CN202111787U - Automatic multi-target tracking picture pick-up system - Google Patents

Automatic multi-target tracking picture pick-up system Download PDF

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Publication number
CN202111787U
CN202111787U CN2011201880706U CN201120188070U CN202111787U CN 202111787 U CN202111787 U CN 202111787U CN 2011201880706 U CN2011201880706 U CN 2011201880706U CN 201120188070 U CN201120188070 U CN 201120188070U CN 202111787 U CN202111787 U CN 202111787U
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Prior art keywords
cloud terrace
camera
video camera
unit
control
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CN2011201880706U
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Inventor
刘海川
楼冬明
张昕
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Xiamen Bocong Information Technology Co., Ltd.
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AQUILLA NETWORK TECHNOLOGIES Inc
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Abstract

The utility model relates to an automatic multi-target tracking picture pick-up system, which comprises a camera, a pan/tilt/zoom unit, a central control unit and a pan/tilt/zoom unit movement server unit. The camera is fixed at the pan/tilt/zoom unit; the central control unit comprises a pan/tilt/zoom unit posture control subunit and a camera focusing control subunit which are connected mutually; the camera focusing control subunit is connected with the camera; the pan posture control subunit is connected with the pan/tilt/zoom unit through the pan/tilt/zoom unit movement server unit; and the central control unit is further connected with an external target obtaining system. The camera focusing control subunit of the automatic multi-target tracking picture pick-up system adopting the structure determines the focusing value of the camera according to the pan/tilt/zoom unit angle control value of the pan/tilt/zoom unit posture control subunit, and sends the focusing value of the camera to the camera, so as to control a focal length; the system is guaranteed to be still capable of accurately focusing a tracked substance when a tracked object has a foreground shield or light is weaker and is not enough to enable the camera to automatically focus; and the image of a target is guaranteed to be clear.

