CN106683048A - Image super-resolution method and image super-resolution equipment - Google Patents

Abstract

The invention discloses a super-resolution image generation method. The super-resolution image generation method includes inputting a real image sample into a generation network so as to output a super-resolution image sample after the generation network and a distinguishing network are preset, acquiring distinguishing probabilities outputted by the distinguishing network after the real image sample and the super-resolution image sample are outputted, determining generation network loss functions and distinguishing network loss functions according to the real image sample, the super-resolution image sample and the distinguishing probabilities, and adjusting configuration parameters of the generation network and the distinguishing network according to the generation network loss functions and the distinguishing network loss functions; receiving a low-resolution image to be processed after adjustment is completed, generating a super-resolution image of the low-resolution image according to the generation network, and subjecting the super-resolution image to visualized processing. By the super-resolution image generation method, image super-resolution effect and realness of the super-resolution image are both improved remarkably.

Description

A kind of image super-resolution method and equipment

Technical field

The present invention relates to communication technical field, more particularly to a kind of image super-resolution method.The present invention is also related to A kind of image super-resolution equipment.

Background technology

Image super-resolution rebuilding technology is to produce list using one group of low quality, low-resolution image (or motion sequence) Panel height quality, high-definition picture.Image super-resolution rebuilding application and its broadness, in military affairs, medical science, public safety, The aspects such as computer vision all have important application prospect.In computer vision field, image super-resolution rebuilding technology There is a possibility that image is realized from detection level to the conversion of identification level, or further realize to carefully distinguishing horizontal conversion.

Based on the image super-resolution rebuilding technology of the identification ability and accuracy of identification that can improve image, prior art is carried The single-frame imagess super-resolution that high-definition picture is generated using single frames low resolution, undersampled image is gone out.Single-frame imagess surpass Resolution reconstruction technology can realize the absorbed analysis of object, such that it is able to obtain area-of-interest more high spatial resolution Image, without the configuration for directly adopting the huge high spatial resolution images of data volume.

With the continuous development in artificial neural network field, current technical staff can be based on depth convolutional neural networks reality Existing single-frame imagess super-resolution so that single-frame imagess super-resolution technique has huge progress.Convolutional neural networks are artificial One kind of neutral net, it has also become current speech analyzes the study hotspot with field of image recognition.The shared network knot of its weights Structure is allowed to be more closely similar to biological neural network, reduces the complexity of network model, reduces the quantity of weights.The advantage is in net What is showed when the input of network is multidimensional image becomes apparent from, allow image directly as the input of network, it is to avoid traditional knowledge Complicated feature extraction and data reconstruction processes in other algorithm.Convolutional network is to recognize one of two-dimensional shapes and particular design Multilayer perceptron, this network structure has height invariance to translation, proportional zoom, inclination or the deformation of his form common.

At present, in the single-frame imagess super-resolution based on depth convolutional neural networks, the method is by low point of input Resolution image carries out a series of convolution or deconvolution operation, is output as the high-resolution image of a frame.By calculating output High-definition picture and the mean square deviation (MSE) of true high-definition picture, believe as the supervision that depth convolutional neural networks are trained Number.

However, inventor has found during the application is realized, when prior art is carried out at big decimation factor to picture During reason (such as 4x is up-sampled, i.e. the wide height of image is enlarged into respectively original 4 times), the recovery of grain details yet suffers from problem, So as to details is not clear enough.Even using the single-frame imagess super-resolution of depth convolutional neural networks, also can be in decimation factor Result is generally too smoothed when larger, lack detail of the high frequency, lead to not meet demand.

The content of the invention

The invention provides a kind of super-resolution image generation method, believes to the details for preferably retaining pending image Breath, and solve in prior art to export the unsharp problem of high-definition picture grain details when decimation factor is larger.The party Method pre-sets generation network and differentiates that the type of network, the generation network and the differentiation network is depth nerve Network, the method also includes：

Super-resolution image sample after true picture sample is input into into the generation network to export super-resolution processing；

The acquisition differentiation network is respectively after the true picture sample and the super-resolution image sample is input into The differentiation probability of output, the differentiation probability is the probability of the input picture for true picture of the differentiation network；

Network losses are generated according to the true picture sample, super-resolution image sample and the differentiation determine the probability Function and differentiation network losses function, and according to the generation network losses function and the differentiation network losses function pair The configuration parameter of the generation network and the differentiation network is adjusted；

After the adjustment for completing the configuration parameter, pending low-resolution image is received, according to the generation net Network generates the super-resolution image of the low-resolution image, and carries out visualization processing to the super-resolution image；

Wherein, when the loss function of the generation network is less, the super-resolution image exported with the generation network Validity it is higher；

When the loss function of the differentiation network is less, the accuracy of the differentiation probability for differentiating network output is higher.

