CN104599291B - Infrared motion target detection method based on structural similarity and significance analysis - Google Patents

Abstract

A kind of infrared motion target detection method based on structural similarity and significance analysis of image processing field, using GBVS to source images significance analysis, obtains salient region；Source images are divided into change intense regions and change shoulder by improved SSIM again, and using the method optimizing gauss hybrid models of different learning rates；Closed area finally is detected using the gauss hybrid models after optimization, the overlapping region of the closed area and salient region is the final moving target of present frame.The problem of present invention solves mixed Gaussian algorithm edge blurry, with preferable adaptivity and Detection results.

Description

Infrared motion target detection method based on structural similarity and significance analysis

Technical field

It is specifically that one kind is based on structural similarity and conspicuousness the present invention relates to a kind of technology of image processing field The infrared motion target detection method of analysis.

Background technology

Moving target detection in real time is succeeding target tracking, and the premise of identification, its effect directly affects the steady of follow-up work Strong property and accuracy.Moving object detection refers to extract the foreground target that there is relative motion with background in the video sequence, Motion analysis for higher levels such as subsequent target followings is prepared, and is an important research direction of computer vision field, It is used widely in fields such as intelligent monitor system, man-machine interactive systems.

Moving object detection detects moving target by analyzing the image sequence that imaging sensor is photographed, Good basis is laid for the behavior understanding of higher.Moving object detection is the emphasis and difficult point of video sequence analysis.In motion In the studying for a long period of time of target detection, it has been proposed that including many classic algorithms such as calculus of finite differences, Background difference, optical flow method.Wherein：With Background subtraction is most widely used, and moving target is detected by obtaining background model and comparing frame difference.The essence of background model Degree determines the validity of background subtraction, if background modeling process occurrence scene changes, and situations such as imaging device trembles can be serious The contrast and signal to noise ratio of image are reduced, the identification to infrared target is influenceed.

Background modeling method based on gauss hybrid models, by continuous Gaussian component modeling background information, is recycled Background information Difference test goes out moving target, can preferably solve multi-modal background problems, is especially suitable for outdoor light and weather The small and fireballing moving object detection of change.But when gauss hybrid models initialization, new model set up and learning rate not Timing can all produce diplopia phenomenon.

By the retrieval discovery to prior art, Chinese patent literature CN103810703A discloses (bulletin) day 2014.05.21, a kind of tunnel video moving object detection method based on image procossing is disclosed, this method includes following step Suddenly：Set up initial back-ground model；Set up dynamic in real time and update background model；Construct partial structurtes similarity measure function；Construction Local gray level statistical measurement function；Motion is extracted according to partial structurtes similarity measure function and local gray-scale statistical measure function Target area.But the technology merely determines whether moving target, it is discrete to extract moving target by algorithm, not comprising original Beginning clarification of objective information, it is impossible to provide support for the follow-up further processing to moving target.

The content of the invention

The present invention can not detect the change of background in time for traditional Gauss mixed model, by its detection obtain it is red Outer target includes false profile, is difficult the deficiency accurately identified, proposes a kind of red based on structural similarity and significance analysis Outer moving target detecting method and system, the spatial information for combining sign target area discrete pixels point by watershed algorithm are obtained To enclosed region, then pass through point based on PCNN (Pulse Coupled Neural Network, Pulse Coupled Neural Network) Cut algorithm eliminate diplopia, finally detect complete infrared motion target, so as to preferably extract foreground target, with compared with Good effect and stronger robustness.

The present invention is achieved by the following technical solutions：

It is sharp first the present invention relates to a kind of infrared motion target detection method based on structural similarity and significance analysis It is notable to source images with GBVS (Graph-Based Visual Saliency, the saliency parser based on graph theory) Property analysis, obtain salient region；By source images, by improved SSIM, (Structural similarity, structure is similar again Degree algorithm) change intense regions and change shoulder are divided into, and using the method optimizing Gaussian Mixture mould of different learning rates Type；Closed area finally is detected using the gauss hybrid models after optimization, the overlay region of the closed area and salient region Domain is the final moving target of present frame.

Described salient region, carries out significance analysis to infrared sequence image using GBVS and obtains.