Description

The multiple target automatically tracking video taking system
Technical field
The utility model relates to the automatic monitored control system field, particularly the automatically tracking video taking system technical field.
Background technology
In the prior art, have the video camera of the traditional automatic focus technology of multiple employing, the shortcoming of this type of video camera is; Occur blocking in prospect; During like objects such as electric wire, branches, often video camera can be autofocusing on the shelter of prospect, and causing needs the objective fuzzy of focusing unclear.Therefore, in the automatically tracking video taking system technical field, being badly in need of providing a kind of can be not enough to a little less than to let under the situation of camera automatic focusing having prospect shelter or light, still can accurately focus on by tracked object, guarantees target image camera system clearly.
The utility model content
The purpose of the utility model is to have overcome above-mentioned shortcoming of the prior art; Providing a kind of is not enough to a little less than to let under the situation of camera automatic focusing having prospect shelter or light; Still can accurately focus on, guarantee that target image is clear by tracked object, and simple in structure; With low cost, range of application is the multiple target automatically tracking video taking system comparatively widely.
In order to realize above-mentioned purpose; The multiple target automatically tracking video taking system of the utility model comprises video camera, The Cloud Terrace, central control unit and The Cloud Terrace motion server unit; Described video camera is fixed in described The Cloud Terrace; Described central control unit comprises interconnective The Cloud Terrace attitude control sub unit and video camera focus control subelement; Described video camera focus control subelement connects described video camera, and described The Cloud Terrace attitude control sub unit connects described The Cloud Terrace through described The Cloud Terrace motion server unit, and described central control unit also connects external object and obtains system.
In this multiple target automatically tracking video taking system; Described The Cloud Terrace motion server unit comprises cradle head control server, The Cloud Terrace move both vertically control circuit and The Cloud Terrace horizontal movement control circuit; Described The Cloud Terrace comprises move both vertically drive motors and horizontal movement drive motors; Described cradle head control server connects described The Cloud Terrace attitude control sub unit; Described cradle head control server also connects the drive motors that moves both vertically of described The Cloud Terrace through the described The Cloud Terrace control circuit that moves both vertically, and connects the horizontal movement drive motors of described The Cloud Terrace through described The Cloud Terrace horizontal movement control circuit.
In this multiple target automatically tracking video taking system, described video camera focus control subelement comprises the focal length computation processor, and described focal length computation processor connects described The Cloud Terrace attitude control sub unit and video camera respectively.
In this multiple target automatically tracking video taking system; Described focal length computation processor comprises The Cloud Terrace level and vertical angle read port, and described focal length computation processor is connected described The Cloud Terrace attitude control sub unit through this The Cloud Terrace level with the vertical angle read port.
In this multiple target automatically tracking video taking system, described video camera is a Pan/Tilt/Zoom camera, and described Pan/Tilt/Zoom camera has the optical lens controller, and described focal length computation processor connects described optical lens controller.
Adopted the multiple target automatically tracking video taking system of the utility model; Its central control unit comprises interconnective The Cloud Terrace attitude control sub unit and video camera focus control subelement, and described video camera focus control subelement connects described video camera, thereby described video camera focus control subelement is able to confirm the video camera focus value according to the The Cloud Terrace angle controlling value of described The Cloud Terrace attitude control sub unit; And this focus value is sent to described video camera; With the control focal length, guarantee that this system has prospect shelter or light when being not enough to let camera automatic focusing a little less than at the object of being followed the tracks of, and still can accurately focus on by tracked object; The assurance target image is clear; And the multiple target automatically tracking video taking system is simple in structure, with low cost, and the focus method range of application of this system is comparatively extensive.
Description of drawings
Fig. 1 is the structural representation of the multiple target automatically tracking video taking system of the utility model.
The schematic flow sheet of the focus method that Fig. 2 is adopted for the multiple target automatically tracking video taking system of the utility model.
The geometric representation of the focus method that Fig. 3 is adopted for the multiple target automatically tracking video taking system of the utility model.
Fig. 4 is video camera imaging principle simplified model figure.
Fig. 5 is measured value (L, x) position view in coordinate of N group object distance L and focus value x.
Fig. 6 is the focusing curve after the match and the comparison sketch map of measured value x in the multiple target automatically tracking video taking system of the utility model.
Fig. 7 is the graph of relation of video camera focus value and shooting distance in the multiple target automatically tracking video taking system of the utility model.
Embodiment
In order more to be expressly understood the technology contents of the utility model, the special following examples of lifting specify.
See also shown in Figure 1ly, be the structural representation of the multiple target automatically tracking video taking system of the utility model.