Preferably, the loss function for generating network is according to antagonism loss function, rule constraint loss function and picture The mean square deviation loss function of plain level is generated, wherein：

The antagonism loss function is according to sentencing that the differentiation network is exported after the super-resolution image sample is input into Other probability is generated；

The rule constraint function determines according to the Space Consistency of the super-resolution image sample；

The mean square deviation loss function of the Pixel-level is according to the super-resolution image sample and the true picture sample This determination.

Preferably, the super-resolution after by the true picture sample input generation network to export super-resolution processing After image pattern, also include：

Respectively described true picture sample and the super-resolution image sample arrange label；

Wherein, the label of the true picture sample puts 1, and the label of the super-resolution image sample sets to 0.

Preferably, label and each described image sample of the loss function for differentiating network according to all image patterns Generate in the differentiation probability through the differentiation network output.

Preferably, the true picture sample is zoomed in and out at process and normalization before the generation network is input into Reason；The low-resolution image is normalized before the generation network is input into.

Accordingly, disclosed herein as well is a kind of super-resolution image generates equipment, including：

Preset module, pre-sets generation network and differentiates network, the generation network and the differentiation network Type is deep neural network；

Input module, the super-resolution after true picture sample is input into into the generation network to export super-resolution processing Image pattern；

Acquisition module, obtains the differentiation network and is input into the true picture sample and the super-resolution figure respectively The differentiation probability exported after decent, the differentiation probability is the probability of the input picture for true picture of the differentiation network；

Determining module, gives birth to according to the true picture sample, super-resolution image sample and the differentiation determine the probability Into network losses function and differentiation network losses function, and according to the generation network losses function and the differentiation network Loss function is adjusted to the configuration parameter of the generation network and the differentiation network；

Generation module, after the adjustment for completing the configuration parameter, receives pending low-resolution image, according to institute State and generate the super-resolution image of the network generation low-resolution image, and the super-resolution image is carried out at visualization Reason；

Wherein, when the loss function of the generation network is less, the super-resolution image exported with the generation network Validity it is higher；

When the loss function of the differentiation network is less, the accuracy of the differentiation probability for differentiating network output is higher.

Preferably, the loss function for generating network is according to antagonism loss function, rule constraint loss function and picture The mean square deviation loss function of plain level is generated, wherein：

The antagonism loss function is according to sentencing that the differentiation network is exported after the super-resolution image sample is input into Other probability is generated；

The rule constraint function determines according to the Space Consistency of the super-resolution image sample；

The mean square deviation loss function of the Pixel-level is according to the super-resolution image sample and the true picture sample This determination.

Preferably, also include：

Label model, respectively described true picture sample and the super-resolution image sample arrange label；

Wherein, the label of the true picture sample puts 1, and the label of the super-resolution image sample sets to 0.

Preferably, label and each described image sample of the loss function for differentiating network according to all image patterns Generate in the differentiation probability through the differentiation network output.

Preferably, the true picture sample is zoomed in and out at process and normalization before the generation network is input into Reason；The low-resolution image is normalized before the generation network is input into.

As can be seen here, by the technical scheme using the application, after pre-setting generation network and differentiating network, will The super-resolution image sample that true picture sample is input into after generating network to export super-resolution processing, and obtain differentiation network The differentiation probability for exporting after input true picture sample and super-resolution image sample respectively, finally according to true picture sample Originally, super-resolution image sample and differentiation determine the probability generate network losses function and differentiate network losses function, and root Adjusted according to the configuration parameter for generating network losses function and differentiation network losses function pair generation network and differentiation network It is whole.So when pending low-resolution image is received after the completion of adjustment, low resolution can be generated according to network is generated The super-resolution image of rate image, and visualization processing is carried out to super-resolution image.So as to significantly improve Image Super-resolution The verity of rate effect and super resolution image.