Described change intense regions and change shoulder, are obtained in the following manner：

1) structure for asking for the local block of adjacent two frames figure in infrared sequence image using improved SSIM algorithms is similar Degree；

2) the structural similarity statistical value of local block is calculated using sliding window mode, and generation is based on this basis The statistical chart of infrared sequence image；

3) using image local situation of change in CDF mode counting statistics figures, smooth rear distribution curve maximum curvature is found The corresponding cumulative number Au of point_max, Au will be more than in statistical chart_maxPoint constitute region divide into change intense regions, remaining For change shoulder.

Described optimization gauss mixed model refers to：For change intense regions using larger learning rate, change flat zone Domain uses smaller learning rate.

The present invention relates to a kind of system for realizing the above method, including：Salient region extraction module, structural similarity point Generic module, Gauss model update module and closed area detection module, wherein：Structural similarity sort module is divided the image into Background area and target area, Gauss model update module are connected with structural similarity sort module, and different study are respectively adopted Rate updates background area and target area, and transmitting discrete moving target information, closed area detection module updates with Gauss model Model, which is connected, transmits closure target information, and salient region extraction module is connected to transmit with closed area detection module accurately to be transported Moving-target information.

Technique effect

Compared with prior art, the present invention, to solve the replacement problem of background model, utilizes structure in terms of model learning Similarity algorithm by infrared image background be divided into graded substantially with slow region, different learning rates are set respectively and are updated Gauss hybrid models, it is ensured that the Stability and veracity of model, with the position in quick obtaining infrared motion target region；In target Context of detection, the enclosed region of target is obtained using the watershed algorithm based on spatial information, recycles the vision based on figure Conspicuousness (Graph-Based Visual Salience, GBVS) algorithm removes diplopia, finally gives complete moving target. Test result indicates that, the problem of this method solves mixed Gaussian algorithm edge blurry well, with preferable adaptivity And Detection results.

Brief description of the drawings

Fig. 1 is cumulative distribution function figure；

Fig. 2 is schematic flow sheet of the present invention；

Fig. 3 is the effect diagram of embodiment 1；

In figure：(a), (b) is respectively the frame of infrared sequence image the 18th, 19, and (c), (d) is respectively constant learning rate and becomes The target area of habit rate detection, (e)-(h) is respectively by frame difference method, background subtraction and the present invention between watershed algorithm, neighbour The testing result that method is obtained.

Fig. 4 is to split obtained accurate target region by hand by Fig. 3 (b).

Embodiment

Embodiments of the invention are elaborated below, the present embodiment is carried out lower premised on technical solution of the present invention Implement, give detailed embodiment and specific operating process, but protection scope of the present invention is not limited to following implementations Example.

Embodiment 1

As shown in Fig. 2 the present embodiment is A to infrared sequence image_t(t=1 ... n) carries out following handle：

The first step：Using GBVS algorithms to infrared sequence image A_tSignificance analysis is carried out, salient region B is obtained_t, tool Body step includes：

1.1) defined nucleotide sequence image A_tTwo pixel m of characteristic pattern₁(i₁,j₁) and m₂(i₂,j₂) otherness：

Wherein：M_f() is characterized the pixel in figure.

1.2) obtain constructing each summit in the figure connected entirely, figure after the otherness of any two points in image and represent one Pixel, each edge represents the weight between two pixels, i.e., Wherein：σ is scale factor, m₁(i₁,j₁) and m₂(i₂,j₂) it is two pixels；

1.3) salient region is obtained after all weights are normalized.

Second step：The structure of the local block of adjacent two frames figure in infrared sequence image is asked for using improved SSIM algorithms Similarity, specific steps include：

2.1) entire image is pressed from top to bottom, if being sequentially divided into from left to right by the sliding window of 7 × 7 pixel sizes Dry weight folds sub-block, and then carrying out mirror-extended to image when sliding window exceeds image range obtains 7 × 7 sub-blocks, if the chi of image It is very little be m × n when, then the sub-block number obtained be m × n；

2.2) the sub-block Block (x, y) of same position structural similarity is in image F and image L：

Wherein：(x, y) represents sub-block center pixel, u_F、u_L、σ_F、σ_LImage F and image L sub-block Block is represented respectively The average and variance of (x, y)；C₁、C₂Respectively tend to 0 normal amount.