In one embodiment; This multiple target automatically tracking video taking system comprises video camera, The Cloud Terrace, central control unit and The Cloud Terrace motion server unit; Described video camera is fixed in described The Cloud Terrace; Described central control unit comprises interconnective The Cloud Terrace attitude control sub unit and video camera focus control subelement; Described video camera focus control subelement connects described video camera, and described The Cloud Terrace attitude control sub unit connects described The Cloud Terrace through described The Cloud Terrace motion server unit, and described central control unit also connects external object and obtains system.
Adopt the focus method of the system of this execution mode, as shown in Figure 2, may further comprise the steps:
(1) described central control unit obtains system from said external object and obtains target position information;
(2) described The Cloud Terrace attitude control sub unit is confirmed described The Cloud Terrace angle controlling value according to described target position information;
(3) described The Cloud Terrace attitude control sub unit is sent to described video camera focus control subelement and The Cloud Terrace motion server unit with described The Cloud Terrace angle controlling value;
(4) described The Cloud Terrace motion server unit carries out the control of The Cloud Terrace angle according to described The Cloud Terrace angle controlling value;
(5) described video camera focus control subelement is confirmed focal length value according to described The Cloud Terrace angle controlling value, and this focal length value is sent to described video camera;
(6) described video camera is focused according to described focal length value.
Wherein, described The Cloud Terrace angle controlling value comprises The Cloud Terrace level angle α and The Cloud Terrace vertical angle β.
In a kind of more preferably execution mode; Described The Cloud Terrace motion server unit comprises cradle head control server, The Cloud Terrace move both vertically control circuit and The Cloud Terrace horizontal movement control circuit; Described The Cloud Terrace comprises move both vertically drive motors and horizontal movement drive motors; Described cradle head control server connects described The Cloud Terrace attitude control sub unit; Described cradle head control server also connects the drive motors that moves both vertically of described The Cloud Terrace through the described The Cloud Terrace control circuit that moves both vertically, and connects the horizontal movement drive motors of described The Cloud Terrace through described The Cloud Terrace horizontal movement control circuit.
In the focus method of the system that adopts this execution mode, described step (4) specifically may further comprise the steps:
(41) described The Cloud Terrace motion server unit is sent to described The Cloud Terrace horizontal movement control circuit with described The Cloud Terrace level angle α, and described The Cloud Terrace horizontal movement control circuit is controlled described horizontal movement drive motors according to described level angle α;
(42) described The Cloud Terrace motion server unit is sent to the described The Cloud Terrace control circuit that moves both vertically with described The Cloud Terrace vertical angle β, and described The Cloud Terrace moves both vertically control circuit according to the described drive motors that moves both vertically of described The Cloud Terrace vertical angle β control.
In preferred execution mode; Described video camera focus control subelement comprises the focal length computation processor; Described focal length computation processor comprises The Cloud Terrace level and vertical angle read port; Described focal length computation processor is connected described The Cloud Terrace attitude control sub unit through this The Cloud Terrace level with the vertical angle read port, described focal length computation processor also connects described video camera, and described video camera is a Pan/Tilt/Zoom camera; Described Pan/Tilt/Zoom camera has the optical lens controller, and described focal length computation processor connects described optical lens controller.
In the focus method of the system that adopts this execution mode, described step (5) specifically may further comprise the steps:
(51) described focal length computation processor obtains described The Cloud Terrace vertical angle β through described vertical angle read port from described The Cloud Terrace attitude control sub unit;
(52) described focal length computation processor is confirmed as described object distance L:
L = h cos β ,
Wherein h is that video camera is provided with height;
(53) described focal length computation processor is according to described object distance L, calculate camera lens to the video camera imaging element apart from q:
1 f = 1 L + 1 q ,
Wherein, f is the camera lens focal length;
(54) described focal length computation processor according to following formula with described camera lens to the video camera imaging element convert video camera focus value x to apart from q,
q=kx+a,
Wherein, k and a are constant;
(55) described focal length computation processor is sent to described video camera with focus value x.
In the application of the utility model, the multiple target automatically tracking video taking system of the utility model comprises following part:
1, Pan/Tilt/Zoom camera (Pan/Tilt/Zoom who is furnished with Zoom optic lens; The Cloud Terrace is comprehensive to be moved, camera lens becomes doubly, zoom control video camera), the adjusting that its optical lens group can be carried out optical magnification via screw rod and the step motor drive of inside and the adjusting of focusing focal length.The relative position of internal optics lens group is realized via the read-write of video camera external communication port to video camera internal control register.
2, respectively by a vertical stepper motor driven cradle head structure that is used to load the optical zoom video camera of horizontal step motor drive with another.This structure can be carried out the accessible rotation of 360 degree in the horizontal direction, can between vertical direction and horizontal direction, come back rotation by 90 degree simultaneously.