Description of the drawings

Fig. 1 is a kind of structural representation of the generation network disclosed in the application specific embodiment；

Fig. 2 is a kind of structural representation of the differentiation network disclosed in the application specific embodiment；

Fig. 3 is a kind of schematic flow sheet of super resolution image generation method that the application is proposed；

The training process workflow schematic diagram that Fig. 4 is proposed by the application specific embodiment；

Fig. 5 is super-resolution image calculation process schematic diagram in the application this specific embodiment；

Fig. 6 is the structural representation that a kind of super resolution image that the application is proposed generates equipment.

Specific embodiment

As stated in the Background Art, the single-frame imagess super-resolution based on depth convolutional neural networks so that single-frame imagess surpass Resolution technique has huge progress.But for the up-sampling factor than it is larger when (such as 4 times up-sampling) grain details Recovery yet suffers from problem, so as to cause details not clear enough.

In view of this, present applicant proposes a kind of super resolution image generation method, the method is for single-frame imagess super-resolution Rate proposes a kind of antagonism network frame, and including two deep neural networks, one is to generate network, and one is to differentiate net Network, two networks are trained and vied each other simultaneously.The purpose for generating network is to generate high-definition picture from low-resolution image, and And the high-definition picture for generating is difficult to be distinguished with true picture；The purpose for differentiating network is to discriminate between true picture and super-resolution The image of generation.By resisting network training, generation network output real high-definition picture as far as possible is made.Just because in this, Before elaborating the detailed step of technical scheme, the application pre-sets generation network and differentiates network, needs Illustrate, the type of the generation network and differentiation network is deep neural network, below for both network integrations Specific embodiment is illustrated：

As shown in figure 1, in the application specific embodiment generate network structural representation, in the generation network structure Every layer of concrete meaning it is as follows：

1st layer of InputLR represents input low-resolution image；

2nd and the 3rd layer represents that (Rectified linear unit, correct linear unit, are for a convolutional layer and ReLU One kind of deep learning activation primitive) activation primitive layer, wherein the step-length of convolution operation be 1, convolution kernel size be 3*3, convolution Nuclear volume is 64；

4th to the 9th layer is a residual error network element function block, has used two groups of convolutional layers to closely follow batch standardization layer, with ReLU, as activation primitive, is finally that Element-Level is added layer, and the wherein step-length of convolution operation is 1, and convolution kernel size is 3*3, is rolled up Product nuclear volume is 64；

10th to the 33rd layer is 4 residual error network element function blocks, and each residual error network element function block is ibid；

34th to the 37th layer is two groups of warp product units, for picture up-sampling.The step-length of deconvolution layer operation is 0.5, Convolution kernel size is 3*3, and convolution nuclear volume is 64；The zoom factor that this example is adopted is for 4, so employing two groups of deconvolution lists Unit；Zoom factor is such as crossed for 2, then one group of warp product unit can be adopted；

38th layer is a convolutional layer, and convolution operation step-length is 1, and convolution kernel size is 3*3, and convolution nuclear volume is 3, purpose It is the RGB data for generating 3 passages.

What last layer of the generation network was exported is super-resolution image.

As shown in Fig. 2 in the application specific embodiment differentiation network structural representation, the differentiation network structure In every layer of concrete meaning it is as follows：

1st layer of Input HR/SR represents the high-resolution true picture or super-resolution image of input；True picture mark 1 is designated as, super-resolution image is labeled as 0；

Layers 2 and 3 represents a convolutional layer and an activation primitive layer, convolution；Wherein convolutional layer step-length is 1, volume Product core size is 3*3, and convolution nuclear volume is 64；

4th layer to the 6th layer represents convolutional layer, an activation primitive layer and a batch rule layer；Wherein convolution Layer step-length is 2, and convolution kernel size is 3*3, and convolution nuclear volume is 64；

7th layer to the 9th layer represents convolutional layer, an activation primitive layer and a batch rule layer；Wherein convolution Layer step-length is 1, and convolution kernel size is 3*3, and convolution nuclear volume is 128；