3rd step：The structural similarity statistical value A of local block is calculated using sliding window mode_t' (x, y), and herein On the basis of generate the statistical chart based on infrared sequence image：

D_t(x, y)=A_t'(x,y)-A_t(x, y),

Wherein：Ones (x, y) is all 1's matrix of centered on (x, y) 7 × 7 sizes, when the structural similarity of local block During higher than 0.9, it is believed that its intensity of variation is little, A_t(x, y) is constant, when the structural similarity of sub-block is less than 0.9, with (x, y) Centered on 7 × 7 statistical value of matrix add 1.

Described statistical chart D_tThe gray value bigger region representation regional change degree is more violent in (x, y).

4th step：Utilize CDF (s) (Cumulative Distribution Function, cumulative distribution function) mode Counting statistics figure D_tImage local situation of change in (x, y), the point for finding smooth rear distribution curve maximum curvature is corresponding cumulative Number Au_max, by statistical chart D_tIt is more than Au in (x, y)_maxThe region that constitutes of point divide into change intense regions A_tr, remaining is change Shoulder A_tg。

Described cumulative distribution function is the function of the localized variation degree of image, that is, seeks image D_tPixel value s in (x, y) The probability P (s) of appearance, cumulative distribution function CDF (s)=P (S≤s) obtains smoothed curve function by 10 difference fittings, such as Shown in Fig. 1；Obtain D corresponding to the maximum point of the curvature of curve_tThe value Au of (x, y)_max, by D_tPixel value is more than Au in (x, y)_max Point composition region be change intense regions.

5th step：By infrared sequence image A_t(t=1 ... n) updates Gauss by way of different zones correspondence learning rate Mixed model, i.e. gauss hybrid models are carried out more in learning process according to the image information of a new frame to weight, average, variance Newly, and change intense regions are updated with 10 times of learning rates, change shoulder keeps original learning rate α, specific steps Including：

5.1) pixel for representing moving target is calculated：

Wherein：P(S_t) it is S_tThe distribution function of (x, y), S_t(x, y) represents the pixel value of t width images, ω_i,t(x, y) table Show that t width image slices vegetarian refreshments belongs to the weights of i-th of Gaussian Profile, u_i,tFor Gauss model average, Σ_i,tFor the association of Gauss model Variance, σ_i,tFor standard deviation, I is unit matrix, and n is X_tDimension, η () be Gauss model probability density function.

5.2) following update is carried out to Gauss model：

Wherein：α is learning rate, represents that moving target incorporates the speed of background, by pixel value S_t(x, y) and K Gaussian mode Type is matched, and works as S_t(x, y) and i-th of Gauss model difference are less than 2.5 times of standard deviation sigmas_i,tWhen think to match with "current" model, That is M_tMatching is represented when=1, the M when mismatching_t=0, and accordingly reduce weight and average and variance are not updated.

5.3) due to S_tThe Gauss model that (x, y) is matched the most has maximum weights and minimum standard deviation, by K Gauss model is according to ω_i,t/σ_i,tThe arrangement of ratio descending, the Gauss model at the top of sequence most possibly describes the stable back of the body Scape, and the Gauss model in sequence bottom describes moving target, therefore：

Using preceding Num in K Gauss model as background model, τ represents background Gauss model institute in probability distribution The number of the minimum scale accounted for, i.e. background model

Work as S_t(x, y) is all mismatched with K Gauss model, then is x last Gauss model is come using average_t, standard Poor σ_i,tWith weights ω_i,tThe Gauss model for being respectively set to initial value is replaced；After the completion of updating every time, to weights ω_i,tReturned One change is handled.

6th step：Using the gray value of each pixel as level height value, P (S are calculated_t) spatial frequency SF_tObtain discrete The edge of target, then closed area E is obtained using watershed algorithm connection edge_t。

Described spatial frequency refers to：The index of grey scale change severe degree in phenogram picture, i.e., gray scale is in plane space On gradient.

Described watershed algorithm is realized by following iterative manner：

Wherein：X (h) be when level value is h each Gray value is less than the set of h point in the joint of regional ensemble, i.e. image, and I (p) represents the gray value of image, h_minAnd h_maxTable Diagram is as minimum and highest gray value；T(h_min) corresponding connected domain when gray value is minimum is represented, MIN (h+1) is gray value in h The joint of all Minimum Areas, Z when+1_T(h+1)(X (h)) represents geodetic influence areas of the region X (h) in connected domain T (h+1).