3, the horizontal movement motor and the motor that moves both vertically are controlled via the motion control servo processor, and drive through horizontal direction circuit for controlling motor and vertical direction circuit for controlling motor respectively.Through the segmentation control circuit, can realize the resolution of horizontal direction and vertical direction 0.01 degree.
4, the lens location of video camera and The Cloud Terrace athletic posture calculate and control via CPU.
5, to the control of moving target and catch by preprocessor and be issued to CPU through communication control module.
6, a level 360 degree are set up and safeguarded to CPU; Vertical 90 degree, resolution is the spatial coordinate system of 0.01 degree, makes the camera lens of video camera can aim at space 36000 * 9000; Promptly 300,000,000 2 thousand 4 hundred ten thousand directions realize accurate location and tracking to any target in the picture.
In practical application; As shown in Figure 3; Pan/Tilt/Zoom camera is erected at apart from ground G point highly for the position O of h; Multiple target tracking and the control of video camera attitude are sent instruction via CPU, and moving to level angle by horizontal motor and motor vertical driving The Cloud Terrace is α, and vertical angle is the position of β.
Because OG is perpendicular to GT, h and β are known, can obtain object distance L through triangle relation easily,
L = h cos β .
In video camera imaging principle simplified model figure as shown in Figure 4, object distance L is the distance of reference object to camera lens A.And q is the distance of outside camera lens A to image-forming component CCD; F is the distance of internal lens B to the CCD focus, i.e. focal length.According to lens principle, L, q and f satisfy relation:
1 f = 1 L + 1 q - - - ( 1 )
The mobile L of making change through camera lens A realizes optical zoom, supposes that L and video camera internal focus value x are linear, that is:
q=kx+a (2)
According to (1) formula and (2) formula, can obtain the relational expression of object distance L and focus value x:
1 L + 1 kx + a = 1 f - - - ( 3 )
For a certain video camera, k, a, f are constant, so object distance L and focus value x are the hyperbolic function relation.In the reality, k, a, f are unknown quantity, and L and x are for measuring.Only need in theory 3 groups of measured values (L, x) can calculate (k, a, f), thus the explicit analytic expression of the formula of obtaining (3).But, obtain optimum (k, a, f) value through least square fitting because the existence of measure error needs to adopt many group measured values.
When actual measurement object distance L and focus value x, utilize video camera to take the reference object under a certain distance L, adjustment video camera focus value x makes that image shows under a certain stationary value the most clear, obtain one group of measured value (L, x).From the close-by examples to those far off change object distance L, above-mentioned steps can obtain N group measured value (L repeatedly 1, x 1), (L 2, x 2) ..., (L N, x N).The position of N group measured value in coordinate is as shown in Figure 5.
Then, N is organized measured value substitution formula (3), can obtain N equation:
1 L 1 + 1 kx 1 + a = 1 f
1 L 2 + 1 kx 2 + a = 1 f - - - ( 4 )
1 L N + 1 kx N + a = 1 f
Getting N is even number, and above-mentioned equation is merged in twos, obtains:
( 1 L 1 + 1 kx 1 + a ) - ( 1 L N + 1 kx N + a ) = 0
( 1 L 2 + 1 kx 2 + a ) - ( 1 L N - 1 + 1 kx N - 1 + a ) = 0 - - - ( 5 )
( 1 L N / 2 + 1 kx N / 2 + a ) - ( 1 L N / 2 + 1 + 1 kx N / 2 + 1 + a ) = 0
To make up the least square function:
y = Σ n = 1 N / 2 ( ( 1 L n + 1 kx n + a ) - ( 1 L N + 1 - n + 1 kx N + 1 - n + a ) ) 2 - - - ( 6 )
At given N group measured value (L 1, x 1), (L 2, x 2) ..., (L N, x N) under, obtain make function y obtain minimum value (k, a) value, be optimal solution (k Opt, a Opt).
With (k Opt, a Opt) in the equation of substitution formula successively (4), obtain N f value: f 1, f 2..., f N, making even all obtains optimal solution:
f opt = 1 N Σ n = 1 N f n - - - ( 7 )
Obtain the explicit analytic expression of object distance L and focus value x thus:
1 L + 1 k opt x + a opt = 1 f opt - - - ( 8 )
Focusing curve after the match and measured value x's is more as shown in Figure 6, in practical application, for certain individually defined thing apart from L 0,, can calculate feasible imaging focusing parameter value x the most clearly according to analytic expression (8) 0Thereby, realize the zoom control algolithm.
Through data fitting, video camera focus value (ordinate) is as shown in Figure 7 with the relation curve of shooting distance (abscissa), and wherein the curve of top is a color mode, and the curve of below is a grayscale mode, and the below lines are the difference of said two patterns.The Control Parameter of camera lens is sent instruction by CPU to video camera; Assembling control data with 16 writes in the inner servo motor control register of video camera; Realizing control, directly focusing on shown in Fig. 3, on the T point apart from video camera L to focal length of camera.
Adopted the multiple target automatically tracking video taking system of the utility model; Its central control unit comprises interconnective The Cloud Terrace attitude control sub unit and video camera focus control subelement; Described video camera focus control subelement connects described video camera, thus described video camera focus control subelement be able to confirm the video camera focus value according to the The Cloud Terrace angle controlling value of described The Cloud Terrace attitude control sub unit, and this video camera focus value is sent to described video camera; With the control focal length; Guarantee that this system can focus on the object of being followed the tracks of all the time when continuing to follow the tracks of, when a little less than having prospect shelter or light, being not enough to let camera automatic focusing, still can accurately focus on by tracked object; The assurance target image is clear; And the multiple target automatically tracking video taking system is simple in structure, with low cost, and the focus method range of application of this system is comparatively extensive.
In this specification, the utility model is described with reference to its certain embodiments.But, still can make various modifications and conversion obviously and not deviate from the spirit and the scope of the utility model.Therefore, specification and accompanying drawing are regarded in an illustrative, rather than a restrictive.