10th layer to the 12nd layer represents convolutional layer, an activation primitive layer and a batch rule layer；Wherein roll up Lamination step-length is 2, and convolution kernel size is 3*3, and convolution nuclear volume is 128；

It is that convolution nuclear volume is 256 that 13rd layer is distinguished to the 18th layer similar to the 7th to the 12nd layer, uniquely；

It is that convolution nuclear volume is 512 that 19th layer is distinguished to the 24th layer similar to the 7th to the 12nd layer, uniquely；

25th layer and the 26th layer is a full articulamentum and a ReLU activation primitive layer；

27th layer and the 28th layer is a full articulamentum and Sigmoid (by the use of sigmoid functions as activation letter Number, is one kind of deep learning activation primitive) activation primitive layer, wherein full articulamentum node number is 1；

Last layer of the differentiation network exports a probit, represents probability of the input picture for true picture.

The generation network to the application is distributed above in association with specific network structure and function and differentiate that network enters Go explanation, but it should be noted that above structure is only the one kind proposed in the application specific embodiment is preferable to carry out Example scheme, is super resolution image deep neural network is based on by the way that input picture is carried out into superresolution processing, and for defeated The image for entering is carried out on the basis of the judgement of true picture/super resolution image, and other remodeling that those skilled in the art are done are equal Belong to the protection domain of the application.

Based on the generation network and differentiation network that are pre-created, the super resolution image generation method that the application is proposed Schematic flow sheet is as shown in figure 3, comprise the following steps：

S301, the super-resolution image after true picture sample is input into into the generation network to export super-resolution processing Sample.

The defeated of network is generated because the application is intended to be improved by the deep neural network to different functions to optimize Go out effect, therefore the application is broadly divided into two big flow elements, Part I generates low-resolution image of the network according to input Output high-definition picture；Part II differentiates that network carries out verity judgement to input picture.Generate the output image of network As the input picture for differentiating network, differentiate the output of network as the feedback signal for generating network.

Based on described above, the step generates network using existing picture as the input of true picture sample first, defeated Enter and generate before network, need in the usual course true picture sample to be carried out into some pretreatment works, such as scaling is processed, normalizing Change process etc..Specific zooming parameter and normalized parameter can be configured by technical staff according to practical situation, these tune The whole protection domain for belonging to the application.

Because the application needs the verification accuracy rate for differentiating network to test, and true picture sample is raw with follow-up Into super resolution image there is certain similarity, it is respectively described true therefore in a preferred embodiment of the application Image pattern and the super-resolution image sample arrange label to make a distinction, and the label of wherein true picture sample puts 1, The label of super-resolution image sample sets to 0.

S302, obtains the differentiation network and is input into the true picture sample and the super-resolution image sample respectively The differentiation probability exported after this, the differentiation probability is the probability of the input picture for true picture of the differentiation network.

Based in S301 generate super-resolution image sample and original true picture sample, the application by it simultaneously Input differentiates network, and the verification accuracy for differentiating network is detected with this.Either it is input into true picture sample or super-resolution Rate image pattern, differentiates that network can all export a differentiation probability, and the probability is to describe input picture in the inspection for differentiating network It is the probability of true picture after testing.In specific application scenarios, the probability can be relative with the label value of each sample image Should, such as probit represents that the probability of true picture is higher closer to 1；Probit represents super-resolution image closer to 0 Probability is higher.

S303, generates network and damages according to true picture sample, super-resolution image sample and the differentiation determine the probability Lose function and differentiate network losses function, and according to generation network losses function and differentiate that network losses function pair generates net The configuration parameter of network and differentiation network is adjusted.

Because the application is based on single-frame imagess super-resolution training method come phase in the training stage using two depth networks Mutually antagonism, therefore based on the differentiation probability in the super-resolution image and S302 in S301, the application will be respectively directed to generate Network and differentiation network determine its respective loss function, for network is generated, when the loss letter of the generation network Number is less, and the validity of the super-resolution image exported with the generation network is higher, and for network is differentiated, works as institute State and differentiate that the loss function of network is less, the accuracy of the differentiation probability for differentiating network output is higher.