Described closed areaWshed_maxFor area in image most Big enclosed region, Wshed (f)=D-X (h_max) i.e. in image D_tX (h in (x, y)_max) supplementary set.

Described geodetic influence area refers to：WhenIt is to be divided into the k region B being connected_i, i=1 ..., k, Then in A, subset B_iGeodetic influence area be defined as：P ∈ A |=d_A(p,B_i) ＜ d_A(p,B\B_i), geodetic influence area claims For reception basin, and the border of reception basin then forms watershed.

7th step：By the gauss hybrid models after being updated in the 5th step to the closed area E in the 6th step_tDetected, Gained region and the salient region B obtained in the first step_tLap region be present frame final moving target.

The target area that this method is obtained than the result complete and accurate that other method is obtained, as shown in figure 3, by with Fig. 4 Shown in shown standard picture is compared as follows, wherein MI represents coefficient correlation, and QAB/F represents edge gradient information, is worth bigger table Show obtained moving target and former target closer to.

	MI	QAB/F
			This method	0.2577	0.5922
Background subtraction	0.2459	0.4003
			Calculus of finite differences between neighbour	0.0854	0.1374

Claims (7)

1. a kind of infrared motion target detection method based on structural similarity and significance analysis, it is characterised in that sharp first With GBVS to source images significance analysis, salient region is obtained；Source images are divided into change by improved SSIM again acute Strong region and change shoulder, and using the method optimizing gauss hybrid models of different learning rates；Finally utilize after optimization Gauss hybrid models detect closed area, and the overlapping region of the closed area and salient region is the final fortune of present frame Moving-target；

Described change intense regions and change shoulder, are obtained in the following manner：

1) structural similarity of the local block of adjacent two frames figure in infrared sequence image is asked for using improved SSIM algorithms；

2) the structural similarity statistical value A of local block is calculated using sliding window mode_t' (x, y), and generate on this basis Statistical chart D based on infrared sequence image_t(x,y)；

3) CDF mode counting statistics figures D is utilized_tImage local situation of change in (x, y), finds smooth rear distribution curve curvature most The corresponding cumulative number Au of big point_max, by statistical chart D_tIt is more than Au in (x, y)_maxTo divide into change violent in the point region that constitutes Region A_tr, remaining is change shoulder A_tg；

The structural similarity of described local block, is obtained in the following manner：

I) entire image is pressed from top to bottom by the sliding window of 7 × 7 pixel sizes, be sequentially divided into from left to right some overlapping Sub-block, sliding window exceed image range when then to image carry out mirror-extended obtain 7 × 7 sub-blocks, if the size of image be m × During n, then the sub-block number obtained is m × n；

Ii) the sub-block Block (x, y) of same position structural similarity is in image F and image L：

Wherein：(x, y) represents sub-block center pixel, u_F, u_L, σ_F, σ_LImage F and image L sub-block Block (x, y) average and variance is represented respectively；C₁, C₂Respectively tend to 0 it is normal Amount；

The described statistical chart based on infrared sequence image, the structure phase of local block is calculated using sliding window mode Like degree statistical value A_t' (x, y), and D is generated on this basis_t(x, y)=A_t'(x,y)-A_t(x, y),Wherein：Ones (x, y) is is with (x, y) 1 matrix of the size of center 7 × 7, when the structural similarity of local block is higher than 0.9, it is believed that its intensity of variation is little, A_t(x, Y) constant, when the structural similarity of sub-block is less than 0.9, the statistical value of centered on (x, y) 7 × 7 matrix adds 1.

2. according to the method described in claim 1, it is characterized in that, described salient region, using GBVS algorithms to infrared sequence Row image A_tCarry out significance analysis to obtain, specific steps include：

1.1) defined nucleotide sequence image A_tTwo pixel m of characteristic pattern₁(i₁,j₁) and m₂(i₂,j₂) otherness：Wherein：M_f() is characterized the pixel in figure；

1.2) obtain constructing each summit in the figure connected entirely, figure after the otherness of any two points in image and represent a picture Element, each edge represents the weight between two pixels, i.e., Wherein：σ is scale factor, m₁(i₁,j₁) and m₂(i₂,j₂) it is two pixels；

1.3) salient region is obtained after all weights are normalized.

