described base body 41 and described kinetic energy feed unit 30, so that when the anti-shake technical testing system of described camera head is during in unused state, described vibration unit 10 is parallel with described base body 41.

Described pedestal 40 also comprises a stopping element 44, one end of described stopping element 44 is extended and is fixed on described base body 41, described kinetic energy feed unit 30 is installed on described stopping element 44, so that have stable position relationship between described kinetic energy feed unit 30 and described pedestal 40.Thereby, guarantee the anti-shake technical testing system of described camera head stability and reliability in use.

According to an aspect of the present utility model, described vibration unit 10 comprises one first vibrating elements 12, and near-end is fixed on one second vibrating elements 13 of described the first vibrating elements 12, wherein said fixed cell 20 is arranged at the far-end of described the second vibrating elements 13, described installation elements 11 is arranged at the sidepiece of described the first vibrating elements 12, described kinetic energy feed unit 30 is arranged at described the first vibrating elements 12 with respect to the sidepiece of described installation elements 11, and the synchronized movement of described the first vibrating elements 12 and described the second vibrating elements 13.

Described vibration unit 10 also comprises a connection element 14 that is arranged at described the second vibrating elements 13 far-ends, and wherein said connection element 14 has a location hole 141, and with spaced the first location notch 142 of described location hole 141; Correspondingly, described fixed cell 20 has one first setting element 21, one second setting element 22 and one second location notch 23, wherein said the first setting element 21 is arranged at described location hole 121 and described the second location notch 23 simultaneously, and described the second setting element 22 is arranged at described the first location notch 142 and described the second location notch 23 simultaneously.Thereby, make to there is stable structure between described fixed cell 20 and described the second vibrating elements 13 and combine.

It is worth mentioning that, the curved setting of described the first location notch 142, so that slide in the track that described the second setting element 22 is able to form at described the first location notch 142, thereby, make the angle between described fixed cell 20 and described the second vibrating elements 13 adjusted.That is to say, the vibration angle of described camera head to be tested can be adjusted by described the second setting element 22.In this specific embodiment of the present utility model, the vibration angle of camera head described to be tested can be realized the adjustment of 0 ° to 90 ° by described the second setting element 22 in described the first location notch 142 interior slips.

Described fixed cell 20 also comprises a fixed component 24, and described fixed component 24 has one or more holes 241 of admittedly stopping, for fixedly mounting described camera head.

When described vibration unit 10 is moved by described kinetic energy feed unit 30 drivings, the camera head that is fixed on described fixed cell 20 is simulated the hand shake of user when use has the mobile device of camera head.In addition, by adjusting the angle between described fixed cell 20 and described vibration unit 10, and the relevant parameter of adjusting described kinetic energy feed unit 30, can also simulate different shake effects.

It is worth mentioning that, described pedestal 40 is made by aluminium with described vibration unit 10, it is advantageous that described pedestal 40 and evenness and the flatness of described vibration unit 10 can both accurately be guaranteed, with this, guarantee the amplitude of the anti-shake technical testing system of described camera head and frequency can both obtain effectively and accurately control.It will be appreciated by persons skilled in the art that described pedestal 40 and described vibration unit 10 also can be made by other materials.

According to the implementation of the kinetic energy transmission of the utility model above preferred embodiment described kinetic energy feed unit 30 as shown in Figure 2.Combine the utility model one object, described kinetic energy feed unit 30 comprises power supply 31, one control units 32 and a mechanical energy generating means 33, and wherein said control unit 32 is electrically connected to respectively described power supply 31 with described mechanical energy generating means 33.Specifically, described power supply 31 provides electric energy for described control unit 32 and described mechanical energy generating means 33, and described control unit 32 is for controlling the operational factor of described mechanical energy generating means 33.

Described mechanical energy generating means 33 further comprises a mechanical energy generation member 331, and one first actuated element 332 coupling with described mechanical energy generation member 331; Correspondingly, described vibration unit 10 also comprises one second actuated element 15 mutually exchanging with described the first actuated element 332.In other words, the kinetic energy that described mechanical energy generation member 331 produces is able to conduct to described shaking platform 10 by described the first actuated element 332 with described the second actuated element 15.

In this preferred embodiment of the present utility model, described the second actuated element 15 is arranged at described the first vibrating elements 12, and described the first actuated element 332 is in contact with one another with described the second actuated element 15.