As it was previously stated, generate network and differentiate that the type of network is deep neural network, its respectively by convolution unit and Multiple functions are constituted as functional module, therefore in the concrete application scene of the application, based on generation network losses function pair The weighted value for generating each network node in network is adjusted, and each in network losses function pair differentiation network based on differentiating The weighted value of individual network node is adjusted.

It should be noted that the validity of the super-resolution image mentioned in above content is super-resolution image sample For true picture sample, and accuracy is then to differentiate probability relative to the true picture/super-resolution under truth For rate image, the specific form of expression can in the light of actual conditions be set by technical staff.Additionally, for generating net The parameter configuration of network/differentiation network can be adjusted by technical staff according to loss function, and these belong to the guarantor of the application Shield scope.

In a preferred embodiment of the application, generate network loss function according to antagonism loss function, rule about The mean square deviation loss function of beam loss function and Pixel-level is generated, and specifically, the generating mode of each function is as follows：

(1) the antagonism loss function is exported according to the differentiation network after the super-resolution image sample is input into Differentiate that probability is generated.

In specific application scenarios, the determination mode for resisting loss function is as follows：

Wherein, D (I^SR) representing that super-resolution output image is input to the output differentiated after network, this value is bigger, represents Super-resolution output image is closer to true picture, and antagonism loss function value is less.

(2) the rule constraint function determines according to the Space Consistency of the super-resolution image sample.

In the concrete application scene of the application, rule constraint loss function is designated as LG^REG, main purpose is to maintain oversubscription The Space Consistency of resolution image, determination mode is as follows：

(3) the mean square deviation loss function of the Pixel-level is according to the super-resolution image sample and the true picture Sample determines.

In the concrete application scene of the application, the mean square deviation loss function of Pixel-level is designated as LG^MSE, computing formula is such as Under：

Wherein, I^HRRepresent high-resolution true picture, I^SRRepresent the image after superresolution processing.

Based on above-mentioned function, the preferred embodiment of the application, can be according to difference when the loss function of network is generated Function distributes different weights for the accuracy of super-resolution image, and specific weighted value can be by technical staff according to reality Applicable cases are configured, and these belong to the protection domain of the application.

Above content describes the concrete generating mode of the loss function for generating network, and another in the application is preferable to carry out In example, the loss function for differentiating network is then based on the mark for distributing for true picture sample and super-resolution image sample in advance Sign and differentiate the differentiation probability generation that network is drawn after these images are input into respectively.One in the application is embodied as In example, it is assumed that the loss function for differentiating network is LD, then its corresponding determination mode is as follows：

Wherein, a_iInput label is represented, 1 represents true picture, and 0 represents super-resolution image；y_iRepresent and differentiate network output Class probability.

Based on the loss function of the loss function and differentiation network for generating network, the application loses further with these Function pair generates network and differentiates that the configuration parameter of network is adjusted.Here is it should be noted that S301- in the application The adjustment process of S303 is not limited in once, but the degree of optimization and technical staff according to network is directed to super-resolution figure The generation technique required precision of picture repeats necessary number of times, and these belong to the protection domain of the application.

S304, after the adjustment for completing the configuration parameter, receives pending low-resolution image, according to the life The super-resolution image of the low-resolution image is generated into network, and visualization processing is carried out to the super-resolution image.

After the completion of the step of parameter of network to be generated and differentiation network passes through S301-S303 adjustment, by antagonism Network training enables generation network to export real high-definition picture as far as possible.Subsequently when technical staff is needed for low resolution When rate image generates super-resolution image, you can using low-resolution image as input picture to generation network inputs, and with this Generate super-resolution image.Compared to existing Pixel-level error statistics, can preferably retain image detail information, and solve Output high-definition picture grain details unsharp problem when decimation factor is larger.

In order to the technological thought of the present invention is expanded on further, in conjunction with super shown in the training process and Fig. 5 shown in Fig. 4 Image in different resolution determines that flow process is illustrated to technical scheme.