3. according to the method described in claim 1, it is characterized in that, described image local situation of change, by calculating iterated integral The function of the localized variation degree of cloth function, i.e. image is obtained：Counting statistics figure D_tThe probability P that pixel value occurs in (x, y) (s), cumulative distribution function CDF (s)=P (S≤s) obtains smoothed curve function by 10 difference fittings, and the curvature of curve is most D corresponding to big point_tThe value Au of (x, y)_max, by D_tPixel value is more than Au in (x, y)_maxThe region of point composition be that change is acute Strong region.

4. method according to claim 2, it is characterized in that, described optimization gauss mixed model refers to：By infrared sequence Image updates gauss hybrid models, i.e. the gauss hybrid models root in learning process by way of different zones correspondence learning rate Weight, average, variance are updated according to the image information of a new frame, and change intense regions are carried out more with 10 times of learning rates Newly, change shoulder keeps original learning rate α.

5. the method according to claim 2 or 4, it is characterized in that, described optimization gauss mixed model is specifically included：

I) pixel for representing moving target is calculated：Wherein：P (S_t) it is S_tThe distribution function of (x, y), S_t(x, y) represents the pixel value of t width images, ω_i,t(x, y) represents t width image slices Vegetarian refreshments belongs to the weights of i-th of Gaussian Profile, u_i,tFor Gauss model average, ∑_i,tFor the covariance of Gauss model, σ_i,tFor mark Accurate poor, I is unit matrix, and n is X_tDimension, η () be Gauss model probability density function；

Ii following update) is carried out to Gauss model：Wherein：α is learning rate, table Show that moving target incorporates the speed of background, by pixel value S_t(x, y) is matched with K Gauss model, and works as S_t(x, y) is high with i-th The difference of this model is less than 2.5 times of standard deviation sigmas_i,tWhen think to match with "current" model, i.e. M_tMatching is represented when=1, when mismatching M_t=0, and accordingly reduce weight and average and variance are not updated；

Iii) due to S_tThe Gauss model that (x, y) is matched the most has maximum weights and minimum standard deviation, by K Gauss Model is according to ω_i,t/σ_i,tThe arrangement of ratio descending, the Gauss model at the top of sequence most possibly describes Steady Background Light, and Gauss model in sequence bottom describes moving target, and using preceding Num in K Gauss model as background model, τ is represented The number of background Gauss model minimum scale, i.e. background model shared in probability distribution

Iv S) is worked as_t(x, y) is all mismatched with K Gauss model, then is x last Gauss model is come using average_t, standard Poor σ_i,tWith weights ω_i,tThe Gauss model for being respectively set to initial value is replaced；After the completion of updating every time, to weights ω_i,tReturned One change is handled；

Iv) using the gray value of each pixel as level height value, P (S are calculated_t) spatial frequency SF_tObtain the side of dispersive target Edge, then closed area E is obtained using watershed algorithm connection edge_t。

6. method according to claim 5, it is characterized in that, described closed areaWshed_maxFor the enclosed region that area in image is maximum, i.e. watershed Region, Wshed (f)=D_t(x,y)-X(h_max), wherein：Image D_tIn (x, y), X (h_max) it is that level value is h_maxWhen regional Gray value is less than h in union of sets, i.e. image_maxPoint set；

Described watershed is formed by the border of geodetic influence area, is iterated to calculate and is obtained especially by watershed algorithm：

Wherein：X (h) is regional when level value is h Gray value is less than the set of h point in union of sets, i.e. image, and I (p) represents the gray value of image, h_minAnd h_maxRepresent figure As minimum and highest gray value；T(h_min) corresponding connected domain when gray value is minimum is represented, MIN (h+1) is gray value in h+1 The joint of all Minimum Areas, Z_T(h+1)(X (h)) represents geodetic influence areas of the region X (h) in connected domain T (h+1).

7. a kind of system for realizing any of the above-described claim methods described, it is characterised in that including：Salient region extracts mould Block, structural similarity sort module, Gauss model update module and closed area detection module, wherein：Structural similarity point Generic module divides the image into background area and target area, and Gauss model update module is connected with structural similarity sort module, Different learning rates are respectively adopted and update background area and target area, transmitting discrete moving target information, closed area detection mould Block is connected with Gauss model more new model transmits closure target information, salient region extraction module and closed area detection module It is connected to transmit accurately moving target information.