Claims (5)

1. multiple target automatically tracking video taking system; It is characterized in that; Described system comprises video camera, The Cloud Terrace, central control unit and The Cloud Terrace motion server unit; Described video camera is fixed in described The Cloud Terrace, and described central control unit comprises interconnective The Cloud Terrace attitude control sub unit and video camera focus control subelement, and described video camera focus control subelement connects described video camera; Described The Cloud Terrace attitude control sub unit connects described The Cloud Terrace through described The Cloud Terrace motion server unit, and described central control unit also connects external object and obtains system.
2. multiple target automatically tracking video taking system according to claim 1; It is characterized in that; Described The Cloud Terrace motion server unit comprises cradle head control server, The Cloud Terrace move both vertically control circuit and The Cloud Terrace horizontal movement control circuit; Described The Cloud Terrace comprises move both vertically drive motors and horizontal movement drive motors; Described cradle head control server connects described The Cloud Terrace attitude control sub unit, and described cradle head control server also connects the drive motors that moves both vertically of described The Cloud Terrace through the described The Cloud Terrace control circuit that moves both vertically, and connects the horizontal movement drive motors of described The Cloud Terrace through described The Cloud Terrace horizontal movement control circuit.
3. according to each described multiple target automatically tracking video taking system in claim 1 or 2; It is characterized in that; Described video camera focus control subelement comprises the focal length computation processor, and described focal length computation processor connects described The Cloud Terrace attitude control sub unit and video camera respectively.
4. multiple target automatically tracking video taking system according to claim 3; It is characterized in that; Described focal length computation processor comprises The Cloud Terrace level and vertical angle read port, and described focal length computation processor is connected described The Cloud Terrace attitude control sub unit through this The Cloud Terrace level with the vertical angle read port.
5. multiple target automatically tracking video taking system according to claim 3 is characterized in that, described video camera is a Pan/Tilt/Zoom camera, and described Pan/Tilt/Zoom camera has the optical lens controller, and described focal length computation processor connects described optical lens controller.
CN2011201880706U 2011-06-07 2011-06-07 Automatic multi-target tracking picture pick-up system Expired - Lifetime CN202111787U (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102256109A (en) * 2011-06-07 2011-11-23 上海芯启电子科技有限公司 Automatic tracking camera system for multiple targets and focusing method for system
CN102530727A (en) * 2012-02-02 2012-07-04 上海成业科技工程有限公司 Lifting appliance shot automatic tracking and control system
CN102616663A (en) * 2012-04-13 2012-08-01 上海成业科技工程有限公司 Automatic tracking control device and control method for hanger lens
CN104580915A (en) * 2015-01-28 2015-04-29 苏州科达科技股份有限公司 PTZ (pan/tilt/zoom) camera focusing method and system
CN109981968A (en) * 2017-12-27 2019-07-05 浙江宇视科技有限公司 Quick focusing method, device and electronic equipment
CN111629141A (en) * 2019-02-27 2020-09-04 杭州海康威视数字技术股份有限公司 Camera, focus control method and focus control device

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102256109A (en) * 2011-06-07 2011-11-23 上海芯启电子科技有限公司 Automatic tracking camera system for multiple targets and focusing method for system
CN102530727A (en) * 2012-02-02 2012-07-04 上海成业科技工程有限公司 Lifting appliance shot automatic tracking and control system
CN102530727B (en) * 2012-02-02 2014-05-21 上海成业科技工程有限公司 Lifting appliance shot automatic tracking and control system
CN102616663A (en) * 2012-04-13 2012-08-01 上海成业科技工程有限公司 Automatic tracking control device and control method for hanger lens
CN102616663B (en) * 2012-04-13 2014-11-12 上海成业科技工程有限公司 Automatic tracking control device and control method for hanger lens
CN104580915A (en) * 2015-01-28 2015-04-29 苏州科达科技股份有限公司 PTZ (pan/tilt/zoom) camera focusing method and system
CN104580915B (en) * 2015-01-28 2017-09-12 苏州科达科技股份有限公司 A kind of Pan/Tilt/Zoom camera focus method and system
CN109981968A (en) * 2017-12-27 2019-07-05 浙江宇视科技有限公司 Quick focusing method, device and electronic equipment
CN109981968B (en) * 2017-12-27 2020-11-17 浙江宇视科技有限公司 Fast focusing method and device and electronic equipment
CN111629141A (en) * 2019-02-27 2020-09-04 杭州海康威视数字技术股份有限公司 Camera, focus control method and focus control device

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