Training sample in each training process of this specific embodiment is to go out N from random cropping in training pictures The picture of Width*Height, such as N are 32, Width=Height=128.These training samples are simultaneously as generation network With the input for differentiating network.As shown in figure 4, the training process workflow proposed by the application specific embodiment, including such as Lower step：

Step one, scaling and normalized.Bicubic interpolation down-sampling is carried out to training sample, decimation factor is 4；So The image after down-sampling is normalized afterwards, i.e., each passage pixel value is divided by 255；As the input data for generating network；

Step 2, generation network propagated forward.According to network structure is generated, forward direction travels through all layers；

Step 3, output super-resolution image, while for differentiating the input of network and generating the costing bio disturbance of network；

Step 4, sample preprocessing.Sample is divided into two sources at this, and one is training sample, each passage pixel value Divided by 255, as true picture, classification 1 is labeled as；Another is the output of step 3, is program as super-resolution image Produce, be different from true picture, be labeled as classification 0；Each class sample N, amount to 2N；

Step 5, differentiation network propagated forward.According to network structure is differentiated, forward direction travels through all layers；

Step 6, output class probability, probit represents that the probability of true picture is higher closer to 1；Probit closer to 0, represent that the probability of super-resolution image is higher；

Step 7, generation network losses function are calculated.Generate network losses function and be designated as LG, it is made up of three parts：

1) the mean square deviation loss function of Pixel-level, is designated as LG^MSE, determination mode is as follows：

Wherein, x, y represent pixel coordinate position in the picture, I^HRRepresent high-resolution true picture, I^SRRepresent super Image after resolution process.

2) loss function is resisted, it is therefore an objective to count the verity of this super-resolution image, be designated as LG^ADV.Its determination mode It is as follows：

Wherein, N is quantity N of sample in step 4, and i represents the numbering of current sample, D (I^SR) represent that super-resolution is defeated Go out image and be input to the output differentiated after network, that is, differentiate the differentiation probability of network, this value is bigger, represent super-resolution output Image is closer to true picture, and antagonism loss function value is less.

3) rule constraint loss function, is designated as LG^REG, main purpose is to maintain the Space Consistency of super-resolution image.Its Determination mode is as follows：

Wherein, I^SR _{X, y}Represent certain pixel in the image after superresolution processing.

Generating network losses function can generate in three partial weightings summation by more than, and concrete mode is as follows：

LG=γ₀LG^MSE+γ₁LG^ADV+γ₂LG^REG

Wherein γ₀Can be with value 0.9, γ₁Can be with value 0.002, γ₂Can be with value 2*10^-8, can specifically adjust these Parameter.

Step 8, generation network back propagation.According to the generation network losses function that step 7 is calculated, back propagation is whole Network is generated, i.e., is generated each network node in network using network losses function pair and is adjusted, in specific applied field Jing Zhong, technical staff can generate the weighted value of network node according to the loss function adjustment；

Step 9, differentiation network losses function are calculated.Differentiate that network losses function is designated as LD, computing formula equation below 1：

Wherein a_iInput label is represented, 1 represents true picture, and 0 represents super-resolution image；y_iRepresent and differentiate network output Differentiation probability；

Step 10, differentiation network back propagation.According to the differentiation network losses function that step 9 is calculated, back propagation is whole Differentiate network, adjustment differentiates network node weighted value；

In actual application process, technical staff can as needed simultaneously execution step seven, eight and step 9, ten, Concrete step performs the protection domain that precedence has no effect on the application.

After configuration parameter is have adjusted for the loss function for generating network and differentiation network, in this specific embodiment Super-resolution image calculation process is as shown in figure 5, comprise the following steps：

Step one, input low-resolution image；

Step 2, normalized, i.e. image each passage pixel value is done to input picture divided by 255；

Step 3, generation network propagated forward.According to network structure is generated, forward direction travels through all layers；

Step 4, output super-resolution image；

Step 5, image viewing, i.e., to the super-resolution image of generation network output, each passage pixel value is multiplied by 255, and fixed point.

By the technical scheme using embodiments above, single-frame imagess super-resolution efect is improve, it is particularly right In the situation that zoom factor is larger, but also the verity of single-frame imagess super resolution image is improved, and be not limited solely to letter Make an uproar ratio.