On the other hand, the synchronized movement of described mechanical energy generation member 331 and described the first actuated element 332.When described mechanical energy generation member 331 produces kinetic energy under the effect of described power supply 31, this kinetic energy is able to drive to described the second actuated element 15 via described the first actuated element 332.Especially, described the second actuated element 15 is arranged at described the first vibrating elements 12 rotationally, it is advantageous that, at described the first actuated element 332, drive described the second actuated element 15 to drive described the first vibrating elements 12 when preset direction produces motion and displacement, described the second actuated element 15 is also done the axial motion with respect to described the first actuated element 332 simultaneously, to alleviate as much as possible the impact collision between described the first actuated element 332 and described the second actuated element 15, thereby, the Oscillation Amplitude of the anti-shake technical testing system of described camera head can be accessed more accurately and monitoring effectively.

It is worth mentioning that, described the first actuated element 332 is eccentric wheel, when described mechanical energy generation member 331 is producing after kinetic energy, the eccentric structure of described the first vibrating elements 332 obtains so that this kinetic energy conducts to described the first vibrating elements 12, thereby, reach the object that described vibration unit 10 is moved reciprocatingly.More, operator can need according to different uses, selects and changes the first different actuated elements 332, makes described vibration unit 10 have different amplitudes and frequency.Thereby, make the anti-shake technical testing system of described camera head can simulate different vibrating effects.

According to this preferred embodiment of the present utility model, described mechanical energy generation member 331 is preferably stepping motor, it is advantageous that, the rotating speed of stepping motor is high, and moment is large, and stepping motor can also be adjusted its power output and frequency easily.Therefore,, with respect to other forms of motor, stepping motor can more effectively meet the anti-shake technical testing system of described camera head in order to the needs of analog subscriber hand shake effect.

According to the implementation of the kinetic energy transmission of an another described kinetic energy feed unit 30 of the utility model above preferred embodiment as shown in Figure 3.Described kinetic energy feed unit 30 comprises power supply 31, one control units 32 and a mechanical energy generating means 33A, and wherein said control unit 32 is electrically connected to respectively described power supply 31 with described mechanical energy generating means 33A.Specifically, described power supply 31 provides electric energy with described mechanical energy generating means 33A for described control unit 32, and described control unit 32 is for controlling the operational factor of described mechanical energy generating means 33A.

Described mechanical energy generating means 33A further comprises a mechanical energy generation member 331A, and the one first actuated element 332A coupling with described mechanical energy generation member 331A; Correspondingly, described vibration unit 10 also has a guiding groove 15A, described the first actuated element 332A extends in described guiding groove 15A, and, when described mechanical energy generation member 331A produces after kinetic energy, described the first actuated element 332A is able to, via described guiding groove 15A, this kinetic energy is driven to described vibration unit 10, so that described vibration unit 10 produces motion.Thereby the described fixed cell 20 that makes to be fixed on described the second vibrating elements 13 far-ends is able to the hand dither process of analog subscriber.

It is worth mentioning that, described guiding groove 15A can be circular, oval or special-shaped, so that operator can need to select to have according to different uses described the first vibrating elements 12 of described guiding groove 15A easily, thereby, make the different shake effect of the anti-shake technical testing system simulation of described camera head.

According to the distortion execution mode of the kinetic energy feed unit of the utility model above preferred embodiment as shown in Figure 4.Described kinetic energy feed unit 30 comprises power supply 31, one control units 32 and an electromagnetic energy generating means 33B, and wherein said control unit 32 is electrically connected to respectively described power supply 31 with described electromagnetic energy generating means 33B.Specifically, described power supply 31 provides electric energy with described electromagnetic energy generating means 33B for described control unit 32, and described control unit 32 is in order to control the operational factor of described electromagnetic energy generating means 33B.

According to this execution mode of the present utility model, described electromagnetic energy generating means 33B comprises the one first electromagnetic component 331B that is arranged at described base body 41, and the one second electromagnetic component 332B that is arranged at described the first vibrating elements 10 and mutually exchanges with described the first electromagnetic component 331B.