To reach above technical purpose, the invention allows for a kind of super-resolution image generates equipment as shown in fig. 6, bag Include：

Preset module 610, pre-sets generation network and differentiates network, the generation network and the differentiation network Type be deep neural network；

Input module 620, the oversubscription after true picture sample is input into into the generation network to export super-resolution processing Resolution image pattern；

Acquisition module 630, obtains the differentiation network and is input into the true picture sample and the super-resolution respectively The differentiation probability exported after rate image pattern, it is the general of true picture that the differentiation probability is the input picture of the differentiation network Rate；

Determining module 640, according to the true picture sample, super-resolution image sample and the differentiation determine the probability Generate network losses function and differentiate network losses function, and according to the generation network losses function and the differentiation net Network loss function is adjusted to the configuration parameter of the generation network and the differentiation network；

Generation module 650, after the adjustment for completing the configuration parameter, receives pending low-resolution image, root The super-resolution image of the low-resolution image is generated according to the generation network, and the super-resolution image is carried out visually Change is processed；

Wherein, when the loss function of the generation network is less, the super-resolution image exported with the generation network Validity it is higher；

When the loss function of the differentiation network is less, the accuracy of the differentiation probability for differentiating network output is higher.

In specific application scenarios, the loss function for generating network is damaged according to antagonism loss function, rule constraint The mean square deviation loss function for losing function and Pixel-level is generated, wherein：

The antagonism loss function is according to sentencing that the differentiation network is exported after the super-resolution image sample is input into Other probability is generated；

The rule constraint function determines according to the Space Consistency of the super-resolution image sample；

The mean square deviation loss function of the Pixel-level is according to the super-resolution image sample and the true picture sample This determination.

In specific application scenarios, also include：

Label model, respectively described true picture sample and the super-resolution image sample arrange label；

Wherein, the label of the true picture sample puts 1, and the label of the super-resolution image sample sets to 0.

In specific application scenarios, the loss function for differentiating network is according to the label of all image patterns and each Described image sample is generated in the differentiation probability through the differentiation network output.

In specific application scenarios, the true picture sample be input into it is described generation network before zoom in and out process with And normalized；The low-resolution image is normalized before the generation network is input into.

As can be seen here, by the technical scheme using the application, after pre-setting generation network and differentiating network, will The input of true picture sample generates network to export super-resolution image sample, and obtains differentiation network respectively in the true figure of input The differentiation probability exported after decent and super-resolution image sample, according to true picture sample, super-resolution image sample And differentiate determine the probability generate network losses function and differentiate network losses function, according to generate network losses function and Differentiate that network losses function pair generates network and differentiates that the configuration parameter of network is adjusted.When the tune for completing configuration parameter After whole, pending low-resolution image is received, can be according to the super-resolution figure for generating network generation low-resolution image Picture, and visualization processing is carried out to super-resolution image.So as to significantly improve image super-resolution effect and super-resolution figure The verity of picture.

Through the above description of the embodiments, those skilled in the art can be understood that the present invention can lead to Cross hardware realization, it is also possible to realize by the mode of software plus necessary general hardware platform.Based on such understanding, this Bright technical scheme can be embodied in the form of software product, and the software product can be stored in a non-volatile memories In medium (can be CD-ROM, USB flash disk, portable hard drive etc.), including some instructions are used so that a computer equipment (can be Personal computer, server, or network equipment etc.) perform method described in each implement scene of the invention.

It will be appreciated by those skilled in the art that accompanying drawing is a schematic diagram for being preferable to carry out scene, module in accompanying drawing or Flow process is not necessarily implemented necessary to the present invention.

It will be appreciated by those skilled in the art that the module in the device in implement scene can according to implement scene describe into Row is distributed in the device of implement scene, it is also possible to carry out one or more dresses that respective change is disposed other than this implement scene In putting.The module of above-mentioned implement scene can merge into a module, it is also possible to be further split into multiple submodule.

The invention described above sequence number is for illustration only, does not represent the quality of implement scene.

Disclosed above is only that the several of the present invention are embodied as scene, but, the present invention is not limited to this, Ren Heben What the technical staff in field can think change should all fall into protection scope of the present invention.