Specifically, when described the first electromagnetic component 331B produces electromagnetic energy under the effect of described power supply 31, described the second electromagnetic component 332B is able to and described the first electromagnetic component 331B electromagnetic ground induction, to order about described the first vibrating elements 12, has motion and the displacement towards preset direction; When described the first electromagnetic component 331B does not produce electromagnetic energy, described the first vibrating elements 12 has motion and the displacement of returning to predeterminated position under the effect of gravity; In the process that described electromagnetic energy generating means 33B switches under above-mentioned two states, described the first vibrating elements 12 has been realized reciprocating motion.Thereby the anti-shake technical testing system of described camera head has realized the object of analog subscriber hand shake.

It is worth mentioning that, by described control unit 32, there is the operational factor of revising easily described electromagnetic energy generating means 33, so that the first vibrating elements 12 has different amplitudes and frequency, thereby, make the anti-shake technical testing system of described camera head carry out the different shake effect of analog subscriber hand.

As shown in Figure 5, in the respective embodiments described above of the present invention, the chip of described control unit 32 adopts single-chip microcomputer cheaply, with respect to traditional anti-shake development platform, it is advantageous that and can meet on the basis of the anti-shake technical testing system of described camera head needs, make the anti-shake technical testing system of described camera head there is lower cost.

Specifically, described control unit 32 comprises a display element 322 and a parameter modification port 324, described display element 322 is electrically connected to respectively described control unit 32 with described parameter modification port 324, wherein said display element 322 is for showing the service data of described kinetic energy feed unit 30, and described parameter modification port 324 is for revising or change the service data of described kinetic energy feed unit 30.

Described control unit 32 has been simplified the operating process of the anti-shake technical testing system of described camera head, so that unskilled operator operates on it.Operator can general layout the use of different camera heads need, by described parameter modification port 324, be that described kinetic energy feed unit 30 is selected suitable parameter, and, the motion state of this parameter and described kinetic energy feed unit 30 is able in described display element 322, show simultaneously, so that operator reads relevant data, thereby operator can control the anti-shake technical testing system works of described camera head more accurately.

One skilled in the art will understand that the embodiment of the present utility model shown in foregoing description and accompanying drawing only limits the utility model as an example and not.The purpose of this utility model is complete and realization effectively.Function of the present utility model and structural principle are shown in an embodiment and are illustrated, are not deviating under described principle, and execution mode of the present utility model can have any distortion or modification.

Claims (23)

1. the anti-shake technical testing system of camera head, it is characterized in that, comprise a vibration unit, be arranged at a fixed cell of described vibration unit far-end, and a kinetic energy feed unit that is arranged at described vibration unit near-end, wherein said fixed cell is used for installing a camera head, and described kinetic energy feed unit is used for ordering about described vibration unit motion, thereby make described fixed cell drive described camera head motion, with analog dither process.

2. test macro as claimed in claim 1, it is characterized in that, the anti-shake technical testing system of described camera head also comprises a pedestal, and wherein said pedestal comprises a base body, and the end two stands that is fixed on described base body and be arranged in parallel, every described support has an installing hole; Described vibration unit sidepiece comprises an installation elements, and the both ends of wherein said installation elements are arranged at respectively the described installing hole of every described support.

3. test macro as claimed in claim 2, it is characterized in that, described pedestal also comprises an adjustment element, described adjustment element is arranged between described base body and described kinetic energy feed unit, to guarantee that the anti-shake technical testing system of described camera head is under unused state, described vibration unit is parallel with described base body.

4. test macro as claimed in claim 2, is characterized in that, described pedestal also comprises a stopping element, and an end of described stopping element is extended and is fixed on described base body, and described kinetic energy feed unit is installed on described stopping element.

5. test macro as claimed in claim 3, is characterized in that, described pedestal also comprises a stopping element, and an end of described stopping element is extended and is fixed on described base body, and described kinetic energy feed unit is installed on described stopping element.

6. test macro as claimed in claim 5, is characterized in that, described installation elements both ends comprise respectively a bearing, and every described bearing is arranged at the described installing hole of every described support.

7. test macro as claimed in claim 2, is characterized in that, described vibration unit and described pedestal are made by aluminium.

8. test macro as claimed in claim 1, it is characterized in that, described vibration unit comprises one first vibrating elements, and near-end is arranged at one second vibrating elements of described the first vibrating elements, wherein said fixed cell is arranged at the far-end of described the second vibrating elements, and the synchronized movement of described the first vibrating elements and described the second vibrating elements.