Claims (10)

1. a kind of super-resolution image generation method, it is characterised in that pre-set generation network and differentiate network, the life Type into network and the differentiation network is deep neural network, and the method also includes：

Super-resolution image sample after true picture sample is input into into the generation network to export super-resolution processing；

Obtain the differentiation network to export after the true picture sample and the super-resolution image sample is input into respectively Differentiation probability, the differentiation probability be it is described differentiation network input picture for true picture probability；

Network losses function is generated according to the true picture sample, super-resolution image sample and the differentiation determine the probability And differentiate network losses function, and according to the generation network losses function and the differentiation network losses function pair The configuration parameter for generating network and the differentiation network is adjusted；

After the adjustment for completing the configuration parameter, pending low-resolution image is received, according to the generation network life Into the super-resolution image of the low-resolution image, and visualization processing is carried out to the super-resolution image；

Wherein, it is described to generate the true of the super-resolution image that network is exported when the loss function of the generation network is less Degree is higher；

When the loss function of the differentiation network is less, the accuracy of the differentiation probability for differentiating network output is higher.

2. the method for claim 1, it is characterised in that the loss function of the generation network is according to antagonism loss letter The mean square deviation loss function of number, rule constraint loss function and Pixel-level is generated, wherein：

The antagonism loss function is general according to the differentiation that the differentiation network is exported after the super-resolution image sample is input into Rate is generated；

The rule constraint function determines according to the Space Consistency of the super-resolution image sample；

The mean square deviation loss function of the Pixel-level is true according to the super-resolution image sample and the true picture sample It is fixed.

3. the method as described in any one of claim 1 or 2, it is characterised in that true picture sample is input into into the generation Network to export super-resolution processing after super-resolution image sample after, also include：

Respectively described true picture sample and the super-resolution image sample arrange label；

Wherein, the label of the true picture sample puts 1, and the label of the super-resolution image sample sets to 0.

4. method as claimed in claim 3, it is characterised in that

The loss function for differentiating network is according to the label and each described image sample of all image patterns through described The differentiation probability for differentiating network output is generated.

5. method as claimed in claim 4, it is characterised in that

The true picture sample zooms in and out process and normalized before the generation network is input into；

The low-resolution image is normalized before the generation network is input into.

6. a kind of super-resolution image generates equipment, it is characterised in that include：

Preset module, pre-sets generation network and differentiates the type of network, the generation network and the differentiation network It is deep neural network；

Input module, the super-resolution image after true picture sample is input into into the generation network to export super-resolution processing Sample；

Acquisition module, obtains the differentiation network and is input into the true picture sample and the super-resolution image sample respectively The differentiation probability exported after this, the differentiation probability is the probability of the input picture for true picture of the differentiation network；

Determining module, according to the true picture sample, super-resolution image sample and the differentiation determine the probability net is generated Network loss function and differentiation network losses function, and according to the generation network losses function and differentiate network losses function The configuration parameter of the generation network and the differentiation network is adjusted；

Generation module, after the adjustment for completing the configuration parameter, receives pending low-resolution image, according to the life The super-resolution image of the low-resolution image is generated into network, and visualization processing is carried out to the super-resolution image；

Wherein, when the loss function of the generation network is less, with described the true of the super-resolution image that network is exported is generated Solidity is higher；

When the loss function of the differentiation network is less, the accuracy of the differentiation probability for differentiating network output is higher.

7. equipment as claimed in claim 6, it is characterised in that the loss function of the generation network is according to antagonism loss letter The mean square deviation loss function of number, rule constraint loss function and Pixel-level is generated, wherein：

The antagonism loss function is general according to the differentiation that the differentiation network is exported after the super-resolution image sample is input into Rate is generated；

The rule constraint function determines according to the Space Consistency of the super-resolution image sample；

The mean square deviation loss function of the Pixel-level is true according to the super-resolution image sample and the true picture sample It is fixed.

8. the equipment as described in any one of claim 6 or 7, it is characterised in that also include：

Label model, respectively described true picture sample and the super-resolution image sample arrange label；

Wherein, the label of the true picture sample puts 1, and the label of the super-resolution image sample sets to 0.

9. equipment as claimed in claim 8, it is characterised in that

The loss function for differentiating network is according to the label and each described image sample of all image patterns through described The differentiation probability for differentiating network output is generated.

10. equipment as claimed in claim 9, it is characterised in that

The true picture sample zooms in and out process and normalized before the generation network is input into；

The low-resolution image is normalized before the generation network is input into.