9. test macro as claimed in claim 2, it is characterized in that, described vibration unit comprises one first vibrating elements, and near-end is arranged at one second vibrating elements of described the first vibrating elements, wherein said fixed cell is arranged at the far-end of described the second vibrating elements, and the synchronized movement of described the first vibrating elements and described the second vibrating elements.

10. test macro as claimed in claim 8, it is characterized in that, described vibration unit also comprises a connection element that is arranged at described the second vibrating elements far-end, and wherein said connection element has a location hole, and with spaced one first location notch of described location hole; Described retaining element has one first setting element, one second setting element and one second location notch; Described the first setting element is arranged at described location hole and described the second location notch simultaneously, and described the second setting element is arranged at described the first location notch and described the second location notch simultaneously.

11. test macros as claimed in claim 9, it is characterized in that, described vibration unit also comprises a connection element that is arranged at described the second vibrating elements far-end, and wherein said connection element has a location hole, and with spaced one first location notch of described location hole; Described retaining element has one first setting element, one second setting element and one second location notch; Described the first setting element is arranged at described location hole and described the second location notch simultaneously, and described the second setting element is arranged at described the first location notch and described the second location notch simultaneously.

12. test macros as claimed in claim 10, is characterized in that, described the first location notch is arc, in the track that described the second setting element is able to form at described the first location notch, slide.

13. test macros as claimed in claim 11, is characterized in that, described the first location notch is arc, in the track that described the second setting element is able to form at described the first location notch, slide.

14. as the test macro as described in arbitrary in claim 1 to 13, it is characterized in that, described kinetic energy feed unit comprises a power supply, one control unit and a mechanical energy generating means, wherein said control unit and described mechanical energy generating means are electrically connected to respectively described power supply, and described control unit is for controlling the operational factor of described mechanical energy generating means.

15. test macros as claimed in claim 14, is characterized in that, described mechanical energy generating means comprises a mechanical energy generation member, and one first actuated element coupling with described mechanical energy generation member; Described vibration unit also comprises one second actuated element mutually exchanging with described the first actuated element, and the synchronized movement of described the first actuated element and described the second actuated element.

16. test macros as claimed in claim 14, is characterized in that, described mechanical energy generating means comprises a mechanical energy generation member, and one first actuated element coupling with described mechanical energy generation member; Described vibration unit has a guiding groove, described the first actuated element is extended to described guiding groove, and when described mechanical energy generation member produces kinetic energy, described the first actuated element is able to, via described guiding groove, this kinetic energy is conducted to described vibration unit, thereby, make described fixed cell analog dither process.

17. test macros as described in claim 15 or 16, is characterized in that, described the first actuated element is eccentric wheel.

18. test macros as claimed in claim 16, is characterized in that, described guiding groove is circular or oval.

19. as the test macro as described in arbitrary in claim 2 to 13, it is characterized in that, described kinetic energy feed unit comprises a power supply, one control unit and an electromagnetic energy generating means, wherein said control unit and described electromagnetic energy generating means are electrically connected to respectively described power supply, and described control unit is for controlling the operational factor of described electromagnetic energy generating means.

20. test macros as claimed in claim 19, it is characterized in that, described electromagnetic energy generating means comprises one first electromagnetic component that is arranged at described base body, and one second electromagnetic component that is arranged at described vibration unit and mutually exchanges with described the first electromagnetic component; Wherein, when described the first electromagnetic component and described the second electromagnetic component electromagnetic ground induction, described kinetic energy feed unit is ordered about described vibration unit reciprocating motion, thereby, make described fixed cell analog dither process.

21. test macros as claimed in claim 14, it is characterized in that, described control unit comprises a display element, it is for showing the service data of described kinetic energy feed unit, an and parameter modification port, it is for revising or change the operational factor of described kinetic energy feed unit, and wherein said display element and described parameter modification port are respectively coupled to described control unit.

22. test macros as claimed in claim 19, it is characterized in that, described control unit comprises a display element, it is for showing the service data of described kinetic energy feed unit, an and parameter modification port, it is for revising or change the operational factor of described kinetic energy feed unit, and wherein said display element and described parameter modification port are respectively coupled to described control unit.

23. test macros as claimed in claim 19, is characterized in that, described camera head is selected from camera module, have a kind of in the mobile phone of camera and digital camera.